[Federal Register Volume 68, Number 100 (Friday, May 23, 2003)]
[Proposed Rules]
[Pages 28328-28603]
From the Federal Register Online via the Government Publishing Office [www.gpo.gov]
[FR Doc No: 03-9737]
[[Page 28327]]
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Part II
Environmental Protection Agency
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40 CFR Parts 69, 80, 89, et al.
Control of Emissions of Air Pollution From Nonroad Diesel Engines and
Fuel; Proposed Rule
Federal Register / Vol. 68, No. 100 / Friday, May 23, 2003 / Proposed
Rules
[[Page 28328]]
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ENVIRONMENTAL PROTECTION AGENCY
40 CFR Parts 69, 80, 89, 1039, 1065, and 1068
[AMS-FRL-7485-8]
RIN 2060-AK27
Control of Emissions of Air Pollution From Nonroad Diesel Engines
and Fuel
AGENCY: Environmental Protection Agency (EPA).
ACTION: Notice of proposed rulemaking.
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SUMMARY: Nonroad diesel engines contribute considerably to our nation's
air pollution. These engines, used primarily in construction,
agricultural, and industrial applications, are projected to continue to
contribute large amounts of particulate matter (PM), nitrogen oxides
(NOX), and sulfur oxides (SOX), all of which
contribute to serious public health problems in the United States.
These problems include premature mortality, aggravation of respiratory
and cardiovascular disease, aggravation of existing asthma, acute
respiratory symptoms, chronic bronchitis, and decreased lung function.
We believe that diesel exhaust is likely to be carcinogenic to humans
by inhalation.
Today EPA is proposing new emission standards for nonroad diesel
engines and sulfur reductions in nonroad diesel fuel that will
dramatically reduce emissions attributed to nonroad diesel engines.
This comprehensive national program will regulate nonroad diesel
engines and diesel fuel as a system. New engine standards will begin to
take effect in the 2008 model year. These standards are based on the
use of advanced exhaust emission control devices. We estimate PM
reductions of 95%, NOX reductions of 90%, and the virtual
elimination of sulfur oxides (SOX) from nonroad engines
meeting the new standards. Nonroad diesel fuel sulfur reductions of up
to 99% from existing levels will provide significant health benefits as
well as facilitate the introduction of high-efficiency catalytic
exhaust emission control devices as these devices are damaged by
sulfur. These fuel controls would begin in mid-2007. Today's nonroad
proposal is largely based on EPA's 2007 highway diesel program.
To better ensure the benefits of the standards are realized in-use
and throughout the useful life of these engines, we are also proposing
new test procedures, including not-to-exceed requirements, and related
certification requirements. The proposal also includes provisions to
facilitate the transition to the new engine and fuel standards and to
encourage the early introduction of clean technologies and clean
nonroad diesel fuel. We have also developed provisions for both the
proposed engine and fuel programs designed to address small business
considerations.
The requirements in this proposal would result in substantial
benefits to public health and welfare and the environment through
significant reductions in emissions of NOX and PM, as well
as nonmethane hydrocarbons (NMHC), carbon monoxide (CO), sulfur oxides
(SOX) and air toxics. We project that by 2030, this program
would reduce annual emissions of NOX, and PM by 827,000 and
127,000 tons, respectively. These emission reductions would prevent
9,600 premature deaths, over 8,300 hospitalizations, and almost a
million work days lost, and other quantifiable benefits every year. All
told the benefits of this rule would be approximately $81 billion
annually by 2030. Costs for both the engine and fuel requirements would
be many times less, at approximately $1.5 billion annually.
DATES: Comments: Send written comments on this proposal by August 20,
2003. See section IX for more information about written comments.
Hearings: We will hold public hearings on the following dates: June
10, 2003; June 12, 2003; and June 17, 2003. Each hearing will start at
9 a.m. local time. If you want to testify at a hearing, notify the
contact person listed below at least 10 days before the hearing. See
section IX for more information about public hearings.
ADDRESSES: Comments: Comments may be submitted by mail to: Air Docket,
Environmental Protection Agency, Mailcode: 6102T, 1200 Pennsylvania
Ave., NW., Washington, DC 20460, Attention Docket ID No. A-2001-28.
Comments may also be submitted electronically, by facsimile, or
through hand delivery/courier. Follow the detailed instructions as
provided in section IX of the SUPPLEMENTARY INFORMATION section.
Hearings: We will hold public hearings at the following three
locations:
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New York, New York, Park Central New York, June 10, 2003
870 Seventh Avenue at 56th Street, New York,
NY 10019, Telephone: (212) 247-8000, Fax:
(212) 541-8506.
Chicago, Illinois, Hyatt Regency O'Hare, 9300 June 12, 2003.
W. Bryn Mawr Avenue, Rosemont, IL 60018,
Telephone: (847) 696-1234, Fax: (847) 698-
0139.
Los Angeles. California, Hyatt Regency Los June 17, 2003.
Angeles, 711 South Hope Street, Los Angeles,
California, USA. 90017, Telephone: (213) 683-
1234, Fax: (213) 629-3230.
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See section IX, ``Public Participation'' below for more information
on the comment procedure and public hearings.
FOR FURTHER INFORMATION CONTACT: U.S. EPA, Office of Transportation and
Air Quality, Assessment and Standards Division hotline, (734) 214-4636,
[email protected]. Carol Connell, (734) 214-4349; [email protected].
SUPPLEMENTARY INFORMATION:
Regulated Entities
This action would affect you if you produce or import new heavy-
duty diesel engines which are intended for use in nonroad vehicles such
as agricultural and construction equipment, or produce or import such
nonroad vehicles, or convert heavy-duty vehicles or heavy-duty engines
used in nonroad vehicles to use alternative fuels. It would also affect
you if you produce, import, distribute, or sell nonroad diesel fuel, or
sell nonroad diesel fuel.
The following table gives some examples of entities that may have
to follow the regulations. But because these are only examples, you
should carefully examine the regulations in 40 CFR parts 80, 89, 1039,
1065, and 1068. If you have questions, call the person listed in the
FOR FURTHER INFORMATION CONTACT section of this preamble:
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NAICS SIC
Category codes codes Examples of potentially regulated entities
\a\ \b\
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Industry...................................... 333618 3519 Manufacturers of new nonroad diesel engines.
[[Page 28329]]
Industry...................................... 333111 3523 Manufacturers of farm machinery and equipment.
Industry...................................... 333112 3524 Manufacturers of lawn and garden tractors (home).
Industry...................................... 333924 3537 Manufacturers of industrial trucks.
Industry...................................... 333120 3531 Manufacturers of construction machinery.
Industry...................................... 333131 3532 Manufacturers of mining machinery and equipment.
Industry...................................... 333132 3533 Manufacturers of oil and gas field machinery and equipment.
Industry...................................... 811112 7533 Commercial importers of vehicles and vehicle components.
811198 7549
Industry...................................... 324110 2911 Petroleum refiners.
Industry...................................... 422710 5171 Diesel fuel marketers and distributors.
422720 5172
Industry...................................... 484220 4212 Diesel fuel carriers.
484230 4213
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\a\ North American Industry Classification System (NAICS).
\b\ Standard Industrial Classification (SIC) system code.
How Can I Get Copies of This Document and Other Related Information?
Docket. EPA has established an official public docket for this
action under Docket ID No. A-2001-28. The official public docket
consists of the documents specifically referenced in this action, any
public comments received, and other information related to this action.
Although a part of the official docket, the public docket does not
include Confidential Business Information (CBI) or other information
whose disclosure is restricted by statute. The official public docket
is the collection of materials that is available for public viewing at
the Air Docket in the EPA Docket Center, (EPA/DC) EPA West, Room B102,
1301 Constitution Ave., NW., Washington, DC. The EPA Docket Center
Public Reading Room is open from 8:30 a.m. to 4:30 p.m., Monday through
Friday, excluding legal holidays. The telephone number for the Reading
Room is (202) 566-1742, and the telephone number for the Air Docket is
(202) 566-1742.
Electronic Access. You may access this Federal Register document
electronically through the EPA Internet under the ``Federal Register''
listings at http://www.epa.gov/fedrgstr/.
An electronic version of the public docket is available through
EPA's electronic public docket and comment system, EPA Dockets. You may
use EPA Dockets at http://www.epa.gov/edocket/ to submit or view public
comments, access the index listing of the contents of the official
public docket, and to access those documents in the public docket that
are available electronically. Once in the system, select ``search,''
then key in the appropriate docket identification number.
Certain types of information will not be placed in the EPA Dockets.
Information claimed as CBI and other information whose disclosure is
restricted by statute, which is not included in the official public
docket, will not be available for public viewing in EPA's electronic
public docket. EPA's policy is that copyrighted material will not be
placed in EPA's electronic public docket but will be available only in
printed, paper form in the official public docket. To the extent
feasible, publicly available docket materials will be made available in
EPA's electronic public docket. When a document is selected from the
index list in EPA Dockets, the system will identify whether the
document is available for viewing in EPA's electronic public docket.
Although not all docket materials may be available electronically, you
may still access any of the publicly available docket materials through
the docket facility identified in section IX.
For public commenters, it is important to note that EPA's policy is
that public comments, whether submitted electronically or in paper,
will be made available for public viewing in EPA's electronic public
docket as EPA receives them and without change, unless the comment
contains copyrighted material, CBI, or other information whose
disclosure is restricted by statute. When EPA identifies a comment
containing copyrighted material, EPA will provide a reference to that
material in the version of the comment that is placed in EPA's
electronic public docket. The entire printed comment, including the
copyrighted material, will be available in the public docket.
Public comments submitted on computer disks that are mailed or
delivered to the docket will be transferred to EPA's electronic public
docket. Public comments that are mailed or delivered to the Docket will
be scanned and placed in EPA's electronic public docket. Where
practical, physical objects will be photographed, and the photograph
will be placed in EPA's electronic public docket along with a brief
description written by the docket staff.
For additional information about EPA's electronic public docket
visit EPA Dockets online or see 67 FR 38102, May 31, 2002.
Outline of This Preamble
I. Overview
A. What Is EPA Proposing?
1. Nonroad Diesel Engine Emission Standards
2. Nonroad, Locomotive, and Marine Diesel Fuel Quality Standards
B. Why Is EPA Making This Proposal?
1. Nonroad, Locomotive, and Marine Diesels Contribute to Serious
Air Pollution Problems
2. Technology and Fuel Based Solutions
3. Basis For Action Under the Clean Air Act
II. What Is the Air Quality Impact of the Sources Covered by the
Proposed Rule?
A. Overview
B. Public Health Impacts
1. Particulate Matter
a. Health Effects of PM2.5 and PM10
b. Current and Projected Levels
i. PM10 Levels
ii. PM2.5 Levels
2. Air Toxics
a. Diesel exhaust
i. Potential Cancer Effects of Diesel Exhaust
ii. Other Health Effects of Diesel Exhaust
iii. Ambient Levels and Exposure to Diesel Exhaust PM
iv. Diesel Exhaust PM Exposures
b. Gaseous Air Toxics
3. Ozone
a. What are the health effects of ozone pollution?
b. Current and projected 8-hour ozone levels
C. Other Environmental Effects
1. Visibility
a. Visibility is Impaired by Fine PM and Precursor Emissions
From Nonroad Engines Subject to this Proposed Rule
b. Visibility Impairment Where People Live, Work and Recreate
[[Page 28330]]
c. Visibility Impairment in Mandatory Federal Class I Areas
2. Acid Deposition
3. Eutrophication and Nitrification
4. Polycyclic Organic Matter Deposition
5. Plant Damage from Ozone
D. Other Criteria Pollutants Affected by This NPRM
E. Emissions From Nonroad Diesel Engines
1. PM2.5
2. NOX
3. SO2
4. VOC and Air Toxics
III. Nonroad Engine Standards
A. Why are We Setting New Engine Standards?
1.The Clean Air Act and Air Quality
2. The Technology Opportunity for Nonroad Diesel Engines
B. What Engine Standards are We Proposing?
1. Exhaust Emissions Standards
a. Standards Timing
b. Phase-In of NOX and NMHC Standards
c. Rationale for Restructured Horsepower Categories
d. PM Standards for Smaller Engines
i. <25 hp
ii. 25-75 hp
e. Engines Above 750 hp
f. CO Standards
g. Exclusion of Marine Engines
2. Crankcase Emissions Control
C. What Test Procedure Changes Are Being Proposed?
1. Supplemental Transient Test
2. Cold Start Testing
D. What Is Being Done To Help Ensure Robust Control In Use?
1. Not-to-Exceed Requirements
a. NTE Standards We are Proposing
b. Comment Request on an Alternative NTE Approach
2. Plans for Future In-Use Testing and Onboard Diagnostics
a. Manufacturer-Run In-Use Test Program
b. Onboard Diagnostics
E. Are the Proposed New Standards Feasible?
1.Technologies To Control NOX and PM Emissions From
Mobile Source Diesel Engines
a. PM Control Technologies
b. NOX Control Technologies
2. Can These Technologies Be Applied to Nonroad Engines and
Equipment?
a. Nonroad Operating Conditions and Exhaust Temperatures
b. Nonroad Operating Conditions and Durability
3. Are the Standards Proposed for Engines of 75 hp or Higher
Feasible?
4.Are the Standards Proposed for Engines =25 hp and
<75 hp Feasible?
a. What makes the 25-75 hp category unique?
b. What engine technology is used today, and will be used for
the applicable Tier 2 and Tier 3 standards?
c. Are the proposed standards for 25-75 hp engines
technologically feasible?
i. 2008 PM Standards
ii. 2013 Standards
d. Why EPA has not proposed more stringent Tier 4 NOX
standards
5. Are the Standards Proposed for Engines <25 hp Feasible?
a. What makes the < 25 hp category unique?
b. What engine technology is currently used in the <25 hp
category?
c. What data indicates that the proposed standards are feasible?
d. Why has EPA not proposed more stringent PM or NOX
standards for engines <25 hp?
6. Meeting the Crankcase Emissions Requirements
F. Why Do We Need 15ppm Sulfur Diesel Fuel?
1. Catalyzed Diesel Particulate Filters and the Need for Low
Sulfur Fuel
a. Inhibition of Trap Regeneration Due to Sulfur
b. Loss of PM Control Effectiveness
c. Increased Maintenance Cost for Diesel Particulate Filters Due
to Sulfur
2. Diesel NOX Catalysts and the Need for Low Sulfur
Fuel
a. Sulfur Poisoning (Sulfate Storage) on NOX
Adsorbers
b. Sulfate Particulate Production and Sulfur Impacts on
Effectiveness of NOX Control Technologies
G. Reassessment of Control Technology for Engines Less Than 75
hp in 2007
IV. Our Proposed Program for Controlling Nonroad, Locomotive and
Marine Diesel Fuel Sulfur
A. Proposed Nonroad, Locomotive and Marine Diesel Fuel Quality
Standards
1. What Fuel Is Covered by this Proposal?
2. Standards and Deadlines for Refiners, Importers, and Fuel
Distributors
a. The First Step to 500 ppm
b. The Second Step to 15 ppm
c. Other Standard Provisions
d. Cetane Index or Aromatics Standard
B. Program Design and Structure
1. Background
2. Proposed Fuel Program Design and Structure
a. Program Beginning June 1, 2007
i. Use of a Marker To Differentiate Heating Oil from NRLM
ii. Non-highway Distillate Baseline Cap
iii. Setting the Non-highway Distillate Baseline
iv. Diesel Sulfur Credit Banking, and Trading Provisions for
2007
b. 2010
i. A Marker To Differentiate Locomotive and Marine Diesel from
Nonroad Diesel
ii. Diesel Sulfur Credit Banking and Trading Provisions for 2010
c. 2014
3. Other Options Considered
a. Highway Baseline and a NRLM baseline for 2007
i. Highway Baseline
ii. Nonroad, Locomotive, and Marine Baseline
iii. Combined Impact of Highway and NRLM Baselines
b. Locomotive and Marine Baseline for 2010
c. Designate and Track Volumes in 2007
i. Replacement for the Non-highway Baseline Approach
ii. Designate and Track as a Refiners Option in Addition to the
Baseline Approach
C. Hardship Provisions for Qualifying Refiners
1. Hardship Provisions for Qualifying Small Refiners
a. Qualifying Small Refiners
i. Regulatory Flexibility for Small Refiners
ii. Rationale for Small Refiner Provisions
iii. Limited Impact of Small Refiner Options on Program
Emissions Benefits
b. How Do We Define Small Refiners for Purposes of the Hardship
Provisions?
c. What Options Are Available for Small Refiners?
i. Delays in Nonroad Fuel Sulfur Standards for Small Refiners
ii. Options to Encourage Earlier Compliance by Small Refiners
d. How Do Refiners Apply for Small Refiner Status?
2. General Hardship Provisions
a. Temporary Waivers From Non-highway Diesel Sulfur Requirements
in Extreme Unforeseen Circumstances
b. Temporary Waivers Based on Extreme Hardship Circumstances
D. Should Any Individual States or Territories Be Excluded From
This Rule?
1. Alaska
a. How Was Alaska Treated Under the Highway Diesel Standards?
b. What Nonroad Standards Do We Propose for Urban Areas of
Alaska?
c. What Do We Propose for Rural Areas of Alaska?
2. American Samoa, Guam, and the Commonwealth of Northern
Mariana Islands
a. What Provisions Apply in American Samoa, Guam, and the
Commonwealth of Northern Mariana Islands?
b. Why Are We Treating These Territories Uniquely?
E. How Are State Diesel Fuel Programs Affected by the Sulfur
Diesel Program?
F. Technological Feasibility of the 500 and 15 ppm Sulfur Diesel
Fuel Program
1. What Is the Nonroad, Locomotive and Marine Diesel Fuel Market
Today?
2. How Do Nonroad, Locomotive and Marine Diesel Fuel Differ From
Highway Diesel Fuel?
3. What Technology Would Refiners Use To Meet the Proposed 500
ppm Sulfur Cap?
4. Has Technology To Meet a 500 ppm Cap Been Commercially
Demonstrated?
5. Availability of Leadtime To Meet the 2007 500 ppm Sulfur Cap
6. What Technology Would Refiners Use To Meet the Proposed 15
ppm Sulfur Cap for Nonroad Diesel Fuel?
7. Has Technology To Meet a 15 ppm Cap Been Commercially
Demonstrated?
8. Availability of Leadtime To Meet the 2010 15 ppm Sulfur Cap
9. Feasibility of Distributing Nonroad, Locomotive and Marine
Diesel Fuels That Meet the Proposed Sulfur Standards
a. Limiting Sulfur Contamination
b. Potential Need for Additional Product Segregation
G. What Are the Potential Impacts of the 15 ppm Sulfur Diesel
Program on Lubricity and Other Fuel Properties?
1. What Is Lubricity and Why Might It Be a Concern?
2. A Voluntary Approach on Lubricity
[[Page 28331]]
3. What Other Impact Would Today's Actions Have on the
Performance of Diesel and Other Fuels?
H. Refinery Air Permitting
V. Economic Impacts
A. Refining and Distribution Costs
1. Refining Costs
2. Cost of Lubricity Additives
3. Distribution Costs
4. How EPA's Projected Costs Compare to Other Available
Estimates
5. Supply of Nonroad, Locomotive and Marine Diesel Fuel
6. Fuel Prices
B. Cost Savings to the Existing Fleet From the Use of Low Sulfur
Fuel
C. Engine and Equipment Cost Impacts
1. Engine Cost Impacts
a. Engine Fixed Costs
i. Engine and Emission Control Device R&D
ii. Engine-Related Tooling Costs
iii. Engine Certification Costs
b. Engine Variable Costs
i. NOX Adsorber System Costs
ii. Catalyzed Diesel Particulate Filter (CDPF) Costs
iii. CDPF Regeneration System Costs
iv. Closed-Crankcase Ventilation System (CCV) Costs
v. Variable Costs for Engines Below 75 Horsepower and Above 750
Horsepower
c. Engine Operating Costs
2. Equipment Cost Impacts
a. Equipment Fixed Costs
b. Equipment Variable Costs
3. Overall Engine and Equipment Cost Impacts
D. Annual Costs and Cost Per Ton
1. Annual Costs for the 500 ppm Fuel Program
2. Cost Per Ton for the 500 ppm Fuel Program
3. Annual Costs for the Proposed Two-Step Fuel Program and
Engine Program
4. Cost per Ton of Emissions Reduced for the Total Program
5. Comparison With Other Means of Reducing Emissions
E. Do the Benefits Outweigh the Costs of the Standards?
1. What were the results of the benefit-cost analysis?
2. What was our overall approach to the benefit-cost analysis?
3. What are the significant limitations of the benefit-cost
analysis?
F. Economic Impact Analysis
1. What is an Economic Impact Analysis?
2. What is EPA's Economic Analysis Approach for This Proposal?
3. What Are the Results of This Analysis?
a. Expected Market Impacts
b. Expected Welfare Impacts
VI. Alternative Program Options
A. Summary of Alternatives
B. Introduction of 15 ppm Nonroad Diesel Sulfur Fuel in One Step
1. Description of the One-Step Alternative
2. Engine Emission Impacts
3. Fuel Impacts
4. Emission and Benefit Impacts
C. Applying 15 ppm Requirement to Locomotive and Marine Diesel
Fuel
D. Other Alternatives
VII. Requirements for Engine and Equipment Manufacturers
A. Averaging, Banking, and Trading
1. Are we proposing to keep the ABT program for nonroad diesel
engines?
2. What are the provisions of the proposed ABT program?
3. Should we expand the nonroad ABT program to include credits
from retrofit of nonroad engines?
a. What would be the environmental impact of allowing ABT
nonroad retrofit credits?
b. How would EPA ensure compliance with retrofit emissions
standards?
c. What is the legal authority for a nonroad ABT retrofit
program?
B. Transition Provisions for Equipment Manufacturers
1. Why are we proposing transition provisions for equipment
manufacturers?
2. What transition provisions are we proposing for equipment
manufacturers?
a. Percent-of-Production Allowance
b. Small-Volume Allowance
c. Hardship Relief Provision
d. Existing Inventory Allowance
3. What are the recordkeeping, notification, reporting, and
labeling requirements associated with the equipment manufacturer
transition provisions?
a. Recordkeeping Requirements for Engine and Equipment
Manufacturers
b. Notification Requirements for Equipment Manufacturers
c. Reporting Requirements for Engine and Equipment Manufacturers
d. Labeling Requirements for Engine and Equipment Manufacturers
4. What are the proposed requirements associated with use of
transition provisions for equipment produced by foreign
manufacturers?
C. Engine and Equipment Small Business Provisions (SBREFA)
1. Nonroad Diesel Small Engine Manufacturers
a. Lead Time Transition Provisions for Small Engine
Manufacturers
i. What the Panel Recommended
ii. What EPA Is Proposing
b. Hardship Provisions for Small Engine Manufacturers
i. What the Panel Recommended
ii. What EPA Is Proposing
c. Other Small Engine Manufacturer Issues
i. What the Panel Recommended
ii. What EPA Is Proposing
2. Nonroad Diesel Small Equipment Manufacturers
a. Transition Provisions for Small Equipment Manufacturers
i. What the Panel Recommended
ii. What EPA Is Proposing
b. Hardship Provisions for Small Equipment Manufacturers
i. What the Panel Recommended
ii. What EPA is Proposing
D. Phase-In Provisions
E. What Might Be Done To Encourage Innovative Technologies?
1. Incentive Program for Early or Very Low Emission Engines
2. Continuance of the Existing Blue Sky Program
F. Provisions for Other Test and Measurement Changes
1. Supplemental Transient Test
2. Cold Start Testing
3. Control of Smoke
4. Steady-State Testing
5. Maximum Test Speed
6. Improvements to the Test Procedures
G. Not-To-Exceed Requirements
H. Certification Fuel
I. Labeling and Notification Requirements
J. Temporary In-Use Compliance Margins
K. Defect Reporting
L. Rated Power
M. Hydrocarbon Measurement and Definition
N. Auxiliary Emission Control Devices and Defeat Devices
O. Other Issues
VIII. Nonroad Diesel Fuel Program: Compliance and Enforcement
Provisions
A. Fuel Covered and Not Covered by This Proposal
1. Covered Fuel
2. Special Fuel Provisions and Exemptions
a. Fuel Used in Military Applications
b. Fuel Used in Research and Development
c. Fuel Used in Racing Equipment
d. Fuel for Export
B. Additional Requirements for Refiners and Importers
1. Transfer of Credits
2. Additional Provisions for Importers and Foreign Refiners
Subject to the Credit Provisions or Hardship Provisions
3. Proposed Provisions for Transmix Facilities
4. Highway or Nonroad Diesel Fuel Treated as Blendstock (DTAB)
C. Requirements for Parties Downstream of the Refinery or Import
Facility
1. Product Segregation and Contamination
a. The Period From June 1, 2007 Through May 31, 2010
b. The Period From June 1, 2010 Through May 31, 2014
c. After May 31, 2014
2. Diesel Fuel Pump Labeling To Discourage Misfueling
a. Pump Labeling Requirements 2006
b. Pump Labeling Requirements 2007-2010
c. Pump Labeling Requirements 2010-2014
d. Pump Labeling Requirements Beginning June 1, 2014
e. Nozzle Size Requirements or Other Requirements To Prevent
Misfueling
3. Use of Used Motor Oil in New Nonroad Diesel Equipment
4. Use of Kerosene in Diesel Fuel
5. Use of Diesel Fuel Additives
6. End User Requirements
7. Anti-Downgrading Provisions
D. Diesel Fuel Sulfur Sampling and Testing Requirements
1. Testing Requirements
a. Test Method Approval, Recordkeeping, and Quality Control
Requirements
i. How Can a Given Method Be Approved?
ii. What Information Would Have To Be Reported to the Agency?
iii. What Quality Control Provisions Would Be Required?
b. Requirements To Conduct Fuel Sulfur Testing.
2. Two Part-Per-Million Downstream Sulfur Measurement Adjustment
3. Sampling Requirements
4. Alternative Sampling and Testing Requirements for Importers
of Diesel
[[Page 28332]]
Fuel Who Transport Diesel Fuel by Tanker Truck
E. Fuel Marker Test Method
1. How Can a Given Marker Test Method Be Approved?
2. What Information Would Have To Be Reported to the Agency?
F. Requirements for Recordkeeping, Reporting, and Product
Transfer Documents
1. Registration of Refiners and Importers
2. Application for Small Refiner Status
3. Applying for Refiner Hardship Relief
4. Applying for a Non-Highway Distillate Baseline Percentage
5. Pre-Compliance Reports
6. Annual Compliance Reports and Batch Reports for Refiners and
Importers
7. Product Transfer Documents (PTDs)
a. The Period From June 1, 2007 Through May 31, 2010
b. The Period from June 1, 2010 Through May 31, 2014
c. The Period After May 31, 2014
d. Kerosene and Other Distillates To Reduce Viscosity
e. Exported Fuel
f. Additives
8. Recordkeeping Requirements
9. Record Retention
G. Liability and Penalty Provisions for Noncompliance
1. General
2. What Are the Proposed Liability Provisions for Additive
Manufacturers and Distributors, and Parties That Blend Additives
Into Diesel Fuel?
a. General
b. Liability When the Additive Is Designated as Complying With
the 15 ppm Sulfur Standard
c. Liability When the Additive Is Designated as Having a
Possible Sulfur Content Greater Than 15 ppm
H. How Would Compliance With the Sulfur Standards Be Determined?
IX. Public Participation
A. How and to Whom Do I Submit Comments?
1. Electronically
i. EPA Dockets
ii. E-mail
iii. Disk or CD ROM
2. By Mail
3. By Hand Delivery or Courier
B. How Should I Submit CBI to the Agency?
C. Will There Be a Public Hearing?
D. Comment Period
E. What Should I Consider as I Prepare My Comments for EPA?
X. Statutory and Executive Order Reviews
A. Executive Order 12866: Regulatory Planning and Review
B. Paperwork Reduction Act
C. Regulatory Flexibility Act (RFA), as Amended by the Small
Business Regulatory Enforcement Fairness Act of 1996 (SBREFA), 5
U.S.C. 601 et. seq
1. Overview
2. Background
3. Summary of Regulated Small Entities
a. Nonroad Diesel Engine Manufacturers
b. Nonroad Diesel Equipment Manufacturers
c. Nonroad Diesel Fuel Refiners
d. Nonroad Diesel Fuel Distributors and Marketers
4. Potential Reporting, Record Keeping, and Compliance
5. Relevant Federal Rules
6. Summary of SBREFA Panel Process and Panel Outreach
a. Significant Panel Findings
b. Panel Process
c. Transition Flexibilities
i. Nonroad Diesel Engines
ii. Nonroad Diesel Equipment
iii. Nonroad Diesel Fuel Refiners
iv. Nonroad Diesel Fuel Distributors and Marketers
D. Unfunded Mandates Reform Act
E. Executive Order 13132: Federalism
F. Executive Order 13175: Consultation and Coordination With
Indian Tribal Governments
G. Executive Order 13045: Protection of Children From
Environmental Health and Safety Risks
H. Executive Order 13211: Actions That Significantly Affect
Energy Supply, Distribution, or Use
I. National Technology Transfer Advancement Act
J. Plain Language
XI. Statutory Provisions and Legal Authority
I. Overview
Nonroad diesel engines are the largest remaining contributor to the
overall mobile source emissions inventory. We have already taken steps
to dramatically reduce emissions from light-duty vehicles and heavy-
duty vehicles and engines through the Tier 2 and 2007 highway diesel
programs.\1\ With expected growth in the nonroad sector, the relative
emissions contribution from nonroad diesel engines is projected to be
even larger in future years. This proposed rule sets out emissions
standards for nonroad diesel engines used mainly in construction,
agricultural, industrial, and mining operations that will achieve
reductions in PM and NOX emissions levels from today's
engines in excess of 95% and 90%, respectively. Nonroad diesel fuel is
currently unregulated. This proposal represents the first time nonroad
diesel fuel will be regulated. We are proposing to reduce sulfur levels
in nonroad diesel fuel by more than 99 percent to 15 parts per million
(ppm). Taken together, controls included in this proposal would result
in large public health and welfare benefits.
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\1\ See 65 FR 6698 (February 10, 2000) and 66 FR 5001 (January
18, 2001) for the final rules regarding the Tier 2 and 2007 highway
diesel programs, respectively.
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The proposed standards for nonroad diesel engines and sulfur
reductions for nonroad diesel fuel represent a dramatic step in
emissions control, based on the use of advanced emissions control
technology. Until the mid-90's, these engines had no emissions
requirements. As a comparison, cars and trucks have been subject to a
series of increasingly stringent emissions control programs since the
1970s. In terms of fuel quality requirements, nonroad diesel fuel is
currently uncontrolled at the Federal level. EPA has already issued
rules ending these disparities for diesel engines used in highway
applications. Starting in 2007, these engines will meet standards of
the same level of stringency as comparable gasoline vehicles, based on
the use of advanced aftertreatment technologies and ultra low sulfur
diesel fuel (containing no more than 15 ppm sulfur). This proposal is
largely based on the performance of the same advanced aftertreatment
technologies, and would bring nonroad diesel fuel to the same 15 ppm
cap for sulfur that will be required for highway diesel fuel starting
in 2006. We believe it is highly appropriate to propose dramatic steps
forward in emissions standards and reductions in sulfur levels in
nonroad diesel fuel. As discussed throughout this proposal, such steps
represent a feasible progression in the application of advanced
emissions control technologies, would achieve needed production of low
sulfur diesel fuel to enable the advanced emission control
technologies, the standards are cost-effective, and provide very large
public health and welfare benefits.
We followed certain principles when developing the elements of this
proposal. First, the program must achieve reductions in NOX,
SOx, and PM emissions as early as possible. This includes reductions
from the in-use fleet of nonroad diesel engines. Second, as we did in
the 2007 highway diesel program, we are treating vehicles and fuels as
a system since we believe this is the best way to achieve the greatest
emissions reductions. Third, the implementation of low sulfur
requirements for nonroad diesel fuel must in no way interfere with the
implementation and expected benefits of introducing ultra low sulfur
fuel in the highway market, as required by the 2007 highway diesel
program. Lastly, the program must provide sufficient lead time to allow
the integration of advanced emissions control technologies from the
highway sector onto nonroad diesel engines as well as the expansion of
ultra low sulfur fuel production to the nonroad market.
This proposal sets out new engine exhaust emissions standards,
emissions test procedures, including not-to-exceed requirements, for
nonroad engines, and sulfur control requirements for nonroad,
locomotive, and marine diesel fuel. The proposed exhaust standards
would
[[Page 28333]]
result in particulate matter (PM) and nitrogen oxide (NOX)
emissions levels that are in excess of 95 percent and 90 percent,
respectively, below comparable levels in effect today. They will begin
to take effect in the 2008 model year, with a phase-in of standards
across five different engine power rating groupings. New engine
emissions test procedures are proposed to take effect with these new
standards to better ensure emissions control over real-world engine
operation and to help provide for effective compliance determination.
Diesel fuel used in nonroad, locomotive, and marine applications would
meet a 500 ppm cap starting in June 2007, a reduction of approximately
90%. There are large benefits to taking this first sulfur reduction
action, especially in the reduction of particulate matter from the in-
use fleet. In 2010, sulfur levels in nonroad diesel fuel (though not
locomotive or marine diesel fuel) would meet a 15 ppm cap, for a total
reduction of over 99%. While there are important health and welfare
benefits associated with the reduction from 500 ppm to 15 ppm, the main
benefit will be to facilitate the introduction of advanced
aftertreatment devices on nonroad engines, which would in turn lead to
significant benefits. We are also seeking comment on and seriously
considering applying the 15 ppm cap to locomotive and marine diesel
fuel.
The requirements in this proposal would result in substantial
benefits to public health and welfare and the environment through
significant reductions in emissions of NOX and PM, as well
as nonmethane hydrocarbons (NMHC), carbon monoxide (CO), sulfur oxides
(SOX) and air toxics. We project that by 2030, this program
would reduce annual emissions of NOX, and PM by 827,000, and
127,000 tons, respectively. These annual emission reductions would
prevent 9,600 premature deaths, over 8,300 hospitalizations, and almost
a million work days lost, among quantifiable benefits. The overall
quantifiable benefits of this rule would be approximately $81 billion
annually by 2030. Costs for both the engine and fuel requirements would
be significantly less, at approximately $1.5 billion annually.
A. What Is EPA Proposing?
This proposal is a further step in EPA's long-term program to
control emissions from nonroad diesel engines. The EPA has taken
measures to reduce harmful emissions from nonroad diesel engines in two
past regulatory actions. A 1994 final rule, developed under provisions
of section 213 of the Clean Air Act, set initial emissions standards
for new nonroad diesel engines greater than 50 hp (59 FR 31306, June
17, 1994). These standards gained modest reductions in NOX
emissions and are referred to as EPA's ``Tier 1'' standards for large
nonroad engines. A subsequent final rule published in 1998 set more
stringent Tier 2 and Tier 3 standards for these engines, as well as
Tier 1 and Tier 2 standards for the nonroad diesel engines under 50 hp
(63 FR 56968, October 23, 1998). Nonroad diesel fuel quality is not
presently regulated by the EPA.
We also expressed our intent in the 1998 final rule to continue
evaluating the rapidly changing state of diesel emissions control
technology, and to perform a review in the 2001 timeframe of the
technological feasibility of the Tier 3 standards, and of the Tier 2
standards for engines rated under 50 hp. This review was completed in
2001 and documented in an EPA staff technical paper that confirmed the
feasibility of those standards, finding that the number of potential
control options had expanded since the 1998 final rule to include new
technologies and more effective application of existing
technologies.\2\
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\2\ ``Nonroad Diesel Emissions Standards Staff Technical
Paper'', EPA420-R-01-052, October 2001.
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There are two basic parts to this proposed program: (1) New exhaust
emission standards and test procedures for nonroad diesel engines, and
(2) new sulfur limits for nonroad, locomotive, and marine diesel fuel.
The systems approach of combining the engine and fuel standards into a
single program is critical to the success of our overall efforts to
reduce emissions, because the emission standards will not be feasible
without the fuel change. This proposal is largely based on the 2007
highway diesel program.
We looked at a number of alternative program options, as discussed
in more detail in section VI below and chapter 12 of the draft
Regulatory Impact Analysis (RIA). For example, we analyzed a program
that would require refiners to produce 15 ppm nonroad diesel fuel
starting in 2008, with appropriate engine standards phased-in beginning
in 2009. Many of these alternatives provided a very similar level of
projected emissions control and health and welfare benefits as our
proposed program. However, taking into account the need for appropriate
lead time, achieving the greatest possible emissions reductions as
early as possible, and the interaction of requirements in this proposal
with existing highway diesel engine environmental programs, we believe
our proposed program provides the best opportunity for achieving all of
our goals, as described above, including timely and significant
emissions reductions from nonroad diesel engines and the associated
introduction of ultra low sulfur nonroad diesel fuel. We are asking for
comments on the alternatives discussed in this proposal.
The elements of the rule are outlined below. Detailed provisions
and justifications for our proposed rule are discussed in subsequent
sections and the draft RIA.
1. Nonroad Diesel Engine Emission Standards
Today's action proposes standards for nonroad diesel engines
ranging from 3 to over 3,000 horsepower. Applicable emissions standards
are determined by year for each of five engine power band categories.
For engines less than 25 hp, we are proposing new engine standards for
PM (0.30 g/bhp-hr) and CO (4.9 g/bhp-hr) to go along with existing
NOX standards beginning in 2008. For engines between 25-75
hp, we are proposing standards reflecting approximately 50% reduction
in PM control from today's engines applicable in 2008. Then, starting
in 2013, PM standards of 0.02 g/bhp-hr and NOX standards of
3.5 g/bhp-hr would apply. For engines between 75-175 hp, the proposed
standards would be 0.01 g/bhp-hr for PM, 0.30 g/bhp-hr for
NOX, and 0.14 g/bhp-hr for HC beginning in 2012. These same
standards would apply for both engines between 175-750 hp and greater
than 750 hp starting in 2011. These PM, NOX, and NMHC
standards are similar in stringency to the final standards included in
the 2007 highway diesel program and are expected to require the use of
high-efficiency aftertreatment systems to ensure compliance. Thus,
virtually all nonroad diesel engines after 2013 would likely be using
advanced aftertreatment systems. We are phasing in many of these
proposed standards over a period of three years in order to address
lead time, workload, and feasibility considerations.
We are also proposing to continue the averaging, banking, and
trading nonroad emissions credits provisions to demonstrate compliance
with the standards. In addition, we are proposing to include
turbocharged diesels in the existing prohibition on crankcase
emissions, effective in the same year that the proposed Tier 4
standards first apply in each power category. More specific information
on the proposed standards can be found in section III below.
[[Page 28334]]
To better ensure the benefits of the standards are realized in-use
and throughout the useful life of these engines, we are also proposing
new test procedures and related certification requirements. We believe
the new supplemental transient test, Constant Speed Variable Load
transient duty cycle, cold start transient test, and not-to-exceed test
procedures and standards will all help achieve our goal. This is a
significant and important aspect of this proposal that would bring
greater confidence and certainty to the compliance program.
The proposal also includes provisions to facilitate the transition
to the new engine and fuel standards and to encourage the early
introduction of clean technologies. We are also including proposed
adjustments to various fuel and engine testing and compliance
requirements. These provisions are described further in sections III,
IV, and VI.
2. Nonroad, Locomotive, and Marine Diesel Fuel Quality Standards
We are proposing that sulfur levels for nonroad diesel fuel be
reduced from current uncontrolled levels ultimately to 15 ppm, though
we are proposing an interim cap of 500 ppm. Beginning June 1, 2007,
refiners would therefore be required to produce nonroad, locomotive,
and marine diesel fuel that meets a maximum sulfur level of 500 ppm.
This does not include diesel fuel for home heating, industrial boiler,
or stationary power uses or diesel fuel used in aircraft. We estimate
there are significant health and welfare benefits associated with this
proposed reduction, including reductions in sulfate emissions and
reduced engine operating expenses. Then, beginning in June 1, 2010,
fuel used for nonroad diesel applications (excluding locomotive and
marine engines) is proposed to meet a maximum sulfur level of 15 ppm,
since all 2011 and later model year nonroad diesel-fueled engines with
aftertreatment must be refueled with this new ultra low sulfur diesel
fuel. This sulfur standard is based on our assessment of the impact of
sulfur on advanced exhaust emission control technologies and a
corresponding assessment of the feasibility of ultra low sulfur fuel
production and distribution. We are also asking for comment on bringing
sulfur levels for locomotive and marine fuel to 15 ppm in 2010 and note
that we anticipate beginning the process of developing new engine
controls for these two sources in 2004. This proposal includes a
combination of provisions available to refiners, especially small
refiners, to ensure a smooth transition to ultra low sulfur nonroad
diesel fuel.
In addition, this proposal includes unique provisions for
implementing the ultra low sulfur diesel fuel program in the State of
Alaska. We are also proposing that certain U.S. territories be excluded
from both the nonroad engine standards and diesel fuel standards.
Similar actions were taken as part of the 2007 highway diesel program.
The compliance provisions for ensuring diesel fuel quality are
essentially consistent with those that have been in effect since 1993
for highway diesel fuel, reflecting updated requirements that were
included in the 2007 highway diesel program. Additional compliance
provisions are proposed for the transition years of the program
concerning the interaction of the nonroad, locomotive, and marine
sulfur control requirements with existing highway diesel sulfur control
provisions. These provisions could also help discourage misfueling of
nonroad equipment utilizing high-efficiency aftertreatment devices. The
proposed compliance requirements include provisions that would prohibit
equipment operators from fueling their machines with higher sulfur
fuels after completion of the shift to lower sulfur nonroad diesel
fuels, regardless of the age of their equipment.
B. Why Is EPA Making This Proposal?
1. Nonroad, Locomotive, and Marine Diesels Contribute to Serious Air
Pollution Problems
As discussed in detail in section II and chapter 2 and 3 of draft
RIA, emissions from nonroad, locomotive, and marine diesel engines
contribute greatly to a number of serious air pollution problems, and
these emissions would have continued to do so into the future absent
further controls to reduce them. First, these engines contribute to the
health and welfare effects associated with ozone, PM, NOX,
SOX, and volatile organic compounds (VOCs), including toxic
compounds such as formaldehyde. These adverse effects include premature
mortality, aggravation of respiratory and cardiovascular disease (as
indicated by increased hospital admissions and emergency room visits,
school absences, work loss days, and restricted activity days), changes
in lung function and increased respiratory symptoms, changes to lung
tissues and structures, altered respiratory defense mechanisms, chronic
bronchitis, and decreased lung function.3 4 5 Second and
importantly, in addition to its contribution to ambient PM inventories,
diesel exhaust is of specific concern because it has been judged to
likely pose a lung cancer hazard for humans as well as a hazard from
noncancer respiratory effects. The Agency has classified diesel exhaust
as likely to be carcinogenic to humans by inhalation at environmental
exposures. Third, ozone and PM cause significant public welfare harm.
Specifically, ozone causes damage to vegetation which leads to economic
crop and forestry losses, as well as harm to national parks, wilderness
areas, and other natural systems. PM causes damage to materials and
soiling of commonly used building materials and culturally important
items such as statues and works of art. Fourth, NOX,
SOX and direct emissions of PM contribute to substantial
visibility impairment in many parts of the U.S. where people live,
work, and recreate, including mandatory Federal Class I areas. Finally,
NOX emissions from nonroad diesel engines contribute to the
acidification, nitrification and eutrophication of water bodies.
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\3\ U.S. EPA (1996) Air Quality Criteria for Particulate
Matter--Volumes I, II, and III, EPA Office of Research and
Development, National Center for Environmental Assessment, July
1996. Report No. EPA/600/P-95/001aF, EPA/600/P-95/001bF, EPA/600/P-
95/001cF.
\4\ U.S. EPA (2002), Air Quality Criteria for Particulate
Matter--Volumes I and II (Third External Review Draft). This
material is available electronically at http://cfpub.epa.gov/ncea/
cfm/partmatt.cfm.
\5\ U.S. EPA (1996) Air Quality Criteria for Ozone and Related
Photochemical Oxidants. EPA Office of Research and Development,
National Center for Environmental Assessment, July 1996. Report No.
EPA/600/P-93/004aF. The document is available on the Internet at
http://www.epa.gov/ncea/ozone.htm.
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Millions of Americans live in areas with unhealthful air quality
that may endanger public health and welfare (i.e., levels not requisite
to protect the public health with an adequate margin of safety). Based
upon data for 1999-2001, there are 291 counties that are violating the
8-hour ozone NAAQS, totaling 111 million people. In addition, at least
65 million people in 129 counties live in areas where annual design
values of ambient PM2.5 violate the PM2.5 NAAQS.
There are an additional 9 million people in 20 counties where levels
above the PM2.5 NAAQS are being measured, but the data are
incomplete. Without emission reductions from the proposed new standards
for nonroad engines, there is a significant future risk that 32
counties with 47 million people across the country may violate the 8-
hour ozone national ambient air quality standard (NAAQS) in 2030, based
on our modeling. Similarly, modeled PM2.5 concentrations in
107 counties where 85 million people live are above specified levels in
2030. An additional 64 million people are projected to live in counties
[[Page 28335]]
within 10 percent of the PM2.5 standard in 2030, and 44
million people are projected to live in counties within 10 percent of
the level of the 8-hour standard in 2030. Thus, our analyses show that
these counties face a significant risk of exceeding or failing to
maintain the PM2.5 and the 8-hour ozone NAAQS without
significant additional controls between 2007 and 2030.
Federal, State and local governments are working to bring ozone and
particulate levels into compliance with the NAAQS through State
Implementation Plan (SIP) attainment and maintenance plans, and to
ensure that future air quality reaches and continues to achieve these
health- and welfare-based standards. The reductions in this proposed
rulemaking will play a critical part in these important efforts to
attain and maintain the NAAQS. In addition, reductions from this action
will also reduce public health and welfare effects associated with
maintenance of the 1-hour ozone and PM10 NAAQS.
Emissions from nonroad, locomotive, and marine diesel engines
account for substantial portions of the country's ambient PM and
NOX levels. NOX is a key precursor to ozone and
PM formation. We estimate that these engines account for about ten
percent of total NOX emissions and about ten percent of
total PM emissions. These proportions are even higher in some urban
areas, where these engines contribute up to 19 percent of the total
NOX emissions and up to 18 percent of the total PM emissions
inventory. Over time, the relative contribution of these diesel engines
to air quality problems will go even higher unless EPA takes action to
further reduce pollution levels. For example, EPA has already taken
steps to bring emissions levels from light-duty and heavy-duty vehicles
and engines to near-zero levels by the end of this decade. The PM and
NOX standards for nonroad, locomotive, and marine diesel
engines in this proposal would have a substantial impact on emissions.
By 2030, NOX emissions from these diesel engines under
today's standards will be reduced by 827,000 tons, and PM emissions
will decline by about 127,000 tons, dramatically reducing this source
of NOX and PM emissions. Urban areas, which include many
poorer neighborhoods, can be disproportionately impacted by such diesel
emissions, and these neighborhoods will thus receive a relatively
larger portion of the benefits expected from proposed emissions
controls. Diesel exhaust is of special concern because it is associated
with increased risk of lung cancer and respiratory disease. EPA
recently issued its Health Assessment Document for Diesel Exhaust.\6\
The Agency has classified diesel exhaust as likely to be carcinogenic
to humans by inhalation at environmental exposures. State and local
governments, in their efforts to protect the health of their citizens
and comply with requirements of the Clean Air Act (CAA or ``the Act''),
have recognized the need to achieve major reductions in diesel PM
emissions, and have been seeking Agency action in setting stringent new
standards to bring this about.\7\
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\6\ U.S. EPA (2002) Health Assessment Document for Diesel Engine
Exhaust. EPA/600/8-90/057F Office of Research and Development,
Washington DC. This document is available electronically at http://
cfpub.epa.gov/ncea/cfm/recordisplay.cfm?deid=29060.
\7\ For example, see letters dated April 9, 2002, from Agency
Secretary of California EPA, Commissioner of NY State DEC, and
Commissioner of Texas NRCC to Governor Whitman; dated January 28,
2003 from Western Regional Air Partnership to Governor Whitman, and
dated December 17, 2002, from State and Territorial Air Pollution
Program Administrators and Association of Local Air Pollution
Control Officials and Northeast States for Coordinated Air Use
Mangement (and other organizations).
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2. Technology and Fuel Based Solutions
Although the air pollution from nonroad diesel exhaust is
challenging, we believe they can be addressed through the application
of high-efficiency emissions control technologies. As discussed in much
greater detail in section III, the development of diesel emissions
control technology has advanced in recent years so that very large
emission reductions (in excess of 90 percent) are possible, especially
through the use of catalytic emission control devices installed in the
nonroad equipment's exhaust system and integrated with the engine
controls. These devices are often referred to as ``exhaust emission
control'' or ``aftertreatment'' devices. Exhaust emission control
devices, in the form of the well-known catalytic converter, have been
used in gasoline-fueled automobiles for 28 years.
Based on the Clean Air Act requirements in section 213, we are
proposing stringent new emission standards that will result in the use
of these diesel exhaust emission control devices. We are also proposing
changes to nonroad diesel fuel quality standards, under section 211(c)
of the Act, in order to enable these high-efficiency technologies.
To meet the proposed new standards, application of high-efficiency
exhaust emission controls for both PM and NOX will be needed
for most engines. High-efficiency PM exhaust emission control
technology has been available for several years. This technology has
continued to improve over the years, especially with respect to
durability and robust operation in use. It has also proved extremely
effective in reducing exhaust hydrocarbon emissions. Thousands of such
systems are now in use, especially in Europe. It is the same technology
we expect to be applied to meet the PM standards in the 2007 heavy-duty
highway diesel engine rule. However, as discussed in detail in section
III, these systems are very sensitive to sulfur in the fuel. For the
technology to be viable and capable of meeting the standards, we
believe it will require diesel fuel with sulfur content capped at the
15 ppm level.
Similarly, high-efficiency NOX exhaust emission control
technology will be needed if nonroad diesel engines are to attain the
proposed standards. This is the same technology that we anticipate will
be applied to heavy-duty highway diesel engines to meet the
NOX standards included in the 2007 highway diesel program.
This technology, like the PM technology, is dependant on the 15 ppm
maximum nonroad diesel fuel levels being proposed in this action in
order to be feasible and capable of achieving the standards. Similar
high-efficiency NOX exhaust emission control technology has
been quite successful in gasoline direct injection engines that operate
with an exhaust composition fairly similar to diesel exhaust and is
expected to be used to meet the 2007 and later heavy-duty highway
diesel standards. As discussed in section III, application of this
technology to nonroad diesels has some additional engineering
challenges. In that section, we discuss the current status of this
technology as well as the major development issues still to be
addressed and the development steps that can be taken. With the lead-
time available and the introduction of ultra low sulfur nonroad diesel
fuel, we are confident the proposed application of this technology to
nonroad diesels would proceed at a reasonable rate of progress and will
result in systems capable of achieving the standards.
This view is further supported by the fact that manufacturers are
already working on developing high-efficiency aftertreatment devices in
order to have them available for introduction on highway diesel engines
by 2007. EPA issued a progress report in June 2002 which discussed our
findings that industry was making substantial progress in developing
these devices. Additionally, the Clean Diesel Independent Review Panel
issued a report in October 2002 on similar
[[Page 28336]]
questions and concluded that, while technical issues remain, there were
no technical hurdles identified that would prevent market introduction
of high-efficiency aftertreatment devices on schedule.
The need to reduce sulfur in nonroad diesel fuel is driven by the
requirements of the exhaust emission control technology that we project
will be needed to meet the proposed standards for most nonroad diesel
engines. The challenge in accomplishing the sulfur reduction is driven
by the capacity to implement the needed refinery modifications, and by
the costs of making the modifications and running the equipment. Today,
a number of refiners are acting to provide low sulfur diesel to some
markets. We believe that controlling the sulfur content of highway
diesel fuel to the 15 ppm level is necessary, feasible, and cost-
effective.
Additionally, there are health and welfare benefits associated with
the initial step of reducing the sulfur level of nonroad, locomotive,
and marine diesel fuel to 500 ppm. This proposed action will provide
dramatic, immediate reductions in direct sulfate PM and SO2
emissions from the in-use fleet. As described in this proposal, we
believe this fuel control strategy is a cost-effective air quality
solution as well.
3. Basis for Action Under the Clean Air Act
Section 213 of the Act gives us the authority to establish
emissions standards for nonroad engines and vehicles. Section 213(a)(3)
authorizes the Administrator to set standards for NOX, VOCs,
or carbon monoxide, to reduce ambient levels of ozone and carbon
monoxide which ``standards shall achieve the greatest degree of
emission reduction achievable through the application of technology
which the Administrator determines will be available for the engines or
vehicles.'' As part of this determination, the Administrator must give
appropriate consideration to cost, lead time, noise, energy, and safety
factors associated with the application of such technology. Section
213(a)(4) authorizes the Administrator to establish standards to
control emissions of pollutants which ``may reasonably be anticipated
to endanger public health and welfare''. Here, the Administrator may
promulgate regulations that are deemed appropriate for new nonroad
vehicles and engines which cause or contribute to such air pollution,
taking into account costs, noise, safety, and energy factors. EPA
believes the proposed controls for PM in today's rule would be an
appropriate exercise of EPA's discretion under the authority of section
213(a)(4).
We believe the evidence provided in section III and the Draft
Regulatory Impact Analysis (RIA) indicates that the stringent emission
standards proposed today are feasible and reflect the greatest degree
of emission reduction achievable in the model years to which they
apply. We have given appropriate consideration to costs in proposing
these standards. Our review of the costs and cost-effectiveness of
these standards indicate that they will be reasonable and comparable to
the cost-effectiveness of other emission reduction strategies that have
been required or could be required in the future. We have also reviewed
and given appropriate consideration to the energy factors of this rule
in terms of fuel efficiency and effects on diesel fuel supply,
production, and distribution, as discussed below, as well as any safety
factors associated with these proposed standards.
The information in section II and chapter 2 of the draft RIA
regarding air quality and the contribution of nonroad, locomotive, and
marine diesel engines to air pollution provides strong evidence that
emissions from such engines significantly and adversely impact public
health or welfare. First, as noted earlier, there is a significant risk
that several areas will fail to attain or maintain compliance with the
NAAQS for 8-hour ozone concentrations or for PM2.5 concentrations
during the period that these new vehicle and engine standards will be
phased into the vehicle population, and that nonroad, locomotive, and
marine diesel engines contribute to such concentrations, as well as to
concentrations of other NAAQS-related pollutants. This risk will be
significantly reduced by the standards adopted today, as also noted
above. However, the evidence indicates that some risk remains even
after the reductions achieved by these new controls on nonroad diesel
engines and nonroad, locomotive, and marine diesel fuel. Second, EPA
believes that diesel exhaust is likely to be carcinogenic to humans.
The risk associated with exposure to diesel exhaust includes the
particulate and gaseous components among which are benzene,
formaldehyde, acetaldehyde, acrolein, and 1,3-butadiene, all of which
are known or suspected human or animal carcinogens, or have serious
noncancer health effects. Third, emissions from nonroad diesel engines
(including locomotive and marine diesel engines) contribute to regional
haze and impaired visibility across the nation, as well as acid
deposition, POM deposition, eutrophication and nitrification, all of
which are serious environmental welfare problems.
EPA has already found in previous rules that emissions from new
nonroad diesel engines contribute to ozone and carbon monoxide (CO)
concentrations in more than one area which has failed to attain the
ozone and carbon monoxide NAAQS. 59 FR 31306 (June 17, 1994). EPA has
also previously determined that it is appropriate to establish
standards for PM from new nonroad diesel engines under section
213(a)(4), and the additional information on diesel exhaust
carcinogenicity noted above reinforces this finding. In addition, we
have already found that emissions from nonroad engines significantly
contribute to air pollution that may reasonably be anticipated to
endanger public welfare due to regional haze and visibility impairment.
67 FR 68242, 68243 (Nov. 8, 2002). We find here, based on the
information in section II of this preamble and chapter 2 of the draft
RIA, that emissions from the new nonroad diesel engines covered by this
proposal likewise contribute to regional haze and to visibility
impairment that may reasonably be anticipated to endanger public
welfare. Taken together, these findings indicate the appropriateness of
the nonroad diesel engine standards proposed today for purposes of
section 213(a)(3) and (4) of the Act.
Section 211(c) of the CAA allows us to regulate fuels where
emission products of the fuel either: (1) Cause or contribute to air
pollution that reasonably may be anticipated to endanger public health
or welfare, or (2) will impair to a significant degree the performance
of any emission control device or system which is in general use, or
which the Administrator finds has been developed to a point where in a
reasonable time it will be in general use were such a regulation to be
promulgated. This rule meets both of these criteria. SOx and sulfate PM
emissions from nonroad, locomotive, marine and diesel vehicles are due
to sulfur in diesel fuel. As discussed above, emissions of these
pollutants cause or contribute to ambient levels of air pollution that
endanger public health and welfare. Control of sulfur to 500 ppm for
this fuel would lead to significant, cost-effective reductions in
emissions of these pollutants. The substantial adverse effect of high
sulfur levels on the performance of diesel emission control devices or
systems that would be expected to be used to meet the nonroad standards
is discussed in detail in section III. Control of sulfur to 15 ppm in
nonroad diesel fuel would enable emissions control technology that will
achieve significant, cost-
[[Page 28337]]
effective reduction in emissions of these pollutants, as discussed in
section II below. In addition, our authority under section 211(c) is
discussed in more detail in Appendix A to the draft RIA.
II. What Is the Air Quality Impact of the Sources Covered by the
Proposed Rule?
With this proposal, EPA is acting to extend highway types of
emission controls to another major source of diesel engine emissions,
nonroad diesel engines. These emissions are significant contributors to
atmospheric pollution from particulate matter, ozone and a variety of
toxic air pollutants. In our most recent nationwide inventory used for
this proposal (1996), the nonroad diesels affected by this proposal \8\
contribute over 43 percent of diesel PM emissions from mobile sources,
up to 18 percent of PM2.5 emissions in urban areas, and up
to 14 percent of NOX emissions in urban areas.
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\8\ For NOX and PM2.5 this includes all
land-based nonroad diesel engines, but not locomotive, commercial
marine vessel, and recreational marine vessel engines. Since the
latter three engine categories are affected by the fuel sulfur
portions of the proposal, they are included for SO2.
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Without further control beyond those standards we have already
adopted, by the year 2020, these engines will emit 62 percent of diesel
PM emissions from mobile sources, up to 19 percent of PM2.5
emissions in urban areas, and up to 20 percent of NOX
emissions in urban areas.
When fully implemented, this proposal would reduce nonroad diesel
PM2.5 and NOX emissions by more than 90 percent.
It will also virtually eliminate nonroad diesel SOx
emissions, which amounted to nearly 230,000 tons in 1996, and would
otherwise grow to approximately 340,000 tons by 2020.
These dramatic reductions in nonroad emissions are a critical part
of the effort by Federal, State and local governments to reduce the
health-related impacts of air pollution and to reach attainment of the
NAAQS for PM and ozone, as well as to improve other environmental
effects such as atmospheric visibility. Based on the most recent data
available for this rule (1999-2001), such problems are widespread in
the United States. There are over 65 million people living in counties
with monitored PM2.5 levels exceeding the PM2.5
NAAQS, and 111 million people living in counties with monitored
concentrations exceeding the 8-hour ozone NAAQS. Figure II.-1
illustrates the widespread nature of these problems. Shown in this
figure are counties exceeding either or both of the two NAAQS plus
mandatory Federal Class I areas, which have particular needs for
reductions in atmospheric haze.
[GRAPHIC] [TIFF OMITTED] TP23MY03.000
As we will describe later in this preamble, the air quality
improvements expected from this proposal is anticipated to produce
major benefits to human health and welfare, with a combined value in
excess of half a
[[Page 28338]]
trillion dollars between 2007 and 2030. By the year 2030, this proposed
rule would be expected to prevent approximately 9,600 deaths per year
from premature mortality, and 16,000 nonfatal heart attacks. It is
estimated to also prevent 14,000 acute bronchitis attacks in children,
260,000 respiratory symptoms in children, and nearly 1 million lost
work days in 2030. The reductions will also improve visibility.
In the remainder of this section we will describe in more detail
the air pollution problems associated with emissions from nonroad
diesel engines, and the emission and air quality benefits we expect to
realize from the fuel and engine controls in this proposal.
A. Overview
The emissions from nonroad engines that are being directly
controlled by the standards in this rulemaking are NOX, PM
and NMHC, and to a lesser extent, CO. Gaseous air toxics from nonroad
diesels will also be reduced as a consequence of the proposed
standards. In addition there will be a substantial reduction in
SOx emissions resulting from the proposed reduction in
sulfur level in diesel fuel.
From a public health perspective, we are primarily concerned with
nonroad engine contributions to atmospheric levels of particulate
matter in general, diesel PM in particular and various gaseous air
toxics emitted by diesel engines, and ozone.\9\ We will first review
important public health effects linked to these pollutants, briefly
describing the human health effects and the current and expected future
ambient levels of direct or indirectly caused pollution. Our
presentation will show that substantial further reductions of these
pollutants, and the underlying emissions from nonroad diesel engines,
are needed to protect public health.
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\9\ Ambient particulate matter from nonroad diesel engine is
associated with the direct emission of diesel particulate matter,
and with particulate matter formed indirectly in the atmosphere by
NOX and SOx emissions (and to a lesser extent
NMHC emissions). Both NOX and NMHC participate in the
atmospheric chemical reactions that produce ozone.
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Following discussion of health effects, we will discuss a number of
welfare effects associated with emissions from diesel engines. These
effects include atmospheric visibility impairment, ecological and
property damage caused by acid deposition, eutrophication and
nitrification of surface waters, environmental threats posed by
polycyclic organic matter (POM) deposition, and plant and crop damage
from ozone. Once again, the information available to us indicates a
continuing need for further nonroad emission reductions to bring about
improvements in air quality.
Next, we will describe our understanding of the engine emission
inventories for the primary pollutants affected by the proposal. As
noted above, these include PM, NOX, SOX, Air
Toxics and HC. We will present current and projected future levels of
emissions for the base case, including anticipated reductions from
control programs already adopted by EPA and the States, but without the
controls proposed today. Then we will identify expected emission
reductions from nonroad engines. These reductions will make important
contributions to controlling the health and welfare problems associated
with ambient PM and ozone levels and with diesel related air toxics.
While the material we will present in this section will describe
our understanding of the need for control of nonroad engine emissions
and the air quality improvements we expect to realize, this section is
not an exhaustive treatment of these issues. For a fuller understanding
of the topics treated here, you should refer to the extended
presentations in the Draft Regulatory Impact Analysis accompanying this
proposal.
B. Public Health Impacts
1. Particulate Matter
Particulate matter (PM) represents a broad class of chemically and
physically diverse substances. It can be principally characterized as
discrete particles that exist in the condensed (liquid or solid) phase
spanning several orders of magnitude in size. PM10 refers to
particles with an aerodynamic diameter less than or equal to a nominal
10 micrometers. Fine particles refer to those particles with an
aerodynamic diameter less than or equal to a nominal 2.5 micrometers
(also known as PM2.5), and coarse fraction particles are
those particles with an aerodynamic diameter greater than 2.5 microns,
but less than or equal to a nominal 10 micrometers. Ultrafine PM refers
to particles with diameters of less than 100 nanometers (0.1
micrometers). The health and environmental effects of PM are associated
with fine PM fraction and, in some cases, to the size of the particles.
Specifically, larger particles (10 [mu]m) tend to be removed
by the respiratory clearance mechanisms whereas smaller particles are
deposited deeper in the lungs. Also, particles scatter light
obstructing visibility.
The emission sources, formation processes, chemical composition,
atmospheric residence times, transport distances and other parameters
of fine and coarse particles are distinct. Fine particles are directly
emitted from combustion sources and are formed secondarily from gaseous
precursors such as sulfur dioxide (SOX), oxides of nitrogen
(NOX), or organic compounds. Fine particles are generally
composed of sulfate, nitrate, chloride, ammonium compounds, organic
carbon, elemental carbon, and metals. Nonroad diesels currently emit
high levels of NOX which react in the atmosphere to form
secondary PM2.5 (namely ammonium nitrate). Nonroad diesel
engines also emit SO2 and HC which react in the atmosphere
to form secondary PM2.5 (namely sulfates and organic
carbonaceous PM2.5). Combustion of coal, oil, diesel,
gasoline, and wood, as well as high temperature process sources such as
smelters and steel mills, produce emissions that contribute to fine
particle formation. In contrast, coarse particles are typically
mechanically generated by crushing or grinding. They include
resuspended dusts and crustal material from paved roads, unpaved roads,
construction, farming, and mining activities. These coarse particles
can be either natural in source such as road dust or anthropogenic.
Fine particles can remain in the atmosphere for days to weeks and
travel through the atmosphere hundreds to thousands of kilometers,
while coarse particles deposit to the earth within minutes to hours and
within tens of kilometers from the emission source.
The relative contribution of various chemical components to
PM2.5 varies by region of the country. Data on
PM2.5 composition are available from the EPA Speciation
Trends Network in 2001 and the Interagency Monitoring of PROtected
Visual Environments (IMPROVE) network in 1999 covering both urban and
rural areas in numerous regions of the U.S. These data show that
carbonaceous PM2.5 makes up the major component for
PM2.5 in both urban and rural areas in the western U.S.
Carbonaceous PM2.5 includes both elemental and organic
carbon. Nitrates formed from NOX also play a major role in
the western U.S., especially in the California area where it is
responsible for about a quarter of the ambient PM2.5
concentrations. Sulfate plays a lesser role in these regions. For the
eastern and mid U.S., these data show that both sulfates and
carbonaceous PM2.5 are major contributors to ambient
PM2.5 in both urban and rural areas. In some eastern areas,
carbonaceous PM2.5 is responsible for up to half of ambient
PM2.5 concentrations. Sulfate is also a
[[Page 28339]]
major contributor to ambient PM2.5 in the eastern U.S. and
in some areas make greater contributions than carbonaceous
PM2.510 11
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\10\ Rao, Venkatesh; Frank, N.; Rush, A.; and Dimmick, F.
(November 13-15, 2002). Chemical speciation of PM2.5 in
urban and rural areas (November 13-15, 2002) In the Proceedings of
the Air & Waste Management Association Symposium on Air Quality
Measurement Methods and Technology, San Francisco Meeting.
\11\ EPA (2002) Latest Finds on National Air Quality, EPA 454/K-
02-001.
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Nonroad engines, and most importantly nonroad diesel engines,
contribute significantly to ambient PM2.5 levels, largely
through emissions of carbonaceous PM2.5. Carbonaceous
PM2.5 is a major portion of ambient PM2.5,
especially in populous urban areas. Nonroad diesels also emit high
levels of NOX which react in the atmosphere to form
secondary PM2.5 (namely nitrate). Nonroad diesels also emit
SO2 and NMHC which react in the atmosphere to form secondary
PM2.5 (namely sulfates and organic carbonaceous
PM2.5). For more details, consult the draft RIA for this
proposed rule.
Diesel particles from nonroad diesel are a component of both coarse
and fine PM, but fall mainly in the fine (and even ultrafine) size
range. As discussed later, diesel PM also contains small quantities of
numerous mutagenic and carcinogenic compounds associated with the
particulate (and also organic gases). In addition, while toxic trace
metals emitted by nonroad diesel engines represent a very small portion
of the national emissions of metals (less than one percent) and a small
portion of diesel PM (generally less than one percent of diesel PM), we
note that several trace metals of potential toxicological significance
and persistence in the environment are emitted by diesel engines. These
trace metals include chromium, manganese, mercury and nickel. In
addition, small amounts of dioxins have been measured in highway engine
diesel exhaust, some of which may partition into the particulate phase;
dioxins through out the environment are a major health concern
(although the diesel contribution has not been judged significant at
this point). Diesel engines also emit polycyclic organic matter (POM),
including polycyclic aromatic hydrocarbons (PAH), which can be present
in both gas and particle phases of diesel exhaust. Many PAH compounds
are classified by EPA as probable human carcinogens.
For additional, detailed, information on PM beyond that summarized
below, see the draft Regulatory Impact Analysis.
a. Health Effects of PM2.5 and PM10
Scientific studies show ambient PM (which is attributable to a
number of sources, including nonroad diesel) is associated with a
series of adverse health effects. These health effects are discussed in
detail in the EPA Criteria Document for PM as well as the draft updates
of this document released in the past year.12 13 In
addition, EPA's final ``Health Assessment Document for Diesel Engine
Exhaust,'' (the Diesel HAD) also reviews health effects information
related to diesel exhaust as a whole including diesel PM, which is one
component of ambient PM.\14\
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\12\ U.S. EPA (1996.) Air Quality Criteria for Particulate
Matter--Volumes I, II, and III, EPA, Office of Research and
Development. Report No. EPA/600/P-95/001a-cF. This material is
available electronically at http://www.epa.gov/ttn/oarpg/ticd.html.
\13\ U.S. EPA (2002). Air Quality Criteria for Particulate
Matter--Volumes I and II (Third External Review Draft) This material
is available electronically at http://cfpub.epa.gov/ncea/cfm/
partmatt.cfm.
\14\ U.S. EPA (2002). Health Assessment Document for Diesel
Engine Exhaust. EPA/600/8-90/057F Office of Research and
Development, Washington DC. This document is available
electronically at http://cfpub.epa.gov/ncea/cfm/
recordisplay.cfm?deid=29060.
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As described in these documents, health effects associated with
short-term variation in ambient particulate matter (PM) have been
indicated by epidemiologic studies showing associations between
exposure and increased hospital admissions for ischemic heart disease,
heart failure, respiratory disease, including chronic obstructive
pulmonary disease (COPD) and pneumonia. Short-term elevations in
ambient PM have also been associated with increased cough, lower
respiratory symptoms, and decrements in lung function. Short-term
variations in ambient PM have also been associated with increases in
total and cardiorespiratory daily mortality. Studies examining
populations exposed to different levels of air pollution over a number
of years, including the Harvard Six Cities Study and the American
Cancer Society Study suggest an association between exposure to ambient
PM2.5 and premature mortality, including deaths attributed
to lung cancer.15 16 Two studies further analyzing the
Harvard Six Cities Study's air quality data have also established a
specific influence of mobile source-related PM2.5 on daily
mortality \17\ and a concentration-response function for mobile source-
associated PM2.5 and daily mortality.\18\ Another recent
study in 14 U.S. cities examining the effect of PM10 on
daily hospital admissions for cardiovascular disease found that the
effect of PM10 was significantly greater in areas with a
larger proportion of PM10 coming from motor vehicles,
indicating that PM10 from these sources may have a greater
effect on the toxicity of ambient PM10 when compared with
other sources.\19\ Additional studies have associated changes in heart
rate and/or heart rhythm in addition to changes in blood
characteristics with exposure to ambient PM.20 21 For
additional information on health effects, see the draft RIA.
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\15\ Dockery, DW; Pope, CA, III; Xu, X; et al. (1993) An
association between air pollution and mortality in six U.S. cities.
N Engl J Med 329:1753-1759.
\16\ Pope, CA, III; Thun, MJ; Namboordiri, MM; et al. (1995)
Particulate air pollution as a predictor of mortality in a
prospective study of U.S. adults. Am J Respir Crit Care Med 151:669-
674.
\17\ Laden F; Neas LM; Dockery DW; et al. (2000) Association of
fine particulate matter from different sources with daily mortality
in six U.S. cities. Environ Health Perspect 108(10):941-947.
\18\ Schwartz J; Laden F; Zanobetti A. (2002) The concentration-
response relation between PM(2.5) and daily deaths. Environ Health
Perspect 110(10): 1025-1029.
\19\ Janssen NA; Schwartz J; Zanobetti A.; et al. (2002) Air
conditioning and source-specific particles as modifiers of the
effect of PM10 on hospital admissions for heart and lung
disease. Environ Health Perspect 110(1):43-49.
\20\ Pope CA III, Verrier RL, Lovett EG; et al. (1999) Heart
rate variability associated with particulate air pollution. Am Heart
J 138(5 Pt 1):890-899.
\21\ Magari SR, Hauser R, Schwartz J; et al. (2001) Association
of heart rate variability with occupational and environmental
exposure to particulate air pollution. Circulation 104(9):986-991.
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The health effects of PM10 are similar to those of
PM2.5, since PM10 includes all of
PM2.5 plus the coarse fraction from 2.5 to 10 micrometers in
size. EPA is also evaluating the health effects of PM between 2.5 and
10 micrometers in the draft revised Criteria Document. As discussed in
the Diesel HAD and other studies, most diesel PM is smaller than 2.5
micrometers.\22\ Both fine and coarse fraction particles can enter and
deposit in the respiratory system.
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\22\ U.S. EPA (1985). Size specific total particulate emission
factor for mobile sources. EPA 460/3-85-005. Office of Mobile
Sources, Ann Arbor, MI.
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In addition to the information in the draft revised Criteria
Document, the relevance of health effects associated with on-road
diesel engine-generated PM to nonroad applications is supported by the
observation in the Diesel HAD that the particulate characteristics in
the zone around nonroad diesel engines is likely to be substantially
the same as published air quality measurements made along busy
roadways.
Of particular relevance to this rule is a recent cohort study which
examined the association between mortality and
[[Page 28340]]
residential proximity to major roads in the Netherlands. Examining a
cohort of 55 to 69 year-olds from 1986 to1994, the study indicated that
long-term residence near major roads, an index of exposure to primary
mobile source emissions (including diesel exhaust), was significantly
associated with increased cardiopulmonary mortality.\23\ Other studies
have shown children living near roads with high truck traffic density
have decreased lung function and greater prevalence of lower
respiratory symptoms compared to children living on other roads.\24\ A
recent review of epidemiologic studies examining associations between
asthma and roadway proximity concluded that some coherence was evident
in the literature, indicating that asthma, lung function decrement,
respiratory symptoms, and other respiratory problems appear to occur
more frequently in people living near busy roads.\25\ As discussed
later, nonroad diesel engine emissions, especially particulate, are
similar in composition to those from highway diesel vehicles. Although
difficult to associate directly with PM2.5, these studies
indicate that direct emissions from mobile sources, and diesel engines
specifically, may explain a portion of respiratory health effects
observed in larger-scale epidemiologic studies. Recent studies
conducted in Los Angeles have illustrated that a substantial increase
in the concentration of ultrafine particles is evident in locations
near roadways, indicating substantial differences in the nature of PM
immediately near mobile source emissions.\26\
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\23\ Hoek, G; Brunekreef, B; Goldbohm, S; et al. (2002)
Association between mortality and indicators of traffic-related air
pollution in the Netherlands: a cohort study. Lancet 360(9341):
1203-1209.
\24\ Brunekreef, B; Janssen NA; de Hartog, J; et al. (1997) Air
pollution from traffic and lung function in children living near
motor ways. Epidemiology (8): 298-303.
\25\ Delfino RJ. (2002) Epidemiologic evidence for asthma and
exposure to air toxics: linkages between occupational, indoor, and
community air pollution research. Env Health Perspect Suppl 110(4):
573-589.
\26\ Yifang Zhu, William C. Hinds, Seongheon Kim, Si Shen and
Constantinos Sioutas Zhu Y; Hinds WC; Kim S; et al. (2002) Study of
ultrafine particles near a major highway with heavy-duty diesel
traffic. Atmos Environ 36(27): 4323-4335.
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Also, as discussed in more detail later, in addition to its
contribution to ambient PM inventories, diesel PM is of special concern
because diesel exhaust has been associated with an increased risk of
lung cancer. As also discussed later in more detail, we concluded that
diesel exhaust ranks with other substances that the national-scale air
toxics assessment suggests pose the greatest relative risk.
b. Current and Projected Levels
There are NAAQS for both PM10 and PM2.5.
Violations of the annual PM2.5 standard are much more
widespread than are violations of the PM10 standards.
Emission reductions needed to attain the PM2.5 standards
will also assist in attaining and maintaining compliance with the
PM10 standards. Thus, since most PM emitted by diesel
nonroad engines is fine PM, the emission controls proposed today should
contribute to attainment and maintenance of the existing PM NAAQS. More
broadly, the proposed standards will benefit public health and welfare
through reductions in direct diesel PM and reductions of
NOX, SOX, and NMHCs which contribute to secondary
formation of PM. The reductions from these proposed rules will assist
States as they implement local controls as needed to help their areas
attain and maintain the standards.
i. PM10 Levels
The current NAAQS for PM10 were established in 1987. The
primary (health-based) and secondary (public welfare based) standards
for PM10 include both short- and long-term NAAQS. The short-
term (24 hour) standard of 150 ug/m3 is not to be exceeded
more than once per year on average over three years. The long-term
standard specifies an expected annual arithmetic mean not to exceed 50
ug/m3 averaged over three years.
Currently, 29 million people live in PM10 nonattainment
areas. There are currently 58 moderate PM10 nonattainment
areas with a total population of 6.8 million. The attainment date for
the initial moderate PM10 nonattainment areas, designated by
operation of law on November 15, 1990, was December 31, 1994. Several
additional PM10 nonattainment areas were designated on
January 21, 1994, and the attainment date for these areas was December
31, 2000. There are an additional 8 serious PM10
nonattainment areas with a total affected population of 22.7 million.
According to the Act, serious PM10 nonattainment areas must
attain the standards no later than 10 years after designation. The
initial serious PM10 nonattainment areas were designated
January 18, 1994, and had an attainment date set by the Act of December
31, 2001. The Act provides that EPA may grant extensions of the serious
area attainment dates of up to 5 years, provided that the area
requesting the extension meets the requirements of section 188(e) of
the Act. Four serious PM10 nonattainment areas (Phoenix,
Arizona; Coachella Valley, South Coast (Los Angeles), and Owens Valley,
California) have received extensions of the December 31, 2001,
attainment date and thus have new attainment dates of December 31,
2006.\27\ While all of these areas are expected to be in attainment
before the emission reductions from this proposed rule are expected to
occur, these reductions will be important to assist these areas in
maintaining the standards.
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\27\ EPA has also proposed to grant Las Vegas, Nevada, an
extension until December 31, 2006.
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ii. PM2.5 Levels
The need for reductions in the levels of PM2.5 is
widespread. Figure II-1 at the beginning of this air quality section
highlighted monitor locations measuring concentrations above the level
of the NAAQS. As can be seen from that figure, high ambient levels are
widespread throughout the country.
The NAAQS for PM2.5 were established by EPA in 1997 (62
FR 38651, July 18, 1997). The short term (24-hour) standard is set at a
level of 65 [mu]g/m3 based on the 98th percentile
concentration averaged over three years. (This air quality statistic
compared to the standard is referred to as the ``design value.'') The
long-term standard specifies an expected annual arithmetic mean not to
exceed 15 ug/m3 averaged over three years.
Current PM2.5 monitored values for 1999-2001, which
cover counties having about 75 percent of the country's population,
indicate that at least 65 million people in 129 counties live in areas
where annual design values of ambient fine PM violate the
PM2.5 NAAQS. There are an additional 9 million people in 20
counties where levels above the NAAQS are being measured, but there are
insufficient data at this time to calculate a design value in
accordance with the standard, and thus determine whether these areas
are violating the PM2.5 NAAQS. In total, this represents 37
percent of the counties and 64 percent of the population in the areas
with monitors with levels above the NAAQS. Furthermore, an additional
14 million people live in 41 counties that have air quality
measurements within 10 percent of the level of the standard. These
areas, although not currently violating the standard, will also benefit
from the additional reductions from this rule in order to ensure long
term maintenance.
Our air quality modeling performed for this proposal also indicates
that similar conditions are likely to continue
[[Page 28341]]
to exist in the future in the absence of additional controls. For
example, in 2020 based on emission controls currently adopted, we
project that 66 million people will live in 79 counties with average
PM2.5 levels above 15 ug/m\3\. In 2030, the number of people
projected to live in areas exceeding the PM2.5 standard is
expected to increase to 85 million in 107 counties. An additional 24
million people are projected to live in counties within 10 percent of
the standard in 2020, which will increase to 64 million people in 2030.
Our modeling also indicates that the reductions we are expecting
will make a substantial contribution to reducing exposures in these
areas.\28\ In 2020, the number of people living in counties with
PM2.5 levels above the NAAQS would be reduced from 66
million to 60 million living in 67 counties, which reflects a reduction
of 9 percent in potentially exposed population and 15 percent of the
number of counties. In 2030, there would be a reduction from 85 million
people to 71 million living in 84 counties. These represent even
greater improvements than projected for 2020 (numbers of people
potentially exposed down 16 percent and number of counties down 21
percent). Furthermore, our modeling also shows that the emission
reductions would assist areas with future maintenance of the standards.
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\28\ The results illustrate the type of PM changes for the
preliminary control option, as discussed in the Draft RIA in section
3.6. The proposal differs from the modeled control case based on
updated information; however, we believe that the net results would
approximate future emissions, although we anticipate the PM
reductions might be slightly smaller.
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We estimate that the reduction of PM levels expected from this
proposed rule would produce nationwide air quality improvements in PM
levels. On a population weighted basis, the average change in future
year annual averages would be a decrease of 0.33 ug/m\3\ in 2020, and
0.46 ug/m\3\ in 2030. The reductions are discussed in more detail in
chapter 2 of the draft RIA.
While the final implementation process for bringing the nation's
air into attainment with the PM2.5 NAAQS is still being
completed in a separate rulemaking action, the basic framework is well
defined by the statute. EPA's current plans call for designating
PM2.5 nonattainment areas in late-2004. Following
designation, Section 172(b) of the Clean Air Act allows states up to
three years to submit a revision to their state implementation plan
(SIP) that provides for the attainment of the PM2.5
standard. Based on this provision, states could submit these SIPs as
late as the end of 2007. Section 172(a)(2) of the Clean Air Act
requires that these SIP revisions demonstrate that the nonattainment
areas will attain the PM2.5 standard as expeditiously as
practicable but no later than five years from the date that the area
was designated nonattainment. However, based on the severity of the air
quality problem and the availability and feasibility of control
measures, the Administrator may extend the attainment date ``for a
period of no greater than 10 years from the date of designation as
nonattainment.'' Therefore, based on this information, we expect that
most or all areas will need to attain the PM2.5 NAAQS in the
2009 to 2014 time frame, and then be required to maintain the NAAQS
thereafter.
Since the emission reductions expected from this proposal would
begin in this same time frame, the projected reductions in nonroad
emissions would be used by states in meeting the PM2.5
NAAQS. States and state organizations have told EPA that they need
nonroad diesel engine reductions in order to be able to meet and
maintain the PM2.5 NAAQS as well as visibility regulations,
especially in light of the otherwise increasing emissions from nonroad
sources without more stringent standards.29 30 31
Furthermore, this action would ensure that nonroad diesel emissions
will continue to decrease as the fleet turns over in the years beyond
2014; these reductions will be important for maintenance of the NAAQS
following attainment. The future reductions are also important to
achieve visibility goals, as discussed later.
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\29\ California Air Resources Board and New York State
Department of Environmental Conservation (April 9, 2002), Letter to
EPA Administrator Christine Todd Whitman.
\30\ State and Territorial Air Pollution Program Administrators
(STAPPA) and Association of Local Air Pollution Control Officials
(ALAPCO) (December 17, 2002), Letter to EPA Assistant Administrator
Jeffrey R. Holmstead.
\31\ Western Regional Air Partnership (WRAP) (January 28, 2003),
Letter to Governor Christine Todd Whitman.
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2. Air Toxics
a. Diesel Exhaust
A number of health studies have been conducted regarding diesel
exhaust including epidemiologic studies of lung cancer in groups of
workers, and animal studies focusing on non-cancer effects specific to
diesel exhaust. Diesel exhaust PM (including the associated organic
compounds which are generally high molecular weight hydrocarbon types
but not the more volatile gaseous hydrocarbon compounds) is generally
used as a surrogate measure for diesel exhaust.
i. Potential Cancer Effects of Diesel Exhaust
In addition to its contribution to ambient PM inventories, diesel
exhaust is of specific concern because it has been judged to pose a
lung cancer hazard for humans as well as a hazard from noncancer
respiratory effects.
EPA recently released its ``Health Assessment Document for Diesel
Engine Exhaust,'' (the Diesel HAD).\32\ There, diesel exhaust was
classified as likely to be carcinogenic to humans by inhalation at
environmental exposures, in accordance with the revised draft 1996/1999
EPA cancer guidelines. A number of other agencies (National Institute
for Occupational Safety and Health, the International Agency for
Research on Cancer, the World Health Organization, California EPA, and
the U.S. Department of Health and Human Services) have made similar
classifications. It should be noted that the conclusions in the Diesel
HAD were based on diesel engines currently in use, including nonroad
diesel engines such as those found in bulldozers, graders, excavators,
farm tractor drivers and heavy construction equipment. As new diesel
engines with significantly cleaner exhaust emissions replace existing
engines, the conclusions of the Diesel HAD will need to be reevaluated.
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\32\ U.S. EPA (2002). Health Assessment Document for Diesel
Engine Exhaust. EPA/600/8-90/057F Office of Research and
Development, Washington DC. This document is available
electronically at http://cfpub.epa.gov/ncea/cfm/
recordisplay.cfm?deid=29060.
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For the EPA Diesel HAD, EPA reviewed 22 epidemiologic studies in
detail, finding increased lung cancer risk in 8 out of 10 cohort
studies and 10 out of 12 case-control studies. Relative risk for lung
cancer associated with exposure range from 1.2 to 2.6. In addition, two
meta-analyses of occupational studies of diesel exhaust and lung cancer
have estimated the smoking-adjusted relative risk of 1.35 and 1.47,
examining 23 and 30 studies, respectively.33 34 That is,
these two studies show an overall increase in lung cancer for the
exposed groups of 35 percent and 47 percent compared to the groups not
exposed to diesel exhaust. In the EPA Diesel HAD, EPA selected 1.4
[[Page 28342]]
as a reasonable estimate of occupational relative risk for further
analysis.
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\33\ Bhatia, R., Lopipero, P., Smith, A. (1998). Diesel exhaust
exposure and lung cancer. Epidemiology 9(1):84-91.
\34\ Lipsett, M: Campleman, S.; (1999). Occupational exposure to
diesel exhaust and lung cancer: a meta-analysis. Am J Public Health
80(7):1009-1017.
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EPA generally derives cancer unit risk estimates to calculate
population risk more precisely from exposure to carcinogens. In the
simplest terms, the cancer unit risk is the increased risk associated
with average lifetime exposure of 1 ug/m\3\. EPA concluded in the
Diesel HAD that it is not possible currently to calculate a cancer unit
risk for diesel exhaust due to a variety of factors that limit the
current studies, such as a lack of standard exposure metric for diesel
exhaust and the absence of quantitative exposure characterization in
retrospective studies.
EPA generally derives cancer unit risk estimates to calculate
population risk more precisely from exposure to carcinogens. In the
simplest terms, the cancer unit risk is the increased risk associated
with average lifetime exposure of 1 ug/m\3\. EPA concluded in the
Diesel HAD that it is not possible currently to calculate a cancer unit
risk for diesel exhaust due to a variety of factors that limit the
current studies, such as lack of an adequate dose-response relationship
between exposure and cancer incidence.
However, in the absence of a cancer unit risk, the EPA Diesel HAD
sought to provide additional insight into the possible ranges of risk
that might be present in the population. Such insights, while not
confident or definitive, nevertheless contribute to an understanding of
the possible public health significance of the lung cancer hazard. The
possible risk range analysis was developed by comparing a typical
environmental exposure level to a selected range of occupational
exposure levels and then proportionally scaling the occupationally
observed risks according to the exposure ratio's to obtain an estimate
of the possible environmental risk. If the occupational and
environmental exposures are similar, the environmental risk would
approach the risk seen in the occupational studies whereas a much
higher occupational exposure indicates that the environmental risk is
lower than the occupational risk. A comparison of environmental and
occupational exposures showed that for certain occupations the
exposures are similar to environmental exposures while, for others,
they differ by a factor of about 200 or more.
The first step in this process is to note that the occupational
relative risk of 1.4, or a 40 percent from increased risk compared to
the typical 5 percent lung cancer risk in the U.S. population,
translates to an increased risk of 2 percent (or 10-2) for
these diesel exhaust exposed workers. The Diesel HAD derived a typical
nationwide average environmental exposure level of 0.8 ug./m\3\ for
diesel PM from highway sources for 1996. Diesel PM is a surrogate for
diesel exhaust and, as mentioned above, has been classified as a
carcinogen by some agencies.
This estimate was based on national exposure modeling; the
derivation of this exposure is discussed in detail in the EPA Diesel
HAD. The possible risk range in the environment was estimated by taking
the relative risks in the occupational setting, EPA selected 1.4 and
converting this to absolute risk of 2% and then ratioing this risk by
differences in the occupational vs environmental exposures of interest.
A number of calculations are needed to accomplish this, and these can
be seen in the EPA Diesel HAD. The outcome was that environmental risks
from diesel exhaust exposure could range from a low of 10-4
to 10-5 or be as high as 10-3 this being a
reflection of the range of occupational exposures that could be
associated with the relative and absolute risk levels observed in the
occupational studies.
While these risk estimates are exploratory and not intended to
provide a definitive characterization of cancer risk, they are useful
in gauging the possible range of risk based on reasonable judgement. It
is important to note that the possible risks could also be higher or
lower and a zero risk cannot be ruled out. Some individuals in the
population may have a high tolerance to exposure from diesel exhaust
and low cancer susceptibility. Also, one cannot rule out the
possibility of a threshold of exposure below which there is no cancer
risk, although evidence has not been seen or substantiated on this
point.
Also, as discussed in the Diesel HAD, there is a relatively small
difference between some occupational settings where increased lung
cancer risk is reported and ambient environmental exposures. The
potential for small exposure differences underscores the
appropriateness of the extrapolation from occupational risk to ambient
environmental exposure levels is reasonable and appropriate.
EPA also recently completed an assessment of air toxic emissions
(the National-Scale Air Toxics Assessment or NATA) and their associated
risk, and we concluded that diesel exhaust ranks with other substances
that the national-scale assessment suggests pose the greatest relative
risk.\35\ This assessment estimates average population inhalation
exposures to diesel PM in 1996 for nonroad as well as on-road sources.
These are the sum of ambient levels in various locations weighted by
the amount of time people spend in each of the locations. This analysis
shows a somewhat higher diesel exposure level than the 0.8 ug/m\3\ used
to develop the risk perspective in the Diesel HAD. The NATA levels are
1.4 ug/m\3\ total with an on-road source contribution of 0.5 ug/m\3\ to
average nationwide exposure in 1996 and a nonroad source contribution
of 0.9 ug/m\3\. The average urban exposure concentration was 1.6 ug/
m\3\ and the average rural concentration was 0.55 ug/m\3\. In five
percent of urban census tracts across the United States, average
concentrations were above 4.3 ug/m\3\. The Diesel HAD states that use
of the NATA exposure number results instead of the 0.8 ug/m\3\ results
in a similar risk perspective.
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\35\ U.S. EPA (2002). National-Scale Air Toxics Assessment. This
material is available electronically at http://www.epa.gov/ttn/atw/
nata/.
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In 2001, EPA completed a rulemaking on mobile source air toxics
with a determination that diesel particulate matter and diesel exhaust
organic gases be identified as a Mobile Source Air Toxic (MSAT).\36\
This determination was based on a draft of the Diesel HAD on which the
Clean Air Scientific Advisory Committee of the Science Advisory Board
had reached closure. The purpose of the MSAT list is to provide a
screening tool that identifies compounds emitted from motor vehicles or
their fuels for which further evaluation of emissions controls is
appropriate.
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\36\ U.S. EPA (2001). Control of Emissions of Hazardous Air
Pollutants from Mobile Sources; Final Rule. 66 FR 17230-17273 (March
29, 2001).
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In summary, even though EPA does not have a specific carcinogenic
potency with which to accurately estimate the carcinogenic impact of
diesel PM, the likely hazard to humans at environmental exposure levels
leads us to conclude that diesel exhaust emissions of PM and organic
gases should be reduced from nonroad engines in order to protect public
health.
ii. Other Health Effects of Diesel Exhaust
The acute and chronic exposure-related effects of diesel exhaust
emissions are also of concern to the Agency. The Diesel HAD established
an inhalation Reference Concentration (RfC) specifically based on
animal studies of diesel exhaust. An RfC is defined by EPA as ``an
estimate of a continuous inhalation exposure to the human population,
including sensitive subgroups, with uncertainty spanning
[[Page 28343]]
perhaps an order of magnitude, that is likely to be without appreciable
risks of deleterious noncancer effects during a lifetime.'' EPA derived
the RfC from consideration of four chronic rat inhalation studies
showing adverse pulmonary effects. The diesel RfC is based on a ``no
observable adverse effect'' level of 144 ug/m\3\ that is further
reduced by applying uncertainty factors of 3 for interspecies
extrapolation and 10 for human variations in sensitivity. The resulting
RfC derived in the Diesel HAD is 5 ug/m\3\ for diesel exhaust as
measured by diesel PM. This RfC does not consider allergenic effects
such as those associated with asthma or immunologic effects. There is
growing evidence that diesel exhaust can exacerbate these effects, but
the exposure-response data is presently lacking to derive an RfC.
Again, this RfC is based on animal studies and is meant to estimate
exposure that is unlikely to have deleterious effects on humans based
on those studies alone.
The Diesel HAD also briefly summarizes health effects associated
with ambient PM and the EPA's annual NAAQS for PM2.5 of 15
ug/m\3\. There is a much more extensive body of human data showing a
wide spectrum of adverse health effects associated with exposure to
ambient PM, of which diesel exhaust is an important component due to
its large contribution to ambient concentrations. The RfC is not meant
to say that 5 ug/m\3\ provides adequate public health protection for
ambient PM2.5. There may be benefits to reducing diesel PM
below 5 ug/m\3\ since diesel PM is a major contributor to ambient
PM2.5. Recent epidemiologic studies of ambient PM2.5 do not
indicate a threshold of effects at low concentrations.\37\
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\37\ EPA-SAB-Council-ADV-99-012, 1999. The Clean Air Act
Amendments Section 812 Prospective Study of Costs and Benefits
(1999): Advisory by the Health and Ecological Effects Subcommittee
on Initial Assessments of Health and Ecological Effects, Part 1.
July 28, 1999.
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Also, as mentioned earlier in the health effects discussion for
PM2.5, there are a number of other health effects associated
with PM in general, and motor vehicle exhaust including diesels in
particular, that provide additional evidence for the need for
significant emission reductions from nonroad diesel sources. For
example, the Diesel HAD notes that acute or short-term exposure to
diesel exhaust can cause acute irritation (e.g., eye, throat,
bronchial), neurophysiological symptoms (e.g., lightheadedness,
nausea), and respiratory symptoms (e.g., cough, phlegm). There is also
evidence for an immunologic effect such as the exacerbation of
allergenic responses to know allergens and asthma-like symptoms. All of
these health effects plus the designation of diesel exhaust as a likely
human carcinogen provide ample health justification for control.
iii. Ambient Levels and Exposure to Diesel Exhaust PM
Because diesel PM is part of overall ambient PM and cannot be
easily distinguished from overall PM, we do not have direct
measurements of diesel PM in the ambient air. Ambient diesel PM
concentrations are estimated instead using one of three approaches: (1)
Ambient air quality modeling based on diesel PM emission inventories;
(2) using elemental carbon concentrations in monitored data as
surrogates; or (3) using the chemical mass balance (CMB) model in
conjunction with ambient PM measurements. (Also, in addition to CMB,
UNMIX/PMF have also been used). Estimates using these three approaches
are described below. In addition, estimates developed using the first
two approaches above are subjected to a statistical comparison to
evaluate overall reasonableness of estimated concentrations. It is
important to note that, while there are inconsistencies in some of
these studies on the relative importance of gasoline and diesel PM, the
studies which are discussed in the Diesel HAD all show that diesel PM
is a significant contributor to overall ambient PM. Some of the studies
differentiate nonroad from on-road diesel PM.
(1) Air Quality Modeling
In addition to the general ambient PM modeling conducted for this
proposal, diesel PM concentrations specifically were recently estimated
for 1996 as part of NATA. In this assessment, the PM inventory
developed for the recent regulation promulgating 2007 heavy duty
vehicle standards was used. Note that the nonroad inventory used in
this modeling was based on an older version of the draft NONROAD Model
which showed higher diesel PM than the current version. Ambient impacts
of mobile source emissions were predicted using the Assessment System
for Population Exposure Nationwide (ASPEN) dispersion model. Overall
mean annual national levels for both on-road and nonroad diesels of
2.06 ug/m\3\ diesel PM were calculated with a mean of 2.41 in urban
counties and 0.74 in rural counties. These are ambient levels such as
would be seen at monitors rather than the exposure levels discussed
earlier. Over half of the diesel PM comes from nonroad diesels.
Diesel PM concentrations were also recently modeled across a
representative urban area, Houston, for 1996, using the Industrial
Source Complex Short Term (ISCST3) model. This modeling is designed to
more specifically account for local traffic patterns including diesel
truck traffic along specific roadways. The modeling in Houston suggests
strong spatial gradients for Diesel PM and indicates that ``hotspot''
concentrations can be very high, up to 8 ug/m\3\ at receptor versus a 3
ug/m\3\ average in Houston. Such concentrations are above the RfC for
diesel exhaust and indicate a potential for adverse health effects from
chronic exposure to diesel PM. These results also suggest that PM from
diesel vehicles makes a major contribution to total ambient PM
concentrations. Such ``hot spot'' concentrations along certain roadways
suggest the presence of both high localized exposures plus higher
estimated average annual exposure levels for urban centers than what
has been estimated in assessments such as NATA, which are designed to
focus on regional and national scale averages. There are similar ``hot
spot'' concentrations in the immediate vicinity of use of nonroad
equipment such as in urban construction sites.
(2) Elemental Carbon Measurements
As mentioned before, the carbonaceous component is significant in
ambient PM. The carbonaceous component consists of organic carbon and
elemental carbon. Monitoring data on elemental carbon concentrations
can be used as a surrogate to determine ambient diesel PM
concentrations. Elemental carbon is a major component of diesel
exhaust, contributing to approximately 60 to 80 percent of diesel
particulate mass, depending on engine technology, fuel type, duty
cycle, lube oil consumption, and state of engine maintenance. In most
areas, diesel engine emissions are major contributors to elemental
carbon in the ambient air, with other potential sources including
gasoline exhaust, combustion of coal, oil, or wood (including forest
fires), charbroiling, cigarette smoke, and road dust. Because of the
large portion of elemental carbon in diesel particulate matter, and the
fact that diesel exhaust is one of the major contributors to elemental
carbon in most areas, ambient diesel PM concentrations can be bounded
using elemental carbon measurements.
The measured mass of elemental carbon at a given site varies
depending on the measurement technique used. Moreover, to estimate
diesel PM concentration based on elemental
[[Page 28344]]
carbon level, one must first estimate the percentage of PM attributable
to diesel engines and the percentage of elemental carbon in diesel PM.
Thus, there are significant uncertainties in estimating diesel PM
concentrations using an elemental carbon surrogate. Depending on the
measurement technique used, and assumptions made, average nationwide
concentrations for current years of diesel PM estimated from elemental
carbon data range from about 1.2 to 2.2 ug/m\3\. EPA has compared these
estimates based on elemental carbon measurements to modeled
concentrations in NATA and concluded that the two sets of data agree
reasonably well. This performance compares favorably with the model to
monitor results for other pollutants assessed in NATA, with the
exception of benzene, for which the performance of the NATA modeling
was better. These comparisons are discussed in greater detail in the
draft RIA.
(3) Chemical Mass Balance
The third approach for estimating ambient diesel PM concentrations
uses the CMB model for source apportionment in conjunction with ambient
PM measurements and chemical source ``fingerprints'' to estimate
ambient diesel PM concentrations. The CMB model uses a statistical
fitting technique to determine how much mass from each source would be
required to reproduce the chemical fingerprint of each speciated
ambient monitor. This source apportionment technique presently does not
distinguish between on-road and nonroad but, instead, gives diesel PM
as a whole. This source apportionment technique can distinguish between
diesel and gasoline PM. Caution in interpreting CMB results is
warranted, as the use of fitting species that are not specific to the
sources modeled can lead to misestimation of source contributions.
Ambient concentrations using this approach are generally about 1 ug/
m\3\ annual average. UNMIX/PMF models show similar results. Results
from various studies are discussed in the draft RIA.
iv. Diesel Exhaust PM Exposures
Exposure of people to diesel exhaust depends on their various
activities, the time spent in those activities, the locations where
these activities occur, and the levels of diesel exhaust pollutants
(such as particulate) in those locations. The major difference between
ambient levels of diesel particulate and exposure levels for diesel
particulate is that exposure accounts for a person moving from location
to location, proximity to the emission source, and whether the exposure
occurs in an enclosed environment.
(1) Occupational Exposures
Diesel particulate exposures have been measured for a number of
occupational groups over various years but generally for more recent
years (1980s and later) rather than earlier years. Occupational
exposures had a wide range varying from 2 to 1,280 ug/m3 for
a variety of occupational groups including miners, railroad workers,
firefighters, air port crew, public transit workers, truck mechanics,
utility linemen, utility winch truck operators, fork lift operators,
construction workers, truck dock workers, short-haul truck drivers, and
long-haul truck drivers. These individual studies are discussed in the
Diesel HAD. As discussed in the Diesel HAD, the National Institute of
Occupational Safety and Health (NIOSH) has estimated a total of
1,400,000 workers are occupationally exposed to diesel exhaust from on-
road and nonroad equipment.
Many measured or estimated occupational exposures are for on-road
diesel engines although some (especially the higher ones) are for
occupational groups (e.g., fork lift operators, construction workers,
or mine workers) who would be exposed to nonroad diesel exhaust.
Sometimes, as is the case for the nonroad engines, there are only
estimates of exposure based on the length of employment or similar
factors rather than a ug/m3 level. Estimates for exposures
to diesel PM for diesel fork lift operators have been made that range
from 7 to 403 ug/m3 as reported in the Diesel HAD. In
addition, the Northeast States for Coordinated Air Use Management
(NESCAUM) is presently measuring occupational exposures to particulate
and elemental carbon near the operation of various diesel non-road
equipment. Exposure groups include agricultural farm operators, grounds
maintenance personnel (lawn and garden equipment), heavy equipment
operators conducting multiple job tasks at a construction site, and a
saw mill crew at a lumber yard. Samples will be obtained in the
breathing zone of workers. Some initial results are expected in late
2003.
(2) General Ambient Exposures
Currently, personal exposure monitors for PM cannot differentiate
diesel from other PM. Thus, we use modeling to estimate exposures.
Specifically, exposures for the general population are estimated by
first conducting dispersion modeling of both on-road and non-road
diesel emissions, described above, and then by conducting exposure
modeling. The most comprehensive modeling for cumulative exposures to
diesel PM is the NATA. This assessment calculates exposures of the
national population as a whole to a variety of air toxics, including
diesel PM. As discussed previously, the ambient levels are calculated
using the ASPEN dispersion model. The preponderance of modeled diesel
PM concentrations are within a factor of 2 of diesel PM concentrations
estimated from elemental carbon measurements.\38\ This comparison adds
credence to the modeled ASPEN results and associated exposure
assessment.
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\38\ U.S. EPA (2002). Diesel PM model-to-measurement comparison.
Prepared by ICF Consulting for EPA, Office of Transportation and Air
Quality. Report No. EPA420-D-02-004.
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The modeled ambient concentrations are used as inputs into the
Hazardous Air Pollution Exposure Model (HAPEM4) to calculate exposure
levels. Average exposures calculated nationwide are 1.44 ug/
m3 with levels of 1.64 ug/m3 for urban counties
and 0.55 ug/m3 for rural counties. Again, nonroad diesels
account for over half of this modeled exposure.
(3) Ambient Exposures--Microenvironments
One common microenvironment for diesel exposure is beside freeways.
Although freeway locations are associated mostly with on-road rather
than nonroad diesels, there are many similarities between on-road and
nonroad diesel emissions as discussed in the Diesel HAD. The California
Air Resources Board (CARB) measured elemental carbon near the Long
Beach Freeway in 1993. Levels measured ranged from 0.4 to 4.0 ug/
m3 (with one value as high as 7.5 ug/m3) above
background levels. Microenvironments associated with nonroad engines
would include construction zones. PM and elemental carbon samples are
being collected by NESCAUM in the immediate area of the nonroad engine
operations (such as at the edge or fence line of the construction
zone). Besides PM and elemental carbon levels, various toxics such as
benzene, 1,3-butadiene, formaldehyde, and acetaldehyde will be sampled.
Some initial results should be available in late 2003 and will be
especially useful since they focus on those microenvironments affected
by nonroad diesels.
Also, EPA is funding research in Fresno to measure indoor and
outdoor PM component concentrations in the homes of over 100 asthmatic
children. Some of these homes are located near
[[Page 28345]]
agricultural, construction, and utility nonroad equipment operations.
This work will measure infiltration of elemental carbon and other PM
components to indoor environments. The project also evaluates lung
function changes in the asthmatic children during fluctuations in
exposure concentrations and compositions. This information may allow an
evaluation of adverse health effects associated with exposures to
elemental carbon and other PM components from on-road and nonroad
sources. Some initial results may be available in late 2003.
b. Gaseous Air Toxics
Nonroad diesel engine emissions contain several substances known or
suspected as human or animal carcinogens, or that have noncancer health
effects. These other compounds include benzene,1,3-butadiene,
formaldehyde, acetaldehyde, acrolein, dioxin, and polycyclic organic
matter (POM). For some of these pollutants, nonroad diesel engine
emissions are believed to account for a significant proportion of total
nation-wide emissions. All of these compounds were identified as
national or regional ``risk'' drivers in the 1996 NATA. That is, these
compounds pose a significant portion of the total inhalation cancer
risk to a significant portion of the population. Mobile sources
contribute significantly to total emissions of these air toxics. As
discussed later in this section, this proposed rulemaking will result
in significant reductions of these emissions.
Benzene: Nonroad diesel engines accounted for about 3 percent of
ambient benzene emissions in 1996. Of ambient benzene levels due to
mobile sources, 5 percent in urban and 3 percent in rural areas came
from nonroad diesel.
The EPA's IRIS database lists benzene as a known human carcinogen
(causing leukemia at high, prolonged air exposures) by all routes of
exposure, and exposure is associated with additional health effects
including genetic changes in humans and animals and increased
proliferation of bone marrow cells in mice.39 40 41 42 EPA
states in its IRIS database that the data indicate a causal
relationship between benzene exposure and acute lymphocytic leukemia
and suggest a relationship between benzene exposure and chronic non-
lymphocytic leukemia and chronic lymphocytic leukemia. Respiration is
the major source of human exposure and at least half of this exposure
is attributable to gasoline vapors and automotive emissions. A number
of adverse noncancer health effects including blood disorders, such as
preleukemia and aplastic anemia, have also been associated with low-
dose, long-term exposure to benzene.43 44
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\39\ U.S. EPA (2000). Integrated Risk Information System File
for Benzene. This material is available electronically at http://
www.epa.gov/iris/subst/0276.htm.
\40\ International Agency for Research on Cancer, IARC
monographs on the evaluation of carcinogenic risk of chemicals to
humans, Volume 29, Some industrial chemicals and dyestuffs,
International Agency for Research on Cancer, World Health
Organization, Lyon, France, p. 345-389, 1982.
\41\ Irons, R.D., W.S. Stillman, D.B. Colagiovanni, and V.A.
Henry, Synergistic action of the benzene metabolite hydroquinone on
myelopoietic stimulating activity of granulocyte/macrophage colony-
stimulating factor in vitro, Proc. Natl. Acad. Sci. 89:3691-3695,
1992.
\42\ U.S. EPA (1998). Carcinogenic Effects of Benzene: An
Update, National Center for Environmental Assessment, Washington,
DC. 1998.
\43\ Aksoy, M. (1989). Hematotoxicity and carcinogenicity of
benzene. Environ. Health Perspect. 82: 193-197.
\44\ Goldstein, B.D. (1988). Benzene toxicity. Occupational
medicine. State of the Art Reviews. 3: 541-554.
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1,3-Butadiene: Nonroad diesel engines accounted for about 1.5
percent of ambient butadiene emissions in 1996. Of ambient butadiene
levels due to mobile sources, 4 percent in urban and 2 percent in rural
areas came from nonroad diesel.
EPA earlier identified 1,3-butadiene as a probable human carcinogen
in its IRIS database and recently redesignated it as a known human
carcinogen (but with a lower carcinogenic potency than previously
used).\45\ The specific mechanisms of 1,3-butadiene-induced
carcinogenesis are unknown, however, it is virtually certain that the
carcinogenic effects are mediated by genotoxic metabolites of 1,3-
butadiene. Animal data suggest that females may be more sensitive than
males for cancer effects; nevertheless, there are insufficient data
from which to draw any conclusions on potentially sensitive
subpopulations. 1,3-Butadiene also causes a variety of reproductive and
developmental effects in mice; no human data on these effects are
available. The most sensitive effect was ovarian atrophy observed in a
lifetime bioassay of female mice.\46\
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\45\ U.S. EPA (2002). Health Assessment of 1,3-Butadiene. Office
of Research and Development, National Center for Environmental
Assessment, Washington Office, Washington, DC. Report No. EPA/600/P-
98/001F.
\46\ Bevan, C; Stadler, JC; Elliot, GS; et al. (1996) Subchronic
toxicity of 4-vinylcyclohexene in rats and mice by inhalation.
Fundam. Appl. Toxicol. 32:1-10.
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Formaldehyde: Nonroad diesel engines accounted for about 22 percent
of ambient formaldehyde emissions in 1996. Of ambient formaldehyde
levels due to mobile sources, 37 percent in urban and 27 percent in
rural areas came form nonroad diesel. These figures are for tailpipe
emissions of formaldehyde. Formaldehyde in the ambient air comes not
only from tailpipe (of direct) emissions but is also formed from
photochemical reactions of hydrocarbons.
EPA has classified formaldehyde as a probable human carcinogen
based on evidence in humans and in rats, mice, hamsters, and
monkeys.\47\ Epidemiological studies in occupationally exposed workers
suggest that long-term inhalation of formaldehyde may be associated
with tumors of the nasopharyngeal cavity (generally the area at the
back of the mouth near the nose), nasal cavity, and sinus.\48\
Formaldehyde exposure also causes a range of noncancer health effects,
including irritation of the eyes (tearing of the eyes and increased
blinking) and mucous membranes. Sensitive individuals may experience
these adverse effects at lower concentrations than the general
population and in persons with bronchial asthma, the upper respiratory
irritation caused by formaldehyde can precipitate an acute asthmatic
attack. The agency is currently conducting a reassessment of risk from
inhalation exposure to formaldehyde.
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\47\ U.S. EPA (1987). Assessment of Health Risks to Garment
Workers and Certain Home Residents from Exposure to Formaldehyde,
Office of Pesticides and Toxic Substances, April 1987.
\48\ Blair, A., P.A. Stewart, R.N. Hoover, et al. (1986).
Mortality among industrial workers exposed to formaldehyde. J. Natl.
Cancer Inst. 76(6): 1071-1084.
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Acetaldehyde: Nonroad diesel engines accounted for about 34 percent
of acetaldehyde emissions in 1996. Of ambient acetaldehyde levels due
to mobile sources, 24 percent in urban and 17 percent in rural areas
came form nonroad diesel. Also, acetaldehyde can be formed
photochemically in the atmosphere. Counting both direct emissions and
photochemically formed acetaldehyde, mobile sources were responsible
for the major portion of acetaldehyde in the ambient air according to
the National-Scale Air Toxics Assessment for 1996.
Acetaldehyde is classified in EPA's IRIS database as a probable
human carcinogen and is considered moderately toxic by the inhalation,
oral, and intravenous routes.\49\ The primary acute effect of exposure
to acetaldehyde vapors is irritation of the eyes, skin, and
[[Page 28346]]
respiratory tract. At high concentrations, irritation and pulmonary
effects can occur, which could facilitate the uptake of other
contaminants. Some asthmatics have been shown to be a sensitive
subpopulation to decrements in FEV1 upon acetaldehyde inhalation.\50\
The agency is currently conducting a reassessment of risk from
inhalation exposure to acetaldehyde.
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\49\ U.S. EPA (1988). Integrated Risk Information System File of
Acetaldehyde. This material is available electronically at http://
www.epa.gov/iris/subst/0290.htm.
\50\ Myou, S.; Fujimura, M.; Nishi K.; Ohka, T.; and Matsuda, T.
(1993) Aerosolized acetaldehyde induces histamine-mediated
bronchoconstriction in asthmatics. Am Rev Respir Dis 148(4 Pt 1):
940-3.
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Acrolein: Nonroad diesel engines accounted for about 17.5 percent
of acrolein emissions in 1996. Of ambient acrolein levels due to mobile
sources, 28 percent in urban and 18 percent in rural areas came form
nonroad diesel.
Acrolein is extremely toxic to humans when inhaled, with acute
exposure resulting in upper respiratory tract irritation and
congestion. The Agency has developed a reference concentration for
inhalation (RfC) of acrolein of 0.02 micrograms/m\3\.\51\
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\51\ U.S. EPA (1993). Environmental Protection Agency,
Integrated Risk Information System (IRIS), National Center for
Environmental Assessment, Cincinnati, OH.
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Although no information is available on its carcinogenic effects in
humans, based on laboratory animal data, EPA considers acrolein a
possible human carcinogen.
Polycyclic Organic Matter (POM): POM is generally defined as a
large class of chemicals consisting of organic compounds having
multiple benzene rings and a boiling point greater than 100 degrees C.
Polycyclic aromatic hydrocarbons (PAHs) are a chemical class that is a
subset of POM. POM are naturally occurring substances that are
byproducts of the incomplete combustion of fossil fuels and plant and
animal biomass (e.g., forest fires). They occur as byproducts from
steel and coke productions and waste incineration. They also are a
component of diesel particulate emissions. Many of the compounds
included in the class of compounds known as POM are classified by EPA
as probable human carcinogens based on animal data. In particular, EPA
frequently obtains data on 7 of the POM compounds, which we analyzed
separately as a class in the 1996 NATA. Nonroad diesel engines account
for less than 1 percent of these 7 POM compounds with total mobile
sources responsible for only 4 percent of the total; most of the 7 POMs
come from area sources. For total POM compounds, mobile sources as a
whole are responsible for only 1 percent. The mobile source emission
numbers used to derive these inventories are based on only particulate
phase POM and do not include the semi-volatile phase POM levels. Were
those additional POMs included (which is now being done), these
inventory numbers would be substantially higher.
Even though mobile sources are responsible for only a small portion
of total POM emissions, the particulate reductions from today's action
will reduce these emissions.
Dioxins: Recent studies have confirmed that dioxins are formed by
and emitted from diesels (both heavy-duty diesel trucks and non-road
diesels although in very small amounts) and are estimated to account
for about 1 percent of total dioxin emissions in 1995. Recently EPA
issued a draft assessment designating one dioxin compound, 2,3,7,8-
tetrachlorodibenzo-p-dioxin as a human carcinogen and the complex
mixtures of dioxin-like compounds as likely to be carcinogenic to
humans using the draft 1996 carcinogen risk assessment guidelines. EPA
is working on its final assessment for dioxin.\52\ An interagency
review group is evaluating EPA's designation of dioxin as a likely
human carcinogen. Reductions from today's nonroad proposal will have
minimal impact on overall dioxin emissions.
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\52\ U.S. EPA (June 2000) Exposure and Human Health Reassessment
of 2,3,7,8-Tetrachlorodibenzo-p-Dioxin (TCDD) and Related Compounds,
External Review Draft, EPA/600/P-00/001Ag. This material is
available electronically at http://www.epa.gov/ncea/dioxin.htm.
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3. Ozone
a. What Are the Health Effects of Ozone Pollution?
Ground-level ozone pollution (sometimes called ``smog'') is formed by
the reaction of volatile organic compounds (VOC) and nitrogen oxides
(NOX) in the atmosphere in the presence of heat and
sunlight. These two pollutants, often referred to as ozone precursors,
are emitted by many types of pollution sources, including on-road and
off-road motor vehicles and engines, power plants and industrial
facilities, and smaller ``area'' sources.
Ozone can irritate the respiratory system, causing coughing, throat
irritation, and/or uncomfortable sensation in the
chest.53 54 Ozone can reduce lung function and make it more
difficult to breathe deeply, and breathing may become more rapid and
shallow than normal, thereby limiting a person's normal activity. Ozone
also can aggravate asthma, leading to more asthma attacks that require
a doctor's attention and/or the use of additional medication. In
addition, ozone can inflame and damage the lining of the lungs, which
may lead to permanent changes in lung tissue, irreversible reductions
in lung function, and a lower quality of life if the inflammation
occurs repeatedly over a long time period (months, years, a lifetime).
People who are of particular concern with respect to ozone exposures
include children and adults who are active outdoors. Those people
particularly susceptible to ozone effects are people with respiratory
disease, such as asthma, and people with unusual sensitivity to ozone,
and children. Beyond its human health effects, ozone has been shown to
injure plants, which has the effect of reducing crop yields and
reducing productivity in forest ecosystems.55 56
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\53\ U.S. EPA (1996). Air Quality Criteria for Ozone and Related
Photochemical Oxidants, EPA/600/P-93/004aF. Docket No. A-99-06.
Document Nos. II-A-15 to 17.
\54\ U.S. EPA. (1996). Review of National Ambient Air Quality
Standards for Ozone, Assessment of Scientific and Technical
Information, OAQPS Staff Paper, EPA-452/R-96-007. Docket No. A-99-
06. Document No. II-A-22.
\55\ U.S. EPA (1996). Air Quality Criteria for Ozone and Related
Photochemical Oxidants, EPA/600/P-93/004aF. Docket No. A-99-06.
Document Nos. II-A-15 to 17.
\56\ U.S. EPA. (1996). Review of National Ambient Air Quality
Standards for Ozone, Assessment of Scientific and Technical
Information, OAQPS Staff Paper, EPA-452/R-96-007. Docket No. A-99-
06. Document No. II-A-22.
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The 8-hour ozone standard, established by EPA in 1997, is based on
well-documented science demonstrating that more people are experiencing
adverse health effects at lower levels of exertion, over longer
periods, and at lower ozone concentrations than addressed by the one-
hour ozone standard. (See, e.g., 62 FR 38861-62, July 18, 1997). The 8-
hour standard addresses ozone exposures of concern for the general
population and populations most at risk, including children active
outdoors, outdoor workers, and individuals with pre-existing
respiratory disease, such as asthma.
There has been new research that suggests additional serious health
effects beyond those that had been known when the 8-hour ozone health
standard was set. Since 1997, over 1,700 new health and welfare studies
relating to ozone have been published in peer-reviewed journals.\57\
Many of these studies have investigated the impact of ozone exposure on
such health effects as changes in lung structure and biochemistry,
inflammation of the
[[Page 28347]]
lungs, exacerbation and causation of asthma, respiratory illness-
related school absence, hospital and emergency room visits for asthma
and other respiratory causes, and premature mortality. EPA is currently
in the process of evaluating these and other studies as part of the
ongoing review of the air quality criteria and NAAQS for ozone. A
revised Air Quality Criteria Document for Ozone and Other Photochemical
Oxidants will be prepared in consultation with EPA's Clean Air Science
Advisory Committee (CASAC). Key new health information falls into four
general areas: development of new-onset asthma, hospital admissions for
young children, school absence rate, and premature mortality.
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\57\ New Ozone Health and Environmental Effects References,
Published Since Completion of the Previous Ozone AQCD, National
Center for Environmental Assessment, Office of Research and
Development, U.S. Environmental Protection Agency, Research Triangle
Park, NC 27711 (7/2002) Docket No. A-2001-11. Document No. IV-A-19.
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Aggravation of existing asthma resulting from short-term ambient
ozone exposure was reported prior to the 1997 decision and has been
observed in studies published subsequently.58 59 In
particular, a relationship between long-term ambient ozone
concentrations and the incidence of new-onset asthma in adult males
(but not in females) was reported by McDonnell et al. (1999).\60\
Subsequently, an additional study suggests that incidence of new
diagnoses of asthma in children is associated with heavy exercise in
communities with high concentrations (i.e., mean 8-hour concentration
of 59.6 ppb) of ozone.\61\ This relationship was documented in children
who played 3 or more sports and thus had higher exposures and was not
documented in those children who played one or two sports. The larger
effect of high activity sports than low activity sports and an
independent effect of time spent outdoors also in the higher ozone
communities strengthened the inference that exposure to ozone may
modify the effect of sports on the development of asthma in some
children.
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\58\ Thurston, G.D., M.L. Lippman, M.B. Scott, and J.M. Fine.
1997. Summertime Haze Air Pollution and Children with Asthma.
American Journal of Respiratory Critical Care Medicine, 155: 654-
660.
\59\ Ostro, B, M. Lipsett, J. Mann, H. Braxton-Owens, and M.
White (2001) Air pollution and exacerbation of asthma in African-
American children in Los Angeles. Epidemiology 12(2): 200-208.
\60\ McDonnell, W.F., D.E. Abbey, N. Nishino and M.D. Lebowitz.
1999. ``Long-term ambient ozone concentration and the incidence of
asthma in nonsmoking adults: the ahsmog study.'' Environmental
Research. 80(2 Pt 1): 110-121.
\61\ McConnell, R.; Berhane, K.; Gilliland, F.; London, S.J.;
Islam, T.; Gauderman, W.J.; Avol, E.; Margolis, H.G.; Peters, J.M.
(2002) Asthma in exercising children exposed to ozone: a cohort
study. Lancet 359: 386-391.
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Previous studies have shown relationships between ozone and
hospital admissions in the general population. A study in Toronto
reported a significant relationship between 1-hour maximum ozone
concentrations and respiratory hospital admissions in children under
the age of two.\62\ Given the relative vulnerability of children in
this age category, we are particularly concerned about the findings.
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\62\ Burnett, R.T.; Smith--Doiron, M.; Stieb, D.; Raizenne,
M.E.; Brook, J.R.; Dales, R.E.; Leech, J.A.; Cakmak, S.; Krewski, D.
(2001) Association between ozone and hospitalization for acute
respiratory diseases in children less than 2 years of age. Am. J.
Epidemiol. 153: 444-452.
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Increased respiratory disease that are serious enough to cause
school absences have been associated with 1-hour daily maximum and 8-
hour average ozone concentrations in studies conducted in Nevada \63\
in kindergarten to 6th grade and in Southern California in grades 4
through 6.\64\ These studies suggest that higher ambient ozone levels
may result in increased school absenteeism.
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\63\ Chen, L.; Jennison, B.L.; Yang, W.; Omaye, S.T. (2000)
Elementary school absenteeism and air pollution. Inhalation Toxicol.
12: 997-1016.
\64\ Gilliland, FD, K Berhane, EB Rappaport, DC Thomas, E Avol,
WJ Gauderman, SJ London, HG Margolis, R McConnell, KT Islam, JM
Peters (2001) The effects of ambient air pollution on school
absenteeism due to respiratory illnesses Epidemiology 12:43-54.
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The air pollutant most clearly associated with premature mortality
is PM, with dozens of studies reporting such an association. However,
repeated ozone exposure is a possible contributing factor for premature
mortality, causing an inflammatory response in the lungs which may
predispose elderly and other sensitive individuals to become more
susceptible to other stressors, such as PM.65 66 67 Although
the findings have been mixed, the findings of three recent analyses
suggest that ozone exposure is associated with increased mortality.
Although the National Morbidity, Mortality, and Air Pollution Study
(NMMAPS) did not report an effect of ozone on total mortality across
the full year, the investigators who conducted the NMMAPS study did
observe an effect after limiting the analysis to summer when ozone
levels are highest.68 69 Similarly, other studies have shown
associations between ozone and mortality.70 71 Specifically,
Toulomi et al. (1997) found that 1-hour maximum ozone levels were
associated with daily numbers of deaths in 4 cities (London, Athens,
Barcelona, and Paris), and a quantitatively similar effect was found in
a group of four additional cities (Amsterdam, Basel, Geneva, and
Zurich).
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\65\ Samet JM, Zeger SL, Dominici F, Curriero F, Coursac I,
Dockery DW, Schwartz J, Zanobetti A. 2000. The National Morbidity,
Mortality and Air Pollution Study: Part II: Morbidity, Mortality and
Air Pollution in the United States. Research Report No. 94, Part II.
Health Effects Institute, Cambridge MA, June 2000. (Docket Number A-
2000-01, Document Nos. IV-A-208 and 209).
\66\ Devlin, R.B.; Folinsbee, L.J.; Biscardi, F.; Hatch, G.;
Becker, S.; Madden, M.C.; Robbins, M.; Koren, H. S. (1997)
Inflammation and cell damage induced by repeated exposure of humans
to ozone. Inhalation Toxicol. 9: 211-235.
\67\ Koren HS, Devlin RB, Graham DE, Mann R, McGee MP, Horstman
DH, Kozumbo WJ, Becker S, House DE, McDonnell SF, Bromberg, PA.
1989. Ozone-induced inflammation in the lower airways of human
subjects. Am. Rev. Respir. Dies. 139: 407-415.
\68\ Samet JM, Zeger SL, Dominici F, Curriero F, Coursac I,
Dockery DW, Schwartz J, Zanobetti A. 2000. The National Morbidity,
Mortality and Air Pollution Study: Part II: Morbidity, Mortality and
Air Pollution in the United States. Research Report No. 94, Part II.
Health Effects Institute, Cambridge MA, June 2000. (Docket Number A-
2000-01, Documents No. IV-A-208 and 209).
\69\ Samet JM, Zeger SL, Dominici F, Curriero F, Coursac I,
Zeger, S. Fine Particulate Air Pollution and Mortality in 20 U.S.
Cities, 1987--1994. The New England Journal of Medicine. Vol. 343,
No. 24, December 14, 2000. P. 1742-1749.
\70\ Thurston, G.D.; Ito, K. (2001) Epidemiological studies of
acute ozone exposures and mortality. J. Exposure Anal. Environ.
Epidemiol. 11: 286-294.
\71\ Touloumi, G.; Katsouyanni, K.; Zmirou, D.; Schwartz, J.;
Spix, C.; Ponce de Leon, A.; Tobias, A.; Quennel, P.; Rabczenko, D.;
Bacharova, L.; Bisanti, L.; Vonk, J.M.; Ponka, A. (1997) Short-term
effects of ambient oxidant exposure on mortality: a combined
analysis within the APHEA project. Am. J. Epidemiol. 146: 177-185.
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In all, the new studies that have become available since the 8-hour
ozone standard was adopted in 1997 continue to demonstrate the harmful
effects of ozone on public health, and the need to attain and maintain
the NAAQS.
b. Current and projected 8-hour ozone levels
As shown earlier (Figure II-1), unhealthy ozone concentrations
exceeding the level of the 8-hour standard (i.e., not requisite to
protect the public health with an adequate margin of safety) occur over
wide geographic areas, including most of the nation's major population
centers. These monitored areas include much of the eastern half of the
U.S. and large areas of California.
Based upon data from 1999-2001, there are 291 counties where 111
million people live that are measuring values that violate the 8-hour
ozone NAAQS.\72\ An additional 37 million people live in 155 counties
that have air quality measurements within 10 percent of the level of
the standard. These areas, though currently not violating the standard,
will also benefit from the additional emission reductions from this
rule.
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\72\ Additional counties may have levels above the NAAQS but do
not currently have monitors.
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From our air quality modeling for this proposal, we anticipate that
without emission reductions beyond those
[[Page 28348]]
already required under promulgated regulation and approved SIPs, ozone
nonattainment will likely persist into the future. With reductions from
programs already in place, the number of counties violating the ozone
8-hour standard is expected to decrease in 2020 to 30 counties where 43
million people are projected to live. Thereafter, exposure to unhealthy
levels of ozone is expected to begin to increase again. In 2030 the
number of counties violating the ozone 8-hour NAAQS is projected to
increase to 32 counties where 47 million people are projected to live.
In addition, in 2030, 82 counties where 44 million people are projected
to live will be within 10 percent of violating the ozone 8-hour NAAQS.
EPA is still developing the implementation process for bringing the
nation's air into attainment with the ozone 8-hour NAAQS. EPA's current
plans call for designating ozone 8-hour nonattainment areas in April
2004. EPA is planning to propose that States submit SIPs that address
how areas will attain the 8-hour ozone standard within three years
after nonattainment designation regardless of their classification. EPA
is also planning to propose that certain SIP components, such as those
related to reasonably available control technology (RACT) and
reasonable further progress (RFP) be submitted within 2 years after
designation. We therefore anticipate that States will submit their
attainment demonstration SIPs by April 2007. Section 172(a)(2) of the
Clean Air Act requires that SIP revisions for areas that may be covered
only under subpart 1 of part D, title I of the Act demonstrate that the
nonattainment areas will attain the ozone 8-hour standard as
expeditiously as practicable but no later than five years from the date
that the area was designated nonattainment. However, based on the
severity of the air quality problem and the availability and
feasibility of control measures, the Administrator may extend the
attainment date ``for a period of no greater than 10 years from the
date of designation as nonattainment.'' Based on these provisions, we
expect that most or all areas covered under subpart 1 will attain the
ozone standard in the 2007 to 2014 time frame. For areas covered under
subpart 2, the maximum attainment dates provided under the Act range
from 3 to 20 years after designation, depending on an area's
classification. Thus, we anticipate that areas covered by subpart 2
will attain in the 2007 to 2014 time period.
Since the emission reductions expected from this proposal would
begin during the same time period, the projected reductions in nonroad
emissions would be extremely important to States in their effort to
meet the new NAAQS. It is our expectation that States will be relying
on such nonroad reductions in order to help them attain and maintain
the 8-hour NAAQS. Furthermore, since the nonroad emission reductions
will continue to grow in the years beyond 2014, they will also be
important for maintenance of the NAAQS for areas with attainment dates
of 2014 and earlier.
Using air quality modeling of the impacts of emission reductions,
we have made estimates of the change in future ozone levels that would
result from the proposed rule.\73\ That modeling shows that this rule
would produce nationwide air quality improvements in ozone levels. On a
population-weighted basis, the average change in future year design
values would be a decrease of 1.6 ppb in 2020, and 2.6 ppb in 2030.
Within areas predicted to violate the NAAQS in the projected base case,
the average decrease would be somewhat higher: 1.9 ppb in 2020 and 3.0
ppb in 2030.\74\
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\73\ These results are ozone changes projected for the
preliminary control option used for our modeling, as discussed in
the Draft RIA in section 3.6. The proposal differs from the modeled
control case based on updated information; however, we believe that
the net results would approximate future emissions, although we
anticipate the ozone changes might be slightly different.
\74\ This is in spite of the fact that NOX reductions
can at certain times in some areas cause ozone levels to increase.
Such ``disbenefits'' are predicted in our modeling, but these
results make clear that the overall effect of the proposed rule is
positive. See the draft RIA for more information.
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The model predictions of whether specific counties will violate the
NAAQS or not is uncertain, especially for counties with design values
falling very close to the standard. This makes us more confident in our
prediction of average air quality changes than in our prediction of the
exact numbers of counties projected as exceeding the NAAQS.
Furthermore, actions by States to meet their SIP obligations will
change the number of counties violating the NAAQS in the time frame we
are modeling for this rule. If State actions resulted in an increase in
the number of areas that are very close to, but still above, the NAAQS,
then this rule might bring many of those counties down sufficiently to
eliminate remaining violations. In addition, if State actions brought
several counties we project to be very close to the standard in the
future down sufficiently to eliminate violations, then the air quality
improvements from this proposal might serve more to assist these areas
in maintaining the standards than in changing their status. Bearing
this in mind, our modeling indicates that, out of 32 counties predicted
to violate the NAAQS, the proposal would reduce the number of violating
counties by 2 in 2020 and by 4 in 2030, without consideration of new
State or Federal programs.
C. Other Environmental Effects
The following section presents information on five categories of
public welfare and environmental impacts related to nonroad heavy-duty
vehicle emissions: visibility impairment, acid deposition,
eutrophication of water bodies, plant damage from ozone, and water
pollution resulting from deposition of toxic air pollutants with
resulting effects on fish and wildlife.
1. Visibility
a. Visibility is Impaired by Fine PM and Precursor Emissions From
Nonroad Engines Subject to this Proposed Rule
Visibility can be defined as the degree to which the atmosphere is
transparent to visible light.\75\ Fine particles with significant
light-extinction efficiencies include organic matter, sulfates,
nitrates, elemental carbon (soot), and soil. Size and chemical
composition of particles strongly affects their ability to scatter or
absorb light. Sulfates contribute to visibility impairment especially
on the haziest days across the U.S., accounting in the rural Eastern
U.S. for more than 60 percent of annual average light extinction on the
best days and up to 86 percent of average light extinction on the
haziest days. Nitrates and elemental carbon each typically contribute 1
to 6 percent of average light extinction on haziest days in rural
Eastern U.S. locations.\76\
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\75\ National Research Council, 1993. Protecting Visibility in
National Parks and Wilderness Areas. National Academy of Sciences
Committee on Haze in National Parks and Wilderness Areas. National
Academy Press, Washington, DC. This document is available on the
Internet at http://www.nap.edu/books/0309048443/html/. See also U.S.
EPA Air Quality Criteria Document for Particulate Matter (1996)
(available on the Internet at http://cfpub.epa.gov/ncea/cfm/
partmatt.cfm) and Review of the National Ambient Air Quality
Standards for Particulate Matter: Policy Assessment of Scientific
and Technical Information. These documents can be found in Docket A-
99-06, Documents No. II-A-23 and IV-A-130-32.
\76\ U.S. EPA Trends Report 2001. This document is available on
the Internet at http://www.epa.gov/airtrends/.
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Visibility is important because it directly affects people's
enjoyment of daily activities in all parts of the country. Individuals
value good visibility for the well-being it provides them directly,
both in where they live and work, and in places where they enjoy
recreational opportunities.
[[Page 28349]]
Visibility is also highly valued in significant natural areas such as
national parks and wilderness areas, because of the special emphasis
given to protecting these lands now and for future generations.
To quantify changes in visibility, we compute a light-extinction
coefficient, which shows the total fraction of light that is decreased
per unit distance. Visibility can be described in terms of visual range
or light extinction and is reported using an indicator called
deciview.\77\ In addition to limiting the distance that one can see,
the scattering and absorption of light caused by air pollution can also
degrade the color, clarity, and contrast of scenes.
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\77\ Visual range can be defined as the maximum distance at
which one can identify a black object against the horizon sky. It is
typically described in miles or kilometers. Light extinction is the
sum of light scattering and absorption by particles and gases in the
atmosphere. It is typically expressed in terms of inverse megameters
(Mm-1), with larger values representing worse visibility.
The deciview metric describes perceived visual changes in a linear
fashion over its entire range, analogous to the decibel scale for
sound. A deciview of 0 represents pristine conditions. Under many
scenic conditions, a change of 1 deciview is considered perceptible
by the average person.
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In addition, visibility impairment can be described by its impact
over various periods of time, by its source, and the physical
conditions in various regions of the country. Visibility impairment can
be said to have a time dimension in that it might relate to short-term
excursions or to longer periods (e.g., worst 20 percent of days and
annual average levels). Anthropogenic contributions account for about
one-third of the average extinction coefficient in the rural West and
more than 80 percent in the rural East. In the Eastern U.S., reduced
visibility is mainly attributable to secondarily formed particles,
particularly those less than a few micrometers in diameter, such as
sulfates. While secondarily formed particles still account for a
significant amount in the West, primary emissions contribute a larger
percentage of the total particulate load than in the East. Because of
significant differences related to visibility conditions in the Eastern
and Western U.S., we present information about visibility by region.
Furthermore, it is important to note that even in those areas with
relatively low concentrations of anthropogenic fine particles, such as
the Colorado Plateau, small increases in anthropogenic fine particulate
concentrations can lead to significant decreases in visual range. This
is one of the reasons mandatory Federal Class I areas have been given
special consideration under the Clean Air Act.\78\
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\78\ The Clean Air Act designates 156 national parks and
wilderness areas as mandatory Federal Class I areas for visibility
protection.
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b. Visibility Impairment Where People Live, Work and Recreate
The secondary PM NAAQS is designed to protect against adverse
welfare effects which includes visibility impairment. In 1997, EPA
established the secondary PM2.5 NAAQS as equal to the
primary (health-based) NAAQS of 15 ug/m3 (based on a 3-year average of
the annual mean) and 65 ug/m3 (based on a 3-year average of
the 98th percentile of the 24-hour average value) (62 FR 38669, July
18, 1997). EPA concluded that PM2.5 causes adverse effects
on visibility in various locations, depending on PM concentrations and
factors such as chemical composition and average relative humidity. In
1997, EPA demonstrated that visibility impairment is an important
effect on public welfare and that unacceptable visibility impairment is
experienced throughout the U.S., in multi-state regions, urban areas,
and remote federal Class I areas. In many cities having annual mean
PM2.5 concentrations exceeding annual standard, improvements
in annual average visibility resulting from the attainment of the
annual PM2.5 standard are expected to be perceptible to the
general population. Based on annual mean monitored PM2.5
data, many cities in the Northeast, Midwest, and Southeast as well as
Los Angeles would be expected to experience perceptible improvements in
visibility if the PM2.5 annual standard were attained.
The updated monitoring data and air quality modeling, summarized
above and presented in detail in the draft RIA, confirm that the
visibility situation identified during the NAAQS review in 1997 is
still likely to exist, and it will continue to persist when these
proposed standards for nonroad diesel engines take effect. Thus, the
determination in the NAAQS rulemaking about broad visibility impairment
and related benefits from NAAQS compliance are still relevant.
Furthermore, in setting the PM2.5 NAAQS, EPA
acknowledged that levels of fine particles below the NAAQS may also
contribute to unacceptable visibility impairment and regional haze
problems in some areas, and section 169 of the Act provides additional
authorities to remedy existing impairment and prevent future impairment
in the 156 national parks, forests and wilderness areas labeled as
mandatory Federal Class I areas (62 FR 38680-81, July 18, 1997).
In making determinations about the level of protection afforded by
the secondary PM NAAQS, EPA considered how the section 169 regional
haze program and the secondary NAAQS would function together.\79\
Regional strategies are expected to improve visibility in many urban
and non-Class I areas as well.
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\79\ U.S. EPA Review of the National Ambient Air Quality
Standards for Particulate Matter: Policy Assessment of Scientific
and Technical Information OAQPS Staff Paper. EPA-452/R-96-013. 1996.
Docket Number A-99-06, Documents Nos. II-A-18, 19, 20, and 23. The
particulate matter air quality criteria documents are also available
at http://www.epa.gov/ncea/partmatt.htm.
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Fine particles may remain suspended for days or weeks and travel
hundreds to thousands of kilometers, and thus fine particles emitted or
created in one county may contribute to ambient concentrations in a
neighboring region.\80\
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\80\ Review of the National Ambient Air Quality Standards for
Particulate Matter: Policy Assessment for Scientific and Technical
Information, OAQPS Staff Paper, EPA-452/R-96-013, July, 1996, at IV-
7. This document is available from Docket A-99-06, Document II-A-23.
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The 1999-2001 PM2.5 monitored values indicate that at
least 74 million people live in areas where long-term ambient fine PM
levels are at or above 15 [mu]g/m3.\81\ Thus, at least these
populations (plus those who travel to those areas) are experiencing
significant visibility impairment, and emissions of PM and its
precursors from nonroad diesel engines contribute to this
impairment.\82\
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\81\ U.S. EPA Air Quality Data Analysis 1999-2001. Technical
Support Document for Regulatory Actions. March 2003.
\82\ These populations would also be exposed to PM
concentrations associated with the adverse health impacts discussed
above.
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Because of the importance of chemical composition and size to
visibility, we used EPA's Regional Modeling System for Aerosols and
Deposition (REMSAD)\83\ model to project visibility conditions in 2020
and 2030 in terms of deciview, accounting for the chemical composition
of the particles and transport of precursors. Our projections included
anticipated emissions from the nonroad diesel engines subject to this
proposed rule as well as all other sources.
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\83\ Additional information about the Regional Modeling System
for Aerosols and Deposition (REMSAD) and our modeling protocols can
be found in our Regulatory Impact Analysis: Heavy-Duty Engine and
Vehicle Standards and Highway Diesel Fuel Sulfur Control
Requirements, document EPA420-R-00-026, December 2000. Docket No. A-
2000-01, Document No. A-II-13. This document is also available at
http://www.epa.gov/otaq/disel.htm#documents.
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Based on this modeling, we predict that in 2030, 85 million people
(25
[[Page 28350]]
percent of the future population) would be living in areas with
visibility degradation where fine PM levels are above 15 [mu]g/m3
annually.\84\ Thus, at least a quarter of the population would
experience visibility impairment in areas where they live, work and
recreate.
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\84\ Technical Memorandum, EPA Air Docket A-99-06, Eric O.
Ginsburg, Senior Program Advisor, Emissions Monitoring and Analysis
Division, OAQPS, Summary of Absolute Modeled and Model-Adjusted
Estimates of Fine Particulate Matter for Selected Years, December 6,
2000, Table P-2. Docket Number 2000-01, Document Number II-B-14.
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As shown in Table I.C-1, accounting for the different visibility
impact of the chemical constituents of the PM2.5, in 2030 we
expect visibility in the East to be about 20.5 deciviews (or visual
range of 50 kilometers) on average, with poorer visibility in urban
areas, compared to the average Eastern visibility conditions without
man-made pollution of 9.5 deciviews (or visual range of 150
kilometers). Likewise, we expect visibility in the West to be about 8.8
deciviews (or visual range of 162 kilometers) on average in 2030, with
poorer visibility in urban areas, compared to the average Western
visibility conditions without man-made pollution of 5.3 deciviews (or
visual range of 230 kilometers). Thus, the emissions from these nonroad
diesel sources, especially SOx emissions that become sulfates in the
atmosphere, contribute to future visibility impairment summarized in
the table.
Control of nonroad land-based engines emissions, as shown in Table
I.C-1, will improve visibility across the nation. Taken together with
other programs, reductions from this proposal will help to improve
visibility. Control of these emissions in and around areas with PM
levels above the annual PM2.5 NAAQS will likely improve
visibility in other locations such as mandatory Federal Class I areas.
Specifically, for a preliminary control option described in the draft
RIA chapter 3.6 that is similar to our proposal, we expect on average
for visibility to improve to about 0.33 deciviews in the East and 0.35
deciviews in the West. The improvement from our proposal is likely to
be similar but slightly smaller than what was modeled due to the
differences in emission reductions between the proposal and the modeled
scenario.
Table I.C-1--Summary of Modeled 2030 National Visibility Conditions
[Average annual deciviews]
------------------------------------------------------------------------
Predicted
Predicted 2030 Change in
2030 visibility annual
Regions \a\ visibility with rule average
baseline controls deciviews
\b\
------------------------------------------------------------------------
Eastern U.S...................... 20.54 20.21 0.33
Urban........................ 21.94 21.61 0.33
Rural........................ 19.98 19.65 0.33
Western U.S...................... 8.83 8.58 0.25
Urban........................ 9.78 9.43 0.35
Rural........................ 8.61 8.38 0.23
------------------------------------------------------------------------
Notes:
\a\ Eastern and Western Regions are separated by 100 degrees north
longitude. Background visibility conditions differ by region. Natural
background is 9.5 deciviews in the East and 5.3 in the West.
\b\ The results illustrate the type of visibility improvements for the
preliminary control option, as discussed in the Draft RIA. The
proposal differs based on updated information; however, we believe
that the net results would approximate future PM emissions, although
we anticipate the visibility improvements would be slightly smaller.
c. Visibility Impairment in Mandatory Federal Class I Areas
The Clean Air Act establishes special goals for improving
visibility in many national parks, wilderness areas, and international
parks. In the 1990 Clean Air Act amendments, Congress provided
additional emphasis on regional haze issues (see CAA section 169B). In
1999, EPA finalized a rule that calls for States to establish goals and
emission reduction strategies for improving visibility in all 156
mandatory Federal Class I areas. In that rule, EPA established a
``natural visibility'' goal, and also encouraged the States to work
together in developing and implementing their air quality plans. The
regional haze program is focused on long-term emissions decreases from
the entire regional emissions inventory comprised of major and minor
stationary sources, area sources and mobile sources. The regional haze
program is designed to improve visibility and air quality in our most
treasured natural areas from these broad sources. At the same time,
control strategies designed to improve visibility in the national parks
and wilderness areas are expected to improve visibility over broad
geographic areas. For mobile sources, there is a need for a Federal
role in reduction of those emissions, especially because mobile source
engines are regulated primarily at the Federal level.
Because of evidence that fine particles are frequently transported
hundreds of miles, all 50 states, including those that do not have
mandatory Federal Class I areas, participate in planning, analysis,
and, in many cases, emission control programs under the regional haze
regulations. Virtually all of the 156 mandatory Federal Class I areas
experience impaired visibility, requiring all States with those areas
to prepare emission control programs to address it. Even though a given
State may not have any mandatory Federal Class I areas, pollution that
occurs in that State may contribute to impairment in such Class I areas
elsewhere. The rule encourages states to work together to determine
whether or how much emissions from sources in a given state affect
visibility in a downwind mandatory Federal Class I area.
The regional haze program also calls for states to establish goals
for improving visibility in national parks and wilderness areas to
improve visibility on the haziest 20 percent of days and to ensure that
no degradation occurs on the clearest 20 percent of days (64 FR 35722,
July 1, 1999). The rule requires states to develop long-term strategies
including enforceable measures designed to meet reasonable progress
goals toward natural visibility conditions. Under the regional haze
[[Page 28351]]
program, States can take credit for improvements in air quality
achieved as a result of other Clean Air Act programs, including
national mobile source programs.\85\
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\85\ In a recent case, American Corn Growers Association v. EPA,
291 F. 3d 1 (D.C. Cir 2002), the court vacated the Best Available
Retrofit Technology (BART) provisions of the Regional Haze rule, but
the court denied industry's challenge to EPA's requirement that
states' SIPs provide for reasonable progress towards achieving
natural visibility conditions in national parks and wilderness areas
and the ``no degradation'' requirement. Industry did not challenge
requirements to improve visibility on the haziest 20 percent of
days. A copy of this decision can be found in Docket A-2000-01,
Document IV-A-113.
---------------------------------------------------------------------------
In the PM air quality modeling described above, we also modeled
visibility conditions in the mandatory Federal Class I areas, and we
summarize the results by region in Table I.C-2. The information shows
that these areas also are predicted to have high annual average
deciview levels in the future. Emissions from nonroad land-based diesel
engines and locomotive and marine engines contributed significantly to
these levels, because these diesel engines represent a sizeable portion
of the total inventory of anthropogenic emissions related to
PM2.5 (as shown in the tables above.). Furthermore, numerous
types of nonroad engines may operate in or near mandatory Federal Class
I areas (e.g., mining, construction, and agricultural equipment). As
summarized in the table, we expect visibility improvements in mandatory
Federal Class I areas from the reductions of emissions from nonroad
diesel engines subject to this proposed rule.
Table I.C-2--Summary of Modeled 2030 Visibility Conditions in Mandatory
Federal Class I Areas
[Annual average deciview]
------------------------------------------------------------------------
Predicted
Predicted 2030 Change in
Region a 2030 visibility annual
visibility with rule average
baseline b control c deciviews
------------------------------------------------------------------------
Eastern:
Southeast................... 21.62 21.38 0.24
Northeast/Midwest........... 18.56 18.32 0.24
Western:
Southwest................... 7.03 6.82 0.21
California.................. 9.56 9.26 0.3
Rocky Mountain.............. 8.55 8.34 0.21
Northwest................... 12.18 11.94 0.24
National Class I Area Average... 11.8 11.56 0.24
------------------------------------------------------------------------
Notes:
a Regions are depicted in Figure VI-5 in the Regulatory Support
Document. Background visibility conditions differ by region: Eastern
natural background is 9.5 deciviews (or visual range of 150
kilometers) and in the West natural background is 5.3 deciviews (or
visual range of 230 kilometers).
b The results average visibility conditions for mandatory Federal Class
I areas in the regions.
c The results illustrate the type of visibility improvements for the
preliminary control option, as discussed in the draft RIA. The
proposal differs based on updated information; however, we believe
that the net results would approximate future PM emissions, although
we anticipate the improvements would be slightly smaller.
2. Acid Deposition
Acid deposition, or acid rain as it is commonly known, occurs when
SO2 and NOX react in the atmosphere with water,
oxygen, and oxidants to form various acidic compounds that later fall
to earth in the form of precipitation or dry deposition of acidic
particles.\86\ It contributes to damage of trees at high elevations and
in extreme cases may cause lakes and streams to become so acidic that
they cannot support aquatic life. In addition, acid deposition
accelerates the decay of building materials and paints, including
irreplaceable buildings, statues, and sculptures that are part of our
nation's cultural heritage. To reduce damage to automotive paint caused
by acid rain and acidic dry deposition, some manufacturers use acid-
resistant paints, at an average cost of $5 per vehicle--a total of $80-
85 million per year when applied to all new cars and trucks sold in the
U.S.
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\86\ Much of the information in this subsection was excerpted
from the EPA document, Human Health Benefits from Sulfate Reduction,
written under title IV of the 1990 Clean Air Act Amendments, U.S.
EPA, Office of Air and Radiation, Acid Rain Division, Washington, DC
20460, November 1995. Available in Docket A-2000-01, Document No.
II-A-32.
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Acid deposition primarily affects bodies of water that rest atop
soil with a limited ability to neutralize acidic compounds. The
National Surface Water Survey (NSWS) investigated the effects of acidic
deposition in over 1,000 lakes larger than 10 acres and in thousands of
miles of streams. It found that acid deposition was the primary cause
of acidity in 75 percent of the acidic lakes and about 50 percent of
the acidic streams, and that the areas most sensitive to acid rain were
the Adirondacks, the mid-Appalachian highlands, the upper Midwest and
the high elevation West. The NSWS found that approximately 580 streams
in the Mid-Atlantic Coastal Plain are acidic primarily due to acidic
deposition. Hundreds of the lakes in the Adirondacks surveyed in the
NSWS have acidity levels incompatible with the survival of sensitive
fish species. Many of the over 1,350 acidic streams in the Mid-Atlantic
Highlands (mid-Appalachia) region have already experienced trout losses
due to increased stream acidity. Emissions from U.S. sources contribute
to acidic deposition in eastern Canada, where the Canadian government
has estimated that 14,000 lakes are acidic. Acid deposition also has
been implicated in contributing to degradation of high-elevation spruce
forests that populate the ridges of the Appalachian Mountains from
Maine to Georgia. This area includes national parks such as the
Shenandoah and Great Smoky Mountain National Parks.
A study of emissions trends and acidity of water bodies in the
Eastern U.S. by the General Accounting Office (GAO) found that from
1992 to 1999 sulfates declined in 92 percent of a representative sample
of lakes, and nitrate levels increased in 48 percent of the lakes
sampled.\87\ The decrease in sulfates is consistent with emissions
[[Page 28352]]
trends, but the increase in nitrates is inconsistent with the stable
levels of nitrogen emissions and deposition. The study suggests that
the vegetation and land surrounding these lakes have lost some of their
previous capacity to use nitrogen, thus allowing more of the nitrogen
to flow into the lakes and increase their acidity. Recovery of
acidified lakes is expected to take a number of years, even where soil
and vegetation have not been ``nitrogen saturated,'' as EPA called the
phenomenon in a 1995 study.\88\ This situation places a premium on
reductions of SOx and especially NOX from all
sources, including nonroad diesel engines, in order to reduce the
extent and severity of nitrogen saturation and acidification of lakes
in the Adirondacks and throughout the U.S.
---------------------------------------------------------------------------
\87\ Acid Rain: Emissions Trends and Effects in the Eastern
United States, U.S. General Accounting Office, March, 2000 (GOA/
RCED-00-47). Available in Docket A-99-06, Document No. IV-G-159.
\88\ Acid Deposition Standard Feasibility Study: Report to
Congress, EPA 430R-95-001a, October, 1995.
---------------------------------------------------------------------------
The SOX and NOX reductions from today's
action will help reduce acid rain and acid deposition, thereby helping
to reduce acidity levels in lakes and streams throughout the country
and help accelerate the recovery of acidified lakes and streams and the
revival of ecosystems adversely affected by acid deposition. Reduced
acid deposition levels will also help reduce stress on forests, thereby
accelerating reforestation efforts and improving timber production.
Deterioration of our historic buildings and monuments, and of
buildings, vehicles, and other structures exposed to acid rain and dry
acid deposition also will be reduced, and the costs borne to prevent
acid-related damage may also decline. While the reduction in sulfur and
nitrogen acid deposition will be roughly proportional to the reduction
in SOX and NOX emissions, respectively, the
precise impact of today's action will differ across different areas.
3. Eutrophication and Nitrification
Eutrophication is the accelerated production of organic matter,
particularly algae, in a water body. This increased growth can cause
numerous adverse ecological effects and economic impacts, including
nuisance algal blooms, dieback of underwater plants due to reduced
light penetration, and toxic plankton blooms. Algal and plankton blooms
can also reduce the level of dissolved oxygen, which can also adversely
affect fish and shellfish populations.
In 1999, NOAA published the results of a five year national
assessment of the severity and extent of estuarine eutrophication. An
estuary is defined as the inland arm of the sea that meets the mouth of
a river. The 138 estuaries characterized in the study represent more
than 90 percent of total estuarine water surface area and the total
number of U.S. estuaries. The study found that estuaries with moderate
to high eutrophication conditions represented 65 percent of the
estuarine surface area. Eutrophication is of particular concern in
coastal areas with poor or stratified circulation patterns, such as the
Chesapeake Bay, Long Island Sound, or the Gulf of Mexico. In such
areas, the ``overproduced'' algae tends to sink to the bottom and
decay, using all or most of the available oxygen and thereby reducing
or eliminating populations of bottom-feeder fish and shellfish,
distorting the normal population balance between different aquatic
organisms, and in extreme cases causing dramatic fish kills.
Severe and persistent eutrophication often directly impacts human
activities. For example, losses in the nation's fishery resources may
be directly caused by fish kills associated with low dissolved oxygen
and toxic blooms. Declines in tourism occur when low dissolved oxygen
causes noxious smells and floating mats of algal blooms create
unfavorable aesthetic conditions. Risks to human health increase when
the toxins from algal blooms accumulate in edible fish and shellfish,
and when toxins become airborne, causing respiratory problems due to
inhalation. According to the NOAA report, more than half of the
nation's estuaries have moderate to high expressions of at least one of
these symptoms--an indication that eutrophication is well developed in
more than half of U.S. estuaries.
In recent decades, human activities have greatly accelerated
nutrient inputs, such as nitrogen and phosphorous, causing excessive
growth of algae and leading to degraded water quality and associated
impairments of freshwater and estuarine resources for human uses.\89\
Since 1970, eutrophic conditions worsened in 48 estuaries and improved
in 14. In 26 systems, there was no trend in overall eutrophication
conditions since 1970.\90\ On the New England coast, for example, the
number of red and brown tides and shellfish problems from nuisance and
toxic plankton blooms have increased over the past two decades, a
development thought to be linked to increased nitrogen loadings in
coastal waters. Long-term monitoring in the U.S., Europe, and other
developed regions of the world shows a substantial rise of nitrogen
levels in surface waters, which are highly correlated with human-
generated inputs of nitrogen to their watersheds.
---------------------------------------------------------------------------
\89\ Deposition of Air Pollutants to the Great Waters, Third
Report to Congress, June, 2000. Available in Docket A-99-06,
Document No. IV-A-06.
\90\ Deposition of Air Pollutants to the Great Waters, Third
Report to Congress, June, 2000. Great Waters are defined as the
Great Lakes, the Chesapeake Bay, Lake Champlain, and coastal waters.
The first report to Congress was delivered in May, 1994; the second
report to Congress in June, 1997. Available in Docket A-99-06,
Document No. IV-A-06.
---------------------------------------------------------------------------
Between 1992 and 1997, experts surveyed by National Oceanic and
Atmospheric Administration (NOAA) most frequently recommended that
control strategies be developed for agriculture, wastewater treatment,
urban runoff, and atmospheric deposition.\91\ In its Third Report to
Congress on the Great Waters, EPA reported that atmospheric deposition
contributes from 2 to 38 percent of the nitrogen load to certain
coastal waters.\92\ A review of peer reviewed literature in 1995 on the
subject of air deposition suggests a typical contribution of 20 percent
or higher.\93\ Human-caused nitrogen loading to the Long Island Sound
from the atmosphere was estimated at 14 percent by a collaboration of
Federal and State air and water agencies in 1997.\94\ The National
Exposure Research Laboratory, U.S. EPA, estimated based on prior
studies that 20 to 35 percent of the nitrogen loading to the Chesapeake
Bay is attributable to atmospheric deposition.\95\ The mobile source
portion of atmospheric NOX contribution to the Chesapeake
Bay was modeled at about 30 percent of total air deposition.\96\
---------------------------------------------------------------------------
\91\ Bricker, Suzanne B., et al., National Estuarine
Eutrophication Assessment, Effects of Nutrient Enrichment in the
Nation's Estuaries, National Ocean Service, National Oceanic and
Atmospheric Administration, September, 1999. Available in Docket A-
99-06, Document No. IV-G-145.
\92\ Deposition of Air Pollutants to the Great Waters, Third
Report to Congress, June, 2000. Available in Docket A-99-06,
Document No. IV-A-06.
\93\ Valigura, Richard, et al., Airsheds and Watersheds II: A
Shared Resources Workshop, Air Subcommittee of the Chesapeake Bay
Program, March, 1997. Available in Docket A-99-06, Document No. IV-
G-144.
\94\ The Impact of Atmospheric Nitrogen Deposition on Long
Island Sound, The Long Island Sound Study, September, 1997.
\95\ Dennis, Robin L., Using the Regional Acid Deposition Model
to Determine the Nitrogen Deposition Airshed of the Chesapeake Bay
Watershed, SETAC Technical Publications Series, 1997.
\96\ Dennis, Robin L., Using the Regional Acid Deposition Model
to Determine the Nitrogen Deposition Airshed of the Chesapeake Bay
Watershed, SETAC Technical Publications Series, 1997.
---------------------------------------------------------------------------
Deposition of nitrogen from nonroad diesel engines contributes to
elevated nitrogen levels in waterbodies. The proposed standards for
nonroad diesel
[[Page 28353]]
engines will reduce total NOX emissions by 831,000 tons in
2030. The NOX reductions will reduce the airborne nitrogen
deposition that contributes to eutrophication of watersheds,
particularly in aquatic systems where atmospheric deposition of
nitrogen represents a significant portion of total nitrogen loadings.
4. Polycyclic Organic Matter Deposition
EPA's Great Waters Program has identified 15 pollutants whose
deposition to water bodies has contributed to the overall contamination
loadings to the these Great Waters.\97\ One of these 15 pollutants, a
group known as polycyclic organic matter (POM), are compounds that are
mainly adhered to the particles emitted by mobile sources and later
fall to earth in the form of precipitation or dry deposition of
particles. The mobile source contribution of the 7 most toxic POM is at
least 62 tons/year and represents only those POM that adhere to mobile
source particulate emissions.\98\ The majority of these emissions are
produced by diesel engines.
---------------------------------------------------------------------------
\97\ Deposition of Air Pollutants to the Great Waters-Third
Report to Congress, June, 2000, Office of Air Quality Planning and
Standards Deposition of Air Pollutants to the Great Waters-Second
Report to Congress, Office of Air Quality Planning and Standards,
June 1997, EPA-453/R-97-011. Available in Docket A-99-06, Document
No. IV-A-06.
\98\ The 1996 National Toxics Inventory, Office of Air Quality
Planning and Standards, October 1999.
---------------------------------------------------------------------------
The PM reductions from this proposed action will help reduce not
only the PM emissions from nonroad diesel engines but also the
deposition of the POM adhering to the particles, thereby helping to
reduce health effects of POM in lakes and streams, accelerate the
recovery of affected lakes and streams, and revive the ecosystems
adversely affected.
5. Plant Damage From Ozone
Ground-level ozone can also cause adverse welfare effects.
Specifically, ozone enters the leaves of plants where it interferes
with cellular metabolic processes. This interference can be manifest
either as visible foliar injury from cell injury or death, and/or as
decreased plant growth and yield due to a reduced ability to produce
food. With fewer resources, the plant reallocates existing resources
away from root storage, growth and reproduction toward leaf repair and
maintenance. Plants that are stressed in these ways become more
susceptible to disease, insect attack, harsh weather and other
environmental stresses. Because not all plants are equally sensitive to
ozone, ozone pollution can also exert a selective pressure that leads
to changes in plant community composition.
Since plants are at the center of the food web in many ecosystems,
changes to the plant community can affect associated organisms and
ecosystems (including the suitability of habitats that support
threatened or endangered species and below ground organisms living in
the root zone). Given the range of plant sensitivities and the fact
that numerous other environmental factors modify plant uptake and
response to ozone, it is not possible to identify threshold values
above which ozone is toxic and below which it is safe for all plants.
However, in general, the science suggests that ozone concentrations of
0.10 ppm or greater can be phytotoxic to a large number of plant
species, and can produce acute foliar injury responses, crop yield loss
and reduced biomass production. Ozone concentrations below 0.10 ppm
(0.05 to 0.09 ppm) can produce these effects in more sensitive plant
species, and have the potential over a longer duration of creating
chronic stress on vegetation that can lead to effects of concern such
as reduced plant growth and yield, shifts in competitive advantages in
mixed populations, and decreased vigor leading to diminished resistance
to pests, pathogens, and injury from other environmental stresses.
Studies indicate that these effects described here are still
occurring in the field under ambient levels of ozone. The economic
value of some welfare losses due to ozone can be calculated, such as
crop yield loss from both reduced seed production (e.g., soybean) and
visible injury to some leaf crops (e.g., lettuce, spinach, tobacco) and
visible injury to ornamental plants (i.e., grass, flowers, shrubs),
while other types of welfare loss may not be fully quantifiable in
economic terms (e.g., reduced aesthetic value of trees growing in Class
I areas).
As discussed above, nonroad diesel engine emissions of VOCs and
NOX contribute to ozone. This proposed rule would reduce
ozone and, therefore, help to reduce crop damage and stress from ozone
on vegetation. See the draft RIA for a more detailed discussion of the
science of these effects.
D. Other Criteria Pollutants Affected by This NPRM
The standards being proposed today would also help reduce levels of
other pollutants for which NAAQS have been established: carbon monoxide
(CO), nitrogen dioxide (NO2), and sulfur dioxide
(SO2). Currently every area in the United States has been
designated to be in attainment with the NO2 NAAQS. As of
November 4, 2002, there were 24 areas designated as non-attainment with
the SO2 standard, and 14 designated CO non-attainment areas.
The current primary NAAQS for CO are 35 parts per million for the
one-hour average and 9 parts per million for the eight-hour average.
These values are not to be exceeded more than once per year. Over 22
million people currently live in the 14 non-attainment areas for the CO
NAAQS. See the draft RIA for a detailed discussion of the emission
benefits of this proposed rule.
Carbon monoxide is a colorless, odorless gas produced through the
incomplete combustion of carbon-based fuels. Carbon monoxide enters the
bloodstream through the lungs and reduces the delivery of oxygen to the
body's organs and tissues. The health threat from CO is most serious
for those who suffer from cardiovascular disease, particularly those
with angina or peripheral vascular disease. Healthy individuals also
are affected, but only at higher CO levels. Exposure to elevated CO
levels is associated with impairment of visual perception, work
capacity, manual dexterity, learning ability and performance of complex
tasks.
Land-based nonroad engines contributed about one percent of CO from
mobile sources in 1996. EPA previously determined that the category of
nonroad diesel engines cause or contribute to ambient CO and ozone in
more than one non-attainment area (65 FR 76790, December 7, 2000). In
that action EPA found that nonroad engines contribute to CO non-
attainment in areas such as Los Angeles, Phoenix, Spokane, Anchorage,
and Las Vegas. Nonroad land-based diesel engines emitted 927,500 tons
of CO in 1996 (1% of mobile source CO).
E. Emissions From Nonroad Diesel Engines
Emissions from nonroad diesel engines will continue to be a
significant part of the emissions inventory in the coming years. In the
absence of new emission standards, we expect overall emissions from
nonroad diesel engines subject to this proposal to generally decline
across the nation for the next 10 to 15 years, depending on the
pollutant.\99\ Although nonroad diesel engine emissions will decline
during this period, this trend will not be enough to adequately reduce
the large amount of emissions that these engines contribute. For
example, the declines are insufficient to prevent significant
[[Page 28354]]
contributions to nonattainment of PM2.5 and ozone NAAQS, or
to prevent widespread exposure to significant concentrations of nonroad
engine air toxics. In addition, after the 2010 to 2015 time period we
project that this trend reverses and emissions rise into the future in
the absence of additional regulation of these engines. (This phenomenon
is further described later in this section.) The initial downward trend
occurs as the nonroad fleet becomes increasingly dominated over time by
engines that comply with existing emission regulations. The upturn in
emissions beginning around 2015 results as growth in the nonroad sector
overtakes the effect of the existing emission standards.
---------------------------------------------------------------------------
\99\ As defined here, nonroad diesel engines include land-based,
locomotive, commercial marine vessel, and recreational marine
engines.
---------------------------------------------------------------------------
The engine and fuel standards in this proposal will affect fine
particulate matter (PM2.5), oxides of nitrogen
(NOX), sulfur oxides (SO2), volatile organic
hydrocarbons (VOC), and air toxics. For locomotive, commercial marine
vessel (CMV), and recreational marine vessel (RMV) engines, the
proposed fuel standards will affect PM2.5 and
SO2. CO is not specifically targeted in this proposal but
its reductions are discussed in the draft RIA.\100\
---------------------------------------------------------------------------
\100\ We are proposing only a few minor adjustments of a
technical nature to current CO standards.
---------------------------------------------------------------------------
Each sub-section within section II discusses the emissions of a
pollutant that the proposal addresses.\101\ This is followed by a
discussion of the expected emission reductions associated with the
proposed standards for land-based nonroad diesel engines.\102\ The
tables and figures illustrate the Agency's projection of future
emissions from nonroad diesel engines for each pollutant.\103\ The
baseline case represents future emissions from land-based nonroad
diesel engines with current standards. The controlled case estimates
the future emissions of these engines based on the proposed standards
in this notice.
---------------------------------------------------------------------------
\101\ The estimates of baseline emissions and emissions
reductions from the proposed rule reported here for nonroad land-
based, recreational marine, locomotive, and commercial marine vessel
diesel engines are based on 50 state emissions inventory estimates.
However, 50 state emissions inventory data are not available for
other emission sources. Thus, emissions estimates for other sources
are based on a 48 state inventory that excludes Alaska and Hawaii.
The 48 state inventory was done for air quality modeling that EPA
uses to analyze regional ozone transport, of which Alaska and Hawaii
are not a part. In cases where land-based nonroad diesel engine
emissions are summed or compared with other emissions sources, we
use a 48 state emissions inventory.
\102\ For the purpose of this proposal, land-based nonroad
diesel engines include engines used in equipment modeled by the
draft NONROAD emissions model, except for recreational marine
engines. Recreational marine diesel engines are not subject to the
exhaust emission standards contained in this proposal but would be
affected by the fuel sulfur requirements applicable to locomotive
and commercial marine vessel engines.
\103\ The air quality modeling results described in sections
II.B and II.C use a slightly different emissions inventory based on
earlier, preliminary modeling assumptions. Chapter 3 of the draft
RIA and the technical support documents fully describe this
inventory, as well as the differences between it and the inventory
reflecting the proposal.
---------------------------------------------------------------------------
1. PM2.5
As described earlier in this section of the preamble, the Agency
believes that reductions of diesel PM2.5 emissions are
needed as part of the Nation's progress toward clean air and to reach
attainment of the NAAQS for PM2.5. The nonroad engines
controlled by this proposal are the major sources of nonroad diesel
emissions. Table II.E-1 shows that the PM2.5 emissions from land-based
nonroad diesels amount to increasingly large percentages of total
manmade diesel PM2.5 in the years 1996, 2020 and
2030.104 105
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\104\ Nitrate and sulfate secondary fine particulate as
described in section II.B and are not included in the values
reported here or elsewhere, but are discussed in the Regulatory
Impact Analysis, chapter X.
\105\ As a function of the available national inventories from
other sources, we are only able to present a 48-state inventory.
Wherever possible we present a 50-state inventory.
Table II.E-1--Base-Case National (48 State) Diesel PM2.5
(Short tons)
------------------------------------------------------------------------
Nonroad
land-
Nonroad based
Total land- percent
Year diesel based of total
PM2.5 diesel diesel
PM2.5 PM2.5
(percent)
------------------------------------------------------------------------
1996................................... 414,000 177,000 43
2020................................... 206,000 124,000 60
2030................................... 220,000 140,000 64
------------------------------------------------------------------------
The contribution of land-based nonroad CI engines to PM2.5
inventories can be significant, especially in densely populated urban
areas.\106\ As illustrated in Table II.E.-2, our city-specific analysis
of selected metropolitan areas for 1996 and 2020 shows that the land-
based nonroad diesel engine contribution to total PM2.5
ranges up to 18 percent in 1996 and 19 percent in 2020.\107\
---------------------------------------------------------------------------
\106\ Construction, industrial, and commercial nonroad diesel
equipment comprise most of the land-based nonroad emissions
inventory. These types of equipment are more concentrated in urban
areas where construction projects, manufacturing, and commercial
operations are prevalent. For more information, please refer to the
report, ``Geographic Allocation of State Level Nonroad Engine
Population Data to the County Level,'' NR-014b, EPA 420-P-02-009.
\107\ We selected these cities to show a collection of typical
cities spread across the United States in order to compare typical
urban inventories with national average ones.
Table II.E-2--Baseline Land-Based Nonroad Diesel Percent Contribution to
PM2.5 Inventories in Selected Urban Areas in 1996 and 2020
------------------------------------------------------------------------
Land-Based Land-Based
Nonroad Nonroad
PM2.5 PM2.5
MSA, State Contribution Contribution
to Total to Total
PM2.5a in PM2.5a in
1996 2020
------------------------------------------------------------------------
Atlanta, GA................................. 7 6
Boston, MA.................................. 18 18
Chicago, IL................................. 8 7
Dallas-Ft. Worth, TX........................ 13 10
Indianapolis, IN............................ 15 13
Minneapolis-St. Paul, MN.................... 10 8
New York, NY................................ 13 12
Orlando, FL................................. 14 12
Sacramento, CA.............................. 7 7
San Diego, CA............................... 9 7
Denver, CO.................................. 11 8
El Paso, TX................................. 15 19
Las Vegas, NV............................... 15 12
Phoenix-Mesa, AZ............................ 15 12
Seattle, WA................................. 7 7
National Averageb........................... 8 6
------------------------------------------------------------------------
\a\ Includes only direct exhaust diesel emissions; see Section II.C for
a discussion of secondary fine PM levels.
\b\ This is a 48 state national average.
Emissions of PM2.5 from land-based nonroad diesel
engines based on a 50 state inventory are shown in Table II.E-3, along
with our estimates of the reductions in 2020 and 2030 we expect would
result from our proposal for a PM2.5 exhaust emission
standard and changes in the sulfur level in nonroad diesel fuel. For
comparison purposes, PM2.5 emissions based on lowering
nonroad diesel fuel sulfur levels to about 340 ppm in-use \108\ (500
ppm maximum) without any other controls are shown, along with the
estimated emissions with the proposed PM2.5 standard and a
sulfur level of 11 ppm in-use (15 ppm maximum). Figure II.E-1 shows our
estimate of PM2.5 emissions between 2000 and 2030 both
without
[[Page 28355]]
and with the proposed PM2.5 standard (along with an assumed
sulfur level of 11 ppm in-use, 15 ppm maximum). By 2030, we estimate
that PM2.5 emissions from this source would be reduced by 86
percent in that year.
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\108\ This value (340 ppm) represents the average in-use sulfur
concentration of fuel produced to meet a 500 ppm sulfur standard. In
practice, off-highway equipment will sometimes be refueled with
diesel fuel meeting the more stringent highway standard of 15 ppm.
Therefore, the actual average in-use sulfur level of the fuel used
by off-highway equipment will be somewhat lower than 340 ppm. The
emission benefits shown here reflect this lower in-use sulfur level.
Table II.E-3.--Estimated National (50 State) Reductions in PM2.5 Emissions From Nonroad Land-Based, Locomotive, Commercial Marine, and Recreational
Marine Diesel Engines
--------------------------------------------------------------------------------------------------------------------------------------------------------
PM2.5 reductions
PM2.5 with 500 with 500 ppm fuel PM2.5 with rule PM2.5 reductions
PM2.5* without ppm fuel sulfur sulfur (340 in- (15 ppm sulfur with rule (15 ppm
Year rule [short (340 in-use) and use) and no other level, 11 in-use) sulfur level, 11
tons] no other controls controls [short [short tons] in-use) [short
[short tons] tons] tons]
--------------------------------------------------------------------------------------------------------------------------------------------------------
2020..................................................... 186,000 163,000 100,000 23,000 86,000
2030..................................................... 205,000 178,000 77,000 27,000 127,000
--------------------------------------------------------------------------------------------------------------------------------------------------------
[GRAPHIC] [TIFF OMITTED] TP23MY03.001
Nonroad diesel engines used in locomotives, commercial marine
vessels, and recreational marine vessels are not affected by the
emission standards of this proposal. PM2.5 emissions from
these engines would be reduced by the reductions in diesel fuel sulfur
for these types of engines from an in-use average of between 2,300 and
2,400 ppm today to an in-use average of about 340 ppm (500 ppm maximum)
in 2007. The estimated reductions in PM2.5 emissions from
these engines based on the proposed change in diesel fuel sulfur are
about 6,000 tons in 2020 and 7,000 tons in 2030.\109\ For more
information on proposed fuel sulfur reductions, please see chapter 7 of
the draft RIA.
---------------------------------------------------------------------------
\109\ These reductions are based on a 50 state emissions
inventory estimate.
---------------------------------------------------------------------------
2. NOX
Table II.E-4 shows the 50 state estimated tonnage of NOX
emissions for 2020 and 2030 without the proposed rule and the estimated
tonnage of emissions eliminated with the proposed rule in place. These
results are shown graphically in Figure II.E-2. By 2030, we estimate
that NOX emissions from these engines will be reduced by 67
percent in that year.
Table II.E.-4.--Estimated National (50 State) Reductions in NOX
Emissions From Nonroad Land-Based Diesel Engines
------------------------------------------------------------------------
NOX
NOX without NOX with reductions
Calendar year rule rule with rule
[short [short [short
tons] tons] tons]
------------------------------------------------------------------------
2020............................. 1,147,000 640,000 507,000
2030............................. 1,239,000 412,000 827,000
------------------------------------------------------------------------
[[Page 28356]]
[GRAPHIC] [TIFF OMITTED] TP23MY03.002
Table E.II-5 shows that the engines affected by the proposal emit a
significant portion of total NOX emissions in 1996 and 2020,
especially in cities. This is not surprising given the high density of
these engines operating in urban areas.\110\ We selected a variety of
cities from across the nation and found that these engines contribute
up to 14 percent of the total NOX inventories in 1996 and as
much as 20 percent to total NOX inventories in 2020.\111\
---------------------------------------------------------------------------
\110\ Construction, industrial, and commercial nonroad diesel
equipment comprise most of the land-based nonroad emissions
inventory. These types of equipment are more concentrated in urban
areas where construction projects, manufacturing, and commercial
operations are prevalent. For more information, please refer to the
report, ``Geographic Allocation of State Level Nonroad Engine
Population Data to the County Level,'' NR-014b, EPA 420-P-02-009.
\111\ We selected these cities to show a collection of typical
cities spread across the United States in order to compare typical
urban inventories with national average ones.[FEDREG][VOL]*[/
VOL][NO]*[/NO][DATE]*[/DATE][PRORULES][PRORULE][PREAMB][AGENCY]*[/
AGENCY][SUBJECT]*[/SUBJECT][/PREAMB][SUPLINF][HED]*[/HED]
Table II.E-5--Baseline Land-Based Nonroad Diesel Percent Contribution to
NOX Inventories in Selected Urban Areas in 2020
------------------------------------------------------------------------
Land-based NR NOX Land-based NR NOX
MSA, State as percentage of as percentage of
total NOX in 1996 total NOX in 2020
------------------------------------------------------------------------
Atlanta, GA................... 5 7
Boston, MA.................... 14 19
Chicago, IL................... 6 7
Dallas-Fort Worth, TX......... 10 13
Indianapolis, IN.............. 8 12
Minneapolis-St. Paul, MN...... 6 6
New York, NY.................. 11 20
Orlando, FL................... 10 13
Sacramento, CA................ 10 19
San Diego, CA................. 9 14
Denver, CO.................... 8 8
El Paso, TX................... 8 15
Las Vegas, NV-AZ.............. 11 12
Phoenix-Mesa, AZ.............. 9 11
Seattle, WA................... 8 11
National Averagea............. 6 7
------------------------------------------------------------------------
a This is a 48 state national average.
3. SO2
We estimate that land-based nonroad, CMV, RMV, and locomotive
diesel engines emitted about 227,000 tons of SO2 in 1996,
accounting for about 30 percent of the SO2 from mobile
sources (based on a 48 state inventory). With no reduction in diesel
fuel sulfur levels, we estimate that these emissions will continue to
increase, accounting for about 60 percent of mobile source
SO2 emissions by 2030.
As part of this proposal, sulfur levels in fuel would be
significantly reduced, leading to large reductions in nonroad diesel
SO2 emissions. By 2007, the sulfur in diesel fuel used by
all nonroad diesel engines would be reduced from the current average
in-use level of between 2,300 and 2,400 ppm to an average in-use level
of about 340 ppm with a maximum level of 500 ppm. By 2010, the sulfur
in diesel fuel used by land-based nonroad engines would be
[[Page 28357]]
reduced to an average in-use level of 11 ppm with a maximum level of 15
ppm. The sulfur in diesel fuel used by locomotives, CMVs, and RMVs
would remain at an average in-use level of about 340 ppm. Figure II.E-3
shows the estimated reductions from these sulfur changes. For more
information on this topic, please see chapter 7 of the RIA.\112\
---------------------------------------------------------------------------
\112\ Under this proposal, the introduction of 340 ppm
(approximate average in-use level, 500 ppm maximum) sulfur diesel
fuel for all nonroad diesel engines would take place in June of
2007. The introduction of 11 ppm sulfur diesel fuel (average in-use,
15 ppm maximum) for land-based nonroad engines would take place in
June 2010.
[GRAPHIC] [TIFF OMITTED] TP23MY03.003
Table II.E-6 shows 50 state estimates of total SO2
emissions without the proposed rule and how SO2 emissions
would be reduced by the diesel fuel sulfur reductions in 2020 and 2030.
Lowering diesel fuel sulfur to a maximum of 500 ppm (340 ppm in-
use) for CMV, locomotive and land-based nonroad engines would result in
a reduction of about 360,000 tons/year of SO2 in 2030.
Lowering diesel fuel sulfur to a maximum of 500 ppm (340 ppm in-use)
for CMV and locomotive engines and a maximum of 15 ppm (11 ppm in-use)
for land-based nonroad engines would result in a reduction of about
390,000 tons of SO2 in 2030.
Table II.E-6--Estimated National (50 State) Emissions of Land-Based Nonroad, Locomotive, Commercial Marine
Vessel, and Recreational Marine Vessel
[SO2 Emissions From Lowering Diesel Fuel Sulfur Levels]
----------------------------------------------------------------------------------------------------------------
Total SO2
emissions at 2400 500 ppm sulfur 500 ppm sulfur 15 ppm sulfur (11
ppm sulfur (340 ppm in-use) (340 in-use) land- ppm in-use) land-
Year without proposed locomotives, based nonroad based nonroad
rule [short CMVs, RMVsa [short tons] [short tons]
tons] [short tons]
----------------------------------------------------------------------------------------------------------------
1996................................ 229,000 ................. ................. .................
2020................................ 345,000 9,000 26,000 1,000
2030................................ 401,000 10,000 30,000 1,000
----------------------------------------------------------------------------------------------------------------
Notes:
a CMV = commercial marine vessels, RMV = Recreational marine vessels.
4. VOC and Air Toxics
Based on a 48 state emissions inventory, we estimate that land-
based nonroad diesel engines emitted over 221 thousand tons of VOC in
1996. Between 1996 and 2030, we estimate that land-based nonroad diesel
engines will contribute about 2 to 3 percent to mobile source VOC
emissions. Without further controls, land-based nonroad diesel engines
will emit over 97
[[Page 28358]]
thousand tons/year of VOC in 2020 and 2030 nationally.\113\
---------------------------------------------------------------------------
\113\ VOC emissions remain about the same in 2030 as 2020
because while nonroad diesel emission factors decrease and newer
engines continue to be introduced into the fleet, the engine/
equipment population continues to increase. The increase in engine/
equipment population offsets the effect of decreasing emission
factors.
---------------------------------------------------------------------------
Tables II.E-7 shows our projection of the reductions in 2020 and
2030 for VOC emissions that we expect from implementing the proposed
NMHC standards. This estimate is based on a 50 state emissions
inventory. By 2030, VOC reductions would be reduced by 30 percent.
Table II.E-7--Estimated National (50 State) Reductions in VOC Emissions From Nonroad Land-Based Diesel Engines
----------------------------------------------------------------------------------------------------------------
VOC reductions
Calendar year VOC without rule VOC with rule with rule [short
[short tons] [short tons] tons]
----------------------------------------------------------------------------------------------------------------
2020............................................. 97,000 79,000 18,000
2030............................................. 98,000 68,000 30,000
----------------------------------------------------------------------------------------------------------------
Air toxics pollutants are in VOCs and are included in the total
land-based nonroad diesel VOC emissions estimate. We base these numbers
on the assumption that air toxic emissions are a constant fraction of
hydrocarbon exhaust emissions.
Although we are not proposing any specific gaseous air toxics
standards, air toxics emissions would nonetheless be reduced through
NMHC standards included in the proposed rule. By 2030, we estimate that
emissions of air toxics pollutants, such as benzene, formaldehyde,
acetaldehyde, 1,3-butadiene, and acrolein, would be reduced by 30
percent from land-based nonroad diesel engines. For specific air toxics
reductions please see chapter 3 of the RIA. In section II.B.2 we
discuss the health effects of these pollutants.?
III. Nonroad Engine Standards
In this section we describe the nonroad diesel emission standards
we are proposing in order to address the serious air quality problems
discussed in section II. Specifically, we discuss:
[sbull] The Clean Air Act and why we are proposing new emission
standards.
[sbull] The technology opportunity for nonroad diesel emissions
control.
[sbull] Our proposed engine standards, and our proposed schedule
for implementing them.
[sbull] Proposals for supplemental test procedures and standards to
help control emissions during transient operating modes and engine
start-up.
[sbull] Proposals to help ensure robust emissions control in use.
[sbull] The feasibility of the proposed standards (in conjunction
with the proposed low-sulfur nonroad diesel fuel requirement discussed
in section IV).
[sbull] How diesel fuel sulfur affects an engine's ability to meet
the proposed standards.
[sbull] Plans for a future reassessment of the technology needed to
comply with proposed standards for engines below 75 hp.
Additional proposed provisions for engine and equipment
manufacturers are discussed in detail in section VII. Briefly, these
include changes to our engine manufacturer averaging, banking, and
trading (ABT) program, changes to our transition program for equipment
manufacturers, special provisions to aid small businesses in
implementing our requirements, and an incentive program to encourage
innovative technologies and the early introduction of new technologies.
We welcome comment on all facets of this discussion, including the
levels and timing of the proposed emissions standards and our
assessment of technological feasibility, as well as on the supporting
analyses contained in the Draft Regulatory Impact Analysis (RIA). We
also request comment on the timing of the proposed diesel fuel standard
in conjunction with these proposed emission standards. We ask that
commenters provide any technical information that supports the points
made in their comments.
A. Why Are We Setting New Engine Standards?
1. The Clean Air Act and Air Quality
We believe that Agency action is needed to address the air quality
problems discussed in section II. We are therefore proposing new engine
standards and related provisions under sections 213(a)(3) and (4) of
the Clean Air Act which, among other things, direct us to establish
(and from time to time revise) emission standards for new nonroad
diesel engines. Because emissions from these engines contribute greatly
to a number of serious air pollution problems, especially the health
and welfare effects of ozone, PM, and air toxics, we believe that the
air quality need for stringent nonroad diesel standards is well
established. This, and our belief that a significant degree of emission
reduction from these engines is achievable through the application of
diesel emission control technology that will be available in the lead
time provided (giving appropriate consideration to cost, noise, safety,
and energy factors as required by the Act), along with coordinated
reductions in nonroad diesel fuel sulfur levels, leads us to believe
that these new emission standards are warranted and appropriate.
We also believe that the proposed engine standards are consistent
with the Clean Air Act section 213 requirements on availability of
technology and appropriate lead time. The basis for our conclusion is
described in this section and in the Draft RIA.
2. The Technology Opportunity for Nonroad Diesel Engines
Substantial progress has been made in recent years in controlling
diesel exhaust emissions through the use of robust, high-efficiency
catalytic devices placed in the exhaust system. Particularly promising
are the catalytic soot filter or particulate trap for PM and
hydrocarbon control, and the NOX adsorber. These
technologies are expected to be applied to highway heavy-duty diesel
engines (HDDEs) beginning in 2007 to meet stringent new standards for
these engines. The final EPA rule establishing those standards contains
extensive discussion of how these devices work, how effective they are
at reducing emissions, and what their limitations are, particularly
their dependence on very-low sulfur diesel fuel to function properly
(66 FR 5002, January 18, 2001; see especially section III of the
preamble starting at 5035). Reviews of ongoing progress in the
development of these technologies have recently been performed by EPA
and by
[[Page 28359]]
an independent review panel.114 115 These reviews found that
significant progress has been made since the final rule was published,
reinforcing our confidence that the highway engine standards can be
met. (Our consideration of these highway engine standards is consistent
with the requirement in Clean Air Act section 213(a)(3) that EPA
consider nonroad engine standards equivalent in stringency to those
adopted for comparable highway engines regulated under section 202 of
the Act.)
---------------------------------------------------------------------------
\114\ ``Highway Diesel Progress Review'', U.S. EPA, June 2002.
EPA420-R-02-016. (www.epa.gov/air/caaac/dieselreview.pdf).
\115\ ``Meeting Technology Challenges For the 2007 Heavy-Duty
Highway Diesel Rule'', Final Report of the Clean Diesel Independent
Review Subcommittee, Clean Air Act Advisory Committee, October 30,
2002. (www.epa.gov/air/caaac/diesel/finalcdirpreport103002.pdf).
---------------------------------------------------------------------------
Although there are important differences, nonroad diesel engines
operate fundamentally like heavy-duty highway diesel engines. In fact,
many nonroad engine designs are derived from highway engine platforms.
We believe that, given the availability of nonroad diesel fuel meeting
our proposed 15 ppm maximum sulfur requirement and adequate development
lead time, nonroad diesel engines can be designed to successfully
employ the same high-efficiency exhaust emission control technologies
now being developed for highway use. Indeed, some nonroad diesel
applications, such as in underground mining, have pioneered the use of
similar technologies for many years. These technologies, the experience
gained with them in nonroad applications, the issues involved in
transferring technology from highway to nonroad applications, and the
appropriate standards and test procedures for this nonroad Tier 4
program are discussed in detail in the remainder of this section.
B. What Engine Standards Are We Proposing?
1. Exhaust Emissions Standards
The PM, NOX, and NMHC emissions standards being proposed
for nonroad diesel engines are summarized in Figures III.B-1 and 2. We
are also making minor adjustments to CO standards as discussed in
section III.B.1.f. All of these standards would apply to covered
nonroad engines over the useful life periods specified in our
regulations, except where temporary in-use compliance margins would
apply as discussed in section VII.J.\116\ We are not proposing changes
to the current useful life periods because we do not have any relevant
new information that would lead us to propose changes. However, we do
ask for comment on whether or not changes are warranted and, if so, on
what the useful life periods should be. The testing requirements by
which compliance with the standards would be measured are discussed in
section III.C. In addition we are proposing new ``not-to-exceed'' (NTE)
emission standards and associated test procedures to help ensure robust
control of emissions in use. These standards are discussed as part of a
broader outline of proposed NTE provisions in sections III.D and VII.G.
---------------------------------------------------------------------------
\116\ The useful life for engines =50 hp is 8,000
hours or 10 years, whichever occurs first. For engines <25 hp, and
for 25-50 hp engines that operate at constant speed at or above 3000
rpm, it is 3000 hours or 5 years. For other 25-50 hp engines, it is
5,000 hours or 7 years.
Figure III.B-1--Proposed PM Standards (g/bhp-hr) and Schedule
----------------------------------------------------------------------------------------------------------------
Model Year
Engine Power -----------------------------------------------------------------
2008 2009 2010 2011 2012 2013
----------------------------------------------------------------------------------------------------------------
hp < 25 (kW < 19)............................. \a\ 0.30 ......... ......... ......... ......... .........
25 <= hp < 75 (19 <= kW < 56)................. \b\0.22 ......... ......... ......... ......... 0.02
75 <= hp < 175 (56 <= kW < 130)............... ......... ......... ......... ......... 0.01 .........
175 <= hp <= 750 (130 <= kW <= 560)........... ......... ......... ......... 0.01 ......... .........
hp 750 (kW 560)....... ......... ......... ......... \c\ 0.01 ......... .........
----------------------------------------------------------------------------------------------------------------
Notes:
\a\ For air-cooled, hand-startable, direct injection engines under 11 hp, a manufacturer may instead delay
implementation until 2010 and demonstrate compliance with a less stringent PM standard of 0.45 g/bhp-hr,
subject also to additional provisions discussed in Section III.B.1.d.i.
\b\ A manufacturer has the option of skipping the 0.22 g/bhp-hr PM standard for all 50-75 hp engines; the 0.02 g/
bhp-hr PM standard would then take effect one year earlier for all 50-75 hp engines (in 2012).
\c\ 50% of a manufacturer's U.S.-directed production must meet the 0.01 g/bhp-hr PM standard in this model year.
In 2014, 100% must comply.
Figure III.B-2--Proposed NOX and NMHC Standards and Schedule
----------------------------------------------------------------------------------------------------------------
Standard (g/bhp-hr)
Engine Power -------------------------------------------------
NOX NMHC
----------------------------------------------------------------------------------------------------------------
25 <= hp < 75 (19 <= kW < 56)................................. 3.5 NMHC+NOX \a\
75 <= hp < 175 (56 <= kW < 130)............................... 0.30 0.14
175 <= hp <= 750 (130 <= kW <= 560)........................... 0.30 0.14
hp 750 (kW 560)....................... 0.30 0.14
----------------------------------------------------------------------------------------------------------------
----------------------------------------------------------------------------------------------------------------
Phase-in Schedule
Engine Power ---------------------------------------------------
2011 2012 2013 2014
----------------------------------------------------------------------------------------------------------------
25 <= hp < 75 (19 <= kW < 56)............................... ........... ........... 100% ...........
75 <= hp < 175 (56 <= kW < 130)............................. ........... \b\ 50% \b\ 50% \b\ 100%
175 <= hp <= 750 (130 <= kW <= 560)......................... 50% 50% 50% 100%
hp 750 (kW 560)..................... 50% 50% 50% 100%
----------------------------------------------------------------------------------------------------------------
Notes:
Percentages are U.S.-directed production required to comply with the Tier 4 standards in the indicated model
year.
\a\ This is the existing Tier 3 combined NMHC+NOX standard level for the 50-75 hp engines in this category; in
2013 it would apply to the 25-50 hp engines as well.
[[Page 28360]]
\b\ Manufacturers may use banked Tier 2 NMHC+NOX credits to demonstrate compliance with the proposed 75-175 hp
engine NOX standard in this model year. Alternatively, manufacturers may forego this special banked credit
option and instead meet an alternative phase-in requirement in 2012, 2013, and part of 2014. See Section
III.B.1.b.
The proposed long-term 0.01 and 0.02 g/bhp-hr Tier 4 PM standards
for 75 hp and 25-75 hp engines, respectively, combined with
the fuel change and proposed new requirements to ensure robust control
in the field, represent a reduction of over 95% from in-use levels
expected with Tier 2/Tier 3 engines.\117\ The proposed 0.30 g/bhp-hr
Tier 4 NOX standard for 75 hp engines represents
a NOX reduction of about 90% from in-use levels expected
with Tier 3 engines. The basis for the proposed standard levels is
presented in Section III.E.
a. Standards Timing
---------------------------------------------------------------------------
\117\ Note that we are grouping all standards proposed in this
rule under the general designation of ``Tier 4 standards'',
including those proposed to take effect in 2008. As a result, there
are no ``Tier 3'' standards in the multi-tier nonroad program for
engines below 50 hp or above 750 hp.
---------------------------------------------------------------------------
The timing of the Tier 4 NOX, PM, and NMHC standards is
closely tied to the proposed timing of fuel quality changes discussed
in section IV, in keeping with the systems approach we are taking for
this program. The earliest Tier 4 standards would take effect in model
year 2008, in conjunction with the introduction of 500 ppm maximum
sulfur nonroad diesel fuel in mid-2007. This fuel change serves a dual
environmental purpose. First, it provides a large immediate reduction
in PM emissions for the existing fleet of engines in the field. Second,
its widespread availability by the end of 2007 aids engine designers in
employing emission controls capable of achieving the proposed standards
for model year 2008 and later engines; this is because the performance
and durability of such technologies as exhaust gas recirculation (EGR)
and diesel oxidation catalysts is improved by lower sulfur fuel.\118\
The reduction of sulfur in nonroad diesel fuel will also provide
sizeable economic benefits to machine operators as it will extend oil
change intervals and reduce wear and corrosion (see section V).
---------------------------------------------------------------------------
\118\ ``Nonroad Diesel Emissions Standards Staff Technical
Paper'', EPA420-R-01-052, October 2001.
---------------------------------------------------------------------------
We are not, however, proposing new 2008 standards for engines at or
above 100 hp because these engines are subject to existing Tier 3
NMHC+NOX standards (Tier 2 for engines above 750 hp) in 2006
or 2007. Setting new 2008 standards would provide only one or two years
before another round of design changes would have to be made for Tier
4. Engines between 50-100 hp also have a Tier 3 NMHC+NOX
standard, but it takes effect in 2008, providing an opportunity to
coordinate with Tier 4 to provide the desired pull-ahead of PM control.
We believe that we can accomplish this PM pull-ahead without hampering
manufacturers' Tier 3 compliance efforts by providing two Tier 4
compliance options for 50-75 hp engines. This reflects the splitting of
the current 50-100 hp category of engines to match the new rated power
\119\ categories shown in Figures III.B-1 and 2. We are proposing to
provide manufacturers with the option to skip the Tier 4 2008 PM
standard (see Figure III-B.1) and instead to focus design efforts on
introducing PM filters for these engines one year earlier, in 2012.
This option would ensure that a manufacturer's Tier 3
NMHC+NOX compliance plans are not complicated by having to
meet a new Tier 4 PM standard in the same timeframe, if that were to
become a concern for a manufacturer.
---------------------------------------------------------------------------
\119\ The term rated power is used in this document to mean the
maximum power of an engine. See section VII.L for more information
about how the maximum power of an engine is determined.
---------------------------------------------------------------------------
We are concerned that this optional approach for 50-75 hp engines
might be abused by equipment manufacturers whose engine suppliers opt
not to meet the PM pull-ahead standard in 2008, but who then switch
engine suppliers to avoid PM filter-equipped engines in 2012. We are
therefore proposing that an equipment manufacturer making a product
with engines not meeting the pull-ahead standard in any of the years
2008-2011, must use engines in that product in 2012 meeting the 0.02 g/
bhp-hr PM standard; that is, from the same engine manufacturer or from
another engine manufacturer choosing the same compliance option. This
restriction would not apply if the 2008-2011 engines at issue are being
produced under the equipment manufacturer flexibility provisions
discussed in section VII.B. Also, we would not prohibit an equipment
manufacturer who is using non-pull-ahead engines in 2008-2011 from
making use of available equipment manufacturer flexibility provisions
in 2012 or later. That is, they could continue to use Tier 3 engines in
2012 that are purchased under these provisions; they would, however,
still be subject to the above-described restriction on switching
manufacturers. We solicit comment on whether this restriction should
have a numerical basis (e.g., the ``no switch'' restriction in 2012
applies to the same percentage of 50-75 hp machines produced with non-
pull-ahead engines in 2008-2011) to avoid further abuse by equipment
manufacturers who redefine their product models to dodge the
requirement, and on other suggestions for dealing with this concern.
Note that we are not proposing the optional 2008 PM standard for
engines between 75 and 100 hp, even though they, like the 50-75 hp
engines, are subject to a 2008 Tier 3 standard. This is because we
believe that these larger engines, proposed to be grouped into a new
75-175 hp category, would be subject to stringent new PM and
NOX standards beginning in 2012, and adding a 2008 PM
component to this program for a quarter of this 75-175 hp range would
complicate manufacturers' efforts to comply in 2012 for the overall
category.
We view the 2008 portion of the Tier 4 program as highly important
because it provides substantial PM and NOX emissions
reductions during the several years prior to 2011. Initiating Tier 4 in
2008 also fits well with the lead time, stability, cost, and technology
availability considerations of the overall program.\120\ Initiating the
Tier 4 standards in 2008 would provide three to four years of stability
after the start of Tier 2 for engines under 50 hp. As mentioned above,
it also coincides with the start date of Tier 3 NOX+NMHC
standards for engines between 50 and 75 hp and so introduces no
stability issues for these engines. As the Agency expects to finalize
this rule in early 2004, the 2008 start date provides almost 4 years of
lead time to accomplish redesign and testing. The evolutionary
character of the 2008 standards, based as they are on proven
technologies, and the fact that some certified engines already meet
these standards as discussed in Section
[[Page 28361]]
III.E leads us to conclude that this will provide adequate lead time.
---------------------------------------------------------------------------
\120\ Section 213(b) of the Clean Air Act does not specify a
minimum lead time period, nor does it mandate a set minimum period
of stability for the standards (differing in these respects from the
comparable provision section (202(a)(3)(C)) applicable to highway
engines). However, in considering the amount of lead time and
stability provided, EPA takes into consideration the need to avoid
disruptions in the engine and equipment manufacturing industries
caused by redesign mandates that are too frequent or too soon after
a final rulemaking. These are appropriate factors to consider in
determining ``the lead time necessary to permit the development and
application of the requisite technology'', and are part of taking
cost into consideration, as required under section 213 (b).
---------------------------------------------------------------------------
The second fuel change, to 15 ppm maximum sulfur in mid-2010, and
the related engine standards that begin to phase-in in the 2011 model
year, provide the large majority of the environmental benefits of the
program. These standards are also timed to provide adequate lead time
for manufacturers, and to phase in over time to allow for the orderly
transfer of technology from the highway sector. We believe that the
high-efficiency exhaust emission technologies being developed to meet
our 2007 emission standards for heavy-duty highway diesel engines can
be adapted to nonroad diesel applications. The engines for which we
believe this adaptation from highway applications will be most
straightforward are those in the over 175 hp power range, and thus
under our proposal these engines would be subject to new standards
requiring high-efficiency exhaust emission controls as soon as the 15
ppm sulfur diesel fuel is widely available, that is, in the 2011 model
year. Engines between 75 and 175 hp would be subject to the new
standards in the following model year, 2012, reflecting the greater
effort involved in adapting highway technologies to these engines.
Lastly, engines between 25 and 75 hp would be subject to the new PM
standard in 2013, reflecting the even greater challenge of adapting PM
filter technology to these engines which typically do not have highway
counterparts. There are additional phase-in provisions discussed in
Section III.B.1.b aimed at further drawing from the highway technology
experience.
In addition to addressing technology transfer, this approach
reflects the need to distribute the workload for engine and equipment
redesign over three model years, as was provided for in Tier 3.
Overall, this approach provides 4 to 6 years of real world experience
with the new technology in the highway sector, involving millions of
engines (in addition to the several additional years provided by
demonstration fleets already on the road), before the new standards
take effect.
b. Phase-In of NOX and NMHC Standards
Because the Tier 4 NOX emissions control technology,
like PM control technology, is expected to be derived from technology
first introduced in highway HDDEs, we believe that the implementation
of the Tier 4 NOX standard should follow the pattern we
adopted for the highway program. This will help to ensure a focused,
orderly development of robust high-efficiency NOX control in
the nonroad sector and will also help to ensure that manufacturers are
able to take maximum advantage of the highway engine development
program, with resulting cost savings. The heavy-duty highway rule
allows for a gradual phase-in of the NOX and NMHC
requirements over multiple model years: 50 percent of each
manufacturer's U.S.-directed production volume must meet the new
standard in 2007-2009, and 100 percent must do so by 2010. We also
provided flexibility for highway engine manufacturers to meet that
program's environmental goals by allowing somewhat less-efficient
NOX controls on more than 50% of their production before
2010 via emissions averaging. Similarly, we are proposing to phase in
the NOX standards for nonroad diesels over 2011-2013 as
indicated in Figure III.B-2, based on compliance with the Tier 4
standards for 50% of a manufacturer's U.S.-directed production in each
power category at or above 75 hp in each phase-in model year.
With a NOX phase-in, all manufacturers are able to
introduce their new technologies on a limited number of engines,
thereby gaining valuable experience with the technology prior to
implementing it on their entire product line. In tandem with the
equipment manufacturer transition program discussed in section VII.B,
the phase-in ensures timely progress to the Tier 4 standards levels
while providing a great degree of implementation flexibility for the
industry.
We are proposing this ``percent of production phase-in'' to take
maximum advantage of the highway program technology development. It
adds a new dimension of implementation flexibility to the staggered
``phase-in by power category'' used in the nonroad program for Tiers 1,
2 and 3 which, though structured to facilitate technology development
and transfer, is more aimed at spreading the redesign workload. Because
the Tier 4 program would involve substantial challenges in addressing
both technology development and redesign workload, we believe that
incorporating both of these phase-in mechanisms into the proposed
program is warranted, resulting in the coordinated phase-in plan shown
in Figure III.B-2. Note that this results in our proposing that new
NOX requirements for 75-175 hp engines be deferred for the
first year of the 2011-2013 general phase-in, in effect creating a 50-
50% phase-in in 2012-2013 for this category. This then staggers the
Tier 4 start years by power category as in past tiers: 2011 for engines
at or above 175 hp, 2012 for 75-175 hp engines, and 2013 for 25-75 hp
engines (for which no NOX adsorber-based standard and thus
no percentage phase-in is being proposed), while still providing a
production-based phase-in for advanced NOX control
technologies.
We believe that the 75-175 hp category of engines and equipment may
involve added workload challenges for the industry to develop and
transfer technology. We note that this category, though spanning only
100 hp, represents a great diversity of applications, and comprises a
disproportionate number of the total nonroad engine and machine models.
Some of these engines, though having characteristics comparable to many
highway engines such as turbocharging and electronic fuel control, are
not directly derived from highway engine platforms and so are likely to
require more development work than larger engines to transfer emission
control technology from the highway sector. Furthermore, the engine and
equipment manufacturers have greatly varying market profiles in this
category, from focused one- or two-product offerings to very diverse
product lines with a great many models. We are interested in providing
useful flexibility for a wide range of companies in implementing the
Tier 4 standards, while keeping a priority on bringing PM emissions
control into this diverse power category as quickly as possible.
We are therefore proposing two compliance flexibility provisions
just for this category. First, we propose to allow manufacturers to use
NMHC+NOX credits generated by Tier 2 engines over 50 hp (in
addition to any other allowable credits) to demonstrate compliance with
the Tier 4 requirement for 75-175 hp engines in 2012, 2013, and 2014
only. This would not otherwise be allowed, for reasons explained in
section VII.A. These Tier 2 credits would be subject to the power
rating conversion already established in our ABT program, and to the
20% credit adjustment we are proposing for use of NMHC+NOX
credits as NOX credits. (See section VII.A.)
Second, we realize that some manufacturers, especially those with
limited product offerings, may not have sufficient banked credits
available to them to benefit from this special flexibility, and so we
are also proposing an alternative flexibility provision. A manufacturer
may optionally forego the Tier 2 banked credit use provision described
above, and instead demonstrate compliance with a reduced phase-in
requirement for NOX and NMHC. Use of credits other than
banked Tier 2 credits would still be allowed, in
[[Page 28362]]
accordance with the other ABT program provisions. In no case could the
phase-in compliance demonstration drop below 25% in each of 2012, 2013,
and the first 9 months of 2014, except as allowed under the ``good
faith projection deficit'' provision discussed in Section VII.D. Full
compliance (100% phase-in) with the Tier 4 standards would need to be
demonstrated in the last 3 months of 2014 and thereafter.
In addition, a manufacturer using this reduced phase-in option
would not be allowed to generate credits from engines in this power
category in 2012, 2013, and the first 9 months of 2014, except for use
in averaging within this power category only (no banking or trading, or
averaging with engines in other power categories). This restriction
would apply throughout this period even if the reduced phase-in option
is exercised during only a portion of this period. We believe that this
ABT restriction is important to avoid potential abuse of the added
flexibility allowance, considering that larger engine categories will
be required to demonstrate substantially greater compliance levels with
the 0.30 g/bhp-hr NOX standard several years earlier than
engines built under this option. The restriction should be no burden to
manufacturers, as only those using the option would be subject to it,
and the production of credit-generating engines would be contrary to
the option's purpose.
We are proposing to phase in the Tier 4 NMHC standard with the
NOX standard, as is being done in the highway program.
Engines certified to the new NOX requirement would be
expected to certify to the NMHC standard as well. The ``phase-out''
engines (the 50 percent not certified to the new Tier 4 NOX
and NMHC standards) would continue to be certified to the applicable
Tier 3 NMHC+NOX standard. As discussed in section III.E, we
believe that the NMHC standard is readily achievable through the
application of PM traps to meet the PM standard, which for most engines
does not involve a phase-in. However, in the highway program we chose
to phase in the NMHC standard with the NOX standard for
administrative reasons, to simplify the phase-in under the percent-of-
production approach taken there, thus avoiding subjecting the ``phase-
out'' engines to separate standards for NMHC and NMHC+NOX.
The same reasoning applies here because, as in the highway program, the
previous-tier standards are combined NMHC+NOX standards.
Because of the tremendous variety of engine sizes represented in
the nonroad diesel sector, we are proposing that the 50 percent phase-
in requirement be met separately in each of the three power categories
for which a phase-in is proposed (75-175 hp, 175-750 hp, and
750 hp).\121\ For example, a manufacturer that produces 1000
engines for the 2011 U.S. market in the 175 to 750 hp range would have
to demonstrate compliance to the proposed NOX and NMHC
standards on at least 500 of these engines, regardless of how many
complying engines the manufacturer produces in other hp categories.
(Note, however, that we would allow averaging of emissions across these
engine category cutpoints through the use of power-weighted ABT program
credits, as provided for in the existing nonroad diesel engine
program.) We believe that this restriction reflects the availability of
emissions control technology, and is needed to avoid erosion of
environmental benefits that might occur if a manufacturer with a
diverse product offering were to meet the phase-in with relatively low
cost smaller engines, thereby delaying compliance on larger engines
with much higher lifetime emissions potential. Even so, the horsepower
ranges for these power categories are fairly broad, so this restriction
allows ample freedom to manufacturers to structure compliance plans in
the most cost-effective manner. We could as well choose to handle this
concern by weighting complying engines by horsepower, as we do in the
ABT program, but we believe that creating a simple phase-in structure
based simply on counting engines, as we did in the highway HDDE rule,
avoids unnecessary complexity and functional overlap with ABT.
---------------------------------------------------------------------------
\121\ Note proposed exceptions to the 50 percent requirements
during the phase-in model years discussed in sections VII.D and
VII.E. These deal with differences between a manufacturer's actual
and projected production levels, and with incentives for early or
very low emission engine introductions.
---------------------------------------------------------------------------
c. Rationale for Restructured Horsepower Categories
We are proposing to regroup the power categories in the proposed
Tier 4 program compared to the previous tiers of standards.\122\ We are
doing so because this will more closely match the degree of challenge
involved in transferring advanced emissions control technology from
highway engines to nonroad engines. For a variety of reasons, highway
engines have in the past been equipped with new emission control
technologies some years before nonroad engines. As a result, the
nonroad engine platforms that are directly derived from highway engine
designs in turn become the lead application point for the migration of
emission control technologies into the nonroad sector. Smaller and
larger nonroad engines, as well as similar-sized engines that cannot
directly use a highway base engine (such as farm tractor engines that
are structurally part of the tractor chassis), may then employ these
technologies after additional lead time for needed adaptation. This
progression has been reflected in EPA standards-setting activity to
date, especially in implementation schedules, in which the earliest
standards are applied to engines in the most ``highway-like'' power
categories.
---------------------------------------------------------------------------
\122\ The Tier 1 / 2 / 3 programs make use of 9 categories
divided by horsepower: <11, 11-25, 25-50, 50-100, 100-175, 175-300,
300-600, 600-750, and 750 hp.
---------------------------------------------------------------------------
Although there is not an abrupt power cutpoint above and below
which the highway-derived nonroad engine families do and do not exist,
we believe that 75 hp is a more appropriate cutpoint for this purpose
than either of the closest previously adopted power category cutpoints
of 50 or 100 hp. These two cutpoints were first adopted in a 1994 final
rule that chose them in order to establish categories for a staggered
implementation schedule designed to spread out development costs (59 FR
31306, June 17, 1994). Nonroad diesels produced today with rated power
above 75 hp (up to several hundred hp) are mostly variants of nonroad
engine platforms with four or more cylinders and per-cylinder
displacements of one liter or more. These in turn are derived from or
are similar to heavy-duty highway engine platforms. Even where nonroad
engine models above 75 hp are not so directly derived from highway
models, they typically share many common characteristics such as
displacements of one liter per cylinder or more, direct injection
fueling, turbocharging, and, increasingly, electronic fuel injection.
These common features provide key building blocks in transferring high-
efficiency exhaust emission control technology from highway to similar
nonroad diesel engines. We have discussed this matter with relevant
engine manufacturers, and we are confident based on these discussions
that 75 hp represents an industry consensus on the appropriate cutpoint
for this purpose. We invite comment on the 75 hp cutpoint.
We are therefore proposing to regroup power ratings using the 75 hp
cutpoint. Some have expressed that this may somewhat complicate the
transition from tier to tier and efforts to harmonize with the European
Union's nonroad diesel program (which currently uses
[[Page 28363]]
power cutpoints corresponding to 50 and 100 hp). However, we believe
that it provides substantial long-term benefits for the environment
(for example, by linking NOX standard-setting to an engine
technology-based 75 hp cutpoint). We will continue working with key
entities to advance harmonization as this rule is developed.
We are also proposing to consolidate some power categories that
were created in the past to allow for variations in standards levels
and timing appropriate for Tiers 1, 2 and 3, and that remain in effect
for those tiers, but which under this proposal are no longer distinct
from each other with respect to standards levels and timing. These
consolidations are: (1) The less than 11 hp and 11-25 hp categories
into a single category of less than 25 hp, (2) the 75-100 hp portion of
the 50-100 hp category and the 100-175 hp category into a single
category of 75-175 hp, and (3) the 175-300 hp, 300-600 hp, and 600-750
hp categories into a single category of 175-750 hp. The result is the 5
power bands shown in Figures III.B-1 and 2 instead of the former 9.
This will also help to facilitate use of equipment manufacturer
transition flexibility allowances which can be applied only within each
power band, as discussed in section VII.B. We ask for comment on this
regrouping, especially with regard to the appropriate power cutpoint
for the engine families that are similar to highway engine families.
Again, most useful in this regard would be information showing how
highway and nonroad engines in this range do or do not share common
design bases.
d. PM Standards for Smaller Engines
i. <25 hp
We believe that standards based on the use of PM filters should not
be proposed at this time for the very small diesel engines below 25 hp.
Although this technology could be adapted to these engines, the cost of
doing so with known technology could be unacceptably high, relative to
the cost of producing the engines themselves. Based on past experience,
we expect that advancements in reducing these costs will occur over
time. We plan to reassess the appropriate long-term standards in a
technology review as discussed in section III.G. For the nearer-term,
we believe that other proven PM-reducing technologies such as diesel
oxidation catalysts and engine optimization can be applied to engines
under 25 hp for very cost-efficient PM control, as discussed in
sections III.E and V.A. When implemented, the PM standard proposed in
Figure III.B-1 for these engines, along with the proposed transient
test cycle, will yield an in-use PM reduction of over 50% for these
engines, and large reductions in toxic hydrocarbons as well. Achieving
these emission reductions is very important, considering the fact that
many of these smaller engines operate in populated areas and in
equipment without closed cabs-- in mowers, portable electric power
generators, small skid steer loaders, and the like. We invite comment
on this proposed approach to controlling harmful emissions from very
small nonroad diesel engines.
It is our assessment that achieving low PM emission levels is
especially challenging for one subclass of small engines: the air-
cooled, direct injection engines under 11 hp that are startable by
hand, such as with a crank or recoil starter. These typically one-
cylinder engines find utility in applications such as plate compactors,
where compactness and simplicity are needed, but where the ruggedness
typical of a diesel engine is also essential. There are a number of
considerations in the design, manufacture, and marketing of these
engines that combine to make them difficult to optimize for low
emissions. These include the air-cooled engine's need for relatively
loose design fit tolerances to accommodate thermal expansion
variability (which can lead to increased soluble organic PM), small
cylinder displacement and bore sizes that limit use of some combustion
chamber design strategies and increase the propensity for PM-producing
fuel impingement on cylinder walls, the difficulty in obtaining
components for small engines with machining tolerances tight enough to
yield consistent emissions performance, and cost reduction pressures
caused by competition from cheaper gasoline engines in some of the same
applications.
As a result, we are proposing an alternative compliance option that
allows manufacturers of these engines to delay Tier 4 compliance until
2010, and in that year to certify them to a PM standard of 0.45 g/hp-
hr, rather than to the 0.30 g/hp-hr PM standard applicable to the other
engines in this power category beginning in 2008. Engines certified
under this alternative compliance requirement would not be allowed to
generate credits as part of the ABT program, although credit use by
these engines would still be allowed. We believe that this ABT
restriction is important to avoid potential abuse of this option, and
is a reasonable means of dealing with the concern as it would apply
only to those air-cooled, hand-startable, direct injection engines
under 11 hp that are certified under this special compliance option,
and the production of credit-generating engines would be contrary to
the option's purpose. Furthermore, because the proposed 2010 Tier 4
implementation year for these engines is the same year that 15 ppm
sulfur nonroad diesel fuel would become available, we are also
proposing that certification testing and any subsequent compliance
testing on engines certified under this option may be conducted using
the 7-15 ppm sulfur test fuel discussed in section VII.H. Although this
is one year earlier than would be otherwise allowable, we believe it
would have a minimal impact on the proposed program's environmental
benefit considering the extremely small contribution these engines make
to emissions inventories, and the fact that these engines would
generally operate in the field on higher sulfur fuels for at most a few
months.
ii. 25-75 hp
We believe that the proposed 0.22 g/bhp-hr PM standard for 25-75 hp
engines in 2008 is warranted because the Tier 2 PM standards that take
effect in 2004 for these engines, 0.45 and 0.30 g/bhp-hr for 25-50 and
50-75 hp engines, respectively, do not represent the maximum achievable
reduction using technology which will be available by 2008. However, as
discussed in section III.B.1.a, filter-based technology for these
engines is not expected to be available on a widespread basis until the
2013 model year. The proposed 2008 PM standard for these engines should
maximize reduction of PM emissions based on technology available in
that year. We believe that the 2008 standards are feasible for these
engines, based on the same engine or oxidation catalyst technologies
feasible for engines under 25 hp in 2008, following the proposed
introduction of nonroad diesel fuel with sulfur levels reduced below
500 ppm. We expect in-use PM reductions for these engines of over 50%,
and large reductions in toxic hydrocarbons as well over the five model
years this standard would be in effect (2008-2012). These engines will
constitute a large portion of the in-use population of nonroad diesel
engines for many years after 2008.
We request comment on our proposal to implement Tier 4 PM standards
for 25-75 hp engines in the two phases just noted: a non-PM filter
based standard in 2008 and a filter-based standard in 2013. In
addition, we request comment on whether it would be better not to set a
Tier 4 PM standard in 2008 so that engine designers could instead focus
[[Page 28364]]
their efforts on meeting a PM-filter based standard for these engines
earlier, say in 2012. (It should be noted that the proposed rule would
provide this as an option for a subgroup of these engines (50-75 hp).
See Figure III.B-1 note b.) We would assume that under this approach
the proposed new NOX+NMHC standard for 25-50 hp engines in
this category would also start in 2012, to avoid requiring two design
changes in two years. Any comments in support of this approach should,
if possible, include information to support a conclusion that the
earlier start date for a PM filter-based standard would be
technologically feasible.
We believe that the proposed 2008 PM standards for engines under 75
hp can be met either through engine optimization, by the use of diesel
oxidation catalysts, or by some combination thereof, as discussed in
section III.E. For engines that comply through the use of oxidation
catalysts, NMHC emissions are expected to be very low because properly
designed oxidation catalysts are effective at oxidizing gaseous
hydrocarbons as well as the soluble organic fraction of diesel exhaust
PM. Engines complying with the proposed 2008 PM standard without the
use of oxidation catalysts would, on the other hand, be expected to
emit NMHC at about the same levels as Tier 2 engines. Recognizing that
NMHC emissions from diesel engines can include a number of toxic
compounds, and that there are many of these small diesel engines
operating in populated areas, we are interested in comment on the
appropriateness of setting a more stringent NMHC standard for these
engines in 2008 to better control these emissions. We expect that doing
so would likely result in more widespread use of oxidation catalysts
(rather than engine optimization) for these engines. We would not,
however, expect this to lead to a more stringent PM standard than the
one we are proposing, based on the feasibility discussion in section
III.E.
e. Engines Above 750 hp
For engines above 750 hp, additional lead time to fully implement
Tier 4 is warranted due to the relatively long product design cycles
typical of these high-cost, low-sales volume engines and machines. The
long product design cycle issue is the primary reason we did not set
Tier 3 standards for these engines in the 1998 rule and are not
proposing to do so now. Instead, we are proposing that these engines
move from the Tier 2 standards, which take effect in 2006, to Tier 4
standards beginning in 2011, five years later. Moreover, we are
proposing that the Tier 4 PM standard be phased in for these engines on
the same 50-50-50-100% schedule as the NOX and NMHC phase-in
schedule, rather than all at once in 2011 as for engines between 175
and 750 hp. (See Figure III.B-1.) This would provide engine
manufacturers with up to 8 years of design stability to address
concerns associated with product design cycles and low sales volumes
typical of this category. The engine manufacturer ABT program adds
additional flexibility. Even longer stability periods could exist for
equipment manufacturers using these engines because they have their own
transition flexibility provisions available on top of the engine
standard phase-in. This is especially significant because many of these
large machines are built by manufacturers who build their own engines,
or who work closely with their engine suppliers, and can thus create a
long-term product plan making coordinated use of engine and equipment
flexibility provisions.
We think that, taken together, these provisions appropriately
balance the need for expeditious emission reductions with issues
relating to lead time, technology development, and cost for these
engines and machines. Even so, some engine and equipment manufacturers
have expressed concerns to us that, though not challenging the Tier 4
program endpoint (high-efficiency PM and NOX exhaust
emission controls), in their estimation our proposed program
implementation provisions do not adequately address their timing
concerns. In particular, they have expressed a view that they need
until 2012 (one additional year) before they could begin to phase in
Tier 4 standards for this category. They have also expressed the view
that mobile machinery such as mine haul trucks and dozers (as
differentiated from equipment such as nonroad diesel generators that
also use engines in this hp range) present unique challenges that could
require more time to resolve than would be afforded by the proposed
2014 phase-in completion date.
Although we believe that the implementation schedule and
flexibility provisions we are proposing will enable the manufacturers
to meet these challenges, we acknowledge the manufacturers' concerns
and ask for comment on this issue. Specifically, we request comment on
whether this category, or some subset of it defined by hp or
application, should have a later phase-in start date, a later phase-in
end date, adjusted standards, additional equipment manufacturer
flexibility provisions, or some combination of these. Technical
information backing the commenter's view would be most helpful in this
regard.
As with the NOX/NMHC phase-in for all engines at or
above 75 hp, we are proposing that the PM phase-in for engines above
750 hp would have to be met on the same engines as the Tier 4
NOX and NMHC standards during the phase-in years. That is,
engines certified to the Tier 4 NOX and NMHC requirements
would be expected to certify to the Tier 4 PM standard as well.
f. CO Standards
We are proposing minor changes in CO standards for some engines
solely for the purpose of helping to consolidate power categories.
These amount to a change for engines under 11 hp from 6.0 to 4.9 g/bhp-
hr in 2008 to match the existing Tier 2 CO standard for 11-25 hp
engines, and a change for engines at or above 25 hp but below 50 hp
from 4.1 to 3.7 g/bhp-hr to match the existing Tier 3 CO standard for
50-75 hp engines, also in 2008. These minor proposed changes are not
expected to add a notable compliance burden. Nevertheless, we expect
that the use of high-efficiency exhaust emission controls will yield a
substantial reduction in CO emissions, as discussed in Chapter 4 of the
draft RIA.
These minor adjustments to the CO standard are based solely on our
desire to simplify the administrative process for the engine
manufacturers which arises from the reduction in the number of the
engine power categories we have proposed for Tier 4. We are not
exercising our authority to revise the CO standard for nonroad diesel
engines for the purpose of improving air quality at this time, and
therefore the minor adjustments we have proposed today, though
feasible, are not based on a detailed evaluation of the capabilities of
advanced exhaust aftertreatment technology to reduce CO levels.
g. Exclusion of Marine Engines
These proposed emission standards would apply to engines in the
same applications covered by EPA's existing nonroad diesel engine
standards, at 40 CFR part 89, except that they would not apply to
marine diesel engines. Marine diesel engines below 50 hp were included
in our 1998 rule that set nonroad diesel emission standards (63 FR
56968, October 23, 1998). In that rule, we expected that the engine
modifications needed to achieve those standards (e.g., in-cylinder
controls) for marine engines would not need to be different from those
for land-based engines of this size.
[[Page 28365]]
The standards for diesel engines below 50 hp being proposed in this
action are likely to require PM filters or diesel oxidation catalysts
on many or all engines, and transferring this technology to the marine
diesel engines of any size raises unique issues. For example, many
marine diesel engines have water-jacketed exhaust which may result in
different exhaust temperatures and which could affect aftertreatment
efficiency. The modified marine engine designs would also have to meet
Coast Guard requirements. These and other conditions may require
separate design efforts for marine diesel engines. Therefore, we
believe it is more appropriate to consider more stringent standards for
marine diesel engines below 50 hp in a future action. It should be
noted, however, that the existing Tier 2 standards will continue to
apply to marine diesel engines under 50 hp until that future action is
completed.
2. Crankcase Emissions Control
Crankcase emissions are the pollutants that are emitted in the
gases that are vented from an engine's crankcase. These gases are also
referred to as ``blowby gases'' because they result from engine exhaust
from the combustion chamber ``blowing by'' the piston rings into the
crankcase. These gases are often vented to prevent high pressures from
occurring in the crankcase. Our existing emission standards require
control of crankcase emissions from all nonroad diesel engines except
turbocharged engines. The most common way to eliminate crankcase
emissions has been to vent the blowby gases into the engine air intake
system, so that the gases can be recombusted. Following the precedent
we set for heavy-duty highway diesel engines in an earlier rulemaking,
we made the exception for turbocharged nonroad diesel engines because
of concerns about fouling that could occur by routing the diesel
particulates (including engine oil) into the turbocharger and
aftercooler. Our concerns are now alleviated by newly developed closed
crankcase filtration systems, specifically designed for turbocharged
diesel engines. These new systems are already required in parts of
Europe for new highway diesel engines under the EURO III emission
standards, and are expected to be used in meeting new U.S. EPA
crankcase emission control standards for heavy-duty highway diesel
engines beginning in 2007 (see section III.C.1.c of the preamble to the
2007 heavy-duty highway final rule).
We are therefore proposing to eliminate the exception for
turbocharged nonroad diesel engines starting in the same model year
that Tier 4 exhaust emission standards first apply in each power
category. This is 2008 for engines below 75 hp, except for 50-75 hp
engines for which a manufacturer opts to skip the 2008 PM standard. The
crankcase requirement applies to ``phase-in'' engines above 750 hp
under the 50% phase-in requirement for 2011-2013, but not to the
``phase-out'' engines in that power category during those years. This
is an environmentally significant proposal since many nonroad machine
models use turbocharged engines, and a single engine can emit over 100
pounds of NOX, NMHC, and PM from the crankcase over the
lifetime of the engine. We also note that the cost of control is small
(see section V).
Our existing regulatory requirement for controlling crankcase
emissions from naturally-aspirated nonroad engines allows manufacturers
to route the crankcase gases into the exhaust stream instead of the
engine air intake system, provided they keep the combined total of the
crankcase emissions and the exhaust emissions below the applicable
exhaust emission standards. We are proposing to extend this allowance
to the turbocharged engines as well. We are also proposing to give
manufacturers the option to measure crankcase emissions instead of
completely eliminating them, and adding the measured emissions to
exhaust emissions in assessing compliance with exhaust emissions
standards. This allowance was adopted for highway HDDEs in 2001 (see
section VI.A.3 of the preamble to the 2007 heavy-duty highway final
rule). As in the highway program, manufacturers choosing to use this
allowance rather than to seal the crankcase would need to modify their
exhaust deterioration factors or to develop separate deterioration
factors to account for increases in crankcase emissions as the engine
ages. Manufacturers would also be responsible for ensuring that
crankcase emissions would be readily measurable in use.
C. What Test Procedure Changes Are Being Proposed?
We are proposing a number of changes to the certification test
procedures by which compliance with emission standards is determined.
Two of these are particularly significant: The addition of a
supplemental transient emissions test and the addition of a cold start
testing component to the proposed transient emissions test. These are
discussed briefly in this section, and in more detail in section VII.F.
Other proposed changes are also discussed in section VII.F and deal
with:
[sbull] Adoption of an improved smoke testing procedure, with
associated standards levels and exemptions.
[sbull] Addition of a steady-state test cycle for transportation
refrigeration units.
[sbull] Test procedure changes intended to improve testing
precision, especially with regards to sampling methods.
[sbull] A clarification to existing EPA defeat device regulations.
1. Supplemental Transient Test
In the 1998 final rule that set new emission standards for nonroad
diesel engines, we expressed a concern that the steady-state test
cycles used to demonstrate compliance with emission standards did not
adequately reflect transient operation, and, because most nonroad
engines are used in applications that are largely transient in nature,
would therefore not yield adequate control in use (63 FR 56984, October
23, 1998). Although we were not prepared to adopt a transient test at
that time, we announced our intention in that final rule to move
forward with the development of such a test. This development has
progressed steadily since that time, and has resulted in the creation
of a Nonroad Transient Composite (NRTC) test cycle, which we are now
proposing to adopt in our nonroad diesel program, to supplement the
existing steady-state tests. We expect that this proposed requirement
will significantly reduce real world emissions from nonroad diesel
equipment. Instead of sampling engine operation at the few isolated
operating points of steady-state emission tests, proper transient
testing can capture emissions from the broad range of engine speed and
load combinations that the engine may attain in use, as well as
emissions resulting from the change in speed or load itself, such as
those induced by turbocharger lag.
The proposed NRTC cycle will capture transient emissions over much
of the typical nonroad engine operating range, and thus help ensure
effective control of all regulated pollutants. In keeping with our goal
to maximize the harmonization of emissions control programs as much as
possible, we have developed this cycle in collaboration with nonroad
engine manufacturers and regulatory bodies in the United States,
Europe, and Japan over the last several years.\123\ Further, the NRTC
cycle has been introduced as a work item for
[[Page 28366]]
possible adoption as a potential global technical regulation under the
1998 Agreement for Working Party 29 at the United Nations.\124\
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\123\ Letter from Jed Mandel of the Engine Manufacturers
Association to Chet France of U.S. EPA, Office of Transportation and
Air Quality, Docket A-2001-28.
\124\ Informal Document No. 2, ISO--45th GRPE, ``Proposal for a
Charter for the Working Group on a New Test Protocol for Exhaust
Emissions from Nonroad Mobile Machinery,'' 13-17 January 2003,
Docket A-2001-28.
---------------------------------------------------------------------------
The Agency is proposing that emission standards be met on both the
current steady-state duty cycles and the new transient duty cycles. The
transient testing would begin in the model year that the trap-based
Tier 4 PM standards and/or adsorber-based Tier 4 NOX
standards first apply. This would be 2011 for engines at or above 175
hp, 2012 for 75-175 hp engines (2012 for 50-75 hp engines made by a
manufacturer choosing the optional approach described in footnote b of
Figure III.B-1), and 2013 for engines under 75 hp. See also Table
VII.F.-1. In addition, any engines for which a manufacturer claims
credit under the incentive program for early-introduction engines (see
section VII.E) would have to be certified to that program's standards
under the NRTC cycle and, in turn, the 2011 or later model year engines
that use these engine count-based credits would not need to demonstrate
compliance under the NRTC cycle.
Although we intend that transient emissions control be an integral
part of Tier 4 design considerations, we do not believe it appropriate
to mandate compliance with the transient test for the engines under 75
hp subject to proposed PM standards in 2008. We recognize that
transient emissions testing, though routine in highway engine programs,
involves a fair amount of new laboratory equipment and expertise in the
nonroad engine certification process. As with the transfer of advanced
emission control technology itself, we believe that the transient test
requirement should be implemented first for larger engines more likely
to be made by engine manufacturers who also have highway engine
markets. We do not believe that the smaller engines should be the lead
power categories in implementing the new transient test, especially
because many manufacturers of these engines do not make highway engines
and are not as experienced or well-equipped as their large-engine
counterparts for conducting transient cycle testing.
Engines below 25 hp involve an additional consideration for timing
of the transient test requirement because we are not proposing PM-
filter based standards for them. We propose that testing on the NRTC
cycle not be required for these engines until the 2013 model year, the
last year in which engines in higher power categories are required to
use this test. We are concerned that manufacturers not view this
proposed deferral of the transient test requirement as a structured
second level of required control for these engines. To address this
concern and because we wish to encourage the demonstration of transient
emission control as early as possible, we are proposing to allow
manufacturers to optionally certify engines below 25 hp under the NRTC
cycle beginning in the 2008 model year, and to extend this option to
25-75 hp engines subject to engines meeting the transitional PM
standard in 2008. (See also the discussion in section VII.F.1 on this
issue.) We request comment on this proposed approach and on whether it
would be better to deal with this concern by requiring compliance under
the transient test when the Tier 4 standards begin in 2008.
In applying the NRTC test requirement coincident with the start of
PM filter-based standards, we do not mean to imply that control of PM
from filter-equipped engines is the only or even the primary concern
being addressed by transient testing. In fact, we believe that advanced
NOX emission controls may be more sensitive to transient
operation than PM filters. It is, however, our intent that the control
of emissions during transient operation be an integral part of Tier 4
engine design considerations, and we therefore have proposed that
transient testing be applied with the PM filter-based Tier 4 PM
standards, because these standards precede or accompany the earliest
Tier 4 NOX or NMHC standards in every power category. Even
so, we request comment on whether the ``phase-out'' engines above 75 hp
(those engines for which compliance with the Tier 4 NOX
standard is not required during the phase-in period) should be exempted
from the requirement to meet the applicable NMHC+NOX
standard using the transient test. Although our interest in ensuring
transient emissions control as quickly as possible in the Tier 4
program, and in avoiding test program complexity, would argue against
this approach, we are also interested in not diverting engine designers
from the challenging task of redesigning engines to meet the proposed
0.30 g/bhp-hr Tier 4 NOX standard before and during the
phase-in years by having to deal with transient control under an
NMHC+NOX standard that is being phased out.
We are in fact not proposing to apply the transient test to phase-
out engines above 750 hp that are carried over from pre-2011 Tier 2
engine designs. Unlike phase-out engines at or below 750 hp, these
engines are not subject to a Tier 4 PM standard in 2011. They would
thus be Tier 2 engine designs and we do not believe that subjecting
them to transient testing would be appropriate. On the other hand,
engines in any power category certified to an average NOX
standard under the ``split family'' provision described in section
VII.A would all be subject to the transient test requirement, as they
would clearly have to be substantially redesigned to achieve Tier 4
compliance, regardless of whether or not they use high-efficiency
exhaust emission controls.
The Agency is proposing that engine manufacturers may certify
constant-speed engines using EPA's Constant Speed Variable Load (CSVL)
transient duty cycle \125\ as an alternative to testing these engines
under the NRTC provisions. The CSVL transient cycle more closely
matches the speed and load operating characteristics of many constant-
speed nonroad diesel applications than EPA's proposed NRTC cycle.\126\
However, the manufacturer would be obligated to ensure that such
engines would be used only in constant-speed applications. A more
detailed discussion of the proposed NRTC and CSVL supplemental
transient test cycles and associated provisions is contained in section
VII.F of this preamble and in chapter 4 of the Draft RIA.
---------------------------------------------------------------------------
\125\ Memoranda from Kent Helmer to Cleophas Jackson, ``Speed
and Load Operating Schedule for the Constant Speed Variable Load
(CSVL) transient test cycle'' and ``CSVL Cycle Construction''; and
Southwest Research Institute--Final Report, all in Docket A-2001-28.
\126\ Memorandum from Kent Helmer to Cleophas Jackson, ``Brake-
specific Emissions Impact of Nonroad Diesel Engine Testing Over the
NRTC, AWQ, and AW1 duty cycles'', Docket A-2001-28.
---------------------------------------------------------------------------
2. Cold Start Testing
In the field, the typical nonroad diesel machine will be started
and will warm to a point of heat-stable operation at least once a
workday. Such ``cold start'' conditions may also occur at other times
over the course of the workday, after a lunch break for example. During
these periods of cold start operation, the engine may be emitting at a
higher rate than when the engine is running efficiently at its
stabilized operating temperature. This may be especially the case for
emission control designs employing catalytic devices in the exhaust
system, which require heating to a ``light-off'' temperature to begin
working. EPA's highway engine and vehicle programs, which have resulted
in increasingly widespread use of such catalytic devices, have
recognized and dealt with this concern for several years,
[[Page 28367]]
typically by repeating transient tests in both the ``cold'' and ``hot''
conditions, and weighting emission results in some fashion to create a
combined result for evaluation against emission standards.
We believe that our proposed move to supplemental transient
testing, combined with our proposed Tier 4 standards that will bring
about the use of catalytic devices in nonroad diesel engines, makes it
imperative that we also propose to include such a cold start test as
part of the transient test procedure requirement. We propose to weight
the cold start emission test results as one-tenth of the total with
hot-start emissions accounting for the other nine-tenths. The one-tenth
weighting factor is derived from a review of the present nonroad
equipment population. For more detailed information on this proposal,
refer to section VII.F of this preamble and chapter 4 of the Draft RIA.
EPA requests comment on this approach to ensuring control of cold start
emissions.
D. What Is Being Done To Help Ensure Robust Control in Use?
EPA's goal is to ensure real-world emissions control over the broad
range of in-use operation that can occur, rather than just controlling
emissions over prescribed test cycles executed under restricted
laboratory conditions. An important tool for achieving this in-use
emissions control is the setting of Not-To-Exceed (NTE) emission
standards, which, in this notice, the Agency is proposing to adopt for
new nonroad engines. EPA is also considering two additional means of
in-use emissions control that will be proposed in separate notices.
These are (1) a manufacturer-run in-use emissions test program and (2)
on-board diagnostics (OBD) requirements for new nonroad diesel engines.
When implemented, all three of these will help assure that in-use
emissions control is achieved.
1. Not-to-Exceed Requirements
EPA proposes to adopt not-to-exceed (NTE) emission standards for
all new nonroad diesel engines subject to the Tier 4 emissions
standards beginning in 2011 proposed in section III. B. of this
proposal. EPA already has similar NTE standards set for highway heavy-
duty diesel engines, compression ignition marine engines, and nonroad
spark-ignition engines.
To help ensure that nonroad diesel emissions are controlled over
the wide range of speed and load combinations commonly experienced in-
use, EPA is proposing to apply NTE limits and related test procedures.
The NTE approach establishes an area (the ``NTE zone'') under the
torque curve of an engine where emissions must not exceed a specified
value for any of the regulated pollutants. The NTE standard would apply
under any conditions that could reasonably be expected to be seen by
that engine in normal vehicle operation and use, within certain broad
ranges of real ambient conditions. The NTE requirements would help to
ensure emission benefits over the full range of in-use operating
conditions. EPA believes that basing the emissions standards on a set
of distinct steady state and transient cycles and using the NTE zone to
help ensure in-use control creates a comprehensive program. In
addition, the NTE requirements would also be an effective element of an
in-use testing program. The test procedure is very flexible so it can
represent most in-use operation and ambient conditions. Therefore, the
NTE approach takes all of the benefits of a numerical standard and test
procedure and expands it to cover a broad range of conditions. Also,
with the NTE approach, in-use testing and compliance become much easier
since emissions may be sampled during normal vehicle use. A standard
that relies on laboratory testing over a very specific driving schedule
makes it harder to perform in-use testing, especially for engines,
since the engines would have to be removed from the vehicle. Testing
during normal vehicle use, using an objective numerical standard, makes
enforcement easier and provides more certainty of what is occurring in
use versus a fixed laboratory procedure.
In today's notice, we are proposing an NTE standard which is based
on the approach taken for the 2007 highway heavy-duty diesel engines.
In addition, we are requesting comment on an alternative NTE standard
approach which, while different from the highway NTE standard approach,
is designed to achieve the same environmental objectives. Both of these
approaches are described below.
a. NTE Standards We Are Proposing
The Agency proposes to adopt for new Tier 4 non-road diesel engines
similar NTE specifications as those finalized as part of the heavy-duty
highway diesel engine rulemaking (See 66 FR 5001, January 18, 2001).
These specifications for the highway diesel engines are contained in 40
CFR part 86.007-11 and 40 CFR part 86.1370-2007.
Our NTE proposal for nonroad contains the same basic provisions as
the highway NTE. The proposed nonroad NTE standard establishes an area
(the ``NTE control area'') under the torque curve of an engine where
emissions must not exceed a specified value for any of the regulated
pollutants.\127\ This NTE control area is defined in the same manner as
the highway NTE control areas, and is therefore a subset of the
engine's possible speed and load operating range. The NTE standard
would apply under any engine operating conditions that could reasonably
be expected to be seen by that engine in normal vehicle/equipment
operation and use which occurs within the NTE control zone and which
also occurs during the wide range of real ambient conditions specified
for the NTE. The NTE standard applies to emissions sampled during a
time duration as small as 30 seconds. The NTE standard requirements for
nonroad diesel engines are summarized below and specified in the
proposed regulations at 40 CFR 1309.101 and 40 CFR 1039.515. These
requirements would take effect as early as 2011, as shown in shown in
Table III.D-1. The NTE standard would apply to engines at the time of
certification as well as in use throughout the useful life of the
engine.
---------------------------------------------------------------------------
\127\ Torque is a measure of rotational force. The torque curve
for an engine is determined by an engine ``mapping'' procedure
specified in the Code of Federal Regulations. The intent of the
mapping procedure is to determine the maximum available torque at
all engine speeds. The torque curve is merely a graphical
representation of the maximum torque across all engine speeds.
Table III.D-1.--NTE Standard Implementation Schedule
------------------------------------------------------------------------
NTE
Power category Implementation
model year \a\
------------------------------------------------------------------------
<25 hp................................................ 2013
25-75 hp.............................................. \b\ 2013
[[Page 28368]]
75-175 hp............................................. 2012
175-750 hp............................................ 2011
750 hp..................................... \c\ 2011
------------------------------------------------------------------------
Notes:
\a\ The NTE applies for each power category once Tier 4 standards were
implemented, such that all engines in a given power category are
required to meet NTE standards.
\b\ The NTE standard would apply in 2012 for any engines in the 50-75 hp
range who choose not to comply with the proposed 2008 transitional PM
standard.
\c\ The NTE standard only applies to the 50 percent of the engines in
the 750 hp category which are complying with the proposed
Tier 4 standard. Beginning in 2014 the NTE standard would apply to all
nonroad engines 750 hp when the remaining 50 percent of the
engines must comply with the Tier 4 standard.
The NTE test procedure can be run in nonroad equipment during field
operation or in an emissions testing laboratory using an appropriate
dynamometer. The test itself does not involve a specific operating
cycle of any specific length, rather it involves nonroad equipment
operation of any type which could reasonably be expected to occur in
normal nonroad equipment operation that could occur within the bounds
of the NTE control area. The nonroad equipment (or engine) is operated
under conditions that may reasonably be expected to be encountered in
normal vehicle operation and use, including operation under steady-
state or transient conditions and under varying ambient conditions.
Emissions are averaged over a minimum time of thirty seconds and then
compared to the applicable emission standard. The NTE standard applies
over a wide range of ambient conditions, including up to an altitude of
5,500 feet above-sea level at ambient temperatures as high as 86 deg.
F, and at sea-level up to ambient temperatures as high as 100 deg. F.
The specific temperature and altitude conditions under which the NTE
applies, as well as the proposed methodology for correcting emissions
results for temperature and/or humidity are specified in the proposed
regulations.
In addition, as with the 2007 highway NTE standard, we are
proposing a transition period during which a manufacturer could apply
for an NTE deficiency for a nonroad diesel engine family. The NTE
deficiency provisions would allow the Administrator to accept a nonroad
diesel engine as compliant with the NTE standards even though some
specific requirements are not fully met. We are proposing these NTE
deficiency provisions because we believe that, despite the best efforts
of manufacturers, for the first few model years it is possible some
manufacturers may have technical problems that are limited in nature
but can not be remedied in time to meet production schedules. We are
not limiting the number of NTE deficiencies a manufacturer can apply
for during the first 3 model years for which the NTE applies. For the
fourth through the seventh model year after which the NTE standards are
implemented, a manufacturer could apply for no more than three NTE
deficiencies per engine family. No deficiency may be applied for or
granted after the seventh model year. The NTE deficiency provision will
only be considered for failures to meet the NTE requirements. EPA will
not consider an application for a deficiency for failure to meet the
FTP or supplemental transient standards.
The NTE standards we are proposing are a function of FTP emission
standards contained in this proposal and described in section III.B. As
with the NTE standards we have established for the 2007 highway rule,
we are proposing an NTE standard which is determined as a multiple of
the engine families underlying FTP emission standard. In addition, as
with the 2007 highway standard, the multiple is either 1.25 or 1.5,
depending on the value of the FTP standard (or the engine families
FEL). These multipliers are based on EPA's assessment of the
technological feasibility of the NTE standard, and our assessment that
as the underlying FTP standard becomes more stringent, the NTE
multiplier should increase (from 1.25 to 1.5). The proposed standard or
FEL thresholds for the 1.25x multiplier and the 1.5x multiplier are
specified for each regulated emission in Table III.D-2.
Table III.D-2.--Thresholds for Applying NTE Standard of 1.25xFTP Standard vs. 1.5x FTP Standard
----------------------------------------------------------------------------------------------------------------
Emission Apply 1.25xNTE when . . . Apply 1.5xNTE when . . .
----------------------------------------------------------------------------------------------------------------
NOX.............................. NOX std or FEL >=1.5 g/ NOX std or FEL <1.5 g/bhp-hr
bhp-hr.
NMHC............................. NOX std or FEL >=1.5 g/ NOX std or FEL <1.5 g/bhp-hr
bhp-hr.
NOX+NMHC......................... NMHC+NOX std or FEL >=1.6 NMHC+NOX std or FEL <1.6 g/bhp-hr
g/bhp-hr.
PM.................... PM std or FEL =0.05 g/bhp-hr.
CO............................... All stds or FELs......... No stds or FELs
----------------------------------------------------------------------------------------------------------------
For example, beginning in 2011, the proposed NTE standard for
engines meeting a FTP PM standard of 0.01 g/bhp-hr and a FTP
NOX standard of 0.30 g/bhp-hr would be 0.02 g/bhp-hr PM and
0.45 g/bhp-hr NOX.
In addition, the nonroad NTE proposal specifies a number of
additional engine operating conditions which are not subject to the NTE
standard. Specifically: The NTE does not apply during engine start-up
conditions; the NTE does not apply during very cold engine intake
conditions defined in the proposed regulations for EGR equipped engines
during which the engine may require an engine protection strategy; and,
finally, for engines equipped with an exhaust emission control device
(such as a CDPF or a NOX adsorber), the NTE does not apply
during warm-up conditions for the exhaust emission control device,
specifically the NTE does not apply
[[Page 28369]]
with the exhaust gas temperature on the outlet side of the exhaust
emission control device is less than 250 degrees Celsius.
b. Comment Request on an Alternative NTE Approach
In addition the Agency requests comment on the following set of NTE
specifications as an alternative to those NTE provisions proposed. This
alternative NTE would use the same numeric standard values as under the
proposed NTE standards discussed in section III.D.1a, however, the test
procedure itself is quite different, as described below. The Agency
believes that these alternative specifications and the range of
operation covered by the standard would provide for similar, if not
more robust nonroad engine compliance compared to the application of
the proposed NTE specifications to nonroad engines. These alternative
provisions have been developed to emphasize compliance over all engine
operation, including engine operation that would not be covered under
the proposed NTE approach. In addition these specifications were
developed specifically to simplify on-vehicle testing for NTE
compliance. The NTE control area would include all engine operation.
The averaging intervals over which NTE standards must be met are
different than the 30-second minimum set in the proposal. They are
variable in time but are constant as a function of work. Emissions
would be measured over a constant averaging work interval, determined
as ten percent (10%) of the total work performed by the engine over a
specified period of time (e.g., a minimum of six hours of operation).
This 10% window of work ``moves'' through data at one percent (1%)
increments so as to always return about ninety (90) individual data
points for direct comparison to the NTE standards.
Comments should address the potential exclusive use of these
alternative provisions for nonroad diesel engine NTE compliance. For
more detailed information on these alternative NTE provisions, refer to
Preamble section VIIG ``Not-to-Exceed Requirements'' and chapter 4 of
the draft RIA of this proposal.
2. Plans for a Future In-Use Testing and Onboard Diagnostics
In addition to the proposals in this notice, EPA is currently
reviewing several related regulatory provisions concerning control of
emissions from nonroad diesel engines. They are not included in this
proposal, as EPA believes these aspects of an effective emission
control program would benefit from further evaluation and development
prior to their proposal. EPA intends to explore these provisions
further in the coming months and publish a separate notice of proposed
rulemaking dealing with these issues. In particular, there are two
issues which will be discussed: (1) A manufacturer-run in-use emissions
testing program; and (2) OBD requirements for nonroad diesel engines.
The Agency believes that it is appropriate to proceed with the current
rulemaking, expecting that these two issues will be proposed in the
near future. EPA expects these programs would be adopted in advance of
the effective date of the engine emissions standards. This will allow
us to gather information and work with interested parties in a separate
process regarding these issues. EPA will work with all parties
involved, including states, environmental organizations and
manufacturers, to develop robust, creative, environmentally protective
and cost-effective proposals addressing these issues.
a. Plans for a Future Manufacturer-Run In-Use Test Program
It is critical that nonroad diesel engines meet the applicable
emission standards throughout their useful lives, to sustain those
emission benefits over the broadest range of in-use operating
conditions. The Agency believes that a manufacturer-run in-use testing
program that is designed to generate data on in-use emissions of
nonroad diesel engines can be used by EPA and the engine manufacturers
to ensure that emissions standards are met throughout the useful life
of the engines, under conditions normally experienced in-use. An
effective program can be designed to monitor for NTE compliance and to
help ensure overall compliance with emission standards.
The Agency expects to pattern the manufacturer-run in-use testing
requirements for nonroad diesel engines after a program that is being
developed for heavy-duty highway vehicles. In this latter program, EPA
is committed to incorporating a two-year pilot program. The pilot
program will allow the Agency and manufacturers to gain the necessary
experience with the in-use testing protocols and generation of in-use
test data using portable emission measurement devices prior to fully
implementing program. A similar pilot program is expected to be part of
any manufacturer-run in-use NTE test program for nonroad engines.
The Agency plans to promulgate the in-use testing requirements for
heavy-duty highway vehicles in the December 2004 time frame. EPA
anticipates proposing a manufacturer-run in-use testing program for
nonroad diesel engines by 2005 or earlier. As mentioned above, the
nonroad diesel engine program is expected to be patterned after the
heavy-duty highway program.
b. Onboard Diagnostics
Today's notice does not propose to require onboard diagnostic (OBD)
systems for non-road diesel vehicles and engines. However, EPA has
committed to creating OBD requirements for heavy-duty highway engines/
vehicles over 14,000 lbs GVWR and will develop OBD requirements for
nonoad in conjunction with or following the highway OBD development.
The Agency will propose nonroad diesel OBD requirements, along with
heavy-duty highway OBD requirements, because OBD is necessary for
maintaining and ensuring compliance with emission standards over the
lifetime of engines. We will gather further information and coordinate
with the heavy-duty highway and nonroad diesel industry and other
stakeholders to develop proposed OBD system requirements.
E. Are the Proposed New Standards Feasible?
Prior to 1990, diesel engines could be broadly grouped into two
categories; indirect-injection (IDI) diesel engines that were
relatively inexpensive while providing somewhat better fuel economy
compared to gasoline engines, and direct-injection (DI) diesel engines
that were substantially more expensive but which offered better fuel
economy. The majority of diesel engines fell into the first category,
especially in the case of passenger cars, smaller heavy-duty trucks and
most nonroad engines below 200 horsepower.
Diesel engine technology has changed rapidly since the early 1990s
with the widespread use of electronics, onboard computers and the rise
to preeminence of turbocharged direct-injection diesel engines. While
some IDI engines remain, especially in the low horsepower portion of
the nonroad market, most new diesel engines (including higher
horsepower nonroad diesel engines) are turbocharged and direct-
injected. Today's diesel engine has significantly improved, compared to
historic engines with regard to issues of most concern to the user
including noise, vibration, visible smoke emissions, startability, and
performance. At the same time environmental benefits have also been
realized with lower NOX emissions, lower PM emissions, and
improving fuel economy. These changes have been most pronounced for
smaller
[[Page 28370]]
diesel engines applied in passenger cars and light-heavy trucks.
Acceptance of the technology by the public, especially in Europe, has
lead to a rapid increase in diesel use for smaller vehicles with diesel
sales for passenger cars exceeding 50 percent in some countries.
At the end of the 1990s continuing concern regarding the serious
risk to public health and welfare from diesel emissions and the
emergence of new emission control technologies enabled by low sulfur
fuels led policy makers to set new future diesel fuel specifications
and to set challenging new diesel emission standards for highway
vehicles. In the United States, the EPA has set stringent new diesel
emission standards for heavy-duty highway engines which will go into
effect in 2007. These new standards are predicated on the use of
Catalyzed Diesel Particulate Filters (CDPFs) which when used with less
than 15ppm sulfur diesel fuel can reduce PM emissions by well over 90%,
and on the use of NOX adsorber catalyst technology which
when used with less than 15 ppm diesel fuel can reduce NOX
emissions by more than 90%. When these technologies are fully
implemented, the resulting diesel engine emissions will be 98% lower
than the levels common to these diesel engines before 1990.
EPA has been conducting an ongoing technology progress review to
measure industry progress to develop and introduce the needed clean
fuel and clean engine technologies by 2007. The first in what will be a
series of reports was published by EPA in June of 2002.\128\ In the
report, we concluded that technology developments by industry were
progressing rapidly and that the necessary catalyzed diesel particulate
filter and NOX adsorber technologies would be available for
use by 2007.
---------------------------------------------------------------------------
\128\ Highway Diesel Progress Review, United States
Environmental Protection Agency, June 2002, EPA 420-R-02-016. Copy
available in EPA Air Docket A-2001-28.
---------------------------------------------------------------------------
Nonroad diesel engines are fundamentally similar to highway diesel
engines. As noted above in section III.B, in many cases, virtually
identical engines are certified and sold for use in highway vehicles
and nonroad equipment. Thus, emission control technologies developed
for diesel engines can in general be applied to both highway and
nonroad engines giving appropriate considerations to unique aspects of
each application.
Today, we are proposing to set stringent new standards for a broad
category of nonroad diesel engines. At the same time we are proposing
to dramatically lower the sulfur level in nonroad diesel fuel
ultimately to 15 ppm. We believe these standards are feasible given the
availability of the clean 15 ppm sulfur fuel and the rapid progress to
develop the needed emission control technologies. We acknowledge that
these standards will be challenging for industry to meet in part due to
differences in operating conditions and duty cycles for nonroad diesel
engines. Also, we recognize that transferring and effectively applying
these technologies, which have largely been developed for highway
engines, will require additional lead time. We have given consideration
to these issues in determining the appropriate timing and emission
levels for the standards proposed today.
The following sections will discuss how these technologies work,
issues specific to the application of these technologies to new nonroad
engines, and why we believe that the emission standards proposed here
are feasible. A more in-depth discussion of these technologies can be
found in the draft RIA associated with this proposal, in the final RIA
for the HD2007 emission standards and in the recently completed 2002
Highway Diesel Progress Review.\129\ The following discussion
summarizes the more detailed discussion found in the Draft RIA.
---------------------------------------------------------------------------
\129\ Highway Diesel Progress Review, United States
Environmental Protection Agency, June 2002, EPA 420-R-02-016. Copy
available in EPA Air Docket A-2001-28.
---------------------------------------------------------------------------
1. Technologies To Control NOX and PM Emissions From Mobile
Source Diesel Engines
Present mobile source rules control the emissions of non-methane
hydrocarbons (NMHC), oxides of nitrogen (NOX), carbon
monoxide (CO), air toxics and particulate matter (PM) from diesel
engines. Of these, PM and NOX emissions are typically the
most difficult to control. CO and NMHC emissions are inherently low
from diesel engines and under most conditions can be controlled to low
levels without difficulty. NMHC emissions also serve as a proxy for
some of the air toxic emissions from these engines, since many air
toxics are a component of NMHC and are typically reduced in proportion
to NMHC reductions. Most diesel engine emission control technologies
are designed to reduce PM and NOX emissions without
increasing CO and NMHC emissions above the already low diesel levels.
Technologies to control PM and NOX emissions are described
below separately. We also discuss the potential for these technologies
to decrease CO and NMHC emissions as well as their potential to reduce
emissions of air toxics.
a. PM Control Technologies
Particulate matter from diesel engines is made of three components;
[sbull] Solid carbon soot,
[sbull] Volatile and semi-volatile organic matter, and
[sbull] Sulfate.
The formation of the solid carbon soot portion of PM is inherent in
diesel engines due to the heterogenous distribution of fuel and air in
a diesel combustion system. Diesel combustion is designed to allow for
overall lean (excess oxygen) combustion giving good efficiencies and
low CO and HC emissions with a small region of rich (excess fuel)
combustion within the fuel injection plume. It is within this excess
fuel region of the combustion that PM is formed when high temperatures
and a lack of oxygen cause the fuel to pyrolize, forming soot. Much of
the soot formed in the engine is burned during the combustion process
as the soot is mixed with oxygen in the cylinder at high temperatures.
Any soot that is not fully burned before the exhaust valve is opened
will be emitted form the engine as diesel PM.
The soot portion of PM emissions can be reduced by increasing the
availability of oxygen within the cylinder for soot oxidation during
combustion. Oxygen can be made more available by either increasing the
oxygen content in-cylinder or by increasing the mixing of the fuel and
oxygen in-cylinder. A number of technologies exist that can influence
oxygen content and in-cylinder mixing including, improved fuel
injection systems, air management systems, and combustion system
designs.\130\ Many of these PM reducing technologies offer better
control of combustion in general, and better utilization of fuel
allowing for
[[Page 28371]]
improvements in fuel efficiency concurrent with reductions in PM
emissions. Improvements in combustion technologies and refinements of
these systems is an ongoing effort for highway engines and for some
nonroad engines where emission standards or high fuel use encourage
their introduction. The application of better combustion system
technologies across the broad range of nonroad engines in order to meet
the new emission standards proposed here offers an opportunity for
significant reductions in engine-out PM emissions and possibly for
reductions in fuel consumption. The soot portion of PM can be reduced
further with aftertreatment technologies as discussed later in this
section.
---------------------------------------------------------------------------
\130\ The most effective means to reduce the soot portion of
diesel PM engine-out is to operate the diesel engine with a
homogenous method of operation rather than the typical heterogenous
operation. In homogenous combustion, also called premixed
combustion, the fuel is dispersed evenly with the air throughout the
combustion system. This means there are no fuel rich/oxygen deprived
regions of the system where fuel can be pyrolized rather than
burned. Gasoline engines are typically premixed combustion engines.
Homogenous combustion is possible with a diesel engine under certain
circumstances, and is used in limited portions of engine operation
by some engine manufacturers. Unfortunately, homogenous diesel
combustion is not possible for most operation in today's diesel
engine. We believe that more manufacturers will utilize this means
to control diesel emissions within the limitations of the
technology. A more in-depth discussion of homogenous diesel
combustion can be found in the draft RIA.
---------------------------------------------------------------------------
The volatile and semi-volatile organic material in diesel PM is
often simply referred to as the soluble organic fraction (SOF) in
reference to a test method used to measure its level. SOF is primarily
composed of engine oil which passes through the engine with no or only
partial oxidation and which condenses in the atmosphere to form PM. The
SOF portion of diesel PM can be reduced through reductions in engine
oil consumption and through oxidation of the SOF catalytically in the
exhaust.
The sulfate portion of diesel PM is formed from sulfur present in
diesel fuel and engine lubricating oil that oxidizes to form sulfuric
acid (H2SO4) and then condenses in the atmosphere
to form sulfate PM. Approximately two percent of the sulfur that enters
a diesel engine from the fuel is emitted directly from the engine as
sulfate PM.\131\ The balance of the sulfur content is emitted from the
engine as SO2. Oxidation catalyst technologies applied to
control the SOF and soot portions of diesel PM can inadvertently
oxidize SO2 in the exhaust to form sulfate PM. The oxidation
of SO2 by oxidation catalysts to form sulfate PM is often
called sulfate make. Without low sulfur diesel fuel, oxidation catalyst
technology to control diesel PM is limited by the formation of sulfate
PM in the exhaust as discussed in more detail in Section III.F below.
---------------------------------------------------------------------------
\131\ Exhaust and Crankcase Emission Factors for Nonroad Engine
Modeling--Compression-Ignition, EPA420-P-02-016, NR-009B. Copy
available in EPA Air Docket A-2001-28.
---------------------------------------------------------------------------
There are two common forms of exhaust aftertreatment designed to
reduce diesel PM, the diesel oxidation catalyst (DOC) and the diesel
particulate filter (DPF). DOCs reduce diesel PM by oxidizing a small
fraction of the soot emissions and a significant portion of the SOF
emissions. Total DOC effectiveness to reduce PM emissions is normally
limited to approximately 30 percent because the SOF portion of diesel
PM for modern diesel engines is typically less than 30 percent and
because the DOC increases sulfate emissions reducing the overall
effectiveness of the catalyst. Limiting fuel sulfur levels to 15 ppm,
as we have proposed today, allows DOCs to be designed for maximum
effectiveness (nearly 100% control of SOF with highly active catalyst
technologies) since their control effectiveness is not reduced by
sulfate make (i.e., there sulfate make rate is high but because the
sulfur level in the fuel is low the resulting PM emissions are well
controlled). A reduction in diesel fuel sulfur to 500 ppm as we are
proposing today, is also directionally helpful for the application of
DOCs. While 500 ppm sulfur fuel will not make the full range of highly
active catalyst technologies available to manufacturers, it will
decrease the amount of sulfate make and may allow for slightly more
active (i.e., effective) catalysts to be used. We believe that this is
an additional benefit of the proposed 500 ppm sulfur fuel program. DOCs
are also very effective at reducing the air toxic emissions from diesel
engines. Test data shows that emissions of toxics such as polycyclic
aromatic hydrocarbons (PAHs) can be reduced by more than 80 percent
with a DOC.\132\ DOCs also significantly reduce (by more than 80
percent) the already low HC and CO emissions of diesel engines.\133\
DOCs are ineffective at controlling the solid carbon soot portion of
PM. Therefore, even with 15 ppm sulfur fuel DOCs would not be able to
achieve the level of PM control needed to meet the standard proposed
today.
---------------------------------------------------------------------------
\132\ ``Demonstration of Advanced Emission Control Technologies
Enabling Diesel-Powered Heavy-Duty Engines to Achieve Low Emission
Levels'', Manufacturers of Emission Controls Association, June 1999.
Air Docket A-2001-28.
\133\ ``Demonstration of Advanced Emission Control Technologies
Enabling Diesel-Powered Heavy-Duty Engines to Achieve Low Emission
Levels'', Manufacturers of Emission Controls Association, June 1999.
Air Docket A-2001-28.
---------------------------------------------------------------------------
DPFs control diesel PM by capturing the soot portion of PM in a
filter media, typically a ceramic wall flow substrate, and then by
oxidizing (burning) it in the oxygen-rich atmosphere of diesel exhaust.
The SOF portion of diesel PM can be controlled through the addition of
catalytic materials to the DPF to form a catalyzed diesel particulate
filter (CDPF).\134\ The catalytic material is also very effective to
promote soot burning. This burning off of collected PM is referred to
as ``regeneration.'' In aggregate over an extended period of operation,
the PM must be regenerated at a rate equal to or greater that its
accumulation rate, or the DPF will clog. For a non-catalyzed DPF the
soot can regenerate only at very high temperatures, in excess of
600[deg]C, a temperature range which is infrequently realized in normal
diesel engine operation (for many engines exhaust temperatures may
never reach 600[deg]C). With the addition of a catalytic coating to
make a CDPF, the temperature necessary to ensure regeneration is
decreased significantly to approximately 250[deg]C, a temperature
within the normal operating range for most diesel engines.\135\
---------------------------------------------------------------------------
\134\ With regard to gaseous emissions such as NMHCs and CO, the
CDPF works in the same manner with similar effectiveness as the DOC
(i.e., NMHC and CO emissions are reduced by more than 80 percent).
\135\ Engelhard DPX catalyzed diesel particulate filter retrofit
verification, www.epa.gov/otaq/retrofit/techlist-engelhard.htm, a
copy of this information is available in Air Docket A-2001-28.
---------------------------------------------------------------------------
However, the catalytic materials that most effectively promote soot
and SOF oxidation are significantly impacted by sulfur in diesel fuel.
Sulfur both degrades catalyst oxidation efficiency (i.e. poisons the
catalyst) and forms sulfate PM. Both catalyst poisoning by sulfur and
increases in PM emissions due to sulfate make influence our decision to
limit the sulfur level of diesel fuel to 15 ppm as discussed in greater
detail in section III.F.
Filter regeneration is affected by catalytic materials used to
promote oxidation, sulfur in diesel fuel, engine-out soot rates, and
exhaust temperatures. At higher exhaust temperatures soot oxidation
occurs at a higher rate. Catalytic materials accelerate soot oxidation
at a single exhaust temperature compared to non-catalyst DPFs, but even
with catalytic materials increasing the exhaust temperature further
accelerates soot oxidation.
Having applied 15 ppm sulfur diesel fuel and the best catalyst
technology to promote low temperature oxidation (regeneration), the
regeneration balance of soot oxidation equal to or greater than soot
accumulation over aggregate operation simplifies to: are the exhaust
temperatures high enough on aggregate to oxidize the engine-out PM
rate? \136\ The answer is yes, for most highway applications and many
nonroad applications, as demonstrated by the widespread success of
retrofit CDPF systems for nonroad equipment and the
[[Page 28372]]
use of both retrofit and original equipment CDPF systems for highway
vehicles.137 138 139 However, it is possible that for some
nonroad applications the engine-out PM rate may exceed the soot
oxidation rate, even with low sulfur diesel fuel and the best catalyst
technologies. Should this occur, successful regeneration requires that
either engine-out PM rates be decreased or exhaust temperatures be
increased, both feasible strategies. In fact, we expect both to occur
as highway based technologies are transferred to nonroad engines. As
discussed earlier, engine technologies to lower PM emissions while
improving fuel consumption are continuously being developed and
refined. As these technologies are applied to nonroad engines driven by
both new emission standards and market pressures for better products,
engine-out PM rates will decrease. Similarly, techniques to raise
exhaust temperatures periodically in order to initiate soot oxidation
in a PM filter have been developed for highway diesel vehicles as
typified by the PSA system used on more than 400,000 vehicles in
Europe.140 141
---------------------------------------------------------------------------
\136\ If the question was asked, ``without 15 ppm sulfur fuel
and the best catalyst technology, are the exhaust temperatures high
enough on aggregate to oxidize the engine-out PM rate?'' the answer
would be no, for all but a very few nonroad or highway diesel
engines.
\137\ ``Particulate Traps for Construction Machines, Properties
and Field Experience,'' 2000, SAE 2000-01-1923.
\138\ Letter from Dr. Barry Cooper, Johnson Matthey, to Don
Kopinski, U.S. EPA. Copy available in EPA Air Docket A-2001-28.
\139\ EPA Recognizes Green Diesel Technology Vehicles at
Washington Ceremony, Press Release from International Truck and
Engine Company, July 27, 2001. Copy available in EPA Air Docket A-
2001-28.
\140\ There is one important distinction between the current PSA
system and the kind of system that we project industry will use to
comply with the Tier 4 standards. The PSA system incorporates a
cerium fuel additive to help promote soot oxidation. The additive
serves a similar function to a catalyst to promote soot oxidation at
lower temperatures. Even with the use of the fuel additive passive
regeneration is not realized on the PSA system and an active
regeneration is conducted periodically involving late cycle fuel
injection and oxidation of the fuel on an up-front diesel oxidation
catalyst to raise exhaust temperatures. This form of supplemental
heating to ensure infrequent but periodic PM filter regeneration has
proven to be robust and reliable for more than 400,000 PSA vehicles.
Our 2002 progress review found that other manufacturers will be
introducing similar systems in the next few years without the use of
a fuel additive.
\141\ Nino, S. and Lagarrigue, M. ``French Perspective on Diesel
Engines and Emissions,'' presentation at the 2002 Diesel Engine
Emission Reduction workshop in San Diego, California, Air Docket A-
2001-28.
---------------------------------------------------------------------------
During our 2002 Highway Diesel Progress Review, we investigated the
plans of highway engine manufacturers to use CDPF systems to comply
with the HD2007 emission standards for PM. We learned that all diesel
engine manufacturers intend to comply through the application of CDPF
system technology. We also learned that the manufacturers are
developing means to raise the exhaust temperature, if necessary, to
ensure that CDPF regeneration occurs.\142\ These technologies include
modifications to fuel injection strategies, modifications to EGR
strategies, and modifications to turbocharger control strategies. These
systems are based upon the technologies used by the engine
manufacturers to comply with the 2004 highway emission standards. In
general, the systems anticipated to be used by highway manufacturers to
meet the 2004 emission standards are the same technologies that engine
manufacturers have indicated to EPA that they will use to comply with
the Tier 3 nonroad regulations (e.g., electronic fuel systems).\143\ In
a manner similar to highway engine manufacturers, we expect nonroad
engine manufacturers to adapt their Tier 3 emission control
technologies to provide back-up regeneration systems for CDPF
technologies in order to comply with the standards we are proposing
today. We have estimated costs for such systems in our cost analysis.
---------------------------------------------------------------------------
\142\ Highway Diesel Progress Review, United States
Environmental Protection Agency, June 2002, EPA 420-R-02-016. Copy
available in EPA Air Docket A-2001-28.
\143\ ``Nonroad Diesel Emissions Standards Staff Technical
Paper'', EPA420-R-01-052, October 2001. Copy available in EPA Air
Docket A-2001-28.
---------------------------------------------------------------------------
Emission levels from CDPFs are determined by a number of factors.
Filtering efficiencies for solid particle emissions like soot are
determined by the characteristics of the PM filter, including wall
thickness and pore size. Filtering efficiencies for diesel soot can be
99 percent with the appropriate filter design.\144\ Given an
appropriate PM filter design the contribution of the soot portion of PM
to the total PM emissions are negligible (less than 0.001 g/bhp-hr).
This level of soot emission control is not dependent on engine test
cycle or operating conditions due to the mechanical filtration
characteristics of the particulate filter.
---------------------------------------------------------------------------
\144\ Miller, R. et. al, ``Design, Development and Performance
of a Composite Diesel Particulate Filter,'' March 2002, SAE 2002-01-
0323.
---------------------------------------------------------------------------
Control of the SOF portion of diesel soot is accomplished on a CDPF
through catalytic oxidation. The SOF portion of diesel PM consists of
primarily gas phase hydrocarbons in engine exhaust due to the high
temperatures and only forms particulate in the environment when it
condenses. Catalytic materials applied to CDPFs can oxidize a
substantial fraction of the SOF in diesel PM just as the SOF portion
would be oxidized by a DOC. However, we believe that for engines with
very high SOF emissions the emission rate may be higher than can be
handled by a conventionally sized catalyst resulting in higher than
zero SOF emissions. If a manufacturer's base engine technology has high
oil consumption rates, and therefore high engine-out SOF emissions
(i.e., higher than 0.04 g/bhp-hr), compliance with the 0.01 g/bhp-hr
emission standard proposed today may require additional technology
beyond the application of a CDPF system alone.\145\
---------------------------------------------------------------------------
\145\ SOF oxidation efficiency is typically better than 80
percent and can be better than 90 percent. Given a base engine SOF
rate of 0.04 g/bhp-hr and an 80 percent SOF reduction a tailpipe
emission of 0.008 can be estimated from SOF alone. This level may be
too high to comply with a 0.01 g/bhp-hr standard once the other
constituents of diesel PM (soot and sulfate) are added. In this
case, SOF emissions will need to be reduced engine-out or SOF
control greater than 90 percent will need to be realized by the
CDPF.
---------------------------------------------------------------------------
Modern highway diesel engines have controlled SOF emission rates in
order to comply with the existing 0.1 g/bhp-hr emission standards. For
modern highway diesel engines, the SOF portion of PM is typically on a
small fraction of the total PM emissions (less than 0.02 g/bhp-hr).
This level of SOF control is accomplished by controlling oil
consumption through the use of engine modifications (e.g., piston ring
design, the use of 4-valve heads, the use of valve stem seals,
etc.).\146\ Nonroad diesel engines may similarly need to control
engine-out SOF emissions in order to comply with the standard proposed
today. The means to control engine-out SOF emissions are well known and
have additional benefits, as they decrease oil consumption reducing
operating costs. With good engine-out SOF control (i.e., engine-out SOF
< 0.02 g/bhp-hr) and the application of catalytic material to the DPF,
SOF emissions from CDPF equipped nonroad engines will contribute only a
very small fraction of the total tailpipe PM emissions (less than 0.004
g/bhp-hr). Alternatively, it may be less expensive or more practical
for some applications to ensure that the SOF control realized by the
CDPF is in excess of 90 percent, thereby allowing for higher engine-out
SOF emission levels.
---------------------------------------------------------------------------
\146\ Hori, S. and Narusawa, K. ``Fuel Composition Effects on
SOF and PAH Exhaust Emissions from DI Diesel Engines,'' SAE 980507.
---------------------------------------------------------------------------
The best means to reduce sulfate emissions from diesel engines is
by reducing the sulfur content of diesel fuel and lubricating oils.
This is one of the reasons that we have proposed today to limit nonroad
diesel fuel sulfur levels to be 15ppm or less. The catalytic material
on the CDPF is crucial to
[[Page 28373]]
ensuring robust regeneration and high SOF oxidation; however, it can
also oxidize the sulfate in the exhaust with high efficiency. The
result is that the predominant form of PM emissions from CDPF equipped
diesel engines is sulfate PM. Even with 15ppm sulfur diesel fuel a CDPF
equipped diesel engine can have total PM emissions including sulfate
emissions as high as 0.009 g/bhp-hr over some representative operating
cycles using conventional diesel engine oils.\147\ Although this level
of emissions will allow for compliance with our proposed PM emissions
standard of 0.01 g/bhp-hr, we believe that there is room for reductions
from this level in order to provide engine manufacturers with
additional compliance margin. During our 2002 Highway Progress Review,
we learned that a number of engine lubricating oil companies are
working to reduce the sulfur content in engine lubricating oils. Any
reduction in the sulfur level of engine lubricating oils will be
beneficial. Similarly, as discussed above, we expect engine
manufacturers to reduce engine oil consumption in order to reduce SOF
emissions and secondarily to reduce sulfate PM emissions. While we
believe that sulfate PM emissions will be the single largest source of
the total PM from diesel engines, we believe with the combination of
technology, and the appropriate control of engine-out PM, that sulfate
and total PM emissions will be low enough to allow compliance with a
0.01 g/bhp-hr standard, except in the case of small engines with higher
fuel consumption rates as described later in this section.
---------------------------------------------------------------------------
\147\ See Table III.F.1 below.
---------------------------------------------------------------------------
CDPFs have been shown to be very effective at reducing PM mass by
reducing dramatically the soot and SOF portions of diesel PM. In
addition, recent data show that they are also very effective at
reducing the overall number of emitted particles when operated on low
sulfur fuel. Hawker, et. al., found that a CDPF reduced particle count
by over 95 percent, including some of the smallest measurable particles
(< 50 nm), at most of the tested conditions. The lowest observed
efficiency in reducing particle number was 86 percent. No generation of
particles by the CDPF was observed under any tested conditions.\148\
Kittelson, et al., confirmed that ultrafine particles can be reduced by
a factor of ten by oxidizing volatile organics, and by an additional
factor of ten by reducing sulfur in the fuel. Catalyzed PM traps
efficiently oxidize nearly all of the volatile organic PM precursors
(i.e. SOF), and the reduction of diesel fuel sulfur levels to 15ppm or
less will substantially reduce the number of ultrafine PM emitted from
diesel engines. The combination of CDPFs with low sulfur fuel is
expected to result in very large reductions in both PM mass and the
number of ultrafine particles.
---------------------------------------------------------------------------
\148\ Hawker, P., et al., Effect of a Continuously Regenerating
Diesel Particulate Filter on Non-Regulated Emissions and Particle
Size Distribution, SAE 980189.
---------------------------------------------------------------------------
As described here, the range of technologies available to reduce PM
emissions is broad, extending from improvements to existing combustion
system technologies to oxidation catalyst technologies to complete CDPF
systems. The CDPF technology along with 15ppm or less sulfur diesel
fuel is the system that we believe will allow engine manufacturers to
comply with the 0.01 g/bhp-hr PM standard that we have proposed for a
wide range of nonroad diesel engines. While it may be possible to apply
CDPFs across the full range of nonroad diesel engine sizes, the
complexity of full diesel particulate filter systems makes application
to the smallest range of diesel engines difficult to accurately
forecast at this time. As described in the following sections, the
Agency has given consideration to the engineering complexity, cost and
packaging of these systems in setting emission standards for various
nonroad engine power categories.
b. NOX Control Technologies
Oxides of nitrogen (NO and NO2, collectively called
NOX) are formed at high temperatures during the combustion
process from nitrogen and oxygen present in the intake air. The
NOX formation rate is exponentially related to peak cylinder
temperatures and is also strongly related to nitrogen and oxygen
content (partial pressures). NOX control technologies for
diesel engines have focused on reducing emissions by lowering the peak
cylinder temperatures and by decreasing the oxygen content of the
intake air. A number of technologies have been developed to accomplish
these objectives including fuel injection timing retard, fuel injection
rate control, charge air cooling, exhaust gas recirculation (EGR) and
cooled EGR. The use of these technologies can result in significant
reductions in NOX emissions, but are limited due to
practical and physical constraints of heterogeneous diesel
combustion.149 150
---------------------------------------------------------------------------
\149\ Flynn, P. et al, ``Minimum Engine Flame Temperature
Impacts on Diesel and Spark-Ignition Engine NOX
Production,'' SAE 2000-01-1177, March 2000.
\150\ Dickey, D. et al, ``NOX Control in Heavy-Duty
Diesel Engines--What is the Limit?,'' SAE 980174, February 1998.
---------------------------------------------------------------------------
EPA is investigating strategies to address these limitations of
heterogenous diesel combustion in a research program. This concept
consists of higher intake charge boost levels using a low-pressure loop
cooled EGR system, combined with a proprietary fuel injection and
combustion system to control engine-out NOX.\151\ The
results from prototype laboratory research engines show NOX
control consistent with the standards proposed today. The technology
must still overcome the limitations of increased PM emissions at low
NOX levels as well as other practical considerations of
performance and durability. EPA intends to continue investigating this
technology, but at this time cannot project that this technology would
be generally available for use in compliance with the proposed
standards.
---------------------------------------------------------------------------
\151\ Gray, Charles ``Assessing New Diesel Technologies,''
November 2002, MIT Light Duty Diesel Workshop, available on MIT's
website or in Air Docket A-2001-28. http://web.mit.edu/chrisng/www/
dieselworkshop--files/Charles%20Gray.PDF.
---------------------------------------------------------------------------
A new form of diesel engine combustion, commonly referred to as
homogenous diesel combustion or premixed diesel combustion, can give
very low NOX emissions over a limited range of diesel engine
operation. In the regions of diesel engine operation over which this
combustion technology is feasible (light load conditions),
NOX emissions can be reduced enough to comply with the 0.3
g/bhp-hr NOX emission standard that we have proposed
today.\152\ Some engine manufacturers are today producing engines which
utilize this technology over a narrow range of engine operation.\153\
Unfortunately, it is not possible today to apply this technology over
the full range of diesel engine operation. We do believe that more
engine manufacturers will utilize this alternative combustion approach
in the limited range over which it is effective, but will have to rely
on conventional heterogenous diesel combustion for the bulk of engine
operation. Therefore, we believe that catalytic NOX emission
control technologies will be required in order to realize the
NOX emission standards proposed today. Catalytic emission
control technologies can extend the reduction of NOX
emissions
[[Page 28374]]
by an additional 90 percent or more over conventional ``engine-out''
control technologies alone.
---------------------------------------------------------------------------
\152\ Stanglmaier, Rudolf and Roberts, Charles ``Homogenous
Charge Compression Ignition (HCCI): Benefits, Compromises, and
Future Engine Applications''. SAE 1999-01-3682.
\153\ Kimura, Shuji, et al., ``Ultra-Clean Combustion Technology
Combining a Low-Temperature and Premixed Combustion Concept for
Meeting Future Emission Standards'', SAE 2001-01-0200.
---------------------------------------------------------------------------
NOX emissions from gasoline-powered vehicles are
controlled to extremely low levels through the use of the three-way
catalyst technology first introduced in the 1970s. Three-way-catalyst
technology is very efficient in the stoichiometric conditions found in
the exhaust of properly controlled gasoline-powered vehicles. Today, an
advancement upon this well-developed three-way catalyst technology, the
NOX adsorber, has shown that it too can make possible
extremely low NOX emissions from lean-burn engines such as
diesel engines.\154\ The potential of the NOX adsorber
catalyst is limited only by its need for careful integration with the
engine and engine control system (as was done for three-way catalyst
equipped passenger cars in the 1980s and 1990s) and by poisoning of the
catalyst from sulfur in the fuel. The Agency set stringent new
NOX standards for highway diesel engines beginning in 2007
predicated upon the use of the NOX adsorber catalyst enabled
by significant reductions in fuel sulfur levels (15 ppm sulfur or
less). In today's action, we are proposing similarly stringent
NOX emission standards for nonroad engines again using
technology enabled by a reduction in fuel sulfur levels.
---------------------------------------------------------------------------
\154\ NOX adsorber catalysts are also called,
NOX storage catalysts (NSCs), NOX storage and
reduction catalysts (NSRs), and NOX traps.
---------------------------------------------------------------------------
NOX adsorbers work to control NOX emissions
by storing NOX on the surface of the catalyst during the
lean engine operation typical of diesel engines. The adsorber then
undergoes subsequent brief rich regeneration events where the
NOX is released and reduced across precious metal catalysts.
The NOX storage period can be as short as 15 seconds and as
along as 10 minutes depending upon engine-out NOX emission
rates and exhaust temperature. A number of methods have been developed
to accomplish the necessary brief rich exhaust conditions necessary to
regenerate the NOX adsorber technology including late-cycle
fuel injection, also called post injection, in exhaust fuel injection,
and dual bed technologies with off-line
regeneration.155 156 157 This method for NOX
control has been shown to be highly effective when applied to diesel
engines but has a number of technical challenges associated with it.
Primary among these is sulfur poisoning of the catalyst as described in
section III.F below. In the HD2007 RIA we identified four issues
related to NOX adsorber performance: performance of the
catalyst across a broad range of exhaust temperatures, thermal
durability of the catalyst when regenerated to remove sulfur
(desulfated), management of sulfur poisoning, and system integration on
a vehicle. In the HD 2007 RIA, we provided a description of the
technology paths that we believed manufacturers would use to address
these challenges. We are conducting an ongoing review of industry's
progress to overcome these challenges and have updated our analysis of
the progress to address these issues in the draft RIA associated with
today's NPRM.
---------------------------------------------------------------------------
\155\ Johnson, T. ``Diesel Emission Control in Review--the Last
12 Months,'' SAE 2003-01-0039.
\156\ Koichiro Nakatani, Shinya Hirota, Shinichi Takeshima,
Kazuhiro Itoh, Toshiaki Tanaka, and Kazuhiko Dohmae, ``Simultaneous
PM and NOX Reduction System for Diesel Engines.'', SAE
2002-01-0957, SAE Congress March 2002.
\157\ Schenk, C., McDonald, J. and Olson, B. ``High Efficiency
NOX and PM Exhaust Emission Control for Heavy-Duty On-
Highway Diesel Engines,'' SAE 2001-01-1351.
---------------------------------------------------------------------------
One of the areas that we have identified as needing improvement for
the NOX adsorber catalyst is performance at low and high
exhaust temperatures. NOX adsorber performance is limited at
very high temperatures (due to thermal release of NOX under
lean conditions) and very low temperatures (due to poor catalytic
activity for NO oxidation under lean conditions and low activity for
NOX reduction under rich conditions) as described
extensively in the draft RIA. Our review of highway HD2007 technologies
showed that significant progress has been made to broaden the
temperature range of effective NOX control of the
NOX adsorber catalysts (the temperature ``window'' of the
catalyst). Every catalyst development company that we visited was able
to show us new catalyst formulations with improved performance at both
high and low temperatures. Similarly, many of the engine manufacturers
we visited showed us data indicating that the improvements in catalyst
formulations corresponded to improvements in emission reductions over
the regulated test cycles. It is clear from the data presented to EPA
that the progress with regard to NOX adsorber performance
has been both substantial and broadly realized by most technology
developers. The importance of this temperature window to nonroad engine
manufacturers is discussed in more detail later in this section.
Long term durability has been the greatest concern for the
NOX adsorber catalyst. We have concluded as described
briefly in III.F below and in some detail in the draft RIA, that in
order for NOX adsorbers to effectively control
NOX emission throughout the life of a nonroad diesel engine
the fuel sulfur level will have to be maintained at or below 15 ppm,
that the NOX adsorber catalyst thermal durability will need
to improve in order to allow for sulfur regeneration events (since
adsorber thermal degradation, ``sintering,'' is associated with each
desulfation event, the number of desulfation events should be
minimized), and that system improvements will have to be made in order
to allow for appropriate management of sulfur poisoning. It is in this
area of durability that NOX adsorbers had the greatest need
for improvement, and it is here where some of the most impressive
ongoing strides in technology development have been made. During our
ongoing review, we have learned that catalyst companies are making
significant improvements in the thermal durability of the catalyst
materials used in NOX adsorbers. Similarly, the substrate
manufacturers are developing new materials that address the problem of
NOX storage material migration into the substrate.\158\ The
net gain from these simultaneous improvements are NOX
adsorber catalysts which can be desulfated (go through a sulfur
regeneration process) with significantly lower levels of thermal damage
to the catalyst function. In addition, engine manufacturers and
emission control technology vendors are developing new strategies to
accomplish desulfation that allow for improved sulfur management while
minimizing the damage due to sulfur poisoning. It was clear in our
review that the total system improvements being made when coupled with
changes to catalytic materials and catalyst substrates are delivering
significantly improved catalyst durability to the NOX
adsorber technology.
---------------------------------------------------------------------------
\158\ Some NOX storage materials can interact with
the catalyst substrate especially at elevated temperatures making
the storage material unavailable for NOX storage and
weakening the substrate.
---------------------------------------------------------------------------
Practical application of the NOX adsorber catalyst in a
vehicle was an issue during the HD2007 rulemaking and similarly there
are issues regarding the application of NOX adsorbers to
nonroad equipment. Although there is considerable evidence that
NOX adsorbers are highly effective and that durability
issues can be addressed, some worry that the application of the
NOX adsorber systems to vehicles and nonroad equipment will
be impractical due to packaging constraints and the
[[Page 28375]]
potential for high fuel consumption. Our review of progress has left us
more certain than ever that practical system solutions can be applied
to control emissions using NOX adsorbers. We have tested a
diesel passenger car (one of the most difficult packaging situations)
with a complete NOX adsorber and particulate filter system
that demonstrated both exceptional emission control and very low fuel
consumption.\159\ Heavy-duty engine manufacturers have shared with us
their improvements in system design and means to regenerate
NOX while minimizing fuel consumption.\160\ Our own in-house
testing program at the National Vehicle and Fuel Emissions Laboratory
(NVFEL) is developing a number of novel ideas to reduce the total
system package size while maintaining high levels of emission control
and low fuel consumption rates as discussed more fully in the draft
RIA. Similarly, a number of Department of Energy (DOE), Advanced
Petroleum Based Fuel--Diesel Emission Control (APBF-DEC) program
NOX adsorber projects are working to address the system
integration challenges for a diesel passenger car, a large sport
utility vehicle and for a heavy heavy-duty truck.\161\ By citing these
numerous examples, we are not intending to imply that the challenge of
integrating and packaging advanced emission control technologies is
easy. Rather, we believe these examples show that even though
significant challenges exist, they can be overcome through careful
design and integration efforts. Nonroad equipment manufacturers have
addressed similar challenges in the past when they have added
additional customer features (e.g., packaged an air-conditioning
system) or in accommodating other emission control technologies (e.g.,
charge air cooling systems).
---------------------------------------------------------------------------
\159\ McDonald, J and Bunker, B. ``Testing of the Toyota Avensis
DPNR at U.S. EPA-NVFEL,'' SAE 2002-01-2877.
\160\ Hakim, N. ``NOX Adsorbers for Heavy Duty Truck
Engines--Testing and Simulation,'' presentation at Motor Fuels:
Effects on Energy Efficiency and Emissions in the Transportation
Sector Joint Meeting of Research Program Sponsored by the USA Dept.
of Energy, Clean Air for Europe and Japan Clean Air, October 9-10,
2002. Copy available in EPA Air Docket A-2001-28.
\161\ Details with quarterly updates on the APBF-DEC programs
can be found on the DOE website at the following location http://
www.ott.doe.gov/apbf.shtml.
---------------------------------------------------------------------------
All of the issues described above and highlighted first during the
HD2007 rulemaking are likely to be concerns to nonroad engine and
nonroad equipment manufacturers. We believe the challenge to overcome
these issues will be significant for nonroad engines and equipment.
Yet, we have documented substantial progress by industry in the last
year to overcome these challenges, and we continue to believe based on
the progress we have observed that the NOX adsorber catalyst
technology will be mature enough for application to many diesel engines
by 2007. In the case of NOX adsorber temperature window,
which could be especially challenging for nonroad engines, we have
performed an analysis summarized below in section III.E.2 and
documented in the draft RIA, that leads us to conclude the technology
can be successfully applied to nonroad engines provided there is some
additional lead time for further engine and catalyst system technology
development. Similarly, we acknowledge that the diverse nature and
sheer number of different nonroad equipment types makes the challenge
of packaging advanced emission control technologies more difficult.
Therefore, we have included a number of equipment manufacturer
flexibilities in the program proposed today in order to allow equipment
manufacturers to manage the engineering resource challenges imposed by
these regulations.
Another NOX catalyst based emission control technology
is selective catalytic reduction (SCR). SCR catalysts require a
reductant, ammonia, to reduce NOX emissions. Because of the
significant safety concerns with handling and storing ammonia, most SCR
systems make ammonia within the catalyst system from urea. Such systems
are commonly called urea SCR systems. (Throughout this document the
term SCR and urea SCR may be used interchangeably and should be
considered as referring to the same urea based catalyst system.) With
the appropriate control system to meter urea in proportion to engine-
out NOX emissions, urea SCR catalysts can reduce
NOX emissions by over 90 percent for a significant fraction
of the diesel engine operating range.\162\ Although EPA has not done an
extensive analysis to evaluate its effectiveness, we believe it may be
possible to reduce NOX emissions with a urea SCR catalyst to
levels consistent with compliance with the proposed NOX
standards.
---------------------------------------------------------------------------
\162\ ``Demonstration of Advanced Emission Control Technologies
Enabling Diesel-Powered Heavy-Duty Engines to Achieve Low Emission
Levels'', Manufacturers of Emissions Controls Association, June 1999
Air Docket A-2001-28.
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However, we have significant concerns regarding a technology that
requires extensive user intervention in order to function properly and
the lack of the urea delivery infrastructure necessary to support this
technology. Urea SCR systems consume urea in proportion to the engine-
out NOX rate. The urea consumption rate can be on the order
of five percent of the engine fuel consumption rate. Therefore, unless
the urea tank is prohibitively large, the urea must be replenished
frequently. Most urea systems are designed to be replenished every time
fuel is added or at most every few times that fuel is added. Today,
there is not a system in place to deliver or dispense automotive grade
urea to diesel fueling stations. One study conducted for the National
Renewable Energy Laboratory (NREL), estimated that if urea were to be
distributed to every diesel fuel station in the United States, the cost
would be more than $30 per gallon.\163\
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\163\ Fable, S. et al, ``Subcontractor Report--Selective
Catalytic Reduction Infrastructure Study,'' AD Little under contract
to National Renewable Energy Laboratory, July 2002, NREL/SR-5040-
32689. Copy available in EPA Air Docket A-2001-28.
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We are not aware of a proven mechanism that ensures that the user
will replenish the urea supply as necessary to maintain emissions
performance. Further, we believe given the additional cost for urea,
that there will be significant disincentives for the end-user to
appropriately replenish the urea because the cost of urea could be
avoided without equipment performance loss. See NRDC v. EPA, 655 F. 2d
318, 332 (D.C. Cir. 1981) (referring to ``behavioral barriers to
periodic restoration of a filter by a [vehicle] owner'' as a valid
basis for EPA considering a technology unavailable). Due to the lack of
an infrastructure to deliver the needed urea, and the lack of a track
record of successful ways to ensure urea use, we have concluded that
the urea SCR technology is not likely to be available for general use
in the time frame of the proposed standards. Therefore, we have not
based the feasibility or cost analysis of this emission control program
on the use or availability of the urea SCR technology. However, we
would not preclude its use for compliance with the emission standards
provided that a manufacturer could demonstrate satisfactorily to the
Agency that urea would be used under all conditions. We believe that
only a few unique applications will be able to be controlled in a
manner such that urea use can be assured, and therefore believe it is
inappropriate to base a national emission control program on a
technology which can serve effectively only in a few niche
applications.
This section has described a number of technologies that can reduce
[[Page 28376]]
emissions from diesel engines. The following section describes the
challenges to applying these diesel engine technologies to engines and
equipment designed for nonroad applications.
2. Can These Technologies Be Applied to Nonroad Engines and Equipment?
The emission standards and the introduction dates for those
standards, as described earlier in this section, are premised on the
transfer of diesel engine technologies being or already developed to
meet light-duty and heavy-duty vehicle standards that begin in 2007.
The standards that we are proposing today for engines =75
horsepower will begin to go into effect four years later. This time lag
between equivalent highway and nonroad diesel engine standards is
necessary in order to allow time for engine and equipment manufacturers
to further develop these highway technologies for nonroad engines and
to align this program with nonroad Tier 3 emission standards that begin
to go into effect in 2006.
As discussed previously, the test procedures and regulations for
the HD2007 highway engines include a transient test procedure, a broad
steady-state procedure, and NTE provisions that require compliant
engines to emit at or below 1.5 times the regulated emission levels
under virtually all conditions. An engine designed to comply with the
2007 highway emission standards would comply with the equivalent
nonroad emission standards proposed today if it were to be tested over
the transient and steady-state nonroad emission test procedures
proposed today, which cover the same regions and types of engine
operation. Said in another way, a highway diesel engine produced in
2007 could be certified in compliance with the transient and steady-
state standards proposed today for nonroad diesel engines several years
in advance of the date when these standards would go into effect.
However, that engine, while compliant with certain of the nonroad
emission standards proposed today, would not necessarily be designed to
address the various durability and performance requirements of many
nonroad equipment manufacturers. We expect that the engine
manufacturers will need additional time to further develop the
necessary emission control systems to address some of the nonroad
issues described below as well as to develop the appropriate
calibrations for engine rated speed and torque characteristics required
by the diverse range of nonroad equipment. Furthermore, not all nonroad
engine manufacturers produce highway diesel engines or produce nonroad
engines that are developed from highway products. Therefore, there is a
need for lead time between the Tier 3 emission standards which go into
effect in 2006-2008 and the Tier 4 emission standards. We believe the
technologies developed to comply with the Tier 3 emission standards
such as improved air handling systems and electronic fuel systems will
form an essential technology baseline which manufacturers will need to
initiate and control the various regeneration functions required of the
catalyst based technologies for Tier 4. The Agency has given
consideration to all of these issues in setting the emission standards
and the timing of those standards as proposed today.
This section describes some of the challenges to applying advanced
emission control technologies to nonroad engines and equipment, and why
we believe that technologies developed for highway diesel engines can
be further refined to address these issues in a timely manner for
nonroad engines consistent with the emission standards proposed today.
This section paraphrases a more in-depth analysis in the draft RIA.
a. Nonroad Operating Conditions and Exhaust Temperatures
Nonroad equipment is highly diverse in design, application, and
typical operating conditions. This variety of operating conditions
affects emission control systems through the resulting variety in the
torque and speed demands (i.e. power demands). This wide range in what
constitutes typical nonroad operation makes the design and
implementation of advanced emission control technologies more
difficult. The primary concern for catalyst based emission control
technologies is exhaust temperature. In general, exhaust temperature
increases with engine power and can vary dramatically as engine power
demands vary.
For most catalytic emission control technologies there is a minimum
temperature below which the chemical reactions necessary for emission
control do not occur. The temperature above which substantial catalytic
activity is realized is often called the light-off temperature. For
gasoline engines, the light-off temperature is typically only important
in determining cold start emissions. Once gasoline vehicle exhaust
temperatures exceed the light-off temperature, the catalyst is ``lit-
off'' and remains fully functional under all operating conditions.
Diesel exhaust is significantly cooler than gasoline exhaust due to the
diesel engine's higher thermal efficiency and its operation under
predominantly lean conditions. Absent control action taken by an
electronic engine control system, diesel exhaust may fall below the
light-off temperature of catalyst technology even when the vehicle is
fully warmed up.
The relationship between the exhaust temperature of a nonroad
diesel engine and light-off temperature is an important factor for both
CDPF and NOX adsorber technologies. For the CDPF technology,
exhaust temperature determines the rate of filter regeneration and if
too low causes a need for supplemental means to ensure proper filter
regeneration. In the case of the CDPF, it is the aggregate soot
regeneration rate that is important, not the regeneration rate at any
particular moment in time. A CDPF controls PM emissions under all
conditions and can function properly (i.e., not plug) even when exhaust
temperatures are low for an extended time and the regeneration rate is
lower than the soot accumulation rate, provided that occasionally
exhaust temperatures and thus the soot regeneration rate are increased
enough to regenerate the CDPF. A CDPF can passively (without
supplemental heat addition) regenerate if exhaust temperatures remain
above 250[deg]C for more than 30 percent of engine operation.\164\
Similarly, there is a minimum temperature (e.g., 200[deg]C) for
NOX adsorbers below which NOX regeneration is not
readily possible and a maximum temperature (e.g., 500[deg]C) above
which NOX adsorbers are unable to effectively store
NOX. These minimum and maximum temperatures define a
characteristic temperature window of the NOX adsorber
catalyst. When the exhaust temperature is within the temperature window
(above the minimum and below the maximum) the catalyst is highly
effective. When exhaust temperatures fall outside this window of
operation, NOX adsorber effectiveness is diminished.
Therefore, there is a need to match diesel exhaust temperatures to
conditions for effective catalyst operation under the various operating
conditions of nonroad engines.
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\164\ Engelhard DPX catalyzed diesel particulate filter retrofit
verification, www.epa.gov/otaq/retrofit/techlist-engelhard.htm, a
copy of this information is available in Air Docket A-2001-28.
---------------------------------------------------------------------------
Although the range of products for highway vehicles is not as
diverse as for nonroad equipment, the need to match exhaust
temperatures to catalyst characteristics is still present. This is a
significant concern for highway engine
[[Page 28377]]
manufacturers and has been a focus of our ongoing diesel engine
progress review. There we have learned that substantial progress is
being made to broaden the operating temperature window of catalyst
technologies while at the same time engine systems are being designed
to better control exhaust temperatures. Highway diesel engine
manufacturers are working to address this need through modifications to
engine design, modifications to engine control strategies and
modifications to exhaust system designs. Engine design changes,
including the ability for multiple late fuel injections and the ability
to control total air flow into the engine, give controls engineers
additional flexibility to change exhaust temperature characteristics.
Modifications to the exhaust system, including the use of insulated
exhaust manifolds and exhaust tubing, can help to preserve the
temperature of the exhaust gases. New engine control strategies
designed to take advantage of engine and exhaust system modifications
can then be used to manage exhaust temperatures across a broad range of
engine operation. The technology solutions being developed for highway
engines to better manage exhaust temperature are built upon the same
emission control technologies (i.e., advanced air handling systems and
electronic fuel injection systems) that we expect nonroad engine
manufacturers to use in order to comply with the Tier 3 emission
standards.
Matching the operating temperature window of the broad range of
nonroad equipment may be somewhat more challenging for nonroad engines
than for many highway diesel engines simply because of the diversity in
equipment design and equipment use. Nonetheless, the problem has been
successfully solved in highway applications facing low temperature
performance situations as difficult to address as any encountered by
nonroad applications. The most challenging temperature regime for
highway engines are encountered at very light-loads as typified by
congested urban driving. Under congested urban driving conditions
exhaust temperatures may be too low for effective NOX
reduction with a NOX adsorber catalyst. Similarly, exhaust
temperatures may be too low to ensure passive CDPF regeneration. To
address these concerns, light-duty diesel engine manufacturers have
developed active temperature management strategies that provide
effective emissions control even under these difficult light-load
conditions. Toyota has shown with their prototype DPNR vehicles that
changes to EGR and fuel injection strategies can realize an increase in
exhaust temperatures of more than 100[deg]F under even very light-load
conditions allowing the NOX adsorber catalyst to function
under these normally cold exhaust conditions.\165\ Similarly, PSA has
demonstrated effective CDPF regeneration under demanding light-load
taxi cab conditions with current production technologies.\166\ Both of
these are examples of technology paths available to nonroad engine
manufacturers to increase temperatures under light-load conditions.
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\165\ Sasaki, S., Ito, T., and Iguchi, S., ``Smoke-less Rich
Combustion by Low Temperature Oxidation in Diesel Engines,'' 9th
Aachener Kolloquim Fahrzeug--und Motorentechnik 2000. Copy available
in EPA Air Docket A-2001-28.
\166\ Jeuland, N., et al, ``Performances and Durability of DPF
(Diesel Particulate Filter) Tested on a Fleet of Peugeot 607 Taxis
First and Second Test Phases Results,'' October 2002, SAE 2002-01-
2790.
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We are not aware of any nonroad equipment in-use operating cycles
which would be more demanding of low temperature performance than
passenger car urban driving. Both the Toyota and PSA systems are
designed to function even with extended idle operation as would be
typified by a taxi waiting to pick up a fare. By actively managing
exhaust temperatures engine manufacturers can ensure highly effective
catalyst based emission control performance (i.e., compliance with the
emission standards) and reliable filter regeneration (failsafe
operation) across a wide range of engine operation as would be typified
by the broad range of in-use nonroad duty cycles and the new nonroad
transient test proposed today.
The systems described here from Toyota and PSA are examples of
highly integrated engine and exhaust emission control systems based
upon active engine management designed to facilitate catalyst function.
Because these systems are based upon the same engine control
technologies likely to be used to comply with the Tier 3 standards and
because they allow great flexibility to trade-off engine control and
catalyst control approaches depending on operating mode and need, we
believe most nonroad engine manufacturers will use similar approaches
to comply with the emission standards proposed today. However, there
are other technologies available that are designed to be added to
existing engines without the need for extensive integration and engine
management strategies. One example of such a system is an active DPF
system developed by Deutz for use on a wide range on nonroad equipment.
The Deutz system has been sold as an OEM retrofit technology that does
not require changes to the base engine technology. The system is
electronically controlled and uses supplemental in-exhaust fuel
injection to raise exhaust temperatures periodically to regenerate the
DPF. Deutz has sold over 2,000 of these units and reports that the
systems have been reliable and effective. Some manufacturers may choose
to use this approach for compliance with the PM standard proposed
today, especially in the case of engines which may be able to comply
with the proposed NOX standards with engine-out emission
control technologies (i.e., engines rated between 25 and 75
horsepower).
High temperature operating regimes such as a heavy heavy-duty
diesel truck at full payload driving up a grade are also challenging
for the NOX catalyst technology. Although less common,
similar high temperature conditions of full engine load operation can
be imagined for nonroad equipment. However, because highway engines
typically have higher power density (defined as rated power divided by
engine displacement), the highest operating conditions would be
expected to be encountered with highway vehicles. High exhaust
temperatures (in excess of 500[deg]C) are challenging for the
NOX adsorber catalyst technology because the stored
NOX emissions can be released thermally without going
through a reduction step, leading to increased NOX
emissions. In the absence of a reductant (normally provided by the
standard NOX regeneration function) the thermally released
NOX is emitted from the exhaust system without treatment. To
address this issue, NOX storage catalyst technologies with
higher levels of thermal stability are being developed, but these
technologies trade-off improved high temperature performance for even
greater sensitivity to fuel sulfur. Beyond catalyst improvements, the
exhaust temperature from the engine can be controlled prior to the
NOX adsorber catalyst simply through heat loss in the
exhaust system (i.e. by locating the catalyst further from the engine).
Another approach being considered for GDI vehicle applications which
operate at much higher temperatures than would be encountered by a
diesel engine is to use a relatively simple exhaust layout design to
increase heat loss at high temperatures while still providing
acceptable low temperature
[[Page 28378]]
performance.\167\ Additionally, exhaust temperatures well in excess of
500[deg]C are not frequently experienced by nonroad engines. Higher
exhaust temperatures would be expected from naturally aspirated engines
due to their lower air flow (for the same power/heat input, naturally
aspirated engines have less air to heat up and thus the exhaust reaches
a higher temperature). Today, less than ten percent of nonroad diesel
engines with rated power greater than 100 horsepower are naturally
aspirated and we have projected that an even greater percentage of
nonroad engines meeting the Tier 3 emission standards will be
turbocharged.
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\167\ Damson, B., ``Exhaust Cooling for NOX-Traps for
Lean Spark-Ignition Engines,'' SAE 2002-01-0737.
---------------------------------------------------------------------------
We have conducted an analysis of various nonroad equipment
operating cycles and various nonroad engine power density levels to
better understand the matching of nonroad engine exhaust temperatures,
catalyst installation locations and catalyst technologies. This
analysis, documented in the draft RIA, showed that for many engine
power density levels and equipment operating cycles, exhaust
temperatures are quite well matched to catalyst temperature window
characteristics. In particular, the nonroad transient cycle (NRTC), the
cycle we are proposing to use for certification, was shown to be well
matched to the NOX adsorber characteristics with estimated
performance in excess of 90 percent for a turbocharged diesel engine
tested under a range of power density levels. The analysis also
indicated that the exhaust temperatures experienced over the NRTC are
better matched to the NOX adsorber catalyst temperature
window than the temperatures that would be expected over the highway
FTP test cycle. This suggests that compliance with the proposed NRTC
will be somewhat easier, using similar technology, than complying with
the highway 2007 emission standards on the FTP.
For engines with low power density (e.g., <25 hp per liter of
engine displacement) the analysis showed that, absent actions to
increase exhaust temperatures (e.g., increased use of EGR a light
loads), compliance with the NRTC cycle will be more difficult than for
engines with higher power density levels. Specifically, the analysis
predicted 92% control for the high power density engine and 86% control
for the low power density engine.
Note that this analysis approach is only effective to predict
differences in performance, but not effective to predict absolute
performance. The same analysis approach predicted 83% control for the
high power density engine on the heavy-duty FTP, although testing at
EPA has shown for this engine (a different example of this same engine)
greater than 90% NOX control.\168\ Nevertheless, the
analysis suggests that additional attention must be made to designing
system for low power density applications, and that technology changes
may be necessary to ensure adequate performance (e.g., the use of EGR
or other control methods to raise exhaust temperatures). One change,
which is occurring independent of EPA's regulation, is increasing power
density for nonroad engines. EPA has documented in the draft RIA a
clear trend of certified engine ratings that indicates manufacturers
are increasing engine power without increasing engine displacement.
Engine manufacturers are motivated to increase engine power density
because engine pricing is largely done on a power basis, while the cost
of manufacturing is more closely related to engine displacement.
Therefore, increasing engine power levels without increasing
displacement may increase the sale price of the engine more than it
increases the cost of manufacturing. Increasing power density typically
results in higher exhaust temperatures and, in this case, better
matching to catalyst operating requirements. Alternatively, nonroad
engine manufacturers can apply the same temperature management
strategies previously described for highway engines.
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\168\ Schenk, C., McDonald, J. and Olson, B. ``High Efficiency
NOX and PM Exhaust Emission Control for Heavy-Duty On-
Highway Diesel Engines,'' SAE 2001-01-1351.
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The analysis also suggests that the temperature challenge for
nonroad equipment will be greater with regard to the NTE provisions of
this proposal than for the nonroad transient test (NRTC) provisions. In
fact as discussed previously, the NRTC cycle appears to be a better
match to the characteristics of the NOX adsorber catalyst
than the FTP cycle used for heavy-duty highway truck certification.
This is due to the higher average engine load experienced over the NRTC
and thus the higher average temperature. Therefore, we believe that
complying with the NOX standard over the transient test
cycle proposed today for nonroad engines will not be significantly more
difficult than complying with the HD2007 NOX emission
standard over the FTP. The analysis also shows that many nonroad
engines may operate in-use in a way different from the NRTC (i.e. even
the NRTC is not an all-encompassing test; no single test realistically
could be), and that NTE standards are therefore needed to assure that
nonroad engine emissions are controlled for the full range of possible
in-use operating conditions.\169\ The technical challenge of
controlling NOX emissions, even under these diverse
conditions, is no more difficult on a per engine basis than for highway
diesel engines which must comply with similar NTE test provisions. This
is because both highway and nonroad engine manufacturers must address
control at the same high load and low load conditions (minimum power
from both are the same, 0 hp, and maximum power is typically higher for
highway engines, due to higher power density). Also, both engine
manufacturers must be able to respond to changes in user demanded
torque (transient conditions) that are similarly unpredictable.
However, given the sheer number of different nonroad equipment types
and engine ratings, this represents a real challenge for the nonroad
industry which is one of the primary considerations given by the Agency
in determining the appropriate timing for the emission standards
proposed today.
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\169\ The fact that developing compliant engines for the NTE
provisions may be more difficult than developing for the transient
test cycle does not diminish the value of the transient test as a
means to evaluate the overall effectiveness of the emission control
system under transient conditions. There is no doubt that
controlling average emissions under transient conditions will be an
important part of the emission control system and that evaluating
overall performance under transient conditions is needed.
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We believe, based on our analysis of nonroad engines and equipment
operating characteristics, that in-use some nonroad engines will
experience conditions that require the use of temperature management
strategies in order to effectively use the NOX adsorber and
CDPF systems needed to meet the proposed standards. We have assumed in
our cost analysis that all nonroad engines complying with a PM standard
of 0.02 g/bhp-hr or lower will have an active means to control
temperature (i.e. we have costed a backup regeneration system, although
some applications likely may not need one). We have made this
assumption believing that manufacturers will not be able to accurately
predict in-use conditions for every piece of equipment and will thus
choose to provide the technologies on a back-up basis. As explained
earlier, the technologies necessary to accomplish this temperature
management are enhancements of the Tier 3 emission control technologies
that will form the
[[Page 28379]]
baseline for Tier 4 engines, and the control strategies being developed
for highway diesel engines. We do not believe that there are any
nonroad engine applications above 25 horsepower for which these highway
engine approaches will not work. However, given the diversity in
nonroad equipment design and application, we believe that additional
time will be needed in order to match the engine performance
characteristics to the full range of nonroad equipment.
We believe that given the timing of the emissions standards
proposed today, and the availability and continuing development of
technologies to address temperature management for highway engines
which technologies are transferrable to all nonroad engines with
greater than 25 hp power rating, that nonroad engines can be designed
to meet the proposed standards in the lead time provided in this
proposal.
b. Nonroad Operating Conditions and Durability
Nonroad equipment is designed to be used in a wide range of tasks
in some of the harshest operating environments imaginable, from mining
equipment to crop cultivation and harvesting to excavation and loading.
In the normal course of equipment operation the engine and its
associated hardware will experience levels of vibration, impacts, and
dust that may exceed conditions typical of highway diesel vehicles.
Specific efforts to design for the nonroad operating conditions
will be required in order to ensure that the benefits of these new
emission control technologies are realized for the life of nonroad
equipment. Much of the engineering knowledge and experience to address
these issues already exists with the nonroad equipment manufacturers.
Vibration and impact issues are fundamentally mechanical durability
concerns (rather than issues of technical feasibility of achieving
emissions reductions) for any component mounted on a piece of equipment
(e.g., an engine coolant overflow tank). Equipment manufacturers must
design mounting hardware such as flanges, brackets, and bolts to
support the new component without failure. Further, the catalyst
substrate material itself must be able to withstand the conditions
encountered on nonroad equipment without itself cracking or failing.
There is a large body of real world testing with retrofit emission
control technologies that demonstrates the durability of the catalyst
components themselves even in the harshest of nonroad equipment
applications.
Deutz, a nonroad engine manufacturer, sold approximately 2,000
diesel particulate filter systems for nonroad equipment in the period
from 1994 through 2000. Many of these systems were sold for use in
mining equipment. No other applications are likely to be more demanding
than this. Mining equipment is exposed to extraordinarily high levels
of vibration, experiences impacts with the mine walls and face, and
high levels of dust. Yet in meetings with the Agency, Deutz shared
their experience that no system had failed due to mechanical failure of
the catalyst or catalyst housing.\170\ The Deutz system utilized a
conventional cordierite PM filter substrate as is commonly used for
heavy-duty highway truck CDPF systems. The canning and mounting of the
system was a Deutz design. Deutz was able to design the catalyst
housing and mounting in such a way as to protect the catalyst from the
harsh environment as evidenced by its excellent record of reliable
function.
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\170\ ``Summary of Conference Call between U.S. EPA and Deutz
Corporation on September 19, 2002 regarding Deutz Diesel Particulate
Filter System'', EPA Memorandum to Air Docket A-2001-28.
---------------------------------------------------------------------------
Other nonroad equipment manufacturers have also offered OEM diesel
particulate filter systems in order to comply with requirements of some
mining and tunneling worksite standards. Liebherr, a nonroad engine and
equipment manufacturer, offers diesel particulate filter systems as an
OEM option on its range of construction machine models. As of January
2000, 340 Liebherr machines have been fitted with PM filter
systems.\171\ We believe that this experience shows that appropriate
design considerations, as are necessary with any component on a piece
of nonroad equipment, will be adequate to address concerns with the
vibration and impact conditions which can occur in some nonroad
applications. This experience applies equally well to the
NOX adsorber catalyst technologies as the mechanical
properties of DOCs, CDPFs, and NOX adsorbers are all
similar. We do not believe that any new or fundamentally different
solutions will need to be invented in order to address the vibration
and impact constraints for nonroad equipment. Our cost analysis
includes the hardware costs for mounting and shrouding the
aftertreatment equipment as well as the engineering cost for equipment
redesign.
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\171\ ``Particulate Traps for Construction Machines: Properties
and Field Experience'' J. Czerwinski et. al., Society of Automotive
Engineers Technical Paper 2000-01-1923.
---------------------------------------------------------------------------
Certain nonroad applications, including some forms of harvesting
equipment and mining equipment, may have specific limits on maximum
surface temperature for equipment components in order to ensure that
the components do not serve as ignition sources for flammable dust
particles (e.g. coal dust or fine crop dust). Some have suggested that
these design constraints might limit the equipment manufacturers
ability to install advanced diesel catalyst technologies such as
NOX adsorbers and CDPFs. This concern seems to be largely
based upon anecdotal experience with gasoline catalyst technologies
where under certain circumstances catalyst temperatures can exceed
1,000[deg]C and without appropriate design considerations could
conceivably serve as an ignition source. We do not believe that these
concerns are justified in the case of either the NOX
adsorber catalyst or the CDPF technology. Catalyst temperatures for
NOX adsorbers and CDPFs should not exceed the maximum
exhaust manifold temperatures already commonly experienced by diesel
engines (i.e, catalyst temperatures are expected to be below
800[deg]C).\172\ CDPF temperatures are not expected to exceed
approximately 700[deg]C in normal use and are expected to only reach
the 650[deg]C temperature during periods of active regeneration.
Similarly, NOX adsorber catalyst temperatures are not
expected to exceed 700[deg]C and again only during periods of active
sulfur regeneration as described in Section III.F below. Under
conditions where diesel exhaust temperatures are naturally as high as
650[deg]C, no supplemental heat addition from the emission control
system will be necessary and therefore exhaust temperatures will not
exceed their natural level. When natural exhaust temperatures are too
low for effective emission system function then supplemental heating as
described earlier may be necessary but would not be expected to produce
temperatures higher than the maximum levels normally encountered in
diesel exhaust. Furthermore, even if it were necessary to raise exhaust
temperatures to a higher level in order to promote effective emission
control, there are technologies available to isolate the higher exhaust
[[Page 28380]]
temperatures from flammable materials such as dust. One approach would
be the use of air-gapped exhaust systems (i.e., an exhaust pipe inside
another concentric exhaust pipe separated by an air-gap) that serve to
insulate the inner high temperature surface from the outer surface
which could come into contact with the dust. The use of such a system
may be additionally desirable in order to maintain higher exhaust
temperatures inside the catalyst in order to promote better catalyst
function. Another technology to control surface temperature already
used by some nonroad equipment manufacturers is water cooled exhaust
systems.\173\ This approach is similar to the air-gapped system but
uses engine coolant water to actively cool the exhaust system. We do
not believe that flammable dust concerns will prevent the use of either
a NOX adsorber or a CDPF because catalyst temperatures are
not expected to be unacceptably high and because remediation
technologies exist to address these concerns. In fact, exhaust emission
control technologies (i.e., aftertreatment) have already been applied
on both an OEM basis and for retrofit to nonroad equipment for use in
potentially explosive environments. Many of these applications must
undergo Underwriters Laboratory (UL) approval before they can be
used.\174\
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\172\ The hottest surface on a diesel engine is typically the
exhaust manifold which connects the engines exhaust ports to the
inlet of the turbocharger. The hot exhaust gases leave the engine at
a very high temperature (800[deg]C at high power conditions) and
then pass through the turbocharger where the gases expand driving
the turbocharger providing work. The process of extracting work from
the hot gases cools the exhaust gases. The exhaust leaving the
turbocharger and entering the catalyst and the remaining pieces of
the exhaust system is cooler (as much as 200[deg]C at very high
loads) than in the exhaust manifold.
\173\ ``Engine Technology and Application Aspects for
Earthmoving Machines and Mobile Cranes, Dr. E. Brucker, Liebherr
Machines Bulle, SA, AVL International Commercial Powertrain
Conference, October 2001. Copy available in EPA Air Docket A-2001-
28, Docket Item II-A-12.
\174\ Phone conversation with Manufacturers of Emission Control
Association (MECA), 9 April, 2003 confirming the use of emission
control technologies on nonroad equipment used in coal mines,
refineries, and other locations where explosion proofing may be
required.
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Nonroad engines greater than 750 hp are unique in that they do not
have direct highway equivalents. However, this does not mean that
unique catalyst based emission control technologies need to be
developed separately for these larger applications. Rather, larger
engines can, and do in retrofit applications today, use multiple
catalyst systems in a parallel configuration. As an example, a highway
12 liter displacement in-line six cylinder engine might use a single 18
liter CDPF, while a nonroad 24 liter displacement V12 cylinder (a vee
engine has two rows of cylinders set at an angle to each other) engine
would use two 18 liter CDPFs, one for each bank of the vee engine.
Using two smaller catalysts in place of one larger catalyst can be
easier to package and may allow for close coupling of the catalyst
technology to the turbocharger exhaust outlet to improve temperature
management in some applications. Today, many passenger cars and light-
duty trucks with V6 or V8 engines use individual catalysts for each
engine bank to improve packaging and better manage temperatures.
We agree that nonroad equipment must be designed to address durable
performance for a wide range of operating conditions and applications
that would not commonly be experienced by highway vehicles. We believe
further as demonstrated by retrofit experiences around the world that
technical solutions exist which allow catalyst-based emission control
technologies to be applied to nonroad equipment.
3. Are the Standards Proposed for Engines of 75 hp or Higher Feasible?
There are three primary test provisions and associated standards in
the Tier 4 program we are proposing today. These are the proposed
Nonroad Transient Cycle (NRTC), the existing ISO C1 steady-state cycle,
and the proposed highway based Not-To-Exceed (NTE) provisions. A
nonroad diesel engine meeting the proposed standards for each of these
three test cycles would be lawful for use in any kind of nonroad
equipment. Additionally, we have alternative optional test cycles
including the proposed Constant Speed Variable Load (CSVL) cycle, the
existing ISO-D2 steady-state cycle and the proposed Transportation
Refrigeration Unit (TRU) cycle which a manufacturer can choose to use
for certification provided that the manufacturer can demonstrate to the
Agency that the engine will only be used in a limited range of nonroad
equipment with specifically defined operating conditions. Compliance on
the proposed transient test cycles includes weighting the results from
a cold start and hot start test with the cold start emissions weighted
at 1/10 and hot start emissions weighted at 9/10. A complete discussion
of these various test cycles can be found in chapter 4.2 and 4.3 of the
draft RIA.
The standards proposed today for nonroad engines with rated power
greater than or equal to 75 horsepower are based upon the technologies
and standards for highway diesel engines which go into effect in 2007.
As explained above, we believe these technologies, namely
NOX adsorbers and catalyzed diesel particulate filters
enabled by 15 ppm sulfur diesel fuel, can be applied to nonroad diesel
engines in a similar manner as for highway diesel engines. We
acknowledge that there are additional constraints on nonroad diesel
engines which must be considered in setting these standards, and we
have addressed those issues by allowing for additional lead time or
slightly less stringent standards for nonroad diesel engines in
comparison to highway diesel engines (and likewise have made
appropriate cost estimates to account for the technology and
engineering needed to address these constraints).
We have proposed a PM standard for engines in this category of 0.01
g/bhp-hr based upon the emissions reductions possible through the
application of a CDPF and 15 ppm sulfur diesel fuel. This is the same
emissions level as for highway diesel engines in the HD2007 program.
While baseline soot (the solid carbon fraction of PM) emission levels
may be somewhat higher for some nonroad engines when compared to
highway engines, these emissions are virtually eliminated (reduced by
99 percent) by the CDPF technology. As discussed previously, the
baseline (engine-out) SOF emissions levels may also need to be reduced
through the application of modern piston ring pack designs and valve
stem seals. With application of the CDPF technology, the SOF portion of
diesel PM is predicted to be all but eliminated. The primary emissions
from a CDPF equipped engine are sulfate PM emissions formed from sulfur
in diesel fuel. The emissions rate for sulfate PM is determined
primarily by the sulfur level of the diesel fuel and the rate of fuel
consumption. With the 15 ppm sulfur diesel fuel the PM emissions level
from a CDPF equipped nonroad diesel engine will be similar to the
emissions rate of a comparable highway diesel engine. Therefore, the
0.01 g/bhp-hr emission level is feasible for nonroad engines tested on
the NRTC cycle and on the steady-state cycles, C1 and D2. Put another
way, control of PM using CDPF technology is essentially independent of
duty cycle given active catalyst technology (for reliable regeneration
and SOF oxidation), adequate control of temperature (for reliable
regeneration) and low sulfur diesel fuel (for reliable regeneration and
low PM emissions).
The most challenging PM emissions control conditions for a CDPF are
encountered under high engine load operation where high exhaust
temperatures promote conversion of sulfur in diesel fuel to sulfate PM
emissions. Under these high load conditions, soot and SOF oxidation
rates will be very high and control of those portions of PM emissions
will be highly effective. Sulfate PM emissions, however, will be higher
than for other operating conditions. In a worst case scenario, where
all of the sulfur is
[[Page 28381]]
converted to sulfate, it could be perhaps as high as 0.02 g/bhp-
hr.\175\ This level of PM emissions would comply with our proposed NTE
provisions once consideration is given to the 1.5 times multiplier on
the emission standard for NTE test conditions.\176\ Since this estimate
is made at a worst case condition (assuming 100% conversion of sulfur
to sulfate), we feel confident that the PM NTE provisions of this
proposal can be met.
---------------------------------------------------------------------------
\175\ An estimate of the maximum sulfate PM emissions rate can
be made by assuming a fuel consumption rate (e.g., 0.5 lbm/bhp-hr),
the fuel sulfur level (e.g., 15 ppm) and the sulfur to sulfate
conversion (e.g., 100% maximum) resulting in a calculated sulfate PM
emissions rate of 0.02 g/bhp-hr. This represents a worst case
analysis (100% sulfur conversion with 15 ppm sulfur fuel). In-use
emissions would be significantly lower.
\176\ The PM standard is expressed to two significant digits
0.01 g/bhp-hr, so when the 1.5 NTE multiplier is applied, the NTE
limit becomes 0.015 which is rounded to two significant figures as
0.02 g/bhp-hr.
---------------------------------------------------------------------------
Under contract from the California Air Resources Board, two nonroad
diesel engines were recently tested for PM emissions performance with
the application of a CDPF over a number of transient and steady-state
test cycles.\177\ The first engine is a 1999 Caterpillar 3408 (480 hp,
18 liter displacement) nonroad diesel engine certified to the Tier 1
standards. The engine was tested with and without a CDPF on 12 ppm
sulfur diesel fuel. The transient emission results for this engine are
summarized in Table III.E-1 below. The steady-state emission results
are summarized in Table III.1-2. The test results confirm the excellent
PM control performance realized by a CDPF with low sulfur diesel fuel
across a wide range of nonroad operating cycles in spite of the
relatively high engine-out PM emissions from this Tier 1 engine. We
would expect engine-out PM emissions to be lower for production Tier 3
compliant diesel engines that will form the technology baseline for
Tier 4 engines meeting the proposed standard. The engine demonstrated
PM emissions of 0.009 g/bhp-hr on the proposed Nonroad Transient Cycle
(NRTC) from an engine-out level of 0.256 g/bhp-hr, a reduction of 0.247
g/bhp-hr. The engine also demonstrated excellent PM performance on the
existing steady-state ISO C1 cycle with PM emissions of 0.010 g/bhp-hr
from an engine-out level of 0.127, a reduction of 0.107 g/bhp-hr. Thus
this engine would be compliant with the proposed PM emission standard
for =75 hp variable speed nonroad engines.
---------------------------------------------------------------------------
\177\ Application of Diesel Particulate Filters to Three Nonroad
Engines--Interim Report, January 2003. Copy available in EPA Air
Docket A-2001-28.
---------------------------------------------------------------------------
When tested on the proposed optional constant speed variable load
cycle (CSVL) (a test to which this engine would not be subject to under
this proposal) the engine-out PM emission levels were 0.407 g/bhp-hr
and were reduced to 0.016 g/bhp-hr (a reduction of 0.391 g/bhp-hr) with
the addition of the PM filter. As tested this engine would not be
compliant with the proposed optional CSVL standard, but this is not
surprising given that this Tier 1 engine was designed for variable
speed engine operation and not for single speed operation. We have
great confidence given the substantial PM reduction realized in this
testing over the proposed CSVL cycle with a CDPF that a properly
designed nonroad diesel engine will be able to meet the standard of
0.01 g/bhp-hr.
[GRAPHIC] [TIFF OMITTED] TP23MY03.004
Table III.E-1 also shows results over a large number of additional
test cycles developed from real world in-use test data to represent
typical operating cycles for different nonroad equipment applications
(see chapter 4.2 of the draft RIA for information on these test
cycles). These test cycles are not used for regulatory purposes,
although the information from these cycles was used in developing the
proposed NRTC. The results show that the CDPF technology is highly
effective to control in-use PM emissions over any number of disparate
operating conditions. Remembering that the base Tier 1 engine was not
designed to meet a transient PM standard, the CDPF emissions
demonstrated here
[[Page 28382]]
show that very low emission levels are possible even when engine-out
emissions are exceedingly high (e.g., a reduction of 0.558 g/bhp-hr is
demonstrated on the AW2 cycle).
The results summarized in the two tables are also indicative of the
feasibility of the proposed NTE provisions of this rulemaking. In spite
of the Tier 1 baseline of this engine, there are only three test
results with emissions higher than the permissible limit for the
proposed NTE. The first in Table III.E-1 shows PM emissions of 0.031
over the AW2 cycle but from a very high baseline level of nearly 0.6 g/
bhp-hr. We believe that simple improvements to the engine-out PM
emissions as needed to comply with the Tier 2 emission standard would
reduce these emission below the 0.02 level required by the standard.
There are two other test points in Table III.E-2 which are above the
proposed NTE emission level, both at 10 percent engine load. However,
both are outside the NTE zone which excludes emissions for engine loads
below 30 percent. It is important to note that although the engine
would not be constrained to meet the NTE under these conditions, the
resulting reductions at both points are still substantial in excess of
96 percent.
Table III.E-2--Steady-State PM Emissions from a Tier 1 NR Diesel Engine w/CDPF
----------------------------------------------------------------------------------------------------------------
1999 (Tier 1) Caterpillar 3408 (480hp, 181)
-----------------------------------------------------------------------------------------------------------------
PM ([g/bhp-hr]
Engine speed % Engine load % ---------------------------------------------- Reduction %
Engine out w/CDPF
----------------------------------------------------------------------------------------------------------------
100 100 0.059 0.10 83
100 75 0.103 0.009 91
100 50 0.247 0.012 95
100 25 0.247 0.000 100
100 10 0.925 0.031 97
60 100 0.028 0.011 61
60 75 0.138 0.009 93
60 50 0.180 0.010 95
60 25 0.370 0.007 98
60 10 0.801 0.018 98
91 82 0.091 0.006 93
80 63 0.195 0.008 96
63 40 0.240 0.008 97
0 0 ..................... ..................... ....................
(\1\) 0.127 0.011 91
----------------------------------------------------------------------------------------------------------------
ISO C1 Composite.
The second engine tested was a prototype engine developed at
Southwest Research Institute (SwRI) under contract to EPA.\178\ The
engine, dubbed Deere Development Engine 4045 (DDE-4045) because the
prototype engine was based on a John Deere 4045 production engine, was
also tested with a CDPF from a different manufacturer on the same 12
ppm diesel fuel. The engine is very much a prototype and experienced a
number of part failures during testing, including to the turbocharger
actuator. Nevertheless, the transient emission results summarized in
Table III.E-3 and the steady-state results summarized in Table III.E-4
show that substantial PM reductions are realized on this engine as
well. The emission levels on the NRTC and the ISO C1 cycle would be
compliant with the proposed PM standard of 0.01 g/bhp-hr once the
appropriate rounding convention was applied.\179\ It is also
interesting to note that the highway FTP transient emissions are higher
than for either of the proposed nonroad transient tests. This suggests
that developing PM compliant engines on the proposed nonroad transient
cycles may not be substantially different from developing compliant
technologies for highway engines. Our analysis of exhaust temperature
characteristics for NOX adsorber catalysts discussed in the
preceding section, noted a similar trend for NOX
technologies (i.e., that the exhaust temperature characteristics of the
NRTC may be better matched catalyst technologies than the HD FTP).
---------------------------------------------------------------------------
\178\ ``Nonroad Diesel Emission Standards--Staff Technical
Paper'', EPA Publication EPA420-R-01-052, October 2001. Copy
available in EPA Air Docket A-2001-28.
\179\ The rounding procedures in ASTM E29-90 are applied to the
emission standard, therefore, the emission results are rounded to
the same number of significant digits as the specified standard,
i.e., 0.014 g/bhp-hr is rounded to 0.01 g/bhp-hr, while 0.015 g/bhp-
hr would be rounded to 0.02 g/bhp-hr.
---------------------------------------------------------------------------
[[Page 28383]]
[GRAPHIC] [TIFF OMITTED] TP23MY03.005
As with the results from the Caterpillar engine, the two low-load
(10 percent load) steady-state emissions points have some of the
highest brake specific emission rates. These rates are not high enough,
however, to preclude compliance with the steady-state emission cycle,
are not within the proposed NTE zone, and still show substantial PM
reduction levels.
[GRAPHIC] [TIFF OMITTED] TP23MY03.006
[[Page 28384]]
While the resulting PM emission levels for nonroad diesel engines
are similar to the levels for highway diesel engines, the challenge of
ensuring soot regeneration of the CDPF may be more difficult for some
nonroad equipment types. As explained earlier, effective regeneration
occurs when the aggregate soot rate into the CDPF over an extended
period is less than or equal to the soot oxidation rate over the same
period. Because the baseline PM soot rate into the CDPF level may be
higher for some nonroad engines and because the average exhaust
temperature may be lower for some operating cycles, additional engine
and aftertreatment system development will be needed for some nonroad
engines. These additional developments include improved thermal
management and improved active back-up systems which can periodically
raise exhaust temperatures in order to initiate regeneration. We expect
these systems to be evolutionary advancements based primarily on the
core technologies used by nonroad manufacturers to comply with the Tier
3 emission standards with enhancements from the highway technologies
developed to comply with the HD2007 standards. The implementation dates
for the standards proposed today were selected in part based upon the
time we believe will be necessary to transfer and further develop these
highway technologies to nonroad diesel engines and equipment.
We are proposing a NOX standard of 0.3 g/bhp-hr for
engines in this category based upon the emission reductions possible
from the application of NOX adsorber catalysts and the
expected emission levels for Tier 3 compliant engines which form the
baseline technology for Tier 4 engines. The Tier 3 emission standards
are a combined NOX+NMHC standard of 3.0 g/bhp-hr for engines
greater than 100 hp and less than 750 horsepower. For engines less than
100 hp but greater than 50 horsepower the Tier 3 NOX+NMHC
emission standard is 3.5 g/bhp-hr. For engines greater than 750
horsepower there is no Tier 3 NOX+NMHC standard. We believe
that in the time-frame of the Tier 4 emission standards proposed today,
all engines of 75 horsepower or higher can be developed to control
NOX emissions to engine-out levels of 3.0 g/bhp-hr or lower.
This means that all engines will need to apply Tier 3 emission control
technologies (i.e., turbochargers, charge-air-coolers, electronic fuel
systems, and for some manufacturers EGR systems) to get to this
baseline level, even those engines without a Tier 3 standard (i.e.,
750hp engines). As discussed in more detail in the draft
RIA, our analysis of the NRTC and the ISO C1 cycles indicates that the
NOX adsorber catalyst can provide a 90 percent or greater
NOX reduction level on the cycles. The proposed standard of
0.3 g/bhp-hr reflects a baseline emissions level of 3.0 g/bhp-hr and a
90 percent or greater reduction of NOX emissions through the
application of the NOX adsorber catalyst. The additional
lead time available to nonroad engine manufacturers and the substantial
learning that will be realized from the introduction of these same
technologies to highway diesel engines, plus the lack of any
fundamental technical impediment, makes us confident that the proposed
NOX standards can be met.
The proposed standard is 50 percent higher than the corresponding
HD2007 standard of 0.2 g/bhp-hr because of the higher baseline
NOX emissions for Tier 3 engines. The higher baseline
(engine-out) NOX level is due primarily to a lack of ram-air
for improved charge-air cooling for nonroad diesel engines when
compared to highway diesel engines compliant with the 2004 highway
emission standards. Although nonroad engine manufacturers may be able
to lower engine-out NOX emissions below the levels required
for Tier 3, we continue to expect that the lack of ram air will limit
nonroad engine-out NOX performance, and therefore we have
accounted for that difference by proposing this higher NOX
emissions level.
We believe that the NOX adsorber technology developed
for highway engines can be applied with equal effectiveness to nonroad
diesel engines with additional developments in engine thermal
management (as discussed in section III.E.2 above) to address the more
widely varied nonroad operating cycles. In fact, as discussed
previously, the NOX adsorber catalyst temperature window is
particularly well matched to transient operating conditions as typified
by the NRTC.
Compliance with the NTE provisions proposed today will be
challenging for the nonroad engine industry due to the diversity of
nonroad products and operating cycles. However, the technical challenge
is reduced somewhat by the 1.5 multiplier used to calculate the NTE
standard. Controlling NOX emissions under NTE conditions is
fundamentally similar for both highway and nonroad engines. The range
of control is the same and the amount of reduction required is also the
same. We know of no technical impediment that would prevent achieving
the NTE standard under the full range of operating conditions.
The proposed NOX standard is phased in over a number of
years in a manner similar to the HD2007 NOX phase-in. In the
early years of the program half of the engines produced by a
manufacturer must be certified to the new emission standard while the
remaining engines can continue to be sold at the previous standard. We
provided this phase-in period for highway engines in the HD2007
rulemaking to allow manufacturers to focus resources on the portion of
their products best suited to NOX catalysts first and then
to apply the learning to the remainder of their products three years
later.\180\ Provisions of the averaging program in the HD2007
rulemaking allow manufacturers to alternatively comply with some engine
families at an ``averaged'' standard that is approximately halfway
between the old and new NOX standards. In fact, we have
learned from a number of engine manufacturers that they are likely to
employ this strategy for some fraction of their new highway engines in
2007. The averaging provisions that we have proposed today for Tier 4
would also allow for compliance with the proposed Tier 4 NOX
standard with a single engine product during the transitional
NOX phase-in period. This provision allows manufacturers to
transfer the same highway NOX technologies to nonroad
engines and to comply with an appropriately stringent standard. We
believe as with the HD2007 rule that this provision is necessary in
order to manage resource requirements to develop the necessary
technologies and that this provision provides significant additional
flexibility for manufacturers to comply with the proposed
NOX standards. Similarly, we have proposed a modified phase-
in schedule for the greater than 750 horsepower engines in part because
of the lack of a Tier 3 standard for those engine and the extra work
required to develop a full Tier 4 emission control system from a Tier 2
baseline.
---------------------------------------------------------------------------
\180\ Control of Air Pollution from New Motor Vehicles: Heavy-
duty Engine and Vehicle Standards and Highway Diesel Sulfur Control
Requirements; Final Rule, 66 FR 5002, January 18, 2001.
---------------------------------------------------------------------------
Meeting the proposed NMHC standard under the lean operating
conditions typical of the biggest portion of NOX adsorber
operation should not present any special challenges to nonroad diesel
engine manufacturers. Since CDPFs and NOX adsorbers contain
platinum and other precious metals to oxidize NO to NO2,
they are also very efficient oxidizers of hydrocarbons. NMHC reductions
of greater than 95 percent have been shown over transient
[[Page 28385]]
and steady-state test procedures.\181\ Given that typical engine-out
NMHC is expected to be in the 0.40 g/bhp-hr range or lower for engines
meeting the Tier 3 standards, this level of NMHC reduction will mean
that under lean conditions emission levels will be well below the
standard.
---------------------------------------------------------------------------
\181\ ``The Impact of Sulfur in Diesel Fuel on Catalyst Emission
Control Technology,'' report by the Manufacturers of Emission
Controls Association, March 15, 1999, pp. 9 & 11. Copy available in
EPA Air Docket A-2001-28.
---------------------------------------------------------------------------
The NOX regeneration strategies for the NOX
adsorber technology may prove difficult to control precisely, leading
to a possible increase in NMHC emissions under the rich operating
conditions required for NOX regeneration. Even with precise
control of the regeneration cycle, NMHC slip may prove to be a
difficult problem due to the need to regenerate the NOX
adsorber under net rich conditions (excess fuel) rather than the
stoichiometric (fuel and air precisely balanced) operating conditions
typical of a gasoline three-way catalyst. It seems possible therefore,
that in order to meet the NMHC standards we have proposed, an
additional clean up catalyst may be required. A diesel oxidation
catalyst, like those applied historically for NMHC and partial PM
control, can reduce NMHC emissions (including toxic HCs) by more than
90 percent.\182\ This amount of additional control along with optimized
NOX regeneration strategies will ensure very low NMHC
emissions. Our cost analysis described in section V includes the cost
for the application of a clean-up DOC catalyst for all engines which
must comply with the 0.3 g/bhp-hr NOX standard.
---------------------------------------------------------------------------
\182\ ``Demonstration of Advanced Emission Control Technologies
Enabling Diesel-Powered Heavy-Duty Engines to Achieve Low Emission
Levels'', Manufacturers of Emissions Controls Association, June
1999. Copy available in EPA Air Docket A-2001-28.
---------------------------------------------------------------------------
Test results from a prototype integrated NOX/PM and NMHC
control system for diesel engines documented in the draft RIA show that
NMHC emissions can be controlled below 0.14 g/bhp-hr under transient
and steady-state test conditions for highway diesel engines while
simultaneously controlling NOX emissions below 0.2 g/bhp-hr
and PM emissions below 0.01 g/bhp-hr. Since the slip of hydrocarbon
emissions are predominantly a function of the NOX
regeneration event and not engine transient events, the level of
control demonstrated in this testing is expected to be the same for
other operating conditions as represented by the proposed NRTC cycle
and the NTE provisions of this rulemaking. Based on our engineering
judgement and experience testing integrated NOX adsorber and
PM filter systems with DOC clean-up catalyst technologies, we can
conclude that the 0.14 g/bhp-hr NMHC standard will be feasible in the
Tier 4 time frame.
The proposed standards include a cold start provision with the
transient test procedures. This means that the results of a cold start
transient test will be weighted with the emissions of a hot start test
in order to calculate the emissions for compliance against the proposed
standards. The proposed weightings are 1/10 cold start and 9/10 for the
hot start as described more fully in chapter 4.2 of the draft RIA.
Because exhaust temperatures are so important to catalyst performance
the cold start provision is an important tool to ensure that the
emissions realized in use are consistent with the expectations of this
program and represents an additional technical challenge for
NOX control and to a lesser extent CO and NMHC control. PM
control with a CDPF is not expected to be significantly impacted by
cold-start provisions. NOX control in the period before
temperatures exceed the catalyst light-off temperature are reduced
significantly. As a result, exhaust stack NOX emissions will
be higher over the cold start portion of the test. However, we believe
that this increase in NOX emissions will not be high enough
to preclude compliance with the proposed NOX standard once
the 1/10 weighting is applied.
There are a number of technologies available to the engine
manufacturer to promote rapid warmup of the exhaust and emission
control system. These include retarding injection timing, increasing
EGR, and potentially late cycle injection all of which are technologies
we expect manufacturers to apply as part of the normal operation of the
NOX adsorber catalyst system. These are the same
technologies we expect highway engine manufacturers to use in order to
comply with the highway cold start FTP provision which weights cold
start emissions more heavily with a 1/7 weighting. As a result, we
expect the transfer of highway technology to be well matched to
accomplish this control need for nonroad engines as well. Using these
technologies we expect nonroad engine manufacturers to be able to
comply with the proposed NOX, NMHC and CO emissions
including the cold start provisions of the transient test procedure.
We did not set new Tier 3 emission standards for 750 hp
nonroad engines in the 1998 Tier \2/3\ rulemaking because of the long
lead time we believed appropriate, given the long product redesign
cycles typical of these large engines and their low sales volumes. The
Tier 2 standards set in that rulemaking for 750 hp engines
do not go into effect until 2006. We reasoned in the Tier \2/3\ rule
that the uncertainties involved in setting a Tier 3 standard for
750hp nonroad engines that wouldn't go into effect before
2010 would be too large. Therefore, we deferred setting new standards
for these engines at that time. Given new technology enabled by low
sulfur diesel fuel, we believe that it is now appropriate to project
the technologies which will be available for these engines in the
future (i.e., CDPFs and NOX adsorbers) and to set new
standards accordingly.
Although we have proposed a unique phase-in schedule for
750hp engines as explained in section III.B, we do not doubt
that these engines, like engines <750hp, can be developed to meet the
standards proposed today. These large engines are fundamentally similar
to other nonroad engines. The project emissions control mechanisms are
the same. Retrofits of PM filter systems have been applied to large
locomotives and other similar size engines. We are unaware of any
fundamental difference in technology function that would lead us to
conclude that the proposed standards are inappropriate for engines
750hp. However, given the need to apply both new engine-out
control technologies (i.e., Tier 3 type technologies) in addition to
the new catalyst based technologies in order to comply with the
proposed standards, and given the low sales volumes for these engines,
we do believe it is appropriate to have a different phase-in structure
for these engines. We invite comment supported by data on this issue,
particularly if a commenter believes there are fundamental technology
differences which would make alternate standards more appropriate for
750hp nonroad engines.
The standards that we have proposed today for nonroad engines with
rated horsepower levels =75 horsepower are based upon the
same emission control technologies, clean 15ppm or lower sulfur diesel
fuel, and relative levels of emission control effectiveness as the HD
2007 emission standards. We have given consideration to the diversity
of nonroad equipment for which these technologies must be developed and
the timing of the Tier 3 emissions standards in determining the
appropriate timing for the Tier 4 standards we have proposed today.
Based upon the availability of the emission control technologies, the
proven effectiveness of the technologies to control diesel emissions to
these levels, the technology
[[Page 28386]]
paths identified here to address constraints specific to nonroad
equipment, and the additional lead time afforded by the timing of the
standards, we have concluded that the proposed standards are feasible.
4. Are the Standards Proposed for Engines =25 hp and <75 hp
Feasible?
As discussed in section III.B, our proposal for standards for
engines between 25 and 75 hp consists of a 2008 transitional standard
and long-term 2013 standards. The proposed transitional standard is a
0.22 g/bhp-hr PM standard. The 2013 standards consist of a 0.02 g/bhp-
hr PM standard and a 3.5 g/bhp-hr NMHC+NOX standard. As
discussed in section III.B, the transitional standard is optional for
50-75 hp engines, as the proposed 2008 implementation date is the same
as the effective date of the Tier 3 standards. Manufacturers may
decide, at their option, not to undertake the 2008 transitional PM
standard, in which case their implementation date for the 0.02 g/bhp-hr
PM standard begins in 2012.
In addition, we have proposed a minor revision to the CO standard
for the 25-50 hp engines beginning in 2008 to align these engines with
the 50-75 hp engines. This proposed CO standard is 3.7 g/bhp-hr.
The remainder of this section discusses:
[sbull] What makes the 25-75 hp category unique;
[sbull] What engine technology is used today, and will be used for
applicable Tier 2 and Tier 3 standards;
[sbull] Why the proposed standards are technologically feasible;
and,
[sbull] Why EPA has not proposed more stringent NOX
standards at this time for these engines.
a. What makes the 25--75 hp category unique?
As discussed in section III.B.1.d, many of the nonroad diesel
engines =75 hp are either a direct derivative of highway
heavy-duty diesel engines, or share a number of common traits with
highway diesel engines. These include similarities in displacement,
aspiration, fuel systems, and electronic controls. Table III.E-3
contains a summary of a number of key engine parameters from the 2001
engines certified for sale in the U.S.\183\
---------------------------------------------------------------------------
\183\ Data in Table III.E-3 is derived from a combination of the
publically available certification data for model year 2001 engines,
as well as the manufacturers reported estimates of 2001 production
targets, which is not public information.
Table III.E-3: Summary of Model Year 2001 Key Engine Parameters by Power Category
----------------------------------------------------------------------------------------------------------------
Percent of 2001 U.S. Production \a\
---------------------------------------------------------------
Engine Parameter 100
0-25 hp 25-75 hp 75-100 hp hp
----------------------------------------------------------------------------------------------------------------
IDI Fuel System................................. 83% 47% 4% <0.1%
DI Fuel System.................................. 17% 53% 96% 99%
Turbocharged.................................... 0% 7% 62% 91%
1 or 2 Cylinder Engines......................... 47% 3% 0% 0%
Electronic fuel systems (estimated)............. not available limited availability commonly
today available today available
today today
----------------------------------------------------------------------------------------------------------------
Notes:
\a\ Based on sales weighting of 2001 engine certification data.
As can be seen in Table III.E-3, the engines in the 25-75 hp
category have a number of technology differences from the larger
engines. These include a higher percentage of indirect-injection fuel
systems, and a low fraction of turbocharged engines. (The distinction
in the <25 hp category is quite different, with no turbocharged
engines, nearly one-half of the engines have two cylinders or less, and
a significant majority of the engines have indirect-injection fuel
systems.)
The distinction is particularly marked with respect to
electronically controlled fuel systems. These are commonly available in
the = 75 hp power categories, but, based on the available
certification data as well as our discussions with engine
manufacturers, we believe there are very limited numbers, if any, in
the 25-75 hp category (and no electronic fuel systems in the less than
25 hp category). The research and development work being performed
today for the heavy-duty highway market is targeted at engines which
are 4-cylinders or more, direct-injection, electronically controlled,
turbocharged, and with per-cylinder displacements greater than 0.5
liters. As discussed in more detail below, as well as in section
III.E.5 (regarding the <25 hp category), these engine distinctions are
important from a technology perspective and warrant a different set of
standards for the 25-75 hp category (as well as for the <25 hp
category).
b. What Engine Technology Is Used Today, and Will Be Used for the
Applicable Tier 2 and Tier 3 Standards?
In the 1998 nonroad diesel rulemaking, we established Tier 1 and
Tier 2 standards for engines in the 25-50 hp category. Tier 1 standards
were implemented in 1999, and the Tier 2 standards take effect in 2004.
The 1998 rule also established Tier 2 and Tier 3 standards for engines
between 50 and 75 hp. The Tier 2 standards take effect in 2004, and the
Tier 3 standards take effect in 2008. The Tier 1 standards for engines
between 50 and 75 hp took effect in 1998. Therefore, all engines in the
25-75 hp range have been meeting Tier 1 standards for the past several
years, and the data presented in Table III.E-3 represent performance of
Tier 1 technology for this power range.
As discussed in section III.E.4.a, engines in the 25-75 hp category
use either indirect injection (IDI) or direct injection (DI) fuel
systems. The IDI system injects fuel into a pre-chamber rather than
directly into the combustion chamber as in the DI system.\184\ This
difference in fuel systems results in substantially different emission
characteristics, as well as differences in several important operating
parameters. In general, the IDI engine has lower engine-out PM and
NOX emissions, while the DI engine has better fuel
efficiency and lower heat rejection.\185\
---------------------------------------------------------------------------
\184\ See for example ``Diesel-engine Management'' published by
Robert Bosch GmbH, 1999, second edition, pages 6-8 for a more
detailed discussion of the differences between IDI and DI engines.
\185\ See chapter 14, section 4 of ``Turbocharging the Internal
Combustion Engine'', N. Watson and M.S. Janota, published by John
Wiley and Sons, 1982.
---------------------------------------------------------------------------
We expect a significant shift in the engine technology which will
be used in this power category as a result of the upcoming Tier 2 and
Tier 3 standards, in particular for the 50-75 hp engines. In the 50-75
hp category, the 2008 Tier
[[Page 28387]]
3 standards will likely result in the significant use of turbocharging
and electronic fuel systems, as well as the introduction of both cooled
and uncooled exhaust gas recirculation by some engine manufacturers and
possibly the use of charge-air-cooling.\186\ In addition, we have heard
from some engine manufacturers that the engine technology used to meet
Tier 3 for engines in the 50-75 hp range will also be made available on
those engines in the 25-50 hp range which are built on the same engine
platform. For the Tier 2 standards for the 25-50 hp products, a large
number of engines meet these standards today, and therefore we expect
to see only moderate changes in these engines, including the potential
additional use of turbocharging on some models.\187\
---------------------------------------------------------------------------
\186\ See section 2.2 through 2.3 in ``Nonroad Diesel Emission
Standards--Staff Technical Paper'', EPA Publication EPA420-R-01-052,
October 2001. Copy available in EPA Air Docket A-2001-28.
\187\ See Table 3-2 in ``Nonroad Diesel Emission Standards--
Staff Technical Paper'', EPA Publication EPA420-R-01-052, October
2001. Copy available in EPA Air Docket A-2001-28.
---------------------------------------------------------------------------
c. Are the Proposed Standards for 25-75 hp Engines Technologically
Feasible?
This section will discuss the technical feasibility of both the
proposed 2008 PM standard and the 2013 standards. For an explanation
and discussion of the proposed implementation dates, please refer to
section III.B of this this proposal.
i. 2008 PM Standards.\188\ As just discussed in section III.E.4.b,
engines in the 25-50 hp category must meet Tier 1 NMHC+NOX
and PM standards today. We have examined the model year 2002 engine
certification data for engines in the 25-50 hp category. These data
indicate that over 10 percent of the engine families meet the proposed
2008 0.22 g/bhp-hr PM standard and 5.6 g/bhp-hr NMHC+NOX
standard (unchanged from Tier 2 in 2008) today. These include a variety
of engine families using a mix of engine technologies (IDI and DI,
turbocharged and naturally aspirated) tested on a variety of
certification test cycles.\189\ Five engine families are more than 20
percent below the proposed 0.22 g/bhp-hr PM standard, and an additional
24 engine families are within 30 percent of the proposed 2008 PM
standards while meeting the NMHC+NOX standard. A detailed
discussion of these data is contained in the draft RIA. Unfortunately,
similar data do not exist for engines between 50 and 75 hp. There is no
Tier 1 PM standard for engines in this power range, and therefore
engine manufacturers are not required to report PM emission levels
until Tier 2 starts in 2004. However, in general, the 50-75 hp engines
are more technologically advanced than the smaller horsepower engines
and would be expected to perform as well as, if not better than, the
engines in the 25-50 hp range.
---------------------------------------------------------------------------
\188\ As discussed in section III.B., manufacturers can choose,
at their option, to pull-ahead the 2013 PM standard for the 50-75 hp
engines to 2012, in which case they do not need to comply with the
transitional 2008 PM standard.
\189\ The Tier 1 standards for this power category must be
demonstrated on one of a variety of different engine test cycles.
The appropriate test cycle is selected by the engine manufacturer
based on the intended in-use application of the engine.
---------------------------------------------------------------------------
The model year 2002 engines in this power range use well known
engine-out emission control technologies, such as optimized combustion
chamber design and fuel injection timing control strategies, to comply
with the existing standards. These data have a two-fold significance.
First, they indicate that a number of engines in this power range can
already achieve the proposed 2008 standard for PM using only engine-out
technology, and that other engines should be able to achieve the
standard making improvements just to engine-out performance. Despite
being certified to the same emission standards with similar engine
technology, the emission levels from these engines vary widely. Figure
III.E-1 is a graph of the model year 2002 HC+NOX and PM data
for engines in the 25-50 hp range. As can be seen in the figure, the
emission levels cover a wide range. Figure III.E-1 highlights a
specific example of this wide range: engines using naturally aspirated
DI technology and tested on the 8-mode test cycle. Even for this subset
of DI engines achieving approximately the same HC+NOX level
of [sim]6.5 g/bhp-hr, the PM rates vary from approximately 0.2 to more
than 0.5 g/bhp-hr. There is limited information available to indicate
why for these small diesel engines with similar technology operating at
approximately the same HC+NOX level the PM emission rates
cover such a broad range. We are therefore not predicating the proposed
2008 PM standard on the combination of diesel oxidation catalysts and
the lowest engine-out emissions being achieved today, because it is
uncertain whether or not additional engine-out improvements would lower
all engines to the proposed 2008 PM standard. Instead, we believe there
are two likely means by which companies can comply with the proposed
2008 PM standard. First, some engine manufacturers can comply with this
standard using known engine-out techniques (e.g., optimizing combustion
chamber designs, fuel-injection strategies). However, based on the
available data it is unclear whether engine-out techniques will work in
all cases. Therefore, we believe some engine companies will choose to
use a combination of engine-out techniques and diesel oxidation
catalysts, as discussed below.
[[Page 28388]]
[GRAPHIC] [TIFF OMITTED] TP23MY03.007
For those engines which do not already meet the proposed 2008 Tier
4 PM standard, a number of engine-out technologies are available to
achieve the standards by 2008. In our recent Staff Technical Paper on
the feasibility of the Tier 2 and Tier 3 standards, we projected that
in order to comply with the Tier 3 standards, engines greater than 50
hp would rely on some combination of a number of technologies,
including electronic fuel systems such as electronic rotary pumps or
common-rail fuel systems.\190\ In addition to enabling the Tier 3
NMHC+NOX standards, electronic fuel systems with high
injection pressure and the capability to perform pilot-injection and
rate-shaping, have the potential to substantially reduce PM
emissions.\191\ Even for mechanical fuel systems, increased injection
pressures can reduce PM emissions substantially.\192\ As discussed
above, we are projecting that the Tier 3 engine technologies used in
engines between 50 and 75 hp, such as turbocharging and electronic fuel
systems, will make their way into engines in the 25-50 hp range.
However, we do not believe this technology will be required to achieve
the proposed 2008 PM standard. As demonstrated by the 2002
certification data, engine-out techniques such as optimized combustion
chamber design, fuel injection pressure increases and fuel injection
timing can be used to achieve the proposed standards for many of the
engines in the 25-75 hp category without the need to add turbocharging
or electronic fuel systems.
---------------------------------------------------------------------------
\190\ See section 2.2 through 2.3 in ``Nonroad Diesel Emission
Standards--Staff Technical Paper'', EPA Publication EPA420-R-01-052,
October 2001. Copy available in EPA Air Docket A-2001-28.
\191\ Ikegami, M., K. Nakatani, S. Tanaka, K. Yamane: ``Fuel
Injection Rate Shaping and Its Effect on Exhaust Emissions in a
Direct-Injection Diesel Engine Using a Spool Acceleration Type
Injection System'', SAE paper 970347, 1997. Dickey D.W., T.W. Ryan
III, A.C. Matheaus: ``NOX Control in Heavy-Duty Engines--
What is the Limit?'', SAE paper 980174, 1998. Uchida N, K.
Shimokawa, Y. Kudo, M. Shimoda: ``Combustion Optimization by Means
of Common Rail Injection System for Heavy-Duty Diesel Engines'', SAE
paper 982679, 1998.
\192\ ``Effects of Injection Pressure and Nozzle Geometry on DI
Diesel Emissions and Performance,'' Pierpont, D., and Reitz, R., SAE
Paper 950604, 1995.
---------------------------------------------------------------------------
For those engines which are not able to achieve the proposed
standards with known engine-out techniques, we project that diesel
oxidation catalysts can be used to achieve the proposed standards. DOCs
are passive flow-through emission control devices which are typically
coated with a precious metal or a base-metal washcoat. DOCs have been
proven to be durable in use on both light-duty and heavy-duty diesel
applications. In addition, DOCs have already been used to control
carbon monoxide on some nonroad applications.\193\
---------------------------------------------------------------------------
\193\ EPA Memorandum ``Documentation of the Availability of
Diesel Oxidation Catalysts on Current Production Nonroad Diesel
Equipment'', William Charmley. Copy available in EPA Air Docket A-
2001-28.
---------------------------------------------------------------------------
Certain DOC formulations can be sensitive to diesel fuel sulfur
level, and depending on the level of emission reduction necessary,
sulfur in diesel fuel can be an impediment to PM reductions. As
discussed in section III.E.1.a, precious metal oxidation catalysts can
oxidize the sulfur in the fuel and form particulate sulfates. However,
even with today's high sulfur nonroad fuel, some manufacturers have
demonstrated that a properly formulated DOC can be used to achieve the
existing Tier 2 PM standards for larger engines (i.e., the 0.15 g/bhp-
hr standard).\194\ However, given the high level of sulfur in nonroad
fuel today, the use of DOCs
[[Page 28389]]
as a PM reduction technology is severely limited. Data presented by one
engine manufacturer regarding the existing Tier 2 PM standard shows
that while a DOC can be used to meet the current standard even when
tested on 2,000 ppm sulfur fuel, lowering the fuel sulfur level to 380
ppm enabled the DOC to reduce PM by 50 percent from the 2,000 ppm
sulfur fuel.\195\ Without the availability of 500 ppm sulfur fuel in
2008, DOCs would be of limited use for nonroad engine manufacturers and
would not provide the emissions necessary to meet the proposed
standards for most engine manufacturers. With the availability of 500
ppm sulfur fuel, DOC's can be designed to provide PM reductions on the
order of 20 to 50%, while suppressing particulate sulfate reduction.
These levels of reductions have been seen on transient duty cycles as
well as highway and nonroad steady-state duty cycles.\196\ As discussed
in section VII of this preamble, the 2008 PM standard must be met on
the existing nonroad steady-state cycle, the supplemental standards
(nonroad transient cycle and NTE) are not implemented until 2013 for
this power category. As discussed above, 24 engine families in the 25-
50 hp range are within 30 percent of the proposed 2008 PM standard and
are at or below the 2008 NMHC+NOX standard for this power
range, indicating that use of DOCs should readily achieve the
incremental improvement necessary to meet the proposed 2008 PM
standard.
---------------------------------------------------------------------------
\194\ See Table 2-4 in ``Nonroad Diesel Emission Standards--
Staff Technical Paper'', EPA Publication EPA420-R-01-052, October
2001. Copy available in EPA Air Docket A-2001-28.
\195\ See Table 2-4 in ``Nonroad Diesel Emission Standards--
Staff Technical Paper'', EPA Publication EPA420-R-01-052, October
2001. Copy available in EPA Air Docket A-2001-28.
\196\ ``Demonstration of Advanced Emission Control Technologies
Enabling Diesel-Powered Heavy-duty Engines to Achieve Low Emission
Levels: Interim Report Number 1--Oxidation Catalyst Technology, copy
available in EPA Air Docket A-2001-28. ``Reduction of Diesel Exhaust
Emissions by Using Oxidation Catalysts,'' Zelenka et al., SAE Paper
90211, 1990. See Table 2-4 in ``Nonroad Diesel Emission Standards--
Staff Technical Paper'', EPA Publication EPA420-R-01-052, October
2001, copy available in EPA Air Docket A-2001-28.
---------------------------------------------------------------------------
Based on the existence of a number of engine families which already
comply with the proposed 0.22 g/bhp-hr PM standard (and the 2008
NMHC+NOX standard), and the availability of well known PM
reduction technologies such as engine-out improvements and diesel
oxidation catalysts, we project the proposed 0.22 g/bhp-hr PM standards
is technologically feasible by model year 2008. All of these are
conventional technologies which have been used on both highway and
nonroad diesel engines in the past. As such, we do not expect there to
be any negative impacts with respect to noise or safety. In addition,
PM reduction technologies such as improved combustion through the use
of higher pressure fuel injection systems have the potential to improve
fuel efficiency. DOCs are not predicted to have any substantial impact
on fuel efficiency.
As discussed in section III.B, we have also proposed a minor change
in the CO standard for the 25-50 hp engines, in order to align it with
the standard for the 50-75 hp engines. As discussed in section III.B.,
this small change in the CO standard is intended to simplify EPA's
regulations as part of our decision to propose a reduction in the
number of engine power categories for Tier 4. The current CO standard
for this category is 4.1 g/bhp-hr, and the proposed standard is 3.7 g/
bhp-hr (i.e., the current standard for engines in the 50-75 hp range).
The model year 2002 certification data shows that more than 95 percent
of the engine families in the 25-50 hp engine range meet the proposed
CO standard today. In addition, a recent EPA test program run by a
contractor on two nonroad diesel engines in this power range showed
that CO emissions were well below the proposed standards not only when
tested on the existing steady-state 8-mode test procedure, but also
when tested on the nonroad transient duty cycle we are proposing in
today's action.\197\ Finally, DOCs typically reduce CO emissions on the
order of 50 percent or more, on both transient and steady-state
conditions.\198\ Given that more than 95 percent of the engines in this
category meet the proposed standard today, and the ready availability
of technology which can easily achieve the proposed standard, we
project this CO standard will be achievable by model year 2008.
---------------------------------------------------------------------------
\197\ See Tables 6, 8, and 14 of ``Nonroad Emission Study of
Catalyzed Particulate Filter Equipped Small Diesel Engines'
Southwest Research Institute, September 2001. Copy available in EPA
Air Docket A-2001-28.
\198\ ``Demonstration of Advanced Emission Control Technologies
Enabling Diesel-Powered Heavy-duty Engines to Achieve Low Emission
Levels: Interim Report Number 1--Oxidation Catalyst Technology and
``Reduction of Diesel Exhaust Emissions by Using Oxidation
Catalysts'', P. Zelenka et al., Society of Automotive Engineers
paper 902111, October 1990.
---------------------------------------------------------------------------
ii. 2013 Standards
For engines in the 25-50 range, we are proposing standards
commencing in 2013 of 3.5 g/bhp-hr for NMHC+NOX and 0.02 g/
bhp-hr for PM. For the 50-75 hp engines, we are proposing a 0.02 g/bhp-
hr PM standard which will be implemented in 2013, and for those
manufacturers who choose to pull-ahead the standard one-year, 2012
(manufacturers who choose to pull-ahead the 2013 standard for engine in
the 50-75 range do not need to comply with the transitional 2008 PM
standard).
PM Standard
Sections III.E.1 through III.E.3 have already discussed catalyzed
diesel particulate filters, including explanations of how CDPFs reduce
PM emissions, and how to apply CDPFs to nonroad engines. We concluded
there that CDPFs can be used to achieve the proposed PM standard for
engines =75 hp. As also discussed in section III.E.2.a, PM
filters will require active back-up regeneration systems for many
nonroad applications above and below 75 hp because low temperature
operation is an issue across allpower categories. A number of secondary
technologies are likely required to enable proper regeneration,
including possibly electronic fuel systems such as common rail systems
which are capable of multiple post-injections which can be used to
raise exhaust gas temperatures to aid in filter regeneration.
Particulate filter technology, with the requisite trap regeneration
technology, can also be applied to engines in the 25 to 75 hp range.
The fundamentals of how a filter is able to reduce PM emissions as
described in section III.E.1. are not a function of engine power, and
CDPF's are just as effective at capturing soot emissions and oxidizing
SOF on smaller engines as on larger engines. As discussed in more
detail below, particulate sulfate generation rates are slightly higher
for the smaller engines, however, we have addressed this issue in our
proposal. The PM filter regeneration systems described in section
III.E.1 and 2 are also applicable to engines in this size range and are
therefore likewise feasible. There are specific trap regeneration
technologies which we believe engine manufacturers in the 25-75 hp
category may prefer over others. Specifically, an electronically-
controlled secondary fuel injection system (i.e., a system which
injects fuel into the exhaust upstream of a PM filter). Such a system
has been commercially used successfully by at least one nonroad engine
manufacturer, and other systems have been tested by technology
companies.\199\
---------------------------------------------------------------------------
\199\ ``The Optimized Deutz Service Diesel Particulate Filter
System II'', H. Houben et al., SAE Technical Paper 942264, 1994 and
``Development of a Full-Flow Burner DPF System for Heavy Duty Diesel
Engines, P. Zelenka et al., SAE Technical Paper 2002-01-2787, 2002.
---------------------------------------------------------------------------
We are, however, proposing a slightly higher PM standard (0.02 g/
bhp-hr rather than 0.01) for these engines. As discussed in section
III.E.1.a, with the
[[Page 28390]]
use of a CDPF, the PM emissions emitted by the filter are primarily
derived from the fuel sulfur. The smaller power category engines tend
to have higher fuel consumption than larger engines. This occurs for a
number of reasons. First, the lower power categories include a high
fraction of IDI engines which by their nature consume approximately 15
percent more fuel than a DI engine. Second, as engine displacements get
smaller, the engine's combustion chamber surface-to-volume ratio
increases. This leads to higher heat-transfer losses and therefor lower
efficiency and higher fuel consumption. In addition, frictional losses
are a higher percentage of total power for the smaller displacement
engines which also results in higher fuel consumption. Because of the
higher fuel consumption rate, we expect a higher particulate sulfate
level, and therefore we have proposed a 0.02 g/bhp-hr standard.
Test data confirm that this proposed standard is achievable. In
2001, EPA completed a test program run by a contractor on two small
nonroad diesel engines (a 25 hp IDI engine and a 50 hp IDI engine)
which demonstrated the proposed 0.02 g/bhp-hr standard can be achieved
with the use of a CDPF.\200\ This test program included testing on the
existing 8-mode steady-state test cycle as well as the nonroad
transient cycle proposed in today's action. The 0.02g/bhp-hr level was
achieved on each engine over both test cycles. One of the engines was
also tested on the proposed constant speed, variable load transient
cycle with a particulate filter, and this engine also met the proposed
0.02 g/bhp-hr PM standard.\201\ This test program also demonstrates why
EPA has proposed a slightly higher PM standard for the 25-75 hp
category (0.02 g/bhp-hr vs 0.01). The data from the test program
described above showed fuel consumption rates over the 8-mode test
procedure between 0.4 and 0.5 lbs/bhp-hr, while typical values for a
modern turbocharged DI engine with 4-valves per cylinder in the
=75 hp categories are on the order of 0.3 to 0.35 lbs/hp-hr.
However, the data is less conclusive with respect to the proposed NTE
standard. The test program at SwRI included a number of individual
steady-state emission points which are within the proposed NTE control
zone for nonroad diesel engines. For most of these points, the
emissions were well below the proposed NTE standard for both engines.
However, both engines included as a test point the maximum torque test
point, and in each case the emissions were above the proposed NTE
standard. For one engine, the engine-out emissions were 1.2 g/bhp-hr PM
and when equipped with a CDPF the emissions were 0.05 g/bhp-hr. While
this is more than a 95 percent reduction in PM, 0.05 is above our
proposed NTE standard of 0.03 g/bhp-hr. The second test engine at the
maximum torque mode produced an engine-out PM value of 0.35 g/bhp-hr,
and when equipped with a CDPF the results were 0.04g/bhp-hr. While this
is nearly a 90 percent reduction in PM, the engines do not meet the
proposed NTE standard. We believe these results are a combination of
high engine-out PM emissions as well as high exhaust gas temperature.
While a CDPF is very effective at reducing PM emissions, it is not 100
percent effective. These engines would likely require additional
engine-out PM reductions at the maximum torque mode in order to comply
with the proposed NTE standard. In addition, the peak torque mode is
one of the highest exhaust gas temperature mode, and therefore one of
the highest particulate-sulfate generating modes when equipped with a
CDPF. More careful management of the engine-out temperature at this
mode, such as by altering the engines air-fuel ratio, may be necessary
to lower the engine-out temperature and comply with the proposed NTE
standard.
---------------------------------------------------------------------------
\200\ See Tables 6, 8, and 14 of ``Nonroad Emission Study of
Catalyzed Particulate Filter Equipped Small Diesel Engines''
Southwest Research Institute, September 2001. Copy available in EPA
Air Docket A-2001-28.
\201\ See Tables 8 of ``Nonroad Emission Study of Catalyzed
Particulate Filter Equipped Small Diesel Engines' Southwest Research
Institute, September 2001. Copy available in EPA Air Docket A-2001-
28. Note that the ``AWQ'' cycle specified in Table 8 is the same as
the proposed constant speed, variable load cycle.
---------------------------------------------------------------------------
NMHC+NOX Standard
We have proposed a 3.5 g/bhp-hr NMHC+NOX standard for
engines in the 25-50 hp range for 2013. This will align the
NMHC+NOX standard for engines in this power range with the
Tier 3 standard for engines in the 50-75 hp range which are implemented
in 2008. EPA's recent Staff Technical paper which reviewed the
technological feasibility of the Tier 3 standards contains a detailed
discussion of a number of technologies which are capable of achieving a
3.5 g/bhp-hr standard. These include cooled EGR, uncooled EGR, as well
as advanced in-cylinder technologies relying on electronic fuel systems
and turbocharging.\202\ These technologies are capable of reducing
NOX emission by as much as 50 percent. Given the Tier 2
NMHC+NOX standard of 5.6 g/bhp-hr, a 50 percent reduction
would allow a Tier 2 engine to comply with the 3.5 g/bhp-hr
NMHC+NOX standard proposed in this action. In addition,
because this NMHC+NOX standard is concurrent with the 0.02
g/bhp-hr PM standards which we project will be achievable with the use
of particulate filters, engine designers will have significant
additional flexibility in reducing NOX because the PM filter
will eliminate the traditional concerns with the engine-out
NOX vs. PM trade-off. Our recent highway 2004 standard
review rulemaking (see 65 FR 59896) demonstrated that a diesel engine
with advanced electronic fuel injection technology as well as
NOX control technology such as cooled EGR is capable of
complying with an NTE standard set at 1.25 times the laboratory based-
standard FTP standard. We project that the same technology (electronic
fuel systems and cooled EGR) are also capable for engine in the 25-75
hp range of complying with the proposed NTE standard of 4.4 g/bhp-hr
NMHC+NOX (1.25 x 3.5) in 2013. This is based on the broad
NOX reduction capability of cooled EGR technology, which is
capable of reducing NOX emissions across the engine
operating map by at least 30 percent even under high load
conditions.\203\
---------------------------------------------------------------------------
\202\ See section 2.2 through 2.3 in ``Nonroad Diesel Emission
Standards--Staff Technical Paper'', EPA Publication EPA420-R-01-052,
October 2001. Copy available in EPA Air Docket A-2001-28.
\203\ See section 8 of ``Control of Emissions of Air Pollution
from 2004 and Later Model Year Heavy-Duty Highway Engines and
Vehicles: Response to Comments'', EPA document EPA420-R-00-011, July
2000, and Chapter 3 of ``Regulatory Impact Analysis: Control of
Emissions of Air Pollution from Highway Heavy-duty Engines'', EPA
document EPA420-R-00-010, July 2000. Copies of both documents
available in EPA docket A-2001-28.
---------------------------------------------------------------------------
Based on the information available to EPA and presented here, and
giving appropriate consideration to the lead time necessary to apply
the technology as well, we have concluded the proposed 0.02 g/bhp-hr PM
standard for engines in the 25-75 hp category and the 3.5 g/bhp-hr
NMHC+NOX standards for the 25-50 hp engines are achievable.
d. Why EPA has not Proposed More Stringent Tier 4 NOX
Standards
Today's notice proposes to revise the NMHC+NOX standard
for engines between 25 and 50 hp to a level of 3.5 g/bhp-hr beginning
in 2013 (the same numeric level as the Tier 3 standards for engines in
the 50-75 hp range). As discussed below, we believe this standard can
be met using a variety of technologies, including but not limited to
cooled EGR. Similar technologies will be used on engines in the 50-100
hp
[[Page 28391]]
range beginning in 2008. At this time, we are not proposing further
reductions in the NOX standards for engines between 25 and
75 hp.
As discussed in section III.B.1.d, engines =75 hp are
similar to, or are direct derivatives of, highway HDDEs. As discussed
in section III.E.1-III.E.3, NOX adsorber technology is being
developed today in order to comply with the 2007 highway heavy-duty
standards. However, NOX adsorber technologies will require
additional development beyond what has occurred at this time in order
to achieve the 2007 highway standards. Section III.E.1-III.E.3 also
discuss the high degree of complexity and engine/aftertreatment
integration which will be required in order for NOX
adsorbers to be applied successfully to nonroad diesel engines.
As discussed above, and as illustrated in Table III.E-3, engines
<75 hp include a significant fraction of naturally aspirated engines
and engines with indirect-injection fuel systems, and we are not
predicting a significant shift away from IDI technology engines. Given
the relatively unsophisticated level of technology used in this power
category today, as well as our prediction that even in the 2011-13 time
frame these engines will lag significantly behind the =75 hp
engines, we believe it is appropriate not to propose NOX
adsorber based standards at this time. Rather, as discussed in section
III.H, we have proposed to undertake a technology assessment in the
2007 time frame which would evaluate the status of emission control
technologies for engines less than 75 hp, and such a review would
revisit this issue. In addition, section VI of this proposal contains
additional discussion regarding our analysis of applying NOX
adsorbers to engines in the 25-75 hp category. EPA invites further
comment on the above discussion, and also solicits comment on the cost
impacts of NOX aftertreatment devices, including unit costs,
on these engines.
5. Are the Standards Proposed for Engines <25 hp Feasible?
As discussed in section III.B, our proposal for standards for
engines less than 25 hp is a new PM standard of 0.30 g/bhp-hr beginning
in 2008. As discussed below, we are not proposing to set a new standard
more stringent than the existing Tier 2 NMHC+NOX standard
for this power category at this time. This section describes:
[sbull] What makes the <25 hp category unique;
[sbull] Engine technology currently used in the <25 hp category;
[sbull] Why the proposed standards are technologically feasible;
and,
[sbull] Why EPA has not proposed more stringent standards at this
time.
a. What Makes the <25 hp Category Unique?
Nonroad engines less than 25 hp are the least sophisticated nonroad
diesel engines from a technological perspective. All of the engines
currently sold in this power category lack electronic fuel systems and
turbochargers (see Table III.E-3). Nearly 50 percent of the products
have two-cylinders or less, and 14 percent of the engines sold in this
category are single-cylinder products, a number of these have no
batteries and are crank-start machines, much like today's simple walk
behind lawnmower engines. In addition, given what we know today and
taking into account the Tier 2 standards which have not yet been
implemented, we are not projecting any significant penetration of
advanced engine technology, such as electronically controlled fuel
systems, into this category in the next 5 to 10 years.
We have proposed a PM standard for engines in the <25 hp category
which is higher than the standard proposed for engines in the 25-75 hp
category (0.30 g/bhp-hr vs. 0.22 g/bhp-hr). We have done this for a
number of reasons. First, the existing Tier 2 PM standards specifies
standards which become numerically higher for the smaller power
categories. Specifically, for engines 175 hp, the Tier 2 PM
standard is 0.15 g/bhp-hr, which increases to 0.30 g/bhp-hr for engines
in the 50-100hp range, 0.45 g/bhp-hr for engines in the 25-50hp range,
and finally 0.60 g/bhp-hr for engines <25 hp. In the Tier 2 time frame,
engines in the higher power categories are expected to use more
sophisticated technologies such as turbocharging and high pressure
electronically controlled fuel systems. These technologies are more
capable of reducing PM emissions as compared to naturally aspirated
engines with lower pressure mechanical fuel systems. To some extent
this same trend is expected to continue in the 2008 time frame. As
discussed above, we expect that many engines in the 25-75hp engine
category will use turbocharging, and some engines will have electronic
fuel systems. However, we are not predicting that any engines in the
<25hp category will use either of these technologies. In addition, very
small diesel engines present a number of unique challenges for reducing
PM emissions. First, the smaller engines inherently have high
combustion chamber surface-to-volume ratios. This results in higher
heat loss, which results in a quenching of the oxidation process
earlier than for larger engines, and therefore higher PM emission
rates. In addition, the small diesel engines are more limited in the PM
reduction which can be achieved by higher fuel injection pressures. Due
to the very small size of the combustion chamber, high pressure
injection (which is intended to improve fuel atomization and mixing,
both of which lower PM emissions) will result in fuel impaction on the
combustion chamber, which will not improve fuel atomization. The
benefits of higher pressure fuel injection as a PM reduction technology
therefore reaches a point of diminishing returns with higher and higher
pressures, and this point of diminishing returns is reached much
quicker for the smaller engines than for the larger engines. For these
reasons we have proposed a 2008 PM standard for engines <25 hp which is
higher than the proposed 2008 PM standard for engines in the 25-75 hp
category.
b. What Engine Technology is Currently Used in the <25 hp category?
In the 1998 nonroad diesel rulemaking we established Tier 1 and
Tier 2 standards for these products. Tier 1 was implemented in model
year 2000, and Tier 2 will be implemented in model year 2005. As
discussed in EPA's recent Staff Technical Paper, we project the Tier 2
standards will be met by basic engine-out emission optimization
strategies.\204\ We are not predicting that Tier 2 will require
electronic fuel systems, EGR, or turbocharging. As discussed in the
Staff Technical Paper, a large number of engines in this power category
already meet the Tier 2 standards by a wide margin.\205\
---------------------------------------------------------------------------
\204\ See section 3 of ``Nonroad Diesel Emission Standards--
Staff Technical Paper'', EPA Publication EPA420-R-01-052, October
2001. Copy available in EPA Air Docket A-2001-28.
\205\ See Table 3-2 in ``Nonroad Diesel Emission Standards--
Staff Technical Paper'', EPA Publication EPA420-R-01-052, October
2001. Copy available in EPA Air Docket A-2001-28.
---------------------------------------------------------------------------
Two basic types of engine fuel injection technologies are currently
present in the less than 25 hp category, mechanical indirect injection
(IDI) and mechanical direct injection (DI). As discussed in section
III.D.4, the IDI system injects fuel into a pre-chamber rather than
directly into the combustion chamber as in the DI system. This
difference in fuel systems results in substantially different emission
characteristics, as well as several important operating parameters. In
general, as noted earlier, the IDI engine has lower engine-out PM and
NOX
[[Page 28392]]
emissions, while the DI engine has better fuel efficiency and lower
heat rejection.
c. What Data Indicates That the Proposed Standards Are Feasible?
We project the proposed Tier 4 PM standard can be met by 2008 based
on:
[sbull] The existence of a large number of engine families which
meet the proposed standards today;
[sbull] The use of engine-out reduction techniques; and
[sbull] The use of diesel oxidation catalysts.
We have examined the recent model year (2002) engine certification
data for nonroad diesel engines less than 25 hp. These data indicate
that a number of engine families meet the proposed Tier 4 PM standard
(and the 2008 NMHC+NOX standard, unchanged from Tier 2)
today. The current data indicates approximately 28% of the engine
families are at or below the proposed PM standard today, while meeting
the 2008 NMHC+NOX standard. These include both IDI and DI
engines, as well as a range of certification test cycles.\206\ Many of
the engine families are certified well below the proposed Tier 4
standard while meeting the 2008 NMHC+NOX level.
Specifically, 15 percent of the engine families exceed the proposed
Tier 4 PM standard by more than 20 percent. The public certification
data indicate that these engines do not use turbocharging, electronic
fuel systems, exhaust gas recirculation, or aftertreatment
technologies.
---------------------------------------------------------------------------
\206\ The Tier 1 and Tier 2 standards for this power category
must be demonstrated on one of a variety of different engine test
cycles. The appropriate test cycle is selected by the engine
manufacturer based on the intended in-use applications(s) of the
engine.
---------------------------------------------------------------------------
These model year 2002 engines use well known engine-out emission
control technologies, such as combustion chamber design and fuel
injection timing control strategies, to comply with the existing
standards. As with 25-75 hp engines, these data have a two-fold
significance. First, they indicate that a number of engines in this
power category can already achieve the proposed 2008 standard for PM
using only engine-out technology, and that other engines should be able
to achieve the standard making improvements just to engine-out
performance. Second, despite being certified to the same emission
standards with similar engine technology, the emission levels from
these engines vary widely. Figure III.E-2 is a graph of the model year
2002 HC+NOX and PM data. As can be seen in the figure, the
emission levels cover a wide range. Figure III.E-2 highlights a
specific example of this wide range: engines using naturally aspirated
IDI technology and tested on the 6-mode test cycle. Even for this
subset of IDI engines achieving approximately the same
HC+NOX level of[sim]4.5 g/bhp-hr, the PM rates vary from
approximately 0.15 to 0.5 g/bhp-hr. (A more detailed discussion of this
data is contained in the draft RIA.) There is limited information
available to indicate why for these small diesel engines with similar
technology operating at approximately the same HC+NOX level
the PM emission rates cover such a broad range. We are therefore not
predicating the proposed 2008 PM standard on the combination of diesel
oxidation catalysts and the lowest engine-out emissions being achieved
today, because it is uncertain whether or not additional engine-out
improvements would lower all engines to the proposed 2008 PM standard.
Instead, we believe there are two likely means by which companies can
comply with the proposed 2008 PM standard. First, some engine
manufacturers can comply with this standard using known engine-out
techniques (e.g., optimizing combustion chamber designs, fuel-injection
strategies). However, based on the available data it is unclear whether
engine-out techniques will work in all cases. Therefore, we believe
some engine companies will choose to use a combination of engine-out
techniques and diesel oxidation catalysts, as discussed below.
[[Page 28393]]
[GRAPHIC] [TIFF OMITTED] TP23MY03.008
PM emissions can be reduced through in-cylinder techniques for
small nonroad diesel engines using similar techniques as used in larger
nonroad and highway engines. As discussed in section III.E.1.a, there
are a number of technologies which exist that can influence oxygen
content and in-cylinder mixing (and thus lower PM emissions) including
improved fuel injection systems and combustion system designs. For
example, increased injection pressure can reduce PM emissions
substantially.\207\ The wide-range of emission characteristics present
in the existing engine certification data is likely a result of
differences in fuel systems and combustion chamber designs. For many of
the engines which have higher emission levels, further optimization of
the fuel system and combustion chamber can provide additional PM
reductions.
---------------------------------------------------------------------------
\207\ ``Effects of Injection Pressure and Nozzle Geometry on DI
Diesel Emissions and Performance,'' Pierpont, D., and Reitz, R., SAE
Paper 950604, 1995.
---------------------------------------------------------------------------
Diesel oxidation catalysts (DOC) also offer the opportunity to
reduce PM emissions from the engines in this power category. DOCs are
passive flow through emission control devices which are typically
coated with a precious metal or a base-metal wash-coat. DOCs have been
proven to be durable in-use on both light-duty and heavy-duty diesel
applications. In addition, DOCs have already been used to control
carbon monoxide on some nonroad applications.\208\ However, as
discussed in section III.E.1.a., certain DOC formulations can be
sensitive to diesel fuel sulfur level. Specifically, precious-metal
based oxidation catalysts (which have the greatest potential for
reducing PM) can oxidize the sulfur in the fuel and form particulate
sulfates. Given the high level of sulfur in nonroad fuel today, the use
of DOCs as a PM reduction technology is severely limited. Data
presented by one engine manufacturer regarding the existing Tier 2 PM
standard shows that while a DOC can be used to meet the current
standard when tested on 2,000 ppm sulfur fuel, lowering the fuel sulfur
level to 380 ppm enabled the DOC to reduce PM by 50 percent from the
2,000 ppm sulfur fuel.\209\ Without the availability of 500 ppm sulfur
fuel in 2008, DOCs would be of limited use for nonroad engine
manufacturers and would not provide the emissions necessary to meet the
proposed standards for most engine manufacturers. With the availability
of 500 ppm sulfur fuel, DOC's can be designed to provide PM reductions
on the order of 20 to 50%, while suppressing particulate sulfate
reduction. These levels of reductions have been seen on transient duty
cycles as well as highway and nonroad steady-state duty cycles.\210\ As
discussed in section III.D, we are proposing to apply supplemental test
procedures and standards (nonroad transient test cycle
[[Page 28394]]
and not-to-exceed requirements) to engines in the <25 hp category
beginning in 2013. The supplemental test procedures and standards will
apply not only to PM, but also to NMHC+NOX. While we believe
the engine technology necessary to comply with the supplemental test
procedures and standards is the same as the technology necessary to
comply with the 2008 standard, we are delaying the implementation of
the supplemental test procedures and standards until 2013 in order to
implement the supplemental requirements on the larger powered nonroad
engines before the smallest power category (see section III.C. above).
This will also provide engine manufacturers with additional time to
install any emission testing equipment upgrades they may need in order
to implement the new nonroad transient test cycle. Nevertheless, the
technologies described above are capable of complying with both the
proposed nonroad transient test cycle and the NTE standard. As just
described, DOCs are capable of reducing PM emissions up to 50 percent
during transient testing. With respect to feasibility under NTE
testing, it has been demonstrated, as a result of a recent Agency
action, that engines which rely on retarded injection timing as a
primary NOX control technology, which is also the primary
technology that engines in the <25 hp category will likely use to
comply with the Tier 2 NMHC+NOX standard, are capable of
complying with an NMHC+NOX NTE standard of 1.25 x the FTP
for engines with emission levels on the order of 4 g/bhp-hr
NOX. Specifically, as a result of federal consent decrees
with a number of highway heavy-duty diesel engine manufactures, many
highway engines certified to an FTP standard of 4 g/bhp-hr
NOX were also designed to comply with an NTE limit of 5 g/
bhp-hr (i.e., 1.25 x FTP standard).\211\ The Tier 2 NMHC+NOX
standard for engines <25hp is 5.6 g/bhp-hr, therefore, in 2013 the
proposed NTE standard is 7.0 g/bhp-hr NMHC+NOX. Based on the
experience which a number of highway diesel engine companies, we
project that the proposed NTE standard for engines <25 hp can be
achieved by 2013.
---------------------------------------------------------------------------
\208\ EPA Memorandum ``Documentation of the Availability of
Diesel Oxidation Catalysts on Current Production Nonroad Diesel
Equipment'', William Charmley. Copy available in EPA Air Docket A-
2001-28.
\209\ See Table 2-4 in ``Nonroad Diesel Emission Standards--
Staff Technical Paper'', EPA Publication EPA420-R-01-052, October
2001. Copy available in EPA Air Docket A-2001-28.
\210\ ``Demonstration of Advanced Emission Control Technologies
Enabling Diesel-Powered Heavy-duty Engines to Achieve Low Emission
Levels: Interim Report Number 1--Oxidation Catalyst Technology, copy
available in EPA Air Docket A-2001-28. ``Reduction of Diesel Exhaust
Emissions by Using Oxidation Catalysts,'' Zelenka et. al., SAE Paper
90211, 1990. See Table 2-4 in ``Nonroad Diesel Emission Standards--
Staff Technical Paper'', EPA Publication EPA420-R-01-052, October
2001, copy available in EPA Air Docket A-2001-28.
\211\ EPA Memorandum ``Summary of Model Year 1999 and 2000
Federal On-highway Heavy-duty Diesel Engine Families Certified as
Compliant with Not-to-Exceed Requirements, Euro-3 Steady State
Requirements, and Maximum Allowable Emission Limits Requirements'',
copy available in EPA Air Docket A-2001-28.
---------------------------------------------------------------------------
As discussed in section III.B, we have also proposed a minor change
in the CO standard for the <11 hp engines, in order to align those
standards with the standards for the 11-25 hp engines. As discussed in
section III.B., the small change in the CO standard is intended to
simplify EPA's regulations as part of our decision to propose a
reduction in the number of engine power categories for Tier 4. The
current CO standard for this category is 6.0 g/bhp-hr, and the proposed
standard is 4.9 g/bhp-hr (i.e., the current standard for engines in the
11-25 hp range). The model year 2002 certification data shows that more
than 90 percent of the engine families in this power category meet the
proposed standards today. In addition, DOCs typically reduce CO
emissions on the order of 50 percent or more during both transient and
steady-state operation.\212\ Given that more than 90 percent of the
engines in this category meet the proposed standard today, and the
ready availability of technology which can easily achieve the proposed
standard, we project this CO standard will be achievable by model year
2008.
---------------------------------------------------------------------------
\212\ ``Demonstration of Advanced Emission Control Technologies
Enabling Diesel-Powered Heavy-duty Engines to Achieve Low Emission
Levels: Interim Report Number 1--Oxidation Catalyst Technology, and
``Reduction of Diesel Exhaust Emissions by Using Oxidation
Catalysts'', P. Zelenka et. al., Society of Automotive Engineers
paper 902111, October 1990.
---------------------------------------------------------------------------
Based on the existence of a number of engine families which already
comply with the proposed Tier 4 PM standard (and the 2008
NMHC+NOX standard), and the availability of PM reduction
technologies such as improved fuel systems, combustion chamber
improvements, and in particular diesel oxidation catalysts, we project
the proposed 0.30 g/bhp-hr PM standards is technologically feasible by
model year 2008. All of these are conventional technologies which have
been used on both highway and nonroad diesel engines in the past. As
such, we do not expect there to be any negative impacts with respect to
noise or safety. In addition, PM reduction technologies such as
improved combustion through the use of higher pressure fuel injection
systems as well as DOCs are not predicted to have any substantial
impact on fuel efficiency.
d. Why has EPA not Proposed More Stringent PM or NOX
Standards for Engines <25 hp?
Section III.E.4 contains a detailed discussion of why we don't
believe it is appropriate at this time to revise the NOX
standards based on NOX absorber technology for engines
between 25 and 75 hp. These same arguments apply for engines below 25
hp. In addition, we have not proposed to revise the NOX
standard for <25 hp engines in this action, nor do we believe PM
standards based on particulate filters are appropriate for this power
category based on a number of factors, as discussed below.
In EPA's recent Staff Technical Paper regarding the feasibility of
the Tier 3 NMHC+NOX standards for engines greater than 50
hp, we projected that a number of engine technologies can be used to
meet the Tier 3 standards, including cooled EGR or hot EGR, both with
advanced electronic fuel systems, as well as with internal combustion
techniques using advanced electronic fuel systems, advanced
turbocharging systems (e.g., waste-gated or variable geometry
turbochargers), and possibly variable valve actuation.\213\ In
addition, we presumed the use of charge-air cooling In order to set
more stringent NOX standards for <25 hp engines without
increasing PM emissions, the most logical list of technologies is
turbocharging, electronically controlled hot or cooled EGR, an
electronic fuel system, and possibly charge-air-cooling. No nonroad
diesel engine <25 hp uses any combination of these technologies today.
While we are able to postulate that some of this technology could be
applied to the <25 hp engines, the application of some of the
technology (such as turbocharging) is technologically uncertain. It is
the combination of these two issues (the traditional NOX-PM
trade-off and the difficulties with turbocharging 1 and 2 cylinder
engines) which is the primary reason we are not proposing to revise the
NOX standard for engines in this size range. NOX
reduction control technologies such as advancing fuel injection timing
or using EGR will increase PM emissions. In order to reduce
NOX emissions and reduce or maintain current PM levels
additional technologies must be used. Fundamental among these is the
need to increase oxygen content, which can be achieved principally with
turbocharging. However, turbocharging systems do not lend themselves to
1 and 2 cylinder products, which are approximately 50 percent of the
engines in this power category. In addition, even if these technologies
could be applied to engines in the < 25 hp category, the costs would be
substantial relative to both the base engine cost and to the cost of
the nonroad equipment itself . Therefore, for the reasons discussed
above, we have not proposed to revise the NOX standard for
these engines at
[[Page 28395]]
this time. As discussed in section III.H, we have proposed that a
technology assessment occur in 2007 which would evaluate the status of
emission control technologies for engines less than 75 hp, and such a
review would revisit this issue.
---------------------------------------------------------------------------
\213\ See section 2.3.1 through 2.3.3 of ``Nonroad Diesel
Emission Standards--Staff Technical Paper'', EPA Publication EPA420-
R-01-052, October 2001. Copy available in EPA Air Docket A-2001-28.
---------------------------------------------------------------------------
In addition, we have not proposed to apply particulate filter based
standards for engines less than 25 hp. As discussed in sections III.E.1
through 4, there are two basic types of particulate filter systems we
believe could be used by engine manufacturers. The first is a CDPF
which uses post-injection from a common-rail electronic fuel injection
system in order to ensure filter regeneration. The second type of
system would use a CDPF with a stand-alone (i.e., independent from the
engine's fuel system) fuel injection system to ensure filter
regeneration. In either case, an electronic control system is required,
as well as the CDPF. Such systems are not being developed for engines
of this size for either highway light-duty or heavy-duty diesel
applications, and (as noted earlier) it is unclear whether the
technology development which is being done for the highway market will
transfer down to engines in this power category. In addition, based on
currently available information, we believe the cost of these
technologies are relatively high compared to the overall cost of the
equipment. As discussed in section III.H, we have proposed that a
technology assessment occur in 2007 which would evaluate the status of
emission control technologies for engines less than 75 hp, and such a
review would revisit this issue.
6. Meeting the Crankcase Emissions Requirements
The most common way to eliminate crankcase emissions has been to
vent the blow-by gases into the engine air intake system, so that the
gases can be recombusted. Prior to the HD2007 rulemaking, we have
required that crankcase emissions be controlled only on naturally
aspirated diesel engines. We had made an exception for turbocharged
diesel engines (both highway and nonroad) because of concerns in the
past about fouling that could occur by routing the diesel particulates
(including engine oil) into the turbocharger and aftercooler. However,
this is an environmentally significant exception since most nonroad
equipment over 70hp use turbocharged engines, and a single engine can
emit over 100 pounds of NOX, NMHC, and PM from the crankcase
over its lifetime.
Given the available means to control crankcase emissions, we
eliminated this exception for highway engines in 2007 and are proposing
to eliminate the exception for nonroad diesel engines as well. We
anticipate that the diesel engine manufacturers will be able to control
crankcase emissions through the use of closed crankcase filtration
systems or by routing unfiltered blow-by gases directly into the
exhaust system upstream of the emission control equipment. However, the
proposed provision has been written such that if adequate control can
be had without ``closing'' the crankcase then the crankcase can remain
``open.'' Compliance would be ensured by adding the emissions from the
crankcase ventilation system to the emissions from the engine control
system downstream of any emission control equipment. We propose to
limit this provision for controlling emissions from open crankcases to
turbocharged engines, which is the same as for heavy-duty highway
diesel engines. We request comment on extending this provision to
naturally aspirated engines, as we did for marine diesel engines in our
1999 final rule (64 FR 73300, December 29, 1999).
We expect that in order to meet the stringent tailpipe emission
standards set here, that manufacturers will have to utilize closed
crankcase approaches as described here. Closed crankcase filtration
systems work by separating oil and particulate matter from the blow-by
gases through single or dual stage filtration approaches, routing the
blow-by gases into the engine's intake manifold and returning the
filtered oil to the oil sump. Oil separation efficiencies in excess of
90 percent have been demonstrated with production ready prototypes of
two stage filtration systems.\214\ By eliminating 90 percent of the oil
that would normally be vented to the atmosphere, the system works to
reduce oil consumption and to eliminate concerns over fouling of the
intake system when the gases are routed through the turbocharger. Hatz,
a nonroad engine manufacturer, currently has closed crankcase systems
on many of its turbocharged engines.
---------------------------------------------------------------------------
\214\ Letter from Marty Barris, Donaldson Corporation, to Byron
Bunker U.S. EPA, March 2000. Copy available in EPA Air Docket A-
2001-28.
---------------------------------------------------------------------------
F. Why Do We Need 15ppm Sulfur Diesel Fuel?
As stated earlier, we strongly believe that fuel sulfur control is
critical to ensuring the success of NOX and PM
aftertreatment technologies. In order to evaluate the effect of sulfur
on diesel exhaust control technologies, we used three key factors to
categorize the impact of sulfur in fuel on emission control function.
These factors were efficiency, reliability, and fuel economy. Taken
together these three factors lead us to believe that diesel fuel sulfur
levels of 15 ppm will be required for the nonroad emission standards
proposed here to be feasible. Brief summaries of these factors are
provided below.
The efficiency of emission control technologies to reduce harmful
pollutants is directly affected by sulfur in diesel fuel. Initial and
long term conversion efficiencies for NOX, NMHC, CO and
diesel PM emissions are significantly reduced by catalyst poisoning and
catalyst inhibition due to sulfur. NOX conversion
efficiencies with the NOX adsorber technology in particular
are dramatically reduced in a very short time due to sulfur poisoning
of the NOX storage bed. In addition, total PM control
efficiency is negatively impacted by the formation of sulfate PM. As
explained in the following sections, the CDPF, NOX adsorber,
and urea SCR catalyst technologies described here have the potential to
make significant amounts of sulfate PM under operating conditions
typical of many nonroad engines. We believe that the formation of
sulfate PM will be in excess of the total PM standard, unless diesel
fuel sulfur levels are at or below 15 ppm. Based on the strong negative
impact of sulfur on emission control efficiencies for all of the
technologies evaluated, we believe that 15 ppm represents an upper
threshold of acceptable diesel fuel sulfur levels.
Reliability refers to the expectation that emission control
technologies must continue to function as required under all operating
conditions for the life of the engine. As discussed in the following
sections, sulfur in diesel fuel can prevent proper operation of both
NOX and PM control technologies. This can lead to permanent
loss in emission control effectiveness and even catastrophic failure of
the systems. Sulfur in diesel fuel impacts reliability by decreasing
catalyst efficiency (poisoning of the catalyst), increasing diesel
particulate filter loading, and negatively impacting system
regeneration functions. Among the most serious reliability concerns
with sulfur levels greater than 15 ppm are those associated with
failure to properly regenerate. In the case of the NOX
adsorber, failure to regenerate the stored sulfur (desulfate) will lead
to rapid loss of NOX emission control as a result of sulfur
poisoning of the NOX adsorber bed. In the case of the diesel
particulate filter, sulfur in the fuel reduces the reliability of the
regeneration function.
[[Page 28396]]
If regeneration does not occur, catastrophic failure of the filter
could occur. It is only by the availability of low sulfur diesel fuels
that these technologies become feasible.
Fuel economy impacts due to sulfur in diesel fuel affect both
NOX and PM control technologies. The NOX adsorber
sulfur regeneration cycle (desulfation cycle) can consume significant
amounts of fuel unless fuel sulfur levels are very low. The larger the
amount of sulfur in diesel fuel, the greater the adverse effect on fuel
economy. As sulfur levels increase above 15 ppm, the adverse effect on
fuel economy becomes more significant, increasing above one percent and
doubling with each doubling of fuel sulfur level. Likewise, PM trap
regeneration is inhibited by sulfur in diesel fuel. This leads to
increased PM loading in the diesel particulate filter and increased
work to pump exhaust across this restriction. With low sulfur diesel
fuel, diesel particulate filter regeneration can be optimized to give a
lower (on average) exhaust backpressure and thus better fuel economy.
Thus, for both NOX and PM technologies the lower the fuel
sulfur level the lower the operating costs of the vehicle.
1. Catalyzed Diesel Particulate Filters and the Need for Low Sulfur
Fuel
CDPFs function to control diesel PM through mechanical filtration
of the solid PM (soot) from the diesel exhaust stream and then
oxidation of the stored soot (trap regeneration) and oxidation of the
SOF. Through oxidation in the catalyzed diesel particulate filter the
stored PM is converted to CO2 and released into the
atmosphere. Failure to oxidize the stored PM leads to accumulation in
the trap, eventually causing the trap to become so full that it
severely restricts exhaust flow through the device, leading to trap or
vehicle failure.
Uncatalyzed diesel particulate filters require exhaust temperatures
in excess of 650[deg]C in order for the collected PM to be oxidized by
the oxygen available in diesel exhaust. That temperature threshold for
oxidation of PM by exhaust oxygen can be decreased to 450[deg]C through
the use of base metal catalytic technologies. For a broad range of
operating conditions typical of in-use diesel engine operation, diesel
exhaust can be significantly cooler than 400[deg]C. If oxidation of the
trapped PM could be assured to occur at exhaust temperatures lower than
300[deg]C, then diesel particulate filters would be expected to be more
robust for most applications and operating regimes. Oxidation of PM
(regeneration of the trap) at such low exhaust temperatures can occur
by using oxidants which are more readily reduced than oxygen. One such
oxidant is NO2.
NO2 can be produced in diesel exhaust through the
oxidation of the nitrogen monoxide (NO), created in the engine
combustion process, across a catalyst. The resulting NO2-
rich exhaust is highly oxidizing in nature and can oxidize trapped
diesel PM at temperatures as cool as 250[deg]C.\215\ Some platinum
group metals are known to be good catalysts to promote the oxidation of
NO to NO2. Therefore in order to promote more effective
passive regeneration of the diesel particulate filters, significant
amounts of platinum group metals (primarily platinum) are being used in
the wash-coat formulations of advanced CDPFs. The use of platinum to
promote the oxidation of NO to NO2 introduces several system
vulnerabilities affecting both the durability and the effectiveness of
the CDPF when sulfur is present in diesel exhaust. (In essence, diesel
engine exhaust temperatures are in a range necessitating use of
precious metal catalysts in order to adequately regenerate the PM
filter, but precious metal catalysts are in turn highly sensitive to
sulfur in diesel fuel.) The two primary mechanisms by which sulfur in
diesel fuel limits the robustness and effectiveness of CDPFs are
inhibition of trap regeneration, through inhibition of the oxidation of
NO to NO2, and a dramatic loss in total PM control
effectiveness due to the formation of sulfate PM. Unfortunately, these
two mechanisms trade-off against one another in the design of CDPFs.
Changes to improve the reliability of regeneration by increasing
catalyst loadings lead to increased sulfate emissions and, thus, loss
of PM control effectiveness. Conversely, changes to improve PM control
by reducing the use of platinum group metals and, therefore, limiting
``sulfate make'' leads to less reliable regeneration. Even with an
active regeneration system, reducing catalytic loading to reduce
sulfate make unacceptably trades off regeneration effectiveness (i.e.,
robustness). We believe the best means of achieving good PM emission
control and reliable operation is to reduce sulfur in diesel fuel, as
shown in the following subsections.
---------------------------------------------------------------------------
\215\ Hawker, P. et al, ``Experience with a New Particulate Trap
Technology in Europe,'' SAE 970182.
---------------------------------------------------------------------------
a. Inhibition of Trap Regeneration Due to Sulfur
The CDPF technology relies on the generation of a very strong
oxidant, NO2, to ensure that the carbon captured by the PM
trap's filtering media is oxidized under the exhaust temperature range
of normal operating conditions. This prevents plugging and failure of
the PM trap. NO2 i2 produced through the oxidation of NO in
the exhaust across a platinum catalyst. This oxidation is inhibited by
sulfur poisoning of the catalyst surface.\216\ This inhibition limits
the total amount of NO2 available for oxidation of the
trapped diesel PM, thereby raising the minimum exhaust temperature
required to ensure trap regeneration. Without sufficient
NO2, the amount of PM trapped in the diesel particulate
filter will continue to increase and can lead to excessive exhaust back
pressure and low engine power.
---------------------------------------------------------------------------
\216\ Hawker, P. et al, ``Experience with a New Particulate Trap
Technology in Europe,'' SAE 970182.
---------------------------------------------------------------------------
The failure mechanisms experienced by diesel particulate filters
due to low NO2 availability vary significantly in severity
and long term consequences. In the most fundamental sense, the failure
is defined as an inability to oxidize the stored particulate at a rate
fast enough to prevent net particulate accumulation over time. The
excessive accumulation of PM over time blocks the passages through the
filtering media, making it more restrictive to exhaust flow. In order
to continue to force the exhaust through the now more restrictive
filter, the exhaust pressure upstream of the filter must increase. This
increase in exhaust pressure is commonly referred to as increasing
``exhaust backpressure'' on the engine.
The increase in exhaust backpressure represents increased work
being done by the engine to force the exhaust gas through the
increasingly restrictive particulate filter. Unless the filter is
frequently cleansed of the trapped PM, this increased work can lead to
reductions in engine performance and increases in fuel consumption.
This loss in performance may be noted by the equipment operator in
terms of sluggish engine response.
Full field test evaluations and retrofit applications of these
catalytic trap technologies are occurring in parts of the United States
and Europe where low sulfur diesel fuel is already available.\217\ The
experience gained in these field
[[Page 28397]]
tests helps to clarify the need for low sulfur diesel fuel. In Sweden
and some European city centers where below 10 ppm diesel fuel sulfur is
readily available, more than 3,000 catalyzed diesel particulate filters
have been introduced into retrofit applications without a single
failure. Given the large number of vehicles participating in these test
programs, the diversity of the vehicle applications which included
intercity trains, airport buses, mail trucks, city buses and garbage
trucks, and the extended time periods of operation (some vehicles have
been operating with traps for more than 5 years and in excess of
300,000 miles\218\, there is a strong indication of the robustness of
this technology on 10 ppm low sulfur diesel fuel. The field experience
in areas where sulfur is capped at 50 ppm has been less definitive. In
regions without extended periods of cold ambient conditions, such as
the United Kingdom, field tests on 50 ppm cap low sulfur fuel have also
been positive, matching the durability at 10 ppm, although sulfate PM
emissions are much higher. However, field tests on 50 ppm fuel in
Finland, where colder winter conditions are sometimes encountered
(similar to many parts of the United States), showed a significant
number of failures (10 percent) due to trap plugging. This 10 percent
failure rate has been attributed to insufficient trap regeneration due
to fuel sulfur in combination with low ambient temperatures.\219\ Other
possible reasons for the high failure rate in Finland when contrasted
with the Swedish experience appear to be unlikely. The Finnish and
Swedish fleets were substantially similar, with both fleets consisting
of transit buses powered by Volvo and Scania engines in the 10 to 11
liter range. Further, the buses were operated in city areas and none of
the vehicles were operated in northern extremes such as north of the
Arctic Circle.\220\ Given that the fleets in Sweden and Finland were
substantially similar, and given that ambient conditions in Sweden are
expected to be similar to those in Finland, we believe that the
increased failure rates noted here are due to the higher fuel sulfur
level in a 50 ppm cap fuel versus a 10 ppm cap fuel.\221\
---------------------------------------------------------------------------
\217\ Through tax incentives 50 ppm cap sulfur fuel is widely
available in the United Kingdom and 10 ppm sulfur fuel is available
in Sweden and in certain European city centers.
\218\ Allansson, et al., ``European Experience of High Mileage
Durability of Continuously Regenerating Filter Technology,'' SAE
2000-01-0480.
\219\ Letter from Dr. Barry Cooper, Johnson Matthey, to Don
Kopinski, U.S. EPA. Copy available in EPA Air Docket A-2001-28.
\220\ Telephone conversation between Dr. Barry Cooper, Johnson
Matthey, and Todd Sherwood, EPA, Air Docket A-99-06.
\221\ The average temperature in Helsinki, Finland, for the
month of January is 21[deg]F. The average temperature in Stockholm,
Sweden, for the month of January is 26[deg]F. The average
temperature at the University of Michigan in Ann Arbor, Michigan,
for the month of January is 24[deg]F. The temperatures reported here
are from www.worldclimate.com based upon the Global Historical
Climatology Network (GHCN) produced jointly by the National Climatic
Data Center and Carbon Dioxide Information Analysis Center at Oak
Ridge National Laboratory (ORNL).
---------------------------------------------------------------------------
Testing on an even higher fuel sulfur level of 200 ppm was
conducted in Denmark on a fleet of 9 vehicles. In less than six months
all of the vehicles in the Danish fleet had failed due to trap
plugging.\222\ The failure of some fraction of the traps to regenerate
when operated on fuel with sulfur caps of 50 ppm and 200 ppm is
believed to be primarily due to inhibition of the NO to NO2
conversion as described here. Similarly the increasing frequency of
failure with higher fuel sulfur levels is believed to be due to the
further suppression of NO2 formation when higher sulfur
level diesel fuel is used. Since this loss in regeneration
effectiveness is due to sulfur poisoning of the catalyst this real
world experience would be expected to apply equally well to nonroad
engines (i.e., operation on lower sulfur diesel fuel, 15 ppm versus 50
ppm, will increase regeneration robustness).
---------------------------------------------------------------------------
\222\ Letter from Dr. Barry Cooper to Don Kopinski U.S. EPA.
Copy available in EPA Air Docket A-2001-28.
---------------------------------------------------------------------------
As shown above, sulfur in diesel fuel inhibits NO oxidation leading
to increased exhaust backpressure and reduced fuel economy. Therefore,
we believe that, in order to ensure reliable and economical operation
over a wide range of expected operating conditions, nonroad diesel fuel
sulfur levels should be at or below 15 ppm.
b. Loss of PM Control Effectiveness
In addition to inhibiting the oxidation of NO to NO2,
the sulfur dioxide (SO2) in the exhaust stream is itself
oxidized to sulfur trioxide (SO3) at very high conversion
efficiencies by the precious metals in the catalyzed particulate
filters. The SO3 serves as a precursor to the formation of
hydrated sulfuric acid (H2SO4+H2O), or
sulfate PM, as the exhaust leaves the vehicle tailpipe. Virtually all
of the SO3 is converted to sulfate under dilute exhaust
conditions in the atmosphere as well in the dilution tunnel used in
heavy-duty engine testing. Since virtually all sulfur present in diesel
fuel is converted to SO2, the precursor to SO3,
as part of the combustion process, the total sulfate PM is directly
proportional to the amount of sulfur present in diesel fuel. Therefore,
even though diesel particulate filters are very effective at trapping
the carbon and the SOF portions of the total PM, the overall PM
reduction efficiency of catalyzed diesel particulate filters drops off
rapidly with increasing sulfur levels due to the formation of sulfate
PM downstream of the CDPF.
SO2 oxidation is promoted across a catalyst in a manner
very similar to the oxidation of NO, except it is converted at higher
rates, with peak conversion rates in excess of 50 percent. The
SO2 oxidation rate for a platinum based oxidation catalyst
typical of the type which might be used in conjunction with, or as a
washcoat on, a CDPF can vary significantly with exhaust temperature. At
the low temperatures the oxidation rate is relatively low, perhaps no
higher than ten percent. However at the higher temperatures that might
be more typical of agricultural tractor use pulling a plow and the
highway Supplemental Emission Test (also called the EURO III or 13 mode
test), the oxidation rate may increase to 50 percent or more. These
high levels of sulfate make across the catalyst are in contrast to the
very low SO2 oxidation rate typical of diesel exhaust
(typically less than 2 percent). This variation in expected diesel
exhaust temperatures means that there will be a corresponding range of
sulfate production expected across a CDPF.
The U.S. Department of Energy in cooperation with industry
conducted a study entitled DECSE to provide insight into the
relationship between advanced emission control technologies and diesel
fuel sulfur levels. Interim report number four of this program gives
the total particulate matter emissions from a heavy-duty diesel engine
operated with a diesel particulate filter on several different fuel
sulfur levels. A straight line fit through this data is presented in
Table III.F-1 below showing the expected total direct PM emissions from
a diesel engine on the supplemental emission test cycle.\223\ The SET
test cycle, a 13 mode steady-state cycle, that this data was developed
on is similar to the C1 eight mode steady-state nonroad test cycle.
Both cycles include operation at full and intermediate load points at
approximately rated speed conditions and torque peak speed conditions.
As a
[[Page 28398]]
result, the sulfate make rate for the C1 cycle and the SET cycle would
be expected to be similar. The data can be used to estimate the PM
emissions from diesel engines operated on fuels with average fuel
sulfur levels in this range.
---------------------------------------------------------------------------
\223\ Note that direct emissions are those pollutants emitted
directly from the engine or from the tailpipe depending on the
context in which the term is used, and indirect emissions are those
pollutants formed in the atmosphere through chemical reactions
between direct emissions and other atmospheric constituents.
Table III. F-1--Estimated PM Emissions From a Diesel Engine at the Indicated Fuel Sulfur Levels
----------------------------------------------------------------------------------------------------------------
Steady state emissions performance
--------------------------------------------
Fuel sulfur [ppm] Tailpipe PMb PM increase relative to 3
[g/bhp-hr] ppm sulfur
----------------------------------------------------------------------------------------------------------------
3.................................................................. 0.003 ...........................
7a................................................................. 0.006 100%
15a................................................................ 0.009 200%
30................................................................. 0.017 470%
150................................................................ 0.071 2300%
----------------------------------------------------------------------------------------------------------------
Notes:
a The PM emissions at these sulfur levels are based on a straight-line fit to the DECSE data; PM emissions at
other sulfur levels are actual DECSE data. (Diesel Emission Control Sulfur Effects (DECSE) Program--Phase II
Interim Data Report No. 4, Diesel Particulate Filters-Final Report, January 2000. Table C1.) Although DECSE
tested diesel particulate filters at these fuel sulfur levels, they do not conclude that the technology is
feasible at all levels, but they do note that testing at 150 ppm is a moot point as the emission levels exceed
the engine's baseline emission level.
b Total exhaust PM (soot, SOF, sulfate).
Table III.F-1 makes it clear that there are significant PM emission
reductions possible with the application of catalyzed diesel
particulate filters and low sulfur diesel fuel. At the observed sulfate
PM conversion rates, the DECSE program results show that the 0.01 g/
bhp-hr total PM standard is feasible for CDPF equipped engines operated
on fuel with a sulfur level at or below 15 ppm. The results also show
that diesel particulate filter control effectiveness is rapidly
degraded at higher diesel fuel sulfur levels due to the high sulfate PM
make observed with this technology. It is clear that PM reduction
efficiencies are limited by sulfur in diesel fuel and that, in order to
realize the PM emissions benefits sought in this rule, diesel fuel
sulfur levels must be at or below 15 ppm.
c. Increased Maintenance Cost for Diesel Particulate Filters Due to
Sulfur
In addition to the direct performance and durability concerns
caused by sulfur in diesel fuel, it is also known that sulfur can lead
to increased maintenance costs, shortened maintenance intervals, and
poorer fuel economy for CDPFs. CDPFs are highly effective at capturing
the inorganic ash produced from metallic additives in engine oil. This
ash is accumulated in the filter and is not removed through oxidation,
unlike the trapped soot PM. Periodically the ash must be removed by
mechanical cleaning of the filter with compressed air or water. This
maintenance step is anticipated to occur on intervals of well over
1,500 hours (depending on engine size). However, sulfur in diesel fuel
increases this ash accumulation rate through the formation of metallic
sulfates in the filter, which increases both the size and mass of the
trapped ash. By increasing the ash accumulation rate, the sulfur
shortens the time interval between the required maintenance of the
filter and negatively impacts fuel economy.
2. Diesel NOX Catalysts and the Need for Low Sulfur Fuel
NOX adsorbers are damaged by sulfur in diesel fuel
because the adsorption function itself is poisoned by the presence of
sulfur. The resulting need to remove the stored sulfur (desulfate)
leads to a need for extended high temperature operation which can
deteriorate the NOX adsorber. These limitations due to
sulfur in the fuel affect the overall performance and feasibility of
the NOX adsorber technology.
a. Sulfur Poisoning (Sulfate Storage) on NOX Adsorbers
The NOX adsorber technology relies on the ability of the
catalyst to store NOX as a metallic nitrate
(MNO3) on the surface of the catalyst, or adsorber (storage)
bed, during lean operation. Because of the similarities in chemical
properties of SOx and NOX, the SO3 present in the
exhaust is also stored by the catalyst surface as a sulfate
(MSO4). The sulfate compound that is formed is significantly
more stable than the nitrate compound and is not released and reduced
during the NOX release and reduction step (NOX
regeneration step). Since the NOX adsorber is essentially
100 percent effective at capturing SO2 in the adsorber bed,
the sulfur build up on the adsorber bed occurs rapidly. As a result,
sulfate compounds quickly occupy all of the NOX storage
sites on the catalyst thereby rendering the catalyst ineffective for
NOX storage and subsequent NOX reduction
(poisoning the catalyst).
The stored sulfur compounds can be removed by exposing the catalyst
to hot (over 650 [deg]C) and rich (air-fuel ratio below the
stoichiometric ratio of 14.5 to 1) conditions for a brief period.\224\
Under these conditions, the stored sulfate is released and reduced in
the catalyst.\225\ While research to date on this procedure has been
very favorable with regards to sulfur removal from the catalyst, it has
revealed a related vulnerability of the NOX adsorber
catalyst. Under the high temperatures used for desulfation, the metals
that make up the storage bed can change in physical structure. This
leads to lower precious metal dispersion, or ``metal sintering,'' (a
less even distribution of the catalyst sites) reducing the
effectiveness of the catalyst.\226\ This degradation of catalyst
efficiency due to high temperatures is often referred to as thermal
degradation. Thermal degradation is known to be a cumulative effect.
That is, with each excursion to high temperature operation, some
additional degradation of the catalyst occurs.
---------------------------------------------------------------------------
\224\ Dou, Danan and Bailey, Owen, ``Investigation of
NOX Adsorber Catalyst Deactivation,'' SAE 982594.
\225\ Guyon, M. et al, ``Impact of Sulfur on NOX Trap
Catalyst Activity--Study of the Regeneration Conditions'', SAE
982607.
\226\ Though it was favorable to decompose sulfate at 800
[deg]C, performance of the NSR (NOX Storage Reduction
catalyst, i.e. NOX Adsorber) catalyst decreased due to
sintering of precious metal.--Asanuma, T. et al, ``Influence of
Sulfur Concentration in Gasoline on NOX Storage--
Reduction Catalyst'', SAE 1999-01-3501.
---------------------------------------------------------------------------
One of the best ways to limit thermal degradation is by limiting
the accumulated number of desulfation events over the life of the
vehicle. Since
[[Page 28399]]
the period of time between desulfation events is expected to be
determined by the amount of sulfur accumulated on the catalyst (the
higher the sulfur accumulation rate, the shorter the period between
desulfation events) the desulfation frequency is expected to be
proportional to the fuel sulfur level. In other words for each doubling
in the average fuel sulfur level, the frequency and accumulated number
of desulfation events are expected to double. We concluded in the
HD2007 rulemaking, that this thermal degradation would be unacceptable
high for fuel sulfur levels greater than 15 ppm. Some commenters to the
HD2007 rule suggested that the NOX adsorber technology could
meet the HD2007 NOX standard using diesel fuel with a 30 ppm
average sulfur level. This would imply that the NOX adsorber
could tolerate as much as a four fold increase in desulfation frequency
(when compared to an expected seven to 10 ppm average) without any
increase in thermal degradation. That conclusion was inconsistent with
our understanding of the technology at the time of the HD2007
rulemaking and remains inconsistent with our understanding of progress
made by industry since that time. Diesel fuel sulfur levels must be at
or below 15 ppm in order to limit the number and frequency of
desulfation events. Limiting the number and frequency of desulfation
events will limit thermal degradation and, thus, enable the
NOX adsorber technology to meet the NOX standard.
This conclusion remains true for the highway NOX
adsorber catalyst technology that this proposal is based upon and will
be equally true for nonroad engines applying the NOX
adsorber technology to comply with our proposed Tier 4 standards.
Nonroad and highway diesel engines are similarly durable and thus
over their lifetimes consume a similar amount of diesel fuel. This
means that both nonroad and highway diesel engines will have the same
exposure to sulfur in diesel fuel and thus will require the same number
of desulfation cycles over their lifetimes. This is true independent of
the test cycle or in-use operation of the nonroad engine.
Sulfur in diesel fuel for NOX adsorber equipped engines
will also have an adverse effect on fuel economy. The desulfation event
requires controlled operation under hot and net fuel rich exhaust
conditions. These conditions, which are not part of a normal diesel
engine operating cycle, can be created through the addition of excess
fuel to the exhaust. This addition of excess fuel causes an increase in
fuel consumption.
Future improvements in the NOX adsorber technology, as
we have observed in our ongoing diesel progress reviews, are expected
and needed in order to meet the NOX emission standards
proposed today. Some of these improvements are likely to include
improvements in the means and ease of removing stored sulfur from the
catalyst bed. However because the stored sulfate species are inherently
more stable than the stored nitrate compounds (from stored
NOX emissions) and so will always be stored preferentially
to NOX on the adsorber storage sites, we expect that a
separate release and reduction cycle (desulfation cycle) will always be
needed in order to remove the stored sulfur. Therefore, we believe that
fuel with a sulfur level at or below 15 ppm sulfur will be necessary in
order to control thermal degradation of the NOX adsorber
catalyst and to limit the fuel economy impact of sulfur in diesel fuel.
b. Sulfate Particulate Production and Sulfur Impacts on Effectiveness
of NOX Control Technologies
The NOX adsorber technology relies on a platinum based
oxidation function in order to ensure high NOX control
efficiencies. As discussed more fully in section III.F.1, platinum
based oxidation catalysts form sulfate PM from sulfur in the exhaust
gases significantly increasing PM emissions when sulfur is present in
the exhaust stream. The NOX adsorber technology relies on
the oxidation function to convert NO to NO2 over the
catalyst bed. For the NOX adsorber this is a fundamental
step prior to the storage of NO2 in the catalyst bed as a
nitrate. Without this oxidation function the catalyst will only trap
that small portion of NOX emissions from a diesel engine
which is NO2. This would reduce the NOX adsorber
effectiveness for NOX reduction from in excess of 90 percent
to something well below 20 percent. The NOX adsorber relies
on platinum to provide this oxidation function due to the need for high
NO oxidation rates under the relatively cool exhaust temperatures
typical of diesel engines. Because of this fundamental need for a
precious metal catalytic oxidation function, the NOX
adsorber inherently forms sulfate PM when sulfur is present in diesel
fuel, since sulfur in fuel invariably leads to sulfur in the exhaust
stream.
The Compact-SCR technology, like the NOX adsorber
technology, uses an oxidation catalyst to promote the oxidation of NO
to NO2 at the low temperatures typical of much of diesel
engine operation. By converting a portion of the NOX
emissions to NO2 upstream of the ammonia SCR reduction
catalyst, the overall NOX reductions are improved
significantly at low temperatures. Without this oxidation function, low
temperature SCR NOX effectiveness is dramatically reduced
making compliance with the NOX standard impossible.
Therefore, future Compact-SCR systems would need to rely on a platinum
oxidation catalyst in order to provide the required NOX
emission control. This use of an oxidation catalyst in order to enable
good NOX control means that Compact SCR systems will produce
significant amounts of sulfate PM when operated on anything but the
lowest fuel sulfur levels due to the oxidation of SO2 to
sulfate PM promoted by the oxidation catalyst.
Without the oxidation catalyst promoted conversion of NO to
NO2, neither of these NOX control technologies
can meet the proposed NOX standard. Therefore, each of these
technologies will require low sulfur diesel fuel to control the sulfate
PM emissions inherent in the use of highly active oxidation catalysts.
The NOX adsorber technology may be able to limit its impact
on sulfate PM emissions by releasing stored sulfur as SO2
under rich operating conditions. The Compact-SCR technology, on the
other hand, has no means to limit sulfate emissions other than through
lower catalytic function or lowering sulfur in diesel fuel. The degree
to which the NOX emission control technologies increase the
production of sulfate PM through oxidation of SO2 to
SO3 varies somewhat from technology to technology, but it is
expected to be similar in magnitude and environmental impact to that
for the PM control technologies discussed previously, since both the
NOX and the PM control catalysts rely on precious metals to
achieve the required NO to NO2 oxidation reaction.
At fuel sulfur levels below 15 ppm this sulfate PM concern is
greatly diminished. Without this low sulfur fuel, the NOX
control technologies are expected to create PM emissions well in excess
of the PM standard regardless of the engine-out PM levels. Thus, we
believe that diesel fuel sulfur levels will need to be at or below 15
ppm in order to apply the NOX control technology.
G. Reassessment of Control Technology for Engines Less Than 75 hp in
2007
By structuring our program to benefit extensively from prior
experience with core technologies in the highway sector, we believe
that a nonroad diesel technology review of the extent being pursued for
the heavy-duty highway
[[Page 28400]]
engine program will not be needed.\227\ Indeed the results of that
ongoing review have already had a very helpful impact in shaping this
proposal. Nevertheless, there are some technology issues that will not
be addressed in the highway program review. In particular we believe
that a future review of particulate filter technology for engines under
75 hp may be warranted. Under our proposed schedule presented in
section III.B, standards based on the performance of this technology
will take effect in the 2013 model year for 25-75 hp engines (or in the
2012 model year for manufacturers opting to skip the transitional
standards for 50-75 hp engines).
---------------------------------------------------------------------------
\227\ See ``Highway Diesel Progress Review'', U.S. EPA, June
2002. EPA420-R-02-016. (www.epa.gov/air/caaac/dieselreview.pdf).
---------------------------------------------------------------------------
At this time we have not decided what the long-term PM standards
should be for engines under 25 hp. No PM filter-based standards are
being proposed for engines under 25 hp as part of this Tier 4 proposal.
Likewise, we have not decided what the long-term NOX
standards should be for engines under 75 hp, and no NOX
adsorber-based standards are being proposed for engines under 75 hp. As
part of the technology review, we plan to thoroughly evaluate progress
made toward applying advanced PM and NOX control
technologies to these smaller engines.
We propose to conduct the technology review in 2007, and to
conclude it by the end of that year, to give manufacturers lead time
should an adjustment in the program be considered appropriate. We do
not intend to include in the technology review a reassessment of PM
filter technology needed to meet the optional 0.02 g/hp-hr PM standard
for 50-75 hp engines in 2012. We assume that manufacturers would only
choose this option if they had confidence that they could meet the 0.02
g/hp-hr standard in 2012, a year earlier than otherwise required.
We recognize the importance of harmonization of international
standards and have worked diligently with our colleagues in Europe and
Japan to achieve that objective. Harmonization of these standards will
allow manufacturers continued access to world markets and lower the
required research and development and tooling costs needed to meet
different standards. We will continue to work with both governments and
the manufacturers abroad and within the United States. We have
incorporated feedback from the on-going dialogue and have continued to
work through the international process as we have developed this
proposal. The Commission has proposed amendments in December 2002 to EC
Directive 97/68 which are currently being addressed in the European
Council and Parliament. We believe that today's proposal and the
European approach together provide the framework for additional
harmonization. While not identical, manufacturers have expressed
appreciation for the similarities which do exist and they represent a
significant step toward mitigating the differences in design challenges
that would otherwise exist. The limit values and test procedures
provide a basis for common development which manufacturers can use on a
global basis. The amendments would control fuel sulfur levels to enable
aftertreatment, set nonroad mobile machine emissions limits that would
be based on performance of diesel particulate traps. NOX
limits are being set to match the Agency's Tier 3 NOX
program. There are a few differences in approaches that we will
continue to discuss with the EU. One difference is that the EC has
chosen a leadtime for trap-based PM standards for engines in the 50-100
hp range which is one year earlier than we are proposing today. Another
difference is the inclusion of a review of the availability of
NOX emission control technology for larger engines. The EC
has also chosen not to set performance requirements that would require
the use of PM traps for engines under 50 hp, while we are proposing
performance-based standards that would likely require the use of PM
traps for engines between 25-75 hp. The EC has again chosen not to set
standards for engines below 19 kW (25 hp) and greater than 560 kW (750
hp). With respect to long term NOX control, the Commission
has chosen to have a technology review (which would also reassess
issues related to PM) to address implementing potentially more
stringent NOX standards in the same timeframe as potential
EPA standards.\228\ For additional information about the harmonization
effort and the results to date, please see chapter 2.4.2 of the SBREFA
panel report. We request comment on opportunities to further enhance
harmonization.
---------------------------------------------------------------------------
\228\ Commission of the European Communities, ``Proposal for a
Directive of the European Parliament and of the Council amending
Directive 97/68/EC'', section 3.9.
---------------------------------------------------------------------------
We expect that any changes to the level or timing of emission
standards found appropriate in the 2007 review would be made as part of
a rulemaking process, and that process would take additional time after
the review is completed. If the 2007 review should determine that PM
trap technology is feasible for engine under 25 hp, or that advanced
NOX control technology is feasible for engines under 75 hp,
or that Tier 4 standards should be made more stringent in some other
way, we would expect the rulemaking implementing such changes to
provide for adequate lead time. Therefore, it would be premature for us
to target 2013 or any specific model year for implementing such
standards changes at this time. We solicit comment on the scope,
timing, and need for a future reassessment of emissions control
technology for nonroad diesel engines.
IV. Our Proposed Program for Controlling Nonroad, Locomotive and Marine
Diesel Fuel Sulfur
We are proposing to reduce the sulfur content of nonroad,
locomotive and marine (NRLM) diesel fuel to no more than 500 ppm
beginning in 2007. We are also proposing to reduce the sulfur content
of nonroad diesel fuel to no more than 15 ppm beginning in 2010. These
provisions mirror controls on highway diesel fuel to 500 ppm in 1993
\229\ and 15 ppm in 2006.\230\
---------------------------------------------------------------------------
\229\ 55 FR 34120 (August 21, 1990).
\230\ 66 FR 5002 (January 18, 2001).
---------------------------------------------------------------------------
There are two reasons that we are proposing these standards. First,
fuel sulfur significantly inhibits or impairs the function of the
diesel exhaust emission control devices, which would generally be
necessary to meet the proposed nonroad diesel engine emission
standards. In conjunction with the proposed 15 ppm sulfur standard for
nonroad diesel fuel we have concluded that this emission control
technology will be available to achieve the reductions required by the
stringent NOX and PM emission standards proposed for model
year 2011 and later nonroad diesel engines. Second, sulfur in diesel
fuel is emitted from the engine as sulfate PM and sulfur dioxide, both
of which cause adverse health and welfare impacts, as described in
section II. above. Reducing the level of sulfur in diesel fuel to 500
ppm beginning in 2007 would achieve important emission reductions of
these pollutants and provide significant public health and welfare
benefits. The further reduction to 15 ppm in 2010 will expand upon
these benefits.
In developing the proposed diesel fuel program, we identified
several principles that we wanted the program to achieve:
[[Page 28401]]
(1) Maintain the benefits and program integrity of the highway
diesel fuel program;
(2) Achieve the greatest reduction in sulfate PM and sulfur dioxide
emissions from nonroad, locomotive, and marine diesel engines as early
as practicable;
(3) Provide for a smooth transition of the nonroad diesel fuel pool
to 15 ppm sulfur;
(4) Ensure that 15 ppm sulfur diesel fuel is produced and
distributed widely for use in all 2011 and later model year nonroad
engines;
(5) Enable the efficient distribution of all diesel fuels; and
(6) Ensure that the program's requirements are enforceable and
verifiable.
As described below, we believe the proposed fuel program achieves
these principles.
The remainder of this section is organized as follows:
(A) The fuel standards proposed today,
(B) The design and structure of the fuel program,
(C) Special hardship provisions proposed for small refiners and
refiners facing particularly difficult circumstances,
(D) Special provisions proposed for fuel sold in the State of
Alaska and U.S. Territories,
(E) The affect of the proposed program on state diesel fuel control
programs,
(F) The technological feasibility of the production and
distribution of 500 ppm and 15 ppm sulfur nonroad, locomotive and
marine diesel fuel,
(G) The impact of the program on other fuel properties and
specialty fuels, and
(H) The need for some refiners to obtain air permits for their
desulfurization equipment.
Analyses supporting the design of these provisions can be found in
chapter V and VII of the Draft RIA for today's action. Section VIII of
this preamble provides a discussion of the compliance and enforcement
provisions affecting diesel fuel and additional explanation of various
elements of the proposed program.
A. Proposed Nonroad, Locomotive and Marine Diesel Fuel Quality
Standards
The following paragraphs describe the requirements, standards, and
deadlines that apply to refiners, importers, and distributors of
nonroad, locomotive and marine (NRLM) diesel fuel and the options
available to all refiners.
1. What Fuel Is Covered by This Proposal?
The proposed standards generally cover all the diesel fuel that is
used in mobile applications but is not already covered by the previous
standards for highway diesel fuel. This fuel is defined primarily by
the type of engine which it is used to power: nonroad, locomotive, and
marine diesel engines. These fuels typically include:
(1) Any number 1 and 2 distillate fuels used, intended for use, or
made available for use in nonroad, locomotive or marine diesel engines,
(2) Any number 1 distillate fuel (e.g., kerosene) added to such
number 2 diesel fuel, e.g., to improve its cold flow properties, and
(3) Any other fuel used in or blended with diesel fuel for use in
nonroad, locomotive, or marine diesel engines that has comparable
chemical and physical characteristics.
Primary examples of fuels under (1) would be those meeting ASTM
D975 or D396 specifications for grades number 1-D and number 2-D or
ASTM DMX and DMA specifications, if used in the engines mentioned
above. Primary examples under (3) would be certain specialty fuels
grades such as JP-5, JP-8, and F76 if used in nonroad, locomotive, or
marine equipment for which a national security exemption has not been
approved (See section VIII.A.2) and non-distillate fuels such as
biodiesel.
This proposal would not apply to:
(1) Number 1 distillate fuel used to power jet aircraft,
(2) Number 1 or number 2 distillate fuel used for other purposes,
such as to power stationary diesel engines or for heating,
(3) Number 4 and 6 fuels (e.g., bunker or residual fuels, IFO Heavy
Fuel Oil Grades 30 and higher, ASTM DMB and DMC fuels), and
(4) Any fuel used to power equipment for which a national security
exemption has been approved (see section VIII.A.2).
The proposed program would reduce the sulfur in all diesel fuel
likely used in mobile off-highway equipment and achieve very
significant short and long-term environmental benefits. States, not the
Agency, have responsibility for any fuel sulfur specifications for
heating oil, so this fuel would not be covered by this proposal.\231\
However, we do propose a number of provisions, as described below, that
would ensure that heating oil would not be used in nonroad, locomotive,
or marine applications.
---------------------------------------------------------------------------
\231\ For the purposes of this proposal, the term heating oil
refers to any number 1 or number 2 distillate other than jet fuel
and diesel fuel used in highway, nonroad, locomotive, or marine
applications. For example, heating oil includes fuel which is
suitable for use in furnaces, boilers, stationary diesel engines and
similar applications and is commonly or commercially known or sold
as heating oil, fuel oil, and other similar trade names.
---------------------------------------------------------------------------
As in the recent highway diesel rule, in those cases where the same
batch of kerosene is distributed for two purposes (e.g., as kerosene to
be used for heating and to improve the cold flow of number 2 nonroad
diesel fuel), that batch of kerosene would have to meet the standards
being proposed today for nonroad diesel fuel. However, an alternative
compliance approach would be to produce and distribute two distinct
kerosene fuels. In our example above, one batch would meet the proposed
sulfur standards and could be blended into number 2 NRLM diesel fuel.
The other batch would only have to meet any applicable specifications
for heating oil.
2. Standards and Deadlines for Refiners, Importers, and Fuel
Distributors
The proposed fuel program consists of a two-step program to reduce
the sulfur content of nonroad diesel fuel. By doing so, the program
would allow the refining industry to smoothly transition the sulfur
content from its current uncontrolled levels down to the very stringent
15 ppm level. By beginning with an initial step down to 500 ppm, we can
start to achieve significant emission reductions and associated health
and welfare benefits from the current fleet of equipment as soon as
possible. While we considered and are seeking comment on a one-step
approach of going directly to 15 ppm in 2008, as discussed in section
VI, we believe that on balance the advantages of the proposed two-step
approach outweigh those of a single step.
The specific proposed deadlines for meeting the 500 and 15 ppm
sulfur standards would not apply to refineries covered by special
hardship provisions for small refiners. In addition, a different
schedule would apply for any refineries approved under the proposed
general hardship provisions. All of these hardship provisions are
described below in section IV.C.
a. The First Step to 500 ppm
Under this proposal NRLM diesel fuel produced by refiners or
imported into the U.S. would be required to meet a 500 ppm sulfur
standard beginning June 1, 2007. Refiners and importers could comply by
either producing such fuel at or below 500 ppm, or could comply by
obtaining credits as discussed in Section B below.
We believe that the proposed level of 500 ppm is appropriate for
several reasons. This 500 ppm level is consistent with current highway
diesel fuel, a grade which may remain for
[[Page 28402]]
highway purposes until 2010. As such, adopting the same 500 ppm level
for NRLM helps to avoid any issues and costs associated with more
grades of fuel in the distribution system during this initial step of
the program. The reduction to 500 ppm is also significant
environmentally. The 500 ppm level achieves approximately 90 percent of
the sulfate PM and SO2 benefits otherwise achievable by
going all the way to 15 ppm. Yet, the costs would be roughly half that
associated with full control down to 15 ppm. Because this first step is
only to 500 ppm, it also allows for a short lead time for
implementation, enabling the environmental benefits to begin accruing
as soon as possible. After careful analysis of feasibility as discussed
in section IV.F.5, we believe that the proposed start date of June 1,
2007, is the earliest that the 500 ppm step could take effect.
To allow for the enforcement of the proposed fuel standards while
at the same time allowing for a smooth and orderly transition of diesel
fuel in the distribution system to 500 ppm, we are proposing that
parties downstream of the refineries be allowed time to turnover their
NRLM tanks to 500 ppm. We are proposing that at the terminal level,
NRLM diesel fuel would be required to meet the 500 ppm sulfur standard
beginning August 1, 2007. At bulk plants, wholesale purchaser-
consumers, and any retail stations carrying NRLM diesel, this fuel
would have to meet the 500 ppm sulfur standard by October 1, 2007.\232\
The only exceptions to these dates would be for high sulfur NRLM
produced under the hardship and fuel credit provisions discussed below
in sections IV.B. and C.\233\
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\232\ A bulk plant is a secondary distributor of refined
petroleum products. They typically receive fuel from terminals and
distribute fuel in bulk by truck to end users. Consequently, while
for highway fuel, bulk plants often serve the role of a fuel
distributor, delivering fuel to retail stations, for nonroad fuel,
they often serve the role of the retailer, delivering fuel directly
to the end-user.
\233\ Furthermore, as discussed in subsection B, we propose that
high sulfur nonroad diesel fuel which is produced after June 1, 2007
due to the small refiner and fuel credit provisions could be
commingled with 500 ppm nonroad diesel fuel after it has been dyed
to the IRS specifications. Thus, at some points in the distribution
system, nonroad fuel higher than the 500 ppm standard would remain
until it is precluded from production beginning June 1, 2010.
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This downstream turnover schedule is slightly more relaxed than for
the second step to 15 ppm discussed below. This first step down to 500
ppm is designed to achieve the public health and welfare benefits from
reduced emissions in the current fleet of engines. Since the sulfate PM
and SO3 benefits accrue as the fuel is desulfurized to any
degree, mixing in the distribution system during the transition to 500
ppm would not reduce this benefit or cause any adverse consequences.
Mixing in the distribution system would also not reduce the engine
performance and durability benefits from the reduction in sulfur. As a
result, the immediate turnover of the fuel pool downstream of the
refinery gate is of less concern and a more relaxed schedule than
described below for the second step is possible. We seek comment on
this proposed schedule.
b. The Second Step to 15 ppm
In order to enable the application of high efficiency exhaust
emission control technologies to nonroad diesel engines beginning with
the 2011 model year, we are proposing that all nonroad diesel fuel
produced or imported after June 1, 2010, would have to meet a 15 ppm
sulfur cap. We are proposing that diesel fuel used for locomotive and
marine diesel engines could continue to the meet the 500 ppm cap first
applicable in 2007.
In order to allow for a smooth and orderly transition of diesel
fuel in the distribution system to 15 ppm, we are proposing that
parties downstream of the refineries be allowed some additional time to
turnover their tanks to 15 ppm. We are proposing that at the terminal
level, nonroad diesel fuel would be required to meet the 15 ppm sulfur
standard beginning July 15, 2010. At bulk plants, wholesale purchaser-
consumers, and any retail stations carrying nonroad diesel, this fuel
would have to meet the 15 ppm sulfur standard by September 1, 2010. The
proposed transition schedule for compliance with the 15 ppm standard at
refineries, terminals, and secondary distributors is the same as that
allowed under the recently promulgated highway diesel fuel program.
As with the 500 ppm standard, refiners and importers could comply
with this standard by either physically producing 15 ppm fuel or by
obtaining sulfur credits, as described below.
We are seriously considering bringing the sulfur level of
locomotive and marine diesel fuel to 15 ppm as early as June 1, 2010,
along with nonroad diesel fuel. As discussed in more detail in section
VI and in chapter 12 of the draft RIA, there are several advantages
associated with this alternative. First, it would provide important
sulfate PM and SO3 emission reductions and the estimated
benefits from these reductions would outweigh the costs by a
considerable margin. Second, it would simplify the fuel distribution
system and the design of the fuel program proposed today. Third, it
would help reduce the potential opportunity for misfueling of 2007 and
later model year highway vehicles and 2011 and later model year nonroad
equipment with higher sulfur fuel. Finally, it would allow refiners to
coordinate plans to reduce the sulfur content of all of their nonroad
diesel fuel at one time.
However, discussions with refiners have suggested there are
advantages to leaving locomotive and marine diesel fuel at 500 ppm, at
least in the near-term and until we set more stringent standards for
those engines. The locomotive and marine diesel fuel markets could
provide a market for off-spec product which is important for refiners,
particularly during the transition to 15 ppm for highway and nonroad
diesel fuel in 2010. Waiting just a year or two beyond 2010 would
address the critical near term needs during the transition. Second,
waiting just another year or two beyond 2010 is also projected to allow
virtually all refiners to take advantage of the new lower cost
technology.
In addition to seeking comment on whether to apply the 15 ppm
standard to locomotive and marine diesel fuel in 2010, we also seek
comment on other timing for doing so, and especially on how the Agency
should coordinate a 15 ppm standard for locomotive and marine with the
nonroad diesel fuel standard being proposed today. It is the Agency's
intention to propose in the near future new emission standards for
locomotive and marine engines that could require the use of high
efficiency exhaust emission control technology, and thus, also require
the use of 15 ppm sulfur diesel fuel. We anticipate that such engine
standards would likely take effect in the 2011-13 time frame, requiring
15 ppm locomotive and marine diesel fuel in the 2010-12 time frame. We
intend to publish an advanced notice of proposed rulemaking (ANPRM) for
such a rule in the Spring of 2004 and complete action on a final rule
by 2007.
c. Other Standard Provisions
We are proposing that the 500 ppm NRLM and 15 ppm nonroad diesel
fuel standards would apply to the areas of Alaska served by the Federal
Aid Highway System (FAHS). Rural areas, those outside the FAHS, would
not be subject to either the 15 or 500 ppm standards. Market forces in
these areas would be relied upon to provide 15 ppm diesel fuel for 2011
and later nonroad diesel engines used in these areas. This is
consistent with the approach which is
[[Page 28403]]
in the process of being developed by the State of Alaska for
implementing the 2007 highway diesel fuel program. EPA can revisit this
issue when it takes action on Alaska's plan for implementation of the
highway sulfur requirements, allowing for coordination of the nonroad
and highway fuel requirements. The specifics of our proposal for diesel
fuel sold in Alaska are described in more detail in section IV.D.1.
below. In addition, these proposed 500 and 15 ppm sulfur caps would not
apply to diesel fuel sold in three Pacific U.S. territories, as
described in more detail in section IV.D.2. below.
The early credits and other special provisions create the
probability that high sulfur NRLM diesel fuel would be produced and
sold after June 1, 2007, and that 500 ppm nonroad diesel fuel would be
produced and sold after June 1, 2010. Under the proposal, fuel
distributors would be responsible for ensuring the necessary product
segregations and that statements on product transfer documents and fuel
product labels are consistent with the corresponding fuel quality. The
specific requirements for both fuel distributors and end-users are
described in detail in section VIII.
d. Cetane Index or Aromatics Standard
Currently, in addition to containing no more than 500 ppm sulfur,
EPA requires that highway diesel fuel meet a minimum cetane index level
of 40 or, as an alternative contain no more than 35 volume percent
aromatics. We are proposing today to extend this cetane index/aromatics
content specification to NRLM diesel fuel. Extension of these content
specifications would reduce NOX and PM emissions from the
current nonroad equipment fleet slightly, providing associated public
health and welfare benefits.
Low diesel fuel cetane levels are associated with increases in
NOX and PM emissions in current nonroad diesel engines.
Thus, we expect that this cetane index specification would lead to a
reduction in these emissions from the existing fleet. Because the vast
majority of current NRLM diesel fuel already meets this specification,
the NOX and PM emission reductions would be small. Also, the
impact of cetane on NOX and PM emissions appears to be very
weak or nonexistent for diesel engines equipped with EGR. Thus, the
positive emission impact of this specification would likely decrease
over time as these engines gradually dominate the in-use fleet.
ASTM already applies a cetane number specification of 40 to NRLM
diesel fuel, which in general is more stringent than the similar 40
cetane index specification. Because of this, the vast majority of
current NRLM diesel fuel already meets the EPA cetane index/aromatics
specification for highway diesel fuel. Thus, the proposed requirement
would have an actual impact only on a limited number of refiners and
there would be little overall cost associated with producing fuel to
meet the proposed cetane/aromatic requirement. In fact, as discussed in
section 5.9 of the draft RIA, complying with the sulfur standards
proposed today is expected to result in a small cetane increase,
leaving little or no further control to meet the standard.
In addition, we expect that if all NRLM fuel met the cetane index
or aromatics specification as proposed, refiners would benefit from the
ability to fungibly (mixed together) distribute highway and NRLM diesel
fuels of like sulfur content. For that fraction of fuel that today does
not meet this specification, the proposed requirement would eliminate
the need to separately distribute fuels of different cetane/aromatics
specifications that would otherwise need to occur. Requiring NRLM
diesel fuel to meet this cetane index specification would thus give
fuel distributors certainty in being able to combine shipments of
highway and NRLM diesel fuels. Overall, we believe that the economic
benefits from more efficient fuel distribution would likely exceed the
cost of refining the small volume of NRLM diesel fuel that might not
currently meet the cetane index or aromatics content specification.
We request comment on the costs and benefits of our proposal to
extend the cetane index and alternative aromatics standard applicable
to highway diesel fuel to NRLM diesel fuel.
B. Program Design and Structure
In addition to the proposed content standards and their timing, the
program must be designed and structured carefully to achieve the
overall principles of this proposed nonroad diesel fuel program. The
health and welfare benefits and the need for widespread availability of
15 ppm highway diesel fuel must be maintained. This will only happen if
the program is designed such that the amount of low sulfur fuel
expected to be produced under the highway diesel program is in fact
produced. Likewise, the benefits of the low sulfur diesel program
proposed today will only be achieved if the program is designed such
that the volume of diesel fuel consumed by NRLM engines is matched by
the production and distribution of at least the same volume of diesel
fuel produced to the appropriate low sulfur levels. At the same time,
promoting the efficiency of the distribution system calls for fungible
distribution of physically similar products, and minimizing the need
for segregation of products in the distribution system.
1. Background
Prior to the highway diesel sulfur standard that took effect in
1993, most number 2 distillate fuel was produced to essentially the
same specifications, shipped fungibly, and used interchangeably for
highway diesel engines, nonroad diesel engines, locomotive and marine
diesel engines and heating oil applications. Beginning in 1993, highway
diesel fuel was required to meet a 500 ppm sulfur cap and was
segregated from other distillate fuels as it left the refinery by the
use of a visible level of dye solvent red 164 in all non-highway
distillate.\234\ At about the same time, the IRS similarly required
non-highway diesel fuel to be dyed red to a much higher concentration
prior to retail sale to distinguish it from highway diesel fuel for
excise tax purposes. Dyed non-highway fuel is exempt from this tax.
This splitting of the distillate pool necessitated changes in the
distribution system to ship and store the now distinct products
separately. In some parts of the country where the costs to segregate
non-highway diesel fuel from highway diesel fuel could not be
justified, both fuels have been produced to the highway
specifications.\235\
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\234\ Non-highway distillate for the purposes of this proposal
refers to all diesel fuel and distillate used for nonroad,
locomotive, marine and heating oil purposes; in other words, all
number 1 or number 2 distillate other than that used for highway
purposes, and excluding jet fuels.
\235\ Diesel fuel produced to highway specifications but used
for non-highway purposes is referred to as ``spill-over.'' It leaves
the refinery gate and is fungibly distributed as if it were highway
diesel fuel, and is typically dyed at a point later in the
distribution system. Once it is dyed it is no longer available for
use in highway vehicles, and is not part of the supply of highway
fuel. Based on the most recent EIA data, roughly 15 percent of fuel
produced to highway specifications is spillover, representing nearly
a third of non-highway consumption.
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This proposal would set new specifications for nonroad, locomotive,
and marine diesel fuel. However, currently there is no grade of diesel
fuel which is produced and marketed as a distinguishable grade for NRLM
uses. It is typically produced and shipped fungibly with other
distillate used for heating oil purposes, and it is all dyed red in
accordance with EPA and IRS regulations. Therefore, in order to control
the sulfur content of NRLM, but
[[Page 28404]]
not heating oil, this proposal requires some means of distinguishing
fuel used for the two purposes. This is similar to the situation faced
in 1993 in the case of highway diesel fuel. The solution in 1993 for
highway diesel fuel was to dye the non-highway distillate. As discussed
below, a similar approach is proposed today to identify and distinguish
heating oil from NRLM.
This proposal would control the sulfur level of NRLM diesel fuel to
500 ppm in 2007, the same level currently applicable to highway diesel
fuel, and the same level as up to 20 percent of the highway diesel fuel
pool from June 1, 2006, through December 31, 2009. Under the current
provisions of the highway diesel rule, this 500 ppm nonroad diesel fuel
would have to be dyed red at the refinery gate and distributed
separately from 500 ppm highway diesel fuel.
Continuing to implement this dye provision would allow for simple
enforcement of both the proposed NRLM standard and the more stringent
highway standards during this timeframe. Clear, undyed diesel fuel
would have to meet the 80/20 ratio of 15 ppm and 500 ppm applicable to
highway fuel, and diesel fuel (dyed red) would have to meet the 500 ppm
standard applicable to NRLM. Continuing the current dye provisions
would therefore ensure that the intended benefits of both programs were
achieved. However, maintaining this dye distinction would also require
segregation of a new grade of diesel fuel, 500 ppm NRLM, throughout the
entire distribution system. The costs of requiring segregation of two
otherwise identical fuels throughout the entire distribution system
could be quite substantial.\236\
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\236\ Under the highway program the potential exists to add a
third grade of diesel fuel in an estimated 40% of the country, and
we projected one-time tankage and distribution system costs of $1.05
billion to accomplish this. Using similar assumptions, to add a
second 500 ppm grade nationwide would cost in excess of $2 billion.
This assumes that the capability exists to add such new tankage.
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In order to avoid adding unnecessary cost to the fuel distribution
system, we are proposing that the current requirement that non-highway
distillate fuels be dyed at the refinery gate be made voluntary
effective June 1, 2006.\237\ However, in its place we are proposing an
alternate means for refiners to differentiate their highway diesel fuel
from NRLM diesel fuel (see IV.B.3 below). Where it is feasible and cost
effective to continue to dye and segregate their nonroad fuel, we
propose that refiners and importers may continue this option.
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\237\ The IRS requirements concerning dyeing of non-highway fuel
prior to sale to consumers are not changed by this rulemaking.
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Since 500 ppm highway and NRLM diesel fuel would physically be the
same, without some means of differentiating highway diesel fuel from
NRLM diesel fuel, it would be impossible to maintain the benefits and
program integrity of the 2006 highway diesel fuel program. Pre-2007
model year highway vehicles are free to continue using 500 ppm fuel
until 2010 as long as it is available. However, if a refiner produced
all 500 ppm fuel, designating it as nonroad fuel, that refiner would
have no obligation to produce any 15 ppm highway diesel fuel. Without
an effective way of limiting the use in the highway market of 500 ppm
diesel fuel produced as NRLM fuel (provided currently by the refinery
gate dye requirement), much more 500 ppm fuel could, and likely would
find its way into the highway market than would otherwise happen under
the current highway program, displacing 15 ppm that would have
otherwise been produced. This likely series of events would circumvent
the 80/20 intent of the highway rule and sacrifice some of the
resulting PM and SO3 emission benefits of that program.
Perhaps more importantly, if this occurred to any significant degree,
it could also undermine the integrity of the highway program by failing
to ensure adequate availability of 15 ppm fuel nationwide for the
vehicles that need it.
2. Proposed Fuel Program Design and Structure
a. Program Beginning June 1, 2007
To avoid the costs associated with segregating 500 ppm NRLM diesel
fuel from 500 ppm highway fuel, we propose that the existing
requirement that NRLM diesel fuel be dyed leaving the refinery would be
made voluntary. We propose that this change could occur as early as
June 1, 2006. In its place we propose that a baseline volume percentage
of non-highway diesel fuel would be established and enforced for each
refinery and importer. The baseline percentage would be based on a
historical average for a refinery or importer. The baseline percentage
of non-highway diesel fuel would then be used to identify the amount of
500 ppm diesel fuel produced by that refinery or importer that is
subject to the NRLM requirements and the amount of 500 ppm fuel is
subject to the highway requirements. As detailed below, in conjunction
with a marker to prevent the use of heating oil in nonroad equipment,
the baseline percentage would effectively protect the benefits and
integrity of the highway program, ensure that the benefits of the first
step of NRLM diesel fuel to 500 ppm sulfur would be obtained, and would
enable the efficient, fungible distribution of like grades of fuel. A
discussion of this proposal follows, beginning with the introduction of
a fuel marker for heating oil.
i. Use of A Marker to Differentiate Heating Oil From NRLM
If all NRLM diesel fuel were required to meet the 500 ppm standard
beginning June 1, 2007, then heating oil and NRLM diesel fuel could be
differentiated merely on the basis of their sulfur levels. However,
this proposal would allow the limited production of high-sulfur NRLM
fuel by small refiners, and by other refiners through the use of
credits between 2007 and 2010 (see section IV.B.2.b). To ensure that
the only high sulfur diesel fuel used in nonroad, locomotive, and
marine diesel engines is high sulfur NRLM and not heating oil, it would
be necessary for parties in the distribution system, and for EPA, to be
able to distinguish heating oil from high-sulfur NRLM diesel fuel. One
way of ensuring that these fuels remain segregated in the distribution
system would be to require that either a dye or a marker be added to
heating oil to distinguish it from NRLM diesel fuel during the period
of 2007 through 2010.\238\ There is no differentiation today between
fuel used for NRLM uses and heating oil. Both are typically produced to
the same sulfur specification today, and both are required to have the
same red dye added prior to distribution and sale.\239\ As a result,
the dye or marker would have to be different from the current red dye
requirement.
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\238\ A marker is an additive which is phosphorescent or has
some other property which allows it to be easily detected, though
not necessarily visible to the naked eye. A dye is intended to be
visibly identified by the naked eye.
\239\ There may be some exceptions where a refiner produces a
unique grade of distillate fuel solely for heating oil purposes.
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There are a number of types of dyes and markers. Visible dyes are
most common, are inexpensive, and are easily detected. Invisible
markers are beginning to see more use in branded fuels and are somewhat
more expensive than visible markers. Such markers are detected either
by the addition of a chemical reagent or by their fluorescence when
subjected to near-infra-red or ultraviolet light. Some chemical-based
detection methods are suitable for use in the field. Others must
[[Page 28405]]
be conducted in the laboratory due to the complexity of the detection
process or concerns regarding the toxicity of the reagents used to
reveal the presence of the marker. Near-infra-red and ultra-violet
flourescent markers can be easily detected in the field using a small
device and after brief training of the operator. There are also more
exotic markers available such as those based on immunoassay, and
isotopic or molecular enhancement. Such markers typically need to be
detected by laboratory analysis.
Using a second dye for segregation of heating oil based on visual
identification raises certain challenges. Most dye colors that provide
a strong visible trace in fuels are already in use for different fuel
applications. More importantly, mixing two fuels containing different
strong dyes can result in interference between the two dyes rendering
identification of the presence of either dye difficult. Yet, the mixing
of NRLM diesel fuel into heating oil for eventual sale as heating oil
would be an acceptable and often an economically desirable practice.
Furthermore, to avoid interfering with the IRS tax code, it would be
advantageous to maintain the current red color. Based on these
considerations, the best approach to prevent the use of heating oil as
NRLM diesel fuel would appear to be requiring the addition to heating
oil of either a dye that does not impart a significant color to diesel
fuel or a marker that imparts no color at all. The dye or marker would
be added at the refinery gate, just as visible evidence of the red dye
is required today. Fuel containing the marker would be segregated from
highway and NRLM diesel fuel and would be prohibited from use in
highway, nonroad, locomotive, or marine application.
Effective in August 2002, the European Union (EU) enacted a marker
requirement for diesel fuel that is taxed at a lower rate (which
applies in all of the EU member states).\240\ The marker selected by
the EU is N-ethyl-N-[2-[1-(2-methylpropoxy)ethoxyl]-4-phenylazo]-
benzeneamine.\241\ This compound is also referred to as solvent yellow
124 or the Euromarker. We propose that beginning June 1, 2007, solvent
yellow 124 must be added to heating oil in the U.S. We propose that it
be added in a concentration of 6 milligrams per liter, the same
treatment rate as required by the EU. This would ensure adequate
detection in the distribution system even if diluted by a factor of 50.
A level of 0.1 milligrams per liter would therefore be used as a
threshold level to identify heating oil--below this level incidental
contamination would be assumed to have occurred and the prohibition on
use in highway, nonroad, locomotive, or marine applications would not
apply. Despite its name, solvent yellow 124 does not impart a strong
color to diesel fuel when used at the proposed concentration.
Therefore, we do not expect that its use in diesel fuel containing the
IRS-specified red dye would interfere with the use of the red dye by
IRS to identify non-taxed fuels. We request comment on this assessment.
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\240\ The European Union marker legislation, 2001/574/EC,
document C(2001) 1728, was published in the European Council
Official Journal, L203 28.072001.
\241\ Opinion on Selection of a Community-wide Mineral Oils
Marking System, (``Euromarker''), European Union Scientific
Committee for Toxicity, Ecotoxicity and the Environment plenary
meeting, September 28, 1999.
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Solvent yellow 124 is chemically similar to other additives used in
gasoline and diesel fuel, and has been registered by EPA as a fuel
additive under 40 CFR part 79. Its products of combustion would not be
anticipated to have an adverse impact on emission control devices, such
as a catalytic converter. In addition, extensive evaluation and testing
of solvent yellow 124 was conducted by the EC. This included combustion
testing which showed no detectable difference between the emissions
from marked and unmarked fuel. We understand that Norway specifically
evaluated the use of distillate fuel containing solvent yellow 124 for
heating purposes and determined that the presence of the Eurmarker did
not cause an increase in harmful emissions from heating equipment.
Based on the European experience with solvent yellow 124, we do not
expect that there would be concerns regarding the compatibility of
solvent yellow 124 in the U.S. fuel distribution system or for use in
motor vehicle engines and other equipment such as in residential
furnaces. We request comment on whether there are unique public health
concern regarding the use of distillate fuel containing solvent yellow
124. The European Union intends to review the use of Solvent yellow 124
after December 2005, or earlier if any health and safety or
environmental concerns about its use are raised. We intend to keep
abreast of such activities and may initiate our own review of the use
of solvent yellow 124 depending on the European Union's findings.
We also request comment on the extent to which jet fuel might
become contaminated with solvent yellow 124 due to the presence of
solvent yellow 124-containing fuels and jet fuel in the U.S. common
carrier pipeline distribution system, and whether such contamination
would raise concerns for the operation of jet engines. Due to safety
concerns, jet fuel is held to very strict standards regarding the
allowable presence of contaminants and additives. For example, the
Department of Defense maintains a zero-tolerance for any contamination
of jet fuel with the red dye required by the IRS (and EPA) which is
chemically similar to solvent yellow 124. We are not aware that any
testing has been done to date to assess whether solvent yellow 124 does
raise similar concerns, and we request comment with any supporting data
on this issue.
We do not believe that there any significant pathways for such
contamination to take place other than by potential human error. In
addition, the fact that the fuel distribution industry in the U.S. has
been successful in managing contamination of jet fuel with red dye
indicates that the potential contamination of jet fuel with solvent
yellow 124 can also be successfully managed in the U.S. fuel
distribution system. Therefore, we believe that our proposed use of
solvent yellow 124 should not pose a significant risk to the
maintenance of jet fuel purity. We request comment on this assessment.
Solvent yellow 124 is marketed by several manufactures and is in
current wide-scale use in the European community. We anticipate that
these manufactures would have sufficient lead-time to increase their
production of solvent yellow 124 to supply the need for fuel marker
that would result from this proposal. We request comment on whether
there are product licencing or other concerns regarding the manufacture
of solvent yellow 124 for use under this proposed rule.
We request comment on other potential markers that might be used to
identify and segregate heating oil from NRLM fuel. In particular, we
ask that as commenters raise potential concerns with the use of solvent
yellow 124 that they also identify other possible markers that could
overcome their concerns without raising others. One potential
alternative we have identified is the Clir-Code[reg] marker system
manufactured by ISOTAG Technologies Inc. The Clir-Code[reg] marker
system has been used extensively in U.S. fuel and includes a field test
that employs a hand-held near infra-red detector which does not require
the use of any reagents. EPA deferred proposing the use of the Clir-
Code[reg] marker because we believe that the advantage of a simpler
field test would not compensate for the increased
[[Page 28406]]
treatment cost relative to the use of solvent yellow 124. We
furthermore seek comment on whether more than one marker could be
selected, but which could all be detected using the same detection
method. In this manner refiners would not be dependent on a sole
supplier for the marker. Additional discussion of the rationale for our
selection of solvent yellow 124 and the feasibility of its use is
contained in Chapter 5 of the Draft RIA.
Since marked heating oil would be a relatively small volume product
in many parts of the country, we anticipate that it will not be carried
everywhere as a separate fungible product. In places where it is not
carried as a separate fungible grade we anticipate that most shipments
of marked heating oil will be from refinery racks or other segregated
shipments directly into end-user tankage. In these areas any distillate
supplied from the fungible supply system for heating oil purposes will
therefore likely be spillover from 500 ppm NRLM supply. Clearly, in
those parts of the country with high demand for heating oil,
particularly the Northeast and Pacific Northwest, we anticipate that
marked heating oil will in fact be carried by the distribution system
as a separate fungible product. To the extent this is the case, it is
entirely possible that heating oil will no longer be produced to diesel
fuel cetane or aromatic specifications, reducing production costs. The
most difficult to desulfurize streams in a refinery are in fact those
that are low in cetane and high in aromatics. Shifting these streams to
a unique heating oil product can therefore reduce desulfurization
costs, while still producing a high quality heating oil (though we have
not reflected this in our cost analysis in section V.)
ii. Non-highway Distillate Baseline Cap
As discussed above, we are proposing use of a marker in heating oil
to effectively distinguish uncontrolled heating oil from NRLM fuel, so
that the NRLM standards can be enforced throughout the distribution
system and at the end-user. However, in order to allow for the fungible
distribution of highway diesel fuel and NRLM, and continue to have
enforceable highway diesel fuel standards in the absence of a NRLM dye
requirement, we are proposing that a non-highway distillate baseline
percentage be established for each refinery and importer in the
country. This non-highway baseline would be defined as the volume
percentage of all diesel fuel and heating oil (number 1 and number 2)
that a refinery or importer produced or imported during the specified
baseline period that was dyed for non-highway purposes.
We propose that if a refiner chooses to fungibly distribute its
NRLM and highway fuels, then under the first step of the nonroad
program (June 1, 2007--June 1, 2010), the volume of diesel fuel
represented by its non-highway baseline percentage would have to either
meet the 500 ppm NRLM standard or be marked as heating oil. All the
remaining production would have to meet the requirements of the highway
fuel program (i.e., 80 percent of this fuel would have to meet a 15 ppm
sulfur cap). As we recognized in the highway rule, some variation in
the production of highway and non-highway diesel fuel is normal from
year to year. As a result, in any given year it may be possible that a
refiner is unable to produce the amount of 15 ppm diesel fuel required
to meet its highway requirement (80% of 100% minus the non-highway
baseline) simply because of this normal variation. The provisions of
the highway diesel rule already allow for a 5% shortfall in the
production of 15 ppm fuel in a year as long as it is made up in the
following year. We seek comment on whether any additional flexibility
beyond that provided in the highway rule is appropriate to account for
normal fluctuations in refinery output.
An example will help to explain the use of the baseline. Assume the
baseline non-highway percentage has been established as discussed below
and is 40%. That means 40% of the total diesel fuel production in the
baseline years was non-highway fuel, dyed at the refinery gate. If the
refinery then produced a total of 100,000,000 gallons of diesel fuel in
2008, 40,000,000 gallons would be its applicable non-highway baseline.
If it then produced and marked 10,000,000 gallons as heating oil,
30,000,000 gallons of the remaining diesel fuel (dyed or undyed) would
be subject to the NRLM standard of 500 ppm, and all the remaining
diesel fuel, 60,000,000 gallons, would be considered highway diesel
fuel and would have to meet the applicable 80/20 requirements.
We propose that a refiner, for each of its refineries, would need
to choose either to continue to dye all of its NRLM fuel at the
refinery gate, or to apply the non-highway baseline approach to all of
its production. If a refinery's production could be split between these
two options, the refiner could avoid the cap on NRLM imposed by the
baseline percentage by dyeing additional volumes over its baseline, for
example at their refinery rack or co-located terminal. The result could
be a diversion of extra 500 ppm fuel to the highway market while the
dyed 500 ppm fuel was used to serve the nonroad market, resulting in
little or no production of 15 ppm highway diesel fuel. Therefore, the
choice of whether to dye all of their 500 ppm NRLM fuel at the refinery
gate, or comply with the non-highway distillate baseline would have to
be made in advance. We propose that compliance with the baseline be
determined on an annual basis. We therefore also propose that the
decision of whether to dye NRLM 500 ppm fuel at the refinery gate or
comply with the baseline could also be made on an annual basis.
This approach allows a refinery's production of 500 ppm NRLM fuel
and heating oil to remain flexible in response to market demand, while
ensuring that the proportion of fuel they produce in the future to
highway and non-highway requirements remains consistent with their
historical baseline production. Since the non-highway baseline is set
as a percentage of production, the actual volume needed for compliance
with this baseline would rise and fall with the refinery's total
production of diesel fuel. In this way, it would provide refineries
with flexibility similar to that under the 80/20 volume percentage
provisions of the highway rule. If total production of diesel fuel
decreased, the absolute volume of diesel fuel which had to be produced
to highway or NRLM specifications would decrease. If total production
increased, the amount of diesel fuel subject to the 80/20 highway and
the NRLM standards would also increase. A refiner wishing not to be
limited to this non-highway distillate baseline percentage of
production could elect to segregate and dye its NRLM diesel fuel at the
refinery gate.
Like the current dye requirement, this approach would focus
compliance with the highway and NRLM requirements on the refinery or
importer. Once undyed 500 ppm or 15 ppm diesel fuel was produced or
imported and accounted for under the baseline percentage approach, it
could be mixed and shipped fungibly, and sold to either the highway or
the NRLM diesel fuel market by anyone further down the distribution
system. This would provide a significant degree of market flexibility
to refiners and distributors and enable the efficient distribution of
diesel fuel. Compliance with the non-highway baseline would be enforced
at the refinery gate in the same manner as the current 2006 highway
provisions. With the marker for heating oil, compliance with the 15 ppm
and 500 ppm standards could also be enforced through to the
[[Page 28407]]
end-user. But most importantly, this approach would maintain the health
benefits and fuel availability needs of the highway diesel fuel
program, because the overall volume of highway diesel fuel produced to
the 15 ppm cap would be maintained.
iii. Setting the Non-highway Distillate Baseline
The purpose of the non-highway baseline is to identify a historical
level of non-highway production occurring prior to implementation of
the provisions of this proposal, for use as a baseline after such
implementation. We propose to determine the non-highway baseline
percentage for each refinery by averaging the volume of dyed diesel
fuel and heating oil (number 1 and number 2, excluding jet fuel and
exported fuel) that it produced or imported annually over the three
year period from January 1, 2003, through December 31, 2005, and
dividing that volume by the average of all diesel fuel and heating oil
(number 1 and number 2, excluding jet fuel and exported fuel) it
produced or imported annually over the same period (and then multiplied
by 100).\242\ By using a multi-year average, variations that might
otherwise occur from year to year in a refinery's production will get
averaged out. Importers would establish a separate baseline for each
area of importation.\243\
---------------------------------------------------------------------------
\242\ Specialty fuels such as JP-5, JP-8 and F76 are in some
instances also used in nonroad diesel equipment today. However, our
expectation is that the majority of this fuel is today and will be
in the future continue to be used in tactical military equipment
that would be exempted from the provisions of this proposal.
Consequently, we propose that these fuels would not be counted in
either setting the baseline or in determining compliance with the
baseline.
\243\ The areas would be defined as the credit trading areas
(CTAs) as defined in the highway rule.
---------------------------------------------------------------------------
Selecting a baseline period prior to finalization of the final rule
would help to prevent the possibility of entities inappropriately
adjusting their operations solely for the purpose of modifying their
baseline. At the same time, setting a baseline period as close to the
implementation date as possible helps to capture the most recent
changes in the industry's production patterns. The proposed period of
January 1, 2003, through December 31, 2005, is split roughly equally
between production prior to the final rule and production after the
final rule to appropriately balance these competing objectives. One
advantage of ending the baseline period on December 31, 2005, is that
it allows the opportunity for refiners to generate credit for the early
production of 500 ppm NRLM fuel after that date, and at the same time
avoid having to dye it at the refinery gate. The three year period
serves to limit any potential actions to inappropriately adjust the
baseline that a refinery might otherwise attempt. A refiner or importer
would have to dye and sell a greater fraction of its fuel to the non-
highway market over an extended period of time to significantly modify
its baseline. The potential financial loss associated with this,
particularly if other refineries or importers tried to do the same
thing, would likely be prohibitive.
At the same time, we anticipate that a number of refiners may be
changing their highway diesel production volumes as they comply with
the highway diesel fuel standards in 2006. To the extent that a refiner
planned to lower its highway production in 2006, a non-highway baseline
set based on 2003-5 data would penalize them by forcing them to
continue to meet the highway requirements for a greater volume, based
on their pre-2006 production pattern. To avoid this situation, we
propose that refiners would be allowed to set their non-highway
baseline percentage using June 1, 2006, through May 31, 2007, as the
baseline time period. By doing so the refinery's baseline would
automatically take into account changes made for compliance with the
2006 highway standard. It would, however, preclude that refinery from
participating in the early NRLM credit program prior to June 1, 2007,
using the baseline approach, and would require them to continue dyeing
their NRLM at the refinery gate until June 1, 2007, since that is the
period during which the baseline was being established. Since the
purpose of this option is to provide an opportunity to account for the
physical changes refineries make in complying with the highway rule, we
propose that this option would only apply to refiners and not
importers.
Each refinery and importer would have to submit its application for
a non-highway baseline to EPA by February 28, 2006, along with the
supporting information. If the refinery elected to use the optional
baseline period, we propose that the refinery would have to submit its
application for a non-highway baseline to EPA by August 1, 2007. EPA
would then approve these baselines by June 1, 2006, and any optional
baselines by December 1, 2007. We propose that any refinery or importer
which was not in operation for the full period of January 1, 2003,
through December 31, 2005, would establish their baseline using data
from the period they were in operation, as long as that period was
greater than or equal to 12 months. The 12 months need not be
continuous. Any refinery or importer unable to establish a baseline
during this period would have to comply using the dye alternative. In
the case of a new or restarted refinery or new importer, we propose to
assign a non-highway baseline percentage reflecting the projected
average production of non-highway fuel in 2004 for their region of the
country. We propose to use the credit trading areas (CTAs) as defined
in the highway Based on data from the Department of Energy's Energy
Information Agency (EIA) on the current production of low and high
sulfur diesel fuel and heating oil, and EIA and EPA projections of
future fuel use, these PADD average non-highway baseline would be as
shown in Table IV-1.
---------------------------------------------------------------------------
\244\ A value of zero is proposed for California, since we
anticipate that all non-highway diesel fuel in California will be
covered by the same State standards applicable to highway diesel
fuel during this time period.
Table IV-1--Non-highway Baseline for New Refineries
--------------------------------------------------------------------------------------------------------------------------------------------------------
Oregon and California
PADD 1 PADD 2 PADD 3 PADD 4 Washington Alaska Hawaii \244\
--------------------------------------------------------------------------------------------------------------------------------------------------------
41%..................................... 20% 26% 13% 21% 68% 40% 0%
--------------------------------------------------------------------------------------------------------------------------------------------------------
In discussions with various refiners, there was a strong interest
in allowing refiners with multiple refineries and importers with
multiple points of import to aggregate the baselines across all of
their facilities nationwide. However, since the baselines determine how
much of a refineries production must comply with the highway standards,
allowing nationwide aggregation of the baselines would have the same
impact as allowing nationwide
[[Page 28408]]
averaging, banking, and trading of credits under the highway rule. That
approach was rejected in the highway rule due to the negative impact it
would have on the nationwide availability of 15 ppm highway diesel
fuel. For the same reason we are not proposing to allow nationwide
aggregation of the non-highway baselines. However, in the highway rule,
we do allow credit trading within certain credit trading areas (CTAs).
We seek comment on allowing the aggregation of non-highway baselines
within the same CTA and how such aggregation could be accomplished. We
also seek comment on whether a trading program could be established
that allowed for refiners with only one refinery within a CTA to
benefit from similar flexibility, and whether some reasonable
restrictions on refiners who aggregate baselines are needed to protect
the integrity of the highway program.
EPA requests comments on the provisions described above for
establishing the non-highway baseline percentage for each refinery and
importer. We also request comment on any alternative provisions that
could be used to accomplish the objectives discussed above.
iv. Diesel Sulfur Credit Banking, and Trading Provisions for 2007
This proposal includes provisions for refiners and importers to
generate early credits for production of 500 ppm NRLM fuel prior to
June 1, 2007. This will provide implementation flexibility at the start
of the 500 ppm NRLM standard in 2007. These credits would be tradeable
and could be used to delay compliance with either the 500 ppm NRLM
standard in 2007 or the 15 ppm nonroad standard in 2010. The proposed
banking and trading provisions would allow an individual refinery to
purchase credits and delay compliance. This would allow for a somewhat
smoother transition at the start of the program, with some refineries
complying early, others on time, and others a little later.
Nevertheless, on average the overall benefits of the program would be
obtained or perhaps increased, and some environmental benefits could be
achieved earlier than expected. Perhaps the most advantageous use of
these credit provisions, however, might be for individual refineries to
utilize available credits to permit the continued sale of otherwise
off-spec product during the start up of the program when they are still
adjusting their operations for consistent production to the new sulfur
standards.
Credit Generation
We propose two ways to generate credits that can be used to allow
for high sulfur NRLM fuel to be produced after June 1, 2007. First, we
propose that a refinery or importer can generate credit for early
production of NRLM diesel fuel to the 500 standard from June 1, 2006,
through May 31, 2007. Credits would be calculated either using the non-
highway baseline approach or by counting 500 ppm NRLM dyed at the
refinery gate. Refiners that chose to establish their non-highway
baseline using the June 1, 2006--May 31, 2007, baseline period would be
precluded from generating any early credits using the non-highway
baseline approach. Second, under the small refiner hardship provisions
described below in subsection C, small refiners could generate credits
for any production of NRLM fuel to the 500 ppm standard from June 1,
2007, through May 31, 2010. In either case, credits could be banked for
future use, or traded to any other refinery or importer nationwide. For
early credits and small refinery credits generated using the non-
highway baseline approach, these credits would be calculated according
to the following formula:
High-Sulfur NRLM credits \245\ = (15 ppm production volume + 500
ppm production volume )--(100%-non-highway baseline percentage) *
(total 1 and 2 distillate production excluding jet
fuel and exported fuel).
---------------------------------------------------------------------------
\245\ For the purposes of this proposal, the credits are labeled
on the basis of their use in order to follow the convention used in
the highway rule. A high-sulfur credit is generated through the
production of one gallon of 500 ppm NRLM fuel and allows the
production of one gallon of high sulfur NRLM fuel.
---------------------------------------------------------------------------
Early credits or small refinery credits generated using the dye
option would be calculated using the following formula: High-Sulfur
NRLM credits = 500 ppm production volume dyed at the refinery gate.
If the excess production was 15 ppm fuel instead of 500 ppm fuel,
the refiner would of course still have the option of using it to
generate 500 ppm highway credits under the existing highway diesel
provisions. Credit could not be earned under both programs.
Credit Use
There would be two ways in which refiners could use high-sulfur
NRLM credits. First, we propose that these credits could be used during
the period from June 1, 2007--May 31, 2010, to continue to produce high
sulfur NRLM diesel fuel. Any high sulfur NRLM fuel produced, however,
would have to be dyed red at the refinery gate, kept segregated from
other fuels in the distribution system, and tracked through the use of
unique codes on product transfer documents.
Only at the point in the distribution system where NRLM fuel has
been dyed to IRS specifications for excise tax purposes (e.g., after a
terminal or bulk plant) do we propose that high sulfur and 500 ppm
sulfur NRLM fuels could be commingled. Such commingling will not
diminish the PM and SO3 emission reductions or other
benefits associated with the 500 ppm sulfur standard. However, in order
to ensure that owners of nonroad equipment can be confident in knowing
whether the fuel being purchased meets the 500 ppm cap, the PTD and
labels for any commingled fuel will have to indicate that the sulfur
level exceeds 500 ppm. This is particularly a concern for some 2008 and
later model year equipment that may need to run on 500 ppm or lower
sulfur fuel in order to achieve the emission benefits in-use of the
standards proposed today, as discussed in section III.
In most cases we anticipate that the distribution costs associated
with segregating such a small volume product will prevent high-sulfur
NRLM from being carried in the fungible distribution system. As a
result, we anticipate that only those refineries that have their own
segregated distribution system could continue to produce solely high
sulfur NRLM fuel after June 1, 2007. Since there are few refineries set
up to accomplish this, our expectation is that the most likely manner
in which refiners will be able to use high-sulfur NRLM credits will be
through sales made directly from their on-site fuel rack or co-located
terminal. Nevertheless, in order to have confidence that refiners are
making the transition to 500 ppm for NRLM uses, we seek comment on
whether caps on the use of credits would be necessary. In particular,
we seek comment on placing a cap on the use of credits at 25 percent of
its non-highway baseline, less marked heating oil, beginning June 1,
2008.
The second way in which refiners and importer could use high-sulfur
NRLM credits is by banking them for use during the June 1, 2010--May
31, 2012, period. During this period they could continue producing 500
ppm fuel subject to the usage restrictions that apply during that
period, as discussed in subsection B.2.b.ii below. This use of high-
sulfur credits would provide a cost-effective environmental benefit,
since credits generated from the reduction of sulfur levels from high
sulfur to 500 ppm would be used to
[[Page 28409]]
offset the much smaller increment of sulfur control from 500 ppm down
to 15 ppm.
b. 2010
After June 1, 2010, the fuel standards situation is simplified
considerably and the fuel program structure can therefore also be
simplified. The need for the non-highway baseline percentage
disappears, since all highway and nonroad diesel fuel must meet the
same 15 ppm cap. Furthermore, the only high sulfur distillate remaining
in the market should be heating oil, since we are proposing that high
sulfur diesel fuel no longer be permitted to be used in any NRLM
equipment. Heating oil would have to be kept segregated. Preventing its
use in NRLM equipment could be enforced on the basis of sulfur level,
avoiding the need for a unique marker to be added to heating oil.
After June 1, 2010, under this proposal locomotive and marine
diesel fuel would be allowed to remain at the 500 ppm level. In
addition, assuming we allowed the continued production and use of 500
ppm nonroad diesel fuel through the small refiner hardship provisions
discussed in subsection C and fuel credit provisions, 500 ppm nonoad
fuel would continue to exist in the distribution system as late as May
31, 2014. A refiner could produce 500 ppm diesel fuel without the use
of credits for the intended use in locomotive and marine applications,
but if this 500 ppm fuel later made its way into nonroad equipment,
less 15 ppm nonroad fuel would be produced and the full benefits of the
15 ppm nonroad standard would not be achieved. If this happened to a
large enough extent it could call into question the adequate supply of
15 ppm for nonroad purposes beginning in 2010. Thus, some method is
needed to differentiate locomotive and marine 500 ppm diesel fuel from
nonroad 500 ppm diesel fuel after June 1, 2010. EPA is proposing to use
a marker for this purpose.
i. A Marker To Differentiate Locomotive and Marine Diesel From Nonroad
Diesel
This proposal would allow the limited production of 500 ppm nonroad
diesel fuel by small refiners and by other refiners through the use of
credits between 2010 and 2014 (see section IV.B.3.b). This 500 ppm fuel
could only be used in pre-2011 model year nonroad diesel engines, and
would have to be segregated from 15 ppm nonroad diesel fuel and 500 ppm
locomotive and marine diesel fuel. To ensure compliance with the
proposed segregation requirements for such fuel, it would be necessary
for parties in the distribution system, and for EPA, to be able to
distinguish such 500 ppm nonroad diesel fuel from 500 ppm locomotive
and marine diesel fuel. Differentiating locomotive and marine diesel
fuel from nonroad diesel fuel presents a very analogous situation,
though perhaps on a smaller scale, to that described above for heating
oil prior to June 1, 2010.\246\ As a result, we propose to use a marker
to segregate locomotive and marine diesel fuel from 500 ppm nonroad
diesel fuel beginning June 1, 2010. Since both fuels need to be dyed
red for tax purposes prior to sale, for the reasons discussed above
with respect to heating oil, we propose that solvent yellow 124 be used
as the marker for locomotive and marine diesel fuel beginning June 1,
2010. We propose that the marker would be required to be added at the
refinery gate just as visible evidence of the red dye is required
today, and fuel containing more than the trace concentration of 0.1 mg/
l of the marker would be prohibited from use in any nonroad
application.
---------------------------------------------------------------------------
\246\ Without the proposed marker requirement for locomotive and
marine diesel fuel discussed in this section, we expect that there
would be no physical difference between 500 ppm nonroad diesel fuel
and 500 ppm locomotive and marine diesel fuel.
---------------------------------------------------------------------------
Since marked locomotive and marine diesel fuel would be a
relatively small volume product, we anticipate that in most parts of
the distribution system it would not be carried as a separate product
in the fungible distribution system. Therefore we anticipate that most
shipments of marked locomotive and marine fuel would be from refinery
racks or other segregated shipments directly into end-user tankage. Any
diesel fuel supplied off the fungible supply system for locomotive and
marine uses would therefore likely be spillover from 15 ppm nonroad or
highway diesel supply.
Since we anticipate that 500 ppm locomotive and marine diesel fuel
will be a small volume product, not carried in the fungible
distribution system, and only available in limited locations, we also
seek comment on whether the approach of using a marker for locomotive
and marine diesel fuel could be replaced with an alternative approach.
Specifically, we seek comment on whether to just limit supply of 500
ppm locomotive and marine diesel fuel to segregated shipments, with
refineries being liable to ensure and keep records demonstrating that
500 ppm fuel produced for locomotive and marine purposes was
distributed solely for these purposes.
ii. Diesel Sulfur Credit Banking and Trading Provisions for 2010
For the reasons described above for 2007, we are proposing a
similar diesel sulfur credit banking and trading program for 2010. We
propose that refiners and importers could generate early credit for
production of 15 ppm nonroad diesel fuel prior to June 1, 2010. These
credits could be used to delay compliance with the 15 ppm nonroad
diesel standard in 2010. As in 2007, while it is possible that a
refinery could entirely delay compliance with the 15 ppm standard in
2010 through the use of credits, the most advantageous use of these
credit provisions is likely to be the continued sale by individual
refineries of otherwise off-spec product during the startup of the 2010
program, when they are still adjusting their operations for consistent
production to the 15 ppm sulfur standard.
Credit Generation
Under this proposal, highway and NRLM fuels of like sulfur level
would be allowed to be distributed fungibly, and as such would be
indistinguishable. For example, prior to June 1, 2010, undyed 15 ppm
diesel fuel would be distributed together whether or not it was later
dyed for nonroad purposes. Consequently, we are proposing that credits
for production of early 15 ppm nonroad diesel fuel prior to June 1,
2010, be determined using the non-highway baseline. Any volume up to a
refinery's total highway requirement (100 percent minus the non-highway
baseline) would continue to be counted under the provisions of 2007
highway diesel fuel program.\247\ Any production of 15 ppm fuel greater
than this amount (100% minus the non-highway baseline) beginning June
1, 2009 could be used to generate early nonroad credits.
---------------------------------------------------------------------------
\247\ Under the highway program four gallons of excess 15 ppm
diesel fuel produced or imported would generate one 500 ppm diesel
fuel credit. This credit grants the refiner or importer the right to
produce one additional gallon of undyed 500 ppm diesel fuel between
June 1, 2006 and May 31, 2010. These credits can be used (or traded
within the PADD in which they were generated) to produce or import
less than 80% of its highway volume as 15 ppm fuel. This would
continue under this proposal for any production up to (100% minus
the non-highway baseline). For any volume of 15 ppm fuel greater
than 100% minus the non-highway baseline a refiner could either
receive gallon-for-gallon nonroad credit under this proposal, or
treat it as highway fuel and receive 1:4 credit under the provisions
of the highway rule.
---------------------------------------------------------------------------
An example will help to explain the use of these credits. Assume
the baseline non-highway percentage has been established at 40% and the
refinery produces a total of 100,000,000 gallons of diesel fuel from
June 1,
[[Page 28410]]
2009--December 31, 2009. Its applicable non-highway baseline would be
40,000,000 gallons. If it then produced and marked 10,000,000 gallons
of heating oil, 30,000,000 gallons of the remaining diesel fuel (dyed
or undyed) would be subject to the NRLM standard of 500 ppm, and the
remaining 60,000,000 gallons of diesel fuel would be considered highway
diesel fuel and would have to meet the applicable 80/20 requirements
(48,000,000 at 15 ppm and 12,000,000 at 500 ppm). If the refiner
instead produced only 20,000,000 gallons of fuel to the 500 ppm NRLM
standard and produced 70,000,000 gallons to the 15 ppm standard, then
it would receive credit for the 10,000,000 gallons excess 15 ppm NRLM
fuel that it produced. In this example the refiner could also earn
3,000,000 highway credits for the excess production of 15 ppm highway
fuel (1:4 ratio).
In addition to this source of credits, we propose two other sources
of credits to allow production of 500 ppm nonroad diesel fuel after
June 1, 2010. First, as discussed in subsection B.3.a.iv above, high-
sulfur NRLM credits generated prior to June 1, 2010, could be converted
into 500 ppm nonroad credits and carried over for use beginning June 1,
2010. Second, under the small refiner hardship provisions described
below in subsection C, small refiners could generate credits for any
production of NRLM fuel to the 15 ppm standard from June 1, 2010,
through May 31, 2012. These credits could be traded to any other
refinery or importer nationwide.
We seek comment on whether credits should be permitted to be
generated prior to June 1, 2009. Our proposal would restrict the early
credit period to just one year for two main reasons. First, any 15 ppm
fuel produced prior to June 1, 2009, can be treated as highway diesel
fuel and any credits generated on the fuel under the highway program
can be traded under the highway credit program. We do not want the
early nonroad credit provisions to detract from the smooth functioning
of the highway diesel credit program. Second, we do not want the early
credit provisions to undermine the availability of 15 ppm diesel fuel
for nonroad applications in 2010. Allowing more than a years worth of
credits to be generated, plus up to a years worth of high sulfur
credits to be generated and carried over for use in 2010 would raise
concerns that insufficient 15 ppm nonroad diesel fuel might be produced
in 2010 to ensure availability everywhere nationwide. Nevertheless, we
seek comment on extending the period for early credit generation and on
this assessment.
Credit Use
We propose that 500 ppm nonroad credits could be used on a gallon
for gallon basis during the period from June 1, 2010-May 31, 2012,
allowing continued production of 500 ppm nonroad diesel fuel. Small
refiners could continue to produce 500 ppm nonroad diesel until June 1,
2014, without credits. Any 500 ppm nonroad fuel produced would have to
be dyed red at the refinery gate, kept segregated from other fuels in
the distribution system, and tracked through the use of unique codes on
product transfer documents all the way through to the end-user.
Refiners wishing to produce 500 ppm fuel and sell it as nonroad would
have to get EPA approval in advance demonstrating how they will ensure
such segregation.
Given the cost and burden associated with segregating 500 ppm
nonroad diesel fuel as a separate product in the distribution system,
we anticipate that the most likely manner in which refiners will be
able to use 500 ppm nonroad credits will be through sales made directly
from their on-site fuel rack.
We request comment on all aspects of the proposed credit trading
system.
c. 2014
Beginning June 1, 2014, after all small refiner and credit
provisions have ended, both the 15 ppm nonroad diesel fuel standard and
the 500 ppm locomotive and marine diesel fuel standard could be
enforced based on sulfur level throughout the distribution system and
at the end-user. There would no longer be a need for a baseline, a
marker, or a dye. Consequently, we are proposing that after May 31,
2014, the different grades of diesel fuel, 15 ppm, 500 ppm, and high-
sulfur would merely have to be kept segregated in the distribution
system.
3. Other Options Considered
In developing the proposed program structure described above, we
also evaluated a number of other possible approaches. Some of the
alternatives discussed below would allow for even greater fuel
fungibility, for example, extending to smaller volume products such as
those produced through the use of credits. However, these alternative
approaches would either place more restrictions on refinery operations,
or raise significant enforcement and program integrity concerns. As a
result, we are not proposing the following alternatives but seek
comment on them, including ways to minimize or alleviate the concerns
associated with them.
a. Highway Baseline and a NRLM Baseline for 2007
The proposed program described above relies on a non-highway
baseline percentage to distinguish highway fuel from NRLM fuel, and a
marker to distinguish heating oil from NRLM fuel. In lieu of using a
marker for heating oil, another approach would be to use a second
baseline aimed at identifying the NRLM portion of non-highway diesel
fuel. In this case a highway baseline would be established consistent
with the non-highway baseline proposed above (100 percent minus the
proposed non-highway baseline). The highway 80/20 standards would apply
to this baseline. A second NRLM baseline would be established to which
the 500 ppm NRLM standard would apply. The remaining diesel fuel
percentage would be uncontrolled (i.e., it could be high sulfur). This
approach would allow for greater fungibility of fuels with the same
sulfur level. Not only could 500 ppm highway and 500 ppm NRLM fuel be
distributed together, but high sulfur NRLM fuel produced through the
credit and hardship provisions could be fungibly distributed with
heating oil. Heating oil would not need to contain a marker. As a
result, this approach would allow for greater flexibility in using the
fuel credit and hardship provisions. The disadvantage, however, is that
refiners would face additional burden when shifting into the heating
oil market. An explanation of this approach follows.
i. Highway Baseline
The highway baseline would be very analogous to the non-highway
baseline proposed above. It would be calculated in the same way, except
that it would be 100 percent minus the proposed non-highway baseline.
The requirement that NRLM fuel be dyed at the refinery gate would
become voluntary. From June 1, 2007, through May 31, 2010, any volume
of 500 ppm fuel not dyed at the refinery gate would have to meet the
80/20 highway provisions up to the refinery specific highway baseline
percentage. The highway baseline percentage would be determined for
each refinery and importer in the same manner as described above for
the non-highway baseline.
ii. Nonroad, Locomotive, and Marine Baseline
Under this approach, a refiner or importer would be assigned a NRLM
baseline percentage. This baseline
[[Page 28411]]
percentage of a refinery's or importer's current high-sulfur diesel
fuel and heating oil (number 1 and number 2) production would be deemed
to be NRLM diesel fuel and thus, subject to the proposed 500 ppm cap
beginning June 1, 2007. The remaining percentage would remain
uncontrolled and would not need to contain a marker. A refiner's NRLM
baseline percentage would be applied to the percentage of distillate
not included in the highway baseline (i.e., the proposed non-highway
baseline). For example, if a refiner's highway baseline was 50% and its
NRLM baseline was also 50%, then 25% of its production would have to
meet the 500 ppm NRLM standard.
If a refiner chose not to use the NRLM baseline percentage, a
refinery or importer would have to add the proposed marker and
segregate their heating oil from any NRLM diesel fuel throughout the
distribution system, including high sulfur NRLM diesel fuel (produced
through the use of credits or by small refiners or refiners utilizing
hardship provisions). The refinery would have to demonstrate that the
fuel was segregated all the way through to the end-user and that the
end-user used the fuel for legitimate heating oil purposes only. NRLM
end-users would be prohibited from using any fuel with a marker.
There are, however, certain difficulties in establishing an NRLM
baseline percentage. Unlike the situation today where highway diesel
fuel and non-highway distillates are accounted for based upon their
different sulfur levels and the presence of red dye, there is no easy
way to measure a given refinery's current production of NRLM diesel
fuel as compared to their production of heating oil, in order to
accurately establish an individual refinery baseline percentage.
Generally the two fuels are produced and shipped as a single fuel. We
considered whether refiners and importers could reliably track their
high sulfur fuel through the distribution system and estimate the
volumes used as diesel fuel and heating oil to establish individual
refinery baselines. However, most high sulfur diesel fuel and heating
oil is shipped by fungible carriers and we do not believe that
sufficient data exist to accurately determine which refiner's fuel was
actually consumed in either end-use. Discussion with several refiners
have supported this belief. Therefore, we developed an approach that
would assign each refinery a percentage of their current high-sulfur
distillate production, based on the PADD they reside in, as their NRLM
baseline. PADDs 1 and 3 would be combined due to the large amount of
high sulfur non-highway diesel fuel shipped from PADD 3 to PADD 1
today.
Under this approach we would project consumption of NRLM diesel
fuel and heating oil to determine the relative consumption of these two
fuels by PADD. This would be the NRLM baseline assigned to refiners and
importers in that PADD. This volume percentage of non-highway diesel
fuel would then be considered NRLM and have to meet the proposed 500
ppm cap beginning June 1, 2007. The remainder of the non-highway diesel
fuel would remain uncontrolled by EPA and would only have to meet any
applicable state sulfur standards for heating oil. If a refinery
desired to only produce heating oil, then they could either purchase
credits from other refineries or segregate and mark their heating oil.
Using EIA estimated fuel consumption data for the year 2000, grown
to 2008 using EPA NONROAD emission model growth rates for nonroad and
EIA growth rates for other fuels, produces the NRLM baseline
percentages shown in Table IV-2.
Table IV-2--NRLM Diesel Fuel Baseline Percentages
----------------------------------------------------------------------------------------------------------------
Breakdown of High Sulfur Distillate Fuel
Production (In percent)
PADD -----------------------------------------------
Loco and
Nonroad marine Combined
----------------------------------------------------------------------------------------------------------------
1 and 3......................................................... 26 16 42
2............................................................... 57 27 84
4............................................................... 67 29 96
5 (excluding Alaska)............................................ 59 18 77
Alaska.......................................................... 22 28 50
----------------------------------------------------------------------------------------------------------------
One particular concern with this NRLM baseline approach is whether
refiners can easily respond to above average demand for heating oil
(e.g., in unusually cold winter). As today, any short-term, unexpected
increases in demand will be made up from existing inventories of fuel.
Today, if there are insufficient inventories of high sulfur fuel, 500
ppm inventories are tapped as well. The same situation will continue to
occur in the future. As a result, the issue is not one of being able to
supply the market with sufficient fuel to meet demand, but rather what
quality of fuel must be produced to build inventories back up after
high demand has brought them down. This could be addressed in a number
of ways. First, in setting the NRLM baseline itself we could make sure
it is not too high and allows for sufficient volumes of high sulfur
heating oil to be produced even in the event of an unusually cold
winter. Second, we could allow credits to flow across the country
through a nationwide credit trading program. This would allow the
production of high sulfur fuel to likewise flow across the country to
the places experiencing higher than normal demand. Third, provisions
could be made for deficit carry over of credits. If demand for high
sulfur fuel is unusually high in one year, a refiner could increase
production to respond to that demand as long as it is made up the
following year.
Another concern raised by this baseline approach is the inability
to accurately tailor it to each refinery's actual historical production
of NRLM. This NRLM baseline approach does reflect the historical
practice for the industry as a whole--refineries produced fungible high
sulfur fuel for distribution as a common pool of fuel that was later
sold as either NRLM or heating oil. However, it does not allow for
refinery specific customization. The proposed non-highway baseline
approach determines the specific non-highway percentage for each
refinery, and the actual volume of marked and dyed heating oil is
allowed to vary. The lack of individual specificity for the NRLM
baseline approach, however, avoids the need to add a marker to heating
oil.
[[Page 28412]]
iii. Combined Impact of Highway and NRLM Baselines
These baselines, as with the proposed non-highway baseline, are set
on the basis of a percentage of production. Therefore, as a refinery's
overall production of diesel fuel rises and falls, the required volume
of each grade of fuel will also rise and fall. Thus, the baselines are
flexible enough to respond to changes in a refinery's market or
situation. Furthermore, a nationwide credit trading program for 500 ppm
NRLM fuel could be put in place, allowing refineries further
flexibility to change production in response to consumer demand. To add
additional flexibility we could allow for some deficit carry-over of
NRLM credits. Finally, a refinery could always avoid use of the
baselines entirely by dyeing or marking their fuel and ensuring that it
is only used in appropriate end-uses.
The combined effect of the highway baseline and NRLM baseline is
shown in Table IV-3.
Table IV-3--Combined Impact of the Highway and NRLM Baselines for June 1, 2007--May 31, 2010
----------------------------------------------------------------------------------------------------------------
Sulfur level Percentage requirement
----------------------------------------------------------------------------------------------------------------
15 ppm.............................. or = 80% x (highway baseline) or;
or = 80% x All undyed diesel fuel (whichever is less)
15+500 ppm.......................... or = (highway baseline) + (NRLM baseline)(100% highway
baseline) or;
= All fuel without a marker and segregated through to the end-user
----------------------------------------------------------------------------------------------------------------
An example will help to explain the use of these baselines. Assume
a refinery in PADD 3 produces 100,000,000 gallons of diesel fuel and
heating oil per year from 2003-5, 60 percent of which is undyed. Its
highway baseline would thus be 60 percent of its total diesel fuel and
heating oil production. Its NRLM baseline, assigned by EPA from Table
IV-2, would be 42 percent applied to the remaining 40 percent of total
distillate, or 16.8 percent of total distillate. If the refinery then
continues to produce a total of 100,000,000 gallons of diesel fuel in
2008, 60,000,000 gallons would be required to meet the highway 80/20
standards, i.e., 48,000,000 at 15 ppm and 12,000,000 at 500 ppm. An
additional 16.8 percent, or 16,800,000 gallons would be required to
meet the 500 ppm NRLM standard, for a total required 500 ppm production
of 28,800,000 gallons. Its remaining 23,200,000 gallons of production
could remain uncontrolled and could be sold as heating oil or high
sulfur NRLM. If the refiner reduced this 23,200,000 gallons to 500 ppm
it would then earn credits that could be sold to another refiner.
b. Locomotive and Marine Baseline for 2010
The proposed non-highway baseline percentage approach described
above relies on a marker to distinguish locomotive and marine diesel
fuel from nonroad diesel fuel after June 1, 2010. Just as in the
alternative above, a baseline for locomotive and marine fuel could be
used in lieu of a marker. The 2010 locomotive and marine baseline would
be established by EPA and used in the same manner as described above
for the NRLM baseline in 2007. Possible locomotive and marine baselines
are shown in Table IV-2. The advantage of this baseline approach over
the proposed approach is that it allows for the fungible distribution
of 500 ppm locomotive and marine fuel with 500 ppm nonroad fuel
produced through the credit and hardship provisions. As a result, this
approach would allow for greater flexibility in using the diesel fuel
credit and hardship provisions. The disadvantage, however, is that
refiners wishing to produce locomotive and marine fuel in quantities
larger than their baseline would have to purchase credits from other
refiners.
It may be possible for each refiner and importer to track the use
of its diesel fuel to determine what percentage was used by railroads
and marine vessels. This information could then be used in lieu of the
PADD average values shown in Table IV-2. However, this approach would
have to be taken by every refinery and importer to avoid double
counting. Any new refineries or importers would still be assigned a
locomotive and marine baseline from Table IV-2. Tracking diesel fuel
use in this instance could be feasible, since the number of railroads
and marine terminals is relatively small. We request comment on this
alternative approach and details of how such an approach could be
implemented.
c. Designate and Track Volumes in 2007
One main benefit of the proposed non-highway baseline approach is
to allow 500 ppm highway and 500 ppm NRLM diesel fuel to be fungibly
distributed while still ensuring achievement of the benefits of the
highway program. In developing the proposal, several refiners
recommended another possible approach, referred to here as the
``designate and track'' approach. It was suggested as a replacement for
the proposed non-highway baseline approach. After further discussion, a
modified designate and track approach was also described as an
alternative for refiners to choose from, in addition to the baseline
and dye alternatives. We discuss both of these designate and track
approaches below.
We invite comment on these designate and track approaches. However,
we are not proposing them for a number of reasons as discussed in more
detail below. We are concerned that such an approach could reduce the
volume of 15 ppm fuel required to be produced under the highway
program, eroding environmental benefits and calling into question
availability of 15 ppm highway fuel. This concern is compounded by
serious concerns with respect to the workability and enforceability of
such a program, particularly if it is a replacement for the baseline
approach. We are also concerned that such an approach would place too
much burden on the many entities, including many small entities, in the
distribution system. Unlike the situation with the existing highway
diesel program, the downstream parties, not the refiners, would be
liable if insufficient 15 ppm highway diesel fuel was produced and
distributed. Finally, these concerns would appear to be reduced if the
designate and track approach were to be allowed as a choice for
refiners. However, it may then be of such limited usefulness that it is
of little value and only adds program complexity. We are interested in
comments describing how these concerns could be addressed in order to
implement such an approach.
[[Page 28413]]
i. Designate and Track as a Replacement for the Non-Highway Baseline
Approach
Under the designate and track approach, a refiner or importer would
designate its 500 ppm diesel fuel as highway diesel fuel or NRLM diesel
fuel and this refiner designation would be used to differentiate
highway fuel and NRLM fuel instead of the non-highway baseline. For
example, the highway 80/20 requirement would only apply to the amount
of diesel fuel designated by the refinery or importer as highway diesel
fuel. A marker would still be used to segregate heating oil, but the
dye requirement for NRLM at the refinery gate would be removed. As with
the baseline approach, undyed 500 ppm highway and 500 ppm NRLM could be
fungibly distributed up until the point the NRLM diesel fuel is dyed.
These refiner designations would have to follow the fuels through the
distribution system. Under this designate and track approach, fuel
distributors would be required to ensure that they did not sell more
diesel fuel to the highway market than they took in as highway fuel.
For example, if 60% of the fuel they took in was originally designated
by the refineries as NRLM, they could not sell more than 40% to the
highway market. The refiner or importer would have no obligation to
ensure this occurred and no liability if it did not occur.
This approach shifts the focus from monitoring and enforcement of
production at the refinery gate to monitoring and enforcement of the
volumes of fuel handled by each party in the distribution system. Under
the designation and track approach, refiners and importers would have
complete flexibility to designate individual batches of diesel fuel or
even portions of batches as either highway fuel or NRLM fuel. A
pipeline could mix undyed highway 500 ppm and NRLM diesel fuels and
ship them fungibly as a single physical batch as in the non-highway
baseline approach. However, two sets of records would be kept, one
applicable to the highway fuel portion and one applicable to the NRLM
fuel portion. Whenever all or a portion of the fungible batch was split
off or sold, that portion would have to carry one of the two
designations, highway or NRLM. The sum of the volumes designated as
either fuel would always be required to add up to the volumes
designated in the original batch. A combination of fungibly mixed
batches would be handled similarly, with the total volumes of each
designation of volume split off or sold equaling the sum of the volumes
of each designation of the original batches, respectively.
Each party in the distribution system beyond the refinery gate
would be required to reconcile the volumes taken in and the volumes
discharged, based on the designations of the diesel fuel, annually. For
example, assume that over a year a pipeline received a total of
100,000,000 gallons of undyed 500 ppm diesel fuel from various
refineries, with 70% of what it received being designated by the
refiners as highway and 30% designated as NRLM. Over the year the
pipeline would also designate what it discharged at various terminals
or other points as either highway or NRLM. The pipeline would have to
ensure that over a year's time it did not discharge more than 70% of
the volume of this entire pool of 500 ppm diesel fuel as highway diesel
fuel, to ensure that fuel designated as NRLM was not inappropriately
converted to highway use. It could not discharge more 500 ppm fuel as
highway than it took in as highway, and it would have to discharge at
least as much 500 ppm diesel fuel designated as NRLM as it took in.
This same reconciliation process would apply to every party in the
distribution system.
A primary advantage of this designate and track approach for
refiners is that it would allow them complete flexibility in deciding
how much 15 ppm highway diesel fuel to produce, allowing them to react
to changing market conditions. As long as 80 percent of whatever volume
they designated as highway was 15 ppm, they would be in compliance.
However, in order to maintain the integrity of the highway program, EPA
would have to ensure that all diesel fuel designated as NRLM eventually
was dyed and sold to the NRLM market. Otherwise, for example, refiners
and importers could simply designate diesel fuel under the more lenient
NRLM diesel fuel program while downstream in the distribution system
the fuel was shifted to the highway diesel fuel market. Such shifting
would compromise the required 80/20 split between 15 ppm and 500 ppm
highway diesel fuel and undermine the benefits and integrity of the
highway program. Various refiners proposed that EPA compare the volume
of all diesel fuel designated as NRLM by the refineries and importers
nationwide and compare that with the volume dyed nationwide to
determine whether the approach was working. Unfortunately, this
approach is not feasible, since EPA could not determine and take
corrective action against refiners, importers, or distributors if the
designated and dyed volumes did not reconcile. To locate the cause of a
discrepancy between the designated and dyed volumes, EPA would have to
audit the records of every party in the distribution system nationwide.
The refiners and importers would not face any liability under this
approach for any downstream discrepancy unless there was evidence of
collusion with downstream entities.
Thus, under this designate and track approach, EPA would need to
require that all parties handling undyed diesel fuel designated as NRLM
maintain records for each batch of fuel shipped and received and submit
reports periodically demonstrating that the volume of undyed NRLM
designated fuel that they dyed plus that transferred undyed to another
fuel distributor equaled or exceeded the volume of undyed NRLM
designated fuel that they received.\248\ We would also need to require
that all parties handling dyed or undyed NRLM diesel fuel maintain
records and submit reports demonstrating that the volume of NRLM
designated fuel that they received was sold for use in nonroad,
locomotive or marine diesel engines or transferred with the same
designation to another fuel distributor. These requirements would be
applied on an annual basis, providing fuel distributors with
flexibility to shift fuel designated for one use to the other market
and vice versa to address short term supply fluctuations of each fuel
but still maintain overall program integrity.
---------------------------------------------------------------------------
\248\ If the volume of dyed NRLM fuel exceeded the designated
volume, this would imply that some highway 500 ppm fuel was dyed.
This would not compromise the required 80/20 split between 15 ppm
and 500 ppm fuel under the highway program, although the total
social cost of producing the fuel would be higher.
---------------------------------------------------------------------------
Given the large number of entities involved in distributing diesel
fuel and the number of transactions, there are a number of serious
practical concerns regarding the enforceability of such an approach.
Under the baseline approach described above, enforcement is focused on
the roughly 128 refineries producing either highway or NRLM diesel
fuel. This designation and track approach would add the various
entities in the distribution system. In order to improve the chances of
effectively enforcing the program, we would at a minimum have to limit
the scope of the entities involved to bulk terminals and entities
upstream. Thus, all NRLM diesel fuel would have to exhibit visible
evidence of dye after leaving a large bulk terminal. Even with this
limitation, there would be as many as 100 pipelines and 1000 terminals
reporting. Enforcement of such an approach would be difficult because
to determine whether inappropriate changes in
[[Page 28414]]
designation occurred by a given entity, the records of each entity from
which it received fuel and to which it sent fuel over the course of an
entire year would also have to be compared. An electronic reporting
mechanism would likely have to be set up to facilitate reporting and to
track the volumes of fuel received and shipped out by each entity in
the distribution system down to the terminal. If any entity in the
distribution system were unable to verify through their records that
they distributed the same amount or more of NRLM fuel as they took in
with this designation, then they, not the refiners, would be presumed
liable for violating the provisions of the highway rule. Therefore, in
addition to our concerns of ensuring compliance, we invite comment on
the appropriateness of shifting the compliance burden for tracking fuel
volumes, maintaining records, reporting to the Agency, and responding
to enforcement audits from the refiners to the downstream parties,
particularly since many of these entities are small businesses.
In addition to the number of entities involved and transactions
needing to be tracked, there are a number of complications which would
make such an approach difficult to implement. First, due to
contamination in the distribution system that results in some product
being downgraded from one grade to another in the distribution system,
in actuality the volumes of fuel designated at the refinery and those
downstream will likely never match. Some means of addressing this
situation would have to be developed which did not allow fuel produced
as NRLM fuel to be subsequently sold as highway fuel. Second, kerosene
will be blended into NRLM diesel fuel in northern areas during the
winter months. It is difficult to understand how refiners would be able
to designate portions of this fuel as NRLM fuel or highway fuel at the
refinery gate given its many other uses. Therefore, this would further
disrupt the volume reconciliation. Third, it would not always be
entirely clear who should be the entity responsible for compliance,
recordkeeping, and reporting. In many cases in the distribution system
there are entities who have custody of the fuel while a variety of
other entities maintain ownership. A means of sorting out who the
responsible party was under such circumstances would have to be
determined.
One of the advantages of the proposed baseline approach is that
once 500 ppm fuel leaves the refinery gate, the distribution system has
complete flexibility to shift it to either the highway or the NRLM
markets to respond to changing market conditions. Conversely, as
discussed above, one of the main advantages of the designate and track
approach is that it allows refiners complete flexibility to modify
their relative production of 15 ppm and 500 ppm fuel by their choice of
designations (highway or NRLM). However, the market will demand a
certain volume of highway fuel and NRLM fuel, and these decisions will
be made downstream. If the market demands more highway diesel fuel than
what the refiners designated as highway on an annual basis, then under
the designate and track approach the terminals will be restricted from
responding to this market change. They could shift NRLM fuel into the
highway market on a temporary basis, but by the end of the year, they
would have to be able to reconcile their highway and NRLM volumes.
Given the refiner's inability to predict future demand precisely, and
their economic incentive to produce as little 15 ppm diesel fuel as
possible, there is a real possibility that some terminals could find
themselves in a noncomplying situation. Were this to occur, a terminal
would be faced with two difficult choices. They could stop shipping
highway diesel fuel, in which case they would not only fail to deliver
on their contracts to their customers, but would also constrain highway
diesel fuel supply, raising market prices. Or, they could continue to
respond to market pressure and sell additional volumes of fuel
designated as NRLM into the highway market. In this case, they would
risk significant non-compliance penalties from EPA, were we able to
detect the violation. Thus, we are concerned that the designate and
track approach could result in either widespread noncompliance or
disruption of the fuel distribution system.
We are also concerned that the designate and track approach would
not maintain the benefits and integrity of the highway program. Nearly
a third of all non-highway distillate today is produced to the highway
specifications due primarily to limitations in the distribution system.
The sulfate PM and SO2 emission benefits predicted from the
highway rule, and the assumptions with respect to program cost and fuel
availability, were all based on the assumption that 80% of this
spillover volume would comply with the 15 ppm highway standard and
would be available for highway use if needed. Under the proposed dye
approach, in the future this ``spillover'' from the highway market
could technically be dyed at the refinery gate to avoid compliance with
the 2006 highway standards. However, our expectation is that the
majority of the spillover today would continue into the future as it
would be costly to significantly change the current distribution
practices. While the dye approach would not ensure this and spillover
could decline, it would be unlikely to drop significantly. Similarly,
the proposed baseline approach would maintain spillover at historical
rates (either 2003-5 the average level or June 1, 2006--May 31, 2007,
level). However, under the designate and track approach, wherever
undyed 500 ppm was distributed as a grade of fuel, the prior spillover
volume could instead be designated as NRLM fuel, and would no longer be
subject to the highway program standards (i.e., 80 percent of it would
no longer have to meet the 15 ppm sulfur standard.). The segregation
and associated cost that previously led to spillover would be gone. As
a result, the benefits projected from this fuel volume under the
highway rule would be reduced. Furthermore, with the reduced volume of
15 ppm fuel produced, we would need to reevaluate whether sufficient 15
ppm fuel would still be available in all parts of the country for the
vehicles that would need it. The areas where availability of 15 ppm
fuel would be of greatest concern would be those areas where 500 ppm
fuel would be distributed and spillover would decline under the
designate and track approach. The enforcement concerns cited in the
paragraphs above only serve to heighten this concern.
EPA requests comments on the practical viability of this approach.
In addition to the issues noted above, we specifically request comments
on the following:
(1) What would be the impacts of this approach on fuel
distributors?
(2) What information would need to be kept and/or reported?
(3) How might the required reports be automated in a common,
electronic format?
(4) How often should reports be required (e.g., annually,
quarterly, each batch if electronically)?
(5) How might`the record keeping requirements be combined with
those already required by the U.S. Internal Revenue Service?
(6) How would the record keeping requirements work for pipelines
and certain terminals that handle fuel without taking ownership and
that do not control the decision to dye certain diesel fuel prior to
sale?
(7) How might the IRS records for refiners, importers and
distributors be used as an independent check on the
[[Page 28415]]
volumes of undyed diesel fuel handled which are eventually dyed and
which are sold undyed?
(8) What would be the cost associated with the tracking, record
keeping and reporting?
(9) Could the industry utilize independent auditors to simplify
EPA's enforcement oversight?
(10) Could refiners feasibly be responsible to ensure the necessary
volumes are dyed downstream at the terminal rather than placing the
responsibility and liability with the fuel distributors?
(11) What changes could be made to the program to avoid losing the
benefits of the highway program (e.g., avoid loss in production of 15
ppm attributable to the spillover volume)?
ii. Designate and Track as a Refiner's Option in Addition to the
Baseline Approach
Several refiners indicated that the designate and track approach
should be considered as an option in addition to the baseline approach.
Including the designate and track approach as a refiner's option,
however, would significantly alter the design and implications of the
approach.
With such an approach, no longer could compliance be determined
simply on the basis of whether a terminal dyed at least as much volume
of diesel fuel as the volume received designated as NRLM 500 ppm fuel,
since the dyed diesel fuel could have been produced under either the
non-highway baseline approach or the designate and track approach. In a
situation where volumes produced under the designate and track approach
are fungibly distributed with volumes produced under the baseline
approach, there is no clear way to identify whether dyed volumes have
been accurately reconciled under the designate and track approach,
risking significant loss in the benefits expected from the highway
program.
For example, assume a terminal receives a certain volume of undyed
diesel fuel and 30% of it was originally designated by the refinery as
NRLM under the designate and track approach. The remaining 70% would
have been produced by refineries using the non-highway baseline
approach. Some significant portion of the 70% produced by refineries
under the baseline approach would have been produced subject to the 500
ppm standard for the NRLM market, not the standards for highway market,
and produced with the expectation that it could later be dyed at the
terminal. If the terminal dyes only 30% of the entire volume it
receives, there is every expectation that some or even all of that 30%
could have been produced by refineries using the baseline approach, and
should not be counted towards the volume reconciliation under the
designate and track approach. If all of the 30% of dyed diesel fuel was
produced by refineries using the baseline approach, then the terminal
would have effectively sold into the highway market all of the fuel
received as NRLM under the designate and track approach.
Thus, in order to allow for volumes to be reconciled using such an
approach, we concluded that fuel distributors would have to track which
refinery or importer the fuel came from and how they disposed of the
fuel for that refinery or importer, in addition to whether it was NRLM
or highway. Thus, allowing the designate and track approach as a
refiner's option would add one more layer of complexity to the
tracking, recordkeeping, and reporting.
The following example explains how the approach could work in
theory. Over the course of a year, a terminal receives 6 million
gallons of 500 ppm diesel fuel identified as baseline fuel from
refinery A, 2 million gallons of 500 ppm diesel fuel designated as
``designate and track'' NRLM fuel from refinery B, and 2 million
gallons of 500 ppm diesel fuel designated as ``designate and track''
highway fuel from refinery B. At the end of the year, the terminal
would have had to have dyed at least 2 million gallons of the fuel it
received from refinery B and delivered it to or on behalf of that
refinery as dyed NRLM. (If they do not deliver the fuel back to the
entity that designated the fuel, then the dyed fuel could have been
baseline fuel from refinery A, and we could not enforce the dyeing of
the designate and track fuel volume from refinery B.) The terminal
would need to do this separately for each refinery or importer from
which it received designate and track diesel fuel.
Based on the above discussion, we believe that in order to have an
enforceable program, only those refineries and importers who maintain
ownership of the fuel all the way through the pipeline and terminal
could take advantage of the option to designate and track their fuel.
This could be a very small subset of refiners since they would have to
maintain ownership of all of their NRLM diesel fuel distributed through
all of its distribution pathways to the point where the fuel is dyed.
If this were a very small subset, then it would raise questions as to
whether the flexibility of this approach would be worth the added
program and enforcement complexity.
Since the pipelines and terminals in this situation are basically
providing a service to these refineries and importers, transporting
their fuel and dyeing it for them, a different responsibility and
liability scheme could be considered. Instead of the fuel distributors
being solely responsible for recordkeeping and reporting to the Agency
and liable for any violations, it might be possible to leave this
burden with the refiner. The refiner could be responsible for ensuring
that they took delivery from a terminal of at least as much dyed NRLM
diesel fuel as they sent undyed NRLM to that terminal from their
refinery gate. The refiner would be responsible for collecting and
maintaining the records from the various points in the distribution
system to demonstrate compliance and to submit an annual report
demonstrating compliance. At the same time EPA would have to be able to
verify the refiner's report and as a result, fuel distributors may
still have to maintain records.
For the baseline approach to exist simultaneously with the
designate and track approach, a refinery or importer would have to
choose which approach to utilize and maintain that approach. We could
consider allowing the refinery to change approaches on a year to year
basis, as with the baseline and dye alternatives.
EPA requests comment on the designate and track approach as a
refinery's option and whether it could be enforced as described above.
EPA specifically requests comment on:
(1) The advantages and disadvantages of placing the recordkeeping,
reporting, and liability burden on the refinery of the designate and
track approach if it is an option along with baseline approach;
(2) If this responsibility were not place on the refiners, what
level of voluntary participation would occur among fuel distributors
(e.g., pipelines and terminals) and how might EPA structure a viable
enforcement oversight program;
(3) What level of voluntary refinery participation would occur and
whether it warrants the added program complexity;
(4) The extent to which this approach might reduce 15 ppm highway
diesel production (i.e., reduced spillover to non-highway markets)
(5) What would be the cost associated with the tracking, record
keeping and reporting?
[[Page 28416]]
C. Hardship Provisions for Qualifying Refiners
1. Hardship Provisions for Qualifying Small Refiners
In developing our proposed off-highway diesel sulfur program, we
evaluated the need and the ability of refiners to meet the 500 and 15
ppm standards as expeditiously as possible. We believe it is feasible
and necessary for the vast majority of the program to be implemented in
the proposed time frame to achieve the air quality benefits as soon as
possible. Based on information available from small refiners and
others, we believe that refineries owned by small businesses generally
face unique hardship circumstances, compared to larger refiners. Thus,
as discussed below, we are proposing several special provisions for
refiners that qualify as ``small refiners'' to reduce the
disproportionate burden that nonroad diesel sulfur requirements would
have on these refiners.\249\
---------------------------------------------------------------------------
\249\ The proposed small refiner provisions would not apply to
importers, as the burden from capital expenditures for physical
refinery improvements are not imposed on importers.
---------------------------------------------------------------------------
a. Qualifying Small Refiners
EPA is proposing several special provisions that would be available
to companies approved as small refiners. The primary reason for these
provisions is that small refiners generally lack the resources
available to large companies that help large companies, including those
large companies that own small-capacity refineries, to raise capital
for investing in desulfurization equipment, such as shifting of
internal funds, securing of financing, or selling of assets. Small
refiners are also likely to have more difficulty in competing for
engineering resources and completing construction of the needed
desulfurization equipment in time to meet the standards proposed today.
Since small refiners are more likely to face hardship circumstances
than larger refiners, we are proposing temporary provisions that would
provide additional time to meet the sulfur standards for refineries
owned by small businesses. This approach would allow the overall
program to begin as early as possible, avoiding the need for delay in
order to address the ability of small refiners to comply.
i. Regulatory Flexibility for Small Refiners
As explained in the discussion of our compliance with the
Regulatory Flexibility Act in section X.C and in the Initial Regulatory
Flexibility Analysis in chapter 11 of the Draft RIA, we considered the
impacts of the proposed regulations on small businesses. Most of our
analysis of small business impacts was performed as a part of the work
of the Small Business Advocacy Review (SBAR) Panel convened by EPA,
pursuant to the Regulatory Flexibility Act as amended by the Small
Business Regulatory Enforcement Fairness Act of 1996 (SBREFA). The
final report of the Panel is available in the docket for this proposed
rule.
For the SBREFA process, EPA conducted outreach, fact-finding, and
analysis of the potential impacts of our regulations on small
businesses. Based on these discussions and analyses by all panel
members, the Panel concluded that small refiners in general would
likely experience a significant and disproportionate financial hardship
in reaching the objectives of the proposed nonroad diesel fuel sulfur
program.
One indication of this disproportionate hardship for small refiners
is the relatively high cost per gallon projected for producing nonroad
diesel fuel under the proposed program. Refinery modeling of refineries
owned by refiners likely to qualify as small refiners, and of non-small
refineries, indicates significantly higher refining costs for small
refiners. Specifically, we project that without special provisions,
refining costs for small refiners on average would be about 5.5 cents
per gallon compared to about 4.0 cents per gallon for non-small
refiners.
The Panel also noted that the burden imposed on the small refiners
by the proposed sulfur standards may vary from refiner to refiner.
Thus, the Panel recommended more than one type of burden reduction
measure so that most if not all small refiners could benefit. We have
continued to consider the issues raised during the SBREFA process and
have decided to propose each of the provisions recommended by the
Panel.
ii. Rationale for Small Refiner Provisions
Generally, we structured these proposed provisions to reduce the
burden on small refiners while expeditiously achieving air quality
benefits and ensuring that the availability of 15 ppm nonroad diesel
fuel would coincide with the introduction of 2011 model year nonroad
diesel engines and equipment. We believe the proposed special
provisions for small refiners are necessary and appropriate.
First, the proposed compliance schedule for the nonroad diesel
program, combined with flexibility for small refiners, would achieve
the air quality benefits of the program as soon as possible, while
helping to ensure that small refiners will have adequate time to raise
capital for new or upgraded fuel desulfurization equipment. Most small
refiners have limited additional sources of income beyond refinery
earnings for financing and typically do not have the financial backing
that larger and generally more integrated companies have. Therefore,
they can benefit from additional time to accumulate capital internally
or to secure capital financing from lenders.
Second, we recognize that while the sulfur levels in this proposed
program can be achieved using conventional refining technologies, new
technologies are also being developed that may reduce the capital and/
or operational costs of sulfur removal. Thus, we believe that allowing
small refiners some additional time for newer technologies to be proven
out by other refiners would have the added benefit of reducing the
risks faced by small refiners. The added time would likely allow for
small refiners to benefit from the lower costs of these improvements in
desulfurization technology (e.g., better catalyst technology or lower-
pressure hydrotreater technology). This would help to offset the
financial burden facing small refiners.
Third, providing small refiners more time to comply would increase
the availability of engineering and construction resources. Most
refiners would need to install additional processing equipment to meet
the nonroad diesel sulfur requirements. We anticipate that there may be
significant competition for technology services, engineering resources,
and construction management and labor. In addition, vendors will be
more likely to contract their services with the larger refiners first,
as their projects will offer larger profits for the vendors.
Temporarily delaying compliance for small refiners would spread out the
demand for these resources and probably reduce any cost premiums caused
by limited supply.
We discuss below the provisions we are proposing to minimize the
degree of hardship for small refiners. With these provisions we are
confident about going forward with the 500 ppm sulfur standard for NRLM
diesel fuel in 2007 and the 15 ppm sulfur standard for nonroad diesel
fuel in 2010 for the rest of the industry. Without small refiner
flexibility, EPA would have to consider delaying the overall program
until the burden of the program on many small refiners were diminished,
which would delay the air quality benefits of the overall program. By
providing
[[Page 28417]]
temporary relief to small refiners, we are able to adopt a program that
expeditiously reduces off-highway diesel sulfur levels in a feasible
manner for the industry as a whole.
iii. Limited Impact of Small Refiner Options on Program Emissions
Benefits
Small refiners that choose to make use of the delayed nonroad
diesel sulfur requirements would also delay to some extent the emission
reductions that would otherwise have been achieved. However, the
overall impact of these postponed emission reductions would be small,
for several reasons.
First, small refiners represent only a fraction of national non-
highway diesel production. Today, refiners that we expect would qualify
as small refiners represent only about 6 percent of all high-sulfur
diesel production. Second, the proposed delayed compliance provisions
described below would affect only engines without new emission
controls. During the first step to 500 ppm NRLM fuel, small refiner
nonroad fuel could be well above 500 ppm, but the new advanced engine
controls would not yet be required. During the second step to 15 ppm
nonroad diesel fuel, equipment with the new controls would be entering
the market, but use of the 500 ppm small refiner fuel would be
restricted to older engines without the new controls. There would be
some loss of sulfate PM control in the older engines that operated on
higher sulfur small refiner fuel, but no effect on the major emission
reductions that the proposed new engine standards would achieve
starting in 2011. Finally, because small diesel refiners are generally
dispersed geographically across the country, the limited loss of
sulfate PM control would also be dispersed.
One proposed small refiner option would allow a modest 20%
relaxation in the gasoline sulfur interim standards for small refiners
that produce all nonroad diesel fuel at 15 ppm by June 1, 2006. To the
extent that small refiners elected this option, a small loss of
emission control from Tier 2 gasoline vehicles that used the higher
sulfur gasoline could occur. We believe that such a loss of control
would be very small. A very few small refiners would be in a position
to use this provision. Further, the relatively small production of
gasoline with slightly higher sulfur levels should have no measurable
impact on the emission of new Tier 2 vehicles, even if the likely
``blending down'' of sulfur levels did not occur as this fuel mixed
with lower sulfur fuel during distribution. This provision would also
maintain the maximum 450 ppm gasoline sulfur per-gallon cap standard in
all cases, providing a reasonable sulfur ceiling for any small refiners
making use of this provision.
b. How Do We Define Small Refiners for Purposes of the Hardship
Provisions?
The definition of small refiner for the proposed nonroad diesel
program is basically the same as our small refiner definitions in the
Tier 2/Gasoline Sulfur and Highway Diesel rules. A small refiner must
demonstrate that it meets both of the following criteria:
[sbull] No more than 1,500 employees corporate-wide, based on the
average number of employees for all pay periods from January 1, 2002 to
January 1, 2003.
[sbull] A corporate crude oil capacity less than or equal to
155,000 barrels per calendar day (bpcd) for 2002.
As with the earlier fuel sulfur programs, the dates for the
employee count and for calculation of the crude capacity represent the
latest complete years prior to the issuing of the proposed rule.
In determining the total number of employees and crude oil
capacity, a refiner must include the number of employees and crude oil
capacity of any subsidiary companies, any parent company and
subsidiaries of the parent company, and any joint venture partners. We
define a subsidiary of a company to mean any subsidiary in which the
company has a 50 percent or greater ownership interest. However, we are
proposing that a refiner be eligible for small refiner status if it is
owned and controlled by an Alaska Regional or Village Corporation
organized under the Alaska Native Claims Settlement Act (43 U.S.C.
1626), regardless of number of employees and crude oil capacity. Such
an exclusion would be consistent with our desire to grant relief from
the regulatory burden to that part of the industry that can least
afford compliance. We believe that very few refiners, probably only
one, would qualify under this provision. Similarly, we are proposing to
incorporate this exclusion into the small refiner provisions of the
highway diesel and gasoline sulfur rules, which did not address this
issue.
As with the earlier fuel sulfur rules, we are proposing that a
refiner that restarts a refinery in the future may be eligible for
small refiner status. Thus, a refiner restarting a refinery that was
shut down or non-operational between January 1, 2002, and January 1,
2003, could apply for small refiner status. In such cases, we would
judge eligibility under the employment and crude oil capacity criteria
based on the most recent 12 consecutive months unless we conclude from
data provided by the refiner that another period of time is more
appropriate. Companies with refineries built after January 1, 2002,
would not eligible for the small refiner hardship provisions.
2. The Effect of Financial Transactions on Small Refiner Status and
Small Refiner Relief Provisions
During the implementation of the gasoline sulfur and highway diesel
sulfur programs, several refiners have raised concerns about how
various kinds of financial transactions would affect implementation of
the small refiner fuel sulfur provisions. The kind of transactions
typically involve refiners with approved small refiner status that are
involved in potential or actual sales of the small refiner's refinery,
or involve the purchase by the small refiner of another refinery or
other non-refining asset. We believe that these concerns are also
relevant to the small refiner provisions proposed below for the nonroad
diesel sulfur program.
a. Large Refiner Purchasing a Small Refiner's Refinery
One situation involves a ``non-small'' refiner that wishes to
purchase a refinery owned by an approved small refiner. The small
refiner may not have completed or even begun refinery upgrades to meet
the long-term fuel sulfur standards, since it is making use of the
special small refiner relief provisions. This situation is of most
concern where the purchase is to take place near or after the beginning
of the gasoline or highway diesel sulfur programs. Under the existing
gasoline sulfur and highway diesel sulfur programs, once such a
purchase is completed, the ``non-small'' purchaser would not have the
benefit of the small refiner relief provisions that had applied to the
previous owner.
The purchasing refiner would have to perform the necessary upgrades
to meet the ``non-small'' sulfur standards. As the gasoline sulfur and
highway diesel sulfur provisions exist today, such a refiner would be
left with very little or (if the respective fuel sulfur control program
has already begun) no lead time for compliance. The refiners that have
raised this issue have claimed that refiners in this situation would
not be able to comply with the ``non-small refiner'' standards upon
acquisition of the new refinery. These refiners claim that this could
prevent them from purchasing a refinery from a small refiner and, as a
result, this would severely limit the ability of small refiners to sell
such an asset. The refiners that have raised this issue have
[[Page 28418]]
said that some sort of ``grace period'' of additional lead time before
the non-small refiner sulfur standards take effect would address this
issue.
We believe these concerns are valid and are proposing that an
appropriate period of lead time for compliance with the nonroad diesel
sulfur requirements be provided where a refiner purchases any refinery
owned by a small refiner, whether by purchase of the refinery or
purchase of the small refiner entity. We propose that a refiner that
acquires a refinery from an approved small refiner be provided 24
additional months from the date of the completion of the purchase
transaction (or until the end of the applicable small refiner relief
interim period if it is within 24 months--June 1, 2010, for 500 ppm
fuel and June 1, 2014, for 15 ppm fuel). During this interim period,
production at the newly-acquired refinery could remain at the interim
sulfur levels that applied to that refinery for the previous small
refiner owner under the small refiner options discussed below. At the
end of this period, the refiner would need to comply with the ``non-
small refinery'' sulfur standards.
We expect that in most if not all cases, the proposed 24 months of
additional lead time would be sufficient for the new refiner-owner to
accomplish the necessary engineering, permitting, construction, and
start-up of the necessary desulfurization project, since planning for
this could be expected to be a part of any purchase decision. If a
refiner nonetheless believed that the technical characteristics of its
planned desulfurization project would require additional lead time, the
refiner could apply for additional time and EPA would consider such
requests on a case-by-case basis. Such an application would be based on
the technical factors supporting the need for more time and include
detailed technical information and projected schedules for engineering,
permitting, construction, and startup. Based on information provided in
such an application and other relevant information, EPA would decide
whether additional time was technically necessary and, if so, how much
additional time would be appropriate. As discussed above, in no case
would compliance dates be extended beyond the time frame of the
applicable small refiner relief provisions (June 1, 2010, for 500 ppm
fuel and June 1, 2014, for 15 ppm fuel).\250\
---------------------------------------------------------------------------
\250\ This process would be similar to the general hardship
provisions of the existing gasoline sulfur and highway diesel sulfur
programs and proposed today for nonroad diesel fuel. However, the
focus here would be simply on the lead time needed for the technical
upgrades and would not consider any claimed financial hardship.
---------------------------------------------------------------------------
During the 24 months additional lead time (and any further lead
time approved by EPA for the purchasing refiner), all existing small
refiner provisions and restrictions, as described below, would also
remain in place for that refinery. This would include the per-refinery
volume limitation on the amount of nonroad diesel that could be
produced at the small refiner standards. There would be no adverse
environmental impact of this provision, since the small refiner would
already have been provided relief prior to the purchase and this
provision would be no more generous.
b. Small Refiner Losing Its Small Refiner Status
A second situation involves a refiner with approved small refiner
status that later loses its small refiner status because it exceeds the
small refiner criteria. In the existing gasoline sulfur and highway
diesel sulfur programs, an approved small refiner that exceeds 1,500
employees due to merger or acquisition would lose its small refiner
status. (We also intended for refiners that exceeded the 155,000 barrel
per calendar day crude capacity limit due to merger or acquisition to
lose its small refiner status and we are proposing below to amend the
regulations to reflect that criterion as well.) This includes
exceedences of the criteria caused by acquisitions of assets such as
plant and equipment, as well as acquisitions of business entities.
Our intent in the gasoline and highway diesel sulfur programs, as
well as the proposed nonroad diesel sulfur program, has been and
continues to be to reserve the small refiner relief provisions for a
small subset of refiners that generally tend to face the kinds of
special challenges discussed above. At the same time, it is also our
intent to avoid stifling normal business growth among small refiners.
Therefore, we designed our existing regulations, as well as the
proposed regulations, to disqualify a refiner from small refiner status
when it exceeds the small refiner criteria through its involvement in
transactions such as being acquired by or merging with another entity
or through the small refiner itself purchasing another entity or assets
from another entity. However, as in the existing regulations, we are
proposing that if an approved small refiner were to exceed the criteria
without merger or acquisition, it would keep its small refiner status.
Consistent with our intent in the earlier fuel sulfur programs to
limit the use of the small refiner hardship provisions, we also
intended in the gasoline sulfur and highway diesel sulfur programs for
an exceedence of the other small refiner criterion--a limit of 155,000
barrels per calendar day of crude capacity--due to merger or
acquisition to be grounds for disqualifying a refiner's small refiner
status. However, we inadvertently failed to include this second
criterion as grounds for disqualification. In today's action, we
propose to resolve this error by adding the crude capacity limit to the
employee limit in this context for both the gasoline sulfur and highway
diesel sulfur programs, to begin January 1, 2004. Thus, a refiner
exceeding either criterion due to merger or acquisition would lose its
small refiner status.
We recognize that a small refiner that loses its small refiner
status because of a merger or acquisition would face the same type of
lead time concerns in complying with the non-small refiner standards as
would a non-small refiner that acquired a small refiner's refinery, as
discussed above. Therefore, we propose that the additional lead time
proposed above for non-small refiners purchasing a small refiner's
refinery also apply to this situation. Thus, this additional lead time
would apply to any refineries, existing or newly-purchased, that had
previously been subject to the small refiner program, but would not
apply to a newly-purchased refinery that is subject to the non-small
refiner standards. Again, there would be no adverse environmental
impact because of the newly-purchased small refiner's pre-existing
relief provisions.
The issues discussed in this subsection apply equally to the
gasoline sulfur and highway diesel sulfur programs. Thus, we are also
proposing that the same provisions relating to additional lead time in
cases of financial transaction be applied to the small refiner programs
in the earlier fuel sulfur programs. Because these proposed provisions
for the existing fuel sulfur programs are independent of today's
nonroad diesel fuel program, we may choose to finalize them separately
from and earlier than the identical provisions proposed for today's
nonroad rule. If this occurs, we will seek to finalize nonroad diesel
fuel provisions that are identical or as similar as appropriate to
those finalized for the gasoline sulfur and highway diesel program.
In addition, we are inviting comment on several other related
provisions we are considering:
[[Page 28419]]
(1) We propose above that a small refiner that loses its small
refiner status be granted 24 months of lead time at its existing
refineries. Should such a small refiner instead be allowed to
``grandfather in'' its existing small refiner relief program for its
existing refinery or refineries? An argument can be made that in
purchasing a new refinery or other assets, the small refiner would no
longer demonstrate the kind of financial hardship that was the basis
for general small refiner relief. However, we also do not intend to
stifle normal growth of small refiners, and ``grandfathering in'' the
small refiner interim relief program would have no environmental
impact, since it would merely continue an existing program at that
refinery.
(2) If a small refiner exceeds the small refiner criteria due to
the purchases of a non-small refiner, should the proposed additional
lead time apply to that refinery? Or should the refiner be required to
meet the non-small refiner standards on schedule at the ``new''
refinery, since the previous owner could be assumed to have anticipated
the new standards and taken steps to accomplish this prior to the
purchase?
c. What Options Are Available for Small Refiners?
We propose several provisions intended to reduce the burdens on
small refiners discussed above as well as to encourage their early
compliance whenever possible. As described below, these proposed small
refiner provisions consist of additional time for compliance and, for
small refiners that choose to comply earlier than required, the option
of either generating diesel sulfur credits or receiving a limited
relaxation of gasoline sulfur requirements.
i. Delays in Nonroad Fuel Sulfur Standards for Small Refiners
We propose that small refiners be allowed to postpone reducing
sulfur in nonroad locomotive and marine diesel fuel until June 1, 2010.
As described earlier, we are proposing that all refiners producing
nonroad diesel fuel be provided significant lead time for making the
capital and operational investments to produce 15 ppm fuel, including
about three years before the 500 ppm requirement would become
effective, and three additional years before 15 ppm was required--June
1, 2007, through May 31, 2010, when 500 ppm fuel could be produced.
While this lead time would be useful for small and non-small refiners
alike, we believe that in general small refiners would still face
disproportionate challenges, and the proposed delay in the first step
of control for small refiners would help mitigate these challenges.
Then, beginning June 1, 2010, when the second step of the proposed
base program would require 15 ppm fuel for other refiners for nonroad
diesel fuel, we propose that small refiners be required to meet a 500
ppm sulfur standard for NR diesel fuel. We propose that this interim
standard be effective for four years (until June 1, 2014), after which
small refiners would meet the 15 ppm sulfur standard for nonroad diesel
fuel. As for other refiners, the small refiner standard for locomotive
and marine diesel fuel would remain at 500 ppm. Since new engines with
sulfur sensitive emission controls would begin to become widespread
during this time, small refiners would need to segregate the 500 ppm NR
fuel and supply it only for use in pre-2011 nonroad equipment or in
locomotives or marine engines. Section VIII below discusses the
requirements for product transfer documents (PTDs) associated with the
production of 500 ppm NR fuel by small refiners during this period.
The following table illustrates the proposed small refiner NRLM and
NRdiesel standards as compared to the standards proposed in the base
nonroad diesel program. (For simplicity, the proposed locomotive and
marine diesel standards for small and non-small refiners described
above do not appear in the table.)
Table IV-4--Proposed Small Refiner Nonroad Diesel Sulfur Standards, ppm a
--------------------------------------------------------------------------------------------------------------------------------------------------------
2006 2007 2008 2009 2010 2011 2012 2013 2014 2015+
--------------------------------------------------------------------------------------------------------------------------------------------------------
Non-small refiners............................................ ....... 500 500 500 15 15 15 15 15 15
Small Refiners................................................ ....... ....... ....... ....... 500 500 500 500 15 15
--------------------------------------------------------------------------------------------------------------------------------------------------------
Notes:
a New standards would take effect in June of the applicable year.
We also request comment on a slightly different compliance schedule
that would require small refiners to produce 15 ppm nonroad diesel fuel
beginning June 1, 2013, one year earlier than proposed above. Such a
schedule would align the end of the interim small refiner provisions
with the end of the proposed phase-in for nonroad engines and equipment
and eliminate higher sulfur nonroad fuel from the distribution system
by the time all new nonroad diesel engines required 15 ppm fuel.
The proposed delayed compliance schedule for small refiners is
intended to compensate for the relatively higher compliance burdens on
these refiners. It is not intended as an opportunity for those refiners
to greatly expand their production of uncontrolled diesel fuel (2007-
2010) or 500 ppm sulfur fuel (2010-2014). To help ensure that any
significant expansion of refining capacity that a small refiner might
undertake in the future would be accompanied by an expansion of
desulfurization capacity, we are proposing that small refiners
producing higher sulfur fuel limit that production to baseline volume
levels.
Specifically, during the first step of the diesel program to 500
ppm (June 2007-June 2010), a small refiner could produce uncontrolled
NRLM diesel fuel up to the proposed non-highway baseline for that
refiner less any marked heating oil it produces, refer to sub-section B
above for an explanation of this baseline. Any diesel fuel produced
over its non-highway baseline would be subject to the 500 ppm standard
applying to other refiners. Similarly, from June 1, 2010, through May
31, 2014, a small refiner could produce nonroad diesel fuel at 500 ppm
up to the non-highway baseline less any volume of heating oil and
marked locomotive and marine diesel fuel it produced. Fuel produced in
excess of this volume would be subject to the 15 ppm nonroad diesel
standard.
ii. Options To Encourage Earlier Compliance by Small Refiners
Some small refiners have indicated that they might find it
necessary to produce fuel meeting the nonroad diesel sulfur standards
earlier than required by the small refiner program described above, for
a variety of reasons. For some small refiners, the distribution systems
might limit the number of grades of diesel fuel that will be carried.
Others might find it economically advantageous to make 500 ppm or 15
[[Page 28420]]
ppm fuel earlier so as not to lose market share. At least one small
refiner has indicated that it might decide to desulfurize its NR pool
at the same time as it desulfurized its highway diesel fuel, in June of
2006, due to limitations in its distribution system and to take
advantage of economies of scale. Given these situations, we propose
that small refiners be able to choose between two mutually exclusive
options, as an incentive for early compliance.
The first proposed option would make the diesel sulfur credit
banking and trading program discussed earlier in this section fully
applicable to small refiners. A small refiner could generate diesel
sulfur credits for production of 500 ppm NRLM diesel fuel prior to June
1, 2010, and for production of 15 ppm nonroad fuel from June 1, 2010,
through May 31, 2012. The specifics of the credit program are described
above in subsection B.2, including how they would be applicable to
small refiners. Generating and selling credits could provide funds to
defray the costs of early nonroad compliance.
The second proposed option would apply to a small refiner that
produced all of its NRLM diesel production at 15 ppm by June 1, 2006,
and elected not to use the provision described above to earn NRLM
sulfur credits for this early compliance. (As for other refiners,
locomotive and marine fuel sulfur would not be controlled in 2006 and
could meet the 500 ppm standard beginning June 1, 2007.) Such a refiner
would receive a modest revision in its interim small refiner gasoline
sulfur standards, starting January 1, 2004. Specifically, the
applicable small refiner annual average and per-gallon cap gasoline
standards would be revised upward by 20 percent for the duration of the
small refiner gasoline sulfur interim program (i.e., through either
2007 or 2010, depending on whether the refiner had extended its
participation in the gasoline sulfur interim program by complying with
the highway diesel standard at the beginning of that program (June,
2006, as provided in 40 CFR 80.552(c))). However, in no case could the
per-gallon cap exceed 450 ppm, the highest level allowed under the
gasoline sulfur program.
We believe it is very important to link any such temporary
relaxation of a small refiner gasoline sulfur interim sulfur standards
with environmental benefit of early desulfurization of a significant
volume of NRLM diesel fuel. Thus, we propose that a small refiner
wishing to use this option must produce a minimum volume of NRLM diesel
fuel at 15 ppm by June 1, 2006. Each participating small refiner would
need to produce a volume of 15 ppm fuel that was at least 85% of the
volume represented by its non-highway distillate baseline percentage.
If the refiner began to produce gasoline in 2004 at the higher interim
standard of this provision but then either failed to meet the 15 ppm
standard for its NRLM fuel by June 1, 2006, or failed to meet the 85%
minimum volume requirement, the original small refiner interim gasoline
sulfur standard applicable to that refiner would be reinstated. In
addition, the refiner would need to compensate for the higher gasoline
levels that it had enjoyed by purchasing gasoline sulfur credits or
producing an equivalent volume of gasoline below the required sulfur
levels.
Under this option, a small refiner could in effect shift some funds
from its gasoline sulfur program to accelerate desulfurization of
nonroad diesel fuel. Given the environmental benefit that would result
from the production of 15 ppm diesel fuel earlier than necessary, and
the small potential loss of emission reduction under the gasoline
sulfur program from fuel produced by the very few small refiners that
we believe would qualify under this second option, we believe the
environmental impact of this option would be neutral or positive.
d. How Do Refiners Apply for Small Refiner Status?
A refiner applying for status as a small refiner would provide EPA
with several types of information by December 31, 2004. The detailed
application requirements are summarized in section VII.E.2 below. In
general, a refiner would need to provide information about the
following for the parent company and all subsidiaries at all locations:
(1) The average number of employees for all pay periods from January 1,
2002, through January 1, 2003; (2) total corporate crude refining
capacity; and (3) an indication of which small refiner option the
refiner is likely to use (see subsection c. above). As with
applications for relief under other rules, applications for small
refiner status under this proposed diesel rule that were later found to
contain false or inaccurate information would be void ab initio.
2. General Hardship Provisions
a. Temporary Waivers from Non-highway Diesel Sulfur Requirements in
Extreme Unforseen Circumstances
We are proposing a provision which, at our discretion, would permit
any domestic or foreign refiner to seek a temporary waiver from the
nonroad, locomotive, or marine diesel sulfur standards under certain
rare circumstances. This waiver provision is similar to provisions in
the reformulated gasoline (RFG), low sulfur gasoline, and highway
diesel sulfur regulations. It is intended to provide refiners short-
term relief in unanticipated circumstances--such as a refinery fire or
a natural disaster--that cannot be reasonably foreseen now or in the
near future.
Under this provision, a refiner may seek permission to distribute
nonroad, locomotive, or marine diesel fuel that does not meet the
applicable 500 or 15 ppm sulfur standards for a brief time period. An
approved waiver of this type could, for example, allow a refiner to
produce and distribute diesel fuel with higher than allowed sulfur
levels, so long as the other conditions described below were met. Such
a request would be based on the refiner's inability to produce
complying nonroad, locomotive or marine diesel fuel because of extreme
and unusual circumstances outside the refiner's control that could not
have been avoided through the exercise of due diligence. The request
would also need to show that other avenues for mitigating the problem,
such as purchase of credits toward compliance under the proposed credit
provisions, had been pursued and yet were insufficient. As with other
types of relief established in this rule, this type of temporary waiver
would have to be designed to prevent fuel exceeding the 15 ppm standard
from being used in 2011 and later model year nonroad engines.
The conditions for obtaining a nonroad diesel waiver are similar to
those in the RFG, Tier 2 gasoline sulfur, and highway diesel
regulations. These conditions are necessary and appropriate to ensure
that any waivers that are granted are limited in scope, and that
refiners do not gain economic benefits from a waiver. Therefore,
refiners seeking a waiver would need to show that the waiver is in the
public interest, that the refiner was not able to avoid the
nonconformity, that it would make up the air quality detriment
associated with the waiver, that it would make up any economic benefit
from the waiver, and that it would meet the applicable diesel sulfur
standards as expeditiously as possible.
b. Temporary Waivers Based on Extreme Hardship Circumstances
In addition to the provision for short-term relief in extreme
unforseen circumstances, we are proposing a provision for relief based
on extreme hardship circumstances that is very similar to those
established in the
[[Page 28421]]
gasoline sulfur and highway diesel sulfur programs. Under the gasoline
sulfur program, we granted waivers to four refiners. Each waiver was
designed for the specific situation of that refiner. Under the highway
diesel program, we have received two applications for which the
decisions are still pending.
As in the earlier rules, we have considered whether any refiners
would face particular difficulty in complying with the standards in the
lead time provided. As described earlier in this section, we concluded
that in general small refiners would experience more difficulty in
complying with the standards on time because they have less ability to
raise the capital necessary for refinery investments, face
proportionately higher costs because of poorer economies of scale, and
are less able to successfully compete for limited engineering and
construction resources. However, it is possible that other refiners
that are not small refiners would also face particular difficulty in
complying with the sulfur standards on time. Therefore, we are
including in this proposed rule a provision which allows us, at our
discretion, to grant temporary waivers from the proposed nonroad diesel
sulfur standards based on a showing of extreme hardship circumstances.
The extreme hardship provision allows any domestic or foreign
refiner to request a waiver from the sulfur standards based on a
showing of unusual circumstances that result in extreme hardship and
significantly affect a refiner's ability to comply with either the 500
ppm or 15 ppm sulfur diesel standards by either June 1, 2007, or June
1, 2010, respectively. EPA would evaluate each application on a case-
by-case basis, considering the factors described below. If EPA approved
a hardship application, we could provide refiners with relief similar
to the provision for small refiners. That is, we might provide an
allowance for producing high sulfur fuel during the 2007-2010 period
when the 500 ppm cap is in effect, or an allowance for producing 500
ppm fuel for a period of time after June 1, 2010. Depending on the
situation of the refiner, such approved delays in meeting the sulfur
requirements might be shorter than those allowed for small refiners
i.e., 3 years for high sulfur fuel beginning June 1, 2007, and 4 years
for 500 ppm fuel beginning June 1, 2010, but would not be longer. In
such an approval, we would expect to impose appropriate conditions to
assure the refiner is making its best effort and to minimize any loss
of emission control from the program. As with other relief provisions
established in this rule, any waiver under this provision would be
designed to prevent fuel exceeding the 15 ppm standard from being used
in 2011 and later model year nonroad engines.
Providing short-term relief to those refiners that need additional
time because they face hardship circumstances facilitates adoption of
an overall program that reduces NRLM diesel fuel sulfur to 500 ppm
beginning in 2007, and nonroad diesel fuel sulfur to 15 ppm in 2010,
for the majority of the industry. However, we do not intend for this
waiver provision to encourage refiners to delay planning and
investments they would otherwise make. We do not expect to grant
temporary waivers that apply to more than approximately one percent of
the national NRLM diesel fuel pool in any given year.
The regulatory language for today's action includes a list of the
information that must be included in a refiner's application for an
extreme hardship waiver. If a refiner fails to provide all the
information, as specified in the regulations, as part of its hardship
application, we can deem the application void. EPA may request
additional information as needed. The following are some examples of
the types of information that must be contained in an application:
[sbull] The crude oil refining capacity and fuel sulfur level(s) of
each diesel fuel product at each of the refiner's refineries.
[sbull] Technical plan for capital equipment and operating changes
to achieve future diesel fuel sulfur levels.
[sbull] The anticipated timing for the overall project the refiner
is proposing and key milestones to ultimately produce 100 percent of
NRLM diesel fuel at 500 ppm sulfur and 100 percent of its nonroad
diesel fuel at 15 ppm sulfur.
[sbull] The refiner's capital requirements for each step of the
proposed projects.
[sbull] Detailed plans for financing the project and financial
statements demonstrating the nature of and degree of financial hardship
and how the requested relief would mitigate this hardship. This would
include a description of the overall financial situation of the company
and its plans to secure financing for the desulfurization project
(e.g., internal cash flow, bank loans, issuing of bonds, sale of
assets, or sale of stock).
[sbull] Description of the market area for the refiner's diesel
fuel products.
[sbull] A plan demonstrating how they would achieve the standards
as quickly as possible, including a timetable for obtaining the
necessary capital, contracting for engineering and construction
resources, obtaining any necessary permits, and beginning and
completing construction.
We would consider several factors in our evaluation of the hardship
waiver applications. Such factors would include whether a refinery's
configuration is unique or atypical; the proportion of non-highway
diesel fuel production relative to other refinery products; whether the
refiner, its parent company, and its subsidiaries are faced with severe
economic limitations (for example, a demonstrated inability to raise
necessary capital or an unfavorable bond rating); and steps the refiner
has taken to attempt to comply with the standards, including efforts to
obtain credits towards compliance. In addition, we would consider the
total crude oil capacity of the refinery and its parent or subsidiary
corporations, if any, in assessing the degree of hardship and the
refiner's role in the diesel market. Finally, we would consider where
the diesel fuel would be sold in evaluating the environmental impacts
of granting a waiver.
This extreme hardship provision is intended to address unusual
circumstances that should be apparent now or would emerge in the near
future. Thus, refiners seeking additional time under this provision
would have to apply for relief by June 1, 2005. We request comment on
this date and whether a separate date would be appropriate for the
second (15 ppm) step of the nonroad diesel program to 15 ppm. We would
review and act on applications and, if a waiver is granted, would
specify a detailed desulfurization schedule under the waiver.
Typically, because of EPA's comprehensive evaluation both financial and
technical information, action on hardship applications can take six or
more months.
D. Should Any Individual States or Territories Be Excluded From This
Rule?
1. Alaska
We propose that the diesel fuel sulfur standards--the 500 ppm cap
for NRLM diesel fuel beginning June 1, 2007, and the 15 ppm cap for
nonroad diesel fuel beginning June 1, 2010--and the aromatics and
cetane standards proposed today apply to the portion of Alaska served
by the Federal Aid Highway System. However, we propose that Alaska's
rural areas be excluded from these proposed fuel content standards. The
engine standards proposed today would apply to all nonroad engines
throughout Alaska.
[[Page 28422]]
Consequently, even in rural Alaska we would still require 2011 and
later model year nonroad diesel engines and equipment to be fueled with
15 ppm diesel fuel. The rationale supporting this proposal follows.
a. How Was Alaska Treated Under the Highway Diesel Standards?
Unlike the rest of the nation, Alaska is currently exempt from the
500 ppm sulfur standard for highway diesel fuel and the dye provisions
for diesel fuel not subject to this standard. Since the beginning of
the 500 ppm highway diesel fuel program, we have granted Alaska
exemptions from both the sulfur standard and dye provisions because of
its unique geographical, meteorological, air quality, and economic
factors.\251\
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\251\ Copies of information regarding Alaska's petition for
exemption, subsequent requests by Alaska, public comments received,
and actions by EPA are available in public docket A-96-26.
---------------------------------------------------------------------------
On December 12, 1995, Alaska submitted a petition for a permanent
exemption for all areas of the state served by the Federal Aid Highway
System, that is, those areas previously covered only by a temporary
exemption. While considering that petition, we started work on a
nationwide rule to consider more stringent highway diesel fuel
requirements for sulfur content. In the subsequent January 18, 2001,
highway diesel sulfur rule (66 FR 5002) the highway engine emission
standards were applied fully in Alaska. Based on factors unique to
Alaska, we provided the State with: (1) an extension of the exemption
from the 500 ppm sulfur highway diesel fuel standard until the
effective date of the new 15 ppm sulfur standard for highway diesel
fuel in 2006, (2) an opportunity to request an alternative
implementation plan for the 15 ppm sulfur diesel fuel program, and (3)
a permanent exemption from the diesel fuel dye provisions.
In response to these provisions in our January 18, 2001, highway
rule, Alaska informed us that areas served by the Federal Aid Highway
System, i.e., communities on the connected road system or served by the
Alaska State ferry system, would follow the nationwide requirements.
Diesel fuel produced for use in areas of Alaska served by the Federal
Aid Highway System will therefore be required to meet the same
requirements for highway diesel fuel as diesel fuel produced for the
rest of the nation. For the rural parts of the State, areas not served
by the Federal Aid Highway System, Alaska informed us that it would
submit by mid-2003 the details for an alternative implementation
approach.\252\ EPA will consider their alternative implementation
approach when it is received, and if appropriate will initiate
rulemaking to finalize its adoption.
---------------------------------------------------------------------------
\252\ Letter and attached document to Jeffrey Holmstead of EPA
from Michele Brown of the Alaska Department of Environmental
Conservation, dated April 1, 2002. The communities on the connected
road system or served by the Alaska State ferry system are listed in
the attached document.
---------------------------------------------------------------------------
b. What Nonroad Standards Do We Propose for Urban Areas of Alaska?
Since Alaska is currently exempt from the 500 ppm sulfur standard
for highway diesel fuel, we also considered exempting Alaska from the
500 ppm step of the proposed NRLM standards. However, despite the
exemption, officials from the State of Alaska have informed us that 500
ppm highway diesel fuel is nevertheless being marketed in many parts of
Alaska. Market forces have brought the prices for 500 ppm diesel fuel
down such that it is now becoming competitive with higher sulfur,
uncontrolled diesel fuel. Assuming this trend continues, requiring that
NRLM diesel fuel be produced to 500 ppm beginning June 1, 2007 would
not appear to be unduly burdensome and for this reason, we propose that
this standard apply.
At the same time, our expectation is that compliance with the
highway program described above may result in the transition of all of
the highway diesel fuel distribution system to 15 ppm beginning in
2006. It could prove very challenging for the distribution system in
some of the areas to segregate a 500 ppm grade of NRLM from a 15 ppm
grade of highway and an uncontrolled grade for other purposes. We
believe economics would determine whether the distribution system would
handle the new grade of fuel or substitute 15 ppm sulfur highway diesel
fuel for NRLM applications. Thus, in the 2007 to 2010 time frame, the
NRLM market in some urban areas might be supplied with 500 ppm sulfur
diesel, and in other areas might be supplied with 15 ppm sulfur diesel.
Regardless of what takes place prior to 2010, we anticipate that 15
ppm highway diesel fuel will be made available in Alaska by this time
frame. The 2007 and later model year highway fleet will be growing,
demanding more and more supply of 15 ppm diesel fuel. Adding nonroad
volume to this would not appear to create any undue burden. Thus, we
also propose that the 15 ppm standard for nonroad diesel fuel would
apply in areas of Alaska served by the FAHS, along with the rest of the
Nation beginning June 1, 2010. We seek comment on whether the 500 ppm
NRLM diesel standard should apply to these areas of Alaska beginning
June 1, 2007, and whether the 15 ppm nonroad standard should apply
beginning June 1, 2010.
During the development of the original 500 ppm highway diesel fuel
standards in the early 1990's refiners and distributors in Alaska
expressed concern that if Alaska were required to dye its non-highway
diesel fuel red along with the rest of the country, residual dye in
tanks or other equipment would be enough to contaminate and disqualify
Jet-A kerosene used as aviation fuel. Since much of the diesel fuel in
Alaska is number 1 and indistinguishable from Jet A kerosene, not only
would tanks and transfer equipment have to be cleaned, but separate
tankage would be needed. Consequently, we granted Alaska temporary
exemptions from the dye requirement and in the January 18, 2001,
highway diesel rule granted them a permanent exemption. The proposed
marker for heating oil in the 2007-10 time period and for locomotive
and marine diesel fuel in the 2010-14 time period could present similar
concerns in Alaska's distribution system. Consequently, we seek comment
on whether to extend the current exemption from the red dye requirement
to the proposed marker requirement. If we were to, we then also seek
comment on what mechanism could be used in Alaska to ensure that 500
ppm diesel fuel was used in NRLM equipment from 2007-10 and 15 ppm in
nonroad equipment after 2010. One possible approach would be to
preclude refineries and importers from using credits to comply with the
sulfur standards and prohibit end-users in Alaska from using anything
but 500 ppm in NRLM equipment from 2007-10 and 15 ppm in nonroad
equipment after 2010.
c. What Do We Propose for Rural Areas of Alaska?
Rural Alaska represents a rather unique situation. In the rural
areas, the state estimates that the heating oil represent approximately
95% of all distillate consumption (about 50% for heating and 45% for
electricity generation). Highway vehicles account for about 1 percent,
and marine engines about 4 percent.\253\ Consequently, nonroad and
locomotive engines and equipment consume a negligible amount of diesel
fuel in the rural areas. The fuel
[[Page 28423]]
storage infrastructure in the villages generally consists of a limited
number of small community storage tanks. The fuel must last during the
entire winter season when fuel deliveries may not be possible. There is
currently only one distillate fuel that is delivered and stored for all
distillate purposes in the villages, including home heating, power
generation, vehicles, marine engines and possibly some nonroad engines
and equipment. Modifications to permit the segregation of small amounts
of low sulfur or ultra low-sulfur distillate fuel for highway and/or
NRLM use or switching to low sulfur or ultra low-sulfur fuel for all
purposes would be an economic hardship for the villages.
---------------------------------------------------------------------------
\253\ E mail from the Alaska Department of Environmental
Conservation, dated July 2, 2002.
---------------------------------------------------------------------------
Furthermore, as discussed above, for areas not served by the
Federal Aid Highway System, the State of Alaska is considering an
alternative implementation plan for the 15 ppm and 500 ppm highway
standards. One option under consideration by the State would be to not
apply these standards in these areas. Rather, the 15 ppm fuel would be
provided based on demand to 2007 and later model year vehicles that
must be operated on 15 ppm fuel as they enter the fleet. Since the
vehicle turnover rate in rural villages is typically very low, and many
of the replacement vehicles are pre-owned vehicles themselves, some
villages may not obtain their first 2007 or later model year diesel
highway vehicle until long after 2010. If such a highway plan would be
finalized and EPA subsequently incorporated it into the regulations,
the proposed NRLM low-sulfur diesel fuel program, without similar
provisions, would require 500 ppm diesel fuel solely for the NRLM
market in rural areas beginning June 1, 2007, and 15 ppm sulfur solely
for the nonroad market beginning June 1, 2010. Since the demand for new
nonroad engines and equipment with aftertreatment (model year 2011 and
later) is expected to be nonexistent or very low in the early years in
rural Alaska, we believe the best approach is to propose no sulfur or
other content requirements for areas of Alaska not served by the FAHS.
EPA can revisit this when it receives and takes action on Alaska's
highway implementation plan. This will allow for coordination between
the highway and NRLM fuel requirements. As proposed, this would allow
rural Alaska to limit the volume of 15 ppm sulfur diesel fuel to that
which is sufficient to meet the demand from the small number of new
nonroad diesel engines and equipment that would be certified to the
Tier 4 nonroad standards proposed today beginning with the 2011 model
year.
Our goal in proposing this approach is to allow rural Alaska to
transition to the low sulfur fuel program in a manner that minimizes
costs while still ensuring that the model year 2011 and later nonroad
engines and equipment with aftertreatment receive the 15 ppm diesel
fuel they need. Similar to the flexibility being considered under the
highway program, the flexibility offered by this proposal would likely
result in a delay of some sulfate emission reduction benefits in the
rural areas of Alaska. The sulfate emissions of NRLM engines and
equipment in Alaska would remain at current levels for as long as high-
sulfur diesel fuel is used.
2. American Samoa, Guam, and the Commonwealth of Northern Mariana
Islands
a. What Provisions Apply in American Samoa, Guam, and the Commonwealth
of Northern Mariana Islands?
We are proposing to exclude American Samoa, Guam and the
Commonwealth of the Northern Mariana Islands from the proposed NRLM
diesel fuel sulfur standard of 500 ppm sulfur in 2007 and 15 ppm sulfur
nonroad standard in 2010, as well as the cetane index and aromatics
requirements. We also propose to exclude these territories from the
Tier 4 nonroad vehicle, engine and equipment emissions standards, and
other requirements associated with those emission standards. The
territories will continue to have access to new nonroad diesel engines
and equipment using pre-Tier 4 technologies, at least as long as
manufacturers choose to market those technologies. We will not allow
the emissions control technology in the territories to backslide from
those available in 2010. If, in the future, manufacturers choose to
market only nonroad diesel engines and equipment with Tier 4 emission
control technologies, we believe the market will determine if and when
the territories will make the investment needed to obtain and
distribute the diesel fuel necessary to support these technologies.
We are also proposing to require that all nonroad diesel engines
and equipment for these territories be certified and labeled to the
applicable requirements--either to the 2010 model year standards and
associated requirements under this proposed exclusion, or to the 2011
and later standards and associated requirements applicable for the
model year of production under the nationwide requirements of this
proposal--and warranted, as otherwise required under the Clean Air Act
and EPA regulations. Special recall and warranty considerations due to
the use of excluded high sulfur fuel would be the same as those for
Alaska during its exemption and transition periods for highway diesel
fuel and for these territories for highway diesel fuel (see 66 FR 5086,
5088, January 18, 2001).
To protect against this exclusion being used to circumvent the
emission requirements applicable to the rest of the United States, we
are restricting the importation of nonroad engines and equipment from
these territories into the rest of the United States. After the 2010
model year, nonroad diesel engines and equipment certified under this
exclusion to meet the 2010 model year emission standards for sale in
American Samoa, Guam and the Commonwealth of the Northern Mariana
Islands will not be permitted entry into the rest of the United States.
b. Why Are We Treating These Territories Uniquely?
Like Alaska, these territories are currently exempt from the 500
ppm sulfur standard for highway diesel fuel. Unlike Alaska and the rest
of the nation, they are also exempt from the new highway diesel fuel
standard effective in 2006 and the new highway vehicle and engine
emission standards effective beginning in 2007 (see 66 FR 5088, January
18, 2001).
Section 325 of the CAA provides that upon request of Guam, American
Samoa, the Virgin Islands, or the Commonwealth of the Northern Mariana
Islands, we may exempt any person or source, or class of persons or
sources, in that territory from any requirement of the CAA, with some
specific exceptions. The requested exemption could be granted if we
determine that compliance with such requirement is not feasible or is
unreasonable due to unique geographical, meteorological, or economic
factors of the territory, or other local factors as we consider
significant. Prior to the effective date of the current highway diesel
sulfur standard of 500 ppm, the territories of American Samoa, Guam and
the Commonwealth of Northern Mariana Islands petitioned us for an
exemption under section 325 of the CAA from the sulfur requirement
under section 211(i) of the CAA and associated regulations at 40 CFR
80.29. We subsequently granted the petitions.\254\ We recently
determined that the 2007 heavy-duty emission standards and 2006 diesel
fuel sulfur
[[Page 28424]]
standard of our January 18, 2001 highway rule (66 FR 5088) would not
apply to these territories.
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\254\ See 57 FR 32010, July 20, 1992 for American Samoa; 57 FR
32010, July 30, 1992 for Guam; and 59 FR 26129, May 19, 1994 for
CNMI.
---------------------------------------------------------------------------
Compliance with this proposal would result in major economic
burden. All three of these territories lack internal petroleum supplies
and refining capabilities and rely on long distance imports. Given
their remote location from Hawaii and the U.S. mainland, most petroleum
products are imported from East rim nations, particularly Singapore.
Although Australia, the Philippines, and certain other Asian countries
have or will soon require low sulfur diesel fuel, their sulfur limit is
500 ppm, not the new 15 ppm sulfur limit established for highway diesel
fuel by the January 18, 2001, highway rule or this proposal for nonroad
diesel fuel beginning in 2010 for the United States. Compliance with
new 15 ppm sulfur requirements for highway diesel fuel beginning in
2006 and the proposed 15 ppm sulfur requirements for nonroad diesel
fuel beginning in 2010 (or the proposed 500 ppm sulfur requirements for
NRLM diesel fuel beginning 2007) would require construction of separate
storage and handling facilities for a unique grade of diesel fuel for
highway and nonroad purposes, or use of 15 ppm diesel fuel for all
purposes to avoid segregation. Either of these alternatives would
require importation of 500 and 15 ppm sulfur diesel fuel from Hawaii or
the U.S. mainland, and would significantly add to the already high cost
of diesel fuel in these territories, which rely heavily on United
States support for their economies. At the same time, it is not clear
that the environmental benefits in these areas would warrant this cost.
Therefore, we are not proposing to apply the fuel and engine standards
to these territories, but seek comment on this.
E. How Are State Diesel Fuel Programs Affected by the Sulfur Diesel
Program?
Section 211(c)(4)(A) of the CAA prohibits states and political
subdivisions of states from prescribing or attempting to enforce, for
purposes of motor vehicle emission control, ``any control or
prohibition respecting any characteristic or component of a fuel or
fuel additive in a motor vehicle or motor vehicle engine,'' if EPA has
prescribed ``a control or prohibition applicable to such characteristic
or component of the fuel or fuel additive'' under section 211(c)(1).
This prohibition applies to all states except California, as explained
in section 211(c)(4)(B). This express preemption provision in section
211(c)(4)(A) applies only to controls or prohibitions respecting any
characteristics or components of fuels or fuel additives for motor
vehicles or motor vehicle engines, that is, highway vehicles. It does
not apply to controls or prohibitions respecting any characteristics or
components of fuels or fuel additives for nonroad engines or nonroad
vehicles.\255\
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\255\ See 66 FR 36543 (July 12, 2001) (Notice proposing approval
of Houston SIP revisions). See also letter from Carl Edlund,
Director, Multimedia Planning and Permitting Division, U.S.
Environmental Protection Agency, Region VI, to Jeffrey Saitas,
Executive Director, Texas Natural Resources Conservation Commission,
dated September 25, 2000, providing comments on proposed revisions
to the Texas State Implementation Plan for the control of ozone,
specifically the Post 99 Rate of Progress Plan and Attainment
Demonstration for the Houston/Galveston area. This letter noted that
preemption under section 211(c)(4) did not apply to controls on
nonroad diesel fuel.
---------------------------------------------------------------------------
Section 211(c)(4)(A) specifically mentions only controls respecting
characteristics or components of fuel or fuel additives in a ``motor
vehicle or motor vehicle engine,'' adopted ``for purposes of motor
vehicle emissions control,'' and the definitions of motor vehicle and
nonroad engines and vehicles in CAA section 216 are mutually exclusive.
This is in contrast to section 211(a) and (b), which specifically
mention application to fuels or fuel additives used in nonroad engines
or nonroad vehicles, and with section 211(c)(1) which refers to fuel
used in motor vehicles or engines or nonroad engines or vehicles.
Thus, this proposal would not preempt state controls or
prohibitions respecting characteristics or components of fuel or fuel
additives used in nonroad engines or nonroad vehicles under the
provisions of section 211(c)(4)(A). At the same time, a state control
that regulates both highway fuel and nonroad fuel is preempted to the
extent the state control respects a characteristic or component of
highway fuel regulated by EPA under section 211(c)(1).
A court could consider whether a state control for fuels or fuel
additives used in nonroad engines or nonroad vehicles is implicitly
preempted under the Supremacy Clause of the U.S. Constitution. Courts
have determined that a state law is preempted by federal law where the
state requirement actually conflicts with federal law by preventing
compliance with the federal requirement, or by standing as an obstacle
to accomplishment of Congressional objectives. A court could thus
consider whether a given state standard for sulfur in nonroad,
locomotive or marine diesel fuel is preempted if it places such
significant cost and investment burdens on refiners that refiners
cannot meet both state and federal requirements in time, or if the
state control would otherwise meet the criteria for conflict
preemption.
F. Technological Feasibility of the 500 and 15 ppm sulfur Diesel Fuel
Program
This section describes the nonroad, locomotive and marine diesel
fuel market and how these fuels differ from current highway diesel
fuel, whose sulfur content is already controlled to no more than 500
ppm sulfur. This section then summarizes our assessment of the
feasibility of refining and distributing NRLM diesel fuel with a sulfur
content of no more than 500 ppm and, for nonroad fuel only, of 15 ppm.
Based on this evaluation, we believe it is technologically feasible for
refiners and distributors to meet both sulfur standards in the lead
time provided. We are only summarizing our analysis here and we refer
the reader to the Draft RIA for more details.
1. What is the Nonroad, Locomotive and Marine Diesel Fuel Market Today
Nonroad, locomotive and marine diesel fuel comprise part of what is
generally called the distillate fuel market. Other fuels in this market
are highway diesel fuel and heating oil, which is used in furnaces and
boilers as well as in stationary diesel engines to generate power.
Nonroad diesel fuel comprises about 15% of all number 2 distillate
fuel, while locomotive and marine diesel fuel comprise about 9% of all
number 2 distillate fuel (see Draft RIA).
ASTM defines three number 2 distillate fuels: (1) low sulfur No. 2-
D (which includes the 500 ppm sulfur cap for fuel used in highway
diesel vehicles), (2) high sulfur No. 2-D, and (3) No. 2 fuel oil
(commonly referred to as heating oil).\256\ Low sulfur No. 2-D fuel
must contain no more than 500 ppm sulfur, have a minimum cetane number
of 40, and have a minimum cetane index limit of 40 (or a maximum
aromatic content of 35 volume percent). This fuel meets EPA's
requirements for current highway diesel vehicle fuel. Both high sulfur
No. 2-D and No. 2 fuel oil must contain no more than 5000 ppm
sulfur.\257\ The ASTM standards for high sulfur No. 2-D fuel also
include a minimum cetane number specification of 40. Practically, since
most No. 2 fuel oil meets the minimum cetane number specification,
pipelines which ship fuel fungibly need only carry one high sulfur
[[Page 28425]]
number 2 distillate fuel which meets both sets of specifications.
Nonroad, locomotive and marine engines can be and are fueled with both
low and high sulfur No. 2-D fuels.
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\256\ ``Standard Specification for Diesel Fuel Oils,'' ASTM D
975-98b and ``Standard Specification for Fuel Oils,'' ASTM D 396-98.
\257\ Some states, particularly those in the Northeast, limit
the sulfur content of No. 2 fuel oil to 2000-3000 ppm.
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During winter months in the northern U.S., No. 1 distillate, such
as kerosene, is sometimes added to No. 2 distillate fuel to prevent
gelling. Any No. 1 distillate added to No. 2 NRLM diesel fuel would
become NRLM diesel fuel.
Highway diesel fuel, comprises about 57% of all number 2 distillate
fuel. Eighty percent of highway diesel fuel will be capped at 15 ppm
sulfur starting in 2006. However, because of limitations in the fuel
distribution system and other factors, about one-third of non-highway,
No. 2 distillate currently meets the 500 ppm highway diesel fuel cap.
Thus, about 69 percent of number 2 distillate pool currently meets the
500 ppm sulfur cap, not just the 57 percent used in highway vehicles.
The result is that about one-third of the 24% of the distillate market
comprised by NRLM diesel fuel currently meets a 500 ppm specification
and is also expected to meet the future highway diesel fuel
requirements even without this proposed rule. Thus, while this proposed
rule would apply to all NRLM diesel fuel, the rule should only
materially affect about two-thirds of all NRLM diesel fuel, or 16% of
today's distillate market. EPA is not considering any national sulfur
standards applicable to home heating fuel or power generation fuel at
this time.
2. How Do Nonroad, Locomotive and Marine Diesel Fuel Differ From
Highway Diesel Fuel?
Refiners blend together a variety of distillate blendstocks to
produce both highway and non-highway diesel fuels. These distillate
blendstocks always include straight run material contained in crude
oil, plus they often include light cycle oil from a fluidized catalytic
cracker, light coker gas oil from a coker and hydrocrackate from a
hydrocracker. The actual mix of these blendstocks in highway and non-
highway diesel fuel at refineries producing both fuels can differ.
However, in general, significant quantities of all of these blendstocks
find their way into both low sulfur and high sulfur diesel fuel today.
A survey of distillate fuel quality conducted by API and NPRA in 1996
indicated the following feedstock composition for low sulfur diesel
fuel and high sulfur diesel fuel and heating oil.
Table IV-5--Composition of Low Sulfur Diesel Fuel and High Sulfur Diesel
Fuel and Heating Oil: 1996 U.S. Non-California Average of Surveyed
Refiners (Volume Percent)a
------------------------------------------------------------------------
High Sulfur No. 2
Feedstocks Low Sulfur No. 2 Diesel Fuel and
Diesel Fuel Heating Oil
------------------------------------------------------------------------
Hydrotreated
------------------------------------------------------------------------
Straight Run Material....... 52 18
Light Cycle Oil............. 20 11
Light Coker Gas Oil......... 8 5
Hydrocrackate............... 4 9
-----------------------------
Non-Hydrotreated
------------------------------------------------------------------------
Straight Run Material....... 12 45
Light Cycle Oil............. 3 11
Light Coker Gas Oil......... 1 1
------------------------------------------------------------------------
Notes:
a We plan to update these compositions to reflect greater use of heavier
crude oils in future analyses.
The primary difference between low and high sulfur number 2
distillate fuels today is the fact that a greater volume percentage of
low sulfur fuel feedstocks have been hydrotreated to meet the 500 ppm
sulfur cap applicable to highway diesel fuel. As shown in the table
above, high sulfur distillate fuels may contain significant amounts of
hydrotreated material, but the final sulfur level of the blend is
usually well above 500 ppm and currently averages 3400 ppm (see Draft
RIA). Hydrotreating today typically involves combining diesel fuel with
hydrogen and a catalyst under pressures of 400-1200 pounds per square
inch and temperatures of roughly 600 degrees Fahrenheit. In general,
the existence of the 500 ppm sulfur cap gives refiners an incentive to
use low sulfur blendstocks, such as hydrocrackate and straight run, in
their low sulfur diesel fuel. However, some high sulfur blendstocks,
such as light cycle oil and light gas coker oil, require hydrotreating
to remove other undesirable compounds, such as olefins and metals. Once
hydrotreated, they are suitable for use in low sulfur diesel fuel.
Also, some light cycle oils and light gas coker oils contain so much
sulfur and olefins and have such a low cetane number that they are
unsuitable for direct blending into even high sulfur diesel fuel, since
most high sulfur diesel fuel meets the ASTM sulfur cap of 5000 ppm and
cetane number minimum of 40.\258\ Where material is hydrotreated in
order to blend into a high sulfur fuel, it is often easier to
hydrotreat the material further to meet a 500 ppm cap and blend
straight run material directly into the high sulfur diesel pool. Thus,
there is no bright line separating the blendstocks used to produce low
and high sulfur diesel fuel today.
---------------------------------------------------------------------------
\258\ Non-highway diesel fuel often meets sulfur standards of
2000-3000 ppm in some states, particularly those in the Northeast.
These states have limited the sulfur content of home heating oil to
these levels. To ease fuel distribution, refiners and distributors
sell the same fuel into the home heating fuel and non-highway diesel
fuel markets.
---------------------------------------------------------------------------
3. What Technology Would Refiners Use to Meet the Proposed 500 ppm
Sulfur Cap?
Refiners currently hydrotreat some or all of their distillate
blendstocks to meet the 500 ppm sulfur cap applicable to highway diesel
fuel. Refiners would be able to meet the proposed 500 ppm sulfur cap
for NRLM diesel fuel using this same technology. As will be discussed
further in the next section, several alternative desulfurization
technologies are being developed. However, these alternative
technologies promise the greatest cost savings at very low sulfur
levels, such as 15 ppm. Also, their ongoing development makes it
[[Page 28426]]
unlikely that they would be selected by most refiners for production as
early as 2007. Finally, the use of conventional hydrotreating
technology to meet a 500 ppm standard can readily be combined later
with these alternative technologies to meet the subsequent 15 ppm
standard in 2010. Thus, we expect that the vast majority of refiners
would use conventional hydrotreating to meet the 500 ppm standard in
2007 applicable to NRLM diesel fuel.
Refiners would also likely need to install or modify several
existing ancillary units related to sulfur removal (e.g., hydrogen
production and purification, sulfur recovery, amine scrubbing and sour
water scrubbing facilities). All of these units currently exist at the
vast majority of refineries, but may have to be expanded or enlarged.
4. Has Technology to Meet a 500 ppm Cap Been Commercially Demonstrated?
Conventional diesel desulfurization technologies have been
available and in use for many years. U.S. refiners have nearly ten
years of experience with this technology in producing diesel fuel with
less than 500 ppm sulfur for highway use. Thus, the technology to
produce 500 ppm NRLM diesel fuel has clearly been demonstrated and
optimized over the last decade.
5. Availability of Leadtime To Meet the 2007 500 ppm Sulfur Cap
About 105 refineries in the U.S. currently produce high sulfur
distillate fuel. Under the fuel-related provisions of this proposal, we
project that roughly 42 of these refineries would likely need to
produce 500 ppm NRLM diesel fuel to satisfy the demand for this fuel.
The remaining 63 or so refineries would continue to produce high sulfur
distillate fuel, either as heating oil or as high sulfur NRLM diesel
fuel.
If we promulgate this proposal one year from today, this would
provide refiners and importers with approximately 38 months before they
would have to begin complying with the 500 ppm cap for NRLM diesel fuel
on June 1, 2007. Our leadtime analysis, which is presented in the draft
RIA, projects that 27-39 months are typically needed to design and
construct a diesel fuel hydrotreater.\259\ Thus, the leadtime available
for the 500 ppm cap in mid-2007 should be sufficient.
---------------------------------------------------------------------------
\259\ ``Highway Diesel Progress Review,'' USEPA, EPA420-R-02-
016, June 2002.
---------------------------------------------------------------------------
Easing the task is the fact that we project that essentially all
refiners would use conventional hydrotreating to comply with the 500
ppm NRLM diesel fuel cap. This technology has been used extensively for
more than 10 years and its capabilities to process a wide range of
diesel fuel blendstocks are well understood. Thus, the time necessary
to optimize this technology for a specific refiner's situation should
be relatively short.
While conventional hydrotreating would likely be used to meet the
500 ppm cap in 2007, most refiners would have to plan to be able
process this fuel further to meet the 15 ppm nonroad diesel fuel cap in
2010. Even those refiners planning on producing 500 ppm locomotive and
marine diesel fuel starting in 2010 would likely have to plan for the
potential that this fuel could be controlled to 15 ppm sulfur at some
time in the future. Thus, the conventional hydrotreater built in 2007
would have to be able to be compatible with the technology eventually
chosen to produce 15 ppm fuel in 2010 or later. This could affect the
hydrotreater's design pressure, physical location and layout and
peripherals, such as hydrogen supply and utilities. However, we project
that 34 out of the 42 refineries which we project would produce this
fuel also produce highway diesel fuel. Thus, over 80 percent of the
refiners likely to produce 500 ppm NRLM fuel in 2007 are already well
into their planning for meeting the 15 ppm highway diesel fuel
standard, effective June 1, 2006. It is likely that these refiners have
already chemically characterized their high sulfur diesel fuel
blendstocks, as well as their highway diesel fuel, for potential
desulfurization. They will also have already assessed the various
technologies for producing 15 ppm diesel fuel and have a good idea of
what technology they might use to meet the 15 ppm nonroad diesel fuel
cap starting in 2010. Those refiners which only produce high sulfur
distillate fuel today would still be able to take advantage of the
significant experience that technology vendors have obtained in helping
refiners of highway diesel fuel plan for producing 15 ppm diesel fuel
in 2006.
Also, of the 34 refineries producing highway diesel fuel today, we
project that three will likely build a new hydrotreater to produce 15
ppm highway diesel fuel in 2006. This would allow them to produce 500
ppm NRLM diesel fuel using their existing highway diesel fuel
hydrotreater. Another 10 of these 34 refineries produce relatively
small volumes of high sulfur distillate compared to highway diesel fuel
today. Thus, we project that they should be able to produce 500 ppm
NRLM fuel from their high sulfur distillate with minor modification to
their existing hydrotreater.
Refiners may also need some time to assess what diesel fuel and
heating oil markets they plan on participating in starting 2010. While
heating oil may not be widely distributed in PADDs 2, 3 and 4, refiners
in PADDs 1 and 3 would still be able to produce heating oil for the
Northeast fuel market. Likewise, heating oil may still be distributed
in the Pacific Northwest. Under this proposal, locomotive and marine
diesel fuel would remain at 500 ppm for some time. Thus, many refiners
would require some time to decide what market to participate in after
2010. This strategic planning should be able to coincide with refiners'
evaluation of 15 ppm technologies and not add to the overall lead time
required.
In all, we project that the task of producing 500 ppm NRLM fuel in
2007 would be less difficult than the task refiners faced with the
implementation of the 500 ppm highway diesel fuel cap in 1993. Refiners
had just over three years of leadtime for the highway diesel fuel cap,
as is the case here and this proved sufficient.
6. What Technology Would Refiners Use to Meet the Proposed 15 ppm
Sulfur Cap for Nonroad Diesel Fuel?
We project that refiners would be able to use a variety of
desulfurization technologies to meet the proposed 15 ppm sulfur cap for
nonroad fuel. One approach would be to use an extension of conventional
hydrotreating technology. We expect that refiners would utilize
hydrotreating to meet the proposed 500 ppm standard. We expect that
refiners would design this hydrotreater to facilitate the addition of a
second reactor or hydrotreating stage to further desulfurize their
distillate blendstocks from 500 ppm to 15 ppm. Refiners might also
shift to the use of an improved catalyst even in the first reactor
(i.e., that producing roughly 500 ppm sulfur product), as well as add
equipment to further purify the hydrogen used.
This is the same technology which EPA projected would be used by
most refiners to meet the 15 ppm sulfur cap for highway diesel fuel.
EPA just recently reviewed the progress being made by refining
technology vendors and refiners in meeting the 2006 highway diesel
sulfur cap.\260\ All evidence available confirms EPA's projection that
conventional hydrotreating will be capable of producing diesel fuel
containing less
[[Page 28427]]
than 10 ppm sulfur. Refiners producing only high sulfur distillate
today should have an added advantage in meeting a 15 ppm sulfur cap for
nonroad fuel over that for highway fuel. They would be able to design
their hydrotreater from the ground up, while most refiners producing 15
ppm diesel fuel for highway use will be trying to utilize their
existing 500 ppm hydrotreaters, which may not be designed to be
revamped to produce 15 ppm fuel in the most efficient manner.
---------------------------------------------------------------------------
\260\ ``Highway Diesel Progress Review,'' EPA, June 2002,
EPA420-R-02-016.
---------------------------------------------------------------------------
Based on our review of the limited catalyst performance data in the
published literature and the one set of confidential data submitted, we
believe that the projections of the more optimistic vendors are the
most accurate for the 2010 timeframe given this additional leadtime.
For example, the confidential commercial data indicated that five ppm
sulfur levels could be achieved with two-stage hydrotreating at
moderate hydrogen pressure despite the presence of a significant amount
of light cycle oil (LCO). The key factor was the inclusion of a
hydrogenation catalyst in the second stage, which saturated many of the
poly-nuclear, aromatic rings in the diesel fuel, allowing the removal
of sulfur from the most sterically hindered compounds. In addition,
refiners that are able to defer production of 15 ppm highway diesel
fuel through the purchase of credits, as well as refiners producing 15
ppm nonroad in 2010, would have the added benefit of being able to
observe the operation of those hydrotreating units starting up in 2006.
This should allow these refiners to be able to select from the best
technologies which are employed in the highway program.
In addition, a number of alternative technologies are presently
being developed which could produce 15 ppm fuel at lower cost.
ConocoPhillips, for example, has developed a version of their S-Zorb
technology for diesel fuel desulfurization. This technology utilizes a
catalytic adsorbent to remove the sulfur atom from hydrocarbon
molecules. It then sends the sulfur-laden catalyst to a separate
reactor, where the sulfur is removed and the catalyst is restored.
Unipure is developing a process which selectively oxidizes the sulfur
contained in diesel fuel. This process have the advantage that the
sulfur containing compounds which are most difficult to desulfurize via
hydrotreating are quite easily desulfurized via oxidation. Finally,
Linde has developed a method which greatly improves the concentration
of hydrogen on hydrotreating catalysts. This process promises to
greatly reduce the reactor volume necessary to produce 15 ppm diesel
fuel.
These three new technologies are at various stages of development.
This is discussed in more detail in the next section. Due to the
projected ability of these technologies to reduce the cost of meeting a
15 ppm sulfur cap and the leadtime available between now and 2010, we
project that 80% of the new volume of 15 ppm nonroad diesel fuel would
be produced using advanced technologies.
7. Has Technology to Meet a 15 ppm Cap Been Commercially Demonstrated?
EPA just completed a review of refiners' progress in preparing to
produce 15 ppm highway diesel fuel.\261\ The information we obtained
during that review confirm the projections we made in the HD 2007
program--refiners are technically capable of producing 15 ppm sulfur
diesel fuel using extensions of conventional technology and, in fact,
they are moving forward with their plans to comply with the program.
Thus, we believe there are no technological hurdles to producing 15 ppm
diesel fuel.
---------------------------------------------------------------------------
\261\ Ibid.
---------------------------------------------------------------------------
The European Union has also determined that diesel fuel can be
desulfurized to meet a sulfur cap in the range of 10-15 ppm. Europe has
established a 10 ppm sulfur cap on highway diesel fuel, effective in
2009, with plans underway for a 10 ppm sulfur cap for nonroad diesel
fuel soon thereafter. As with our standards, Europe's 10 ppm cap
applies throughout the distribution system. However, fuel tends to be
transported much shorter distances in Europe. Therefore, we believe
that both the 10 and 15 ppm sulfur caps will require refiners to meet
the same 7-8 ppm sulfur target at the refinery gate. Given this, the
European standard will require the same technology as that required in
the U.S. Most European diesel fuel must meet a higher cetane number
specification than U.S. diesel fuel, which causes it to be
predominantly comprised of straight run material. This material is
easier to desulfurize to sub-15 ppm levels using conventional
hydtrotreating technology. In some European countries, nonroad diesel
fuel is the same as heating oil and contains significant amounts of
cracked material. Thus, on average, it should be easier for European
refiners to meet a 10 ppm sulfur cap with their highway diesel fuel
than in the U.S. As the 10 ppm cap is extended to nonroad diesel fuel,
the stringency of the European standard will be much closer to that of
a 15 ppm cap here in the U.S.
We have met with a number of diesel fuel refiners to learn about
their plans to produce 15 ppm highway diesel fuel by the June 2006
program compliance date. Since the 15 ppm diesel fuel sulfur standard
was established based on the use of extensions of conventional diesel
desulfurization technologies, diesel fuel refineries are well
positioned to make firm plans for implementation by 2006. Our review
has found that this is exactly what refiners are doing. We are very
encouraged by the actions some refiners have already taken in terms of
announcing specific plans for low sulfur diesel fuel production. It may
still be early in the process, but virtually all refiners are already
in the stage of planning their approach for compliance. Thus, the
refining industry is where we anticipated it would be at this point in
time. Moreover, some refining companies are ahead of schedule and will
be capable of producing significant quantities of 15 ppm sulfur diesel
fuel as early as next year. Thus, we expect that the capability of
conventional hydrotreating to produce 15 ppm diesel fuel in refinery-
scale quantities will be demonstrated in the U.S. by the end of 2003.
Phillips Petroleum is currently in the process of designing and
constructing a commercial sized S-Zorb unit to produce sub-15 ppm
diesel fuel at their Sweeney, Texas refinery. This plant is scheduled
to begin commercial operation in 2004. This would provide refiners with
roughly 3 years of operating data before they would have to decide
which technology to use to meet the 15 ppm nonroad sulfur cap in 2010.
This should be enough operating experience for most refiners to have
sufficient confidence in this advanced process to include it in their
options for 2010 compliance. Based on information received from
Phillips Petroleum, we estimate that this technology could reduce the
cost of meeting the 15 ppm cap for many refiners by 25 percent.
Linde has also developed a new approach for improving the contact
between hydrogen, diesel fuel and conventional desulfurization
catalysts. Linde projects that their Iso-Therming process could reduce
the hydrotreater volume required to achieve sub-15 ppm sulfur levels by
roughly a factor of 2. Linde has already built a commercial-sized
demonstration unit at a refinery in New Mexico and has been operating
the equipment since September 2002. Thus, refiners would have 4-5 years
of operating data available on this process before they would have to
decide which technology to use to meet the 15 ppm nonroad sulfur cap in
2010. This should be ample operating experience for
[[Page 28428]]
essentially all refiners to include this process in their options for
2010. Based on information received from Linde, we estimate that this
technology could reduce the cost of meeting the 15 ppm cap for many
refiners by 40 percent.
Finally, Unipure Corporation is developing a desulfurization
process which oxidizes the sulfur atom in diesel fuel molecules,
facilitating its removal. This process operates at low temperatures and
ambient pressure, so it avoids the need for costly, thick walled,
pressure vessels and compressors. It also consumes no hydrogen. Thus,
it could be particularly advantageous for refiners who lack an
inexpensive supply of hydrogen (e.g., isolated or smaller refineries
who cannot construct a world scale hydrogen plant based on inexpensive
natural gas). However, the oxidant is very powerful, so specialized,
oxidation resistant materials are needed. Unipure has demonstrated its
process at the pilot plant level, but has yet to build a commercial
sized demonstration unit. However, time still remains for this to be
done before refiners need to make final decisions for their 2010
compliance plans. Thus, while more uncertain than the other two
advanced processes, the Unipure oxidation process could be selected by
a number of refiners to meet the 2010 15 ppm cap. Based on inputs from
Unipure, we estimate that their process could reduce the cost of
meeting the 15 ppm cap for roughly one-fourth of all refineries by 25-
35 percent.
The savings associated with each technology varies with the size,
location and complexity of the refinery. However, on average the Linde
process appears to have the potential reduce the cost of desulfurizing
500 ppm diesel fuel to 15 ppm by 35-40 percent. The savings associated
with the Phillips and Unipure processes appear to be more refinery
specific. For about 25 refineries, the Phillips process appears to have
the potential to reduce these desulfurization costs by 20-40 percent.
The primary advantage of the Unipure process is its lower capital
costs. For about 30 refineries, the Unipure process appears to have the
potential to reduce the capital investment related to produce 15 ppm
fuel from 500 ppm diesel fuel by an average of 40 percent.
8. Availability of Leadtime To Meet the 2010 15 ppm Sulfur Cap
If we promulgate this proposal one year from today, this would
provide refiners and importers with more than six years before they
would have to begin complying with the 15 ppm cap for nonroad diesel
fuel on June 1, 2010. Our leadtime analysis, which is presented in the
draft RIA, projects that 30-39 months are typically needed to design
and construct a diesel fuel hydrotreater.\262\ Thus, refiners would
have about 3 years before they would have to begin detailed design and
construction. This would allow them time to observe the performance of
the hydrotreaters being used to produce 15 ppm highway diesel fuel for
at least one year. While not a full catalyst cycle, any unusual
degradation in catalyst performance over time should be apparent within
the first year. Thus, we project that the 2010 start date would allow
refiners to be quite certain that the designs they select in mid-2007
will perform adequately in 2010.
---------------------------------------------------------------------------
\262\ ``Highway Diesel Progress Review,'' USEPA, EPA420-R-02-
016, June 2002.
---------------------------------------------------------------------------
In addition, we expect that most of the advanced technologies will
be demonstrated on a commercial scale by the end of 2004. Thus,
refiners would have at least two and a half years to observe the
performance of these technologies before having to select a technology
to meet the 2010 15 ppm cap. This should be more than adequate to fully
access the costs and capabilities of these technologies for all but the
most cautious refiners.
9. Feasibility of Distributing Nonroad, Locomotive and Marine Diesel
Fuels That Meet the Proposed Sulfur Standards
There are two considerations with respect to the feasibility of
distributing non-highway diesel fuels meeting the proposed sulfur
standards. The first pertains to whether sulfur contamination can be
adequately managed throughout the distribution system so that fuel
delivered to the end-user does not exceed the specified maximum sulfur
concentration. The second pertains to the physical limitations of the
system to accommodate any additional segregation of product grades.
a. Limiting Sulfur Contamination
With respect to limiting sulfur contamination during distribution,
the physical hardware and distribution practices for non-highway diesel
fuel do not differ significantly from those for highway diesel fuel.
Therefore, we do not anticipate any new issues with respect to limiting
sulfur contamination during the distribution of non-highway fuel that
would not have already been accounted for in distributing highway
diesel fuel. Highway diesel fuel has been required to meet a 500 ppm
sulfur standard since 1993. Thus, we expect that limiting contamination
during the distribution of 500 ppm non-highway diesel engine fuel can
be readily accomplished by industry.
In the highway diesel rule, EPA acknowledged that meeting a 15 ppm
sulfur specification would pose a substantial new challenge to the
distribution system. Refiners, pipelines and terminals would have to
pay careful attention to and eliminate any potential sources of
contamination in the system (e.g., tank bottoms, deal legs in
pipelines, leaking valves, interface cuts, etc.) In addition, bulk
plant operators and delivery truck operators would have to carefully
observe recommended industry practices to limit contamination,
including practices as simple as cleaning out transfer hoses, proper
sequencing of fuel deliveries, and parking on a level surface. Due to
the need to prepare for compliance with the highway diesel program, we
anticipate that issues related to limiting sulfur contamination during
the distribution of 15 ppm nonroad diesel fuel will be resolved well in
advance of the proposed 2010 implementation date for nonroad fuel. We
are not aware of any additional issues that might be raised unique to
nonroad fuel. If anything we anticipate limiting contamination will
become easier as batch sizes are allowed to increase and potential
sources of contamination decrease. We request comment on whether there
are unique considerations regarding the transition to a 15 ppm standard
for nonroad diesel fuel and what actions we should take beyond those
that are already underway in preparation for the 15 ppm highway diesel
program.
b. Potential Need for Additional Product Segregation
As discussed in sub-section B, we have designed the proposed
program to minimize the need for additional product segregation and the
associated feasibility and cost issues associated with it. This
proposal would allow for the fungible distribution of 500 ppm highway
and 500 ppm NRLM diesel fuel in 2007, and 15 ppm highway and 15 ppm
nonroad diesel fuel in 2010, up until the point where NRLM or nonroad
fuel must be dyed for IRS excise tax purposes. Heating oil would be
required to be segregated as a separate pool beginning in 2007 through
the use of a new marker, and locomotive and marine fuel by use of the
same marker beginning in 2010. With this program design, we believe we
have eliminated any potential feasibility issues associated with the
need for product segregation. This is not to say that steps will not
have to be taken. We have
[[Page 28429]]
identified only a single instance where it seems likely that the
adoption of this proposal would result in entities in the distribution
system choosing to add new tankage due to new product segregation. Bulk
plants in areas of the country where heating oil is expected to remain
in the market will have to decide whether to add tankage to distribute
both heating oil and 500 ppm NRLM fuel. In all other cases we
anticipate segments of the distribution system will choose to avoid any
fuel segregation costs by limiting the range of sulfur grades they
choose to carry, just as they do today. Regardless, however, the costs
and impacts of these choices are small. We request comment on this
assessment. A more detailed explanation of this assessment can be found
in Chapter 5.6 of the draft RIA.
G. What Are the Potential Impacts of the 15 ppm Sulfur Diesel Program
on Lubricity and Other Fuel Properties?
1. What Is Lubricity and Why Might it Be a Concern?
Engine manufacturers and owner/operators depend on diesel fuel
lubricity properties to lubricate and protect moving parts within fuel
pumps and injection systems for reliable performance. Unit injector
systems and in-line pumps, commonly used in diesel engines, are
actuated by cams lubricated with crankcase oil, and have minimal
sensitivity to fuel lubricity. However, rotary and distributor type
pumps, commonly used in light and medium-duty diesel engines, are
completely fuel lubricated, resulting in high sensitivity to fuel
lubricity. The types of fuel pumps and injection systems used in
nonroad diesel engines are the same as those used in highway diesel
vehicles. Consequently, nonroad and highway diesel engines share the
same need for adequate fuel lubricity to maintain fuel pump and
injection system durability.
Diesel fuel lubricity concerns were first highlighted for private
and commercial vehicles during the initial implementation of the
Federal 500 ppm sulfur highway diesel program and the state of
California's diesel program. The Department of Defense (DoD) also has a
longstanding concern regarding the lubricity of distillate fuels used
in its equipment as evidenced by the implementation of its own fuel
lubricity improver performance specification in 1989.\263\ The diesel
fuel requirements in the state of California differed from the federal
requirements by substantially restricting the content of diesel fuel
requires more severe hydrotreating than reducing the sulfur content to
meet a 500 ppm standard.\264\ Consequently, concerns regarding diesel
fuel lubricity have primarily been associated with California diesel
fuel and some California refiners treat their diesel fuel with a
lubricity additive as needed. Outside of California, hydrotreating to
meet the current 500 ppm sulfur specification does not typically result
in a substantial reduction of lubricity. Diesel fuels outside of
California seldom require the use of a lubricity additive. Therefore,
we anticipate only a marginal increase in the use of lubricity
additives in NRLM diesel fuel meeting the proposed 500 ppm sulfur
standard for 2007.\265\ This proposal would require diesel fuel used in
nonroad engines to meet a 15 ppm sulfur standard in 2010. Based on the
following discussion, we believe that the increase in the use of
lubricity additives in 15 ppm nonroad diesel fuel would be the same as
that estimated for 15 ppm highway diesel fuel.
---------------------------------------------------------------------------
\263\ DoD Performance Specification, Inhibitor, Corrosion/
Lubricity Improver, Fuel Soluble, , MIL-PRF-25017F, 10 November
1997, Superseding MIL-I-25017E, 15 June 1989.
\264\ Chevron Products Diesel Fuel Technical Review provides a
discussion of the impacts on fuel lubricity of current diesel fuel
compositional requirements in California versus the rest of the
nation. http://www.chevron.com/prodserv/fuels/bulletin/diesel/
l2%5F7%5F2%5Frf.htm.
\265\ The cost from the increased use of lubricity additives in
500 ppm NRLM diesel fuel in 2007 and in 15 ppm nonroad diesel fuel
in 2010 is discussed in section V of today's preamble.
---------------------------------------------------------------------------
The state of California currently requires the same standards for
diesel fuel used in nonroad equipment as in highway equipment. Outside
of California, highway diesel fuel is often used in nonroad equipment
when logistical constraints or market influences in the fuel
distribution system limit the availability of high sulfur fuel. Thus,
for nearly a decade nonroad equipment has been using federal 500 ppm
sulfur diesel fuel and California diesel fuel, some of which may have
been treated with lubricity additives. During this time, there has been
no indication that the level of diesel lubricity needed for fuel used
in nonroad engines differs substantially from the level needed for fuel
used in highway diesel engines.
Blending small amounts of lubricity-enhancing additives increases
the lubricity of poor-lubricity fuels to acceptable levels. These
additives are available in today's market, are effective, and are in
widespread use around the world. Among the available additives,
biodiesel has been suggested as one potential means for increasing the
lubricity of conventional diesel fuel. Indications are that low
concentrations of biodiesel would be sufficient to raise the lubricity
to acceptable levels.
Considerable research remains to be performed to better understand
which fuel components are most responsible for lubricity. Consequently,
it is unclear whether and to what degree the proposed sulfur standards
for non-highway diesel engine fuel will impact fuel lubricity.
Nevertheless, there is evidence that the typical process used to remove
sulfur from diesel fuel--hydrotreating--can impact lubricity depending
on the severity of the treatment process and characteristics of the
crude. We expect that hydrotreating will be the predominant process
used to reduce the sulfur content of non-highway diesel engine fuel to
meet the 500 ppm sulfur standard during the first step of the proposed
program. The highway diesel program projected that hydrotreating would
be the process most frequently used to meet the 15 ppm sulfur standard
for highway diesel fuel. The 2010 implementation date for the proposed
15 ppm standard for nonroad diesel fuel would allow the use of new
technologies to remove sulfur from fuel.\266\ These new technologies
have less of a tendency to affect other fuel properties than does
hydrotreating.
---------------------------------------------------------------------------
\266\ See section IV.F for a discussion of which desulfurization
processes we expect will be used to meet the 15 ppm standard for
nonroad diesel fuel.
---------------------------------------------------------------------------
Based on our comparison of the blendstocks and processes used to
manufacture non-highway diesel fuels, we believe that the potential
decrease in the lubricity of these fuels from hydrotreating that might
result from the proposed sulfur standards should be approximately the
same as that experienced in desulfurizing highway diesel fuel.\267\ To
provide a conservative, high cost estimate, we assumed that the
potential impact on fuel lubricity from the use of the new
desulfurization processes would be the same as that experienced when
hydrotreating diesel fuel to meet a 15 ppm sulfur standard. We request
comment on the potential impact of these new desulfurization
technologies on lubricity (as well as other fuel properties) that might
help us to improve our estimate of the potential impacts of this
proposal on fuel properties other than sulfur. Given that the
requirements for fuel lubricity in highway and non-highway engines are
the same, and the potential decrease in lubricity from desulfurization
of non-highway diesel engine would be no greater than that experienced
in desulfurizing highway diesel fuel, we
[[Page 28430]]
estimate that the potential need for lubricity additives in non-highway
diesel engine fuel under this proposal would be the same as that for
highway diesel fuel meeting the same sulfur standard.
---------------------------------------------------------------------------
\267\ See chapter 5 of the RIA for a discussion of the potential
impacts on fuel lubricity of this proposal.
---------------------------------------------------------------------------
2. A Voluntary Approach on Lubricity
In the United States, there is no government or industry standard
for diesel fuel lubricity. Therefore, specifications for lubricity are
determined by the market. Since the beginning of the 500 ppm sulfur
highway diesel program in 1993, refiners, engine manufacturers, engine
component manufacturers, and the military have been working with the
American Society for Testing and Materials (ASTM) to develop protocols
and standards for diesel fuel lubricity in its D-975 specifications for
diesel fuel. ASTM is working towards a single lubricity specification
that would be applicable to all diesel fuel used in any type of engine.
Although ASTM has not yet adopted specific protocols and standards,
refiners that supply the U.S. market have been treating diesel fuel
with lubricity additives on a batch to batch basis, when poor lubricity
fuel is expected. Other examples include the U.S. military, Sweden, and
Canada. The U.S. military has found that the traditional corrosion
inhibitor additives used in its fuels have been highly effective in
reducing fuel system component wear. Since 1991, the use of lubricity
additives in Sweden's 10 ppm sulfur Class I fuel and 50 ppm sulfur
Class II fuel has resulted in acceptable equipment durability.\268\
Since 1997, Canada has required that its 500 ppm sulfur diesel fuel not
meeting a minimum lubricity be treated with lubricity additives.
---------------------------------------------------------------------------
\268\ Letter from L. Erlandsson, MTC AB, to Michael P. Walsh,
dated October 16, 2000. EPA air docket A-99-06, docket item IV-G-42.
---------------------------------------------------------------------------
The potential need for lubricity additives in diesel fuel meeting a
15 ppm sulfur specification was evaluated during the development of
EPA's highway diesel rule. In response to the proposed highway diesel
rule, all comments submitted regarding lubricity either stated or
implied that the proposed sulfur standard of 15 ppm would likely cause
the refined fuel to have lubricity characteristics that would be
inadequate to protect fuel injection equipment, and that mitigation
measures such as lubricity additives would be necessary. However, the
commenters suggested varied approaches for addressing lubricity. For
example, some suggested that we need to establish a lubricity
requirement by regulation while others suggested that the current
voluntary, market based system would be adequate. The Department of
Defense recommended that we encourage the industry (ASTM) to adopt
lubricity protocols and standards before the 2006 implementation date
of the 15 ppm sulfur standard for highway diesel fuel.
The final highway diesel rule did not establish a lubricity
standard for highway diesel fuel. We believe the issues related to the
need for diesel lubricity in fuel used in non-highway diesel engines
are substantially the same as those related to the need for diesel
lubricity for highway engines. Consequently, we expect the same
industry-based voluntary approach to ensuring adequate lubricity in
non-highway diesel fuels that we recognized for highway diesel fuel. We
believe the best approach is to allow the market to address the
lubricity issue in the most economical manner, while avoiding an
additional regulatory scheme. A voluntary approach should provide
adequate customer protection from engine failures due to low lubricity,
while providing the maximum flexibility for the industry. This approach
would be a continuation of current industry practices for diesel fuel
produced to meet the current federal and California 500 ppm sulfur
highway diesel fuel specifications, and benefits from the considerable
experience gained since 1993. It would also include any new
specifications and test procedures that we expect would be adopted by
the American Society for Testing and Materials (ASTM) regarding
lubricity of NRLM diesel fuel quality.
Regardless, this is an issue that will be resolved to meet the
demands of the highway diesel market, and whatever resolution is
reached for highway diesel fuel could be applied to non-highway diesel
engine fuel with sufficient advance notice. We are continuing to
participate in the ASTM Diesel Fuel Lubricity Task Force \269\ and will
assist their efforts to finalize a lubricity standard in whatever means
possible. We are hopeful that ASTM can reach a consensus early this
summer at the next meeting of the ASTM's Lubricity Task Force. We
request comment on what actio ns EPA should take to ensure adequate
lubricity of non-highway diesel engine fuel beyond those already
underway for highway diesel fuel.
---------------------------------------------------------------------------
\269\ ASTM sub committee D02.E0.
---------------------------------------------------------------------------
3. What Other Impact Would Today's Actions Have on the Performance of
Diesel and Other Fuels?
We do not expect that the proposed fuel program would have any
negative impacts on the performance of diesel engines in the existing
fleet which would use the fuels regulated today. In the early 1990's,
California lowered the maximum allowable level of sulfur content of
highway and nonroad diesel fuel to 500 ppm, and at the same time
California significantly lowered the aromatic content of diesel fuel.
California required a cap on total aromatics of 10 percent by volume,
while the in-use average at the time was on the order of 35 percent.
The lowering of the total aromatic content resulted in some problems
with leaks from the fuel pump O-ring seals in some diesel engines due
to a change specifically in the polynuclear aromatics content (PNA). In
the process of meeting California's 10 percent total aromatic content
requirement, the end result typically lowered PNA's from approximately
10-15 percent by volume to near-zero. In the early 1990's, some diesel
engine manufacturers used a certain material (Nitrile) for O-rings in
diesel fuel pumps. The Nitrile seals were found to be susceptible to
leakage with the use of diesel fuel with very low PNA content.
Normally, the PNA in the fuel penetrated the Nitrile material and cause
it to swell, thereby providing a seal with the throttle shaft. When
very low PNA fuel is used after conventional fuel has been used, the
PNA already in the swelled O-ring would leach out into the very low PNA
fuel. Subsequently, the Nitrile O-ring would shrink and pull away, thus
causing leaks, or the stress on the O-ring during the leaching process
would cause it to crack and leak. Not all 500 ppm sulfur fuels caused
this problem, because the amount and type of aromatics varied, and the
in-use seal problems were focused in California due to the 10 percent
aromatic requirements and the resulting very low PNA content. This was
not a wide-spread issue for the rest of the U.S. where highway diesel
fuel also had a 500ppm sulfur cap because the federal requirements did
not include a lower aromatic cap. While the process of lowering sulfur
levels to 500ppm does lower PNA, it does not achieve the near-zero
levels seen in California. Since the 1990's, diesel engine
manufacturers have switched to alternative materials (such as Viton),
which do not experience leakage. We believe that no issues with leaking
fuel pump O-rings would occur with the changes in diesel fuel sulfur
levels
[[Page 28431]]
contained in this proposal (both the 500 ppm requirement in 2008 and
the 15 ppm requirement in 2010) because while we do believe PNA content
will be reduced, we are not predicting it will achieve the near-zero
level experienced in California.
We expect that this proposal would have no negative impacts on
other fuels, such as jet fuel or heating oil. We do expect that the
sulfur levels of heating oil would decrease because of this proposal.
Beginning in mid-2007, we expect that controlling NRLM diesel fuel to
500 ppm would lead many pipelines to discontinue carrying high sulfur
heating oil as a separate grade. In areas served by these pipelines,
heating oil users would likely switch to 500 ppm diesel fuel. This
would reduce emissions of sulfur dioxide and sulfate PM from furnaces
and boilers fueled with heating oil. The primary exception to this
would likely be the Northeast and some areas of the Pacific Northwest,
where a distinct higher sulfur heating oil would still be distributed
as a separate fuel. Also, we expect that a small volume of high sulfur
distillate fuel would be created during distribution from the mixing of
low sulfur diesel fuels and higher sulfur fuels, such as jet fuel in
the pipeline interface. Such high sulfur distillate would likely be
sold by the terminal as high sulfur heating oil or reprocessed by
transmix processors.
H. Refinery Air Permitting
Prior to making diesel desulfurization changes, some refineries may
be required to obtain a preconstruction permit, under the New Source
Review (NSR) program, from the applicable state/local air pollution
control agency.\270\ We believe that the proposed program provides
sufficient lead time for refiners to obtain any necessary NSR permits
well in advance of the compliance date.
---------------------------------------------------------------------------
\270\ Hydrotreating diesel fuel involves the use of process
heaters, which have the potential to emit pollutants associated with
combustion, such as NOX, PM, CO and SO3. In
addition, reconfiguring refinery processes to add desulfurization
equipment could increase fugitive VOC emissions. The emissions
increases associated with diesel desulfurization would vary widely
from refinery to refinery, depending on many source-specific
factors, such as crude oil supply, refinery configuration, type of
desulfurization technology, amount of diesel fuel produced, and type
of fuel used to fire the process heaters.
---------------------------------------------------------------------------
Given that today's diesel sulfur program would provide roughly
three years of lead time before the 500 ppm standard would take effect,
we believe refiners would have time to obtain any necessary
preconstruction permits. Nevertheless, we believe it is reasonable to
continue our efforts under the Tier 2 and highway diesel fuel programs,
to help states in facilitating the issuance of permits under the NRLM
diesel sulfur program. For example, the guidance on Best Available
Control Technology (BACT) and Lowest Achievable Emission Rate (LAER)
control technology that was developed for the gasoline sulfur program
should have application for diesel desulfurization (highway and NRLM)
projects as well. Similarly, we believe the concept of EPA permit teams
for gasoline sulfur projects could readily be extended to permits
related to diesel projects as well. These teams, as needed, would track
the overall progress of permit issuance and would be available to
assist state/local permitting authorities, refineries and the public
upon request to resolve site-specific permitting questions. In
addition, these teams would be available, as necessary, to assist in
resolving case specific issues to ensure timely issuance of permits.
Finally, to facilitate the processing of permits, we encourage
refineries to begin discussions with permitting agencies and to submit
permit applications as early as possible.
V. Program Costs and Benefits
In this section, we present the projected cost impacts and cost
effectiveness of the proposed nonroad Tier 4 emission standards and
low-sulfur fuel requirement. We also present a benefit-cost analysis
and an economic impact analysis. The benefit-cost analysis explores the
net yearly economic benefits to society of the reduction in mobile
source emissions likely to be achieved by this rulemaking. The economic
impact analysis explores how the costs of the rule will likely be
shared across the manufacturers and users of the engines, equipment and
fuel that would be affected by the standards.
The results detailed below show that this rule would be highly
beneficial to society, with net present value benefits through 2030 of
$550 billion, compared to a net present value of social cost of only
about $16.5 billion (net present values in the year 2004). The impact
of these costs on society should be minimal, with the prices of goods
and services produced using equipment and fuel affected by the proposal
being expected to increase about 0.02 percent.
Further information on these and other aspects of the economic
impacts of our proposal are summarized in the following sections and
are presented in more detail in the Draft RIA for this rulemaking. We
invite the reader to comment on all aspects of these analyses,
including our methodology and the assumptions and data that underlie
our analysis.
A. Refining and Distribution Costs
As described above, the fuel-related requirements associated with
this proposed rule would be implemented in two steps. Nonroad,
locomotive and marine diesel fuel would be subject to a 500 ppm sulfur
cap beginning June 1, 2007, while nonroad diesel fuel would be subject
to a 15 ppm sulfur cap beginning June 1, 2010. Meeting these standards
would generally require refiners adding hydrotreating equipment and
possibly new or expanded hydrogen and sulfur plants in their refineries
for desulfurizing their nonroad diesel fuel and dispensing of the
removed sulfur. Using information provided by vendors of
desulfurization equipment and through discussions with distributors of
nonroad diesel fuel, we estimated the desulfurization and associated
distribution and additive cost for complying with this two step
desulfurization program. Except for the costs presented at the end of
this section, the costs below reflect a fully phased in fuels program
without the proposed small refiner exemption. Costs are in 2002
dollars. We request comment on the cost estimates presented below and
the methodologies used to develop them. You can refer to the Draft RIA
for details.
The cost to provide nonroad, locomotive and marine diesel fuel
under the proposed fuel program is summarized in Table V-A-1 below. The
costs shown (and all of the costs described in the rest of this
section) only apply to the roughly 65 percent of current nonroad,
locomotive and marine diesel fuel that contains more than 500 ppm
sulfur (hereafter referred to as the affected volume). We estimate that
the other 35 percent of this fuel is actually fuel certified to the
highway diesel fuel standards and project that this will continue.
Thus, the proposed fuel program would not affect this fuel and no
additional costs would be incurred by its refiners or distributors. The
costs and benefits of desulfurizing this highway fuel which spills over
into the non-highway markets was already included in EPA's 2007 highway
diesel fuel rule.
[[Page 28432]]
Table V-A-1.--Increased Cost of Providing Nonroad, Locomotive and Marine Diesel Fuel
----------------------------------------------------------------------------------------------------------------
Cents per gallon of affected fuel Affected fuel
------------------------------------------------ volume
(million
Refining Lubricity and Total gallons/year)
distribution a
----------------------------------------------------------------------------------------------------------------
Step One--500 ppm NRLM diesel fuel.............. 2.2 0.3 2.5 9,504
Step Two--5 ppm Nonroad diesel fuel............. 4.4 0.4 4.8 7,803
Step Two--500 ppm Locomotive and Marine diesel 2.2 b 0.2 2.4 4,093
fuel...........................................
----------------------------------------------------------------------------------------------------------------
Notes:
a 2008 for Step One (without consideration of small refiner provisions), 2015 for Step Two.
b 0.4 cent per gallon from mid-2010 to mid-2014 due to need for marker.
The majority of the fuel-related cost of the proposal is refining-
related. These costs include required capital investments amortized at
7 percent per annum before taxes. The derivation of these costs is
discussed in more detail below and in the Draft RIA. We request comment
on the estimated cost of meeting the 15 ppm and 500 ppm sulfur caps.
We also project that the increased cost of refining and
distributing 15 ppm and 500 ppm fuel would be substantially offset by
reductions in maintenance costs. These savings would apply to all
diesel engines in the field, not just new engines. Refer to section V.
B for a more complete discussion on the projected maintenance savings
associated with lower sulfur fuels.
1. Refining Costs
Our process for estimating the refining costs associated with the
proposed fuel program consisted of four steps. One, we estimated the
volume of 500 and 15 ppm nonroad, locomotive and marine diesel fuel
which had to be produced in each PADD \271\ in each phase of the
program. This step utilized diesel fuel and heating oil use estimates
from the Energy Information Administration's (EIA) Fuel Oil and
Kerosene Survey for 2000, shipments of diesel fuel between PADDs,
projected loss of 15 and 500 ppm volume due to contamination during
distribution and small refiner provisions. This nonroad diesel fuel
consumption in 2000 is lower than that inherent in the emission
estimates described above, which are based directly on the results of
EPA's NONROAD emission model. We are investigating ways to make the two
estimates more consistent.
---------------------------------------------------------------------------
\271\ Petroleum Administrative for Defense Districts.
---------------------------------------------------------------------------
Growth in distillate fuel use off this year 2000 base was estimated
using projections from EIA's Annual Energy Outlook, with one exception.
This exception was that the growth in nonroad diesel fuel use was taken
from EPA's NONROAD emission model (roughly three percent per year), as
opposed to EIA's projected growth of roughly one percent per year. The
higher growth rate is consistent with that inherent in the emission
estimates described above.
Refinery production of low and high sulfur distillate fuel in the
year 2000 was based on actual reports provided to EIA by all U.S.
refiners and importers. Refinery production of low and high sulfur
distillate fuel was assumed to grow at the same rate as consumption of
the two types of fuel, respectively. These rates were roughly three
percent and one and a half percent for low and high sulfur distillate
fuel production, respectively. The specific volumes of highway,
nonroad, locomotive, and marine diesel fuel by calendar year are
presented in chapter 7 of the Draft RIA.
Two, we estimated the cost for each refinery to desulfurize its
high sulfur fuel to 500 and 15 ppm. This was based on their historical
production volume of high sulfur diesel fuel and estimates of the
composition of this fuel (straight run, light cycle oil, etc.).\272\ We
also considered whether these refineries would be modifying or building
hydrotreating capacity in order to meet the 15 ppm highway cap.
---------------------------------------------------------------------------
\272\ The composition of nonroad diesel fuel in each PADD was
based on a survey conducted by API and NPRA in 1996. Crude oils
processed by domestic refiners have been becoming heavier over time,
necessitating greater use of coking and hydrocracking to convert the
heavy material into lighter, saleable products. Thus, the
contributions of coker and hydrocracked distillate to the overall
distillate pool are rising. Coker distillate is somewhat more
difficult to desulfurize than average distillate, but hydrocracked
distillate is much easier to desulfurize. Overall, this trend could
increase projected desulfurization costs slightly. We plan to update
these compositions to reflect trends in crude oil quality and
refinery configuration in our analysis for the final rule to the
extent that more recent data allow.
---------------------------------------------------------------------------
Three, we estimated which refineries would find it difficult to
market all of their current high sulfur diesel fuel as heating oil, due
to their location relative to major pipelines and the size of the
heating oil market in their area. Those not located in major heating
oil markets and not connected to pipelines serving these areas were
projected to have to meet the 500 ppm cap in 2007.
Four, we determined the additional refineries which would produce
500 ppm and 15 ppm fuel to satisfy demand during each phase of the fuel
program. Refineries projected to have the lowest compliance costs in
each PADD were projected to produce the lower sulfur fuels until demand
was met. PADD 3 refineries were allowed to ship low sulfur fuel to the
Northeast, but no other inter-PADD transfers were assumed. Imports of
500 ppm highway diesel fuel were assumed to increase at the rate of
highway diesel fuel consumption and be converted to 15 ppm diesel fuel,
80 percent in 2006 and 100 percent in 2010. Imports of high sulfur
distillate fuel were assumed to increase at the rate of high sulfur
distillate fuel consumption, but were assumed to remain entirely high
sulfur heating oil even after today's NRLM fuel proposal. In other
words, all 15 ppm and 500 ppm NRLM fuel produced under this proposal
was assumed to be produced by domestic refineries. This assumption
increased the projected costs of the proposal described above more than
would have been the case had we assumed that domestic production and
imports of high sulfur distillate fuel would each keep their respective
shares of the NRLM diesel fuel and heating oil markets in response to
this proposal. The relative costs of producing 15 ppm nonroad diesel
fuel by domestic and overseas refiners is discussed further in section
V.A.6. below.
With the onset of a 2007 500 ppm sulfur cap for nonroad, locomotive
and marine diesel fuel, we project that the market for high sulfur
diesel fuel and heating oil would become so small that high sulfur fuel
would no longer be shipped through common carrier pipelines in most
areas. The prime exception to this would be the Northeast, where the
heating oil market is very large. Thus, refiners located in the
Northeast and those along the major pipelines serving the Northeast,
namely the Colonial and Plantation pipelines, could continue to produce
high sulfur
[[Page 28433]]
heating oil. Other refineries would shift the production of high sulfur
diesel fuel and heating oil to the 500 ppm NRLM market. The second
exception would be refiners granted special provisions due to the small
size of their business (i.e., SBREFA refiners) or economic hardship, as
discussed in section IV above. The high sulfur distillate production
levels of these refineries is small enough that they can sell into more
local nonroad, locomotive and marine markets or the heating oil market
without using pipelines and so they could continue to produce high
sulfur distillate.
Based on refinery distillate production data from the Energy
Information Administration (EIA), there are 122 refineries currently
producing highway diesel fuel and 105 refineries producing high sulfur
diesel fuel or heating oil. Using the methodology described above,
absent this proposal, we project that roughly 114 refineries will
invest in additional desulfurization equipment to produce 15 ppm
highway diesel fuel; 74 refineries in 2006 and 40 in 2010.\273\ These
114 refineries include 109 of the 122 refineries which currently
produce highway diesel fuel, plus 5 refineries which currently only
produce high sulfur distillate fuel today. Again absent the proposed
NRLM diesel fuel program, we project that roughly 13 refineries
currently producing highway diesel fuel will shift to producing high
sulfur distillate fuel. This would leave a total of 113 refineries
still producing high sulfur distillate after full implementation of the
2007 highway diesel fuel program.
---------------------------------------------------------------------------
\273\ These (and the subsequent) estimates of the number of
refineries investing in new equipment to produce diesel fuels of
various sulfur levels should be understood as rough estimates which
assist us in projecting costs and other impacts related to this
proposal. They are most reasonable when evaluating the total number
of refineries investing in a particular year or region. We are not
indicating that we believe that we can predict which specific
refineries would invest in desulfurization equipment in response to
this proposal.
---------------------------------------------------------------------------
The number of these 113 domestic refineries expected to produce
either 500 ppm of 15 ppm NRLM diesel fuel in response to this proposal
is summarized in Table V-A-2.
Table V-A-2 Refineries Projected to Produce NRLM Diesel Fuel Under This Proposal
----------------------------------------------------------------------------------------------------------------
500 ppm diesel fuel 15 ppm diesel fuel
---------------------------------------------------------------
Year of Program Small Small
All refineries refineries All refineries refineries
----------------------------------------------------------------------------------------------------------------
2007-2010....................................... 42 0 0 0
2010-2014....................................... 37 19 25 0
2014+........................................... 25 12 37 7
----------------------------------------------------------------------------------------------------------------
As shown in this table, we project that 42 of the 113 refineries
currently producing some high sulfur distillate would desulfurize their
high sulfur diesel fuel in response to the proposed 500 ppm standard in
2007. The remainder would continue producing either high sulfur NRLM
diesel fuel under the proposed small refiner provisions, or high sulfur
heating oil. As explained in section IV.F, we project that these
refiners would use conventional hydrotreating technology to meet this
standard. Of these 42 refineries, we project that 32 would build new
hydrotreaters to meet the 500 ppm sulfur cap. We project that three of
the remaining ten refineries would be able to meet the 500 ppm cap with
their existing hydrotreater which is currently being used to produce
highway diesel fuel. These three refineries are projected to build a
new hydrotreater to produce 15 ppm highway diesel fuel in 2006, so
their existing highway fuel hydrotreater could process their current
high sulfur diesel fuel. The remaining seven refineries currently
produce relatively small amounts of high sulfur diesel fuel compared to
their highway diesel fuel production. We project that these refiners
would be able to economically revamp their existing highway
hydrotreater to process their non-highway diesel fuel.
We project that the capital cost involved to meet the 2007 500 ppm
sulfur cap would be $600 million, or $9.7 million per refinery building
a new hydrotreater. The bulk of this capital would be invested in 2007
($500 million), with the remainder being invested in 2010.\274\
Operating costs would be about $3 million per year for the average
refinery. We request comment on the number of refiners who would need
to build new equipment to meet the 500 ppm sulfur cap, the capital cost
for this new equipment and the cost of operating this equipment.
---------------------------------------------------------------------------
\274\ Some refineries would be able to delay production of 500
ppm NRLM fuel until 2010 due to the proposed small refiner
provisions. Likewise, some refineries would be able to delay
production of 15 ppm nonroad diesel fuel until 2014.
---------------------------------------------------------------------------
Starting in mid-2010, we project that 25 refineries would add or
revamp equipment to meet the 15 ppm cap on nonroad diesel fuel, while
20 refineries (nearly all of them small refiners) would add or revamp
equipment to produce 500 ppm nonroad or locomotive and marine diesel
fuel. Finally, an additional 12 refineries (again nearly all of them
small refiners) would begin producing 15 ppm nonroad diesel fuel in
2014.
We project that 80 percent of the 15 ppm nonroad diesel fuel volume
would be desulfurized by advanced technologies, while the remaining 20
percent would be desulfurized by conventional hydrotreaters. Since the
bulk of the hydrotreating capacity being used to meet the 2007 500 ppm
standard for NRLM diesel fuel would have just been built in 2007 or
2010, we expect that it would have been designed to facilitate further
processing to 15 ppm sulfur and the added 15 ppm facilities would be
revamps. However, those refiners who used their existing highway diesel
fuel hydrotreaters to meet the proposed 500 ppm cap in 2007 would
likely have to construct new equipment in 2010 or 2014 to meet the 15
ppm cap on nonroad diesel fuel, since these hydrotreaters could not be
revamped in 2006 to produce 15 ppm highway diesel fuel. When the
proposed NRLM diesel fuel program would be fully implemented in 2014,
roughly 51 refineries are still projected to produce high sulfur
heating oil and thus, would not face any refining costs related to this
proposal.
Our projection that 80 percent of refineries would utilize some
form of advanced technology to meet the proposed 15 ppm nonroad fuel
sulfur cap is based on the fact that this 15 ppm cap would follow the
production of 15 ppm highway diesel fuel by four years. Several firms
are expending significant research and development resources to bring
such advanced technologies to the market for the highway diesel fuel
[[Page 28434]]
program. We developed cost estimates for two such technologies: Linde
Iso-Therming and Phillips S-Zorb. The development of cost estimates for
these two advanced technologies, as well as conventional hydrotreating,
is described in detail in Chapter 7 of the Draft RIA. We request
comment on the potential viability and cost savings associated with
advanced desulfurization technologies, particularly in the 2010
timeframe.
The total capital cost of new equipment and revamps related to the
proposed 2010 sulfur standard would be $640 million, or $17 million per
refinery adding or revamping equipment. Total operating costs would be
about $5 million per year for the average refinery. The total refining
cost, including the amortized cost of capital, would be 4.4 cents per
gallon of new 15 ppm nonroad fuel. This cost is relative to the cost of
producing high sulfur fuel today, and includes the cost of meeting the
500 ppm standard beginning in 2007. We request comment on the number of
refiners who would need to build new equipment to meet the 15 ppm
sulfur cap, the capital cost for this new equipment and the cost of
operating this equipment. The average cost of continuing to meet the
500 ppm standard for locomotive and marine fuel would continue at 2.2
cents per gallon.
The above costs reflect national averages for the fully phased in
program for each control step. Some refiners would face lower costs
while others would face higher costs. Excluding small refiners because
they are able to take advantage of the proposed small refiner
provisions, the average refining costs by refining region are shown in
the table below. Combined costs are shown for PADDs 1 and 3 because of
the large volume of diesel fuel which is shipped from PADD 3 to PADD 1.
Table V-A-3.--Average Refining Costs by Region (cents per gallon)
------------------------------------------------------------------------
2007 500 ppm Cap 2010 15 ppm Cap
------------------------------------------------------------------------
PADDs 1 and 3............... 1.4 2.6
PADD 2...................... 2.9 5.7
PADD 4...................... 4.0 8.5
PADD 5...................... 2.6 5.4
Nationwide.................. 2.2 4.4
------------------------------------------------------------------------
We request comment on the range of estimated refining costs for the
various regions for both the proposed 500 and 15 ppm sulfur caps.
2. Cost of Lubricity Additives
Hydrotreating diesel fuel tends to reduce the natural lubricating
quality of diesel fuel, which is necessary for the proper functioning
of certain fuel system components. There are a variety of fuel
additives which can be used to restore diesel fuel's lubricating
quality. These additives are currently used to some extent in highway
diesel fuel. We expect that the need for lubricity additives that would
result from the proposed 500 ppm sulfur standard for off-highway diesel
engine fuel would be similar to that for highway diesel fuel meeting
the current 500 ppm sulfur cap standard.\275\ Industry experience
indicates that the vast majority of highway diesel fuel meeting the
current 500 ppm sulfur cap does not need lubricity additives.
Therefore, we expect that the great majority of off-highway diesel
engine fuel meeting the proposed 500 ppm sulfur standard would also not
need lubricity additives. In estimating lubricity additive costs for
500 ppm diesel fuel, we assumed that fuel suppliers would use the same
additives at the same concentration as we projected would be used in 15
ppm highway diesel fuel. Based on our analysis of this issue for the
2007 highway diesel fuel program, the cost per gallon of the lubricity
additive is about 0.2 cent. This level of use is likely conservative,
as the amount of lubricity additive needed increases substantially as
diesel fuel is desulfurized to lower levels. We also project that only
5 percent of all 500 ppm NRLM diesel fuel would require the use of a
lubricity additive. Thus, we project that the cost of additional
lubricity additives for the affected 500 ppm NRLM diesel fuel would be
0.01 cent per gallon. See the Draft RIA for more details on the issue
of lubricity additives.
---------------------------------------------------------------------------
\275\ Please refer to section IV in today's preamble for
additional discussion regarding our projections of the potential
impact on fuel lubricity of this proposed rule.
---------------------------------------------------------------------------
We project that all nonroad diesel fuel meeting a 15 ppm cap would
require treatment with lubricity additives. Thus, the projected cost
would be 0.2 cent per affected gallon of 15 ppm nonroad diesel fuel.
3. Distribution Costs
The proposed fuel program is projected to impact distribution costs
in three ways. One, we project that more diesel fuel would have to be
distributed under the proposal than without it. This is due to the fact
that some of the desulfurization processes reduce the fuel's volumetric
energy density during processing. Total energy is not lost during
processing, as the total volume of fuel is increased. However, a
greater volume of fuel must be consumed in the engine to produce the
same amount of power. We assumed that the current cost of distributing
diesel fuel of 10 cents per gallon (see Draft RIA for further details)
would stay constant (i.e., a 1 percent increase in the amount of fuel
distributed would increase total distribution costs by 1 percent).
We project that desulfurizing diesel fuel to 500 ppm would reduce
volumetric energy content by 0.7 percent. This would increase the cost
of distributing fuel by 0.07 cent per gallon. We project that
desulfurizing diesel fuel to 15 ppm would reduce volumetric energy
content by an additional 0.35 percent. This would increase the cost of
distributing fuel by an additional 0.04 cent per gallon, or a total
cost of 0.11 cent per gallon of affected 15 ppm nonroad diesel fuel.
Two, while this proposal minimizes the segregation of similar
fuels, some additional segregation of products in the distribution
system would still be required. The proposed allowance that highway and
off-highway diesel engine fuel meeting the same sulfur specification
can be shipped fungibly until it leaves the terminal obviates the need
for additional storage tankage in this segment of the distribution
system.\276\ This proposal would also allow 500 ppm NRLM diesel fuel to
be mixed with high-sulfur NRLM diesel fuel once the fuels are dyed to
meet IRS requirements. This provision would ease the last part of the
distribution of high-sulfur NRLM diesel fuel.
---------------------------------------------------------------------------
\276\ Including the refinery, pipeline, marine tanker, and barge
segments of the distribution system.
---------------------------------------------------------------------------
However, we expect that the implementation of the proposed 500 ppm
standard for NRLM diesel fuel in 2007 would compel some bulk plants in
those parts of the country still
[[Page 28435]]
distributing heating oil as a separate fuel grade to install a second
diesel storage tank to handle this 500 ppm nonroad fuel. These bulk
plants currently handle only high-sulfur fuel and hence would need a
second tank to continue their current practice of selling fuel into the
heating oil market in the winter and into the nonroad market in the
summer.\277\ We believe that some of these bulk plants would convert
their existing diesel tank to 500 ppm fuel in order to avoid the
expense of installing an additional tank. However, to provide a
conservatively high estimate we assumed that 10 percent of the
approximately 10,000 bulk plants in the U.S. (1,000) would install a
second tank in order to handle both 500 ppm NRLM diesel fuel and
heating oil. The cost of an additional storage tank at a bulk plant is
estimated at $90,000 and the cost of de-manifolding their delivery
truck at $10,000.\278\ If all 1,000 bulk plants were to install a new
tank, the total one-time capitol cost would be $100,000,000. Amortizing
the capital costs over 20 years, results in a estimated cost for
tankage at such bulk plants of 0.1 cent per gallon of affected NRLM
diesel fuel supplied. Although the impact on the overall cost of the
proposed program is small, the cost to those bulk plant operators who
need to put in a separate storage tank may represent a substantial
investment. Thus, as discussed in section IV.F., we believe many of
these bulk plants could make other arrangements to continue servicing
both heating oil and NRLM markets.
---------------------------------------------------------------------------
\277\ See section IV.E.9. of this proposal and chapter 5 of the
RIA for additional discussion of the potential impacts of the
proposed sulfur standards on the distribution system.
\278\ This estimated cost includes the addition of a separate
delivery system on the tank truck.
---------------------------------------------------------------------------
Due to the end of the highway program temporary compliance option
(TCO) in 2010 and the disappearance of high-sulfur diesel fuel from
much of the fuel distribution system due to the implementation of this
proposed rule, we expect that storage tanks at many bulk plants which
were previously devoted to 500 ppm TCO highway fuel and high-sulfur
fuel would become available for dyed 15 ppm nonroad diesel service.
Based on this assessment, we do not expect that a significant number of
bulk plants would need to install an additional storage tank in order
to provide dyed and undyed 15 ppm diesel fuel to their customers
beginning in 2010 (the proposed implementation date for the 15 ppm
nonroad standard).\279\ There could potentially be some additional
costs related to the need for new tankage in some areas not already
carrying 500 ppm fuel under the temporary compliance option of the
highway diesel program and which continue to carry high sulfur fuel.
However, we expect them to minimal relative to the above 0.1 cent per
gallon cost. Thus, we estimate that the total cost of additional
storage tanks that would result from the adoption of this proposal
would be 0.1 cent per gallon of affected off-highway diesel engine fuel
supplied.
---------------------------------------------------------------------------
\279\ See section IV of today's preamble for additional
discussion of our rational for this conclusion.
---------------------------------------------------------------------------
Three, the proposed requirement that high sulfur heating oil be
marked between 2007 and 2010 and that locomotive and marine diesel fuel
be marked from 2010 until 2014 would increase the cost of distributing
these fuels slightly. Based on input from marker manufacturers, we
estimate that marking these fuels would cost no more than 0.2 cent per
gallon and could cost considerably less. There should be no capital
cost associated with this requirement, as we are proposing to remove
the current requirement that refiners dye all high sulfur distillate at
the refinery. The current dyeing equipment should work equally well for
the marker. Because heating oil is being marked to prevent its use in
NRLM engines, we have spread the cost for this marker over NRLM diesel
fuel. Thus, from a regulatory point of view, the heating oil marker
would increase the cost of NRLM diesel fuel between 2007 and 2010 by
0.16 cent per gallon. We attribute the cost of marking 500 ppm
locomotive and marine diesel fuel directly to this fuel, so the marker
cost is simply 0.2 cent per gallon of locomotive and marine diesel fuel
between 2010 and 2014.
We do not project any additional downgrade of 15 ppm diesel fuel
would result from the proposed fuel program. In our analysis of the 15
ppm highway fuel program, we also projected additional distribution
costs due to the need to downgrade more volume of highway diesel fuel
to a lower value product. This is a consequence of the large difference
between the sulfur content of 15 ppm fuel and other distillate
products, like high sulfur diesel fuel, heating oil and jet fuel.\280\
We do not project that these costs would increase with this proposed
rule. Highway diesel fuel meeting a 15 ppm cap will already be being
distributed in all major pipeline and terminal networks. Thus, we
expect that 15 ppm nonroad fuel would be added to batches of 15 ppm
already being distributed. In this situation, the total interface
volume needing to be downgraded would not increase. At the same time,
we are not projecting that interface volume would decrease, as high
sulfur fuels, such as jet fuel, would still be in the system.
---------------------------------------------------------------------------
\280\ Off-highway diesel fuel sulfur content is currently
unregulated and is approximately 3,400 ppm on average. The maximum
allowed sulfur content of heating oil is 5,000 ppm. The maximum
allowed sulfur content of kerosene (and jet fuel) is 3,000 ppm.
---------------------------------------------------------------------------
Thus, overall, we estimate that the total additional distribution
would be 0.3 cent per gallon of nonroad, locomotive and marine fuel
during the first step of the proposed program (from 2007 through 2010).
We project that distribution costs would increase to 0.4 cent gallon
for 500 ppm locomotive and marine diesel fuel from 2010 to 2014, but
decrease to 0.2 cent per gallon thereafter. Finally, we project that
distribution costs for 15 ppm nonroad diesel fuel would be 0.2 cent
gallon.
4. How EPA's Projected Costs Compare to Other Available Estimates
We used two different methods for evaluating how well our cost
estimates reflect the true costs for complying with the two step
nonroad fuel program. The first method compared our costs with the
incremental market price of diesel fuel meeting a 15 or 500 ppm
standard. The second method compared our cost estimate to that from an
engineering analysis analogous to the one we performed.
Beginning with market prices, highway diesel fuel meeting a 500 ppm
sulfur cap has been marketed in the U.S. for almost ten years. Over the
five year period from 1995-1999, its national average price has
exceeded that of high sulfur diesel fuel by about 2.4 cent per gallon
(see chapter 7 of the Draft RIA). While fuel prices are a often a
function of market forces which might not reflect the cost of producing
the fuel, the comparison of the price difference over a fairly long
period such as 5 years would tend to reduce the effect of the market on
the prices and more closely reflect the cost of complying with the 500
ppm cap standard. Thus, we feel that this is a sound basis for
evaluating our cost estimate. This price difference is essentially the
same as our estimated cost for refining and distributing 500 ppm non-
highway diesel fuel, thus the price difference for producing and
distributing 500 ppm highway fuel corroborates our cost analysis.
Some 15 ppm diesel fuel is marketed today. However, it is either
being produced in very limited quantities using equipment designed to
meet less
[[Page 28436]]
stringent sulfur standards or with other properties which make it
unrepresentative of typical U.S. NRLM diesel fuel. Thus, current market
prices are not a good indication of the long term price impact of the
proposed 15 ppm cap.
Regarding engineering studies, the Engine Manufactures Association
(EMA) commissioned a study by Mathpro to estimate the cost of
controlling the sulfur content of highway and nonroad diesel fuel to
levels consistent with both 500 ppm and 15 ppm cap standards.\281\
Mathpro used a higher rate of return on new capital so we adjusted
their per-gallon costs to reflect our own amortization methodology.
Also, the Mathpro study was completed in 1999 so we adjusted their
costs for inflation to year 2002 dollars. After these two adjustments,
Mathpro's cost to desulfurize the high sulfur non-highway pool to 500
ppm is 2.5 cents per gallon, while that for a 15 ppm cap is 5.8 cents
per gallon.\282\ The 500 ppm cost estimate compares quite favorably
with our own estimate of 2.2 cents per gallon cost. One reason for our
somewhat lower estimate for complying with the 500 ppm standard is that
our refinery-specific analysis has only the lowest cost refineries
complying as many more expensive refineries can continue to produce
heating oil. It is likely that the refineries which our analysis show
would comply are more optimized for desulfurizating diesel fuel than
the average refinery used by Mathpro. This reason applies even more for
15 ppm cap standard as fewer, more optimized refineries need to comply
to produce nonroad diesel fuel which complies with a 15 ppm sulfur cap
standard. Furthermore, we considered the use of advanced
desulfurization technologies for complying with the 15 ppm standard,
while Mathpro did not. Since the Mathpro study was performed in 1999,
cost estimates were not available for either of the two technologies
which we included. The adjustment of the Mathpro costs and the
comparison with our own cost estimates are discussed in detail in the
Draft RIA. We request comment on the degree that the results of the
Mathpro study for EMA and the comparison with real-world prices support
our own cost estimates.
---------------------------------------------------------------------------
\281\ Hirshfeld, David, MathPro, Inc., ``Refining economics of
diesel fuel sulfur standards,'' performed for the Engine
Manufactuers Association, October 5, 1999.
\282\ The Mathpro costs cited reflect their case where current
diesel fuel hydrotreaters are revamped with a new reactor in series,
which is the most consistent with our technology projection.
---------------------------------------------------------------------------
5. Supply of Nonroad, Locomotive and Marine Diesel Fuel
EPA has developed the proposed fuel program to minimize its impact
on the supply of distillate fuel. For example: we have proposed to
transition the fuel sulfur level down to 15 ppm in two steps, providing
an estimated 6 years of leadtime for the final step; we are proposing
to provide flexibility to refiners through the availability of banking
and trading provisions; and we have provided relief for small refiners
and hardship relief for any qualifying refiner. In order to evaluate
the effect of this proposal on supply, EPA evaluated four possible
cases: (1) whether the proposed standards could cause refiners to
remove certain blendstocks from the fuel pool, (2) whether the proposed
standards could require chemical processing which loses fuel in the
process, (3) whether the cost of meeting the proposed standards could
lead some refiners to leave that market, and (4) whether the cost of
meeting the proposed standards could lead some refiners to stop
operations altogether (i.e., shut down). In all cases, as discussed
below, we have concluded that the answer is no. Therefore, consistent
with our findings made during the 2007 highway diesel rule, we do not
expect this proposed rule to cause any supply shortages of nonroad,
locomotive and marine diesel fuel. The reader is referred to the draft
RIA for a more detailed discussion of the potential supply impact of
this proposed rule.
Blendstock Shift: There should be no long term reduction in the
amount of material derived from crude oil available for blending into
diesel fuel or heating oil as a result of this proposal. Technology
exists to desulfurize any commercial diesel fuel to less than 10 ppm
sulfur. This technology is just now being proven on a commercial scale
with a range of no. 2 diesel fuel blendstocks, as a number of refiners
are producing 15 ppm fuel for diesel fleets which have been retro-
fitted with PM traps or for pipeline testing. Therefore, there is no
technical necessity to remove certain blendstocks from the diesel fuel
pool. It costs more to process certain blendstocks, such as light cycle
oil, than others. Therefore, there may be economic incentives to move
certain blendstocks out of the diesel fuel market to reduce compliance
costs. However, that is an economic issue, not a technical issue and
will be addressed below when we consider whether refiners might choose
to exit the NRLM diesel fuel market.
Processing Losses: The impact of the proposed rule on the total
output of liquid fuel from refineries would be negligible. Conventional
desulfurization processes do not reduce the energy content of the input
material. However, the form of the material is affected slightly. With
conventional hydrotreating, about 98 percent of the diesel fuel fed to
a hydrotreater producing 15 ppm sulfur product leaves as diesel fuel.
Of the 2 percent loss, three-fourths, or about 1.5 percent leaves the
unit as naphtha (i.e., gasoline feedstock). The remainder is split
evenly between liquified petroleum gas (LPG) and refinery fuel gas.
Both naphtha and LPG have higher valuable uses as liquid fuels. Naphtha
can be used to produce gasoline. Refiners can adjust the relative
amounts of gasoline and diesel fuel which they produce, especially to
this small degree. This additional naphtha can displace other gasoline
blendstocks, which can then be shifted to the diesel fuel pool. LPG, on
the other hand, is primarily used in heating, where it competes with
heating oil. Thus, additional LPG can be used to displace gasoline and
heating oil, which in turn can be shifted to the diesel fuel pool.
Thus, there should be little or no direct impact of desulfurization on
refinery fuel production. The shift from diesel fuel to fuel gas is
very small (0.25 percent) and this fuel gas can be used to reduce
consumption of natural gas within the refinery. These figures apply to
the full effect of the proposed standards (i.e., the reduction in
sulfur content from 3400 ppm to 15 ppm). For the first step of the
proposed fuel program and that portion of the diesel fuel pool which
would remain at the 500 ppm level indefinitely, the impacts would only
be about 40 percent of those described above.
The use of advanced desulfurization technologies would further
reduce these impacts. These technologies are projected to be used in
the second step of reducing 500 ppm diesel fuel to 15 ppm sulfur. We
project that the Linde process would reduce the above losses for the
second step by 55 percent, while the Phillips SZorb process would have
no loss in diesel fuel production.
Exit the NRLM Diesel Fuel Market: While the cost of meeting the
proposed standards might cause some individual refiners to consider
reducing their production of NRLM fuel or leave the market entirely, we
do not believe that across the entire industry such a shift is possible
or likely. As mentioned above, all diesel fuels and heating oil are
essentially identical both chemically and physically, except for sulfur
level. Thus, if a refiner could shift his high
[[Page 28437]]
sulfur distillate material from the nonroad, locomotive and marine
diesel fuel markets to the heating oil market starting in mid-2007, it
would avoid the need to invest in new desulfurization equipment.
Likewise, starting in mid-2010, a refiner could focus his 500 ppm
diesel fuel in the locomotive and marine diesel fuel markets or shift
this material to the heating oil market. The problem would be a
potential oversupply of heating oil starting in 2007 and locomotive and
marine diesel fuel and heating oil starting in 2010. An oversupply
could lead to a substantial drop in market price, significantly
increasing the cost of leaving the nonroad, locomotive and marine
diesel fuel markets. Or, it may be necessary to export the higher
sulfur fuel in order to sell it. This could entail transportation costs
and overseas prices no higher than existed in the U.S. before the
oversupply (and possibly lower due to these imports now entering these
overseas markets).
We addressed this same issue during the development of 2007 highway
diesel fuel program. There, the issue was whether refiners would shift
some or all of their current highway diesel fuel production to either
domestic or overseas markets for high sulfur diesel fuel or heating oil
in order to avoid investing to meet the 15 ppm cap for highway diesel
fuel. A study by Charles River Associates, et al., sponsored by API
projected that there could be a near-term shortfall in highway diesel
fuel supply of as much as 12 percent.\283\ However, supported by a
study by Muse, Stancil, we concluded that refiners would incur greater
economic loss in trying to avoid meeting the 15 ppm highway diesel fuel
cap than they would by complying at current production levels even if
the market did not allow them to recover their capital investment. A
study by Mathpro, Inc. for AAM and EMA also criticized the conclusions
of the Charles River study, particularly their assumption that
compliance costs alone would drive investment decisions and that there
was essentially a single highway diesel fuel market nationwide.\284\
Mathpro demonstrated that smaller refineries located, for example, in
the Rocky Mountain region, likely faced higher per gallon compliance
costs, but also had been more profitable over the past 15 years than
larger refiners in other areas with lower overall costs. This was due
to their market niches and the inability for lower cost refiners to
ship large volumes of fuel economically to their market.
---------------------------------------------------------------------------
\283\ ``An Assessment of the Potential Impacts of Proposed
Environmental Regulations on U.S. Refinery Supply of Diesel Fuel,''
Charles River Associates and Baker and O'Brien, for API, August
2000.
\284\ ``Prospects for Adequate Supply of Ultra Low Sulfur Diesel
Fuel in the Transition Period (2006-2007), An Analysis of Technical
and Economic Driving Forces for Investment in ULSD Capacity in the
U.S. Refining Sector,'' MathPro, Inc., for AAM and EMA, December 7,
2001.
---------------------------------------------------------------------------
We believe that the same conclusions apply to the proposed fuel
program for six reasons. One, the alternative markets for high sulfur
diesel fuel and heating oil would be even more limited after the
proposed sulfur caps on nonroad, locomotive and marine diesel fuel than
they will be in 2006, as half of the current U.S. market for high
sulfur, no. 2 distillate would disappear. We expect that high sulfur
heating oil would not even by carried be common carrier pipelines
except those serving the Northeast. Therefore, refiners' sale of high
sulfur distillate may be limited to markets serviceable by truck. Two,
the desulfurization technology to meet a 500 ppm cap has been
commercially demonstrated for over a decade. The desulfurization
technology to meet a 15 ppm cap will have been commercially
demonstrated in mid-2006, a full four years prior to the implementation
of the 15 ppm cap on nonroad diesel fuel. Three, the volume of fuel
affected by the 15 ppm nonroad diesel fuel standard would be only one-
seventh of that affected by the highway diesel fuel program. This
dramatically reduces the required capital investment. Four, both Europe
and Japan are implementing sulfur caps for highway and nonroad diesel
fuel in the range of 10-15 ppm, eliminating these markets as a sink for
high sulfur diesel fuel. Five, refineries outside of the U.S. and
Europe are operating at a lower percentage of their capacity than U.S.
refineries. Thus, U.S. refineries would not be able to obtain
attractive prices for high sulfur diesel fuel overseas. Finally,
refinery profit margins were much higher during the last part of 2000
and most of 2001 than over the past ten years, indicating a potential
long-term improvement in profitability. Margins decreased again during
most in 2002, but recovered during the last few months of that year and
in early 2003.
Once refiners have made their investments to meet the proposed NRLM
diesel fuel standards, or have decided to produce high sulfur heating
oil, we expect that the various distillate markets would operate very
similar to today's markets. When fully implemented in 2014, there will
be three distillate fuels in the market, 15 ppm highway and nonroad
diesel fuel, 500 ppm locomotive and marine diesel fuel and high sulfur
heating oil. The market for 500 ppm locomotive and marine diesel fuel
is much smaller than the other two, particularly considering that it is
nationwide and the heating oil market is geographically concentrated.
Therefore, the vast majority of refiners are expected to focus on
producing either 15 ppm or high sulfur distillate, which is similar to
today, where there are two fuels, 500 ppm and high sulfur distillate.
In this case, refiners with the capability of producing 15 ppm diesel
fuel have the most flexibility, since they can sell their fuel to any
of the three markets. Refiners with only 500 ppm desulfurization
capability can supply two markets. Those refiners only capable of
producing high sulfur distillate would not be able to participate in
either the 15 or 500 ppm markets. However, this is not different from
today. Generally, we do not expect one market to provide vastly
different profit margins than the others, as high profit margins in one
market will attract refiners from another via investment in
desulfurization equipment.
Refinery Closure: There are a number of reasons why we do not
believe that refineries would completely close down under this proposed
rule. One reason is that we have included provisions to provide relief
for small refiners, as well as any refiner facing unusual financial
hardship. Another reason is that nonroad, locomotive and marine diesel
fuel is usually the third or fourth most important product produced by
the refinery from a financial perspective. A total shutdown would mean
losing all the revenue and profit from these other products. Gasoline
is usually the most important product, followed by highway diesel fuel
and jet fuel. A few refineries do not produce either gasoline or
highway diesel fuel, so jet fuel and high sulfur diesel fuel and
heating oil are their most important products. The few refiners in this
category likely face the biggest financial challenge in meeting the
proposed requirements. However, those refiners would also presumably be
in the best position to apply for special hardship provisions,
presuming that they do not have readily available source of investment
capital. The additional time afforded by these provisions should allow
the refiner to generate sufficient cash flow to invest in the required
desulfurization equipment. Investment here could also provide them the
opportunity to expand into more profitable (e.g., highway diesel)
markets.
A quantitative evaluation of whether the cost of the proposed fuel
program could cause some refineries to cease operations completely
would be very difficult, if not impossible to perform. A
[[Page 28438]]
major factor in any decision to shut down is the refiner's current
financial situation. It is very difficult to assess an individual
refinery's current financial situation. This includes a refiner's debt,
as well as its profitability in producing fuels other than those
affected by a particular regulation. It can also include the
profitability of other operations and businesses owned by the refiner.
Such an intensive analysis can be done to some degree in the
context of an application for special hardship provisions, as discussed
above. However, in this case, EPA can request detailed financial
documents not normally available. Prior to such application, as is the
case now, this financial information is usually confidential. Even when
it is published, the data usually apply to more than just the operation
of a single refinery.
Another factor is the need for capital investments other than for
this proposed rule. EPA can roughly project the capital needed to meet
other new fuel quality specifications, such as the Tier 2 or highway
diesel sulfur standards. However, we cannot predict investments to meet
local environmental and safety regulations, nor other investments
needed to compete economically with other refiners.
Finally, any decision to close in the future must be based on some
assumption of future fuel prices. Fuel prices are very difficult to
project in absolute terms. The response of prices to changes in fuel
quality specifications, such as sulfur content, as is discussed in the
next section, are also very difficult to predict. Thus, even if we had
complete knowledge of a refiner's financial status and its need for
future investments, the decision to stay in business or close would
still depend on future earnings, which are highly dependent on the
prices of all products produced by that refinery.
Some studies in this area point to fuel pricing over the past 15
years or so and conclude that prices will only increase to reflect
increased operating costs and will not reflect the cost of capital. In
fact, the rate of return on refining assets has been poor over the past
15 years and until recently, there has been a steady decline in the
number of refineries operating in the U.S. However, this may have been
due to a couple of circumstances specific to that time period. One,
refinery capacity utilization was less than 80 percent in 1985. Two, at
least regarding gasoline, the oxygen mandate for reformulated gasoline
caused an increase in gasoline supply despite low refinery utilization
rates. While this led to healthy financial returns for oxygenate
production, it did not help refining profit margins.
Today, refinery capacity utilization in the U.S. is generally
considered to be at its maximum sustainable rate. There are no
regulatory mandates on the horizon which will increase production
capacity significantly, even if ethanol use in gasoline increases
substantially.\285\ Consistent with this, refining margins have been
much better over the past two and a half years than during the previous
15 years and the refining industry itself is projecting good returns
for the foreseeable future.
---------------------------------------------------------------------------
\285\ Both houses of the U.S. Congress are considering bills
which would require the increased use of renewables, like ethanol,
in gasoline and diesel fuel. While the amount of renewables could be
considerable, it is well below the annual growth in transportation
fuel use.
---------------------------------------------------------------------------
6. Fuel Prices
It is well known that it is difficult to predict fuel prices in
absolute terms with any accuracy. The price of crude oil dominates the
cost of producing gasoline and diesel fuel. Crude oil prices have
varied by more than a factor of two in the past year. In addition,
unexpectedly warm or cold winters can significantly affect heating oil
consumption, which affects the amount of gasoline produced and the
amount of distillate material available for diesel fuel production.
Economic growth, or its lack, affects fuel demand, particularly for
diesel fuel. Finally, both planned and unplanned shutdowns of
refineries for maintenance and repairs can significantly affect total
fuel production, inventory levels and resulting fuel prices.
Predicting the impact of any individual factor on fuel price is
also difficult. The overall volatility in fuel prices limits the
ability to determine the effect of a factor which changed at a specific
point in time which might have led to the price change, as other
factors continue to change over time. Occasionally, a fuel quality
change, such as reformulated gasoline or a 500 ppm cap on diesel fuel
sulfur content, only affects a portion of the fuel pool. In this case,
an indication of the impact on price can be inferred by comparing the
prices of the two fuels at the same general location over time.
However, this is still only possible after the fact, and cannot be done
before the fuel quality change takes place.
Because of these difficulties, EPA has generally not attempted to
project the impact of its rules on fuel prices. However, in response to
Executive Order 13211, we are doing so for this proposed rule. To
reflect the inherent uncertainty in making such projections, we
developed three projections for the potential impact of the proposed
fuel program on fuel prices. The range of potential long-term price
increases are shown in Table V-A-4. Short-term price impacts are highly
volatile, as are short-term swings in absolute fuel prices, and much
too dependent on individual refiners' decisions, unexpected shutdowns,
etc. to be predicted even with broad ranges.
Table V-A-4.--Range of Possible Total Diesel Fuel Price Increases (cents per gallon) a
----------------------------------------------------------------------------------------------------------------
Lower Limit Mid-Point Maximum
----------------------------------------------------------------------------------------------------------------
2007 500 ppm Sulfur Cap: Nonroad, Locomotive and Marine Diesel Fuel
-------------------------------------------------------------------------------------------------
PADDs 1 and 3................................................... 0.9 1.5 3.4
PADD 2.......................................................... 2.3 3.0 4.8
PADD 4.......................................................... 1.7 4.1 5.8
PADD 5.......................................................... 1.0 2.8 4.3
-----------------------------------------------------------------
2010 15 ppm Sulfur Cap: Nonroad Diesel Fuel
-------------------------------------------------------------------------------------------------
PADDs 1 and 3................................................... 1.8 3.0 5.4
PADD 2.......................................................... 2.9 6.1 7.4
PADD 4.......................................................... 3.0 8.9 9.3
PADD 5.......................................................... 1.7 5.9 8.4
----------------------------------------------------------------------------------------------------------------
Notes:
a At the current wholesale price of approximately $1.00 per gallon, these values also represent the percentage
increase in diesel fuel price.
[[Page 28439]]
The lower end of the range assumes that prices within a PADD
increased to reflect the highest operating cost increase faced by any
refiner in that PADD. In this case, this refiner with the highest
operating cost would not recover any of his invested capital, but all
other refiners would recover some or all of their investment. In this
case, the price of nonroad, locomotive and marine diesel fuel would
increase in 2007 by 1-2 cents per gallon, depending on the area of the
country. In 2010, the price of nonroad diesel fuel would increase a
total of 2-3 cents per gallon. Locomotive and marine diesel fuel prices
would continue to increase by 1-2 cents per gallon.
The mid-range estimate of price impacts assumes that prices within
a PADD increase by the average refining and distribution cost within
that PADD, including full recovery of capital (at 7 percent per annum
before taxes). Lower cost refiners would recover more than their
capital investment, while those with higher than average costs recover
less. Under this assumption, the price of nonroad, locomotive and
marine diesel fuel would increase in 2007 by 2-4 cents per gallon,
depending on the area of the country. In 2010, the price of nonroad
diesel fuel would increase a total of 3-9 cents per gallon. Locomotive
and marine diesel fuel prices would continue to increase by 2-4 cents
per gallon.
The upper end estimate of price impacts assumes that prices within
a PADD increase by the maximum total refining and distribution cost of
any refinery within that PADD, including full recovery of capital (at 7
percent per annum before taxes). All other refiners would recover more
than their capital investment. Under this assumption, the price of
nonroad, locomotive and marine diesel fuel would increase in 2007 by 3-
6 cents per gallon, depending on the area of the country. In 2010, the
price of nonroad diesel fuel would increase a total of 5-9 cents per
gallon. Locomotive and marine diesel fuel prices would continue to
increase by 3-6 cents per gallon.
In addition to the differences noted above, there are a number of
assumptions inherent in all three of the above price projections.
First, both the lower and upper limits of the projected price impacts
described above assume that the refinery facing the highest compliance
costs is currently the price setter in their market. This is a worse
case assumption which is impossible to validate. Many factors affect a
refinery's total costs of fuel production. Most of these factors, such
as crude oil cost, labor costs, age of equipment, etc., are not
considered in projecting the incremental costs associated with lower
NRLM diesel fuel sulfur levels. Thus, current prices may very well be
set in any specific market by a refinery facing lower incremental
compliance costs than other refineries. This point was highlighted in a
study by the National Economic Research Associates (NERA) for AAM of
the potential price impacts of EPA's 2007 highway diesel fuel
program.\286\ In that study, NERA criticized the above referenced study
performed by Charles River Associates, et al. for API, which projected
that prices would increase nationwide to reflect the total cost faced
by the U.S. refinery with the maximum total compliance cost of all the
refineries in the U.S. producing highway diesel fuel. To reflect the
potential that the refinery with the highest projected compliance costs
under the maximum price scenario is not the current price setter, we
included the mid-point price impacts above. It is possible that even
the lower limit price impacts are too high, if the conditions exist
where prices are set based on operating costs alone. However, these
price impacts are sufficiently low that considering even lower price
impacts was not considered critical to estimating the potential
economic impact of this rule.
---------------------------------------------------------------------------
\286\ ``Potential Impacts of Environmental Regulations on Diesel
Fuel Prices,'' NERA, for AAM, December 2000.
---------------------------------------------------------------------------
Second, we assumed that a single refinery's costs could affect fuel
prices throughout an entire PADD. While this is a definite improvement
over analyses which assume that a single refinery's costs could affect
fuel prices throughout the entire nation, it is still conservative.
High cost refineries are more likely to have a more limited
geographical impact on market pricing than an entire PADD.
Third, by focusing solely on the cost of desulfurizing NRLM diesel
fuel, we assume that the production of NRLM diesel fuel is independent
of the production of other refining products, such as gasoline, jet
fuel and highway diesel fuel. However, this is clearly not the case.
Refiners have some flexibility to increase the production of one
product without significantly affecting the others, but this
flexibility is quite limited. It is possible that the relative
economics of producing other products could influence a refiner's
decision to increase or decrease the production of NRLM diesel fuel
under the proposed standards. This in turn could increase or decrease
the price impact relative to those projected above.
Fourth, all three of the above price projections are based on the
projected cost for U.S. refineries of meeting the proposed NRLM diesel
fuel sulfur caps. Thus, these price projections assume that imports of
NRLM fuel, which are currently significant in the Northeast, are
available at roughly the same cost as those for U.S. refineries in
PADDs 1 and 3. We have not performed any analysis of the cost of lower
sulfur caps on diesel fuel produced by foreign refiners. However, there
are reasons to believe that imports of 500 and 15 ppm NRLM diesel fuel
would be available at prices in the ranges of those projected for U.S.
refiners.
One recent study analyzed the relative cost of lower sulfur caps
for Asian refiners relative to those in the U.S., Europe and
Japan.\287\ It concluded that costs for Asian refiners would be
comparatively higher, due to the lack of current hydrotreating capacity
at Asian refineries. This conclusion is certainly valid when evaluating
lower sulfur levels for highway diesel fuels which are already at low
levels in the U.S., Europe and Japan and for which refineries in these
areas have already invested in hydrotreating capacity. It would appear
to be less valid when assessing the relative cost of meeting lower
sulfur standards for nonroad diesel fuels and heating oils which are
currently at much higher sulfur levels in the U.S., Europe and Japan.
All refineries face additional investments to remove sulfur from these
fuels and so face roughly comparable control costs on a per gallon
basis.
---------------------------------------------------------------------------
\287\ ``Cost of Diesel Fuel Desulfurization In Asian
Refineries,'' Estrada International Ltd., for the Asian Development
Bank, December 17, 2002.
---------------------------------------------------------------------------
One factor arguing for competitively priced imports is the fact
that refinery utilization rates are currently higher in the U.S. and
Europe than in the rest of the world. The primary issue is whether
overseas refiners will invest to meet tight sulfur standards for U.S.,
European and Japanese markets. Many overseas refiners will not invest,
instead focusing on local, higher sulfur markets. However, many
overseas refiners focus on exports. Both Europe and the U.S. are moving
towards highway and nonroad diesel fuel sulfur caps in the 10-15 ppm
range. Europe is currently and projected to continue to need to import
large volumes of highway diesel fuel. Thus, it seems reasonable to
expect that a number of overseas refiners would invest in the capacity
to produce some or all of their diesel fuel at these levels. Overseas
refiners also have the flexibility to produce 10-15 ppm diesel fuel
from their cleanest blendstocks, as
[[Page 28440]]
most of their available markets have less stringent sulfur standards.
Thus, there are reasons to believe that some capacity to produce 10-15
ppm diesel fuel would be available overseas at competitive prices. If
these refineries were operating well below capacity, they might be
willing to supply complying product at prices which only reflect
incremental operating costs. This could hold prices down in areas where
importing fuel is economical. However, it is unlikely that these
refiners could supply sufficient volumes to hold prices down
nationwide. Despite this expectation, to be conservative, in the
refining cost analysis conducted earlier in this chapter, we assumed no
imports of 500 ppm or 15 ppm NRLM diesel fuel. All 500 ppm and 15 ppm
nonroad diesel fuel was produced by domestic refineries. This raised
the average and maximum costs of 500 ppm and 15 ppm NRLM diesel fuel
and increased the potential price impacts projected above beyond what
would have been projected had we projected that 5-10 percent of NRLM
diesel fuel would be imported at competitive prices.
B. Cost Savings to the Existing Fleet from the Use of Low Sulfur Fuel
We estimate that reducing fuel sulfur to 500 ppm would reduce
engine wear and oil degradation to the existing nonroad diesel
equipment fleet and that a further reduction to 15 ppm sulfur would
result in even greater reductions. This reduction in wear and oil
degradation would provide a dollar savings to users of nonroad
equipment. The cost savings would also be realized by the owners of
future nonroad engines that are subject to the standards in this
proposal. As discussed below, these maintenance savings have been
conservatively estimated to be greater than 3 cents per gallon for the
use of 15 ppm sulfur fuel when compared to the use of today's
unregulated nonroad diesel fuel. A summary of the benefits of low-
sulfur fuel is presented in Table V.B-1.\288\
---------------------------------------------------------------------------
\288\ See Heavy-duty 2007 Highway Final RIA, Chapter V.C.5, and
``Study of the Effects of Reduced Diesel Fuel Sulfur Content on
Engine Wear'', EPA report 460/3-87-002, June 1987.
Table V.B-1--Engine Components Potentially Affected by Lower Sulfur
Levels in Diesel Fuel
------------------------------------------------------------------------
Effect of Lower Potential Impact on
1Affected Components Sulfur Engine System
------------------------------------------------------------------------
Piston Rings.................. Reduced corrosion Extended engine life
wear. and less frequent
rebuilds.
Cylinder Liners............... Reduced corrosion Extended engine life
wear. and less frequent
rebuilds.
Oil Quality................... Reduced deposits, Reduce wear on piston
reduced acid ring and cylinder
build-up, and liner and less
less need for frequent oil
alkaline changes.
additives.
Exhaust System (tailpipe)..... Reduced corrosion Less frequent part
wear. replacement.
Exhaust Gas Recirculation Reduced corrosion Less frequent part
System. wear. replacement.
------------------------------------------------------------------------
The monetary value of these benefits over the life of the equipment
will depend upon the length of time that the equipment operates on low-
sulfur diesel fuel and the degree to which engine and equipment
manufacturers specify new maintenance practices and the degree to which
equipment operators change engine maintenance patterns to take
advantage of these benefits. For equipment near the end of its life in
the 2008 time frame, the benefits will be quite small. However, for
equipment produced in the years immediately preceding the introduction
of 500 ppm sulfur fuel, the savings would be substantial. Additional
savings would be realized in 2010 when the 15 ppm sulfur fuel would be
introduced.
We estimate the single largest savings would be the impact of lower
sulfur fuel on oil change intervals. The draft RIA presents our
analysis for the oil change interval extension which would be realized
by the introduction of 500 ppm sulfur fuel in 2007, as well as the
additional oil extension which would be realized with the introduction
of 15 ppm sulfur nonroad diesel fuel in 2010. As explained in the draft
RIA, these estimates are based on our analysis of publically available
information from nonroad engine manufacturers. Due to the wide range of
diesel fuel sulfur which today's nonroad engines may see around the
world, engine manufacturers specify different oil change intervals as a
function of diesel sulfur levels. We have used this data as the basis
for our analysis. Taken together, when compared to today's relatively
high nonroad diesel fuel sulfur levels, we estimate the use of 15 ppm
sulfur fuel will enable an oil change interval extension of 35 percent
from today's products.
We present here a fuel cost savings attributed to the oil change
interval extension in terms of a cents per gallon operating cost. We
estimate that an oil change interval extension of 31 percent, as would
be enabled by the use of 500 ppm sulfur fuel in 2007, results in a fuel
operating costs savings of 3.0 cents per gallon for the nonroad fleet.
We project an additional cost savings of 0.3 cents per gallon for the
oil change interval extension which would be enabled by the use of 15
ppm sulfur beginning in 2010. Thus, for the nonroad fleet as a whole,
beginning in 2010 nonroad equipment users can realize an operating cost
savings of 3.3 cents per gallon compared to today's engine. This means
that the end cost to the typical user for 15ppm sulfur fuel is
approximately 1.5 cents per gallon (4.8 cent per gallon cost for fuel
minus 3.3 cent per gallon maintenance savings). For a typical 100
horsepower nonroad engine this represents a net present value lifetime
savings of more than $500.
These savings will occur without additional new cost to the
equipment owner beyond the incremental cost of the low-sulfur diesel
fuel, although these savings are dependent on changes to existing
maintenance schedules. Such changes seem likely given the magnitude of
the savings. We have not estimated the value of the savings from the
other benefits listed in Table V.B-1, and therefore we believe the 3.3
cents per gallon savings is conservative as it only accounts for the
impact of low sulfur fuel on oil change intervals.
C. Engine and Equipment Cost Impacts
The following sections briefly discuss the various engine and
equipment cost elements considered for this proposal and present the
total costs we have estimated; the reader is referred to the draft RIA
for a complete discussion. Estimated engine and equipment costs depend
largely on both the size of the piece of equipment and its engine, and
on the technology package being added to the engine to ensure
compliance with the proposed standards. The wide size variation (e.g.,
<4 horsepower engines through 2500 horsepower engines) and
[[Page 28441]]
the broad application variation (e.g., lawn equipment through large
mining trucks) that exists in the nonroad industry makes it difficult
to present here an estimated cost for every possible engine and/or
piece of equipment. Nonetheless, for illustrative purposes, we present
some example per engine/equipment cost impacts throughout this
discussion. This analysis is presented in detail in Chapter 6 of the
draft RIA. We are also considering doing a sensitivity analysis on
cost/engine data, which would be put into the docket for comment.
It is important to note that the costs presented here do not
reflect any savings that are expected to occur because of the engine
ABT program and the equipment manufacturer transition program, both of
which are discussed in Section VII. As discussed in the draft RIA,
these optional programs have the potential to provide significant
savings for both engine and equipment manufacturers. We request comment
with supporting data and/or analysis on the cost estimates presented
here and the underlying analysis presented in chapter 6 of the draft
RIA.
1. Engine Cost Impacts
Estimated engine costs are broken into fixed costs (for research
and development, retooling, and certification), variable costs (for new
hardware and assembly time), and life-cycle operating costs. Total
operating costs include the estimated incremental cost for low-sulfur
diesel fuel, any expected increases in maintenance costs associated
with new emission control devices, any costs associated with increased
fuel consumption, and any decreases in operating cost (i.e.,
maintenance savings) expected due to low-sulfur fuel. Cost estimates
presented here represent an expected incremental cost of engines in the
model year of their introduction. Costs in subsequent years would be
reduced by several factors, as described below. All engine and
equipment costs are presented in 2001 dollars.
a. Engine Fixed Costs
i. Engine and Emission Control Device R&D
The technologies described in section III represent those
technologies we believe will be used to comply with the proposed Tier 4
emission standards. These technologies are part of an ongoing research
and development effort geared toward compliance with the 2007 heavy-
duty diesel highway emission standards. The engine manufacturers making
R&D expenditures toward compliance with highway emission standards will
have to undergo some additional R&D effort to transfer emission control
technologies to engines they wish to sell into the nonroad market.
These R&D efforts will allow engine manufacturers to develop and
optimize these new technologies for maximum emission-control
effectiveness with minimum negative impacts on engine performance,
durability, and fuel consumption. Many nonroad engine manufacturers are
not part of the ongoing R&D effort toward compliance with highway
emissions standards because they do not sell engines into the highway
market. These manufacturers are expected to benefit from the R&D work
that has already occurred and will continue through the coming years
through their contact with highway manufacturers, emission control
device manufacturers, and the independent engine research laboratories
conducting relevant R&D.
Several technologies are projected for complying with the proposed
Tier 4 emission standards. We are projecting that NOX
adsorbers and catalyzed diesel particulate filters (CDPFs) would be the
most likely technologies applied by industry to meet our proposed
emissions standards for 75 horsepower engines. The fact that
these technologies are being developed for implementation in the
highway market prior to the implementation dates in this proposal, and
the fact that engine manufacturers would have several years before
implementation of the proposed Tier 4 standards, ensures that the
technologies used to comply with the nonroad standards would undergo
significant development before reaching production. This ongoing
development could lead to reduced costs in three ways. First, we expect
research will lead to enhanced effectiveness for individual
technologies, allowing manufacturers to use simpler packages of
emission control technologies than we would predict given the current
state of development. Similarly, we anticipate that the continuing
effort to improve the emission control technologies will include
innovations that allow lower-cost production. Finally, we believe that
manufacturers would focus research efforts on any drawbacks, such as
fuel economy impacts or maintenance costs, in an effort to minimize or
overcome any potential negative effects.
We anticipate that, in order to meet the proposed standards,
industry would introduce a combination of primary technology upgrades.
Achieving very low NOX emissions would require basic
research on NOX emission control technologies and
improvements in engine management to take advantage of the exhaust
emission control system capabilities. The manufacturers are expected to
take a systems approach to the problem of optimizing the engine and
exhaust emission control system to realize the best overall
performance. Since most research to date with exhaust emission control
technologies for nonroad applications has focused on retrofit programs,
there remains room for significant improvements by taking such a
systems approach. The NOX adsorber technology in particular
is expected to benefit from re-optimization of the engine management
system to better match the NOX adsorber's performance
characteristics. The majority of the dollars we have estimated for
research is expected to be spent on developing this synergy between the
engine and NOX exhaust emission control systems. Therefore,
for engines requiring both a CDPF and a NOX adsorber (i.e.,
75 horsepower), we have attributed two-thirds of the R&D
expenditures to NOX control, and one-third to PM control.
In the 2007 HD highway rule, we estimated that each engine
manufacturer would expend $35 million for R&D to redesign their engines
and apply catalyzed diesel particulate filters (CDPF) and
NOX adsorbers. For their nonroad R&D efforts on engines
requiring CDPFs and NOX adsorbers (i.e., 75
horsepower), engine manufacturers selling into the highway market would
incur some level of R&D effort but not at the level incurred for the
highway rule. In many cases, the engines used by highway manufacturers
in nonroad products are based on the same engine platform as those used
in highway products. However, horsepower and torque characteristics are
often different so some effort will have to be expended to accommodate
those differences. For these manufacturers, we have estimated that they
would incur an R&D expense of $3.5 million. This $3.5 million R&D
expense would allow for the transfer of R&D knowledge from their
highway experience to their nonroad engine product line. Two-thirds of
this R&D is attributed to NOX control and one-third to PM
control.
For those manufacturers that sell engines only into the nonroad
market, and where those engines require a CDPF and a NOX
adsorber, we believe that they will incur an R&D expense nearing that
incurred by highway manufacturers for the highway rule, although not at
the level incurred by highway manufacturers for the highway rule.
Nonroad manufacturers would be able to learn from the R&D efforts
already
[[Page 28442]]
under way for both the highway rule and for the Tier 2 light-duty
highway rule (65 FR 6698). This learning could be done via seminars,
conferences, and contact with highway manufacturers, emission control
device manufacturers, and the independent engine research laboratories
conducting relevant R&D. Therefore, for these manufacturers, we have
estimated an expenditure of $24.5 million. This lower number--$24.5
million versus $35 million in the highway rule--reflects the transfer
of knowledge to nonroad manufacturers that would occur from the many
stakeholders in the diesel industry. Two-thirds of this R&D is
attributed to NOX control and one-third to PM control.
Note that the $3.5 million and $24.5 million estimates represent
our estimate of the average R&D expected by manufacturers. These
estimates would be different for each manufacturer--some higher, some
lower--depending on product mix and the ability to transfer knowledge
from one product to another.
For those engine manufacturers selling engines that would require
CDPF-only R&D (i.e., 25 to 75 horsepower engines in 2013), we have
estimated that the R&D they would incur would be roughly one-third that
incurred by manufacturers conducting CDPF/NOX adsorber R&D.
We believe this is a good estimate because CDPF technology is further
along in its development than is NOX adsorber technology
and, therefore, a 50/50 split would not be appropriate. Using this
estimate, the R&D incurred by manufacturers that have already done
selling any engines into both the highway and the nonroad markets would
be $1.2 million, and the R&D for manufacturers selling engines into
only the nonroad market would be roughly $8 million. All of this R&D is
attributed to PM control.
For those engine manufacturers selling engines that would require
DOC-only or some engine-out modification R&D (i.e., <75 horsepower
engines in 2008), we have estimated that the R&D they would incur would
be roughly one-half the amount estimated for their CDPF-only R&D. Using
this estimate, the R&D incurred by manufacturers selling any engines
into both the highway and nonroad markets would be roughly $600,000,
and the R&D for manufacturers selling engines into only the nonroad
market would be roughly $4 million. All of this R&D is attributed to PM
control.
Some manufacturers of engines produce engines to specifications
developed by other manufacturers. Such joint venture manufacturers do
not conduct engine-related R&D but simply manufacture an engine
designed and developed by another manufacturer. For such manufacturers,
we have assumed no R&D expenditures given that we believe they will
conduct no R&D themselves and will rely on their joint venture partner.
This is true unless the parent company has no engine sales in the
horsepower categories covered by the partner company. Under such a
situation, we have accounted for the necessary R&D by attributing it to
the parent company. We have also estimated that some manufacturers will
choose not to invest in R&D for the U.S. nonroad market due to low
volume sales that probably cannot justify the expense. More detail on
these assumptions and the number of manufacturers assumed not to expend
R&D is presented in Chapter 6 of the draft RIA. We welcome comments and
supporting documentation.
We have assumed that all R&D expenditures occur over a five year
span preceding the first year any emission control device is introduced
into the market. Where a phase-in exists (e.g., for NOX
standards on 75 horsepower engines), expenditures are
assumed to occur over the five year span preceding the first year
NOX adsorbers would be introduced, and then to continue
during the phase-in years; the expenditures would be incurred in a
manner consistent with the phase-in of the standard. All R&D
expenditures are then recovered by the engine manufacturer over an
identical time span following the introduction of the technology. We
assume a seven percent rate of return for all R&D. We have apportioned
these R&D costs across all engines that are expected to use these
technologies, including those sold in other countries or regions that
are expected to have similar standards. We have estimated the fraction
of the U.S. sales to this total sales at 42 percent. Therefore, we have
attributed this amount to U.S. sales.
Using this methodology, we have estimated the total R&D
expenditures attributable to the proposed standards at $199 million.
ii. Engine-Related Tooling Costs
Once engines are ready for production, new tooling will be required
to accommodate the assembly of the new engines. In the 2007 highway
rule, we estimated approximately $1.6 million per engine line for
tooling costs associated with CDPF/NOX adsorber systems. For
the proposed nonroad Tier 4 standards, we have estimated that nonroad-
only manufacturers would incur the same $1.6 million per engine line
requiring a CDPF/NOX adsorber system and that these costs
would be split evenly between NOX control and PM control.
For those systems requiring only a CDPF, we have estimated one-half
that amount, or $800,000 per engine line. For those systems requiring
only a DOC or some engine-out modifications, we have applied a one-half
factor again, or $400,000 per engine line. Tooling costs for CDPF-only
and for DOC engines are attributed solely to PM control.
For those manufacturers selling into both the highway and nonroad
markets, we have estimated one-half the baseline tooling cost, or
$800,000, for those engine lines requiring a CDPF/NOX
adsorber system. We believe this is reasonable since many nonroad
engines are produced on the same engine line with their highway
counterparts. For such lines, we believe very little to no tooling
costs would be incurred. For engine lines without a highway
counterpart, something approaching the $1.6 million tooling cost would
be applicable. For this analysis, we have assumed a 50/50 split of
engine product lines for highway manufacturers and, therefore, a 50
percent factor applied to the $1.6 million baseline. These tooling
costs would be split evenly between NOX control and PM
control. For engine lines <75 horsepower, we have used the same tooling
costs as the nonroad-only manufacturers because these engines tend not
to have a highway counterpart. Therefore, for those engine lines
requiring only a CDPF (i.e., those between 25 and 75 horsepower), we
have estimated a tooling cost of $800,000. Similarly, the tooling costs
for DOC and/or engine-out engine lines has been estimated to be
$400,000. Tooling costs for CDPF-only and for DOC engines are
attributed solely to PM control.
We expect engines in the 25 to 50 horsepower range to apply EGR
systems to meet the proposed NOX standards for 2013. For
these engines, we have included an additional tooling cost of $40,000
per engine line, consistent with the EGR-related tooling cost estimated
for 50-100 horsepower engines in our Tier 2/3 rulemaking. This tooling
cost is applied equally to all engine lines in that horsepower range
regardless of the markets into which the manufacturer sells. We have
applied this tooling cost equally because engines in this horsepower
range do not tend to have highway counterparts. Tooling costs for EGR
systems are attributed solely to NOX control.
We have applied all the above tooling costs to all manufacturers
that appear to actually make engines. We have not
[[Page 28443]]
eliminated joint venture manufacturers because these manufacturers
would still need to invest in tooling to make the engines even if they
do not conduct any R&D. We have assumed that all tooling costs are
incurred one year in advance of the new standard and are recovered over
a five year period following implementation of the new standard; all
tooling costs are marked up seven percent to reflect the time value of
money. As done for R&D costs, we have attributed a portion of the
tooling costs to U.S. sales and a portion to sales in other countries
expected to have similar levels of emission control. More information
is contained in Chapter 6 of the draft RIA and we request comment on
how we have applied our tooling cost estimates and to whom we have
applied them.
Using this methodology, we estimate the total tooling expenditures
attributable to the proposed standards at $67 million.
iii. Engine Certification Costs
Manufacturers will incur more than the normal level of
certification costs during the first few years of implementation
because engines will need to be certified to the new emission
standards. Consistent with our recent standard setting regulations, we
have estimated engine certification costs at $60,000 per new engine
certification to cover testing and administrative costs. To this we
have added the proposed certification fee of $2,156 per new engine
family. This cost, $62,156 per engine family was used for <75
horsepower engines certifying to the 2008 standards. For 25 to 75
horsepower engines certifying to the 2013 standards, and for
75 horsepower engines certifying to their proposed
standards, we have added costs to cover the proposed test procedures
for nonroad diesel engines (i.e., the transient test and the NTE);
these costs were estimated at $10,500 per engine family. These
certification costs--whether it be the $62,156 or the $72,656 per
engine family--apply equally to all engine families for all
manufacturers regardless of into what markets the manufacturer sells.
We have applied these certification costs to only the US sold engines
because the certification conducted for US sales is not presumed to
fulfill the certification requirements of other countries.
Applying these costs to each of the 665 engine families as they are
certified to a new emissions standard results in total costs of $72
million expended during implementation of the proposed standards. These
costs are attributed to NOX and PM control consistent with
the phase-in of the new emissions standards--where new NOX
and PM standards are introduced together, the certification costs are
split evenly; where only a new PM standard is introduced, the
certification costs are attributed to PM only; where a NOX
phase-in becomes 100% in a year after full implementation of a PM
standard, the certification costs are attributed to NOX
only. All certification costs are assumed to occur one year prior to
the new emission standard and are then recovered over a five year
period following compliance with the new standard; all certification
costs are marked up seven percent to reflect the time value of money.
b. Engine Variable Costs
This section summarizes the detailed analysis presented in the
draft RIA for this proposed rule. We encourage the reader to refer to
chapter 6 of that draft RIA for the details of what is presented here
and encourage comments and supporting data and/or analysis regarding
those details. Of particular interest are comments regarding the costs
of precious metals, or platinum group metals (PGM). The PGM costs are a
significant fraction of the total costs for aftertreatment devices. For
our analysis, we have used the 2002 annual average costs for platinum
and rhodium (the two PGMs we expect will be used) because we believe
they represent a better estimate of the cost for PGM than other
metrics. We request comment on this approach and whether an alternative
approach would be more appropriate. Specifically, we request comment
regarding the use of a five year average in place of the one year
average we have used. Additionally, EPA invites comment on the impacts,
if any, that this rulemaking would have in the context of a variety of
rulemakings on the market impacts on precious metals.
i. NOX Adsorber System Costs
The NOX adsorber system that we are anticipating would
be applied for Tier 4 would be the same as that used for highway
applications. In order for the NOX adsorber to function
properly, a systems approach that includes a reductant metering system
and control of engine A/F ratio is also necessary. Many of the new air
handling and electronic system technologies developed in order to meet
the Tier 2/3 nonroad engine standards can be applied to accomplish the
NOX adsorber control functions as well. Some additional
hardware for exhaust NOX or O2 sensing and for
fuel metering will likely be required. The cost estimates include a DOC
for clean-up of hydrocarbon emissions that occur during NOX
adsorber regeneration events. We have also assumed that warranty costs
would increase due to the application of this new hardware. Chapter 6
of the draft RIA contains the details for how we estimated costs
associated with the new NOX control technologies required to
meet the proposed Tier 4 emission standards. These costs are estimated
to increase engine costs by roughly $670 in the near-term for a 150
horsepower engine, and $2,070 in the near-term for a 500 horsepower
engine. In the long-term, we estimate these costs to be $550 and $1,670
for the 150 horsepower and 500 horsepower engines, respectively. Note
that we have estimated costs for all engines in all horsepower ranges,
and these estimates are presented in detail in the draft RIA.
Throughout this discussion of engine and equipment costs, we present
costs for a 150 and a 500 horsepower engine for illustrative purposes.
ii. Catalyzed Diesel Particulate Filter (CDPF) Costs
CDPFs can be made from a wide range of filter materials including
wire mesh, sintered metals, fibrous media, or ceramic extrusions. The
most common material used for CDPFs for heavy-duty diesel engines is
cordierite. We have based our cost estimates on the use of silicon
carbide (SiC) even though it is more expensive than other filter
materials. We request comment on our assumption that SiC will be used
in favor of cordierite. We estimate that the CDPF systems will add $780
to engine costs in the near-team for a 150 horsepower engine and $2,770
in the near-term for a 500 horsepower engine. In the long-term, we
estimate these CDPF system costs to be $590 and $2,110 for the 150
horsepower and the 500 horsepower engines, respectively.
iii. CDPF Regeneration System Costs
Application of CDPFs in nonroad applications is expected to present
challenges beyond those of highway applications. For this reason, we
anticipate that some additional hardware beyond the diesel particulate
filter itself may be required to ensure that CDPF regeneration occurs.
For some engines this may be new fuel control strategies that force
regeneration under some circumstances, while in other engines it might
involve an exhaust system fuel injector to inject fuel upstream of the
CDPF to provide necessary heat for regeneration under some operating
conditions. We estimate the near-term costs of a CDPF regeneration
system to be $190 for a 150
[[Page 28444]]
horsepower engine and $320 for a 500 horsepower engine. In the long-
term, we estimate these costs at $140 and $240, respectively.
iv. Closed-Crankcase Ventilation System (CCV) Costs
We are proposing to eliminate the exemption that allows turbo-
charged nonroad diesel engines to vent crankcase gases directly to the
environment. Such engines are said to have an open crankcase system. We
project that this requirement to close the crankcase on turbo-charged
engines would force manufacturers to rely on engineered closed
crankcase ventilation systems that filter oil from the blow-by gases
prior to routing them into either the engine intake or the exhaust
system upstream of the CDPF. We have estimated the initial cost of
these systems to be roughly $40 for low horsepower engines and up to
$100 for very high horsepower engines. These costs are incurred only by
turbo-charged engines because today's naturally aspirated engines
already have CCV systems.
v. Variable Costs for Engines Below 75 Horsepower and Above 750
Horsepower
This proposal includes standards for engines <25 horsepower that
begin in 2008, and two sets of standards for 25 to 75 horsepower
engines--one set that begins in 2008 and another that begins in 2013.
The 2008 standards for all engines <75 horsepower are of similar
stringency and are expected to result in similar technologies (i.e.,
the addition of a DOC). The 2013 standards for 25 to 75 horsepower
engines are considerably more stringent than the 2008 standards and are
expected to force the addition of a CDPF along with some other engine
hardware to enable the proper functioning of that new technology. More
detail on the mix of technologies expected for all engines <75
horsepower is presented in section III. As discussed there, if changes
are needed to comply, we expect manufacturers to comply with the 2008
standards through either engine improvements or through the addition of
a DOC. From a cost perspective, we have projected that engines would
comply by either adding a DOC or by making some engine modifications
resulting in engine-out emission reductions. Presumably, the
manufacturer would choose the least costly approach that provided the
necessary reduction. If engine-out modifications are less costly than a
DOC, our estimate here is conservative. If the DOC proves to be less
costly, then our estimate is representative of what most manufacturers
would do. Therefore, we have assumed that, beginning in 2008, all
engines below 75 horsepower add a DOC. Note that this is a conservative
estimate in that we have assume this cost for all engines when, as
discussed in section IV, some engines <75 horsepower already meet the
proposed PM standards. We have estimated this added hardware to result
in an increased engine cost of $150 in the near-term and $140 in the
long-term for a 30 horsepower engine.
We have also projected that some engines in the 25 to 75 horsepower
range would have to upgrade their fuel systems to accommodate the CDPF.
We have estimated the incremental costs for these fuel systems at
roughly $740 in the 25-50 horsepower range, and around $430 in the 50-
75 horsepower range. This difference reflects a different base fuel
system, with the smaller engines assumed to have mechanical fuel
systems and the larger engines assumed to already be electronic. The
electronic systems will incur lower costs because they already have the
control unit and electronic fuel pump. Also, we have assumed these fuel
changes would occur for only direct injection (DI) engines; indirect
injection engines (IDI) are assumed to remain IDI but to add more
hardware as part of their CDPF regeneration system to ensure proper
regeneration under all operating conditions. Such a regeneration
system, described above, is expected to cost roughly twice that
expected for DI engines, or around $320 for a 30 horsepower IDI engine
versus $160 for a DI engine.
We have also projected that engines in the 25-50 horsepower range
would add cooled EGR to comply with their new NOX standard.
We have estimated that this would add $90 in the near-term and $70 in
the long-term to the cost of a 30 horsepower engine.
We believe there are factors that would cause variable hardware
costs to decrease over time, making it appropriate to distinguish
between near-term and long-term costs. Research in the costs of
manufacturing has consistently shown that as manufacturers gain
experience in production, they are able to apply innovations to
simplify machining and assembly operations, use lower cost materials,
and reduce the number or complexity of component parts.\289\ Our
analysis, as described in more detail in the draft RIA, incorporates
the effects of this learning curve by projecting that the variable
costs of producing the low-emitting engines decreases by 20 percent
starting with the third year of production. For this analysis, we have
assumed a baseline that represents such learning already having
occurred once due to the 2007 highway rule (i.e., a 20 percent
reduction in emission control device costs is reflected in our near-
term costs). We have then applied a single learning step from that
point in this analysis. We invite comment on this methodology to
account for the learning curve phenomenon and also request comment on
whether learning is likely to reduce costs even further in this
industry (e.g., should a second learning step be applied to our near-
term costs?). Additionally, manufacturers are expected to apply ongoing
research to make emission controls more effective and to have lower
operating costs over time. However, because of the uncertainty involved
in forecasting the results of this research, we conservatively have not
accounted for it in this analysis.
---------------------------------------------------------------------------
\289\ ``Learning Curves in Manufacturing,'' Linda Argote and
Dennis Epple, Science, February 23, 1990, Vol. 247, pp. 920-924.
---------------------------------------------------------------------------
c. Engine Operating Costs
We are projecting that a variety of new technologies will be
introduced to enable nonroad engines to meet the proposed Tier 4
emissions standards. Primary among these are advanced emission control
technologies and low-sulfur diesel fuel. The technology enabling
benefits of low-sulfur diesel fuel are described in section III, and
the incremental cost for low-sulfur fuel is described in section V.A.
The new emission control technologies are themselves expected to
introduce additional operating costs in the form of increased fuel
consumption and increased maintenance demands. Operating costs are
estimated in the draft RIA over the life of the engine and are
expressed in terms of cents/gallon of fuel consumed. In section V.C.3,
we present these lifetime operating costs as a net present value (NPV)
in 2001 dollars for several example pieces of equipment.
Total operating cost estimates include the following elements: the
change in maintenance costs associated with applying new emission
controls to the engines; the change in maintenance costs associated
with low sulfur fuel such as extended oil change intervals; the change
in fuel costs associated with the incrementally higher costs for low
sulfur fuel, and the change in fuel costs due to any fuel consumption
impacts associated with applying new emission controls to the engines.
This latter cost is attributed to the CDPF and its need for periodic
regeneration which we estimate may result in a one percent fuel
consumption increase where a NOX
[[Page 28445]]
adsorber is also applied, or a two percent fuel consumption increase
where no NOX adsorber is applied (refer to chapter 6,
section 6.2.3.3). Maintenance costs associated with the new emission
controls on the engines are expected to increase since these devices
represent new hardware and, therefore, new maintenance demands. For
CDPF maintenance, we have used a maintenance interval of 3,000 hours
for smaller engines and 4,500 hours for larger engines and a cost of
$65 through $260 for each maintenance event. For closed-crankcase
ventilation (CCV) systems, we have used a maintenance interval of 675
hours for all engines and a cost per maintenance event of $8 to $48 for
small to large engines. Offsetting these maintenance cost increases
would be a savings due to an expected increase in oil change intervals
because low sulfur fuel would be far less corrosive than is current
nonroad diesel fuel. Less corrosion would mean a slower acidification
rate (i.e., less degradation) of the engine lubricating oil and,
therefore, more operating hours between needed oil changes. As
discussed in section V.B, the use of 15 ppm sulfur fuel can extend oil
change intervals by as much as 35 percent for both new and existing
nonroad engines and equipment. We have used a 35 percent increase in
oil change interval along with costs per oil change of $70 through $400
to arrive at estimated savings associated with increased oil change
intervals.
These operating costs are expressed as a cent/gallon cost (or
savings). As a result, operating costs are directly proportional to the
amount of fuel consumed by the engine. We have estimated these
operating costs, inclusive of fuel-related costs, to be 3.4 cents/
gallon for a 150 horsepower engine and 4.2 cents/gallon for a 500
horsepower engine. More detail on operating costs can be found in
chapter 6 of the draft RIA.
The existing fleet will also benefit from lower maintenance costs
due to the use of low sulfur diesel fuel. The operating costs for the
existing fleet are discussed in Section V.B.
2. Equipment Cost Impacts
In addition to the costs directly associated with engines that
incorporate new emission controls to meet new standards, we expect cost
increases due to the need to redesign the nonroad equipment in which
these engines are used. Such redesigns would probably be necessary due
to the expected addition of new emission control systems, but could
also occur if the engine has a different shape or heat rejection rate,
or is no longer made available in the configuration previously used.
Based on their past experiences, equipment manufacturers have told EPA
that a major concern with a new standard is their ability to redesign a
large number of applications in a short period of time. Therefore, we
have provided equipment manufacturers transition flexibility provisions
to help them avoid business disruptions resulting from the changes
associated with new emission standards. These flexibility provisions
are presented in detail in Section III.E.4.
In assessing the economic impact of the new emission standards, EPA
has made a best estimate of the modifications to equipment that relate
to packaging (installing engines in equipment engine compartments). The
incremental costs for new equipment would be comprised of fixed costs
(for redesign to accommodate new emission control devices) and variable
costs (for new equipment hardware and for labor to install new emission
control devices). Note that the fixed costs do not include
certification costs, as did the engine fixed costs, because equipment
is not certified to emission standards. We have attributed all changes
in operating costs (e.g., additional maintenance) to the cost estimates
for engines. Included in section V.C.3 is a discussion of several
example pieces of equipment (e.g., skid/steer loader, dozer, etc.) and
the costs we have estimated for these specific example pieces of
equipment. Full details of our equipment cost analysis can be found in
chapter 6 of the draft RIA. All costs are presented in 2001 dollars.
a. Equipment Fixed Costs
The most significant changes anticipated for equipment redesign are
changes to accommodate the physical changes to engines, especially for
those engines that add PM traps and NOX adsorbers. The costs
for engine development and the emission control devices are included as
costs to the engines, as described above. What remains to be quantified
for equipment manufacturers is the effort to integrate the engine and
emissions control devices into the overall functioning of the
equipment. What remains to be quantified for equipment manufacturers is
the effort to integrate the engine and emissions control devices into
the overall functioning of the equipment. We have allocated extensive
engineering time for this effort.
The costs we have estimated are based on engine power and whether
an application is non-motive (e.g., a generator set) or motive (e.g., a
skid steer loader). The designs we have considered to be non-motive are
those that lack a propulsion system. In addition, the proposed emission
standards for engines rated under 25 horsepower and the proposed 2008
standards for 25-75 horsepower engines are projected to require no
significant equipment redesign beyond that done to accommodate the Tier
2 standards. We expect that these engines would comply with the
proposesd Tier 4 standards through either engine modifications to
reduce engine-out emissions or through the addition of a DOC. We have
projected that engine modifications would not affect the outer
dimensions of the engine and that a DOC would replace the existing
muffler. Therefore, either approach taken by the engine manufacturer
should have minimal to no impact on the equipment design. Nonetheless,
we have conservatively estimated their redesign costs at $50,000 per
model.
A number of equipment manufacturers have shared detailed
information with us regarding the investments made for Nonroad Tier 2
equipment redesign efforts, as well as redesign estimates for
significant changes such as installing a new engine design. These
estimates range from approximately $50,000 for some lower powered
equipment models to well over $1 million dollars for high horsepower
equipment with very challenging design constraints. Based on that
input, for the proposed Tier 4 standards, we have estimated that
equipment redesign costs would range from $50,000 per model for 25
horsepower equipment up to $750,000 per model for 300 horsepower
equipment and above. We have attributed only a portion of the equipment
redesign costs to U.S. sales in a manner consistent with that taken for
engine R&D costs and engine tooling costs. In addition, we expect
manufacturers to incur some fixed costs to update service and operation
manuals to address the maintenance demands of new emission control
technologies and the new oil service intervals which we estimate to be
between $2,500 and $10,000 per equipment model.
These equipment fixed costs (redesign and manual updates) were then
allocated appropriately to each new model to arrive at a total
equipment fixed cost of $697 million. We have assumed that these costs
would be recovered over a ten year period at a seven percent interest
rate.
b. Equipment Variable Costs
Equipment variable cost estimates are based on costs for additional
materials to mount the new hardware (i.e., brackets and bolts required
to secure the
[[Page 28446]]
aftertreatment devices) and additional sheet metal assuming that the
body cladding of a piece of equipment (i.e., the hood) might change to
accommodate the aftertreatment system. Variable costs also include the
labor required to install these new pieces of hardware. For engines
75 horsepower--those expected to incorporate CDPF and
NOX adsorber technology--the amount of sheet metal is based
on the size of the aftertreatment devices.
For equipment of 150 horsepower and 500 horsepower, respectively,
we have estimated the costs to be roughly $60 to $140. Note that we
have estimated costs for equipment in all horsepower ranges, and these
estimates are presented in detail in the draft RIA. Throughout this
discussion of engine and equipment costs, we present costs for a 150
and a 500 horsepower engine for illustrative purposes.
3. Overall Engine and Equipment Cost Impacts
To illustrate the engine and equipment cost impacts we are
estimating for the proposed standards, we have chosen several example
pieces of equipment and presented the estimated costs for them. Using
these examples, we can calculate the costs for a specific piece of
equipment in several horsepower ranges and better illustrate the cost
impacts of the proposed standards. These costs along with information
about each example piece of equipment are shown in Table V.C-1. Costs
presented are near-term and long-term costs for the final standards to
which each piece of equipment would comply. Long-term costs are only
variable costs and, therefore, represent costs after all fixed costs
have been recovered and all projected learning has taken place.
Included in the table are estimated prices for each piece of equipment
to provide some perspective on how our estimated control costs relate
to existing equipment prices.
Table V.C-1--Near-Term and Long-Term Costs for Several Example Pieces of Equipmenta
($2001, for the final emission standards to which the equipment must comply)
--------------------------------------------------------------------------------------------------------------------------------------------------------
Skid/steer Off-highway
GenSet loader Backhoe Dozer Ag tractor Dozer truck
--------------------------------------------------------------------------------------------------------------------------------------------------------
Horsepower 9 hp 33 hp 76 hp 175 hp 250 hp 503 hp 1,000 hp
Incremental engine & equipment cost
Long-term $120 $760 $1,210 $2,590 $2,000 $4,210 $6,780
Near-term $170 $1,100 $1,680 3,710 $2,950 $6,120 $10,100
Estimated equipment price when new b $3,500 $13,500 $50,000 $235,000 $130,000 $575,000 $700,000
Incremental operating costs c -$90 $40 $370 $1,550 $1,320 $4,950 $12,550
Baseline operating costs (fuel & oil $940 $2,680 $7,960 $77,850 $23,750 $77,850 $179,530
only) c
--------------------------------------------------------------------------------------------------------------------------------------------------------
Notes:
a Near-term costs include both variable costs and fixed costs; long-term costs include only variable costs and represent those costs that remain
following recovery of all fixed costs.
b ``Estimated Price of New Nonroad Example Equipment,'' memorandum from Zuimdie Guerra to docket A-2001-28.
c Present value of lifetime costs.
More detail and discussion regarding what these costs and prices
mean from an economic impact perspective can be found in section V.E.
D. Annual Costs and Cost Per Ton
One tool that can be used to assess the value of the proposed
standards for nonroad fuel and engines is the costs incurred per ton of
emissions reduced. This analysis involves a comparison of our proposed
program to other measures that have been or could be implemented.
We have calculated the cost per ton of our proposed program based
on the net present value of all costs incurred and all emission
reductions generated over a 30 year time window following
implementation of the program. This approach captures all of the costs
and emissions reductions from our proposed program including those
costs incurred and emissions reductions generated by the existing
fleet. The baseline (i.e., the point of comparison) for this evaluation
is the existing set of fuel and engine standards (i.e., unregulated
fuel and the Tier 2/Tier 3 program). The 30 year time window chosen is
meant to capture both the early period of the program when very few new
engines that meet the proposed standards would be in the fleet, and the
later period when essentially all engines would meet the proposed
standards.
As discussed in section IV, the proposal contains two separate fuel
programs. We are proposing a 500 ppm sulfur cap on nonroad, locomotive,
and marine fuels beginning in 2007. This fuel program, the first step
in our two step fuel program, provides significant air quality benefits
through reduced SO2 and PM emissions from both new and
existing nonroad, locomotive, and marine engines. In sections V.D.1 and
2, we summarize the cost for this program as if it remained in place
for 30 years, even though it would be supplanted by the second step of
our fuel program in 2010. We also provide an analysis of the cost per
ton for the SO2 reductions that would be realized by the 500
ppm fuel program for the same 30 year time window. In this way, the
cost per ton of the SO2 reductions realized by the 500 ppm
fuel program can be compared to other available means to control
SO2 emissions. The significant PM reductions are not
accounted for in the relative cost per ton estimate, but are accounted
for in our inventory analysis presented in section II and in the
benefits analysis presented later in this section. Additional detail
regarding all of the estimates presented here are available in the
draft RIA.
We are proposing a second step in the fuel program that would cap
nonroad fuel sulfur levels at 15 ppm beginning in 2010. This fuel
program enables the introduction of advanced emission control
technologies including CDPFs and NOX adsorbers. The
combination of the two-step fuel program and the new diesel engine
standards represents the total Tier 4 program for nonroad diesel
engines and fuel proposed today. In sections V.D.3 and 4, we present
our estimate of the annual and total costs for
[[Page 28447]]
this complete program beginning in 2007 and continuing for 30 years.
Also included is an estimate of the cost per ton of emissions
reductions realized by this program for NMHC+NOX, PM, and
SO2.
1. Annual Costs for the 500 ppm Fuel Program
Cent per gallon costs for the proposed 500 ppm fuel program (i.e.,
the reduction to a 500 ppm sulfur cap) were presented in section V.A.
Having this fuel would result in maintenance savings associated with
increased oil change intervals for both the new and the existing fleet
of nonroad, locomotive, and marine engines. These maintenance savings
were discussed in section V.B. There are no engine and equipment costs
associated with the 500 ppm fuel program because new emission standards
are not part of that proposed program. Figure V.D-1 shows the annual
costs associated with the 500 ppm fuel program.
As can be seen in Figure V.D-1, the costs for refining and
distributing the 500 ppm fuel range from $250 million in 2008 to nearly
$400 million in 2036. These control costs are largely offset by the
maintenance savings that range from $200 million in 2008 to $380
million in 2036. Despite the fact that the costs of the 500 ppm fuel
for nonroad diesel fuel is 2.5 cents/gallon and the maintenance savings
are 3 cents per gallon, the net costs are positive because of the costs
for the locomotive and marine fuel is not off-set by the maintenance
savings. As a whole, the net cost of the program in each year is
essentially zero, ranging from $50 million in the early years to only
$18 million in 2036. The net present value of the net costs and savings
associated with the proposed 500 ppm fuel program during the years 2007
to 2036 is estimated at $510 million.
[GRAPHIC] [TIFF OMITTED] TP23MY03.009
2. Cost Per Ton for the 500 ppm Fuel Program
The 2007 fuel program would result in large reductions of both
SO2 and PM emissions. Roughly 98 percent of fuel sulfur is
converted to SO2 in the engine with the remaining two
percent being exhausted as sulfate PM. Because the majority of the
emissions reductions associated with this program would be
SOX, we have attributed all the control costs to
SOX in calculating the cost per ton associated with this
program. However, we have modeled both the SOX and PM
reductions so that our inventory and benefits analysis fully account
for them.
As noted above, we have calculated both the costs and emission
reductions of the 500 ppm fuel program as if it were to remain in place
indefinitely. Figure V.D-1 shows the costs in each year of the program,
the net present value of which is estimated at $510 million. We have
estimated the 30 year net present value of the SOX emission
reductions at 5.6 million tons.
Table V.D-1 shows the cost per ton of emissions reduced as a result
of the proposed 500 ppm fuel program. The cost per ton numbers include
costs and emission reductions that would occur from both the new and
the existing fleet (i.e., those pieces of nonroad equipment that were
sold into the market prior to the proposed emission standards) of
[[Page 28448]]
nonroad, locomotive, and marine engines.
Table V.D-1--500 ppm Fuel Program Aggregate Cost per Ton and Long-Term
Annual Cost per Ton ($2001)
------------------------------------------------------------------------
2004-2036
Discounted Long-term
Pollutant lifetime cost per
cost per ton in 2036
ton
------------------------------------------------------------------------
SOX........................................... $90 $50
------------------------------------------------------------------------
We also considered the cost per ton of the 500 ppm fuel program
without taking credit for the expected maintenance savings associated
with low sulfur fuel. Without the maintenance savings, the cost per ton
of SOX reduced would be $990 per ton for each year of the
program. More detail on how the costs and cost per ton numbers
associated with the 500 ppm fuel program were calculated can be found
in the draft RIA.
3. Annual Costs for the Proposed Two-Step Fuel Program and Engine
Program
The costs of the total proposed engine and fuel program include
costs associated with both steps in the fuel program--the reduction to
500 ppm sulfur in 2007 and the reduction to 15 ppm sulfur in 2010. Also
included are costs for the proposed 2008 engine standards for <75
horsepower engines, the proposed 2013 standards for 25 to 75 horsepower
engines, and costs for the proposed engine standards for 75
horsepower engines. Included are all maintenance costs and savings
realized by both the existing fleet (nonroad, locomotive, and marine)
and the new fleet of engines complying with the proposed standards.
Figure V.D-2 presents these results. All capital costs for fuel
production and engine and equipment fixed costs have been amortized.
The figure shows that total annual costs are estimated to be $120
million in the first year the new engine standards apply, increasing to
a peak of $1.7 billion in 2036 as increasing numbers of engines become
subject to the new standards and an ever increasing amount of fuel is
consumed. The net present value of the annualized costs over the period
from 2007 to 2036 is $20.7 billion.
[GRAPHIC] [TIFF OMITTED] TP23MY03.010
4. Cost per Ton of Emissions Reduced for the Total Program
We have calculated the cost per ton of emissions reduced associated
with the proposed engine and fuel program. We have done this using the
net present value of the annualized costs of the program through 2036
and the net present value of the annual emission reductions through
2036. We have also calculated the cost per ton of emissions in the year
2036 using the annual costs
[[Page 28449]]
and emission reductions in that year alone. This number represents the
long-term cost per ton of emissions reduced after all fixed costs of
the program have been recovered by industry leaving only the variable
costs of control. The cost per ton numbers include costs and emission
reductions that would occur from the existing fleet (i.e., those pieces
of nonroad equipment that were sold into the market prior to the
proposed emission standards). These results are shown in Table V.D-2.
We did the cost analysis using a 3% discount rate. We will also be
conducting a similar analysis using a 7% discount rate and including
this information in the docket.
Table V.D-2--Total Proposed Fuel and Engine Program Aggregate Cost per
Ton and Long-Term Annual Cost Per Ton ($2001)
------------------------------------------------------------------------
2004-2036
Discounted Long-term
Pollutant lifetime cost per
cost per ton in 2036
ton
------------------------------------------------------------------------
NOX+NMHC...................................... $810 $530
PM............................................ 8,700 6,900
SOX........................................... \a\ 200 170
------------------------------------------------------------------------
Notes:
\a\ This result does not match that in Table 8.4-2 because the nonroad
portion of the fuel is reduced to 15 ppm and does not stay at 500
(locomotive and marine portions are kept at 500ppm). The costs to
reduce fuel sulfur from uncontrolled to 15ppm were assigned 50/50 to
NOX+NMHC and PM for the reduction to 15 ppm is to enable
aftertreatment technology.
5. Comparison With Other Means of Reducing Emissions
In comparison with other programs to control these pollutants, we
believe that the proposed programs represent a cost effective strategy
for generating substantial NOX+NMHC, PM, and SO2
reductions. This can be seen by comparing the 2007 fuel program (i.e.,
a sulfur cap of 500 ppm) cost per ton and the total program cost per
ton with a number of standards that EPA has adopted in the past. Table
V.D-3 summarizes the cost per ton of several past EPA actions for
NOX+NMHC. Table V.D-4 summarizes the cost per ton of several
past EPA actions for PM.
Table V.D-3--Cost per Ton of Previous Mobile Source Programs for NOX +
NMHC
------------------------------------------------------------------------
Program $/ton
------------------------------------------------------------------------
Tier 2 Nonroad Diesel................................... 630
Tier 3 Nonroad Diesel................................... 430
Tier 2 vehicle/gasoline sulfur.......................... 1,410-2,370
2007 Highway HD......................................... 2,260
2004 Highway HD......................................... 220-430
Off-highway diesel engine............................... 450-710
Tier 1 vehicle.......................................... 2,160-2,930
NLEV.................................................... 2030
Marine SI engines....................................... 1,230-1,940
On-board diagnostics.................................... 2,430
Marine CI engines....................................... 30-190
------------------------------------------------------------------------
Note: Costs adjusted to 2001 dollars using the Producer Price Index for
Total Manufacturing Industries.
Table V.D-4.--Cost per Ton of Previous Mobile Source Programs for PM
------------------------------------------------------------------------
Program $/ton
------------------------------------------------------------------------
Tier 1/Tier 2 Nonroad Diesel........................... 2,410
2007 Highway HD........................................ 14,280
Marine CI engines...................................... 5,480-4,070
1996 urban bus......................................... 12,870-20,590
Urban bus retrofit/rebuild............................. 31,740
1994 highway HD diesel................................. 21,930-25,670
------------------------------------------------------------------------
Note: Costs adjusted to 2001 dollars using the Producer Price Index for
Total Manufacturing Industries.
To compare the cost per ton of SO2 emissions reduced, we
looked at the cost per ton for the Title IV SO2 trading
programs. This information is found in EPA report 430/R-02-004,
``Documentation of EPA Modeling Applications (V.2.1) Using the
Integrated Planning Model'', in Figure 9.11 on page 9-14 (www.epa.gov/
airmarkets/epa-ipm/index.html#documentation). The SO2 cost
per ton results of the proposed program presented in Table V.D-2
compare very favorably with the program shown in Table V.D-5.
Table V.D-5--Cost per Ton of SO2 From EPA Base Case 2000 for the Title
IV SO2 Trading Programs
------------------------------------------------------------------------
Program $/ton
------------------------------------------------------------------------
Title IV SO2 Trading Programs............. $490 in 2010 to $610 in
2020.
------------------------------------------------------------------------
Note: Costs adjusted to 2001 dollars using the Producer Price Index for
Total Manufacturing Industries.
E. Do the Benefits Outweigh the Costs of the Standards?
Our analysis of the health and welfare benefits to be expected from
this proposal are presented in this section. Briefly, the analysis
projects major benefits throughout the period from initial
implementation of the rule through 2030, the last year analyzed. As
described below, thousands of deaths and other serious health effects
would be prevented, yielding a net present value in 2004 of those
benefits we could monetize of approximately $550 billion dollars. These
benefits exceed the net present value of the social cost of the
proposal ($17 billion) by a factor of over 30 to one.
1. What Were the Results of the Benefit-Cost Analysis?
Table V.E-1 presents the primary estimate of reduced incidence of
PM-related health effects for the years 2020 and 2030. In interpreting
the results, it is important to keep in mind the limited set of effects
we are able to monetize. Specifically, the table lists the PM-related
benefits associated with the reduction of several health effects.\290\
In 2030, we estimate that there will be 9,600 fewer fatalities per year
associated with fine PM, and the rule will result in about 5,700 fewer
cases of chronic bronchitis, 8,300 fewer hospitalizations (for
respiratory and cardiovascular disease combined), and result in
significant reductions in days of restricted activity due to
respiratory illness (with an estimated 5.7 million fewer cases). We
also estimate substantial health improvements for children from reduced
upper and lower respiratory illness, acute bronchitis, and asthma
attacks.\291\
---------------------------------------------------------------------------
\290\ Based upon recent preliminary findings by the Health
Effects Institute, the concentration-response functions used to
estimate reductions in hospital admissions may over or underestimate
the true concentration-response relationship. See letter from Dan
Greenberg, President, Health Effects Institute, May 30, 2002,
attached to letter from Dr. Hopke, dated August 8, 2002. Docket A-
2000-01, Document IV-A-145.
\291\ Our estimate incorporates significant reductions of
150,000 fewer cases of lower respiratory symptoms in children ages 7
to 14 each year, 110,000 fewer cases of upper respiratory symptoms
(similar to cold symptoms) in asthmatic children each year, and
14,000 fewer cases of acute bronchitis in children ages 8 to 12 each
year. In addition, we estimate that this rule will reduce almost
6,000 emergency room visits for asthma attacks in children each year
from reduced exposure to particles. Additional incidents would be
avoided from reduced ozone exposures. Asthma is the most prevalent
chronic disease among children and currently affects over seven
percent of children under 18 years of age.
---------------------------------------------------------------------------
Table V.E-2 presents the total monetized benefits for the years
2020 and 2030. This table also indicates with a ``B'' those additional
health and environmental effects which we were unable to quantify or
monetize. These effects are additive to estimate of total benefits, and
EPA believes there is
[[Page 28450]]
considerable value to the public of the benefits that could not be
monetized. A full listing of the benefit categories that could not be
quantified or monetized in our estimate are provided in Table V.E-5.
In summary, EPA's primary estimate of the benefits of the rule are
approximately $81 + B billion in 2030. In 2020, total monetized
benefits are approximately $43 + B billion. These estimates account for
growth in real gross domestic product (GDP) per capita between the
present and the years 2020 and 2030. As the table indicates, total
benefits are driven primarily by the reduction in premature fatalities
each year, which account for over 90 percent of total benefits.
Table V.E-1.--Reductions in Incidence of PM-Related Adverse Health
Effects Associated With the Proposed Nonroad Diesel Engine and Fuel
Standards
------------------------------------------------------------------------
Avoided incidence \a\ (cases/
year)
Endpoint -------------------------------
2020 2030
------------------------------------------------------------------------
Premature mortality \b\--Base estimate: 5,200 9,600
Long-term exposure (adults, 30 and
over)..................................
Chronic bronchitis (adults, 26 and over) 3,600 5,700
Non-fatal myocardial infarctions 9,200 16,000
(adults, 18 and older).................
Hospital admissions--Respiratory 2,400 4,500
(adults, 20 and older) \c\.............
Hospital admissions--Cardiovascular 1,900 3,800
(adults, 20 and older) \d\.............
Emergency Room Visits for Asthma (18 and 3,600 5,700
younger)...............................
Acute bronchitis (children, 8-12)....... 8,400 14,000
Lower respiratory symptoms (children, 7- 92,000 150,000
14)....................................
Upper respiratory symptoms (asthmatic 77,000 110,000
children, 9-11)........................
Work loss days (adults, 18-65).......... 650,000 960,000
Minor restricted activity days (adults, 3,900,000 5,700,000
age 18-65).............................
------------------------------------------------------------------------
Notes:
\a\ Incidences are rounded to two significant digits.
\b\ Premature mortality associated with ozone is not separately included
in this analysis
\c\ Respiratory hospital admissions for PM includes admissions for COPD,
pneumonia, and asthma.
\d\ Cardiovascular hospital admissions for PM includes total
cardiovascular and subcategories for ischemic heart disease,
dysrhythmias, and heart failure.
Table V.E-2.--EPA Primary Estimate of the Annual Quantified and
Monetized Benefits Associated With Improved PM Air Quality Resulting
From the Proposed Nonroad Diesel Engine and Fuel Standards
------------------------------------------------------------------------
Monetary Benefits\a,\ \b\
(millions 2000$, adjusted for
Endpoint income growth)
-------------------------------
2020 2030
------------------------------------------------------------------------
Premature mortality \c\ Long-term $39,000 $74,000
exposure (adults, 30 and over).........
Chronic bronchitis (WTP valuation; 1,600 2,600
adults, 26 and over)...................
Non-fatal myocardial infarctions........ 750 1,300
Hospital Admissions from Respiratory 38 74
Causes \d\.............................
Hospital Admissions from Cardiovascular 40 80
Causes \e\.............................
Emergency Room Visits for Asthma........ 1 2
Acute bronchitis (children, 8-12)....... 3 5
Lower respiratory symptoms (children, 7- 2 3
14)....................................
Upper respiratory symptoms (asthmatic 2 3
children, 9-11)........................
Work loss days (adults, 18-65).......... 90 130
Minor restricted activity days (adults, 210 320
age 18-65).............................
Recreational visibility (86 Class I 1,200 1,900
Areas).................................
-----------------
Total Monetized Benefits \f\........ 43,000 + B 81,000 + B
------------------------------------------------------------------------
Notes:
\a\ Monetary benefits are rounded to two significant digits.
\b\ Monetary benefits are adjusted to account for growth in real GDP per
capita between 1990 and the analysis year (2020 or 2030).
\c\ Valuation assumes the 5 year distributed lag structure described
earlier. Results reflect the use of two different discount rates; a 3%
rate which is recommended by EPA's Guidelines for Preparing Economic
Analyses (US EPA, 2000a), and 7% which is recommended by OMB Circular
A-94 (OMB, 1992).
\d\ Respiratory hospital admissions for PM includes admissions for COPD,
pneumonia, and asthma.
\e\ Cardiovascular hospital admissions for PM includes total
cardiovascular and subcategories for ischemic heart disease,
dysrhythmias, and heart failure.
\f\ B represents the monetary value of the unmonetized health and
welfare benefits. A detailed listing of unquantified PM, ozone, CO,
and NMHC related health effects is provided in Table V.E-5.
The estimated social cost (measured as changes in consumer and
producer surplus) in 2030 to implement the final rule from Table V.F-2
is $1.5 billion (2000$). Thus, the net benefit (social benefits minus
social costs) of the program at full implementation is approximately
$79 + B billion. In 2020, partial implementation of the program yields
net benefits of $42 + B billion. Therefore, implementation of the final
rule is expected to provide society with a net gain in social welfare
based on economic efficiency criteria. Table V.E-3 presents a summary
of the benefits,
[[Page 28451]]
costs, and net benefits of the proposed rule. Figure VE.1 displays the
stream of benefits, costs, and net benefits of the Nonroad Land-based
Diesel Vehicle Rule from 2007 to 2030. In addition, Table V-E.4
presents the net present value of the stream of benefits, costs, and
net benefits associated with the rule for this 23 year period (using a
three percent discount rate). The total net present value in 2004 of
the stream of net benefits (benefits minus costs) is $530 billion.
Table V.E-3.--Summary of Benefits, Costs, and Net Benefits of the Proposed Nonroad Diesel Engine and Fuel
Standards
----------------------------------------------------------------------------------------------------------------
2020 \a\ (billions of 2000 2030 \a\ (billions of 2000
dollars) dollars)
----------------------------------------------------------------------------------------------------------------
Social Costs \b\...................... $1.4............................... $1.5.
Social Benefits \b,\ \c,\ \d\:
CO, VOC, Air Toxic-related Not monetized...................... Not monetized.
benefits.
Ozone-related benefits............ Not monetized...................... Not monetized.
PM-related Welfare benefits....... $1.2............................... $1.9.
PM-related Health benefits........ $42+ B............................. $79 + B.
Net Benefits (Benefits-Costs) \c\. $42 + B............................ $79 + B.
----------------------------------------------------------------------------------------------------------------
Notes:
\a\ All costs and benefits are rounded to two significant digits.
\b\ Note that costs are the total costs of reducing all pollutants, including CO, VOCs and air toxics, as well
as NOX and PM. Benefits in this table are associated only with PM, NOX and SO3 reductions.
\c\ Not all possible benefits or disbenefits are quantified and monetized in this analysis. Potential benefit
categories that have not been quantified and monetized are listed in Table V.E-5. B is the sum of all
unquantified benefits and disbenefits.
[[Page 28452]]
[GRAPHIC] [TIFF OMITTED] TP23MY03.011
Table V.E-4.--Net Present Value in 2004 of the Stream of Benefits,
Costs, and Net Benefits for the Proposed Nonroad Diesel Engine and Fuel
Standards
[Billions of 2000$]
------------------------------------------------------------------------
------------------------------------------------------------------------
Social Costs............................................ $17
Social Benefits......................................... 550
Net Benefits............................................ \a\ 530
------------------------------------------------------------------------
Notes:
\a\ Numbers do not add due to rounding.
2. What Was Our Overall Approach to the Benefit-Cost Analysis?
The basic question we sought to answer in the benefit-cost analysis
was, ``What are the net yearly economic benefits to society of the
reduction in mobile source emissions likely to be achieved by this
proposed rulemaking?'' In designing an analysis to address this
question, we selected two future years for analysis (2020 and 2030)
that are representative of the stream of benefits and costs at partial
and full-implementation of the program.
To quantify benefits, we evaluated PM-related health effects
(including directly emitted PM, SO3, and NOX
contributions to fine particulate matter). Our approach requires the
estimation of changes in air quality expected from the rule and then
estimating the resulting impact on health. In order to characterize the
benefits of today's action, given the constraints on time and resources
available for the analysis, we adopted a benefits transfer technique
that relies on air quality and benefits modeling for a preliminary
control option for nonroad diesel engines and fuels. Results from the
modeled preliminary control option in 2020 and 2030 are then scaled and
transferred to the emission reductions expected from the proposed rule.
We also transferred modeled results by using scaling factors associated
with time to examine the stream of benefits in years other than 2020
and 2030.
More specifically, our health benefits assessment is conducted in
two phases. Due to the time requirements for running the sophisticated
emissions and air quality models needed to obtain estimates of the
benefits expected to result from implementation of the rule, it is
often necessary to select an example set of emission reductions to use
for the purposes of emissions and air quality modeling. In phase one,
we evaluate the PM and ozone related health effects associated with a
modeled preliminary control option that was a close approximation of
the proposed standards in the years 2020 and 2030. Using information
from the modeled preliminary control option on the changes in ambient
concentrations of PM and ozone, we then conduct a
[[Page 28453]]
health assessment to estimate the number of reduced incidences of
illnesses, hospitalizations, and premature fatalities associated with
this scenario and estimate the total economic value of these health
benefits. The standards we are proposing in this rulemaking, however,
are slightly different in the amount of emission reductions expected to
be achieved in 2020 and 2030 relative to the modeled scenario. Thus, in
phase two of the analysis we apportion the results of the phase one
analysis to the underlying NOX, SO3, and PM
emission reductions and scale the apportioned benefits to reflect
differences in emissions reductions between the modeled preliminary
control option and the proposed standards. The sum of the scaled
benefits for the PM, SO3, and NOX emission
reductions provide us with the total benefits of the rule.
The benefit estimates derived from the modeled preliminary control
option in phase one of our analysis uses an analytical structure and
sequence similar to that used in the benefits analyses for the Heavy
Duty Engine/Diesel Fuel final rule and in the ``section 812 studies''
to estimate the total benefits and costs of the full Clean Air
Act.\292\ We used many of the same models and assumptions used in the
Heavy Duty Engine/Diesel Fuel analysis as well as other Regulatory
Impact Analyses (RIAs) prepared by the Office of Air and Radiation. By
adopting the major design elements, models, and assumptions developed
for the section 812 studies and other RIAs, we have largely relied on
methods which have already received extensive review by the independent
Science Advisory Board (SAB), by the public, and by other federal
agencies. In addition, we will be working through the next section 812
study process to enhance our methods.\293\ Interested parties will
therefore be able to obtain further information from the section 812
study on the kinds of methods we are likely to use for estimating
benefits and costs in the final nonroad diesel rule.
---------------------------------------------------------------------------
\292\ The section 812 studies include: (1) US EPA, Report to
Congress: The Benefits and Costs of the Clean Air Act, 1970 to 1990,
October 1997 (also known as the ``Section 812 Retrospective
Report''); and (2) the first in the ongoing series of prospective
studies estimating the total costs and benefits of the Clean Air Act
(see EPA report number: EPA-410-R-99-001, November 1999). See Docket
A-99-06, Document II-A-21.
\293\ We anticipate a public SAB meeting June 11-13, 2003, in
Washington, DC, regarding components of our analytical blueprint.
Interested parties may want to consult the Web page: http://
www.epa.gov/science1.
---------------------------------------------------------------------------
The benefits transfer method used in phase two of the analysis is
similar to that used to estimate benefits in the recent analysis of the
Nonroad Large Spark-Ignition Engines and Recreational Engines standards
(67 FR 68241, November 8, 2002). A similar method has also been used in
recent benefits analyses for the proposed Industrial Boilers and
Process Heaters NESHAP and the Reciprocating Internal Combustion
Engines NESHAP.
On September 26, 2002, the National Academy of Sciences (NAS)
released a report on its review of the Agency's methodology for
analyzing the health benefits of measures taken to reduce air
pollution. The report focused on EPA's approach for estimating the
health benefits of regulations designed to reduce concentrations of
airborne particulate matter (PM).
In its report, the NAS said that EPA has generally used a
reasonable framework for analyzing the health benefits of PM-control
measures. It recommended, however, that the Agency take a number of
steps to improve its benefits analysis. In particular, the NAS stated
that the Agency should:
[sbull] Include benefits estimates for a range of regulatory
options;
[sbull] Estimate benefits for intervals, such as every five years,
rather than a single year;
[sbull] Clearly state the projected baseline statistics used in
estimating health benefits, including those for air emissions, air
quality, and health outcomes;
[sbull] Examine whether implementation of proposed regulations
might cause unintended impacts on human health or the environment;
[sbull] When appropriate, use data from non-U.S. studies to broaden
age ranges to which current estimates apply and to include more types
of relevant health outcomes;
[sbull] Begin to move the assessment of uncertainties from its
ancillary analyses into its Base analyses by conducting probabilistic,
multiple-source uncertainty analyses. This assessment should be based
on available data and expert judgment.
Although the NAS made a number of recommendations for improvement
in EPA's approach, it found that the studies selected by EPA for use in
its benefits analysis were generally reasonable choices. In particular,
the NAS agreed with EPA's decision to use cohort studies to derive
benefits estimates. It also concluded that the Agency's selection of
the American Cancer Society (ACS) study for the evaluation of PM-
related premature mortality was reasonable, although it noted the
publication of new cohort studies that should be evaluated by the
Agency.
EPA has addressed many of the NAS comments in our analysis of the
proposed rule. We provide benefits estimates for each year over the
rule implementation period for a wide range of regulatory alternatives,
in addition to our proposed emission control program. We use the
estimated time path of benefits and costs to calculate the net present
value of benefits of the rule. In the RIA, we provide baseline
statistics for air emissions, air quality, population, and health
outcomes. We have examined how our benefits estimates might be impacted
by expanding the age ranges to which epidemiological studies are
applied, and we have added several new health endpoints, including non-
fatal heart attacks, which are supported by both U.S. studies and
studies conducted in Europe. We have also improved the documentation of
our methods and provided additional details about model assumptions.
Several of the NAS recommendations addressed the issue of
uncertainty and how the Agency can better analyze and communicate the
uncertainties associated with its benefits assessments. In particular,
the Committee expressed concern about the Agency's reliance on a single
value from its analysis and suggested that EPA develop a probabilistic
approach for analyzing the health benefits of proposed regulatory
actions. The Agency agrees with this suggestion and is working to
develop such an approach for use in future rulemakings. EPA plans to
hold a meeting of its Science Advisory Board (SAB) in early Summer 2003
to review its plans for addressing uncertainty in its analyses. Our
likely approach will incorporate short-term elements intended to
provide interim methods in time for the final Nonroad rule to address
uncertainty in important analytical parameters such as the
concentration-response relationship for PM-related premature mortality.
Our approach will also include longer-term elements intended to provide
scientifically sound, peer-reviewed characterizations of the
uncertainty surrounding a broader set of analytical parameters and
assumptions, including but not limited to emissions and air quality
modeling, demographic projections, population health status,
concentration-response functions, and valuation estimates.
3. What Are the Significant Limitations of the Benefit-Cost Analysis?
Every benefit-cost analysis examining the potential effects of a
change in
[[Page 28454]]
environmental protection requirements is limited to some extent by data
gaps, limitations in model capabilities (such as geographic coverage),
and uncertainties in the underlying scientific and economic studies
used to configure the benefit and cost models. Deficiencies in the
scientific literature often result in the inability to estimate
quantitative changes in health and environmental effects, such as
potential increases in premature mortality associated with increased
exposure to carbon monoxide. Deficiencies in the economics literature
often result in the inability to assign economic values even to those
health and environmental outcomes which can be quantified. While these
general uncertainties in the underlying scientific and economics
literatures, which can cause the valuations to be higher or lower, are
discussed in detail in the Regulatory Support Document and its
supporting documents and references, the key uncertainties which have a
bearing on the results of the benefit-cost analysis of this final rule
include the following:
[sbull] The exclusion of potentially significant benefit categories
(such as health and ecological benefits of reduction in CO, VOCs, air
toxics, and ozone);
[sbull] Errors in measurement and projection for variables such as
population growth;
[sbull] Uncertainties in the estimation of future year emissions
inventories and air quality;
[sbull] Uncertainties associated with the scaling of the results of
the modeled benefits analysis to the proposed standards, especially
regarding the assumption of similarity in geographic distribution
between emissions and human populations and years of analysis;
[sbull] Variability in the estimated relationships of health and
welfare effects to changes in pollutant concentrations;
[sbull] Uncertainties in exposure estimation;
[sbull] Uncertainties associated with the effect of potential
future actions to limit emissions.
Despite these uncertainties, we believe the benefit-cost analysis
provides a reasonable indication of the expected economic benefits of
the proposed rulemaking in future years under a set of assumptions.
One significant limitation to the benefit transfer method applied
in this analysis is the inability to scale ozone-related benefits.
Because ozone is a homogeneous gaseous pollutant, it is not possible to
apportion ozone benefits to the precursor emissions of NOX
and VOC. Coupled with the potential for NOX reductions to
either increase or decrease ambient ozone levels, this prevents us from
scaling the benefits associated with a particular combination of VOC
and NOX emissions reductions to another. Because of our
inability to scale ozone benefits, we do not include ozone benefits as
part of the monetized benefits of the proposed standards. For the most
part, ozone benefits contribute substantially less to the monetized
benefits than do benefits from PM, thus their omission will not
materially affect the conclusions of the benefits analysis. Although we
expect economic benefits to exist, we were unable to quantify or to
value specific changes in ozone, CO or air toxics because we did not
perform additional air quality modeling.
There are also a number of health and environmental effects which
we were unable to quantify or monetize. A full appreciation of the
overall economic consequences of the proposed rule requires
consideration of all benefits and costs expected to result from the new
standards, not just those benefits and costs which could be expressed
here in dollar terms. A complete listing of the benefit categories that
could not be quantified or monetized in our estimate are provided in
Table V.E-5. These effects are denoted by ``B'' in Table V.E-3 above,
and are additive to the estimates of benefits.
Table V.E-5.--Additional, Non-monetized Benefits of the Proposed Nonroad
Diesel Engine and Fuel Standards
------------------------------------------------------------------------
Pollutant Unquantified effects
------------------------------------------------------------------------
Ozone Health................. Premature mortality.\a\
Increased airway responsiveness to
stimuli.
Inflammation in the lung.
Chronic respiratory damage.
Premature aging of the lungs.
Acute inflammation and respiratory cell
damage.
Increased susceptibility to respiratory
infection.
Non-asthma respiratory emergency room
visits.
Increased school absence rates.
Ozone Welfare................ Decreased yields for commercial forests
(for example, Western US).
Decreased yields for fruits and
vegetables.
Decreased yields for non-commercial
crops.
Damage to urban ornamental plants.
Impacts on recreational demand from
damaged forest aesthetics.
Damage to ecosystem functions.
PM Health.................... Infant mortality.
Low birth weight.
Changes in pulmonary function.
Chronic respiratory diseases other than
chronic bronchitis.
Morphological changes.
Altered host defense mechanisms.
Cancer.
Non-asthma respiratory emergency room
visits.
PM Welfare................... Visibility in many Class I areas.
Residential and recreational visibility
in non-Class I areas.
Soiling and materials damage.
Damage to ecosystem functions.
[[Page 28455]]
Nitrogen and Sulfate Impacts of acidic sulfate and nitrate
Deposition Welfare. deposition on commercial forests.
Impacts of acidic deposition to
commercial freshwater fishing.
Impacts of acidic deposition to
recreation in terrestrial ecosystems.
Reduced existence values for currently
healthy ecosystems.
Impacts of nitrogen deposition on
commercial fishing, agriculture, and
forests.
Impacts of nitrogen deposition on
recreation in estuarine ecosystems.
Damage to ecosystem functions.
CO Health.................... Premature mortality.\a\
Behavioral effects.
HC Health \b\................ Cancer (benzene, 1,3-butadiene,
formaldehyde, acetaldehyde).
HC Welfare................... Direct toxic effects to animals.
Bioaccumulation in the food chain.
Damage to ecosystem function.
Odor.
------------------------------------------------------------------------
Notes:
\a\ Premature mortality associated with ozone and carbon monoxide is not
separately included in this analysis. In this analysis, we assume that
the ACS/Krewski, et al. C-R function for premature mortality captures
both PM mortality benefits and any mortality benefits associated with
other air pollutants. A copy of Krewski, et al., can be found in
Docket A-99-06, Document No. IV-G-75.
\b\ Many of the key hydrocarbons related to this rule are also hazardous
air pollutants listed in the Clean Air Act.
F. Economic Impact Analysis
An Economic Impact Analysis (EIA) was prepared to estimate the
economic impacts of this proposal on producers and consumers of nonroad
engines and equipment and related industries. The Nonroad Diesel
Economic Impact Model (NDEIM), developed for this analysis, was used to
estimate market-level changes in price and outputs for affected engine,
equipment, fuel, and application markets as well as the social costs
and their distribution across economic sectors affected by the program.
This section presents the results of the economic impact analysis. A
detailed description of the NDEIM, the model inputs, and several
sensitivity analyses can be found in chapter 10 of the Draft Regulatory
Impact Analysis prepared for this proposal.
1. What Is an Economic Impact Analysis?
Regulatory agencies conduct economic impact analyses of potential
regulatory actions to inform decision makers about the effects of a
proposed regulation on society's current and future well-being. In
addition to informing decision makers within the Agency, economic
impact analyses are conducted to meet the statutory and administrative
requirements imposed by Congress and the Executive office. The Clean
Air Act requires an economic impact analysis under section 317, while
Executive Order 12866--Regulatory Planning and Review requires
Executive Branch agencies to perform benefit-costs analyses of all
rules it deems to be ``significant'' (typically over $100 million
annual social costs) and submit these analyses to the Office of
Management and Budget (OMB) for review. This economic impact analysis
estimates the potential market impacts of the proposed rule's
compliance costs and provides the associated social costs and their
distribution across stakeholders for comparison with social benefits
(as presented in Section V.E).
2. What Is EPA's Economic Analysis Approach for This Proposal?
The underlying objective of an EIA is to evaluate the effect of a
proposed regulation on the welfare of affected stakeholders and society
in general. Using information on the expected compliance costs of the
proposed program as presented in the preceding discussion, this EIA
explores how the companies that produce nonroad diesel engines,
equipment, or fuel may change their production behavior in response to
the costs of complying with the standards. It also explores how the
consumers who use the affected products may change their purchasing
decisions. For example, the construction industry may reduce purchases
if the prices of nonroad diesel equipment increase, thereby reducing
the volume of equipment sold (or market demand) for such equipment.
Alternatively, the construction industry may pass along these
additional costs to the consumers of their final goods and services by
increasing prices, which would mitigate the potential impacts on the
purchases of nonroad diesel equipment.
The conceptual approach of the NDEIM is to link significantly
affected markets to mimic how compliance costs will potentially ripple
through the economy. The compliance costs will be directly borne by
engine manufacturers, equipment manufacturers, and petroleum
refineries. Depending on market characteristics, some or all of these
compliance costs will be passed on through the supply chain in the form
of higher prices extending to producers and consumers in the
application markets (i.e., construction, agriculture, and
manufacturing). The NDEIM explicitly models these linkages and
estimates behavioral responses that lead to new equilibrium prices and
output for all related markets and the resulting distribution of costs
across stakeholders.
The NDEIM uses a multi-market partial equilibrium approach to track
changes in price and quantity for 60 integrated product markets, as
follows:
[sbull] 7 diesel engine markets (less than 25 hp, 26 to 50 hp, 51
to 75 hp, 76 to 100 hp, 101 to 175 hp, 176 to 600 hp, and greater than
600 hp; the EIA includes more horsepower categories than the standards,
allowing more efficient use of the engine compliance cost estimates
developed for this proposal).
[sbull] 42 diesel equipment markets (7 horsepower categories within
7 application categories: agricultural, construction, general
industrial, pumps and compressors, generator and welder sets,
refrigeration and air conditioning, and lawn and garden; there are 7
horsepower/application categories that did not have sales in 2000 and
are not included in the model, so the total number of diesel equipment
markets is 42 rather than 49).
[sbull] 3 application markets (agricultural, construction, and
manufacturing).
[sbull] 8 nonroad diesel fuel markets (2 sulfur content levels of
15 ppm and 500 ppm for each of 4 PADDs; PADDs 1 and
[[Page 28456]]
3 are combined for the purpose of this analysis). It should be noted
that PADD 5 includes Alaska and Hawaii. Because those two states are
geographically separate from the rest of PADD 5, we seek comment on
whether they should be considered as separate fuel markets.
The NDEIM uses an intermediate run time frame and assumes perfect
competition in the market sectors. It is a computer model comprised of
a series of spreadsheet modules that define the baseline
characteristics of the supply and demand for the relevant markets and
the relationships between them. A detailed description of the model
methodology, inputs, and parameters is provided in chapter 10 of the
draft RIA prepared for this proposal. The model methodology is firmly
rooted in applied microeconomic theory and was developed following the
OAQPS Economic Analysis Resource Document.\294\ Based on the specified
market linkages, the model is shocked by applying the engineering
compliance cost estimates to the appropriate market suppliers and then
numerically solved using an iterative auctioneer approach by ``calling
out'' new prices until a new equilibrium is reached in all markets
simultaneously.
---------------------------------------------------------------------------
\294\ U.S. Environmental Protection Agency, Office of Air
Quality Planning and Standards, Innovative Strategies and Economics
Group, OAQPS Economic Analysis Resource Document, April 1999. A copy
of this document can be found in Docket A-2001-28, Document No. II-
A-14.
---------------------------------------------------------------------------
The actual economic impacts of the proposed rule will be determined
by the ways in which producers and consumers of the engines, equipment,
and fuels affected by the proposal change their behavior in response to
the costs incurred in complying with the standards. In the NDEIM, these
behaviors are modeled by the demand and supply elasticities. The supply
elasticities for the engine and equipment markets and the demand
elasticities for the application markets were estimated using
econometric methods. The procedures and results are reported in
Appendix 10.1 of the draft RIA. Literature-based estimates were used
for the supply elasticities in the application and fuel markets.
There are two ways to handle the demand elasticities for the
engine, equipment, and fuel markets. In the approach used in NDEIM,
these demand elasticities are internally derived based on the specified
market linkages, i.e., the demand for engines, equipment, and fuel are
modeled as directly related to the supply and demand of goods and
services supplied by the final application markets. In other words, the
supply of those goods and services determines the demand for equipment
and fuel, and the supply of equipment determines the demand for
engines. Using this approach, the NDEIM predicts that engine and
equipment production will decrease by only a small amount: 0.013% and
0.014% respectively (see Table V.F-1). Also, please see draft RIA
Appendices 10A and 10B for more detailed estimates on the price
increase estimates. Because the application markets are modeled with
inelastic or unit elastic demand and supply elasticities (quantity
supplied/demanded is expected to be fairly insensitive to price changes
or they will vary directly with price changes), the model predicts that
engine and equipment manufacturers will pass along virtually all of
their costs to end users.
An alternative approach could be used in which the demand
elasticities for the equipment, engine, and fuel markets are not
derived as part of the model. They could be estimated separately or a
sensitivity analysis could be conducted that assumes more elastic
values than those generated by the NDEIM. We are continuing to
investigate this matter and will be placing additional information
about elasticities in the docket during the comment period for this
rule. We request comment on that information as well as on the
methodology and other aspects of this EIA.
The estimated engine and equipment market impacts are based solely
on the expected increase in variable costs associated with the proposed
standards. Fixed costs associated with the engine emission standards
are not included in the market analysis reported in Table IV-F-1. This
is because in an analysis of competitive markets the industry supply
curve is based on its marginal cost curve, and fixed costs are not
reflected in changes in the marginal cost curve. In addition, fixed
costs are primarily R&D costs associated with design and engineering
changes, and firms in the affected industries currently allocate funds
for these costs. Therefore, fixed costs are not likely to affect the
prices of engines or equipment. This assumption is described in greater
detail in section 10.2 of the draft RIA. R&D costs are a long-run
concern and decisions to invest or not invest in R&D are made in the
long run. If funds have to be diverted from some other activity into
R&D needed to meet the environmental regulations, then these costs
represent a component of the social costs of the rule. Therefore, fixed
costs are included in the welfare impact estimates reported in Table
V.F-2 as additional costs on producers. We also performed a sensitivity
analysis, included in chapter 10 of the draft RIA for this proposal,
that includes fixed costs as part of the model. This results in a
transfer of welfare losses from engine and equipment markets to the
application markets, but does not change the overall welfare losses
associated with the proposal.
Economic theory indicates that, in the long run, prices are
expected to reflect the average total costs of the marginal producer in
a market and not just variable costs. This suggests that it may be
necessary to treat fixed costs differently for a long-run analysis. We
will continue to investigate this effect and intend to place additional
information in the docket during the comment period for this rule. We
request comment on that information as well as on how fixed costs and
R&D expenditures are handled in the NDEIM.
In addition to the variable and fixed costs described above, there
are three additional costs components that are included in the total
social cost estimates of the proposed regulation but that are not
explicitly included in the NDEIM. These are operating savings (costs),
fuel marker costs, and spillover from 15 ppm fuel to higher sulfur
fuel. We request comment on how best to incorporate each of these costs
in the analysis.
Operating savings (costs) refers to changes in operating costs that
are expected to be realized by users of both existing and new nonroad
diesel equipment as a result of the reduced sulfur content of nonroad
diesel fuel. These include operating savings (cost reductions) due to
fewer oil changes, which accrue to nonroad engines, and marine and
locomotive engines, that are already in use as well as new nonroad
engines that will comply with the proposed standards (see section
V.B.). These savings (costs) also include any extra operating costs
associated with the new PM emission control technology which may accrue
to new engines that use this new technology. These savings (costs) are
not included directly in the model because some of the savings accrue
to existing engines and because these savings (costs) are not expected
to affect consumer decisions with respect to new engines. Instead, they
are added into the estimated welfare impacts as additional costs to the
application markets, since it is the users of these engines that will
see these savings (costs). Nevertheless, a sensitivity analysis was
also performed in which these savings (costs) are included as inputs to
the NDEIM, where they are modeled as benefits accruing to the
application producers. The results of
[[Page 28457]]
this analysis are presented in Chapter 10 of the draft RIA.
Fuel marker costs refers to costs associated with marking high
sulfur diesel fuel in the locomotive, marine, and heating oil markets
between 2007 and 2014. Marker costs are not included in the market
analysis because locomotive, marine, and heating oil markets are not
explicitly modeled in the NDEIM. Similar to the operating savings
(costs), marker costs are added into the estimated welfare impacts
separately.
The costs of fuel that spills over from the 15 ppm market to higher
grade sulfur fuel are also not included in the NDEIM but, instead, are
added into the estimated welfare impacts separately. As described in
section IV above, refiners are expected to produce more 15 ppm fuel
than is required for the nonroad diesel fuel market. This excess 15 ppm
fuel will be sold into markets that allow fuel with a higher sulfur
level (e.g., locomotive, marine diesel, or home heating fuel). Because
this spillover fuel will meet the 15 ppm limit, it is necessary to
count the costs of sulfur reduction processes against those fuels.
Consistent with the engine and equipment cost discussion in section
V.C. of this preamble, the EIA does not include any cost savings
associated with the proposed equipment transition flexibility program
or the proposed nonroad engine ABT program. As a result, the results of
this EIA can be viewed as somewhat conservative, in this respect.
3. What Are the Results of this Analysis?
The economic analysis consists of two parts: a market analysis and
welfare analysis. The market analysis looks at expected changes in
prices and quantities for directly and indirectly affected market
commodities. The welfare analysis looks at economic impacts in terms of
annual and present value changes in social costs. For this proposed
rule, the social costs are computed as the sum of market surplus offset
by operating cost savings. Market surplus is equal to the aggregate
change in consumer and producer surplus based on the estimated market
impacts associated with the proposed rule. Operating cost savings are
associated with the decreased sulfur content of diesel fuel. These
include maintenance savings (cost reductions) and changes in fuel
efficiency. Increased maintenance costs may also be incurred for some
technologies. Operating costs are not included in the market analysis
but are instead listed as a separate category in the social cost
results tables.
Economic impact results for 2013, 2020, and 2030 are presented in
this section. The first of these years, 2013, corresponds to the first
year in which the standards affect all engines, equipment, and fuels.
It should be noted that, as illustrated in Table V.D-2, above,
aggregate program costs peak in 2014; increases in costs after that
year are due to increases in the population of engines over time. The
other years, 2020 and 2030, correspond to years analyzed in our
benefits analysis. Detailed results for all years are included in
Appendix 10.E. for this chapter.
a. Expected Market Impacts
The market impacts of this rule suggest that the overall economic
impact of the proposed emission control program on society is expected
to be small, on average. According to this analysis, the average prices
of goods and services produced using equipment and fuel affected by the
proposal are expected to increase by about 0.02 percent. The estimated
price increases and quantity reductions for engines and equipment vary
depending on compliance costs. In general, we would expect for price
increases to be higher (lower) as a result of a high (low) relative
level of compliance costs to market price. We would also expect the
change in price to be highest when compliance costs are highest.
The estimated market impacts for 2013, 2020, and 2030 are presented
in Table V.F-1. The market-level impacts presented in this table
represent production-weighted averages of the individual market-level
impact estimates generated by the model: the average expected price
increase and quantity decrease across all of the units in each of the
engine, equipment, fuel, and final application markets. For example,
the model includes seven individual engine markets that reflect the
different horsepower size categories. The 23 percent price change for
engines shown in Table V.F-1 for 2013 is an average price change across
all engine markets weighted by the number of production units.
Similarly, equipment impacts presented in Table V.F-1 are weighted
averages of 42 equipment-application markets, such as small (< 25hp)
agricultural equipment and large (600hp) industrial
equipment. It should be noted that price increases and quantity
decreases for specific types of engines, equipment, application
sectors, or diesel fuel markets are likely to be different. But the
data in this table provide a broad overview of the expected market
impacts that is useful when considering the impacts of the proposal on
the economy as a whole. The individual market-level impacts are
presented in Chapter 10 of the draft RIA for this proposal.
Engine Market Results: Most of the variable costs associated with
the proposed rule are passed along in the form of higher prices. The
average price increase in 2013 for engines is estimated to be about 23
percent. This percentage is expected to decrease to about 19.5 percent
for 2020 and later. This expected price increase varies by engine size
because compliance costs are a larger share of total production costs
for smaller engines. In 2013, the year of greatest compliance costs
overall, the largest expected percent price increase is for engines
between 25 and 50 hp: 34 percent or $852; the average price for an
engine in this category is about $2,500. However, this price increase
is expected to drop to 26 percent, or about $647, for 2016 and later.
The smallest expected percent price increase in 2013 is for engines in
the greater than 600 hp category. These engines are expected to see
price increases of about 3 percent increase in 2013, increasing to
about 5.6 percent in 2014 and beyond. The expected price increase for
these engines is about $4,211 in 2013, increasing to about $6,950 in
2014 and later, for engines that cost on average about $125,000.
The market impact model predicts that even with these increases in
engine prices, total demand is not expected to change very much. The
expected average change in quantity is only about 69 engines per year
in 2013, out of total sales of more than 500,000 engines. The estimated
change in market quantity is small because as compliance costs are
passed along the supply chain they become a smaller share of total
production costs. In other words, firms that use these engines and
equipment will continue to purchase them even at the higher cost
because the increase in costs will not have a large impact on their
total production costs. Diesel equipment is only one factor of
production for their output of construction, agricultural, or
manufactured goods. The average decrease in the quantity of all engines
produced as a result of the regulation is estimated to be about 0.013
percent. This decrease ranges from 0.010 percent for engines less than
25 hp to 0.016 percent for engines 175 to 600 hp.
Equipment Market Results: Estimated price changes for the equipment
markets reflect both the direct costs of the proposed standards on
equipment production and the indirect cost through increased engine
prices. In 2013, the average price increase for nonroad diesel
equipment is estimated
[[Page 28458]]
to be about 5.2 percent. This percentage is expected to decrease to
about 4.5 percent for 2020 and beyond. The range of estimated price
increases across equipment types parallels the share of engine costs
relative to total equipment price, so the estimated percentage price
increase among equipment types also varies. The market price in 2013
for agricultural equipment between 175 and 600 hp is estimated to
increase about 1.4 percent, or $1,835 for equipment with an average
cost of $130,000. This compares with an estimated engine price increase
of about $1,754 for engines of that size. The largest expected price
increase in 2013 for equipment is $4,335, or 4.9 percent, for pumps and
compressors over 600 hp. This compares with an estimated engine price
increase of about $4,211 for engines of that size. The smallest
expected price increase in 2013 for equipment is $125, or 3.6 percent,
for construction equipment less than 25 hp. This compares with an
estimated engine price increase of about $124 for engines of that size.
The price changes for the equipment are less than that for engines
because the engine is only one input in the production of equipment.
The output reduction for nonroad diesel equipment is estimated to
be very small and to average about 0.014 percent for all years. This
decrease ranges from 0.005 percent for general manufacturing equipment
to 0.019 percent for construction equipment. The largest expected
decrease in quantity in 2013 is 13 units of construction equipment per
year for construction equipment between 100 and 175 hp, out of about
62,800 units. The smallest expected decrease in quantity in 2013 is
less than one unit per year in all hp categories of pumps and
compressors.
Table V.F-1.--Summary of Market Impacts ($2001)
----------------------------------------------------------------------------------------------------------------
Engineering Change in price Change in quantity
cost ---------------------------------------------------------------
Market ---------------- Absolute
Per unit ($million) Percent Absolute Percent
----------------------------------------------------------------------------------------------------------------
2013
----------------------------------------------------------------------------------------------------------------
Engines......................... $1,087 $840 22.9 -69 a -0.013
Equipment....................... 1,021 1,017 5.2 -118 -0.014
Application Markets b........... .............. .............. 0.02 .............. -0.010
No. 2 Distillate Nonroad........ 0.039 0.038 4.1 -1.38 c -0.013
---------------------------------
2020
----------------------------------------------------------------------------------------------------------------
Engines......................... $1,028 $779 19.5 -79 a -0.013
Equipment....................... 1,018 1,013 4.4 -135 -0.014
Application Markets b........... .............. .............. 0.02 .............. -0.010
No. 2 Distillate Nonroad........ 0.039 0.039 4.1 -1.58 c -0.014
---------------------------------
2030
----------------------------------------------------------------------------------------------------------------
Engines......................... $1,027 $768 19.4 -92 a -0.013
Equipment....................... 1,004 999 4.5 -156 -0.014
Application Markets b........... .............. .............. 0.02 .............. -0.010
No. 2 Distillate Nonroad........ 0.039 0.039 4.1 -1.84 c -0.014
----------------------------------------------------------------------------------------------------------------
Notes:
a The absolute change in the quantity of engines represents only engines sold on the market. Reductions in
engines consumed internally by integrated engine/equipment manufacturers are not reflected in this number but
are captured in the cost analysis. For this reason, the absolute change in the number of engines and equipment
does not match.
b The model uses normalized commodities in the application markets because of the great heterogeneity of
products. Thus, only percentage changes are presented.
c Units are in million of gallons.
Application Market Results: The estimated price increase associated
with the proposed standards in all three of the application markets is
very small and averages about 0.02 percent for all years. In other
words, on average, the prices of goods and services produced using the
engines, equipment, and fuel affected by this proposal are expected to
increase only negligibly. This is because in all of the application
markets the compliance costs passed on through price increases
represent a very small share of total production costs. For example,
the construction industry realizes an increase in production costs of
approximately $468 million in 2013 because of the price increases for
diesel equipment and fuel. However, this represents only 0.03 percent
of the $1,392 billion value of shipments in the construction industry
in 2001. The estimated average commodity price increase in 2013 ranges
from 0.06 percent in the agricultural application market to about 0.01
percent in the manufacturing application market. The percentage change
in output is also estimated to be very small and averages about 0.01
percent. This reduction ranges from less than a 0.01 percent decrease
in manufacturing to about a 0.02 percent decrease in construction. Note
that these estimated price increases and quantity decreases are average
for these sectors and may vary for specific subsectors. Also, note that
absolute changes in price and quantity are not provided for the
application markets in Table V.F-1 because normalized commodity values
are used in the market model. Because of the great heterogeneity of
manufactured or agriculture products, a normalized commodity ($1 unit)
is used in the application markets. This has no impact on the estimated
percentage change impacts but makes interpretation of the absolute
changes less informative.
Fuel Markets Results: The estimated average price increase across
all nonroad diesel fuel is about 4 percent for all years. For 15 ppm
fuel, the estimated price increase for 2013 ranges from 3.2 percent in
the East Coast region (PADD 1&3) to 9.3 percent in the mountain region
(PADD 4). The average
[[Page 28459]]
national output decrease for all fuel is estimated to be about 0.01
percent for all years, and is relatively constant across all four
regional fuel markets.
b. Expected Welfare Impacts
Social cost impact estimates are presented in Table V.F-2. A time
series of social costs from 2007 through 2030 is presented in Table
IV.F-3. As described above, the total social cost of the regulation is
the sum of the changes in producer and consumer surplus estimated by
the model plus engine maintenance savings (negative costs) resulting
from using fuel with a lower sulfur content. Total social costs in 2013
are projected to be 1,202.4 million ($2001). About 82 percent of the
total social costs is expected to be borne by producers and consumers
in the application markets, indicating that the majority of the costs
are expected to be passed on in the form of higher prices. When these
estimated impacts are broken down, 58 percent are expected to be borne
by consumers in the application markets and 42 percent are expected to
be borne by producers in the application markets. Equipment
manufacturers are expected to bear about 10 percent of the total social
costs. Engine manufacturers and diesel fuel refineries are expected to
bear 2.5 percent and 0.5 percent, respectively. The remaining 5.0
percent is accounted for by fuel marker costs and the additional costs
of 15 ppm fuel being sold in to markets such as marine diesel,
locomotive, and home heating fuel that do not require it.
In 2030, the total social costs are projected to be about $1,509.6
million ($2001). The increase is due to the projected annual growth in
the engine and equipment populations. As in earlier years, producers
and consumers in the application markets are expected to bear the large
majority of the costs, approximately 94 percent. This is consistent
with economic theory, which states that, in the long run, all costs are
passed on to the consumers of goods and services.
The present value of total social costs through 2030 is estimated
to be $16.5 billion ($2001). This present value is calculated using a
social discount rate of 3 percent from 2004 through 2030. We also
performed an analysis using an alternative 7 percent social discount
rate. Using that discount rate, the present value of the social costs
through 2030 is estimated to be $9.9 billion ($2001).
Table V.F-2.--Summary of Social Costs Estimates Associated With Primary Program: 2013, 2020, and 2030
[$million]a,b
--------------------------------------------------------------------------------------------------------------------------------------------------------
Maximum cost year (2013) Year 2020 Final year (2030)
-----------------------------------------------------------------------------------------------------------
Market Operating Market Operating Market Operating
surplus savings Total surplus savings Total surplus savings Total
($10\6\) ($10\6\) ($10\6\) ($10\6\) ($10\6\) ($10\6\)
--------------------------------------------------------------------------------------------------------------------------------------------------------
Engine Producers Total...................... 30.2 ............ 30.2 0.1 ............ 0.1 0.1 ............ 0.1
Equipment Producers Total................... 116.1 ............ 116.1 102.6 ............ 102.6 5.3 ............ 5.3
Agricultural Equipment.................. 39.9 ............ 39.9 33.2 ............ 33.2 1.3 ............ 1.3
Construction Equipment.................. 53.0 ............ 53.0 48.2 ............ 48.2 3.8 ............ 3.8
Industrial Equipment.................... 23.2 ............ 23.2 21.2 ............ 21.2 0.2 ............ 0.2
Application Producers and Consumers Total... 1,231.8 (241.9) 989.8 1,386.5 (190.1) 1,196.3 1,598.9 (174.5) 1,424.5
Total Producer.......................... 515.7 ............ ......... 583.4 ............ ......... 672.9 ............ .........
Total Consumer.......................... 716.1 ............ ......... 803.1 ............ ......... 926.0 ............ .........
Agriculture............................. 348.7 (44.7) 304.0 339.2 (35.2) 364.0 416.5 (32.3) 429.2
Construction............................ 468.3 (77.9) 390.4 550.4 (61.2) 489.3 635.7 (56.1) 579.5
Manufacturing........................... 414.8 (119.3) 295.5 436.8 (93.8) 343.0 501.8 (86.0) 415.7
Fuel Producers Total........................ 7.8 ............ 7.8 9.0 ............ 9.0 10.5 ............ 10.5
PADD I&III.............................. 3.6 ............ 3.6 4.1 ............ 4.1 4.8 ............ 4.8
PADD II................................. 2.9 ............ 2.9 3.3 ............ 3.3 3.9 ............ 3.9
PADD IV................................. 0.8 ............ 0.8 0.9 ............ 0.9 1.0 ............ 1.0
PADD V.................................. 0.5 ............ 0.5 0.6 ............ 0.6 0.8 ............ 0.8
Nonroad Spillover........................... ......... 51.2 ......... ......... 58.6 ......... ......... 69.2
Marker Costs................................ ......... 7.3 ......... ......... ............ ......... ......... ............ .........
------------
--------------------------------------------------------------------------------------------------------------------------------------------------------
Notes:
\a\ Figures are in 2001 dollars.
\b\ Operating savings are shown as negative costs.
[[Page 28460]]
Table IV.F-3--National Engineering Compliance Costs and Social Costs
Estimates for the Proposed Rule: 2004-2030
[$10 \6\] a
------------------------------------------------------------------------
Engineering Total
Year compliance social
costs costsb
------------------------------------------------------------------------
2004....................................... 0.00 0.00
2005....................................... 0.00 0.00
2006....................................... 0.00 0.00
2007....................................... 39.61 39.61
2008....................................... 130.41 130.40
2009....................................... 132.25 132.25
2010....................................... 262.02 262.01
2011....................................... 641.12 641.07
2012....................................... 1,010.37 1,010.27
2013....................................... 1,202.52 1,202.40
2014....................................... 1,329.14 1,329.01
2015....................................... 1,260.74 1,260.62
2016....................................... 1,298.40 1,298.27
2017....................................... 1,318.75 1,318.62
2018....................................... 1,325.02 1,324.89
2019....................................... 1,339.30 1,339.16
2020....................................... 1,366.79 1,366.66
2021....................................... 1,351.08 1,350.94
2022....................................... 1,349.58 1,349.44
2023....................................... 1,365.53 1,365.38
2024....................................... 1,371.60 1,371.45
2025....................................... 1,395.98 1,395.83
2026....................................... 1,419.79 1,419.64
2027....................................... 1,442.91 1,442.76
2028....................................... 1,465.41 1,465.26
2029....................................... 1,487.68 1,487.53
2030....................................... 1,509.77 1,509.61
--------------------------------------------
NPV at 3%.................................. 16,524.29 16,522.66
NPV at 7%.................................. 9,894.02 9,893.06
------------------------------------------------------------------------
Notes:
a Figures are in 2001 dollars.
b Figures in this column do not include the human health and
environmental benefits of the proposal.
VI. Alternative Program Options
Our proposed emission control program consists of a two-step
program to reduce the sulfur content of nonroad diesel fuel in
conjunction with the proposed Tier 4 engine standards. As we developed
this proposal, we evaluated a number of alternative options with regard
to the scope, level, and timing of the standards. This section presents
a summary of our analysis of several alternative control scenarios. A
complete discussion of all the alternatives, their feasibility, and
their inventory, benefits, and cost impacts can be found in Chapter 12
of the draft Regulatory Impact Analysis for this proposal.
While we are interested in comments on all of the alternatives
presented, we are especially interested in comments on two alternative
scenarios which EPA believes merit further consideration in developing
the final rule: a program in which sulfur levels are required to be
reduced to 15 ppm in essentially a single step, and a variation on the
proposed two-step fuel control program, in which the second step of
sulfur control to 15 ppm in 2010 would apply to locomotive and marine
diesel fuel in addition to nonroad diesel fuel. This section describes
these two options in greater detail; additional information can be
found in Chapter 12 of the draft Regulatory Impact Analysis for this
proposal.
A. Summary of Alternatives
We developed emissions, benefits, and cost analyses for a number of
alternatives. The alternatives we considered can be categorized
according to the structure of their fuel requirements: whether the 15
ppm fuel sulfur limit is reached in two-steps, like the proposed
program, or one-step.
One-step alternatives are those in which the fuel sulfur standard
is applied in a single step: there are no fuel-based phase-ins. We
evaluated three one-step alternatives. Option 1 is described in detail
in Section VI.B, below. We considered two other one-step alternatives
which differ from Option 1 in the timing of the fuel option (2006 or
2008) and the engines standards (level of the standards and when they
are introduced). As described in Table IV-1, Option 1b differs from
Option 1 regarding the timing of the fuel standards, while Option 1a
differs from Option 1 in terms of the engine standards. Both Option 1a
and 1b would also extend the 15 ppm fuel sulfur limit to locomotive and
marine diesel fuel as well.
Two-step alternatives are those in which the fuel sulfur standard
is set first at 500 ppm and then is reduced to 15 ppm. The two-step
alternatives vary from the proposal in terms of both the timing and
levels of the engine standards and the timing of the fuel standards.
Option 2a is the same as the proposed program except the 500 ppm fuel
standard is introduced a year earlier, in 2006. Option 2b is the same
as the proposed program except the 15 ppm fuel standard is introduced a
year earlier in 2009 and the trap-based PM standards begin earlier for
all engines. Option 2c is the same as the proposed program except the
15 ppm fuel standard is introduced a year earlier in 2009 and the trap-
based PM standards begin earlier for engines 175-750 hp. Option 2d is
the same as the proposed program except the NOX standard is
reduced to 0.30 g/bhp-hr for engines 25-75 hp, and this standard is
phased in. Finally, Option 2e is the same as the proposed program
except there are no new Tier 4 NOX limits.
Options 3 and 4 are identical to the proposed program, except
Option 3 would exempt mining equipment over 750 hp from the Tier 4
standards, and Option 4 would include applying the 15 ppm sulfur limit
to both locomotive and marine diesel fuel. Option 4 is discussed in
detail in Section IV.C, below.
Option 5a and 5b are identical to the proposal except for the
treatment of engines less than 75 hp. Option 5a is identical to the
proposal except that no new program requirements would be set in Tier 4
for engines under 75 hp. Instead Tier 2 standards and testing
requirements for engines under 50 hp, and Tier 3 standards and testing
requirements for 50-75 hp engines, would continue indefinitely. The
Option 5b program is identical to the proposal except that for engines
under 75 hp only the 2008 engine standards would be set. There would be
no additional PM filter-based standard in 2013 for 25-75 hp engines,
and no additional NOX+NMHC standard in 2013 for 25-50 hp
engines.
Table VI-1 contains a summary of a number of these alternatives and
the expected emission reductions, costs, and monetized benefits
associated with them in comparison to the proposal. These alternatives
cover a broad range of possible approaches and serve to provide insight
into the many other program design alternatives not expressly evaluated
further. The analysis was done using a 3% discount rate. If we were to
use another rate, the values would change but not to such a degree as
to change our conclusions regarding the various options. A complete
discussion of all the alternatives, their feasibility, and their
inventory, benefits, and cost impacts can be found in Chapter 12 of the
draft Regulatory Impact Analysis for this proposal.
[[Page 28461]]
[GRAPHIC] [TIFF OMITTED] TP23MY03.012
[[Page 28462]]
[GRAPHIC] [TIFF OMITTED] TP23MY03.013
[[Page 28463]]
B. Introduction of 15 ppm Nonroad Diesel Sulfur Fuel in One Step
EPA carefully evaluated and is seeking comment on alternative
regulatory approaches. Instead of the proposed two-step reduction in
nonroad diesel sulfur, one alternative would require that the nonroad
diesel sulfur level be reduced to 15ppm beginning June 1, 2008. This
alternative would have the advantage of enabling use of high efficiency
exhaust emission control technology for nonroad engines as early as the
2009 model year. It also would have several disadvantages which have
prompted us not to propose it. The disadvantages in comparison to the
proposal include inadequate lead-time for engine and equipment
manufacturers and refiners, leading to increased costs and potential
market disruptions. In this section, we describe this alternative in
greater detail and discuss potential engine and fuel impacts. We also
present our estimated emission and benefit impacts. Two other one-step
fuel options which are variations of the alternative discussed in this
section, Options 1a and 1b in Table VI-1, are presented in Chapter 12
of the draft RIA for this proposal.
1. Description of the One-Step Alternative
While numerous engine standards and phase-in schedules are
possible, we considered the standards shown in Tables VI-2 and VI-3 as
being the most stringent one-step program that could be considered
potentially feasible considering cost, lead-time, and other factors.
These standards are similar to those in our proposed option, the
primary difference being the generally earlier phase-in dates for the
PM standards.
Table VI-2.--PM Standards for 1-Step Fuel Scenario
[g/bhp-hr]
----------------------------------------------------------------------------------------------------------------
Model year
Engine power -----------------------------------------------------------------
2009 2010 2011 2012 2013 2014
----------------------------------------------------------------------------------------------------------------
hp < 25....................................... 0.30 ......... ......... ......... ......... .........
25 <= hp <50.................................. 10.22 ......... ......... ......... 0.02 .........
50 <= hp <75.................................. ......... ......... ......... ......... 0.02 .........
75 <= hp <175................................. ......... ......... 0.01 ......... ......... .........
......... \a\ 50% \a\ 50% \a\ 100% ......... .........
175 <= hp <750................................ ......... 0.01 ......... ......... ......... .........
\a\ 50% \a\ 50% \a\ 100% ......... ......... .........
hp = 750........................... ......... ......... ......... ......... 0.01 .........
......... ......... \a\ 50% \a\ 50% \a\ 50% \a\ 100%
----------------------------------------------------------------------------------------------------------------
Notes:
\a\ Percentages are the model year sales required to comply with the indicated standard.
Table VI-3.--NOX and NMHC Standards for 1-Step Fuel Scenario
[g/bhp-hr]
----------------------------------------------------------------------------------------------------------------
Model year
Engine power ---------------------------------------------
2011 2012 2013 2014
----------------------------------------------------------------------------------------------------------------
25 <= hp < 75..................................................... ......... ......... a 3.5 ...........
------------
0.30 NOX
75 <= hp <175..................................................... 0.14 NMHC
------------
b 50% b 50% b 100%
------------
0.30 NOX
175 <= hp <750.................................................... 0.14 NMHC
------------
b 50% b 50% b 50% b 100%
------------
0.30 NOX
hp =750................................................ 0.14 NMHC
------------
b 50% b 50% b 50% b 100%
----------------------------------------------------------------------------------------------------------------
Notes:
a A 3.5 NMHC + NOX standard would apply to the 25-50 hp engines. Engines greater than 50hp are already subject
to this standard in 2008 under the existing Tier 3 program.
b Percentages are the model year sales required to comply with the indicated standards.
2. Engine Emission Impacts
The main advantage associated with this one-step approach is
pulling ahead the long-term PM engine standards. By making 15 ppm
sulfur fuel widely available by late 2008, we could accelerate the
long-term PM engine standards, leading to the introduction of precious
metal catalyzed PM traps as early as 2009, two years earlier than
possible under the two-step sulfur reduction approach. Some
stakeholders have expressed the concern that a two-step approach leads
to later than desired introduction of high-efficiency exhaust emissions
controls on nonroad diesels because this cannot happen until the 15 ppm
fuel standard goes into effect. As shown in Table VI-1, there would be
additional public health benefits associated with this one-step
approach. However, in comparison to the proposal, the additional
benefits are
[[Page 28464]]
relatively small, less than one percent or about $3 billion more than
the proposed program.\295\
---------------------------------------------------------------------------
\295\ A variation on this one-step approach would be to also
require the sulfur content of locomotive and marine fuel to meet the
15 ppm standard in 2008. The decision of whether or not to require
the sulfur content of locomotive and marine fuel to also be reduced
to 15 ppm, however, is not unique to the one step approach, and, as
discussed below is an alternative also being evaluated under our
proposed 2-step program. Were we to require locomotive and marine
diesel fuel to also meet the 15 ppm standard in 2008 under a one-
step approach, there would be additional inventory reductions of
about 10,000 tons of PM and 128,000 tons of SO3 (NPV 3%
through 2030).
---------------------------------------------------------------------------
Even though 15 ppm fuel would be available beginning June 1, 2008
under this one-step approach, we do not believe it would be feasible to
propose an aggressive turnover of new engines to trap-equipped versions
in 2009. Nor would it be possible to introduce NOX controls
any earlier than we are already proposing, model year 2011. The
proposed standards need to be coordinated with Tier 3 standards, and
with the heavy duty highway diesel standards. The coordination of Tier
4 standards with Tier 3 standards and with the development of emissions
control technology for highway diesel engines is of critical importance
to successful implementation of the Tier 4 standards. Even those
manufacturers who do not make highway engines are expected to gain
substantially from the highway PM and NOX control
development work, provided they can plan for standards set at a similar
level of stringency and timed in a way to allow for the orderly
migration of highway engine technology to nonroad applications.
Thus, although the application of high-efficiency exhaust PM
emission controls to nonroad diesels would be enabled with the
introduction of 15 ppm sulfur nonroad fuel in 2008 under a one-step
program, we believe that to require the application of PM controls
across the wide spectrum of nonroad engines shortly thereafter would
raise serious feasibility concerns that could only be resolved, if at
all, through a very large additional R&D effort undertaken roughly in
parallel with the similarly large highway R&D effort, a duplication of
effort we wish to avoid for reasons discussed in Section III. Nonroad
engine designers would need to accomplish much of this development well
before the diesel experience begins to accumulate in earnest in 2007,
in order to be ready for a 2009 first introduction date. Waiting until
2007 before initiating 2009 model year design work would risk the
possibility of product failures, limited product availability and major
market disruptions. At the same time, for those engine manufacturers
who participate in both the highway and nonroad diesel engine markets,
attempting to have concurrent engine product developments for highway
and nonroad, could result in the possibility of product failures,
limited product availability and major disruptions for the highway
market as well. Thus, in balancing their costs and burden, many
manufacturers may be forced to choose which products would be available
for 2009 and which products would be delayed for release. Manufacturers
would also incur large additional costs to redesign hundreds of engine
models and thousand of machine types to meet Tier 4 standards only one
to three years after Tier 3 standards take effect in 2006-2008. These
cost impacts are reflected in Table VI-1 and their derivation is
explained in chapter 12 of the draft RIA. This extra expenditure could
only be modestly mitigated by phasing in the standards, since a crash
R&D effort with limited benefit from highway experience would still be
necessary.
Moreover, with respect to NOX, it would be impractical
or simply infeasible to pull the standards ahead on the same schedule.
This is because EPA's highway diesel program allows manufacturers to
phase in NOX technology over 2007-2010. As a result, we do
not expect that the high-efficiency NOX control technology
could reasonably be applied to nonroad engines any earlier under a one-
step program than under a two-step program (i.e., beginning in 2011).
In summary, this option would lead us to apply PM and
NOX standards in two different model years, or else forgo
any opportunity to apply PM traps in 2009. Redesigning engines and
emission controls for early PM control and then again a couple of years
later for NOX control, on top of shortened Tier 3 stability
periods, would likely add substantial costs to the program. As
manufacturers attempt to avoid these costs and optimize their
development they may simply have to restrict product offerings for some
period, leading to price spikes and shortages due to lack of product
availability. Having the NOX and PM standards phase in
simultaneously under our proposed approach avoids cost and design
stability issues for both engine and equipment manufacturers. In
addition, the longer leadtime for the engine standards under our
proposed program will allow greater economic efficiencies for engine
manufacturers as they transfer highway emission reduction technology to
nonroad engines.
3. Fuel Impacts
In addition to the challenges associated with pulling ahead the PM
standards described above, there are also some concerns regarding the
practicality of an early 15 ppm nonroad diesel sulfur standard. A one-
step approach may result in several economic inefficiencies that would
increase the cost of the program. For example, refiners will have
little opportunity to take advantage of the newer desulfurization
technologies currently being developed. As described in sections IV and
V, refiners will only begin to be able to take advantage of these new
technologies in 2008. By 2010, the ability to incorporate them into
their refinery modifications is expected to double. If refiners have to
take steps to reduce the sulfur content of nonroad diesel fuel earlier,
they will likely have to use more expensive current technology. The
cost impacts of this decision will persist, since the choice of
technology is a long term decision. If a refiner is forced by the
effective date of the standards to employ a more expensive technology,
that choice will affect that refiner's output indefinitely, since the
cost of upgrading to the new technologies will be prohibitive. As
presented in section 5.2 of the Draft RIA, we estimate that the costs
of achieving a 15 ppm standard in 2008 is approximately 0.4 c/gal
greater than for the proposal. While difficult to quantify there are
also considerable advantages to allowing refiners some operating time
in producing 15 ppm diesel fuel for the highway program prior to
requiring them to solidify their designs for producing nonroad diesel
fuel to 15 ppm. The primary advantage is that the design of
desulfurization equipment used to produce 15 ppm nonroad diesel fuel
can reflect the operating experience of the equipment used to produce
15 ppm highway diesel fuel starting in 2006. This extra time would also
provide current refiners of high sulfur diesel fuel with highly
confident estimates of the cost of producing 15 ppm diesel fuel,
reducing uncertainty and increasing their likelihood of investing to
produce this fuel. With a start date of June 1, 2008 refiners would
have to solidify their designs and start construction prior to getting
any data on the performance of their highway technology. This would
increase the cost of producing 15 ppm nonroad diesel fuel for the life
of the new desulfurization equipment, as well as potentially delaying
some refiners' decision to invest in new desulfurization equipment due
to uncertainties in cost, performance, etc.
[[Page 28465]]
4. Emission and Benefit Impacts
We used the nonroad model to estimate the emission inventory
impacts associated with this one-step option, as well as the other
options listed in Table VI-1. As for all the alternatives, we then used
the benefits transfer method to estimate the monetized benefits of the
alternative.\296\ The results are shown in Table VI-1. As is evidenced
by the values in Table VI-1, the one-step alternative would achieve
slightly greater PM and NOX emission reductions through 2030
than the proposed 2-step program, with 6,000 and 11,000 additional tons
reduced, respectively (or less than 0.5 percent). Unlike the proposed
2-step program, however, there would be no SO2 emission
reductions in 2007 due to the delay in fuel sulfur control, although
2009 and later emission are slightly greater due primarily to the
earlier introduction of engines using PM filters. Nevertheless, the
SO2 benefits of the one-step program are slightly less than
the proposed 2-step program in the long run, by about 191,000 tons
(about 4 percent) through 2030.
---------------------------------------------------------------------------
\296\ The results that were obtained for Option 1a were
extrapolated based on the emission inventory changes to the proposed
program and were obtained for the other alternatives by assuming the
air quality changes between the alternative and the actual case run
were small enough to allow for such extrapolation. An explanation of
the benefits transfer method is contained in Chapter 9 of the draft
RIA.
---------------------------------------------------------------------------
After careful consideration of these matters, we have decided to
propose the two-step approach in today's notice. The two-step program
avoids adverse risks to the smooth implementation of the entire Tier 4
nonroad program that could be caused by the significantly shortened
lead-time and stability of the one-step program. There are also
concerns about the potential negative impacts the one-step option may
have on the 2007 highway program, including the implications of the
overlap of implementation schedules (see above and Chapter 12 of the
draft RIA). Nevertheless, we believe that the one-step approach is a
regulatory alternative worth considering. In addition to seeking
comment on our proposed program, we also seek comment on the relative
merits and shortcomings of a one-step approach to regulating nonroad
diesel fuel and the associated schedule for implementing the engine
standards.
C. Applying 15 ppm Requirement to Locomotive and Marine Diesel Fuel
To enable the high efficiency exhaust emission control technology
to begin to be applied to nonroad diesel engines beginning with the
2011 model year, we are proposing that all nonroad diesel fuel produced
or imported after June 1, 2010 would have to meet a 15 ppm sulfur cap.
Although locomotive and marine diesel engines are similar in size to
some of the diesel engines covered in this proposal, there are many
differences that have caused us to treat them separately in past EPA
programs.\297\ These include differences in duty cycles and exhaust
system design configurations, size, and rebuild and maintenance
practices. Because of these differences, we are not proposing new
engine standards today for these engine categories. Since we are not
proposing more stringent emission standards, we are also not proposing
that the second step of sulfur control to 15 ppm in 2010 be applied to
locomotive and marine diesel fuel. Instead, we are proposing to set a
sulfur fuel content standard of 500 ppm for diesel fuel used in
locomotive and marine applications. This fuel standard is expected to
provide considerable sulfate PM and SO2 benefits even
without establishing more stringent emission standards for these
engines. We estimate that, cumulatively through 2030, reducing the
sulfur content of locomotive and marine diesel fuel would eliminate
about 102,000 tons of sulfate PM (net present value, based on a 3
percent discount rate).
---------------------------------------------------------------------------
\297\ Locomotives, in fact, are treated separately from other
nonroad engines and vehicles in the Clean Air Act, which contains
provisions regarding them in section 213(a)(5). Less than 50 hp
marine engines were included in the 1998 final rule for nonroad
diesel engines, albeit with some special provisions to deal with
marine-specific engine characteristics and operating cycles.
---------------------------------------------------------------------------
As discussed in section IV, we are seriously considering the option
of extending the 15 ppm sulfur standard to locomotive and marine fuel
as early as June 1, 2010, including them in the second step of the
proposed two-step program. There are several advantages associated with
this alternative. First, as reflected in Table VI-1, it would provide
important additional sulfate PM and SO2 emission reductions
and the estimated benefits from these reductions would outweigh the
costs by a considerable margin. Second, in some ways it would simplify
the fuel distribution system and the design of the fuel program
proposed today since a marker would not be required for locomotive and
marine diesel fuel. Furthermore, the prices for locomotive and marine
diesel fuel may be virtually unaffected. Under the proposal, we expect
that a certain amount of marine fuel will be 15 ppm sulfur fuel
regardless of the standard due to limitations in the production and
distribution of unique fuel grades. Where 500 ppm fuel is available,
the possible suppliers of fuel will likely be more constrained,
limiting competition and allowing prices to approach that of 15 ppm
fuel. If we were to bring locomotive and marine fuel to 15 ppm, the
pool of possible suppliers could expand beyond those today, since
highway diesel fuel will also be at the same standard. Third, it would
help reduce the potential opportunity for misfueling of 2007 and later
model year highway vehicles and 2011 and later model year nonroad
equipment with higher sulfur fuel. Finally, it would allow refiners to
coordinate plans to reduce the sulfur content of all of their nonroad,
locomotive, and marine diesel fuel at one time. While in many cases
this may not be a significant advantage, it may be a more important
consideration here since it is probably not a question of whether
locomotive and marine fuel must meet a 15 ppm cap, but merely when. As
discussed in section IV, it is the Agency's intention to propose action
in the near future to set new emission standards for locomotive and
marine engines that could require the use of high efficiency exhaust
emission control technology, and thus, also require the use of 15 ppm
sulfur diesel fuel.\298\ We anticipate that such engine standards would
likely take effect in the 2011-13 timeframe, requiring 15 ppm
locomotive and marine diesel fuel in the 2010-12 timeframe. We intend
to publish an advance notice of proposed rulemaking for such standards
by the Spring of 2004 and finalize those standards by 2007.
---------------------------------------------------------------------------
\298\ EPA established the most recent new standards for
locomotives and marine diesel engines (including those under 50 hp)
in separate actions (63 FR 18977, April 16, 1998, and 67 FR 68241,
November 8, 2002).
---------------------------------------------------------------------------
However, discussions with refiners have suggested there are
significant advantages to leaving locomotive and marine diesel fuel at
500 ppm, at least in the near-term and until we set more stringent
standards for those engines. The locomotive and marine diesel fuel
markets could provide an important market for off-specification
product, particularly during the transition to 15 ppm for highway and
nonroad diesel fuel in 2010. Waiting just a year or two beyond 2010
would address the critical near-term needs during the transition. In
addition, waiting just another year or two beyond 2010 is also
projected to allow virtually all refiners to take advantage of the new
lower cost technology.
After careful consideration of these matters, we have decided not
to propose
[[Page 28466]]
to apply the second step of sulfur control of 15 ppm to locomotive and
marine diesel fuel at this time. Nevertheless, for the reasons
described above, we are carefully weighing whether it would be
appropriate to do so. Therefore, we seek comment on this alternative
and the various advantages, disadvantages, and implications of it.
D. Other Alternatives
We have also analyzed a number of other alternatives, as summarized
in Table VI-1. Some of these focus on control options more stringent
than our proposal while others reflect modified engine requirements
that result in less stringent control. EPA has evaluated these options
in terms of the feasibility, emissions reductions, costs, and other
relevant factors. EPA believes the proposed approach is the proper one
with respect to these factors, and believes the options discussed above
while having possible merit in some areas, raise what we believe are
different and significant concerns with respect to these factors
compared to the proposed approach. Hence we did not include these
options. These concerns are discussed in more detail in Chapter 12.
These concerns are discussed in more detail in Chapter 12 of the draft
RIA. Hence, we did not include these options as part of our proposal
for nonroad fuel and engine controls. We are interested in comment on
these alternatives, especially information regarding their feasibility,
costs, and other relevant concerns.
VII. Requirements for Engine and Equipment Manufacturers
This section describes the regulatory changes proposed for the
engine and equipment compliance program. First, the proposed
regulations for Tier 4 engines have been written in plain language.
They are structured to contain the provisions that are specific to
nonroad CI engines in a new proposed part 1039, and to apply the
general provisions of existing parts 1065 and 1068. The proposed plain
language regulations, however, are not intended to significantly change
the compliance program, except as specifically noted in today's notice
(and we are not soliciting comment on any part of the rule that remains
unchanged substantively). As proposed, these plain language regulations
would only apply for Tier 4 engines. The changes from the existing
nonroad program are described below along with other notable aspects of
the compliance program.
A. Averaging, Banking, and Trading
1. Are We Proposing To Keep the ABT Program for Nonroad Diesel Engines?
EPA has included averaging, banking, and trading (ABT) programs in
most mobile source emission control programs adopted in recent years.
Our existing regulations for nonroad diesel engines include an ABT
program (Sec. 89.201 through Sec. 89.212). We are proposing to retain
the basic structure of the existing nonroad diesel ABT program with
today's notice, though we are proposing a number of changes to
accommodate implementation of the proposed emission standards. Behind
these changes is the recognition that the proposed standards represent
a major technological challenge to the industry. The proposed ABT
program is intended to enhance the ability of engine manufacturers to
meet the stringent standards proposed today. The proposed program is
also structured to limit production of very high-emitting engines and
to avoid unnecessary delay of the transition to the new exhaust
emission control technology.
We view the proposed ABT program as an important element in setting
emission standards that are appropriate under CAA section 213 with
regard to technological feasibility, lead time, and cost. The ABT
program helps to ensure that the stringent standards we are proposing
are appropriate under section 213(a) given the wide breadth and variety
of engines covered by the standards. For example, if there are engine
families that will be particularly costly or have a particularly hard
time coming into compliance with the standard, this flexibility allows
the manufacturer to adjust the compliance schedule accordingly, without
special delays or exceptions having to be written into the rule.
Emission-credit programs also create an incentive (for example, to
generate credits in early years to create compliance flexibility for
later engines) for the early introduction of new technology, which
allows certain engine families to act as trailblazers for new
technology. This can help provide valuable information to manufacturers
on the technology before they apply the technology throughout their
product line. This early introduction of clean technology improves the
feasibility of achieving the standards and can provide valuable
information for use in other regulatory programs that may benefit from
similar technologies. Early introduction of such engines also secures
earlier emission benefits.
In an effort to make information on the ABT program more available
to the public, we intend to issue periodic reports summarizing use of
the proposed ABT program by engine manufacturers. The information
contained in the periodic reports would be based on the information
submitted to us by engine manufacturers, and summarized in a way that
protects the confidentiality of individual engine manufacturers. We
believe this information will also be helpful to engine manufacturers
by giving them a better indication of the availability of credits.
Again, our periodic reports would not contain any confidential
information submitted by individual engine manufacturers, such as sales
figures. Also, the information would be presented in a format that
would not allow such confidential information to be determined from the
reports.
2. What Are the Provisions of the Proposed ABT Program?
The following section describes the changes proposed to the
existing ABT program. In addition to those areas specifically
highlighted, we are soliciting comments on all aspects of the proposed
ABT changes, including comments on the need for and benefit of these
changes to manufacturers in meeting the proposed emission standards.
The ABT program has three main components. Averaging means the
exchange of emission credits between engine families within a given
engine manufacturer's product line. (Engine manufacturers divide their
product line into ``engine families'' that are comprised of engines
expected to have similar emission characteristics throughout their
useful life.) Averaging allows a manufacturer to certify one or more
engine families at levels above the applicable emission standard, but
below a set upper limit. However, the increased emissions must be
offset by one or more engine families within that manufacturer's
product line that are certified below the same emission standard, such
that the average emissions from all the manufacturer's engine families,
weighted by engine power, regulatory useful life, and production
volume, are at or below the level of the emission standard. (The
inclusion of engine power, useful life, and production volume in the
averaging calculations is designed to reflect differences in the in-use
emissions from the engines.) Averaging results are calculated for each
specific model year. The mechanism by which this is accomplished is
certification of the engine family to a ``family emission limit'' (FEL)
set by the manufacturer, which may be above or below the standard. An
FEL that is established
[[Page 28467]]
above the standard may not exceed an upper limit specified in the ABT
regulations. Once an engine family is certified to an FEL, that FEL
becomes the enforceable emissions limit for all the engines in that
family for purposes of compliance testing. Averaging is allowed only
between engine families in the same averaging set, as defined in the
regulations.
Banking means the retention of emission credits by the engine
manufacturer for use in future model year averaging or trading. Trading
means the exchange of emission credits between nonroad diesel engine
manufacturers which can then be used for averaging purposes, banked for
future use, or traded to another engine manufacturer.
The existing ABT program for nonroad diesel engines covers
NMHC+NOX emissions as well as PM emissions. With today's
notice we are proposing to make the ABT program available for the
proposed NOX standards and proposed PM standards. (For
engines less than 75 horsepower where we are proposing combined
NMHC+NOX standards, the ABT program would continue to be
available for the proposed NMHC+NOX standards as well as the
proposed PM standards.) ABT would not be available for the proposed
NMHC standards for engines above 75 horsepower or for the proposed CO
standards for any engines.
As noted earlier, the existing ABT program for nonroad diesel
engines includes FEL caps--limits on how high the emissions from
credit-using engine families can be. No engine family may be certified
above these FEL caps. These limits provide the manufacturers compliance
flexibility while protecting against the introduction of unnecessarily
high-emitting engines. When we propose new standards, we typically
propose new FEL caps for the new standards. In the past, we have
generally set the FEL caps at the emission levels allowed by the
previous standard, unless there was some specific reason to do
otherwise. We are proposing to do otherwise here because the proposed
standard levels in today's notice are so much lower than the current
standards levels, especially the Tier 4 standards for engines above 75
horsepower. The transfer to new technology is feasible and appropriate.
Thus, to ensure that the ABT provisions are not used to continue
producing old-technology high-emitting engines under the new program,
the proposed FEL caps would not, in general, be set at the previous
standards. An exception is for the proposed NMHC+NOX
standard for engines between 25 and 50 horsepower effective in model
year 2013, where we are proposing to use the previously applicable
NMHC+NOX standard for the FEL cap since the gap between the
previous and proposed standards is approximately 40 percent (rather
than 90 percent for engines above 75 horsepower).
For engines above 75 horsepower certified during the phase-in
period, there would be two separate sets of engines with different FEL
caps. For engines certified to the existing (Tier 3)
NMHC+NOX standards during the phase-in, the FEL cap would
necessarily continue to be the existing FEL caps as adopted in the
October 1998 rule. For engines certified to the proposed Tier 4
NOX standard during the phase-in, the FEL cap would be 3.3
g/bhp-hr for engines between 75 and 100 horsepower, 2.8 g/bhp-hr for
engines between 100 and 750 horsepower, and 4.6 g/bhp-hr for engines
above 750 horsepower. These proposed NOX FEL caps represent
an estimate of the NOX emission level that is expected under
the combined NMHC+NOX standards that apply with the existing
previous tier standards. Beginning in model year 2014 when the proposed
Tier 4 NOX standard for engines above 75 horsepower take
full effect, we are proposing a NOX FEL cap of 0.60 g/bhp-hr
for engines above 75 horsepower. (As described below, we are proposing
to allow a small number of engines greater than 75 horsepower to have
NOX FELs above the 0.60 g/bhp-hr cap beginning in model year
2014.) Given the fact that the proposed Tier 4 NOX standard
is approximately a 90 percent reduction from the existing standards for
engines above 75 horsepower, we do not believe the previous standard
would be appropriate as the FEL cap for all engines once the Tier 4
standards are fully phased-in. We believe that the proposed
NOX FEL caps will ensure that manufacturers adopt
NOX aftertreatment technology across all of their engine
designs (with the exception of a limited number) but will also allow
for some meaningful use of averaging during the phase-in period. When
compared to the proposed 0.30 g/bhp-hr NOX standard, the
proposed NOX FEL cap of 0.60 g/bhp-hr (effective when the
Tier 4 standards are fully phased-in) is consistent with FEL caps set
in previous rulemakings.
For the transitional PM standards being proposed for engines
between 25 and 75 horsepower effective in model year 2008 and for the
Tier 4 PM standards for engines below 25 horsepower, we are proposing
the previously applicable Tier 2 PM standards (which do vary within the
25 to 75 horsepower category) for the FEL caps since the gap between
the previous and proposed standards is approximately 50 percent (rather
than in excess of 90 percent for engines above 75 horsepower). For the
proposed Tier 4 PM standard effective in model year 2013 for engines
between 25 and 75 horsepower, we are proposing a PM FEL cap of 0.04 g/
bhp-hr, and for the proposed Tier 4 PM standard effective in model
years 2011 and 2012 for engines between 75 and 750 horsepower, we are
proposing a PM FEL cap of 0.03 g/bhp-hr. (As described below, we are
proposing to allow a small number of Tier 4 engines greater than 25
horsepower to have PM FELs above these caps.) Given the fact that the
proposed Tier 4 PM standards for engines above 25 horsepower are less
than 10 percent of the previous standards, we do not believe the
previous standards would be appropriate as FEL caps once the Tier 4
standards take effect. We believe that the proposed PM FEL caps will
ensure that manufacturers adopt PM aftertreatment technology across all
of their engine designs (except for a limited number of engines), yet
will still provide substantial flexibility in meeting the standards.
For the proposed Tier 4 PM standards for engines above 750
horsepower there is a phase-in period during model years 2011 through
2013. During the phase-in period, there would be two separate sets of
engines with different FEL caps. For engines certified to the existing
Tier 2 PM standard, the FEL cap would continue to be the existing PM
FEL cap adopted in the October 1998 rule. For engines certified to the
proposed Tier 4 PM standard during the phase-in, the FEL cap would be
0.15 g/bhp-hr (the PM standard for the previous tier). Beginning in
model year 2014, when the proposed Tier 4 PM standard for engines above
750 horsepower takes full effect, consistent with the proposed caps for
lower horsepower categories, we are proposing a PM FEL cap of 0.03 g/
bhp-hr. (As described below, we are proposing to allow a small number
of engines greater than 750 horsepower to have PM FELs above the 0.03
g/bhp-hr cap beginning in model year 2014.) We believe that the
proposed PM FEL caps for engines above 750 horsepower will ensure that
manufacturers adopt PM aftertreatment technology across all of their
engine designs once the standard is fully phased-in (with the exception
of a limited number) while allowing for some meaningful use of
averaging during the phase-in period.
Table VII.A-1 contains the proposed FEL caps and the effective
model year
[[Page 28468]]
for the FEL caps (along with the associated standards proposed for Tier
4). We request comment on the need for and the levels of these proposed
FEL caps. It should be noted that for Tier 4, where we are proposing a
new transient test, as well as retaining the current steady-state test,
the FEL established by the engine manufacturer would be used as the
enforceable limit for the purpose of compliance testing under both test
cycles. In addition, under the NTE requirements, the FEL times the
appropriate multiplier would be used as the enforceable limit for the
purpose of such compliance testing.
Table VII.A-1.--Proposed FEL Caps for the Proposed Tier 4 Standards in the ABT Program
[g/bhp-hr]
--------------------------------------------------------------------------------------------------------------------------------------------------------
NOX
Power category Effective model year standard NOX FEL cap PM standard PM FEL cap
--------------------------------------------------------------------------------------------------------------------------------------------------------
hp < 25 (kW < 19)..................... 2008+........................... (\a\) (\a\).................................. \b\ 0.30 0.60
25 <= hp < 50 (19 <= kW < 37)......... 2008-2012....................... (\a\) (\a\).................................. 0.22 0.45
25 <= hp < 50 (19 <= kW < 37)......... 2013+\d\........................ \e\ 3.5 5.6 \e\................................ 0.02 \f\ 0.04
50 <= hp < 75 (37 <= kW < 56)......... 2008-2012....................... (\a\) (\a\).................................. 0.22 0.30
50 <= hp < 75 (37 <= kW < 56)......... 2013+........................... (\a\) (\a\).................................. 0.02 \f\ 0.04
75 <= hp <175 (56 <= kW <130)......... 2012-2013 \g\................... 0.30 3.3 for hp < 100 2.8 for hp = 100.
75 <= hp <175 (56 <= kW <130)......... 2014+........................... 0.30 0.60 \f\............................... 0.01 \f\ 0.03
175 <= hp <=750 (130 <= kW <=560)..... 2011-2013....................... 0.30 2.8.................................... 0.01 \f\ 0.03
175 <= hp <=750 (130 <= kW <=560)..... 2014+........................... 0.30 0.60 \f\............................... 0.01 \f\ 0.03
hp 750 (kW 560). 2011-2013....................... 0.30 4.6.................................... 0.01 0.15
hp 750 (kW 560). 2014+........................... 0.30 0.60 \f\............................... 0.01 \f\ 0.03
--------------------------------------------------------------------------------------------------------------------------------------------------------
Notes:
\a\ The existing NMHC+NOX standard and FEL cap apply (see CFR Title 40, section 89.112).
\b\ A PM standard of 0.45 g/bhp-hr would apply to air-cooled, hand-startable, direct injection engines under 11 horsepower, effective in 2010.
\c\ The proposed FEL caps do not apply if the manufacturer elects to comply with the optional standards. The existing FEL caps continue to apply.
\d\ FEL caps apply in model year 2012 if the manufacturer elects to comply with the optional standards.
\e\ These are a combined NMHC+NOX standard and FEL cap.
\f\ As described in this section, a small number of engines are allowed to exceed these FEL caps.
\g\ This period would extend through the first nine months of 2014 under the alternative, reduced phase-in requirement (see Section III.B.1. for a
description of the proposed alternative).
As noted above, we are proposing to allow a limited number of
engines to have a higher FEL than the caps noted in Table VII.A-1 in
certain instances. Under this proposal, the allowance to certify up to
these higher FEL caps would apply to Tier 4 engines at or above 25
horsepower. The provisions are intended to provide some limited
flexibility for engine manufacturers as they transition to the
stringent standards while ensuring that the vast majority of engines
are converted to the advanced low-emission technologies expected under
the Tier 4 program. This additional lead time appears appropriate,
given the potential that a limited set of nonroad engines may face
especially challenging difficulties in complying, and considering
further that the same amount of overall emission reductions would be
achieved through the need for credit-generating nonroad engines.
Beginning the first year Tier 4 standards apply in each power
category above 25 horsepower, an engine manufacturer would be allowed
to certify up to ten percent of its engines in each power category with
PM FELs above the caps shown in Table VII.A-1. The PM FEL cap for such
engines would instead be the applicable previous tier PM standard. The
ten percent allowance would be available for the first four years the
Tier 4 standards apply. For the power categories in which we are
proposing a phase-in requirement for the Tier 4 NOX
standards, the allowance to use a higher FEL cap would apply only to PM
during the phase-in years. Once the phase-in period is complete, the
allowance would apply to NOX as well. (For engines above 750
horsepower, where we are proposing a phase-in for both NOX
and PM, the allowance to use a higher FEL cap would not take effect
until model year 2014 when the phase-in was complete.)
After the fourth year the Tier 4 standards apply, the allowance to
certify engines using the higher FEL caps would still be available but
for no more than five percent of a manufacturer's engines in each power
category. (For the power category between 25 and 75 horsepower, this
allowance would apply beginning with the 2013 model year and would
apply to PM. The allowance to use the higher FEL caps is not necessary
for the 2008 proposed standards or the 2013 proposed
NMHC+NOX standards because the FEL caps for those standards
are set at the previously applicable tier standards.)
Table VII.A-2 presents the model years, percent of engines, and
higher FEL caps that would apply under this allowance. Because the
engines certified with the higher FEL caps are certified to the Tier 4
standards (albeit through the use of credits), they would be considered
Tier 4 engines and all other requirements for Tier 4 engines would also
apply, including the Tier 4 NMHC standard. We invite comment on whether
additional provisions may be necessary for the limited number of
engines certified to the higher FELs, including whether an averaging
program for NMHC would be needed.
[[Page 28469]]
Table VII.A-2.--Allowance for Limited Use of an FEL Cap Higher Than the Tier 4 FEL Caps
--------------------------------------------------------------------------------------------------------------------------------------------------------
Engines
allowed to
Power category Model years have higher NOX FEL cap (g/bhp-hr) PM FEL cap (g/bhp-hr)
FELs
--------------------------------------------------------------------------------------------------------------------------------------------------------
25 <= hp <75 (19 <= kW < 56)......... 2013-2016....................... 10 Not applicable......... 0.22.
2017+........................... 5 ......................................
--------------------------------------
75 <= hp <175 (56 <= kW <130)........ 2012-2013a...................... 10 Not applicable......... 0.30 for hp <100.
---------------------------------------------------------------------------
2014-2015....................... 10 3.3 for hp <100........ 0.22 for hp =100.
--------------------------------------------------
2016+........................... 5 2.8 for hp =100.
--------------------------------------
175 <= hp <=750 (130 <= kW <= 560)... 2011-2013....................... 10 Not applicable......... 0.15.
--------------------------------------------------
2015+........................... 5 ......................................
--------------------------------------
hp 750 (kW 2014-2017....................... 10 4.6.................... 0.15.
560).
--------------------------------------------------
2018+........................... 5 ......................................
--------------------------------------------------------------------------------------------------------------------------------------------------------
a This period would extend through the first nine months of 2014 under the alternative, reduced phase-in requirement (see Section III.B.1. for a
description of the proposed alternative).
We request comment on the proposed provisions to allow higher FELs
on a limited number of Tier 4 engines, including whether the proposed
allowance limits of 10 percent and 5 percent have been set at the right
levels and whether the allowance to use a higher FEL cap is appropriate
for the Tier 4 program. We also request comment on allowing
manufacturers to use the allowances in a slightly different manner over
the first four years. Instead of allowing manufacturers to certify up
to ten percent for each of the first four years, manufacturers could
certify up to 40 percent of one year's production but spread it out
over four years in an unequal manner (e.g., 15 percent in the first and
second years, and 5 percent in the third and fourth years). Last of
all, we request comment on whether the allowance should be available
for NOX during the years we a proposing a phase-in for the
Tier 4 NOX standards. As proposed, we would not cover
NOX during the phase-in years because manufacturers already
can certify up to 50 percent of their engines to the Tier 3
NMHC+NOX standards.
Under the proposed Tier 4 program, for engines above 75 horsepower
there will be two different groups of engines during the phase-in
period. In one group, engines would certify to the applicable Tier 3
NMHC+NOX standard (or Tier 2 standard for engines above 750
horsepower), and would be subject to the ABT restrictions and
allowances previously established for those tiers. In the other group,
engines would certify to the 0.30 g/bhp-hr NOX standard, and
would be subject to the restrictions and allowances in this proposed
program. While engines in each group are certified to different
standards, we are proposing to allow manufacturers to transfer credits
across these two groups of engines with the following adjustment. As
proposed, manufacturers could use credits generated during the phase-
out of engines subject to the Tier 3 NMHC+NOX standard (or
Tier 2 NMHC+NOX standard for engines above 750 horsepower)
to average with engines subject to the 0.30 g/bhp-hr NOX
standard, but these credits will be subject to a 20 percent discount.
In other words, each gram of NMHC+NOX credits from the
phase-out engines would be worth 0.8 grams of NOX credits in
the new ABT program. The ability to average credits between the two
groups of engines will give manufacturers a greater opportunity to gain
experience with the low-NOX technologies before they are
required to meet the final Tier 4 standards across their full
production. (The 20 percent discount would also apply to
NMHC+NOX credits generated on less than 75 horsepower
engines and used for averaging purposes with the NOX
standards for engines greater than 75 horsepower.)
We are proposing the 20 percent discount for two main reasons.
First, the discounting addresses the fact that NMHC reductions can
provide substantial NMHC+NOX credits, which are then treated
as though they were NOX credits. For example, a 2010 model
year engine (between 175 and 750 horsepower) emitting at 2.7 g/bhp-hr
NOX and 0.3 g/bhp-hr NMHC meets the 3.0 g/bhp-hr
NMHC+NOX standard in that year, but gains no credits. In
2011, that engine, equipped with a PM trap to meet the new PM standard,
will have very low NMHC emissions because of the trap, an emission
reduction already accounted for in our assessment of the air quality
benefit of this program. As a result, without substantially redesigning
the engine to reduce NOX or NMHC, the manufacturer could
garner a windfall of nearly 0.3 g/bhp-hr of NMHC+NOX credit
for each of these engines produced. (Engines designed at lower
NOX levels than this in 2010 can gain even more credits.)
Allowing these NMHC-derived credits to be used undiscounted to offset
NOX emissions on the phase-in engines in 2011 (for which
each 0.1 g/bhp-hr of margin can make a huge difference in facilitating
the design of engines to meet the 0.30 g/bhp-hr NOX
standard) would be inappropriate. Second, the discounting would work
toward providing a net environmental benefit from the ABT program, such
that the more that manufacturers use banked and averaged credits, the
greater the potential emission reductions overall.
Some foreign engine manufacturers have commented that it is
difficult for them to accurately predict the number of engines that
eventually end up in the U.S., especially when they sell to a number of
different equipment manufacturers who may import equipment. This would
make it difficult for the engine manufacturer to ensure they are
complying with the proposed NOX phase-in requirements for
engines above 75 horsepower and the proposed PM phase-in requirements
for engines above 750 horsepower. Therefore, we are proposing to allow
engine
[[Page 28470]]
manufacturers to demonstrate compliance with the NOX phase
in requirements for engines above 75 horsepower and the PM phase in
requirements for engines above 750 horsepower by certifying ``split''
engine families (i.e., an engine family that is split into two equal-
sized subfamilies, one that generates a number of credits and one that
uses an equal number of credits). In order to facilitate compliance
with the proposed standards, we are proposing that this option be
available to all engine manufacturers (i.e., both foreign and domestic
manufacturers). Manufacturers would be allowed to certify split engine
families with FELs no higher than the levels specified in Table VII.A-
3. The maximum NOX FEL values specified in Table VII.A-3
were set at the level which would result in NOX ABT credits
from engines above the Tier 4 standards offsetting ABT credits from
engines below the previously applicable NMHC+NOX standards,
including the 20 percent discount for using NMHC+NOX credits
on Tier 4 engines. The maximum PM FEL value for engines above 750
horsepower was set at the level halfway between the Tier 2 and proposed
Tier 4 PM standard for engines above 750 horsepower. Manufacturers
certifying split engine families would exclude those engines from end
of the year ABT calculations (and therefore would not need to determine
actual U.S. sales of such engine families for ABT credit calculation
purposes). Manufacturers certifying split engine families would also
exclude those engines from the calculations demonstrating compliance
with the phase-in percentage requirements as well.
Table VII.A-3.--Maximum FEL for Engine Families Certified as ``Split''
Engine Families
------------------------------------------------------------------------
Maximum
Power category Pollutant FEL, g/
bhp-hr
------------------------------------------------------------------------
75 <= hp 175 (56 <= kW NOX.................... \a\ 1.7
<130).
175 <= hp <=750 (130 <= kW <560)... NOX.................... 1.5
hp 750 (kW X.................... 2.3
eq>560).
hp 750 (kW 560).
------------------------------------------------------------------------
Notes:
\a\ A limit of 2.5 g/bhp-hr would apply under the alternative, reduced
phase-in requirement (see Section III.B.1. for a description of the
proposed alternative).
We are proposing one additional restriction on the use of credits
under the ABT program. For the proposed Tier 4 standards we are
proposing that manufacturers may only use credits generated from other
Tier 4 engines or from engines certified to the previous tier of
standards (i.e., Tier 2 for engines below 50 horsepower, Tier 3 for
engines between 50 and 750 horsepower, and Tier 2 engines above 750
horsepower). (As discussed in more detail below, we are proposing
slightly different restrictions on the use of previous tier credits for
engines between 75 and 175 horsepower.) We currently have a similar
provision that prohibits the use of Tier 1 credits to demonstrate Tier
3 compliance, and given the levels of the final Tier 4 standards being
proposed today, we believe it is appropriate to apply a similar
restriction. Otherwise, we would be concerned about the possibility
that credits from engines certified to relatively high standards could
be used to significantly delay the implementation of the final Tier 4
program and its benefits.
For reasons explained in Section III.B.1.b. of today's notice, we
are proposing unique phase-in requirements for engines between 75 and
175 horsepower in order to ensure appropriate lead time for these
engines. Because of these unique phase-in provisions for engines
between 75 and 175 horsepower, we are proposing slightly different
provisions regarding the use of previous-tier credits. Under this
proposal, manufacturers that choose to demonstrate compliance with the
proposed phase-in requirements (i.e., 50 percent in 2012 and 2013 and
100 percent in 2014) would be allowed to use Tier 2 NMHC+NOX
credits generated by engines above 50 horsepower (along with any other
allowable credits) to demonstrate compliance with the Tier 4 standards
for engines between 75 and 175 horsepower during model years 2012, 2013
and 2014 only. These Tier 2 credits would be subject to the power
rating conversion already established in our ABT program, and to the
20% credit adjustment we are proposing for use of NMHC+NOX
credits as NOX credits. Manufacturers that choose to
demonstrate compliance with the optional reduced phase-in requirement
for engines between 75 and 175 horsepower, would not be allowed to use
Tier 2 credits generated by engines above 50 horsepower to demonstrate
compliance with the Tier 4 standards. (Use of credits other than banked
Tier 2 credits from engines above 50 horsepower would still be allowed,
in accordance with other ABT program provisions.) In addition,
manufacturers choosing the reduced phase-in option would not be allowed
to generate NOX credits from engines in this power category
in 2012, 2013, and the first 9 months of 2014, except for use in
averaging within this power category (i.e., no banking or trading, or
averaging with engines in other power categories would be permitted).
This restriction would apply throughout this period even if the reduced
phase-in option is exercised during only a portion of this period. We
believe that this restriction is important to avoid potential abuse of
the added flexibility allowance, considering that larger engine
categories will be required to demonstrate substantially greater
compliance levels with the 0.30 g/bhp-hr NOX standard
several years earlier than engines built under this option.
Under this proposal, we are not proposing any averaging set
restrictions for Tier 4 engines. An averaging set is a group of
engines, defined by EPA in the regulations, within which manufacturers
may use credits under the ABT program. In the current nonroad diesel
ABT program, there are averaging set restrictions. The current
averaging sets consist of engines less than 25 horsepower and engines
greater than or equal to 25 horsepower. The restriction was adopted
because of concerns over the ability of manufacturers to generate
significant credits from the existing engines and use the credits to
delay compliance with the newly adopted standards. (See 63 FR 56977.)
We believe the proposed Tier 4 standards are sufficiently protective to
limit the ability of manufacturers to generate significant credits from
their current engines. In addition, we believe the proposed FEL caps
provide sufficient assurance that low-emissions technologies will be
introduced in a timely manner. Therefore, under this proposal,
averaging would be allowed between all engine power categories without
restriction effective with the Tier 4 standards. The averaging set
restriction placed on credits generated from Tier 2 and Tier 3 engines
would continue to apply if they are used to demonstrate compliance for
Tier 4 engines.
As described in section III.B.1.d.i. of today's notice, we are also
proposing a separate PM standard for air-cooled, hand-startable, direct
injection engines under 11 horsepower. In order to avoid potential
abuse of this standard, engines certified under this proposed
requirement would not be allowed to generate credits as part of the ABT
program. Credit use by these engines
[[Page 28471]]
would be allowed. The restriction should be no burden to manufacturers,
as it would apply only to those air-cooled, hand-startable, direct
injection engines under 11 horsepower that are certified under the
special standard, and the production of credit-generating engines would
be contrary to the standard's purpose.
The current ABT program contains a restriction on trading credits
generated from indirect injection engines greater than 25 horsepower.
The restriction was originally adopted because of concerns over the
ability of manufacturers to generate significant credits from existing
technology engines. (See 63 FR 56977.) Under this proposal, we are not
proposing the restriction which prohibits manufacturers from trading
credits generated on Tier 4 indirect fuel injection engines greater
than 25 horsepower. Based on the certification levels of indirect
injection engines, we do not believe there is the potential for
manufacturers to generate significant credits from their currently
certified engines against the proposed Tier 4 standards. Therefore, we
are not proposing to restrict the trading of credits generated on Tier
4 indirect injection engines to other manufacturers. The restriction
placed on the trading of credits generated from Tier 2 and Tier 3
indirect injection engines would continue to apply in the Tier 4
timeframe.
We are not proposing to apply a specific discount to Tier 3 PM
credits used to demonstrate compliance with the Tier 4 standards. PM
credits generated under the Tier 3 standards are based on testing
performed over a steady-state test cycle. Under the proposed Tier 4
standards, the test cycle is being supplemented with a transient test
(see Section III.C above and VII.F below). Because in-use PM emissions
from Tier 3 engines will vary depending on the type of application in
which the engine is used (some having higher in-use PM emissions, some
having lower in-use PM emissions), the relative ``value'' of the Tier 3
PM credits in the Tier 4 timeframe will differ. Instead of requiring
manufacturers to gather information to estimate the level of in-use PM
emissions compared to the PM level of the steady-state test, we believe
allowing manufacturers to bring Tier 3 PM credits directly into the
Tier 4 time frame without any adjustment is appropriate because it
discounts their value for use in the Tier 4 timeframe (since the
initial baseline being reduced is probably higher than measured in the
Tier 2 test procedure).
3. Should We Expand the Nonroad ABT Program To Include Credits From
Retrofit of Nonroad Engines?
We are considering expanding the scope of the standards by setting
voluntary new engine standards applicable to the retrofit of nonroad
diesel engines, and allowing these nonroad diesel engines to generate
PM and NOX credits available for use by other nonroad diesel
engines. This program could achieve greater emission reductions of
these pollutants than could otherwise be achieved, in a cost-effective
manner. Specifically, we would allow existing in-use nonroad diesel
engines that are retrofitted to achieve more stringent levels of
emissions than are otherwise required to generate credits available for
use in the ABT program by new nonroad engines. Credit-generating
engines electing to participate in the program would be considered new
nonroad diesel engines, subject to the normal compliance mechanisms
applicable to other new nonroad diesel engines. These new nonroad
engines could generate credits that could be used in the ABT program
for other new nonroad diesel engines. Any such program would also have
to ensure that credits are surplus, verifiable, quantifiable, and
enforceable. We request comment on whether such a program would be
feasible and appropriate for the Tier 4 nonroad standards, and on how
such a program might be structured.
We are considering an approach for credit generation based on the
use of advanced exhaust emission control technology/engine system
combinations that would provide significant emissions reductions. To
accomplish this, simple changes that are easy to circumvent
accidentally or to defeat intentionally would not be eligible to
generate credits, and essentially, only changes involving introduction
of post combustion emissions control technology would be eligible.
Thus, we would structure the program such that engine recalibration as
the sole mechanism to reduce emissions would not be eligible for
retrofit credits. Also, as noted, for purposes of a nonroad retrofit
ABT program, in order to generate credits, the manufacturer of the
nonroad retrofit engine system choosing to participate in the program
would accept that the retrofit engine would be considered a new nonroad
engine, subject to enforceable standards and normal certification and
compliance requirements. We have outlined in a memorandum to the docket
our ideas for meeting these objectives, including possible ways to
structure the program.\299\ This memorandum describes potential
procedures for credit generation, credit use, and a number of
compliance, implementation, and enforcement measures.
---------------------------------------------------------------------------
\299\ Memorandum to the Docket, Chris Lieske and Joseph
McDonald, EPA, Additional Information on Nonroad Retrofit Engine ABT
Credit Concepts, Docket A-2001-28.
---------------------------------------------------------------------------
We recognize that expanding the ABT program in this way would
introduce new issues and complexities to the nonroad Tier 4 program,
and that there are several ways to structure the program. We are
seeking comment on whether such an expansion of the ABT program is
feasible and appropriate, as well as on the details of how a program
could be structured. We have considered and described a possible
framework for nonroad retrofit credits in an effort to help commenters
provide input. The level of detail provided below and in the memorandum
to the docket does not indicate that we have made any decisions on
whether nonroad retrofit credits are appropriate for the ABT program or
about how the program should function. We invite comment not only on
the provisions described below and in the memorandum to the docket, but
also on alternative approaches that commenters believe would lead to a
better overall program.
We are also seeking comment on the timing of a retrofit credits
approach. We believe that if such a program were adopted, credit
generation could start in 2004 at the earliest, and request comment on
ending the program in the 2015 time frame. We view this as primarily a
transitional program which could be most useful in the early years of
the nonroad program. Ending the program in 2015 may also ease concerns
about long-term impact of such a program on the environment.
We encourage commenters to carefully address all aspects of a
nonroad retrofit credits program including its usefulness, feasibility,
compliance and enforcement measures, environmental benefits, and
potential cost savings. We specifically request comment on the
potential for such a program to provide additional emissions reductions
than would otherwise be obtained and request comment on the potential
impacts such provisions would have on emissions reductions associated
with the proposed nonroad standards. We are also interested in comments
on practical issues and details regarding how the program would operate
and be enforced.
a. What would be the environmental impact of allowing ABT nonroad
retrofit credits?
[[Page 28472]]
We would structure any nonroad credit ABT program in a way that
provides greater overall emissions reductions over the life of the
group of nonroad engines involved than would otherwise be achieved.
These additional overall reductions would be achieved by applying a
discount of 20 percent to ABT retrofit credits that are used to meet
nonroad standards. The result of applying a discount would be that each
ABT retrofit credit generated would translate to less than one nonroad
engine credit available for consumption in the nonroad program. For
example, a discount of 20 percent would reduce the consumable credits
by 20 percent. The discount would provide greater overall net emissions
reductions from the use of an ABT retrofit program, and the amount of
this environmental benefit would increase with increased use of the
program. Also, applying a discount would be consistent with past Agency
actions (see additional discussion in the memorandum to the docket
noted above).
A discount would be an essential element of the nonroad retrofit
credit provisions, since one of our objectives if we promulgated such
an expanded ABT program would be to create greater net emission
reductions. The absence of a discount would result in no net
environmental impact, as the generation of credits would lead to
emissions reductions which would be offset by the increase in emissions
when the credits were used. A discount would also serve to mitigate the
potential for net environmental detriments due to uncertainties in
credit calculation and use.
We request comment on whether a discount of 20 percent would be
appropriate given the expectation that the discount will generate cost-
effective emissions reductions that would otherwise not occur, as well
as the more prevalent uncertainties associated with trading credits
between nonroad retrofits and new nonroad engines.
b. How would EPA ensure compliance with retrofit emissions
standards?
If this program were adopted, we would expect to require the
retrofit manufacturer to specify all emissions related maintenance and
to list the type of fuel used to certify its retrofit-engine system and
whether a particular fuel sulfur level is necessary to meet the
standard and to maintain emissions compliance of the retrofit-engine
system in-use. If such a fuel is necessary to maintain emissions
compliance in-use, EPA would also consider the fuel to be ``critical
emission related scheduled maintenance'' under a retrofit engine
program. As a result of such classification, the manufacturer would be
required to demonstrate that proper fueling will be performed in-use.
Such a demonstration would include a showing that the required fuel is
available to, and would be used by, the ultimate consumer or fleet
operator receiving the retrofitted engines. Such retrofitted engines
would also have to be labeled appropriately to reflect the new engine
family and may also require labeling for the type of fuel to be used.
In general, we would require the manufacturer to submit a plan for
implementing all relevant aspects of the retrofit to ensure proper
installation and emissions compliance throughout the useful life
period. A full discussion of compliance issues and possible compliance
provisions, such as recall, in-use testing, useful life, and warranty
is provided in the memorandum to the docket, noted above. We request
comment on these approaches for ensuring in-use compliance with
possible nonroad retrofit emissions standards and requirements.
c. What is the legal authority for a nonroad ABT retrofit program?
Allowing use by new nonroad engines of credits generated by
retrofit of in-use nonroad engines is justified legally as an aspect of
EPA's standard setting authority. As we envision a program, a retrofit
nonroad engine would be considered to be a new nonroad engine when the
manufacturer opts into a voluntary retrofit program (if established).
Upon such opt-in, this new engine would be subject to enforceable
standards under CAA section 213, somewhat similar to opting into the
voluntary Blue Sky series standards (see Section VII.E.2). Thus, the
generation of credits by nonroad retrofits and their use by new engines
subject to Tier 4 would be similar to conventional ABT. Put another
way, the generation of credits by retrofitting in-use non-road engines
and their subsequent use by new nonroad engines subject to the Tier 4
standards is an averaging program involving emission credits generated
by one type of new nonroad engine and used by other new nonroad
engines, similar to conventional ABT programs. With a nonroad retrofit
credit program, and the emissions reductions associated with it, the
overall emission reductions from Tier 4 nonroad engines and nonroad
retrofit engines, taken together, would be the greatest achievable
considering cost, noise, safety and energy factors, and would also be
appropriate after considering those same factors. See also NRDC v.
Thomas, 805 F.2d 410, 425 (D.C. Cir. 1986) (averaging provisions upheld
against challenge that they are inconsistent with NCP provisions), and
Husqvarna AB v. EPA, 254 F.3d 195, 202 (D.C. Cir 2001) (averaging,
banking, and trading provisions cited as an element supporting EPA's
selection of lead time under section 213(b)). At the same time, we also
note that the proposed standards are the greatest achievable (taking
all statutory factors into account) and appropriate independent of the
nonroad retrofit program, as explained elsewhere in this preamble.\300\
---------------------------------------------------------------------------
\300\ There is one minor exception to this analysis. Retrofits
involving use of new nonroad engines as replacement engines in older
nonroad equipment would be justified primarily as an aspect of EPA's
lead time authority under section 213(d). This is because credits
would not be generated from an engine certifying to a more stringent
standard, so that the credit is effectively generated by equipment
rather than by an engine, i.e. generated by something other than a
new non-road engine.
---------------------------------------------------------------------------
B. Transition Provisions for Equipment Manufacturers
1. Why Are We Proposing Transition Provisions for Equipment
Manufacturers?
As EPA developed the 1998 Tier 2/3 standards for nonroad diesel
engines, we determined that provisions were needed to avoid unnecessary
hardship for equipment manufacturers. The specific concern is the
amount of work required and the resulting time needed for equipment
manufacturers to incorporate all of the necessary equipment redesigns
into their applications in order to accommodate engines that have been
redesigned to meet the new emission standards. We therefore adopted a
set of provisions for equipment manufacturers to provide them with
reasonable leadtime for the transition process to the newly adopted
standards. The program consisted of four major elements: (1) A percent-
of-production allowance, (2) a small-volume allowance, (3) availability
of hardship relief, and (4) continuance of the allowance to use up
existing inventories of engines. See 63 at FR 56977-56978 (Oct. 23,
1998).
Given the level of the proposed Tier 4 standards, we believe that
there will be engine design changes comparable in magnitude to those
involved during the transition to Tier 2/3. We thus believe that at
least some equipment manufacturers will face comparable challenges
during the transition to the Tier 4 standards. This is confirmed by
comments to EPA by a number of the equipment Small Entity
Representatives during the SBREFA process, which indicated that the
Tier 2/3 transition provisions were proving beneficial in providing
adequate leadtime and urging
[[Page 28473]]
EPA to adopt comparable provisions in a Tier 4 rule. See Report of the
Small Business Advocacy Review Panel, section 8.4.1 (Dec. 23, 2002).
Therefore, with a few exceptions described in more detail below, we are
proposing to adopt transition provisions for Tier 4 in this notice that
are similar to those adopted with the previous Tier 2/3 rulemaking. The
following section describes the proposed transition provisions
available to equipment manufacturers. (Section VII.C. of today's notice
describes all of the proposed provisions that would be available
specifically for small businesses.)
Our experience to date with the transition provisions for the Tier
2/3 standards above 50 horsepower is limited. In the one power category
where manufacturers have been required to submit information on the
number of engines using the allowances (engines between 300 and 600
horsepower), approximately 20 percent of the engines in the category
are relying on the allowances in the first year that the Tier 2
standards apply. (For the power categories below 50 horsepower,
manufacturers are reporting that there are very few engines using
allowances. However, given the level of the Tier 1 standards, we would
not expect there to have been much need for equipment redesign to
handle Tier 1 engines.) While this information is useful, we do not
believe there is enough information available to determine if the level
of the existing allowances should be revised for the Tier 4 proposal.
For this reason, we are primarily relying on the provisions of the Tier
2/3 equipment manufacturer transition provisions for the Tier 4
proposal. However, as described in more detail below, we are proposing
to add notification, reporting, and labeling requirements to the Tier 4
proposal, which are not required in the existing transition provisions
for equipment manufacturers. We believe these additional proposed
provisions are necessary for EPA to gain a better understanding of the
extent to which these provisions will be used and to ensure compliance
with the Tier 4 transition provisions. We are also proposing new
provisions dealing specifically with foreign equipment manufacturers
and the special concerns raised by the use of the transition provisions
for equipment imported into the U.S.
As under the existing provisions, equipment manufacturers would not
be obligated to use any of these provisions, but all equipment
manufacturers would be eligible to do so. Also, as under the existing
program, we are proposing that all entities under the control of a
common entity, and that meet the definition in the regulations of a
nonroad vehicle or nonroad equipment manufacturer contained in the
regulations, would have to be considered together for the purposes of
applying exemption allowances. This would not only provide certain
benefits for the purpose of pooling exemptions, but would also preclude
the abuse of the small-volume allowances that would exist if companies
could treat each operating unit as a separate equipment manufacturer.
2. What Transition Provisions Are We Proposing for Equipment
Manufacturers?
a. Percent-of-Production Allowance
Under the proposed percent-of-production allowance, each equipment
manufacturer may install engines not certified to the proposed Tier 4
emission standards in a limited percentage of machines produced for the
U.S. market. Equipment manufacturers would need to provide written
assurance to the engine manufacturer that such engines are being
procured for the purpose of the transition provisions for equipment
manufacturers. These engines would instead have to be certified to the
standards that would apply in the absence of the Tier 4 standards
(i.e., Tier 2 for engines below 50 horsepower, Tier 3 for engines
between 50 and 750 horsepower,\301\ and Tier 2 for engines above 750
horsepower). This percentage would apply separately to each of the
proposed Tier 4 power categories (engines below 25 horsepower, engines
between 25 and 75 horsepower, engines between 75 and 175 horsepower,
engines between 175 and 750 horsepower, and engines above 750
horsepower) and is expressed as a cumulative percentage of 80 percent
over the seven years beginning when the Tier 4 standards first apply in
a category. No exemptions would be allowed after the seventh year. For
example, an equipment manufacturer could install engines certified to
the Tier 3 standards in 40 percent of its entire 2011 production of
nonroad equipment that use engines rated between 175 and 750
horsepower, 30 percent of its entire 2012 production in this horsepower
category, and 10 percent of its entire 2013 production in this
horsepower category. (During the transitional period for the Tier 4
standards, the fifty percent of engines that would be allowed to
certify to the previous tier NOX standard but meet the Tier
4 PM standard would be considered as Tier 4-compliant engines for the
purpose of the equipment manufacturer transition provisions.) If the
same manufacturer were to produce equipment using engines rated above
750 horsepower, a separate cumulative percentage allowance of 80
percent would apply to these machines during the seven years beginning
in 2011. This proposed percent-of-production allowance is almost
identical to the percent-of-production allowance adopted in the October
1998 final rule, the difference being, as explained earlier, that we
are proposing to have fewer power categories associated with the
proposed Tier 4 standards.
---------------------------------------------------------------------------
\301\ Under this proposal, for engines between 50 and 75
horsepower, the NMHC+NOX standard that would apply in
Tier 4 is the same as the existing Tier 3 NMHC+NOX
standard.
---------------------------------------------------------------------------
The proposed 80 percent exemption allowance, were it to be used to
its maximum extent by all equipment manufacturers, would bring about
the introduction of cleaner engines several months later than would
have occurred if the new standards were to be implemented on their
effective dates. However, the equipment manufacturer flexibility
program has been integrated with the standard-setting process from the
initial development of this proposal, and as such we believe it is a
key factor in assuring that there is sufficient lead time to initiate
the Tier 4 standards according to the proposed schedule.\302\
---------------------------------------------------------------------------
\302\ For emissions modeling purposes, we have assumed that
manufacturers take full advantage of the existing allowances under
the transition program for equipment manufacturers in establishing
the emissions baseline. This assumption is based on information
provided to us by engine manufacturers for model year 2001, which
shows that approximately 20 percent of the engines in the 300-600
horsepower category are relying on the allowances in the first year
that the Tier 2 standards apply. In modeling the Tier 4 program,
because the program will not take effect for many years and it is
not possible to accurately forecast use of the proposed transition
program for equipment manufacturers and to assess costs in a
conservative manner, we have assumed that all engines will meet the
Tier 4 standards in the timeframe proposed. As discussed in section
V.C., this is consistent with our cost analysis, which assumes no
use of the proposed transition program for equipment manufacturers.
---------------------------------------------------------------------------
Machines that use engines built before the effective date of the
proposed Tier 4 standards would not be included in an equipment
manufacturer's percent of production calculations under this allowance.
Machines that use engines certified to the previous tier of standards
under our Small Business provisions (as described in Section VII.C. of
this proposal) would not be included in an equipment manufacturer's
percent of production calculations under this allowance. All engines
certified to the Tier 4 standards, including those engines that produce
emissions at higher levels than the
[[Page 28474]]
standards, but for which an engine manufacturer uses ABT credits to
demonstrate compliance, would count as Tier 4 complying engines and
would not be included in an equipment manufacturer's percent of
production calculations. As noted earlier, engines that meet the
proposed Tier 4 PM standards but are allowed to meet the Tier 3
NMHC+NOX standards during the phase-in period would also
count as Tier 4 complying engines and would not be included in an
equipment manufacturer's percent of production calculations. And, as
also noted earlier, all engines used under the percent-of-production
allowance would have to certify to the standards that would be in
effect in the absence of the Tier 4 standards (i.e., the Tier 3
standards for engines between 50 and 750 horsepower and the Tier 2
standards for engines below 50 horsepower and above 750 horsepower).
The choice of a cumulative percent allowance of 80 percent is based
on our best estimate of the degree of reasonable leadtime needed by
equipment manufacturers. We believe the 80 percent allowance responds
to the need for flexibility identified by equipment manufacturers,
while ensuring a significant level of emission reductions in the early
years of the proposed program.
We are also proposing to allow manufacturers to start using a
limited number of the new Tier 4 flexibilities once the seven-year
period for the existing Tier 2/Tier 3 program expires (and so continue
producing engines meeting Tier 1 or Tier 2 standards). In this way, a
manufacturer could potentially continue exempting the most difficult
applications once the seven-year period of the current Tier 2/3
flexibility provisions is finished. (Under the existing transition
program for equipment manufacturers, any unused allowances expire after
the seven year period. We are not reopening this provision with this
proposal.) However, opting to start using Tier 4 allowances once the
seven-year period from the current Tier 2/Tier 3 program expires would
reduce the available percent of production exemptions available from
the Tier 4 standards. We are proposing that equipment manufacturers may
use up to a total of 10 percent of their Tier 4 allowances prior to the
effective date of the proposed Tier 4 standards. (The early use of Tier
4 allowances would be allowed in each Tier 4 power category.) This
percentage of equipment utilizing the early Tier 4 allowances would be
subtracted from the proposed Tier 4 allowance of 80 percent for the
appropriate power category, resulting in fewer allowances once the Tier
4 standards take effect. For example, if an equipment manufacturer used
the maximum amount of early Tier 4 allowances of 10 percent, then the
manufacturer would have a cumulative total of 70 percent remaining when
the Tier 4 standards take effect (i.e., 80 percent production allowance
minus 10 percent). We are also requesting comment on requiring
equipment manufacturers to take a two-for-one loss of Tier 4 allowances
for each allowance used prior to the Tier 4 effective date. This would
reduce the number of overall engines that could be exempted under the
Tier 4 allowance program and result in greater environmental benefits
than would be realized if manufacturers used all of the Tier 4
allowances in the Tier 4 timeframe.
We view this proposed provision on early use of Tier 4 allowances
as providing reasonable leadtime for introducing Tier 4 engines, since
it should result in earlier introduction of Tier 4-compliant engines
(assuming that the 80% allowance would otherwise be utilized) with
resulting net environmental benefit (notwithstanding longer utilization
of earlier Tier engines, due to the stringency of the Tier 4 standards)
and should do so at net reduction in cost by providing cost savings for
the engines that have used the Tier 4 allowances early. As discussed
above, once the Tier 4 implementation model year begins, engines which
use the transition provision allowances must be certified to the
standards that would apply in the absence of the Tier 4 standards.
b. Small-Volume Allowance
The percent-of-production approach described above may provide
little benefit to businesses focused on a small number of equipment
models. Therefore we are proposing to allow any equipment manufacturer
to exceed the percent-of-production allowances described above during
the same seven year period, provided the manufacturer limits the number
of exempted engines to 700 total over the seven years, and to 200 in
any one year. As noted earlier, equipment manufacturers would need to
provided written assurance to the engine manufacturer when it purchases
engines under the transition provisions for equipment manufacturers.
The limit of 700 exempted engines would apply separately to each of the
proposed Tier 4 power categories (engines below 25 horsepower, engine
between 25 and 75 horsepower, engines between 75 and 175 horsepower,
engines between 175 and 750 horsepower, and engines above 750
horsepower). In addition, manufacturers making use of this provision
must limit exempted engines to a single engine family in each Tier 4
power category.
As with the proposed percent-of-production allowance, machines that
use engines built before the effective date of the proposed Tier 4
standards would not be included in an equipment manufacturer's count of
engines under the small-volume allowance. Similarly, machines that use
engines certified to the previous tier of standards under our Small
Business provisions (as described in Section VII.C. of this proposal)
would not be included in an equipment manufacturer's count of engines
under the small-volume allowance. All engines certified to the Tier 4
standards, including those that produce emissions at higher levels than
the standards but for which an engine manufacturer uses ABT credits to
demonstrate compliance, would be considered as Tier 4 complying engines
and would not be included in an equipment manufacturer's count of
engines under the small-volume allowance. Engines that meet the
proposed Tier 4 PM standards but are allowed to meet the Tier 3
NMHC+NOX standards during the phase-in period would also be
considered as Tier 4 complying engines and would not be included in an
equipment manufacturer's count of engines under the small-volume
allowance. All engines used under the small-volume allowance would have
to certify to the standards that would be in effect in the absence of
the Tier 4 standards (i.e., the Tier 3 standards for engines between 50
and 750 horsepower and the Tier 2 standards for engines below 50
horsepower and above 750 horsepower).
In discussions regarding the current small-volume allowance, some
manufacturers expressed the desire to be able to exempt engines from
more than one engine family, but still fall under the number of
exempted engine limit. (Under the current rules, although equipment
manufacturers are allowed to exempt up to 700 units over seven years,
they must all use the same engine family. In many cases, a
manufacturer's largest sales volume model does not even sell 700 units
over seven years. As a result, the maximum number of units a
manufacturer can exempt under the small-volume allowance is less than
the 700 unit limit.) We are concerned, however, that allowing
manufacturers to exempt engines in more than one family, but retaining
the current 700-unit allowance, could lead to significantly higher
numbers of engines being exempted from the Tier 4 program.
[[Page 28475]]
Using data of equipment sales by equipment manufacturers that
qualify as small businesses under Small Business Administration (SBA)
guidelines, we have analyzed the effects of a small-volume allowance
program that would set an exempted engine allowance lower than 700
units over seven years but allow manufacturers to exempt engines from
more than one engine family. Based on sales information for small
businesses, we believe we could revise the small-volume allowance
program to include lower caps and allow manufacturers to exempt more
than one engine family while still keeping the total number of engines
eligible for the allowance at roughly the same overall level as the
700-unit program described above.\303\ Such a program would in general
provide sufficient leadtime for equipment manufacturers, allowing them
to temporarily exempt greater numbers of equipment models from the
proposed Tier 4 standards, but, as noted above, keeping the total
number of engines eligible for the allowance at roughly the same
overall level as the existing program would allow (and so not allow
more leadtime than necessary). Based on our analysis, the small-volume
allowance program could be revised to allow equipment manufacturers to
exempt 525 machines over seven years (with a maximum of 150 in any
given year) for each of the three power categories below 175
horsepower, and 350 machines over seven years (with a maximum of 100 in
any given year) for the two power categories above 175 horsepower.
Concurrent with the revised caps, manufacturers would be allowed to
exempt engines from more than one engine family under the small-volume
allowance program. Table VII.B-1 compares the proposed small-volume
allowance program to the variation described in this paragraph.
---------------------------------------------------------------------------
\303\ ``Analysis of Small Volume Equipment Manufacturer
Flexibilities,'' EPA memo from Phil Carlson to Docket A-2001-28.
Table VII.B-1.--Small-Volume Allowance Program Comparison
----------------------------------------------------------------------------------------------------------------
Maximum
exempted
Engines exempted over 7 years engines Single engine family
in one restriction?
year
----------------------------------------------------------------------------------------------------------------
Proposed program........................ --700 for each power category.. 200 --Yes
Variation under consideration........... --525 for power categories < 100 --No
175 hp.
--350 for power categories 175 hp.
----------------------------------------------------------------------------------------------------------------
We request comment on adopting a small-volume allowance program
with the lower caps noted above that allows manufacturers to exempt
more than one engine family in each power category. We specifically
request comment on allowing equipment manufacturers to choose between
the two small-volume allowance programs described above. Alternatively,
we request comment on whether we should replace the current program
(which allows 700 units over seven years with a one engine family
restriction) with this revised small-volume allowance program (which
would allow fewer units over seven years but without the single engine
family restriction). Our analysis of small businesses noted above did
show that there were a very limited number of companies that could
potentially get fewer total allowances under a revised program with the
lower caps compared to the existing program (i.e., a company that sells
an equipment model that utilizes one engine family whose sales over a
seven year period are above the revised limits noted above but less
than 700). Allowing an equipment manufacturer to choose between the two
programs would help to ensure that manufacturers are able to retain the
current level of flexibility they have under the current program.
Because we are proposing fewer power categories for the Tier 4
standards, the proposed equipment flexibility program is designed to
reflect those changes. Therefore, under the proposed small-volume
allowance, the specified unit allowances will apply separately to each
of the five power categories being proposed for the Tier 4 standards.
As noted earlier, we are also proposing to allow manufacturers to
start using a limited number of the new Tier 4 flexibilities once the
seven-year period for the existing Tier 2/Tier 3 program expires (and
so continue producing engines meeting Tier 1 or Tier 2 standards).
Under the proposed small-volume allowance, any engines used by the
manufacturer prior to Tier 4 would be subtracted from the proposed 700
unit allowance (for the appropriate Tier 4 power category), resulting
in fewer allowances once the Tier 4 standards take effect. As with the
proposed percent-of-production allowance, we are proposing to limit the
number of Tier 4 small-volume allowances that can be used prior to the
effective dates of the Tier 4 standards to a total of 100 units in each
of the Tier 4 power categories. We are taking comment on requiring
equipment manufacturers to take a two-for-one loss of Tier 4 small-
volume allowances for each allowance used prior to the Tier 4 effective
date. As explained above, we view this proposal as providing reasonable
leadtime for introduction of Tier 4 engines by providing the
possibility of earlier introduction of such engines with a net cost
savings.
c. Hardship Relief Provision
We are proposing to extend the availability of the ``hardship
relief provision'' with the Tier 4 transition provisions for equipment
manufacturers. Under the proposal, an equipment manufacturer that does
not make its own engines could obtain limited additional relief by
providing evidence that, despite its best efforts, it cannot meet the
implementation dates, even with the proposed equipment flexibility
program provisions outlined above. Such a situation might occur if an
engine supplier without a major business interest in the equipment
manufacturer were to change or drop an engine model very late in the
implementation process. As with other equipment manufacturer transition
provisions, the equipment Small Entity Representatives indicated that
the availability this allowance was useful to them in the transition to
the Tier 2/3 standards, and they urged that it be continued in any Tier
4 rule. Report of the Small Business Advocacy Panel, section 8.4.1.
[[Page 28476]]
Applications for hardship relief would have to be made in writing,
and would need to be submitted before the earliest date of
noncompliance. The application would also have to include evidence that
failure to comply was not the fault of the equipment manufacturer (such
as a supply contract broken by the engine supplier), and would need to
include evidence that serious economic hardship to the company would
result if relief is not granted. We would work with the applicant to
ensure that all other remedies available under the flexibility
provisions were exhausted before granting additional relief, if
appropriate, and would limit the period of relief to no more than one
year. Applications for hardship relief generally will only be accepted
during the first year after the effective date of an applicable new
emission standard.
The Agency expects this provision would be rarely used. This
expectation has been supported by our initial experience with the Tier
2 standards in which only one equipment manufacturer has applied under
the hardship relief provisions. Requests for hardship relief would be
evaluated by EPA on a case-by-case basis, and may require, as a
condition of granting the applications, that the equipment manufacturer
agree (in writing) to some appropriate measure to recover the lost
environmental benefit.
d. Existing Inventory Allowance
The current program for nonroad diesel engines includes a provision
for equipment manufacturers to continue to use engines built prior to
the effective date of new standards, until the older engine inventories
are depleted. It also prohibits stockpiling of previous tier engines.
We are proposing to extend these provisions as manufacturers transition
to the standards contained in this proposal. We are also proposing to
extend the existing provision that provides an exception to the
applicable compliance regulations for the sale of replacement engines.
In proposing to extend this provision, we are requiring that engines
built to replace certified engines be identical in all material
respects to an engine of a previously certified configuration that is
of the same or later model year as the engine being replaced. The term
``identical in all material respects'' would allow for minor
differences that would not reasonably be expected to affect emissions.
3. What Are the Recordkeeping, Notification, Reporting, and Labeling
Requirements Associated With the Equipment Manufacturer Transition
Provisions?
a. Recordkeeping Requirements for Engine and Equipment
Manufacturers
We are proposing to extend the recordkeeping requirements from the
current equipment manufacturer transition program. Under the proposed
requirements, engine manufacturers would be allowed to continue to
build and sell previous tier engines needed to meet the market demand
created by the equipment manufacturer flexibility program, provided
they receive written assurance from the engine purchasers that such
engines are being procured for this purpose. We are proposing that
engine manufacturers would be required to keep copies of the written
assurance from the engine purchasers for at least five full years after
the final year in which allowances are available for each power
category.
Equipment manufacturers choosing to take advantage of the proposed
Tier 4 allowances would be required to: (1) Keep records of the
production of all pieces of equipment excepted under the allowance
provisions for at least five full years after the final year in which
allowances are available for each power category; (2) include in such
records the serial and model numbers and dates of production of
equipment and installed engines, and the rated power of each engine,
(3) calculate annually the number and percentage of equipment made
under these transition provisions to verify compliance that the
allowances have not been exceeded in each power category; and (4) make
these records available to EPA upon request.
b. Notification Requirements for Equipment Manufacturers
We are also proposing some new notification requirements for
equipment manufacturers with the Tier 4 program. Under this proposal,
equipment manufacturers wishing to participate in the Tier 4 transition
provisions would be required to notify EPA prior to their use of the
Tier 4 transition provisions. Equipment manufacturers would be required
to submit their notification before the first calendar year in which
they intend to use the transition provisions. We believe that prior
notification will not be a significant burden to the equipment
manufacturer, but will greatly enhance our ability to ensure
compliance. Indeed, EPA believes that in order for an equipment
manufacturer to properly use either of the allowances provided, it
would already have the information required in the notification. Thus
we are not requiring additional planning or information gathering
beyond that which the equipment manufacturer must already be doing in
order to ensure its compliance with the regulations. Under the proposed
notification requirements, each equipment manufacturer would be
required to notify EPA in writing and provide the following
information:
(1) The nonroad equipment manufacturer's name, address, and contact
person's name, phone number;
(2) the allowance program that the nonroad equipment manufacturer
intends to use by power category;
(3) the calendar years in which the nonroad equipment manufacturer
intends to use the exception;
(4) an estimation of the number of engines to be exempted under the
transition provisions by power category;
(5) the name and address of the engine manufacturer from whom the
equipment manufacturer intends to obtain exempted engines; and
(6) identification of the equipment manufacturer's prior use of
Tier 2/3 transition provisions.
EPA is requesting comment on whether the notification provisions
should also apply to the current Tier 2/Tier 3 transition program, and
if so, how these provisions should be phased in for equipment
manufacturers using the current Tier 2/Tier 3 transition provisions.
EPA believes such a notification provision could be implemented as soon
as 2005 and requests comments on the appropriate start date should we
adopt such a notification provision for equipment manufacturers for the
Tier 2/Tier 3 transition program.
c. Reporting Requirements for Engine and Equipment Manufacturers
As with the current program, engine manufacturers who participate
in the proposed Tier 4 program would be required to annually submit
information on the number of such engines produced and to whom the
engines are provided, in order to help us monitor compliance with the
program and prevent abuse of the program.
We are proposing new reporting requirement for equipment
manufacturers participating in the Tier 4 equipment manufacturer
transition provisions. Under this proposal, equipment manufacturers
participating in the program would be required to submit an annual
written report to EPA that calculates its annual number of exempted
engines under the transition provisions by power category in the
[[Page 28477]]
previous year. Equipment manufacturers using the percent of production
allowance, would also have to calculate the percent of production the
exempted engines represented for the appropriate year. Each report
would include a cumulative calculation (both total number and, if
appropriate, the percent of production) for all years the equipment
manufacturer has used the transition provisions for each of the
proposed Tier 4 power categories. In order to ease the reporting burden
on equipment manufacturers, EPA intends to work with the manufacturers
to develop an electronic means for submitting information to EPA.
EPA is requesting comment on whether these reporting requirements
should also apply to the current Tier 2/Tier 3 transition program, and
if so, how these provisions should be phased in for equipment
manufacturers using the current Tier 2/Tier 3 transition provisions.
Because equipment manufacturers are already required to keep the
information we would require under the reporting requirements described
above, we believe such a reporting requirement could be implemented to
cover exempted engines produced in the 2005 model year. We request
comments on the appropriate start date should we adopt such reporting
requirements for equipment manufacturers for the Tier 2/Tier 3
transition program.
d. Labeling Requirements for Engine and Equipment Manufacturers
Engine manufacturers are currently required to label their
certified engines with a label that contains a variety of information.
Under this proposal, we are proposing that engine manufacturers would
be required to identify on the engine label if the engine is exempted
under the Tier 4 transition program. In addition, equipment
manufacturers would be required to apply a label to the engine or piece
of equipment that identifies the equipment as using an engine produced
under the Tier 4 transition program for equipment manufacturers. These
proposed labeling requirements would allow EPA to easily identify the
exempted engines and equipment, verify which equipment manufacturers
are using these exceptions, and more easily monitor compliance with the
transition provisions. Labeling of the equipment could also help U.S.
Customs to quickly identify equipment being imported using the
exemptions for equipment manufacturers.
EPA is requesting comment on whether these labeling requirements
should also apply to the current Tier 2/Tier 3 transition program, and
if so, how these provisions should be phased in for engine
manufacturers and equipment manufacturers. Due to limited impact of
such a labeling requirement, we believe such a requirement could be
implemented to cover model year 2005 engines and equipment using those
engines. We request comments on the appropriate start date should we
adopt such labeling requirements for engine manufacturers and equipment
manufacturers for the Tier 2/Tier 3 transition program.
4. What Are the Proposed Requirements Associated With Use of Transition
Provisions for Equipment Produced by Foreign Manufacturers?
Under the current regulations, importers are treated as equipment
manufacturers and are each allowed the full allowance under the
transition provisions. Therefore, under the current provisions,
importers of equipment from a foreign equipment manufacturer could as a
group import more excepted equipment from that foreign manufacturer
than 80% of that manufacturer's production for the U.S. market or more
than the small volume allowances identified in the transition
provisions. Therefore, the current regulation creates a potentially
significant disparity between the treatment of foreign and domestic
equipment manufacturers. EPA did not intend this outcome, and does not
believe it is needed to provide reasonable leadtime to foreign
equipment manufacturers.
Under this proposal, only the nonroad equipment manufacturer that
is most responsible for the manufacturing and assembling process would
qualify for the allowances or other relief provided under the Tier 4
transition provisions. Foreign equipment manufacturers who comply with
the compliance related provisions discussed below would receive the
same allowances and other transition provisions as domestic
manufacturers. Foreign equipment manufacturers who do not comply with
the compliance related provisions discussed below would not receive
allowances. Importers that have little involvement in the manufacturing
and assembling of the equipment would not receive any allowances or
other transition relief directly, but could import exempt equipment if
it is covered by an allowance or transition provision associated with a
foreign equipment manufacturer. This would allow transition allowances
and other provisions to be used by foreign equipment manufacturers in
the same way as domestic equipment manufacturers, while avoiding the
potential for importers unnecessarily using allowances. For the
purposes of this proposal, a foreign equipment manufacturer would
include any equipment manufacturer that produces equipment outside of
the United States that is eventually sold in the United States.
All foreign nonroad equipment manufacturers wishing to use the
transition provisions would have to comply with all requirements of the
regulation discussed above including: notification, recordkeeping,
reporting and labeling. Along with the equipment manufacturer's
notification described earlier, a foreign nonroad equipment
manufacturer would have to comply with various compliance related
provisions similar to those adopted in several fuel regulations
relating to foreign refiners.\304\ As part of the notification, the
foreign nonroad equipment manufacturer would have to:
---------------------------------------------------------------------------
\304\ See, for example, 40 CFR 80.410 concerning provisions for
foreign refiners with individual gasoline sulfur baselines.
---------------------------------------------------------------------------
(1) Agree to provide EPA with full, complete and immediate access
to conduct inspections and audits;
(2) Name an agent in the District of Columbia for service of
process;
(3) Agree that any enforcement action related to these provisions
would be governed by the Clean Air Act;
(4) Submit to the substantive and procedural laws of the United
States;
(5) Agree to additional jurisdictional provisions;
(6) Agree that the foreign nonroad equipment manufacturer will not
seek to detain or to impose civil or criminal remedies against EPA
inspectors or auditors for actions performed within the scope of EPA
employment related to the provisions of this program;
(7) Agree that the foreign nonroad equipment manufacturer becomes
subject to the full operation of the administrative and judicial
enforcement powers and provisions of the United States without
limitation based on sovereign immunity; and
(8) Submit all reports or other documents in the English language,
or include an English language translation.
In addition to these proposed requirements, we are requesting
comment on requiring foreign equipment manufacturers that participate
in the transition program to comply with a bond requirement for engines
imported into the U.S. We describe a bond program below which we
believe could be an important tool to ensure that foreign equipment
manufacturers are subject to the same
[[Page 28478]]
level of enforcement as domestic equipment manufacturers. We believe a
bonding requirement for the foreign equipment manufacturer is an
important enforcement tool in order to ensure that EPA has the ability
to collect any judgements assessed against a foreign equipment
manufacturer for violations of these transition provisions. We request
comments on all aspects of the specific program we describe here, but
also on alternative measures which would achieve the same goal. A memo
has been placed in the docket for today's notice that contains draft
regulatory language that would apply if we adopted a bonding
requirement as discussed in this section.\305\
---------------------------------------------------------------------------
\305\ ``Potential Bond Regulations for Foreign Equipment
Manufacturers Under the Tier 4 Nonroad Diesel Proposal,'' EPA
memorandum from Leslie Kirby-Miles, U.S. EPA/OECA to Docket A-2001-
28.
---------------------------------------------------------------------------
Under a bond program, the participating foreign equipment
manufacturer would have to obtain annually a bond in the proper amount
that is payable to satisfy United States judicial judgments that
results from administrative or judicial enforcement actions for conduct
in violation of the Clean Air Act. The foreign equipment manufacturer
would have three options for complying with the bonding requirement.
The foreign equipment manufacturer could:
(1) Post a bond by paying the amount of the bond to the Treasurer
of the United States;
(2) obtain a bond in the proper amount from a third party surety
agent, provided EPA agrees in advance as to the third party and the
nature of the surety agreement; or
(3) obtain an EPA waiver from the bonding requirement, if the
foreign equipment manufacturer can show that it has assets of an
appropriate value in the United States.
EPA expects the third bond option to address instances where an
equipment manufacturer produces equipment outside the United States
containing flexibility engines, but also has facilities (and thus
significant assets) inside the United States. Under this third option,
such a manufacturer could apply to the EPA for a waiver of the bonding
requirement.
Since EPA's concerns of compliance will relate to the nature and
tier of engine used in the transition equipment, we believe the bond
value should be related to the value of the engine used. Therefore, we
are requesting comment on a value of the bond set at a level designed
to represent approximately 10% of the cost of the engine for each piece
of transition equipment produced for import into the United States
under this program. So that manufacturers have certainty regarding the
bond amounts and so that there isn't a need for extensive data
submittals and evaluation between EPA and the manufacturer, we request
comment on EPA specifying in this rulemaking the estimated average cost
for a Tier 4 engine on which the bond would be based. For example, we
believe cost estimates on the order of those contained in Table 10.3-3
of the draft RIA may be an appropriate basis. Under this approach,
transition equipment using engines in the less than 25 horsepower
category would require a bond of $150 per piece of equipment (10
percent of $1,500), equipment using engines in the 25-50 horsepower
range would require a bond of $250 per piece of equipment (10 percent
of $2,500), etc. We also request comment on whether 10 percent is a
sufficient value for the bond or whether higher values, such as 50
percent, or lower values are more appropriate.
Finally, if a foreign equipment manufacturer's bond is used to
satisfy a judgment, the foreign equipment manufacturer would then be
required to increase the bond to cover the amount used within 90 days
of the date the bond is used.
In addition to the foreign equipment manufacturer requirements
discussed above, EPA also proposes to require importers of exempted
equipment from a complying foreign equipment manufacturer to comply
with certain provisions. EPA believes these importer provisions are
essential to EPA's ability to monitor compliance with the transition
provisions. EPA proposes that the regulations would require each
importer to notify EPA prior to their initial importation of equipment
exempted under the Tier 4 transition provisions. Importers would be
required to submit their notification prior to the first calendar year
in which they intend to import exempted equipment from a complying
foreign equipment manufacturer under the transition provisions. The
importer's notification would need to include the following
information:
(1) The name and address of importer (and any parent company);
(2) The name and address of the manufacturers of the exempted
equipment and engines the importer expects to import;
(3) Number of exempted equipment the importer expects to import for
each year broken down by equipment manufacturer and power category; and
(4) The importer's use of the transition provisions in prior years
(number of flexibility engines imported in a particular year, under
what power category, and the names of the equipment and engine
manufacturers).
In addition, EPA is proposing that any importer electing to import
to the United States exempted equipment from a complying foreign
equipment manufacturer would have to submit annual reports to EPA. The
annual report would include the number of exempted equipment the
importer actually imported to the United States in the previous
calendar year; and the identification of the equipment manufacturers
and engine manufacturers whose exempted equipment/engines were
imported.
C. Engine and Equipment Small Business Provisions (SBREFA)
The Regulatory Flexibility Act (RFA) generally requires an agency
to prepare a regulatory flexibility analysis of any rule subject to
notice and comment rulemaking requirements under the Administrative
Procedure Act or any other statute, unless the agency certifies that
the rule will not have a significant economic impact on a substantial
number of small entities. Small entities include small businesses,
small organizations, and small governmental jurisdictions. Since EPA
believes that the proposed rule may have a significant economic impact
on small businesses, we intend to prepare a regulatory flexibility
analysis as part of this rulemaking, and have prepared an initial
regulatory flexibility analysis (IRFA) pursuant to section 603 of the
RFA which is part of the record for this proposal.
Under section 609(b) of the RFA, a Small Business Advocacy Review
Panel (SBAR Panel or Panel) is required to be convened prior to
publication of an IRFA that an agency may be required to prepare under
the RFA. Section 609(b) directs the Panel to, through outreach with
small entity representatives (SERs), report on the comments of the SERs
and make findings on issues related to identified elements of an IRFA
under section 603 of the RFA (see Section X.C of this preamble for more
discussion on the elements of an IRFA). The purpose of the Panel is to
gather information to identify potential impacts on small businesses
and to develop options to mitigate these concerns. At the completion of
the SBAR Panel process, the Panel is required to prepare a Final Panel
Report. This report includes background information on the proposed
rule being developed, information on the types of small entities that
would be subject to the proposed rule, a description of efforts
[[Page 28479]]
made to obtain the advice and recommendations of representatives of
those small entities, and a summary of the comments that have been
received to date from those representatives. Once completed, the Panel
report is provided to the agency issuing the proposed rule and included
in the rulemaking record. The report provides the Panel and the Agency
with an opportunity to identify and explore potential ways of shaping
the proposed rule to minimize the burden of the rule on small entities
while achieving the rule's purposes and when consistent with Clean Air
Act statutory requirements.
EPA has approached this process with care and diligence. To
identify representatives of small businesses for this process, we used
the definitions provided by the Small Business Administration (SBA) for
manufacturers of nonroad diesel engines and vehicles. The categories of
small entities in the nonroad diesel sector that will potentially be
affected by this rulemaking are defined in the following table:
----------------------------------------------------------------------------------------------------------------
Defined as small entity by
Industry SBA if: Major SIC codes
----------------------------------------------------------------------------------------------------------------
Engine manufacturers................... Less than 1,000 employees. Major Group 35.
Equipment manufacturers:
--construction equipment........... Less than 750 employees... Major Group 35.
--industrial truck manufacturers less than 750 employees... Major Group 35.
(i.e., forklifts).
--all other nonroad equipment Less than 500 employees... Major Group 35.
manufacturers.
----------------------------------------------------------------------------------------------------------------
One small engine manufacturer and 5 small equipment manufacturers
agreed to serve as Small Entity Representatives (SERs) throughout the
SBAR Panel process for this proposal. These companies represented the
nonroad market well, as the group of SERs consisted of businesses that
manufacture various types of nonroad diesel equipment.
The following are the provisions recommended by the SBAR Panel,
including both the provisions that we, EPA, are proposing and those on
which we are requesting comment. As described in section VII.B above,
there are other provisions that apply to all equipment manufacturers;
however, most of the discussion in this section is geared to small
entities only. We request comment on all aspects of both the provisions
recommended by the Panel and on those that we are proposing in today's
action.
1. Nonroad Diesel Small Engine Manufacturers
a. Lead Time Transition Provisions for Small Engine Manufacturers
i. What the Panel Recommended
The transition provisions recommended by the SBAR Panel for engines
produced or imported by small entities are listed below. For all of the
provisions, the Panel recommended that small engine manufacturers and
small importers must have certified engines in model year 2002 or
earlier in order to take advantage of these provisions. Each
manufacturer would be limited to 2,500 units per year as this number
allows for some market growth. The Panel recommended these stipulations
in order to prohibit the misuse of the transition provisions as a tool
to enter the nonroad diesel market or to gain unfair market position
relative to other manufacturers.
Currently, certified nonroad diesel engines produced by small
manufacturers all have a horsepower rating of 80 or less. The
transition provisions that the Panel considered were dependent upon
what approach, or approaches, were proposed for the rulemaking.
[sbull] For an approach with two phases of standards:
[sbull] An engine manufacturer could skip the first phase and
comply on time with the second; or,
[sbull] A manufacturer could delay compliance with each phase of
standards for three years.
[sbull] For an approach that entails only one phase of standards,
the manufacturer could opt to delay compliance. It was recommended that
the length of the delay be three years; however the Panel suggested
that we request comment on whether this delay period should be two,
three, or four years. Each delay would be pollutant specific (i.e., the
delay would apply to each pollutant as it is phased in).
The Panel believed that these options could offer an opportunity to
reduce the burden on small manufacturers while at the same time meet
the regulatory goals of the Agency. The Panel further believed that
these options would not put small manufacturers at a significant
disadvantage as they would be in compliance with the Tier 4 standards
in the long run and the options would give them more lead time to
comply. The Panel also felt that a complete exemption from the upcoming
standards (even assuming that such an exemption could be justified
legally) would put these manufacturers at a competitive disadvantage as
the rest of the market would be producing compliant engines and
eventually there would not be equipment designed to accommodate their
engines.
ii. What EPA is Proposing
Due to the structure of the standards and their timing as discussed
in Section III, EPA is proposing transition provisions for small engine
manufacturers which encompass both approaches recommended by the Panel,
with the inclusion of the 2,500 unit limit (as suggested by the Panel)
for each manufacturer.
[sbull] First, with regard to PM:
[sbull] Engines under 25 hp and those between 75 and 175 hp have
only one standard so the manufacturer could delay compliance with these
standards for up to three years. Based on available data, we believe
that there are no small manufacturers of nonroad diesel engines above
175 hp.
[sbull] For engines between 50 and 75 hp, EPA is proposing a one
phase program with the option to delay compliance for one year if
interim standards are met. For this power category we are treating the
PM standard as a two phase standard with the stipulation that small
manufacturers cannot use PM credits to meet the interim standard.
Furthermore, if a small manufacturer elects the optional approach to
the standard (elects to skip the interim standard), no further relief
will be provided.
[sbull] Second, with regard to NOX:
[sbull] There is no change in the NOX standard for
engines under 25 hp and those between 50 and 75 hp. For these two power
bands EPA is proposing no special provisions.
[sbull] For engines in the 25-50 hp and the 75-175 hp categories we
are proposing a three year delay in the program consistent with the
one-phase approach recommendation above. Based on available data, we
believe that there are no small manufacturers of nonroad diesel engines
above 175 hp.
b. Hardship Provisions for Small Engine Manufacturers
i. What the Panel Recommended
[[Page 28480]]
The Panel recommended two types of hardship provisions for small
engine manufacturers. These provisions are:
[sbull] For the case of a catastrophic event, or other extreme
unforseen circumstances, beyond the control of the manufacturer that
could not have been avoided with reasonable discretion (i.e., fire,
tornado, supplier not fulfilling contract, etc.); and
[sbull] For the case where a manufacturer has taken all reasonable
business, technical, and economic steps to comply but cannot.
Either hardship relief provision would provide lead time for up to
2 years, and a manufacturer would have to demonstrate to EPA's
satisfaction that failure to sell the noncompliant engines would
jeopardize the company's solvency, EPA may also require that the
manufacturer make up the lost environmental benefit.
ii. What EPA is Proposing
EPA is proposing to adopt the Panel recommendations for hardship
provisions for small engine manufacturers. While perhaps ultimately not
necessary given the phase-in schedule discussed above, such provisions
provide a useful safety valve in the event of unforeseen extreme
hardship.
c. Other Small Engine Manufacturer Issues
i. What the Panel Recommended
The Panel also recommended that an ABT program be included as part
of the overall rulemaking program. In addition, the Panel suggested
that EPA take comment on including specific ABT provisions for small
engine manufacturers.
ii. What EPA is Proposing
As discussed above, an ABT program has been included in the overall
program in this rule proposal. ABT is being proposed in today's action
as it is intended to enhance the flexibility offered to engine
manufacturers that will be of assistance in making the transition to
meet the stringent standards proposed in today's rules in the leadtime
proposed. As noted in Section VII.A, EPA is proposing to retain the
basic structure of the current nonroad diesel ABT program, though a
number of changes (which will help to accommodate implementation of the
proposed emission standards) are being proposed today.
Though the Panel recommended small engine manufacturer-specific ABT
provisions, such provisions are not being included in this proposal.
EPA does not believe it would be appropriate to provide a different ABT
program for small engine manufacturers, especially given the provisions
mentioned above. Discussions during the SBAR process indicated that
small volume manufacturers would need extra time to comply due to cost
and personnel constraints, and there is little reason to believe that
small manufacturer specific ABT provisions could create an incentive to
accelerate compliance. Small manufacturers would of course be able to
participate in the general ABT program, which EPA believes will provide
sufficient lead time for small entities.
2. Nonroad Diesel Small Equipment Manufacturers
a. Transition Provisions for Small Equipment Manufacturers
i. What the Panel Recommended
The Panel recommended that EPA adopt the transition provisions
described below for small manufacturers and small importers of nonroad
diesel equipment. These transition provisions are similar to those in
the Tier 2/3 rule (see 89.102). The recommended transition provisions
are as follows:
[sbull] Percent-of-Production Allowance: Over a seven model year
period, equipment manufacturers may install engines not certified to
the new emission standards in an amount of equipment equivalent to 80
percent of one year's production. This is to be implemented by power
category with the average determined over the period in which the
flexibility is used.
[sbull] Small Volume Allowance: A manufacturer may exceed the 80
percent allowance in seven years as described above, provided that the
previous Tier engine use does not exceed 700 total over seven years,
and 200 in any given year. This is limited to one family per power
category.
Alternatively, the Panel also recommended, at the manufacturer's
choice by hp category, a program that eliminates the ``single family
provision'' restriction with revised total and annual sales limits as
shown below:
[sbull] For categories <175 hp--525 previous Tier engines (over 7
years) with an annual cap of 150 units (these engine numbers are
separate for each hp category defined in the regulations)
[sbull] For categories of 175hp--350 previous Tier
engines (over 7 years) with an annual cap of 100 units (these engine
numbers are separate for each hp category defined in the regulations)
The Panel recommended that EPA seek comment on the total number of
engines and annual cap values listed above. In contrast to the Tier 2/
Tier 3 rule promulgated in 1998, SBA expects the transition to the Tier
4 technology will be more costly and technically difficult. Therefore,
the small equipment manufacturers may need more liberal flexibility
allowances especially for equipment using the lower hp engines. The
Panel's recommended flexibility may not adequately address the
approximately 50 percent of small business equipment models where the
annual sales per model is less than 300 and the fixed costs are higher.
Thus, the SBA and OMB Panel members recommended that comment be sought
on implementing the small volume allowance (700 engine provision) for
small equipment manufacturers without a limit on the number of engine
families which could be covered in any hp category.
[sbull] Due to the changing nature of the technology as the
manufacturers transition from Tier 2 to Tier 3 and Tier 4, the Panel
recommended that the equipment manufacturers be permitted to borrow
from the Tier 3/Tier 4 flexibilities for use in the Tier 2/Tier 3 time
frame.
[sbull] Lastly, the Panel recommended proposing a continuation of
the current transition provisions, without modifications to the levels
or nature of the provisions, that are available to these manufacturers.
To maximize the likelihood that the application of these provisions
will result in the availability of previous Tier engines for use by the
small equipment manufacturers, the Panel recommended that--similar to
the application of flexibility options that are currently in place--
these provisions should be provided to all equipment
manufacturers.\306\
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\306\ The Panel recognized that, similar to the Tier 2/3
standards, it may be necessary to provide transition provisions for
all equipment manufacturers, not just for small entities; and the
Panel recommended that this be taken into account. However, the work
of the SBAR Panel is meant to develop regulatory alternatives for
small manufacturers, thus the Panel nominally recommended transition
provisions for small equipment manufacturers only.
---------------------------------------------------------------------------
During the SBAR Panel process, an issue was raised requesting that
EPA establish a provision which would allow small entity manufacturers
to request limited ``application specific'' alternative standards for
equipment configurations which present unusually challenging technical
issues for compliance. The Panel recommended that EPA seek comment on
the need for and value of special application specific standards for
small equipment manufacturers.
ii. What EPA is Proposing
EPA is in fact proposing the Percent-of-Production and Small Volume
Allowances for all equipment manufacturers, and explicitly took the
[[Page 28481]]
Panel report into account in making that proposal (see Section VII.B.
above). The Agency believes that this proposal should provide the type
of transition leeway recommended by the Panel. EPA believes that the
transition provisions could allow small equipment manufacturers to
postpone any redesign needed on low sales volume or difficult equipment
packages, thus saving both money and strain on limited engineering
staffs. Within limits, small equipment manufacturers would be able to
continue to use their current engine/equipment configuration and avoid
out-of-cycle equipment redesign until the allowances are exhausted or
the time limit passes.
With respect to these transition provisions, EPA requests comment
on the Panel's suggested exemption and annual cap values listed above.
As discussed above in Section VII.B, EPA also requests comment on
implementing the small volume allowance provision without the single
family limit provision using caps slightly lower than 700 units, with
this provision being applied separately to each engine power category
subject to the proposed standards.
Similar to the discussion in Section VII.B above, EPA requests
comment on new proposed requirements associated with use of transition
provisions by foreign importers. During the SBREFA Panel process, the
Panel discussed the possible misuse of the transition provisions by
using them as a loophole to enter the nonroad diesel equipment market
or to gain unfair market position relative to other manufacturers. The
Panel recognized that this was a possible problem, and believed that
the requirement that small equipment manufacturers and importers have
reported equipment sales using certified engines in model year 2002 or
earlier was sufficient to alleviate this problem. Upon further
analysis, EPA found that importers of equipment from a foreign
equipment manufacturer could as a group import more excepted equipment
from that foreign manufacturer than 80% of that manufacturer's
production for the United States market or more than the small volume
allowances identified in the transition provisions. This also creates a
potentially significant disparity between the treatment of foreign and
domestic equipment manufacturers. EPA did not intend this outcome, and
does not believe it is needed to provide reasonable leadtime to foreign
equipment manufacturers.
Therefore, as explained earlier in Section VII.B, EPA is requesting
comment on the additional requirement that only the nonroad diesel
equipment manufacturer that is most responsible for the manufacturing
and assembling process, and therefore the burden of complying with the
proposed standards, would qualify for the allowances provided under the
small equipment manufacturer transition provisions. Under this
requirement, only an importer that produces or manufactures nonroad
diesel equipment would be eligible for these transition provisions. An
importer that does not manufacture or produce equipment does not face a
burden in complying with the proposed standard, and therefore would not
receive any allowances under these transition provisions directly, but
could import exempt equipment if it is covered by an allowance or
transition provisions associated with a foreign small equipment
manufacturer. EPA believes that this requirement transfers the
flexibility offered in these transition provisions to the party with
the burden and would allow transition provisions and allowances to be
used by foreign equipment manufacturers in the same way as domestic
equipment manufacturers, while avoiding the potential for misuse by
importers of unnecessary allowances. EPA also sees no reason that this
provision should not apply in the same way to all importers, and thus
(as explained in Section VII.B) is proposing that the provision apply
uniformly.
EPA is also proposing the Panel's recommendation that equipment
manufacturers be allowed to borrow from Tier 4 flexibilities in the
Tier 2/3 timeframe. See the more extended discussion on this issue in
Section VII.B above.
With regard to the Panel recommendation for a provision allowing
small manufacturers to request limited ``application specific''
alternative standards for equipment configurations which present
unusually challenging technical issues for compliance, EPA requests
comment on this recommendation. EPA believes that the need for such a
provision has not been established and that it likely would provide
more lead time than can be justified, and could undermine emission
reductions which are achievable. Moreover, no participant in the SBAR
process offered any empirical support that such a problem even exists.
Nor have such issues been demonstrated (or raised) by equipment
manufacturers, small or large, in implementing the current nonroad
standards. In addition, EPA believes that any application-specific
difficulties can be accommodated by the transition provisions the
Agency is proposing including ABT. Nonetheless, in keeping with the
SBAR recommendations, comment is requested on the value of, and need
for, special application specific standards for small equipment
manufacturers.
b. Hardship Provisions for Small Equipment Manufacturers
i. What the Panel Recommended
The Panel also recommended that two types of hardship provisions be
extended to small equipment manufacturers. These provisions are:
[sbull] For the case of a catastrophic event, or other extreme
unforseen circumstances, beyond the control of the manufacturer that
could not have been avoided with reasonable discretion (i.e. fire,
tornado, supplier not fulfilling contract, etc.).
[sbull] For the case where a manufacturer has taken all reasonable
business, technical, and economic steps to comply but cannot. In this
case relief would have to be sought before there is imminent jeopardy
that a manufacturer's equipment could not be sold and a manufacturer
would have to demonstrate to the Agency's satisfaction that failure to
get permission to sell equipment with a previous Tier engine would
create a serious economic hardship. Hardship relief of this nature
cannot be sought by a ``integrated'' manufacturer (one which also
manufactures the engines for its equipment).
ii. What EPA is Proposing
EPA is proposing that the Panel recommended hardship provisions be
extended to small equipment manufacturers in addition to the transition
provisions described above. To be eligible for these hardship
provisions (as well as the proposed transition provisions), equipment
manufacturers and importers must have reported equipment sales using
certified engines in model year 2002 or earlier. As explained earlier,
this proposal is needed to thwart misuse of these provisions as a
loophole to enter the nonroad diesel equipment market or to gain unfair
market position relative to other manufacturers. We request comment on
this restriction.
As explained earlier, hardship relief would not be available until
other allowances have been exhausted. Either relief provision would
provide small equipment manufacturers with additional lead time for up
to two model years based on the circumstances, but EPA may require
recovery of the lost environmental benefit.
EPA requests comment on all of the aspects of the proposed hardship
provisions for small equipment manufacturers.
[[Page 28482]]
D. Phase-In Provisions
In Section III we described the proposed NOX and NMHC
standards phase-in schedule. This phase-in requirement is based on
percentages of a manufacturer's production for the U.S. market. We
recognize, however, that manufacturers need to plan for compliance well
in advance of the start of production, and that actual production
volumes for any one model year may differ from their projections. On
the other hand, we believe that it would be inappropriate and
infeasible to base compliance solely on a manufacturer's projections.
That could encourage manufacturers to overestimate their production of
complying phase-in engines, and could result in significantly lower
emission benefits during the phase-in. We voiced the same concern with
respect to the highway HDDE phase-in schedule (see 66 FR 5109). As in
the highway HDDE program we propose to initially only require nonroad
diesel manufacturers to project compliance with the phase-in based on
their projected production volumes, provided that they made up any
deficits (in terms of percent of production) the following year.
Because we expect that a manufacturer making a good-faith
projection of sales would not be very far off of the actual production
volumes, we are proposing to limit the size of the deficit that would
be allowed, as in the highway program. In all cases, the manufacturer
would be required to produce at least 25% of its production in each
phase-in power category as ``phase-in'' engines (meeting the proposed
NOX and NMHC standards or demonstrating compliance through
use of ABT credits) in the phase-in years (after factoring in any
adjustments for Early Introduction or Blue Sky Series engine credits;
see Section VII.E). This minimum required production level would be 20%
for the 75-175 hp category if a manufacturer exercises the option to
comply with a reduced phase-in schedule in lieu of using banked Tier 2
ABT credits, as discussed in Section III.B1.b. Another important
proposed restriction is that manufacturers would not be allowed to have
a deficit in the year immediately preceding the completion of the
phase-in to 100%. This would help ensure that manufacturers are able to
make up the deficit. Since they could not produce more than 100% low-
NOX engines after the final phase-in year, it would not be
possible to make up a deficit from this year. These provisions are
identical to those adopted in the highway HDDE program.
E. What Might Be Done To Encourage Innovative Technologies?
1. Incentive Program for Early or Very Low Emission Engines
In our rulemakings for heavy-duty highway engines and light-duty
Tier 2 vehicles, we expressed our view that providing incentives for
manufacturers to introduce engines emitting at very low levels early,
or at levels significantly below the final standards, is appropriate
and beneficial. We believe that such inducements may help pave the way
for greater and/or more cost effective emission reductions from future
engines and vehicles. We believe this also holds for the early
introduction of low-emitting nonroad diesel engines. We also believe
that the opportunity for a practical early-engine program is even
greater for the nonroad sector than for the highway sector, considering
the long lead times before these proposed nonroad diesel standards
would take effect, the large variety of applications (and therefore
potential pull-ahead opportunities) in the nonroad sector, the large
number of machines fueled at dedicated fuel stations on construction
sites, farms, and industrial complexes, and the widespread availability
of very low sulfur diesel fuel at highway outlets after 2006, even
sooner in some areas. Thus we are proposing an early-engine incentive
program very similar to that adopted for highway engines and vehicles.
Specifically, we are proposing that manufacturers be permitted to
take credit for engines certified to this rule's proposed standards
prior to the 2011 model year in exchange for making fewer engines
certified to these standards in or after the 2011 model year. In other
words, clean engines sold earlier than required reduces the requirement
to sell similar engines later. The emission standards levels must
actually be met by qualifying engines to earn the early introduction
credit, without use of ABT credits. Therefore, the early introduction
engine credit is an alternative to the ABT program in that any early
engines or vehicles can earn either the engine credit or the ABT
emission credit, but not both. The purpose of the incentive is to
encourage introduction of clean technology engines earlier than
required in exchange for added flexibility during the phase-in years.
Any early engine credits earned for a diesel-fueled engine would be
predicated on the assurance by the manufacturer that the engine would
indeed be fueled with low sulfur diesel fuel in the marketplace. We
expect this would occur through selling such engines into fleet
applications, such as municipal maintenance fleets, large construction
company fleets, or any such well-managed centrally-fueled fleet.
Because obtaining a reliable supply of 15 ppm maximum sulfur diesel
fuel prior to the 2011 model year will require some effort by nonroad
diesel machine operators, we believe it is necessary and appropriate to
provide a greater incentive for early introduction of clean diesel
technology. Therefore, we propose to count one early diesel engine as
1.5 diesel engines later. This extra early credit for diesel engines
means that fewer clean diesel engines than otherwise would be required
may enter the market during the years 2011 and later. But, more
importantly, it means that emission reductions would be realized
earlier than under our base program. We believe that providing
incentives for early emission reductions is a worthwhile goal for this
program, because improving air quality is an urgent need in many parts
of the country as explained in Section II, and because the early
learning opportunity with new technologies can help to ensure a smooth
transition to Tier 4 standards. Therefore, we are proposing these
provisions for manufacturers willing to make the early investment in
cleaner engines.
We are proposing to provide this early introduction credit to
diesel engines at or above 25 hp that meet all of today's Tier 4
emissions standards (NOX, PM, and NMHC) in the applicable
power category. We are also providing this early introduction credit to
diesel engines that pull-ahead compliance with only the PM standard.
However, a PM-only early engine would offset only the ``phase-out''
engines during the phase-in years (those required to meet the Tier 4
standard for PM but not for NOX or NMHC); it would not
offset engines required to meet the Tier 4 NOX, NMHC, and PM
standards. Tier 4 engines certified to, or required to meet, the 2008
PM standard would not participate in this program, either as credit
generators or as credit users.
An important aspect of the early incentive provision is that it
must be done on an engine count basis. That is, a diesel engine meeting
new standards early would count as 1.5 such diesel engines later. This
contrasts with a provision done on an engine percentage basis which
would count one percent of diesel engines early as 1.5 percent of
diesel engines later. Basing the incentive on an engine count would
alleviate any possible influence of fluctuations in engine sales in
different model years.
[[Page 28483]]
Another important aspect of this proposed program is that it would
be limited to engines sold prior to the 2011 model year for engines at
or above 175 hp, prior to the 2012 model year for engines between 75
and 175 hp, or prior to the 2013 model year for engines between 25 and
75 hp. In other words, as in the highway program, nonroad diesel
engines sold during the transitional ``phase-in'' model years would not
be considered ``early'' introduction engines and would therefore
receive no early introduction credit. However, such engines and
vehicles would still be able to generate ABT credits. As with the
phase-in itself, and for the same reasons, we are proposing that an
early introduction credit could only be used to offset requirements for
engines in the same power category as the credit-generating engine (see
Section III.B).
As a further incentive to introduce clean engines and vehicles
early, we are also proposing a provision that would give manufacturers
an early introduction credit equal to two engines during or after the
phase-in years. This ``Blue Sky'' incentive would apply for diesel
engines achieving standards levels at one-half of the proposed long-
term NOX standard while also meeting the NMHC and PM
standards. Due to the extremely low emission levels to which these Blue
Sky series engines and vehicles would need to certify, we believe that
the double engine count credit is appropriate. Table VII.E-1 shows the
emission levels that would be required for diesel engines to earn any
early introduction credits (other than ABT credits).
Table VII.E-1.--Proposed Program for Early Introduction of Clean Engines
At or Above 25 hp
------------------------------------------------------------------------
Per engine
Category Must meet \a\ credit
------------------------------------------------------------------------
Early PM-only \b\............. 0.01 g/bhp-hr (=75 hp) or PM 0.02
g/bhp-hr PM (<75 hp)
or 0.02 g/bhp-hr PM
(<75 hp).
Early Engine \b\.............. above-indicated PM 1.5-to-1
standard +
0.30/0.14 g/bhp-hr NOX
/ NMHC (>=75 hp) or
3.5 g/bhp-hr NMHC +
NOX (<75 hp).
Blue Sky Series Engine........ as above for Early 2-to-1
Rnginr, except must
meet 0.15 g/bhp-hr
NOX standard.
------------------------------------------------------------------------
Notes:
\a\ Engines in all 3 categories must also meet the Tier 4 crankcase
emissions requirements.
\b\ Engine count credits must be earned prior to the start of phase-in
requirements in applicable power categories (prior to 2103 for 25-75
hp engines).
We welcome comment on these proposed provisions, as well as other
ideas for encouraging the introduction of Tier 4 engines early, or of
engines cleaner than Tier 4 levels. One area we especially seek comment
on is whether or not engines below 25 hp that achieve the proposed
long-term Tier 4 PM standard for 25-75 hp engines of 0.02 g/bhp-hr, or
engines below 75 hp that achieve the proposed long-term Tier 4
NOX standard for 75 hp engines of 0.30 g/bhp-hr,
should gain credits under this program that could be used to offset
requirements for larger engines, as a means of encouraging the
migration of clean technologies to smaller engines.
2. Continuance of the Existing Blue Sky Program
In the 1998 final rule, the Agency established its original Blue
Sky Series Engine program for nonroad diesel engines (63 FR 56968; see
preamble Section III.I). This program encourages the early introduction
of engines with emission levels (as measured on a transient test) about
40% lower than the Tier 2 standards levels. Manufacturers could
designate these engines as Blue Sky Series engines and sell them for
use in state, municipal, or commercial programs calling for these
cleaner engines (but not in the ABT program, to avoid double-counting
of emission reductions). Because the Agency's direction for the nonroad
engine program was not completely settled at the time, the 1998 final
rule limited the Blue Sky program to engines built in the 2004 and
earlier model years, but discussed our intent to consider extending it
later. This Tier 4 proposal does provide more clarity for the future
direction of the nonroad engine program, and so at this time we are
asking for comment on extending or revising the existing Blue Sky
Series engine program. We believe that the levels set for the existing
Blue Sky program are not stringent enough to warrant their continuance
into the Tier 4 years, but we also note that the lack of a transient
certification test in Tier 3 may make continuance of this program
beyond 2004, perhaps through Tier 3 (and Tier 2 for engines under 50
hp), useful. We welcome comment on this, as well as on any experience
with the program thus far, plans to use it in the future, whether the
standards and test cycle should be changed and, if so, beginning in
what model year.
F. Provisions for Other Test and Measurement Changes
This section contains further detail and explanation regarding
several related nonroad diesel engine emissions test and measurement
provisions. There are five topics which will be discussed: (1) EPA's
proposed supplemental nonroad transient test; (2) an additional cold
start transient test requirement for nonroad diesel engines; (3) a
provision for control of smoke testing; (4) steady-state testing; (5)
maximum test speed; and (6) general improvements to test procedure
precision.
1. Supplemental Transient Test
Nonroad diesel engines and equipment for the most part run on a
more transient basis than their highway diesel counterparts through
operations such as shifting loads, powering auxiliary equipment and
performing repetitive tasks. A smaller, but significant, transient
segment of nonroad equipment operates in a constant-speed manner for
most or all of its useful life as with electrical generating sets, arc
welders and the like. However, nonroad test regulations to date have
tended to not capture a broad area of real world operating
characteristics and the emissions which result from these modes of
equipment operation. The Agency believes that it is important to ensure
that nonroad engines meet emission standards in-use under typical
operating conditions so that the expected benefits of the program will
be achieved over the life of the program. The supplemental nonroad
diesel engine transient test provisions EPA is proposing are intended
to help achieve this goal. Steady-state emission testing of nonroad
diesel engines will be retained because it covers types of in-use
diesel engine
[[Page 28484]]
operation not represented in nonroad diesel transient operation.
Steady-state emission testing provides a benchmark as well for simpler
test programs, like Selective Enforcement Audits (SEAs).
As explained in section III.C. above, EPA is proposing to
supplement its steady-state emission testing in nonroad diesel engines
with a transient duty emission test procedure for nonroad diesel
engines, the Nonroad Transient Composite (NRTC) \307\ test cycle. The
Agency's NRTC cycle is described in proposed regulations at 40 CFR part
1039. A detailed discussion of the proposed transient test cycle and
its derivation is contained in Chapter 4 of the Draft RIA for this
proposal. Like current nonroad diesel standards, any new emission
standards would apply to certification, Selective Enforcement Audits
(SEAs), and equipment in actual use for engines covered by the
standards.
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\307\ Memoranda to Docket A-2001-28: ``Speed and Load Operating
Schedule for the Nonroad Transient Composite test cycle'' and ``NRTC
Cycle Construction''.
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EPA's supplemental nonroad transient test will apply to a nonroad
diesel engine when that engine must first show compliance with EPA's
proposed Tier 4 PM and NOX+NMHC emissions standards which
are based on the performance of the advanced post-combustion emissions
control systems (e.g. CDPFs and NOX adsorbers), with the
specific exception of engines under 25 hp for PM and under 75 hp for
NOX. The transient duty cycle would be applicable to Tier 4
phase-in engines, as well as the phase-out engines (as defined in
section III.B.1.b of this preamble). However, we are seeking comment on
whether the transient test procedure should only be required for the PM
standard for phase out engines. The table VII.F.-1 below outlines the
dates for implementation of this requirement and notes specific
exceptions for phase-in of some engine standards.
Table VII.F.-1. Implementation Model Year for Nonroad Transient Testing
------------------------------------------------------------------------
Transient test
Power category implementation
model year \a\
------------------------------------------------------------------------
< 25 hp................................................. 2013
25 <= hp < 75........................................... \b\ 2013
75 <= hp < 175.......................................... 2012
175 <= hp <= 750 hp..................................... 2011
750 hp....................................... \c\ 2011
------------------------------------------------------------------------
Note:
\a\ We are taking comment on whether the transient test procedure should
only be required for the PM standard for phase out engines under 750
hp and we are seeking comment on not requiring the transient test
procedure for carry over engines over 750 hp.
\b\ The transient test would apply in 2012 for any engines in the 50-75
hp range that choose not to comply with the proposed 2008 transitional
PM standard.
\c\ Beginning in 2014, when the phase-in has been completed, the
transient test would apply to all nonroad engines 750 hp,
however we are taking comment on this approach.
While manufacturers of nonroad diesel engines under 75 hp are not
subject to the transient test procedure and therefore not required to
submit data demonstrating that their engines will meet the Tier 4
nonroad PM emission standard beginning in 2008, it is our expectation
that manufacturers, in anticipation of the transient test requirements
and in accordance with applicable defeat device prohibitions, would
design their engines with effective, in-use control over the expected
range of operating conditions, including transients. Given this, we
feel this affords a good balance to address workload constraints for
these manufacturers as they prepare for addressing Tier 4 compliance.
As explained earlier in section III of this preamble, actual submission
of transient test data will not be required of engine manufacturers in
these power categories until 2013.\308\ EPA recognizes that the timing
of interim standards for these engines could otherwise force
manufacturers of smaller engines to have to certify under the proposed
NRTC duty cycle test requirement before the requirement applies to the
broader market of engine manufacturers in the 2011 to 2013 time frame.
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\308\ See Note ``b'' in Table VII-F-1 above for engines between
25 and 75 hp (19-56 kW).
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The Agency notes however that some manufacturers have reported
difficulties measuring transient PM emissions in 750 hp and over
engines under full-flow constant volume sampling (CVS) emission
measurement systems. It has been reported that this may be due to
difficulties apportioning the large exhaust volumes to sample
emissions. Additionally, manufacturers have raised concerns regarding a
requirement to conducttransient testing for engines over 750 hp, based
on concerns related to facility impacts and sales volumes that are
particular for engines over 750 hp. To address the concerns raised, the
Agency is taking comment on not requiring the engine manufacturer to
conduct transient testing for engines over 750 hp for purposes of
certification. Manufacturers would have the option to submit an
engineering analysis that demonstrates compliance with the applicable
transient standard. This engineering analysis would have to include
relevant test data, such as steady state test data, that would support
the engineering analysis.
Similarly, PM exhaust emissions gathered from these large engines
using partial flow sampling systems (PFSS) tend to be high in volatile
PM fractions \309\ under some low load operating modes. To date,
volatile PM measured from PFSS has not been proven to be consistently
comparable to volatile PM measured by a full-flow CVS. The pressure
across the filter and other sample zone conditions, coupled with
differences in the dilution rate and method and residence time, may
combine to yield a different PM composition in PFSS than in full-flow
CVS systems at these operating conditions. EPA requests comment from
manufacturers on the use of PFSS test practices for PM emission data
collection in these large displacement engines.
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\309\ Memorandum to Docket ``Partial Flow Testing Concerns in
Large Nonroad Diesel Engines as Regards Emission Testing Through
Partial Flow Sampling'', Docket A-2001-28.
---------------------------------------------------------------------------
EPA recognizes that there may be practical difficulties with
emission testing in large nonroad diesel engines over 750 hp, systems
which often have multiple exhaust manifolds and may incorporate several
catalysts or other pieces of emission control equipment. Further, the
Agency does not intend at this time to require that manufacturers use
PFSS to determine PM emissions from their engines for certification. A
large engine manufacturer may, however, choose to submit PM data to the
Agency using PFSS as an alternative test method, if that manufacturer
can demonstrate test equivalency using a paired-T test, as outlined in
regulations at 40 CFR 86.1306-07.
EPA is also proposing, as an alternative to the NRTC for a limited
class of engines, a Constant Speed Variable Load (CSVL) transient duty
cycle. The CSVL transient duty cycle is derived from the EPA's Arc
Welder Highly Transient Torque application duty cycle. The CSVL cycle
is described in the proposed regulations at 40 CFR 1039.510. Because of
the more limited range of engine operation in the CSVL cycle,
manufacturers must ensure that engines certified with data generated
with this cycle are used exclusively in constant-speed applications.
Accordingly, these engines must include labeling information indicating
this limited emission certification. An example of engines in this
category of
[[Page 28485]]
nonroad diesel equipment include power generating sets which are very
tightly governed for operating speed changes. Other ``constant speed''
equipment may be less closely regulated for changes in speed such as
those that utilize a 3% droop-type of engine speed governor. One might
expect that this latter group would more easily pass cycle performance
statistics over a constant speed transient test than the more speed
change-sensitive former group, represented by electrical generating
sets, for example. However, both types of constant speed engines
experience some fluctuations in speed and load during operation in-use
and the CSVL duty cycle would capture emissions from these infrequent
modes of operation, as well.
Transient testing requires consideration of statistical parameters
for verifying that test engines adequately follow the prescribed
schedule of speed and load values. The proposed regulations in Sec.
1065.530 detail these statistical parameters (or ``cycle statistics'')
for nonroad diesel engines. These values are somewhat different than
the comparable values for highway diesel engines to take into account
the characteristics of the nonroad composite cycle and the CSVL cycle.
Note also that we are proposing to modify certain cycle statistics
previously established for nonroad spark-ignition engines. These
changes generally allow testing spark-ignition engines in a way that
follows the speed and load traces somewhat less precisely than
previously established. All of the proposed changes for spark-ignition
engines are consistent with the comparable cycle statistics we are
proposing for nonroad diesel engines.
While designed to control for a broad range of constant-speed
nonroad engines, the Agency's CSVL cycle has an average speed which may
be lower than the speed which a manufacturer considers optimal for
their engines in-use. Further, EPA recognizes that some constant speed
equipment may operate near or at its rated engine rpm during much of
that equipment's useful life. As such, EPA is proposing that constant-
speed engines tested in the laboratory with installed speed governors
be required to meet cycle statistics for engine load, but not for
engine speed. This addresses the concern that different engines may
have different degrees of engine speed variation and that some engines
may be set to operate at speeds slightly different than the defined
point of maximum test speed. At the same time, the installed governor
forces the test engine to operate in a way that is representative of
in-use operation. This is described further in Chapter 4 of the Draft
RIA for this rulemaking.
Engine manufacturers have raised additional concerns about
designing constant-speed engines to meet emission standards over the
CSVL cycle. These concerns generally focus on the fact that the cycle
has relatively light engine loads and is derived from an arc welder
powered by a naturally aspirated engine. Manufacturers questioned the
representativeness of this cycle for generators, which is a more common
application for constant-speed engines. We continue to believe that
transient testing of these engines will add assurance that they control
emissions under real in-use operation. While the CSVL cycle does not
capture the full operating experience of every engine application, we
believe that engines designed to this cycle will control emissions
effectively under other types of transient operation not specifically
included in the certification procedure. Especially given the
anticipated emission-control technologies, we believe engines that are
capable of meeting emission standards on the CSVL cycle will have the
transient-response characteristics that are appropriate for controlling
emissions at higher engine loads and for less dynamic transient
operation. At the same time, we share engine manufacturers' interest in
creating duty cycles that achieve in-use emission reductions without
requiring approaches that lead to laboratory improvements unrelated to
an engine's in-use operation. We are therefore expecting to continue
discussions with engine manufacturers to pursue the possibility of
developing a constant-speed transient cycle that addresses these
concerns. We request comment on the extent to which the CSVL cycle will
pose design burdens or constraints unrelated to improving in-use
emission control.
EPA recently adopted a similar transient duty cycle for spark-
ignition constant-speed engines (67 FR 68242, 68298-99, November 8,
2002). This duty cycle, which is based on the same underlying engine
operation of an arc welder powered by a diesel engine, includes a
combination of equal parts typical and high-transient operation. There
was no effort to modify the schedule of engine operation to make it
more representative of spark-ignition engines, so the expectation was
that the same cycle would eventually apply to nonroad diesel engines.
Aside from the different selection of engine operation from the
available operating welder described above, the proposed constant-speed
transient cycle includes several adjustments that would need to be
factored into the ``spark-ignition'' cycle before it could be applied
to nonroad diesel engines. These adjustments include renormalization
with a more robust engine map (based on updated specifications of the
original engine) and ``I-alpha'' corrections to synchronize
measurements made with and without a flywheel (see Section 4.2.8.1 of
the Draft RIA). EPA requests comment on whether the previously adopted
constant-speed transient cycle (in modified form) should apply equally
to nonroad diesel engines. Conversely, if EPA adopts the proposed
constant-speed transient cycle for nonroad diesel engines, we would
expect to change the regulations for spark-ignition engines to align
with the conclusions in this rulemaking. EPA accordingly requests
comment on these same issues as they relate to spark-ignition engines.
EPA is proposing an optional test cycle specifically for engines
used in transport refrigeration units (TRUs). These engines would be
certified to a four-mode steady-state duty cycle, developed by the
California-EPA Air Resources Board.\310\ Two modes would be run at the
engine's maximum test speed, one mode at 50% of observed engine torque
and the other mode at 75% of observed engine torque. The third and
fourth modes would be run at the engine's intermediate test speed and,
again, one mode would be run at 50% of observed engine torque and the
other mode at 75% of observed engine torque. All four modes would be
weighted equally in determining an operating mode's contribution to the
engine's emissions.
---------------------------------------------------------------------------
\310\ Information on the proposed TRU cycle may be found on the
California ARB Web site at http://www.arb.ca.gov/diesel/
dieselrrp.htm.
---------------------------------------------------------------------------
Manufacturers certifying engines to the TRU cycle would need to
state on the emission control label that the engines may only be used
in TRUs, provide installation instructions to ensure they will operate
only in the modes covered by the test cycle, and keep records on
delivery destinations for these engines. Although these engines would
not be subject to a transient duty cycle, they would be subject to not-
to-exceed standards based on any normal operation that they might
experience in the field. Manufacturers of these engines may petition
EPA at certification for a waiver of the requirement to provide smoke
emission data for their constant-torque engines. We request comment on
whether different modes, or different weighting
[[Page 28486]]
factors, would be more appropriate for characterizing TRU emissions.
2. Cold Start Testing
EPA is proposing to include a requirement for a cold start
transient test to be run in conjunction with the Agency's proposed
nonroad diesel engine transient test. While EPA does not have available
a database of emission information to characterize cold start emissions
from all power categories of nonroad diesel engines, EPA has been able
to analyze the second-by-second in-use operation of some forty pieces
of Tier 1 and older nonroad equipment. Using a subset of equipment from
this study, the Agency characterized the ``average'' workday of each
piece of equipment in the data set \311\ and attempted to define the
role ``cold start'' operation, generally characterized by lower exhaust
temperatures and higher-than-idle engine speeds, played in engine
emissions. Generally, the Agency found that times when the engine was
operating at cold start, higher engine emission rates were seen than
during normal, temperature-stabilized operation of the engine. These
cold start, or ``warming-up'', periods were seen to last on average ten
minutes after equipment key-on for the units in our study.
---------------------------------------------------------------------------
\311\ Memorandum to Docket, ``Analysis of Second-by-Second
Emission and Activity Data for a Private Rental Fleet of
Construction Equipment'' Docket A-2001-28.
---------------------------------------------------------------------------
The Agency found, that over an eight to ten hour workday, a piece
of nonroad equipment would spend between 25 and 35 percent of its in-
use day running in idle operation at a relatively low rate of emission
output. With downtime on the equipment for operator lunch times and
equipment transport, there could be a further period of an hour or more
of low to no emissions from the equipment in-use. At first key-on of
the workday, and with each additional ``key-on'' cold start event
during the day, the equipment experiences a period of higher emissions
until it reaches a stabilized operating temperature. Start-up of the
equipment after a period of downtime which lasted an hour or more was
generally seen to experience rates of engine emissions similar to those
seen at first key-on, or cold start, and were considered periods of
cold start emissions, as well. The total time the equipment in the
study spent at these higher rates of ``cold start'' engine emissions
could be estimated to generate approximately one-tenth of the engine
emissions that the equipment would be expected to produce over the
whole workday. Therefore, EPA proposes to weight the emission test
results from its additional cold start transient test requirement as
one tenth of the composite transient emission test results for a
particular engine. The Agency requests comments as to the robustness of
this weighting factor and as to its applicability across the spectrum
of nonroad diesel equipment.
In addition, EPA requests comment on the potential to apply an
approach adopted for commercial spark-ignition engines, in which
engines operate over a single ``warm-start'' cycle (67 FR 68298,
November 8, 2002; see 40 CFR 1048.510), to nonroad diesel engines. The
regulations for these spark-ignition engines address cold-start
emissions indirectly through a combination of provisions. First, the
warm-up period before emission measurement can start is limited to
three minutes of operation. As a result, any engine operation after
this three-minute period is fully accounted for by emission
measurements. Second, the regulations direct manufacturers to design
their emission-control systems to start working as soon as possible
after engine starting and to describe in their application for
certification how their engines meet this objective. For engines that
take advantage of the period of unmeasured emissions with a design that
has unnecessarily high emissions, we can consider this a defeat device
and deny certification. Manufacturers therefore need to take steps to
design their engines and any emission-control equipment to control
emissions during the warm-up period without the additional effort of
supplemental cold-start testing. EPA requests comment on whether this
approach would be appropriate for nonroad diesel engines. In
particular, we request comment on how long the warm-up period prior to
start of emissions measurement should be for diesel engines. The three-
minute warm-up period specified for these spark-ignition engines
reflects the time needed for their catalysts to start working. The
emission-control technologies anticipated for diesel engines under this
proposal would need additional time, perhaps 10 minutes, before they
achieved nearly full effectiveness in controlling diesel emissions. Any
comments regarding this approach should address how the changed
procedure would affect measured emission levels and how the emission
standard should be adjusted to reflect these changes.
3. Control of Smoke
Manufacturers are currently responsible for testing and reporting
results for nonroad ``peak acceleration'' and ``lugging'' smoke
emissions. These regulations are detailed in 40 CFR 89.113 \312\ and
refer the reader back to 40 CFR 86, subpart I, which was developed for
highway engines. This rulemaking however proposes to replace the
present Federal Smoke Procedure for nonroad engines with the ISO 8178
Part 9 nonroad smoke procedure as the method and standards by which
engine manufacturers will certify their nonroad engines. This new smoke
testing procedure with its related smoke standards will become
effective for a particular engine when that engine is certified to
EPA's proposed Tier 4 or transition PM and NOX-NMHC
standards. Proposed regulations may be found at 40 CFR part 1039.
---------------------------------------------------------------------------
\312\ Smoke testing guidelines are detailed under ISO 8178-9,
First Ed. 10-15-2000, ``Reciprocating internal combustion engines-
Exhaust emission measurement-Part 9: Test cycles and test procedures
for test bed measurement of exhaust gas smoke emissions from
compression ignition engines operating under transient conditions''.
A copy of the testing procedure may be found for reference only in
Docket A-2001-28.
---------------------------------------------------------------------------
The ISO-TC70/SC8/WG1 committee developed a nonroad smoke test
procedure, ISO 8178-9 and finalized it on October 15, 2000. Recognizing
the value of harmonized test procedures and limit standards, EPA is
proposing through this rulemaking to use ISO 8178-9 for smoke testing
of nonroad diesel engines. EPA has analyzed ISO 8178-9 and concluded
that it is appropriate for adoption within the Agency's nonroad test
procedures. It is important to note that the ISO 8178-9 smoke emissions
test procedure is very different from the procedure specified in
Subpart I of Part 86. As a consequence, in adopting the ISO 8178-9
procedure, EPA proposes to revise the numerical limit value associated
with this ISO procedure. EPA proposes that the appropriate (maximum)
numerical standard for ISO 8178-9 peak (acceleration) smoke value
measurement will be 20 percent opacity, peak smoke values at 3x, 6x,
and 9x will be 18 percent opacity, 16 percent opacity and 14 percent
opacity, respectively, and the lug smoke value will be 10 percent
opacity. The Agency has determined this value on review of data from
smoke tests on various engines \313\ across differing programs and
requests comment as to the appropriateness of these particular limit
values.
---------------------------------------------------------------------------
\313\ ``Nonroad Diesel Engine Smoke Testing and Limited Filter
Analysis'' May, 2001.Final Report to Engine Manufacturers
Association from Southwest Research Institute. Docket A-2001-28
---------------------------------------------------------------------------
Some state governments have expressed a desire for a federal smoke
regulatory program that would enable
[[Page 28487]]
them to test in-use nonroad engines in a manner that would permit
action against gross emitters of smoke. In a like manner, EPA could
propose additional smoke testing regulations as part of any future
rulemaking which would address manufacturer's in-use smoke test
requirements. The main elements of any in-use smoke program would be a
new Federal smoke standard(s) and test procedure for new engines,
guidance from EPA for state in-use smoke control programs (including a
full smoke test procedure and accompanying state limit values), and a
means by which the data from the two programs could be related. The
current smoke test procedure from Part 86, Subpart I does not provide
data comparable to the most practical in-use smoke test procedure, a
snap-idle acceleration test with measured opacity. However, based on
the current ISO 8178-9 procedure, EPA believes data from an ISO 8178-9
certification smoke test could provide the desired link.
In applying nonroad smoke standards and procedures to engines rated
50 hp and under, EPA has chosen to exempt one-cylinder engines, the
large majority of which are being used in generator sets and other
constant-speed applications, from the smoke standards. EPA still
believes that testing of these engines is unique in ways that would
need to be addressed before requiring smoke standards and testing for
this class of engines. These engines tend to produce puffs of smoke
that may make the smoke measurement erratic. The Agency believes the
air quality impact of this decision will be minimal. EPA expects to
reconsider this issue in the future in relation to other in-use testing
concerns.
Finally, the Agency proposes to exempt from smoke standards those
nonroad diesel engines which have certified PM emission levels or
Family Emission Limits (FELs) below 0.05 g/hp-hr. The Agency believes
that engines meeting an FEL below 0.05 g/hp-hr would utilized control
technology, such as particulate traps, that would provide adequate
smoke control.
4. Steady-State Testing
Recognizing the variety of both power classes and work applications
to be found within the nonroad vehicle and engine population, EPA will
retain current Federal steady-state test procedures for nonroad
engines. The steady state duty cycle applicable in each of the
following categories: 1) nonroad engines 25 hp and greater; 2) nonroad
engines less than 25 hp; and 3) nonroad engines having constant-speed,
variable-load applications, (e.g., generator sets) as set out in Table
VII.F-2. The steady-state cycles remain, respectively, the 8-mode
cycle, the 6-mode cycle and the 5-mode cycle.\314\ We envision
manufacturers that satisfy the requirements to certify on the steady
state ISO 8178-D2 duty cycle might likewise satisfy the requirements to
test over the Constant Speed Variable Load Duty Cycle (CSVL).
Manufacturers will be required to meet emission standards under steady-
state conditions, in addition to meeting emission standards under the
proposed supplemental transient test cycle. Steady-state test cycles
are needed so that testing for certification will reflect the broad
range of operating conditions experienced by these engines. A steady-
state test cycle represents an important type of modern engine
operation, in power and speed ranges that are typical in-use. The mid-
to-high speeds and loads represented by present steady-state testing
requirements are the speeds and loads at which these engines are
designed to operate for extended periods for maximum efficiency and
durability. Details concerning the three steady-state procedures for
nonroad engines and equipment can be found in proposed regulations at
proposed 40 CFR 1039.510 and in the three appendices which follow that
section, one for each cycle.
---------------------------------------------------------------------------
\314\ The three proposed steady-state test cycles are similar to
test cycles found in the International Standard ISO 8178-4:1996 (E)
and remain consistent with the existing 40 CFR part 89 steady state
duty cycles.
---------------------------------------------------------------------------
Manufacturers would perform each steady-state test following all
applicable test procedures in proposed regulations at proposed 40 CFR
part 1039, e.g., procedures for engine warm-up and exhaust emissions
measurement. We are proposing that the testing must be conducted with
all emission-related engine control variables in the maximum
NOX-producing condition which could be encountered for a 30
second or longer averaging period at a given test point. Table VII.F.-2
below summarizes the steady-state testing requirements by individual
engine power categories.
Table VII.F-2.--Summary of Steady-State Test Requirements
----------------------------------------------------------------------------------------------------------------
Steady-state testing requirements
--------------------------------------------------------------------------
Nonroad engine power classes 8-Mode cycle (ISO 8178- 6-Mode cycle (ISO 8178- 5-Mode cycle (ISO 8178-
4 C1) 4 G3) 4 D2)
----------------------------------------------------------------------------------------------------------------
hp < 25 (kW < 19).................... NA \a\................. applies................ applies \b\.
25 <= hp < 75 (19 <= kW < 56)........ applies................ NA \a\................. applies \b\.
75 <= hp <175 (56 <= kW <130) applies................ NA \a\................. applies \b\.
175 <= hp <=750 (130 <= kW <=560).... applies................ NA \a\................. applies \b\.
hp 750 (kW 560) applies................ NA \a\................. applies \b\.
----------------------------------------------------------------------------------------------------------------
\a\ Testing procedure not applicable to this class of engines.
\b\ For constant, or nearly constant, speed engines and equipment with variable, or intermittent, load.
5. Maximum Test Speed
We are proposing to make a slight change to how test cycles are
specified. We are proposing to apply the existing definition of maximum
test speed in part 1065 to nonroad CI engines. This definition of
maximum test speed is the single point on an engine's normalized
maximum power versus speed curve that lies farthest away from the zero-
power, zero-speed point. This is intended to ensure that the maximum
speed of the test is representative of actual engine operating
characteristics and is not improperly used to influence the parameters
under which their engines are certified. In establishing this
definition of maximum test speed, it was our intent to specify the
highest speed at which the engine is likely to be operated in use.
Under normal circumstances this maximum test speed should be close to
the speed at which peak power is achieved. However, in past
discussions, some manufacturers have indicated that it is possible for
the maximum test speed to be unrepresentative of in-use operation.
Since we were aware of this potential during the original development
of this
[[Page 28488]]
definition, we included provisions to address issues such as these.
Part 1065 allows EPA to modify test procedures in situations where the
specified test procedures would otherwise be unrepresentative of in-use
operation. Thus, in cases in which the definition of maximum test speed
resulted in an engine speed that was not expected to occur with in-use
engines, we would work with the manufacturers to determine the maximum
speed that would be expected to occur in-use.
6. Improvements to the Test Procedures
We are proposing changes to the test procedures to improve the
precision of emission measurements. These changes address the potential
effect of measurement precision on the feasibility of the standards. It
is important to note that these changes are not intended to bias
results high or low, but only to improve the precision of the
measurements. Based on our experience with these modified test
procedures, and our discussions with manufacturers about their
experiences, we are confident that these changes will not affect the
stringency of the standards. These changes are summarized briefly here,
and the rationale for the changes affecting Constant Volume Sampling
(CVS) and PM testing are summarized in a memo to the docket (Air Docket
A-99-06, IV-B-11), which was originally submitted in support of the
recent highway heavy-duty diesel engine rule (66 FR 5001, January 18,
2001). The rationale for any other changes are summarized in a memo to
the docket for this proposal.
Many of the changes are to the PM sampling procedures. The PM
procedures will be the same as those finalized as part of the highway
heavy-duty diesel engine rule (66 FR 5001, January 18, 2001). These
include changes to the type of PM filters that are used and
improvements in how PM filters are weighed before and after emission
measurements, including requirements for more precise microbalances.
Another area includes changes to the CVS dilution air and flow
measurement specifications to allow for lower dilution ratios. These
changes are also the same as those changes finalized in the highway
rule.
Another area of change is the NOX calibration procedure.
These changes are also the same as those changes finalized in the
highway rule. The new calibration procedures will result in more
precise continuous measurement of very low concentrations of
NOX.
Other changes are being proposed to allow for other measurement
options, including the complete or partial adoption of the
International Standards Organization's test procedures as specified in
ISO 8178-1 (2002-2003 revision) and ISO 8178-11 DIS. EPA has
participated in draft changes to these procedures and feels that
adopting these procedures, at least in part, would not only allow for
the use of the most technically correct procedures, but would also
improve harmonization with international standards, which might offer
cost savings for some manufacturers. EPA requests comments on the
appropriateness of adopting parts of or all of ISO 8178-1 (2002-2003
revision) and ISO 8178-11 DIS.
If finalized, manufacturers would be allowed to use the new
procedures immediately for all certifications of all engines (i.e. to
certify any nonroad engine, not just Tier 4 engines), and manufacturers
will also be able to use their current procedures up to a certain
transition date to allow for a gradual transition to the new
procedures. The reason for this is that some of these changes may not
be convenient or cost-effective in the short term, and manufacturers
may be willing to live with some slightly lower measurement precision
in order to lower short-term testing costs. We believe, though, that
manufacturers should be able to individually optimize their test
facilities in this manner. In addition, it is important for
manufacturers to understand that we will conduct our confirmatory
testing in the manner specified in these regulations.
We are also proposing a new regulatory provision that specifies the
steps that someone would need to follow to demonstrate that their own
alternate measurement procedure is as good as or better than the
procedure specified by our regulations. This provision will be the same
as that finalized for highway testing, which can be found in 40 CFR
86.1306-07. The proposed test procedure changes just discussed can be
found in 40 CFR Part 1065 of the proposed regulations.
G. Not-To-Exceed Requirements
EPA is proposing to adopt not-to-exceed (NTE) emission standards
for new non-road diesel engines which are similar to those the Agency
set for highway heavy-duty diesel engines. Specifically, the Agency
proposes to adopt for non-road diesel engines NTE specifications
similar to those finalized as part of the heavy-duty highway diesel
engine rulemaking. These specifications are currently published in 40
CFR 86.007-11 and 40 CFR 86.1370-2007.
NTE standards are set as multipliers of FTP standards, therefore,
the NTE standards are also set as emissions mass per unit work
performed (i.e. brake-specific, g/kW-hr). EPA proposes that non-road
NTE standards be applicable to NOX, CO, THC, and PM mass
emissions from the engines subject to this proposed rule. These
standards are evaluated against EPA-prescribed procedures for
conducting in-use testing. Such tests may be conducted in an engine or
chassis dynamometer laboratory, or they may be conducted on a piece of
non-road equipment operating normally in-use by using EPA-prescribed
field-testing procedures.
For new nonroad diesel engines, EPA proposes that manufacturers
state in their application for certification that they are able to meet
the NTE standards under all conditions that may reasonably be expected
to occur in normal equipment operation and use. Manufacturers will have
to maintain a detailed description of any testing, engineering
analysis, and other information that forms the basis for their
statement. This information may include a variety of steady-state
emission measurements not included in the prescribed emission testing
duty cycles. It may also include a continuous trace showing how
emissions vary during the transient test or operation manufacturers
believe are representative of the way their engines normally operate in
the field. This data may also consist of field testing data. Any of the
aforementioned data may be analyzed using the NTE data reduction
procedures proposed in this regulation; with the final emissions data
set then compared to the appropriate NTE standards.
EPA requests comment on an alternative NTE specification that
differs from the highway NTE specification. If adopted, this would be
the sole NTE test procedure for Tier 4 nonroad diesel engines. The
alternative utilizes all engine operation to determine compliance.
Other differences in its data reduction procedures would eliminate the
need for measuring engine torque for the alternative NTE, which can be
particularly difficult on-board nonroad vehicles. These alternative
procedures would also eliminate the need for an absolute exhaust flow
measurement for these engines by relying on a signal linearly
proportional to standard exhaust flow. This alternative approach would
address some concerns of the ease of practical in-use implementation of
NTE testing. For more detailed information on EPA's NTE provisions,
refer to Chapter 4.3 of the draft RIA for this proposal.
[[Page 28489]]
H. Certification Fuel
It is well-established that measured emissions may be affected by
the properties of the fuel used during the test. For this reason, we
have historically specified allowable ranges for test fuel properties
such as cetane and sulfur content. These specifications are intended to
represent most typical fuels that are commercially available in use.
This helps to ensure that the emissions reductions expected from the
standards occur in use as well as during emissions testing. Because we
are proposing to lower the upper limit for in-use nonroad diesel fuel
sulfur content to 500 ppm in 2007, and again to 15 ppm in 2010, we are
also proposing to establish new ranges of allowable sulfur content for
testing. These are proposed to be 300 to 500 ppm (by weight) for model
year 2008 to 2010 engines, and 7 to 15 ppm (by weight) for 2011 and
later model year engines. We believe that these ranges best correspond
to the fuels that diesel machines will potentially see in use. (See 66
FR 5112-5113 where we adopted a similar approach to certification fuels
for highway HDDEs.) These specifications will apply to emission testing
conducted for certification, selective enforcement audits, in-use, and
NTE testing, as well as any other laboratory engine testing for
compliance purposes for engines in the designated model years. Any
compliance testing of previous model year engines will be done with the
fuels designated in our regulations for those model years. Note that we
are allowing certification with fuel meeting the 7 to 15 ppm sulfur
specification in 2010 for under 11 hp, air-cooled, hand-startable, DI
engines certified under the proposed optional standard provision
discussed in Section III.B.1.d.i.
It is important to note that while these specifications include the
maximum sulfur level allowed for in-use fuel, we believe that it is
generally appropriate to test using the most typical fuels. As for
highway fuel, we expect that, under the 15 ppm maximum sulfur
requirement, refineries will typically produce diesel fuel with about 7
ppm sulfur, and that the fuel could have slightly higher sulfur levels
after distribution. Thus, we expect that we would use fuel having a
sulfur content between 7 and 10 ppm sulfur for our emission testing.
This is the same as the range we indicated would be used for HDDE
engine testing in model year 2007 and later (66 FR 5002); and as with
the highway fuel, should we determine that the typical in-use nonroad
diesel fuel has significantly more sulfur than this, we would adjust
this target upward.
We are also proposing two options for early use of the new 7 to 15
ppm diesel test fuel. The first would be available beginning in the
2007 model year for engines employing sulfur-sensitive technology.
(Model year 2007 coincides approximately with the introduction of 15
ppm highway fuel.) This allowance to use the new fuel in model years
before 2011 would only be available for engines which the manufacturer
demonstrates will be operated in use on fuel with 15 ppm sulfur or
less. Any testing that we perform on these engines would also use fuel
meeting this lower sulfur specification. This optional certification
fuel provision is intended to encourage the introduction of low-
emission diesel technologies in the nonroad sector. These engines will
be able to use the lower sulfur fuel throughout their operating life,
given the early availability of this fuel under the highway program,
and the assured availability of this fuel for nonroad engines by mid-
2010.
Considering that our proposed Tier 4 program would subject engines
under 75 hp to new emission standards in 2008 when 15 ppm maximum
sulfur fuel will be readily available from highway fuel pumps (and will
enter the nonroad fuel market shortly after in 2010), we believe it is
appropriate to provide a second, less proscriptive, option for use of
15 ppm sulfur certification fuel. This option would be available to any
manufacturers willing to take extra steps to encourage the use of this
fuel before it is required in the field. We are proposing to allow the
early use of 15 ppm certification fuel for 2008-2010 engines under 75
hp, provided the certifying manufacturer ensures that ultimate
purchasers of equipment using these engines are informed that the use
of fuel meeting the 15 ppm specification is recommended, and also
recommends to equipment manufacturers buying these engines that labels
be applied at the fuel inlet to remind users of this recommendation.
This option would not apply to those 50-75 hp engines not being
certified to the 0.22 g/bhp-hr PM standard, under the manufacturers'
option discussed in Section III.B.1.a. Comment is request on whether or
not application of this label should be mandatory for the equipment
manufacturers, and on whether the engine manufacturers should supply
the labels.
We believe that there may be a very small loss of emissions benefit
from any of these engines for which the operator chooses to ignore the
recommendation. This is because the engine manufacturer will be
designing the engine to comply with the emissions standards when tested
using 15 ppm fuel, potentially resulting in slightly higher emissions
when it is not operated on the 15 ppm fuel. We also believe, however,
that this is more than offset overall by the encouragement this
provision provides for early use of 15 ppm fuel. We are not proposing
that this option be available for engine designs employing oxidation
catalysts or other sulfur-sensitive exhaust emission control devices
except under the more restrictive provision for early use of 15 ppm
fuel described above, involving a demonstration by the manufacturer
that the fuel will indeed be used. Because these devices could
potentially have very high sulfur-to-sulfate conversion rates, and
because very high-sulfur fuels will still be available to some extent,
we believe that allowing this provision for these engines would risk
very high PM emissions until the 15 ppm nonroad fuel is introduced.
Comment is requested on whether or not we should deal with early use of
15 ppm test fuel to certify catalyst-equipped engines in some other
way, such as through a weighted-average emissions criterion using
results from testing on both higher-and lower-sulfur fuels. We are also
not proposing to make this second early 15 ppm test fuel option
available for engines not subject to a new Tier 4 standard in 2008 as
these engines should already be designed to meet applicable standards
in earlier years without need for the 15 ppm fuel.
We are also proposing a similar provision for use of certification
fuel meeting the proposed 300-500 ppm sulfur specification before the
2008 model year. We believe certification of model year 2006 and 2007
engines being designed to meet new Tier 2 or Tier 3 emission standards
taking effect in those years (2006 for engines at or above 175 hp and
2007 for 100-175 hp engines) should be able to use this fuel, provided
the certifying manufacturer is willing to take measures equivalent to
those discussed above to encourage the early use of this fuel (a
recommendation to the ultimate purchaser to use fuel with 500 ppm
maximum sulfur and a recommendation to equipment manufacturers to so
label their equipment). We also request comment as above on whether the
labeling should be mandatory. The widespread availability of 500 ppm
sulfur highway fuel, the short time that these 2006 and 2007 engines
could use higher sulfur fuels if an operator were to ignore the
recommendation, and the eventual use
[[Page 28490]]
of 15 ppm sulfur fuel in most of these engines for most of their
operating lives, gives us confidence that this provision to encourage
early use of lower sulfur fuel would be beneficial to the environment
overall. As with the proposed change to 300-500 ppm cert fuel for model
years 2008-2010, engine manufacturers would design their engines to
comply based on the test fuel specifications for certification and
compliance testing. The change from a fuel specification for compliance
testing that ranges up to 2000 ppm sulfur for Tier 2 and 3 engines to a
specification of 500 ppm sulfur maximum could have some limited effect
on the emissions control designs used on these Tier 2 and 3 engines, in
that it would be slightly easier to meet the Tier 2 and 3 standards
using the lower sulfur test fuel. In general, it is reasonable to set
specifications of test fuel reflecting representative in-use fuels, and
here the engines are expected to be using fuel with sulfur levels of
500 ppm or lower until 2010, and 15 ppm or lower after that. In this
case, any impact on expected engine emissions from this change in test
fuel for Tier 2 and 3 is expected to be slight.
We note that under current regulations manufacturers are already
allowed to conduct testing with certification fuel sulfur levels as low
as 300 ppm. The additional proposed provision for early use of 300-500
ppm sulfur test fuel would, however, result in any compliance testing
conducted by the Agency being done with fuel meeting the 300-500 ppm
specification. Likewise choice of the option for early use of 15 ppm
sulfur test fuel would result in any Agency testing being done using
that fuel. However, under both of these early certification fuel
options involving a recommended fuel use provision, the Agency would
not reject engines from in-use testing for which there was evidence or
suspicion that the engine had been fueled at some time with higher
sulfur fuel.
Finally, we are proposing to extend a provision adopted in the 1998
final rule. In that rule we set a 2000 ppm upper limit on the test fuel
sulfur concentration for any testing to be performed by the Agency on
Tier 1 engines under 50 hp and Tier 2 engines at or above 50 hp. We did
not extend this provision to later model year engines at that time
because we felt that more time was needed to assess trends in fuel
sulfur levels for fuels used in nonroad diesels. At this time we are
not aware of any additional information that would indicate that a
change in this test specification is warranted. More importantly,
because the fuel regulation we are proposing would make 500 ppm maximum
sulfur nonroad diesel fuel available by mid-2007, Tier 3 engines at or
above 50 hp (which phase in beginning in 2006) will be in the field for
only 1\1/2\ years prior to the in-use introduction of 500 ppm fuel, and
Tier 2 engines under 50 hp (which phase in beginning in 2004) will be
in the field for at most 3\1/2\ years prior to this time. We believe it
is appropriate to avoid adding the unnecessary complication of frequent
multiple changes to the test fuel specification. We are therefore
proposing to extend the 2000 ppm limit to testing conducted on engines
until the 2008 model year when the 500 ppm maximum test fuel sulfur
level takes effect as discussed above.
I. Labeling and Notification Requirements
As explained in Section III, the emissions standards contained in
the proposed regulations would make it necessary for manufacturers to
employ exhaust emission control devices that require very low-sulfur
fuel (less than 15 ppm) to ensure proper operation. This action
therefore proposes to restrict the sulfur content of diesel fuel used
in these engines. However, the 2008 emissions standards would be
achievable with less sensitive technologies and thus it could be
appropriate for those engines to use diesel fuel with up to 500 ppm
sulfur. There could be situations in which vehicles requiring either 15
ppm fuel or 500 ppm may be accidentally or purposely misfueled with
higher-sulfur fuel. Any of these misfueling events could seriously
degrade the emission performance of sulfur-sensitive exhaust emission
control devices, or perhaps destroy their functionality altogether.
In the highway rule we adopted a requirement that heavy-duty
vehicle manufacturers notify each purchaser that the vehicle must be
fueled only with the applicable low-sulfur diesel fuel. We also
required that diesel vehicles be equipped by the manufacturer with
labels near the refueling inlet to indicate that low sulfur fuel is
required.\315\ We are proposing similar requirements here.
Specifically, we are proposing that manufacturers notify each purchaser
that the nonroad engine must be fueled only with the applicable low-
sulfur diesel fuel, and ensure that the equipment is labeled near the
refueling inlet to indicate that low sulfur fuel is required. We
believe that these measures would help owners find and use the correct
fuel and would be sufficient to address misfueling concerns. Thus, more
costly provisions, such as fuel inlet restrictors, should not be
necessary.
---------------------------------------------------------------------------
\315\ We also required that highway vehicles be labeled on the
dashboard. Given the type of equipment using nonroad CI engines, we
are proposing equivalent dashboard requirement here.
---------------------------------------------------------------------------
Beginning in model year 2011, the required fuel would be 15 ppm.
For these engines, the label should state: ``ULTRA LOW-SULFUR NONROAD
DIESEL FUEL OR ON-HIGHWAY DIESEL FUEL ONLY (15 parts per million)''.
For model years 2008 to 2010, when the proposed test fuel would contain
300 to 500 ppm sulfur, the label should state: ``LOW-SULFUR NONROAD
DIESEL FUEL, ULTRA LOW-SULFUR NONROAD DIESEL FUEL, OR ON-HIGHWAY DIESEL
FUEL ONLY (500 ppm maximum)''. Engine manufacturers may choose during
earlier model years to certify engines using test fuel with sulfur
levels between 500 and 2,000 ppm. We would not require that these
engines be labeled.
This approach would ensure that the proper functioning of the
emission controls is not compromised by misfueling, while allowing
owners flexibility with respect to in-use fuels in those cases in which
their engines do not use sulfur-sensitive technologies.
For non-integrated manufacturers, the engine manufacturer will be
required to provide such a label to the equipment manufacturer, which
the equipment manufacturer will be required to install. Optionally, if
an equipment manufacturer chooses to install its own label, the engine
manufacturer will not be required to provide the label.
J. Temporary In-Use Compliance Margins
The Tier 4 standards will be challenging for diesel engine
manufacturers to achieve, and will require manufacturers to develop and
adapt new technologies for a large number and wide variety of engine
platforms. Not only will manufacturers be responsible for ensuring that
these technologies will allow engines to meet the standards at the time
of certification, they will also have to ensure that these technologies
continue to be highly effective in a wide range of in-use environments
so that their engines would comply in use when tested by EPA.
Furthermore, for the first time, these nonroad diesel engines will be
subject to a new transient test cycle and NTE standards. However, in
the early years of a program that introduces new technology, there are
risks of in-use compliance problems that may not appear in the
certification process or
[[Page 28491]]
during developmental testing. Thus, we believe that for a limited
number of model years after new standards take effect it is appropriate
to adjust the compliance levels for assessing in-use compliance for
diesel engines equipped with particulate traps or NOX
adsorbers. This would provide assurance to the manufacturers that they
will not face recall if they exceed standards by a small amount during
this transition to clean technologies. This approach is very similar to
that taken in the light-duty highway Tier 2 final rule (65 FR 6796) and
the highway heavy-duty rule (66 FR 5113-5114), both of which involve
similar approaches to introducing the new technologies.
Table VII.J-1 shows the in-use adjustments that we propose to
apply. These adjustments would be added to the appropriate FELs (see
Section VII.A) or, for engines certified to the standards without the
use of credits, to the standards themselves, in determining the in-use
compliance level for a given in-use hours accumulation. These
adjustment levels were chosen to be roughly equivalent to the temporary
in-use standard adjustments adopted for the heavy-duty highway program.
Note also the limiting of these adjustments to engines certified to
FELs below certain threshold levels. This is similar to the approach
taken in the heavy-duty rule which applied the in-use standards only to
vehicles using advanced low-emission technologies (see 66 FR 5113-
5114). Our intent is that these add-on levels be available only for
highly-effective advanced technologies such as particulate traps and
NOX adsorbers. As in our other mobile source programs, we do
not believe that the standards are stringent enough or the required
technology change radical enough to warrant add-ons for other proposed
standards changes (the NOX standard for 25-75 hp engines,
the 2008 PM standards for engines below 75 hp, or the NMHC standards).
Table VII.J-1.--Add-on Levels Used in Determining In-use Standards
----------------------------------------------------------------------------------------------------------------
PM add-on
NOX add-on level to FEL \a\ (g/bhp- level to FEL
Engine power Model years hr) \b\ (g/bhp-
hr)
----------------------------------------------------------------------------------------------------------------
25<= hp <75 (19 <= kW < 56)................ 2013-2014 none...............................
75 <= hp <175 (56 <= kW < 130)............. 2012-2015 0.10 for operating hours <=4000.... 0.01
0.20 for operating hours 4000.
hp =175 (kW =130).... 2011-2015 0.10 for operating hours <=4000....
0.20 for operating hours 4000.
----------------------------------------------------------------------------------------------------------------
Notes:
\a\ Applicable only to those engines with FELs at or below 1.5 g/bhp-hr NOX.
\b\ Applicable only to those engines with FELs at or below the Tier 4 PM standard.
Note that these in-use add-on levels apply only to engines
certified through the first few model years of the new standards and
having FELs below the specified levels. The in-use add-ons are
available through model year 2015 for such engines above 75 hp because
our proposed implementation schedule does not complete the phase-in
process in these power categories until 2014. The 2015 date provides 2
years for the designers of those engine models that are last to be
phased in (which may comprise upwards of 50% of sales and a large
number of low-volume engine models) to discover and resolve any
problems not showing up in the certification process or developmental
testing.\316\ This is the same period as that provided in the highway
HDDE rule.
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\316\ Flexibility provisions such as our ABT program and the
incentive program for early or very low emission engines may result
in some engines that incorporate the advanced emission control
technologies even later. However, we do not believe it is
appropriate to adjust the in-use compliance levels for engines on
which achieving the standard is delayed by manufacturer's choice,
nor did we do so in our highway HDDE program.
---------------------------------------------------------------------------
During the certification demonstration, manufacturers will still be
required to demonstrate compliance with the unadjusted Tier 4
certification standards using deteriorated emission rates. Therefore,
the manufacturer will not be able to use these in-use standards as the
design targets for the engine. They will need to project that most
engines would meet the standards in-use without adjustment. The in-use
adjustments will merely provide some assurance that they would not be
forced to recall engines because of some small miscalculation of the
expected deterioration rates.
K. Monitoring and Reporting of Emissions Related Defects
We are proposing to apply the defect reporting requirements of
Sec. 1068.501 to replace the provisions of 40 CFR part 85 for nonroad
engines. The requirements obligate manufacturers to tell us when they
learn that emission control systems are defective and to conduct
investigations under certain circumstances to determine if an emission-
related defect is present. We are also proposing a requirement that
manufacturers initiate these investigations when warranty information,
parts shipments, and any other information which is available indicates
that a defect investigation may be fruitful. For this purpose, we
consider defective any part or system that does not function as
originally designed for the regulatory useful life of the engine or the
scheduled replacement interval specified in the manufacturer's
maintenance instructions. The parts and systems are those covered by
the emissions warranty, and listed in Appendix I and II of part 1068.
We believe the investigation requirement proposed in this rule will
allow both EPA and the engine manufacturers to fully understand the
significance of any unusually high rates of warranty claims and parts
replacements for parts or parameters that may have an impact on
emissions. We believe that as part of its normal product quality
practices prudent engine manufacturers already conduct a thorough
investigation when available data indicate recurring parts failures.
Such data is valuable and readily available to most manufacturers and,
under this proposal it must be considered to determine whether or not
there is a possible defect of an emission-related part.
Defect reports submitted in compliance with the current regulations
are based on a single threshold applicable to engine families of all
production volumes. No affirmative requirement for gathering
information about the full extent of the problem was applicable. For
very large volume engine families, the proposed approach may result in
fewer total defect reports being submitted by manufacturers than the
traditional approach because the
[[Page 28492]]
number of defects triggering the submission requirement generally rises
in proportion to the engine family size. The single threshold in the
existing regulations results in reporting of defects in the smallest
engine families covered by this regulation very rarely because a
relatively high proportion of such engines would have to be known to be
defective before reporting is required under a fixed threshold scheme.
Therefore, under this proposal, the threshold for reporting for the
smallest engine families has been decreased as compared to the current
requirements.
We are aware that accumulation of warranty claims and part
shipments will likely include many claims and parts that do not
represent defects, so we are establishing a relatively high threshold
for triggering the manufacturer's responsibility to investigate whether
there is, in fact, a real occurrence of an emission-related defect.
Manufacturers are not required to count towards the investigation
threshold any replacement parts they require to be replaced at
specified intervals during the useful life, as specified in the
application for certification and maintenance instructions to the
owner, because shipment of such parts clearly do not represent defects.
All such parts would be excluded from investigation of potential
defects and reporting of defects, whether or not any specific part was,
in fact, shipped for specified replacement.
This proposal is intended to require manufacturers to use
information we would expect them to keep in the normal course of
business. We believe in most cases manufacturers would not be required
to institute new programs or activities to monitor product quality or
performance. A manufacturer that does not keep warranty or replacement
part information may ask for our approval to use an alternate defect-
reporting methodology that is at least as effective in identifying and
tracking potential emissions related defects as the proposed
requirements. However, until we approve such a request, the proposed
thresholds and procedures continue to apply.
The thresholds for investigation proposed today are 4 percent of
total production to date, or 4,000 engines, whichever is less, but
never fewer than 40 for any single engine family in one model year.
These thresholds are reduced by 50 percent for defects related to any
aftertreatment devices, including particulate traps, because these
components typically play such a significant role in controlling engine
emissions. For example, for an engine family with a sales volume of
20,000 units in a given model year, the manufacturer would have to
investigate potential emission-related defects if there were warranty
claims or parts shipments for replacing electronic control units in 800
or more engines; or catalytic converters on 400 or more engines. For an
engine family with sales volume of 500 units in a given model year, the
manufacturer would have to investigate potential emission-related
defects if there were warranty claims or parts shipments of electronic
control units in 40 or more engines; or catalytic converters on 20 or
more engines. Please note, manufacturers would not investigate for
emission related defects until either warranty claims or parts
shipments separately reach the investigation threshold. We recognize
that a part shipment may ultimately be associated with a particular
warranty claim in the manufacturer's database and, therefore, warranty
claims and parts shipments would not be aggregated for the purpose of
triggering the investigation threshold under this proposal.
In order to carry out an investigation to determine if there is an
emission-related defect, manufacturers would have to use available
information such as preexisting assessments of warranted parts or other
replaced parts. Manufacturers would also have to gather information by
assessing previously unexamined parts submitted with warranty claims
and replacement parts which are available or become available for
examination and analysis. If available parts are deemed too voluminous
to conduct a timely investigation, manufacturers would be permitted to
employ appropriate statistical analyses of representative data to help
draw timely conclusions regarding the existence of a defect. These
investigative activities should be summarized in the periodic reports
of recently opened or closed investigations as discussed below. It is
important to note that EPA does not regard having reached the
investigation thresholds as conclusive proof of the existence of a
defect, only that initiation of an appropriate investigation is merited
to determine whether a defect exists.
The second threshold in this proposal specifies when a manufacturer
must report that there is an emission-related defect. This threshold
involves a smaller number of engines because each potential defect has
been screened to confirm that it is an emission-related defect. In
counting engines to compare with the defect-reporting threshold, the
manufacturer would consider a single engine family and model year.
However, when a defect report is required, the manufacturer would
report all occurrences of the same defect in all engine families and
all model years which use the same part. For engines subject to this
proposal, the threshold for reporting a defect is 0.25 percent of total
production for any single engine family, or 250 defects, whichever is
less. The thresholds are reduced 50 percent for reporting defects
related to aftertreatment devices. Additionally, this proposal requires
a minimum of 5 defects before a report must be filed so that limited
isolated parts failures that occur for low volume engine families do
not require a defect report. It is important to note that while EPA
regards occurrence of the defect threshold as proof of the existence of
a reportable defect, it does not regard that occurrence as conclusive
proof that recall or other action is merited.
If the number of engines with a specific defect is found to be less
than the threshold for submitting a defect report, but information,
such as warranty claims or parts shipment data, later indicates
additional potentially defective engines, under this proposal the
information must be aggregated for the purpose of determining whether
the threshold for submitting a defect report has been met. If a
manufacturer has actual knowledge from any source that the threshold
for submitting a defect report has been met, a defect report would have
to be submitted even if the trigger for investigating has not yet been
met. For example, if manufacturers receive information from their
dealers, technical staff or other field personnel showing conclusively
that there is a recurring emission-related defect, they would have to
submit a defect report if the submission threshold is reached.
For both the investigation and reporting thresholds, Sec. 1068.501
specifies lower thresholds for very large engines. A defect in these
engines can have a much greater impact than defects in smaller engines
due to their higher g/hr emission rates and the increased likelihood
that such large engines will be used more continuously.
Under this proposal at specified times the manufacturer would also
have to report open investigations as well as recently closed
investigations that did not require a defect report. We are not
proposing a fixed time limit for manufacturers to complete their
investigations. The periodic reports required by the regulations,
however, will allow us to monitor these investigations and determine if
it is necessary or appropriate for us to take further action.
[[Page 28493]]
We are requesting comment on this approach, especially with respect
to the thresholds. Should we adopt slightly higher thresholds for
nonroad engines given their relatively small engine family sizes?
Should we focus the defect reporting requirements more on
aftertreatment defects since such defects will generally have more
significant impacts than other defects? We are also requesting comment
on whether these reporting requirements should also apply to the
current Tier 2/Tier 3 compliance program, and if so, when these
provisions should be applied.
L. Rated Power
We are proposing to add a definition of ``maximum engine power'' to
the regulations. This term would be used instead of previously
undefined terms such as ``rated power'' or ``power rating'' to specify
the applicability of the standards. The addition of this definition is
intended to allow for more objective applicability of the standards.
More specifically, we are proposing that:
Maximum engine power means the measured maximum brake power
output of an engine. The maximum engine power of an engine
configuration is the average maximum engine power of the engines
within the configuration. The maximum engine power of an engine
family is the highest maximum engine power of the engines within the
family.
Currently, since rated power and power rating are undefined, they are
determined by the engine manufacturer. This makes the applicability of
the standards too subjective and confusing. One manufacturer may choose
to define rated power as the maximum measured power output, while
another may define it as the maximum measured power at a specific
engine speed. Using this second approach, an engine's rated power may
be somewhat less than the true maximum power output of the engine.
Given the importance of engine power in defining which standards an
engine must meet and when, we believe that it is critical that a
singular power value be determined objectively according to a specific
regulatory definition.
We are also adding a clarification to the regulations recognizing
that actual engine power will vary to some degree during production.
The proposed regulations would require manufacturers to specify a range
of actual maximum engine power for each engine configuration. As noted
above, we would base the applicability of the standards on the average
maximum power of the engines.
M. Hydrocarbon Measurement and Definition
Both the existing standards and the proposed Tier 4 standards apply
to nonmethane hydrocarbons, rather than total hydrocarbons. Methane
emissions generally are considered to be nonreactive with respect to
ozone, and are not regulated under part 89. However, excluding methane
requires that it be separately measured, which complicates the
measurement procedures. While we are not proposing to change the
standards to total hydrocarbons we are requesting comment on the need
to measure methane and the appropriateness of excluding it from our
standards.
N. Auxiliary Emission Control Devices and Defeat Devices
Existing nonroad regulations prohibit the use of a defeat device
(see 40 CFR 89.107) in nonroad diesel engines. The defeat device
prohibition is intended to ensure that engine manufacturers do not use
auxiliary emission control devices (AECD) which sense engine operation
in a regulatory test procedure and as a result reduce the emission
control effectiveness \317\ of that procedure. In today's notice we are
proposing to supplement existing nonroad test procedures with a
transient engine test cycle and NTE emission standards with associated
test requirements. As such, the Agency believes that a clarification of
the existing nonroad diesel engine regulations regarding defeat devices
is required in light of these proposed additional emission test
requirements. The defeat device prohibition makes it clear that AECDs
which reduce the effectiveness of the emission control system are
defeat devices, unless one of several conditions is met. One of these
conditions is that an AECD which operates under conditions ``included
in the test procedure'' \318\ is not a defeat device. While the
existing defeat device definition does contain the term ``test
procedure'', and therefore should be interpreted as including the
supplemental testing requirements, we want to make it clear that both
the supplemental transient test cycle and NTE emission test procedures
are included within the defeat device regulations as conditions under
which an operational AECD will not be considered a defeat device.
Therefore, we are proposing to clarify the defeat device regulations by
specifying the appropriate test procedures (i.e., the existing steady-
state procedures and the supplemental tests).
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\317\ Auxiliary emission control device is defined at 40 CFR
89.2 as `` any element of design that senses temperature, vehicle
speed, engine RPM, transmission gear, or any other parameter for the
purpose of activating, modulating, delaying or deactivating the
operation of any part of the emission control system.''
\318\ 40 CFR 89.107(b)(1) states ``Defeat device includes any
auxiliary emission control device (AECD) that reduces the
effectiveness of the emission control system under conditions which
may reasonably be expected to be encountered in normal operation and
use unless such conditions are included in the test procedure.''
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We are also proposing today to provide clarification regarding the
engine manufacturers certification reporting requirements with respect
to the description of AECDs. The proposed clarification will aid engine
manufacturers in preparing a complete application for certification
which will allow EPA to review the application in a timely manner.
Under the existing nonroad engine regulations, manufacturers are
required to provide a generalized description of how the emissions
control system operates and a ``detailed'' description of each AECD
installed on the engine (See 40 CFR 89.115(d)(2)). This proposal is
intended to clarify what is meant by ``detailed.''
Under the nonroad diesel Tier 1 standards there was limited use of
AECDs. AECDs have begun to be much more common with the Tier 2
standards, and we expect this trend to continue. Engines designed to
meet the significantly more stringent Tier 4 standards will certainly
rely on sophisticated technologies that will likely employ very complex
AECDs. We have seen a similar trend with highway heavy-duty diesel
engines. In the late 1980's, few highway HDDEs had electronic controls
and most manufacturers relied on in-cylinder techniques to control
emissions. However, with the application of technologies such as
electronically controlled fuel systems, electronically controlled EGR
systems, and variable geometry turbochargers, highway HDDEs now have
numerous AECDs which are used both for performance as well as emissions
control.
A thorough disclosure of the presence and purpose of AECDs is
essential in allowing EPA to evaluate the AECD and determine whether it
represents a defeat device. Clearly, any AECD which is not fully
identified in the manufacturer's application for certification cannot
be appropriately evaluated by EPA and therefore cannot be determined to
be acceptable by EPA. Our proposed clarifications to the certification
application requirements include additional detail specific to those
AECDs which the manufacturer believes are necessary to protect the
engine or the equipment in which it is installed against damage or
accident (``engine
[[Page 28494]]
protection'' AECDs). While the definition of a defeat device allows as
an exception strategies needed to protect the engine and equipment
against damage or accident, we intend to continue our policy of closely
reviewing the use of this exception. In evaluating whether a reduction
in emissions control effectiveness is needed for engine protection, EPA
will closely evaluate the actual technology employed on the engine
family, as well as the use and availability of other emission control
technologies across the industry, taking into consideration how
widespread the use is, including its use in similar engines and similar
equipment. While we have specified additional information related to
engine protection AECDs in the proposed regulations, we reserve the
right to request additional information on a case-by-case basis as
necessary.
In the last several years, EPA has issued extensive guidance on the
disclosure of AECDs for both highway and nonroad diesel engine
manufactures.\319\ This proposal does not impose any new certification
burden on engine manufacturers, rather, it clarifies the existing
certification application regulations by specifying what type of
information manufacturers must submit regarding AECDs.
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\319\ See EPA Dear Manufacturer Letter VPCD-98-13, ``Heavy-duty
Diesel Engines Controlled by Onboard Computers: Guidance on
Reporting and Evaluating Auxiliary Emission Control Devices and the
Defeat Device Prohibition of the Clean Air Act'', October 15, 1998
and EPA Advisory Circular 24-3, ``Implementation of Requirements
Prohibiting Defeat Devices for On-Highway Heavy-Duty Diesel
Engines.'' A copy of both of these documents is available in EPA Air
Docket A-2001-28
---------------------------------------------------------------------------
Finally, we take this opportunity to emphasize that the information
submitted must be specific to each engine family. The practice of
describing AECDs in a ``common'' section, wherein the strategies are
described in general for all the manufacturer's engines, is acceptable
as long as each engine family's application contains specific
references to the AECDs in the common section which clearly indicate
which AECDs are present on that engine family, and the application
contains specific calibration information for that engine family's
AECDs. The proposed regulatory requirements can be found at 40 CFR
89.115(d)(2) in today's notice.
We are requesting comment on whether these clarifications should
also be applied to the current Tier 2/Tier 3 compliance program, and if
so, when these provisions should be applied.
O. Other Issues
We are also proposing other minor changes to the compliance program
for Tier 4 nonroad engines. For example, we are proposing that engine
manufacturers be required to provide installation instructions to
equipment manufacturers to ensure that engine cooling systems,
aftertreatment exhaust emission controls, and related sensors are
properly installed by the equipment manufacturer. Proper installation
of these systems is critical to the emission performance of the
equipment. Equipment manufacturers would be expected to follow the
instructions to avoid improper installation that could render emission
controls inoperative, and subject the equipment manufacturer to
penalties for t violation of a prohibited act.
Under the existing regulations and the proposed new regulations,
engine manufacturers are responsible for all emission-related
components, both in terms of emission performance during certification
and in-use testing, and emission-related warranties. This requires that
engine manufacturers provide their engines with the necessary emission
controls before selling them to equipment manufacturers. We are
proposing to use the same approach as is used with highway engines,
where the engine manufacturer is required to either install catalysts
or traps before selling the engine to a vehicle manufacturer, or to
ship the catalyst or trap with the engine, with appropriate
installation instructions. We are requesting comment on whether this is
appropriate for nonroad engines equipped with traps and other
aftertreatment exhaust emission controls. We are concerned that
allowing engine manufacturers to sell engines without traps included
might lead to equipment being introduced into service without the
emission controls properly installed. We are requesting comment on
whether it is sufficient to require manufacturers to fully describe in
their installation instructions all necessary emission control hardware
, and whether the engine manufacturer should be held responsible for
ensuring the aftertreatment is properly installed, including requiring
some management by the engine manufacturers of the installation
process, such as auditing the installations and reporting the results
to EPA.
In Sec. 89.109, we limit the amount of maintenance that
manufacturers can perform during service accumulation. We are proposing
to continue these limits in the proposed new Sec. 1039.125. However,
we are not carrying over the provisions of Sec. 89.109(h)(2) (iii) and
(iv) that are related to allowances for additional maintenance for
engines equipped with onboard diagnostic systems that include visible
warning lights. We believe that these provisions would be better
addressed in a rulemaking addressing onboard diagnostic standards.
Both the existing regulations and the proposed regulations specify
default criteria to define engine family groups, but allow exceptions
for cases where other groups would more appropriately represent similar
emission characteristics. The proposed regulations specify the same
criteria as part 89, plus two new criteria. We are proposing that
mechanically controlled engines and electronically controlled engines
generally be certified in separate engine families. We are also
proposing that engines in different power categories generally must be
in separate engine families.
We are proposing to clarify the applicability of the nonroad CI
standards to engines operating on alcohols and other oxygenated fuels.
As part of this, we are proposing to add a requirement that
compression-ignition alcohol-fueled engines be required to comply with
the evaporative emission control requirements in 40 CFR 1048.105. That
section allows manufacturers to comply with the requirement by
incorporating simple emission controls. This requirement is not
expected to have a significant impact on manufacturers since we are not
aware of any alcohol-fueled nonroad engines currently in production.
The proposed provision is merely intended to prevent new emission
problem from occurring in the future.
We are proposing to change the way in which manufacturers specify
deterioration factors (DFs) for Tier 4 trap-equipped engines. The
current regulations specify that the DFs for engines with
aftertreatment devices must be multiplicative. They must be expressed
as a proportion of the engine's initial emission rate. Manufacturers
have indicated in past discussions that, given the general operating
mechanism of PM traps and the very low PM levels emitted, trap
deterioration is not expected to depend on the initial emission rate,
as increased emissions from deterioration that tend to be non-sulfate
PM, and therefore not related to the initial emissions rate. Therefore,
we are proposing to specify additive DFs for PM that account for a
fixed amount of deterioration and are independent of the engine's
initial emission rate.
[[Page 28495]]
We are proposing to extend to CI engines that operate on unrefined
natural gas the same provisions we have adopted for similar SI engines.
Such engines are sometimes used to operate pumps at oil fields where
unrefined natural gas is a readily available and inexpensive fuel
source. This provision would allows manufacturers greater flexibility
with respect to engine adjustment to address variability in fuel
properties.
In addition, we are proposing to require that manufacturers label
uncertified engines that they import for stationary applications.
Because these engines look the same as or very similar to regulated
nonroad engines, it can be difficult to distinguish the two without
labels. These labels will also help manufacturers and others who import
these engines to avoid potential problems with customs inspections.
Another labeling issue relates to the primary emission control
information label that engine manufacturers put on every certified
engine they produce. The current regulations require equipment
manufacturers to put a duplicate label on the equipment if the engine
is installed in a way that obscures the label on the engine. We are
proposing to clarify this requirement for duplicate labels to ensure
that labels are accessible without creating a supply of duplicate
labels that are not authentic and used appropriately. Specifically, we
are proposing to require engine manufacturers to supply duplicate
labels to equipment manufacturers that request them and keep records to
show how many labels they supply. Similarly, we are proposing to
require equipment manufacturers to request from engine manufacturers a
specific number of duplicate labels, with a description of which engine
and equipment models are involved and why the duplicate labels are
necessary. Equipment manufacturers would need to destroy any excess
labels and keep records to show the disposition of all the labels they
receive. We request comment on these provisions. In addition, we
request comment on an alternative approach to labeling equipment. If
equipment manufacturers were required to add a label to each piece of
equipment with basic information related to the engine's emission
controls, the information would be most accessible in all situations.
Such a label would need to at least identify the engine manufacturer,
engine family and serial number, manufactured date, power rating, and
any important engine specifications. This would make it easier for us
to verify that engines are meeting requirements and it would be easier
for U.S. Customs (Bureau of Customs and Border Protection) to clear
imported equipment with certified engines. Note that some equipment
manufacturers have already been voluntarily attaching such labels or
plates to their equipment. We request comment on a uniform requirement
to apply labels to equipment using nonroad diesel engines to uniquely
identify the installed engine.
We are also clarifying the general requirement that all engines
subject to this final rule may not cause or contribute to an
unreasonable risk to public health, welfare, or safety, especially with
respect to noxious or toxic emissions that may increase as a result of
emission-control technologies. The proposed regulatory language, which
addresses the same general concept as the existing Sec. 89.106,
implements sections 202(a)(4) and 206(a)(3) of the Act and clarifies
that the purpose of this requirement is to prevent control technologies
that would cause unreasonable risks, rather than to prevent trace
emissions of any noxious compounds. This requirement prevents the use
of emission-control technologies that produce high levels of pollutants
for which we have not set emission standards, but nevertheless pose a
risk to the public.
In the part 89 regulations we use the same definition for
``aircraft'' as is used in 40 CFR part 87. The definition, which is
used to exclude aircraft engines from the part 89 regulations, states
that aircraft means ``any airplane a U.S. airworthiness certificate or
equivalent foreign airworthiness certificate has is issued.'' We are
proposing to use this same definition for the new part 1039
regulations. We believe that this definition encompasses all vehicles
that are capable of sustained air travel above treetop heights using
compression ignition engines. We request comment on whether there are
any aircraft that do not meet this definition, and use compression-
ignition engines, but that should not be regulated under part 1039.
Finally, we are not revising at this time the regulation on
preemption of state and local controls currently found in Part 89. This
regulation will continue in effect. We are, however, considering
whether we should clarify the binding regulatory nature of this
language, consistent with the decision of the court in Engine
Manufacturers Association v. EPA, 88 F.3d 1075 (D.C. Cir. 1996).
VIII. Nonroad Diesel Fuel Program: Compliance and Enforcement
Provisions
Section IV above describes the proposed program for the reduction
of sulfur in nonroad, locomotive and marine (NRLM) diesel fuel. In
general, this proposal would require refiners and importers to meet a
500 ppm sulfur standard for nonroad, locomotive, and marine diesel fuel
starting June 1, 2007 and to meet a 15 ppm standard for nonroad diesel
fuel beginning June 1, 2010. Locomotive and marine diesel fuel would
remain subject to the 500 ppm standard. Among other provisions, Section
IV also describes a temporary non-highway distillate baseline
percentage method to differentiate volumes of diesel fuel subject to
the NRLM standards and volumes of diesel fuel subject to the highway
fuel standards; provisions to identify unregulated fuel such as heating
oil; provisions for diesel fuel credit generation and use; and special
provisions for small refiners, refiners seeking hardship relief, and
parties supplying diesel fuel to Alaska and U.S. territories.
As with earlier fuel programs, we have developed a comprehensive
set of compliance and enforcement provisions designed to promote
effective and efficient implementation of this fuel program and thus to
achieve the full environmental potential of the program. The proposed
compliance provisions are designed to ensure that nonroad, locomotive,
and marine diesel fuel sulfur content requirements are met throughout
the distribution system, from the refiner or importer through the end
user, subject to certain provisions applicable during the early
transition years. Several of these provisions are described in Section
IV above, and others are summarized in this section. The full details
of all proposed provisions are found in the regulatory language
associated with today's notice.
The proposed compliance and enforcement provisions discussed in
this section fall into several broad categories:
[sbull] Fuel uses covered and not covered under the proposed
program;
[sbull] Provisions not described in Section IV applicable to
refiners and importers;
[sbull] Provisions not described in Section IV applicable to
parties downstream of the refinery or importer;
[sbull] Special provisions regarding additives, kerosene, and the
use of motor oil in fuel;
[sbull] Fuel testing and sampling requirements;
[sbull] Records required to be kept (including those applying under
the
[[Page 28496]]
small refiner and refiner hardship provisions);
[sbull] Reporting requirements;
[sbull] Exemptions from the program; and
[sbull] Provisions concerning liability, defenses, and penalties
for noncompliance.
A. Fuel Covered and Not Covered by this Proposal
1. Covered Fuel
As discussed in section IV.A.1 above, this proposed standards
generally cover all the diesel fuel that is intended or likely to be
used in nonroad, locomotive, and marine (NRLM) applications that is not
already covered by the standards for highway diesel fuel. For the
purposes of this preamble, this fuel is defined primarily by the type
of engine which it is used to power: land-based nonroad, locomotive,
and marine diesel engines.
2. Special Fuel Provisions and Exemptions
Section IV.A.1 above also describes several types of petroleum
distillate that are not covered by this proposal, including jet fuel
and heating oil. In addition, the next paragraphs discuss several
provisions and exemptions for nonroad diesel fuel that we propose to
apply in special circumstances.
a. Fuel Used in Military Applications
We propose to treat NRLM diesel fuel used in military applications
in the same manner as the recent highway diesel rule. We propose to
define NRLM diesel fuel so that JP-5 and JP-8 military fuel that is
used or intended for use in NRLM diesel engines would be subject to all
of the requirements applicable to NRLM diesel fuel. However, we also
propose to exempt JP-5 and JP-8 fuels from the proposed diesel fuel
content and other requirements in certain circumstances. First, these
fuels would be exempt if they were used in tactical military equipment
that have a national security exemption. Due to national security
considerations, EPA's existing regulations allow the military to
request and receive national security exemptions (NSE) for their NRLM
diesel engines from emissions regulations if the operational
requirements for such engines warrant such an exemption. This proposal
would not change these provisions. Second, these fuels would also be
exempt if they were used in tactical military equipment that is not
covered by a national security exemption but for national security
reasons, needs to be fueled on the same fuel as motor vehicles or
nonroad equipment with a national security exemption such as the need
to be ready for immediate deployment overseas. Use of JP-5 and JP-8
fuel not meeting the proposed NRLM diesel fuel standards in a NRLM
diesel engine other than the tactical military equipment described
above would be prohibited under today's rule.
EPA and the Department of Defense will develop a process to address
the tactical nonroad equipment to be covered by the diesel fuel
exemption. Based on data provided by the Department of Defense to date
in the context of implementing a similar exemption provision in the
highway program, EPA believes that providing an exemption for JP-5 and
JP-8 fuel used in tactical nonroad equipment would not have any
significant environmental impact.
b. Fuel Used in Research and Development
This proposed rule would permit parties to request an exemption
from the sulfur or other standards for NRLM diesel fuel used for
research, development and testing purposes (``R & D exemption''). We
recognize that there may be legitimate research programs that require
the use of diesel fuel with higher sulfur levels than allowed under
this proposed rule. As a result, this proposal contains provisions for
obtaining an exemption from the prohibitions for persons distributing,
transporting, storing, selling, or dispensing NRLM diesel fuel that
exceeds the standards, where such diesel fuel is necessary to conduct a
research, development, or testing program.
Under the proposed rule, parties seeking an R & D exemption would
be required to submit an application for exemption to EPA that
describes the purpose and scope of the program, and the reasons why
higher-sulfur diesel fuel is necessary. Upon presentation of the
required information, an exemption could be granted at the discretion
of the Administrator, with the condition that EPA could withdraw the
exemption in the event the Agency determines the exemption is not
justified. In addition, an exemption based on false or inaccurate
information could be considered void ab initio. Fuel subject to an
exemption would be exempt from certain provisions of this proposed
rule, including the sulfur standards, provided certain requirements are
met. These requirements include the segregation of the exempt fuel from
non-exempt NRLM and highway diesel fuel, identification of the exempt
fuel on product transfer documents, pump labeling, and where
appropriate, the replacement, repair, or removal from service of
emission systems damaged by the use of the high sulfur fuel.
c. Fuel Used in Racing Equipment
This proposed rule would provide no exemption from the sulfur or
other content standard and other requirements of the proposal for
diesel fuel used in racing. Under certain conditions, racing vehicles
would not be considered nonroad vehicles. See, for example, 40 CFR
89.2, definition of ``nonroad vehicle''. The fuel used by such racing
vehicles would not necessarily be considered nonroad diesel fuel.
However, we believe that there is a realistic chance that such fuel
also could be used in NRLM equipment, and therefore, should be
considered NRLM diesel fuel. During the highway diesel rulemaking, we
received no comments supporting the need for an exemption for racing
fuel. We are not aware of any advantage for racing vehicles or racing
equipment to use fuel having higher sulfur levels than are required by
this proposed rule, and we are concerned about the potential for
misfueling of nonroad equipment and motor vehicles that could result
from having a high sulfur (e.g., 3,400 ppm) fuel for vehicle or nonroad
equipment available in the marketplace. Consequently, as was the case
with the highway diesel rule, this proposal does not provide an
exemption from the nonroad diesel fuel requirements for fuel used in
racing vehicles or equipment.
d. Fuel for Export
Fuel produced for export, and that is actually exported for use in
a foreign country, would be exempt from the fuel content standards and
other requirements of this proposed rule, such as the non-highway
baseline provisions. Such fuel would be considered as intended for use
in the U.S. and subject to the proposed standards unless it was
designated by the refiner as for export only and product transfer
documents stated that the fuel was for export only. Fuel intended for
export would need to be segregated from all fuel intended for use in
the U.S., and distributing or dispensing such fuel for domestic use
would be illegal.
B. Additional Requirements for Refiners and Importers
The primary requirements proposed today for refiners and importers
are discussed in Section IV above. In that section, we discuss the
general structure of the compliance and enforcement provisions
applicable to refiners and importers, including fuel content standards,
baseline provisions, and credit provisions. In this subsection, we
discuss several additional requirements
[[Page 28497]]
for refiners and importers that are not addressed in Section IV. In
addition, Sections VIII.D, E, and F below discuss several provisions
that apply to all parties in the diesel fuel production and
distribution system, including refiners and importers.
1. Transfer of Credits
This proposal includes provisions for diesel sulfur credit
transfers that are essentially identical to other fuels rules that have
credits provisions. As in other fuels rules, nonroad diesel sulfur
credits could only be transferred between the refiner or importer
generating the credits and the refiner or importer using the credits.
If a credit purchaser could not use all the credits it purchased from
the refiner who generated them, the credits could be transferred one
additional time. We recognize that there is potential for credits to be
generated by one party and subsequently purchased and used in good
faith by another party, where the credits are later found to have been
calculated or created improperly, or otherwise found to be invalid. As
with the reformulated gasoline rule, the Tier 2/Gasoline Sulfur rule,
and the highway diesel rule, invalid credits purchased in good faith
would not be valid for use by the purchaser. To allow such use would
not be consistent with the environmental goals of the regulation. In
addition, both the seller and purchaser of invalid credits would have
to adjust their credit calculations to reflect the proper credits and
either party (or both) could be deemed in violation if the adjusted
calculations demonstrated noncompliance. The parties to such a credit
transaction can be expected to develop contractual provisions to
address these circumstances.
Nevertheless, in a situation where invalid credits are transferred,
our strong preference would be to hold the credit seller liable for the
violation, rather than the credit purchaser. As a general matter we
would expect to enforce a shortfall in credit compliance calculations
against the credit seller, and we would expect to enforce a compliance
shortfall (caused by the good faith purchase of invalid credits)
against a good faith purchaser only in cases where we are unable to
recover sufficient valid credits from the seller to cover the
shortfall. Moreover, in settlement of such cases we would strongly
encourage the seller to purchase credits to cover the good faith
purchaser's credit shortfall. EPA would consider the covering of a
credit deficit through the purchase of valid credits a very important
factor in mitigation of any case against a good faith purchaser,
whether the purchase of valid credits is made by the seller or by the
purchaser.
2. Additional Provisions for Importers and Foreign Refiners Subject to
the Credit Provisions or Hardship Provisions
Since this proposed rule includes several compliance options that
could be used by NRLM diesel fuel importers and foreign refiners, we
are also proposing specific compliance and enforcement provisions to
ensure compliance for imported NRLM diesel fuel. These additional
foreign refiner provisions are similar to those under the conventional
gasoline regulations, the gasoline sulfur regulations and the highway
diesel fuel regulations (see 40 CFR 80.94, 80.410 and 80.620).
Under this proposal, standards for NRLM diesel fuel produced by
refineries owned by foreign refiners must be met by the importer,
unless the foreign refiner has been approved to produce NRLM diesel
fuel under the credit provisions, small refiner provisions or hardship
provisions of this proposal. If the foreign refiner is approved under
any of these provisions, the volume requirements would be met by the
foreign refiner's refinery(s) and the foreign refinery(s) would be the
entity(s) generating, using, banking or trading credits for the NRLM
diesel fuel produced for and imported into the U.S. We are proposing
that importers themselves not be eligible for small refiner or hardship
relief. Importers may participate in the proposed credit programs;
however, an importer and a foreign refiner may not generate credits for
the same fuel.
Any foreign refiner that applies for and obtains approval to
produce NRLM diesel fuel subject to credit provisions, small refiner
provisions or the hardship provisions would be subject to the same
requirements as domestic refiners operating under the same provisions.
Additionally, we are proposing provisions for foreign refiners similar
to the provisions at 40 CFR 80.94, 80.410, and 80.620, which include:
[sbull] Segregation of NRLM diesel fuel produced at the foreign
refinery until it reaches the U.S. and separate tracking of volumes
imported into each PADD;
[sbull] Controls on product designation;
[sbull] Load port and port of entry testing; and
[sbull] Requirements regarding bonds and sovereign immunity.
These provisions would aid the Agency in tracking NRLM diesel fuel
from the foreign refinery to its point of import into this country. We
believe these provisions would be necessary and sufficient to ensure
that foreign refiners' compliance could be monitored and that the
proposed diesel fuel requirements could be enforced against foreign
refiners. For more discussion of the rationale for these enforcement
provisions, see preamble to the final Anti-Dumping Foreign Refiners
rule (see 62 FR 45533, Aug. 28, 1997) and the gasoline sulfur rule (see
65 FR 6698, February 10, 2000).
3. Proposed Provisions for Transmix Facilities
In the petroleum products distribution system, certain types of
interface mixtures in product pipelines cannot be added in any
significant quantity to either of the adjoining products that produced
the interface. These mixtures are known as ``transmix.'' The pipeline
and terminal industry's practice is to transport transmix via truck,
pipeline, or barge to a facility with an on-site fractionator that is
designed to separate the products. The owner or operator of such a
facility is called a ``transmix processor.'' Such entities are
generally considered to be a refiner under existing EPA fuel
regulations.
Under the non-highway baseline percentage approach proposed in
today's diesel rule, absent special treatment transmix processors that
wished to commingle highway and NRLM fuel would need to comply with the
baseline percentage requirements. Transmix processors, as with
conventional refiners, are also currently subject to the ``80 percent/
20 percent'' production requirements for 15 ppm and 500 ppm highway
diesel fuel. In both of these cases, producing fuel in set percentages
appears to be inconsistent with the inherent nature of the transmix
processors' business. Unlike conventional refiners, transmix processors
refine shipments of fuel that vary in volume and timing--largely
unpredictably. Complying with set percentages of different highway and
NRLM sulfur grades would be very difficult, probably resulting in
either a need to purchase credits or to postpone processing of some
shipments.
In light of this disproportionate burden on transmix processors, we
propose that transmix processors could choose to not be covered by both
the proposed non-highway baseline provision and the TCO provisions for
highway diesel fuel. This would only be an option for diesel fuel
produced according to typical operational practices involving
separation of transmix and not, for example, diesel fuel produced due
to the blending of blend stocks. If the processor chooses not to be
covered by these provisions,
[[Page 28498]]
then the processor could produce highway or NRLM diesel fuel without
these limits on production or percentages. For example, the processor
could choose whether to produce 15 ppm highway, 500 ppm highway, 500
ppm NRLM, or 15 ppm NR in any proportions, during the time periods when
the non-highway baseline volume percentage or the highway TCO are
applicable. We are concerned that to discourage abuse, some reasonable
limit on a transmix processor's production volume that could be
exempted from the requirements may be necessary. Thus, we propose to
limit it to 105% of its 2003-2005 average production but seek comment
on whether additional flexibility is warranted.
The processor would still need to properly designate its fuel with
the proper product transfer documents and, in the case of heating oil
between 2007 and 2014 and locomotive and marine fuel between 2010 and
2014, to apply the specified marker and comply with other reporting and
recordkeeping requirements applicable to refiners. A processor choosing
this approach would not be eligible to generate or use NRLM or highway
sulfur credits.
Because the volume of fuel involved would be small and the fuel
processed would already have been ``off-spec,'' we believe that
providing these options for transmix processors would have essentially
no environmental impact and would not affect the efficient functioning
of the proposed program or the existing highway diesel program. Rather,
these options would allow fuel volume to remain in the highway and/or
NRLM markets that might otherwise be forced into the heating oil
market.
4. Highway or Nonroad Diesel Fuel Treated as Blendstock (DTAB)
Under the proposed program, a situation could arise for importers
where that was expected to comply with the 15 ppm NR or highway
standard is found to be slightly higher in sulfur than the standard.
Rather than require that importer to account for, and report, that fuel
as 500 ppm fuel, we propose to allow the importer to designate the non-
complying fuel as blendstock--``diesel fuel treated as blendstock'' or
DTAB--rather than as either highway or nonroad diesel fuel. In its
capacity as a refiner, the party could blend this DTAB fuel with lower
sulfur diesel fuel to cause the sulfur level of the combined product to
meet the 15 ppm nonroad or highway standard.
Where previously certified diesel fuel is used to reduce the sulfur
level of the DTAB to 15 ppm or less, the party, in its refiner
capacity, would report only the volume of the imported DTAB as the
amount of diesel fuel produced. This avoids the double counting that
would result if the same diesel fuel is reported twice. If the product
that is blended with the DTAB is not previously certified diesel fuel,
but is also blendstock, the total combined volume of the DTAB and other
blendstock would constitute the batch produced.
When an importer classifies diesel fuel as DTAB, that DTAB would
not count toward the importer's calculations under the highway diesel
rule's temporary compliance option, toward credit generation or use, or
for compliance calculations under the non-highway baseline
approach.\320\ The same party, however, would include the DTAB in such
calculations in its capacity as refiner. We believe such an approach
would increase the supply of 15 ppm fuel by reducing the volume of
near-compliant fuel that is downgraded to higher sulfur designations.
In essence, it allows importers the same flexibility that refiners have
within their refinery gate.
---------------------------------------------------------------------------
\320\ Importer/refiners availing themselves of the DTAB
provisions would still be subject to the non-highway distillate
baseline provisions, downgrading provisions, and other provisions
applicable to any importer or refiner.
---------------------------------------------------------------------------
C. Requirements for Parties Downstream of the Refinery or Import
Facility
In order for the environmental benefits of the proposed program to
be ensured, parties in the fuel distribution system downstream of the
refinery (including pipelines, terminals, bulk plants, wholesale
purchaser-consumers, and retailers) must in most cases keep the various
grades of fuel in the system separate. Owners and operators of nonroad
diesel equipment must also be required in certain circumstances to use
fuels meeting specific sulfur content standards. The following
paragraphs discuss several provisions that we propose to apply to these
parties: segregation of various fuel sulfur grades; diesel fuel pump
labeling; use of used motor oil in diesel fuel; use of kerosene in
diesel fuel; use of additives in diesel fuel; requirements for end
users; and provisions covering downgrading of undyed diesel fuel to
different grades of fuel. These provisions are analogous to similar
provisions that apply to highway diesel fuel under the highway program.
1. Product Segregation and Contamination
This subsection discusses the various grades and uses of NRLM fuel
under the proposed program and when these fuel grades must be
segregated from each other. In later subsections, we discuss related
requirements for product transfer documents to identify fuels
throughout the distribution system and provisions relating to the
liability all parties in the distribution face for preventing
contamination of these different fuel sulfur grades.
a. The Period From June 1, 2007 through May 31, 2010
Starting June 1, 2007, NRLM fuel having a sulfur content exceeding
500 ppm that is produced or imported under the credit, small refiner,
or hardship provisions would need to be segregated from other NRLM fuel
subject to the 500 ppm standard, until the point where IRS dye is
added. After that point the 500 ppm NRLM fuel could be mixed with NRLM
small refiner, hardship or credit fuel, but could not be mixed with
heating oil without changing the designation to heating oil. However,
during this period there would also be nonroad equipment equipped with
engines subject to emission standards, where some of this equipment is
expected to be equipped with sulfur sensitive technology that needs to
operate on 500 ppm or less sulfur fuel in order to meet the proposed
emission standards in-use. Fuels sold for use in, or dispensed into,
these engines would need to be identified as meeting the 15 ppm
standard or the 500 ppm standard, as applicable, and if so identified
it would need to meet such standard, and avoid being contaminated with
higher sulfur fuels.
We are proposing an additional segregation requirement for heating
oil. As provided in Section IV of the preamble, such fuel would be
required to be identified by a marker and segregated throughout the
distribution system to the end user. It could not be used as nonroad,
locomotive or marine fuel but could only be used as heating oil. NRLM
fuel could, however, be used as heating oil. To be able to effectively
enforce the segregation of heating oil, we are proposing that heating
oil be marked by the refiner or importer by the addition of 6 mg/L of
solvent yellow 124.
b. The Period From June 1, 2010 through May 31, 2014
Because of the extreme sulfur sensitivity of the expected engine
emission control systems beginning in model year 2011 for nonroad
diesel engines, it would be imperative that the distribution system
segregate nonroad diesel fuel subject to the 15 ppm sulfur standard
from higher sulfur distillate products, such as 500 ppm diesel fuel
produced by small refiners or through the use of credits, heating oil,
and jet fuel.
[[Page 28499]]
We are also concerned about potential misfueling of engines
requiring 15 ppm fuel at retail or wholesale purchaser-consumer
facilities as defined under this proposal, or other end-user
facilities, even when segregation of 15 ppm fuel from the higher-sulfur
grades of diesel fuel has been maintained in the distribution system.
Thus, downstream compliance and enforcement provisions of the proposed
rule are aimed at both preventing contamination of nonroad diesel fuel
subject to the 15 ppm sulfur standard and preventing misfueling of new
nonroad equipment.
As proposed in Section IV above, small refiners would be able to
continue to produce 500 ppm nonroad fuel, until June 1, 2014. Other
refiners could also produce fuel under the 500 ppm nonroad standard,
through the use of credits, but only until June 1, 2012. In either
case, we are proposing that during this period the 500 ppm fuel must be
segregated from 15 ppm nonroad fuel throughout the distribution system,
including the end user. We are also proposing that refiners and
importers wishing to distribute 500 ppm nonroad diesel fuel during this
period be required to petition the Agency for approval of a plan
demonstrating the segregation of such fuel. The plan would also be
required to include a quality assurance program that would ensure that
the 500 ppm fuel would not cause fuel subject to the 15 ppm standard to
be contaminated, and to ensure that model year 2011 and later nonroad
diesel engines would not be misfueled.
As discussed in section IV above, we propose that during this
period, locomotive and marine fuel be segregated using the same marker
as was used for heating oil before June 1, 2010. During this time,
heating oil would not be marked but would be segregated based on its
sulfur content, since no other fuel could exceed 500 ppm.
c. After May 31, 2014
After all regulatory flexibilities have expired, the three
remaining fuels (15 ppm highway and nonroad fuel, 500 ppm locomotive
and marine fuel, and heating oil) would be segregated based on their
sulfur content and identifying information on product transfer
documents.
2. Diesel Fuel Pump Labeling To Discourage Misfueling
For any multiple-fuel program like the two-step program proposed
today, we believe that the clear labeling of nonroad diesel fuel pumps
would be vital so that end users could readily distinguish between the
several grades of fuel that may be available at fueling facilities, and
properly fuel their nonroad equipment. Section VII above describes the
labels that manufacturers would be required to place on model year 2011
and later nonroad equipment, and information that would be provided to
nonroad equipment owners. Today's proposal includes requirements for
labeling fuel pump stands at retail facilities, including bulk plants
or portable fuel storage facilities used as a fueling facility, and
wholesale purchaser-consumer facilities.
To help prevent misfueling of nonroad, locomotive and marine
engines, and to thus assure the environmental benefits of the program
are realized, we are proposing pump labeling requirements similar to
those adopted in the highway diesel rule (40 CFR 80.570). These labels
would apply to diesel fuel dyed for tax purposes, and thus generally
could not be used in highway vehicles. The proposed fuel pump dispenser
labeling requirements would supersede the non-highway labeling
requirement established by the highway diesel rule on June 1, 2007.
These pump dispenser labeling requirements are discussed separately for
each of four time periods: Beginning June 1, 2006, June 1, 2007-August
31, 2010; September 1, 2010-August 31, 2014; and September 1, 2014
forward.
We are also proposing to amend the pump dispenser labeling language
in the highway diesel regulations for consistency with this proposal.
Because the highway diesel rule prohibits highway diesel fuel with
sulfur levels above 500 ppm, the highway diesel rule and this proposal
have different meanings for the terms ``low sulfur'' and ``high
sulfur'', and the highway diesel rule does not use the term ``ultra
low-sulfur.'' Further, because the highway diesel rule did not need to
categorize the different uses of non-highway diesel fuel, the highway
diesel rule and this proposal have different meanings for the term
``nonroad''.\321\ The proposed amendments to the highway pump dispenser
labeling language are to avoid confusion at the fuel pumps caused by
labels with terms that would otherwise have different meanings
depending on whether the pump dispenser is designated to dispense
highway or non-highway diesel fuel. We are also proposing to add
effective dates to each paragraph of the labeling provisions of the
highway diesel rule for consistency with the additional pump labeling
sections of this proposal, and to distinguish the non-highway labeling
requirement effective June 1, 2006 under the highway diesel rule from
the non-highway labeling requirements of this proposal effective 2007.
---------------------------------------------------------------------------
\321\ In the highway diesel rule, the term ``high-sulfur'' means
diesel fuel with a sulfur level greater than 15 ppm, whereas in this
proposal it means diesel fuel with a sulfur level greater than 500
ppm. In the highway diesel rule, the term ``low-sulfur'' means
diesel fuel with a sulfur level of no greater than 15 ppm, whereas
in this proposal it means diesel fuel with a sulfur level of no
greater than 500 ppm. In addition, the term ``nonroad'' as used in
the highway diesel rule means ``non-highway'' (i.e., all fuel that
is not highway fuel), but the term ``nonroad'' as used in this
proposal excludes locomotive diesel, marine diesel and heating oil.
---------------------------------------------------------------------------
a. Pump Labeling Requirements for 2006
We propose to amend the pump dispenser labeling language of the
highway diesel rule for consistency with this proposal, and to avoid
confusion at the fuel pumps caused by labels with terms that would
otherwise have different meanings depending on whether the pump
dispenser is dispensing highway or non-highway diesel fuel.
For pumps dispensing highway diesel fuel subject to the 500 ppm
sulfur standard of Sec. 80.520(c), we propose that the label read as
follows:
LOW-SULFUR HIGHWAY DIESEL FUEL (500 ppm Maximum)
WARNING
May damage model year 2007 and later highway vehicles and engines.
Federal Law prohibits use in these vehicles
For pumps dispensing highway diesel fuel subject to the 15 ppm
sulfur standard of Sec. 80.520(a)(1), we propose that the label read
as follows:
ULTRA LOW-SULFUR HIGHWAY DIESEL FUEL (15 ppm Maximum)
Recommended for use in all diesel vehicles and engines.
Required for model year 2007 and later highway diesel vehicles and
engines.
For pumps dispensing diesel fuel for non-highway equipment that
does not meet the standards for motor vehicle diesel fuel, we propose
that the label read as follows:
NON-HIGHWAY DIESEL FUEL (May Exceed 500 ppm Sulfur)
WARNING
May damage or destroy highway engines and their emission controls.
Federal Law prohibits use in any highway vehicle or engine
b. Pump Labeling Requirements for 2007-2010
As discussed in section IV of the preamble, between June 1, 2007
and August 31, 2010, this proposal would
[[Page 28500]]
not require end users to dispense fuel meeting the 500 ppm sulfur
standard into nonroad, equipment, locomotives or marine vessels. During
this time period, small refiner fuel and fuel produced under the credit
provisions with sulfur levels exceeding 500 ppm would still exist in
the distribution system. Furthermore, this fuel could be mixed
downstream at the point where the fuels are dyed for IRS tax purposes
with fuel meeting the 500 ppm standard and introduced into nonroad,
locomotive and marine engines. During this time period, there would
also be nonroad equipment with engines subject to ``pull-ahead''
emission standards (i.e., engines equipped with emission controls that
allow them to meet standards earlier than required). Some of this pull-
ahead equipment is expected to be equipped with sulfur sensitive
technology that would need to operate on fuel of 500 ppm or less sulfur
in order to meet the proposed emission standards in-use. For this
reason, it is important that NRLM end users be able to know the sulfur
level of the fuel they are purchasing and dispensing. Therefore, fuel
pump dispensers for the various sulfur grades would also need to be
properly labeled.
For pumps dispensing 500 ppm (maximum) sulfur content diesel fuel
for nonroad equipment engines subject to pull-ahead standards, we
propose that the label read as follows:
LOW-SULFUR NON-HIGHWAY DIESEL FUEL
(500 ppm Maximum)
WARNING
Not for Use In Highway Vehicles or Engines
It is also likely that prior to June 1, 2010 some 15 ppm (maximum)
diesel fuel will be introduced into the nonroad market early. Both the
engine and fuel credit provisions envision such early introduction of
2011-compliant engines and 15 ppm fuel. Thus, it is important that
nonroad end users be able to know when they are purchasing diesel fuel
with 15 ppm or less sulfur. For pumps dispensing 15 ppm (maximum)
sulfur content diesel fuel for nonroad equipment engines subject to
pull-ahead standards, we propose that the label read as follows:
ULTRA-LOW SULFUR NON-HIGHWAY DIESEL FUEL
(15 ppm Maximum)
Required for All Model Year 2011 and Newer Nonroad Diesel Engines
Recommended for Use in All Nonroad, Locomotive and Marine Diesel
Engines
WARNING
Not for Use in Highway Vehicles or Engines
For all other nonroad equipment, locomotive, and marine engine
diesel fuel pumps (that is, pumps dispensing diesel fuel having a
sulfur content greater than 500 ppm) we propose that the label read as
follows:
HIGH-SULFUR NON-HIGHWAY DIESEL FUEL
(May Exceed 500 ppm)
WARNING
Not for Use In Highway Vehicles or Engines
Not for Use in Nonroad, Locomotive, or Marine Engines after August 31,
2010
May Damage Engines Certified for Use on Low-Sulfur or Ultra-Low Sulfur
Diesel Fuel
During this time period, as discussed in section IV.B.2.b, it would
be necessary to segregate heating oil from nonroad, locomotive and
marine diesel fuel to avoid circumventing the intent of the first step
of the proposed nonroad standards--that PM and SO3 benefits
be achieved by producing fuel to the NRLM diesel fuel standards in an
amount that fully corresponds to the amount of fuel used in these
engines. Consequently, for pumps dispensing non-highway diesel fuel for
use other than in nonroad, locomotive or marine engines, such as for
use in stationary diesel engines or as heating oil, we propose that the
label read as follows:
HEATING OIL (May Exceed 500 ppm Sulfur)
WARNING
Federal Law Prohibits Use in Highway Vehicles or Engines, or in
Nonroad, Locomotive, or Marine Engines
May Damage Engines Certified for Use on Low-Sulfur or Ultra-Low Sulfur
Diesel Fuel
c. Pump Labeling Requirements for 2010-2014
Beginning September 1, 2010, with certain exceptions, all fuel
introduced into any nonroad engine, regardless of year of manufacture,
would be required to meet the 15 ppm standard. The exceptions are that
segregated small refiner nonroad diesel fuel and credit nonroad diesel
fuel would be allowed to meet the 500 ppm sulfur standard only for use
in pre-model year 2011 engines. This limited use of 500 ppm fuel would
continue through August 31, 2014,\322\ after which all nonroad fuel
would have to meet the 15 ppm standard. Fuel for use in locomotive and
marine engines would be required to meet the 500 ppm standard without
exception. As discussed in section IV.B.3.b, during this time period,
it would be necessary to segregate the 500 ppm (maximum) locomotive and
marine diesel fuel from the small refiner and credit 500 ppm (maximum)
nonroad diesel fuel to ensure an adequate supply of ultra low-sulfur
(15 ppm maximum) nonroad diesel fuel for nonroad purposes.
---------------------------------------------------------------------------
\322\ Production of 500 ppm fuel under the credit provisions
would be allowed until June 1, 2012, but small refiner fuel subject
to the 500 ppm standard could continue to be produced until June 1,
2014 and would be available to end users until September 1, 2014.
---------------------------------------------------------------------------
For pumps dispensing 15 ppm (maximum) sulfur content nonroad diesel
fuel, we propose that the label read as follows:
ULTRA-LOW SULFUR NON-HIGHWAY DIESEL FUEL
(15 ppm Maximum)
Required for all Model Year 2011 and Newer Nonroad Diesel Engines
Recommended for Use in All Nonroad, Locomotive and Marine Diesel
Engines
WARNING
Not for Use in Highway Vehicles or Engines
For pumps dispensing segregated small refiner or credit 500 ppm
(maximum) nonroad diesel fuel, as discussed in section IV.B.3.b, we
propose that the label read as follows:
LOW-SULFUR NON-HIGHWAY DIESEL FUEL
(500 ppm Maximum)
WARNING
May Damage Model Year 2011 and Newer Nonroad Engines
Federal Law Prohibits Use in All Model Year 2011 and Newer Nonroad
Engines
Not for Use In Highway Vehicles or Engines
For pumps dispensing marked 500 ppm sulfur (maximum) locomotive and
marine diesel fuel, as discussed in section IV.B.3.b, we propose that
the label read as follows:
[[Page 28501]]
LOW-SULFUR LOCOMOTIVE OR MARINE DIESEL FUEL
(500 ppm Maximum)
WARNING
Federal Law Prohibits Use in Other Nonroad Engines or in Highway
Vehicles or Engines
May Damage Model Year 2007 and Newer Highway Diesel Engines and 2011
and Newer Nonroad Diesel Engines
For pumps dispensing high-sulfur fuel for use as heating oil, we
propose that the label read as follows:
HEATING OIL (May Exceed 500 ppm Sulfur)
WARNING
Federal Law Prohibits Use in Highway Vehicles or Engines, or in
Nonroad, Locomotive, or Marine Engines
May Damage Engines Certified for Use on Low-Sulfur or Ultra-Low Sulfur
Diesel Fuel
d. Pump Labeling Requirements for 2014 and Beyond
Beginning September 1, 2014, all nonroad fuel distributed to end-
users would be required to meet the 15 ppm standard, without exception.
Locomotive and marine fuel would continue to be subject to the 500 ppm
standard, without exception. The pump labels for heating oil would
continue to be the same as for the period 2010 through 2014.
For pumps dispensing nonroad diesel fuel, we propose that the label
read as follows:
ULTRA-LOW SULFUR NON-HIGHWAY DIESEL FUEL
(15 ppm Maximum)
Required for all Nonroad Diesel Engines
Recommended for Use in All Nonroad, Locomotive and Marine Diesel
Engines
WARNING
Not for Use in Highway Vehicles or Engines
For pumps dispensing locomotive or marine diesel fuel, we propose
that the label read as follows:
LOW-SULFUR LOCOMOTIVE OR MARINE DIESEL FUEL
(500 ppm maximum)
WARNING
Federal Law Prohibits Use in Other Nonroad Engines or in Highway
Vehicles or Engines
May Damage Model Year 2007 and Newer Highway Diesel Engines and 2011
and Newer Nonroad Diesel Engines
For pumps dispensing high-sulfur fuel for use as heating oil, we
propose that the label read the same as for that same fuel during the
2010-2014 time period, as follows:
HEATING OIL (May Exceed 500 ppm Sulfur)
WARNING
Federal Law Prohibits Use in Highway Vehicles or Engines, or in
Nonroad, Locomotive, or Marine Engines
May Damage Engines Certified for Use on Low-Sulfur or Ultra-Low Sulfur
Diesel Fuel
e. Nozzle Size Requirements or Other Requirements To Prevent
Misfueling
Like the highway diesel fuel program, the proposed NRLM diesel fuel
program does not include a nozzle size requirement. In part this is
because we are not aware of an effective and practicable scheme to
prevent misfueling through the use of different nozzle sizes or shapes,
and in part because we do not believe that improper fueling would be a
significant enough problem to warrant such an action. In the preamble
to the highway diesel fuel rule, we stated our belief that the use of
unique nozzles, color-coded scuffguards, or dyes to distinguish the
grades of diesel fuel may be useful in preventing accidental use of the
wrong fuel. (See 66 FR 5119, January 18, 2001.) However, we did not
finalize any such requirements, for the reasons described in the RIA
for that final rule (Chapter IV.E.).
Similar reasoning applies to the proposed NRLM diesel fuel program.
For example, 15 ppm diesel fuel would be the dominant fuel in the
market by 2010, likely comprising more than 80 percent of all number 2
distillate. Furthermore, after 2010, we believe that 500 ppm diesel
fuel would have limited availability until 2014. High-sulfur distillate
for heating oil uses would remain, but will only exist in significant
volumes in certain parts of the country. In any event, we believe that
most owners and operators of new nonroad diesel engines and equipment
would not risk voiding the general warranty and the emissions warranty
by misfueling.
Although in the highway diesel fuel rule we did not finalize any
provisions beyond fuel pump labeling requirements, we recognized that
some potential for misfueling would still exist. Consequently, we
expressed a desire to continue to explore with industry simple, cost-
effective approaches that could further minimize misfueling potential
such as color-coded nozzles/scuff guards. Since the highway diesel rule
was promulgated, we have had discussions with fuel retailers, wholesale
purchaser-consumers, vehicle manufacturers, and nozzle manufacturers
and continue to examine different methods for preventing accidental or
intentional misfueling under the highway diesel fuel sulfur program. To
date, no consensus exists among the affected stakeholders, including
engine and truck manufacturers, truck operators, fuel retailers, and
fuel nozzle manufacturers. However, we will continue discussions with
these and other stakeholders. We will consider any new developments
that result from these highway discussions in a future nonroad action.
3. Use of Used Motor Oil in New Nonroad Diesel Equipment
We understand that used motor oil is sometimes blended with diesel
fuel for use as fuel in nonroad diesel equipment. Such practices
include blending used motor oil directly into the equipment fuel tank,
blending it into the fuel storage tanks, and blending small amounts of
motor oil from the engine crank case into the fuel system as the
equipment is operated.
However, motor oil normally contains high levels of sulfur. Thus,
the addition of used motor oil to nonroad diesel fuel could
substantially impair the sulfur-sensitive emissions control equipment
expected to be used by engine manufacturers to meet the emissions
standards proposed in today's NPRM. Depending on how the oil is
blended, it could increase the sulfur content of the fuel by as much as
200 ppm. As a result, we believe blending used motor oil into nonroad
diesel fuel could render inoperative the expected emission control
technology and potentially cause driveability problems. It should be
prohibited as a violation of the tampering prohibition in the Act. See
CAA Sections 203(a)(3), 213(d).
Therefore, like the highway diesel rule, this proposal would
prohibit any person from introducing or causing or allowing the
introduction of used motor oil, or diesel fuel containing used motor
[[Page 28502]]
oil, into the fuel delivery systems of nonroad equipment engines
manufactured in model year 2011 and later. The only exception to this
would be where the engine was explicitly certified to the emission
standard with used motor oil added and the oil was added in a manner
consistent with the certification.
4. Use of Kerosene in Diesel Fuel
As we discussed in the highway diesel final rule, kerosene is
commonly added to diesel fuel to reduce fuel viscosity in cold weather
(see 66 FR 5120, January 18, 2001). This proposal would not limit this
practice with regard to 500 ppm NRLM diesel fuel. However the resulting
blend would still be subject to the 500 ppm sulfur standard. Consistent
with the highway diesel fuel rule, kerosene that is used, intended for
use, or made available for use as, or for blending with, 15 ppm sulfur
nonroad diesel fuel would itself be required to meet the 15 ppm
standard starting June 1, 2010 and must be itself classified as
``nonroad diesel fuel'' unless it was already classified as ``motor
vehicle diesel fuel.'' This classification as nonroad diesel fuel use
could be made by the kerosene fuel's refiner or could be made by a
downstream party at the point when that party chooses to use the
kerosene in its possession for use as nonroad diesel fuel subject to
the 15 ppm sulfur standard.
To help ensure that only distillates that comply with the proposed
15 ppm nonroad diesel fuel standard are blended into 15 ppm nonroad
diesel fuel, this proposal would require that kerosene meeting the 15
ppm standard and distributed by the transferring party for use in
nonroad equipment engines must be accompanied by PTDs accurately
stating that the product meets the 15 ppm sulfur standard. (See Section
VIII.E.7, below.)
As a general matter, any party who would blend kerosene, or any
blendstock, into nonroad diesel fuel, or who would produce nonroad
diesel fuel by mixing blendstocks, would be a refiner and would be
subject to the requirements and prohibitions applicable to refiners
under the proposed rule. However, under this proposal, in deference to
the longstanding and widespread practice of blending kerosene into
diesel fuel at downstream locations, downstream parties who only blend
kerosene into nonroad diesel fuel will not be subject to the
requirements applicable to other refiners, provided that they do not
alter the fuel in any other way. This activity is treated the same way
under the final highway diesel rule.
In order to ensure the continued compliance of 15 ppm fuel with the
15 ppm standard, downstream parties choosing to blend kerosene into 15
ppm nonroad diesel fuel would be required to either have a PTD for that
kerosene indicating compliance with the 15 ppm standard, or to have
test results for the kerosene establishing such compliance. Further,
downstream parties choosing to blend kerosene into 15 ppm nonroad
diesel fuel would be entitled to the 2 ppm adjustment factor discussed
above for both the kerosene and the diesel fuel into which it is
blended at downstream locations, provided that the kerosene had been
transferred to the party with a PTD indicating compliance with that
standard. Sulfur test results from downstream locations of parties who
do not have such a PTD for their kerosene will not be subject to this
adjustment factor, either for the kerosene itself, or for the nonroad
diesel fuel into which it is blended.
Any party who causes the sulfur content of nonroad diesel fuel
subject to the 15 ppm sulfur standard to exceed 15 ppm by blending
kerosene into nonroad diesel fuel, or by using high sulfur kerosene as
nonroad diesel fuel, would be subject to liability for violating the
sulfur standard. Similarly, parties who cause the sulfur level of
nonroad diesel fuel subject to the 500 ppm nonroad diesel fuel to
exceed that standard by blending kerosene into the fuel, would also be
subject to liability.
The proposed rule would not require refiners or importers of
kerosene to produce or import kerosene meeting the 15 ppm sulfur
standard. However, we believe that refiners will produce low sulfur
kerosene in the same refinery processes that they use to produce low
sulfur diesel fuel, and that the market will drive supply of low sulfur
kerosene for those areas where, and during those seasons when, the
product is needed for blending with nonroad, as well as highway, diesel
fuel. We request comments regarding this proposed provision.
5. Use of Diesel Fuel Additives
Diesel fuel additives include lubricity improvers, corrosion
inhibitors, cold-operability improvers, and static dissipaters. Use of
such additives is distinguished from the use of kerosene by the low
concentrations at which they are used and their relatively more complex
chemistry.\323\ The suitability of diesel fuel additives for use in
diesel fuel meeting a 500 ppm sulfur specification has been well
established due to the existence of 500 ppm highway diesel fuel in the
marketplace since 1993. The suitability of additives for use in 15 ppm
diesel fuel was addressed in the highway diesel program, which requires
highway diesel fuel to meet a 15 ppm sulfur standard beginning in 2006.
Our review of data submitted by additive and fuel manufacturers to
comply with EPA's Fuel and Fuel Additive Registration requirements
indicates that additives to meet every purpose, including static
dissipation, are currently in common use which meet a 15 ppm cap on
sulfur content.\324\ Since such low-sulfur additives are currently in
use side-by-side with high-sulfur additives, it is reasonable to
conclude that there is not a significant difference in their cost. The
ability of industry to provide low-sulfur additives is supported by the
fact that diesel fuel meeting a 10 ppm cap on sulfur content has been
marketed in Sweden for some time and is beginning to be marketed in
other countries such as Germany. Fifteen ppm diesel fuel is also being
made available to a number of centrally fueled fleets across the U.S.
---------------------------------------------------------------------------
\323\ Diesel fuel additives are used at concentrations commonly
expressed in parts per million. Diesel fuel additives can include
specially-formulated polymers and other complex chemical components.
Kerosene is used at much higher concentrations, expressed in volume
percent. Unlike diesel fuel additives, kerosene is a narrow
distillation fraction of the range of hydrocarbons normally
contained in diesel fuel.
\324\ See Chapter IV.D. of the RIA for the highway diesel fuel
rule for more information on diesel fuel additives, EPA Air docket
A-99-06, docket item V-B-01. Also See 40 CFR part 79.
---------------------------------------------------------------------------
Even if not yet available for certain purposes, we believe that it
is reasonable to assume that low-sulfur additives will become available
before the 15 ppm sulfur standard for highway diesel fuel becomes
effective in 2006. This will be well in advance of the proposed 2010
implementation date for a 15 pm sulfur standard on nonroad diesel fuel.
As discussed in section V of today's preamble, we expect that
reducing the sulfur content of NRLM diesel fuel to meet proposed sulfur
standards would not have a disproportionate impact on fuel lubricity
compared to the reduction in lubricity associated with desulfurizing
highway diesel fuel. We have no reason to expect that this situation
would be any different with respect to the potential impact on nonroad
diesel fuel properties other than fuel lubricity which might require
the use of additives such as cold flow, and susceptibility to static
build up. Consequently, our estimate of the increase in additive use
that would
[[Page 28503]]
result from the adoption of the proposed rule parallels that under the
highway program. We estimate that the use of lubricity additives would
increase, and that the use of other additives would be unaffected.\325\
We request comment on this assessment.
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\325\ See Section IV.G. of today's preamble for a discussion of
the potential impact of the proposed sulfur standards on fuel
lubricity.
---------------------------------------------------------------------------
Similar to the highway diesel rule, this proposed rule would allow
the use of diesel fuel additives with a sulfur content greater than 15
ppm in nonroad diesel fuel. However, nonroad diesel fuel containing
such additives would remain subject to the proposed 15 ppm sulfur cap.
We believe that it is most appropriate for the market to determine how
best to accommodate increases in the fuel sulfur content from the
refinery gate to the end user, while maintaining the 15 ppm cap, and
whether such increases result from contamination in the distribution
system or diesel additive use. By providing this flexibility, we
anticipate that market forces will encourage an optimal balance between
the competing demands of manufacturing fuel lower than the 15 ppm
sulfur cap, limiting contamination in the distribution system, and
limiting the additive contribution to fuel sulfur content.
As in the highway diesel program, additive manufacturers that
market additives with a sulfur content higher than 15 ppm and blenders
that use them in nonroad diesel fuel subject to the proposed 15 ppm
sulfur standard would have additional requirements to ensure that the
15 ppm sulfur cap is not exceeded. The 15 ppm sulfur cap on highway
diesel fuel that becomes effective in 2006 may encourage the gradual
retirement of additives that do not meet a 15 ppm sulfur cap. The
proposed 15 ppm sulfur cap for nonroad diesel fuel in 2010 may further
this trend. However, we do not anticipate that this will result in
disruption to additive users and producers or a significant increase in
cost. Additive manufacturers commonly reformulate their additives on a
periodic basis as a result of competitive pressures. We anticipate that
any reformulation that might need to occur to meet a 15 ppm sulfur cap
will be accomplished prior to the implementation of the 15 ppm sulfur
cap on highway diesel fuel in 2006.
Like the highway diesel fuel rule, this proposed rule would limit
the continued use in nonroad diesel fuel that is subject to the
proposed 15 ppm sulfur standard of additives that exceed 15 ppm sulfur.
These additives would be limited to use in concentrations of less than
one volume percent. We believe that this limitation is appropriate and
would not cause any undue burden because the diesel fuel additives for
which this flexibility was included are always used today at
concentrations well below one volume percent. Further, one volume
percent is the threshold above which the blender of an additive becomes
subject to all the requirements applicable to a refiner. See 40 CFR
79.2(d)(1).
The specific proposed requirements regarding the use of diesel fuel
additives in nonroad diesel fuel subject to the proposed 15 ppm
standard are as follows:
[sbull] Additives that have a sulfur content at or below 15 ppm
must be accompanied by a PTD that states: ``The sulfur content of this
additive does not exceed 15 ppm.''
[sbull] Additives that exceed 15 ppm sulfur could continue to be
used in nonroad diesel fuel subject to the proposed 15 ppm sulfur
standard provided that they are used at a concentration of less than
one volume percent and their transfer is accompanied by a PTD that
lists the following:
(1) A warning that the additive's sulfur content may exceed 15 ppm,
(2) The additive's maximum sulfur concentration,
(3) The maximum recommended concentration for use of the additive
in diesel fuel, and,
(4) The contribution to the sulfur level of the fuel that would
result if the additive is used at the maximum recommended
concentration.
Blenders of additives that exceed 15 ppm in sulfur content would be
liable if their actions caused the sulfur content of the finished
nonroad diesel fuel to exceed 15 ppm. In some cases, blenders may not
find it feasible to conduct testing, or otherwise obtain information on
the sulfur content of the fuel either before or after additive
blending, without incurring substantial cost. We anticipate that
blenders would manage the risk associated with the use of additives
above 15 ppm in sulfur content under such circumstances with actions
such as the following:
[sbull] Selecting an additive with minimal sulfur content above 15
ppm that is used at a low concentration, and
[sbull] Working with their upstream suppliers to provide fuel of
sufficiently low sulfur content to accommodate the small increase in
sulfur content which results from the use of the additive.
This is similar to the way distributors would manage contamination
from their distribution hardware, such as tank trucks. Distributors
would not necessarily test for fuel sulfur content after each
opportunity for contamination, but rather will rely on mechanisms set
up to minimize the contamination, and to obtain fuel sufficiently below
the standard to accommodate the increase in sulfur content from the
contamination.
The recordkeeping, reporting, and PTD provisions associated with
these proposed requirements are discussed in Section VIII.E below. The
liability provisions are discussed in Section VIII.F below.
The 1993 and 2007 highway diesel programs did not contain any
requirements regarding the maximum sulfur content of additives used in
highway diesel fuel subject to a 500 ppm sulfur cap.\326\ Our
experience under the highway program indicates that application of the
500 ppm sulfur cap throughout the distribution system to the end-user
has been sufficient to prevent the use of additives from jeopardizing
compliance with the 500 ppm sulfur standard. The potential increase of
several ppm in the sulfur content of diesel fuel which might result
from the use of diesel additives raises substantial concerns regarding
the impact on compliance with a 15 ppm sulfur cap. However, this is not
the case with respect to the potential impact on compliance with a 500
ppm sulfur cap. The current average sulfur content of highway diesel
fuel of 340 ppm provides ample margin for the minimal increase in the
fuel sulfur content which might result from the use of additives. We
expect that this would also be the case for NRLM fuel subject to the
proposed 500 ppm sulfur standard. Therefore, we are not proposing any
requirements regarding the sulfur content of additives used in NRLM
fuel subject to the proposed 500 ppm sulfur standard. We believe that
the proposed requirement that NRLM fuel comply with the 500 ppm sulfur
cap throughout the distribution system to the end-user would be
sufficient to ensure that entities who introduce additives into such
fuel take into account the potential increase in fuel sulfur content.
---------------------------------------------------------------------------
\326\ The 500 ppm highway diesel final rule contains the
requirement that highway diesel fuel not exceed 500 ppm in sulfur
content at any point in the fuel distribution system including after
the blending of additives. Fuel Quality Regulations for Highway
Diesel Fuel Sold in 1993 and Later Calendar Years, Final Rule, 55 FR
34120, August 21, 1990.
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6. End User Requirements
In light of the importance of ensuring that the proper fuel is used
in nonroad, locomotive, and marine engines covered
[[Page 28504]]
by the proposed program, we propose to prohibit any person from fueling
such an engine with fuel not meeting the applicable sulfur standard.
We propose that (1) no person may introduce, or permit the
introduction of, fuel that exceeds 15 ppm sulfur content into nonroad
equipment with a model year 2011 or later engine; (2) beginning
December 1, 2010, no person may introduce, or permit the introduction
of locomotive or marine fuel into any nonroad diesel engine; (3)
beginning December 1, 2010, no person may introduce, or permit the
introduction of any fuel exceeding 15 ppm sulfur content into any
nonroad diesel engine regardless of year of manufacture, except that
segregated 500 ppm nonroad diesel fuel produced by qualified small
refiners, hardship refiners, or refiners using credits may be
introduced into pre-2011 model year nonroad diesel engines; (4)
beginning December 1, 2010, no person may introduce, or permit the
introduction of fuel exceeding 500 ppm sulfur content into any
locomotive or marine diesel engine; and (5) beginning December 1, 2014,
no person may introduce, or permit the introduction of, fuel exceeding
15 ppm sulfur content into any nonroad diesel engine.
7. Anti-Downgrading Provisions
The highway diesel rule restricts downgrading of 15 ppm highway
diesel fuel to 500 ppm highway diesel fuel, from June 1, 2006-May 31,
2010 by preventing downstream entities from intentionally downgrading
15 ppm highway fuel. This is to protect the nationwide availability of
15 ppm highway fuel. The concern was that since both 15 ppm highway
fuel and 500 ppm highway fuel were expected to be comparably priced,
entities downstream of the refinery could simply take delivery of
whichever fuel was cheapest and commingle the two fuel grades into a
single pool of 500 ppm highway fuel. We chose not to restrict
downgrading to non-highway fuel grades, however, for three reasons.
First, in order to avoid reprocessing costs, an outlet was needed for
legitimately downgraded fuel produced through contamination in the
distribution system. Second, the price differential between 15 ppm fuel
and high sulfur non-highway fuel was expected to be sufficient to deter
any intentional downgrading. Third, many of the entities such as
retailers and fleets that might have an incentive to downgrade 15 ppm
highway fuel do not market non-highway fuel, and therefore would have
no opportunity to do so.
With this proposal, however, all NRLM diesel fuel would also be
required to meet the 500 ppm sulfur standard beginning June 1, 2007 and
it could be mixed fungibly with 500 ppm sulfur highway fuel up to the
point where dye was added for IRS excise tax purposes. As a result,
application of the current anti-downgrading provision in the highway
diesel rule is ambiguous with respect to what would and would not be
allowed under this proposal. Furthermore, the assumption in the highway
rule that the price differential between 15 ppm highway and non-highway
fuel would be sufficient to deter intentional downgrading would not
necessarily be valid any longer, given the application of the 500 ppm
sulfur standard to NRLM diesel fuel. For these reasons, we propose that
the anti-downgrading provisions contained in 40 CFR 80.527 be modified
to restrict downgrading of undyed 15 ppm diesel fuel to any 500 ppm
diesel fuel, whether the 500 ppm sulfur fuel is intended for highway
purposes or NRLM purposes. We would continue to allow unrestricted
downgrading of undyed 15 ppm diesel fuel to fuel which is marked as
heating oil.
We further propose that the downgrading restriction apply to any
undyed 15 ppm diesel fuel produced. Since the two fuels would be
distributed together, this modification to the downgrading limitations
would be needed to enable enforcement of the highway diesel fuel
downgrading limitations. We are not proposing any extension of that the
anti-downgrading provisions beyond their current set date of June 1,
2010. The purpose of the anti-downgrading provisions is to ensure
availability of 15 ppm highway fuel nationwide, and we do not
anticipate this as a concern after June 1, 2010. This proposal allows
early credit for 15 ppm NRLM diesel fuel produced beginning June 1,
2009. Although availability is not an issue for this fuel, it will be
fungible with highway fuel subject to the 15 ppm sulfur standard.
Consequently, we seek comment on whether the anti-downgrading provision
could expire then as well without negatively impacting the availability
of 15 ppm diesel fuel for highway vehicles. We request comment on these
proposed revisions of the anti-downgrading provisions.\327\
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\327\ Since the time of the highway diesel final rule, we have
become aware of the need for several other clarifications of the
anti-downgrading provisions. We intend to address these general
issues through a future amendment to the highway diesel rule.
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While these proposed downgrading provisions apply primarily to
parties in the distribution system downstream of the refiners and
importers, these requirements would also apply to refiners and
importers.
D. Diesel Fuel Sulfur Sampling and Testing Requirements
1. Testing Requirements
As part of today's action, we are proposing a new approach for fuel
sulfur measurement. The details of this approach are described below,
followed by a description of who would be required to conduct fuel
sulfur testing as well as what fuel they would be required to test.
a. Test Method Approval, Recordkeeping, and Quality Control
Requirements
Most current and past EPA fuel programs designated specific
analytical methods which refiners, importers, and downstream parties
use to analyze fuel samples at all points in the fuel distribution
system for regulatory compliance purposes. Some of these programs have
also allowed certain specific alternative methods which may be used as
long as the test results are correlated to the designated test method.
The highway diesel rule (66 FR 5002, January 18, 2001), for example,
specifies one designated test method and three alternative methods for
measuring the sulfur content of highway diesel fuel subject to the 15
ppm sulfur standard. The rule also specifies one designated method and
three alternative methods for measuring the sulfur content of highway
diesel fuel subject to the 500 ppm sulfur standard.
The highway diesel fuel sulfur rule also announced the Agency's
intention to adopt a performance-based test method approach in the
future, as well as our intention to continue working with the industry
to develop and improve sulfur test methods. Under today's action, we
are proposing to adopt a performance-based test method approach for
diesel fuel subject to the 15 ppm sulfur standard. We are also
proposing to adopt such an approach as an option for diesel fuel
subject to the 500 ppm sulfur standard. The current approach for
measuring the sulfur content of diesel fuel subject to the 500 ppm
sulfur standard, i.e., using the designated sulfur test method or one
of the alternative test methods with correlation could continue to be
used.
[[Page 28505]]
Table IV-D-1.--Designated and Alternative Sulfur Test Methods Allowed
Under the Highway Diesel Program
------------------------------------------------------------------------
Sulfur test method 500 ppm 15 ppm
------------------------------------------------------------------------
ASTM D 2622-98 as modified, Designated........ Alternative.
Standard Test Method for Sulfur
in Petroleum Products by X-Ray
Spectrometry.
ASTM D 3120-96, Standard Test .................. Alternative.
Method for Trace Quantities of
Sulfur in Light Liquid
Petroleum Hydrocarbons by
Oxidative Microcoulometry.
ASTM D 4294, Standard Test Alternative.......
Method for Sulfur in Petroleum
and Petroleum Products by
Energy-Dispersive X-ray
Fluorescence Spectrometry.
ASTM D 5453-00, Standard Test Alternative....... Alternative.
Method for Determination of
Total Sulfur in Light
Hydrocarbons, Motor Fuels and
Oils by Ultraviolet
Fluorescence.
ASTM D 6428-99, Test Method for Alternative....... Designated.
Total Sulfur in Liquid Aromatic
Hydrocarbons and Their
Derivatives by Oxidative
Combustion and Electrochemical
Detection.
------------------------------------------------------------------------
Under the performance-based approach, a given test method would be
approved for use in a specific laboratory by meeting certain precision
and accuracy criteria specified in the regulations. The method would be
approved for use by that laboratory as long as appropriate quality
control procedures were followed. Properly selected precision and
accuracy values potentially would allow multiple methods and multiple
commercially available instruments to be approved, thus providing
greater flexibility in method and instrument selection while also
encouraging the development and use of better methods and
instrumentation in the future. Under this approach, there would be no
designated sulfur test method as specified under previous regulations.
Since any test method that meets the specified performance criteria
may qualify, this type of approach does not conflict with the
``National Technology Transfer and Advancement Act of 1995'' (NTTAA),
section 12(d) of Public Law 104-113, and the Office of Management and
Budget (OMB) Circular A-119. Both of these documents are designed to
encourage the adoption of standards developed by ``voluntary consensus
bodies'' and to reduce reliance on government-unique standards where
such consensus standards would suffice. Under the performance criteria
approach proposed today, methods developed by consensus bodies as well
as methods not yet approved by a consensus body would qualify for
approval provided they met the specified performance criteria as well
as the recordkeeping and reporting requirements for quality control
purposes.
i. How Can a Given Method Be Approved?
Under the proposed performance criteria approach, a given test
method would be approved for use under today's program by meeting
certain precision and accuracy criteria. Approval would apply on a
laboratory/facility-specific basis. If a company chose to employ more
than one laboratory for fuel sulfur testing purposes, then each
laboratory would have to separately seek approval for each method it
intends to use. Likewise, if a laboratory chose to use more than one
sulfur test method, then each method would have to be approved
separately. Separate approval would not be necessary for individual
operators or laboratory instruments within a given laboratory facility.
The specific precision and accuracy criteria that we are proposing
were derived from existing sulfur test methods that are either required
or allowed under the highway diesel fuel sulfur program. The first
criterion, precision, refers to the consistency of a set of
measurements and is used to determine how closely analytical results
can be duplicated based on repeat measurements of the same material
under prescribed conditions. To demonstrate the precision of a given
sulfur test method under the performance-based approach, a laboratory
facility would perform 20 repeat tests over 20 days on samples taken
from a homogeneous supply of a commercially available diesel fuel. We
request comment on an alternative number of days over which these 20
repeat tests should be conducted. Using the test results \328\ of ASTM
D 3120 for diesel fuel subject to the 15 ppm sulfur standard, the
precision would have to be less than 0.72 ppm.\329\ Similarly, using
the test results of ASTM D 2622 for diesel fuel subject to the 500 ppm
sulfur standard, the precision would have to be less than 9.68 ppm.
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\328\ Sulfur Repeatability of Diesel by Method at 15 ppm, ASTM
Report on Low Level Sulfur Determination in Gasoline and Diesel
Interlaboratory Study--A Status Report, June 2002.
\329\ 0.72 ppm is equal to 1.5 times the standard deviation of
ASTM D 3120, where the standard deviation is equal to the
repeatability of ASTM D 3120 (1.33) divided by 2.77. 9.68 ppm is
equal to 1.5 times the standard deviation of ASTM D 2622, where the
standard deviation is equal to the repeatability of ASTM D 2622
(26.81) divided by 2.77. Since the conditions of the precision
qualification test admit more sources of variability than the
conditions under which ASTM repeatability is determined (longer time
span, different operators, environmental conditions, etc.) the
repeatability standard deviation derived from the round robin was
multiplied by what we believe to be a reasonable adjustment factor,
1.5, to compensate for the difference in conditions.
---------------------------------------------------------------------------
The second criterion, accuracy, refers to the closeness of
agreement between a measured or calculated value and the actual or
specified value. To demonstrate the accuracy of a given test method
under the performance-based approach, a laboratory facility would be
required to perform 10 repeat tests on a standard sample, the mean of
which for diesel fuel subject to the 15 ppm sulfur standard could not
deviate from the Accepted Reference Value (ARV) of the standard by more
than 0.54 ppm and for diesel fuel subject to the 500 ppm sulfur
standard could not deviate from the ARV of the standard by more than
7.26 ppm.\330\ These tests would be performed using commercially
available gravimetric sulfur standards. Ten tests would be required
using each of two different sulfur standards--one in the range of 1-10
ppm sulfur and the other in the range of 10-20 ppm sulfur for 15 ppm
fuel and one in the range of 100-200 ppm sulfur and the other in the
[[Page 28506]]
range of 400-500 ppm sulfur for 500 ppm sulfur diesel fuel. Therefore,
a minimum of 20 total tests would be required for sufficient
demonstration of accuracy for a given sulfur test method at a given
laboratory facility. Finally, any known interferences for a given test
method would have to be mitigated.
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\330\ 0.54 and 7.26 are equal to 0.75 times the precision values
of 0.72 for 15 ppm sulfur diesel and 9.68 for 500 ppm sulfur diesel,
respectively.
---------------------------------------------------------------------------
These requirements are not intended to be overly burdensome.
Indeed, we believe these requirements are equivalent to what a
laboratory would do during the normal start up procedure for a given
test method. In addition, we believe this approach would allow
regulated entities to know that they are measuring diesel fuel sulfur
levels accurately and within reasonable site reproducibility limits.
Nevertheless, we request comment on this performance criteria approach
and the specific precision and accuracy criteria we are proposing.
ii. What Information Would Have To Be Reported to the Agency?
For test methods that have already been approved by a voluntary
consensus standards body \331\ (VCSB), such as ASTM or the
International Standards Organization (ISO), each laboratory facility
would be required to report to the Agency the precision and accuracy
results as described above for each method for which it is seeking
approval. Such submissions to EPA, as described elsewhere, would be
subject to the Agency's review for 90 days, and the method would be
considered approved in the absence of EPA comment. Laboratory
facilities would be required to retain the fuel samples used for
precision and accuracy demonstration for 30 days. We seek comment on an
alternative number of days for which such fuel samples should be
retained.
---------------------------------------------------------------------------
\331\ These are standard-setting organizations, like ASTM, and
ISO that have broad representation of all interested stakeholders
and make decisions by consensus.
---------------------------------------------------------------------------
For test methods that have not been approved by a VCSB, full test
method documentation, including a description of the technology/
instrumentation that makes the method functional, as well as subsequent
EPA approval of the method would also be required. These submissions
would also be subject to the Agency's review for 90 days, and the
method would be considered approved in the absence of EPA comment.
Submission of VCSB methods would not be required since they are
available in the public domain. In addition, industry and the Agency
have likely had substantial experience with such methods. The approval
of non-VCSB methods would be valid for five years. After this time
period, the approval would be rescinded unless the method had been
adopted by a consensus body. If, a consensus body does not ultimately
approve the method then the method could no longer be used as an
approved method.
As described above, federal government and EPA policy is to use
standards developed by voluntary consensus bodies when available. The
purpose of the NTTAA, at least in part, is to foster consistency in
regulatory requirements, to take advantage of the collective industry
wisdom and wide-spread technical evaluation required before a test
method is approved by a consensus body, and to take advantage of the
ongoing oversight and evaluation of a test method by the consensus body
that results from wide-spread use of an approved method e.g., the
ongoing round-robin type analysis and typical annual updating of the
method by the consensus body. These goals are not met where the Agency
allows use of a non-consensus body test method in perpetuity. Moreover,
it is not possible to realize many of the advantages that result from
consensus status where a test method is used by only one or a few
companies. It will not have the practical scrutiny that comes from
ongoing wide-spread use, or the independent scrutiny of the consensus
body and periodic updating. In addition, EPA does not have the
resources to conduct the degree of initial scrutiny or ongoing scrutiny
that are practiced by consensus bodies. Nevertheless, EPA believes it
is appropriate to allow limited use of a proprietary test method for a
limited time, even though the significant advantages of consensus test
methods are absent, because EPA can evaluate the initial quality of a
method and a company may have invested significant resources in
developing a method. However, if after a reasonable time a test method
fails to gain consensus body approval, EPA believes approval of the
method should be withdrawn because of the absence of ongoing consensus
oversight. Accordingly, we propose that a non-VCSB method will cease to
be qualified five years from the date of its original approval by EPA
in the absence of VCSB approval.
To assist the Agency in determining the performance of a given
sulfur test method, non-VCSB methods, in particular, we propose to
reserve the right to send samples of commercially available fuel to
laboratories for evaluation. Such samples would be intended for
situations in which the Agency had concerns regarding a test method
and, in particular, its ability to measure the sulfur content of a
random commercially available diesel fuel. Laboratory facilities would
be required to report their results from three tests of this material
to the Agency.
iii. What Quality Control Provisions Would Be Required?
We are proposing to require ongoing Quality Control (QC) procedures
for sulfur measurement instrumentation. These are procedures used by
laboratory facilities to ensure that the test methods they have
qualified and the instruments on which the methods are run are yielding
results with appropriate accuracy and precision, e.g., that the results
from a particular instrument do not ``drift'' over time to yield
unacceptable values. It is our understanding that most laboratories
already employ QC procedures, and that these are commonly viewed as
important good laboratory practices. Under the performance-based
approach, laboratories would be required, at a minimum, to abide by the
following QC procedures for each instrument used to certify batches of
diesel fuel under these regulations:
(1) Follow the mandatory provisions of ASTM D 6299-02, Standard
Practice for Applying Statistical Quality Assurance Techniques to
Evaluate Analytical Measurement System Performance. Laboratories would
be required to construct control charts from the mandatory QC sample
testing prescribed in paragraph 7.1, following the guidelines under A
1.5.1 for individual observation charts and A 1.5.2 for moving range
charts.
(2) Follow ASTM D6299-02 paragraph 7.3.1 (check standards) using a
standard reference material. Check standard testing would be required
to occur at least monthly and should take place following any major
change to the laboratory equipment or test procedure. Any deviation
from the accepted reference value of the check standard greater than
1.44 ppm for diesel fuel subject to the 15 ppm sulfur standard and
19.36 ppm for diesel fuel subject to the 500 ppm sulfur standard \332\
would have to be investigated.
---------------------------------------------------------------------------
\332\ 1.44 ppm is equal to two times the proposed precision of
0.72 ppm for 15 ppm diesel and 19.36 is equal to two times the
proposed precision of 9.68 ppm for 500 ppm diesel.
---------------------------------------------------------------------------
(3) Upon discovery of any QC testing violation of A 1.5.2.1 or A
1.5.3.2 or check standard deviation greater than 1.44 ppm and 19.36 ppm
for 15 ppm sulfur diesel and 500 ppm sulfur diesel, respectively, as
provided in item 2 above, any measurement made while the system was out
of control would be required to be tagged as suspect and an
[[Page 28507]]
investigation conducted into the reasons for this anomalous
performance. We also propose that refiners and importers would be
required to retain batch samples for a limited amount of time. For
example, a retain period could be equal to the interval between QC
sample tests. If an instrument was found to be out of control, we
propose that all of the retained samples since the last time the
instrument was shown to be in control would have to be retested. We
seek comment on alternative ways to handle situations in which a method
goes out of control at some unknown point in time between check
standard tests or between QC sample tests.
(4) QC records, including investigations under item 3 above would
be required to be retained for five years and to be provided to the
Agency upon request.
b. Requirements To Conduct Fuel Sulfur Testing.
Given the importance of assuring that nonroad diesel fuel
designated to meet the 15 ppm sulfur standard in fact meets that
standard, we are proposing that refiners and importers must test each
batch of nonroad diesel fuel designated to meet the 15 ppm sulfur
standard and to maintain records of such testing. Requiring that
refiners and importers test each batch of fuel subject to the 15 ppm
nonroad standard would assure that compliance could be confirmed
through testing records, and even more importantly, would assure that
nonroad diesel fuel exceeding the 15 ppm standard was not introduced
into commerce as fuel for use in nonroad equipment having sulfur-
sensitive emission control devices. Batch testing is currently not
required under the highway diesel rule, and instead such testing is
typically performed to establish a defense to potential liability.
However, for the same reasons discussed above, we propose to extend
this batch testing requirement to 15 ppm sulfur highway diesel fuel
beginning in 2006.
We are not proposing to require downstream parties to conduct
every-batch testing. However, we believe most downstream parties would
voluntarily conduct ``periodic'' sampling and testing for quality
assurance purposes if they wanted to establish a defense to presumptive
liability, as discussed in VIII.G below.
2. Two Part-Per-Million Downstream Sulfur Measurement Adjustment
We believe that it would be appropriate to recognize sulfur test
variability in determining compliance with the proposed nonroad diesel
fuel sulfur standard downstream of a refinery or import facility. Thus,
we propose that for all 15 ppm sulfur nonroad diesel fuel at locations
downstream of the refinery or import facility, sulfur test results
could be adjusted by subtracting two ppm. The sole purpose of this
downstream compliance provision is to address test variability
concerns. We anticipate that the reproducibility of sulfur test methods
is likely to improve to two ppm or even less by the time the 15 ppm
sulfur standard for highway diesel fuel is implemented--four years
before implementation date of the proposed 15 ppm standard for nonroad
diesel fuel. With this provision, we anticipate that refiners would be
able to produce diesel fuel with an average sulfur level of
approximately 7-8 ppm and some contamination could occur throughout the
distribution system, without fear of causing a downstream violation due
solely to test variability. As test methods improve in the future, we
propose to reevaluate whether two ppm is the appropriate allowance for
purposes of this compliance provision.
3. Sampling Requirements
This proposed rule would adopt the same sampling methods adopted by
the highway diesel rule (66 FR 5002, January 18, 2001). The requirement
to use these methods would be effective for nonroad diesel fuel June 1,
2007. These same methods were also adopted for use in the Tier 2/
Gasoline Sulfur rule.\333\ These sampling methods are American Society
for Testing and Materials (ASTM) D 4057-95 (manual sampling) and D
4177-95 (automatic sampling from pipelines/in-line blending).
---------------------------------------------------------------------------
\333\ 65 FR 6833-34 (Feb. 10, 2000). These methods are also
proposed for use under the RFG and CG rules. See 62 FR 37337 et seq.
(July 11, 1997).
---------------------------------------------------------------------------
4. Alternative Sampling and Testing Requirements for Importers of
Diesel Fuel Who Transport Diesel Fuel By Tanker Truck
We understand that importers who transport diesel fuel into the
U.S. by tanker truck are frequently relatively small businesses that
could be subject to a substantial burden if they were required to
sample and test each batch of nonroad or highway diesel fuel imported
by truck, especially where a trucker imports many small loads of diesel
fuel. Therefore, we are proposing that truck importers could comply
with an alternative sampling and testing requirement, involving a
sampling and testing program of the foreign truck loading terminal, if
certain conditions were met. For an importer to be eligible for the
alternative sampling and testing requirement, the terminal would have
to conduct sampling and testing of the nonroad or highway diesel fuel
immediately after each receipt into its terminal storage tank or
immediately before loading product into the importer's tanker truck
storage compartments. Moreover, the importer would be required to allow
EPA to conduct periodic quality assurance testing of the terminal's
diesel fuel, and the importer would be required to assure that EPA
would be allowed to make unannounced inspections and audits, to sample
and test fuel at the foreign terminal facility, to assure that the
terminal maintained sampling and testing records, and to submit such
records to EPA upon request. We request comment on this proposal.
E. Fuel Marker Test Method
As discussed in section IV.B.2.a.i above, we propose the use of
solvent yellow 124 to differentiate diesel fuel intended for different
uses. This marker is currently use in Europe. However, there is
currently no test procedure recognized by the European Union to
quantify the presence of the solvent yellow 124 in distillate fuels.
The most commonly accepted method used in the European Union is based
on the chemical extraction of the Euromarker using hydrocloric acid
solution and cycloxane, and the subsequent evaluation of the extract
using a visual spectrometer to determine the concentration of the
marker.\334\ This test is inexpensive and easy to use for field
inspections. However, the test involves reagents that require some
safety precautions and the small amount of fuel required in the test
must be disposed of as hazardous waste. Nevertheless, we believe that
such safety concerns are manageable here in the U.S. just as they are
in Europe and that the small amount of waste generated can be handled
along with other similar waste generated by the company conducting the
test, and that the associated effort/costs would be negligible.
---------------------------------------------------------------------------
\334\ Memorandum to the docket entitled ``Use of a Visible
Spectrometer Based Test Method in Detecting the Presence and
Determining the Concentration of Solvent Yellow 124 in Diesel
Fuel.''
---------------------------------------------------------------------------
Similar to the approach proposed regarding the measurement of fuel
sulfur content discussed in Section VIII.D. above, we are proposing a
performance-based procedure to measure the concentration of solvent
yellow 124 in distillate fuel. Section VIII.D above describes our
rationale for
[[Page 28508]]
proposing performance-based test procedures. Under the performance-
based approach, a given test method could be approved for use in a
specific laboratory or for field testing by meeting certain precision
and accuracy criteria. Properly selected precision and accuracy values
potentially would allow multiple methods and multiple commercially
available instruments to be approved, thus providing greater
flexibility in method and instrument selection while also encouraging
the development and use of better methods and instrumentation in the
future. For example, we are hopeful that with more time and effort a
simpler test can be developed that can avoid the use of reagents and
the generation of hazardous waste that is by product of the current
commonly accepted method.
Under the performance criteria approach proposed today, methods
developed by consensus bodies as well as methods not yet approved by a
consensus body would qualify for approval provided they met the
specified performance criteria as well as the recordkeeping and
reporting requirements for quality control purposes. There would be no
designated marker test method. We request comment on whether it would
be more appropriate to adopt a designated marker test method. Such
comments would be most useful if they include complete details on a
suitable designated marker test method.
1. How Could a Given Marker Test Method Be Approved?
Under the proposed performance criteria approach, a given marker
test method would be approved for use under today's program by meeting
certain precision and accuracy criteria. Approval would apply on a
laboratory/facility-specific basis. If a company chose to employ more
than one laboratory for fuel marker testing purposes, then each
laboratory would have to separately seek approval for each method it
intends to use. Likewise, if a laboratory chose to use more than one
marker test method, then each method would have to be approved
separately. Separate approval would not be necessary for individual
operators or laboratory instruments within a given laboratory facility.
The method would be approved for use by that laboratory as long as
appropriate quality control procedures were followed.
In developing the precision and accuracy criteria for the sulfur
test method, EPA drew upon the results of an interlaboratory study
conducted by the American Society for Testing and Materials (ASTM) to
support ASTM's standardization of the sulfur test method.
Unfortunately, there has not been sufficient time for industry to
standardize the test procedure used to measure the concentration of
solvent yellow 124 in distillate fuels or to conduct an interlaboratory
study regarding the variability of the method. Nevertheless, the
European Union has been successful in implementing its marker
requirement while relying on the marker test procedures which are
currently available, as noted above. We are proposing to use this
procedure to establish the precision and accuracy criteria on which a
marker test procedure would be approved under the performance-based
approach. We request comment on the suitability of the proposed
reference marker test method, including whether standardized
acceptability criteria exist regarding the visible spectrometer
apparatus and associated measurement procedure used in performing the
test.
There has been substantial experience in the use of the proposed
reference market test method since the August 2002 effective date of
the European Union's marker requirement. However, EPA is aware of only
limited summary data on the variability of the reference test method
from a manufacturer of the visible spectrometer apparatus used in the
testing.\335\ The stated resolution of the test method from in the
materials provided by this equipment manufacturer is 0.1 mg/L, with a
repeatability of plus or minus 0.08 mg/L and a reproducibility of plus
or minus 0.2 mg/L.\336\ In the lack of more extensive data, we propose
to use these available data as the basis of our proposed precision and
accuracy criteria as discussed below. We request that comments which
suggest that these data are unsuitable for the intended use also
include additional test data where possible to improve the derivation
of precision and accuracy criteria.
---------------------------------------------------------------------------
\335\ Technical Data on Fuel/Dye/Marker & Color Analyzers, as
downloaded from the Petroleum Analyzer Company L.P. Web site at
http://www.petroleum-analyzer.com/product/PetroSpec/lit--pspec/
DTcolor.pdf.
\336\ Repeatability and reproducibility are terms related to
test variability. ASTM defines repeatability as the difference
between successive results obtained by the same operator with the
same apparatus under constant operating conditions on identical test
materials that would, in the long run, in the normal and correct
operation of the test method be exceeded only in one case in 20.
Reproducibility is defined by ASTM as the difference between two
single and independent results obtained by different operators
working in different laboratories on identical material that would,
in the long run, be exceeded only in one case in twenty.
---------------------------------------------------------------------------
Using a similar methodology to that employed in deriving the
proposed sulfur test procedure precision value results in a precision
value for the marker test procedure of 0.043 mg/L.\337\ However, we are
concerned that the use of this precision value, because it is based on
very limited data, might preclude the acceptability of test procedures
that would be adequate for the intended regulatory use. In addition,
the lowest measurement of marker concentration that would have
relevance under the regulations is 0.1 mg per liter. Consequently, we
are proposing that the precision of a marker test procedure would need
to be less than 0.1 mg/L for it to qualify. We request comment on this
proposed precision level.
---------------------------------------------------------------------------
\337\ See Section VIII.D. of this proposal for a discussion of
the methodology used in deriving the proposed precision and accuracy
values for the sulfur test method.
---------------------------------------------------------------------------
We are proposing that to demonstrate the accuracy of a given test
method, a laboratory facility would be required to perform 10 repeat
tests, the mean of which could not deviate from the Accepted Reference
Value (ARV) of the standard by more than 0.05 mg/L. We believe that the
proposed accuracy level is not overly restrictive, while being
sufficiently protective considering that the lowest marker level of
regulatory significance would be 0.1 mg/L. Ten tests would be required
using each of two different marker standards, one in the range of 0.1
to 1 mg/L and the other in the range of 4 to 10 mg/L of solvent yellow
124. Therefore, a minimum of 20 total tests would be required for
sufficient demonstration of accuracy for a given marker test method at
a given laboratory facility. Finally, any known interferences for a
given test method would have to be mitigated. We are proposing that
these tests be performed using commercially available solvent yellow
124 standards. Since the European Union's marker requirement would have
been in effect for over six years and we expect this requirement to
continue indefinitely, we believe that such standards would be
available by the implementation date for this proposed rule. We request
comment on this assessment and on whether we should allow facilities
that conduct the proposed tests to blend up their own marker standards
using a pure supply of the fuel marker.
We request comment on the proposed precision and accuracy criteria
described above. These requirements are not intended be overly
burdensome. To the contrary, we believe these requirements are
equivalent to what a laboratory would do during the normal start up
procedure for a given test
[[Page 28509]]
method. In addition, we believe this approach would allow regulated
entities to know that they are measuring fuel marker levels accurately
and within reasonable site reproducibility limits.
2. What Information Would Have To Be Reported to the Agency?
As noted above, the European Union's (EU) marker requirement would
have been in effect for over six years prior to the effective data for
the proposed marker requirements and we expect the EU requirement to
continue indefinitely. Thus, we anticipate that the European testings
standards community will likely have standardized a test procedure to
measure the concentration of solvent yellow 124 in distillate fuels
prior to the implementation of the proposed marker requirement. Given
the limited duration of the proposed marker requirements, we do not
anticipate that the United States testing standards community would
enact such a standardized test procedure. To the extent that marker
test methods that have already been approved by a voluntary consensus
standards body \338\ (VCSB), such as the International Standards
Organization (ISO) or the American Society for Testing and Materials
(ASTM), each laboratory facility would be required to report to the
Agency the precision and accuracy results as described above for each
method for which it is seeking approval. Such submissions to EPA, as
described elsewhere, would be subject to the Agency's review for 30
days, and the method would be considered approved in the absence of EPA
comment. Laboratory facilities would be required to retain the fuel
samples used for precision and accuracy demonstration for a limited
amount of time (e.g., 30 days).
---------------------------------------------------------------------------
\338\ These are standard-setting organizations, like ASTM, and
ISO that have broad representation of all interested stakeholders
and make decisions by consensus.
---------------------------------------------------------------------------
For test methods that have not been approved by a VCSB, full test
method documentation, including a description of the technology/
instrumentation that makes the method functional, as well as subsequent
EPA approval of the method would also be required. These submissions
would also be subject to the Agency's review for 60 days, and the
method would be considered approved in the absence of EPA comment.
Submission of VCSB methods would not be required since they are
available in the public domain. In addition, industry and the Agency
have likely had substantial experience with such methods.
To assist the Agency in determining the performance of a given
marker test method (non-VCSB methods, in particular), we propose to
reserve the right to send samples of commercially available fuel to
laboratories for evaluation. Such samples would be intended for
situations in which the Agency had concerns regarding a test method
and, in particular, its ability to measure the marker content of a
random commercially available diesel fuel. Laboratory facilities would
be required to report their results from three tests of this material
to the Agency.
Given the limited duration of the proposed marker requirements, we
are proposing that qualified test methods would remain valid for as
long as the marker requirements remained in effect, provided that
additional faults with the test method were not discovered. We are also
proposing that ongoing Quality Control (QC) procedures for marker
measurement instrumentation similar to those that we proposed for the
sulfur test procedures in Section VIII.D above. We request comment on
whether such QC procedures are needed for the marker test method.
F. Requirements for Recordkeeping, Reporting, and Product Transfer
Documents
1. Registration of Refiners and Importers
By December 31, 2004, refiners and importers that may produce or
supply NRLM diesel fuel by June 1, 2007 would be required to register
with EPA. There would be no need to register if a refiner (and all its
refineries), or an importer, is already registered under the highway
diesel program. The registration would include the following
information:
[sbull] Corporate name and address of the refiner or importer and
any parent companies and a contact person.
[sbull] Name and address of all refineries or import facilities
(including, for importers, the PADD(s)).
[sbull] A contact person.
[sbull] Location of records.
[sbull] Business activity (refiner or importer).
[sbull] Capacity of each refinery in barrels of crude oil per
calendar day.
2. Application for Small Refiner Status
We propose that an application of a refiner for small refiner
status be submitted to EPA by June 1, 2005 and include the following
information:
[sbull] The name and address of each location at which any employee
of the company, including any parent companies or subsidiaries,\339\
worked during the 12 months preceding January 1, 2003;
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\339\ ``Subsidiary'' here covers entities of which the parent
company has 50 percent or greater ownership.
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[sbull] The average number of employees at each location, based on
the number of employees for each of the company's pay periods for the
12 months preceding January 1, 2003;
[sbull] The type of business activities carried out at each
location; and
[sbull] The total crude oil refining capacity of the corporation.
We define total capacity as the sum of all individual refinery
capacities for multiple-refinery companies, including any and all
subsidiaries, as reported to the Energy Information Administration
(EIA) for 2002, or in the case of a foreign refiner, a comparable
reputable source, such as professional publication or trade
journal.\340\ Refiners do not need to include crude oil capacity used
in 2002 through a lease agreement with another refiner in which it has
no ownership interest.
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\340\ We will evaluate each foreign refiner's documentation of
crude oil capacity on an individual basis.
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The crude oil capacity information reported to the EIA or
comparable reputable source is presumed to be correct. However, in
cases where a company disputes this information, we propose to allow 60
days after the company submits its application for small refiner status
for that company to petition us with detailed data it believes shows
that the EIA or other source's data was in error. We would consider
this data in making a final determination about the refiner's crude oil
capacity.
Small refinery facilities could not be approved for small refiner
status unless the refinery produces diesel fuel from crude oil. This is
because a small refiner's relief is intended to address the hardship
encountered in making capital improvements to a crude oil refinery. No
such costs are involved in operations that only blend previously
refined products.
3. Applying for Refiner Hardship Relief
As discussed above in Section IV.C.2, a refiner seeking general
hardship relief under the proposed program would apply to EPA and
provide several types of financial and technical information, such as
internal cash flow data and information on bank loans, bonds, and
assets as well as detailed engineering and construction plans and
permit status. Applications for hardship relief would be due June 1,
2005.
[[Page 28510]]
4. Applying for a Non-Highway Distillate Baseline Percentage
As discussed in section IV above, we are proposing that refiners or
importers wishing to fungibly distribute highway and NRLM fuel from any
refinery or import facility apply to EPA for a non-highway baseline
percentage for each such refinery or facility. Refiners or importers
would provide EPA with data to quantify its annual average production
or importation of distillate that was dyed for use in any non-highway
application for each year during the period from January 1, 2003
through December 31, 2005. Specifically, this data would consist of the
following for each batch of diesel fuel during this period:
[sbull] The date the refiner finished production of the batch
[sbull] The volume of the batch
[sbull] Whether the fuel in the batch was dyed
We propose that applications for non-highway baselines be submitted
to EPA by February 28, 2006. We would act on these baselines by June 1,
2006, in time for the refiner or importer to earn early credits if they
wished.
5. Pre-Compliance Reports
We believe that an early general understanding of the progress of
the refining industry in complying with the proposed requirements would
be valuable to both the affected industries and EPA. As with the
highway diesel program, we propose that each refiner and importer
provide annual reports on the progress of and plans for each of their
refineries or import facilities. These pre-compliance reports would be
required by June 1 of each year beginning in 2005 and continuing up
through 2010, or until the entity produced or imported any 15 ppm
nonroad fuel, whichever is later.
EPA would maintain the confidentiality of information submitted in
pre-compliance reports to the full extent authorized by law. We would
report generalized summaries of this data following the receipt of the
pre-compliance reports. We recognize that plans may change for many
refiners or importers as the compliance dates approach. Thus,
submission of the report would not impose an obligation to follow
through on plans projected in the pre-compliance reports.
Pre-compliance reports could, at the discretion of the refiner/
importer, be submitted in conjunction with the annual compliance
reports proposed below and/or the pre-compliance and annual compliance
reports required under the highway diesel program, so long as all
information required in all reports is clearly provided.
In their pre-compliance reports, refiners and importers would need
to include the following information:
[sbull] Any changes in their basic corporate or facility
information since registration.
[sbull] Estimates of the volumes (in gallons) of each sulfur grade
of highway and non-highway fuel produced (or imported) at each refinery
(or facility). These volume estimates would be provided both for fuel
produced from crude oil, as well as any fuel produced from other
sources.
[sbull] For entities expecting to participate in the credit
program, estimates of numbers of credits to be earned and/or used.
[sbull] Information regarding engineering plans such as design and
construction, the status of obtaining any necessary permits, and
capital commitments for making the necessary modifications to produce
low sulfur nonroad diesel fuel, and actual construction progress.
[sbull] The pre-compliance reports in 2006 and later years must
provide an update of the progress in each of these areas.
6. Annual Compliance Reports and Batch Reports for Refiners and
Importers
After the nonroad diesel sulfur requirements begin on June 1, 2007,
refiners and importers would be required to submit annual compliance
reports for each refinery that demonstrated compliance with the
proposed requirements. If a refiner produces 15 ppm or 500 ppm fuel
early under the credit provisions, its annual compliance reporting
requirement would begin on June 1 following the beginning of the early
fuel production. These reporting requirements would sunset after all
flexibility provisions end (i.e., 2012 for non-small refiners and 2014
for small refiners). Annual compliance reports would be due on August
31 of the year.
A refiner's (for each refinery) or importer's annual compliance
report would include the following information:
[sbull] Report demonstrating compliance with the applicable sulfur
content requirements using the non-highway baseline percentage approach
or demonstrating compliance using an alternative compliance option
e.g., a small refiner option or the option to dye all nonroad,
locomotive/marine diesel fuel at the refinery, as applicable.
[sbull] Report on the generation, use, transfer and retirement of
diesel sulfur credits. Credit transfer information would include the
identification of the number of credits obtained from, or transferred
to, each entity. Reports would also show the credit balance at the
start of the period, and the balance at the end of the period. NRLM or
nonroad diesel sulfur credit information would be required to be stated
separately from highway diesel credit information since the 2 credit
programs would be treated separately.
[sbull] Batch reports for each batch produced or imported providing
information regarding volume, sulfur level, cetane/aromatics standard
compliance and whether the fuel was dyed and/or marked. The
certification that fuel was marked with the specified chemical marker
at the refinery or import facility would apply to heating oil for the
period June 1, 2007 through June 1, 2010 and to locomotive and marine
fuel for the period June 1, 2010 through June 1, 2014.
[sbull] For a small refiner that elects to produce 15 ppm nonroad
diesel fuel by June 1, 2006 and therefore is eligible for a limited
relaxation in its interim small refiner gasoline sulfur standards, the
annual reports would also include specific information on gasoline
sulfur levels and progress toward highway and nonroad diesel
desulfurization.
7. Product Transfer Documents (PTDs)
Today we are proposing that refiners and importers must provide
information on commercial PTDs that would identify diesel fuel
distributed for use in nonroad, locomotive, or marine equipment or
motor vehicles, as appropriate, and state which sulfur standard the
fuel is subject to. PTDs must state whether NRLM fuel complies with the
500 ppm sulfur standard or the 15 ppm sulfur standard. This would
continue to be necessary even after 2010, since locomotive and marine
engines could still use 500 ppm diesel fuel after all nonroad equipment
would have to use 15 ppm fuel. Until all highway fuel sulfur content
must meet the 15 ppm sulfur standard in 2010, it would be necessary for
PTDs to indicate if 500 ppm fuel is dyed or undyed, and in all cases,
PTDs would need to indicate if 15 ppm fuel is dyed or undyed, so that
its appropriate use can be determined by transferees. Moreover, some
nonroad diesel fuel, such as segregated small refiner fuel, could
exceed the 15 ppm standard until as late as August 31, 2014; however,
it could only be used in model year 2010 and earlier nonroad diesel
engines.
We believe this additional information on commercial PTDs is
necessary because of the importance of keeping the several sulfur
grades and uses of diesel fuel separate from one
[[Page 28511]]
another in the distribution system. Each party in the system would
better be able to identify which type of fuel it is dealing with and
could more effectively ensure that they were meeting the proposed
requirements of the program. This in turn would help ensure that
misfueling of sulfur sensitive engines does not occur and that the
program would otherwise result in the needed emission reductions.
Except for transfers to truck carriers, retailers and wholesale
purchaser-consumers, this proposal would allow use of product codes to
convey the information. We believe that more explicit language on PTDs
to these parties is necessary since employees of such parties are less
likely to be aware of the meaning of product codes. PTDs would not be
required for transfers of product into nonroad, locomotive, or marine
equipment at retail outlets or wholesale purchaser-consumer facilities.
a. The Period From June 1, 2007 through May 31, 2010
During the first years of the program, unique PTDs would be
required to distinguish the types of fuel that could be produced and
sold and any restrictions on its use \341\:
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\341\ Note that for each time period discussed in this
subsection, we expect few if any areas would be supplied with all
the potential types of fuel listed.
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[sbull] Undyed 500 ppm fuel.
[sbull] Undyed 15 ppm fuel.
[sbull] Dyed 500 ppm fuel (not for use in highway vehicles).
[sbull] Dyed 15 ppm fuel (not for use in highway vehicles).
[sbull] Dyed high-sulfur fuel (not for use in highway vehicles or
certain nonroad engines).
[sbull] Marked heating oil (not for use in NRLM equipment or
highway vehicles).
b. The Period from June 1, 2010 through May 31, 2014
Beginning June 1, 2010, unique PTDs would be required to
distinguish the types of fuel that could be produced and sold during
this period:
[sbull] Undyed 15 ppm.
[sbull] Dyed 15 ppm fuel (not for use in highway vehicles).
[sbull] Dyed 500 ppm fuel (not for use in model year 2011 and later
nonroad engines, or highway vehicles).
[sbull] Marked 500 ppm locomotive and marine fuel (not for use in
nonroad equipment or highway vehicles).
[sbull] Heating oil (not for use in NRLM equipment or highway
vehicles).
c. The Period After May 31, 2014
Beginning June 1, 2014, unique PTDs would be required to
distinguish remaining types of fuel that could be produced and sold
during this period.
[sbull] Undyed 15 ppm fuel.
[sbull] Dyed 15 ppm fuel (not for use in highway vehicles).
[sbull] 500 ppm locomotive and marine fuel (not for use in nonroad
equipment or highway vehicles).
[sbull] Heating oil (not for use in highway vehicles or NRLM
equipment).
d. Kerosene and Other Distillates To Reduce Viscosity
To assure that downstream parties can determine the sulfur level of
kerosene or other distillates that may be distributed for use for
blending into 15 ppm highway or NRLM diesel fuel, e.g. to reduce
viscosity in cold weather, this proposal would require that PTDs
identify distillates specifically distributed for such use as meeting
the 15 ppm standard.
e. Exported Fuel
Consistent with other fuels rules, NRLM diesel fuel to be exported
from the U.S. would not be required to meet the sulfur content
requirements of the proposed regulations. For example, where a refiner
designates a batch of diesel fuel for export, and can demonstrate
through commercial documents that the fuel was exported, that volume
would not be used in calculating compliance with applicable baselines.
Product transfer documents accompanying the transfer of custody or
title to such fuel at each point in the distribution system would be
required to state that the fuel is for export only and may not be used
in the United States.
f. Additives
This proposal would require that PTDs for additives for use in
nonroad diesel fuel state whether the additive complies with the 15 ppm
sulfur standard. Like the highway diesel rule, this proposal would
allow the sale of additives, for use by fuel terminals or other parties
in the diesel fuel distribution system, that have a sulfur content
greater than 15 ppm under specified conditions.
Under this proposal for additives that have a sulfur content not
exceeding 15 ppm, the PTD would state: ``The sulfur content of this
additive does not exceed 15 ppm.''. For additives that have a sulfur
content exceeding 15 ppm, the additive manufacturer's PTD, and PTDs
accompanying all subsequent transfers, would provide: a warning that
the additive's sulfur content exceeds 15 ppm; the maximum sulfur
content of the additive; the maximum recommended concentration for use
of the additive in diesel fuel, stated as gallon of additive per gallon
of diesel fuel; and the increase in sulfur concentration of the fuel
the additive will cause when used at the maximum recommended
concentration.
We are also proposing provisions for additives sold to owner/
operators for use in diesel powered nonroad equipment. This is because
of the concern that additives designed for engines not requiring 15 ppm
sulfur content fuel, such as locomotives or marine engines, could
accidentally be introduced into nonroad engines if they have no label
stating appropriate use. Under this proposal, end user additives for
use in highway or NRLM diesel engines would be required to be
accompanied by information that states that the additive either:
complies with the 15 ppm sulfur content requirements or that it has a
sulfur content exceeding 15 ppm and is not for use in model year 2011
or later nonroad diesel equipment. We believe this information is
necessary for end users to determine if an additive is appropriate for
nonroad equipment use.
8. Recordkeeping Requirements
Under the highway rule, refiners that produce or importers that
import highway diesel fuel must maintain the following records for each
batch of diesel fuel produced or imported) The batch designations; the
applicable sulfur content standard; whether the fuel is dyed or undyed;
whether the fuel is marked or unmarked; the batch volumes; whether the
fuel was dyed or undyed, and sampling and testing records. The refiner
or importer would also be required to maintain records regarding credit
generation, use, transfer, purchase, or termination, separately for
highway and nonroad credit programs.
We propose that these requirements from the highway rule be applied
to all nonroad, locomotive, and marine diesel fuel subject to this rule
as well.
9. Record Retention
This proposal would adopt a retention period of 5 years for all
records required to be kept by the rule. This is the same period of
time required in other fuels rules, and it coincides with the
applicable statute of limitations. We believe that for other reasons,
most parties in the distribution system would maintain some or all of
these records for this length of time even without the requirement.
This retention period would apply to PTDs, records of any test
results performed by any regulated party for quality assurance purposes
or otherwise
[[Page 28512]]
(whether or not such testing was required by this rule), along with
supporting documentation such as date of sampling and testing, batch
number, tank number, and volume of product. Business records regarding
actions taken in response to any violations discovered would also be
required to be maintained for 5 years.
All records required to be maintained by refiners or importers
participating in the generation or use of credits, hardship options (or
by importers of diesel fuel produced by a foreign refiner approved for
the temporary compliance option or a hardship option), including small
refiner options, would also be covered by the retention requirement.
G. Liability and Penalty Provisions for Noncompliance
1. General
The liability and penalty provisions of the proposed NRLM diesel
sulfur rule would be very similar to the liability and penalty
provisions found in the highway diesel sulfur rule, the gasoline sulfur
rule, the RFG rule and other EPA fuels regulations.\342\ Regulated
parties would be subject to prohibitions which are typical in EPA fuels
regulations, such as prohibitions on selling or distributing fuel that
does not comply with the applicable standard, and causing others to
commit prohibited acts. Liability would also arise under the NRLM
diesel rule for prohibited acts specific to the diesel sulfur control
program, such as introducing nonroad diesel fuel not meeting the 15 ppm
sulfur standard into model year 2011 or later nonroad equipment. In
addition, parties would be liable for a failure to meet certain
requirements, such as the recordkeeping, reporting, or PTD
requirements, or causing others to fail to meet such requirements.
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\342\ See section 80.5 (penalties for fuels violations); section
80.23 (liability for lead violations); section 80.28 (liability for
gasoline volatility violations); section 80.30 (liability for
highway diesel violations); section 80.79 (liability for violation
of RFG prohibited acts); section 80.80 (penalties for RFG/CG
violations); section 80.395 (liability for gasoline sulfur
violations); section 80.405 (penalties for gasoline sulfur
regulations).; and section 80.610-614 (prohibited acts, liability
for violations, and penalties for highway diesel sulfur
regulations).
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Under this proposal, the party in the diesel fuel distribution
system that controls the facility where a violation occurred, and other
parties in that fuel distribution system (such as the refiner,
reseller, and distributor), would be presumed to be liable for the
violation.\343\ As in the Tier 2 gasoline sulfur rule and the highway
diesel fuel rule, the proposed rule would explicitly prohibit causing
another person to commit a prohibited act or causing non-conforming
diesel fuel to be in the distribution system. Non-conforming includes:
(1) diesel fuel with sulfur content above 15 ppm incorrectly designated
as appropriate for model year 2011 or later nonroad equipment or other
engines requiring 15 ppm fuel; (2) diesel fuel with sulfur content
above 500 ppm incorrectly designated as appropriate for nonroad
equipment or locomotives or marine engines after the applicable date
for the 500 ppm standard for these pieces of equipment; or (3)
distillates not containing required markers or otherwise not complying
with the requirements of this proposal. Parties outside the diesel fuel
distribution system, such as diesel additive manufacturers and
distributors, would also be subject to liability for those diesel rule
violations which could have been caused by their conduct.
---------------------------------------------------------------------------
\343\ An additional type of liability, vicarious liability, is
also imposed on branded refiners under the proposal.
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This proposal also would provide affirmative defenses for each
party presumed liable for a violation, and all presumptions of
liability would be rebuttable. In general, in order to rebut the
presumption of liability, parties would be required to establish that:
(1) the party did not cause the violation; (2) PTD(s) exist which
establish that the fuel or diesel additive was in compliance while
under the party's control; and (3) the party conducted a quality
assurance sampling and testing program. As part of their affirmative
defense diesel fuel refiners or importers, diesel fuel additive
manufacturers, and blenders of high sulfur additives into diesel fuel,
would also be required to provide test results establishing the
conformity of the product prior to leaving that party's control.
Branded refiners would have additional affirmative defense elements to
establish. The proposed defenses under the nonroad diesel sulfur rule
are similar to those available to parties for violations of the highway
diesel sulfur, RFG, gasoline volatility, and the gasoline sulfur
regulations. This proposed rule would also clarify that parent
corporations are liable for violations of subsidiaries, in a manner
consistent with the gasoline sulfur rule and the highway diesel sulfur
rule. Finally, the proposed NRLM diesel sulfur rule mirrors the
gasoline sulfur rule and the highway diesel sulfur rule by clarifying
that each partner to a joint venture would be jointly and severally
liable for the violations at the joint venture facility or by the joint
venture operation.
As is the case with the other EPA fuels regulations, the proposed
diesel sulfur rule would apply the provisions of section 211(d)(1) of
the Clean Air Act (Act) for the collection of penalties. These penalty
provisions currently subject any person that violates any requirement
or prohibition of the diesel sulfur rule to a civil penalty of up to
$31,500 for every day of each such violation and the amount of economic
benefit or savings resulting from the violation. A violation of a NRLM
diesel sulfur standard would constitute a separate day of violation for
each day the diesel fuel giving rise to the violation remains in the
fuel distribution system. Under the proposed regulation, the length of
time the diesel fuel in question remains in the distribution system is
deemed to be twenty-five days unless there is evidence that the fuel
remained in its distribution system a lesser or greater amount of time.
This is the same time presumption that is incorporated in the RFG,
gasoline sulfur and highway diesel sulfur rules. The penalty provisions
would also be similar to the penalty provisions for violations of these
regulations.
EPA has included in this proposal two prohibitions for ``causing''
violations: (1) causing another to commit a violation; and (2) causing
non-complying diesel fuel to be in the distribution system. These
causation prohibitions are like similar prohibitions included in the
gasoline sulfur and the highway diesel sulfur regulations, and, as
discussed in the preamble to those rules, EPA believes they are
consistent with EPA's implementation of prior motor vehicle fuel
regulations. See the liability discussion in the preamble to the
gasoline sulfur final rule, at 65 FR 6812 et seq.
The prohibition against causing another to commit a violation would
apply where one party's violation is caused by the actions of another
party. For example, EPA may conduct an inspection of a terminal and
discover that the terminal is offering for sale nonroad diesel fuel
designated as complying with the 15 ppm sulfur standard, while it, in
fact, had an actual sulfur content greater than the standard.\344\ In
this scenario, parties in the fuel distribution system, as well as
parties in the distribution system of any diesel additive that had been
blended into the fuel, would be presumed liable
[[Page 28513]]
for causing the terminal to be in violation. Each party would have the
right to present an affirmative defense to rebut this presumption.
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\344\ At downstream locations the violation would occur if EPA's
test result showed a sulfur content of greater than 17 ppm, which
takes into account the two ppm adjustment factor for testing
reproducibility for downstream parties.
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The prohibition against causing non-complying diesel fuel to be in
the distribution system would apply, for example, if a refiner
transfers non-complying diesel fuel to a pipeline. This prohibition
could encompass situations where evidence shows high sulfur diesel fuel
was transferred from an upstream party in the distribution system, but
EPA may not have test results to establish that parties downstream also
violated a prohibited act with this fuel.
The Agency would expect to enforce the liability scheme of the NRLM
diesel sulfur rule in the same manner that we have enforced the similar
liability schemes in our prior fuels regulations. As in other fuels
programs, we would attempt to identify the party most responsible for
causing the violation, recognizing that party should primarily be
liable for penalties for the violation.
2. What Are the Proposed Liability Provisions for Additive
Manufacturers and Distributors, and Parties That Blend Additives Into
Diesel Fuel?
a. General
The final highway diesel rule permits the blending of diesel
additives with sulfur content in excess of 15 ppm into 15 ppm highway
diesel fuel under limited circumstances. As more fully discussed
earlier in this preamble, this proposed rule would permit downstream
parties to blend fuel additives having a sulfur content exceeding 15
ppm into 15 ppm nonroad diesel, provided that: (1) The blending of the
additive does not cause the diesel fuel's sulfur content to exceed the
15 ppm sulfur standard; (2) the additive is added in an amount no
greater than one volume percent of the blended product; and (3) the
downstream party obtained from its additive supplier a product transfer
document (``PTD'') with the additive's sulfur content and the
recommended treatment rate, and that it complied with such treatment
rate.
Since the proposed rule would permit the limited use in nonroad
diesel fuel of additives with high sulfur content, the Agency believes
it would be more likely that a diesel fuel sulfur violation could be
caused by the use of high sulfur additives. This could result from the
additive manufacturer's misrepresentation or inaccurate statement of
the additive's sulfur content or recommended treat rate on the
additive's PTD, or an additive distributor's contamination of low
sulfur additives with high sulfur additives during transportation. The
increased probability that parties in the diesel additive distribution
system could cause a violation of the sulfur standard warrants the
imposition by the Agency of increased liability for such parties.
Therefore, the proposed rule, like the final highway diesel rule, would
explicitly make parties in the diesel additive distribution system
liable for the sale of nonconforming diesel fuel additives, even if
such additives have not yet been blended into diesel fuel. In addition,
the proposed rule would impose presumptive liability on parties in the
additive distribution system if diesel fuel into which the additive has
been blended is determined to have a sulfur level in excess of its
permitted concentration. This presumptive liability would differ
depending on whether the blended additive was designated as meeting the
15 ppm sulfur standard (a ``15 ppm additive'') or designated as a
greater than 15 ppm sulfur additive (a ``high sulfur additive''), as
discussed below.
b. Liability When the Additive Is Designated as Complying With the 15
ppm Sulfur Standard
Additives blended into diesel fuel downstream of the refinery would
be required to have a sulfur content no greater than 15 ppm, and be
accompanied by PTD(s) accurately identifying them as complying with the
15 ppm sulfur standard, with the sole exception of diesel additives
blended into nonroad diesel fuel at a concentration no greater than one
percent by volume of the blended fuel.
All parties in the fuel and additive distribution systems would be
subject to presumptive liability if the blended fuel exceeds the sulfur
standard. The two ppm downstream adjustment would apply when EPA tests
the fuel subject to the 15 ppm sulfur standard. Low sulfur additives
present a less significant threat to diesel fuel sulfur compliance than
would occur with the use of additives designated as possibly exceeding
15 ppm sulfur. Thus, parties in the additive distribution system of the
low sulfur additive could rebut the presumption of liability by showing
the following: (1) Additive distributors would only be required to
produce PTDs stating that the additive complies with the 15 ppm sulfur
standard; (2) additive manufacturers would also be required to produce
PTDs complying in an accurate manner with the regulatory requirements,
as well as producing test results, or retained samples on which tests
could be run, establishing the additive's compliance with the 15 ppm
sulfur standard prior to leaving the manufacturer's control. Once their
presumptive liability was refuted by producing such documentation in a
convincing manner, these additive system parties would only be held
responsible for the diesel fuel non-conformity in situations in which
EPA can establish that the party actually caused the violation.
Under this proposed rule, parties in the diesel fuel distribution
system would have the typical affirmative defenses of other fuels
rules. For parties blending an additive into their diesel fuel, the
requirement of producing PTDs showing that the product complied with
the regulatory standards would necessarily include PTDs for the
additive that was used, affirming the compliance of the additive and
the fuel.
c. Liability When The Additive Is Designated as Having a Possible
Sulfur Content Greater Than 15 ppm
Under this proposed rule, a nonroad diesel additive would be
permitted to have a maximum sulfur content above 15 ppm if the blended
fuel continues to meet the 15 ppm standard and the additive is used at
a concentration no greater than one volume percent of the blended fuel.
However, if nonroad diesel fuel containing that additive is found by
EPA to have high sulfur content, then all the parties in both the
additive and the fuel distribution chains would be presumed liable for
causing the nonroad diesel fuel violation.
Since this type of high sulfur additive presents a much greater
probability of causing diesel fuel non-compliance, parties in the
additive's distribution system would have to satisfy an additional
element to establish an affirmative defense. In addition to the
elements of an affirmative defense described above, parties in the
additive distribution system for such a high sulfur additive would also
be required to establish that they did not cause the violation, an
element of an affirmative defense that is typically required in EPA
fuel programs to rebut presumptive liability.
Parties in the diesel fuel distribution system would essentially
have to establish the same affirmative elements as in other fuels
rules, with an addition comparable to the highway diesel rule. Blenders
of high sulfur additives into 15 ppm sulfur nonroad diesel fuel, would
have to establish a more rigorous quality control program than would
exist without the addition of such a high sulfur additive. The Agency
believes that parties blending high sulfur additives into their 15 ppm
sulfur nonroad diesel fuel should be required
[[Page 28514]]
to produce test results establishing that the blended fuel was in
compliance with the 15 ppm sulfur standard after being blended with the
high sulfur additive. This additional defense element would be required
as an added safeguard to ensure nonroad diesel fuel compliance, since
the blender has voluntarily chosen to use an additive which increases
the risk of diesel fuel non-compliance.
H. How Would Compliance With the Sulfur Standards Be Determined?
EPA is today proposing that compliance with the diesel sulfur
standards would be determined based on the sulfur level of the diesel
fuel, as measured using a testing methodology approved under the
provisions discussed in Section VIII.D of this preamble. We further
propose that any evidence from any source or location could be used to
establish the diesel fuel sulfur level, provided that such evidence is
relevant to whether the level would have been in compliance if the
regulatory sampling and testing methodology had been correctly
performed. This is consistent with the approach taken under the
gasoline sulfur rule and the highway diesel sulfur rule.
The proposed regulations would provide that the primary determinant
of compliance with the sulfur standards would be use of an approved
test method. Additionally, other information could be used under the
proposed rule, including test results using a non-approved method, if
the evidence is relevant to determining whether the sulfur level would
meet applicable standards had compliance been determined using an
approved test methodology. While the use of such a non-approved method
might produce results relevant to determining sulfur content, this
would not remove any liability for failing to conduct required batch
testing using an approved test method.
For example, the Agency might not have sulfur results derived from
an approved test method for diesel fuel sold by a terminal, yet the
terminal's own test results, based on testing using methods other than
those approved under the regulations, could reliably show an exceedence
of the sulfur standard. Under this proposed rule, evidence from the
non-approved test method could be used to establish the diesel fuel's
sulfur level that would have resulted if an approved test method had
been conducted. This type of evidence is available for use by either
the EPA or the regulated party, and could be used to show either
compliance or noncompliance. Similarly, absent the existence of sulfur
test results using an approved method, commercial documents asserting
the sulfur level of diesel fuel or additive could be used as some
evidence of what the sulfur level of the fuel would be if the product
would have been tested using an approved method.
The Agency believes that the same statutory authority for EPA to
adopt the gasoline sulfur rule's evidentiary provisions, Clean Air Act
section 211(c), provides appropriate authority for our proposal of the
evidentiary provisions of today's diesel sulfur rule. For a fuller
explanation of this statutory authority, see Section VI(I) of the
gasoline sulfur final rule preamble, 65 FR 6815, February 10, 2000.
IX. Public Participation
We request comment on all aspects of this proposal. This section
describes how you can participate in this process.
A. How and to Whom Do I Submit Comments?
We are opening a formal comment period by publishing this document.
We will accept comments for the period indicated under DATES above. If
you have an interest in the program described in this document, we
encourage you to comment on any aspect of this rulemaking. We request
comment on various topics throughout this proposal.
Your comments will be most useful if you include appropriate and
detailed supporting rationale, data, and analysis. If you disagree with
parts of the proposed program, we encourage you to suggest and analyze
alternate approaches to meeting the air quality goals described in this
proposal. You should send all comments, except those containing
proprietary information, to our Air Docket (see Addresses) before the
end of the comment period.
You may submit comments electronically, by mail, or through hand
delivery/courier. To ensure proper receipt by EPA, identify the
appropriate docket identification number in the subject line on the
first page of your comment. Please ensure that your comments are
submitted within the specified comment period. Comments received after
the close of the comment period will be marked ``late.'' EPA is not
required to consider these late comments. If you wish to submit CBI or
information that is otherwise protected by statute, please follow the
instructions in Section IX.B. Do not use EPA Dockets or e-mail to
submit CBI or information protected by statute.
1. Electronically
If you submit an electronic comment as prescribed below, EPA
recommends that you include your name, mailing address, and an e-mail
address or other contact information in the body of your comment. Also
include this contact information on the outside of any disk or CD ROM
you submit, and in any cover letter accompanying the disk or CD ROM.
This ensures that you can be identified as the submitter of the comment
and allows EPA to contact you in case EPA cannot read your comment due
to technical difficulties or needs further information on the substance
of your comment. EPA's policy is that EPA will not edit your comment,
and any identifying or contact information provided in the body of a
comment will be included as part of the comment that is placed in the
official public docket, and made available in EPA's electronic public
docket. If EPA cannot read your comment due to technical difficulties
and cannot contact you for clarification, EPA may not be able to
consider your comment.
i. EPA Dockets
Your use of EPA's electronic public docket to submit comments to
EPA electronically is EPA's preferred method for receiving comments. Go
directly to EPA Dockets at http://www.epa.gov/edocket, and follow the
online instructions for submitting comments. To access EPA's electronic
public docket from the EPA Internet Home Page, select ``Information
Sources,'' ``Dockets,'' and ``EPA Dockets.'' Once in the system, select
``Quick Search,'' and then key in Docket ID No. OAR-2003-0012. The
system is an ``anonymous access'' system, which means EPA will not know
your identity, e-mail address, or other contact information unless you
provide it in the body of your comment.
ii. E-mail
Comments may be sent by electronic mail (e-mail) to [email protected],
Attention Docket ID No. A-2001-28. In contrast to EPA's electronic
public docket, EPA's e-mail system is not an ``anonymous access''
system. If you send an e-mail comment directly to the Docket without
going through EPA's electronic public docket, EPA's e-mail system
automatically captures your e-mail address. E-mail addresses that are
automatically captured by EPA's e-mail system are included as part of
the comment that is placed in the official public docket, and made
available in EPA's electronic public docket.
[[Page 28515]]
iii. Disk or CD ROM
You may submit comments on a disk or CD ROM that you mail to the
mailing address identified in Section IX.A.2 below. These electronic
submissions will be accepted in WordPerfect or ASCII file format. Avoid
the use of special characters and any form of encryption.
2. By Mail
Send your comments to: Air Docket, Environmental Protection Agency,
Mailcode: 6102T, 1200 Pennsylvania Ave., NW., Washington, DC, 20460,
Attention Docket ID No. A-2001-28.
3. By Hand Delivery or Courier
Deliver your comments to: EPA Docket Center, (EPA/DC) EPA West,
Room B102, 1301 Constitution Ave., NW., Washington, DC., Attention
Docket ID No. A-2001-28. Such deliveries are only accepted during the
Docket's normal hours of operation from 8:30 a.m. to 4:30 p.m., Monday
through Friday, excluding legal holidays.
B. How Should I Submit CBI to the Agency?
Do not submit information that you consider to be CBI
electronically through EPA's electronic public docket or by e-mail.
Send or deliver information identified as CBI only to the following
address: U.S. Environmental Protection Agency, Assessment and Standards
Division, 2000 Traverwood Drive, Ann Arbor, MI, 48105, Attention Docket
ID No. A-2001-28. You may claim information that you submit to EPA as
CBI by marking any part or all of that information as CBI (if you
submit CBI on disk or CD ROM, mark the outside of the disk or CD ROM as
CBI and then identify electronically within the disk or CD ROM the
specific information that is CBI). Information so marked will not be
disclosed except in accordance with procedures set forth in 40 CFR part
2.
In addition to one complete version of the comment that includes
any information claimed as CBI, a copy of the comment that does not
contain the information claimed as CBI must be submitted for inclusion
in the public docket and EPA's electronic public docket. If you submit
the copy that does not contain CBI on disk or CD ROM, mark the outside
of the disk or CD ROM clearly that it does not contain CBI. Information
not marked as CBI will be included in the public docket and EPA's
electronic public docket without prior notice. If you have any
questions about CBI or the procedures for claiming CBI, please consult
the person identified in the FOR FURTHER INFORMATION CONTACT section.
C. Will There Be a Public Hearing?
We will hold three public hearings; in Los Angeles, Chicago, and
New York City. The hearings will be held on the following dates and
start at the following times, and continue until everyone present has
had an opportunity to speak.
------------------------------------------------------------------------
Hearing location Date Time
------------------------------------------------------------------------
New York, New York, Park Central June 10, 2003..... 9:00 a.m. EDT.
New York, 870 Seventh Avenue at
56th Street, New York, NY
10019, Telephone: (212) 247-
8000, Fax: (212) 541-8506.
Chicago, Illinois, Hyatt Regency June 12, 2003..... 9:00 a.m. CDT.
O'Hare, 9300 W. Bryn Mawr
Avenue, Rosemont, IL 60018,
Telephone: (847) 696-1234, Fax:
(847) 698-0139.
Los Angeles. California, Hyatt June 17, 2003..... 9:00 a.m. PDT.
Regency Los Angeles, 711 South
Hope Street, Los Angeles,
California, USA. 90017,
Telephone: (213) 683-1234, Fax:
(213) 629-3230.
------------------------------------------------------------------------
If you would like to present testimony at a public hearing, we ask
that you notify the contact person listed above at least ten days
before the hearing. You should estimate the time you will need for your
presentation and identify any needed audio/visual equipment. We suggest
that you bring copies of your statement or other material for the EPA
panel and the audience. It would also be helpful if you send us a copy
of your statement or other materials before the hearing.
We will make a tentative schedule for the order of testimony based
on the notifications we receive. This schedule will be available on the
morning of each hearing. In addition, we will reserve a block of time
for anyone else in the audience who wants to give testimony.
We will conduct the hearing informally, and technical rules of
evidence won't apply. We will arrange for a written transcript of the
hearing and keep the official record of the hearing open for 30 days to
allow you to submit supplementary information. You may make
arrangements for copies of the transcript directly with the court
reporter.
We will conduct the hearing informally, and technical rules of
evidence won't apply. We will arrange for a written transcript of the
hearing and keep the official record of the hearing open for 30 days to
allow you to submit supplementary information. You may make
arrangements for copies of the transcript directly with the court
reporter.
D. Comment Period
The comment period for this rule will end on August 20, 2003.
E. What Should I Consider as I Prepare My Comments for EPA?
You may find the following suggestions helpful for preparing your
comments:
1. Explain your views as clearly as possible.
2. Describe any assumptions that you used.
3. Provide any technical information and/or data you used that
support your views.
4. If you estimate potential burden or costs, explain how you
arrived at your estimate.
5. Provide specific examples to illustrate your concerns.
6. Offer alternatives.
7. Make sure to submit your comments by the comment period deadline
identified.
8. To ensure proper receipt by EPA, identify the appropriate docket
identification number in the subject line on the first page of your
response. It would also be helpful if you provided the name, date, and
Federal Register citation related to your comments.
X. Statutory and Executive Order Reviews
A. Executive Order 12866: Regulatory Planning and Review
Under Executive Order 12866 (58 FR 51735, October 4, 1993), the
Agency must determine whether the regulatory action is ``significant''
and therefore subject to review by the Office of Management and Budget
(OMB) and the requirements of this Executive Order.
[[Page 28516]]
The Executive Order defines a ``significant regulatory action'' as any
regulatory action that is likely to result in a rule that may:
[sbull] Have an annual effect on the economy of $100 million or
more or adversely affect in a material way the economy, a sector of the
economy, productivity, competition, jobs, the environment, public
health or safety, or State, Local, or Tribal governments or
communities;
[sbull] Create a serious inconsistency or otherwise interfere with
an action taken or planned by another agency;
[sbull] Materially alter the budgetary impact of entitlements,
grants, user fees, or loan programs, or the rights and obligations of
recipients thereof; or
[sbull] Raise novel legal or policy issues arising out of legal
mandates, the President's priorities, or the principles set forth in
the Executive Order.
A draft Regulatory Impact Analysis has been prepared and is
available in the docket for this rulemaking and at the internet address
listed under ``How Can I Get Copies of This Document and Other Related
Information?'' above. This action was submitted to the Office of
Management and Budget for review under Executive Order 12866. Estimated
annual costs of this rulemaking are estimated to be $1.2 billion per
year, thus this proposed rule is considered economically significant.
Written comments from OMB and responses from EPA to OMB comments are in
the public docket for this rulemaking.
B. Paperwork Reduction Act
The information collection requirements in this proposed rule have
been submitted for approval to the Office of Management and Budget
(OMB) under the Paperwork Reduction Act, 44 U.S.C. 3501 et seq. The
Agency proposes to collect information to ensure compliance with the
provisions in this rule. This includes a variety of requirements, both
for engine manufacturers and for fuel producers. Information-collection
requirements related to engine manufacturers are in EPA ICR
1897.05; requirements related to fuel producers are in EPA ICR
1718.05. Section 208(a) of the Clean Air Act requires that
manufacturers provide information the Administrator may reasonably
require to determine compliance with the regulations; submission of the
information is therefore mandatory. We will consider confidential all
information meeting the requirements of section 208(c) of the Clean Air
Act.
As shown in Table X-1, the total annual burden associated with this
proposal is about 215,000 hours and $16 million, based on a projection
of 470 respondents. The estimated burden for engine manufacturers is a
total estimate for both new and existing reporting requirements. The
fuel-related requirements represent our first regulation of nonroad
diesel fuel, so those burden estimates reflect only new reporting
requirements. Burden means the total time, effort, or financial
resources expended by persons to generate, maintain, retain, or
disclose or provide information to or for a Federal agency. This
includes the time needed to review instructions; develop, acquire,
install, and utilize technology and systems for the purposes of
collecting, validating, and verifying information, processing and
maintaining information, and disclosing and providing information;
adjust the existing ways to comply with any previously applicable
instructions and requirements; train personnel to be able to respond to
a collection of information; and transmit or otherwise disclose the
information.
Table X-1.--Estimated Burden for Reporting and Recordkeeping
Requirements
------------------------------------------------------------------------
Annual Annual
Industry sector Number of burden costs (in
respondents hours millions)
------------------------------------------------------------------------
Engines.......................... 95 160,000 $12.5
Fuels............................ 375 55,000 3.7
----------------------------------
Total........................ 470 215,000 16.2
------------------------------------------------------------------------
An agency may not conduct or sponsor, and a person is not required
to respond to a collection of information unless it displays a
currently valid OMB control number. The OMB control numbers for EPA's
regulations are listed in 40 CFR part 9 and 48 CFR chapter 15.
Comments are requested on the Agency's need for this information,
the accuracy of the provided burden estimates, and any suggested
methods for minimizing respondent burden, including through the use of
automated collection techniques. Send comments on the ICR to the
Director, Collection Strategies Division; U.S. Environmental Protection
Agency (2822); 1200 Pennsylvania Ave., NW., Washington, DC 20460; and
to the Office of Information and Regulatory Affairs, Office of
Management and Budget, 725 17th St., NW., Washington, DC 20503, marked
``Attention: Desk Officer for EPA.'' Include the ICR number in any
correspondence. Since OMB is required to make a decision concerning the
ICR between 30 and 60 days after May 23, 2003, a comment to OMB is best
ensured of having its full effect if OMB receives it by July 23, 2003.
The final rule will respond to any OMB or public comments on the
information collection requirements contained in this proposal.
C. Regulatory Flexibility Act (RFA), as Amended by the Small Business
Regulatory Enforcement Fairness Act of 1996 (SBREFA), 5 U.S.C. 601 et
seq.
1. Overview
The Regulatory Flexibility Act (RFA) generally requires an agency
to prepare a regulatory flexibility analysis for any rule subject to
notice and comment rulemaking requirements under the Administrative
Procedure Act or any other statute unless the agency certifies that the
rule will not have a significant economic impact on a substantial
number of small entities. Small entities include small businesses,
small organizations, and small governmental jurisdictions.
For the purposes of assessing the impacts of today's rule on small
entities, a small entity is defined as: (1) A small business that meets
the definitions based on the Small Business Administration's (SBA) size
standards (see table below); (2) a small governmental jurisdiction that
is a government of a city, county, town, school district or special
district with a population of less than 50,000; and (3) a small
organization that is any not-for-profit enterprise which is
independently owned and operated and is not dominant in its field. The
following table provides an overview of the primary SBA small business
categories potentially affected by this regulation:
[[Page 28517]]
------------------------------------------------------------------------
Defined as small
Industry entity by SBA if: Major SIC a codes
------------------------------------------------------------------------
Engine manufacturers............ Less than 1,000 Major Group 35.
employees.
Equipment manufacturers:........
--construction equipment.... Less than 750 Major Group 35.
employees.
--industrial truck Less than 750 Major Group 35.
manufacturers (i.e. employees.
forklifts).
--all other nonroad Less than 500 Major Group 35.
equipment manufacturers. employees.
Fuel refiners................... Less than 1500 b.. 2911.
Fuel distributors............... (varies).......... (varies).
------------------------------------------------------------------------
Notes:
a Standard Industrial Classification
b EPA has included in past fuels rulemakings a provision that, in order
to qualify for the small refiner flexibilities, a refiner must also
have a company-wide crude refining capacity of no greater than 155,000
barrels per calendar day. EPA has included this criterion in the small
refiner definition for a nonroad diesel sulfur program as well.
2. Background
Controlling emissions from nonroad engines and equipment, in
conjunction with diesel fuel quality controls, has very significant
public health and welfare benefits, as explained in Section II of this
preamble. We are proposing new engine standards and related provisions
under sections 213(a)(3) and (4) of the Clean Air Act which, among
other things, direct us to establish (and from time to time revise)
emission standards for new nonroad diesel engines. Similarly, section
211(c)(1) authorizes EPA to regulate fuels if any emission product of
the fuel causes or contributes to air pollution that may endanger
public health or welfare, or that may impair the performance of
emission control technology on engines and vehicles.
In accordance with Section 603 of the RFA, EPA prepared an initial
regulatory flexibility analysis (IRFA) that examines the impact of the
proposed rule on small entities along with regulatory alternatives that
could reduce that impact. The IRFA is available for review as part of
the draft RIA for the rule. This is available in the public docket and
is summarized below.
3. Summary of Regulated Small Entities
The following section discusses the small entities directly
regulated by this proposed rule.
a. Nonroad Diesel Engine Manufacturers
Using information from the industry profile that was conducted for
the nonroad diesel sector, EPA identified a total of 61 engine
manufacturers. The top 10 engine manufacturers comprise 80 percent of
the total market, while the other 51 companies make up the remaining 20
percent.\345\ Of the 61 manufacturers, four fit the SBA definition of a
small entity. These four manufacturers were Anadolu Motors, Farymann
Diesel GMBH, Lister-Petter Group, and V & L Tools (parent company of
Wisconsin Motors LLC, formerly ``Wis-Con Total Power''). These
businesses comprise 8 percent of the total engine sales for the year
2000.
---------------------------------------------------------------------------
\345\ All sales information used for this analysis was 2000
data.
---------------------------------------------------------------------------
b. Nonroad Diesel Equipment Manufacturers
To determine the number of equipment manufacturers, EPA also used
the industry profile that was conducted. From this, EPA identified over
700 manufacturers with sales and/or employment data that could be
included in the screening analysis. These businesses included
manufacturers in the construction, agricultural, and outdoor power
equipment (mainly, lawn and garden equipment) sectors of the nonroad
diesel market. The equipment produced by these manufacturers ranged
from small walk-behind equipment (sub-25 hp engines) to large mining
and construction equipment (using engines in excess of 750 hp). Of the
manufacturers with available sales and employment data (approximately
500 manufacturers), small equipment manufacturers represent 68 percent
of total equipment manufacturers (and these manufacturers account for
11 percent of nonroad diesel equipment industry sales). Thus, the
majority of the small entities that could potentially experience a
significant impact as a result of this rulemaking are in the nonroad
equipment manufacturing sector.
c. Nonroad Diesel Fuel Refiners
Our current assessment is that 26 refiners (collectively owning 33
refineries) meet SBA's definition of a small business for the refining
industry. The 33 refineries appear to meet both the employee number and
production volume criteria mentioned above. These small refiners
currently produce approximately 6 percent of the total high-sulfur
diesel fuel. It should be noted that because of the dynamics in the
refining industry (e.g., mergers and acquisitions), the actual number
of refiners that ultimately qualify for small refiner status under a
future nonroad diesel sulfur program could be different than this
initial estimate.
d. Nonroad Diesel Fuel Distributors and Marketers
The industry that transports, distributes, and markets nonroad
diesel fuel encompasses a wide range of businesses, including bulk
terminals, bulk plants, fuel oil dealers, and diesel fuel trucking
operations, and totals thousands of entities that have some role in
this activity. More than 90 percent of these entities would meet small
entity criteria. Common carrier pipeline companies are also a part of
the distribution system; 10 of them are small businesses.
4. Potential Reporting, Recordkeeping, and Compliance
As with any emission control program, the Agency must have the
assurance that the regulated entities will meet the emissions standards
and all related provisions. For engine and equipment manufacturers, EPA
is proposing to continue the reporting, recordkeeping, and compliance
requirements prescribed for these categories in 40 CFR part 89. Key
among these are certification requirements and provisions related to
reporting of production, emissions information, use of transition
provisions, etc.
For any fuel control program, EPA must have the assurance that fuel
produced by refiners meets the applicable standard, and that the fuel
continues to meet the standard as it passes downstream through the
distribution system to the ultimate end user. This is particularly
important in the case of diesel fuel, where the aftertreatment
technologies expected to be used to meet the engine standards under
consideration are highly sensitive to sulfur. The recordkeeping,
reporting and compliance provisions of the proposed rule are fairly
consistent with those in place today for other fuel programs, including
the current 15 ppm highway diesel regulation. For example,
[[Page 28518]]
recordkeeping involves the use of product transfer documents, which are
already required under the 15 ppm highway diesel sulfur rule (40 CFR
80.560).
5. Relevant Federal Rules
The proposed certification fees rule, through the Agency's
Certification and Compliance Division (CCD), may have some impact on
the upcoming rule, and the Panel recommended that we take into
consideration the effects that this rule may have on small businesses.
The fuel regulations that we expect to propose would be similar in
many respects to the existing sulfur standard for highway diesel fuel.
We are not aware of any area where the regulations under consideration
would directly duplicate or overlap with the existing federal, state,
or local regulations; however, several small refiners will also be
subject to the gasoline sulfur and highway diesel sulfur control
requirements, as well as air toxics requirements.
More stringent nonroad diesel sulfur standards may require some
refiners to obtain permits from state and local air pollution control
agencies under the Clean Air Act's New Source Review program prior to
constructing the desulfurization equipment needed to meet the
standards.
The Internal Revenue Service (IRS) has an existing rule that levies
taxes on highway diesel fuel only. The rule requires that nonroad
diesel (un-taxed) fuel be dyed so that regulators and customers will
know which type of fuel is which. Because of the need to separate dyed
from undyed diesel fuel, some marketers may choose to install extra
tanks. Therefore, fuel marketers have claimed that, if two grades of
nonroad fuel are allowed in the marketplace, they may decide to
maintain two segregated tanks for both nonroad (dyed 500 ppm and dyed
15 ppm) and highway diesel fuels (undyed 500 ppm and undyed 15 ppm),
during the transition periods for both of these fuels.
6. Summary of SBREFA Panel Process and Panel Outreach
a. Significant Panel Findings
The Small Business Advocacy Review Panel (SBAR Panel, or the Panel)
considered many regulatory options and flexibilities that would help
mitigate potential adverse effects on small businesses as a result of
this rule. During the SBREFA Panel process, the Panel sought out and
received comments on the regulatory options and flexibilities that were
presented to SERs and Panel members. The major flexibilities and
hardship relief provisions that are recommended by the Panel, along
with specific recommendations by individual Panel members, are
described below and are also located in Section 9 of the SBREFA Final
Panel Report which is available in the public docket.\346\
---------------------------------------------------------------------------
\346\ Final Panel Report of the Small Business Advocacy Review
Panel on EPA's Proposed Rule-Control of Emissions of Air Pollution
From Land-Based Nonroad Compression Ignition Engines, December 23,
2003.
---------------------------------------------------------------------------
b. Panel Process
As required by section 609(b) of the RFA, as amended by SBREFA, we
also conducted outreach to small entities and convened a SBAR Panel to
obtain advice and recommendations of representatives of the small
entities that potentially would be subject to the rule's requirements.
On October 24, 2002, EPA's Small Business Advocacy Chairperson
convened a Panel under Section 609(b) of the RFA. In addition to the
Chair, the Panel consisted of the Deputy Director of EPA's Office of
Transportation and Air Quality, the Chief Counsel for Advocacy of the
Small Business Administration, and the Administrator of the Office of
Information and Regulatory Affairs within the Office of Management and
Budget. As part of the SBAR Panel process, we conducted outreach with
representatives from the various small entities that would be affected
by the proposed rulemaking. We met with these Small Entity
Representatives (SERs) to discuss the potential rulemaking approaches
and ways to decrease the impact of the rulemaking on their industries.
We distributed outreach materials-including background on the nonroad
diesel sector, possible regulatory approaches, and possible rulemaking
alternatives to the SERs on October 30, 2002. On November 13, 2002 the
Panel met with the SERs to discuss the outreach materials and receive
initial feedback on the approaches and alternatives detailed in the
outreach packet. The Panel received written comments from the SERs
following the meeting in response to discussions had at the meeting and
the questions posed to the SERs by the Agency. The SERs were
specifically asked to provide comment on regulatory alternatives that
could help to minimize the impact on small businesses as a result of
the rulemaking.
In general, SERs representing the nonroad diesel equipment
manufacturers raised concerns about the added cost of compliance and
the increase in size of compliant engines (and how this would affect
their products). SERs representing the nonroad diesel fuel industry
raised comments that generally included anticipated difficulty in going
to a lower grade of fuel and the need for increased tankage to carry
interim grades of fuel. All SERs raised concerns that small entities do
not have the capital and have fewer resources which make compliance
difficult. Thus, they maintain that there is a need to provide
alternatives and provisions to address these issues, as (per their
view) more stringent emission standards could impose more significant
adverse impacts on small entities than on large businesses. (For the
most part, EPA has not found the facts to support these contentions in
this proposal, and thus is not proposing separate provisions applicable
only to small entities.)
The Panel's findings and discussions are based on the information
that was available during the term of the Panel and issues that were
raised by the SERs during the outreach meetings and in their comments.
It was agreed that EPA should consider the issues raised by the SERs
(and discussions had by the Panel itself) and that EPA should consider
comments on flexibility alternatives that would help to mitigate any
negative impacts on small businesses. Alternatives discussed throughout
the Panel process include those offered in previous or current EPA
rulemakings, as well as alternatives suggested by SERs and Panel
members, and the Panel recommended that all be considered in the
development of the rule. Though some of the flexibilities suggested may
be appropriate to apply to all entities affected by the rulemaking, the
Panel's discussions and recommendations are focused mainly on the
impacts, and ways to mitigate adverse impacts, on small businesses. In
addition some of the provisions, such as the equipment manufacturer
transition provision, that apply to all entities also help to mitigate
the effects on small entities. A summary of these recommendations is
detailed below, and a full discussion of the regulatory alternatives
and hardship provisions discussed and recommended by the Panel can be
found in the SBREFA Final Panel Report. A complete discussion of the
transition and hardship provisions that we are proposing in today's
action can be found in Sections VII.C and III.A of this preamble. Also,
the Panel Report includes all comments received from SERs (Appendix B
of the Report), a summary of those comments (Section 8), and summaries
of the two outreach meetings that were held with the SERs
[[Page 28519]]
(Appendices C and D). In accordance with the RFA/SBREFA requirements,
the Panel evaluated the aforementioned materials and SER comments on
issues related to the Initial Regulatory Flexibility Analysis (IRFA).
The following sections describe the Panel recommendations, along with
specific recommendations by individual Panel members, from the SBAR
Panel Report.
c. Transition Flexibilities
The Panel recommended that EPA consider and seek comment on a wide
range of regulatory alternatives to mitigate the impacts of the
rulemaking on small businesses, including those flexibility options
described below. As previously stated, the following discussion is a
summary of the SBAR Panel recommendations; our proposals regarding
these recommendations are located in earlier sections of this rule
preamble.
i. Nonroad Diesel Engines
(a) Transition Flexibility Alternatives for Small Engine Manufacturers
The Panel recommended the following transition flexibilities to be
considered, which were dependent upon what approach, or approaches, EPA
proposes for the rulemaking.
[sbull] For an approach with two phases of standards:
[sbull] An engine manufacturer could skip the first phase and
comply on time with the second; or,
[sbull] a manufacturer could delay compliance with each phase of
standards.
[sbull] For an approach that entails only one phase of standards,
the manufacturer could opt to delay compliance. The Panel recommended
that the length of the delay be a three year period; the Panel also
recommended that EPA take comment on whether this delay period should
be two, three, or four years. Each delay would be pollutant specific
(i.e., the delay would apply to each pollutant as it is phased in).
(b) Hardship Provisions for Small Engine Manufacturers
The Panel also recommended that two types of hardship provisions be
extended to small engine manufacturers. These provisions are:
[sbull] For the case of a catastrophic event, or other extreme
unforseen circumstances, beyond the control of the manufacturer that
could not have been avoided with reasonable discretion (i.e. fire,
tornado, supplier not fulfilling contract, etc.); and
[sbull] For the case where a manufacturer has taken all reasonable
business, technical, and economic steps to comply but cannot do so.
Either relief provision would provide lead time for up to 2 years--
in addition to the transition flexibilities listed above--and a
manufacturer would have to demonstrate to the Agency's satisfaction
that failure to sell the noncompliant engines would jeopardize the
company's solvency. EPA could require that the manufacturer make up the
lost environmental benefit through the use of programs such as
supplemental environmental projects.
For the transition flexibilities listed above, the Panel
recommended that engine manufacturers and importers must have certified
engines in model year 2002 or earlier in order to take advantage of
these provisions. Each manufacturer would be limited to 2500 units per
year. This number allows for some market growth. The Panel recommended
these provisions in order to prohibit the misuse of these transition
provisions as a tool to enter the nonroad diesel market or to gain
unfair market position relative to other manufacturers.
(c) Other Small Engine Manufacturer Issues
It was also recommended by the SBAR Panel that an averaging,
banking, and trading (ABT) program be included as part of the overall
rulemaking program, and, as discussed above, ABT has been included in
the program.
During the SBREFA panel process several alternative approaches for
engine standards were examined and considered by the panel. See Section
3.1.1 of the SBAR panel report. The SBA Chief Counsel for the Office of
Advocacy also offered some observations about the impacts of the
standards for engines less than 70 hp on affected small engine and
equipment manufacturers which are based on the performance of PM or
NOX advanced aftertreatment devices. While the other Panel
members did not join in these observations, the Panel recommended that
the Administrator carefully consider these points and examine further
the factual, legal and policy questions raised here in developing the
proposed rule. First, given the available information, the Office of
Advocacy stated that they had substantial doubts about the technical
feasibility and cost of engineering aftertreatment devices into a wide
diversity of nonroad diesel applications for engines less than 70 hp.
They stated that considerable concern has been raised regarding the
technical feasibility of PM and NOX advanced aftertreatment
devices, even for larger engines, and particularly in the case of
NOX adsorbers. Second, the low retail cost and low annual
production for many of these applications make it extremely difficult
for the equipment manufacturer to absorb these additional costs. The
Office of Advocacy believes that, based on the available information,
the Agency does not have a sufficient basis to move forward with a
proposal that would require nonroad engines under 70 hp to use
aftertreatment devices. Based on the SERs' concerns about the technical
feasibility of the Tier 4 standards, and the technical information
discussed in the Panel report, SBA recommended that we include a
technological review of the standards in the 2008 time frame in the
rulemaking proposal. The Panel recommended that we consider this
recommendation.
The SBA Office of Advocacy stated that considerable concern has
been raised regarding the technical feasibility of PM and
NOX aftertreatment devices, particularly in the case of
NOX adsorbers. As explained in the preamble, we have found
no factual basis for this statement with respect to PM controls based
on use of advanced aftertreatment for engines between 25 and 75 hp. We
are not proposing standards based on performance of advanced
aftertreatment for engines under 25 hp, and for NOX, for
engines 75 hp and under.
With respect to the PM standards for these engines, however, EPA
disagrees with the statement made by the Office of Advocacy that, based
on available information, we do not have a sufficient basis to move
forward with this proposed rulemaking requiring nonroad engines under
70 hp to use aftertreatment devices. As we have documented in the
preamble and elsewhere in this Draft RIA, EPA believes that the
standards for PM for engines in these power ranges are feasible at
reasonable cost, and will help to improve very important air quality
problems, especially by reducing exposure to diesel PM and by aiding in
attainment of the PM 2.5 National Ambient Air Quality Standards
(NAAQS). Indeed, given these facts, EPA is skeptical that an
alternative of no PM standards for these engines would be appropriate
under section 213(a)(4). Moreover, the statement regarding cost impacts
fails to account for transition flexibilities provided all equipment
manufacturers as part of the proposal.
Further discussion of alternative engine standards below 75 hp can
be found in Section VI of this preamble and Chapter 11 and 12 of the
draft RIA, specifically the discussion of Options 5a and 5b. EPA
invites comment on these specific small engine alternatives, as
[[Page 28520]]
well as all other alternative options discussed in Section VI of this
preamble. We invite comments specifically on the costs of using
advanced aftertreatment devices, particularly on engines below 75 hp.
ii. Nonroad Diesel Equipment
(a) Transition Flexibility Alternatives for Small Equipment
Manufacturers
The Panel recommended that EPA propose to continue the transition
flexibilities offered for the Tier 1 and Tier 2 nonroad diesel emission
standards, as set out in 40 CFR 89.102, with some potential
modifications. The recommended transition flexibilities are:
[sbull] Percent-of-Production Allowance: Over a seven model year
period, equipment manufacturers may install engines not certified to
the new emission standards in an amount of equipment equivalent to 80
percent of one year's production. This is to be implemented by power
category with the average determined over the period in which the
flexibility is used.
[sbull] Small Volume Allowance: A manufacturer may exceed the 80
percent allowance in seven years as described above, provided that the
previous Tier engine use does not exceed 700 total over seven years,
and 200 in any given year. This is limited to one family per power
category. Alternatively, at the manufacturer's choice by hp category, a
program that eliminates the ``single family provision'' restriction
with revised total and annual sales limits as shown below:
[sbull] For categories <=175 hp--525 previous Tier engines (over 7
years) with an annual cap of 150 units (these engine numbers are
separate for each hp category defined in the regulations)
[sbull] For categories of 175hp--350 previous Tier
engines (over 7 years) with an annual cap of 100 units (these engine
numbers are separate for each hp category defined in the regulations).
The Panel recommended that EPA seek comment on the total number of
engines and annual cap values listed above. Specifically, the SBA and
OMB Panel members recommended that EPA seek comment on implementing the
small volume allowance (700 engine provision) for small equipment
manufacturers without a limit on the number of engine families which
could be covered in any hp category.
[sbull] In addition, due to the changing nature of the technology
as the manufacturers transition from Tier 2 to Tier 3 and Tier 4, the
Panel recommended that the equipment manufacturers be permitted to
borrow from the Tier 3/Tier 4 transition flexibilities for use in the
Tier 2/Tier 3 time frame.
To maximize the likelihood that the application of these transition
provisions will result in the availability of previous Tier engines for
use by the small equipment manufacturers, the Panel recommended that
these three provisions be provided to all equipment manufacturers. As
explained earlier in the preamble, this is essentially the approach
that EPA is proposing.
(b) Hardship Provisions for Small Equipment Manufacturers
The Panel also recommended that two types of hardship provisions be
extended to small equipment manufacturers. These are generally the same
as provided above for small engine manufacturers:
[sbull] For the case of a catastrophic event, or other extreme
unforseen circumstances, beyond the control of the manufacturer that
could not have been avoided with reasonable discretion (i.e. fire,
tornado, supplier not fulfilling contract, etc.); and
[sbull] For the case where a manufacturer has taken all reasonable
business, technical, and economic steps to comply but cannot. In this
case relief would have to be sought before there is imminent jeopardy
that a manufacturer's equipment could not be sold and a manufacturer
would have to demonstrate to the Agency's satisfaction that failure to
get permission to sell equipment with a previous Tier engine would
create a serious economic hardship. Hardship relief of this nature
cannot be sought by a manufacturer which also manufactures the engines
for its equipment.
Hardship relief would not be available until other allowances have
been exhausted. Either relief provision would provide additional lead
time for up to 2 model years based on the circumstances, but EPA could
require recovery of the lost environmental benefit. To be eligible for
the hardship provisions listed above (as well as the flexibilities
detailed above), the Panel recommended that equipment manufacturers and
importers must have reported equipment sales using certified engines in
model year 2002 or earlier. This requirement is to prohibit the misuse
of these flexibilities as a loophole to enter the nonroad diesel
equipment market or to gain unfair market position relative to other
manufacturers.
iii. Nonroad Diesel Fuel Refiners
(a) Regulatory Flexibility Alternatives for Diesel Fuel Refiners
The Panel considered a range of options and regulatory alternatives
for providing small refiners with flexibility in complying with new
sulfur standards for nonroad diesel fuel. Taking into consideration the
comments received on these ideas, as well as additional business and
technical information gathered about potentially affected small
entities, the Panel recommended that whether EPA proposes a one-step or
a two-step approach, EPA should provide for delayed compliance for
small refiners as shown below.
Small Refiner Options Under 2-Step Nonroad Diesel Base Programs Recommended Sulfur Standards
[in parts per million (ppm)] \a\
--------------------------------------------------------------------------------------------------------------------------------------------------------
Under 2-step program 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015+
--------------------------------------------------------------------------------------------------------------------------------------------------------
Non-Small \b\............................. ......... 500 500 500 15 15 15 15 15 15
Small..................................... ......... ......... ......... ......... 500 500 500 500 15 15
--------------------------------------------------------------------------------------------------------------------------------------------------------
Notes:
\a\ New standards are assumed to take effect June 1 of the applicable year.
\b\ Assumes 500 ppm standard for marine + locomotive fuel for non-small refiners for 2007 and later and for small refiners for 2010 and later.
(b) Small Refiner Incentives for Early Compliance
In addition to these standards, the Panel recommended that EPA
propose certain transition provisions to encourage early compliance
with the diesel fuel sulfur standards. The Panel recommended that EPA
propose that small refiners be eligible to select one of the two
following options:
[sbull] Credits for Early Desulfurization: The Panel recommended
that the
[[Page 28521]]
Agency propose, as part of an overall trading program, a credit trading
system that allows small refiners to generate and sell credits for
nonroad diesel fuel that meets the small refiner standards earlier than
that required in the above table. Such credits could be used to offset
higher sulfur fuel produced by that refiner or by another refiner that
purchases the credits.
[sbull] Limited Relief on Small Refiner Interim Gasoline Sulfur
Standards: The Panel recommended that a small refiner producing its
entire nonroad diesel fuel pool at 15 ppm sulfur by June 1, 2006, and
that chooses not to generate nonroad credits for its early compliance,
receive a 20 percent relaxation in its assigned small refiner interim
gasoline sulfur standards. However, the Panel recommended that the
maximum per-gallon sulfur cap for any small refiner remain at 450 ppm.
(c) Refiner Hardship Provisions
The Panel recommended that EPA propose refiner hardship provisions
modeled after those established under the gasoline sulfur and highway
diesel fuel sulfur program (see 40 CFR 80.270 and 80.560).
Specifically, the Panel recommended that EPA propose a process that,
like the hardship provisions of the gasoline and highway diesel rules,
allows refiners to seek case-by-case approval of applications for
temporary waivers to the nonroad diesel sulfur standards, based on a
demonstration to the Agency of extreme hardship circumstances. This
provision would allow domestic and foreign refiners, including small
refiners, to request additional flexibility based on a showing of
unusual circumstances that result in extreme hardship and significantly
affect the ability of the refiner to comply by the applicable date,
despite its best efforts.
iv. Nonroad Diesel Fuel Distributors and Marketers
The diesel fuel approach being considered by the Agency includes
the possibility of there being two grades of nonroad diesel fuel (500/
15 ppm) in the market place for at least a transition period. The
distributors support a one-step approach because it has no significant
impact on their operations. The distributors offered some suggestions
on how they might deal with this issue, but indicated that there would
be adverse impact in some circumstances. The Panel recommended that EPA
study this issue further. The costs and related issues relevant to fuel
distributors are further discussed in Chapter 7 of the proposed rule
Regulatory Impact Analysis.
EPA invites comments on all aspects of the proposal and its impacts
on the regulated small entities.
D. Unfunded Mandates Reform Act
Title II of the Unfunded Mandates Reform Act of 1995 (UMRA), Public
Law. 104-4, establishes requirements for Federal agencies to assess the
effects of their regulatory actions on State, local, and tribal
governments and the private sector. Under section 202 of the UMRA, EPA
generally must prepare a written statement, including a cost-benefit
analysis, for proposed and final rules with ``federal mandates'' that
may result in expenditures to State, local, and tribal governments, in
the aggregate, or to the private sector, of $100 million or more in any
one year. Before promulgating an EPA rule for which a written statement
is needed, section 205 of the UMRA generally requires EPA to identify
and consider a reasonable number of regulatory alternatives and adopt
the least costly, most cost-effective, or least burdensome alternative
that achieves the objectives of the rule. The provisions of section 205
do not apply when they are inconsistent with applicable law. Moreover,
section 205 allows EPA to adopt an alternative other than the least
costly, most cost-effective, or least burdensome alternative if the
Administrator publishes with the final rule an explanation of why that
alternative was not adopted.
Before EPA establishes any regulatory requirements that may
significantly or uniquely affect small governments, including tribal
governments, it must have developed under section 203 of the UMRA a
small government agency plan. The plan must provide for notifying
potentially affected small governments, enabling officials of affected
small governments to have meaningful and timely input in the
development of EPA regulatory proposals with significant federal
intergovernmental mandates, and informing, educating, and advising
small governments on compliance with the regulatory requirements.
This rule contains no federal mandates for state, local, or tribal
governments as defined by the provisions of Title II of the UMRA. The
rule imposes no enforceable duties on any of these governmental
entities. Nothing in the rule would significantly or uniquely affect
small governments.
EPA has determined that this rule contains federal mandates that
may result in expenditures of more than $100 million to the private
sector in any single year. EPA believes that the proposal represents
the least costly, most cost-effective approach to achieve the air
quality goals of the rule. The costs and benefits associated with the
proposal are discussed above and in the Draft Regulatory Impact
Analysis, as required by the UMRA.
E. Executive Order 13132: Federalism
Executive Order 13132, entitled ``Federalism'' (64 FR 43255, August
10, 1999), requires EPA to develop an accountable process to ensure
``meaningful and timely input by State and local officials in the
development of regulatory policies that have federalism implications.''
``Policies that have federalism implications'' is defined in the
Executive Order to include regulations that have ``substantial direct
effects on the States, on the relationship between the national
government and the States, or on the distribution of power and
responsibilities among the various levels of government.''
Under Section 6 of Executive Order 13132, EPA may not issue a
regulation that has federalism implications, that imposes substantial
direct compliance costs, and that is not required by statute, unless
the Federal government provides the funds necessary to pay the direct
compliance costs incurred by State and local governments, or EPA
consults with State and local officials early in the process of
developing the proposed regulation. EPA also may not issue a regulation
that has federalism implications and that preempts State law, unless
the Agency consults with State and local officials early in the process
of developing the proposed regulation.
Section 4 of the Executive Order contains additional requirements
for rules that preempt State or local law, even if those rules do not
have federalism implications (i.e., the rules will not have substantial
direct effects on the States, on the relationship between the national
government and the states, or on the distribution of power and
responsibilities among the various levels of government). Those
requirements include providing all affected State and local officials
notice and an opportunity for appropriate participation in the
development of the regulation. If the preemption is not based on
express or implied statutory authority, EPA also must consult, to the
extent practicable, with appropriate State and local officials
regarding the conflict between State law and Federally protected
interests within the agency's area of regulatory responsibility.
This proposed rule does not have federalism implications. It will
not have substantial direct effects on the States, on the relationship
between the national
[[Page 28522]]
government and the States, or on the distribution of power and
responsibilities among the various levels of government, as specified
in Executive Order 13132.
Although Section 6 of Executive Order 13132 does not apply to this
rule, EPA did consult with representatives of various State and local
governments in developing this rule. EPA has also consulted
representatives from STAPPA/ALAPCO, which represents state and local
air pollution officials.
In the spirit of Executive Order 13132, and consistent with EPA
policy to promote communications between EPA and State and local
governments, EPA specifically solicits comment on this proposed rule
from State and local officials.
F. Executive Order 13175: Consultation and Coordination With Indian
Tribal Governments
Executive Order 13175, entitled ``Consultation and Coordination
with Indian Tribal Governments'' (65 FR 67249, November 6, 2000),
requires EPA to develop an accountable process to ensure ``meaningful
and timely input by tribal officials in the development of regulatory
policies that have tribal implications.''
This proposed rule does not have tribal implications as specified
in Executive Order 13175. This rule will be implemented at the Federal
level and impose compliance costs only on engine manufacturers and ship
builders. Tribal governments will be affected only to the extent they
purchase and use equipment with regulated engines. Thus, Executive
Order 13175 does not apply to this rule. EPA specifically solicits
additional comment on this proposed rule from tribal officials.
G. Executive Order 13045: Protection of Children From Environmental
Health and Safety Risks
Executive Order 13045, ``Protection of Children from Environmental
Health Risks and Safety Risks'' (62 FR 19885, April 23, 1997) applies
to any rule that (1) is determined to be ``economically significant''
as defined under Executive Order 12866, and (2) concerns an
environmental health or safety risk that EPA has reason to believe may
have a disproportionate effect on children. If the regulatory action
meets both criteria, Section 5-501 of the Order directs the Agency to
evaluate the environmental health or safety effects of the planned rule
on children, and explain why the planned regulation is preferable to
other potentially effective and reasonably feasible alternatives
considered by the Agency.
This proposed rule is not subject to the Executive Order because it
does not involve decisions on environmental health or safety risks that
may disproportionately affect children.
The effects of ozone and PM on children's health were addressed in
detail in EPA's rulemaking to establish the NAAQS for these pollutants,
and EPA is not revisiting those issues here. EPA believes, however,
that the emission reductions from the strategies proposed in this
rulemaking will further reduce air toxic emissions and the related
adverse impacts on children's health.
H. Executive Order 13211: Actions that Significantly Affect Energy
Supply, Distribution, or Use
This rule is not a ``significant energy action'' as defined in
Executive Order 13211, ``Actions Concerning Regulations That
Significantly Affect Energy Supply, Distribution, or Use'' (66 FR 28355
(May 22, 2001)) because it is not likely to have a significant adverse
effect on the supply, distribution, or use of energy. If promulgated,
this proposed rule would decrease fuel production by less than 4000
barrels per day and would increase fuel production costs, distribution
costs, and prices by less than ten percent. The reader is referred to
Section V above for the estimated cost, price and production impacts of
the proposed fuel program.
I. National Technology Transfer Advancement Act
Section 12(d) of the National Technology Transfer and Advancement
Act of 1995 (``NTTAA''), Public Law 104-113, section 12(d) (15 U.S.C.
272 note) directs EPA to use voluntary consensus standards in its
regulatory activities unless doing so would be inconsistent with
applicable law or otherwise impractical. Voluntary consensus standards
are technical standards (e.g., materials specifications, test methods,
sampling procedures, and business practices) that are developed or
adopted by voluntary consensus standards bodies. NTTAA directs EPA to
provide Congress, through OMB, explanations when the Agency decides not
to use available and applicable voluntary consensus standards.
This proposed rule involves technical standards. The following
paragraphs describe how we specify testing procedures for engines
subject to this proposal.
The International Organization for Standardization (ISO) has a
voluntary consensus standard that can be used to test nonroad diesel
engines. However, the current version of that standard (ISO 8178) is
applicable only for steady-state testing, not for transient testing. As
described in the Draft Regulatory Impact Analysis, transient testing is
an important part of the proposed emission-control program for these
engines. We are therefore not proposing to adopt the ISO procedures in
this rulemaking.
EPA welcomes comments on this aspect of the proposed rulemaking
and, specifically, invites the public to identify potentially
applicable voluntary consensus standards and to explain why such
standards should be used in this regulation.
J. Plain Language
This document follows the guidelines of the June 1, 1998 Executive
Memorandum on Plain Language in Government Writing. To read the text of
the regulations, it is also important to understand the organization of
the Code of Federal Regulations (CFR). The CFR uses the following
organizational names and conventions.
Title 40--Protection of the Environment
Chapter I--Environmental Protection Agency
Subchapter C--Air Programs. This contains parts 50 to 99, where the
Office of Air and Radiation has usually placed emission standards for
motor vehicle and nonroad engines.
Subchapter U--Air Programs Supplement. This contains parts 1000 to
1299, where we intend to place regulations for air programs in future
rulemakings.
Part 1039--Control of Emissions from New Nonroad Compression-
ignition Engines. Most of the provisions in this part apply only to
engine manufacturers.
Part 1065--General Test Procedures for Engine Testing. Provisions
of this part apply to anyone who tests engines to show that they meet
emission standards.
Part 1068--General Compliance Provisions for Engine Programs.
Provisions of this part apply to everyone.
Each part in the CFR has several subparts, sections, and
paragraphs. The following illustration shows how these fit together.
Part 1039
Subpart A
Sec. 1039.1
(a)
(b)
(1)
(2)
(i)
(ii)
[[Page 28523]]
A cross reference to Sec. 1039.1(b) in this illustration would
refer to the parent paragraph (b) and all its subordinate paragraphs. A
reference to ``Sec. 1039.1(b) introductory text'' would refer only to
the single, parent paragraph (b).
XI. Statutory Provisions and Legal Authority
Statutory authority for the engine controls proposed today can be
found in sections 213 (which specifically authorizes controls on
emissions from nonroad engines and vehicles), 203-209, 216 and 301 of
the CAA, 42 U.S.C. 7547, 7522, 7523, 7424, 7525, 7541, 7542, 7543, 7550
and 7601.
Statutory authority for the proposed fuel controls is found in
sections 211(c) and 211(i) of the CAA, which allow EPA to regulate
fuels that either contribute to air pollution which endangers public
health or welfare or which impair emission control equipment which is
in general use or has been in general use. 42 U.S.C. 7545 (c) and (i).
Additional support for the procedural and enforcement-related aspects
of the fuel controls in the proposed rule, including the record keeping
requirements, comes from sections 114(a) and 301(a) of the CAA. 42
U.S.C. sections 7414(a) and 7601(a).
List of Subjects
40 CFR Part 69
Environmental protection, Air pollution controls.
40 CFR Part 80
Fuel additives, Gasoline, Imports, Labeling, Motor vehicle
pollution, Penalties, Reporting and recordkeeping requirements.
40 CFR Part 89
Environmental protection, Administrative practice and procedure,
Confidential business information, Imports, Labeling, Motor vehicle
pollution, Reporting and recordkeeping requirements, Research, Vessels,
Warranties.
40 CFR Part 1039
Environmental protection, Administrative practice and procedure,
Confidential business information, Imports, Labeling, Motor vehicle
pollution, Reporting and recordkeeping requirements, Research, Vessels,
Warranties.
40 CFR Part 1065
Environmental protection, Administrative practice and procedure,
Incorporation by reference, Reporting and recordkeeping requirements,
Research.
40 CFR Part 1068
Environmental protection, Administrative practice and procedure,
Confidential business information, Imports, Motor vehicle pollution,
Penalties, Reporting and recordkeeping requirements, Warranties.
Dated: April 15, 2003.
Christine Todd Whitman,
Administrator.
For the reasons set forth in the preamble, we propose to amend
parts 69, 80, 89, 1039, 1065, and 1068 of title 40 of the Code of
Federal Regulations as follows:
PART 69--SPECIAL EXEMPTIONS FROM THE REQUIREMENTS OF THE CLEAN AIR
ACT
1. The authority citation for part 69 is revised to read as
follows:
Authority: 42 U.S.C. 7545(c), (g) and (i), and 7625-1.
Subpart E--[Amended]
2. Section 69.51 is revised to read as follows:
Sec. 69.51 Motor vehicle diesel fuel.
(a) Diesel fuel that is designated for use only in Alaska and is
used only in Alaska, is exempt from the sulfur standard of 40 CFR
80.29(a)(1) and the dye provisions of 40 CFR 80.29(a)(3) and 40 CFR
80.29(b) until the implementation dates of 40 CFR 80.500, provided
that:
(1) The fuel is segregated from nonexempt diesel fuel from the
point of such designation; and
(2) On each occasion that any person transfers custody or title to
the fuel, except when it is dispensed at a retail outlet or wholesale
purchaser-consumer facility, the transferor must provide to the
transferee a product transfer document stating:
This diesel fuel is for use only in Alaska. It is exempt from the
federal low sulfur standards applicable to highway diesel fuel and red
dye requirements applicable to non-highway diesel fuel only if it is
used in Alaska.
(b) Beginning on the implementation dates in 40 CFR 80.500, motor
vehicle diesel fuel that is designated for use in Alaska or is used in
Alaska, is subject to the applicable provisions of 40 CFR part 80,
Subpart I, except the language of product transfer documents under 40
CFR 80.590 and pump dispenser labels under 40 CFR 80.570(a) and (b) may
be modified, as applicable, to reflect the fact that certain motor
vehicle and non-motor vehicle diesel fuels or heating oil that would
otherwise be required to be segregated due to the red dye requirement
for non-motor vehicle fuels under Sec. Sec. 80.510(c) and 80.520(b)(2)
are permitted to be commingled, distributed and dispensed as one fuel,
due to the exemption from the red dye requirement under 40 CFR 69.52(b)
and (c), if they meet the same sulfur and cetane and/or aromatics
standards as the motor vehicle diesel fuel.
(c) The Governor of Alaska may submit for EPA approval, by April 1,
2002, a plan for implementing the motor vehicle sulfur standard in
Alaska as an alternative to the temporary compliance option provided
under Sec. Sec. 80.530-80.532. If EPA approves an alternative plan,
the provisions as approved by EPA under that plan shall apply to the
diesel fuel subject to this paragraph (b).
3. A new Sec. 69.52 is added to read as follows:
Sec. 69.52 Non-motor vehicle diesel fuel.
(a) Definitions. (1) Areas accessible by the Federal Aid Highway
System are the geographical areas of Alaska designated by the State of
Alaska as being accessible by the Federal Aid Highway System.
(2) Areas not accessible by the Federal Aid Highway System are all
other geographical areas of Alaska.
(3) Nonroad, locomotive, or marine diesel fuel shall have the same
meaning as provided in 40 CFR 80.2.
(b) Non-motor vehicle diesel fuel and heating oil that is used or
intended for use in areas of Alaska accessible by the Federal Aid
Highway System is subject to the provisions of 40 CFR Part 80, Subpart
I, except:
(1) The fuel is exempt from the red dye requirements, and the
presumptions associated with the red dye requirements, under Sec. Sec.
80.510(c) and 80.520(b)(2). Exempt fuel under this paragraph (b) must
be segregated from motor vehicle diesel fuel, unless it meets the same
sulfur standard and applicable cetane and/or aromatics standards as the
motor vehicle diesel fuel and it is not marked by yellow solvent 124
under Sec. Sec. 80.510 and 80.511.
(2) The language of product transfer documents under 40 CFR 80.590
and pump dispenser labels under 40 CFR 80.570--80.573 may be modified,
as applicable, to reflect the fact that the fuel is exempt from the red
dye requirement under paragraph (b) (1) of this section, and that the
exempt fuel that would otherwise be required to be segregated from
motor vehicle diesel fuel is permitted to be commingled, distributed
and dispensed with the motor vehicle fuel if it meets the same sulfur
standard and applicable cetane and/or aromatics standards as the motor
vehicle fuel and is not marked by
[[Page 28524]]
yellow solvent 124 under Sec. Sec. 80.510 and 80.511. Further, the
following language shall be added to the product transfer documents:
``Exempt from red dye requirement applicable to diesel fuel for non-
highway purposes if it is used only in Alaska.''
(3) For purposes of calculating a non-highway baseline percentage
under 40 CFR 80.533, Alaska refiners and importers:
(i) Must declare under 40 CFR 80.533(c)(i)(C), as applicable, that
the fuel was exempt under 69.52 from the dye provisions and did not
meet the definition of motor vehicle diesel fuel; and
(ii) As an alternative to the submission of batch data for the
baseline period under 40 CFR 80.533(c), may assume 30 percent for the
non-highway baseline percentage.
(c) Non-motor vehicle diesel fuel and heating oil that is
designated for use only in areas of Alaska not accessible by the
Federal Aid Highway System, or is used only in areas of Alaska not
accessible by the Federal Aid Highway System, is excluded from the
applicable provisions of 40 CFR Part 80, Subpart I; except that:
(1) All model year 2011 and later nonroad diesel engines and
equipment must be fueled only with diesel fuel that meets the
specifications of Sec. 80.510(b), and the product transfer document
requirements under 40 CFR 80.590 and pump dispenser labels under 40 CFR
80.570--80.573, except that, (i) The language of product transfer
documents under 40 CFR 80.590 and pump dispenser labels under 40 CFR
80.570--80.573 may be modified, as applicable, to reflect the fact that
the fuel is undyed and unmarked, and that diesel fuel for motor
vehicles, nonroad equipment, locomotive or marine engines, and heating
oil that meet the same sulfur, cetane and/or aromatics standards that
would otherwise be required to be segregated are permitted to be
commingled, distributed and dispensed as one fuel under this section
(c), and
(ii) The following language shall be added to the product transfer
documents: ``Exempt from red dye requirement applicable to diesel fuel
for non-highway purposes if it is used only in Alaska.''
(2) Diesel fuel that is exempt under this section, except when
paragraph (c)(1) of this section applies, must meet the requirements
for product transfer documents under 40 CFR 80.590, except the
following language shall be substituted for the language specified
under (a)(5) of that section:
(i) Until August 31, 2010:
This diesel fuel is for use only in those areas of Alaska not
accessible by the Federal Aid Highway System. It is exempt from the
federal sulfur standards applicable to highway, nonroad, locomotive
and marine diesel fuel, and the red dye requirements applicable to
non-highway diesel fuel. It may not be used in model year 2007 and
newer highway vehicles.
(ii) After August 31, 2010:
This diesel fuel is for use only in those areas of Alaska not
accessible by the Federal Aid Highway System. It is exempt from the
federal sulfur standards applicable to highway, nonroad, locomotive
and marine diesel fuel, and the red dye requirements applicable to
non-highway diesel fuel. It may not be used in model year 2007 and
newer highway vehicles or in model year 2011 and newer nonroad
equipment.
(3) Diesel fuel that is exempt under this section, except when
paragraph (c)(1) of this section applies, must meet the labeling
requirements under Sec. Sec. 80.570-80.573, except the following
language shall be substituted for the language on the labels:
(i) Until August 31, 2010:
HIGH-SULFUR DIESEL FUEL
(May Exceed 500 ppm)
WARNING
Federal Law Prohibits Use in Model Year 2007 and Newer Highway
Vehicles.
(ii) After August 31, 2010
HIGH-SULFUR DIESEL FUEL
(May Exceed 500 ppm)
WARNING
Federal Law Prohibits Use in Any Highway Vehicle or in Any Model
Year 2011 and Newer Nonroad Engine.
PART 80--REGULATION OF FUELS AND FUEL ADDITIVES
4. The authority citation for part 80 continues to read as follows:
Authority: 42 U.S.C. 7414, 7545 and 7601(a).
5. Section 80.2 is amended by revising paragraphs (f), (j), (o),
(x), (y), (nn), and (xx) and adding paragraphs (yy) through (ooo) to
read as follows:
Sec. 80.2 Definitions
* * * * *
(f) Previously certified diesel fuel or PCD means diesel fuel that
previously has been included by a refiner or importer in a batch for
purposes of complying with the standards and requirements of subpart I
of this part.
* * * * *
(j) Retail outlet means any establishment, whether stationary or
mobile, at which gasoline, diesel fuel, methanol, natural gas or
liquified petroleum gas is sold or offered for sale for use in motor
vehicles, nonroad engines, locomotive engines or marine engines.
* * * * *
(o) Wholesale purchaser-consumer means any organization that is an
ultimate consumer of gasoline, diesel fuel, methanol, natural gas, or
liquified petroleum gas and which purchases or obtains gasoline, diesel
fuel, natural gas or liquified petroleum gas from a supplier for use in
motor vehicles, nonroad engines, locomotive engines or marine engines
and, in the case of gasoline, diesel fuel, methanol or liquified
petroleum gas, receives delivery of that product into a storage tank of
at least 550-gallon capacity substantially under the control of that
organization.
* * * * *
(x) Diesel fuel means any fuel sold in any State or Territory of
the United States and suitable for use in diesel engines, and which is
commonly or commercially known or sold as number 1 or number 2 diesel
fuel, or any distillate or nondistillate fuel that has comparable
physical or chemical properties.
* * * * *
(nn) Batch of diesel fuel means a quantity of diesel fuel which is
homogeneous with regard to those properties that are specified for
motor vehicle, nonroad, locomotive or marine diesel fuel under subpart
I of this part.
* * * * *
(xx) Diesel fuel additive means any substance not composed solely
of carbon and/or hydrogen, or of diesel blendstocks, that is added,
intended for adding, used, or offered for use in motor vehicle diesel
fuel or NRLM diesel fuel subsequent to the production of diesel fuel by
processing crude oil from refinery processing units, or in diesel motor
vehicle or NRLM fuel systems.
(yy) [Reserved]
(zz) [Reserved]
(aaa) [Reserved]
(bbb) Nonroad (NR) diesel fuel means any diesel fuel, or any
distillate product, that is used, intended for use, or made available
for use, as a fuel in land based diesel engines subject to the
provisions of either 40 CFR part 89 or part 1039.
(ccc) Locomotive and marine (LM) diesel fuel means any diesel fuel,
or any distillate product, that is used, intended for use, or made
available for use, as a fuel in diesel engines subject to the
provisions of either 40 CFR part 92 or part 94, or marine diesel
engines subject to the provisions of part 89.
[[Page 28525]]
(ddd) Nonroad, locomotive, and marine (NRLM) diesel fuel means any
diesel fuel, or any distillate product, that is used, intended for use,
or made available for use, as a fuel in diesel engines subject to the
provisions of either 40 CFR part 89, part 92, part 94, or part 1039.
(eee) Heating oil means any number 1 or number 2 distillate (other
than jet fuel) that does not meet the definitions of motor vehicle,
nonroad, locomotive, marine or NRLM diesel fuel. For example, heating
oil can include fuel suitable for use in furnaces, boilers, stationary
diesel engines, and similar applications and which is commonly or
commercially known or sold as heating oil, fuel oil, and similar trade
names.
(fff) Diesel fuel blending stock, blendstock, or component means
any liquid compound which is blended with other liquid compounds to
produce diesel fuel.
(ggg) Transmix means an interface mixture in a product pipeline
that cannot practicably be added to either of the adjoining products
that produced the interface and still meet product specifications and
standards. For example, a mixture of gasoline and diesel fuel would
generally be considered transmix.
(hhh)-(iii) [Reserved]
(jjj) Fuel marker means the fuel marker required in heating oil
from 2007 through 2010 pursuant to Sec. 80.510(c)(1) and in locomotive
and marine diesel fuel from 2010 through 2014 pursuant to the
requirements of Sec. 80.510(c)(2).
(kkk) Solvent yellow 124 means N-ethyl-N-[2-[1-(2-
methylpropoxy)ethoxyl]-4-phenylazo]-benzeneamine.
(lll) Nonroad diesel engine means, for the purposes of subpart I of
this part only, a land-based nonroad diesel engine subject to the
provisions of either 40 CFR part 89 or part 1039.
(mmm) Locomotive diesel engine means, for purposes of subpart I of
this part only, a diesel engine subject to the provisions of 40 CFR
part 92.
(nnn) Marine diesel engine means, for purposes of subpart I of this
part only, a marine diesel engine subject to the provisions of either
40 CFR part 89 or 40 CFR part 94.
(ooo) Transmix processor means a refiner who produces diesel fuel
or gasoline from transmix.
6. Section 80.230 is amended by revising paragraphs (b)(1) and
(b)(2) to read as follows:
Sec. 80.230 Who is not eligible for the hardship provisions for small
refiners?
* * * * *
(b)(1)(i) Refiners who qualify as small under Sec. 80.225, and
subsequently employ more than 1,500 people as a result of merger with
or acquisition of or by another entity, or exceed the 155,000 bpcd
crude capacity limit as a result of merger with or acquisition of or by
another entity after January 1, 2004, are disqualified as small
refiners. If this occurs the refiner shall notify EPA in writing no
later than 20 days following this disqualifying event.
(ii) Except as provided under paragraph (b)(1)(iii) of this
section, any refiner whose status changes under this paragraph shall
meet the applicable standards of Sec. 80.195 within a period of up to
24 months of the disqualifying event for any of its refineries that
were previously subject to the small refiner standards of Sec.
80.240(a). However, such period shall not extend later than December
31, 2007, or, for refineries for which the Administrator has approved
an extension of the small refiner gasoline sulfur standards under Sec.
80.553(c), December 31, 2010.
(iii) A refiner may apply to EPA for additional time to comply with
the standards of Sec. 80.195 if more than 24 months would be required
for the necessary engineering, permitting, construction, and start-up
work to be completed. Such applications must include detailed technical
information supporting the need for additional time and a proposed
amount of additional time. EPA will base a decision to approve
additional time on information provided by the refiner and on other
relevant information. In no case will EPA extend the compliance date
beyond December 31, 2007, or, for refineries for which the
Administrator has approved an extension of the small refiner gasoline
sulfur standards under Sec. 80.553(c), December 31, 2010.
(2) Any refiner who qualifies as small under Sec. 80.225 may elect
to meet the standards under Sec. 80.195 by notifying EPA in writing no
later than November 15 prior to the year the change will occur. Any
refiner whose status changes under this paragraph shall meet the
standards under Sec. 80.195 beginning with the first averaging period
subsequent to the status change.
* * * * *
7. Section 80.240 is amended by adding paragraph (f) to read as
follows:
Sec. 80.240 What are the small refiner gasoline sulfur standards?
* * * * *
(f)(1) In the case of a refiner without approved small refiner
status under Sec. 80.235 who acquires a refinery from a refiner with
approved small refiner status, the applicable small refiner standards
under paragraph (a) of this section will apply to the acquired small
refinery for a period up to 24 months from the date of acquistion of
the refinery, but no later than December 31, 2007, or, for a refinery
for which the Administrator has approved an extension of the small
refinery gasoline sulfur standards under Sec. 80.553(c), December 31,
2010, after which time the standards of Sec. 80.195 shall apply to the
acquired refinery.
(2) A refiner may apply to EPA for additional time to comply with
the standards of Sec. 80.195 for the acquired refinery if more than 24
months would be required for the necessary engineering, permitting,
construction, and start-up work to be completed. Such applications must
include detailed technical information supporting the need for
additional time and a proposed amount of additional time. EPA will base
a decision to approve additional time on information provided by the
refiner and on other relevant information. In no case will EPA extend
the compliance date beyond December 31, 2007, or, for a refinery for
which the Administrator has approved an extension of the small refiner
gasoline sulfur standards under Sec. 80.553(c), December 31, 2010.
8. Section 80.500 is amended by revising the section heading to
read as follows:
Sec. 80.500 What are the implementation dates for the motor vehicle
diesel fuel sulfur control program?
9. Section 80.501 is amended by revising paragraph (a) to read as
follows:
Sec. 80.501 What diesel fuel is subject to the provisions of this
subpart?
(a) Included fuel and additives. The provisions of this subpart
apply to motor vehicle diesel fuel as defined in Sec. 80.2(y);
nonroad, locomotive, or marine diesel fuel as defined in Sec.
80.2(ddd); diesel fuel additives as defined in Sec. 80.2(xx), heating
oil as defined in Sec. 80.2(eee), and motor oil that is used as or
intended for use as fuel in diesel motor vehicles or nonroad,
locomotive, or marine engines or is blended with diesel fuel for use in
diesel motor vehicles or nonroad, locomotive, or marine engines at any
downstream location, as provided in Sec. 80.522.
* * * * *
10. A new Sec. 80.510 is added to read as follows:
Sec. 80.510 What are the standards and marker requirements for
nonroad, locomotive, and marine diesel fuels?
(a) Beginning June 1, 2007. Except as otherwise specifically
provided in this
[[Page 28526]]
subpart, all NRLM diesel fuel is subject to the following per-gallon
standards:
(1) Sulfur content. 500 parts per million (ppm) maximum.
(2) Cetane index and aromatic content.
(i) A minimum cetane index of 40; or
(ii) A maximum aromatic content of 35 volume percent.
(b) Beginning June 1, 2010. Except as otherwise specifically
provided in this subpart, all NR diesel fuel is subject to the
following per-gallon standards:
(1) Sulfur content. 15 parts per million (ppm) maximum.
(2) Cetane index and aromatic content.
(i) A minimum cetane index of 40; or
(ii) A maximum aromatic content of 35 volume percent.
(c) Marker provisions. (1) Beginning June 1, 2007, or June 1, 2006,
as applicable under Sec. 80.534, and prior to June 1, 2010:
(i) A refiner or importer shall add 6 milligrams per liter of
solvent yellow 124 to any heating oil.
(ii) All NRLM and motor vehicle diesel fuel produced by a refiner
or imported by an importer shall be free of solvent yellow 124.
(iii) Any diesel fuel that contains greater than or equal to 0.1
milligrams per liter of solvent yellow 124 shall be deemed to be
heating oil and shall be prohibited from use in any motor vehicle,
nonroad, locomotive, or marine diesel engine.
(iv) Any diesel fuel that contains less than 0.1 milligrams per
liter of solvent yellow 124 shall be considered motor vehicle diesel
fuel, NR, LM, or NRLM, as appropriate.
(2) Beginning June 1, 2010 and prior to June 1, 2014:
(i) A refiner or importer shall add 6 milligrams per liter of
solvent yellow 124 to any LM diesel fuel.
(ii) All NR produced by a refiner or imported by an importer shall
be free of solvent yellow 124.
(iii) Any diesel fuel which contains greater than or equal to 0.1
milligrams per liter of solvent yellow 124 shall be deemed to be LM
diesel and shall be prohibited from use in any motor vehicle or nonroad
diesel engine.
(iv) Any diesel fuel which contains less than 0.1 milligrams per
liter of solvent yellow 124 shall be considered other than locomotive
and marine diesel fuel and subject to the applicable requirements.
(d) Pursuant and subject to the provisions of Sec. Sec. 80.536,
80.554, 80.560, and 80.561:
(1) Until June 1, 2010, nonroad, locomotive, and marine NRLM diesel
fuel produced or imported in full compliance with the requirements of
those sections is exempt from the per-gallon sulfur content standard
and cetane or aromatics standard of paragraph (a) of this section;
(2) Until June 1, 2014, NR diesel fuel produced or imported in full
compliance with the requirements of those sections is exempt from the
per-gallon standards of paragraph (b) of this section but is subject to
a per-gallon standards for sulfur content, cetane, and aromatics of
paragraph (a) of this section.
11. A new Sec. 80.511 is added to read as follows:
Sec. 80.511 What are the per-gallon and marker requirements that
apply to nonroad, locomotive, and marine diesel fuels and heating oil
downstream of the refinery or importer?
(a) Applicable dates for marker requirements at downstream
locations. (1) From June 1, 2006 through May 31, 2010, all NRLM shall
contain less than 0.10 milligrams per liter of the marker solvent
yellow 124.
(2) Beginning June 1, 2010, all NR diesel fuel shall contain less
than 0.10 milligrams per liter of the marker solvent yellow 124.
(b) Applicable dates for per-gallon standards at downstream
locations. All NR, LM, and NRLM diesel fuel at any downstream location
shall comply with the same per-gallon sulfur content and cetane index
or aromatics standard (``per-gallon standards'' for purposes of this
section) of Sec. 80.510, except as follows:
(1)(i) The per-gallon standards of Sec. 80.510(a) shall apply
beginning August 1, 2007 for all downstream locations other than retail
outlets or wholesale purchaser-consumer facilities, and shall apply
starting October 1, 2007 for retail outlets and wholesale purchaser-
consumer facilities.
(ii) The per-gallon standards of of Sec. 80.510(b) shall apply
beginning July 15, 2010 for all downstream locations other than retail
outlets or wholesale purchaser-consumer facilities, and shall apply
starting September 1, 2010 for retail outlets and wholesale purchaser-
consumer facilities.
(2) Prior to July 15, 2010 at all downstream locations other than
retail outlets and wholesale purchaser-consumer facilities and prior to
September 1, 2010 at retail outlets and wholesale purchaser-consumer
facilities, the 500 ppm per-gallon standard of Sec. 80.510(a) shall
not apply at downstream locations once the diesel fuel has been dyed
red per Internal Revenue Service Code (26 U.S.C. 4082) for any fuel
that was produced or imported pursuant to the provisions of Sec.
80.536(f) or Sec. 80.554(a) or mixed with fuel produced pursuant to
these provisions.
(3) Beginning December 1, 2014, all NR diesel fuel at all
downstream locations shall comply with the sulfur standard of Sec.
80.510(b).
(c) Fuel redesignated at a downstream location. Subject to the
provisions of Sec. 80.527, nonroad, locomotive, and marine diesel fuel
may be redesignated at a downstream location to diesel fuel subject to
a different Sec. 80.510 per-gallon standard, high sulfur NRLM diesel
fuel, LM diesel fuel, or heating oil, provided that the PTD reflects
the standard of the new designation and:
(1) The new PTD complies with the appropriate PTD provisions of
Sec. 80.590;
(2) Fuel redesignated as high sulfur NRLM diesel fuel complies with
the requirements of Sec. 80.536(f)(1) (i) through (iv); and
(3) Fuel redesignated as 500 ppm NR diesel fuel after June 1, 2010
complies with the requirements of Sec. 80.536(g)(2) (i) through (iii).
12. A new Sec. 80.512 is added to read as follows:
Sec. 80.512 May an importer treat diesel fuel as blendstock?
An importer may exclude diesel fuel that it imports from its
calculations under the motor vehicle diesel fuel temporary compliance
option and credit calculations under Sec. Sec. 80.530-80.532, and from
its non-highway baseline and nonroad, locomotive and marine diesel fuel
credit calculations under Sec. Sec. 80.534-80.536, and instead the
importer may designate such diesel fuel as diesel fuel treated as
blendstock (DTAB), if all the following conditions are met:
(a) The DTAB must be included in all applicable baseline, credit
and compliance calculations for diesel fuel for a refinery operated by
the same company that is the importer. That company must meet all
refiner standards and requirements.
(b) The importer-company may not transfer title to the DTAB to
another party until the DTAB has been used to produce diesel fuel and
all refiner standards and requirements have been met for the diesel
fuel produced.
(c) The refinery at which the DTAB is used to produce diesel fuel
must be physically located at either the same terminal at which the
DTAB first arrives in the U.S., the import facility, or at a facility
to which the DTAB is directly transported from the import facility.
(d) The DTAB must be completely segregated from any other diesel
fuel,
[[Page 28527]]
including any diesel fuel tank bottoms, prior to the point of blending,
sampling and testing in the importer company's refinery operation. The
DTAB may, however, be added to a diesel fuel blending tank where the
diesel fuel tank bottom is not included as part of the batch volume for
the prior batch. In addition, the DTAB may be placed into a storage
tank that contains other DTAB imported by that importer. The DTAB also
may be discharged into a tank containing finished diesel fuel of the
same category as the diesel fuel which will be produced using the DTAB
(e.g., 15 ppm undyed or 15 ppm dyed diesel fuel) provided the blending
process is performed in that same tank.
(e) The company must account for the volume of diesel fuel produced
using DTAB in a manner that excludes the volume of any previously
certified diesel fuel. The diesel fuel tank bottom may not be included
in the company's refinery compliance calculations for that batch of
diesel fuel. This exclusion of previously-accounted-for diesel fuel
must be accomplished using the following approach:
(1) Determine the volume of any tank bottom that is previously
certified diesel fuel before any diesel fuel production begins.
(2) Add the DTAB plus any blendstock to the storage tank, and
completely mix the tank.
(3) Determine the volume and sulfur content of the diesel fuel
contained in the storage tank after blending is complete.
Mathematically subtract the volume of the tank bottom to determine the
volume of the DTAB plus blendstock added, which is reported to EPA as a
batch of diesel fuel produced.
(4) If previously certified diesel fuel having a sulfur content of
15 ppm or less is blended to DTAB, and the combined product after
blending has a sulfur content that exceeds 15 ppm, the refiner must
count the volume of previously certified diesel fuel against its
downgrading limitation under Sec. 80.527.
(5) As an alternative to paragraphs (e)(1) through (e)(4) of this
section, where an importer company has a ``blending'' tank that is used
only to combine DTAB and blending components, and no previously
certified diesel fuel is added to the tank, the importer company, in
its refiner capacity, may account for the diesel fuel produced in such
a blending tank by sampling and testing for the sulfur content of the
batch after DTAB and blendstock are added and mixed, and reporting the
volume of diesel fuel shipped from that tank, up to the point a new
blend is produced by adding new DTAB and blendstock.
(f) The importer must include the volume and sulfur content of each
batch of DTAB in the annual importer reports to EPA, but with a
notation that the batch is not included in the importer compliance
calculations because the product is DTAB. Any DTAB that ultimately is
not used in the importer company's refinery operation (e.g., a tank
bottom of DTAB at the conclusion of the refinery operation), must be
treated as newly imported diesel fuel, for which all required sampling
and testing, and recordkeeping must be accomplished, and included in
the company's importer compliance calculations for the averaging period
when this sampling and testing occurs.
(g) The importer must retain records that reflect the importation,
sampling and testing, and physical movement of any DTAB, and must make
these records available to EPA, on request.
13. A new Sec. 80.513 is added to read as follows:
Sec. 80.513 What provisions apply to transmix processors?
(a) Beginning June 1, 2006, transmix processors may elect to
utilize the provisions of Sec. 80.552(a) in lieu of complying with the
standards of this subpart.
(b) Beginning June 1, 2007, transmix processors may elect to use
the provisions of Sec. 80.554(a) in complying with the standards of
this subpart.
(c) Beginning June 1, 2010, transmix processors may elect to use
the provisions of Sec. 80.554(b) in complying with the standards of
this subpart.
(d) The provisions of paragraphs (a) through (c) apply only to that
volume of fuel produced by transmix processors from previously
certified diesel fuel (PCD) that no longer complies with the applicable
standards (i.e., contaminated product).
14. Section 80.520 is revised to read as follows:
Sec. 80.520 What are the standards and dye requirements for motor
vehicle diesel fuel?
(a) Standards. All motor vehicle diesel fuel is subject to the
following per-gallon standards:
(1) Sulfur content. 15 parts per million (ppm) maximum, except as
provided in paragraph (c) of this section;
(2) Cetane index and aromatic content. (i) A minimum cetane index
of 40; or
(ii) A maximum aromatic content of 35 volume percent.
(b) Dye requirements. (1) All motor vehicle diesel fuel shall be
free of visible evidence of dye solvent red 164 (which has a
characteristic red color in diesel fuel), except for motor vehicle
diesel fuel that is used in a manner that is tax exempt under section
4082 of the Internal Revenue Code. All motor vehicle diesel fuel shall
be free of yellow solvent 124.
(2) Except as provided in Sec. 80.534 and until June 1, 2010 per
Sec. 80.510(c), any diesel fuel that does not show visible evidence of
dye solvent red 164 shall be considered to be motor vehicle diesel fuel
and subject to all the requirements of this subpart for motor vehicle
diesel fuel, except for diesel fuel designated or classified for use
only in:
(i) The State of Alaska as provided under 40 CFR 69.51; or
(ii) Jet aircraft, a research and development testing program
exempted under Sec. 80.600, or motor vehicles covered by an exemption
under Sec. 80.602.
(c) Pursuant and subject to the provisions of Sec. Sec. 80.530-
80.532, 80.552(a), 80.560-80.561, and 80.620, only motor vehicle diesel
fuel produced or imported in full compliance with the requirements of
those provisions is subject to the following per-gallon standard for
sulfur content: 500 ppm maximum.
(d) Kerosene and any other distillate product, that meets the
definition of motor vehicle diesel fuel, is subject to the standards
and requirements under this section.
15. Section 80.521 is revised to read as follows:
Sec. 80.521 What are the standards and identification requirements
for diesel fuel additives?
(a) Except as provided in paragraph (b) of this section, any diesel
fuel additive that is added, intended for adding, used, or offered for
use in diesel fuel subject to the 15 ppm sulfur content standards of
Sec. Sec. 80.510(b) or 80.520(a) at any downstream location must:
(1) Have a sulfur content not exceeding 15 ppm; and
(2) Be accompanied by a product transfer document pursuant to Sec.
80.591 indicating that the additive complies with the 15 ppm standard
for diesel fuel, except for those diesel fuel additives which are only
sold in containers for use by the ultimate consumer of diesel fuel and
which are subject to the requirements of Sec. 80.591(d).
(b) Any diesel fuel additive that is added, intended for adding,
used, or offered for use in diesel fuel subject to the 15 ppm sulfur
content standards of Sec. 80.510(b) or Sec. 80.520(a) may have a
[[Page 28528]]
sulfur content exceeding 15 ppm provided that:
(1) The additive is added or used in the diesel fuel in a quantity
less than 1% by volume of the resultant additive/diesel fuel mixture;
(2) The product transfer document pursuant to Sec. 80.591
indicates that the additive may exceed the 15 ppm sulfur standards of
Sec. 80.510(b) or Sec. 80.520(a), that improper use of the additive
may result in non-complying fuel, and that the additive complies with
the sulfur information requirements of Sec. 80.591(b)(3); and
(3) The additive is not used or intended for use by an ultimate
consumer in diesel motor vehicles or nonroad, locomotive, or marine
engines.
16. Section 80.522 is revised to read as follows:
Sec. 80.522 May used motor oil be dispensed into diesel motor
vehicles or nonroad, locomotive, or marine diesel engines?
No person may introduce used motor oil, or used motor oil blended
with diesel fuel, into the fuel system of model year 2007 or later
diesel motor vehicles or model year 2011 or later nonroad diesel
engines, unless both of the following requirements have been met:
(a) The vehicle or engine manufacturer has received a Certificate
of Conformity under 40 CFR Parts 86 or 89 and the certification of the
vehicle or engine configuration is explicitly based on emissions data
with the addition of motor oil; and
(b) The oil is added in a manner and rate consistent with the
conditions of the Certificate of Conformity.
17. Section 80.523 is revised to read as follows:
Sec. 80.523 What diesel fuel designation requirements apply to
refiners and importers?
Any refiner or importer shall accurately and clearly designate all
fuel it produces or imports for use in diesel motor vehicles as either
motor vehicle diesel fuel meeting the 15 ppm sulfur standard under
Sec. 80.520(a)(1) or as motor vehicle diesel fuel meeting the 500 ppm
sulfur standard under Sec. 80.520(c). Starting June 1, 2007, or June
1, 2006 under the provisions of Sec. 80.535, any refiner or importer
shall accurately and clearly designate all other diesel fuel it
produces or imports as NR diesel fuel, LM diesel fuel, or NRLM diesel
fuel meeting the sulfur standard, if any, applicable to that batch
under this subpart, and any heating oil it produces or imports as
heating oil.
18. Section 80.527 is revised to read as follows:
Sec. 80.527 Under what conditions may motor vehicle or nonroad diesel
fuel subject to the 15 ppm sulfur standard be downgraded as diesel fuel
subject to the 500 ppm sulfur standard?
(a) Definitions. (1) As used in this section, downgrade means
changing the classification of undyed diesel fuel subject to the 15 ppm
sulfur standard under Sec. Sec. 80.523 and 80.510(b) or 80.520(a)(1)
to diesel fuel subject to the 500 ppm sulfur standard under Sec. Sec.
80.510(a) or 80.520(c). A downgrade occurs when the change in
classification takes place. Changing the classification of undyed
diesel fuel subject to the 15 ppm sulfur standard under Sec. Sec.
80.510(b) or 80.520(a)(1) to heating oil is not a downgrade for
purposes of this section and is not limited by the provisions of this
section.
(2) As used in this section undyed diesel fuel means diesel fuel
not containing visible evidence of dye solvent red 164.
(b) Who may downgrade. Any person in the diesel fuel distribution
system who has custody or title to diesel fuel may downgrade it.
(c) Downgrading limitation. (1) Except as provided in paragraphs
(d) and (e) of this section, a person described in paragraph (c)(4) of
this section may not downgrade a total of more than 20% of the undyed
diesel fuel (by volume) that is subject to the 15 ppm sulfur standard
of Sec. Sec. 80.510(b) or 80.520(a)(1) while such person has title to
or custody of such fuel. In addition, a refiner or importer may only
downgrade (subject to the 20% limit) undyed diesel fuel designated
under Sec. 80.523 as subject to 15 ppm sulfur standard under
Sec. Sec. 80.510(b) or 80.520(a)(1) after it has been so designated
and after it has been moved from the refinery's, or import facility's,
storage tank or other vessel where the diesel fuel batch was designated
as subject to the sulfur standard of Sec. 80.520(a) or Sec. 80.510(b)
under Sec. 80.523.
(2) The limitation of paragraph (c)(1) of this section applies
separately to each person who has custody or title of the fuel when it
is downgraded.
(3) Compliance with the limitation of paragraph (c)(1) of this
section shall be on an annual, calendar year basis (except in 2006
compliance shall be for the period June 1, 2006 through December 31,
2006, and in 2010 compliance shall be for the period January 1 through
May 31).
(4) The limitation of this section applies to persons who sell,
offer for sale, dispense, supply, store or transport diesel fuel. The
limitation does not apply to persons who are transferred custody or
title to diesel fuel when it is dispensed into motor vehicles or
nonroad engine equuipment at retail outlets.
(d) Diesel fuel in violation of the 15 ppm standard. Where diesel
fuel subject to the 15 ppm sulfur standard of Sec. Sec. 80.510(b) or
80.520(a)(1) is found to be in violation of any standard under
Sec. Sec. 80.510 (b) or 80.520(a) and is consequently downgraded, the
person, or persons, having custody and title to the fuel at the time it
is found to be in violation must include the volume of such fuel toward
its 20% volume limitation under paragraph (c)(1) of this section,
unless the person, or persons, demonstrates that it did not cause the
violation.
(e) Special provisions for retail outlets and wholesale purchaser-
consumer facilities. Notwithstanding the provisions of paragraph (c)(1)
of this section, retailers and wholesale purchaser-consumers shall
comply with the downgrading limitation as follows:
(1) Retailers and wholesale purchaser-consumers who sell, offer for
sale, or dispense undyed diesel fuel that is subject to the 15 ppm
sulfur standard under Sec. 80.520(a)(1) are exempt from the volume
limitations of paragraph (c)(1) of this section.
(2) A retailer or wholesale purchaser-consumer who does not sell,
offer for sale, or dispense diesel fuel subject to the 15 ppm sulfur
standard under Sec. Sec. 80.510(b) or 80.520(a)(1) may not downgrade a
volume of diesel fuel classified as subject to the 15 ppm sulfur
standard greater than 20% of the total volume of motor vehicle diesel
fuel that it sells, offers for sale, or dispenses annually.
(f) Product transfer documents. If the custody or title to any
diesel fuel that is downgraded under this section is transferred, the
product transfer documents under Sec. 80.590 for such fuel must
reflect the change in classification to diesel fuel subject to the 500
ppm sulfur standard.
(g) Recordkeeping requirement. Any person subject to the provisions
of this section, as described in paragraph (c)(4) of this section, who
downgrades any undyed diesel fuel previously classified as subject to
the 15 ppm sulfur standard under Sec. Sec. 80.510(b) or 80.520(a)(1)
during any calendar year, must make and maintain records sufficient to
show compliance with the requirements and limitations of this section.
(h) Termination of downgrading limitations. The provisions of this
section shall not apply after May 31, 2010.
19. Section 80.530 is revised to read as follows:
[[Page 28529]]
Sec. 80.530 Under what conditions can 500 ppm motor vehicle diesel
fuel be produced or imported?
(a) Beginning June 1, 2006, a refiner or importer may produce or
import motor vehicle diesel fuel subject to the 500 ppm sulfur content
standard of Sec. 80.520(c) if all of the following requirements are
met:
(1) Each batch of motor vehicle diesel fuel subject to the 500 ppm
sulfur content standard must be designated by the refiner or importer
as subject to such standard, pursuant to Sec. 80.523.
(2) The refiner or importer must meet the requirements for product
transfer documents in Sec. 80.590 for each batch subject to the 500
ppm sulfur content standard.
(3)(i) The volume V500 of motor vehicle diesel fuel that is
produced or imported during a compliance period, as provided in
paragraph (a)(5) of this section, may not exceed the following volume
limit:
(A) For compliance periods prior to 2010, 20% of the volume Vt of
motor vehicle diesel fuel that is produced or imported during a
compliance period plus an additional volume of motor vehicle diesel
fuel represented by credits properly generated and used pursuant to the
requirements of Sec. Sec. 80.531 and 80.532.
(B) For the compliance period of January 1, 2010 through May 31,
2010, the volume of motor vehicle diesel fuel represented by credits
properly generated and used pursuant to the requirements of Sec. Sec.
80.531 and 80.532.
(ii) The terms V500 and Vt have the meaning specified in Sec.
80.531(a)(2).
(4) Compliance with the volume limit in paragraph (a)(3) of this
section must be determined separately for each refinery. For an
importer, such compliance must be determined separately for each Credit
Trading Area (as defined in Sec. 80.531) into which motor vehicle
diesel fuel is imported. If a party is both a refiner and an importer,
such compliance shall be determined separately for the refining and
importation activities.
(5) Compliance with the volume limit in paragraph (a)(3) of this
section shall be determined on a calendar year basis, where the
calendar year period is from January 1 through December 31. For the
year 2006, compliance shall be determined for the period June 1, 2006
through December 31, 2006. For the year 2010, compliance shall be
determined for the period of January 1, 2010 through May 31, 2010.
(6) Any motor vehicle diesel fuel produced or imported above the
volume limit in paragraph (a)(3) of this section shall be subject to
the 15 ppm sulfur content standard. However, for any compliance period
prior to and including 2009, a refiner or importer may exceed the
volume limit in paragraph (a)(3) of this section by no more than 5
percent of the volume Vt of diesel fuel produced or imported during the
compliance period, provided that for the immediately following calendar
year:
(i) The refiner or importer complies with the volume limit in
paragraph (a)(3) of this section; and
(ii) The refiner or importer produces or imports a volume of motor
vehicle diesel fuel subject to the 15 ppm sulfur standard, or obtains
credits properly generated and used pursuant to the requirements of
Sec. Sec. 80.531 and 80.532 that represent a volume of motor vehicle
diesel fuel, equal to the volume of the exceedence for the prior
compliance period.
(b) After May 31, 2010, no refiner or importer may produce or
import motor vehicle diesel fuel subject to the 500 ppm sulfur content
standard pursuant to this section.
20. Section 80.531 is amended by revising paragraphs (a)(1) and
(a)(2) to read as follows:
Sec. 80.531 How are motor vehicle diesel fuel credits generated?
(a) * * *
(1) A refiner or importer may generate credits during the period
June 1, 2006 through December 31, 2009, for motor vehicle diesel fuel
produced or imported that is designated as subject to the 15 ppm sulfur
content standard under Sec. 80.520(a)(1). Credits may be generated
only if the volume of motor vehicle diesel fuel designated under Sec.
80.523 as subject to the 15 ppm sulfur standard of Sec. 80.520(a)
exceeds 80% of the total volume of motor vehicle diesel fuel produced
or imported as described in paragraph (a)(2) of this section.
(2) The number of motor vehicle diesel fuel credits generated shall
be calculated for each compliance period (as specified in Sec.
80.530(a)(5)) as follows:
C = V15-(0.80 x Vt)
Where:
C = the positive number of motor vehicle diesel fuel credits generated,
in gallons.
V15 = the total volume in gallons of diesel fuel produced or imported
that is designated under Sec. 80.523 as motor vehicle diesel fuel and
subject to the standards of Sec. 80.520(a) during the compliance
period.
V500 = the total volume in gallons of diesel fuel produced or imported
that is designated under Sec. 80.523 as motor vehicle diesel fuel and
subject to the 500 ppm sulfur standard under Sec. 80.520(c) plus the
total volume of any other diesel fuel (not including V15, diesel fuel
that is dyed in accordance with Sec. 80.520(b) at the refinery or
import facility where the diesel fuel is produced or imported, or that
diesel fuel that is designated as NRLM under Sec. 80.523) represented
as having a sulfur content not exceeding 500 ppm.
Vt = V15 + V500.
* * * * *
21. Section 80.532 is revised to read as follows:
Sec. 80.532 How are motor vehicle diesel fuel credits used and
transferred?
(a) Credit use. Motor vehicle diesel fuel credits generated under
Sec. 80.531 may be used to meet the volume limit of Sec. 80.530(a)(3)
provided that:
(1) The motor vehicle diesel fuel credits were generated and
reported according to the requirements of this subpart; and
(2) The requirements of paragraphs (b), (c), (d), and (e) of this
section are met.
(b) Motor vehicle diesel fuel credits generated under Sec. 80.531
may be used by a refinery or by an importer to comply with Sec. 80.530
by applying one credit for every gallon of motor vehicle diesel fuel
needed to meet compliance with the volume limit of Sec. 80.530(a)(3).
(c) Motor vehicle diesel fuel credits generated may be banked for
use or transfer in a later compliance period or may be transferred to
another refinery or importer for use as provided in paragraph (d) of
this section.
(d) Credit transfers. (1) Motor vehicle diesel fuel credits
obtained from another refinery or from another importer, including
early motor vehicle diesel fuel credits and small refiner motor vehicle
diesel fuel credits as described in Sec. 80.531 (b), (c) (d), and (e),
may be used to satisfy the volume limit of Sec. 80.530(a)(3) if all
the following conditions are met:
(i) The motor vehicle diesel fuel credits were generated in the
same CTA as the CTA in which motor vehicle diesel fuel credits are used
to achieve compliance;
(ii) The motor vehicle diesel fuel credits are used in compliance
with the time period limitations for credit use in this subpart;
(iii) Any credit transfer takes place no later than the last day of
February following the compliance period when the motor vehicle diesel
fuel credits are used;
[[Page 28530]]
(iv) No credit may be transferred more than twice, as follows: The
first transfer by the refiner or importer who generated the credit may
only be made to a refiner or importer who intends to use the credit; if
the transferee cannot use the credit, it may make a second and final
transfer only to a refiner or importer who intends to use the credit.
In no case may a credit be transferred more than twice before being
used or terminated;
(v) The credit transferor must apply any motor vehicle diesel fuel
credits necessary to meet the transferor's annual compliance
requirements before transferring motor vehicle diesel fuel credits to
any other refinery or importer;
(vi) No motor vehicle diesel fuel credits may be transferred that
would result in the transferor having a negative credit balance; and
(vii) Each transferor must supply to the transferee records
indicating the year the motor vehicle diesel fuel credits were
generated, the identity of the refiner (and refinery) or importer who
generated the motor vehicle diesel fuel credits, the CTA of credit
generation, and the identity of the transferring party, if it is not
the same party who generated the motor vehicle diesel fuel credits.
(2) In the case of motor vehicle diesel fuel credits that have been
calculated or created improperly, or are otherwise determined to be
invalid, the following provisions apply:
(i) Invalid motor vehicle diesel fuel credits cannot be used to
achieve compliance with the transferee's volume requirements regardless
of the transferee's good faith belief that the motor vehicle diesel
fuel credits were valid.
(ii) The refiner or importer who used the motor vehicle diesel fuel
credits, and any transferor of the motor vehicle diesel fuel credits,
must adjust their credit records, reports and compliance calculations
as necessary to reflect the proper motor vehicle diesel fuel credits.
(iii) Any properly created motor vehicle diesel fuel credits
existing in the transferor's credit balance after correcting the credit
balance, and after the transferor applies motor vehicle diesel fuel
credits as needed to meet the compliance requirements at the end of the
compliance period, must first be applied to correct the invalid
transfers before the transferor trades or banks the motor vehicle
diesel fuel credits.
(e) Limitations on credit use. (1) Motor vehicle diesel fuel
credits may not be used to achieve compliance with any requirements of
this subpart other than the volume limit of Sec. 80.530(a)(3), unless
specifically approved by the Administrator pursuant to a hardship
relief petition under Sec. 80.560 or Sec. 80.561.
(2) A refiner or importer possessing motor vehicle diesel fuel
credits must use all motor vehicle diesel fuel credits in its
possession prior to applying the credit deficit provisions of Sec.
80.530(a)(6).
(3) No motor vehicle diesel fuel credits may be used to meet
compliance with this subpart subsequent to the compliance period ending
May 31, 2010.
22. A new Sec. 80.533 is added to read as follows:
Sec. 80.533 How does a refiner or importer apply for a non-highway
baseline percentage?
(a) The refiner or importer must submit an application to EPA that
includes the information required under paragraph (c) of this section
by the dates specified in paragraph (f) of this section. A refiner must
apply for a non-highway baseline percentage for each refinery. An
importer must apply for a non-highway baseline percentage for each CTA,
as defined in Sec. 80.531(a)(5), into which it imports NRLM fuel.
(b) The non-highway baseline percentage application must be sent to
the following address: U.S. EPA--Attn: Non-highway Baseline (6406J),
1200 Pennsylvania Avenue, NW, Washington, DC 20460 (regular mail) or
U.S. EPA, Attn: Non-highway Baseline, Transportation and Regional
Programs Division, 501 3rd Street, NW (6406J), Washington, DC 20001
(express mail).
(c) A non-highway baseline percentage application must be submitted
for each refinery or importer and include the following information:
(1) A listing of the names and addresses of all refineries or
importersowned by the corporation for which the refiner or importer is
applying for non-highway baseline percentages.
(2)(i) For refiners or importers, the non-highway baseline
percentage for produced during the three calendar years beginning
January 1 of 2003, 2004, and 2005, as calculated under paragraph (d)(1)
of this section.
(ii) For refiners that so choose, in addition to the baseline
percentage under paragraph (c)(2)(i) of this section, an alternate non-
highway baseline percentage for fuel produced during the period from
June 1, 2006 through May 31, 2007, as calculated under paragraph (d)(2)
of this section.
(3) A letter signed by the president, chief operating officer of
the company, or his/her delegate, stating that the information
contained in the non-highway baseline determination is true to the best
of his/her knowledge.
(4) Name, address, phone number, facsimile number and E-mail
address of a corporate contact person.
(5) For each batch of diesel fuel or heating oil produced or
imported during each 12-month baseline calculation period:
(i) The date that production was completed or importation occurred
for the batch and the batch designation under Sec. 80.523.
(ii) The batch volume; and
(iii) Whether the batch was dyed or not dyed, and if not dyed,
whether the batch was exempt from the dye provisions of Sec.
80.520(b)(2) and not defined as motor vehicle diesel fuel.
(6) Other appropriate information as requested by EPA.
(d) Calculation of the Non-Highway Baseline Percentage, B%. (1)
Under paragraph (c)(2)(i) of this section, B% equals the average annual
volume of diesel fuel and heating oil produced or imported during the
three baseline calendar years that was dyed with solvent red 164 (or if
exempt from the dye provision of Sec. 80.520(b)(2), does not meet the
definition of motor vehicle diesel fuel) divided by the total volume of
diesel fuel and heating oil produced or imported during this period,
multiplied by 100.
(2) Under paragraph (c)(2)(ii) of this section, B% equals the
average annual volume of diesel fuel and heating oil produced during
the period from June 1, 2006 through May 31, 2007 that was dyed with
solvent red 164 (or if exempt from the dye provision of Sec.
80.520(b)(2), does not meet the definition of motor vehicle diesel
fuel) divided by the total volume of diesel fuel and heating oil
produced during this period, multiplied by 100.
(3) For purposes of this section, fuel produced for export, jet
fuel (JetA), and fuel specifically produced to meet military
specification (such as JP-4, JP-8, and F-76), shall not be included in
baseline calculations.
(e) Refineries that did not produce or import facilities that did
not import diesel fuel for at least 12 months during the period from
January 1, 2003 through December 31, 2005 shall be assigned a non-
highway baseline percentage based on their location, as specified in
the following table:
[[Page 28531]]
[In percentages]
----------------------------------------------------------------------------------------------------------------
Oregon and
PADD 1 PADD 2 PADD 3 PADD 4 Washington Alaska Hawaii i California
----------------------------------------------------------------------------------------------------------------
41 20 26 13 21 68 40 0
----------------------------------------------------------------------------------------------------------------
(f)(1) Applications submitted under paragraph (c)(2)(i) of this
section must be postmarked by February 28, 2006.
(2) Applications submitted under paragraph (c)(2)(ii) of this
section must be postmarked by August 1, 2007.
(g)(1) For applications submitted under paragraph (c)(2)(i) of this
section, EPA will notify refiners or importers by June 1, 2006 of
approval of the baselines for each of the refiner's refineries or
importer's import facilities or of any deficiencies in the refiner's or
importer's application.
(2) For applications submitted under paragraph (c)(2)(ii) of this
section, EPA will notify refiners by December 1, 2007 regarding
approval of the baselines for each of the refiner's refineries or of
any deficiencies in the refiner's application.
(g) If at any time the non-highway baseline percentage submitted in
accordance with the requirements of this section is determined to be
incorrect, EPA will notify the refiner of the corrected baseline.
23. A new Sec. 80.534 is added to read as follows:
Sec. 80.534 Use of the non-highway baseline percentage.
(a) Beginning June 1, 2007--or June 1, 2006 pursuant to the
provisions of Sec. 80.535(a)--and until June 1, 2010, a refiner or
importer may use the following provisions in lieu of the dye
requirements of Sec. 80.520(b) if it has an EPA-approved non-highway
baseline percentage under Sec. 80.533.
(1) A refiner or importer must notify EPA of its intention to use
these provisions by April 1, 2006, or by April 1 of any subsequent year
during which it intends to use the these provisions for the first time.
(2) A separate notification is required for each refinery or each
importer by the CTA into which it imports NRLM diesel fuel.
(3) The decision to use or not use these provisions shall apply for
the entire calculation period, as defined below, and for the refinery's
entire production volume or for the importer's entire import volume by
the CTA into which it imports NRLM fuel.
(4) EPA will presume no change from the previous year in the
refiner's or importer's decision to use or not use these provisions
unless the refiner or importer notifies EPA by April 1 of any year
during which such a change would apply.
(b) For purposes of this section:
(1) ``Calculation period'' means a 12-month period from June 1
through May 31 beginning in 2007, 2008, or 2009.
(2) ``Vtotal'' means the total volume of diesel fuel and heating
oil produced or imported during a calculation period by a refinery or
importer CTA, respectively.
(3) ``Vmarked'' means the total volume of heating oil produced or
imported and marked with solvent yellow 124 by the refiner or importer
pursuant to Sec. 80.510(c) during a calculation period.
(4) ``B%'' is the non-highway baseline percentage approved by EPA
for a refinery or importer CTA pursuant to Sec. 80.533(d).
(5) ``Vnrlm'' = (Vtotal x B%/100)-Vmarked).
(6) ``Vmotorvehicle'' = Vtotal * (100%-B%)/100.
(c) For each calculation period:
(1) The total volume of diesel fuel designated as NRLM (including
both 500 ppm diesel fuel and any high sulfur diesel fuel produced
pursuant to the provisions of Sec. Sec. 80.535 and 80.536) whether
dyed or undyed may not be greater than Vnrlm.
(2) The volume of diesel fuel designated by a refiner or importer
as motor vehicle diesel fuel pursuant to Sec. 80.523 shall not be less
than Vmotorvehicle.
(d)(1) All the requirements of this subpart applicable to motor
vehicle diesel fuel shall apply to diesel fuel designated as motor
vehicle diesel fuel under the provisions of this section. Except for
the provisions of Sec. 80.510(c) concerning solvent red 164, all the
requirements of this subpart applicable to nonroad, locomotive and
marine diesel fuel shall apply to diesel fuel designated as NRLM diesel
fuel under the provisions of this section.
(2) Diesel fuel designated as motor vehicle diesel fuel and diesel
fuel designated as NRLM diesel fuel under the provisions of this
section may be mixed after they have been designated, or may remain
commingled if designated without the fuels being physically separated,
as long as the resulting fuel or mixture of fuels complies with all of
the requirements that were applicable to each batch contained in the
mixture.
24. A new Sec. 80.535 is added to read as follows.
Sec. 80.535 How are nonroad, locomotive and marine (NRLM) diesel fuel
credits generated?
(a) Generation of high sulfur NRLM credits from June 1, 2006
through May 31, 2007. (1) During the period June 1, 2006 through May
31, 2007, a refiner or importers may generate credits pursuant to the
provisions of this section if all of the following conditions are met:
(i) The refiner or importer notifies EPA of its intention to
generate credits and the period during which it will generate credits.
This notification must be received by EPA at least 120 calendar days
prior to the date it begins generating credits under this section;
(ii) Each batch or partial batch of NRLM diesel fuel for which
credits are claimed shall be subject to all of the provisions of this
subpart for NRLM diesel fuel as if it had been produced after June 1,
2007 and before June 1, 2010.
(iii) The number of nonroad high-sulfur credits (HSC) in gallons
that are generated shall be a positive number.
(2) The refiner or importer shall choose one of the following
methods for calculating credits for each calculation period.
(i) For fuel that is dyed per the requirements of Sec.
80.510(c)(1)(i), HSC equals the volume of fuel in gallons produced or
imported during the period identified in paragraph (a)(1)(i) of this
section that is designated as NRLM diesel fuel and that is subject to
and complies with the provisions of Sec. 80.510(a); or
(ii) For dyed or undyed fuel that complies with the provisions of
Sec. 80.534 for a calculation period of June 1, 2006 through May 31,
2007, determine HSC as follows:
HSC = V510 + V520-Vmotorvehicle
Where:
V510 = The total volume of fuel produced or imported during
the period identified in paragraph (a)(1)(i) of this section that
complies with the standards of Sec. 80.510(a) or (b).
V520 = The total volume of fuel produced or imported during
the period identified in paragraph (a)(1)(i) of this section that
complies
[[Page 28532]]
with the standards of Sec. 80.520(a) or (c).
Vmotorvehicle = Vtotal * (100%-B%)/100.
(3) High-sulfur nonroad credits shall be generated and designated
as follows:
(i) Credits shall be generated separately for each importer by CTA
or each refinery of a refiner.
(ii) Credits may not be generated by both a foreign refiner and by
an importer for the same motor vehicle diesel fuel.
(iii) Credits shall not be generated under both Sec. 80.531 and
this section for the same diesel fuel.
(iv) Any credits generated by a foreign refiner shall be generated
as provided in Sec. 80.620(c) and this section.
(4) No credits may be generated under this paragraph after May 31,
2007.
(5) The refiner or importer must submit a report to the
Administrator no later than July 31, 2007. The report must demonstrate
that all the nonroad, locomotive, and marine diesel fuel produced or
imported which generated credits met the applicable requirements of
paragraphs (a)(1) through (a)(4) of this section. If the Administrator
finds that such credits did not in fact meet the requirements of
paragraphs (a)(1) through (a)(4) of this section, as applicable, or if
the Administrator determines that there is insufficient information to
determine the validity of such credits, the Administrator may deny the
credits submitted in whole or in part.
(b) Generation of high-sulfur NRLM credits by small refiners from
June 1, 2006 through May 31, 2010. (1) Notwithstanding the dates
specified in paragraph (a) of this section, a refiner that is approved
by the EPA as a small refiner under Sec. 80.551 may generate credits
under paragraph (a) of this section during any calculation period
beginning June 1 of 2006, 2007, 2008, or 2009 for diesel fuel produced
or imported that is designated as NRLM diesel fuel and complies with
the provisions of Sec. 80.510(a).
(2) The small refiner must submit a report to the Administrator no
later than July 31 after the end of each calculation period during
which credits were generated. The report must demonstrate that all the
NRLM diesel fuel produced or imported which generated credits met the
applicable requirements of paragraphs (a)(1) through (a)(4) of this
section. If the Administrator finds that such credits did not in fact
meet the requirements of paragraphs (a)(1) through (a)(4) of this
section, as applicable, or if the Administrator determines that there
is insufficient information to determine the validity of such credits,
the Administrator may deny the credits submitted in whole or in part.
(3) In addition, a foreign refiner that is approved by the
Administrator to generate credits under Sec. 80.554 shall comply with
the requirements of Sec. 80.620.
(c) Generation of 500 ppm nonroad credits from June 1, 2009 through
May 31, 2010. (1) During the calculation period of June 1, 2009 through
May 31, 2010, a refiner or importer may generate credits pursuant to
the provisions of this section if all of the following conditions are
met:
(i) The refiner or importer notifies EPA of its intention to
generate credits and the period during which it will generate credits.
This notification must be received by EPA at least 120 calendar days
prior to the date it begins generating credits under this section;
(ii) Each batch or partial batch of NRLM diesel fuel for which
credits are claimed shall be subject to all of the provisions of this
subpart for NR diesel fuel as if it had been produced after June 1,
2010.
(iii) The number of 500 ppm nonroad credits in gallons that are
generated, C500, shall be a positive number calculated as follows:
C500 = V15-[(100%-B%)/100 x Vtotal]
Where:
V15 = The total volume in gallons of 15 ppm diesel fuel produced or
imported during the period stated under paragraph (c)(1)(i) of this
section that is designated as either motor vehicle diesel fuel or
nonroad diesel fuel.
Vtotal= As defined in Sec. 80.534.
B% = As determined in Sec. 80.534.
(2) 500 ppm nonroad credits shall be generated and designated as
follows:
(i) Credits shall be generated separately for each importer by CTA
or each refinery of a refiner.
(ii) Credits may not be generated by both a foreign refiner and by
an importer for the same diesel fuel.
(iii) Credits shall not be generated under both Sec. 80.531 and
this section for the same diesel fuel.
(iv) Any credits generated by a foreign refiner shall be generated
as provided in Sec. 80.620(c) and this section.
(3) No credits may be generated under this paragraph after May 31,
2010.
(4) The refiner or importer must submit a report to the
Administrator no later than July 31, 2010. The report must demonstrate
that all the 15 ppm NR diesel fuel produced or imported which generated
credits met the applicable requirements of paragraphs (c)(1) through
(c)(4) of this section. If the Administrator finds that such credits
did not in fact meet the requirements of paragraphs (c)(1) through
(c)(4) of this section, as applicable, or if the Administrator
determines that there is insufficient information to determine the
validity of such credits, the Administrator may deny the credits
submitted in whole or in part.
(d) Generation of 500 ppm nonroad credits by small refiners from
June 1, 2009 through May 31, 2012. (1) Notwithstanding the dates
specified in paragraph (c) of this section, a refiner that is approved
by the EPA as a small refiner under Sec. 80.551 may generate credits
under paragraph (c) of this section during any calculation period
beginning June 1 of 2009, 2010, or 2011 for diesel fuel produced or
imported that is designated as NR diesel fuel and complies with the
provisions of Sec. 80.510(a).
(2) The small refiner must submit a report to the Administrator no
later than July 31 after the end of each calculation period during
which credits were generated. The report must demonstrate that all the
15 ppm NR diesel fuel produced or imported for which credits were
generated met the applicable requirements of paragraphs (c)(1) through
(c)(3) of this section. If the Administrator finds that such credits
did not in fact meet the requirements of paragraphs (c)(1) through
(c)(3) of this section, as applicable, or if the Administrator
determines that there is insufficient information to determine the
validity of such credits, the Administrator may deny the credits
submitted in whole or in part.
(3) In addition, a foreign refiner that is approved by the
Administrator to generate credits under Sec. 80.554 shall comply with
the requirements of Sec. 80.620.
25. A new Sec. 80.536 is added to read as follows:
Sec. 80.536 How are nonroad, locomotive, and marine diesel fuel
credits used and transferred?
(a) Credit use. Credits generated under Sec. 80.535(a) and (b) may
be used to meet the nonroad, locomotive, and marine NRLM diesel fuel
sulfur standard of Sec. 80.510(a), and credits generated under Sec.
80.535(c) and (d) may be used to meet the NR diesel fuel sulfur
standard of Sec. 80.510(b), provided that:
(1) The credits were generated and reported according to the
requirements of this subpart; and
(2) The requirements of paragraphs (b), (c), (d), (e), (f), and (g)
of this section are met.
[[Page 28533]]
(b) Credits generated under Sec. 80.535 may be used by a refinery
or an importer to comply with the diesel fuel standards of Sec.
80.510(a) and (b) by applying one credit for every gallon of diesel
fuel that does not comply with the applicable standard.
(c) Credits generated may be banked for use at a later time or may
be transferred to any other refinery or importer nationwide for use as
provided in paragraph (d) of this section.
(d) Credit transfers. (1) Credits generated under Sec. 80.535 that
are obtained from another refinery or importer may be used to comply
with the diesel fuel sulfur standards of Sec. 80.510(a) and (b) if all
the following conditions are met:
(i) The credits are used in compliance with the time period
limitations for credit use in this subpart;
(ii) Any credit transfer is completed no later than the last day of
February following the calendar year when the credits are used to
comply with a standard under paragraph (a) of this section;
(iii) No credit is transferred more than twice, as follows: The
first transfer by the refiner or importer who generated the credit may
only be made to a refiner or importer that intends to use the credit;
if the transferee cannot use the credit, it may make a second and final
transfer only to a refiner or importer who intends to use the credit.
In no case may a credit be transferred more than twice before it is
used or it expires;
(iv) The credit transferor applies any credits necessary to meet
the transferor's annual compliance requirements before transferring
credits to any other refinery or importer;
(v) No credits are transferred that would result in the transferor
having a negative credit balance; and
(vi) Each transferor supplies to the transferee records indicating
the year the credits were generated, the identity of the refiner (and
refinery) or importer that generated the credits, and the identity of
the transferor, if it is not the same party that generated the credits.
(2) In the case of credits that have been calculated or created
improperly, or are otherwise determined to be invalid, the following
provisions apply:
(i) Invalid credits cannot be used to achieve compliance with the
transferee's volume requirements regardless of the transferee's good
faith belief that the credits were valid.
(ii) The refiner or importer that used the credits, and any
transferor of the credits, must adjust its credit records, reports and
compliance calculations as necessary to reflect the proper credits.
(iii) Any properly created credits existing in the transferor's
credit balance after correcting the credit balance, and after the
transferor applies credits as needed to meet the compliance
requirements at the end of the calendar year, must first be applied to
correct the invalid transfers before the transferor trades or banks the
credits.
(e) Limitations on credit use. (1) Credits may not be used to
achieve compliance with any requirements of this subpart other than the
standards of Sec. 80.510(a) and (b), unless specifically approved by
the Administrator pursuant to a hardship relief petition under Sec.
80.560 or Sec. 80.561.
(2) No credits may be used after May 31, 2012.
(f) Use of high sulfur NRLM credits. (1) High sulfur nonroad
credits (HSC) generated under Sec. 80.535(a) or (b) may be used on a
one for one basis to meet the NRLM diesel fuel sulfur standard of Sec.
80.510(a) from June 1, 2007 through May 31, 2010 subject to the
following restrictions. Any high sulfur NRLM diesel fuel produced after
June 1, 2007 through the use of credits must:
(i) Be dyed red per the provisions of Sec. 80.510(c)(1)(i) at the
point of production, importation, or redesignation under Sec.
80.511(c);
(ii) Be associated with a product transfer document that bears a
unique product code as specified in Sec. 80.590;
(iii) Be segregated in the distribution system from any 15 ppm
sulfur diesel fuel throughout the distribution system to the end-user;
and
(iv) Be segregated from any 500 ppm sulfur diesel fuel in the
distribution system up to the point where both fuels are dyed red per
Internal Revenue Service Code (26 U.S.C. 4082).
(2) No high sulfur NRLM credits may be used subsequent to the
compliance period ending May 31, 2010.
(3) Any high sulfur NRLM credits not used under the provisions of
paragraph (f)(1) may be converted into 500 ppm nonroad credits on a one
for one basis.
(g) Use of 500 ppm nonroad credits. (1) 500 ppm nonroad credits
(C500) generated under Sec. 80.535(c) or (d) or converted from high
sulfur nonroad credits under paragraph (f)(3) of this section may be
used on a one for one basis to meet the NR diesel fuel sulfur standard
of Sec. 80.510(b) from June 1, 2010 through May 31, 2012, subject to
the restrictions in paragraphs (g)(2) and (g)(3) of this section.
(2) Any 500 ppm nonroad diesel fuel produced or imported after June
1, 2010 through the use of these credits would have to:
(i) Be dyed red per the provisions of Sec. 80.510(c)(1)(i) at the
point of production, importation, or redesignation under Sec.
80.511(c);
(ii) Bear a unique product code as specified in Sec. 80.590; and
(iii) Be segregated in the distribution system from any 15 ppm
sulfur diesel fuel or 500 ppm sulfur locomotive and marine diesel fuel
throughout the distribution system to the end-user.
(3) Refiners or importers wishing to produce or import 500 ppm
sulfur nonroad diesel fuel and sell it as nonroad diesel fuel after May
31, 2010 would first have to provide EPA with a plan for EPA approval
demonstrating that they will ensure the product segregation described
in paragraph (g)(2)(iii) of this section.
(4) No 500 ppm sulfur credits may be used after May 31, 2012.
26. Section 80.550 is revised to read as follows:
Sec. 80.550 What is the definition of a motor vehicle diesel fuel
small refiner or a NRLM diesel fuel small refiner under this subpart?
(a) A motor vehicle diesel fuel small refiner is defined as any
person, as defined by 42 U.S.C. 7602(e), who:
(1) Produces diesel fuel at a refinery by processing crude oil
through refinery processing units; and
(2) Employed an average of no more than 1,500 people, based on the
average number of employees for all pay periods from January 1, 1999,
to January 1, 2000; and
(3) Had an average crude capacity less than or equal to 155,000
barrels per calendar day (bpcd) for 1999; or
(4) Has been approved by EPA as a small refiner under Sec. 80.235
and continues to meet the criteria of a small refiner under Sec.
80.225.
(b) A NRLM diesel fuel small refiner is defined as any person, as
defined by 42 U.S.C. 7602(e), who:
(1) Produces diesel fuel at a refinery by processing crude oil
through refinery processing units; and
(2) Employed an average of no more than 1,500 people, based on the
average number of employees for all pay periods from January 1, 2002,
to January 1, 2003; and
(3) Had an average crude capacity less than or equal to 155,000
barrels per calendar day (bpcd) for 2002.
(c) For the purpose of determining the number of employees and
crude capacity under paragraph (a) of this section:
(1) The refiner shall include the employees and crude capacity of
any subsidiary companies, any parent company and subsidiaries of the
parent company in which the parent has 50% or greater ownership, and
any joint venture partners.
[[Page 28534]]
(2) For any refiner owned by a governmental entity, the number of
employees and total crude capacity as specified in paragraph (a) of
this section shall include all employees and crude production of the
government to which the governmental entity is a part.
(3) Any refiner owned and controlled by an Alaska Regional or
Village Corporation organized pursuant to the Alaska Native Claims
Settlement Act (43 U.S.C. 1601--1629) is not considered an affiliate of
such entity, or with other concerns owned by such entity solely because
of their common ownership.
(d) For the purpose of determining the number of employees and
crude capacity under paragraph (b) of this section:
(1) The refiner shall include the employees and crude capacity of
any subsidiary companies, any parent company and subsidiaries of the
parent company in which the parent has 50% or greater ownership, and
any joint venture partners.
(2) For any refiner owned by a governmental entity, the number of
employees and total crude capacity as specified in paragraph (b) of
this section shall include all employees and crude production of the
government to which the governmental entity is a part.
(3) Any refiner owned and controlled by an Alaska Regional or
Village Corporation organized pursuant to the Alaska Native Claims
Settlement Act (43 U.S.C. 1601--1629) is not considered an affiliate of
such entity, or with other concerns owned by such entity solely because
of their common ownership.
(e)(1) Notwithstanding the provisions of paragraph (a) of this
section, a refiner that acquires a refinery after January 1, 2000, or
reactivates a refinery that was shut down or was non-operational
between January 1, 1999, and January 1, 2000, may apply for motor
vehicle diesel fuel small refiner status in accordance with the
provisions of Sec. 80.551(c)(1)(ii).
(2) Notwithstanding the provisions of paragraph (b) of this
section, a refiner that acquires a refinery after January 1, 2003, or
reactivates a refinery that was shutdown or was non-operational between
January 1, 2002, and January 1, 2003, may apply for NRLM diesel fuel
small refiner status in accordance with the provisions of Sec.
80.551(c)(2)(ii).
(f) Ineligible parties. The following are ineligible for the small
refiner provisions:
(1)(i) For motor vehicle diesel fuel, refiners with refineries
built or started up after January 1, 2000;
(ii) For NRLM diesel fuel, refiners with refineries built or
started up after January 1, 2002;
(2)(i) For motor vehicle diesel fuel, persons who exceed the
employee or crude oil capacity criteria under this section on January
1, 2000, but who meet these criteria after that date, regardless of
whether the reduction in employees or crude oil capacity is due to
operational changes at the refinery or a company sale or
reorganization;
(ii) For NRLM diesel fuel, persons who exceed the employee or crude
oil capacity criteria under this section on January 1, 2003, but who
meet these criteria after that date, regardless of whether the
reduction in employees or crude oil capacity is due to operational
changes at the refinery or a company sale or reorganization;
(3) Importers; and
(4) Refiners who produce motor vehicle diesel fuel or NRLM diesel
fuel other than by processing crude oil through refinery processing
units.
(g)(1)(i) Refiners who qualify as motor vehicle diesel fuel small
refiners under this section and subsequently employ more than 1,500
people as a result of merger with or acquisition of or by another
entity, or exceed the 155,000 bpcd crude capacity limit as a result of
merger with or acquisition of or by another entity after January 1,
2004, are disqualified as small refiners. If this occurs, the refiner
shall notify EPA in writing no later than 20 days following this
disqualifying event.
(ii) Except as provided under paragraph (g)(3) of this section, any
refiner whose status changes under this paragraph shall meet the
applicable standards of Sec. 80.520 within a period of up to 24 months
of the disqualifying event for any of its refineries that were
previously subject to the small refiner standards of Sec. 80.552, but
no later than May 31, 2010.
(2)(i) Refiners who qualify as NRLM diesel fuel small refiners
under this section and subsequently employ more than 1,500 people as a
result of merger with or acquisition of or by another entity, or exceed
the 155,000 bpcd crude capacity limit as a result of merger with or
acquisition of or by another entity after January 1, 2004, are
disqualified as small refiners. If this occurs, the refiner shall
notify EPA in writing no later than 20 days following this
disqualifying event.
(ii) Except as provided under paragraph (g)(3) of this section, any
refiner whose status changes under this paragraph shall meet the
applicable standards of Sec. 80.510 within a period of up to 24 months
of the disqualifying event for any of its refineries that were
previously subject to the small refiner standards of Sec. 80.552, but
no later than the dates specified in Sec. Sec. 80.554(a) or 80.554(b),
as applicable.
(3) A refiner may apply to EPA for additional time to comply with
the standards of Sec. Sec. 80.520 or 80.510 if more than 24 months
would be required for the necessary engineering, permitting,
construction, and start-up work to be completed. Such applications must
include detailed technical information supporting the need for
additional time and a proposed amount of additional time. EPA will base
a decision to approve additional time on information provided by the
refiner and on other relevant information. In no case will EPA extend
the compliance date beyond May 31, 2010 for a motor vehicle diesel fuel
small refiner or beyond the dates specified in Sec. Sec. 80.554(a) or
80.554(b), as applicable, for a NRLM diesel fuel small refiner.
27. Section 80.551 is revised to read as follows:
Sec. 80.551 How does a refiner obtain approval as a small refiner
under this subpart?
(a)(1)(i) Applications for motor vehicle diesel fuel small refiner
status must be submitted to EPA by December 31, 2001.
(ii) Applications for NRLM diesel fuel small refiner status must be
submitted to EPA by December 31, 2004.
(2)(i) In the case of a refiner who acquires a refinery after
January 1, 2000, or reactivates a refinery that was shutdown between
January 1, 1999, and January 1, 2000, the application for motor vehicle
diesel fuel small refiner status must be submitted to EPA by June 1,
2003.
(ii) In the case of a refiner who acquires a refinery after January
1, 2003, or reactivates a refinery that was shutdown between January 1,
2002, and January 1, 2003, the application for NRLM diesel fuel small
refiner status must be submitted to EPA by June 1, 2006.
(b) Applications for small refiner status must be sent via
certified mail with return receipt or express mail with return receipt
to: U.S. EPA--Attn: Diesel Small Refiner Status (6406J), 1200
Pennsylvania Avenue, NW (6406J), Washington, DC 20460 (certified mail/
return receipt) or Attn: Diesel Small Refiner Status, Transportation
and Regional Programs Division (6406J), 501 3rd Street, NW, Washington,
DC 20001 (express mail/return receipt).
(c) The small refiner status application must contain the following
information for the company seeking small refiner status, plus any
subsidiary companies, any parent company and subsidiaries of the parent
company in
[[Page 28535]]
which the parent has 50% or greater ownership, and any joint venture
partners:
(1) For motor vehicle diesel fuel small refiners:
(i) A listing of the name and address of each location where any
employee worked during the 12 months preceding January 1, 2000; the
average number of employees at each location based upon the number of
employees for each pay period for the 12 months preceding January 1,
2000; and the type of business activities carried out at each location;
or
(ii) In the case of a refiner who acquires a refinery after January
1, 2000, or reactivates a refinery that was shutdown between January 1,
1999, and January 1, 2000, a listing of the name and address of each
location where any employee of the refiner worked since the refiner
acquired or reactivated the refinery; the average number of employees
at any such acquired or reactivated refinery during each calendar year
since the refiner acquired or reactivated the refinery; and the type of
business activities carried out at each location.
(2) For NRLM diesel fuel small refiners:
(i) A listing of the name and address of each location where any
employee worked during the 12 months preceding January 1, 2003; the
average number of employees at each location based upon the number of
employees for each pay period for the 12 months preceding January 1,
2003; and the type of business activities carried out at each location;
or
(ii) In the case of a refiner who acquires a refinery after January
1, 2003, or reactivates a refinery that was shutdown between January 1,
2002, and January 1, 2003, a listing of the name and address of each
location where any employee of the refiner worked since the refiner
acquired or reactivated the refinery; the average number of employees
at any such acquired or reactivated refinery during each calendar year
since the refiner acquired or reactivated the refinery; and the type of
business activities carried out at each location.
(3) The total corporate crude capacity of each refinery as reported
to the Energy Information Administration (EIA) of the U.S. Department
of Energy (DOE) for the most recent 12 months of operation. The
information submitted to EIA is presumed to be correct. In cases where
a company disagrees with this information, the company may petition EPA
with appropriate data to correct the record when the company submits
its application for small refiner status. EPA may accept such alternate
data at its discretion.
(4) For motor vehicle diesel fuel, an indication of whether the
refiner, for each refinery, is applying for:
(i) The ability to produce motor vehicle diesel fuel subject to the
500 ppm sulfur content standard under Sec. 80.520(c) or generate
credits under Sec. 80.531, pursuant to the provisions of Sec.
80.552(a) or (b); or
(ii) An extension of the duration of its small refiner gasoline
sulfur standard under Sec. 80.553, pursuant to the provisions of Sec.
80.552(c).
(5) For NRLM diesel fuel, an indication of whether the refiner, for
each refinery, is applying for:
(i) The ability delay compliance under Sec. 80.554(a) or (b) or to
generate NRLM diesel sulfur credits under Sec. 80.535, pursuant to the
provisions of Sec. 80.554(c); or
(ii) An adjustment to its small refiner gasoline sulfur standard
under Sec. 80.240(a), pursuant to the provisions of Sec. 80.554(d).
(6) A letter signed by the president, chief operating or chief
executive officer of the company, or his/her designee, stating that the
information contained in the application is true to the best of his/her
knowledge.
(7) Name, address, phone number, facsimile number and e-mail
address (if available) of a corporate contact person.
(d) For joint ventures, the total number of employees includes the
combined employee count of all corporate entities in the venture.
(e) For government-owned refiners, the total employee count
includes all government employees.
(f) Approval of small refiner status for refiners who apply under
Sec. 80.550(e) will be based on all information submitted under
paragraph (c) of this section, except as provided in Sec. 80.550(e).
(g) EPA will notify a refiner of approval or disapproval of small
refiner status by letter. If disapproved, the refiner must comply with
the sulfur standards in Sec. 80.520 or Sec. 80.510, as appropriate,
except as otherwise provided in this subpart.
(h) If EPA finds that a refiner provided false or inaccurate
information on its application for small refiner status, upon notice
from EPA the refiner's small refiner status will be void ab initio.
(i) Upon notification to EPA, an approved small refiner may
withdraw its status as a small refiner. Effective on January 1 of the
year following such notification, the small refiner will become subject
to the sulfur standards in Sec. 80.520 or Sec. 80.510, as
appropriate, unless one of the other hardship provisions of this
subpart apply.
28. Section 80.552 is amended by revising the section heading and
paragraphs (a), (b), (c), and (e) to read as follows:
Sec. 80.552 What compliance options are available to motor vehicle
diesel fuel small refiners?
(a) A refiner that has been approved by EPA as a motor vehicle
diesel fuel small refiner under Sec. 80.551(g) may produce motor
vehicle diesel fuel subject to the 500 ppm sulfur content standard
pursuant to the provisions of Sec. 80.530, except that the volume
limits of Sec. 80.530(a)(3) shall only apply to that volume
V500 of diesel fuel that is produced or imported during a
calendar year that exceeds 105% of the baseline volume established
under Sec. 80.595. The calendar year period shall be from January 1st
through December 31st. For the period June 1, 2006 through December 31,
2006, the volume limits shall only apply to that volume V500
that exceeds 60% of the baseline volume.
(b) A refiner that has been approved by EPA as a motor vehicle
diesel fuel small refiner under Sec. 80.551(g) may generate motor
vehicle diesel fuel credits pursuant to the provisions of Sec. 80.531,
except that for purposes of Sec. 80.531(a) the term ``Credit'' shall
equal V15, without further adjustment.
(c) A refiner that has been approved by EPA as a motor vehicle
diesel fuel small refiner under Sec. 80.551(g) may apply for an
extension of the duration of its small refiner gasoline sulfur
standards pursuant to Sec. 80.553.
* * * * *
(e) The provisions of this section shall apply separately for each
refinery owned or operated by a motor vehicle diesel fuel small
refiner.
29. A new Sec. 80.554 is added to read as follows:
Sec. 80.554 What compliance options are available to NRLM diesel fuel
small refiners?
(a) Option 1. A refiner that has been approved by EPA as a NRLM
diesel fuel small refiner under Sec. 80.551(g) may produce NRLM diesel
fuel from June 1, 2007 through May 31, 2010 that is exempt from the
standards of Sec. 80.510(a).
(1) The volume of NRLM diesel fuel that is exempt from Sec.
80.510(a) must be less than or equal to 105 percent of VNRLM
as defined in Sec. 80.534.
(2) Any volume of NRLM diesel fuel in excess of 105 percent of
VNRLM will be subject to the 500 ppm sulfur standard of
Sec. 80.510(a).
(3) High-sulfur NRLM produced under this paragraph must:
[[Page 28536]]
(i) Be dyed red per the provisions of Sec. 80.510(c)(1)(i) at the
point of production, importation, or redesignation under Sec.
80.511(c);
(ii) Be associated with a product transfer document that bears a
unique product code as specified in Sec. 80.590;
(iii) Be segregated in the distribution system from any 15 ppm
sulfur diesel fuel throughout the distribution system to the end-user;
and
(iv) Be segregated from any 500 ppm sulfur diesel fuel in the
distribution system up to the point where both fuels are dyed red per
Internal Revenue Service Code (26 U.S.C. 4082).
(b) Option 2. A refiner that has been approved by EPA as a NR
diesel fuel small refiner under Sec. 80.551(g) may produce from June
1, 2010, through May 31, 2014, NR diesel fuel subject to the standards
of Sec. 80.510(a).
(1) The volume of NR diesel fuel that may be subject to the 500 ppm
sulfur standard must be equal to or less than 105 percent of
VNRLM as defined in Sec. 80.534, less any volume of marked
locomotive and marine diesel fuel pursuant to Sec. 80.510(c).
(2) NR diesel fuel produced in excess of the volume allowed under
paragraph (b)(1) of this section will be subject to the standards of
Sec. 80.510(b)(1).
(3) 500 ppm NR fuel produced under this paragraph must:
(i) Be dyed red per the provisions of Sec. 80.510(c)(1)(i) at the
point of production, importation, or redesignation under Sec.
80.511(c);
(ii) Bear a unique product code as specified in Sec. 80.590; and
(iii) Be segregated in the distribution system from any 15 ppm
sulfur diesel fuel or 500 ppm sulfur locomotive and marine diesel fuel
throughout the distribution system to the end-user.
(4) Refiners or importers wishing to produce or import 500 ppm
sulfur NR diesel fuel and sell it as NR diesel fuel after May 31, 2010
would first have to provide EPA with a plan for EPA approval
demonstrating that they will ensure the product segregation described
in paragraph (3)(iii) of this section.
(c) Option 3. A refiner that has been approved by EPA as a NRLM
diesel fuel small refiner under Sec. 80.551(g) may generate diesel
fuel credits under the provisions of Sec. 80.535(b) and (d), except as
provided in paragraph (d)(1) of this section.
(d)(1) Option 4. In lieu of Options 1, 2, and 3 of this section, a
refiner that has been approved by EPA as a NRLM diesel fuel small
refiner under Sec. 80.551(g) may choose to adjust its small refiner
gasoline sulfur standards, subject to the following conditions:
(i) The refiner must produce NRLM diesel fuel meeting the standards
of Sec. 80.510(b) by June 1, 2006 and every year thereafter until the
expiration of the refiner's small refiner gasoline sulfur standards
(i.e., through calendar years 2007 or 2010);
(ii) The refiner must produce NRLM fuel each year or partial year
under paragraph (d)(1)(i) of this section at a volume that is equal to
at least 85% of VNRLM, as defined in Sec. 80.534,
calculated on an annual basis.
(2)(i) For a refiner meeting the conditions of (d)(1) of this
section, beginning January 1, 2004, the applicable small refiner's
annual average and per-gallon cap gasoline sulfur standards will be the
standards of Sec. 80.240(a) increased by a factor of 1.20 for the
duration of the refiner's small refiner gasoline sulfur standards under
Sec. 80.240(a) or Sec. 80.553 (i.e., through calendar years 2007 or
2010).
(ii) In no case may the per-gallon cap exceed 450 ppm.
(3)(i) If the refiner fails to produce the necessary volume of 15
ppm NRLM fuel by June 1, 2006 under paragraph (d)(1)(i) of this
section, the refiner must report this in its annual report under Sec.
80.599, and the adjustment of gasoline sulfur standards under paragraph
(d)(2)(i) of this section will be considered void as of January 1,
2004.
(ii) If such a refiner had produced gasoline above its interim
gasoline sulfur standard of Sec. 80.240(a) prior to June 1, 2006, such
fuel will not be considered in violation of the small refiner standards
under Sec. 80.240(a), provided the refiner obtains and uses a quantity
of gasoline sulfur credits equal to the volume of gasoline exceeding
the small refiner standards multiplied by the number of parts per
million by which the gasoline exceeded the small refiner standards.
(e) The provisions of this section shall apply separately for each
refinery owned or operated by a NRLM diesel fuel small refiner.
30. A new Sec. 80.555 is added to read as follows:
Sec. 80.555 What provisions are available to a large refiner that
acquires a small refiner or one or more of its refineries?
(a) In the case of a refiner without approved small refiner status
who acquires a refinery from a refiner with approved status as a motor
vehicle diesel fuel small refiner or a NRLM diesel fuel small refiner
under Sec. 80.551(g), the applicable small refiner provisions of
Sec. Sec. 80.552 and 80.554 may apply to the acquired small refinery
for a period of up to 24 months from the date of acquisition of the
refinery. In no case shall this period extend beyond May 31, 2010 for a
motor vehicle diesel fuel small refiner or beyond the dates specified
in Sec. 80.554(a) or (b), as applicable, for a NRLM diesel fuel small
refiner.
(2) A refiner may apply to EPA for additional time to comply with
the standards of Sec. Sec. 80.520 or 80.510 for the acquired refinery
if more than 24 months would be required for the necessary engineering,
permitting, construction, and start-up work to be completed. Such
applications must include detailed technical information supporting the
need for additional time and a proposed amount of additional time. EPA
will base a decision to approve additional time on information provided
by the refiner and on other relevant information. In no case will EPA
extend the compliance date beyond May 31, 2010 for a motor vehicle
diesel fuel small refiner or beyond the dates specified in Sec.
80.554(a) or (b), as applicable, for a NRLM diesel fuel small refiner.
31. Section 80.560 is amended by revising paragraphs (a), (b), (d),
(e), (h), (i), (k) and (l) to read as follows:
Sec. 80.560 How can a refiner seek temporary relief from the
requirements of this subpart in case of extreme hardship circumstances?
(a) EPA may, at its discretion, grant a refiner, for one or more of
its refineries, temporary relief from some or all of the provisions of
this subpart. Such relief shall be no less stringent than the small
refiner compliance options specified in Sec. 80.552 for motor vehicle
diesel fuel and Sec. 80.554 for NRLM diesel fuel. EPA may grant such
relief provided that the refiner demonstrates that:
(1) Unusual circumstances exist that impose extreme hardship and
significantly affect the refiner's ability to comply by the applicable
date; and
(2) It has made best efforts to comply with the requirements of
this subpart.
(b)(i) For motor vehicle diesel fuel, applications must be
submitted to EPA by June 1, 2002 to the following address: Applications
for small refiner status must be sent via certified mail with return
receipt or express mail with return receipt to: U.S. EPA--Attn: Diesel
Hardship (6406J), 1200 Pennsylvania Avenue, NW (6406J), Washington, DC
20460 (certified mail/return receipt) or Attn: Diesel Hardship,
Transportation and Regional Programs Division, 501 3rd Street, NW
(6406J), Washington, DC 20001 (express mail/return receipt). EPA
reserves the right to deny applications for appropriate reasons,
including unacceptable environmental impact. Approval to distribute
motor
[[Page 28537]]
vehicle diesel fuel not subject to the 15 ppm sulfur standard may be
granted for such time period as EPA determines is appropriate, but
shall not extend beyond May 31, 2010.
(ii) For NRLM diesel fuel, applications must be submitted to EPA by
June 1, 2005 to the following address: U.S. EPA--Attn: Diesel Hardship,
1200 Pennsylvania Avenue, NW (6406J), Washington, DC 20460 (certified
mail/return receipt) or Attn: Diesel Hardship, Transportation and
Regional Programs Division, 501 3rd Street, NW (6406J), Washington, DC
20001 (express mail/return receipt). EPA reserves the right to deny
applications for appropriate reasons, including unacceptable
environmental impact. Approval to distribute NRLM diesel fuel not
subject to the 500 ppm sulfur standard may be granted for such time
period as EPA determines is appropriate, but shall not extend beyond
May 31, 2010. Approval to distribute NR diesel fuel not subject to the
500 ppm sulfur standard may be granted for such time period as EPA
determines is appropriate, but shall not extend beyond May 31, 2014.
* * * * *
(d) Applicants must provide, at a minimum, the following
information:
(1) Detailed description of efforts to obtain capital for refinery
investments and efforts made to obtain credits for compliance under
Sec. 80.531 for motor vehicle diesel fuel or Sec. Sec. 80.535-80.536
for NRLM or NR diesel fuel;
(2) Bond rating of entity that owns the refinery (in the case of
joint ventures, include the bond rating of the joint venture entity and
the bond ratings of all partners; in the case of corporations, include
the bond ratings of any parent or subsidiary corporations); and
(3) Estimated capital investment needed to comply with the
requirements of this subpart by the applicable date.
(e) In addition to the application requirements of paragraph (b) of
this section, a refiner's application for temporary relief under this
paragraph must also include a compliance plan. Such compliance plan
shall demonstrate how the refiner will engage in a quality assurance
testing program to ensure that the following conditions are met:
(1) Its motor vehicle diesel fuel subject solely to the sulfur
standards under Sec. 80.520(c) has not caused motor vehicle diesel
fuel subject to the 15 ppm standard Sec. 80.520(a)(1) to fail to
comply with that standard; or
(2) Its NR diesel fuel subject solely to the sulfur standards under
Sec. 80.510(a) has not caused NR diesel fuel subject to the 15 ppm
standard under Sec. 80.510(b) to fail to comply with that standard.
(3) The quality assurance program must at least include periodic
sampling and testing at the party's own facilities and at downstream
facilities in the refiner's or importer's diesel fuel distribution
system, to determine compliance with the applicable sulfur standards
for both categories of motor vehicle diesel fuel; examination at the
party's own facilities and at applicable downstream facilities, of
product transfer documents to confirm appropriate transfers and
deliveries of both products; and inspection of retailer and wholesale
purchaser-consumer pump stands for the presence of the labels and
warning signs required under this section. Any violations that are
discovered shall be reported to EPA within 48 hours of discovery.
* * * * *
(h)(1) Refiners who are granted a hardship relief standard for any
refinery, and importers of fuel subject to temporary refiner relief
standards, may not distribute the diesel fuel subject to the sulfur
standard under Sec. 80.520(c) for use in model year 2007 and later
vehicles and must comply with all applicable provisions of this
subpart.
(2) Refiners who are granted a hardship relief standard for any
refinery, and importers of fuel subject to temporary refiner relief
standards, may not distribute the diesel fuel subject to the sulfur
standard under Sec. 80.510(a) for use in model year 2011 and later
nonroad engines and must comply with all applicable provisions of this
subpart.
(i) EPA may impose any reasonable conditions on waivers under this
section, including limitations on the refinery's volume of motor
vehicle diesel fuel and NRLM diesel fuel subject to temporary refiner
relief standards.
* * * * *
(k) The individual refinery sulfur standard and the compliance plan
will be approved or disapproved by the Administrator, and approval will
be effective when the refiner (or importer, as applicable, in the case
of compliance plans) receives an approval letter from EPA. If
disapproved, the refiner or importer must comply with the motor vehicle
diesel fuel standard under Sec. 80.520(a)(1) by the appropriate
compliance date specified in Sec. 80.500 or the NRLM standards and
compliance dates under Sec. 80.510(a) and (b) as applicable.
(l) If EPA finds that a refiner provided false or inaccurate
information on its application for hardship relief, EPA's approval of
the refiners application will be void ab initio.
32. Section 80.561 is amended by revising the introductory text and
paragraphs (c), (d) and (f) to read as follows:
Sec. 80.561 How can a refiner or importer seek temporary relief from
the requirements of this subpart in case of extreme unforseen
circumstances?
In appropriate extreme, unusual, and unforseen circumstances (e.g.,
natural disaster or refinery fire) which are clearly outside the
control of the refiner or importer and which could not have been
avoided by the exercise of prudence, diligence and due care, EPA may
permit a refiner or importer, for a brief period, to distribute motor
vehicle diesel fuel or NRLM diesel fuel which does not meet the
requirements of this subpart if:
* * * * *
(c) The refiner or importer can show how the requirements for motor
vehicle diesel fuel or NRLM diesel fuel will be expeditiously achieved;
(d) The refiner or importer agrees to make up any air quality
detriment associated with the nonconforming motor vehicle diesel fuel
or NRLM diesel fuel, where practicable;
* * * * *
(f)(1) In the case of motor vehicle diesel fuel distributed under
this section that does not meet the 15 ppm sulfur standard under Sec.
80.520(a)(1), such diesel fuel shall not be distributed for use in
model year 2007 or later motor vehicles, and must meet all the
requirements and prohibitions of this subpart applicable to diesel fuel
meeting the sulfur standard under Sec. 80.520(c), or to diesel fuel
that is not motor vehicle diesel fuel, as applicable.
(2) In the case of NR diesel fuel distributed under this section
after May 31, 2010 that does not meet the 15 ppm sulfur standard under
Sec. 80.510(b), such diesel fuel shall not be distributed for use in
model year 2011 or later nonroad engines, and must meet all the
requirements and prohibitions of this subpart applicable to diesel fuel
meeting the sulfur standard under Sec. 80.510(a) for NRLM fuel.
(3) In the case of NR diesel fuel distributed under this section
during the period June 1, 2007 and May 31, 2010 that does not meet the
500 ppm sulfur standard under Sec. 80.510(a), such diesel fuel must
meet all the requirements and prohibitions applicable to high sulfur
NRLM credit fuel under Sec. 80.536(f).
33. Section 80.570 is revised to read as follows:
Sec. 80.570 What labeling requirements apply to retailers and
wholesale purchaser-consumers of diesel fuel beginning June 1, 2006?
(a) Any retailer or wholesale purchaser-consumer who sells,
[[Page 28538]]
dispenses, or offers for sale or dispensing, motor vehicle diesel fuel
subject to the 500 ppm sulfur standard of Sec. 80.520(c), must
prominently and conspicuously display in the immediate area of each
pump stand from which motor vehicle fuel subject to the 500 ppm
standard is offered for sale or dispensing, the following legible
label, in block letters of no less than 36-point bold type, printed in
a color contrasting with the background:
LOW-SULFUR HIGHWAY DIESEL FUEL (500 ppm maximum)
WARNING
May damage model year 2007 and later highway vehicles and engines.
Federal Law prohibits use in these vehicles.
(b) Any retailer or wholesale purchaser-consumer who sells,
dispenses, or offers for sale or dispensing, motor vehicle diesel fuel
subject to the 15 ppm sulfur standard of Sec. 80.520(a)(1), must affix
the following conspicuous and legible label, in block letters of no
less than 36-point bold type, and printed in a color contrasting with
the background, to each pump stand:
ULTRA LOW-SULFUR HIGHWAY DIESEL FUEL (15 ppm maximum)
Recommended for use in all diesel vehicles and engines.
Required for model year 2007 and later highway diesel vehicles and
engines.
(c) Any retailer or wholesale purchaser-consumer who sells,
dispenses, or offers for sale or dispensing, diesel fuel for non-
highway equipment that does not meet the standards for motor vehicle
diesel fuel, must affix the following conspicuous and legible label, in
block letters of no less than 36-point bold type, and printed in a
color contrasting with the background, to each pump stand:
NON-HIGHWAY DIESEL FUEL (May Exceed 500 ppm Sulfur)
WARNING
May damage or destroy highway engines and their emission controls.
Federal Law prohibits use in any highway vehicle or engine.
(d) The labels required by paragraphs (a) through (c) of this
section must be placed on the vertical surface of each pump housing and
on each side that has gallonage and price meters. The labels shall be
on the upper two-thirds of the pump, in a location where they are
clearly visible.
34. A new Sec. 80.571 is added to read as follows:
Sec. 80.571 What labeling requirements apply to retailers and
wholesale purchaser-consumers of NR, LM, or NRLM diesel fuel or heating
oil beginning June 1, 2007?
Any retailer or wholesale purchaser-consumer who sells, dispenses,
or offers for sale or dispensing, nonroad (NR), locomotive or marine
(LM), or nonroad, locomotive or marine (NRLM) diesel fuel, or heating
oil, must prominently and conspicuously display in the immediate area
of each pump stand from which non-highway diesel fuel is offered for
sale or dispensing, one of the following legible labels, as applicable,
in block letters of no less than 36-point bold type, printed in a color
contrasting with the background:
(a) For pumps dispensing nonroad, locomotive or marine diesel fuel
meeting the 500 ppm sulfur standard of Sec. 80.510(a):
LOW-SULFUR NON-HIGHWAY DIESEL FUEL (500 ppm Maximum)
WARNING
Not for Use In Highway Vehicles or Engines.
(b) For pumps dispensing nonroad, locomotive or marine diesel fuel
meeting the 15 ppm sulfur standard of Sec. 80.510(b):
ULTRA-LOW SULFUR NON-HIGHWAY DIESEL FUEL (15 ppm Maximum)
Required for All Model Year 2011 and Newer Nonroad Diesel Engines.
Recommended for Use in All Nonroad, Locomotive and Marine Diesel
Engines.
WARNING
Not for Use in Highway Vehicles or Engines.
(c) For pumps dispensing nonroad, locomotive or marine diesel fuel
not meeting, or not offered as meeting, the 500 ppm sulfur standard of
Sec. 80.510(a) or the 15 ppm sulfur standard of Sec. 80.510(b):
HIGH-SULFUR NON-HIGHWAY DIESEL FUEL (May Exceed 500 ppm)
WARNING
Not for Use In Highway Vehicles or Engines.
Not for Use in Nonroad, Locomotive, or Marine Engines after August
31, 2010.
May Damage Engines Certified for Use on Low-Sulfur or Ultra-Low
Sulfur Diesel Fuel.
(d) For pumps dispensing non-highway diesel fuel for use other than
in nonroad, locomotive or marine engines, such as for use in stationary
diesel engines or as heating oil:
HEATING OIL (May Exceed 500 ppm Sulfur)
WARNING
Federal Law Prohibits Use in Highway Vehicles or Engines, or in
Nonroad, Locomotive, or Marine Engines.
May Damage Engines Certified for Use on Low-Sulfur or Ultra-Low
Sulfur Diesel Fuel.
(e) The labels required by paragraphs (a) through (d) of this
section must be placed on the vertical surface of each pump housing and
on each side that has gallonage and price meters. The labels shall be
on the upper two-thirds of the pump, in a location where they are
clearly visible.
35. A new Sec. 80.572 is added to read as follows:
Sec. 80.572 What labeling requirements apply to retailers and
wholesale purchaser-consumers of NR or LM diesel fuel and heating oil
beginning June 1, 2010?
Any retailer or wholesale purchaser-consumer who sells, dispenses,
or offers for sale or dispensing, nonroad (NR) or locomotive or marine
(LM) diesel fuel, or heating oil, must prominently and conspicuously
display in the immediate area of each pump stand from which non-highway
diesel fuel is offered for sale or dispensing, one of the following
legible labels, as applicable, in block letters of no less than 36-
point bold type, printed in a color contrasting with the background:
(a) For pumps dispensing NR diesel fuel subject to the 500 ppm
sulfur standard of Sec. 80.510(a):
LOW-SULFUR NON-HIGHWAY DIESEL FUEL (500 ppm Maximum)
WARNING
May Damage Model Year 2011 and Newer Nonroad Engines.
Federal Law Prohibits Use in All Model Year 2011 and Newer Nonroad
Engines.
Not for Use In Highway Vehicles or Engines.
(b) For pumps dispensing NR diesel fuel subject to the 15 ppm
sulfur standard of Sec. 80.510(b):
ULTRA-LOW SULFUR NON-HIGHWAY DIESEL FUEL (15 ppm Maximum)
Required for All Model Year 2011 and Newer Nonroad Diesel Engines.
Recommended for Use in All Nonroad, Locomotive and Marine Diesel
Engines.
WARNING
Not for Use in Highway Vehicles or Engines.
[[Page 28539]]
(c) For pumps dispensing locomotive or marine diesel fuel subject
to the 500 ppm sulfur standard of Sec. 80.510(a):
LOW-SULFUR LOCOMOTIVE OR MARINE DIESEL FUEL (500 ppm Maximum)
WARNING
Federal Law Prohibits Use in Other Nonroad Engines or in Highway
Vehicles or Engines.
May Damage Model Year 2007 and Newer Highway Diesel Engines and
2011 and Newer Nonroad Diesel Engines.
(d) For pumps dispensing non-highway diesel fuel for use other than
in nonroad, locomotive or marine engines, such as for use in stationary
diesel engines or as heating oil:
HEATING OIL (May Exceed 500 ppm Sulfur)
WARNING
Federal Law Prohibits Use in Highway Vehicles or Engines, or in
Nonroad, Locomotive, or Marine Engines.
May Damage Engines Certified for Use on Low-Sulfur or Ultra-Low
Sulfur Diesel Fuel.
(e) The labels required by paragraphs (a) through (d) of this
section must be placed on the vertical surface of each pump housing and
on each side that has gallonage and price meters. The labels shall be
on the upper two-thirds of the pump, in a location where they are
clearly visible.
36. A new Sec. 80.573 is added to read as follows:
Sec. 80.573 What labeling requirements apply to retailers and
wholesale purchaser-consumers of NR, LM, or NRLM diesel fuel, or
heating oil beginning June 1, 2014?
Any retailer or wholesale purchaser-consumer who sells, dispenses,
or offers for sale or dispensing, nonroad (NR) or locomotive or marine
(LM) diesel fuel, or heating oil, must prominently and conspicuously
display in the immediate area of each pump stand from which non-highway
diesel fuel is offered for sale or dispensing, one of the following
legible labels, as applicable, in block letters of no less than 36-
point bold type, printed in a color contrasting with the background:
(a) For pumps dispensing LM diesel fuel subject to the 500 ppm
sulfur standard of Sec. 80.510(a), but not later than December 1,
2014:
LOW-SULFUR LOCOMOTIVE OR MARINE DIESEL FUEL (500 ppm Maximum)
WARNING
Federal Law Prohibits Use in Other Nonroad Engines or in Highway
Vehicles or Engines.
May Damage Model Year 2007 and Newer Highway Diesel Engines and
2011 and Newer Nonroad Diesel Engines.
(b) For pumps dispensing NR diesel fuel subject to the 15 ppm
sulfur standard of Sec. 80.510(b), but not later than December 1,
2014:
ULTRA-LOW SULFUR NON-HIGHWAY DIESEL FUEL (15 ppm Maximum)
Required for all Nonroad Diesel Engines.
Recommended for Use in All Nonroad, Locomotive and Marine Diesel
Engines.
WARNING
Not for Use in Highway Vehicles or Engines.
(c) For pumps dispensing non-highway diesel fuel for use other than
in nonroad, locomotive or marine engines, such as for use in stationary
diesel engines or as heating oil:
HEATING OIL (May Exceed 500 ppm Sulfur)
WARNING
Federal Law Prohibits Use in Highway Vehicles or Engines, or in
Nonroad, Locomotive, or Marine Engines.
May Damage Engines Certified for Use on Low-Sulfur or Ultra-Low
Sulfur Diesel Fuel.
(d) The labels required by paragraphs (a) through (c) of this
section must be placed on the vertical surface of each pump housing and
on each side that has gallonage and price meters. The labels shall be
on the upper two-thirds of the pump, in a location where they are
clearly visible.
37. Section 80.580 is amended by revising paragraphs (a)
introductory text, (a)(2), (a)(3), (a)(4), and (b) to read as follows:
Sec. 80.580 What are the sampling and testing methods for sulfur?
(a) Diesel fuel and diesel fuel additives. The sulfur content of
diesel fuel and diesel fuel additives is to be determined in accordance
with this section.
* * * * *
(2) Test method for sulfur. (i) Until July 22, 2003, for motor
vehicle diesel fuel and diesel fuel additives subject to the 15 ppm
sulfur standard of Sec. 80.520(a)(1), American Society for Testing and
Materials (ASTM) standard test method D 6428-99, entitled ``Test Method
for Total Sulfur in Liquid Aromatic Hydrocarbons and Their Derivatives
by Oxidative Combustion and Electrochemical Detection.''
(ii) For motor vehicle diesel fuel and diesel fuel additives
subject to the 500 ppm sulfur standard of Sec. 80.520(c), and non-
road, locomotive and marine diesel fuel subject to the 500 ppm sulfur
standard of Sec. 80.510(a)(1), ASTM standard test method D 2622-98,
entitled ``Standard Test Method for Sulfur in Petroleum Products by X-
Ray Spectrometry.''
(iii) Starting July 22, 2003, for motor vehicle diesel fuel and
diesel fuel additives subject to the 15 ppm sulfur standard of Sec.
80.520(a)(1), any test method approved under Sec. 80.585.
(iv) For nonroad diesel fuel and diesel fuel additives subject to
the 15 ppm standard of Sec. 80.510(b), any test method approved under
Sec. 80.585.
(3) Alternative test methods for sulfur. (i) Until July 22, 2003,
for motor vehicle diesel fuel and diesel fuel additives subject to the
15 ppm standard of Sec. 80.520(a)(1), sulfur content may be determined
using ASTM standard test method D 5453-00e1, entitled ``Standard Test
Method for Determination of Total Sulfur in Light Hydrocarbons, Motor
Fuels and Oils by Ultraviolet Fluorescence,'' or ASTM D 3120-96,
entitled ``Standard Test Method for Trace Quantities of Sulfur in Light
Liquid Petroleum Hydrocarbons by Oxidative Micrcoulometry,'' provided
that the refiner or importer test result is correlated with the
appropriate method specified in paragraph (a)(2) of this section.
(ii) Options for testing sulfur content of 500 ppm diesel fuel. (A)
For motor vehicle diesel fuel and diesel fuel additives subject to the
500 ppm standard of Sec. 80.520(c), and for nonroad, locomotive and
marine diesel fuel subject to the 500 ppm standard of Sec. 80.510(a),
sulfur content may be determined using ASTM D 4294-02, entitled
``Standard Test Method for Sulfur in Petroleum Products by Energy
Dispersive X-Ray Fluorescence Spectrometry;'' ASTM D 5453-00e1,
``Standard Test Method for Determination of Total Sulfur in Light
Hydrocarbons, Motor Fuels and Oils by Ultraviolet Fluorescence,'' or
ASTM D 6428-99, entitled ``Test Method for Total Sulfur in Liquid
Aromatic Hydrocarbons and Their Derivatives by Oxidative Combustion and
Electrochemical Detection,'' provided that the refiner or importer test
result is correlated with the appropriate method
[[Page 28540]]
specified in paragraph (2)(ii) of this section; or
(B) For motor vehicle diesel fuel and diesel fuel additives subject
to the 500 ppm standard of Sec. 80.520(c), and for nonroad, locomotive
and marine diesel fuel subject to the 500 ppm standard of Sec.
80.510(a), sulfur content may be determined using any test method
approved under Sec. 80.585.
(4) Adjustment Factor for downstream test results. An adjustment
factor of negative 2 ppm shall be applied to the test results, to
account for test variability, but only for testing of motor vehicle
diesel fuel or nonroad diesel fuel identified as subject to the 15 ppm
sulfur standard of Sec. Sec. 80.510(b) or 80.520(a)(1), at a
downstream location as defined in Sec. 80.500(f).
(b) Incorporation by reference. ASTM standard methods D 2622-98,
entitled ``Standard Test Method for Sulfur in Petroleum Products by X-
Ray Spectrometry,'' D 3120-96, entitled ``Standard Test Method for
Trace Quantities of Sulfur in Light Liquid Petroleum Hydrocarbons by
Oxidative Micrcoulometry;'' D 4294-02, entitled ``Standard Test Method
for Sulfur in Petroleum Products by Energy Dispersive X-Ray
Fluorescence Spectrometry;'' D 5453-00e1, entitled ``Test Method for
Determination of Total Sulfur in Light Hydrocarbons, Motor Fuels and
Oils by Ultraviolet Fluorescence;'' and D 6299-02, entitled ``Standard
Practice for Applying Statistical Quality Assurance Techniques to
Evaluate Analytical Measurement System Performance;'' D 6428-99,
entitled ``Test Method for Total Sulfur in Light Aromatic Hydrocarbons
and their Derivatives by Oxidative Combustion and Electrochemical
Detection;'' are incorporated by reference. This incorporation by
reference was approved by the Director of the Federal Register in
accordance with 5 U.S.C. 552(a) and 1 CFR part 51. Copies may be
obtained from the American Society for Testing and Materials, 100 Barr
Harbor Dr., West Conshohocken, PA 19428. Copies may be inspected at the
Air Docket Section (LE-131), room M-1500, U.S. Environmental Protection
Agency, Docket No. A-99-06, 401 M Street, SW., Washington, DC 20460, or
at the Office of the Federal Register, 800 North Capitol Street, NW.,
Suite 700, Washington, DC.
38. A new Sec. 80.581 is added to read as follows:
Sec. 80.581 What are the batch testing and sample retention
requirements for motor vehicle and nonroad, locomotive and marine
diesel fuel?
(a) Beginning on June 1, 2006 or earlier pursuant to Sec. 80.531
for motor vehicle diesel fuel and June 1, 2010 or earlier pursuant to
Sec. 80.535 for NR, LM, or NRLM diesel fuel, each refiner and importer
shall collect a representative sample from each batch of motor vehicle,
NR, LM, or NRLM diesel fuel produced or imported and subject to the 15
ppm sulfur content standard. The refiner or importer shall test each
sample to determine its sulfur content for compliance with the
requirements of this subpart prior to the diesel fuel leaving the
refinery or import facility, using an appropriate sampling and testing
method as specified in Sec. 80.580.
(b) All test results under this paragraph shall be retained for
five years and must be provided to EPA upon request.
39. A new Sec. 80.582 is added to read as follows:
Sec. 80.582 What are the sampling and testing methods for the fuel
marker?
(a)Sampling and testing for methods for the fuel marker. For
heating oil and LM diesel fuel subject to the fuel marker requirement
in Sec. 80.510(c), the identification of the presence and
concentration of the fuel marker in diesel fuel may be determined using
the test procedures qualified in accordance with the requirements in
this section. For NRLM or NR subject to the provisions of Sec. Sec.
80.510(c)(1)(iv) or 80.510(c)(2)(iv) the identification of the presence
and concentration of the fuel marker in diesel fuel may be determined
using the test procedures qualified in accordance with the requirements
in this section.
(1) The sampling, sample preparation, and testing methods qualified
for use in accordance with the requirements of this section may involve
the use of hazardous materials, operations and equipment. This section
does not address the associated safety problems which may exist. It is
the responsibility of the user of the procedures specified in this
section to establish appropriate safety and health practices prior
their use. It is also the responsibility of the user to dispose of any
byproducts which might result from conducting these procedures in a
manner consistent with applicable safety and health requirements.
(2) [Reserved]
(b) What are the precision and accuracy criteria for qualification
of fuel marker test methods? (1) Precision means the consistency of a
set of measurements and is used to determine how closely analytical
results can be duplicated based on repeat measurements of the same
material under prescribed conditions. A precision of <0.1 mg per liter
is required, as determined by performing a minimum of 20 repeat tests
over a minimum of four days on samples taken from a homogeneous
commercially available diesel fuel which meets the applicable industry
consensus and federal regulatory specifications and which contains the
fuel marker at a concentration in the range of 0.1 to 8 mg per liter.
In order to qualify, the 20 results must be a series of tests on the
same material and there must be a sequential record of the analysis
with no omissions.
(2) Accuracy means the closeness of agreement between a measured or
calculated value and the actual or specified value. An accuracy of +/-
0.05 mg per liter is required, as determined by performing a minimum of
10 repeat tests on each of at least two commercially available solvent
yellow 124 standards, as follows:
(i) The arithmetic average of a continuous series of at least 10
tests performed on a commercially available solvent yellow 124 standard
in the range of 0.1 to 1 mg per liter; and
(ii) The arithmetic average of a continuous series of at least 10
tests performed on a commercially available solvent yellow 124 standard
in the range of 4 to 10 mg per liter.
(iii) In applying the tests of paragraphs (b)(2)(i) and (b)(2)(ii)
of this section, individual test results shall be compensated for any
known chemical interferences.
(c) What process must a test facility follow in order to qualify a
test method for determining the fuel marker content of distillate fuels
and how will EPA qualify or decline to qualify a test method?--(1)
Qualification of test methods approved by voluntary consensus-based
standards bodies. Any standard test method developed by a Voluntary
Consensus-Based Standards Body, such as the American Society for
Testing and Materials (ASTM) or International Standards Organization
(ISO), shall be considered a qualified test method for determining the
fuel marker content of distillate fuel provided that it meets the
precision and accuracy criteria under paragraph (b) of this section.
The qualification of a test method is limited to the single test
facility that performed the testing for accuracy and precision. The
individual facility must submit the accuracy and precision results for
each method
[[Page 28541]]
following procedures established by the Administrator.
(2) Qualification of test methods that have not been approved by a
voluntary consensus-based standards body. (i) A test method that has
not been approved by a voluntary consensus-based standards body may be
qualified upon approval by the Administrator. The following information
must be submitted in the application for approval:
(A) Full test method documentation, including a description of the
technology and/or instrumentation that makes the method functional.
(B) Information demonstrating that the test method meets the
accuracy and precision criteria under paragraph (b) of this section.
(C) If requested by the Administrator, test results utilizing the
method and performed on a sample of commercially available distillate
fuel which meets the applicable industry consensus and federal
regulatory specifications and which contains the fuel marker.
(D) Any additional information requested by the Administrator and
necessary to render a decision as to qualification of the test method.
(E) The qualification of a test method is limited to the single
test facility that performed the testing for accuracy and precision and
any other required testing.
(3)(i) Within 90 days of receipt of all materials required to be
submitted under paragraph (c)(1) or (c)(2) of this section, the
Administrator shall determine whether to qualify the test method under
this section. The Administrator shall qualify the test method if all
materials required under this section are received and the test method
meets the accuracy and precision criteria of paragraph (b) of this
section.
(ii) If the Administrator does not act within 90 days of receipt,
the test method shall be deemed qualified until such time as the
Administrator provides written notification declining to qualify the
method.
(iii) If the Administrator finds that an individual test facility
has provided false or inaccurate information under this section, upon
notice from the Administrator, the qualification shall be void ab
initio.
(iv) The qualification of any test method under this paragraph (c)
shall be valid for the duration of when the fuel marker requirements
remain applicable under this subpart.
(d) Quality control procedures for fuel marker measurement
instrumentation. A test shall not be considered a test using a
qualified test method unless the following quality control procedures
are performed separately for each instrument used to make measurements:
(1) Follow all mandatory provisions of ASTM D 6299-02, ``Standard
Practice for Applying Statistical Quality Assurance Techniques to
Evaluate Analytical Measurement System Performance,'' and construct
control charts from the mandatory quality control testing prescribed in
paragraph 7.1 of the method, following guidelines under A 1.5.1 for
individual observation charts and A 1.5.2 for moving range charts.
(2) Follow paragraph 7.3.1 of ASTM D 6299-02 (check standards)
using a standard reference material at least monthly or following any
major change to the laboratory equipment or test procedure. Any
deviation from the accepted reference value of a check standard greater
than 0.1 mg per liter must be investigated.
(3) Retain batch samples for batches of diesel fuel subject to the
fuel marker requirement for a period at least as long as the period
between quality control material or check standard testing.
(4) Upon discovery of any quality control testing violation of
paragraph A 1.5.1.3 or A 1.5.2.1 of ASTM D 6299-02, or any check
standard deviation greater than 0.1 mg per liter, conduct an
investigation and retest retained samples for fuel batches tested since
the last satisfactory quality control material or check standard
testing.
(5) Retain results of quality control testing and retesting of
retained samples under paragraph (d)(3) of this section for five years.
(e) Incorporation by reference. ASTM Standard Methods D 6299-02,
entitled ``Standard Practice for Applying Statistical Quality Assurance
Techniques to Evaluate Analytical Measurement System Performance''.
This incorporation by reference was approved by the Director of the
Federal Register in accordance with 5 U.S.C. 552(a) and 1 CFR part 51.
Copies may be obtained from the American Society for Testing and
Materials, 100 Bar Harbor Dr., West Conshohocken, PA 19428. Copies may
be inspected at the Air Docket Section (LE-131), room M-1500, U.S.
Environmental Protection Agency, Docket No. A-99-06, 401 M Street, SW.,
Washington, DC 20460, or at the Office of the Federal Register, 800
North Capitol Street, NW., Suite 700, Washington, DC.
40. A new Sec. 80.583 is added to read as follows:
Sec. 80.583 What alternative sampling and testing requirements apply
to importers who transport motor vehicle diesel fuel or nonroad diesel
fuel by truck?
Importers who import diesel fuel subject to the standard under
Sec. 80.510(b) or Sec. 80.510(a) into the United States by truck may
comply with the following requirements instead of the requirements to
sample and test each batch of fuel designated as subject to the 15 ppm
sulfur standard under Sec. 80.581 otherwise applicable to importers:
(a) Terminal testing. For purposes of determining compliance with
the 15 ppm sulfur standard, the importer may use test results for
sulfur content testing conducted by the foreign truck-loading terminal
operator for diesel fuel contained in the storage tank from which
trucks used to transport diesel fuel designated as subject to the15 ppm
sulfur content standard into the United States are loaded, provided the
following conditions are met:
(1) The sampling and testing shall be performed after each receipt
of diesel fuel into the storage tank, or immediately before each
transfer of diesel fuel to the importer's truck.
(2) The sampling and testing shall be performed according to Sec.
80.580.
(3) At the time of each transfer of diesel fuel to the importer's
truck for import to the U.S., the importer must obtain a copy of the
terminal test result that indicates the sulfur content of the truck
load, or truck compartment load, as applicable.
(b) Quality assurance program. The importer must conduct a quality
assurance program, as specified in this paragraph, for each truck
loading terminal.
(1) Quality assurance samples must be obtained from the truck-
loading terminal and tested by the importer, or by an independent
laboratory, and the terminal operator must not know in advance when
samples are to be collected.
(2) The sampling and testing must be performed using the methods
specified in Sec. 80.580.
(3) The frequency of the quality assurance sampling and testing
must be at least one sample for each 50 of an importer's trucks that
are loaded at a terminal, or one sample per month, whichever is more
frequent.
(c) Party required to conduct quality assurance testing. The
quality assurance program under paragraph (b) of this section shall be
conducted by the importer. In the alternative, this testing may be
conducted by an independent laboratory that meets the criteria under
Sec. 80.65(f)(2)(iii), provided the importer receives copies of all
results of tests
[[Page 28542]]
conducted no later than 21 days after the sample was taken.
(d) Assignment of batch numbers. The importer must treat each
compartment of each truck load of imported diesel fuel as a separate
batch for purposes of assigning batch numbers and maintaining records
under Sec. 80.592(d), and reporting under Sec. 80.599, except that
where different compartments contain homogeneous product of identical
designation (including dye or marker status, as well as the sulfur
content designation), the total volume of those compartments may be
treated as a single batch.
(e) EPA inspections of terminals. EPA inspectors or auditors must
be given full and immediate access to the truck-loading terminal and
any laboratory at which samples of diesel fuel collected at the
terminal are analyzed, and must be allowed to conduct inspections,
review records, collect diesel fuel samples and perform audits. These
inspections or audits may be either announced or unannounced.
(f) Certified Sulfur-FRDiesel and Certified Sulfur-FRNRDiesel. This
section does not apply to Certified Sulfur-FRDiesel or Certified
Sulfur-FRNRDiesel as defined in Sec. 80.620.
(g) Effect of noncompliance. If any of the requirements of this
section are not met, all motor vehicle diesel fuel and nonroad diesel
fuel imported by the truck importer during the time the requirements
are not met is deemed in violation of the diesel fuel sulfur standards
in Sec. 80.510 or Sec. 80.529(a), as applicable. Additionally, if any
requirement is not met, EPA may notify the importer of the violation,
and, if the requirement is not fulfilled within 10 days of
notification, the truck importer may not in the future use the sampling
and testing provisions in this section in lieu of the provisions in
Sec. 80.581.
41. A new Sec. 80.584 is added to read as follows:
Sec. 80.584 What are the precision and accuracy criteria for approval
of test methods for determining the sulfur content of diesel fuel?
(a) Precision. (1) For motor vehicle diesel fuel and diesel fuel
additives subject to the 15 ppm sulfur standard of Sec. 80.520(a)(1)
and nonroad diesel fuel and diesel fuel additives subject to the 15 ppm
standard of Sec. 80.510(b), a standard deviation less than 0.72 ppm,
computed from the results of a minimum of 20 repeat tests made over a
minimum of four days on samples taken from a single homogeneous
commercially available diesel fuel with a sulfur content in the range
of 5-15 ppm. The 20 results must be a series of tests with a sequential
record of the analyses and no omissions.
(2) For motor vehicle diesel fuel and diesel fuel additives subject
to the 500 ppm standard of Sec. 80.520(c), and for nonroad, locomotive
and marine diesel fuel subject to the 500 ppm standard of Sec.
80.510(a), of a standard deviation less than 9.68 ppm, computed from
the results of a minimum of 20 repeat tests made over a minimum of four
days on samples taken from a single homogeneous commercially available
diesel fuel with a sulfur content in the range of 200-500 ppm. The 20
results must be a series of tests with a sequential record of the
analyses and no omissions.
(b) Accuracy. (1) For motor vehicle diesel fuel and diesel fuel
additives subject to the 15 ppm sulfur standard of Sec. 80.520(a)(1)
and nonroad diesel fuel and diesel fuel additives subject to the 15 ppm
sulfur standard of Sec. 80.510(b):
(i) The arithmetic average of a continuous series of at least 10
tests performed on a commercially available gravimetric sulfur standard
in the range of 1-10 ppm sulfur shall not differ from the accepted
reference value (ARV) of that standard by more than 0.54 ppm sulfur;
and
(ii) The arithmetic average of a continuous series of at least 10
tests performed on a commercially available gravimetric sulfur standard
in the range of 10-20 ppm sulfur shall not differ from the ARV of that
standard by more than 0.54 ppm sulfur.
(iii) In applying the tests of paragraphs (b)(1)(i) and (b)(1)(ii)
of this section, individual test results shall be compensated for any
known chemical interferences.
(2) For motor vehicle diesel fuel and diesel fuel additives subject
to the 500 ppm sulfur standard of Sec. 80.520(c), and for nonroad,
locomotive and marine diesel fuel subject to the 500 ppm sulfur
standard of Sec. 80.510(a):
(i) The arithmetic average of a continuous series of at least 10
tests performed on a commercially available gravimetric sulfur standard
in the range of 100-200 ppm sulfur shall not differ from the ARV of
that standard by more than 7.26 ppm sulfur; and
(ii) The arithmetic average of a continuous series of at least 10
tests performed on a commercially available gravimetric sulfur standard
in the range of 400-500 ppm sulfur shall not differ from the ARV of
that standard by more than 7.26 ppm sulfur.
(iii) In applying the tests of paragraphs (b)(2)(i) and (b)(2)(ii)
of this section, individual test results shall be compensated for any
known chemical interferences.
42. A new Sec. 80.585 is added to read as follows:
Sec. 80.585 What is the process for approval of a test method for
determining the sulfur content of diesel?
(a) Approval of test methods approved by voluntary consensus-based
standards bodies. For such a method to be approved, the following
information must be submitted to the Administrator by each test
facility for each test method that it wishes to have approved: Any test
method approved by a voluntary consensus-based standards body, such as
the American Society for Testing and Materials (ASTM) or International
Standards Organization (ISO), shall be approved as a test method for
determining the sulfur content of diesel fuel if it meets the
applicable accuracy and precision criteria under Sec. 80.584. The
approval of a test method is limited to the single test facility that
performed the testing for accuracy and precision. The individual
facility must submit the accuracy and precision results for each method
following procedures established by the Administrator.
(b) Approval of test methods not approved by a voluntary consensus-
based standards body. For such a method to be approved, the following
information must be submitted to the Administrator by each test
facility for each test method that it wishes to have approved:
(1) Full test method documentation, including a description of the
technology and/or instrumentation that makes the method functional.
(2) Information demonstrating that the test method meets the
applicable accuracy and precision criteria of Sec. 80.584.
(3) If requested by the Administrator, test results from use of the
method to analyze samples of commercially available fuel provided by
EPA.
(4) Any additional information requested by the Administrator and
necessary to render a decision as to approval of the test method.
(c)(1) Within 90 days of receipt of all materials required to be
submitted under paragraphs (a) or (b) of this section, the
Administrator shall determine whether the test method is approved under
this section.
(2) If the Administrator determines that the test method is not
approvable, within 90 days of receipt of all materials required to be
submitted under paragraph (a) or (b) of this section, the Administrator
will notify the applicant of the reasons for not approving the method.
If the Administrator does not notify the applicant within 90 days of
receipt of the application, that the test
[[Page 28543]]
method is not approved, then the test method shall be deemed approved.
(3) If the Administrator finds that an individual test facility has
provided false or inaccurate information under this section, upon
notice from the Administrator the approval shall be void ab initio.
(4) The approval of any test method under paragraph (b) of this
section shall be valid for five (5) years from the date of approval by
the Administrator and shall not be extended. If the method is later
approved by a voluntary consensus-based standards body, the approval
shall remain valid as long as the conditions of paragraph (a) of this
section are met.
(d) Quality assurance procedures for sulfur measurement
instrumentation. A test shall not be considered a test using an
approved test method unless the following quality control procedures
are performed separately for each instrument used to make measurements:
(1) Follow all mandatory provisions of ASTM D 6299-02, ``Standard
Practice for Applying Statistical Quality Assurance Techniques to
Evaluate Analytical Measurement System Performance,'' and construct
control charts from the mandatory quality control testing prescribed in
paragraph 7.1 of the practice, following guidelines under A 1.5.1 for
individual observation charts and A 1.5.2 for moving range charts.
(2) Follow paragraph 7.3.1 of ASTM D 6299-02 (check standards)
using a standard reference material at least monthly or following any
major change to the laboratory equipment or test procedure. Any
deviation from the accepted reference value of a check standard greater
than 1.44 ppm (for diesel fuel subject to the 15 ppm sulfur standard)
or 19.36 ppm (for diesel fuel subject to the 500 ppm sulfur standard)
must be investigated.
(3) Retain samples of tested batches of diesel fuel for a period at
least as long as the period between quality control material or check
standard testing occasions.
(4) Upon discovery of any quality control testing violation of
paragraph A 1.5.1.3 or A 1.5.2.1 of ASTM D 6299-02, or any check
standard deviation greater than 1.44 ppm (for diesel fuel subject to
the 15 ppm sulfur standard) or 19.36 ppm (for diesel fuel subject to
the 500 ppm sulfur standard), conduct an investigation into the cause
of such violation or deviation and, after restoring method performance
to statistical control, retest retained samples from batches originally
tested since the last satisfactory quality control material or check
standard testing occasion.
43. A new Sec. 80.586 is added to read as follows:
Sec. 80.586 What are record retention requirements for test methods
approved under this subpart?
Each individual test facility must retain records related to the
establishment of accuracy and precision values, all test method
documentation, and any quality control testing and analysis under
Sec. Sec. 80.584-80.585, for five (5) years.
44. Section 80.590 is revised to read as follows:
Sec. 80.590 What are the product transfer document requirements for
motor vehicle diesel fuel; nonroad, locomotive and marine diesel fuel;
and heating oil?
(a) On each occasion that any person transfers custody or title to
diesel fuel or heating oil, including distillates used or intended to
be used as diesel fuel or heating oil, except when such fuel is
dispensed into motor vehicles, nonroad equipment, or locomotives at a
retail outlet or wholesale purchaser-consumer facility, the transferor
must provide to the transferee documents which include the following
information:
(1) The name and address of the transferor and transferee;
(2) The volume of diesel fuel which is being transferred;
(3) The location of the diesel fuel at the time of the transfer;
(4) The date of the transfer;
(5) An accurate statement of the applicable fuel designation and
uses, as follows:
(i) Undyed 15 ppm diesel fuel. (A) For the period of June 1, 2006
and later, ``15 ppm (maximum) Undyed Ultra-Low Sulfur Diesel Fuel. For
use in all diesel vehicles and engines.''
(B) [Reserved]
(ii) Dyed 15 ppm diesel fuel. (A) For the period of June 1, 2006
and later, ``15 ppm (maximum) Dyed Ultra-Low Sulfur Diesel Fuel. For
use in all nonroad, locomotive and marine diesel engines. Not for use
in highway vehicles or engines except for tax-exempt use in accordance
with sec. 4082 of the Internal Revenue Code.''
(B) [Reserved]
(iii) Undyed 500 ppm diesel fuel. (A) For the period of June 1,
2006 through November 30, 2010, ``500 ppm (maximum) Undyed Low Sulfur
Diesel Fuel. For use in Model Year 2006 and older diesel highway
vehicles and engines. Also for use in nonroad, locomotive or marine
diesel engines. Not for use in 2007 and newer highway vehicles or
engines.''
(B) [Reserved]
(iv) Dyed 500 ppm diesel fuel. (A) For the period of June 1, 2006
through August 31, 2010, ``500 ppm (maximum) Dyed Low Sulfur Nonroad,
Locomotive and Marine Diesel Fuel. Not for use in highway vehicles or
engines except for use in Model Year 2006 and older highway diesel
vehicles or engines for tax-exempt use in accordance with Sec. 4082 of
the Internal Revenue Code.''
(B) For the period of September 1, 2010 through August 31, 2014,
``500 ppm (maximum) Dyed Low Sulfur Nonroad Diesel Fuel. For use in
2010 and older nonroad diesel engines. May be used in locomotive and
marine diesel engines. Not for use in highway vehicles and engines or
model year 2011 or later nonroad engines.''
(C) For dyed and marked locomotive and marine fuel, during the
period June 1, 2010 through August 31, 2014, ``500 ppm (maximum) Dyed
and Marked Low Sulfur Locomotive and Marine diesel fuel. Not for use in
highway or nonroad vehicles and engines.''.
(D) For dyed locomotive and marine fuel after August 31, 2014,
``500 ppm (maximum) Dyed Low Sulfur Locomotive and Marine diesel fuel.
Not for use in highway or nonroad vehicles and engines.''
(v) Dyed High Sulfur NLRM Fuel under section 80.510(d)(1),
including any mixture of low sulfur and/or ultra-low sulfur diesel fuel
with high sulfur NRLM Diesel Fuel.
(A) For the period June 1, 2006 through August 31, 2010, ``High
Sulfur Dyed Nonroad, Locomotive, and Marine Engine Diesel fuel--sulfur
content may exceed 500 ppm. Not for use in highway vehicles or engines.
Not for use in any nonroad engines.''
(vi) Heating oil. (A) For heating oil produced or imported at any
time beginning June 1, 2006, or beginning June 1, 2006 under section
80.534, ``Heating Oil. Not for use in highway vehicles or engines,
nonroad engines, or locomotive or marine engines.''
(B) [Reserved]
(b) The following may be substituted for the descriptions in
paragraph (a) of this section, as appropriate:
(1) ``This is high sulfur diesel fuel for use only in Guam,
American Samoa, or the Northern Mariana Islands.'';
(2) ``This diesel fuel is for export use only.'';
(3) ``This diesel fuel is for research, development, or testing
purposes only.'';
(4) ``This diesel fuel is for use in diesel highway vehicles or
nonroad, locomotive, or marine engine equipment having an EPA-approved
national security exemption only.''
[[Page 28544]]
(c) If undyed and/or unmarked diesel fuel is dyed and/or marked
subsequent to the issuance of a product transfer document, at the time
the diesel fuel is dyed and/or marked, a new product transfer document
must be prepared with the language under paragraph (a)(5) of this
section applicable to the changed fuel and provided to subsequent
transferees.
(d) Except for transfers to truck carriers, retailers or wholesale
purchaser-consumers, product codes may be used to convey the
information required under this section if such codes are clearly
understood by each transferee. Codes used to convey the statement in
paragraphs (a)(5)(i) and (a)(5)(ii) of this section must contain the
number ``15'', and codes used to convey the statement in paragraphs
(a)(5)(iii) and (a)(5)(iv) of this section must contain the number
``500''. Codes used to convey the statement in paragraph (a)(5)(v) must
contain the statement ``greater than 500'' or ``500''.
(e) Beginning June 1, 2001 and ending May 31, 2005, any transfer
subject to this section, which is also subject to the early credit
provisions of Sec. 80.531(b), must comply with all applicable
requirements of this section.
(f) Beginning June 1, 2005 and ending May 31, 2006, any transfer
subject to this section, which is also subject to the early credit
requirements of Sec. 80.531(c), must comply with all applicable
requirements of this section.
45. Section 80.591 is revised to read as follows:
Sec. 80.591 What are the product transfer document requirements for
additives to be used in diesel fuel?
(a) Except as provided in paragraphs (b) and (d) of this section,
on each occasion that any person transfers custody or title to a diesel
fuel additive to a party in the additive distribution system or in the
diesel fuel distribution system for use downstream of the diesel fuel
refiner, the transferor must provide to the transferee documents which
identify the additive, and:
(1) Identify the name and address of the transferor and transferee;
the date of transfer; the location at which the transfer took place;
the volume of additive transferred; and
(2) Indicates compliance with the 15 ppm sulfur standard by
inclusion of the following statement: ``The sulfur content of this
diesel fuel additive does not exceed 15 ppm.''
(b) On each occasion that any person transfers custody or title to
a diesel fuel additive subject to the requirements of Sec. 80.521(b),
to a party in the additive distribution system or in the diesel fuel
distribution system for use in diesel fuel downstream of the diesel
fuel refiner, the transferor must provide to the transferee documents
which identify the additive, and:
(1) Identify the name and address of the transferor and transferee;
the date of transfer; the location at which the transfer took place;
the volume of additive transferred; and
(2) Indicate the high sulfur potential of the additive by inclusion
of the following statement:
``This diesel fuel additive may exceed the federal 15 ppm sulfur
standard. Improper use of this additive may result in non-complying
diesel fuel.'';
(3) Includes the following information:
(i) The additive's maximum sulfur concentration;
(ii) The maximum recommended concentration in volume percent for
use of the additive in diesel fuel; and
(iii) The contribution to the sulfur level of the fuel, in ppm,
that would result if the additive is used at the maximum recommended
concentration.
(c) Except for transfers of diesel fuel additives to truck
carriers, retailers or wholesale purchaser-consumers, product codes may
be used to convey the information required under paragraphs (a) and (b)
of this section, if such codes are clearly understood by each
transferee. Codes used to convey the statement in paragraph (a)(2) of
this section must contain the number ``15'' and codes used to convey
the statement in paragraph (b)(2) of this section may not contain such
number.
(d) For those diesel fuel additives which are sold in containers
for use by the ultimate consumer of diesel fuel, each transferor must
have displayed on the additive container, in a legible and conspicuous
manner, either of the following statements, as applicable:
(1) ``This diesel fuel additive complies with the federal low
sulfur content requirements for use in diesel motor vehicles and
nonroad, locomotive, and marine diesel equipment engines.''; or
(2) For those additives sold in containers for use by the ultimate
consumer, with a sulfur content in excess of 15 ppm the following
statement: ``This diesel fuel additive does not comply with federal
ultra-low sulfur content requirements for use in model year 2007 and
newer diesel motor vehicles or model year 2011 and newer diesel nonroad
equipment engines.''
46. Section 80.592 is amended by revising paragraphs (a), (b)(4),
and (b)(7) introductory text, redesignating paragraphs (c) through (e)
as paragraphs (e) through (g), and adding new paragraphs (c) and (d) to
read as follows:
Sec. 80.592 What records must be kept?
(a) Records that must be kept by parties in the motor vehicle
diesel fuel and diesel fuel additive distribution systems. Beginning
June 1, 2006, or for a refiner the first compliance period in which the
refiner is generating early credits under Sec. 80.531(b) or (c),
whichever is earlier, any person who produces, imports, sells, offers
for sale, dispenses, distributes, supplies, offers for supply, stores,
or transports motor vehicle diesel fuel subject to the provisions of
this subpart, must keep the following records:
(1) The applicable product transfer documents required under
Sec. Sec. 80.590 and 80.591;
(2) For any sampling and testing for sulfur content under
Sec. Sec. 80.580 and 80.581 for a batch of motor vehicle diesel fuel
produced or imported and subject to the 15 ppm sulfur standard or any
sampling and testing for sulfur content or as part of a quality
assurance testing program, and any sampling and testing for the cetane
index or aromatics content of motor vehicle diesel fuel or motor
vehicle diesel fuel additives:
(i) The location, date, time and storage tank or truck
identification for each sample collected;
(ii) The name and title of the person who collected the sample and
the person who performed the testing; and
(iii) The results of the tests for sulfur content (including where
applicable the test results with and without application of the
adjustment factor under Sec. 80.580(a)(6) or other standard content,
and the volume of product in the storage tank or container from which
the sample was taken; and
(3) The actions the party has taken, if any, to stop the sale or
distribution of any motor vehicle diesel fuel found not to be in
compliance with the sulfur standards specified in this subpart, and the
actions the party has taken, if any, to identify the cause of any
noncompliance and prevent future instances of noncompliance.
(b) * * *
(4) A record designating the batch as motor vehicle diesel fuel
meeting the 500 ppm sulfur standard or as motor vehicle diesel fuel
meeting the 15 ppm sulfur standard.
* * * * *
(7) Information regarding credits, kept separately for each
calendar year compliance period, kept separately for each refinery and
in the case of importers, kept separately for imports into each CTA,
and designated as motor vehicle diesel fuel credits and kept
[[Page 28545]]
separately from NRLM credits, as follows:
* * * * *
(c) Records that must be kept by parties in the nonroad,
locomotive, and marine diesel fuel and diesel fuel additive
distribution systems. Beginning June 1, 2007, or beginning June 1, 2006
for NRLM diesel fuel produced or imported by a refiner or importer
subject to the non-highway baseline starting June 1, 2006 under
Sec. Sec. 80.534 and 80.535, whichever is earlier, any person who
produces, imports, sells, offers for sale, dispenses, distributes,
supplies, offers for supply, stores, or transports nonroad, locomotive
and marine diesel fuel subject to the provisions of this subpart, must
keep the following records:
(1) The applicable product transfer documents required under Sec.
80.590;
(2) For any sampling and testing for sulfur content under
Sec. Sec. 80.580 and 80.581 for a batch of NRLM diesel fuel produced
or imported and subject to the 15 ppm sulfur standard or any sampling
and testing for sulfur content as part of a quality assurance testing
program, and any sampling and testing for the cetane index, aromatics
content or marker under Sec. 80.582, of NRLM diesel fuel, NRLM fuel
additives or heating oil:
(i) The location, date, time and storage tank or truck
identification for each sample collected;
(ii) The name and title of the person who collected the sample and
the person who performed the testing;
(iii) The results of the tests for sulfur content (including where
applicable the test results with and without application of the
adjustment factor under Sec. 80.580(a)(6) or other standard content,
and the volume of product in the storage tank or container from which
the sample was taken; and
(3) The actions the party has taken, if any, to stop the sale or
distribution of any nonroad, locomotive or marine diesel fuel found not
to be in compliance with the sulfur standards specified in this
subpart, and the actions the party has taken, if any, to identify the
cause of any noncompliance and prevent future instances of
noncompliance.
(d) Additional records to be kept by refiners and importers of
nonroad, locomotive and marine diesel fuel subject to non-highway
baseline, credit provisions or small refiner or hardship provisions.
Beginning June 1, 2007, or June 1, 2006, pursuant to the provisions of
Sec. Sec. 80.534 and 80.535, as applicable, any refiner producing
diesel fuel subject to a sulfur standard under Sec. Sec. 80.510,
80.536, 80.554, 80.660 or 80.561 for each of its refineries, and any
importer importing such diesel fuel for each area under Sec.
80.531(a)(5), shall keep records that include the following information
for each batch of NRLM diesel fuel or heating oil produced or imported:
(1) The batch volume;
(2) The batch number, assigned under the batch numbering procedures
under Sec. 80.65(d)(3).
(3) The date of production or import.
(4) A record designating the batch as:
(i) NRLM, NR, LM or heating oil, as applicable;
(ii) Meeting the 500 ppm requirements of Sec. 80.510(a), the 15
ppm requirements of Sec. 80.510(b), the applicable standard under
Sec. 80.536, the applicable small refiner standard under Sec. 80.554,
or other applicable standard;
(iii) Dyed or undyed with visible evidence of dye solvent red 164;
or
(iv) Marked or unmarked with solvent yellow 124.
(5) For foreign refiners, the designations and other records
required to be kept under Sec. 80.620.
(6) In the case of importers, the designations and other records
required under Sec. 80.592.
(7) Information regarding credits, kept separately for each
calendar year calculation period, kept separately for each refinery and
importer, and for importers, kept separately for each CTA under Sec.
80.531(a)(5), and kept separately from motor vehicle diesel fuel
credits.
(i) The number in the refiner's or importer's possession at the
beginning of the of the calendar year;
(ii) The number generated;
(iii) The number used;
(iv) If any were obtained from or transferred to other parties, for
each other party, its name, its EPA refiner or importer registration
number consistent with Sec. 80.597, in the case of credits generated
by an importer the port and CTA of import of the diesel fuel that
generated the credits, and the number obtained from, or transferred to,
the other party;
(v) The number in the refiner's or importer's possession that will
carry over into the subsequent calendar year compliance period; and
(vi) Commercial documents that establish each transfer of credits
from the transferor to the transferee.
(8) The calculations used to determine compliance with the volume
percentage requirements of this subpart;
(9) The calculations used to determine the number of credits
generated;
(10) A copy of reports submitted to EPA under Sec. 80.599.
(e) Additional records importers must keep. Any importer shall keep
records that identify and verify the source of each batch of certified
diesel fuel program foreign refiner (DFR)-Diesel and non-certified DFR-
Diesel imported and demonstrate compliance with the requirements under
Sec. 80.620.
(f) Length of time records must be kept. The records required in
this section shall be kept for five years from the date they were
created, except that records relating to credit transfers shall be kept
by the transferor for 5 years from the date the credits were
transferred, and shall be kept by the transferee for 5 years from the
date the credits were transferred, used or terminated, whichever is
later.
(g) Make records available to EPA. On request by EPA, the records
required in this section must be made available to the Administrator or
the Administrator's representative. For records that are electronically
generated or maintained, the equipment and software necessary to read
the records shall be made available, or if requested by EPA, electronic
records shall be converted to paper documents which shall be provided
to the Administrator's authorized representative.
47. Section 80.594 is amended by revising the section heading to
read as follows:
Sec. 80.594 What are the pre-compliance reporting requirements for
motor vehicle diesel fuel?
48. Section 80.597 is revised to read as follows:
Sec. 80.597 What are the registration requirements?
The following registration requirements apply under this subpart:
(a) Registration for motor vehicle diesel fuel. Refiners having any
refinery that is subject to a sulfur standard under Sec. 80.520(a),
and importers importing such diesel fuel, must provide EPA the
information under Sec. 80.76 no later than December 31, 2001, if such
information has not been provided under the provisions of 40 CFR Part
80. In addition, for each import facility, the same identifying
information as required for each refinery under Sec. 80.76(c) must be
provided.
(b) Registration for nonroad, locomotive and marine diesel.
Refiners and importers that may produce or supply nonroad, locomotive
and/or diesel fuel by June 1, 2007, must provide EPA the information
under Sec. 80.76 no later than December 31, 2004, if such information
has not been provided under the provisions of 40 CFR Part 80. In
addition, for each import facility, the same identifying information as
required for each refinery under Sec. 80.76(c) must be provided.
[[Page 28546]]
49. A new Sec. 80.598 is added to read as follows:
Sec. 80.598 What are the pre-compliance reporting requirements for
nonroad, locomotive and marine diesel?
(a) Beginning on June 1, 2005, and for each year until June 1,
2009, or until the entity produces or imports nonroad fuel meeting the
15 ppm standard of Sec. 80.510(b), all refiners and importers planning
to produce or import nonroad, locomotive or marine diesel fuel, shall
submit the following information to EPA:
(1) Any changes to the information submitted for the company
registration;
(2) Any changes to the information submitted for any refinery or
import facility registration;
(3) An estimate of the annual production or importation, in
gallons, of motor vehicle and nonroad, locomotive or marine fuel
produced or imported at each refinery or import facility for diesel
fuels produced from crude oil, and the volumes of each grade of these
fuels from other sources;
(4) If expecting to participate in the credit trading program,
estimates of the number of credits to be generated and/or used each
year the program;
(5) Information regarding engineering plans (e.g., design and
construction), the status of obtaining any necessary permits, and
capital commitments for making the necessary modifications to produce
low sulfur nonroad, locomotive or marine fuel, and actual construction
progress. The pre-compliance reports due in 2006 and later years must
provide an update of the progress in each of these areas.
(b) Reports under this section may be submitted in conjunction with
reports submitted under Sec. 80.594.
50. A new Sec. 80.599 is added to read as follows:
Sec. 80.599 What are the annual reporting requirements for refiners
and importers of nonroad, locomotive and marine diesel fuel?
Beginning with the annual compliance period that begins June 1,
2007, or June 1, 2006 for refiners or importers who elects not to dye
NRLM fuel starting June 1, 2006, any refiner or importer who produces
or imports nonroad, locomotive or marine diesel fuel must submit annual
compliance reports for each refinery, or for importer, that contain the
information required in this section, and such other information as EPA
may require.
(a) All refiners and importers. (1) The refiner or importer's
company name and the EPA company and refinery registration number, or
CTA of import information.
(2) A declaration whether the refiner or importer is electing to
dye its NRLM fuel with visible evidence of dye solvent red 164 or
whether it is electing to utilize the non-highway baseline under
Sec. Sec. 80.534-80.535 for the compliance period, and if the refiner
is a small refiner, a statement of which small refiner option it is
subject to.
(b) Refiners and importers subject to the non-highway baseline.
Refiners for each refinery, or for each importer separately for each
CTA, that elects to not dye its NRLM fuel and instead utilize the non-
highway baseline:
(1) The total volumes of the following types of fuel produced or
imported during the compliance period:
(i) 15 ppm sulfur content motor vehicle diesel fuel and NRLM diesel
fuel.
(ii) 500 ppm sulfur content motor vehicle diesel fuel, nonroad
diesel fuel or locomotive and marine diesel fuel.
(iii) Heating oil.
(iv) High sulfur NRLM diesel fuel.
(2) The volume percentages under Sec. 80.534 and compliance with
the requirement of Sec. 80.534(d)(2).
(c) Small refiners. (1) For each refinery of small refiners subject
to the provisions of Sec. Sec. 80.551(g) and 80.554(a) for each
compliance period starting June 1, 2007 and ending May 31, 2010,
report:
(i) The total volume of NRLM diesel fuel produced that is exempt
from the sulfur standard of Sec. 80.510(a).
(ii) The total volume NRLM diesel fuel produced as defined in Sec.
80.534.
(iii) The volume of NRLM diesel fuel produced having a sulfur
content of 500 ppm or less.
(iv) The total volume, if any, of NRLM diesel fuel subject to the
500 ppm sulfur standard that had a sulfur content exceeding 500 ppm.
(2) For each refinery of small refiners subject to the provisions
of Sec. Sec. 80.551(g) and 80.554(b), for each compliance period
starting June 1, 2010 and ending May 31, 2014, report:
(i) The total volume of NRLM diesel fuel produced subject to the
500 ppm sulfur standard of Sec. 80.510(a).
(ii) The total volume NRLM diesel fuel produced as defined in Sec.
80.534.
(iii) The total volume of locomotive or marine diesel fuel marked
under Sec. 80.510(c).
(iv) The volume of NRLM diesel fuel produced having a sulfur
content of 15 ppm or less.
(v) The total volume, if any, of NRLM diesel fuel subject to the 15
ppm sulfur standard that had a sulfur content in excess of 15 ppm.
(3) For each refinery of a small refiner that elects to produce
NRLM diesel fuel subject to the 15 ppm nonroad diesel fuel starting
June 1, 2006 under Sec. Sec. 80.551(g) and 80.554(d) for each
compliance period report:
(i) The total volume of NRLM diesel fuel produced having a sulfur
content of 15 ppm or less.
(ii) The total volume of NRLM diesel fuel produced as defined under
Sec. 80.534.
(iii) The total percentage of NRLM as defined under Sec. 80.534
produced having a sulfur content of 15 ppm or less.
(iv) The number of credits purchased, if any, to cover any deficit
as provided in Sec. 80.554(d)(3).
(v) A report of the small refiner's progress toward compliance with
the gasoline standards under Sec. Sec. 80.240 and 80.255.
(d) Credit generation and use. Information regarding the
generation, use, transfer and retirement of credits, separately by
refinery and for importers separately by CTA, including:
(1) The number of credits at the beginning of the compliance
period;
(2) The number of credits generated;
(3) The number of credits used;
(4) If any credits were obtained from or transferred to other
refineries or import ports, for each other refinery or importer, the
name, address, the EPA company registration number, and the number of
credits obtained from or transferred to the other party;
(5) The number of credits retired; and
(6) The credit balance at the start and end of the compliance
period.
(e) Batch reports. For each batch of motor vehicle diesel fuel,
nonroad, locomotive and marine diesel fuel and heating oil produced or
imported during the compliance period under paragraphs (b) and (c) of
this section:
(1) The batch volume.
(2) The batch number assigned using the batch numbering conventions
under Sec. 80.65(d)(3) and the appropriate designation under Sec.
80.523.
(3) The date of production or import.
(4) For each batch provide the information specified in paragraph
(b)(1) of this section.
(5) The sulfur content and cetane and aromatics content of the
fuel;
(6) Whether the batch was dyed with visible evidence of dye solvent
red 164 before leaving the refinery or import facility or was undyed.
(7) Certification that any batch of heating oil produced or
imported under the provisions of Sec. 80.534 starting June 1, 2006 or
June 1, 2007, as applicable, through May 31, 2010 was marked with the
specified chemical marker pursuant to Sec. 80.510(c) or any batch of
locomotive and marine diesel fuel produced or imported starting June 1,
2010 through
[[Page 28547]]
May 31, 2014 was marked pursuant to Sec. 80.510(c), before leaving the
refinery or import facility.
(f) Additional reporting requirements for importers. Importers of
NRLM diesel fuel are subject to the following additional requirements:
(1) The reporting requirements under Sec. 80.620, if applicable.
(2) Importers must exclude certified DFR-Diesel from calculations
under this section.
(g) Report submission. Any report required by this section shall
be:
(1) On forms and following procedures specified by the
Administrator of EPA;
(2) Signed and certified as meeting all the applicable requirements
of this subpart by the owner or a responsible corporate officer of the
refiner or importer; and
(3) Except for small refiners subject to Sec. 80.554(d), submitted
to EPA no later than August 31 each year for the prior June 1-May 31
period. Small refiners subject to the provisions of Sec. 80.554(d),
reports must be submitted the last day of February for the previous
reporting period.
(h) Sunset dates for reporting requirements under this section.
(1) For small refiners under paragraph (c)(1) of this section, no
reports shall be required under this section after August 31, 2010.
(2) For small refiners under paragraph (c)(2) of this section, no
reports shall be required under this section after August 31, 2014.
(3) For small refiners under paragraph (c)(3) of this section, no
reports shall be required under this section after February 28, 2010.
(4) For all other refiners, no reports shall be required under this
section after August 31, 2012.
51. Section 80.600 is amended by revising the section heading and
paragraphs (a), (c)(3)(iv), (c)(4)(iv), (d)(3), and (f) to read as
follows:
Sec. 80.600 What are the requirements for obtaining an exemption for
motor vehicle diesel fuel or nonroad, locomotive or marine diesel fuel
used for research, development or testing purposes?
(a) Written request for R&D exemption. Any person may receive an
exemption from the provisions of this subpart for diesel fuel used for
research, development, or testing (``R&D'') purposes by submitting the
information listed in paragraph (c) of this section to:
Director (6406J), Transportation and Regional Programs Division, U.S.
Environmental Protection Agency, Ariel Rios Building 1200 Pennsylvania
Avenue, NW., Washington, DC 20460 (postal mail); or
Director (6406J), Transportation and Regional Programs Division, U.S.
Environmental Protection Agency 501 3rd Street, NW., Washington, DC
20001 (express mail/courier); and
Director (2242A), Air Enforcement Division, U.S. Environmental
Protection Agency, Ariel Rios Building, 1200 Pennsylvania Avenue, NW.,
Washington, DC 20460.
* * * * *
(c) * * *
(3) * * *
(iv) The quantity of diesel fuel which does not comply with the
requirements of Sec. Sec. 80.520 through 80.526 for motor vehicle
diesel fuel or Sec. 80.510 for nonroad, locomotive or marine diesel.
(4) * * *
(iv) The manner in which the party will ensure that the R&D fuel
will be segregated from motor vehicle diesel fuel or nonroad,
locomotive or marine fuel, as applicable, and how fuel pumps will be
labeled to ensure proper use of the R&D diesel fuel;
* * * * *
(d) * * *
(3) The R&D diesel fuel must be kept segregated from non-exempt
motor vehicle diesel and/or from non-exempt nonroad, locomotive or
marine fuel, as appropriate, at all points in the distribution system.
* * * * *
(f) Effects of exemption. Motor vehicle diesel fuel or nonroad,
locomotive or marine diesel fuel that is subject to an R&D exemption
under this section is exempt from other provisions of this subpart
provided that the fuel is used in a manner that complies with the
purpose of the program under paragraph (c) of this section and the
requirements of this section.
* * * * *
52. Section 80.601 is revised to read as follows:
Sec. 80.601 What requirements apply to diesel fuel for use in the
Territories?
The sulfur standards of Sec. 80.520(a)(1) and (c) related to motor
vehicle diesel fuel, and of Sec. 80.510(a) and (b) related to nonroad,
locomotive and marine diesel fuel, do not apply to diesel fuel that is
produced, imported, sold, offered for sale, supplied, offered for
supply, stored, dispensed, or transported for use in the Territories of
Guam, American Samoa or the Commonwealth of the Northern Mariana
Islands provided that such diesel fuel is:
(a) Designated by the refiner or importer as high sulfur diesel
fuel only for use in Guam, American Samoa, or the Commonwealth of the
Northern Mariana Islands;
(b) Used only in Guam, American Samoa, or the Commonwealth of the
Northern Mariana Islands;
(c) Accompanied by documentation that complies with the product
transfer document requirements of Sec. 80.590(b)(1); and
(d) Segregated from non-exempt motor vehicle diesel fuel and/or
from non-exempt nonroad, locomotive or marine diesel fuel at all points
in the distribution system from the point the diesel fuel is designated
as exempt fuel only for use in Guam, American Samoa, or the
Commonwealth of the Northern Mariana Islands, while the exempt fuel is
in the United States but outside these Territories.
53. Section 80.602 is amended by revising the section heading,
introductory text, and paragraphs (a) and (b)(1) through (b)(4) to read
as follows:
Sec. 80.602 What exemption applies to diesel fuel used in vehicles or
nonroad engines having a national security exemption from motor vehicle
emissions standards?
The motor vehicle diesel fuel standards of Sec. 80.520(a)(1),
(a)(2), and (c) and the nonroad, locomotive and marine diesel standards
of Sec. 80.510(a) and (b) do not apply to diesel fuel that is
produced, imported, sold, offered for sale, supplied, offered for
supply, stored, dispensed, or transported for use in vehicles or
nonroad equipment for which EPA has granted a national security
exemption under 40 CFR 85.1708 from motor vehicle emissions standards
under 40 CFR part 86 or from nonroad emissions standards under 40 CFR
Parts 89 or 1068, provided that such fuel is:
(a) Used only in tactical military motor vehicles or tactical
military nonroad equipment having an EPA national security exemption
from the motor vehicle emissions standards under 40 CFR 85.1708 from
motor vehicle emissions standards under 40 CFR Part 86 or from nonroad
emissions standards under 40 CFR part 89 or 1068; or
(b) * * *
(1) Used only in vehicles or equipment identified in paragraph (a)
of this section or this paragraph (b);
(2) Accompanied by product transfer documents as required under
Sec. 80.590.
(3) Segregated from non-exempt motor vehicle diesel fuel or from
non-exempt nonroad, locomotive or marine diesel fuel, as applicable at
all points in the distribution system; and
(4) Dispensed from a fuel pump stand, fueling truck or tank that is
labeled
[[Page 28548]]
under the provisions of Sec. Sec. 80.570(c), 80.571, 80.572, or
80.573. Any such fuel pump stand, fueling truck or tank may also be
labeled with the appropriate designation of the fuel, such as ``JP-5''
or ``JP-8''.
54. Section 80.610 is revised to read as follows:
Sec. 80.610 What acts are prohibited under the diesel fuel sulfur
program?
Except as provided in 40 CFR 69.51 and 69.52, and in Sec. 80.601,
no person shall:
(a) Standard, dye, marker or product segregation violation. (1)
Produce, import, sell, offer for sale, dispense, supply, offer for
supply, store or transport motor vehicle, nonroad, locomotive or marine
diesel fuel, or heating oil that does not comply with the applicable
standards, dye, or marker requirements under Sec. Sec. 80.510 or
80.520 or the product segregation requirements under Sec. Sec. 80.536
and 80.554.
(2) Except as provided in paragraph (a)(3) of this section,
starting June 1, 2006, produce, import, sell, offer for sale, dispense,
supply, offer for supply, store or transport any diesel fuel for use in
motor vehicle or nonroad, locomotive or marine engines that contains
greater than 0.12 milligrams per liter of solvent yellow 124.
(3) Starting June 1, 2010, produce, import, sell, offer for sale,
dispense, supply, offer for supply, store or transport any diesel fuel
for use in motor vehicles or nonroad engines that contains greater than
0.12 milligrams per liter of solvent yellow 124.
(4) Sell, offer for sale, dispense, supply, offer for supply, store
or transport heating oil for use in nonroad, locomotive or marine
engines.
(5) Sell, offer for sale, dispense, supply, offer for supply, store
or transport locomotive or marine diesel fuel produced or imported
under Sec. 80.510(c)(2) for use in nonroad engines.
(b) Additive violation. (1) Produce, import, sell, offer for sale,
dispense, supply, offer for supply, store or transport any motor
vehicle or nonroad diesel fuel additive for use at a downstream
location that does not comply with the requirements under Sec.
80.521(a) or (b), as applicable.
(2) Blend or permit the blending into motor vehicle diesel fuel or
nonroad diesel fuel at a downstream location, or use, or permit the
use, as motor vehicle diesel fuel or nonroad diesel fuel, of any
additive which does not comply with the requirements of Sec. 80.521(a)
or (b), as applicable.
(c) Used motor oil violation. Introduce into the fuel system of
model year 2007 or later diesel motor vehicles or model year 2011 or
later nonroad engines or other nonroad engines certified for the use of
15 ppm sulfur content fuel, or permit the introduction into the fuel
system of such vehicles or nonroad engines of used motor oil, or used
motor oil blended with diesel fuel, which does not comply with the
requirements of Sec. 80.522.
(d) Improper fuel usage violation. (1) Introduce, or permit the
introduction of, diesel fuel into model year 2007 or later diesel motor
vehicles, and beginning December 1, 2010 into any diesel motor vehicle,
which does not comply with the standards and dye requirements of Sec.
80.520(a) and (b);
(2) Produce, import, sell, offer for sale, dispense, offer for
supply, store, or transport for use in model year 2007 or later diesel
motor vehicles, or introduce or permit the introduction into such motor
vehicles, motor vehicle diesel fuel that is identified as other than
diesel fuel complying with the 15 ppm sulfur standard; and beginning
December 1, 2010, diesel fuel for use in or introduced into any diesel
motor vehicle;
(3) Introduce, or permit the introduction of, diesel fuel into
nonroad engine equipment or locomotive or marine engines which does not
comply with the applicable standards, dye and marker requirements of
Sec. 80.510 or Sec. 80.511, as applicable;
(4) Produce, import, sell, offer for sale, dispense, offer for
supply, store, or transport for use in model year 2011 or later nonroad
equipment diesel engines or other nonroad equipment engines certified
for use of 15 ppm sulfur content fuel, or introduce or permit the
introduction into such nonroad equipment engines, diesel fuel that is
identified as other than diesel fuel complying with the 15 ppm sulfur
standard; and beginning December 1, 2014, diesel fuel for use in or
introduced into any diesel nonroad equipment;
(5) Produce, import, sell, offer for sale, dispense, offer for
supply, store, or transport for use in locomotive or marine engines, or
introduce or permit the introduction into locomotive or marine engines,
diesel fuel not complying with the 500 ppm sulfur standard, as of the
applicable dates specified in Sec. Sec. 80.510 and 80.511; and
beginning December 1, 2010, diesel fuel for use in any locomotive or
marine engines.
(e) Cause another party to violate. Cause another person to commit
an act in violation of paragraphs (a) through (d) of this section.
(f) Cause violating fuel or additive to be in the distribution
system. Cause motor vehicle diesel fuel, or nonroad, locomotive or
marine diesel fuel, to be in the diesel fuel distribution system which
does not comply with the applicable standard, dye, marker or product
segregation requirements of Sec. Sec. 80.536 or 80.554 and paragraphs
(a)(2) and (a)(3) of this section, or cause any motor vehicle diesel
fuel additive or nonroad diesel fuel additive to be in the diesel fuel
additive distribution system which does not comply with the applicable
sulfur, cetane, and/or aromatics standards of Sec. 80.521.
55. Section 80.611 is revised to read as follows:
Sec. 80.611 What evidence may be used to determine compliance with
the prohibitions and requirements of this subpart and liability for
violations of this subpart?
(a) Compliance with sulfur, cetane, and aromatics standards and
marker requirements. Compliance with the standards in Sec. Sec.
80.510, 80.520, 80.521, and 80.522 shall be determined based on the
level of the applicable component or parameter, using the sampling
methodologies specified in Sec. 80.330(b), as applicable, and an
approved testing methodology under the provisions of Sec. Sec.
80.580--80.586 for sulfur; Sec. 80.2(w) for cetane index; Sec.
80.2(z) for aromatic content; and Sec. 80.582 for fuel marker. Any
evidence or information, including the exclusive use of such evidence
or information, may be used to establish the level of the applicable
component or parameter in the diesel fuel or additive, or motor oil to
be used in diesel fuel, if the evidence or information is relevant to
whether that level would have been in compliance with the standard if
the regulatory sampling and testing methodology had been correctly
performed. Such evidence may be obtained from any source or location
and may include, but is not limited to, test results using methods
other than the compliance methods in this paragraph, business records,
and commercial documents.
(b) Compliance with other requirements. Determination of compliance
with the requirements of this subpart other than the standards
described in paragraph (a) of this section and in Sec. Sec. 80.510,
80.520, 80.521, and 80.522, and determination of liability for any
violation of this subpart, may be based on information obtained from
any source or location. Such information may include, but is not
limited to, business records and commercial documents.
[[Page 28549]]
56. Section 80.612 is amended by revising paragraph (a) to read as
follows:
Sec. 80.612 Who is liable for violations of this subpart?
(a) Persons liable for violations of prohibited acts. (1) Standard,
dye, marker, product segregation, additives, used motor oil, heating
oil and introduction violations. (i) Any refiner, importer,
distributor, reseller, carrier, retailer, or wholesale purchaser-
consumer who owned, leased, operated, controlled or supervised a
facility where a violation of Sec. Sec. 80.610(a) through (d)
occurred, or any other person who violates Sec. 80.610(a) through (d),
is deemed liable for the applicable violation.
(ii) Any person who causes another person to violate Sec. Sec.
80.610(a) through (d) is liable for a violation of Sec. 80.610(e).
(iii) Any refiner, importer, distributor, reseller, carrier,
retailer, or wholesale purchaser-consumer who produced, imported, sold,
offered for sale, dispensed, supplied, offered to supply, stored,
transported, or caused the transportation or storage of, diesel fuel
that violates Sec. 80.610(a), is deemed in violation of Sec.
80.610(e).
(iv) Any person who produced, imported, sold, offered for sale,
dispensed, supplied, offered to supply, stored, transported, or caused
the transportation or storage of a diesel fuel additive which is used
in motor vehicle diesel fuel or nonroad diesel fuel that is found to
violate Sec. 80.610(a), is deemed in violation of Sec. 80.610(e).
(2) Cause violating diesel fuel or additive to be in the
distribution system. Any refiner, importer, distributor, reseller,
carrier, retailer, or wholesale purchaser-consumer or any other person
who owned, leased, operated, controlled or supervised a facility from
which diesel fuel or additive was released into the diesel fuel or
additive distribution system which does not comply with the applicable
standards or dye requirements of Sec. Sec. 80.510, 80.511, 80.520,
80.521, 80.536 or 80.554 is deemed in violation of Sec. 80.610(f).
(3) Branded refiner/importer liability. Any refiner or importer
whose corporate, trade, or brand name, or whose marketing subsidiary's
corporate, trade, or brand name appeared at a facility where a
violation of Sec. 80.610(a) occurred, is deemed in violation of Sec.
80.610(a).
(4) Carrier causation. In order for a diesel fuel or diesel fuel
additive carrier to be liable under paragraphs (a)(1)(ii), (iii) or
(iv) of this section, as applicable, EPA must demonstrate, by
reasonably specific showing by direct or circumstantial evidence, that
the carrier caused the violation.
(5) Parent corporation. Any parent corporation is liable for any
violations of this subpart that are committed by any subsidiary.
(6) Joint venture. Each partner to a joint venture is jointly and
severally liable for any violation of this subpart that occurs at the
joint venture facility or is committed by the joint venture operation.
* * * * *
57. Section 80.613 is revised to read as follows:
Sec. 80.613 What defenses apply to persons deemed liable for a
violation of a prohibited act under Subpart I?
(a) Presumptive liability defenses. (1) Any person deemed liable
for a violation of a prohibition under Sec. 80.612 (a)(1)(i) or (iii),
(a)(2), or (a)(3), will not be deemed in violation if the person
demonstrates:
(i) The violation was not caused by the person or the person's
employee or agent;
(ii) Product transfer documents account for fuel or additive found
to be in violation and indicate that the violating product was in
compliance with the applicable requirements when it was under the
party's control;
(iii) The person conducted a quality assurance sampling and testing
program, as described in paragraph (d) of this section, except for
those parties subject to the provisions of paragraph (a)(1)(iv) or (v)
of this section. A carrier may rely on the quality assurance program
carried out by another party, including the party who owns the diesel
fuel in question, provided that the quality assurance program is
carried out properly. Retailers, wholesale purchaser-consumers, and
ultimate consumers of diesel fuel are not required to conduct quality
assurance programs;
(iv) For refiners and importers of diesel fuel subject to the 15
ppm standard under Sec. Sec. 80.510(b) or 80.520(a)(1), or the 500 ppm
sulfur standard under Sec. 80.510(a), test results which:
(A) Were conducted according to an appropriate test methodology
approved or designated under Sec. Sec. 80.580 and 80.584-80.586; and
(B) Establish that, when it left the party's control, the sulfur
content of the diesel fuel did not exceed the 15 ppm standard or the
500 ppm standard, as applicable;
(C) In lieu of testing for marker solvent yellow 124 concentration
a refiner or importer may present evidence of an oversight program,
including records of marker inventory, purchase and additization, and
records of periodic inspection and calibration of additization
equipment that ensures that marker is added to heating oil under Sec.
80.510(c)(1) or locomotive and marine diesel fuel under Sec.
80.510(c)(2) in the required concentration; and
(v) For refiners and importers of heating oil or LM diesel fuel
subject to the marker requirements under Sec. 80.510(c), data which
demonstrates that when it left it left the parties custody, the marker
content was greater than or equal to 0.6 mg/L; and
(vi) For any person who, at a downstream location, blends a diesel
fuel additive subject to the requirements of Sec. 80.521(b) into motor
vehicle diesel fuel or nonroad diesel fuel subject to the 15 ppm sulfur
standard under Sec. Sec. 80.520(a) or 80.510(b), except a blender who
blends additives into fuel tanker trucks at a truck loading rack
subject to the provisions of (d)(2) of this section, test results which
are conducted subsequent to the blending of the additive into the fuel,
and which comply with the requirements of paragraphs (a)(4)(iv)(A) and
(B) of this section.
(2) Any party deemed liable for a violation under Sec.
80.612(a)(1)(iv), in regard to a diesel fuel additive subject to the
requirements of Sec. 80.521(a), will not be deemed in violation if the
person demonstrates that:
(i) Product transfer document(s) account for the additive in the
fuel found to be in violation, which comply with the requirements under
Sec. 80.591(a), and indicate that the additive was in compliance with
the applicable requirements while it was under the party's control; and
(ii) For the additive's manufacturer or importer, test results
which accurately establish that, when it left the party's control, the
additive in the diesel fuel determined to be in violation did not have
a sulfur content in excess of 15 ppm.
(A) Analysis of the additive sulfur content pursuant paragraph
(a)(2) of this section may be conducted at the time the batch was
manufactured or imported, or on a sample of that batch which the
manufacturer or importer retains for such purpose for a minimum of two
years from the date the batch was manufactured or imported;
(B) After two years from the date the additive batch was
manufactured or imported, the additive manufacturer or importer is no
longer required to retain samples for the purpose of complying with the
testing requirements of this paragraph (a)(2) of this section.
[[Page 28550]]
(C) The analysis of the sulfur content of the additive must be
conducted pursuant to the requirements of Sec. 80.580.
(3) Any person who is deemed liable for a violation under Sec.
80.612(a)(1)(iv) with regard to a diesel fuel additive subject to the
requirements of Sec. 80.521(b), will not be deemed in violation if the
person demonstrates that:
(i) The violation was not caused by the party or the party's
employee or agent;.
(ii) Product transfer document(s) which comply with the additive
information requirements under Sec. 80.591(b), account for the
additive in the fuel found to be in violation, and indicate that the
additive was in compliance with the applicable requirements while it
was under the party's control;
(iii) For the additive's manufacturer or importer, test results
which accurately establish that, when it left the party's control, the
additive in the diesel fuel determined to be in violation was in
conformity with the information on the additive product transfer
document pursuant to the requirements of Sec. 80.591(b). The testing
procedures applicable under paragraph (a)(2) of this section, also
apply under paragraph (a)(3) of this section; and
(b) Branded refiner defenses. In the case of a violation found at a
facility operating under the corporate, trade or brand name of a
refiner or importer, or a refiner's or importer's marketing subsidiary,
the refiner or importer must show, in addition to the defense elements
required under paragraph (a)(1) of this section, that the violation was
caused by:
(1) An act in violation of law (other than the Clean Air Act or
this Part 80), or an act of sabotage or vandalism;
(2) The action of any refiner, importer, retailer, distributor,
reseller, oxygenate blender, carrier, retailer or wholesale purchaser-
consumer in violation of a contractual agreement between the branded
refiner or importer and the person designed to prevent such action, and
despite periodic sampling and testing by the branded refiner or
importer to ensure compliance with such contractual obligation; or
(3) The action of any carrier or other distributor not subject to a
contract with the refiner or importer, but engaged for transportation
of diesel fuel, despite specifications or inspections of procedures and
equipment which are reasonably calculated to prevent such action.
(c) Causation demonstration. Under paragraph (a)(1) of this section
for any person to show that a violation was not caused by that person,
or under paragraph (b) of this section to show that a violation was
caused by any of the specified actions, the person must demonstrate by
reasonably specific showing, by direct or circumstantial evidence, that
the violation was caused or must have been caused by another person and
that the person asserting the defense did not contribute to that other
person's causation.
(d) Quality assurance and testing program. To demonstrate an
acceptable quality assurance program under paragraph (a)(1)(iii) of
this section, a person must present evidence of the following:
(1) A periodic sampling and testing program to ensure the diesel
fuel or additive the person sold, dispensed, supplied, stored, or
transported, meets the applicable standards; and
(2) For those parties who, at a downstream location, blend diesel
fuel additives subject to the requirements of Sec. 80.521(b) into fuel
trucks at a truck loading rack, the periodic sampling and testing
program required under this paragraph (d) must ensure, by taking into
account the greater risk of noncompliance created through use of a high
sulfur additive, that the diesel fuel into which the additive was
blended meets the applicable standards subsequent to the blending;
(3) On each occasion when diesel fuel or additive is found not in
compliance with the applicable standard:
(i) The person immediately ceases selling, offering for sale,
dispensing, supplying, offering for supply, storing or transporting the
non-complying product; and
(ii) The person promptly remedies the violation and the factors
that caused the violation (for example, by removing the non-complying
product from the distribution system until the applicable standard is
achieved and taking steps to prevent future violations of a similar
nature from occurring).
(4) For any carrier who transports diesel fuel or additive in a
tank truck, the quality assurance program required under this paragraph
(d) need not include its own periodic sampling and testing of the
diesel fuel or additive in the tank truck, but in lieu of such tank
truck sampling and testing, the carrier shall demonstrate evidence of
an oversight program for monitoring compliance with the requirements of
this subpart relating to the transport or storage of such product by
tank truck, such as appropriate guidance to drivers regarding
compliance with the applicable sulfur standard, product segregation and
product transfer document requirements, and the periodic review of
records received in the ordinary course of business concerning diesel
fuel or additive quality and delivery.
58. Section 80.614 is revised to read as follows:
Sec. 80.614 What penalties apply under this subpart?
(a) Any person liable for a violation under Sec. 80.612 is subject
to civil penalties as specified in section 205 of the Clean Air Act for
every day of each such violation and the amount of economic benefit or
savings resulting from each violation.
(b)(1) Any person liable under Sec. 80.612(a)(1) for a violation
of an applicable standard or requirement under Sec. Sec. 80.510,
80.511, 80.520, 80.524, or 80.554, or of causing another party to
violate such standard or requirement, is subject to a separate day of
violation for each and every day the non-complying diesel fuel remains
any place in the distribution system.
(2) Any person liable under Sec. 80.612(a)(2) for causing motor
vehicle diesel fuel or nonroad, locomotive or marine diesel fuel, or
heating oil, to be in the distribution system which does not comply
with an applicable standard or requirement of Sec. Sec. 80.510,
80.511, or 80.520 is subject to a separate day of violation for each
and every day that the non-complying diesel fuel remains any place in
the diesel fuel distribution system.
(3) Any person liable under Sec. 80.612(a)(1) for blending into
diesel fuel an additive violating the applicable sulfur standard
pursuant to the requirements of Sec. 80.521(a) or (b), as appropriate,
or of causing another party to so blend or add such an additive, is
subject to a separate day of violation for each and every day the motor
vehicle diesel fuel or nonroad diesel fuel into which the noncomplying
additive was blended, remains any place in the fuel distribution
system.
(4) For purposes of this paragraph (b), the length of time the
motor vehicle diesel fuel or nonroad, locomotive or marine diesel fuel,
or heating oil in question remained in the diesel fuel distribution
system is deemed to be twenty-five days, unless a person subject to
liability or EPA demonstrates by reasonably specific showings, by
direct or circumstantial evidence, that the non-complying motor
vehicle, nonroad, locomotive or marine diesel fuel, or heating oil,
remained in the distribution system for fewer than or more than twenty-
five days.
(c) Any person liable under Sec. 80.612(b) for failure to meet, or
[[Page 28551]]
causing a failure to meet, a provision of this subpart is liable for a
separate day of violation for each and every day such provision remains
unfulfilled.
59. Section 80.620 is revised to read as follows:
Sec. 80.620 What are the additional requirements for diesel fuel
produced by foreign refineries subject to a temporary refiner
compliance option, non-highway baseline, hardship provisions, or motor
vehicle or nonroad locomotive and marine diesel fuel credit provisions?
(a) Definitions. (1) A foreign refinery is a refinery that is
located outside the United States, the Commonwealth of Puerto Rico, the
Virgin Islands, Guam, American Samoa, and the Commonwealth of the
Northern Mariana Islands (collectively referred to in this section as
``the United States'').
(2) A foreign refiner is a person who meets the definition of
refiner under Sec. 80.2(i) for a foreign refinery.
(3) A diesel fuel program foreign refiner (``DFR'') is a foreign
refiner that has been approved by EPA for participation in any motor
vehicle diesel fuel or nonroad, locomotive or marine diesel fuel
provision of Sec. Sec. 80.530 through 80.536, 80.540, 80.552, 80.553,
80.554, 80.560 or 80.561 (collectively referred to as ``diesel foreign
refiner program'').
(4) ``DFR-Diesel'' means diesel fuel produced at a DFR refinery
that is imported into the United States.
(5) ``Non-DFR-Diesel'' means diesel fuel that is produced at a
foreign refinery that has not been approved as a DFR foreign refiner,
diesel fuel produced at a DFR foreign refinery that is not imported
into the United States, and diesel fuel produced at a DFR foreign
refinery during a period when the foreign refiner has opted to not
participate in the DFR-Diesel foreign refiner program under paragraph
(c)(3) of this section.
(6) ``Certified DFR-Diesel'' means DFR-Diesel the foreign refiner
intends to include in the foreign refinery's compliance calculations
under any provisions of Sec. Sec. 80.530 through 80.536, 80.540,
80.552, 80.553, 80.554, 80.560 or 80.561 and does include in these
compliance calculations when reported to EPA.
(7) ``Non-Certified DFR-Diesel'' means DFR-Diesel fuel that a DFR
foreign refiner imports to the United States that is not Certified DFR-
Diesel.
(b) Baseline. For any foreign refiner to obtain approval under the
diesel foreign refiner program of subpart I of this part for any
refinery, it must apply for approval under the applicable provisions of
subpart I of this part. To obtain approval the refiner is required, as
applicable, to demonstrate a volume baseline for calendar years 1998
and 1999 for motor vehicle diesel fuel produced for use in the United
States under Sec. Sec. 80.595 and 80.596 or a non-highway baseline for
diesel fuel and heating oil produced for use in the United States for
the calendar years 2003 through 2005 under Sec. Sec. 80.533 and
80.534.
(1) The refiner shall follow the procedures, applicable to volume
baselines and using diesel fuel, or if applicable, heating oil, instead
of gasoline, in Sec. Sec. 80.91 through 80.93 to establish the volume
of motor vehicle diesel fuel that was produced at the refinery and
imported into the United States during 1998 and 1999 for purposes of
establishing a baseline under Sec. Sec. 80.595 and 80.596 or of diesel
fuel and heating oil produced at the refinery and imported into the
United States for the calendar years 2003 through 2005 for the purposes
of establishing a baseline under Sec. 80.533.
(2) In making determinations for foreign refinery baselines EPA
will consider all information supplied by a foreign refiner, and in
addition may rely on any and all appropriate assumptions necessary to
make such determinations.
(3) Where a foreign refiner submits a petition that is incomplete
or inadequate to establish an accurate baseline, and the refiner fails
to correct this deficiency after a request for more information, EPA
will not assign an individual refinery motor vehicle diesel fuel volume
baseline or a non-highway baseline.
(c) General requirements for DFR foreign refiners. A foreign
refiner of a refinery that is approved under the diesel foreign refiner
program of 40 CFR part 80, subpart I, must designate each batch of
diesel fuel produced at the foreign refinery that is exported to the
United States as either Certified DFR-Diesel or as Non-Certified DFR-
Diesel, except as provided in paragraph (c)(3) of this section. It must
further designate all Certified DFR-Diesel as provided in Sec. 80.523,
and designate whether the diesel fuel is dyed or undyed, for heating
oil whether it is marked under Sec. 80.510(c)(1) and for locomotive or
marine fuel, whether it is marked under Sec. 80.510(c)(2). It must
further designate any credits earned as either nonroad diesel credits
or motor vehicle diesel credits.
(1) In the case of Certified DFR-Diesel, the foreign refiner must
meet all requirements that apply to refiners under this subpart I,
except that:
(i) For purposes of complying with the compliance option
requirements of Sec. 80.530, motor vehicle diesel fuel produced by a
foreign refinery must comply separately for each Credit Trading Area of
import, as defined in Sec. 80.531(a)(5).
(ii) For purposes of complying with the compliance option
requirements of Sec. 80.530, credits obtained from any other refinery
or from any importer must have been generated in the same Credit
Trading Area as the Credit Trading Area of import of the fuel for which
credits are needed to achieve compliance.
(iii) For purposes of generating credits under Sec. 80.531,
credits shall be generated separately by Credit Trading Area of import
and shall be designated by Credit Trading Area of importation and by
port of importation.
(2) In the case of Non-Certified DFR-Diesel, the foreign refiner
shall meet all the following requirements:
(i) The designation requirements in this section.
(ii) The reporting requirements in this section and Sec. Sec.
80.593, 80.598 and 80.599.
(iii) The product transfer document requirements in this section
and Sec. Sec. 80.590 and 80.591.
(iv) The prohibitions in this section and Sec. 80.610.
(3)(i) Any foreign refiner that has been approved to produce diesel
fuel subject to the diesel foreign refiner program for a foreign
refinery under subpart I may elect to classify no diesel fuel imported
into the United States as DFR-Diesel provided the foreign refiner
notifies EPA of the election no later than November 1 of the prior
calendar year.
(ii) An election under paragraph (c)(3)(i) of this section shall be
for an entire calendar year and apply to all diesel fuel that is
produced by the foreign refinery that is imported into the United
States, and shall remain in effect for each succeeding year unless and
until the foreign refiner notifies EPA of the termination of the
election. The change in election shall take effect at the beginning of
the next calendar year.
(d) Designation, product transfer documents, and foreign refiner
certification. (1) Any foreign refiner of a foreign refinery that has
been approved by EPA to produce diesel fuel subject to the diesel
foreign refiner program must designate each batch of DFR-Diesel as such
at the time the diesel fuel is produced, unless the refiner has elected
to classify no diesel fuel exported to the United States as DFR-Diesel
under paragraph (c)(3) of this section.
(2) On each occasion when any person transfers custody or title to
any DFR-Diesel prior to its being imported into the United States, it
must include
[[Page 28552]]
the following information as part of the product transfer document
information in this section:
(i) Designation of the diesel fuel as Certified DFR-Diesel or as
Non-Certified DFR-Diesel, and if it is Certified DFR-Diesel, further
designate the fuel pursuant to Sec. 80.523, and whether the diesel
fuel is dyed or undyed, for heating oil whether it is marked under
Sec. 80.510(c)(1) and for locomotive or marine fuel, whether it is
marked under Sec. 80.510(c)(2), and all other applicable product
transfer document information required under Sec. 80.590; and
(ii) The name and EPA refinery registration number (under Sec.
80.593) of the refinery where the DFR-Diesel was produced.
(3) On each occasion when DFR-Diesel is loaded onto a vessel or
other transportation mode for transport to the United States, the
foreign refiner shall prepare a certification for each batch of the
DFR-Diesel that meets the following requirements.
(i) The certification shall include the report of the independent
third party under paragraph (f) of this section, and the following
additional information:
(A) The name and EPA registration number of the refinery that
produced the DFR-Diesel;
(B) The identification of the diesel fuel as Certified DFR-Diesel
or Non-Certified DFR-Diesel;
(C) The volume of DFR-Diesel being transported, in gallons;
(D) In the case of Certified DFR-Diesel:
(1) The sulfur content as determined under paragraph (f) of this
section, and the applicable designations stated in paragraph (d)(2)(i)
of this section; and
(2) A declaration that the DFR-Diesel is being included in the
applicable compliance calculations required by the EPA under subpart I.
(ii) The certification shall be made part of the product transfer
documents for the DFR-Diesel.
(e) Transfers of DFR-Diesel to non-United States markets. The
foreign refiner is responsible to ensure that all diesel fuel
classified as DFR-Diesel is imported into the United States. A foreign
refiner may remove the DFR-Diesel classification, and the diesel fuel
need not be imported into the United States, but only if:
(1)(i) The foreign refiner excludes:
(A) The volume of diesel from the refinery's compliance report
under Sec. Sec. 80.593 or 80.599; and
(B) In the case of Certified DFR-Diesel, the volume of the diesel
fuel from the compliance report under Sec. 80.593 or Sec. 80.599.
(ii) The exclusions under paragraph (e)(1)(i) of this section shall
be on the basis of the designations under Sec. 80.523 and this section
and volumes determined under paragraph (f) of this section; and
(2) The foreign refiner obtains sufficient evidence in the form of
documentation that the diesel fuel was not imported into the United
States.
(f) Load port independent sampling, testing and refinery
identification. (1) On each occasion that DFR-Diesel is loaded onto a
vessel for transport to the United States a foreign refiner shall have
an independent third party:
(i) Inspect the vessel prior to loading and determine the volume of
any tank bottoms;
(ii) Determine the volume of DFR-Diesel loaded onto the vessel
(exclusive of any tank bottoms before loading);
(iii) Obtain the EPA-assigned registration number of the foreign
refinery;
(iv) Determine the name and country of registration of the vessel
used to transport the DFR-Diesel to the United States; and
(v) Determine the date and time the vessel departs the port serving
the foreign refinery.
(2) On each occasion that Certified DFR-Diesel is loaded onto a
vessel for transport to the United States a foreign refiner shall have
an independent third party:
(i) Collect a representative sample of the Certified DFR-Diesel
from each vessel compartment subsequent to loading on the vessel and
prior to departure of the vessel from the port serving the foreign
refinery;
(ii) Determine the sulfur content value for each compartment, and
if applicable, the marker content under Sec. 80.510(c) using an
approved methodology as specified in Sec. 80.580 and Sec. 80.582 by:
(A) The third party analyzing each sample; or
(B) The third party observing the foreign refiner analyze the
sample;
(iii) Review original documents that reflect movement and storage
of the certified DFR-Diesel from the refinery to the load port, and
from this review determine:
(A) The refinery at which the DFR-Diesel was produced; and
(B) That the DFR-Diesel remained segregated from:
(1) Non-DFR-Diesel and Non-Certified DFR-Diesel; and
(2) Other Certified DFR-Diesel produced at a different refinery;
(3) The independent third party shall submit a report:
(i) To the foreign refiner containing the information required
under paragraphs (f)(1) and (f)(2) of this section, to accompany the
product transfer documents for the vessel; and
(ii) To the Administrator containing the information required under
paragraphs (f)(1) and (f)(2) of this section, within thirty days
following the date of the independent third party's inspection. This
report shall include a description of the method used to determine the
identity of the refinery at which the diesel fuel was produced,
assurance that the diesel fuel remained segregated as specified in
paragraph (n)(1) of this section, and a description of the diesel
fuel's movement and storage between production at the source refinery
and vessel loading.
(4) The independent third party must:
(i) Be approved in advance by EPA, based on a demonstration of
ability to perform the procedures required in this paragraph (f);
(ii) Be independent under the criteria specified in Sec.
80.65(e)(2)(iii); and
(iii) Sign a commitment that contains the provisions specified in
paragraph (i) of this section with regard to activities, facilities and
documents relevant to compliance with the requirements of this
paragraph (f).
(g) Comparison of load port and port of entry testing. (1)(i) Any
foreign refiner and any United States importer of Certified DFR-Diesel
shall compare the results from the load port testing under paragraph
(f) of this section, with the port of entry testing as reported under
paragraph (o) of this section, for the volume of diesel fuel and the
sulfur content value; except that;
(ii) Where a vessel transporting Certified DFR-Diesel off loads
this diesel fuel at more than one United States port of entry, and the
conditions of paragraph (g)(2)(i) of this section are met at the first
United States port of entry, the requirements of paragraph (g)(2) of
this section do not apply at subsequent ports of entry if the United
States importer obtains a certification from the vessel owner that
meets the requirements of paragraph (s) of this section, that the
vessel has not loaded any diesel fuel or blendstock between the first
United States port of entry and the subsequent port of entry.
(2)(i) The requirements of this paragraph (g)(2) apply if:
(A) The temperature-corrected volumes determined at the port of
entry and at the load port differ by more than one percent; or
(B) The sulfur content value determined at the port of entry is
higher than the sulfur content value determined at the load port, and
the amount of this difference is greater than the reproducibility
amount specified for the port of entry test result by the American
Society of Testing and Materials (ASTM) for a test method used
[[Page 28553]]
for testing the port of entry sample under the provisions Sec. 80.580.
(ii) The United States importer and the foreign refiner shall treat
the diesel fuel as Non-Certified DFR-Diesel, and the foreign refiner
shall exclude the diesel fuel volume from its diesel fuel volumes
calculations and sulfur standard designations under Sec. 80.523.
(h) Attest requirements. Refiners, for each calendar year, must
arrange to have an attest engagement performed of the underlying
documentation that forms the basis of any report required under this
subpart I. The attest engagement must comply with the procedures and
requirements that apply to refiners under Sec. Sec. 80.125 through
80.130 and must be submitted to the Administrator of EPA by May 30 of
each year for the prior calendar year. The following additional
procedures shall be carried out for any foreign refiner of DFR-Diesel.
(1) The inventory reconciliation analysis under Sec. 80.128(b) and
the tender analysis under Sec. 80.128(c) shall include Non-DFR-Diesel.
(2) Obtain separate listings of all tenders of Certified DFR-Diesel
and of Non-Certified DFR-Diesel, and obtain separate listings of
Certified DFR-Diesel based on whether it is 15 ppm sulfur content
diesel fuel, 500 ppm sulfur content diesel fuel or high sulfur fuel
having a sulfur content greater than 500 ppm (and if so, whether the
fuel is marked heating oil or small refiner diesel fuel or diesel fuel
produced through the use of credits). Agree the total volume of tenders
from the listings to the diesel fuel inventory reconciliation analysis
in Sec. 80.128(b), and to the volumes determined by the third party
under paragraph (f)(1) of this section.
(3) For each tender under paragraph (h)(2) of this section, where
the diesel fuel is loaded onto a marine vessel, report as a finding the
name and country of registration of each vessel, and the volumes of
DFR-Diesel loaded onto each vessel.
(4) Select a sample from the list of vessels identified in
paragraph (h)(3) of this section used to transport Certified DFR-
Diesel, in accordance with the guidelines in Sec. 80.127, and for each
vessel selected perform the following:
(i) Obtain the report of the independent third party, under
paragraph (f) of this section, and of the United States importer under
paragraph (o) of this section.
(A) Agree the information in these reports with regard to vessel
identification, diesel fuel volumes and sulfur content test results.
(B) Identify, and report as a finding, each occasion the load port
and port of entry sulfur content and volume results differ by more than
the amounts allowed in paragraph (g) of this section, and determine
whether the foreign refiner adjusted its refinery calculations as
required in paragraph (g) of this section.
(ii) Obtain the documents used by the independent third party to
determine transportation and storage of the Certified DFR-Diesel from
the refinery to the load port, under paragraph (f) of this section.
Obtain tank activity records for any storage tank where the Certified
DFR-Diesel is stored, and pipeline activity records for any pipeline
used to transport the Certified DFR-Diesel, prior to being loaded onto
the vessel. Use these records to determine whether the Certified DFR-
Diesel was produced at the refinery that is the subject of the attest
engagement, and whether the Certified DFR-Diesel was mixed with any
Non-Certified DFR-Diesel, Non-DFR-Diesel, or any Certified DFR-Diesel
produced at a different refinery.
(5)(i) Select a sample from the list of vessels identified in
paragraph (h)(3) of this section used to transport certified and Non-
Certified DFR-Diesel, in accordance with the guidelines in Sec.
80.127, and for each vessel selected perform the following:
(ii) Obtain a commercial document of general circulation that lists
vessel arrivals and departures, and that includes the port and date of
departure of the vessel, and the port of entry and date of arrival of
the vessel. Agree the vessel's departure and arrival locations and
dates from the independent third party and United States importer
reports to the information contained in the commercial document.
(6) Obtain separate listings of all tenders of Non-DFR-Diesel, and
perform the following:
(i) Agree the total volume and sulfur content of tenders from the
listings to the diesel fuel inventory reconciliation analysis in Sec.
80.128(b).
(ii) Obtain a separate listing of the tenders under paragraph
(h)(6) of this section where the diesel fuel is loaded onto a marine
vessel. Select a sample from this listing in accordance with the
guidelines in Sec. 80.127, and obtain a commercial document of general
circulation that lists vessel arrivals and departures, and that
includes the port and date of departure and the ports and dates where
the diesel fuel was off loaded for the selected vessels. Determine and
report as a finding the country where the diesel fuel was off loaded
for each vessel selected.
(7) In order to complete the requirements of this paragraph (h) an
auditor shall:
(i) Be independent of the foreign refiner;
(ii) Be licensed as a certified public accountant in the United
States and a citizen of the United States, or be approved in advance by
EPA based on a demonstration of ability to perform the procedures
required in Sec. Sec. 80.125 through 80.130 and this paragraph (h);
and
(iii) Sign a commitment that contains the provisions specified in
paragraph (i) of this section with regard to activities and documents
relevant to compliance with the requirements of Sec. Sec. 80.125
through 80.130 and this paragraph (h).
(i) Foreign refiner commitments. Any foreign refiner shall commit
to and comply with the provisions contained in this paragraph (i) as a
condition to being approved for a temporary refiner diesel fuel program
option.
(1) Any United States Environmental Protection Agency inspector or
auditor must be given full, complete and immediate access to conduct
inspections and audits of the foreign refinery.
(i) Inspections and audits may be either announced in advance by
EPA, or unannounced.
(ii) Access will be provided to any location where:
(A) Diesel fuel is produced;
(B) Documents related to refinery operations are kept;
(C) Diesel fuel or blendstock samples are tested or stored; and
(D) DFR-Diesel is stored or transported between the foreign
refinery and the United States, including storage tanks, vessels and
pipelines.
(iii) Inspections and audits may be by EPA employees or contractors
to EPA.
(iv) Any documents requested that are related to matters covered by
inspections and audits must be provided to an EPA inspector or auditor
on request.
(v) Inspections and audits by EPA may include review and copying of
any documents related to:
(A) Refinery baseline establishment, if applicable, including the
volume, sulfur content and dye status of diesel fuel, heating oil and
other distillates; transfers of title or custody of any diesel fuel,
heating oil or blendstocks whether DFR-Diesel or Non-DFR-Diesel,
produced at the foreign refinery during the period January 1, 1998
through the date of the refinery baseline petition or through the date
of the inspection or audit if a baseline petition has not been
approved, and any work papers related to refinery baseline
establishment;
[[Page 28554]]
(B) The volume and sulfur content of DFR-Diesel;
(C) The proper classification of diesel fuel as being DFR-Diesel or
as not being DFR-Diesel, or as Certified DFR-Diesel or as Non-Certified
DFR-Diesel, and all other relevant designations under subpart I,
including Sec. 80.523 and this section;
(D) Transfers of title or custody to DFR-Diesel;
(E) Sampling and testing of DFR-Diesel;
(F) Work performed and reports prepared by independent third
parties and by independent auditors under the requirements of this
section, including work papers; and
(G) Reports prepared for submission to EPA, and any work papers
related to such reports.
(vi) Inspections and audits by EPA may include taking samples of
diesel fuel, heating oil, diesel fuel additives or blendstock, dyes and
chemical markers and interviewing employees.
(vii) Any employee of the foreign refiner must be made available
for interview by the EPA inspector or auditor, on request, within a
reasonable time period.
(viii) English language translations of any documents must be
provided to an EPA inspector or auditor, on request, within 10 working
days.
(ix) English language interpreters must be provided to accompany
EPA inspectors and auditors, on request.
(2) An agent for service of process located in the District of
Columbia shall be named, and service on this agent constitutes service
on the foreign refiner or any employee of the foreign refiner for any
action by EPA or otherwise by the United States related to the
requirements of this subpart.
(3) The forum for any civil or criminal enforcement action related
to the provisions of this section for violations of the Clean Air Act
or regulations promulgated thereunder shall be governed by the Clean
Air Act, including the EPA administrative forum where allowed under the
Clean Air Act.
(4) United States substantive and procedural laws shall apply to
any civil or criminal enforcement action against the foreign refiner or
any employee of the foreign refiner related to the provisions of this
section.
(5) Submitting a petition for participation in the diesel foreign
refiner program or producing and exporting diesel fuel or heating oil
under any such program, and all other actions to comply with the
requirements of this subpart relating to participation in any diesel
foreign refiner program, or to establish an individual refinery motor
vehicle diesel fuel volume baseline of non-highway baseline (if
applicable) constitute actions or activities that satisfy the
provisions of 28 U.S.C. 1605(a)(2), but solely with respect to actions
instituted against the foreign refiner, its agents and employees in any
court or other tribunal in the United States for conduct that violates
the requirements applicable to the foreign refiner under this subpart,
including conduct that violates 18 U.S.C. 1001 and section 113(c)(2) of
the Clean Air Act.
(6) The foreign refiner, or its agents or employees, will not seek
to detain or to impose civil or criminal remedies against EPA
inspectors or auditors, whether EPA employees or EPA contractors, for
actions performed within the scope of EPA employment related to the
provisions of this section.
(7) The commitment required by this paragraph (i) shall be signed
by the owner or president of the foreign refiner business.
(8) In any case where DFR-Diesel produced at a foreign refinery is
stored or transported by another company between the refinery and the
vessel that transports the DFR-Diesel to the United States, the foreign
refiner shall obtain from each such other company a commitment that
meets the requirements specified in paragraphs (i)(1) through (7) of
this section, and these commitments shall be included in the foreign
refiner's petition to participate in any diesel foreign refiner
program.
(j) Sovereign immunity. By submitting a petition for participation
in any diesel foreign refiner program under subpart I of this part (and
baseline, if applicable) under this section, or by producing and
exporting diesel fuel to the United States under any such program, the
foreign refiner, and its agents and employees, without exception,
become subject to the full operation of the administrative and judicial
enforcement powers and provisions of the United States without
limitation based on sovereign immunity, with respect to actions
instituted against the foreign refiner, its agents and employees in any
court or other tribunal in the United States for conduct that violates
the requirements applicable to the foreign refiner under subpart I of
this part including conduct that violates 18 U.S.C. 1001 and section
113(c)(2) of the Clean Air Act.
(k) Bond posting. Any foreign refiner shall meet the requirements
of this paragraph (k) as a condition to approval for any diesel foreign
refiner program under subpart I of this part.
(1) The foreign refiner shall post a bond of the amount calculated
using the following equation:
Bond = G x $0.01
Where:
Bond = amount of the bond in U. S. dollars
G = the volume baseline for motor vehicle diesel fuel produced at the
foreign refinery and exported to the United States, in gallons, and, if
applicable, the volume Vnrlm, as defined in Sec. 80.534.
(2) Bonds shall be posted by:
(i) Paying the amount of the bond to the Treasurer of the United
States;
(ii) Obtaining a bond in the proper amount from a third-party
surety agent that is payable to satisfy United States administrative or
judicial judgments against the foreign refiner, provided EPA agrees in
advance as to the third party and the nature of the surety agreement;
or
(iii) An alternative commitment that results in assets of an
appropriate liquidity and value being readily available to the United
States, provided EPA agrees in advance as to the alternative
commitment.
(3) Bonds posted under this paragraph (k) shall:
(i) Be used to satisfy any judicial judgment that results from an
administrative or judicial enforcement action for conduct in violation
of this subpart, including where such conduct violates 18 U.S.C. 1001
and section 113(c)(2) of the Clean Air Act,
(ii) Be provided by a corporate surety that is listed in the United
States Department of Treasury Circular 570 ``Companies Holding
Certificates of Authority as Acceptable Sureties on Federal Bonds'',
and
(iii) Include a commitment that the bond will remain in effect for
at least five (5) years following the end of latest annual reporting
period that the foreign refiner produces diesel fuel pursuant to the
requirements of this Subpart I.
(4) On any occasion a foreign refiner bond is used to satisfy any
judgment, the foreign refiner shall increase the bond to cover the
amount used within 90 days of the date the bond is used.
(5) If the bond amount for a foreign refiner increases, the foreign
refiner shall increase the bond to cover the shortfall within 90 days
of the date the bond amount changes. If the bond amount decreases, the
foreign refiner may reduce the amount of the bond beginning 90 days
after the date the bond amount changes.
(l) [Reserved]
(m) English language reports. Any report or other document
submitted to
[[Page 28555]]
EPA by a foreign refiner shall be in English language, or shall include
an English language translation.
(n) Prohibitions. (1) No person may combine Certified DFR-Diesel
with any Non-Certified DFR-Diesel or Non-DFR-Diesel, and no person may
combine Certified DFR-Diesel with any Certified DFR-Diesel produced at
a different refinery, until the importer has met all the requirements
of paragraph (o) of this section, except as provided in paragraph (e)
of this section. No person may violate the product segregation
requirements of Sec. 80.511.
(2) No foreign refiner or other person may cause another person to
commit an action prohibited in paragraph (n)(1) of this section, or
that otherwise violates the requirements of this section.
(o) United States importer requirements. Any United States importer
shall meet the following requirements.
(1) Each batch of imported diesel fuel and heating oil shall be
classified by the importer as being DFR-Diesel or as Non-DFR-Diesel,
and each batch classified as DFR-Diesel shall be further classified as
Certified DFR-Diesel or as Non-Certified DFR-Diesel, and each batch of
Certified DFR-Diesel shall be further designated pursuant to the
designation requirements of Sec. 80.523 and this section.
(2) Diesel fuel shall be classified as Certified DFR-Diesel or as
Non-Certified DFR-Diesel according to the designation by the foreign
refiner if this designation is supported by product transfer documents
prepared by the foreign refiner as required in paragraph (d) of this
section, unless the diesel fuel is classified as Non-Certified DFR-
Diesel under paragraph (g) of this section. Additionally, the importer
shall comply with all requirements of subpart I applicable to
importers.
(3) For each diesel fuel batch classified as DFR-Diesel, any United
States importer shall perform the following procedures.
(i) In the case of both Certified and Non-Certified DFR-Diesel,
have an independent third party:
(A) Determine the volume of diesel fuel in the vessel;
(B) Use the foreign refiner's DFR-Diesel certification to determine
the name and EPA-assigned registration number of the foreign refinery
that produced the DFR-Diesel;
(C) Determine the name and country of registration of the vessel
used to transport the DFR-Diesel to the United States; and
(D) Determine the date and time the vessel arrives at the United
States port of entry.
(ii) In the case of Certified DFR-Diesel, have an independent third
party:
(A) Collect a representative sample from each vessel compartment
subsequent to the vessel's arrival at the United States port of entry
and prior to off loading any diesel fuel from the vessel;
(B) Obtain the compartment samples; and
(C) Determine the sulfur content value, and if applicable, the
marker content, of each compartment sample using an appropriate
methodology as specified in Sec. Sec. 80.580 or 80.582, by:
(1) The third party analyzing the sample; or
(2) The third party observing the importer analyze the sample;
(4) Any importer shall submit reports within 30 days following the
date any vessel transporting DFR-Diesel arrives at the United States
port of entry:
(i) To the Administrator containing the information determined
under paragraph (o)(3) of this section; and
(ii) To the foreign refiner containing the information determined
under paragraph (o)(3)(ii) of this section, and including
identification of the port and Credit Trading Area at which the product
was offloaded.
(5)(i) Any United States importer shall meet the requirements
specified in Sec. Sec. 80.510 and 80.520 and all other requirements of
subpart I, for any imported diesel fuel or heating oil that is not
classified as Certified DFR-Diesel under paragraph (o)(2) of this
section.
(ii) [Reserved]
(p) Truck Imports of Certified DFR-Diesel produced at a Foreign
Refinery. (1) Any refiner whose Certified DFR-Diesel is transported
into the United States by truck may petition EPA to use alternative
procedures to meet the following requirements:
(i) Certification under paragraph (d)(5) of this section;
(ii) Load port and port of entry sampling and testing under
paragraphs (f) and (g) of this section;
(iii) Attest under paragraph (h) of this section; and
(iv) Importer testing under paragraph (o)(3) of this section.
(2) These alternative procedures must ensure Certified DFR-Diesel
remains segregated from Non-Certified DFR-Diesel and from Non-DFR-
Diesel until it is imported into the United States. The petition will
be evaluated based on whether it adequately addresses the following:
(i) Provisions for monitoring pipeline shipments, if applicable,
from the refinery, that ensure segregation of Certified DFR-Diesel from
that refinery from all other diesel fuel;
(ii) Contracts with any terminals and/or pipelines that receive
and/or transport Certified DFR-Diesel, that prohibit the commingling of
Certified DFR-Diesel with any of the following:
(A) Other Certified DFR-Diesel from other refineries.
(B) All Non-Certified DFR-Diesel.
(C) All Non-DFR-Diesel.
(D) All diesel fuel or heating oil products required to be
segregated under subpart I.
(iii) Procedures for obtaining and reviewing truck loading records
and United States import documents for Certified DFR-Diesel to ensure
that such diesel fuel is only loaded into trucks making deliveries to
the United States;
(iv) Attest procedures to be conducted annually by an independent
third party that review loading records and import documents based on
volume reconciliation, or other criteria, to confirm that all Certified
DFR-Diesel remains segregated throughout the distribution system and is
only loaded into trucks for import into the United States.
(3) The petition required by this section must be submitted to EPA
along with the application for temporary refiner relief individual
refinery diesel sulfur standard under this subpart I and this section.
(q) Withdrawal or suspension of a foreign refinery's temporary
refinery flexibility program approval. EPA may withdraw or suspend a
diesel refiner baseline or standard approval for a foreign refinery
where:
(1) A foreign refiner fails to meet any requirement of this
section,
(2) A foreign government fails to allow EPA inspections as provided
in paragraph (i)(1) of this section;
(3) A foreign refiner asserts a claim of, or a right to claim,
sovereign immunity in an action to enforce the requirements in this
subpart; or
(4) A foreign refiner fails to pay a civil or criminal penalty that
is not satisfied using the foreign refiner bond specified in paragraph
(k) of this section.
(r) Early use of a foreign refiner motor vehicle diesel fuel
baseline. (1) A foreign refiner may begin using an individual refinery
motor vehicle diesel fuel baseline before EPA has approved the
baseline, provided that:
(i) A baseline petition has been submitted as required in paragraph
(b) of this section;
(ii) EPA has made a provisional finding that the baseline petition
is complete;
(iii) The foreign refiner has made the commitments required in
paragraph (i) of this section;
(iv) The persons who will meet the independent third party and
[[Page 28556]]
independent attest requirements for the foreign refinery have made the
commitments required in paragraphs (f)(3)(iii) and (h)(7)(iii) of this
section; and
(v) The foreign refiner has met the bond requirements of paragraph
(k) of this section.
(2) In any case where a foreign refiner uses an individual refinery
baseline before final approval under paragraph (r)(1) of this section,
and the foreign refinery baseline values that ultimately are approved
by EPA are more stringent than the early baseline values used by the
foreign refiner, the foreign refiner shall recalculate its compliance,
ab initio, using the baseline values approved by the EPA, and the
foreign refiner shall be liable for any resulting violation of the
motor vehicle highway diesel fuel requirements.
(s) Additional requirements for petitions, reports and
certificates. Any petition for approval to produce diesel fuel subject
to the diesel foreign refiner program, any alternative procedures under
paragraph (p) of this section, any report or other submission required
by paragraphs (c), (f)(2), or (i) of this section, and any
certification under paragraph (d)(3) of this section shall be:
(1) Submitted in accordance with procedures specified by the
Administrator, including use of any forms that may specified by the
Administrator.
(2) Be signed by the president or owner of the foreign refiner
company, or by that person's immediate designee, and shall contain the
following declaration:
``I hereby certify: (1) That I have actual authority to sign on
behalf of and to bind [insert name of foreign refiner] with regard to
all statements contained herein; (2) that I am aware that the
information contained herein is being certified, or submitted to the
United States Environmental Protection Agency, under the requirements
of 40 CFR part 80, subpart I, and that the information is material for
determining compliance under these regulations; and (3) that I have
read and understand the information being certified or submitted, and
this information is true, complete and correct to the best of my
knowledge and belief after I have taken reasonable and appropriate
steps to verify the accuracy thereof.
``I affirm that I have read and understand the provisions of 40 CFR
part 80, subpart I, including 40 CFR 80.620 apply to [insert name of
foreign refiner]. Pursuant to Clean Air Act section 113(c) and Title
18, U.S.C. 1001, the penalty for furnishing false, incomplete or
misleading information in this certification or submission is a fine of
up to $10,000 U.S., and/or imprisonment for up to five years.''.
PART 89--CONTROL OF EMISSIONS FROM NEW AND IN-USE NONROAD
COMPRESSION-IGNITION ENGINES
60. The authority citation for part 89 continues to read as
follows:
Authority: 42 U.S.C. 7521, 7522, 7523, 7524, 7525, 7541, 7542,
7543, 7545, 7547, 7549, 7550, and 7601(a).
61. Section 89.2 is amended by revising the definition of ``United
States'' to read as follows:
Sec. 89.2 Definitions.
* * * * *
United States means the States, the District of Columbia, the
Commonwealth of Puerto Rico, the Commonwealth of the Northern Mariana
Islands, Guam, American Samoa, and the U.S. Virgin Islands.
* * * * *
62. Section 89.112 is amended by revising the introductory text of
paragraph (f)(1) to read as follows:
Sec. 89.112 Oxides of nitrogen, carbon monoxide, hydrocarbon, and
particulate matter exhaust emission standards.
* * * * *
(f) * * *
(1) Voluntary standards. Engines may be designated ``Blue Sky
Series'' engines by meeting the voluntary standards listed in Table 3,
which apply to all certification and in-use testing, as follows:
* * * * *
63. Section 89.330 is amended by adding paragraph (e) to read as
follows:
Sec. 89.330 Lubricating oil and test fuels.
(e) Low sulfur test fuel. Upon request, for model years 2006 and/or
2007, the diesel test fuel shall be the diesel test fuel specified in
40 CFR 1065.205, with the following exception: The sulfur content must
be 300-500 ppm instead of 7-15 ppm, subject to the provisions of this
paragraph (e).
(1) To use this option, the manufacturer must:
(i) Ensure that ultimate purchasers of equipment using these
engines are informed that the use of fuel meeting the 500 ppm
specification is recommended.
(ii) Provide to equipment manufacturers labels to be applied at the
fuel inlet recommending 500 ppm fuel.
(2) None of the engines in the engine family may employ sulfur-
sensitive technologies.
(3) For engines at or above 130 kW, this option may be used in 2006
and 2007. For engines at or above 75 kW but less than 130 kW, this
option may only be used in 2007.
64. A new part 1039 is added to subchapter U of chapter I, to read
as follows:
SUBCHAPTER U--AIR POLLUTION CONTROLS
PART 1039--CONTROL OF EMISSIONS FROM NEW AND IN-USE NONROAD
COMPRESSION-IGNITION ENGINES
Subpart A--Overview and Applicability
Sec.
1039.1 Does this part apply for my engines?
1039.5 Which engines are excluded from this part's requirements?
1039.10 How is this part organized?
1039.15 Do any other regulation parts apply to me?
Subpart B--Emission Standards and Related Requirements
1039.101 What exhaust emission standards must my engines meet?
1039.102 What exhaust emission standards must my engines meet before
model year 2014?
1039.104 Are there interim provisions that apply only for a limited
time?
1039.105 What smoke standards must my engines meet?
1039.107 What evaporative emissions standards and requirements
apply?
1039.110 [Reserved]
1039.115 What other requirements must my engines meet?
1039.120 What emission-related warranty requirements apply to me?
1039.125 What maintenance instructions must I give to buyers?
1039.130 What installation instructions must I give to equipment
manufacturers?
1039.135 How must I label and identify the engines I produce?
Subpart C--Certifying Engine Families
1039.201 What are the general requirements for obtaining a
certificate of conformity?
1039.205 What must I include in my application?
1039.210 May I get preliminary approval before I complete my
application?
1039.220 How do I amend the maintenance instructions in my
application?
1039.235 What emission testing must I perform for my application for
a certificate of conformity?
1039.240 How do I demonstrate that my engine family complies with
exhaust emission standards?
1039.245 How do I determine deterioration factors from exhaust
durability testing?
1039.250 What records must I keep and what reports must I send to
EPA?
1039.255 What decisions may EPA make regarding my certificate of
conformity?
Subpart D--[Reserved]
Subpart E--In-use Testing
1039.401 General provisions.
[[Page 28557]]
Subpart F--Test Procedures
1039.501 How do I run a valid emission test?
1039.505 Which duty cycles do I use for steady-state testing?
1039.510 Which duty cycles do I use for transient testing?
1039.515 What are the test procedures related to not-to-exceed
standards?
1039.520 What testing must I perform to establish deterioration
factors?
1039.525 How do I adjust emission levels to account for infrequently
regenerating aftertreatment devices?
Subpart G--Special Compliance Provisions
1039.601 What compliance provisions apply to these engines?
1039.605 What provisions apply to engines already certified under
the motor-vehicle program?
1039.610 What provisions apply to vehicles already certified under
the motor-vehicle program?
1039.615 What special provisions apply to engines using
noncommercial fuels?
1039.620 What are the provisions for exempting engines used solely
for competition?
1039.625 What requirements apply under the program for equipment-
manufacturer flexibility?
1039.626 What special provisions apply to engines imported under the
equipment-manufacturer flexibility program?
1039.630 What are the hardship provisions for equipment
manufacturers?
1039.635 What are the hardship provisions for engine manufacturers?
1039.639 What special provisions apply to engines sold in Guam,
American Samoa, or the Commonwealth of the Northern Mariana Islands?
1039.645 What special provisions apply to engines used for
transportation refrigeration units?
Subpart H--Averaging, Banking, and Trading for Certification
1039.701 General provisions.
1039.705 How do I generate and calculate emission credits?
1039.710 How do I average?
1039.715 How do I bank emission credits?
1039.720 How do I trade emissions credits?
1039.725 What records must I keep?
1039.730 What must I include in my application for certification?
1039.732 What reports must I submit after the end of the model year?
1039.735 What restrictions apply for using credits?
1039.740 What can happen if I do not comply with the provisions of
this subpart?
Subpart I--Definitions and Other Reference Information
1039.801 What definitions apply to this part?
1039.805 What symbols, acronyms, and abbreviations does this part
use?
1039.810 What materials does this part reference?
1039.815 How should I request EPA to keep my information
confidential?
1039.820 How do I request a hearing?
Appendix I to Part 1039--Nonroad Compression-ignition (CI) Steady-
state Cycle for Constant-Speed Engines
Appendix II to Part 1039--[Reserved]
Appendix III to Part 1039--Nonroad Compression-ignition (CI) Steady-
state Cycle for Variable-Speed Engines with Maximum Power below 19
kW
Appendix IV to Part 1039--Nonroad Compression-ignition (CI) Steady-
state Cycle for Variable-Speed Engines with Maximum Power at or
above 19 kW
Appendix V to Part 1039--Nonroad Compression-ignition (CI) Transient
Cycle for Constant-Speed Engines
Authority: 42 U.S.C. 7401-7671(q).
Subpart A--Overview and Applicability
Sec. 1039.1 Does this part apply for my engines?
(a) The regulations in this part 1039 apply for all new,
compression-ignition nonroad engines (defined in Sec. 1039.801),
except as provided in Sec. 1039.5.
(b) In certain cases, the regulations in this part 1039 apply to
engines with maximum brake power at or above 250 kW that would
otherwise be covered by 40 CFR part 1048. See 40 CFR 1048.620 for
provisions related to this allowance.
(c) The definition of nonroad engine in 40 CFR 1068.30 excludes
certain engines used in stationary applications. These engines are not
required to comply with this part, but 40 CFR 1068.101 restricts the
use of stationary engines for non-stationary purposes and 40 CFR
1068.320 requires that you label imported engines that will be used in
stationary applications.
(d)(1) This part 1039 applies for all engines subject to the
emissions standards specified in subpart B of this part. See 40 CFR
part 89 for earlier model years.
(2) For the other compression-ignition engines that do not become
subject to the standards specified in subpart B of this part, this part
applies as follows:
(i) The provisions of Sec. 1039.1(c) and Sec. 1039.801 apply for
stationary engines beginning January 1, 2006.
(ii) The provisions of Sec. 1039.620 and Sec. 1039.801 apply for
engines used solely for competition beginning January 1, 2006.
Sec. 1039.5 Which engines are excluded from this part's requirements?
(a) This part does not apply to the following nonroad engines:
(1) Locomotive engines. Locomotive engines subject to the standards
of 40 CFR part 92 are not subject to the provisions of this part 1039.
Locomotive engines that are not subject to the standards of 40 CFR part
92 because they have been exempted by provisions of 40 CFR part 92,
other than those contained in 40 CFR 92.907, are also not subject to
the provisions of this part 1039. See the provisions of 40 CFR part 92
to determine which engines are subject to the standards of that part
92.
(2) Marine engines. Marine engines subject to the standards of 40
CFR part 94 are not subject to the provisions of this part 1039. Marine
engines that are not subject to the standards of 40 CFR part 94 because
they have been exempted by provisions of 40 CFR part 94, other than
those contained in 40 CFR 94.907, are also not subject to the
provisions of this part 1039. See the provisions of 40 CFR part 94 to
determine which engines are subject to the standards of that part 94.
(3) Mining engines. Engines used in underground mining or in
underground mining equipment and regulated by the Mining Safety and
Health Administration (MSHA) in 30 CFR parts 7, 31, 32, 36, 56, 57, 70,
and 75 are not subject to the provisions of this part 1039.
(4) Hobby engines. Engines with per-cylinder displacement of less
than 50 cc are not subject to the provisions of this part 1039.
(b) Aircraft engines are not subject to the provisions of this part
1039. See 40 CFR part 87 for engines used in aircraft.
Sec. 1039.10 How is this part organized?
The regulations in this part 1039 contain provisions that affect
both engine manufacturers and others. However, the requirements of this
part are generally addressed to the engine manufacturer. Unless we
specifically state otherwise, the term ``you'' means the engine
manufacturer, as defined in Sec. 89.801. This part 1039 is divided
into the following subparts:
(a) Subpart B of this part describes the emission standards and
other requirements that must be met to certify engines under this part.
Note that Sec. 1039.104 discusses certain interim requirements and
compliance provisions that apply only for a limited time.
(b) Subpart C of this part describes how to apply for a certificate
of conformity.
(c) Subpart F of this part describes how to test your engines
(including references to other parts of the Code of Federal
Regulations).
(d) Subpart G of this part and 40 CFR part 1068 describe
requirements, prohibitions, and other provisions that apply to engine
manufacturers, equipment manufacturers, owners, operators, rebuilders,
and all others.
(e) Subpart H of this part describes how engine manufacturers may
generate
[[Page 28558]]
and use emission credits to certify their engines.
Sec. 1039.15 Do any other regulation parts apply to me?
(a) Part 1065 of this chapter describes procedures and equipment
specifications for testing engines. Subpart F of this part describes
how to apply the provisions of part 1065 of this chapter to show your
engines meet the emission standards in this part.
(b) The requirements and prohibitions of part 1068 of this chapter
apply to everyone, including anyone who manufactures, imports,
installs, owns, operates, or rebuilds any of the engines subject to
this part 1039, or equipment containing these engines. Part 1068 of
this chapter describes general provisions, including these seven areas:
(1) Prohibited acts and penalties for engine manufacturers,
equipment manufacturers, and others.
(2) Rebuilding and other aftermarket changes.
(3) Exclusions and exemption for certain engines.
(4) Importing engines.
(5) Selective enforcement audits of your production.
(6) Defect reporting and recall.
(7) Procedures for hearings.
(c) Other parts of this chapter apply if referenced in this part.
Subpart B--Emission Standards and Related Requirements
Sec. 1039.101 What exhaust emission standards must my engines meet?
The exhaust emission standards of this section apply for the model
years noted and later. See Sec. 1039.102 and 40 CFR 89.112 for exhaust
emission standards that apply to earlier model years.
(a) Emission standards for transient testing. Transient exhaust
emissions from your engines may not exceed the applicable emission
standards listed in Table 1 of this section. Measure emissions using
the applicable transient test procedures described in subpart F of this
part.
(b) Emission standards for steady-state testing. Steady-state
exhaust emissions from your engines may not exceed the applicable
emission standards listed in Table 1 of this section. Measure emissions
using the applicable steady-state test procedures described in subpart
F of this part.
Table 1 of Sec. 1039.101.--Tier 4 Exhaust Emissions Standards
----------------------------------------------------------------------------------------------------------------
Emissions standard g/kW-hr
Engine power Model year -----------------------------------------------------------
PM NOX NMHC NOX+NMHC CO
----------------------------------------------------------------------------------------------------------------
kW < 19 \1\............................. 2008 \2\ 0.40 .......... .......... 7.5 6.6
19 <= kW < 56........................... 2013 0.03 .......... .......... 4.7 5.0
56 <= kW < 130.......................... 2014 0.02 0.40 0.19 .......... 5.0
130 <= kW <= 560........................ 2014 0.02 0.40 0.19 .......... 3.5
kW 560...................... 2014 0.02 0.40 0.19 .......... 3.5
----------------------------------------------------------------------------------------------------------------
\1\ Paragraph (a) of this section does not apply for engines under 19 kW until model year 2013.
\2\ See paragraph (j) of this section for provisions related to an optional PM standard for engines under 8 kW.
(c) Averaging banking and trading. In lieu of the NOX,
NOX+NMHC, or PM standards in Table 1 of this section, you
may choose to include an engine family in the averaging, banking, and
trading (ABT) program provided in subpart H of this part. This requires
that you specify a single family emission limit (FEL) for each
pollutant for each engine family included in the ABT program. These
FELs are the applicable emission standards for the engine family with
respect to both transient testing and steady-state testing under
paragraphs (a) and (b) of this section. The FELs will also define the
NTE standards for your engine family, as specified in paragraph (d) of
this section. The FEL may not be higher than the limits in Table 2 of
this section, except as allowed by paragraph (i) of this section.
Table 2 of Sec. 1039.101.--Tier 4 FEL Caps
----------------------------------------------------------------------------------------------------------------
Emission g/kW-hr
Engine power -----------------------------------------------
PM NOX NOX+NMHC
----------------------------------------------------------------------------------------------------------------
kW < 8.......................................................... 0.80 .............. 10.5
8 <= kW < 19.................................................... 0.80 .............. 9.5
19 <= kW < 56................................................... 0.05 .............. 7.5
56 <= kW < 130.................................................. 0.04 0.80 ..............
130 <= kW < 560................................................. 0.04 0.80 ..............
kW = 560............................................. 0.04 0.80 ..............
----------------------------------------------------------------------------------------------------------------
(d) Not-to-exceed standards. (1) Exhaust emissions from the engine
may not exceed the applicable NTE standards. Measure emissions
according to the procedures specified Sec. 1039.515.
(2) The NTE standard, rounded to the same number of decimal places
as the applicable standard in Table 1 of this section, is determined
from the following equation:
NTE standard for each pollutant = (STD) x (M)
Where:
(i) STD = The standard specified for that pollutant in Table 1 of
this section if you certify without using ABT for that pollutant, or
the FEL for that pollutant if you certify using ABT.
(ii) M = The NTE multiplier for that pollutant, as defined in
paragraph (d)(3) of this section.
(3) The NTE multiplier for each pollutant equals 1.25, except in
the following cases:
[[Page 28559]]
Table 3 of Sec. 1039.101
------------------------------------------------------------------------
If . . . or . . . then . . .
------------------------------------------------------------------------
(i)The engine family is The engine famiily The multipliers for
certified to a NOX standard is certified to a NMHC, NOX and/or
less than 2.00 g/k-W-hr NOX FEL less than NOX + NMHC are
without using ABT. 2.00 g/kW-hr (or an 1.50.
NOX +NMHC Fell less
than 2.20 g/kW-hr).
(ii) The engine family is The engine family is The multiplier for
certified to a PM standard certified to a PM PM is 1.50
less than 0.07 g/kw-hr FEL less than 0.07
without using ABT. g.kw-hr.
------------------------------------------------------------------------
(4) (i) There are two sets of specifications of ambient operating
regions that apply for NTE testing. You must choose one set for each
engine family. You may choose separately for each engine family. You
must indicate your choice of ambient operating region in your
application for certification. The region that you choose will apply
for all NTE testing of engines in your engine family. You must choose
one of the following two ambient operating regions:
(A) All altitudes less than or equal to 5,500 feet above sea level,
during all ambient conditions (temperature and humidity).
(B) All altitudes less than or equal to 5,500 feet above sea level,
for temperatures less than or equal to the temperature determined by
the following equation at the specified altitude;
T = -0.00254 x A + 100
Where:
T = ambient air temperature in degrees Fahrenheit.
A = altitude in feet above sea level (A is negative for altitudes
below sea level).
(ii) Temperature and humidity ranges for which correction factors
are allowed are specified in 40 CFR 86.1370-2007(e).
(A) If you choose the ambient operating region specified in
paragraph (c)(4)(i)(A) of this section, then the temperature and
humidity ranges for which correction factors are allowed are defined
under 40 CFR 86.1370-2007(e)(1).
(B) If you choose the ambient operating region specified in
paragraph (c)(4)(i)(B) of this section, then the temperature and
humidity ranges for which correction factors are allowed are defined
under 40 CFR 86.1370-2007(e)(2).
(5) For engines equipped with exhaust-gas recirculation, the NTE
emission limits of this section do not apply during cold operating
conditions as specified in 40 CFR 86.1370-2007(f).
(6) For engines certified to an FEL less than 0.01 g/kW-hr PM, the
PM NTE is 0.02 g/kW-hr.
(e) [Reserved]
(f) Fuel types. The exhaust emission standards in this section
apply for engines using each type of fuel on which the engines in the
engine family are designed to operate. You must meet the numerical
emission standards for NMHC in this section based on the following
types of hydrocarbon emissions for engines powered by the following
fuels:
(1) Diesel-fueled engines: NMHC emissions.
(2) Natural gas-fueled engines: NMHC emissions.
(3) Alcohol-fueled engines: THCE emissions.
(g) Useful life. (1) Your engines must meet the exhaust emission
standards in paragraphs (a) through (d) of this section over their full
useful life. The useful life values are shown in the following table:
Table 4 of Sec. 1039.101
----------------------------------------------------------------------------------------------------------------
And its maximum power And its rated speed is Then its useful life is
If your engine is certified as . . . is . . . . . . . . .
----------------------------------------------------------------------------------------------------------------
Variable speed or constant speed..... Less than 19 kW........ Any speed.............. 3,000 hours or five
years, whichever comes
first.
Constant speed....................... At least 19 kW, but 3,000 rpm or higher.... 3,000 hours or five
less than 37 kW. years, whichever comes
first.
Constant speed....................... At least 19 kW, but Less than 3,000 rpm.... 5,000 hours or seven
less than 37 kW. years, whichever comes
first
Variable speed....................... At least 19 kW, but Any speed.............. 5,000 hours or seven
less than 37 kW. years, whichever comes
first.
Variable speed or constant speed..... 37kW or higher......... Any speed.............. 8,000 hours or ten
years, whichever comes
first
----------------------------------------------------------------------------------------------------------------
(2) You may request in your application for certification that we
approve a shorter useful life for an engine family. We may approve a
shorter useful life if we determine that these engines will rarely
operate longer than the alternate useful life. Your demonstration must
include documentation from in-use engines. Your demonstration must also
include any overhaul interval that you recommend and any mechanical
warranty that you offer for the engine.
(h) Applicability for testing. The emission standards in this
subpart apply to all testing, including certification, selective
enforcement audits and in-use testing.
(i) Alternate FEL caps. You are allowed to certify a limited number
of engines to FELs higher than the caps listed in Table 2 of this
section. The FEL caps shown in Table 5 of this section apply instead of
the otherwise applicable FEL caps, subject to the sales limits listed
in the table.
[[Page 28560]]
Table 5 of Sec. 1039.101.--Alternate FEL Caps
----------------------------------------------------------------------------------------------------------------
Maximum
percentage of
production
that may be NOX FEL cap (g/kW- PM FEL cap (g/kW-
Power category Model years certified to hr) hr)
using these
alternate FEL
caps
----------------------------------------------------------------------------------------------------------------
19 <= kW < 56................ 2013-2016 10 Not applicable...... 0.30
2017+ 5
56 <= kW <130................ 2012-2013 10 Not applicable...... 0.40 for hp <75
2014-2015 10 4.4 for kW <75...... 0.30 for hp =75
2016+ 5 3.8 for kW =75 2014-2015.
130 <= kW <= 560............. 2011-2013 10 Not applicable...... 0.20
2014 10 3.8.................
2015+ 5
kW 560........... 2014-2017 10 6.2................. 0.20
2018+ 5
----------------------------------------------------------------------------------------------------------------
(j) Optional PM standard for engines under 8 kW. You may certify
certain engines under 8 kW to the optional Tier 4 PM standard of 0.60
g/kW-hr, instead of the PM standard listed in Table 1 of this section,
as described in this paragraph.
(1) The provisions of this paragraph (j) are available only for
engines with maximum engine power under 8 kW that are hand-startable,
air-cooled, and direct injection. The term hand-startable generally
refers to engines that are started using a hand crank or pull cord.
(2) Engines certified under paragraphs (j)(3)(i) or (ii) may not be
used to generate positive emission credits under the ABT provisions of
subpart H of this part.
(3)(i) The applicable standard for model years 2008 and 2009 under
this paragraph (j) is 0.80 g/kW-hr.
(ii) Starting with model year 2010 standard under this paragraph
(j) is 0.60 g/kW-hr standard.
(4) The FEL cap for engines certified under this paragraph (j) is
0.80 g/kW-hr.
Sec. 1039.102 What exhaust emission standards must my engines meet
before model year 2014?
The exhaust emission standards of this section apply for the model
years specified in Tables 1 through 6 of this section. See Sec.
1039.101 for exhaust emission standards that apply to later model
years. See 40 CFR 89.112 for exhaust emission standards that apply to
model years before those listed in the tables.
(a) Emission standards for transient testing. Transient exhaust
emissions from your engines may not exceed the applicable emission
standards in Tables 1 through 6 of this section. Measure emissions
using the applicable transient test procedures described in subpart F
of this part. The transient standards do not apply for the following
cases:
(1) Engines less than or equal to 37 kW in model years before 2013.
(2) Phase-out engines over 560 kW that are certified using the
carry-over provisions of Sec. 1039.235(d).
(b) Emission standards for steady-state testing. Steady-state
exhaust emissions from your engines may not exceed the applicable
emission standards listed in Tables 1 through 6 of this section.
Measure emissions using the applicable steady-state test procedures
described in subpart F of this part.
Table 1 of Sec. 1039.102--Interim Tier 4 Exhaust Emissions Standards for Engines 19<=kW<37
----------------------------------------------------------------------------------------------------------------
Emissions standard g/kW-hr
Model years --------------------------------------------------
PM NOX+NMHC CO
----------------------------------------------------------------------------------------------------------------
2008-2012.................................................... 0.30 7.5 5.0
----------------------------------------------------------------------------------------------------------------
Table 2 of Sec. 1039.102.--Interim Tier 4 Exhaust Emissions Standards for Engines 37<=kW<56
----------------------------------------------------------------------------------------------------------------
Emissions standard g/kW-hr
Model years -----------------------------------------------
PM NOX+NMHC CO
----------------------------------------------------------------------------------------------------------------
Option No. 1..................... 2008-2012.................... 0.30 4.7 5.0
Option No. 2..................... 2012 (optional).............. 0.03 4.7 5.0
----------------------------------------------------------------------------------------------------------------
[[Page 28561]]
Table 3 of Sec. 1039.102.--Interim Tier 4 Exhaust Emissions Standards for Engines 56kW<75
----------------------------------------------------------------------------------------------------------------
Emissions standard g/kW-hr
Model years Phase-in option ----------------------------------------------------------------
PM NOX NMHC NOX+NMHC CO
----------------------------------------------------------------------------------------------------------------
2012-2013 Phase-in................ 0.02 0.40 0.19 ........... 5.0
Phase-out (No more than 0.02 ........... ........... 4.7 5.0
50%).
----------------------------------------------------------------------------------------------------------------
Table 4 of Sec. 1039.102.--Interim Tier 4 Exhaust Emissions Standards for Engines 75<=kW<130
----------------------------------------------------------------------------------------------------------------
Emissions standard g/kW-hr
Model years Phase-in option ----------------------------------------------------------------
PM NOX NMHC NOX+NMHC CO
----------------------------------------------------------------------------------------------------------------
2012-2013 Phase-in................ 0.02 0.40 0.19 ........... 5.0
Phase-out (No more than 0.02 ........... ........... 4.0 5.0
50%).
----------------------------------------------------------------------------------------------------------------
Table 5 of Sec. 1039.102.--Interim Tier 4 Exhaust Emissions Standards for Engines 130<=kW<=560
----------------------------------------------------------------------------------------------------------------
Emissions standard g/kW-hr
Model years Phase-in option ----------------------------------------------------------------
PM NOX NMHC NOX+NMHC CO
----------------------------------------------------------------------------------------------------------------
2012-2013 Phase-in................ 0.02 0.40 0.19 ........... 3.5
Phase-out (No more than 0.02 ........... ........... 4.0 3.5
50%).
----------------------------------------------------------------------------------------------------------------
Table 6 of Sec. 1039.102.--Interim Tier 4 Exhaust Emissions Standards for Engines kW560
----------------------------------------------------------------------------------------------------------------
Emissions standard g/kW-hr
Model years Phase-in option ----------------------------------------------------------------
PM NOX NMHC NOX+NMHC CO
----------------------------------------------------------------------------------------------------------------
2012-2013 Phase-in................ 0.02 0.40 0.19 ........... 3.5
Phase-out (No more than 0.02 ........... ........... 6.4 3.5
50%).
----------------------------------------------------------------------------------------------------------------
(c) Phase-in option. The following phase-in provisions apply for
engines with maximum engine power of 56 kW or higher.
(1) For model years noted in Tables 3 through 6 of this section,
you may certify some of your engine families to the combined
NOX+NMHC standard specified in the phase-in option instead
of to the separate NOX and NMHC standards otherwise
specified in the applicable table.
(2) For engines with maximum engine power over 560 kW for the model
years noted in Table 6 of this section, you may certify some of your
engine families to the PM standard specified in the phase-in option
instead of to the PM standard otherwise specified in the applicable
table. Engines certified to the phase-out standards in Table 6 of this
section that are not naturally aspirated are not required to meet the
crankcase emission standard in 1039.115(a).
(3) Engines certified to the phase-out standards in Tables 3
through 5 must comply with all other requirements applicable to Tier 4
engines, except as specified in paragraph (d) of this section.
(4) The combined number of engines in the engine families certified
to phase-out standards may not exceed 50 percent of your U.S.-directed
production volume of nonroad CI engines for that power category for any
model year, except as explicitly allowed by Sec. 1039.104(c).
(d) Other provisions. The provisions of Sec. 1039.101 (c) through
(i) apply with respect to the standards of this section with the
following exceptions:
(1) NTE standards. NTE standards are determined relative to the
standards listed in Tables 1 through 7 of this section, instead of the
standards listed in Table 1 of Sec. 1039.101. There are no NTE
standards for the optional phase-out standards specified in Table 6 of
this section for engines over 560 kW that are certified using the
carry-over provisions of Sec. 1039.235(d).
(2) The FEL caps listed in Tables 7 and 8 of this section apply
instead of the FEL caps in Table 2 of Sec. 1039.101.
Table 7 of Sec. 1039.102.--Interim Tier 4 FEL Caps for Engines With
Maximum Engine Power Less than 56 kW and Phase-in Engines With Maximum
Engine Power Greater than or Equal to 56 kW
------------------------------------------------------------------------
Emission g/kW-hr
Engine power ---------------------------------------
PM NOX NOX+NMHC
------------------------------------------------------------------------
19 <= kW < 37................... 0.60 ........... 9.5
37 <= kW < 56................... 0.40 ........... 7.5
[[Page 28562]]
56 <= kW < 75................... 0.040 4.4 ...........
75 <= kW <= 560................. 0.040 3.7 ...........
kW 560.............. 0.20 6.1 ...........
------------------------------------------------------------------------
Table 8 of Sec. 1039.102.--Interim Tier 4 FEL Caps for Phase-Out
Engines
------------------------------------------------------------------------
Emission g/kW-hr
Engine power --------------------------
PM NOX+NMHC
------------------------------------------------------------------------
56 <= kW < 75................................ 0.040 7.5
75 <= kW < 225............................... 0.040 6.6
225 <= kW < 560.............................. 0.040 6.4
kW = 560.......................... 0.54 10.5
------------------------------------------------------------------------
(e) Banked credits for 56 < kW < 130 engines. The provisions of
this paragraph apply for model year 2012-2014 engines with maximum
engine power at least 56 kW, but less than 130 kW.
(1) You may use under subpart H of this part banked Tier 2
NOX + NMHC credits generated from engines rated at least 37
kW.
(2) If you optionally forego during model years 2012-2014 the use
banked Tier 2 credits allowed by paragraph (e)(1) of this section, you
may certify your 56 <= kW < 130 engines according to the alternate
phase-in schedule described in this paragraph (e)(2). You may not bank
or trade any credits generated from engines certified under this
paragraph (e)(2).
Table 9 of Sec. 1039.102.--Alternate Phase-In Schedule for 56<=kW<130
Engines
------------------------------------------------------------------------
Minimum
Model year phase-in
percentage
------------------------------------------------------------------------
2012....................................................... 25
2013....................................................... 25
2014:
First nine months........................................ 25
Last three months........................................ 100
2015 and later............................................. 100
------------------------------------------------------------------------
Sec. 1039.104 Are there interim provisions that apply only for a
limited time?
The provisions in this section apply instead of other provisions in
this part. This section describes the model years for these interim
provisions apply.
(a) Split Families. For the purpose of using or generating credits
during the phase-in of Tier 4 standards, you may choose to split an
engine family into two subfamilies (for example, one that uses credits
and one that generates credits).
(1) You must indicate in the application for certification that the
engine family is to be split, and may assign the numbers and
configurations of engines within the respective subfamilies at any time
prior to the submission of the end-of-year report. This option is not
available for engine families under 56 kW.
(2) You may exclude the engines within the split family from end-
of-year NOX (or NOX + NMHC) ABT calculations,
provided that the family meets the standards of this paragraph (a)(2)
and neither subfamily generates credits for use by other engine
families, or uses banked credits, or uses averaging credits from other
engine families. All the engines in the split family must be excluded
from the phase-in calculations (both from the number of engines
complying with the Tier 4 emission standards being phased-in and from
the total number of engines in the U.S.-directed production volume).
The engines must comply with all other applicable requirements of this
part.
(i) Label all the engines within the family with a single
NOX FEL, as listed in the following table:
------------------------------------------------------------------------
Then the NOX
FEL for the
If the engine family's maximum-power range is . . . entire family
is . . .
------------------------------------------------------------------------
(A) At least 56 kW, but less than 130 kW................ 2.3 g/kW-hr.
(B) At least 130 but less than 560 kW................... 2.0 g/kW-hr.
(C) 560 kW or higher.................................... 3.1 g/kW-hr.
------------------------------------------------------------------------
(ii) For split families with maximum engine power over 560 kW, your
PM FEL is 0.10 g/kW-hr.
(iii) For engines certified under the alternate phase-in schedule
of Sec. 1039.102(e)(2), the NOX FEL is 3.3 g/kW-hr.
(3) Your engines must comply with all other standards and
requirements applicable to Tier 4 engines.
(b) Incentives for early introduction. You may reduce the number of
engines that are required to meet the standards in Sec. Sec.
1039.101or 1039.102 by certifying engines to the applicable standards
in Sec. 1039.101 (without using the provisions of subpart H of this
part) before the model year otherwise required (either by Sec. Sec.
1039.101 or 1039.102. This option begins in model year 2008.
(1) For engines with maximum engine power at 56 kW or higher:
----------------------------------------------------------------------------------------------------------------
You may reduce the
number of engines in
the same power
If you certify . . . To the . . . category that are In later model years by . . .
required to meet the
. . .
----------------------------------------------------------------------------------------------------------------
Two engines...................... 0.020 g/kW-hr PM 0.020 g/kW-hr PM Three engines.
standard. standard.
[[Page 28563]]
Two engines...................... 0.020 g/kW-hr PM 0.020 g/kW-hr PM Three engines.
standard, the 0.40 standard, the 0.40
g/kW-hr NOX g/kW-hr NOX
standard, and the standard, and the
0.19 g/kW-hr NMHC 0.19 g/kW-hr NMHC
standard. standard.
One engine....................... 0.020 g/kW-hr PM 0.020 g/kW-hr PM Two engines.
standard, the 0.20 standard, the 0.40
g/kW-hr NOX g/kW-hr NOX
standard, and the standard, and the
0.19 g/kW-hr NMHC 0.19 g/kW-hr NMHC
standard. standard.
----------------------------------------------------------------------------------------------------------------
(2) For engines with maximum power less than 56 kW:
----------------------------------------------------------------------------------------------------------------
You may reduce the
number of engines in
any family with
If you certify . . . To a . . . maximum power In later model years by . . .
between 19 and 56 kW
that are required to
meet the . . .
----------------------------------------------------------------------------------------------------------------
Two engines...................... 0.034 g/kW-hr PM 0.034 g/kW-hr PM Three engines.
standard. standard.
----------------------------------------------------------------------------------------------------------------
(3) Example: If you produce 100 56-130 kW engines in 2008 that meet
all of the applicable the standards listed in Sec. 1039.101, and you
produced 10,000 56-130 kW engines in 2012, then only 9,850 of the
engines would need to comply with the standards listed in Sec.
1039.101 in 2012.
(c) Phase-in projections. You may initially base compliance with
the phase-in requirements of Sec. 1039.102 on projected U.S.-directed
production volumes. This is allowed for all phase-in model years,
except the last year in which less than 100 percent compliance is
required. However, if your actual U.S.-directed production volume of
engines that comply with the Tier 4 standards is less than the required
amount, you must make up the shortfall (in terms of number of engines)
before the end of the phase-in period. For example, if you plan in good
faith to produce 50 percent of your projected 10,000 56-130kW engines
(i.e., 5,000 engines) in 2012 in compliance with the Tier 4
NOX and NMHC standards, but are only able to produce 4,500
such engines of an actual 10,000 engines, you would need to produce an
extra 500 engines in 2013 in compliance with the Tier 4 NOX
and NMHC standards.
(1) For phase-in schedules other than the alternate schedule
described in Table 9 of Sec. 1039.102, the deficit allowed by this
paragraph (f) may not exceed 25 percent of your U.S. directed
production volume.
(2) For the phase-in schedule described in Table 9 of Sec.
1039.102, the deficit allowed by this paragraph (f) may not exceed 5
percent of your U.S. directed production volume.
(d) In-use compliance levels. (1) For purposes of determining
compliance after title or custody has transferred to the ultimate
purchaser, for model year 2015 or earlier engines having a
NOX FEL no higher than 2.0 g/kW-hr, the applicable
NOX compliance limit shall be determined by adding the
following adjustment to the otherwise applicable standard or FEL for
NOX.
------------------------------------------------------------------------
If your engine's
In model years . . . maximum power is . . The NOX adjustment
. in g/kW-hr is . . .
------------------------------------------------------------------------
2012-2015................... 56 <= kW < 130...... 0.13 for operating
hours <= 4000.
0.27 for operating
hours
4000.
2011-2015................... kW = 130. 0.13 for operating
hours <= 4000.
0.27 for operating
hours
4000.
------------------------------------------------------------------------
(2) For model years before 2014 for engines with maximum power less
than 56 kW, and model years before 2015 for engines with maximum power
at 56 kW or higher, for purposes of determining compliance after title
or custody has transferred to the ultimate purchaser, the applicable PM
compliance limit shall be determined by adding 0.01 g/kW-hr to the
otherwise applicable standard or FEL for PM.
(e) Provisions for small-volume manufacturers. Special provisions
apply to you if you are a small-volume engine manufacturer subject to
the requirements of this part. You must contact us before 2008 if you
intend to use these provisions.
(1) You may delay complying with the following otherwise applicable
Tier 4 emission standards for three model years:
(i) PM standard for engines with maximum power less than 19 kW.
(ii) NMHC + NOX standard for engines with maximum power
at least 19 kW but less than 37 kW.
(iii) NMHC + NOX and PM standards for engines with
maximum power at least 56 kW but less than 130 kW.
(2) For engines with maximum power at least 19 kW but less than 56
kW, if you choose to meet the interim PM standard in Sec. 1039.102 by
model year 2011 (without using PM credits), you may delay complying
with the Tier 4 PM standard in Sec. 1039.101 for engines with maximum
power at least 19 kW but less than 56 kW for three model years.
(f) Deficiencies for NTE emission standards. (1) For the first
three model years during which Tier 4 standards apply for your engines,
you may ask us to accept an engine as compliant with the NTE standards
even though specific requirements are not fully met. We will grant such
deficiencies (i.e., compliance without meeting specific requirements)
only if compliance would be infeasible or unreasonable considering such
factors as, but not limited to: technical feasibility of the given
hardware and lead time and production cycles, including phase-in or
phase-out of engines or vehicle designs and programmed upgrades of
computers. We will approve deficiencies on an engine-model and/or
horsepower-rating basis within an engine family, and each approval is
applicable for a single model
[[Page 28564]]
year. Your request must include a description of the auxiliary emission
control device(s) which will be used to maintain emissions to the
lowest practical level, considering the deficiency being requested, if
applicable. An application for a deficiency must be made during the
certification process; no deficiency will be granted to retroactively
cover engines already certified.
(2) For the next four model years after the period covered by
paragraph (f)(1) of this section, we may allow up to three deficiencies
per engine family. The provisions of paragraphs (f)(1) of this section
apply for deficiencies allowed by this paragraph (f)(2). In determining
whether to allow the additional deficiencies, we may consider any
relevant factors, including the factors identified in paragraph (f)(1)
of this section. If we approve additional deficiencies, we may set any
additional conditions that we determine to be appropriate.
(3) Unmet requirements should not be carried over from the previous
model year, except where unreasonable hardware or software
modifications would be necessary to correct the deficiency, and we
determine that you have demonstrated an acceptable level of effort
toward compliance. The NTE deficiency should only be seen as an
allowance for minor deviations from the NTE requirements. The NTE
deficiency provisions allow you to apply for relief from the NTE
emission requirements under limited conditions. We expect that you
should have the necessary functioning emission-control hardware in
place to comply with the NTE standards.
(g) Test fuels. The diesel test fuel for model years 2008 through
2010 is the diesel test fuel specified in 40 CFR 1065.205, with the
following exception: the sulfur content must be 300-500 ppm instead of
7-15 ppm. This paragraph (g) also allows the early use of 7-15 ppm
sulfur test fuels in certain cases.
(1) For model years 2008 through 2010, you may use the 7-15 ppm
sulfur test fuel for any engine family where you can demonstrate that
the engines in the family will operate only on fuel with less than 15
ppm sulfur in-use.
(2) For model years 2008 through 2010, you may use the 7-15 ppm
sulfur test fuel for any engine family containing only engines with
maximum engine power less than 56 kW, provided:
(i) You ensure that ultimate purchasers of equipment using these
engines are informed that the use of fuel meeting the 15 ppm
specification is recommended.
(ii) You provide along with your installation instructions to
equipment manufacturers labels to be applied at the fuel inlet
recommending 15 ppm fuel. This labeling requirement applies instead of
the requirement in Sec. 1039.135(f).
(iii) None of the engines in your engine family employ sulfur-
sensitive technologies.
(4) For engines certified under Sec. 1039.101(j) in model year
2010, the diesel test fuel is the diesel test fuel specified in 40 CFR
1065.205.
(h) Requirements for equipment manufacturers. The provisions of
this paragraph (h) apply to equipment manufacturers that use engines
certified to the Tier 3 standards under Option 2 of Table 2 of
Sec. 1039.102 in any model year from 2008 to 2011. For model year
2012, you must use engines certified under Option 2 of Table 2
of Sec. 1039.102 in any product for which you previously used an
engine certified to the Tier 3 standards under Option 2 of
Table 2 of Sec. 1039.102. Use of an engine in model year 2012 that was
certified under Option 1 of Table 2 of Sec. 1039.102 in such
equipment would be a violation of Sec. 1068.101(a)(1).
Sec. 1039.105 What smoke standards must my engines meet?
Your engines must have less than 22 percent opacity when measured
with the smoke test procedure in Sec. 1039.501 throughout its useful
life.
Sec. 1039.107 What evaporative emissions standards and requirements
apply?
There are no evaporative emission standards for diesel-fueled
engines, or engines using other nonvolatile or nonliquid fuels (for
example, natural gas). If your engine uses a volatile liquid fuel, such
as methanol, you must meet the evaporative emission requirements of 40
CFR part 1048 that apply to spark-ignition engines, as follows:
(a) Follow the steps in 40 CFR 1048.245 to show that you meet the
requirements of 40 CFR 1048.105.
(b) Do the following things in your application for certification:
(1) Describe how your engines control evaporative emissions.
(2) Present test data to show your vehicles meet the evaporative
emission standards we specify in subpart B of this part if you do not
use design-based certification under 40 CFR 1048.245. Show these
figures before and after applying deterioration factors, where
applicable.
Sec. 1039.110 [Reserved]
Sec. 1039.115 What other requirements must my engines meet?
Your engines must meet the following requirements:
(a) Crankcase emissions. Crankcase emissions may not be discharged
directly into the ambient atmosphere from any engine, except as
follows:
(1) Engines equipped with turbochargers, pumps, blowers, or
superchargers for air induction may discharge crankcase emissions to
the ambient atmosphere if the emissions are added to the exhaust
emissions (either physically or mathematically) during all emission
testing.
(2) If you take advantage of this exception, you must:
(i) Manufacture the engines so that all crankcase emission can be
routed into the applicable sampling systems specified in 40 CFR part
1065.
(ii) Account for deterioration in crankcase emissions when
determining exhaust deterioration factors.
(3) For the purpose of this paragraph (a), crankcase emissions that
are routed to the exhaust upstream of exhaust aftertreatment during all
operation are not considered to be ``discharged directly into the
ambient atmosphere.''
(b)-(d) [Reserved]
(e) Adjustable parameters. Engines that have adjustable parameters
must meet all the requirements of this part for any adjustment in the
physically adjustable range. An operating parameter is not considered
adjustable if you permanently seal it or if it is not normally
accessible using ordinary tools. We may require that you set adjustable
parameters to any specification within the adjustable range during any
testing, including certification testing, selective enforcement
auditing, or in-use testing.
(f) Prohibited controls. You may not design your engines with
emission-control devices, systems, or elements of design that cause or
contribute to an unreasonable risk to public health, welfare, or safety
while operating. For example, this would apply if the engine emits a
noxious or toxic substance it would otherwise not emit that contributes
to such an unreasonable risk.
(g) Defeat devices. You may not equip your engines with a defeat
device. A defeat device is an auxiliary emission control device that
reduces the effectiveness of emission controls under conditions that
the engine may reasonably be expected to encounter during normal
operation and use. This does not apply to auxiliary emission control
devices you identify in your
[[Page 28565]]
certification application if any of the following is true:
(1) The conditions of concern were substantially included in the
applicable test procedures described in subpart F of this part.
(2) You show your design is necessary to prevent engine (or
equipment) damage or accidents.
(3) The reduced effectiveness applies only to starting the engine.
Sec. 1039.120 What emission-related warranty requirements apply to
me?
(a) General requirements. You must warrant to the ultimate
purchaser and each subsequent purchaser that the new nonroad engine,
including all parts of its emission-control system, meets two
conditions:
(1) It is designed, built, and equipped so it conforms at the time
of sale to the ultimate purchaser with the requirements of this part.
(2) It is free from defects in materials and workmanship that may
keep it from meeting these requirements.
(b) Warranty period. Your emission-related warranty must be valid
for at least as long as the minimum warranty periods listed in this
paragraph (b) in hours of operation and years, whichever comes first.
You may offer an emission-related warranty more generous than we
require. The emission-related warranty for the engine may not be
shorter than any published warranty you offer for the engine. If you
provide a longer warranty (with or without charge) for any components
covered in paragraph (c) of this section, you must also extend the
emission-related warranty to the same degree for the same components.
If an engine has no hour meter, we base the warranty periods in this
paragraph (b) only on the engine's age (in years). The minimum warranty
periods are shown in the following table:
----------------------------------------------------------------------------------------------------------------
And its maximum power And its rated speed is Then its warranty
If your engine is certified as . . . is . . . . . . period is . . .
----------------------------------------------------------------------------------------------------------------
Variable speed or constant speed..... Less than 19 kW........ Any speed.............. 1,500 hours or two
years, whichever comes
first.
Constant speed....................... At least 19 kW, but 3,000 rpm or higher.... 1,500 hours or two
less than 37 kW. years, whichever comes
first.
Constant speed....................... At least 19 kW, but Less than 3,000 rpm.... 3,000 hours or five
less than 37 kW. years, whichever comes
first.
Variable speed....................... At least 19 kW, but Any speed.............. 3,000 hours or five
less than 37 kW. years, whichever comes
first.
Variable speed or constant speed..... 37 kW or higher........ Any speed.............. 3,000 hours or five
years, whichever comes
first.
----------------------------------------------------------------------------------------------------------------
(c) Components covered. The emission-related warranty covers all
components whose failure would increase an engine's emissions. This
includes components listed in 40 CFR 1068, Appendix I, and components
from any other system you develop to control emissions. The emission-
related warranty covers these components even if another company
produces the component. Your emission-related warranty does not cover
components whose failure would not increase an engine's emissions.
(d) Limited applicability. You may deny warranty claims under this
section if the operator caused the problem, as described in 40 CFR
1068.115.
Sec. 1039.125 What maintenance instructions must I give to buyers?
Give the ultimate purchaser of each new nonroad engine written
instructions for properly maintaining and using the engine, including
the emission-control system. The maintenance instructions also apply to
service accumulation on your test engines, as described in 40 CFR part
1065, subpart E.
(a) Critical emission-related maintenance. Critical emission-
related maintenance includes any adjustment, cleaning, repair, or
replacement of air-induction, fuel-system, or ignition components,
aftertreatment devices, exhaust-gas recirculation systems, crankcase
ventilation valves, sensors, or electronic control units. This may also
include any other component whose only purpose is to reduce emissions
or whose failure will increase emissions without significantly
degrading engine performance. You may schedule critical emission-
related maintenance on these components if you meet the following
conditions:
(1) You may ask us to approve critical emission-related maintenance
only if operators are reasonably likely to do the maintenance you call
for.
(2) We will accept scheduled maintenance as reasonably likely to
occur in use if you satisfy any of four conditions:
(i) You present data showing that, if a lack of maintenance
increases emissions, it also unacceptably degrades the engine's
performance.
(ii) You present survey data showing that 80 percent of engines in
the field get the maintenance you specify at the recommended intervals.
(iii) You provide the maintenance free of charge and clearly say so
in maintenance instructions for the customer.
(iv) You otherwise show us that the maintenance is reasonably
likely to be done at the recommended intervals.
(3) For engine's with maximum power below 130 kW, you may not
schedule emission-related maintenance more frequently than the
following minimum intervals, except as specified in paragraph (a)(5) of
this section:
(i) For EGR-related filters and coolers, PCV valves, and fuel
injector tips (cleaning only), the minimum interval is 1,500 hours.
(ii) For fuel injectors, turbochargers, catalytic converter,
electronic engine control units (and associated sensors and actuators),
particulate traps, trap oxidizers, and related components (cleaning and
repair only), EGR system (including related components, but excluding
filters and coolers), and other add-on emission-related components, the
minimum interval is 3,000 hours.
(4) For engine's with maximum power at or above 130 kW, you may not
schedule emission-related maintenance more frequently than the
following minimum intervals, except as specified in paragraph (a)(5) of
this section:
(i) For EGR-related filters and coolers, PCV valves, and fuel
injector tips (cleaning only), the minimum interval is 1,500 hours.
(ii) For fuel injectors, turbochargers, catalytic converter,
electronic engine control units (and associated sensors and actuators),
particulate traps, trap oxidizers, and related components (cleaning and
repair only), EGR system (including related components, but excluding
filters and coolers), and other add-on emission-related components, the
minimum interval is 4,500 hours.
(5) If your engine family has an alternate useful life shorter than
the period specified in paragraph (a)(3) or (a)(4) of this section, you
may not
[[Page 28566]]
schedule maintenance on those components more frequently than the
alternate useful life (see Sec. 1039.101(g)).
(b) Recommended additional maintenance. You may recommend any
additional amount of maintenance on the components listed in paragraph
(a) of this section, as long as you make clear that these maintenance
steps are not necessary to keep the emission-related warranty valid. If
operators do the maintenance specified in paragraph (a) of this
section, but not the recommended additional maintenance, this does not
allow you to disqualify them from in-use testing or deny a warranty
claim.
(c) Special maintenance. You may specify more frequent maintenance
to address problems related to special situations, such as atypical
engine operation.
(d) Noncritical emission-related maintenance. For engine parts not
listed in paragraph (a) of this section, you may schedule any amount of
emission-related inspection or maintenance. But you must state clearly
that these steps are not necessary to keep the emission-related
warranty valid. Also, do not take these inspection or maintenance steps
during service accumulation on your test engines.
(e) Maintenance that is not emission-related. For maintenance
unrelated to emission controls, you may schedule any amount of
inspection or maintenance. You may also take these inspection or
maintenance steps during service accumulation on your test vehicles or
engines. This might include adding engine oil, changing air, fuel, or
oil filters, cooling system maintenance, adjustment of idle speed,
governor, engine bolt torque, valve lash, injector lash, timing, or
lubrication of the exhaust manifold heat control valve. This
nonemission-related maintenance may be performed on durability vehicles
at the least frequent intervals that you recommend to the ultimate
purchaser (not the intervals recommended for severe service).
(f) Source of parts and repairs. Print clearly on the first page of
your written maintenance instructions that any repair shop or person
may maintain, replace, or repair emission-control devices and systems.
Your instructions may not require components or service identified by
brand, trade, or corporate name. Also, do not directly or indirectly
condition your warranty on a requirement that the vehicle be serviced
by your franchised dealers or any other service establishments with
which you have a commercial relationship.
You may disregard the requirements in this paragraph (f) if you do
one of two things:
(1) Provide a component or service without charge under the
purchase agreement.
(2) Get us to waive this prohibition in the public's interest by
convincing us the engine will work properly only with the identified
component or service.
(g) Owner's responsibility for maintenance. The owner is
responsible for proper maintenance of the engine. This includes a
component related to emission control but not designed for emission
control, if it meets either of the following criteria:
(1) The component was in general use on similar engines before
January 1, 1990.
(2) Failure of the component would clearly degrade the engine's
performance enough that the operator would need to repair or replace
it.
Sec. 1039.130 What installation instructions must I give to equipment
manufacturers?
(a) If you sell an engine for someone else to install in a piece of
nonroad equipment, give the buyer of the engine written instructions
for installing it consistent with the requirements of this part.
Include all information necessary to ensure that an engine installed
this way will be in its certified configuration.
(b) Make sure these instructions have the following information:
(1) Include the heading: ``Emission-related installation
instructions''.
(2) State: ``Failing to follow these instructions when installing a
certified engine in a piece of nonroad equipment violates federal law
(40 CFR 1068.105(b)), subject to fines or other penalties as described
in the Clean Air Act.''.
(3) Describe the instructions needed to install the exhaust system
consistent with the requirements of Sec. 1039.205(s).
(4) [Reserved]
(5) Describe any limits on the range of applications needed to
ensure that the engine operates consistently with your application for
certification. For example, if your engines are certified only for
constant-speed operation under Sec. 1039.510(a)(1), tell equipment
manufacturers not to install the engines in variable-speed
applications.
(6) Describe any other instructions to make sure the installed
engine will operate according to design specifications in your
application for certification. This may include, for example,
instructions for installing aftertreatment devices when installing the
engines.
(7) State: ``If you install the engine in a way that makes the
engine's emission control information label hard to read during normal
engine maintenance, you must place a duplicate label on the vehicle, as
described in 40 CFR 1068.105.''.
(c) You do not need installation instructions for engines you
install in your own equipment.
Sec. 1039.135 How must I label and identify the engines I produce?
(a) Assign each engine a legible unique identification number and
permanently and affix or engrave it (including stamping) on the engine.
(b) At the time of manufacture, affix a permanent and legible label
identifying each engine. The label must be:
(1) Attached in one piece so it is not removable without being
destroyed or defaced.
(2) Durable and readable for the engine's entire life.
(3) Secured to a part of the engine needed for normal operation and
not normally requiring replacement.
(4) Written in block letters in English.
(c) The label must:
(1) Include the heading ``EMISSION CONTROL INFORMATION''.
(2) Include your full corporate name and trademark.
(3) Identify the emission-control system; your identifiers must use
names and abbreviations consistent with SAE J1930 (incorporated by
reference in Sec. 1039.810).
(4) List all requirements for fuel and lubricants.
(5) State the date of manufacture [MONTH and YEAR]; you may omit
the date of manufacture from the emission control information label if
you maintain a record of the engine manufacture dates and provide them
to us upon request.
(6) State: ``THIS ENGINE MEETS U.S. ENVIRONMENTAL PROTECTION AGENCY
REGULATIONS FOR [MODEL YEAR] NONROAD COMPRESSION-IGNITION ENGINES.''.
(7) State the emission standards to which the engines are
certified, or the FELs if you certify the engine using the ABT
provisions of subpart H of this part.
(8) Include EPA's standardized designation for the engine family
(and subfamily, where applicable).
(9) State the engine's displacement (in liters) and maximum engine
power for the family. You may use the advertised power for the engine
instead of the maximum engine power for the family, as long as the
advertised power is within the power category for which the engine
family is certified.
(10) State the engine's useful life (see Sec. 1039.101(g)).
[[Page 28567]]
(11) List specifications and adjustments for engine tuneups; show
the proper position for the transmission during tuneup and state which
accessories should be operating.
(12) Describe other information on proper maintenance and use.
(13) If your engines are certified only for constant-speed
operation under Sec. 1039.510(a)(1), add to the engine label
``CONSTANT-SPEED ONLY'.
(14) You may add information to identify other emission standards
that the engine meets or does not meet (such as European standards).
(e) If there is not enough space for an emission control
information label with all the required information, you may omit the
information required in paragraphs (c)(3), (c)(4), and (c)(12) of this
section if you print it in the owner's manual instead.
(f) For diesel-fueled engines, label both the engine and equipment
to indicate the maximum allowable sulfur level of the fuel, as
described in your application for certification.
(1) The label should state either:
(i) ``ULTRA LOW-SULFUR NONROAD DIESEL FUEL OR ON-HIGHWAY DIESEL
FUEL ONLY (15 parts per million)''; or
(ii) ``LOW-SULFUR NONROAD DIESEL FUEL, ULTRA LOW-SULFUR NONROAD
DIESEL FUEL, OR ON-HIGHWAY DIESEL FUEL ONLY (500 ppm maximum)''.
(2) The equipment must be labeled near the fuel inlet. If you
manufacturer the engine, but not the equipment, provide the appropriate
label to the equipment manufacturer and notify the equipment
manufacturer in the installation instructions. Optionally, if the
equipment manufacturer chooses to install its own label, you are not
required to provide the label.
(g) You may ask us to approve modified labeling requirements in
this part if you show that you are unable to meet them. We will approve
your request if this is necessary and your alternate label is
consistent with the requirements of this part.
(h) If you obscure the engine label while installing the engine in
the equipment, you must place a duplicate label on the equipment. If
others install your engine in their equipment in a way that obscures
the engine label, we require them to add a duplicate label on the
equipment (see 40 CFR 1068.105); in that case, give them the number of
duplicate labels they request and keep the following records:
(1) The written request from the equipment manufacturer.
(2) The number of duplicate labels you send and the date you send
them.
Subpart C--Certifying Engine Families
Sec. 1039.201 What are the general requirements for obtaining a
certificate of conformity?
(a) You must send us a separate application for a certificate of
conformity for each engine family. A certificate of conformity is valid
from the date it is issued until December 31 of the model year for
which it is issued.
(b) The application must contain all of the information required by
this part and must not include false or incomplete statements or
information (see Sec. 1039.255).
(c) We may ask you to include less information than we specify in
this subpart, provided that all of the specified information is
maintained as required by Sec. 1039.250.
(d) You must use good engineering judgment for all decisions
related to your application (see 40 CFR 1068.5).
(e) An authorized representative of your company must approve and
sign the application.
(f) See Sec. 1039.255 for provisions describing how we will
process your application.
Sec. 1039.205 What must I include in my application?
This section specifies the information that must be in you
application, unless we ask you to include less information under Sec.
1039.201(c). We may require you to provide additional information to
evaluate your application.
(a) Describe the engine family's specifications and other basic
parameters of the engine's design and emission controls. List the types
of fuel on which your engines are designed to operate (for example,
diesel fuel). For each engine configuration, list the intended maximum
engine power and the associated production tolerances. If the
production tolerance for maximum engine power for any configuration
exceeds +/-5 percent, or if the distribution of actual maximum engine
power is asymmetrically distributed around the intended maximum engine
power, then you must demonstrate that you have taken reasonable steps
to minimize production variability with respect to maximum engine
power.
(b) Explain how the emission-control system operates. Describe in
detail all the system components for controlling exhaust emissions,
including auxiliary emission control devices (AECDs) and all fuel-
system components you will install on any production or test engine.
For this paragraph (b), treat as separate AECDs any devices that
modulate or activate differently from each other. Include all the
following:
(1) Give a general overview of the engine, the emission-control
strategies, and all AECDs.
(2) Describe each AECD's general purpose and function.
(3) Identify the parameters that each AECD senses (including
measuring, estimating, calculating, or empirically deriving the
values). Include equipment-based parameters and state whether you
simulate them during testing with the applicable procedures.
(4) Describe the purpose for sensing each parameter.
(5) Identify the location of each sensor the AECD uses.
(6) Identify the threshold values for the sensed parameters that
activate the AECD.
(7) Describe the parameters that the AECD modulates (controls) in
response to any sensed parameters, including the range of modulation
for each parameter, the relationship between the sensed parameters and
the controlled parameters and how the modulation achieves the AECD's
stated purpose. Use graphs and tables, as necessary.
(8) Describe each AECD's specific calibration details. This may be
in the form of data tables, graphical representations, or some other
description.
(9) Describe the hierarchy among the AECDs when multiple AECDs
sense or modulate the same parameter. Describe whether the strategies
interact in a comparative or additive manner and identify which AECD
takes precedence in responding, if applicable.
(10) Explain the extent to which the AECD is included in the
applicable test procedures specified in subpart F of this part.
(11) Do the following additional things for AECDs designed to
protect engines or equipment:
(i) Identify the engine and/or equipment design limits that make
protection necessary and describe any damage that would occur without
the AECD.
(ii) Describe how each sensed parameter relates to the protected
components' design limits or those operating conditions that cause the
need for protection.
(iii) Describe the relationship between the design limits/
parameters being protected and the parameters sensed or calculated as
surrogates for those design limits/parameters, if applicable.
(iv) Describe how the modulation by the AECD prevents engines and/
or equipment from exceeding design limits.
(v) Explain why it is necessary to estimate parameters instead of
measuring them directly and describe
[[Page 28568]]
how the AECD calculates the estimated value, if applicable.
(vi) Describe how you calibrate the AECD modulation to activate
only during conditions related to the stated need to protect components
and only as needed to sufficiently protect those components.
(c) [Reserved]
(d) Describe the engines you selected for testing and the reasons
for selecting them.
(e) Describe the test equipment and procedures that you used,
including any special or alternate test procedures you used (see Sec.
1039.501).
(f) Describe how you operated the test engine prior to testing,
including the duty cycle and the number of engine operating hours used
to stabilize emission levels. Explain why the method of service
accumulation was selected. Describe any scheduled maintenance you did.
(g) List the specifications of the test fuel to show that it falls
within the required ranges we specify in 40 CFR part 1065, subpart C.
(h) Identify the engine family's useful life.
(i) Propose maintenance and use instructions for the ultimate
purchaser of each new nonroad engine (see Sec. 1039.125).
(j) Propose emission-related installation instructions if you sell
engines for someone else to install in a piece of nonroad equipment
(see Sec. 1039.130).
(k) Propose an emission control information label.
(l) Identify the emission standards or FELs to which you are
certifying engines in the engine family. Identify the of specifications
of ambient operating regions that will apply for NTE testing under
Sec. 1039.101(d)(4) (i).
(m) Identify the engine family's deterioration factors and describe
how you developed them (see Sec. 1039.245). Present any emission test
data you used for this.
(n) Certify that you operated your test engines as described in the
application (including the test procedures, test parameters, and test
fuels) to show you meet the requirements of this part.
(o) Present emission data to show that you meet the applicable
emission standards. Present emission data for hydrocarbons (NMHC or
THCE, as applicable), NOX, and CO on a test engine to show
your engines meet the duty-cycle emission standards we specify in Sec.
1039.101. Show these figures before and after applying regeneration
factors and deterioration factors for each engine. Include test data
for each type of fuel from 40 CFR part 1065, subpart C, on which you
intend for engines in the engine family to operate. If we specify more
than one grade of any fuel type (for example, No. 1 and No. 2 diesel
fuel), you only need to submit test data for one grade, unless the
regulations of this part specify otherwise for your engine. Note that
Sec. 1039.235 allows you to submit an application in certain cases
without new emission data.
(p) Report all test results, including those from invalid tests or
from any other tests, whether or not they were conducted according to
the test procedures of subpart F of this part.
(q) Describe all adjustable operating parameters (see Sec.
1039.115(e)), including production tolerances. Include the following in
your description of each parameter:
(1) The nominal or recommended setting.
(2) The intended physically adjustable range.
(3) The limits or stops used to establish adjustable ranges.
(4) Information showing why the limits, stops, or other means of
inhibiting adjustment are effective in preventing adjustment of
parameters on in-use engines to settings outside the your intended
physically adjustable ranges.
(r) Provide the information to read and interpret all the
information broadcast by an engine's onboard computers and electronic
control modules. State that, upon request, you will give us any
hardware, software, or tools we would need to do this. If you broadcast
a surrogate parameter for torque values, you must provide us what we
need to convert these into torque units. You may reference any
appropriate publicly released standards that define conventions for
these messages and parameters. Format your information consistent with
publicly released standards.
(s) Confirm that nothing will prevent sampling of exhaust emissions
after engines are installed in equipment and placed in service. If this
cannot be done by simply adding a 20-cm extension to the exhaust pipe,
show how to sample exhaust emissions in a way that prevents diluting
the exhaust sample with ambient air.
(t) State whether your engines will be limited to constant-speed
applications. If your certification is limited to constant-speed
applications, describe how you will prevent use of these engines in
applications for which they are not certified.
(u) Certify that all the engines in the engine family comply with
the not-to-exceed emission standards we specify in subpart B of this
part for all normal operation and use when tested as specified in Sec.
1039.515. Describe in detail any testing, engineering analysis, or
other information on which you base this statement.
(v) Unconditionally certify that all the engines in the engine
family comply with the requirements of this part, other referenced
parts of the CFR, and the Clean Air Act.
(w) Include estimates of U.S.-directed production volumes.
(x) Include the information required by other subparts of this
part. For example, include the information required by Sec. 1039.730,
if you participate in the ABT program.
Sec. 1039.210 May I get preliminary approval before I complete my
application?
If you send us information before you finish the application, we
will review it and make any appropriate determinations, especially for
questions related to engine family definitions, deterioration factors,
service accumulation testing, and maintenance. Decisions made under
this section are considered to be preliminary approval, subject to
final review and approval. If you request preliminary approval related
to the upcoming model year or the model year after that, we will make
best-efforts to make the appropriate determinations as soon as
practicable. We will generally not provide preliminary approval related
to a future model year more than two years ahead of time.
Sec. 1039.220 How do I amend the maintenance instructions in my
application?
You may amend your emission-related maintenance instructions after
you submit your application for certification, as long as the amended
instructions remain consistent with maintenance you performed on test
engines and conform to the requirements of this part. You must send the
Designated Compliance Officer a request to amend your application for
certification or certificate of conformity for an engine family if you
want to change the emission-related maintenance instructions in a way
that could affect emissions. In your request, describe the proposed
changes to the maintenance instructions. We will disapprove your
request if we determine that the amended instructions are inconsistent
with maintenance you performed on test engines.
(a) If you are decreasing the specified level of maintenance, you
may distribute the new maintenance instructions to your customers 30
days
[[Page 28569]]
after we receive your request, unless we disapprove your request. We
may approve a shorter time or waive this requirement.
(b) If your requested change would not decrease the specified level
of maintenance, you may distribute the new maintenance instructions
anytime after you send your request. For example, this paragraph (b)
would cover adding instructions to increase the frequency of a
maintenance step for engines in severe-duty applications.
(c) You do not need to request approval if you are only making
minor corrections (such as correcting typographical mistakes),
clarifying your maintenance instructions, or changing instructions for
maintenance unrelated to emission control.
Sec. 1039.225 How do I amend my application or certificate to include
new or modified engines?
Before we issue you a certificate of conformity, you may amend your
application to include new or modified engine configurations, subject
to the provisions of this section. After we have issued your
certificate of conformity, you may ask to amend your certificate to
include new or modified engine configurations, subject to the
provisions of this section. You must amend your application or
certificate if any changes occur with respect to any information
included in your application.
(a) You must amend your application or certificate before you take
either of the following actions:
(1) Add an engine (that is, an additional engine configuration) to
an engine family. In this case, the engine added must be consistent
with other engines in the engine family, with respect to the criteria
listed in Sec. 1039.230.
(2) Make a change that may affect emissions or an emission-related
part to an engine already included in an engine family. This includes
production and design changes. A change is deemed to affect emissions
if it will affect emissions at any time during the engine's lifetime.
(b) Send the Designated Compliance Officer a request to amend the
application or certificate for an engine family. In your request, do
all of the following:
(1) Describe in detail the addition or change in the engine model
or configuration you intend to make.
(2) Include engineering evaluations or data showing that the
amended engine family complies with all applicable emission standards.
You may do this by showing that the original test engine is still
appropriate with respect to showing compliance of the amended family
with all applicable emission standards.
(3) If the original test engine for the engine family is not
appropriate to show compliance for the new or modified nonroad engine,
include new test data showing that the new or modified nonroad engine
meets the requirements of this part.
(c) We may ask for more test data or engineering evaluations. You
must give us these within 30 days after we request them.
(d) For engine families that are already covered by a certificate
of conformity, we will determine whether the certificate of conformity
would cover your new or modified nonroad engine. We will send you a
written explanation of our decision. You may ask for a hearing if we
deny your request (see Sec. 1039.820).
(e) For engine families that are already covered by a certificate
of conformity, you may start producing the new or modified nonroad
engine anytime after you send us your request to amend your
certificate, prior to our decision under paragraph (d) of this section.
If we determine that the affected engines do not meet applicable
requirements, we will notify you to cease production of the engines and
to recall the engines at no expense to the owner. Choosing to produce
engines under this paragraph (e) is deemed to be consent to recall all
engines that we determine do not meet applicable emission standards or
other requirements and to remedy the nonconformity at no expense to the
owner. If you do not provide within 30 days information required under
paragraph (c) of this section, you must stop producing the new or
modified engines.
Sec. 1039.230 How do I select engine families?
(a) Divide your product line into families of engines that are
expected to have similar emission characteristics. Your engine family
is limited to a single model year.
(b) Group engines in the same engine family if they are the same in
all of the following aspects:
(1) The combustion cycle and fuel.
(2) The cooling system (water-cooled vs. air-cooled).
(3) Method of air aspiration.
(4) Method of exhaust aftertreatment (for example, catalytic
converter or particulate trap).
(5) Combustion chamber design.
(6) Bore and stroke.
(7) Number of cylinders, (engines with aftertreatment devices
only).
(8) Cylinder arrangement (engines with aftertreatment devices
only).
(9) Method of control for engine operation other than governing,
(i.e., mechanical or electronic).
(10) Power category.
(c) You may subdivide a group of engines that is identical under
paragraph (b) of this section into different engine families, if you
show the expected emission characteristics are different during the
useful life.
(d) You may group engines that are not identical with respect to
the things listed in paragraph (b) of this section in the same engine
family if you show that their emission characteristics during the
useful life will be similar.
Sec. 1039.235 What emission testing must I perform for my application
for a certificate of conformity?
This section describes the emission testing you must perform to
show compliance with the emission standards in Sec. 1039.101 (a) and
(b). See Sec. 1039.205(u) regarding emission testing related to the
NTE emission standards. See 40 CFR part 1065, subpart E, regarding
service accumulation before emission testing
(a) Test your emission-data engines using the procedures and
equipment specified in subpart F of this part.
(b) Select from each engine family an engine for each fuel type.
Select the engine configuration with the highest fueling rate
(primarily at the point of maximum torque), unless good engineering
judgment indicates that a different configuration is more likely to
exceed (or has emissions nearer to) an applicable emission standard. In
making this selection, consider all factors expected to affect emission
performance and compliance with the standards, including emission
levels of all exhaust constituents, especially NOX and PM.
Select the emission data test engine or engines from this
configuration.
(c) We may choose to measure emissions from any of your test
engines or other engines from the engine family.
(1) If we do this, you must provide the test engine at the location
we select. We may decide to do the testing at your plant or any other
facility. If we choose to do the testing at your plant, you must
schedule it as soon as possible and make available the instruments and
equipment we need.
(2) If we measure emissions on one of your test engines, the
results of that testing become the official emission results for the
engine. Unless we later invalidate this data, we may decide not to
consider your data in determining if your engine family meets the
applicable emission standards.
(3) Before we test one of your engines, we may set its adjustable
parameters to
[[Page 28570]]
any point within the physically adjustable ranges (see Sec.
1039.115(e)).
(4) Calibrate the test engine within normal production tolerances
for anything we do not consider an adjustable parameter (see Sec.
1039.205(q)).
(d) You may ask to use emission data for an equivalent engine
family from previous model years instead of doing new tests, but only
if the data show that the test engine would meet all the requirements
applicable for the engine family covered by the application for
certification. For the purpose of this paragraph, equivalent engine
families are engine families that differ only with respect to model
year.
(e) We may require you to test a second engine in addition to the
engine tested under paragraph (b) of this section.
(f) If you use an alternate testing procedure under 40 CFR 1065.10
and later testing shows that such testing does not produce results that
are equivalent to the procedures specified in subpart F of this part,
we may reject data you generated using the alternate procedure.
(g) You are not required to provide smoke emission data for engines
having a certification PM emission level less than 0.07 g/kW-hr or a PM
FEL less than 0.07 g/kW-hr.
Sec. 1039.240 How do I demonstrate that my engine family complies
with exhaust emission standards?
(a) For purposes of certification, your engine family is considered
in compliance with the applicable numerical emission standards in Sec.
1039.101 (a) and (b) if all emission-data engines representing that
family have test results showing deteriorated emission levels at or
below these standards. (Note: if you participate in the ABT program in
subpart H of this part, your FELs are considered to be applicable
emission standards with which you must comply.)
(b) Your engine family is deemed to not comply if any emission-data
engine representing that family has test results showing a deteriorated
emission level above any applicable emission standard from Sec.
1039.101 for any pollutant.
(c) To compare emission levels from the test engine with the
applicable emission standards, apply deterioration factors to the
measured emission levels for each pollutant. Section 1039.245 specifies
how to test your engine to develop deterioration factors that represent
the deterioration expected in emissions over your engines' full useful
life. Your deterioration factors must be consistent with emission
increases observed from any in-use testing with similar engines. Small-
volume engine manufacturers may use assigned deterioration factors that
we establish. Apply the deterioration factors as follows:
(1) If you use aftertreatment technology (other than particulate
traps) to control emissions of a pollutant, the deterioration factor
for that pollutant is the ratio of exhaust emissions at the end of
useful life to exhaust emissions at the low-hour test point. Adjust the
official emission results for each tested engine at the selected test
point by multiplying the measured emissions by the deterioration
factor. If the factor is less than one, use one. This provision does
not apply for smoke emissions. Multiplicative DFs must be specified to
one more significant figure than the applicable standard.
(2) If you use particulate traps or if you use no aftertreatment
technology to control emissions of a pollutant, the deterioration
factor for that pollutant is the difference between exhaust emissions
at the end of useful life and exhaust emissions at the low-hour test
point. Adjust the official emission results for each tested engine at
the selected test point by adding the factor to the measured emissions.
If the factor is less than zero, use zero. Deterioration factors for
smoke emission are always additive. Additive DFs must be specified to
one more decimal place than the applicable standard.
(3) If your engine vents crankcase emissions to the exhaust or to
the atmosphere, you must account for crankcase emission deterioration,
using good engineering judgment. You may use separate factors for
crankcase emissions (either multiplicative or additive) or include the
effects in combined exhaust and crankcase factors.
(d) After adjusting the emission levels for deterioration, round
them to the same number of decimal places as the emission standard.
Compare the rounded emission levels to the emission standard for each
test engine.
(e) For engines subject to NMHC standards, you may base compliance
on total hydrocarbon (THC) emissions. Indicate in your application for
certification if you are using this option. If you do, measure THC
emissions and calculate NMHC emissions as 98 percent of THC emissions:
NMHC = (0.98) x (THC).
Sec. 1039.245 How do I determine deterioration factors from exhaust
durability testing?
Determine deterioration factors (DFs) to show that your engines
will meet emission standards throughout the useful life, as described
in Sec. Sec. 1039.101 and 1039.240. This section describes how to
determine deterioration factors, either with an engineering analysis,
with pre-existing test data, or with new emission measurements. If you
are required to perform durability testing, see Sec. 1039.220 for
limitations on the maintenance that you may perform on your test
engine. You must determine a separate DF for each pollutant.
(a) You may ask us to approve deterioration factors for an engine
family with established technology based on engineering analysis
instead of testing. Established technology refers to engines for which
the applicable NMHC+NOX standard or FEL is greater than the
Tier 3 NMHC+NOX standard described in 40 CFR Sec. 89.112,
unless the engines use exhaust-gas recirculation or aftertreatment.
Established technology also refers to engines for which the applicable
NMHC+NOX standard or FEL is less than or equal to the Tier 3
NMHC+NOX standard if you can show that the engines do not
have technologies other than those generally used on engines meeting
NMHC+NOX standards less stringent than the Tier 3 standards.
(b) You may ask us to approve deterioration factors for an engine
family based on emission measurements from similar highway or nonroad
engines if you have already given us this data for certifying the other
engines in the same or previous model years. Use good engineering
judgment to decide whether the two engines are similar. We will approve
your request if you show us that the emission measurements from other
engines reasonably represent in-use deterioration for the nonroad
engine family.
(c) If you are unable to determine deterioration factors for an
engine family under paragraph (a) or (b) of this section, select
engines, subsystems, or components for testing. Determine deterioration
factors based on service accumulation and related testing to represent
the deterioration expected from in-use engines over the full useful
life. You must measure emissions from the test engine at least three
times with evenly spaced intervals of service accumulation. You may use
extrapolation to determine deterioration factors once you have
established a trend of increasing emissions with age for each
pollutant. You may use an engine installed in nonroad equipment to
accumulate service hours instead of running the engine only in the
laboratory. Use good engineering judgment for all aspects of the effort
to establish deterioration factors under this paragraph (c).
[[Page 28571]]
(d) Include the following information in your application for
certification (see Sec. 1039.205(n)):
(1) If you use test data from a different engine family, explain
why this is appropriate and include all the emission measurements on
which you base the deterioration factor.
(2) If you determine your deterioration factors based on
engineering analysis, explain why this is appropriate and include a
statement that all data, analyses, evaluations, and other information
you used are available for our review upon request.
(3) If you conduct testing to determine deterioration factors,
describe the form and extent of service accumulation, including a
rationale for selecting the service-accumulation period and the method
you use to accumulate hours.
Sec. 1039.250 What records must I keep and what reports must I send
to EPA?
(a) Within 30 days after the end of the model year, send the
Designated Compliance Officer a report describing how many engines you
produced in each engine family during the model year. You must report
the total number of engines you produced by maximum brake power, total
displacement, and the type of fuel system. We may also ask you to give
us production figures for each assembly plant if you produce engines at
more than one plant. If you produced exempted engines under the
provisions of Sec. 1039.625, include in your report the number of
exempted engines you produced for each engine model and identify the
buyer or shipping destination for each exempted engine.
(b) Organize and maintain the following records:
(1) A copy of all applications and any summary information you sent
us.
(2) Any of the information we specify in Sec. 1039.205 that you
were not required to include in your application.
(3) A detailed history of each emission-data engine. For each
engine, describe all of the following:
(i) The test engine's construction, including its origin and
buildup, steps you took to ensure that it represents production
engines, any components you built specially for it, and all emission-
related components.
(ii) How you accumulated engine operating hours (service
accumulation), including the dates and the number of hours accumulated.
(iii) All maintenance, including modifications, parts changes, and
other service, and the dates and reasons for the maintenance.
(iv) All your emission tests, including documentation on routine
and standard tests, as specified in part 40 CFR part 1065, and the date
and purpose of each test.
(v) All tests to diagnose engine or emission-control performance,
giving the date and time of each and the reasons for the test.
(vi) Any other significant events.
(4) If we ask, you must give us projected production figures for an
engine family. We may ask you to divide your production figures by
maximum brake power, total displacement, or assembly plant.
(5) Emission test results from durability testing, and the
information required by Sec. 1039.245(d).
(6) Keep a list of engine identification numbers for all the
engines you produce under each certificate of conformity.
(b) Keep data from routine emission tests (such as test cell
temperatures and relative humidity readings) for one year after we
issue the associated certificate of conformity. Keep all other
information specified in paragraph (a) of this section for eight years
after we issue your certificate.
(c) Store these records in any format and on any media, as long as
you can promptly send us organized, written records in English if we
ask for them. You must keep these records readily available. We may
review them at any time.
(d) Send us copies of any engine maintenance instructions or
explanations if we ask for them.
Sec. 1039.255 What decisions may EPA make regarding my certificate of
conformity?
(a) If we determine your application is complete and shows that the
engine family meets all the requirements of this part and the Act, we
will issue a certificate of conformity for your engine family for that
model year. We may make the approval subject to additional conditions.
(b) We may deny your application for certification if we determine
that your engine family fails to comply with emission standards or
other requirements of this part or the Act. Our decision may be based
on a review of all information available to us. If we deny your
application, we will explain why in writing.
(c) In addition, we may deny your application or suspend or revoke
your certificate if you do any of the following:
(1) Refuse to comply with any testing or reporting requirements.
(2) Submit false or incomplete information (paragraph (e) of this
section applies if this is fraudulent).
(3) Render inaccurate any test data.
(4) Deny us from completing authorized activities despite our
presenting a warrant or court order (see 40 CFR 1068.20). This includes
a failure to provide reasonable assistance.
(5) Produce engines for importation into the United States at a
location where local law prohibits us from carrying out authorized
activities.
(6) Fail to supply requested information or amend your application
to include all engines being produced.
(7) Take any action that otherwise circumvents the intent of the
Act or this part.
(d) We may void your certificate if you do not keep the records we
require or do not give us information when we ask for it.
(e) We may void your certificate if we find that you intentionally
submitted false or incomplete information.
(f) If we deny your application or suspend, revoke, or void your
certificate, you may ask for a hearing (see Sec. 1039.820).
Subpart D--[Reserved]
Subpart E--In-use Testing
Sec. 1039.401 General Provisions.
We may conduct in-use testing of any engine subject to the
standards of this part. However, we will limit recall testing to the
first 75 percent of each engine's useful life as specified in Sec.
1039.101(g).
Subpart F--Test Procedures
Sec. 1039.501 How do I run a valid emission test?
(a) Use the equipment and procedures for compression-ignition
engines in 40 CFR part 1065 to determine whether engines meet the duty-
cycle emission standards in Sec. 1039.101(a) and (b). Measure the
emissions of CO2 and all the pollutants we regulate in Sec.
1039.101 using the applicable sampling procedures in 40 CFR part 1065.
Use the applicable duty cycles specified in Sec. Sec. 1039.505 and
1039.510.
(b) Section 1039.515 describes the supplemental procedures for
evaluating whether engines meet the not-to-exceed emission standards in
Sec. 1039.101(c).
(c) Use the equipment and procedures in ISO 8178-9 for evaluating
whether engines meet the smoke standards in Sec. 1039.105.
(d) Use the fuels specified in 40 CFR part 1065, subpart C, to
conduct valid tests, except as noted in Sec. 1039.515.
(1) Use these test fuels or any commercially available fuel for
service accumulation.
(2) For diesel-fueled engines, choose one of the diesel fuels in 40
CFR part 1065, subpart C, for emission testing. Identify this test fuel
in your application
[[Page 28572]]
for certification and ensure that the emission control information
label is consistent with your selection of the test fuel (see Sec.
1039.135(f)). For example, do not test with 15 ppm sulfur fuel if you
intend to label your engines to allow 500 ppm sulfur fuel.
(e) You may use special or alternate procedures to the extent we
allow them under 40 CFR 1065.10.
(f) This subpart part is addressed to you as a manufacturer, but it
applies equally to anyone who does testing for you, and to us when we
conduct testing to determine if your engines meet emission standards.
Sec. 1039.505 Which duty cycles do I use for steady-state testing?
(a) Measure emissions by testing the engine on a dynamometer with
one of the following steady-state duty cycles to determine whether it
meets the steady-state emission standards in Sec. 1039.101(b):
(1) Use the 5-mode duty cycle described in Appendix I of this part
for engines that you will certify only for constant-speed operation.
(2) [Reserved]
(3) Use the 6-mode duty cycle described in Appendix III of this
part for engines with maximum power below 19 kW whose certification
will not be limited to constant-speed applications.
(4) Use the 8-mode duty cycle described in Appendix IV of this part
for engines with maximum power at or above 19 kW whose certification
will not be limited to constant-speed applications.
(b) During idle mode, operate the engine with the following
parameters:
(1) Hold the speed within your specifications.
(2) Set the engine to operate at its minimum fueling rate.
(3) Keep engine torque under 5 percent of maximum test torque.
(c) For full-load operating modes, operate the engine at its
maximum fueling rate.
(d) See 40 CFR part 1065 for detailed specifications of tolerances
and calculations.
(e) In the normal test sequence described in 40 CFR part 1065,
subpart F, steady-state testing generally follows the transient test.
For those cases where we do not require transient testing, perform the
steady-state test after an appropriate warm-up period, consistent with
good engineering judgment.
Sec. 1039.510 Which duty cycles do I use for transient testing?
(a) Measure emissions by testing the engine on a dynamometer with
one of the following transient duty cycles to determine whether it
meets the transient emission standards in Sec. 1039.101(a):
(1) If you certify an engine family for constant-speed operation
only, use the transient duty-cycle described in Appendix V of this
part.
(2) For all other engines, use the transient duty-cycle described
in Appendix VI of this part.
(b) The transient test sequence consists of an initial run through
the transient sequence from a cold start, 20 minutes with no engine
operation, then a final run through the same transient sequence. Start
sampling emissions immediately after you start the engine. Combine the
results from these two test runs by applying a weighting factor of 10
percent to the cold-start measurement and 90 percent to the hot-start
measurement.
(c) Conduct repeat tests and cool the engine down between tests as
described in 40 CFR 86.1335-90 and 86.1336-84(e).
Sec. 1039.515 What are the test procedures related to not-to-exceed
standards?
Use the test procedures described in 40 CFR 86.1370-2007 to
determine whether the engine meets the not-to-exceed emission standards
in Sec. 1039.101(c).
Sec. 1039.520 What testing must I perform to establish deterioration
factors?
Section 1039.245 describes the method for using test data or
engineering analysis to establish deterioration factors for an engine
family.
Sec. 1039.525 How do I adjust emission levels to account for
infrequently regenerating aftertreatment devices?
This section describes how to adjust emission results from engines
using aftertreatment technology with infrequent regeneration events.
For this section, ``regeneration'' means an intended event during which
emission levels change while the system restores aftertreatment
performance. For example, exhaust gas temperatures may increase
temporarily to remove sulfur from adsorbers or to oxidize accumulated
particulate matter in a trap. For this section, ``infrequent'' refers
to regeneration events that are expected to occur less than once over
the applicable transient duty cycle.
(a) Developing adjustment factors. Develop an upward adjustment
factor and a downward adjustment factor for each pollutant based on
measured emission data and observed regeneration frequency. Adjustment
factors should generally apply to an entire engine family, but you may
develop separate adjustment factors for different engine configurations
within an engine family. You may use carryover or carry-across data to
establish adjustment factors for an engine family, as described in
Sec. 1039.235(d), consistent with good engineering judgment. All
adjustment factors for regeneration are additive. You may use either of
the following different approaches for engines that use aftertreatment
with infrequent regeneration events:
(1) You may disregard this section if regeneration does not
significantly effect emission levels for an engine family (or
configuration) or if it is not practical to identify when regeneration
occurs. If you do not use adjustment factors under this section, your
engines must meet emission standards for all testing, without regard to
regeneration.
(2) If your engines use aftertreatment technology with extremely
infrequent regeneration and you are unable to apply the provisions of
this section, you may ask us to approve an alternate methodology to
account for regeneration events.
(b) Calculating average adjustment factors. Calculate the average
adjustment factor (EFA) based on the following equation:
EFA = (F)(EFH) + (1-F)(EFL)
Where:
F = the frequency of the regeneration event in terms of the fraction of
tests during which the regeneration occurs.
EFH = measured emissions from a test in which the
regeneration occurs.
EFL = measured emissions from a test in which the
regeneration does not occur.
(c) Applying adjustment factors. Apply adjustment factors based on
whether regeneration occurs during the test run. You must be able to
identify regeneration in a way that is readily apparent during all
testing.
(1) If regeneration does not occur during a test run, add an upward
adjustment factor to the measured emission rate. Determine the upward
adjustment factor (UAF) using the following equation:
UAF = EFA - EFL
(2) If regeneration occurs during a test run, subtract a downward
adjustment factor from the measured emission rate. Determine the
downward adjustment factor (DAF) using the following equation:
[GRAPHIC] [TIFF OMITTED] TP23MY03.014
(d) Sample calculation. If EFL is 0.10 g/kW-hr,
EFH is 0.50 g/kW-hr, and F is 0.1 (the regeneration occurs
once for each ten tests), then:
[[Page 28573]]
[GRAPHIC] [TIFF OMITTED] TP23MY03.015
Subpart G--Special Compliance Provisions
Sec. 1039.601 What compliance provisions apply to these engines?
Engine and equipment manufacturers, as well as owners, operators,
and rebuilders of these engines, and all other persons, must observe
the provisions of this part, the requirements and prohibitions in 40
CFR part 1068, and the requirements of the Act.
Sec. 1039.605 What provisions apply to engines already certified
under the motor-vehicle program?
(a) If you are an engine manufacturer, this section allows you to
certify nonroad engines to the requirements that apply under 40 CFR
parts 85 and 86 instead of certifying them under the requirements of
this part 1039. If you install engines in nonroad equipment, we will
consider you an engine manufacturer if you modify the engine in any of
the ways described in paragraph (c)(2) of this section; note that such
engine modifications prevent you from using the provisions of this
section. We consider engines you produce under this section to be
exempt from the requirements of this part. See Sec. 1039.610 for
similar provisions that apply to engines certified to chassis-based
standards for motor vehicles.
(b) The only requirements or prohibitions from this part that apply
to an engine that is exempt under this section are in this section. The
engine exempted under this section must meet all applicable
requirements from 40 CFR parts 85 and 86. This applies to engine
manufacturers, equipment manufacturers who use these engines, and all
other persons as if these engines were used in a motor vehicle.
(c) If you meet all the following criteria and requirements
regarding your new nonroad engine, it is exempt from the standards in
this part:
(1) Your engine must be covered by a valid certificate of
conformity under 40 CFR part 86.
(2) You must not make any changes to the certified engine that we
could reasonably expect to increase its exhaust emissions. For example,
if you make any of the following changes to one of these engines, you
do not qualify for this exemption:
(i) Change any fuel system parameters from the certified
configuration.
(ii) Change any other emission-related components.
(iii) Modify or design the engine cooling system so that
temperatures or heat rejection rates are outside the original engine
manufacturer's specified ranges.
(3) You must demonstrate that fewer than 50 percent of the engine
model's total sales, from all companies, are used in nonroad
applications.
(4) The engine must have the label we require under 40 CFR part 86.
(5) You must add a permanent supplemental label to the engine in a
position where it will remain clearly visible after installation in the
equipment. In your engine's emission control information label, do the
following:
(i) Include the heading: ``Nonroad Engine Emission Control
Information''.
(ii) Include your full corporate name and trademark.
(iii) State: ``THIS ENGINE WAS ADAPTED FOR NONROAD USE WITHOUT
AFFECTING ITS EMISSION CONTROLS. THE EMISSION-CONTROL SYSTEM DEPENDS ON
THE USE OF FUEL MEETING SPECIFICATIONS THAT APPLY FOR MOTOR-VEHICLE
APPLICATIONS. OPERATING THE ENGINE ON OTHER FUELS MAY BE A VIOLATION OF
FEDERAL LAW.''.
(iv) State the date you finished modifying the engine (month and
year), if applicable.
(6) The original and supplemental labels must be readily visible
after the engine is installed in the equipment or, if the equipment
obscures the engine's emission control information label, the equipment
manufacturer must attach duplicate labels, as described in 40 CFR
1068.105.
(7) Send the Designated Officer a signed letter by the end of each
calendar year (or less often if we tell you) with all the following
information:
(i) Identify your full corporate name, address, and telephone
number.
(ii) List the engine models you expect to produce under this
exemption in the coming year.
(iii) State: ``We produce each listed engine model for nonroad
application without making any changes that could increase its
certified emission levels, as described in 40 CFR 1039.605.''.
(d) If your engines do not meet the criteria listed in paragraph
(c) of this section, they will be subject to the standards and
prohibitions of this part. Producing these engines without a valid
exemption or certificate of conformity would violate the prohibitions
in 40 CFR 1068.101.
(e) If you are the original engine manufacturer of both the highway
and nonroad versions of an exempted engine, you must send us emission
test data on the applicable nonroad duty cycle(s). You may include the
data in your application for certification or in your letter requesting
the exemption.
(f) If you are the original manufacturer of an exempted engine that
is modified by another company under this exemption, we may require you
to send us emission test data on the applicable nonroad duty cycle(s).
If we ask for this data, we will allow a reasonable amount of time to
collect it. You are responsible for emission-related compliance under
40 CFR parts 85 and 86 for these engines, unless another company
becomes the engine manufacturer for these engines (see paragraph (a) of
this section).
(g) If you are not an engine manufacturer, you may produce nonroad
equipment from motor-vehicle engines under this section as long as the
engine has the label we specify in paragraph (c)(5) of this section and
you do not modify the engine in any way that may affect its emission
control. Add the fueling label we specify in Sec. 1039.135(f)(1)(i).
Sec. 1039.610 What provisions apply to vehicles already certified
under the motor-vehicle program?
(a) If you are an engine manufacturer, this section allows you to
certify nonroad vehicles to the requirements that apply under 40 CFR
parts 85 and 85 instead of certifying them under the requirements of
this part 1039. We consider engines and vehicles you produce under this
section to be exempt from the requirements of this part. See Sec.
1039.605 for similar provisions that apply to motor-vehicle engines
certified to engine-based standards.
[[Page 28574]]
(b) The only requirements or prohibitions from this part that apply
to an engine that is exempt under this section are in this section. The
vehicle and the engine exempted under this section must meet all
applicable requirements from 40 CFR parts 85 and 86. This applies to
engine manufacturers, equipment manufacturers who use these engines,
and all other persons as if these engines were used in a motor vehicle.
(c) If you meet all the following criteria and requirements
regarding your new nonroad vehicle, it is exempt from the standards in
this part:
(1) Your vehicle must be covered by a valid certificate of
conformity under 40 CFR part 86.
(2) You must not make any changes to the certified engine or
vehicle that we could reasonably expect to increase its exhaust
emissions. For example, if you make any of the following changes, you
do not qualify for this exemption:
(i) Change any fuel system parameters from the certified
configuration.
(ii) Change any other emission-related components.
(iii) Modify or design the engine cooling system so that
temperatures or heat rejection rates are outside the original engine
manufacturer's specified ranges.
(3) You must demonstrate that fewer than 50 percent of the engine
model's total sales, from all companies, are used in nonroad
applications.
(4) The vehicle must have the label we require under 40 CFR part
86.
(5) You must add a permanent supplemental label to the engine in a
position where it will remain clearly visible after installation in the
equipment. In your engine's emission control information label, do the
following:
(i) Include the heading: ``Nonroad Engine Emission Control
Information''.
(ii) Include your full corporate name and trademark.
(iii) STATE: ``THIS ENGINE WAS ADAPTED FOR NONROAD USE WITHOUT
AFFECTING ITS EMISSION CONTROLS. THE EMISSION-CONTROL SYSTEM DEPENDS ON
THE USE OF FUEL MEETING SPECIFICATIONS THAT APPLY FOR MOTOR-VEHICLE
APPLICATIONS. OPERATING THE ENGINE ON OTHER FUELS MAY BE A VIOLATION OF
FEDERAL LAW.''.
(iv) State the date you finished modifying the engine (month and
year), if applicable.
(6) The original and supplemental labels must be readily visible
after the engine is installed in the equipment or, if the equipment
obscures the engine's emission control information label, the equipment
manufacturer must attach duplicate labels, as described in 40 CFR
1068.105.
(7) Send the Designated Officer a signed letter by the end of each
calendar year (or less often if we tell you) with all the following
information:
(i) Identify your full corporate name, address, and telephone
number.
(ii) List the vehicle models you expect to produce under this
exemption in the coming year.
(iii) State: ``We produce each listed engine or vehicle model for
nonroad application without making any changes that could increase its
certified emission levels, as described in 40 CFR 1039.610.''.
(d) If your engines do not meet the criteria listed in paragraph
(c) of this section, they will be subject to the standards and
prohibitions of this part. Producing these engines without a valid
exemption or certificate of conformity would violate the prohibitions
in 40 CFR 1068.101.
(e) If you are the original engine manufacturer of both the highway
and nonroad versions of an exempted engine, you must send us emission
test data on the applicable nonroad duty cycle(s). You may include the
data in your application for certification or in your letter requesting
the exemption.
(f) If you are the original manufacturer of an exempted engine that
is modified by another company under this exemption, we may require you
to send us emission test data on the applicable nonroad duty cycle(s).
If we ask for this data, we will allow a reasonable amount of time to
collect it. You are responsible for emission-related compliance under
40 CFR parts 85 and 86 for these engines, unless another company
becomes the engine manufacturer for these engines (see paragraph (a) of
this section).
(g) If you are not an engine manufacturer, you may produce nonroad
equipment from motor vehicles under this section as long as the engine
has the label we specify in paragraph (c)(5) of this section and you do
not modify the engine in any way that may affect its emission control.
Sec. 1039.615 What special provisions apply to engines using
noncommercial fuels?
In Sec. 1039.115(e), we generally require that engines meet
emission standards for any adjustment within the full range of any
adjustable parameters. For engines that use noncommercial fuels
significantly different than the specified test fuel of the same type,
you may ask us to use the parameter-adjustment provisions of this
section instead of those in Sec. 1039.115(e). Engines certified under
this section must be in a separate engine family.
(a) If we approve your request, you may do the following:
(1) Certify the engine using the specified test fuel.
(2) Produce the engine without limits or stops to keep the engine
adjusted within the certified range.
(3) Specify in-use adjustments different than the adjustable
settings appropriate for the certified test fuel, consistent with the
provisions of paragraph (b)(1) of this section.
(b) To produce engines under this section, you must do the
following:
(1) Specify in-use adjustments needed so the engine's level of
emission control is equivalent to that from the certified
configuration.
(2) Add the following information to the emission control
information label specified in Sec. 1039.135:
(i) Include instructions describing how to adjust the engine to
operate in a way that maintains the effectiveness of the emission-
control system.
(ii) STATE: ``THIS ENGINE IS CERTIFIED TO OPERATE IN APPLICATIONS
USING NONCOMMERCIAL FUEL. mALADJUSTMENT OF THE ENGINE IS A VIOLATION OF
FEDERAL LAW SUBJECT TO CIVIL PENALTY.''.
(3) Keep records to document the destinations and quantities of
engines produced under this section.
Sec. 1039.620 What are the provisions for exempting engines used
solely for competition?
(a) As an equipment manufacturer, you may use an uncertified engine
if your vehicle or equipment will be used solely for competition.
(b) The definition of nonroad engine in 40 CFR 1068.30 excludes
engines used solely for competition. These engines are not required to
comply with this part, but 40 CFR 1068.101 restricts the use of
competition engines for non-competition purposes and this section
requires that you label these engines.
(c) As an engine manufacturer, your engine is exempt without a
request if you have a written request for an exempted engine from the
equipment manufacturer, showing the basis for believing that the
equipment will be used solely for competition.
(d) We consider a vehicle or piece of equipment to be one that will
be used solely for competition if it has features that are not easily
removed that would make its use other than in competition unsafe,
impractical, or highly unlikely.
(e) We may discontinue your exemption if we find that engines
[[Page 28575]]
exempted under this section are not used solely for competition.
(f) You must permanently label engines exempted under this section
to clearly indicate that they are to be used solely for competition.
Failure to properly label an engine will void its exemption.
Sec. 1039.625 What requirements apply under the program for
equipment-manufacturer flexibility?
The provisions of this section allow equipment manufacturers to
produce equipment with engines certified to previous tiers of emission
standards after the Tier 4 emission standards begin to apply. To be
eligible to use these provisions, you must follow all the instructions
in this section. See 40 CFR 89.102(d) and (e) for provisions that apply
to equipment made while Tier 1, Tier 2, or Tier 3 standards apply. See
Sec. 1039.626 for requirements that apply specifically to equipment
manufacturers using the flexibility provisions of this section for
equipment produced outside the United States.
(a) General. We may allow you to introduce into commerce in the
United States limited numbers of nonroad equipment with exempted
engines under this section. These provisions are available up to seven
years after Tier 4 emission standards begin for each engine-power
category, as shown in Table 1 of this section. Consider all U.S.-
directed equipment sales, including those from any parent or subsidiary
companies, in showing that you meet the requirements of this section.
You may use the exemptions in this section only if you have the primary
responsibility for designing and manufacturing the equipment and
install the engine in the equipment.
Table 1 of Sec. 1039.625
------------------------------------------------------------------------
Engine power Model year
------------------------------------------------------------------------
kW < 19................................................. 2008
19 <= kW < 56........................................... 2013
56 <= kW < 130.......................................... 2012
130 <= kW < 560......................................... 2011
kW 560...................................... 2011
------------------------------------------------------------------------
--(b) Allowances. The following provisions, which apply separately
to each engine-power category used to define emission standards in
Sec. 1039.101, describe how many exempted engines you may produce
under this section:
(1) Percent-of-production allowances. You may produce a certain
number of units with exempted engines based on a percentage of your
total sales within an engine-power category. The sum of these
percentages within an engine-power category during the seven-year
period specified in paragraph (a) of this section may not exceed 80
percent of your U.S.-directed production, except as allowed under
paragraph (b)(2) of this section.
(2) Small-volume allowances. You may produce up to 700 units with
exempted engines within an engine-power category during the seven-year
period, with no more than 200 units in any single calendar year within
an engine-power category. This paragraph (b)(2) applies only to engines
from a single engine family within each calendar year.
(c) Percentage calculation. Calculate annually the percentage of
equipment with exempted engines from your total U.S.-directed
production within an engine-power category if you need to show that you
meet the percent-of-production allowances in paragraph (b)(1) of this
section.
(d) Inclusion of engines not subject to Tier 4 standards. The
following provisions apply to engines that are not subject to Tier 4
standards:
(1) If you use the provisions of Sec. 1068.105(a) to use up your
inventories of engines not certified to new emission standards, do not
include these units in your count of equipment with exempted engines
under paragraph (b) of this section.
(2) If you install engines that are exempted from the Tier 4
standards for any reason, other than for equipment-manufacturer
flexibility under this section, do not include these units in your
count of exempted engines under paragraph (b) of this section. For
example, if we grant a hardship exemption for the engine manufacturer,
you do not need to count those as exempted engines under this section.
This paragraph (d)(2) applies only if the engine has a permanent label
describing why it is exempted from the Tier 4 standards.
(3) If the engine's model year or manufacturing date for its
engine-power category precedes the applicability of the Tier 4
standards, you may nevertheless start using the allowances under this
section before the applicability of the Tier 4 standards apply;
however, you may not start using these early allowances before the
seven-year period for using allowances under the Tier 2 or Tier 3
program expires (see 40 CFR 89.102(d)). To use these early allowances,
you must use engines that meet the emission standards described in
paragraph (e) of this section. You must also count these units or
calculate these percentages as described in paragraph (c) of this
section and apply them to the total number or percentage of equipment
with exempted engines we allow for the Tier 4 standards as described in
paragraph (b) of this section. The maximum number of cumulative early
allowances is 10 percent under the percent-of-production allowance or
100 units under the small-volume allowance.
(4) Do not include equipment using model year 2008 or 2009 engines
certified under the provisions of Sec. 1039.101(j) in your count of
equipment using exempted engines.
(e) Standards. If you produce equipment with exempted engines under
this section, the engines must meet less stringent emission standards.
(1) If you are using the provisions of paragraph (d)(3) of this
section, engines must meet the appropriate Tier 1 (or more stringent)
emission standards described in Sec. 89.112.
(2) In all other cases, engines with maximum power from 37 kW up to
560 kW must meet the appropriate Tier 3 standards described in Sec.
89.112. Engines with maximum power below 37 kW or at least 560 kW must
meet the appropriate Tier 2 standards described in Sec. 89.112.
(f) Equipment labeling. You must add a permanent, legible label,
written in block letters in English to the engine or another readily
visible part of each piece of equipment you produce with exempted
engines under this section. This label, which supplements the engine
manufacturer's emission control information label, must include at
least the following items:
(1) The label heading ``EMISSION CONTROL INFORMATION''.
(2) Your corporate name and trademark.
(3) The calendar year in which the equipment is manufactured.
(4) Whom to contact for further information.
(5) The following statement: THIS EQUIPMENT [or identify the type
of equipment] HAS AN ENGINE THAT HAS BEEN EXEMPTED FROM CURRENT FEDERAL
NONROAD EMISSION STANDARDS, AS ALLOWED BY 40 CFR 1039.625.
(g) Notification and reporting. You must notify us of your intent
to use the provisions of this section and send us an annual report to
verify that you are not exceeding the allowances.
(1) Before January 1 of the first year you intend to use the
flexibility provisions of this section, send the Designated Compliance
Officer and the Designated Enforcement Officer a written notice of your
intent, including:
(i) Your company's name and address.
(ii) Whom to contact for more information.
[[Page 28576]]
(iii) The calendar years you expect to use the exemption provisions
of this section.
(iv) The name and address of the company that produces the engines
you will be using for the equipment exempted under this section.
(v) Your best estimate of the number of units in each engine-power
category you will produce under this section in the upcoming calendar
year and whether you intend to comply under paragraph (b)(1) or (b)(2)
of this section.
(vi) The number of units in each engine-power category you have
sold in previous calendar years under 40 CFR 89.102(d).
(2) For each year that you use the flexibility provisions of this
section, send the Designated Compliance Officer and the Designated
Enforcement Officer a written report by March 31 of the following year.
Include in your report the total number of engines you sold in the
preceding year for each engine-power category, based on actual U.S.-
directed production information. Also identify the percentages of U.S.-
directed production that correspond to the number of units in each
engine-power category and the cumulative numbers and percentages of
units for all the units you have sold under this section for each
engine-power category. You may omit the percentage figures if you
include in the report a statement that you will not be using the
percent-of-production allowances in paragraph (b)(1) of this section.
(h) Recordkeeping. Keep the following records of all equipment with
exempted engines you produce under this section for at least five full
years after the final year in which allowances are available for each
engine-power category:
(1) The model number, serial number, and the date of manufacture
for each engine and piece of equipment.
(2) The maximum power of each engine.
(3) The total number or percentage of equipment with exempted
engines, as described in paragraph (b) of this section and all
documentation supporting your calculation.
(4) The notifications and reports we require under paragraph (g) of
this section.
(i) Enforcement. Producing more exempted engines or equipment than
we allow under this section, or installing engines that do not meet the
certification requirements of paragraph (e) of this section, is a
violation of 40 CFR 1068.101(a)(1). You must give us the records we
require under this section if we ask for them (see 40 CFR
1068.101(a)(2)).
(j) Provisions for engine manufacturers. As an engine manufacturer,
you may produce exempted engines as needed under this section. You do
not have to request this exemption for your engines, but you must have
written assurance from equipment manufacturers that they need a certain
number of exempted engines under this section. Send us an annual report
of the engines you produce under this section, as described in Sec.
1039.250(a). The exempted engines must meet less stringent standards,
as described in paragraph (e) of this section. It must also have the
label we require in Sec. 1039.135, with the following additional
statement: ``THIS ENGINE HAS BEEN EXEMPTED FROM CURRENT FEDERAL NONROAD
EMISSION STANDARDS. SELLING OR INSTALLING THIS ENGINE FOR ANY PURPOSE
OTHER THAN FOR THE EQUIPMENT FLEXIBILITY PROVISIONS OF 40 CFR 1039.625
MAY BE A VIOLATION OF FEDERAL LAW SUBJECT TO CIVIL PENALTY.
(k) Other exemptions. See 40 CFR 1068.255 for exemptions based on
hardship for equipment manufacturers and secondary engine
manufacturers.
Sec. 1039.626 What special provisions apply to engines imported under
the equipment-manufacturer flexibility program?
This section identifies requirements that apply specifically to
equipment manufacturers using the flexibility provisions of Sec.
1039.625 for equipment produced outside the United States. For purposes
of this section, only a nonroad equipment manufacturer with primary
responsibility for designing and manufacturing a piece of equipment
that also installs the engine in the equipment is eligible to use the
allowances under Sec. 1039.625. Companies that import equipment into
the U.S., but do not have the primary responsibility for designing and
manufacturing a piece of equipment or do not install the engine in the
equipment are not eligible for these allowances. They may import exempt
equipment if it is covered by an allowance or transition provision
associated with an equipment manufacturer meeting the requirements of
Sec. 1039.625 and this section. As an equipment manufacturer, you may
use the allowances specified in Sec. 1039.625 if you comply with the
provision in Sec. 1039.625 and commit to the following:
(a) Any United States Environmental Protection Agency inspector or
auditor will be given full, complete and immediate access to conduct
inspections and audits of the foreign nonroad equipment manufacturer.
(1) Inspections and audits may be either announced in advance by
EPA, or unannounced.
(2) Access will be provided to any location where:
(i) Nonroad equipment or vehicle is produced;
(ii) Documents related to manufacturer operations are kept; and
(iii) Equipment or vehicles are tested or stored.
(3) Inspections and audits may be by EPA employees or EPA
contractors.
(4) Any documents requested that are related to matters covered by
inspections and audits will be provided to an EPA inspector or auditor
on request.
(5) Inspections and audits by EPA may include review and copying of
any documents related to demonstrating compliance with the exceptions
in Sec. 1039.625.
(6) Inspections and audits by EPA may include taking samples of
equipment or vehicles, and interviewing employees.
(7) Any employee of a foreign nonroad equipment manufacturer will
be made available for interview by the EPA inspector or auditor, on
request, within a reasonable time period.
(8) English language translations of any documents will be provided
to an EPA inspector or auditor, on request, within 10 working days.
(9) English language interpreters will be provided to accompany EPA
inspectors and auditors, on request.
(b) An agent for service of process located in the District of
Columbia will be named, and service on this agent constitutes service
on the foreign nonroad equipment manufacturer or any officer, or
employee of the foreign nonroad equipment manufacturer for any action
by EPA or otherwise by the United States related to the requirements of
this part.
(c) The forum for any civil or criminal enforcement action related
to the provisions of this section for violations of the Clean Air Act
or regulations promulgated thereunder shall be governed by the Clean
Air Act, including the EPA administrative forum where allowed under the
Clean Air Act.
(d) United States substantive and procedural laws shall apply to
any civil or criminal enforcement action against the foreign nonroad
equipment manufacturer or any employee of the foreign nonroad equipment
manufacturer related to the provisions of this section.
(e) Submitting a notification of intention to use any of the
exceptions in Sec. 1039.625 above, producing and exporting equipment
or vehicles to the
[[Page 28577]]
United States for resale, and all other actions to comply with the
requirements of this part constitute actions or activities covered by
and within the meaning of 28 U.S.C. 1605(a)(2), but solely with respect
to actions instituted against the foreign nonroad equipment
manufacturer, its agents, officers, and employees in any court or other
tribunal in the United States for conduct that violates the
requirements of part 1039, including such conduct that violates 18
U.S.C. 1001, Clean Air Act section 113(c)(2), or other applicable
provisions of the Clean Air Act.
(f) The foreign nonroad equipment manufacturer, or its agents,
officers, or employees, will not seek to detain or to impose civil or
criminal remedies against EPA inspectors or auditors, whether EPA
employees or EPA contractors, for actions performed within the scope of
EPA employment related to the provisions of this section.
(g) The commitment required by this section shall be signed by the
owner or president of the foreign nonroad equipment manufacturer
business.
(h) Sovereign immunity. By submitting a notification of its intent
to use the flexibility provision under Sec. 1039.625, or by producing
and exporting for resale to the United States nonroad equipment under
this section, the foreign nonroad equipment manufacturer, its agents,
officers, and employees, without exception, become subject to the full
operation of the administrative and judicial enforcement powers and
provisions of the United States without limitation based on sovereign
immunity, with respect to actions instituted against the foreign
nonroad equipment manufacturer, its agents, officers, and employees in
any court or other tribunal in the United States for conduct that
violates the requirements applicable to the foreign nonroad equipment
manufacturer under this part, including such conduct that violates 18
U.S.C. 1001, section 113(c)(2) of the Clean Air Act, or other
applicable provisions of the Clean Air Act.
(i) English language reports. Any report or other document
submitted to EPA by any foreign nonroad equipment manufacturer shall be
in the English language, or shall include an English language
translation.
Sec. 1039.630 What are the hardship provisions for equipment
manufacturers?
If you qualify for the hardship provisions specified in 40 CFR
1068.255, we may approve your hardship application subject to three
additional conditions:
(a) You must show that you were selling new equipment with engines
that were certified to meet the requirements of 40 CFR part 89 before
2003.
(b) You must show that you have used up the allowances to produce
equipment with exempted engines under Sec. 1039.625.
(c) You may produce engines under this section for up to one year
total (or two years for small-volume manufacturers).
Sec. 1039.635 What are the hardship provisions for engine
manufacturers?
If you qualify for the hardship provisions specified in 40 CFR
1068.245, we may approve a period of delayed compliance for up to two
years total for small-volume manufacturers or one year total for all
other companies. If you qualify for the hardship provisions specified
in 40 CFR 1068.250 for small-volume manufacturers, we may approve a
period of delayed compliance for up to two years total.
Sec. 1039.639 What special provisions apply to engines sold in Guam,
American Samoa, or the Commonwealth of the Northern Mariana Islands?
Engines introduced into commerce in Guam, American Samoa, or the
Commonwealth of the Northern Mariana Islands are subject to the latest
emission standards in 40 CFR 89.112 instead of the Tier 4 standards in
Sec. 1039.101, but only if the engines include the following statement
on the label we require in 40 CFR 89.110 (or on a separate, permanent
label with your corporate name and trademark): ``THIS ENGINE DOES NOT
CONFORM TO U.S. EPA EMISSION REQUIREMENTS IN EFFECT AT THE TIME OF
PRODUCTION AND MAY NOT BE IMPORTED INTO THE UNITED STATES OR ANY
TERRITORY OF THE UNITED STATES EXCEPT GUAM, AMERICAN SAMOA, OR THE
COMMONWEALTH OF THE NORTHERN MARIANA ISLANDS.''. Introducing any such
engine into commerce in any state or territory of the United States
other than Guam, American Samoa, or the Commonwealth of the Northern
Mariana Islands, throughout its lifetime, is a violation of 40 CFR
1068.101(a)(1).
Sec. 1039.645 What special provisions apply to engines used for
transportation refrigeration units?
The provisions of this section apply for engines used in
transportation refrigeration units (TRUs). All other provisions of this
part apply for these engines, except as specified in this section.
(a) Engines used only in TRU applications may be certified using
the following special provisions:
(1) The engines are not required to meet the transient emission
standards of subpart B of this part.
(2) The steady-state emission standards of subpart B apply for
emissions measured over the steady-state test cycle described in
paragraph (b) of this section instead of the otherwise applicable test
cycle described in Appendix I, III, or IV of this part.
(b) The steady-state test cycle for TRU engines is:
Steady-state Cycle for TRU Engines
------------------------------------------------------------------------
Minimum
Observed time in Weighting
Mode No. Engine speed tourqe \1\ mode factors
(minutes)
------------------------------------------------------------------------
1......... Maximum test speed... 75 3.0 0.25
2......... Maximum test speed... 50 3.0 0.25
3......... Intermediate test 75 3.0 0.25
speed.
4......... Intermediate test 50 3.0 0.25
speed.
------------------------------------------------------------------------
\1\ The percent torque is relative to the maximum torque at the given
engine speed.
(c) Engines certified under this section must be certified in a
separate engine family that contains only TRU engines.
(d) You must do the following for each engine certified under this
section:
(1) State on the emission control information label for each engine
that is certified under the provisions of this
[[Page 28578]]
section: ``This engine is certified to operate only in transportation
refrigeration units. Use of this the engine in other applications is a
violation of federal law subject to civil penalty.''.
(2) State in the installation instructions required by Sec.
1039.130 all instructions necessary to ensure that the engine will
operate only in the modes covered by the test cycle described in this
section.
(3) Keep records to document the destinations and quantities of
engines produced under this section.
(e) An engine is not a TRU engine that can be certified under this
section if any of the following are true:
(1) The engine is installed in any equipment other than
refrigeration units for railcars, truck trailers or other freight
vehicles.
(2) The engine operates in any mode not covered by the test cycle
described in this section, except for negligible transitional operation
between two allowable modes. As an example, a thirty-second transition
period would clearly not be considered negligible.
(3) The engine is sold in a configuration that allows the engine to
operate in any mode not covered by the test cycle described in this
section. As an example, this would include an engine sold without a
governor that limited operation to only those modes covered by the test
cycle described in this section.
(4) The engine is subject to Tier 3 or earlier standards, or phase-
out Tier 4 standards.
(f) All engines certified under this section must comply with the
NTE requirements of subpart B of this part. This requirement applies
without regard to whether the engine would otherwise have been subject
to NTE standards if it had not been certified under this section.
Subpart H--Averaging, Banking, and Trading for Certification
Sec. 1039.701 General provisions.
(a) You may average, bank, and trade (ABT) emission credits for
purposes of certification as described in this subpart to show
compliance with the standards of this part. Participation in this
program is voluntary.
(b) The averaging set restrictions that apply are specified in
Sec. 1039.735.
(c) The definitions of Subpart I of this part apply to this
subpart. The following definitions also apply:
(1) Actual credits means credits you have generated that we have
verified in reviewing the final report.
(2) Broker means any entity that facilitates a trade between a
buyer and seller.
(3) Buyer means the entity that receives credits as a result of
trade.
(4) Reserved credits means credits you have generated that we have
not yet verified in reviewing the final report.
(5) Seller means the entity that provides credits during a trade.
(6) Standard means the standard that applies under subpart B of
this part for engines not participating in the ABT program of this
subpart.
(d) Credits generated under this subpart cannot be used to offset
any exceedances above FEL. This applies for all testing, including
certification, SEA, and in-use testing. Note: You may use credits to
allow you to recertify the engine family to a higher FEL that would be
applicable to future production.
(e) Credits can be used in the year they are generated or in future
years. Credits may not be used for past model years.
(f) Engine families that use credits for one or more pollutants,
may not generate positive credits for another pollutant.
Sec. 1039.705 How do I generate and calculate emission credits?
The provisions of this section apply separately for calculating
NOX credits, NMHC+NOX credits, or PM credits.
(a) Calculate positive credits for an engine family that has an FEL
below the applicable standard. Calculate negative credits for an engine
family that has an FEL above the applicable standard.
(b) For each participating engine family, calculate NOX
emission credits, NMHC+NOX emission credits and/or PM
emission credits (positive or negative) according to the following
equation. Round them to the nearest one-hundredth of a megagram (Mg),
using consistent units throughout the equation:
Emission credits = (Std - FEL) x (Volume) x (AvgPR) `` (UL) x
(10-\6\)
Where:
Std = the standard, in grams per kilowatt-hour, that applies under
subpart B of this part for engines not participating in the ABT program
of this subpart.
FEL = the family emission limit for the engine family in grams per
kilowatt-hour.
Volume = the number of nonroad engines eligible to participate in the
averaging, banking, and trading program within the given engine family
during the model year, as described in paragraph (c) of this section.
AvgPR = the average maximum engine power of all of the configurations
within an engine family, calculated on a sales-weighted basis, in
kilowatts.
UL = the useful life for the given engine family, in hours.
(c) Use quarterly projections of production volumes for initial
certification. Compliance at the end of the model year is determined
based on the actual applicable production/sales volumes. Do not include
any of the following engines in your applicable production/sales
volumes:
(1) Engines exempted under subpart G of this part or under part
1068.
(2) Exported engines.
(3) Engines not subject to the requirements of this part, including
engines excluded under Sec. 1039.5.
(4) Engines certified using special test procedures under 40 CFR
1065.10. (Note: this restriction does not apply for engines certified
using alternate test procedures under 40 CFR 1065.10.)
(5) Any other engines, where we indicate elsewhere in this part
1039 that they are not to be included in the calculations of this
subpart.
Sec. 1039.710 How do I average?
(a) Averaging is the exchange of emissions credits among engine
families.
(b) You may certify one or more engine families to an FEL above or
below the applicable standard if you show, at the time of
certification, that the summation of your projected balance of all
emissions credit transactions in that model year is greater than or
equal to zero.
(c) If you certify an engine family to an FEL that exceeds the
applicable standard, you must obtain sufficient emissions credits to
offset the credit shortfall produced by the engine family. Emissions
credits used in averaging to address this shortfall may come from
emissions credits generated from your other engine families in the same
model year, from banked emissions credits, or from emissions credits
obtained through trading.
Sec. 1039.715 How do I bank emission credits?
(a) Banking is the retention of emissions credits by the
manufacturer generating the emissions credits, for use in averaging or
trading in future model years.
(b) In your application for certification, designate any emissions
credits that you intend to bank. These credits will be considered
reserved
[[Page 28579]]
credits. During the model year, and before submittal of the end-of-year
report, credits originally designated for banking may be redesignated
for trading or averaging for the end-of-year report or final report.
(c) Credits designated for banking from the previous model year
that have not been reviewed by EPA may be used in averaging or trading
transactions. However, such credits may be revoked at a later time
following EPA review of the end-of-year or final report or any
subsequent audit actions.
(d) Banked credits are considered actual credits only after the end
of the model year and after EPA has reviewed the end-of-year and final
reports.
Sec. 1039.720 How do I trade emissions credits?
(a) Trading is the exchange of emissions credits between
manufacturers. Trading of emissions credits may only occur within the
same averaging set.
(b) You may trade actual or reserved credits. Credits banked in a
previous model year or credits generated during the model year of the
trading transaction may be used for trading. Traded reserved credits,
such as those generated during the model year of the trading
transaction, remain reserved until we verify them after the end of the
model year. Traded credits may be used for averaging, banking, or
further trading transactions.
(c) If a negative credit balance results from a transaction, both
the buyer and seller are liable, except in cases deemed involving
fraud. Certificates of all engine families participating in a negative
trade may be voided under Sec. 1039.740.
Sec. 1039.725 What records must I keep?
(a) Establish, maintain and keep the following properly organized
and indexed records for each engine family certified using the ABT
program in this subpart:
(1) Model year and EPA engine family.
(2) FELs.
(3) Useful life.
(4) Maximum engine power for each configuration tested.
(5) Projected applicable production/sales volume for the model
year.
(6) Actual applicable production/sales volume for the model year.
(b) Establish, maintain and keep the following properly organized
and indexed records for each engine in the ABT program:
(1) Model year and EPA engine family.
(2) Engine identification number.
(3) Maximum engine power.
(4) Build date and assembly plant.
(5) Purchaser and destination.
(c) Manufacturers involved in trading reserved credits must
maintain the records specified in this paragraph (c) for each engine
family in the trading program. We may ask you to provide this
information on a quarterly basis. This requirement applies with respect
to the following information:
(1) The engine family.
(2) The actual quarterly and cumulative applicable production/sales
volume.
(3) All values required to calculate credits.
(4) The resulting type and number of credits generated/required.
(5) How and where credit surpluses are dispersed.
(6) How and through what means credit deficits are met.
(d) Keep the records required by this section for eight years from
the due date for the end-of-year report. You may use any appropriate
storage formats or media, including paper, microfilm, or computer
diskettes.
(e) Nothing in this section limits our discretion in requiring the
manufacturer to retain additional records or submit information not
specifically required by this section.
(f) Upon request, you must submit to us the information specified
in this section.
Sec. 1039.730 What must I include in my application for
certification?
(a) You must declare in your application your intent to use the
provisions of this subpart for each engine family that will be
certified using the ABT program. You must also declare for which
pollutants you are using ABT, and declare the FELs for your engine
family for those pollutants. Your FELs must comply with the
specifications of subpart B of this part, including the FEL caps. FELs
must be expressed to the same number of decimal places as the
applicable standards.
(b) Include the following in your application for certification:
(1) A statement that, to the best of your belief, you will not have
a negative credit balance for any engine family when all credits are
calculated.
(2) Detailed calculations of projected emission credits (positive
or negative) based on quarterly projections of applicable production/
sales volume. If your engine family will generate positive emission
credits, state specifically where the credits will be applied (e.g., to
which engine family they will be applied in averaging, trading, or if
they will be reserved for banking). If you have negative emission
credits for your engine family, state the source of positive credits
needed to offset the negative credits. Describe the source of credits
by indicating from which engine family (and manufacturer, as
applicable), and by specifying whether the credits are actual or
reserved and whether they come from banking, trading, or from averaging
with your other engine families within the model year.
Sec. 1039.732 What reports must I submit after the end of the model
year?
This section specifies the requirements for submitting the end-of-
year report and the final report. This section specifies in paragraph
(g) an additional report that must be submitted if you are involved in
a trade of credits.
(a)(1) If any of your engine families are certified using the ABT
provisions of this subpart, you must submit the end-of-year report
within 90 days of the end of the model year. The end-of-year report
must include the information specified in this section. We may waive
the requirement to submit the end-of year report, provided you submit
the final report specified in paragraph (a)(2) of this section.
(2) If any of your engine families are certified using the ABT
provisions of this subpart, you must submit the final report within 270
days of the end of the model year. The final report must include the
information specified in this section.
(b) Failure to submit reports on time is a violation of the Act
with respect to each engine.
(c) Your end-of-year and final reports must identify the engine
families for which they apply and must include:
(i) Detailed calculation of emission credits (positive or negative)
based on actual applicable production/sales volumes. Base your
applicable production/sales volumes on the location of first retail
sale. This location is also called the final product purchase location.
A dealership is a typical location for the first retail sale.
(ii) Demonstrate that you have the positive credits needed to
offset any negative credits.
(iii) State whether you will reserve any credits for banking.
(d) Send end-of-year reports to the Designated Compliance Officer.
(e) If you generate credits for banking and you do not send your
end-of-year reports within 90 days after the end of the model year, you
may not use the credits until we receive and review your reports. You
may not use projected credits pending our review.
[[Page 28580]]
(f) Errors discovered in your end-of-year report or final report,
including errors in calculating credits, are corrected as follows:
(1) Any errors discovered in the end-of-year report may be
corrected in the final report up to 270 days from the end of the model
year.
(2) Errors discovered by the manufacturer in the final report may
be corrected up to 270 days from the end of the model year, and credits
will be recalculated.
(3) If we or you determine within 270 days of the end of the model
year, that an error occurred that mistakenly decreased your positive
credits, the error will be corrected and credits will be recalculated.
Such errors will not be corrected if they are determined more than 270
days from of the end of the model year.
(4) In cases where credit balance is negative, if we determine that
an error occurred that mistakenly decreased your balance of credits, we
may, but are not required to, correct the error and recalculate the
credits. This applies whether or not the error was discovered by you.
(5) If we determine at any time, that an error occurred that
mistakenly increased your balance of credits, we will correct the error
and recalculate the credits to decrease your balance. This applies
whether or not the error was discovered by you.
(g) If you trade credits, you must send the Designated Compliance
Officer a report of the trade, within 90 days of any credit trade, that
includes the following information:
(1) The corporate names of the buyer, seller, and any brokers.
(2) Copies of contracts related to credit trading from the buyer,
seller, and broker, as applicable.
(3) The engine families involved in the trade.
(4) The actual quarterly and cumulative applicable production/sales
volume.
(5) The values required to calculate credits as given in Sec.
1039.705.
(6) The resulting type and number of credits generated.
(7) How and where credit surpluses are dispersed; and
(8) How and through what means credit deficits are met.
(h) Include in each report a statement certifying the accuracy and
authenticity of its contents.
Sec. 1039.735 What restrictions apply for using credits?
The following restrictions apply for credit use:
(a) Averaging sets. Credits may be exchanged only within an
averaging set. For Tier 4 engines, there is a single averaging set that
includes all power categories. See paragraph (b) for provisions related
to credits generated relative to earlier tiers of standards.
(b) Credits from a different tier of standards. (1) For purposes of
ABT under this subpart, you may not use credits generated from engines
subject to emission standards under 40 CFR part 89, except as specified
in the following table:
------------------------------------------------------------------------
If the power rating of the
credit-generating engine is . Then you may use the following credits
. . for Tier 4 compliance . . .
------------------------------------------------------------------------
(i) Less than 37 kW.......... Credits from engines subject to emission
standards in 89.112(a) Table 1,
identified as Tier 2.
(ii) At least 37 kW, but less Credits from engines subject to emission
than 560 kW. standards in 89.112(a) Table 1,
identified as Tier 3.
(iii) 560 kW or higher....... Credits from engines subject to emission
standards in 89.112(a) Table 1,
identified as Tier 2.
------------------------------------------------------------------------
(2) Credits generated from marine engines under the provisions of
40 CFR part 89 may not used under this part.
(3) Credits generated from nonmarine engines under the provisions
of 40 CFR part 89 allowed to be used under this part are subject to the
averaging set restrictions described in 40 CFR 89.204. This means that
credits generated by engines at or above 19 kW may not be used by
engines less than 19 kW, and credits generated by engines less than 19
kW may not be used by engines at or above 19 kW.
(4) See 40 CFR part 89 for other restrictions that may apply for
use of credits generated under that part.
(c) NOX and NMHC + NOX credits. You may use
NOX credits to show compliance with NMHC+NOX
standards. You may use NMHC+NOX credits to show compliance
with NOX standards, but you must adjust the
NMHC+NOX credits downward by twenty percent when you use
them, as shown in the following equation:
NOX credits = (0.8) x (NMHC+NOX credits).
(d) Other restrictions. Other sections of this part may include ABT
restrictions for engines certified under certain special provisions.
Those restrictions apply as specified.
Sec. 1039.740 What can happen if I do not comply with the provisions
of this subpart?
(a)(1) All certificates issued for engine family participating in
this ABT program are conditional upon your full compliance with the
provisions of this subpart during the model year of production and
afterwards.
(2) Failure to comply with any provisions of this subpart will be
deemed to be a failure to satisfy the conditions upon which the
certificate was issued, and the certificate may be voided.
(3) By choosing to participate in this ABT program, you are
responsible to establish to EPA's satisfaction that the conditions
under which the certificate was issued were satisfied or waived.
(b) You may certify your engine family to an FEL above a applicable
standard based on a projection that you will have sufficient credits to
offset the credit deficit for the engine family. However, if you cannot
show in your final report that you have sufficient actual credits to
offset a credit deficit for any engine family, we may void the
certificate of conformity for the engine family.
(c) We may void the certificate of conformity for an engine family
for which you fail to retain the records required in this subpart or to
provide such information to us upon request.
Subpart I--Definitions and Other Reference Information
Sec. 1039.801 What definitions apply to this part?
The following definitions apply to this part. The definitions apply
to all subparts unless we note otherwise. All undefined terms have the
meaning the Act gives to them. The definitions follow:
Act means the Clean Air Act, as amended, 42 U.S.C. 7401 et seq.
Adjustable parameter means any device, system, or element of design
that someone can adjust (including those which are difficult to access)
and that, if adjusted, may affect emissions or engine performance
during emission testing or normal in-use operation. This includes, but
is not limited to parameters related to injection timing and fueling
rate. You may ask us to exclude a parameter that is difficult to
[[Page 28581]]
access if it cannot be adjusted to affect emissions without
significantly degrading performance, or if you otherwise show us that
it will not be adjusted in a way that affects emissions during in-use
operation.
Aftertreatment means relating to any system, component, or
technology mounted downstream of the exhaust valve or exhaust port
whose design function is to reduce exhaust emissions.
Aircraft has the meaning given in 40 CFR 87.1.
Auxiliary emission control device means any element of design that
senses temperature, motive speed, engine RPM, transmission gear, or any
other parameter for the purpose of activating, modulating, delaying, or
deactivating the operation of any part of the emission control system.
Blue Sky Series engine means an engine meeting the requirements of
Sec. 1039.140.
Brake power means the usable power output of the engine, not
including power required to operate fuel pumps, oil pumps, or coolant
pumps.
Broker means any entity that facilitates a trade of emission
credits between a buyer and seller.
Calibration means the set of specifications and tolerances specific
to a particular design, version, or application of a component or
assembly capable of functionally describing its operation over its
working range.
Certification means obtaining a certificate of conformity for an
engine family that complies with the emission standards and
requirements in this part.
Certified emission level means the highest deteriorated emission
level in an engine family for a given pollutant from either transient
or steady-state testing.
Compression-ignition means relating to a type of reciprocating,
internal-combustion engine that is not a spark-ignition engine.
Constant-speed means relating to an engine governed to operate at
rated speed.
Crankcase emissions means airborne substances emitted to the
atmosphere from any part of the engine crankcase's ventilation or
lubrication systems. The crankcase is the housing for the crankshaft
and other related internal parts.
Designated Compliance Officer means the Manager, Engine Programs
Group (6405-J), U.S. Environmental Protection Agency, 1200 Pennsylvania
Ave., Washington, DC 20460.
Designated Enforcement Officer means the Director, Air Enforcement
Division (2242A), U.S. Environmental Protection Agency, 1200
Pennsylvania Ave., NW., Washington, DC 20460.
Deteriorated emission level means the emission level that results
from applying the applicable deterioration factor to the official
emission result of the emission-data engine.
Deterioration factor means a number that is added to or multiplied
by a low-hour test result to project the emission rate at the end of
the useful life.
Emission-control system means any device, system, or element of
design that controls or reduces the regulated emissions from an engine.
Emission-data engine means an engine that is tested for
certification.
Emission-related maintenance means maintenance that substantially
affects emissions or is likely to substantially affect emissions
deterioration.
Engine family means a group of engines with similar emission
characteristics, as specified in Sec. 1039.230.
Engine manufacturer means the manufacturer of the engine. See the
definition of ``manufacturer'' in this section.
Engine used in a locomotive means either an engine placed in the
locomotive to move other equipment, freight, or passenger traffic; or
an engine mounted on the locomotive to provide auxiliary power.
Exempted means relating to an engine that is not required to meet
otherwise applicable standards because the engine conforms to
regulatory conditions specified for an exemption in this part 1039 or
in part 1068 of this chapter. Exempted engines are deemed to be
``subject to'' the standards of this part, even though they are not
required to comply with the otherwise applicable requirements. Engines
exempted with respect to a certain tier of standards may be required to
comply with an earlier tier of standards as a condition of the
exemption; for example, engines exempted with respect to Tier 4
standards may be required to comply with Tier 3 standards.
Excluded means relating to an engine that either:
(1) Has been determined not to be a nonroad engine, as specified in
40 CFR 1068.30; or
(2) Is a nonroad engine that, according to Sec. 1039.5, is not
subject to this part 1039.
Exhaust-gas recirculation means an emission-control technology that
reduces emissions by routing exhaust gases that had been exhausted from
the combustion chamber(s) back into the engine to be mixed with
incoming air prior to or during combustion. The use of valve timing to
increase the amount of residual exhaust gas in the combustion
chamber(s) that is mixed with incoming air prior to or during
combustion is not considered to be exhaust-gas recirculation for the
purposes of this part.
Family emission limit (FEL) means an emission level declared by the
manufacturer to serve in place of an emission standard for
certification under the emission-credit program in subpart H of this
part. The family emission limit must be expressed to the same number of
decimal places as the emission standard it replaces.
Fuel system means all components involved in transporting,
metering, and mixing the fuel from the fuel tank to the combustion
chamber(s), including the fuel tank, fuel tank cap, fuel pump, fuel
filters, fuel lines, carburetor or fuel-injection components, and all
fuel-system vents.
Fuel type means a general category of fuels such as diesel fuel or
natural gas. There can be multiple grades within a single type of fuel,
such as No. 1 diesel and No. 2 diesel.
Good engineering judgment has the meaning we give in 40 CFR 1068.5.
Hydrocarbon (HC) means the hydrocarbon group on which the emission
standards are based for each fuel type. For petroleum-fueled engines
and natural gas-fueled engines, HC means nonmethane hydrocarbon (NMHC).
For alcohol-fueled engines, HC means total hydrocarbon equivalent
(THCE).
Identification number means a unique specification (for example,
model number/serial number combination) that allows someone to
distinguish a particular engine from other similar engines.
Intermediate test speed has the meaning we give in 40 CFR 1065.515.
Manufacture means the physical and engineering process of
designing, constructing, and assembling of a nonroad engine or a piece
of nonroad equipment.
Manufacturer has the meaning given in section 216(1) of the Act. In
general, this term includes any person who manufactures an engine,
vehicle, or piece of equipment for sale in the United States or
otherwise introduces a new nonroad engine into commerce in the United
States. This includes importers who import engines, equipment, or
vehicles for resale. (Note: In Sec. 1039.626, the term ``equipment
manufacturer'' has a more narrow meaning; that narrow meaning only
applies to that section.)
Marine engine means an engine that someone installs or intends to
install on a marine vessel. There are two kinds of marine engines:
[[Page 28582]]
(1) Propulsion marine engine means a marine engine that moves a
vessel through the water or directs the vessel's movement.
(2) Auxiliary marine engine means a marine engine not used for
propulsion.
Marine vessel means a vehicle that is capable of operation in water
but is not capable of operation out of water. Amphibious vehicles are
not marine vessels.
Maximum engine power means the measured maximum brake power output
of an engine. The maximum engine power of an engine configuration is
the average maximum engine power of the engines within the
configuration. The maximum engine power of an engine family is the
highest maximum engine power of the engine configurations within the
family. (Note: Sec. 1039.230 generally prohibits grouping engines from
different power categories in the same engine family.)
Maximum test speed has the meaning we give in 40 CFR 1065.515.
Maximum test torque has the meaning we give in 40 CFR 1065.1001.
Model year means one of the following things:
(1) For freshly manufactured engines (see definition of ``new
nonroad engine,'' paragraph (1)), model year means one of the
following:
(i) Calendar year.
(ii) Your annual new model production period if it is different
than the calendar year. This must include January 1 of the calendar
year for which the model year is named. It may not begin before January
2 of the previous calendar year and it must end by December 31 of the
named calendar year.
(2) For an engine that is converted to a nonroad engine after being
placed into service in a motor vehicle, model year means the calendar
year in which the engine was originally produced (see definition of
``new nonroad engine,'' paragraph (2)).
(3) For a nonroad engine excluded under Sec. 1039.5 that is later
converted to operate in an application that is not excluded, model year
means the calendar year in which the engine was originally produced
(see definition of ``new nonroad engine,'' paragraph (3)).
(4) For engines that are not freshly manufactured but are installed
in new nonroad equipment, model year means the calendar year in which
the engine is installed in the new nonroad equipment. This installation
date is based on the time that final assembly of the equipment is
complete (see definition of ``new nonroad engine,'' paragraph (4)).
(5) For an engine modified by an importer (not the original engine
manufacturer) who has a certificate of conformity for the imported
engine (see definition of ``new nonroad engine,'' paragraph (5)), model
year means one of the following:
(i) The calendar year in which the importer finishes modifying and
labeling the engine.
(ii) Your annual production period for producing engines if it is
different than the calendar year; follow the guidelines in paragraph
(1)(ii) of this definition.
(6) For an engine you import that does not meet the criteria in
paragraphs (1) through (5) of the definition of ``new nonroad engine,''
model year means the calendar year in which the engine manufacturer
completed the original assembly of the engine. In general, this applies
to used equipment that you import without conversion or major
modification.
Motor vehicle has the meaning we give in 40 CFR 85.1703(a). In
general, motor vehicle means a self-propelled vehicle that can
transport one or more people or any material, but doesn't include any
of the following:
(1) Vehicles having a maximum ground speed over level, paved
surfaces no higher than 40 km per hour (25 miles per hour).
(2) Vehicles that lack features usually needed for safe, practical
use on streets or highways--for example, safety features required by
law, a reverse gear (except for motorcycles), or a differential.
(3) Vehicles whose operation on streets or highways would be
unsafe, impractical, or highly unlikely. Examples are vehicles with
tracks instead of wheels, very large size, or features associated with
military vehicles, such as armor or weaponry.
New nonroad engine means any of the following things:
(1) A freshly manufactured nonroad engine for which the ultimate
purchaser has never received the equitable or legal title. This kind of
vehicle might commonly be thought of as ``brand new.'' In the case of
this paragraph (1), the engine is no longer new when the ultimate
purchaser receives this title or the product is placed into service,
whichever comes first.
(2) An engine originally manufactured as a motor vehicle engine
that is later intended to be used in a piece of nonroad equipment. In
this case, the engine is no longer a motor vehicle engine and becomes a
``new nonroad engine''. The engine is no longer new when it is placed
into nonroad service.
(3) A nonroad engine that has been previously placed into service
in an application we exclude under Sec. 1039.5, where that engine is
installed in a piece of equipment for which these exclusions do not
apply. The engine is no longer new when it is placed into nonroad
service. For example, this would apply to a stationary engine that is
no longer used in a stationary application.
(4) An engine not covered by paragraphs (1) through (3) of this
definition that is intended to be installed in new nonroad equipment.
The engine is no longer new when the ultimate purchaser receives a
title for the equipment or the product is placed into service,
whichever comes first. This generally includes installation of used
engines in new equipment.
(5) An imported nonroad engine covered by a certificate of
conformity issued under this part, where someone other than the
original engine manufacturer modifies the engine after its initial
assembly and holds the certificate. The engine is no longer new when it
is placed into nonroad service.
(6) An imported nonroad engine that is not covered by a certificate
of conformity issued under this part at the time of importation. This
addresses uncertified engines and vehicles that have been placed into
service in other countries and that someone seeks to import into the
United States. Importation of this kind of new nonroad engine (or
vehicle containing such an engine) is generally prohibited by 40 CFR
part 1068.
New nonroad equipment means either of the following things:
(1) A nonroad vehicle or other piece of equipment for which the
ultimate purchaser has never received the equitable or legal title. The
product is no longer new when the ultimate purchaser receives this
title or the product is placed into service, whichever comes first.
(2) An imported nonroad piece of equipment with an engine not
covered by a certificate of conformity issued under this part at the
time of importation and manufactured after the date for applying the
requirements of this part.
Noncommercial fuel means a fuel that is not marketed or sold as a
commercial product. For example, this includes methane produced and
released from landfills or oil wells.
Noncompliant engine means an engine that was originally covered by
a certificate of conformity, but is not in the certified configuration
or otherwise does not comply with the conditions of the certificate.
Nonconforming engine means an engine not covered by a certificate
of
[[Page 28583]]
conformity that would otherwise be subject to emission standards.
Nonmethane hydrocarbon means the difference between the emitted
mass of total hydrocarbons and the emitted mass of methane.
Nonroad means relating to nonroad engines or equipment that
includes nonroad engines.
Nonroad engine has the meaning given in 40 CFR 1068.30. In general
this means all internal-combustion engines except motor vehicle
engines, stationary engines, or engines used solely for competition.
This part does not apply to all nonroad engines (see Sec. 1039.5).
Nonroad equipment means a vehicle or piece of equipment that is
powered by one or more nonroad engines.
Nonroad equipment manufacturer means any person engaged in
manufacturing or assembling new nonroad vehicles or equipment or
importing such vehicles or equipment for resale. This includes any
person who acts for and is under the control of any such person in
connection with distributing such vehicles or equipment. A nonroad
vehicle or equipment manufacturer does not include any dealer with
respect to new nonroad vehicles or equipment received by such person in
commerce. A nonroad equipment manufacturer does not include any person
engaged in the manufacturing or assembling of new nonroad vehicles or
equipment who does not install an engine as part of that manufacturing
or assembling process. All nonroad vehicle or equipment manufacturing
entities under the control of the same person are considered to be a
single nonroad equipment manufacturer.
Official emission result means the measured emission rate for a
test engine on a given duty cycle before the application of any
deterioration factor, but after the applicability of regeneration
adjustment factors.
Opacity means the fraction of a beam of light, expressed in
percent, which fails to penetrate a plume of smoke.
Oxides of nitrogen has the meaning given it in 40 CFR part 1065.
Particulate trap means a filtering device that is designed to
physically trap all particulate matter above a certain size.
Placed into service means used for its intended purpose.
Point of first retail sale means the location at which the retail
sale occurs. This generally means a dealership.
Power category means a specific range maximum engine power that
defines the applicability of standards. For example, the 56-130 kW
power category includes all engines with maximum power of at least 56
kW but less than 130 kW. See Sec. 1039.101 for a list of specific
power categories. (Note: In some cases, FEL caps are based on
subcategories of power categories.)
Rated speed means the maximum full load governed speed for governed
engines and the speed of maximum horsepower for ungoverned engines.
Revoke means to discontinue the certificate for an engine family.
If we revoke a certificate, you must apply for a new certificate before
continuing to produce the affected engines. This does not apply to
engines you no longer possess.
Round means to round numbers according to ASTM E29-02 (incorporated
by reference in Sec. 1039.810), unless otherwise specified.
Scheduled maintenance means adjusting, repairing, removing,
disassembling, cleaning, or replacing components or systems that is
periodically needed to keep a part from failing or malfunctioning. It
also may mean actions you expect are necessary to correct an overt
indication of failure or malfunction for which periodic maintenance is
not appropriate.
Small-volume engine manufacturer means an engine manufacturer that
had engine families certified to meet the requirements of 40 CFR part
89 before 2003 and had annual U.S.-directed production of no more than
2,500 units in 2002 and all earlier calendar years. For manufacturers
owned by a parent company, the limit applies to the production of the
parent company and all of its subsidiaries.
Spark-ignition means relating to a gasoline-fueled engine or any
other type of engine with a spark plug (or other sparking device) and
with operating characteristics significantly similar to the theoretical
Otto combustion cycle. Spark-ignition engines usually use a throttle to
regulate intake air flow to control power during normal operation.
Suspend means to temporarily discontinue the certificate for an
engine family. If we suspend a certificate, you may not sell engines
from that engine family unless we reinstate the certificate or approve
a new one.
Test engine means an engine in a test sample.
Test sample means the collection of engines selected from the
population of an engine family for emission testing.
Tier 1 means relating to the Tier 1 emission standards, as shown in
40 CFR 89.112.
Tier 2 means relating to the Tier 2 emission standards, as shown in
40 CFR 89.112.
Tier 3 means relating to the Tier 3 emission standards, as shown in
40 CFR 89.112.
Tier 4 means relating to the Tier 4 emission standards, as shown in
Sec. 1039.101. This includes the emission standards for all pollutants
if an engine is subject to Tier 4 emission standards for any pollutant.
For example, this includes the Tier 3 HC+NOX standard during
the phase-in period when engines are subject to the Tier 4 PM standard.
Total hydrocarbon means the combined mass organic compounds
measured by our total hydrocarbon test procedure, expressed as a
hydrocarbon with a hydrogen-to-carbon mass ratio of 1.85:1.
Total hydrocarbon equivalent means the sum of the carbon mass
contributions of non-oxygenated hydrocarbons, alcohols and aldehydes,
or other organic compounds that are measured separately as contained in
a gas sample, expressed as petroleum-fueled engine hydrocarbons. The
hydrogen-to-carbon ratio of the equivalent hydrocarbon is 1.85:1.
Ultimate purchaser means, with respect to any new nonroad equipment
or new nonroad engine, the first person who in good faith purchases
such new nonroad equipment or new nonroad engine for purposes other
than resale.
United States means the States, the District of Columbia, the
Commonwealth of Puerto Rico, the Commonwealth of the Northern Mariana
Islands, Guam, American Samoa, and the U.S. Virgin Islands.
Upcoming model year means for an engine family the model year after
the one currently in production.
U.S.-directed production volume means the number of engine units,
subject to the requirements of this part, produced by a manufacturer
for which the manufacturer has a reasonable assurance that sale was or
will be made to ultimate purchasers in the United States.
Useful life means the period during which the engine is designed to
properly function in terms of reliability and fuel consumption, without
being remanufactured, specified as a number of hours of operation or
calendar years. It is the period during which a new nonroad engine is
required to comply with all applicable emission standards. See Sec.
1039.101(g).
Variable-speed engine means an engine that is not a constant-speed
engine.
Void means to invalidate a certificate or an exemption. If we void
a certificate, all the engines produced under that engine family for
that model year are
[[Page 28584]]
considered noncompliant, and you are liable for each engine produced
under the certificate and may face civil or criminal penalties or both.
This applies equally to all engines in the engine family including
engines produced before we voided the certificate. If we void an
exemption, all the engines produced under that exemption are considered
uncertified (or nonconforming), and you are liable for each engine
produced under the exemption and may face civil or criminal penalties
or both. You may not produce any additional engines using the voided
exemption.
Volatile liquid fuel means any fuel other than diesel or biodiesel
that is a liquid at atmospheric pressure and has a Reid Vapor Pressure
higher than 2.0 psi.
We (us, our) means the Administrator of the Environmental
Protection Agency and any authorized representatives.
Sec. 1039.805 What symbols, acronyms, and abbreviations does this
part use?
The following symbols, acronyms, and abbreviations apply to this
part:
[deg]C degrees Celsius.
ASTM American Society for Testing and Materials.
cc cubic centimeters.
CFR Code of Federal Regulations.
CI compression-ignition.
cm centimeter.
CO carbon monoxide.
CO2 carbon dioxide.
EPA Environmental Protection Agency.
FEL Family Emission Limit.
g/kW-hr grams per kilowatt-hour.
HC hydrocarbon.
ISO International Organization for Standardization.
kPa kilopascals.
kW kilowatts.
m meters.
MIL malfunction-indicator light.
mm Hg millimeters of mercury.
NMHC nonmethane hydrocarbons.
NOX oxides of nitrogen (NO and NO2).
psi pounds per square inch of absolute pressure.
psig pounds per square inch of gauge pressure.
rpm revolutions per minute.
SAE Society of Automotive Engineers.
SI spark-ignition.
THC total hydrocarbon.
THCE total hydrocarbon equivalent.
TRU transportation refrigeration unit
U.S.C. United States Code.
Sec. 1039.810 What materials does this part reference?
We have incorporated by reference the documents listed in this
section. The Director of the Federal Register approved the
incorporation by reference as prescribed in 5 U.S.C. 552(a) and 1 CFR
part 51. Anyone may inspect copies at the U.S. EPA, Air and Radiation
Docket and Information Center, 1301 Constitution Ave., NW., Room B102,
EPA West Building, Washington, DC 20460 or the Office of the Federal
Register, 800 N. Capitol St., NW., 7th Floor, Suite 700, Washington,
DC.
(a) ASTM material. Table 1 of Sec. 1039.810 lists material from
the American Society for Testing and Materials that we have
incorporated by reference. The first column lists the number and name
of the material. The second column lists the sections of this part
where we reference it. Anyone may purchase copies of these materials
from the American Society for Testing and Materials, 100 Barr Harbor
Dr., West Conshohocken, PA 19428. Table 1 follows:
Table 1 of Sec. 1039.810.--ASTM Materials
------------------------------------------------------------------------
Part 1039
Document number and name reference
------------------------------------------------------------------------
ASTM E29-02, Standard Practice for Using Significant Digits 1039.801
in Test Data to Determine Conformance with Specifications.
------------------------------------------------------------------------
(b) SAE material. Table 2 of Sec. 1039.810 lists material from the
Society of Automotive Engineering that we have incorporated by
reference. The first column lists the number and name of the material.
The second column lists the sections of this part where we reference
it. Anyone may purchase copies of these materials from the Society of
Automotive Engineers, 400 Commonwealth Drive, Warrendale, PA 15096.
Table 2 follows:
Table 2 of Sec. 1039.810.--SAE Materials
------------------------------------------------------------------------
Part 1039
Document number and name reference
------------------------------------------------------------------------
SAE J1930, Electrical/Electronic Systems Diagnostic Terms, 1039.135
Definitions, Abbreviations, and Acronyms, May 1998.
------------------------------------------------------------------------
Sec. 1039.815 How should I request EPA to keep my information
confidential?
(a) Clearly show what you consider confidential by marking,
circling, bracketing, stamping, or some other method. We will store
your confidential information as described in 40 CFR part 2. Also, we
will disclose it only as specified in 40 CFR part 2.
(b) If you send us a second copy without the confidential
information, we will assume it contains nothing confidential whenever
we need to release information from it.
(c) If you send us information without claiming it is confidential,
we may make it available to the public without further notice to you,
as described in 40 CFR 2.204.
Sec. 1039.820 How do I request a hearing?
See 40 CFR part 1068, subpart G, for information related to
hearings.
Appendix I to Part 1039.--Nonroad Compression-Ignition (CI) Steady-State
Cycle for Constant-Speed Engines
------------------------------------------------------------------------
Minimum
time in Weighting
Mode No. Engine speed Torque \1\ mode factors
(minutes)
------------------------------------------------------------------------
1......... Maximum test......... 100 3.0 0.05
2......... Maximum test......... 75 3.0 0.25
3......... Maximum test......... 50 3.0 0.30
4......... Maximum test......... 25 3.0 0.30
[[Page 28585]]
5......... Maximum test......... 10 3.0 0.10
------------------------------------------------------------------------
\1\ The percent torque is relative to the maximum torque at maximum test
speed.
Appendix II to Part 1039--[Reserved]
Appendix III to Part 1039.--Nonroad Compression-Ignition (CI) Steady-
State Cycle for Variable-Speed Engines With Maximum Power Below 19 kW
------------------------------------------------------------------------
Minimum
Observed time in Weighting
Mode No. Engine speed torque \1\ mode factors
(minutes)
------------------------------------------------------------------------
1......... Maximum text speed... 100 3.0 0.09
2......... Maximum test speed... 75 3.0 0.20
3......... Maximum test speed... 50 3.0 0.29
4......... Maximum test speed... 25 3.0 0.30
5......... Maximum test speed... 10 3.0 0.07
6......... Idle................. 0 3.0 0.05
------------------------------------------------------------------------
\1\ The percent torque is relative to the maximum torque at maximum test
speed.
Appendix IV to Part 1039--Nonroad Compression-Ignition (CI) Steady-state
Cycle for Variable-Speed Engines With Maximum Power at or Above 19 kW
------------------------------------------------------------------------
Minimum
Observed time in Weighting
Mode No. Engine speed torque \1\ mode factors
(minutes)
------------------------------------------------------------------------
1......... Maximum test speed... 100 3.0 0.15
2......... Maximum test speed... 75 3.0 0.15
3......... Maximum test speed... 50 3.0 0.15
4......... Maximum test speed... 10 3.0 0.10
5......... Intermediate test 100 3.0 0.10
speed.
6......... Intermediate test 75 3.0 0.10
speed.
7......... Intermediate test 50 3.0 0.10
speed.
8......... Idle................. 0 3.0 0.15
------------------------------------------------------------------------
\1\ The percent torque is relative to the maximum torque at the given
engine speed.
Appendix V to Part 1039.--Nonroad Compression-Ignition (CI) Transient
Cycle for Constant-Speed Engines
------------------------------------------------------------------------
Normalized Normalized
Time (s) speed torque
(percent) (percent)
------------------------------------------------------------------------
1............................................... 58 5
2............................................... 58 5
3............................................... 58 5
4............................................... 58 5
5............................................... 58 5
6............................................... 58 5
7............................................... 58 5
8............................................... 58 5
9............................................... 58 5
10.............................................. 58 5
11.............................................. 58 5
12.............................................. 58 5
13.............................................. 58 5
14.............................................. 58 5
15.............................................. 58 5
16.............................................. 58 5
17.............................................. 58 5
18.............................................. 58 5
19.............................................. 58 5
20.............................................. 58 5
21.............................................. 65 8
22.............................................. 72 11
23.............................................. 79 14
24.............................................. 86 17
25.............................................. 93 20
26.............................................. 93 20
27.............................................. 93 20
28.............................................. 93 20
29.............................................. 93 20
30.............................................. 93 20
31.............................................. 93 20
32.............................................. 94 20
33.............................................. 94 22
34.............................................. 94 23
35.............................................. 93 23
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1036............................................ 93 16
1037............................................ 93 17
1038............................................ 93 16
1039............................................ 93 17
1040............................................ 93 18
1041............................................ 93 17
1042............................................ 93 16
1043............................................ 93 17
1044............................................ 93 17
1045............................................ 93 22
1046............................................ 93 19
1047............................................ 93 19
1048............................................ 95 21
1049............................................ 95 16
1050............................................ 95 12
1051............................................ 95 10
1052............................................ 96 8
1053............................................ 96 7
1054............................................ 95 7
1055............................................ 96 7
1056............................................ 95 6
1057............................................ 96 6
1058............................................ 96 6
1059............................................ 88 5
1060............................................ 89 49
1061............................................ 93 34
1062............................................ 93 27
1063............................................ 93 26
1064............................................ 93 25
1065............................................ 93 22
1066............................................ 93 23
1067............................................ 93 21
1068............................................ 93 21
1069............................................ 93 23
1070............................................ 93 23
1071............................................ 93 23
1072............................................ 93 23
1073............................................ 93 23
1074............................................ 93 22
1075............................................ 93 22
1076............................................ 93 24
1077............................................ 93 23
1078............................................ 93 23
1079............................................ 93 21
1080............................................ 93 19
1081............................................ 93 20
1082............................................ 93 20
1083............................................ 93 22
1084............................................ 93 26
1085............................................ 93 21
1086............................................ 93 20
1087............................................ 93 18
1088............................................ 93 22
1089............................................ 93 20
1090............................................ 94 27
1091............................................ 93 22
1092............................................ 93 23
1093............................................ 93 21
1094............................................ 93 22
1095............................................ 95 22
1096............................................ 95 16
1097............................................ 95 12
1098............................................ 95 10
1099............................................ 95 9
1100............................................ 95 7
1101............................................ 96 7
1102............................................ 95 7
1103............................................ 95 6
1104............................................ 92 42
1105............................................ 93 36
1106............................................ 93 33
1107............................................ 92 60
1108............................................ 93 48
1109............................................ 93 36
1110............................................ 93 30
1111............................................ 93 28
1112............................................ 93 24
1113............................................ 93 24
1114............................................ 93 23
1115............................................ 93 23
1116............................................ 93 25
1117............................................ 93 27
1118............................................ 93 29
1119............................................ 93 26
1120............................................ 93 26
1121............................................ 93 21
1122............................................ 93 23
1123............................................ 93 23
1124............................................ 94 23
1125............................................ 93 40
1126............................................ 94 67
1127............................................ 93 46
1128............................................ 93 38
1129............................................ 93 29
1130............................................ 93 28
1131............................................ 93 27
1132............................................ 93 29
1133............................................ 93 28
1134............................................ 94 33
1135............................................ 93 31
1136............................................ 93 30
1137............................................ 94 42
1138............................................ 93 31
1139............................................ 93 29
1140............................................ 93 27
1141............................................ 93 23
1142............................................ 93 23
1143............................................ 93 20
1144............................................ 93 20
1145............................................ 93 23
1146............................................ 93 22
1147............................................ 93 23
1148............................................ 93 25
1149............................................ 93 20
1150............................................ 93 25
1151............................................ 93 23
1152............................................ 93 23
1153............................................ 93 24
1154............................................ 93 28
1155............................................ 93 23
1156............................................ 93 24
1157............................................ 93 34
1158............................................ 93 31
1159............................................ 93 35
1160............................................ 93 31
1161............................................ 93 32
1162............................................ 93 31
1163............................................ 93 30
1164............................................ 93 23
1165............................................ 93 23
1166............................................ 93 36
1167............................................ 93 32
1168............................................ 93 25
1169............................................ 93 31
1170............................................ 93 33
1171............................................ 93 33
1172............................................ 93 33
1173............................................ 93 33
1174............................................ 93 33
1175............................................ 93 33
1176............................................ 86 28
1177............................................ 79 21
1178............................................ 72 16
1179............................................ 65 10
1180............................................ 58 5
1181............................................ 58 5
1182............................................ 58 5
1183............................................ 58 5
1184............................................ 58 5
1185............................................ 58 5
1186............................................ 58 5
1187............................................ 58 5
1188............................................ 58 5
1189............................................ 58 5
1190............................................ 58 5
1191............................................ 58 5
1192............................................ 58 5
1193............................................ 58 5
1194............................................ 58 5
1195............................................ 58 5
1196............................................ 58 5
1197............................................ 58 5
1198............................................ 58 5
1199............................................ 58 5
------------------------------------------------------------------------
Appendix VI to Part 1039.--Nonroad Compression-Ignition (CI) Composite
Transient Cycle
------------------------------------------------------------------------
Normalized Normalized
Time (s) speed torque
(percent) (percent)
------------------------------------------------------------------------
1............................................... 0 0
2............................................... 0 0
3............................................... 0 0
4............................................... 0 0
5............................................... 0 0
6............................................... 0 0
7............................................... 0 0
8............................................... 0 0
9............................................... 0 0
10.............................................. 0 0
11.............................................. 0 0
12.............................................. 0 0
13.............................................. 0 0
14.............................................. 0 0
15.............................................. 0 0
16.............................................. 0 0
17.............................................. 0 0
18.............................................. 0 0
19.............................................. 0 0
20.............................................. 0 0
21.............................................. 0 0
22.............................................. 0 0
23.............................................. 0 0
[[Page 28592]]
24.............................................. 1 3
25.............................................. 1 3
26.............................................. 1 3
27.............................................. 1 3
28.............................................. 1 3
29.............................................. 1 3
30.............................................. 1 6
31.............................................. 1 6
32.............................................. 2 1
33.............................................. 4 13
34.............................................. 7 18
35.............................................. 9 21
36.............................................. 17 20
37.............................................. 33 42
38.............................................. 57 46
39.............................................. 44 33
40.............................................. 31 0
41.............................................. 22 27
42.............................................. 33 43
43.............................................. 80 49
44.............................................. 105 47
45.............................................. 98 70
46.............................................. 104 36
47.............................................. 104 65
48.............................................. 96 71
49.............................................. 101 62
50.............................................. 102 51
51.............................................. 102 50
52.............................................. 102 46
53.............................................. 102 41
54.............................................. 102 31
55.............................................. 89 2
56.............................................. 82 0
57.............................................. 47 1
58.............................................. 23 1
59.............................................. 1 3
60.............................................. 1 8
61.............................................. 1 3
62.............................................. 1 5
63.............................................. 1 6
64.............................................. 1 4
65.............................................. 1 4
66.............................................. 0 6
67.............................................. 1 4
68.............................................. 9 21
69.............................................. 25 56
70.............................................. 64 26
71.............................................. 60 31
72.............................................. 63 20
73.............................................. 62 24
74.............................................. 64 8
75.............................................. 58 44
76.............................................. 65 10
77.............................................. 65 12
78.............................................. 68 23
79.............................................. 69 30
80.............................................. 71 30
81.............................................. 74 15
82.............................................. 71 23
83.............................................. 73 20
84.............................................. 73 21
85.............................................. 73 19
86.............................................. 70 33
87.............................................. 70 34
88.............................................. 65 47
89.............................................. 66 47
90.............................................. 64 53
91.............................................. 65 45
92.............................................. 66 38
93.............................................. 67 49
94.............................................. 69 39
95.............................................. 69 39
96.............................................. 66 42
97.............................................. 71 29
98.............................................. 75 29
99.............................................. 72 23
100............................................. 74 22
101............................................. 75 24
102............................................. 73 30
103............................................. 74 24
104............................................. 77 6
105............................................. 76 12
106............................................. 74 39
107............................................. 72 30
108............................................. 75 22
109............................................. 78 64
110............................................. 102 34
111............................................. 103 28
112............................................. 103 28
113............................................. 103 19
114............................................. 103 32
115............................................. 104 25
116............................................. 103 38
117............................................. 103 39
118............................................. 103 34
119............................................. 102 44
120............................................. 103 38
121............................................. 102 43
122............................................. 103 34
123............................................. 102 41
124............................................. 103 44
125............................................. 103 37
126............................................. 103 27
127............................................. 104 13
128............................................. 104 30
129............................................. 104 19
130............................................. 103 28
131............................................. 104 40
132............................................. 104 32
133............................................. 101 63
134............................................. 102 54
135............................................. 102 52
136............................................. 102 51
137............................................. 103 40
138............................................. 104 34
139............................................. 102 36
140............................................. 104 44
141............................................. 103 44
142............................................. 104 33
143............................................. 102 27
144............................................. 103 26
145............................................. 79 53
146............................................. 51 37
147............................................. 24 23
148............................................. 13 33
149............................................. 19 55
150............................................. 45 30
151............................................. 34 7
152............................................. 14 4
153............................................. 8 16
154............................................. 15 6
155............................................. 39 47
156............................................. 39 4
157............................................. 35 26
158............................................. 27 38
159............................................. 43 40
160............................................. 14 23
161............................................. 10 10
162............................................. 15 33
163............................................. 35 72
164............................................. 60 39
165............................................. 55 31
166............................................. 47 30
167............................................. 16 7
168............................................. 0 6
169............................................. 0 8
170............................................. 0 8
171............................................. 0 2
172............................................. 2 17
173............................................. 10 28
174............................................. 28 31
175............................................. 33 30
176............................................. 36 0
177............................................. 19 10
178............................................. 1 18
179............................................. 0 16
180............................................. 1 3
181............................................. 1 4
182............................................. 1 5
183............................................. 1 6
184............................................. 1 5
185............................................. 1 3
186............................................. 1 4
187............................................. 1 4
188............................................. 1 6
189............................................. 8 18
190............................................. 20 51
191............................................. 49 19
192............................................. 41 13
193............................................. 31 16
194............................................. 28 21
195............................................. 21 17
196............................................. 31 21
197............................................. 21 8
198............................................. 0 14
199............................................. 0 12
200............................................. 3 8
201............................................. 3 22
202............................................. 12 20
203............................................. 14 20
204............................................. 16 17
205............................................. 20 18
206............................................. 27 34
207............................................. 32 33
208............................................. 41 31
209............................................. 43 31
210............................................. 37 33
211............................................. 26 18
212............................................. 18 29
213............................................. 14 51
214............................................. 13 11
215............................................. 12 9
216............................................. 15 33
217............................................. 20 25
218............................................. 25 17
219............................................. 31 29
220............................................. 36 66
221............................................. 66 40
[[Page 28593]]
222............................................. 50 13
223............................................. 16 24
224............................................. 26 50
225............................................. 64 23
226............................................. 81 20
227............................................. 83 11
228............................................. 79 23
229............................................. 76 31
230............................................. 68 24
231............................................. 59 33
232............................................. 59 3
233............................................. 25 7
234............................................. 21 10
235............................................. 20 19
236............................................. 4 10
237............................................. 5 7
238............................................. 4 5
239............................................. 4 6
240............................................. 4 6
241............................................. 4 5
242............................................. 7 5
243............................................. 16 28
244............................................. 28 25
245............................................. 52 53
246............................................. 50 8
247............................................. 26 40
248............................................. 48 29
249............................................. 54 39
250............................................. 60 42
251............................................. 48 18
252............................................. 54 51
253............................................. 88 90
254............................................. 103 84
255............................................. 103 85
256............................................. 102 84
257............................................. 58 66
258............................................. 64 97
259............................................. 56 80
260............................................. 51 67
261............................................. 52 96
262............................................. 63 62
263............................................. 71 6
264............................................. 33 16
265............................................. 47 45
266............................................. 43 56
267............................................. 42 27
268............................................. 42 64
269............................................. 75 74
270............................................. 68 96
271............................................. 86 61
272............................................. 66 0
273............................................. 37 0
274............................................. 45 37
275............................................. 68 96
276............................................. 80 97
277............................................. 92 96
278............................................. 90 97
279............................................. 82 96
280............................................. 94 81
281............................................. 90 85
282............................................. 96 65
283............................................. 70 96
284............................................. 55 95
285............................................. 70 96
286............................................. 79 96
287............................................. 81 71
288............................................. 71 60
289............................................. 92 65
290............................................. 82 63
291............................................. 61 47
292............................................. 52 37
293............................................. 24 0
294............................................. 20 7
295............................................. 39 48
296............................................. 39 54
297............................................. 63 58
298............................................. 53 31
299............................................. 51 24
300............................................. 48 40
301............................................. 39 0
302............................................. 35 18
303............................................. 36 16
304............................................. 29 17
305............................................. 28 21
306............................................. 31 15
307............................................. 31 10
308............................................. 43 19
309............................................. 49 63
310............................................. 78 61
311............................................. 78 46
312............................................. 66 65
313............................................. 78 97
314............................................. 84 63
315............................................. 57 26
316............................................. 36 22
317............................................. 20 34
318............................................. 19 8
319............................................. 9 10
320............................................. 5 5
321............................................. 7 11
322............................................. 15 15
323............................................. 12 9
324............................................. 13 27
325............................................. 15 28
326............................................. 16 28
327............................................. 16 31
328............................................. 15 20
329............................................. 17 0
330............................................. 20 34
331............................................. 21 25
332............................................. 20 0
333............................................. 23 25
334............................................. 30 58
335............................................. 63 96
336............................................. 83 60
337............................................. 61 0
338............................................. 26 0
339............................................. 29 44
340............................................. 68 97
341............................................. 80 97
342............................................. 88 97
343............................................. 99 88
344............................................. 102 86
345............................................. 100 82
346............................................. 74 79
347............................................. 57 79
348............................................. 76 97
349............................................. 84 97
350............................................. 86 97
351............................................. 81 98
352............................................. 83 83
353............................................. 65 96
354............................................. 93 72
355............................................. 63 60
356............................................. 72 49
357............................................. 56 27
358............................................. 29 0
359............................................. 18 13
360............................................. 25 11
361............................................. 28 24
362............................................. 34 53
363............................................. 65 83
364............................................. 80 44
365............................................. 77 46
366............................................. 76 50
367............................................. 45 52
368............................................. 61 98
369............................................. 61 69
370............................................. 63 49
371............................................. 32 0
372............................................. 10 8
373............................................. 17 7
374............................................. 16 13
375............................................. 11 6
376............................................. 9 5
377............................................. 9 12
378............................................. 12 46
379............................................. 15 30
380............................................. 26 28
381............................................. 13 9
382............................................. 16 21
383............................................. 24 4
384............................................. 36 43
385............................................. 65 85
386............................................. 78 66
387............................................. 63 39
388............................................. 32 34
389............................................. 46 55
390............................................. 47 42
391............................................. 42 39
392............................................. 27 0
393............................................. 14 5
394............................................. 14 14
395............................................. 24 54
396............................................. 60 90
397............................................. 53 66
398............................................. 70 48
399............................................. 77 93
400............................................. 79 67
401............................................. 46 65
402............................................. 69 98
403............................................. 80 97
404............................................. 74 97
405............................................. 75 98
406............................................. 56 61
407............................................. 42 0
408............................................. 36 32
409............................................. 34 43
410............................................. 68 83
411............................................. 102 48
412............................................. 62 0
413............................................. 41 39
414............................................. 71 86
415............................................. 91 52
416............................................. 89 55
417............................................. 89 56
418............................................. 88 58
419............................................. 78 69
[[Page 28594]]
420............................................. 98 39
421............................................. 64 61
422............................................. 90 34
423............................................. 88 38
424............................................. 97 62
425............................................. 100 53
426............................................. 81 58
427............................................. 74 51
428............................................. 76 57
429............................................. 76 72
430............................................. 85 72
431............................................. 84 60
432............................................. 83 72
433............................................. 83 72
434............................................. 86 72
435............................................. 89 72
436............................................. 86 72
437............................................. 87 72
438............................................. 88 72
439............................................. 88 71
440............................................. 87 72
441............................................. 85 71
442............................................. 88 72
443............................................. 88 72
444............................................. 84 72
445............................................. 83 73
446............................................. 77 73
447............................................. 74 73
448............................................. 76 72
449............................................. 46 77
450............................................. 78 62
451............................................. 79 35
452............................................. 82 38
453............................................. 81 41
454............................................. 79 37
455............................................. 78 35
456............................................. 78 38
457............................................. 78 46
458............................................. 75 49
459............................................. 73 50
460............................................. 79 58
461............................................. 79 71
462............................................. 83 44
463............................................. 53 48
464............................................. 40 48
465............................................. 51 75
466............................................. 75 72
467............................................. 89 67
468............................................. 93 60
469............................................. 89 73
470............................................. 86 73
471............................................. 81 73
472............................................. 78 73
473............................................. 78 73
474............................................. 76 73
475............................................. 79 73
476............................................. 82 73
477............................................. 86 73
478............................................. 88 72
479............................................. 92 71
480............................................. 97 54
481............................................. 73 43
482............................................. 36 64
483............................................. 63 31
484............................................. 78 1
485............................................. 69 27
486............................................. 67 28
487............................................. 72 9
488............................................. 71 9
489............................................. 78 36
490............................................. 81 56
491............................................. 75 53
492............................................. 60 45
493............................................. 50 37
494............................................. 66 41
495............................................. 51 61
496............................................. 68 47
497............................................. 29 42
498............................................. 24 73
499............................................. 64 71
500............................................. 90 71
501............................................. 100 61
502............................................. 94 73
503............................................. 84 73
504............................................. 79 73
505............................................. 75 72
506............................................. 78 73
507............................................. 80 73
508............................................. 81 73
509............................................. 81 73
510............................................. 83 73
511............................................. 85 73
512............................................. 84 73
513............................................. 85 73
514............................................. 86 73
515............................................. 85 73
516............................................. 85 73
517............................................. 85 72
518............................................. 85 73
519............................................. 83 73
520............................................. 79 73
521............................................. 78 73
522............................................. 81 73
523............................................. 82 72
524............................................. 94 56
525............................................. 66 48
526............................................. 35 71
527............................................. 51 44
528............................................. 60 23
529............................................. 64 10
530............................................. 63 14
531............................................. 70 37
532............................................. 76 45
533............................................. 78 18
534............................................. 76 51
535............................................. 75 33
536............................................. 81 17
537............................................. 76 45
538............................................. 76 30
539............................................. 80 14
540............................................. 71 18
541............................................. 71 14
542............................................. 71 11
543............................................. 65 2
544............................................. 31 26
545............................................. 24 72
546............................................. 64 70
547............................................. 77 62
548............................................. 80 68
549............................................. 83 53
550............................................. 83 50
551............................................. 83 50
552............................................. 85 43
553............................................. 86 45
554............................................. 89 35
555............................................. 82 61
556............................................. 87 50
557............................................. 85 55
558............................................. 89 49
559............................................. 87 70
560............................................. 91 39
561............................................. 72 3
562............................................. 43 25
563............................................. 30 60
564............................................. 40 45
565............................................. 37 32
566............................................. 37 32
567............................................. 43 70
568............................................. 70 54
569............................................. 77 47
570............................................. 79 66
571............................................. 85 53
572............................................. 83 57
573............................................. 86 52
574............................................. 85 51
575............................................. 70 39
576............................................. 50 5
577............................................. 38 36
578............................................. 30 71
579............................................. 75 53
580............................................. 84 40
581............................................. 85 42
582............................................. 86 49
583............................................. 86 57
584............................................. 89 68
585............................................. 99 61
586............................................. 77 29
587............................................. 81 72
588............................................. 89 69
589............................................. 49 56
590............................................. 79 70
591............................................. 104 59
592............................................. 103 54
593............................................. 102 56
594............................................. 102 56
595............................................. 103 61
596............................................. 102 64
597............................................. 103 60
598............................................. 93 72
599............................................. 86 73
600............................................. 76 73
601............................................. 59 49
602............................................. 46 22
603............................................. 40 65
604............................................. 72 31
605............................................. 72 27
606............................................. 67 44
607............................................. 68 37
608............................................. 67 42
609............................................. 68 50
610............................................. 77 43
611............................................. 58 4
612............................................. 22 37
613............................................. 57 69
614............................................. 68 38
615............................................. 73 2
616............................................. 40 14
617............................................. 42 38
[[Page 28595]]
618............................................. 64 69
619............................................. 64 74
620............................................. 67 73
621............................................. 65 73
622............................................. 68 73
623............................................. 65 49
624............................................. 81 0
625............................................. 37 25
626............................................. 24 69
627............................................. 68 71
628............................................. 70 71
629............................................. 76 70
630............................................. 71 72
631............................................. 73 69
632............................................. 76 70
633............................................. 77 72
634............................................. 77 72
635............................................. 77 72
636............................................. 77 70
637............................................. 76 71
638............................................. 76 71
639............................................. 77 71
640............................................. 77 71
641............................................. 78 70
642............................................. 77 70
643............................................. 77 71
644............................................. 79 72
645............................................. 78 70
646............................................. 80 70
647............................................. 82 71
648............................................. 84 71
649............................................. 83 71
650............................................. 83 73
651............................................. 81 70
652............................................. 80 71
653............................................. 78 71
654............................................. 76 70
655............................................. 76 70
656............................................. 76 71
657............................................. 79 71
658............................................. 78 71
659............................................. 81 70
660............................................. 83 72
661............................................. 84 71
662............................................. 86 71
663............................................. 87 71
664............................................. 92 72
665............................................. 91 72
666............................................. 90 71
667............................................. 90 71
668............................................. 91 71
669............................................. 90 70
670............................................. 90 72
671............................................. 91 71
672............................................. 90 71
673............................................. 90 71
674............................................. 92 72
675............................................. 93 69
676............................................. 90 70
677............................................. 93 72
678............................................. 91 70
679............................................. 89 71
680............................................. 91 71
681............................................. 90 71
682............................................. 90 71
683............................................. 92 71
684............................................. 91 71
685............................................. 93 71
686............................................. 93 68
687............................................. 98 68
688............................................. 98 67
689............................................. 100 69
690............................................. 99 68
691............................................. 100 71
692............................................. 99 68
693............................................. 100 69
694............................................. 102 72
695............................................. 101 69
696............................................. 100 69
697............................................. 102 71
698............................................. 102 71
699............................................. 102 69
700............................................. 102 71
701............................................. 102 68
702............................................. 100 69
703............................................. 102 70
704............................................. 102 68
705............................................. 102 70
706............................................. 102 72
707............................................. 102 68
708............................................. 102 69
709............................................. 100 68
710............................................. 102 71
711............................................. 101 64
712............................................. 102 69
713............................................. 102 69
714............................................. 101 69
715............................................. 102 64
716............................................. 102 69
717............................................. 102 68
718............................................. 102 70
719............................................. 102 69
720............................................. 102 70
721............................................. 102 70
722............................................. 102 62
723............................................. 104 38
724............................................. 104 15
725............................................. 102 24
726............................................. 102 45
727............................................. 102 47
728............................................. 104 40
729............................................. 101 52
730............................................. 103 32
731............................................. 102 50
732............................................. 103 30
733............................................. 103 44
734............................................. 102 40
735............................................. 103 43
736............................................. 103 41
737............................................. 102 46
738............................................. 103 39
739............................................. 102 41
740............................................. 103 41
741............................................. 102 38
742............................................. 103 39
743............................................. 102 46
744............................................. 104 46
745............................................. 103 49
746............................................. 102 45
747............................................. 103 42
748............................................. 103 46
749............................................. 103 38
750............................................. 102 48
751............................................. 103 35
752............................................. 102 48
753............................................. 103 49
754............................................. 102 48
755............................................. 102 46
756............................................. 103 47
757............................................. 102 49
758............................................. 102 42
759............................................. 102 52
760............................................. 102 57
761............................................. 102 55
762............................................. 102 61
763............................................. 102 61
764............................................. 102 58
765............................................. 103 58
766............................................. 102 59
767............................................. 102 54
768............................................. 102 63
769............................................. 102 61
770............................................. 103 55
771............................................. 102 60
772............................................. 102 72
773............................................. 103 56
774............................................. 102 55
775............................................. 102 67
776............................................. 103 56
777............................................. 84 42
778............................................. 48 7
779............................................. 48 6
780............................................. 48 6
781............................................. 48 7
782............................................. 48 6
783............................................. 48 7
784............................................. 67 21
785............................................. 105 59
786............................................. 105 96
787............................................. 105 74
788............................................. 105 66
789............................................. 105 62
790............................................. 105 66
791............................................. 89 41
792............................................. 52 5
793............................................. 48 5
794............................................. 48 7
795............................................. 48 5
796............................................. 48 6
797............................................. 48 4
798............................................. 52 6
799............................................. 51 5
800............................................. 51 6
801............................................. 51 6
802............................................. 52 5
803............................................. 52 5
804............................................. 57 44
805............................................. 98 90
806............................................. 105 94
807............................................. 105 100
808............................................. 105 98
809............................................. 105 95
810............................................. 105 96
811............................................. 105 92
812............................................. 104 97
813............................................. 100 85
814............................................. 94 74
815............................................. 87 62
[[Page 28596]]
816............................................. 81 50
817............................................. 81 46
818............................................. 80 39
819............................................. 80 32
820............................................. 81 28
821............................................. 80 26
822............................................. 80 23
823............................................. 80 23
824............................................. 80 20
825............................................. 81 19
826............................................. 80 18
827............................................. 81 17
828............................................. 80 20
829............................................. 81 24
830............................................. 81 21
831............................................. 80 26
832............................................. 80 24
833............................................. 80 23
834............................................. 80 22
835............................................. 81 21
836............................................. 81 24
837............................................. 81 24
838............................................. 81 22
839............................................. 81 22
840............................................. 81 21
841............................................. 81 31
842............................................. 81 27
843............................................. 80 26
844............................................. 80 26
845............................................. 81 25
846............................................. 80 21
847............................................. 81 20
848............................................. 83 21
849............................................. 83 15
850............................................. 83 12
851............................................. 83 9
852............................................. 83 8
853............................................. 83 7
854............................................. 83 6
855............................................. 83 6
856............................................. 83 6
857............................................. 83 6
858............................................. 83 6
859............................................. 76 5
860............................................. 49 8
861............................................. 51 7
862............................................. 51 20
863............................................. 78 52
864............................................. 80 38
865............................................. 81 33
866............................................. 83 29
867............................................. 83 22
868............................................. 83 16
869............................................. 83 12
870............................................. 83 9
871............................................. 83 8
872............................................. 83 7
873............................................. 83 6
874............................................. 83 6
875............................................. 83 6
876............................................. 83 6
877............................................. 83 6
878............................................. 59 4
879............................................. 50 5
880............................................. 51 5
881............................................. 51 5
882............................................. 51 5
883............................................. 50 5
884............................................. 50 5
885............................................. 50 5
886............................................. 50 5
887............................................. 50 5
888............................................. 51 5
889............................................. 51 5
890............................................. 51 5
891............................................. 63 50
892............................................. 81 34
893............................................. 81 25
894............................................. 81 29
895............................................. 81 23
896............................................. 80 24
897............................................. 81 24
898............................................. 81 28
899............................................. 81 27
900............................................. 81 22
901............................................. 81 19
902............................................. 81 17
903............................................. 81 17
904............................................. 81 17
905............................................. 81 15
906............................................. 80 15
907............................................. 80 28
908............................................. 81 22
909............................................. 81 24
910............................................. 81 19
911............................................. 81 21
912............................................. 81 20
913............................................. 83 26
914............................................. 80 63
915............................................. 80 59
916............................................. 83 100
917............................................. 81 73
918............................................. 83 53
919............................................. 80 76
920............................................. 81 61
921............................................. 80 50
922............................................. 81 37
923............................................. 82 49
924............................................. 83 37
925............................................. 83 25
926............................................. 83 17
927............................................. 83 13
928............................................. 83 10
929............................................. 83 8
930............................................. 83 7
931............................................. 83 7
932............................................. 83 6
933............................................. 83 6
934............................................. 83 6
935............................................. 71 5
936............................................. 49 24
937............................................. 69 64
938............................................. 81 50
939............................................. 81 43
940............................................. 81 42
941............................................. 81 31
942............................................. 81 30
943............................................. 81 35
944............................................. 81 28
945............................................. 81 27
946............................................. 80 27
947............................................. 81 31
948............................................. 81 41
949............................................. 81 41
950............................................. 81 37
951............................................. 81 43
952............................................. 81 34
953............................................. 81 31
954............................................. 81 26
955............................................. 81 23
956............................................. 81 27
957............................................. 81 38
958............................................. 81 40
959............................................. 81 39
960............................................. 81 27
961............................................. 81 33
962............................................. 80 28
963............................................. 81 34
964............................................. 83 72
965............................................. 81 49
966............................................. 81 51
967............................................. 80 55
968............................................. 81 48
969............................................. 81 36
970............................................. 81 39
971............................................. 81 38
972............................................. 80 41
973............................................. 81 30
974............................................. 81 23
975............................................. 81 19
976............................................. 81 25
977............................................. 81 29
978............................................. 83 47
979............................................. 81 90
980............................................. 81 75
981............................................. 80 60
982............................................. 81 48
983............................................. 81 41
984............................................. 81 30
985............................................. 80 24
986............................................. 81 20
987............................................. 81 21
988............................................. 81 29
989............................................. 81 29
990............................................. 81 27
991............................................. 81 23
992............................................. 81 25
993............................................. 81 26
994............................................. 81 22
995............................................. 81 20
996............................................. 81 17
997............................................. 81 23
998............................................. 83 65
999............................................. 81 54
1000............................................ 81 50
1001............................................ 81 41
1002............................................ 81 35
1003............................................ 81 37
1004............................................ 81 29
1005............................................ 81 28
1006............................................ 81 24
1007............................................ 81 19
1008............................................ 81 16
1009............................................ 80 16
1010............................................ 83 23
1011............................................ 83 17
1012............................................ 83 13
1013............................................ 83 27
[[Page 28597]]
1014............................................ 81 58
1015............................................ 81 60
1016............................................ 81 46
1017............................................ 80 41
1018............................................ 80 36
1019............................................ 81 26
1020............................................ 86 18
1021............................................ 82 35
1022............................................ 79 53
1023............................................ 82 30
1024............................................ 83 29
1025............................................ 83 32
1026............................................ 83 28
1027............................................ 76 60
1028............................................ 79 51
1029............................................ 86 26
1030............................................ 82 34
1031............................................ 84 25
1032............................................ 86 23
1033............................................ 85 22
1034............................................ 83 26
1035............................................ 83 25
1036............................................ 83 37
1037............................................ 84 14
1038............................................ 83 39
1039............................................ 76 70
1040............................................ 78 81
1041............................................ 75 71
1042............................................ 86 47
1043............................................ 83 35
1044............................................ 81 43
1045............................................ 81 41
1046............................................ 79 46
1047............................................ 80 44
1048............................................ 84 20
1049............................................ 79 31
1050............................................ 87 29
1051............................................ 82 49
1052............................................ 84 21
1053............................................ 82 56
1054............................................ 81 30
1055............................................ 85 21
1056............................................ 86 16
1057............................................ 79 52
1058............................................ 78 60
1059............................................ 74 55
1060............................................ 78 84
1061............................................ 80 54
1062............................................ 80 35
1063............................................ 82 24
1064............................................ 83 43
1065............................................ 79 49
1066............................................ 83 50
1067............................................ 86 12
1068............................................ 64 14
1069............................................ 24 14
1070............................................ 49 21
1071............................................ 77 48
1072............................................ 103 11
1073............................................ 98 48
1074............................................ 101 34
1075............................................ 99 39
1076............................................ 103 11
1077............................................ 103 19
1078............................................ 103 7
1079............................................ 103 13
1080............................................ 103 10
1081............................................ 102 13
1082............................................ 101 29
1083............................................ 102 25
1084............................................ 102 20
1085............................................ 96 60
1086............................................ 99 38
1087............................................ 102 24
1088............................................ 100 31
1089............................................ 100 28
1090............................................ 98 3
1091............................................ 102 26
1092............................................ 95 64
1093............................................ 102 23
1094............................................ 102 25
1095............................................ 98 42
1096............................................ 93 68
1097............................................ 101 25
1098............................................ 95 64
1099............................................ 101 35
1100............................................ 94 59
1101............................................ 97 37
1102............................................ 97 60
1103............................................ 93 98
1104............................................ 98 53
1105............................................ 103 13
1106............................................ 103 11
1107............................................ 103 11
1108............................................ 103 13
1109............................................ 103 10
1110............................................ 103 10
1111............................................ 103 11
1112............................................ 103 10
1113............................................ 103 10
1114............................................ 102 18
1115............................................ 102 31
1116............................................ 101 24
1117............................................ 102 19
1118............................................ 103 10
1119............................................ 102 12
1120............................................ 99 56
1121............................................ 96 59
1122............................................ 74 28
1123............................................ 66 62
1124............................................ 74 29
1125............................................ 64 74
1126............................................ 69 40
1127............................................ 76 2
1128............................................ 72 29
1129............................................ 66 65
1130............................................ 54 69
1131............................................ 69 56
1132............................................ 69 40
1133............................................ 73 54
1134............................................ 63 92
1135............................................ 61 67
1136............................................ 72 42
1137............................................ 78 2
1138............................................ 76 34
1139............................................ 67 80
1140............................................ 70 67
1141............................................ 53 70
1142............................................ 72 65
1143............................................ 60 57
1144............................................ 74 29
1145............................................ 69 31
1146............................................ 76 1
1147............................................ 74 22
1148............................................ 72 52
1149............................................ 62 96
1150............................................ 54 72
1151............................................ 72 28
1152............................................ 72 35
1153............................................ 64 68
1154............................................ 74 27
1155............................................ 76 14
1156............................................ 69 38
1157............................................ 66 59
1158............................................ 64 99
1159............................................ 51 86
1160............................................ 70 53
1161............................................ 72 36
1162............................................ 71 47
1163............................................ 70 42
1164............................................ 67 34
1165............................................ 74 2
1166............................................ 75 21
1167............................................ 74 15
1168............................................ 75 13
1169............................................ 76 10
1170............................................ 75 13
1171............................................ 75 10
1172............................................ 75 7
1173............................................ 75 13
1174............................................ 76 8
1175............................................ 76 7
1176............................................ 67 45
1177............................................ 75 13
1178............................................ 75 12
1179............................................ 73 21
1180............................................ 68 46
1181............................................ 74 8
1182............................................ 76 11
1183............................................ 76 14
1184............................................ 74 11
1185............................................ 74 18
1186............................................ 73 22
1187............................................ 74 20
1188............................................ 74 19
1189............................................ 70 22
1190............................................ 71 23
1191............................................ 73 19
1192............................................ 73 19
1193............................................ 72 20
1194............................................ 64 60
1195............................................ 70 39
1196............................................ 66 56
1197............................................ 68 64
1198............................................ 30 68
1199............................................ 70 38
1200............................................ 66 47
1201............................................ 76 14
1202............................................ 74 18
1203............................................ 69 46
1204............................................ 68 62
1205............................................ 68 62
1206............................................ 68 62
1207............................................ 68 62
1208............................................ 68 62
1209............................................ 68 62
1210............................................ 54 50
1211............................................ 41 37
[[Page 28598]]
1212............................................ 27 25
1213............................................ 14 12
1214............................................ 0 0
1215............................................ 0 0
1216............................................ 0 0
1217............................................ 0 0
1218............................................ 0 0
1219............................................ 0 0
1220............................................ 0 0
1221............................................ 0 0
1222............................................ 0 0
1223............................................ 0 0
1224............................................ 0 0
1225............................................ 0 0
1226............................................ 0 0
1227............................................ 0 0
1228............................................ 0 0
1229............................................ 0 0
1230............................................ 0 0
1231............................................ 0 0
1232............................................ 0 0
1233............................................ 0 0
1234............................................ 0 0
1235............................................ 0 0
1236............................................ 0 0
1237............................................ 0 0
1238............................................ 0 0
------------------------------------------------------------------------
PART 1065--TEST PROCEDURES AND EQUIPMENT
65. The authority citation for part 1065 continues to read as
follows:
Authority: 42 U.S.C. 7401-7671(q).
66. Section 1065.1 is amended by revising paragraph (a) and
removing and reserving paragraph (b)(6) to read as follows:
Sec. 1065.1 Applicability.
(a) This part describes the procedures that apply to testing that
we require for the following engines or for equipment using the
following engines:
(1) Large nonroad spark-ignition engines we regulate under 40 CFR
part 1048.
(2) Vehicles that we regulate under 40 CFR part 1051 (i.e.,
recreational SI vehicles) that are regulated based on engine testing.
See 40 CFR part 1051 to determine which vehicles may be certified based
on engine test data.
(3) Land-based nonroad compression-ignition engines we regulate
under 40 CFR part 1039.
* * * * *
67. Section 1065.10 is amended by revising paragraph (c)(3) to read
as follows:
Sec. 1065.10 Other test procedures.
* * * * *
(c) * * *
(3) You may ask to use alternate procedures that produce
measurements equivalent to those from the specified procedures. If you
send us a written request showing your procedures are equivalent, and
we agree that they are equivalent, we will allow you to use them. You
may not use an alternate procedure until we approve them, either by:
Telling you directly that you may use this procedure; or issuing
guidance to all manufacturers, which allows you to use the alternate
procedure without additional approval. You may use the statistical
procedures specified in 40 CFR 86.1306-07(d) to demonstrate
equivalence.
* * * * *
68. Section 1065.115 is added to read as follows:
Sec. 1065.115 Exhaust gas sampling system; compression-ignition
engines.
Use the exhaust-gas sampling system specified in 40 CFR 86.1310 to
measure emissions from compression-ignition nonroad engines.
69. Section 1065.205 is added to read as follows:
Sec. 1065.205 Test fuel specifications for distillate diesel fuel.
Petroleum distillate diesel fuel used as a test fuel must meet the
following specifications:
----------------------------------------------------------------------------------------------------------------
Item ASTM test method No. Type 2-D
----------------------------------------------------------------------------------------------------------------
(i) Cetane Number...................... .......................... D613 40-50
(ii) Cetane Index...................... .......................... D976 40-50
(iii) Distillation range:
(A) IBP............................ [deg]C.................... D86 171-204
(B) 10 pct. point.................. [deg]C.................... D86 204-238
(C) 50 pct. point.................. [deg]C.................... D86 243-282
(D) 90 pct. point.................. [deg]C.................... D86 293-332
(E) EP............................. [deg]C.................... D86 D321-366
(iv) Gravity........................... [deg]API.................. D287 32-37
(v) Total sulfur....................... ppm....................... D2622 7-15
(vi) Hydrocarbon composition: (A) pct....................... D5186 10
Aromatics, minimum (Remainder shall be
paraffins, naphthenes, and olefins).
(vii) Flashpoint, min.................. [deg]C.................... D93 54
(viii) Viscosity....................... centistokes............... D445 2.0-3.2
----------------------------------------------------------------------------------------------------------------
70. Section 1065.310 is amended to read as follows:
Sec. 1065.310 CVS calibration.
Use the procedures of 40 CFR 86.1319-90 to calibrate the CVS.
71. Section 1065.405 is amended by revising paragraph (b) to read
as follows:
Sec. 1065.405 Preparing and servicing a test engine.
* * * * *
(b) Run the test engine, with all emission-control systems
operating, long enough to stabilize emission levels.
(1) For SI engines, if you accumulate 50 hours of operation, you
may consider emission levels stable without measurement.
(2) For CI engines, if you accumulate 125 hours of operation, you
may consider emission levels stable without measurement.
* * * * *
72. Section 1065.530 is amended by revising paragraph (b)(3)(iii)
and Table 1 and adding a new Table 2 and paragraph (d) to read as
follows:
Sec. 1065.530 Test cycle validation criteria.
* * * * *
(b) * * *
(3) * * *
(iii) For a valid test, make sure the feedback cycle's integrated
brake kilowatt-hour is within 5 percent of the reference cycle's
integrated brake kilowatt-hour. Also, ensure that the
[[Page 28599]]
slope, intercept, standard error, and coefficient of determination meet
the criteria in the following tables (you may delete individual points
from the regression analyses, consistent with good engineering
judgment):
Table 1 of Sec. 1065.530.--Statistical Criteria for Validating Test Cycles for Spark-Ignition Engines
----------------------------------------------------------------------------------------------------------------
Speed Torque Power
----------------------------------------------------------------------------------------------------------------
1. Slope of the regression line (m).. 0.950 to 1.030......... 0.830 to 1.030......... 0.880 to 1.030.
2. Y intercept of the regression line [bond]b[bond] <= 50 rpm [bond]b[bond] <= 5.0 [bond]b[bond] <= 3.0
(b). percent of maximum percent of maximum
torque from power map. torque from power map.
3. Standard error of the estimate of 100 rpm................ 15 percent of maximum 10 percent of maximum
Y on X (SE). torque from power map. power from power map.
4. Coefficient of determination (r 2) r \2\ = r \2\ = r \2\ =
0.970. 0.880. 0.900.
----------------------------------------------------------------------------------------------------------------
Table 2 of Sec. 1065.530.--Statistical Criteria for Validating Test Cycles for Compression-Ignition Engines
----------------------------------------------------------------------------------------------------------------
Speed Torque Power
----------------------------------------------------------------------------------------------------------------
1. Slope of the regression line (m).. 0.950 to 1.030......... 0.830 to 1.030 (hot); 0.890 to 1.030 (hot);
0.77 to 1.03 (cold). 0.870 to 1.030 (cold).
2. Y intercept of the regression line [bond]b[bond] <= 50 rpm [bond]b[bond] <= 20 Nm [bond]b[bond] <= 40 kW
(b). or [bond]b[bond] <= or [bond]b[bond] <=
2.0 percent of maximum 3.0 percent of maximum
torque from power map, torque from power map,
whichever is greater. whichever is greater.
3. Standard error of the estimate of 100 rpm................ 13 percent of maximum 8 percent of maximum
Y on X (SE). torque from power map. power from power map.
4. Coefficient of determination (r r \2\ = r \2\ = r \2\ =
\2\). 0.970. 0.880 (hot); r \2\ = 0.850 (cold). thn-eq>= 0.850 (cold).
----------------------------------------------------------------------------------------------------------------
* * * * *
(d) Transient testing with constant-speed engines. For constant-
speed engines with installed governor operating over a transient duty
cycle, the test cycle validation criteria in this section apply to
engine-torque values but not engine-speed values.
73. Section 1065.615 is amended by revising paragraphs (c) and (d)
to read as follows:
Sec. 1065.615 Bag sample calculations.
* * * * *
(c) Calculate total brake work (kW-hr) done during the emissions
sampling period of each segment or mode and then weight it by the
applicable test cycle weighting factors.
(d) Calculate emissions in g/kW-hr by dividing the total weighted
mass emission rate (g/test) by the total cycle-weighted brake work for
the test.
* * * * *
74. Section 1065.620 is added to read as follows:
Sec. 1065.620 Continuous sample analysis and calculations.
Use the sample analysis procedures and calculations of 40 CFR
subpart N for continuous samples.
75. Section 1065.701 is added to read as follows:
Sec. 1065.701 Particulate measurements.
Use the particulate sampling system and procedures specified in 40
CFR part 86 subpart N to measure particulate emissions from
compression-ignition nonroad engines.
76. Section 1065.910 is revised to read as follows:
Sec. 1065.910 Measurement accuracy and precision.
Measurement systems used for field testing have accuracy and
precision comparable to those of dynamometer testing. Measurement
systems that conform to the provisions of Sec. Sec. 1065.915 through
1065.950 are deemed to be in compliance with the accuracy and precision
requirements of paragraph of this section. If you use other field
testing measurement systems you need to have documentation indicating
that it is comparable to a dynamometer system.
(a) The two systems must be calibrated independently to NIST
traceable standards or equivalent national standards for this
comparison. We may approve the us of other standards. Calculations of
emissions results for this test should be consistent with the field
testing data reduction scheme for both the in-use equipment and the
dynamometer equipment, and each complete test cycle will be considered
one ``summing interval'', Si as defined in the field-testing data
reduction scheme.
(b) While other statistical analyses may be acceptable, we
recommend that the comparison be based on a minimum of seven (7)
repeats of colocated and simultaneous tests. Perform this comparison
over the applicable steady-state and transient test cycles using an
engine that is fully warmed up such that its coolant temperature is
thermostatically controlled. If there is no applicable transient test
cycle, use the applicable steady-state cycle. Anyone who intends to
submit an alternative comparison is encouraged to first contact EPA
Office of Transportation and Air Quality, Assessment and Standards
Division to discuss the applicant's intended statistical analysis. The
Division may provide further guidance specific to the appropriate
statistical analysis for the respective application.
(c) The following statistical tests are suggested. If the
comparison is paired, it must demonstrate that the alternate system
passes a two-sided, paired t-test. If the test is unpaired, it must
demonstrate that the alternate system passes a two-sided, unpaired t-
test. The average of these tests for the reference system must return
results less than or equal to the applicable emissions standard. The t-
test is performed as follows, where ``n'' equals the number of tests:
(1) Calculate the average of the in-use system results; this is
Iavg.
(2) Calculate the average of the results of the system to which the
in-use system was Referenced; this is Ravg.
(3) Calculate the ``n-1'' standard deviations for the in-use and
reference averages; these are Isd and Rsd respectively. Form the F
ratio: F = (Isd/Rsd) 2. F must be less than the critical F value, Fcrit
at a 95% confidence interval for ``n-1'' degrees of freedom. Table 1 of
this section lists 95% confidence interval Fcrit values for n-1 degrees
of freedom. Note that nA represents the number of alternate
system samples, while nR represents the number of reference
system samples.
(4) For an unpaired comparison, calculate the t-value:
[[Page 28600]]
[GRAPHIC] [TIFF OMITTED] TP23MY03.016
(5) For a paired comparison, calculate the ``n-1'' standard
deviation (squared) of the differences, di, between the
paired results, where ``i'' represents the ith test of n number of
tests:
[GRAPHIC] [TIFF OMITTED] TP23MY03.017
(6) For a paired comparison, calculate the t-value:
[GRAPHIC] [TIFF OMITTED] TP23MY03.018
(d) The absolute value of t must be less than the critical t value,
tcrit at a 95% confidence interval for ``n-1'' degrees of
freedom. Table 2 of this section lists 95% confidence interval
tcrit values for n-1 degrees of freedom.
Table 1 of Sec. 1065.910.--95% Confidence Interval Critical F Values for F-Test
--------------------------------------------------------------------------------------------------------------------------------------------------------
nR-1 nI-1 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
--------------------------------------------------------------------------------------------------------------------------------------------------------
6...................................... ..... 4.284 4.207 4.147 4.099 4.06 4.027 4 3.976 3.956 3.938 3.922 3.908 3.896 3.884 3.874
7...................................... ..... 3.866 3.787 3.726 3.677 3.637 3.603 3.575 3.55 3.529 3.511 3.494 3.48 3.467 3.455 3.445
8...................................... ..... 3.581 3.5 3.438 3.388 3.347 3.313 3.284 3.259 3.237 3.218 3.202 3.187 3.173 3.161 3.15
9...................................... ..... 3.374 3.293 3.23 3.179 3.137 3.102 3.073 3.048 3.025 3.006 2.989 2.974 2.96 2.948 2.936
10..................................... ..... 3.217 3.135 3.072 3.02 2.978 2.943 2.913 2.887 2.865 2.845 2.828 2.812 2.798 2.785 2.774
11..................................... ..... 3.095 3.012 2.948 2.896 2.854 2.818 2.788 2.761 2.739 2.719 2.701 2.685 2.671 2.658 2.646
12..................................... ..... 2.996 2.913 2.849 2.796 2.753 2.717 2.687 2.66 2.637 2.617 2.599 2.583 2.568 2.555 2.544
13..................................... ..... 2.915 2.832 2.767 2.714 2.671 2.635 2.604 2.577 2.554 2.533 2.515 2.499 2.484 2.471 2.459
14..................................... ..... 2.848 2.764 2.699 2.646 2.602 2.565 2.534 2.507 2.484 2.463 2.455 2.428 2.413 2.4 2.388
15..................................... ..... 2.79 2.707 2.641 2.588 2.544 2.507 2.475 2.448 2.424 2.403 2.385 2.368 2.353 2.34 2.328
16..................................... ..... 2.741 2.657 2.591 2.538 2.494 2.456 2.425 2.397 2.373 2.352 2.333 2.317 2.302 2.288 2.276
17..................................... ..... 2.699 2.614 2.548 2.494 2.45 2.413 2.381 2.353 2.329 2.308 2.289 2.272 2.257 2.243 2.23
18..................................... ..... 2.661 2.577 2.51 2.456 2.412 2.374 2.342 2.314 2.29 2.269 2.25 2.233 2.217 2.203 2.191
19..................................... ..... 2.628 2.544 2.477 2.423 2.378 2.34 2.308 2.28 2.256 2.234 2.215 2.198 2.182 2.168 2.155
20..................................... ..... 2.599 2.514 2.447 2.393 2.348 2.31 2.278 2.25 2.225 2.203 2.184 2.167 2.151 2.137 2.124
--------------------------------------------------------------------------------------------------------------------------------------------------------
Table 2 of Sec. 1065.910.--95% Confidence Interval Critical T Values
for T-Test
------------------------------------------------------------------------
n-1 tcrit
------------------------------------------------------------------------
6............................................................ 2.45
7............................................................ 2.36
8............................................................ 2.31
9............................................................ 2.26
10........................................................... 2.23
11........................................................... 2.20
12........................................................... 2.18
13........................................................... 2.16
14........................................................... 2.14
15........................................................... 2.13
16........................................................... 2.12
17........................................................... 2.11
18........................................................... 2.10
19........................................................... 2.09
20........................................................... 2.09
------------------------------------------------------------------------
PART 1068--GENERAL COMPLIANCE PROVISIONS FOR NONROAD PROGRAMS
77. The authority citation for part 1068 continues to read as
follows:
Authority: 42 U.S.C. 7401-7671(q).
78. Section 1068.1 is amended by revising paragraph (a), removing
and reserving paragraph (b)(5), and adding paragraph (e) to read as
follows:
Sec. 1068.1 Does this part apply to me?
(a) The provisions of this part apply to everyone with respect to
the following engines and to equipment using the following engines
(including owners, operators, parts manufacturers, and persons
performing maintenance).
(1) Large nonroad spark-ignition engines we regulate under 40 CFR
part 1048.
(2) Recreational SI engines and vehicles that we regulate under 40
CFR part 1051 (such as snowmobiles and off-highway motorcycles).
(3) Land-based nonroad diesel engines that we regulate under 40 CFR
part 1039.
* * * * *
(e)(1) The provisions of Sec. Sec. 1068.30, 1068.310, and 1068.320
apply for stationary spark-ignition engines beginning January 1, 2004,
and for stationary compression-ignition engines beginning January 1,
2006.
(2) The provisions of Sec. Sec. 1068.30 and 1068.235 apply for the
types of engines listed in paragraph (a) of this section beginning
January 1, 2004, where they are used solely for competition.
79. Section 1068.27 is added to read as follows:
Sec. 1068.27 May EPA conduct testing with my production engines?
If we request it, you must make a reasonable number of production-
line engines available for a reasonable time so we can test or inspect
them for compliance with the requirements of this chapter.
80. Section 1068.30 is amended by adding in alphabetical order a
definition of ``Aftertreatment'' to read as follows:
Sec. 1068.30 What definitions apply to this part?
* * * * *
Aftertreatment means relating to any system, component, or
technology mounted downstream of the exhaust valve or exhaust port
whose design function is to reduce exhaust emissions.
* * * * *
81. Section 1068.101 is amended by revising paragraph (a)(1) and
adding paragraph (b)(6) to read as follows:
Sec. 1068.101 What general actions does this regulation prohibit?
(a) * * *
(1) You may not sell, offer for sale, or introduce or deliver into
commerce in the United States or import into the United States any new
engine or equipment after emission standards take effect for that
engine or equipment, unless it has a valid certificate of conformity
for its model year and the required label or tag. You also may not take
any of the actions listed in the previous sentence with respect to any
equipment containing an engine subject to this part's provisions,
unless the engine has a valid and appropriate certificate of conformity
and the required engine label or tag. For purposes of this paragraph
(a)(1), an appropriate certificate of conformity is one that applies
for the same model year as the model year of the equipment (except as
allowed by Sec. 1068.105(a)), covers the appropriate category of
engines (such as locomotive or CI marine), and conforms to all
requirements specified for equipment in the standard-setting part. This
requirements of this paragraph (a)(1) also cover new engines you
produce to replace an older engine in a piece of equipment, unless the
engine qualifies for the replacement-engine exemption in Sec.
1068.240. We may assess a civil
[[Page 28601]]
penalty up to $31,500 for each engine in violation.
* * * * *
(b) * * *
(6) You must meet your obligation to honor your emission-related
warranty under Sec. 1068.115 and to fulfill any applicable
responsibilities to recall engines under Sec. 1068.505. Failure to
meet these obligations is prohibited. We may assess a civil penalty up
to $31,500 for each engine in violation.
* * * * *
82. Section 1068.105 is amended by adding introductory text and
revising paragraph (c) to read as follows:
Sec. 1068.105 What other provisions apply to me specifically if I
manufacture equipment needing certified engines?
This section describes general provisions that apply to equipment
manufacturers. See the standard-setting part for any requirements that
apply for certain applications.
* * * * *
(c) Attaching a duplicate label. If you obscure the engine's label,
you must do four things to avoid violating Sec. 1068.101(a)(1):
(1) Send a request for duplicate labels in writing with your
company's letterhead to the engine manufacturer. Include the following
information in your request:
(i) Identify the type of equipment and the specific engine and
equipment models needing duplicate labels.
(ii) Identify the engine family (from the original engine label).
(iii) State the reason that you need a duplicate label for each
equipment model.
(iv) Identify the number of duplicate labels you will need.
(2) Permanently attach the duplicate label to your equipment by
securing it to a part needed for normal operation and not normally
requiring replacement. Make sure an average person can easily read it.
(3) Destroy any unused duplicate labels if you find that you will
not need them.
(4) Keep the following records for at least eight years after the
end of the model year identified on the engine label:
(i) Keep a copy of your written request.
(ii) Keep drawings or descriptions that show how you apply the
duplicate labels to your equipment.
(iii) Maintain a count of duplicate labels that you use or destroy.
* * * * *
83. Section 1068.210 is amended by revising paragraph (a) to read
as follows:
Sec. 1068.210 What are the provisions for exempting test engines?
(a) We may exempt engines that are not exempted under other
sections of this part that you will use for research, investigations,
studies, demonstrations, or training. This may include engines placed
into service if the primary purpose is to develop a fundamentally new
emission-control technology related either to an alternative fuel or an
aftertreatment device.
* * * * *
84. Section 1068.215 is amended by revising paragraph (c)(3)(iii)
to read as follows:
Sec. 1068.215 What are the provisions for exempting manufacturer-
owned engines?
* * * * *
(c) * * *
(3) * * *
(iii) Engine displacement, engine family identification (as
applicable), and model year of the engine or whom to contact for
further information.
* * * * *
85. Section 1068.220 is amended by revising paragraph (e)(3) to
read as follows:
Sec. 1068.220 What are the provisions for exempting display engines?
* * * * *
(e) * * *
(3) Engine displacement, engine family identification (as
applicable), and model year of the engine or whom to contact for
further information.
* * * * *
86. Section 1068.310 is amended by revising the introductory text
and paragraphs (a) and (b) to read as follows:
Sec. 1068.310 What are the exclusions for imported engines?
Engines or equipment that are not subject to our emission standards
are not subject to the restrictions on imports in Sec. 1068.301(b). If
you show us that your engines qualify under one of the paragraphs of
this section, we will approve your request to import such excluded
engines. You must have our approval to import an engine under paragraph
(a) of this section. You may, but are not required to request our
approval to import the engines under paragraph (b) or (c) of this
section. The following engines are excluded:
(a) Engines used solely for competition. Engines you use solely for
competition are generally excluded from the restrictions on imports in
Sec. 1068.301(b), but only if they are properly labeled according to
Sec. 1068.320. The standard-setting part may set special provisions
for the manufacture, sale, or import of engines used solely for
competition. Section 1068.101(b)(4) prohibits using these excluded
engines for other purposes.
(b) Stationary engines. The definition of nonroad engine in 40 CFR
1068.30 does not include certain engines used in stationary
applications. Such engines are not subject to the restrictions on
imports in Sec. 1068.301(b), but only if they are properly labeled
according to Sec. 1068.320. Section 1068.101 restricts the use of
stationary engines for non-stationary purposes.
* * * * *
87. Section 1068.315 is amended by revising introductory text and
paragraph (a) and adding paragraph (f)(1)(iii) to read as follows:
Sec. 1068.315 What are the permanent exemptions for imported engines?
We may approve a permanent exemption from the restrictions on
imports under Sec. 1039.301(b) under the following conditions:
(a) National security exemption. You may import an engine under the
national security exemption in Sec. 1068.225, but only if they are
properly labeled according to Sec. 1068.320.
* * * * *
(f) * * *
(1) * * *
(iii) Land-based nonroad diesel engines (see part 1039 of this
chapter).
* * * * *
88. Section 1068.320 is amended by revising the section heading,
paragraph (a) introductory text, and paragraph (b)(4) to read as
follows:
Sec. 1068.320 How must I label an imported engine with an exclusion
or a permanent exemption?
(a) For engines imported under Sec. 1068.310(a) or (b) or Sec.
1068.315(a), you must place a permanent label or tag on each engine. If
no specific label requirements from the standard-setting part or from
subpart C of this part apply, you must meet the following requirements:
* * * * *
(b) * * *
(4) State:
THIS ENGINE IS EXEMPT FROM THE REQUIREMENTS OF [identify the part
referenced in 40 CFR 1068.1(a) that would otherwise apply], AS PROVIDED
IN [identify the paragraph authorizing the exemption (for example, ``40
CFR 1068.315(a)'')]. INSTALLING THIS ENGINE IN ANY DIFFERENT
APPLICATION MAY BE A VIOLATION OF FEDERAL LAW SUBJECT TO CIVIL PENALTY.
* * * * *
[[Page 28602]]
89. Section 1068.325 is amended by revising the introductory text
to read as follows:
Sec. 1068.325 What are the temporary exemptions for imported engines?
If we approve a temporary exemption from the restrictions on
importing an engine under Sec. 1039.301(b), you may import it under
the conditions in this section. We may ask the U.S. Customs Service to
require a specific bond amount to make sure you comply with the
requirements of this subpart. You may not sell or lease one of these
engines while it is in the United States. You must eventually export
the engine as we describe in this section unless you get a certificate
of conformity for it or it qualifies for one of the permanent
exemptions in Sec. 1068.315. Section 1068.330 specifies an additional
temporary exemption allowing you to import certain engines you intend
to sell or lease.
* * * * *
90. A new Sec. 1068.340 is added to read as follows:
Sec. 1068.340 What special provisions apply to Independent Commercial
Importers?
We generally consider engines to be new when they are imported into
the United States, even if they have previously been used outside the
country. See 40 CFR part 89, subpart G and 40 CFR 89.906(b) for special
provisions allowing Independent Commercial Importers to show that such
engines meet the requirements of the standard-setting part without the
full certification process.
91. Section 1068.501 is amended by revising paragraphs (b), (c)(1),
(e), (f), and (h), and adding paragraph (a)(7) to read as follows:
Sec. 1068.501 How do I report engine defects?
(a) * * *
(7) This section distinguishes between defects and possible defect.
A possible defect occurs anytime there is an indication that an
emission-related component might have a defect, as described in
paragraph (b)(1) of this section.
(b) Investigation of possible defects. If the number of engines
that have a possible defect, as defined by paragraph (b)(1) of this
section, exceed the thresholds specified in paragraph (e) of this
section, you must conduct an investigation to determine if an emission-
related component is actually defective.
(1) You must track warranty claims, parts shipments, and the other
information specified in paragraph (b)(1)(iii) of this section. You
must classify an engine component as having a possible defect if any of
the following is true:
(i) A warranty claim is submitted for the component, whether this
is under your emission-related warranty or any other warranty.
(ii) You ship a replacement component other than for normally
scheduled maintenance during the useful life of the engine.
(iii) You receive any other information indicating the component
may be defective, such as information from dealers or hot line
complaints.
(2) Your investigation must be prompt, thorough, consider all
relevant information, follow scientific and engineering principles, and
be designed to obtain all the information specified in paragraph (d) of
this section.
(3) Your investigation only needs to consider possible defects that
occur within the useful life period, or within five years after the end
of the model year, whichever is longer.
(4) You must continue your investigation until you are able to show
that components are not defective or you obtain all the information
specified for a defect report in paragraph (d) of this section. Send us
an updated defect report anytime you have significant additional
information.
(5) If a component with a possible defect is used in additional
engine families or model years, you must investigate whether the
component or part may be defective when used in these additional engine
families or model years, and include these results in any defect report
you send under paragraph (c) of this section.
(6) If your initial investigation concludes that the number of
engines with a defect is fewer than the thresholds specified in
paragraph (f) of this section, but other information later becomes
available that may show that the number of engines with a defect
exceeds these thresholds, then you must resume your investigation. If
you resume an investigation, you must include the information from the
earlier investigation to determine whether to send a defect report.
(c) * * *
(1) Your investigation shows that the number of engines with a
defect exceeds the thresholds specified in paragraph (f) of this
section. Send the defect report within 15 days after the date you
identify this number of defective engines. See paragraph (h) of this
section for reporting requirements that apply if the number of engines
with a defect does not exceed the thresholds in paragraph (f) of this
section.
* * * * *
(e) Thresholds for conducting a defect investigation. Unless the
standard-setting part specifies otherwise, you must begin a defect
investigation based on the following threshold values:
(1) For engine with rated power under 560 kW:
(i) When the component is a catalytic converter (or other
aftertreatment device), for one of the following number of engines that
may have the defect:
(A) For engine families with annual sales below 4,000 units: 20 or
more engines.
(B) For engine families with annual sales between 4,000 and 100,000
units: more than 2 percent of the total number of engines in the engine
family.
(C) For engine families with annual sales above 100,000 units:
2,000 or more engines.
(ii) When the emission-related component is anything but a
catalytic converter (or other aftertreatment device), for one of the
following number of engines that may have the defect:
(A) For engine families with annual sales below 4,000 units: 40 or
more engines.
(B) For engine families with annual sales between 4,000 and 100,000
units: more than 4 percent of the total number of engines in the engine
family.
(C) For engine families with annual sales above 100,000 units:
4,000 or more engines.
(2) For engine with rated power greater than or equal to 560 kW, if
the number of engines in an engine family that may have the defect
exceeds 1 percent of the total number of engines in the engine family
or 5 engines, whichever is greater.
(f) Thresholds for filing a defect report. You must send a defect
report based on the following threshold values:
(1) For engine with rated power under 560 kW:
(i) When the component is a catalytic converter (or other
aftertreatment device), for one of the following number of engines that
may have the defect:
(A) For engine families with annual sales below 4,000 units: 5 or
more engines.
(B) For engine families with annual sales between 4,000 and 100,000
units: more than 0.125 percent of the total number of engines in the
engine family.
(C) For engine families with annual sales above 100,000 units: 125
or more engines.
(ii) When the emission-related component is anything but a
catalytic converter (or other aftertreatment
[[Page 28603]]
device), for one of the following number of engines that may have the
defect:
(A) For engine families with annual sales below 4,000 units: 10 or
more engines.
(B) For engine families with annual sales between 4,000 and 100,000
units: more than 0.250 percent of the total number of engines in the
engine family.
(C) For engine families with annual sales above 100,000 units: 250
or more engines.
(2) For engine with rated power greater than or equal to 560 kW, if
the number of engines in an engine family that has the defect exceeds
0.5 percent of the total number of engines in the engine family or 2
engines, whichever is greater.
* * * * *
(h) Investigation reports. If you investigate possible defects
under paragraph (b) of this section and find that the number of engines
with a defect does not exceed the thresholds specified in paragraph (f)
of this section, you must send us a report supporting this conclusion.
Include the information specified in paragraph (d) of this section, or
explain why the information is not relevant. Send this report within 15
days after the date you reach this conclusion.
* * * * *
[FR Doc. 03-9737 Filed 5-22-03; 8:45 am]
BILLING CODE 6560-50-P