[Federal Register: September 5, 2006 (Volume 71, Number 171)]
[Proposed Rules]
[Page 52381-52401]
From the Federal Register Online via GPO Access [wais.access.gpo.gov]
[DOCID:fr05se06-11]
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Part II
Department of Transportation
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Federal Aviation Administration
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14 CFR Parts 91, 121, and 125
Revisions to Digital Flight Data Recorder Regulations for Boeing 737
Airplanes and for Part 125 Operators; Proposed Rule
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DEPARTMENT OF TRANSPORTATION
Federal Aviation Administration
14 CFR Parts 91, 121, and 125
[Docket No.: FAA-1999-6482; Notice No. 06-12]
RIN 2120-AG87
Revisions to Digital Flight Data Recorder Regulations for Boeing
737 Airplanes and for Part 125 Operators
AGENCY: Federal Aviation Administration (FAA), DOT.
ACTION: Supplemental Notice of Proposed Rulemaking (SNPRM).
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SUMMARY: The FAA is revising a previous proposal to increase the number
of digital flight data recorder (DFDR) parameters required for all
Boeing 737 series airplanes. Based on safety recommendations from the
National Transportation Safety Board (NTSB) following the
investigations of two accidents and other incidents involving 737s, the
FAA proposed the addition of flight recorder equipment to monitor the
rudder system on 737s. Since that time, the FAA has mandated
significant changes to the rudder system on these airplanes.
Accordingly, this new proposed rule would apply to a different set of
airplanes than originally anticipated. We are requesting comment on
this change in applicability and are requesting updated economic
information regarding installation of the proposed monitoring
equipment. The original proposed rule also sought to amend the flight
data recorder (FDR) requirements of part 125 that would affect all
airplanes operated under that part or under deviation from that part;
we have included that same proposal in this SNPRM.
DATES: Send your comments on or before December 4, 2006.
ADDRESSES: You may send comments identified by Docket Number FAA-1999-
6482 using any of the following methods:
DOT Docket Web site: Go to http://dms.dot.gov and follow
the instructions for sending your comments electronically.
Government-wide rulemaking Web site: Go to http://www.regulations.gov
and follow the instructions for sending your
comments electronically.
Mail: Docket Management Facility; U.S. Department of
Transportation, 400 Seventh Street, SW., Nassif Building, Room PL-401,
Washington, DC 20590-0001.
Fax: 1-202-493-2251.
Hand Delivery: Room PL-401 on the plaza level of the
Nassif Building, 400 Seventh Street, SW., Washington, DC, between 9
a.m. and 5 p.m., Monday through Friday, except Federal holidays.
For more information on the rulemaking process, see the
SUPPLEMENTARY INFORMATION section of this document.
Privacy: We will post all comments we receive, without change, to
http://dms.dot.gov, including any personal information you provide. For
more information, see the Privacy Act discussion in the SUPPLEMENTARY
INFORMATION section of this document.
Docket: To read background documents or comments received, go to
http://dms.dot.gov at any time or to Room PL-401 on the plaza level of
the Nassif Building, 400 Seventh Street, SW., Washington, DC, between 9
a.m. and 5 p.m., Monday through Friday, except Federal holidays.
FOR FURTHER INFORMATION CONTACT: For technical issues: Timothy W.
Shaver, Avionics Systems Branch, Aircraft Certification Service, AIR-
130, Federal Aviation Administration, 800 Independence Avenue, SW.,
Washington, DC 20591; telephone (202) 385-4686; facsimile (202) 385-
4651; e-mail tim.shaver@faa.gov. For legal issues: Karen L. Petronis,
Senior Attorney, Regulations Division, AGC-200, Office of the Chief
Counsel, Federal Aviation Administration, 800 Independence Ave., SW.,
Washington, DC 20591; telephone (202) 267-3073; facsimile (202) 267-
7971; e-mail: karen.petronis@faa.gov.
SUPPLEMENTARY INFORMATION:
Comments Invited
The FAA invites interested persons to participate in this
rulemaking by submitting written comments, data, or views. We also
invite comments relating to the economic, environmental, energy, or
federalism impacts that might result from adopting the proposals in
this document. The most helpful comments reference a specific portion
of the proposal, explain the reason for any recommended change, and
include supporting data. We ask that you send us two copies of written
comments.
We will file in the docket all comments we receive, as well as a
report summarizing each substantive public contact with FAA personnel
concerning this proposed rulemaking. The docket is available for public
inspection before and after the comment closing date. If you wish to
review the docket in person, go to the address in the ADDRESSES section
of this preamble between 9 a.m. and 5 p.m., Monday through Friday,
except Federal holidays. You may also review the docket using the
Internet at the Web address in the ADDRESSES section.
Privacy Act: Using the search function of our docket Web site,
anyone can find and read the comments received into any of our dockets,
including the name of the individual sending the comment (or signing
the comment on behalf of an association, business, labor union, etc.).
You may review DOT's complete Privacy Act Statement in the Federal
Register published on April 11, 2000 (65 FR 19477-78) or you may visit
http://dms.dot.gov.
Before acting on this proposal, we will consider all comments we
receive on or before the closing date for comments. We will consider
comments filed late if it is possible to do so without incurring
expense or delay. We may change this proposal in light of the comments
we receive.
If you want the FAA to acknowledge receipt of your comments on this
proposal, include with your comments a pre-addressed, stamped postcard
on which the docket number appears. We will stamp the date on the
postcard and mail it to you.
Proprietary or Confidential Business Information
Do not file in the docket information that you consider to be
proprietary or confidential business information. Send or deliver this
information directly to the person identified in the FOR FURTHER
INFORMATION CONTACT section of this document. You must mark the
information that you consider proprietary or confidential. If you send
the information on a disk or CD-ROM, mark the outside of the disk or
CD-ROM and also identify electronically within the disk or CD-ROM the
specific information that is proprietary or confidential.
Under 14 CFR 11.35(b), when we are aware of proprietary information
filed with a comment, we do not place it in the docket. We hold it in a
separate file to which the public does not have access, and place a
note in the docket that we have received it. If we receive a request to
examine or copy this information, we treat it as any other request
under the Freedom of Information Act (5 U.S.C. 552). We process such a
request under the DOT procedures found in 49 CFR part 7.
Availability of Rulemaking Documents
You can get an electronic copy using the Internet by:
(1) Searching the Department of Transportation's electronic Docket
Management System (DMS) Web page (http://dms.dot.gov/search);
[[Page 52383]]
(2) Visiting the FAA's Regulations and Polices Web page at http://www.faa.gov/regulations_policies/
; or
(3) Accessing the Government Printing Office's Web page at http://www.gpoaccess.gov/fr/index.html
.
You can also get a copy by sending a request to the Federal
Aviation Administration, Office of Rulemaking, ARM-1, 800 Independence
Avenue, SW., Washington, DC 20591, or by calling (202) 267-9680. Make
sure to identify the docket number, notice number or amendment number
of this rulemaking.
Anyone is able to search the electronic form of all comments
received into any of our dockets by the name of the individual
submitting the comment (or signing the comment, if submitted on behalf
of an association, business, labor union, etc.). You may review DOT's
complete Privacy Act statement in the Federal Register published on
April 11, 2000 (Volume 65, Number 70; Pages 19477-78) or you may visit
http://dms.dot.gov.
Small Business Regulatory Enforcement Fairness Act
The Small Business Regulatory Enforcement Fairness Act (SBREFA) of
1996 requires FAA to comply with small entity requests for information
or advice about compliance with statutes and regulations within its
jurisdiction. If you are a small entity and you have a question
regarding this document, you may contact your local FAA official, or
the person listed under FOR FURTHER INFORMATION CONTACT. You can find
out more about SBREFA on the Internet at http://www.faa.gov/avr/arm/sbrefa.htm, or by e-mailing us at -AWA-SBREFA@faa.gov. http://
http://www.faa.gov/regulations_policies/rulemaking/sbre_act/.
Authority for This Rulemaking
The FAA's authority to issue rules regarding aviation safety is
found in Title 49 of the United States Code. Subtitle I, Section 106
describes the authority of the FAA Administrator. Subtitle VII,
Aviation Programs, describes in more detail the scope of the agency's
authority.
This rulemaking is promulgated under the authority described in
Subtitle VII, Part A, Subpart III, Section 44701. Under that section,
the FAA is charged with prescribing regulations providing minimum
standards for other practices, methods and procedures necessary for
safety in air commerce. This regulation is within the scope of that
authority since flight data recorders are the only means available to
account for aircraft movement and flight crew actions critical to
finding the probable cause of incidents or accidents, including data
that could prevent future incidents or accidents.
I. Background
A. Statement of the Problem
Two aviation accidents in the United States involving Boeing 737
series airplanes (737s) appear to have been caused by a rudder hardover
with resultant roll and sudden descent: United Airlines flight 585,
near Colorado Springs, Colorado, on March 3, 1991, and USAir flight
427, near Aliquippa, Pennsylvania, on September 8, 1994. Following
lengthy investigations, the NTSB determined that the rudder on 737s may
experience sudden uncommanded movement, or movement opposite the
pilot's input, which may cause the airplane to roll suddenly. Other
incidents of suspected uncommanded rudder movement have been reported,
including a 1996 incident involving Eastwind Airlines (Eastwind) flight
517, a 737-2H5, and five incidents in 1999 involving U.S.-registered
airplanes.
The 737s involved in the United Airlines and USAir accidents, and
those in the more recent incidents, were equipped with the flight data
recorders required by the regulations then in effect. However, these
airplanes were not required to record, nor were they equipped to
provide, information about the airplane's movement about its three axes
or the position of flight control surfaces immediately preceding the
accident or incident. While the FAA has undertaken a series of measures
designed to address the suspected rudder problems, our efforts have
been limited by a lack of data that focused on the control and movement
of the components of the 737 rudder system. Without more data, neither
the FAA nor the NTSB can definitively identify the causes of suspected
uncommanded rudder events.
B. FAA Actions
Following piloted computer simulations of the USAir accident and
reports of malfunctions in the yaw damper system of 737s, the FAA
mandated design changes to the rudder system of 737s. First, the FAA
issued Airworthiness Directive (AD) 97-14-03 (62 FR 34623, June 27,
1997), which requires installation of a newly designed rudder-limiting
device and a newly designed yaw damper system, in an effort to address
possible rudder hardover situations and uncommanded yaw damper
movements. Second, in response to the possibility of a secondary slide
jam and rudder reversal, the FAA issued AD 97-14-04 (62 FR 35068, June
30, 1997). That AD requires operators to install a new vernier control
rod bolt and a new main rudder power control unit (PCU) servo valve in
each airplane.
C. Safety Recommendations: 1995-1997
Between 1995 and 1997, while investigating the USAir accident, the
NTSB issued 20 safety recommendations dealing with the 737; three of
those (A-95-25, A-95-26, and A-95-27) dealt specifically with upgrades
to the FDR for all 737s. The NTSB stated that if either the United
Airlines or the USAir 737 had recorded data on the flight control
surface positions, flight control inputs, and lateral acceleration, the
NTSB would have been able to identify quickly any abnormal control
surface movements and configuration changes or autopilot status changes
that may have been involved in the loss of control.
At the time it made its recommendations, the NTSB recognized that
the 737 had flown over 92 million hours since its initial certification
in December 1967, and that the airplane's accident rate is comparable
to that of other airplanes of a similar type. Nonetheless, the Board
concluded that the design changes made to the rudder system in
accordance with the issued ADs did not eliminate the possibility of
other potential failure modes and malfunctions.
D. FAA Response: 1997 Regulations
In response to these safety recommendations, the FAA published
revisions to the DFDR requirements for all airplanes (Revisions to
Digital Flight Data Recorder Rules; Final Rule (62 FR 38362, July 17,
1997)). The revised DFDR regulations prescribe the 88 parameters that
must be recorded on DFDRs, with the exact number of parameters required
to be recorded determined by the date of airplane manufacture. The
number of parameters that must be recorded range from 18 for a
transport category airplane manufactured on or before October 11, 1991,
to 88 for airplanes manufactured after August 19, 2002.
E. NTSB's 1999 Findings and Safety Recommendations
On March 24, 1999, the NTSB issued the final report of its
investigation into the crash of USAir flight 427. The NTSB determined
that the probable cause of the accident was a loss of control resulting
from the movement of the rudder surface position to its blowdown limit.
Further, the NTSB stated that
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``* * * the rudder surface most likely deflected in a direction
opposite to that commanded by the pilots as a result of a jam of the
main rudder PCU servo valve secondary slide to the servo valve
housing offset from its neutral position and overtravel of the
primary slide.''
In its March 1999 report, the NTSB concluded that the 1997
regulations for upgrading DFDRs are inadequate for existing 737s,
because they do not require specific flight control information to be
recorded. Because several 737 rudder-related events have been
associated with the yaw damper system (which moves the rudder
independent of flightcrew input), the NTSB concluded that it is
important that yaw damper status (parameter 89), yaw damper command
(parameter 90), standby rudder status (parameter 91), and control
wheel, control column, and rudder pedal forces (parameter 88) be
recorded on all 737s. The NTSB also pointed out that, for optimal
documentation, the indicated parameters need to be sampled more
frequently than is required currently. The NTSB stated that by
recording the yaw damper's operation and the resultant rudder surface
movements, a yaw damper event could be distinguished quickly from a
flightcrew input or a rudder anomaly. The NTSB considers this
information critical to investigating 737 incidents or accidents. The
NTSB stated that if pilot flight control input forces had been recorded
on the United Airlines, USAir, or Eastwind FDRs, the NTSB
investigations would have been resolved more quickly and actions taken
to prevent similar events would have been hastened.
On April 16, 1999, the NTSB submitted the following recommendations
to the FAA regarding recording additional parameters on 737 DFDRs:
Recommendation No. A-99-28. Require that all 737s operated under
part 121 or part 125 that currently have a FDAU be equipped, by July
31, 2000, with a flight data recorder system that records, at a
minimum, the parameters required by the 1997 DFDR regulations
applicable to that airplane, plus the following parameters: Pitch trim,
trailing edge flaps, leading edge flaps, thrust reverser position (each
engine), yaw damper command, yaw damper status, standby rudder status,
and control wheel, control column, and rudder pedal forces. Yaw damper
command, yaw damper status, and control wheel, control column, and
rudder pedal forces should be sampled at a minimum rate of twice per
second.
Recommendation No. A-99-29. Require that all 737s operated under
part 121 or part 125 that are not equipped with a FDAU be equipped, at
the earliest time practicable, but no later than August 1, 2001, with a
flight data recorder system that records, at a minimum, the same
parameters noted in safety recommendation No. A-99-28.
The NTSB also noted in its final report on the USAir accident that
737 flightcrews continue to report anomalous rudder behavior and that
the NTSB considers it possible that another catastrophic event related
to 737 rudder upset could occur.
F. FAA Response: Notice No. 99-19
The FAA agreed with the intent of NTSB Safety Recommendation Nos.
A-99-28 and A-99-29 and the NTSB's concerns regarding continuing
reports of rudder-related incidents on 737s. On November 9, 1999, the
FAA issued Notice No. 99-19 (64 FR 63140, November 18, 1999), which
proposed that all 737s be required to record the parameters listed in
Sec. 121.344(a)(1) through (a)(22), (a)(88), plus three new
parameters, designated as (a)(89) through (a)(91). The new parameters
are yaw damper status, yaw damper command, and standby rudder status.
In addition, the FAA proposed increasing the required sampling rate for
the control forces listed in current paragraph (a)(88) for 737s. The
FAA proposed that all 737s equipped with a FDAU of any type as of July
16, 1996, or manufactured after July 16, 1996, comply by August 18,
2000. For all 737s not equipped with a FDAU of any type as of July 16,
1996, the FAA proposed a compliance date of August 20, 2001. The FAA
noted that if it received sufficient data to support an extension, the
compliance period for airplanes retrofitted to include FDAUs between
July 16, 1996, and November 18, 1999, would be extended to August 19,
2002.
The FAA proposed corresponding changes to part 125 for 737s
operated under that part. In addition, the FAA proposed that no
deviation authority from the FDR requirements of part 125 would be
granted for any model airplane, and that any previously issued
deviation from the DFDR requirements of part 125 would no longer be
valid. The FAA also proposed that Sec. 91.609 be amended to reflect
that all airplanes operating under part 91 under deviation authority
from part 125 must comply with the DFDR requirements in part 125,
notwithstanding such deviation authority.
II. Continuing Need for This Rulemaking
The original NPRM, issued by the FAA in 1999, proposed that in
addition to other applicable requirements, all 737 model airplanes must
record certain additional parameters of flight data, including those
specifically designed to monitor rudder system components. The FAA
added that it planned on issuing the final rule with an immediate
effective date to address the unresolved issues with the airplane as
soon as possible.
In January 2001, Boeing submitted a letter to the docket requesting
that the FAA delay the release of any final rule. The request was based
on Boeing's 737 Rudder System Enhancement Program (RSEP), which itself
was based on an NTSB recommendation to develop a ``reliably redundant
rudder system'' for the 737. Boeing stated that the RSEP changes will
make the 737 rudder system functionally equivalent to the 3-actuator
system found on its 757 and 767 model airplanes.
Boeing's letter states that on January 16, 2001, it presented a
detailed description of its 737 RSEP changes to the NTSB. While noting
that the proposed rule would be applicable to the original rudder
system, not the one being developed under the RSEP, it attempted to
minimize the value of a final rule that applied only to airplanes with
the older system installed. Boeing also questioned whether it would
still be appropriate to treat the 737 different than other airplanes
once the rudder system was modified.
While the redesigned rudder control system meets the latest FAA
system requirements, it remains a system unique to the 737 model
airplane. In Boeing 757/767/777 model airplanes, the rudder control
system has three separate actuators in separate power control units
(PCU) that are always powered. The original design of the 737 rudder
control system had a single input into a valve that controlled two
installed actuators in the PCU. In the redesigned 737 system, there are
three actuators, but they are housed in two PCUs rather than the three
present in the other Boeing model airplanes. The main PCU has two
actuators, each with its own valve that accepts input. The third
actuator is in a standby PCU that is not normally powered unless the
main PCU fails. Thus, the 737 rudder control system effectively still
has only two actuators during normal flight operations, and a single
actuator when the main PCU is inoperative.
Several events have occurred since the NPRM was issued in 1999,
including Boeing's RSEP. One of the recommendations issued by the NTSB
included the formation of an engineering test and evaluation board
(ETEB) to conduct a failure analysis of
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the rudder actuation control system of the 737. The 737 ETEB was formed
in May 1999 and issued its final report in July 2000.
Among the key findings of the 737 ETEB are the following:
(1) The 737 rudder control system is susceptible to a number of
failures and jams. These failures and jams can affect the operation of
the rudder power control units and can result in uncommanded rudder
motion.
(2) A number of failures and jams of the 737 rudder control system
were detected in configurations on which the FAA later issued
corrective action under one or more Airworthiness Directives (ADs).
More than two dozen of these failures and jams (alone or in
combination) have what are considered catastrophic failure effects.
(3) Even when 737s were in compliance with the ADs issued at the
time, rudder control system failures and jams were still present.
(4) Most of the failure modes were discernable on both the older
(classic) models and the newer (next generation) models of the 737.
(5) There were no catastrophic failure modes identified at cruise
speed and altitude. One change to the hydraulic pressure system
mandated by AD reduced the time an airplane was exposed to catastrophic
failure modes, but exposure was not eliminated during takeoffs and
landings.
Among its recommended long-term actions, the ETEB recommended that
the 737 rudder system be modified to ensure that no single failure or
single jam of the rudder control system would cause an uncommanded
rudder motion that has catastrophic results.
The NTSB did not withdraw or change its recommendation regarding
further monitoring of the rudder system on 737s, and indicated in a
February 2001 letter to the FAA that it had not changed its position
regarding the need for installation of the new FDR equipment ``at the
earliest possible opportunity regardless of any rudder system
modification.''
In November 2001, the FAA published a proposed AD that would
require the installation of a new rudder control system (and
accompanying changes to nearby systems) (66 FR 56783, November 13,
2001). The FAA determined that the inherent failure modes in the 737
rudder system, verified by the ETEB, result in a design system
architecture that is unsafe. The FAA also determined that the rudder
system design architecture led to a need for non-normal operational
procedures, which had also been implemented by AD. The FAA concluded
that the combination of the inherent failure modes and the non-normal
operational procedures, considered together, present an unsafe
condition that warranted the incorporation of a newly designed rudder
control system.
The final rule AD was published on October 7, 2002 (67 FR 62341),
with an effective date of November 12, 2002, and gives all operators of
737 model airplanes 6 years to install a new rudder control system.
Boeing has been installing the newly designed rudder control system
on 737 model airplanes manufactured since January 2003. Boeing is also
installing the additional sensors that were proposed in the NPRM on
these newly manufactured 737s, and those parameters are being recorded.
When we began drafting a final rule, we realized that the 737 fleet
that would be affected by the proposed rule--those airplanes with the
original rudder system--had already begun to shrink in number. The
promulgation of several Airworthiness Directives means that by the 2008
compliance date for those ADs, no 737 aircraft left in the U.S. fleet
would have the old rudder system. Therefore, we no longer find it
appropriate to require the installation of flight recorder equipment to
monitor those parts of the aircraft which became life-limited by these
ADs and will be eliminated by 2008.
This SNPRM attempts to address the changes in circumstances
introduced by the RSEP, the findings by the ETEB, and the ADs issued by
the FAA by revising the fleet of airplanes affected by the proposed
rule, and by changing the proposed compliance time to coincide with the
modifications required by the ADs.
The FAA does not have convincing evidence that the redesigned
rudder control system obviates the need for the additional flight
recorder parameters. The newly designed rudder system is unique in that
the third actuator is only activated upon the failure of the main PCU,
at which point the two main actuators are no longer performing. Thus,
the FAA has tentatively concluded that the information that would be
gathered by the addition of the proposed parameters could provide
meaningful information in the event of a rudder control failure. While
the ETEB conducted considerable testing of the 737 aircraft and its
rudder system, those tests cannot duplicate the actual flight
experience of either the original or the new rudder system as it would
be recorded using the parameters proposed. The only way to get this
data is by installation of equipment that will record the movement of
the rudder surface and the companion actions of the yaw dampers. The
ETEB did not have this information because the equipment to record it
was not mandatory. Since the additional parameters have yet to be
installed, investigators of an accident or incident remain similarly
limited today.
Boeing has indicated that there have been no reports of rudder
hardover incidents on 737s with the redesigned rudder system. However,
since the system has only been installed as original equipment on
airplanes since 2003, and since compliance with the retrofit is not
required until 2008, only limited historical data on the function and
reliability of this redesigned system is available.
Additionally, as discussed above, the redesigned rudder system does
not actively power three actuators. Rather, the third actuator only
powers up in the event of a power failure to the two primary actuators.
Thus, while the new design incorporates three actuators, similar to the
design of Boeing's 757/767/777 model airplanes, a functional difference
remains between the new 737 rudder system and that installed on other
Boeing airplanes.
We note that the rudder control system enhancement can be split
into three separate tasks and are not normally accomplished at once.
The first two changes can be accomplished with the old rudder control
system still in place. As of August 2004, Boeing had shipped 2,957 kits
needed for the first part of the installation, but only 728 kits for
the third part. The FAA assumes these numbers have gone up; however,
since there is no reporting requirement for compliance with the AD, we
have no way of knowing how many new components or complete rudder
control systems have been installed. However, the FAA understands that
the wiring kit provided by Boeing for the first part of the redesigned
rudder system includes the wiring required for the proposed additional
sensors, making the installation of the parameters less burdensome than
originally anticipated. Compliance with this rule, if adopted, would
require the installation of the sensors and their connection to the
DFDR system. These circumstances argue for either the issuance of this
rule (to take advantage of the work yet to be accomplished on the
majority of the 737 fleet) or withdrawal, as soon as possible.
We continue to believe that unless the proposed additional flight
recorder sensors are installed and the function of the new system
components are monitored, there will never be any means to eliminate
the rudder system as a possible cause of any future incident
[[Page 52386]]
or accident, or to identify the particular component or action as a
source of the problem if the rudder control system is involved. These
are the circumstances that spurred the original NTSB recommendations on
the 737, but we are cognizant of the significant changes in
circumstances that have occurred in the last five years, including the
mandated changes to the original rudder system, and the decline in
reported incidence of rudder hardover events.
We are also aware that we now need new information on the costs and
benefits of requiring these enhancements on a fleet of aircraft that
did not exist when we originally proposed the rule, those with the new
rudder system installed.
The FAA originally evaluated the cost data associated with this
SNPRM nearly five years ago, shortly after the close of the comment
period for the NPRM. Since then, some 737s may have been retrofitted
with the new rudder, and may be partially equipped to record the
additional flight data parameters. Further, with the introduction of
the new Boeing 737 rudder, there is a new class of airplane that will
incur retrofitting costs that may be different from those costs
reported by the industry and used in the Supplemental Preliminary
Regulatory Evaluation (Supplemental PRE) that accompanies this
rulemaking document. Because the FAA does not have the data necessary
to evaluate the impact of, and need for, a rule requiring the
additional parameters for those 737s equipped with the new rudder
control system, the agency requests more current information for the
following specific questions as well as any additional data that the
public believes needs to be incorporated into the economic analysis.
1. How many 737s are in your fleet?
2. How many 737s do not record the flight parameters that we are
proposing be recorded? How many 737s currently record these parameters?
3. How many 737s have been retrofitted with the new Boeing rudder?
How many of those airplanes do not record the flight data parameters
that we propose to be recorded?
4. How many 737s are expected to be retrofitted with the new Boeing
rudder in each of the years 2006, 2007, and 2008?
5. How many 737s are expected to be retired in each of the years
2006, 2007, and 2008?
6. For those 737s that have already been retrofitted under the AD
but do not record the additional flight data parameters, how much would
it cost to install the equipment to record the additional flight data
parameters? How many days would it take to install the equipment to
record those additional flight data parameters on those airplanes if
the work were done: during a major maintenance session; an overnight
maintenance session?
7. Are the assumptions and estimates made in Table 1 of this notice
and the accompanying Supplemental PRE, and throughout that report,
accurate? If you are able to provide more current data, please submit
it.
8. Please provide an update on the status of the various design
changes that would still need to be accomplished to provide the
information necessary to install the proposed flight recorder
parameters on the fleet expected to be retrofitted with the new rudder
design.
We are issuing this SNPRM to gather information on the need for
flight recorder parameters that monitor the new rudder system. This
proposal represents a shift in the scope of the rule. When the DFDR
enhancements were proposed, work was still in progress in diagnosing
the functions and perceived weaknesses of the original rudder system.
We have modified the original proposed regulatory text to require that
the flight recorder parameters proposed in 1999 be installed concurrent
with the new rudder system; we have redrafted the rule to state that
compliance would be required no later than November 12, 2008, the date
that compliance is required with the Airworthiness Directives mandating
the installation of the redesigned rudder system. We have made other
changes to the proposed regulatory text based on comments to the NPRM.
These changes, which are explained later in the document, will not be
revisited. Accordingly, we request interested parties to direct their
attention to our requests for data, the need for additional parameters
for the redesigned 737 rudder control system, and the proposed November
2008 compliance date.
In summary, the FAA finds this supplemental proposal necessary in
order to update the status of the number and configuration of 737s in
the current fleet. Since we do not track operator compliance with ADs,
the information requested here will tell us how many airplanes have
been retrofitted with the new rudder system and the estimated costs for
installing the DFDR parameters if the new rudder system has already
been installed. We expect to receive information on the number of
retirements expected, as well as the number of aircraft that are
already in compliance because they are new or because the proposed DFDR
rudder parameters may have been installed voluntarily.
III. Summary of Comments
The FAA received 17 comments on the proposed rule. Of the 17
comments, the Air Transport Association of America, Inc. (ATA),
submitted three separate comments; one of the ATA submissions included
seven comments from member airlines. Only one commenter, the Air Line
Pilots Association (ALPA), supports the proposed rule as published.
Specifically, ALPA agreed that a potentially unsafe condition has been
identified and concurs with the proposed amendments. The other
commenters generally supported the intent of the proposed rule;
however, these commenters expressed concern about:
(1) The time frame for compliance proposed in the Notice of
Proposed Rulemaking (NPRM),
(2) the availability of installation instructions,
(3) the unavailability of parts, and
(4) the probability of considerable airplane out-of-service time.
The amount of time that has elapsed since comment was invited, and
the events that have occurred since comment was invited, has caused
most of the comments to become outdated. The proposed compliance times
are no longer applicable, nor are the costs that were applied to them.
Accordingly, we are not including a discussion of comments concerning
compliance time, parts availability, or out of service time since these
issues no longer exist under current circumstances.
Comments on Specific Proposed Requirements
The following disposition of comments addresses those comments that
were not overtaken by intervening events and actions. Some of the
questions and information submitted with them remain relevant to the
actions contemplated under this modified proposal.
Boeing stated that it typically does not develop or commit to
design changes until the release of a final rule. However, because of
the proposed short time frame for compliance, Boeing had already
implemented production design changes in an attempt to accommodate the
expected compliance schedule. Boeing noted that a typical design change
of this magnitude would require a minimum of 18 months to allow time to
develop the design and to work with parts suppliers, operators, and the
FAA.
[[Page 52387]]
A. Compliance Issues for Rudder Pedal Forces
Proposal: The FAA stated in Notice No. 99-19 that it had received
inquiries from the NTSB and Boeing concerning an acceptable means of
recording the rudder pedal control input forces required by paragraph
(a)(88) of Sec. 121.344; the requirement was added in the 1997
amendment to the DFDR regulations.
To meet the 1997 regulations, Boeing developed a rudder pedal force
transducer that is placed ``midstream'' in the rudder control system.
The transducer is designed to identify whether the input was coming
from the cockpit or from the rudder assembly.
The NTSB indicated informally that it would prefer a system that
measures the rudder input force at the individual rudder pedals. This
would require the addition of four transducers (one on each rudder
pedal) rather than the single one designed by Boeing. The FAA noted
that the NTSB believes that only the installation of four rudder pedal
force sensors would meet the intent of its April 16, 1999
recommendation to record rudder input force.
The FAA acknowledged the difference between the data acquired using
Boeing's already approved single transducer system and the NTSB's
suggested four-pedal sensor retrofit. The FAA requested comment on the
necessity and feasibility of instrumenting all four rudder pedals on
737s with force sensors as a means of complying with paragraph (a)(88).
The FAA also requested comment on whether Boeing's single force
transducer should remain an accepted means of compliance with parameter
88 for all 737s that do not have the transducer installed or had not
yet otherwise complied with paragraph (a)(88). In addition, the FAA
requested cost data for the four-pedal retrofit to determine whether
the incremental increase in benefits that would be provided by that
configuration would be offset by the additional time and costs involved
if such a requirement were mandated.
Comments: The FAA received two comments on recording rudder control
inputs, one from the NTSB and one from Boeing.
The NTSB stated that the rudder pedal force exerted by each
crewmember is critical to its understanding the loss of control
problems experienced in the 737. The NTSB added that in its
investigation of a 1999 rudder incident involving Metrojet, not knowing
the amount of rudder pedal force exerted has made it impossible to
separate pilot actions from (possible) rudder system anomalies. The
Board argued that a single sensor placed midstream in the rudder
control system, as introduced by Boeing, would not identify whether the
flightcrew inputs are in opposition to each other or whether the nose
wheel steering (NWS) or some other system anomaly forward of the sensor
causes the inputs. In addition, any jams in the controls between the
pedals and the sensor may go undetected, because the amount of force
exerted by the flightcrew would not be registered by the sensor. The
NTSB stated that, if the upgrade required only a single force sensor in
the rudder system, the possibility would remain that the information
would not be sufficient to identify some future flight control problems
even after the proposed retrofit.
Boeing commented that neither the existing rule nor the proposed
rule includes specific requirements that support a change to the
current design to measure individual rudder pedal force. Boeing stated
that the 1997 rule contained no requirement to measure any disagreement
between pilot inputs. According to Boeing, the NTSB recommendations and
the proposed rule suggested that the only issue is the ability to
quickly distinguish a yaw damper event from a flightcrew input or a
rudder anomaly. Boeing believed the current single transducer design
meets this intent.
Boeing claimed the current 737 NG airplane rudder pedal design
satisfies the parameter 88 requirements defined in the existing rule.
Boeing added that the rudder design on 737-100 through -500 series
airplanes delivered since August 1998 is identical to that on the 737
NG airplanes, and retrofit kits are available for this installation in
airplanes delivered before then. Boeing noted that any change to the
requirements to which this installation complies would require
additional retrofit.
Boeing further stated that the proposed addition of four individual
rudder pedal force sensors would require a significant number of design
changes in the rudder control mechanism and to the structure of the
cockpit floor. The 737 has severely limited space in the area these
would be placed, which limits design options. At the time the NPRM was
issued, Boeing and its suppliers had not yet been able to identify a
design solution that could be implemented without significant
structural and system changes that would make retrofit complex,
lengthy, and costly. Boeing added that it expected the design
definition and implementation of four transducers would take much
longer than the implementation dates proposed.
Boeing also argued that four transducers would provide no major
incremental gain in information. According to Boeing, a single
transducer allows investigators to determine why the rudder moved, by
pilot action or system input, but that a single transducer will not
show whether a pedal jammed. The four transducers would enable Boeing
to determine whether the rudder moved and may allow determination of
which pedal was jammed or restricted. However, the four transducers,
like the single transducer, would not permit determination of why a
rudder pedal was jammed or restricted, because the jam or restriction
is also ``upstream'' of the transducers.
FAA reply: Although specifically requested, the FAA did not receive
any cost data or time estimates for a four-rudder-pedal sensor retrofit
as described in the NPRM. While the FAA understands the NTSB's desire
for the information that such rudder pedal sensors might provide,
general comments from Boeing indicate that such a retrofit would be
both time-consuming and costly. The FAA is unaware of a sensor
currently in production that could meet the design requirements that
would be necessitated by the NTSB's request. Even if such a sensor does
exist, Boeing also indicated (in its comment and in discussions with
the FAA) that major redesign of the aircraft might be necessary,
including moving a floor beam, since there is so little space available
under the rudder pedals of the 737. Such modifications would take
several years to design and incorporate into the production line; the
engineering for in-service airplanes would be more complicated, since
changes to major structural components would mean a change to the
airplane's original type design and the airworthiness certification of
every affected airplane. The time that such design and retrofit would
take far exceeds any recommendation of the NTSB, and argues against the
NTSB's own characterization of the modification as time-sensitive.
Further, the FAA is unable to say with any certainty that the
information that might be gathered by the NTSB's proposed pedal force
sensors would lead to a solution to the rudder problem. The rudder
pedal force sensors may well be able to identify the amount of force an
individual pilot is placing on a pedal, but the amount of force does
not seem to have been an issue in the noted accidents or incidents. If
there is a problem in the rudder system, then the amount of force
exerted in an
[[Page 52388]]
attempt to overcome it is less important than finding where the
malfunction is occurring. If pilots are fighting each other for control
using the rudder pedals, then the issue is not with the airplane
itself. It is a suspected problem with the airplane itself that is the
reason for proposing this rule, and the FAA has determined that
continuing to allow compliance with parameter 88 using a single
midstream transducer reflects the best balance of cost and information
to be gained in an attempt to locate the source of the problem in a
timely fashion.
Accordingly, the FAA has decided against promulgating a four-pedal
sensor requirement. The agency has no basis for concluding that a
retrofit of individual rudder pedal sensors would be cost beneficial
when the costs themselves cannot readily be estimated without a
significant investment of time and energy. Moreover, since the FAA is
unable to quantify the requirements either for the equipment or the
recording rate and sensitivity, any information on estimated costs
becomes that much less reliable and certainly falls short of the legal
requirements for imposing the eventual cost on operators.
B. Compliance Issues for the Control Column and Control Wheel
Proposal: Parameter (a)(88) requires that control wheel and control
column input forces be measured and recorded. The current rule requires
that airplanes with breakaway capability record both left and right
side control wheel forces. The FAA noted in the preamble to the NPRM
that there also are issues of acceptable means of measuring control
column and control wheel forces. The FAA specifically requested comment
on the means and costs of measuring these control forces under the
requirements proposed in this rulemaking.
Comments: The FAA received comments from Boeing, Alaska, United
Airlines, ATA, and the NTSB on the control column and control wheel
systems.
Boeing stated that to comply with the existing rule for parameter
(a)(88), Boeing intended to modify the control column and control wheel
force transducers for DFDR application to achieve the increased force
range. Boeing would also install new flight control computer hardware
and software to interface with the new transducers.
Boeing stated that the retrofit for the 737-100 through -500 series
airplanes is basically the same as that for the 737 NG airplanes.
However, it noted the 737-100 through -500 series airplanes include two
control column force transducers in the same location as the 737 NG
airplanes, but that the force applied by individual pilots cannot be
determined because the elevator control systems of the 737-100 through
-500 series airplanes do not have a jam override device between
columns.
Boeing also described the FAA-approved single-wheel force
transducer design for parameter (a)(88), and stated that it meets the
intent of the existing rule provided that the left and right control
wheel positions also are recorded. Boeing stated that the aileron
system measures both cockpit control positions, but only the left
side's force. Each pilot's control inputs go through the left side
force transducer, except in the event of a failure. Boeing added that
because the FAA does not typically consider dual failures a likely
event, the proposed configuration should be acceptable.
Boeing noted that to comply with the existing requirements for
parameter (a)(88), the control wheel force transducer would have to be
modified specifically for DFDR application to achieve the increased
force range. New flight control computer hardware and software would
have to be installed to interface with the new transducer and the force
transducer stops would have to be modified to allow the additional
range.
Boeing further stated the control wheel retrofit of the 737-100
through -500 series airplanes is basically the same as that of the 737
NG airplanes, except that Boeing would add a (new) second control wheel
position transducer to the first officer's control wheel to allow the
737-100 through -500 series airplanes' configurations to be identical
with that of the 737 NG airplanes.
The NTSB stated that although it is concerned that the current
control force sensors will not meet the range and accuracy requirements
of the proposed rule, suitable control force sensors were likely to be
available by the then proposed compliance dates. The NTSB contended
that separate sensors to measure the pilot and copilot flight control
input forces must be used when breakaway features are employed
(breakaway capability allows either pilot to operate the airplane
independently).
Two operators of 737s and the ATA commented that as of the date of
the NPRM, the required sensors had not yet been developed.
FAA reply: The primary objection raised by the commenters was that
the regulation would force early compliance with parameter (a)(88) for
control wheel and control column forces, and that the sensors required
to record to Appendix M specifications were not available and had not
yet been designed. Sensor design and availability are no longer issues
since all aircraft manufactured after August 19, 2002 have been
required to meet Appendix M standards for parameter (a)(88). Nor is
there any need to provide for more than one sensor type since a sensor
that records to Appendix M standards now exists for use in a retrofit.
Accordingly, the FAA intends to adopt the rule as originally proposed,
with the Appendix M standards applicable to all 737s recording all
functions required by parameter (a)(88) (70 pounds control
wheel force and 85 pounds control column force).
The FAA understands that the lateral control system on the 737 has
an override device between the two control wheels that allows either
pilot to operate the control wheel independently, but that the primary
control path for both pilots is through the left cable control path.
The right control is not usually connected and is used only in the
event of a failure. A single control wheel force transducer in the left
cable path records the inputs from both pilots. The FAA agrees that the
single control wheel force transducer is acceptable, provided the left
and right control wheel positions are also recorded. The use of a
single force transducer with two position sensors is acceptable because
comparison of the two position sensors allows detection of a breakout
of the override between the control wheels; this breakout allows the
right cable control path to become active.
C. Compliance Issues; Other Parameters
1. Standby Rudder Status
Proposal: In the NPRM, the FAA proposed to add recording of the
standby rudder status. The standby rudder system is an alternative
source of hydraulic power to the rudder that is used when primary
hydraulic power is lost. The intent of the proposed requirement was to
record whether the standby rudder system switch is in the on or off
position.
Comment: Boeing believed the intent of recording the standby rudder
status was to determine the actual status of the standby rudder system
and not the position of any particular switch. Boeing indicated that
the system should record the state of the standby hydraulic rudder
shutoff valve, which also is controlled by both of the standby rudder
system switches. Boeing maintained this would provide a clearer
indication of the actual status of the standby rudder
[[Page 52389]]
system than recording whether the standby rudder switch is in the on or
off position. The ATA stated that the sensors for the standby rudder
status parameter have not been designed for any 737.
FAA reply: The FAA agrees with the comments and we have revised the
proposed language in paragraph (a)(91) to indicate that it is the valve
position that needs to be recorded for standby rudder status, not the
position of the switch, as initially proposed.
2. Thrust Reverser
Proposal: Under the 1997 DFDR regulations, instrumentation of the
thrust reversers (Sec. 121.344(a)(22)) was not required until the year
2001 for some airplanes and is not required at all for older airplanes.
The proposal would require all 737s regardless of age to record the
thrust reverser position.
Comment: Boeing stated that the requirement for recording thrust
reverser positions would require modifications to the engine accessory
unit (EAU) to monitor the thrust reverser. According to Boeing,
approximately 937 737-100 and -200 airplanes will require two new PC
cards and associated connectors and wiring, and approximately 250 737-
300 and -400 airplanes will require four new PC cards and associated
connectors and wiring if the proposal is adopted. Boeing requested that
the FAA not require instrumentation of the thrust reversers for the
older 737-100 through -500 series airplanes. The 737 NG airplanes would
be retrofitted to record thrust reverser position. Boeing suggested
specific language that could be used to codify its request.
FAA reply: The SNPRM does not incorporate Boeing's suggested
change. Under Sec. 121.344(b)(1), adopted in 1997, the only airplanes
not required to record thrust reverser position, parameter (a)(22), are
airplanes manufactured on or before October 11, 1991, that were not
equipped with a FDAU as of July 16, 1996. All other airplanes must
either be retrofitted to record, or record at manufacture, thrust
reverser position.
The distinction made in Sec. 121.344(b)(1) was introduced to
prevent the oldest airplanes from having to be retrofitted with a FDAU
to meet the 1997 rule, not because thrust reverser data is not
important. Under this SNPRM, the other recording requirements for 737s
necessitate the installation of a FDAU, eliminating the distinction
made in the 1997 rule. Further, the FAA cannot accept Boeing's
suggested language because it is general and would relieve not only
737s but certain other airplanes from the 1997 requirement to record
parameter (a)(22). This proposal would require all 737s to record
parameter (a)(22).
3. Yaw Damper Status and Yaw Damper Command
Proposal: Proposed paragraph (a)(89) would add the recordation of
yaw damper status. The intent of the requirement is to determine
whether the yaw damper is on or off. Proposed paragraph (a)(90) would
add the recordation of yaw damper command. The intent of this
requirement is to record the amount of voltage being received by the
yaw damper system. This determines how much rudder movement is being
commanded.
Comment: For the 737-100 through -500 series airplanes, Boeing
proposed to record the yaw damper linear variable displacement
transducer (LVDT) position feedback from the new yaw damper coupler
through an ARINC 429 interface, and, if the DFDR capacity allows, the
yaw damper command from the yaw damper coupler through an ARINC 429
interface. Boeing noted that the 737 NG airplanes record both the yaw
damper command from the stall management yaw damper and the yaw damper
LVDT position feedback through an ARINC 429 interface. The ATA stated
that sensors for yaw damper status and yaw damper command parameters
are not addressed in a retrofit service bulletin.
FAA reply: Sensors for the yaw damper status and yaw damper command
parameters have been developed and have been installed in 737s
manufactured since August 18, 2000. The sensors exist and the FAA
continues to believe that the parameters should be required.
4. Other Issues
Proposal: The current DFDR regulation allows single-source
recording for control input and control surface positions, parameters
(a)(12) through (a)(14) or (a)(12) through (a)(17), depending on the
date of airplane manufacture. The proposed rule eliminated the
allowance to record these from a single source.
Comments: Boeing stated that Sec. 121.344(b) and (c), as proposed,
removes the allowance to permit recording parameters (a)(12) through
(a)(17) from a single source and applies the full requirement of
appendix M to part 121 to recording these parameters. However,
paragraph (d) still permits recording parameters (a)(12) through
(a)(17) from a single source.
FAA reply: Removing the allowance for recording control and surface
positions from a single source was an error in the proposed rule. This
SNPRM includes the single-source recording as provided in the 1997
rule. A sentence has been added in Sec. 121.344(m) indicating that
single-source recording would remain available to airplanes otherwise
subject to Sec. 121.344(b)(1), (c)(1), or (d)(1).
Proposal: The proposal removes 737s from the requirements of Sec.
121.344(b) and (c), adds specific 737 requirements to Sec. 121.344(d),
(e), and (f), and adds new Sec. 121.344(m).
Comments: Boeing indicated that Sec. 121.344(d), (e), and (f), as
proposed, state that all 737s must comply with the requirements in
paragraphs (m)(1) and (m)(2). Boeing contended this language overlooks
the requirements of paragraph (m). Boeing also did not understand why
paragraphs (d), (e), and (f) were not revised as paragraphs (b) and (c)
to except the 737. Boeing stated that the addition of paragraph (m)
makes it unclear as to what is required for 737s and that it would be
much clearer to include the additional 737 requirements in the existing
applicable paragraphs. Boeing further stated that Sec. 121.344(m), as
proposed, is inconsistent with paragraphs (b), (c), and (d) in that it
requires recording parameters (a)(88) through (a)(91), while paragraphs
(b), (c), and (d) do not.
FAA reply: The modifications to the compliance schedule for
installation of the additional parameters have removed the issue of
compliance time; compliance time is no longer determined by the date of
FDAU installation.
For consistency, Sec. 121.344(b), (c), (d), (e), and (f) are
similarly revised to reference the 737 requirements in Sec.
121.344(m). The FAA has decided against putting the 737 requirements in
each subparagraph because it would be cumbersome, unnecessarily
repetitive, and introduce more possibilities for error.
Proposal: The note to parameter (a)(88) in current Appendix M to
part 121 requires airplanes that have a flight control breakaway
capability (which allows either pilot to operate controls
independently) to record both control force inputs; the note also
discusses sampling rates.
Comments: Boeing pointed out that the note to parameter 88 in
appendix M to part 121 and appendix E to part 125 indicates that all
the comments in the remarks column do not apply to the 737. Boeing
believed that the note is meant to indicate that it is only the
sampling interval remarks that do not apply to the 737s. The NTSB also
stated that the remarks section covers, in addition to the sampling
rate requirements, a
[[Page 52390]]
requirement to record both control force inputs for those airplanes
that have a flight control breakaway capability that allows either
pilot to independently operate the airplane, which still would apply to
737s.
FAA reply: The FAA agrees with Boeing, and has revised footnote 18
to clarify application of the parameter for 737s. The requirement to
record both control force inputs for systems with breakaway
capabilities does apply to the 737, but as discussed above, the FAA has
approved the use of a single control wheel force transducer provided
that both control wheel positions are recorded (although both pilot's
inputs go through the left side force transducer, except in the event
of a failure). Because the FAA historically has not considered a dual
failure a likely event, this configuration is acceptable.
Proposal: The FAA proposed the same changes to the digital flight
data recorder regulations in Sec. 125.226 as those proposed in Sec.
121.344. In addition, the FAA proposed the same changes to Appendix E
to part 125 as those proposed to Appendix M to part 121. The FAA also
proposed that airplanes operating under deviation authority from part
125 must comply with the flight data recorder requirements of part 125
for the particular aircraft. The FAA specified that this deviation
requirement would apply to all aircraft and not only the 737. The FAA
specifically sought comments on why the flight data recorder
requirements of part 125 should not be made applicable to aircraft
operated under deviation authority. In addition, the FAA sought
comments from affected persons operating aircraft under deviation
authority from part 125 concerning the proposed compliance schedule.
Comments: The FAA received no comments on the proposed changes to
part 125. Accordingly, the changes to part 91, applicable to part 125
airplanes operated under deviation authority, and the changes to part
125 and Appendix E are proposed again here without change from the
original proposal.
IV. Changes Adopted in This SNPRM
When the FAA proposed the recordation of new flight data recorder
parameters in November 1999, the ETEB was still in the process of
conducting its failure analysis, and other action by the agency was not
yet contemplated. The ETEB's finding and the FAA's subsequent decision
to issue the AD requiring replacement of the rudder system mandate that
this rule be modified to account for those actions.
This proposed rule, if adopted, would require the installation of
the flight recorder parameters proposed in the NPRM with the following
modifications. The installation would be accomplished simultaneously
with the installation of the redesigned rudder system in order to
minimize the costs and out-of-service time required. The regulatory
evaluation for this proposed rule has been significantly revised to
include this extended compliance time. This extension of the compliance
time also addresses the majority of the comments received in response
to the proposed rule. Specifically, this SNPRM incorporates the
following changes:
Sections 121.344(b), (c), (d), (e), and (f) and Sec.
125.226(b), (c), (d), (e), and (f) would be amended to indicate that
all 737 model airplanes also must comply with the requirements in Sec.
121.344(m) or Sec. 125.226(m), respectively. Sections 121.344(m) and
125.226(m) would be added to indicate that in addition to other
applicable requirements, all 737 model airplanes must record the
parameters listed in paragraphs (a)(1) through (a)(22) and (a)(88)
through (a)(91) in accordance with the ranges, accuracies, resolutions,
and recording intervals specified in Appendix M to part 121 or Appendix
E to part 125, respectively. The proposed compliance times have been
changed to state that the installation of the equipment required to
record these parameters must be accomplished during the installation of
the modified rudder system required by AD or no later than November
2008. These sections would also reinstate the language allowing single-
source recording, as discussed in the disposition of comments. The
parameters that may be recorded from a single source would be
determined by the age of the airplane and its applicable regulations.
Footnote 18 would be added to parameter 88 in Appendix M
to part 121 and Appendix E to part 125 and would read ``For all 737
model airplanes: The seconds per sampling interval is 0.5 per control
input; the remarks regarding the sampling rate do not apply; a single
control wheel force transducer installed on the left cable control is
acceptable provided the left and right control wheel positions also are
recorded.'' Footnote 19 would be added to parameter 88 in Appendix M to
part 121 and Appendix E to part 125 and would read ``For all 737 model
airplanes manufactured on or before January 31, 2001, Range values are:
Full Range; Control wheel 15 lbs.; Control column 40 lbs.; and Rudder pedal 165 lbs.''
Sections 121.344 (a)(91) and 125.226(a)(91) would be
revised to read ``standby rudder valve status'' and in appendix M to
part 121 and appendix E to part 125, the range for parameter 91 would
be revised to read ``Discrete.''
The range for the rudder pedal in parameter 88 in appendix
M to part 121 would be corrected to read ``Rudder pedal
165 lbs.''
No 737s are exempt from this rulemaking. Airplanes that have been
manufactured since January 2003 would already be incompliance with this
rule because the rudder parameters proposed here would have been
installed at manufacture.
V. Chronology
The following is a list of selected events relevant to 737 rudder
control issues and FAA rulemaking actions:
------------------------------------------------------------------------
Date Event
------------------------------------------------------------------------
December, 1967............... The Boeing 737 is type certificated.
March 3, 1991................ United Airlines flight 585 crashes near
Colorado Springs, CO; loss of rudder
control implicated, but the flight
recorder was rudimentary (5 parameters
recorded as required by regulation).
1993......................... NTSB Recommendation on the 737 rudder
system.
September 8, 1994............ Crash of USAir flight 427 near Aliquippa,
PA.
June 9, 1996................. Rudder hardover reported on Eastwind
flight.
1996......................... FAA issues AD on flight crew procedures
to overcome potential system failures.
1995-1997.................... NTSB issues 20 safety recommendations on
the 737, three in 1995 recommending
upgrades to the DFDRs.
June, 1997................... FAA issues two ADs on 737 rudder system
components.
February 23, 1999............ USAir flight 2710 reports uncommanded
rudder hardover at cruise.
March 24, 1999............... NTSB final report on USAir 427 indicates
loss of control from uncommended rudder
hardover as probable cause; says 1997
DFDR rule changes by FAA not adequate
for 737.
May, 1999.................... ETEB formed to conduct failure analysis
on rudder control actuation system of
the 737.
[[Page 52391]]
November 18, 1999............ FAA NPRM proposing three new DFDR
parameters for 737s, proposing
compliance in 2000 or 2001 based on
installed equipment.
December 20, 1999............ Comment period for NPRM closes.
1999......................... Five rudder hardover incidents reported
on 737s during the year.
July, 2000................... ETEB final report finds numerous failure
modes on 737 rudders, recommends
modification of the entire rudder
system.
September, 2000.............. Boeing begins its Rudder System
Enhancement Program (RSEP).
January 16, 2001............. Boeing makes a presentation to the NTSB
on its RSEP findings.
January, 2001................ Boeing submits letter to FAA rule docket
requesting delay of any final rule in
anticipation of final RSEP findings
expected later that year.
February, 2001............... In a letter to the FAA, the NTSB
maintains its position on installation
of new DFDR parameters on 737s as soon
as possible, and regardless of rudder
system modification.
February, 2001............... Boeing applies for a change in type
design based on its RSEP.
November 13, 2001............ FAA publishes NPRM AD on modified rudder
system.
October 7, 2002.............. FAA publishes final rule AD to install
modified rudder system; compliance is
due in 6 years (11/11/2008); special
flight crew procedures in effect since
1996 are superseded as of installation.
January, 2003................ New Boeing 737s are delivered with the
new rudder system and the three DFDR
rudder parameters as original equipment.
------------------------------------------------------------------------
VI. Paperwork Reduction Act
This SNPRM proposes to amend the regulations to add a requirement
for all 737s to record additional flight data parameters. These
additional parameters are not required by the current regulations and
would provide the only currently available means of gathering
information that the FAA and the NTSB anticipate will help assess the
cause of incidents that appear to be related to rudder anomalies on 737
airplanes.
The respondents are all U.S. certificate holders operating 737
airplanes under parts 91, 121, 125, and 129.
The required information would be electronically recorded on the
DFDR each time the airplane begins its takeoff roll until it has
completed its landing roll and kept until the airplane has been
operated for 25 hours. The recorded data would be overwritten on a
continuing basis and accessed only following an accident. This
requirement would be a nominal addition to a passive information
collection activity and therefore does not contain a measurable
additional hour burden.
As required by the Paperwork Reduction Act of 1995 (44 U.S.C.
3507(d)), the U.S. Department of Transportation submitted the
information collection requirements to the Office of Management and
Budget (OMB) for its review and assignment of an OMB control number and
one was assigned. However, when the control number came up for
reauthorization, we decided not to renew it. If this proposed
requirement is made final, we will reapply for the authorization.
VII. International Compatibility
In keeping with U.S. obligations under the Convention on
International Civil Aviation, FAA policy is to comply with
International Civil Aviation Organization (ICAO) Standards and
Recommended Practices to the maximum extent practicable. The FAA has
determined that there are no ICAO Standards and Recommended Practices
that correspond to these regulations.
VIII. Economic Evaluation, Regulatory Flexibility Determination,
International Trade Impact Assessment, and Unfunded Mandates Assessment
Changes to Federal regulations must undergo several economic
analyses. First, Executive Order 12866 directs each Federal agency to
propose or adopt a regulation only if the agency makes a reasoned
determination that the benefits of the intended regulation justify its
costs. Second, the Regulatory Flexibility Act of 1980 requires agencies
to analyze the economic impact of regulatory changes on small entities.
Third, the Trade Agreements Act (19 U.S.C. 2531-2533) prohibits
agencies from setting standards that create unnecessary obstacles to
the foreign commerce of the United States. In developing U.S.
standards, the Trade Act requires agencies to consider international
standards. Where appropriate, agencies are directed to use those
international standards as the basis of U.S. standards. Fourth, the
Unfunded Mandates Reform Act of 1995 requires agencies to prepare a
written assessment of the costs, benefits, and other effects of
proposed or final rules. This requirement applies only to rules that
include a Federal mandate on State, local, or tribal governments or on
the private sector, likely to result in a total expenditure of $100
million or more in any one year (adjusted for inflation).
Based on the available information, the FAA believes that this
proposed rule:
(1) Would have benefits that justify its costs and would be a
``significant regulatory action'' as defined in the Executive Order and
as defined in DOT's Regulatory Policies and Procedures;
(2) Would have a significant impact on a substantial number of
small entities;
(3) Would have minimal effects on international trade; and
(4) Would not impose an unfunded mandate on state, local or tribal
governments or on the private sector.
The FAA has placed these analyses in the docket and summarizes them
as follows.
Data Sources
The principal data sources used are the public comments from the
ATA and six airlines, as well as discussions with representatives from
Boeing and several airlines that operate 737s, an ATA survey of its
members, avionics vendors, and repair stations that will perform some
of the FDR system retrofits. In this section, the FAA addresses the
public comments concerning the Preliminary Regulatory Evaluation and
the economic effects of the proposed rule.
Affected Airplanes and Industries
In the November 1999 NPRM, the FAA estimated the proposed rule
would affect 1,306 737s projected to be in service in the year 2000,
and 2,144 737s that will be manufactured between 2001 and 2020.
In the Supplemental PRE, the FAA estimates that this proposed rule
would affect 1,171 current 737s projected to be active in 2008. The FAA
believes this proposal would not affect 737s in production because
Boeing voluntarily manufacturers these airplanes to the rule's
requirements. Currently, eight airlines (Southwest Airlines,
Continental Airlines, United Airlines, Delta Airlines, U.S. Airways,
American
[[Page 52392]]
Airlines, America West Airlines, and Alaska Airlines) operate 80
percent of the affected airplanes. One major airline (Southwest
Airlines) and two national airlines (Aloha Airlines and Sun Country
Airlines) operate 737s exclusively.
Benefits
The principal benefit from increasing the number of recorded flight
data parameters is the increased probability that the information
gathered can be used to determine more precisely the causes of future
737 rudder-related accidents. Once these causes are known, regulatory
agencies and the aviation industry could effect corrective actions
(e.g., an airplane design modification or changes in operating
procedures) that could prevent such future accidents.
In the NPRM, the FAA estimated the number of these future 737
accidents based on the assumption the historical accident rate would
remain constant. The ATA and Continental Airlines disagreed by noting
that the FAA issued several ADs on the 737 rudder system since 1995,
and no rudder-associated accidents had happened since then. (These
comments, made in 2000, do not include the 2002 AD (Number 2002-20-07)
that requires 737 rudders to be retrofitted to prevent an uncommanded
rudder hardover event.) Continental Airlines believed that, to the
extent that the ADs have mitigated this unknown problem, an accident
rate based on the pre-AD 737 historical rate will overestimate the
future accident rate. The FAA agrees the historical 737 accident rate
is not appropriate for this analysis. Given the recent ADs, there is
insufficient information to specify the future 737 accident rate and
how much this rulemaking will reduce it. As a result, the FAA has
changed the approach used in the NPRM in analyzing benefits in this
SNPRM analysis. Rather than predicting a number of future accidents, as
was done for the NPRM, the Supplemental PRE estimates the potential
quantified benefits that would occur if recording these flight data
parameters would lead to the prevention of an accident. Should the FAA
receive sufficient data in response to this rulemaking notice to permit
it to predict a number of future accidents, it may revert to the
methodology used in the preliminary regulatory evaluation supporting
the NPRM.
In the NPRM, the FAA used the following values to quantify the
potential benefits from a prevented 737 accident: $2.7 million for each
prevented fatality, an average of 96 passengers and crew on a 737, for
a resulting total of $259.2 million an airplane; $20 million for a
destroyed 737; $5 million for ancillary damage to ground structures;
and $31 million for the resultant government and industry accident
investigation. Thus, the average potential benefit from preventing a
737 in-flight accident was estimated to be $315.2 million in 1999
dollars. There were no comments on this estimate.
In the Supplemental PRE, the FAA uses the following updated values
and average 737 size to quantify the potential benefits from a
prevented 737 accident: $3 million for each prevented fatality; an
average of 113 passengers and crew on a 737, for a resulting total of
$339 million an airplane; $17 million for a destroyed 737; $6 million
for ancillary damage to ground structures; and $33 million for the
resultant government and industry accident investigation. These changes
are the result of increased costs, as well as an increase in the
average number of passengers aboard a 737. Thus, the average potential
benefit from preventing a 737 in-flight accident is about $395 million
in 2003 dollars.
Significant Differences in the Economic Models Used in the Preliminary
Regulatory Evaluation and the Supplemental Preliminary Regulatory
Evaluation
Table 1 lists the significant differences in assumptions and values
between those used in the NPRM and those in this analysis. The specific
impact that each value has on the revised compliance costs is discussed
in the individual compliance cost sections. Although there are other
differences that have changed the calculated costs, the differences
listed in Table 1 are the most significant ones.
Table 1.--Significant Differences in Assumptions and Values Between the
Preliminary Regulatory Evaluation and the Supplemental Preliminary
Regulatory Evaluation
------------------------------------------------------------------------
Supplemental
Assumption or value Preliminary preliminary
regulatory analysis regulatory analysis
------------------------------------------------------------------------
Number of Airplanes......... 1,306 (in Year 2000) 1,567 (in Year
2004).
Number of Retrofitted 1,306 (by Year 2001) 1,171 (by Year
Airplanes. 2008).
Annual Increase in Flight 4.1 percent......... Varies depending on
Hours & Fuel Burn. number of
airplanes.
Year of First Retrofits..... 2000................ 2005.
Number of years to retrofit. 18 months........... 4 years.
How scheduled retirements All airplanes active No airplane
are handled. on the final rule scheduled for
date are retirement before
retrofitted. 2008 is
retrofitted.
Who does initial engineering All individual STC Boeing.
redesign. holders.
Hourly Labor Rates: $100; $70........... $125; $85.
Engineers; Mechanics.
How recorders are affected.. Newer recorders in All recorders in 737
737 ``Classic'' ``Classic''
airplanes can be airplanes must be
reprogrammed at a replaced at a unit
unit cost of cost of $20,000.
$10,000..
How FDAUs are affected...... Existing FDAUs in All FDAUs must be
737 ``Classic'' replaced in 737
airplanes can be ``Classic''
reprogrammed at a airplanes at a unit
unit cost of cost of $50,000.
$20,000.
How FCCs are affected....... No impact--no cost.. Must be reprogrammed
at a cost of
$10,000 per
airplane.
How many airplanes 33 percent.......... 100 percent.
retrofitted during a ``C''
or ``D'' maintenance check.
How many out-of-service days 4-9................. 2-8.\1\
for a retrofit not done
during a ``C'' or ``D''
maintenance check.
How many out-of-service days 2-7................. 0-6.
for a retrofit done during
a ``C'' maintenance check.
Per gallon price of aviation $0.61............... $0.75.
fuel.
[[Page 52393]]
Future production 737s...... All affected at a No cost because
per airplane cost parameters 89-91
of $38,900. would have been
installed in the
absence of the
final rule.
------------------------------------------------------------------------
\1\ In the event we receive information that some airplanes cannot be
retrofitted during a ``C'' or ``D'' check, we will use an out of
service time of 2 to 8 days for FDR equipment installation. We
specifically request that this estimate be verified by affected
operators.
Compliance Costs for the Supplemental Rule
As summarized in Table 2, the FAA estimated in the NPRM that the
cost to retrofit a 737 would vary between $41,800 and $221,950 per
airplane, depending upon the 737 model, its FDR system equipment, and
whether the retrofit would be completed during a ``D'' check, a ``C''
check, or would require a separate dedicated scheduled maintenance
session. See also the footnote to Table 1.
Table 2.--Per Airplane Compliance Cost by 737 Series and FDR System Estimated in the Preliminary Regulatory
Evaluation
[All values in 1999 $]
----------------------------------------------------------------------------------------------------------------
Equipment and Out-of- Out-of-service Total costs and
737 Series labor costs service days lost net revenue lost net revenue
----------------------------------------------------------------------------------------------------------------
200................................. $160,200-176,400 4-7 $250-800 $160,450-177,200
200-Advanced (No FDAU).............. 160,200-176,400 4-7 4,900-8,600 160,690-185,000
200-Advanced (FDAU)................. 68,800-90,000 2-4 2,450-4,900 71,250-94,900
300 (No FDAU)....................... 175,200-191,400 6-9 20,375-30,550 195,575-221,950
300 (FDAU).......................... 35,100-90,000 2-4 6,800-21,550 41,900-111,550
400 (No FDAU)....................... 160,200-176,400 6-9 17,350-30,350 177,550-206,750
400 (FDAU).......................... 35,100-90,000 2-4 8,675-25,250 43,775-107,350
500 (No FDAU)....................... 175,200-191,400 6-9 20,150-30,200 195,350-221,600
500 (FDAU).......................... 35,100-90,000 2-4 6,700-19,100 41,800-109,100
600................................. 35,100 2-4 15,375-30,750 50,475-65,850
700................................. 35,100 2-4 17,350-34,675 52,450-69,775
800................................. 35,100 2-4 20,800-41,575 55,900-76,675
900................................. 35,100 2-4 21,950-43,875 57,050-76,975
----------------------------------------------------------------------------------------------------------------
The FAA estimated in the NPRM the total costs of compliance with
the proposed rule between 2000 and 2020 would be about $255 million,
which had a present value of $205.4 million. Of the $255 million total
costs, the one-time costs to retrofit the existing 737 fleet
(engineering plus retrofitting plus losses from out-of-service time)
would have been $158.7 million. If the rule had been issued on January
1, 2000, the $158.7 million would have been spent within 20 months or
the airplanes would have been grounded. The increased costs to
manufacture future 737s from 2000 through 2019 would have been $86
million. Finally, the increased annual costs of the additional fuel
burn due to the increased weight of the airplane and the additional
maintenance of the FDR system from 2000 through 2019 would have been
$10.3 million.
In the Supplemental PRE, after incorporating data from the comments
and updating the fleet and unit cost data, the FAA has determined that
the cost per 737 will be between $189,320 and $201,320 for a 737-200,
between $189,320 and $209,320 for a 737-300/400/500 that does not have
a FDAU, between $142,120 and $167,120 for a 737-300/400/500 that has a
FDAU, between $49,410 and $63,410 for a 737 NG that does not record
parameters 89-91, and $9,475 for a 737 NG that records parameters 89-
91.
The FAA has tentatively determined the total cost to comply with
this SNPRM would be about $143 million between 2004 and 2014, which has
a present value of about $126.5 million. Of the $143 million, about
$140 million will be expended during the first 4 years for engineering
costs, retrofitting costs, and out-of-service costs, $2 million will be
for increased fuel consumption, and $0.7 million will be for additional
FDR system maintenance. There will be minimal compliance costs for
production 737s because Boeing has been voluntarily installing the
capability to record the additional data required by the proposed rule
since August 2000.
Summary of Factors Creating the Significant Differences Between the
Estimates
There are 4 major factors that create the differences between the
NPRM and SNPRM estimates.
The first factor, which increases one-time retrofitting compliance
costs, is the FAA's assumption that some of the existing solid-state
recorders and existing FDAUs could be reprogrammed. However, the ATA,
Alaska, Aloha Airlines, Continental Airlines, Southwest Airlines, and
United Airlines commented that retrofitting the FDR systems in the 737-
``Classic'' series requires purchasing new recorders and new FDAUs;
they cannot be reprogrammed. Boeing, American, and Aloha Airlines
reported that their 737-``NG'' series recorders and FDAUs could be
reprogrammed. The FAA accepts both these positions. As a new recorder
costs between $10,000 and $15,000 more than a reprogrammed recorder,
and a new FDAU costs $30,000 more than a reprogrammed FDAU, the impact
on the total retrofitting cost is considerable.
[[Page 52394]]
A second factor, which lowers compliance costs, is that 135 fewer
737s will be retrofitted under the SNPRM than would have been
retrofitted under the originally proposed rule.
A third factor, which lowers compliance costs, is that the FAA
significantly reduces its estimated number of labor hours to retrofit
FDR systems to record flight data parameters (a)(19) through (a)(22) in
737s with FDAUs. In the NPRM, the FAA estimated it would take 400 hours
while the FAA now estimates that it takes 100 hours.
A final factor that lowers compliance costs is that the
Supplemental PRE analysis contemplates that the flight data parameter
retrofit will be performed when a 737 is retrofitted with a new rudder
rather than within the 20 months originally proposed in the NPRM. Since
the publication of the proposed rule, more 737s have been retired,
reducing those estimated costs.
Commenters' Retrofit Cost Estimates
In the NPRM, the FAA used retrofitting costs largely provided by
the industry. In the comments to the NPRM estimates, Aloha Airlines
estimated a cost of $165,100 to $185,000 to retrofit its 737-200
Advanced airplanes that did not have a FDAU, $71,250 to $94,900 to
retrofit its 737-200 Advanced airplanes that have a FDAU, and $52,450
to $69,775 to retrofit its 737-700 airplanes. American Airlines
estimated a cost of $47,250 plus lost revenue for 2+ days out-of-
service for each of its 737-800 airplanes. Continental Airlines did not
report a total cost, but was in general agreement with the FAA
estimates, if the FAA adjusted its costs to recognize that existing
recorders and FDAUs in 737-``Classic'' airplanes cannot be reprogrammed
and must be replaced. United Airlines estimated a total retrofitting
cost of $24,100,000 and for its fleet of 158 737-``Classics'', for an
average airplane cost of $152,500. The FAA has tentatively determined
the retrofitting cost of a 737-``Classic'' ranges from $142,000 to
$189,000 while the retrofitting cost of a 737-``NG'' ranges from $9,475
to $49,410.
Time to Engineer New Designs for the Retrofitted FDR Systems
In the NPRM, the FAA assumed that each STC holder would
independently do all the engineering redesign. Boeing, the ATA, Alaska,
Continental Airlines, Southwest Airlines, and United Airlines commented
that such an approach would be inefficient and lead to duplication of
effort. Industry expects Boeing to do the initial engineering work,
which the STC holders would then modify for their various FDR systems.
The FAA accepts those comments and has adjusted its analysis
accordingly.
In the NPRM, the FAA estimated that airlines and repair stations
would redesign 40 FDR systems and it would take 16 to 26 weeks and cost
each FDR system holder $200,000 to complete the first FDR system
redesign. As engineering data from one STC can be used in other STCs,
the FAA assumed that after five such FAA approvals, an STC holder could
use commonality demonstrations to reduce this cost from $200,000 to
$25,000 per STC. Thus, the FAA estimated a total one-time cost of $2.95
million for the initial engineering redesign.
Boeing indicated that the FAA significantly underestimated the
engineering hours required for each individual engineering analysis.
Although Boeing did not provide specific estimates in its comments, the
FAA has assessed the engineering analyses for the 737 series as a one-
time cost of $6.6 million, which consists of 30 engineering years.
In the NPRM, the FAA assumed that three engineers working full-time
for four months (one engineer year) would be needed for an FDR system
redesign STC approval, at a cost of $200,000 per STC application. The
FAA further estimated that 32 applications would be made for a one-time
engineering cost of $7.5 million.
Aloha Airlines, Continental Airlines, Southwest Airlines, United,
and U.S. Airways commented that it would take from six months to one
year after Boeing completes the initial engineering analysis for them
to complete their design modifications and obtain FAA approvals. They
did not, however, provide an estimate of their engineering time or
costs to complete these applications. In the Supplemental PRE, the FAA
estimates that 15 STC applications will require one engineer year (at a
cost of $250,000) to complete, while 25 of the STCs will require 250
engineer hours (at a cost of $31,250) to complete. On that basis, the
calculated total STC engineering cost is $4.6 million.
Aloha Airlines stated the FAA underestimated the number of
engineering analyses because each airplane ``configuration'' within a
737 series would need a separate engineering analysis. They commented
that 13 of their 18 airplanes will need a $200,000 analysis. The FAA
agrees that an adjustment in the cost calculations needs to be made for
the different configurations. However, because much of the engineering
is identical for each configuration within a 737 series, the FAA has
tentatively determined that it will take half of the engineering time
for a commonality demonstration STC (125 hours) for a configuration
STC. The FAA has calculated a per configuration cost of $16,125.
Finally, the FAA has tentatively determined that 60 of these
``configuration'' STCs will be performed because most airlines' fleets
have fewer configurations than the Aloha Airlines fleet. The FAA
estimates a total cost of $967,500 for this engineering.
Alaska also noted that two of the sensors had not been developed
for any airplane and several other sensors had not been approved for
use in many of the 737-``Classic'' airplanes. Thus, as well as the
design STC approval, the FAA would also need to issue Parts
Manufacturing Authorizations (PMAs) to the new sensors manufacturers.
Alaska posited that although the vendors will incur most of these
development costs, these costs should be included in Boeing's initial
engineering costs because Boeing will be the kit supplier.
In the NPRM, the FAA estimated the total one-time engineering costs
to modify the FDR system STCs and obtain FAA approval would have been
$9.15 million. The FAA now calculates the total costs to modify the FDR
system STCs and obtain FAA approvals are $15 million.
Equipment and Labor Costs to Retrofit FDR Systems
In the NPRM, the FAA estimated the equipment and labor costs to
retrofit FDR systems for compliance with the proposed rule would be
$124.3 million. Based on the comments and the revised fleet, the FAA
has reduced the anticipated equipment and labor cost to comply with the
final rule, if adopted, to $111.8 million.
In the NPRM, the FAA estimated that 156 737s would have their
recorders replaced, while the remaining 1,150 737s would have their
recorders upgraded with additional memory. The FAA estimated that: a
new recorder would cost $25,000; upgrading the memory of a recorder
that records 18 flight data parameters would cost $10,000; upgrading
the memory of a recorder that records 22 flight data parameters would
cost $5,000; and upgrading the memory of a recorder that records more
than 22 parameters would cost $1,900.
ATA, Aloha Airlines, Continental Airlines, Southwest Airlines, and
United Airlines commented that all of their 737-``Classics'' would have
their
[[Page 52395]]
recorders replaced because they cannot be reprogrammed.
Accepting and incorporating industry comments, and with the
increased numbers of retirements, the FAA has tentatively determined
that 605 737s will need their recorders replaced and 279 737s will need
their recorders reprogrammed by 2008.
Finally, Continental Airlines reported new recorder costs of
$13,000 while Aloha Airlines reported a recorder cost of $25,000. In
the Supplemental PRE, the FAA has assessed a cost of $20,000 per
recorder, the average of these two estimates and estimates provided by
avionics manufacturers.
In the NPRM, the FAA estimated that installing a new recorder would
require 32 labor hours to remove the old recorder and to install and
test a new recorder. Upgrading an FDR would require 16 labor hours to
remove, reprogram, reinstall, and test. The FAA received no comments on
this estimate and uses it in the Supplemental PRE.
In the NPRM, the FAA estimated the cost of replaced or upgraded
recorders would be $17.2 million. Based on the increased recorder cost
estimate and the fewer retrofitted 737s, the FAA now calculates that
the total cost of replaced or upgraded recorders in this is $14.6
million, which has a present value of $12.8 million.
In the NPRM, the FAA estimated that a FDAU would be retrofitted
into 496 737s that did not have one, while the existing FDAUs in 810
737s would be reprogrammed. The same commenters who addressed the issue
of the recorder all agreed that, whereas the FDAUs in their 737-``NGs''
can be reprogrammed, every FDAU in their 737-``Classics'' would have to
be replaced--those units cannot be reprogrammed. The FAA agrees with
these comments. In the Supplemental PRE, the FAA has tentatively
determined that by 2004 operators of 198 737-200s will have introduced
FDAUs into their airplanes; that operators of 407 737-300/400/500s with
a FDAU will have installed new FDAUs in their airplanes; and that
operators of 279 737-700/800/900s will have reprogrammed their existing
FDAUs.
Continental Airlines and Aloha Airlines reported a $50,000 cost for
a new FDAU and a cost to reprogram a FDAU of between $7,500 and
$10,000. In the Supplemental PRE, the FAA uses a cost of $50,000 for a
new FDAU and an average of the two estimates ($8,750) as the cost to
reprogram a FDAU.
In the NPRM, the FAA noted that retrofitting a 737 with a FDAU
would require rerouting the FDR system wiring because the recorder
(where the wires formerly terminated) is located aft, while the new
FDAU would be in the front. Relying on estimates from Southwest
Airlines and United, the FAA estimated that retrofitting a FDAU would
take 200 labor hours, which includes the associated labor hours to
rewire the existing FDR system. Aloha Airlines submitted the only
specific comment on this issue and it agreed with the FAA estimate.
Thus, the FAA continues to assume 200 labor hours to retrofit a FDAU.
In the NPRM, the FAA estimated that it would take 48 hours for a
FDAU on a 737-``Classic'' airplane and 40 hours for a FDAU on a 737-
``NG'' airplane to be removed, shipped to the manufacturer,
reprogrammed, reinstalled, and tested. Three airlines filed comments on
these estimates. Aloha Airlines reported that it will take the same
number of labor hours (200) to replace an existing FDAU as it will to
retrofit a FDAU in an FDR system that did not previously have one. The
FAA disagrees. The effort to retrofit a FDAU is greater than the effort
to install one in an airplane that did not have it. Continental
Airlines estimated a cost of $71,500 for the equipment and labor costs
to replace a FDAU. However, that estimate also included the cost to
record the additional flight data parameters and the increased sampling
rate for flight data parameter (a)(88). United Airlines similarly
estimated a total labor cost of $33,000 for the entire retrofit. The
numbers submitted by Continental Airlines and United Airlines do not
allow the FAA to distinguish the number of labor hours to replace a
FDAU from the total labor hours for the retrofit. After reviewing the
comments, the FAA has increased the estimated number of labor hours to
replace a 737-``Classic's'' FDAU from 48 hours to 80 hours and reduced
the number of labor hours from 40 hours to 20 hours for a 737-``NG's''
FDAU.
Accordingly, the FAA calculates that the labor costs to install a
FDAU in an FDR system that did not have one is $17,000; the labor costs
to replace a FDAU is $6,800; and the labor costs to install a
reprogrammed FDAU is $1,700.
In the NPRM, the FAA estimated the total FDAU equipment and labor
costs to retrofit FDAUs would be $37.6 million. In the Supplemental
PRE, the FAA calculates the total equipment and a labor cost to
retrofit FDAUs at $40.9 million, which has a present value of $35.8
million.
In the NPRM, the FAA divided the equipment and labor costs for the
additional wiring for adding the sensors into three components: (1) The
costs to record flight data parameters (a)(19) through (a)(22); (2) the
costs to record flight data parameters found in (a)(88) at the greater
ranges and increased sampling rates; and (3) the costs to record flight
data parameters (a)(89) through (a)(91). That division is continued in
this analysis.
In the NPRM, the FAA estimated the costs of the sensors and wiring
for a 737 FDR system to record parameters (a)(19) through (a)(22) were
$20,000. The only specific comment received on this estimate was from
Aloha Airlines, which agreed with the estimate. As a result, the FAA
uses this value in the Supplemental PRE.
In the NPRM, the FAA estimated that the installation of the sensors
and wiring to record flight data parameters (a)(19) through (a)(22)
would take 200 labor hours for a 737-200, a 737-200 Advanced, or a 737-
400 airplane. It would take 400 labor hours for a 737-300 or a 737-500
series airplane.
Boeing commented that the FAA misclassified the labor costs for the
737-400 because the avionics in that series are essentially the same as
the avionics in the 737-300 and 737-500 series airplanes. These
airplanes employ ARINC 700 systems, while the 737-200 and 737-200
Advanced are, basically, ``all analog'' airplanes. Boeing contended the
labor time (and cost) to rewire a 737-400 airplane is similar to the
labor hours (and costs) for a 737-300 or a 737-500 airplane. The FAA
accepts Boeing's comment and has assigned the same number of labor
hours for all the 737-300/400/500 airplanes.
As Aloha Airlines uses the same 200 labor hour estimate for its
737-200 retrofits, the FAA continues to use the 200 labor hours in the
NPRM to retrofit 737-200s in the Supplemental PRE. Boeing noted that
there are minor differences in the amount of wiring among all of its
737- ``Classics''. The FAA agrees and has revised its estimate for the
737-300/400/500 series retrofit to record flight data parameters from
400 labor hours to 200 labor hours. Thus, the FAA calculates the sensor
and labor cost to record flight data parameters (a)(19) through (a)(22)
of $17,000 for a 737-``Classic''. The total anticipated cost to record
flight data parameters (a)(19) through (a)(22) is $37,000. Boeing also
commented that the FAA had not specifically estimated the costs for the
individual sensors and other equipment required to record flight data
parameters (a)(19) through (a)(22). The FAA agrees; however, the FAA
notes that the airline cost estimates were not provided on an
individual sensor basis. Consequently, the FAA could not establish
individual sensor cost estimates.
[[Page 52396]]
In the NPRM, the FAA used preliminary industry estimates that it
would cost $12,000 to add the necessary sensors and wiring to record
flight data parameter (a)(88) in a 737 FDR system that does not
currently record it or that does not record it at the proposed range.
American Airlines commented that it will cost $8,000 for the sensors to
record this flight data parameter at the proposed range. The FAA
accepts the American Airlines estimate and has assumed a cost of
$8,000.
In the NPRM, the FAA assumed that it would cost $12,000 to replace
all sensors currently recording flight data parameter (a)(88) in order
to comply with the higher sampling rate requirement. Boeing, however,
reported that the existing sensors can be reprogrammed to transmit
information at the increased sampling rate. The FAA agrees with Boeing
and has tentatively determined there will be no sensor costs to comply
with the higher sampling rates for flight data parameter (a)(88).
In the NPRM, the FAA estimated that it would take 160 labor hours
to install the sensors in a 737-``Classic'' FDR system that was either
not recording flight data parameter (a)(88) or not recording it at the
proposed range. Aloha Airlines reported a total of 360 labor hours to
record flight data parameters (a)(88) through (a)(91). As three of the
six flight data parameters to be recorded are found in (a)(88), the FAA
has assumed that half of the labor hours reported by Aloha Airlines
(180) hours will be used to install flight data parameter (a)(88) for a
labor cost of $15,300 per airplane.
In the NPRM, the FAA estimated that it would take 160 labor hours
to replace the sensor in a 737-``NG'' that was recording flight data
parameter (a)(88) at the lower sampling rate. The FAA believes that it
takes fewer labor hours to reprogram the sensor to record flight data
parameter (a)(88) than it will take to introduce new sensors and wiring
into a FDR system that had not previously recorded it. In the
Supplemental PRE, the FAA has tentatively determined that it will take
80 labor hours (at a cost of $6,800) to install new sensors for flight
data parameter (a)(88).
Boeing did not provide a labor hour estimate to install
reprogrammed sensors to record at the higher sampling rate. In the
Supplemental PRE, the FAA estimates that it takes one-half (40) hours
to reprogram the sensors than it does to install new sensors at a labor
cost of $3,400 per airplane.
The FAA also estimates that the retrofit costs to install new
sensors to record flight data parameter (a)(88) are $23,300 for a 737-
``Classic'' and $14,800 in a 737-``NG''. The cost to install
reprogrammed sensors in a 737-``NG'' is $3,400.
Aloha Airlines and American Airlines provided sensor costs or the
number of labor hours to retrofit FDR systems to record flight data
parameters (a)(89), (a)(90), and (a)(91). The American Airlines comment
provided aggregated data and the FAA could not disaggregate some of
their costs. Aloha Airlines reported a total wiring and sensor cost of
$12,000 to record flight data parameters (a)(88) through (a)(91). The
FAA agrees with this estimate. As the FAA has also determined that the
wiring and sensor cost to retrofit flight data parameter (a)(88) is
approximately $8,000, the FAA concludes that the wiring and sensor
costs to retrofit flight data parameters (a)(89) through (a)(91) should
be approximately $4,000.
As noted, the FAA has determined that half of the labor time
reported by Aloha Airlines is to install flight data parameter (a)(88)
and half the time is to install flight data parameters (a)(89),
(a)(90), and (a)(91). Thus, the FAA calculates that 180 labor hours (at
a cost of $15,300) will be required to install flight data parameters
(a)(89), (a)(90), and (a)(91) in a 737-``Classic''. The FAA has also
assumed that 80 labor hours (at a cost of $6,800) will be required to
install flight data parameters (a)(89), (a)(90), and (a)(91) in a 737-
``NG''. The FAA calculates that the retrofitting costs to record flight
data parameters (a)(89), (a)(90), and (a)(91) is $27,300 for a 737-
``Classic'' and $10,800 for a 737-``NG''.
In the NPRM, the FAA estimated the total retrofitting sensor and
wiring costs to have been: $84,000 for a 737-200 or a 737-400 airplane
without a FDAU; $100,000 for a 737-300 or a 737-500 airplane without a
FDAU; $49,000 for an older 737 airplane with a FDAU; and $24,000 and
for a newer 737 airplane with a FDAU.
In the Supplemental PRE, the FAA estimates that the retrofitting
sensor and wiring costs, per 737, are: $89,600 for a 737-``Classic''
that records 18 flight data parameters; $52,600 for a 737-``Classic''
that records 22 flight data parameters; $25,600 for a 737-``NG''
manufactured before August 2000: and $10,800 for a 737-``NG''
manufactured after August 2000.
In the NPRM, the FAA estimated that the total sensor and wiring
costs to retrofit all 737 FDR systems by the compliance date would be
$69 million. The FAA now calculates that the total sensor and wiring
costs to retrofit all 737 FDR systems by the compliance date is $48
million, which has a present value of $42 million.
In the NPRM, the FAA did not consider (and did not estimate) any
cost for reprogramming the flight control computers (FCCs). Boeing and
American Airlines commented that recording the additional flight data
parameters would require reprogramming the FCCs. Boeing provided no
cost estimates for FCC reprogramming, but American Airlines reported
that it will cost $5,000 per FCC to reprogram the 2 FCCs (for a total
cost of $10,000 per airplane). The FAA accepts the American Airlines
estimate and applies it to all 737s. The FAA now calculates a total
cost to reprogram the FCCs of $8.8 million, which has a present value
of $7.7 million.
In the NPRM, the FAA estimated that the equipment and labor costs
to retrofit the existing 737 fleet were $17.2 million for recorders,
$37.7 million for FDAUs, and $69.4 million for wiring and sensors, for
a total cost of $124.3 million. In the Supplemental PRE, the FAA
calculates that the equipment and labor costs to retrofit the existing
737 fleet are $14.7 million for recorders, $40.9 million for FDAUs,
$47.2 million for wiring and sensors, and $8.8 million for FCCs, for a
total cost of $111.6 million, which has a present value of $92.6
million.
Total One-Time FDR System Retrofitting Costs
In the NPRM, the FAA estimated the total one-time compliance costs
and losses from out-of-service time would have been $149.6 million.
Based on the comments and updated data, the FAA now calculates that the
total one-time compliance costs and losses from out-of-service time
would be $125.2 million, which has a present value of $109.5 million.
Annual Costs Resulting From Retrofitting 737 FDR Systems
The Supplemental PRE also contemplates annual compliance costs
from: (1) Additional airplane weight due to retrofitted FDR system; and
(2) additional maintenance costs to annually validate the FDAU.
In the NPRM, the FAA estimated that the proposed rule would add 40
pounds to a 737 that does not have a FDAU and records 18 flight data
parameters and add 10 pounds to a 737 that has a FDAU and records at
least 22 flight data parameters. In calculating the estimated
additional fuel cost, the FAA assumed a per-airplane average of 2,750
flight hours per year, a price of $0.61 per gallon of aviation fuel,
and 0.23 additional gallons consumed per additional pound per flight
hour. These assumptions resulted in per-airplane
[[Page 52397]]
annual costs of $400 for a 737 that adds 40 pounds and $100 for a 737
that adds 10 pounds. On that basis, the FAA estimated the total cost
from the increased fuel consumption during 2001 and 2020 would have
been $6.1 million, which has a present value of $3.6 million. There
were no comments on this estimate.
In the Supplemental PRE, the underlying NPRM methodology is
maintained but certain parameters are updated (from 2,750 to 3,360
flight hours per year and from $0.61 to $0.75 per gallon cost of
aviation fuel). However, the FAA has revised the weight added by the
retrofitted sensors and wiring for 737-300/400/500s from 10 pounds to
20 pounds. On that basis, the FAA now calculates that adding 40 pounds
to a 737 would increase its annual fuel costs by $584, adding 20 pounds
would increase its annual fuel costs by $292, and adding 10 pounds
would increase its annual fuel costs by $146. These revised
calculations result in a total fuel cost increase of $2 million between
2005-2014, which has a present value of $1.4 million.
In the NPRM, the FAA estimated that the incremental annual
inspection and validation of a FDAU would cost $750. On that basis, the
FAA estimated the total cost from the increased maintenance during 2001
and 2020 would have been $4.2 million, which has a present value of
$2.7 million. As there were no comments on this estimate, the FAA has
decided to retain it. Based on the number of 737s that would have had
FDAUs introduced into the airplane and on the number that would have
been retired between 2005 to 2014, the FAA calculates a total
maintenance cost increase of $700,000, which has a present value of
$535,000.
In the NPRM, the FAA estimated that the increased annual
operational and maintenance costs between 2001 and 2020 would have been
$10.3 million, which has a present value of $6.3 million. In the
Supplemental PRE, the FAA calculates that the increased annual
operational and maintenance costs between 2005 and 2014 are $2.7
million, which has a present value of $1.9 million.
Compliance Costs for Production 737s
In the NPRM, the FAA estimated a total cost for 737s manufactured
between 2000 and 2020 of $86 million, which has a present value of
$40.4 million, to install the equipment to record proposed flight data
parameters (a)(89), (a)(90), and (a)(91). As previously discussed, the
Supplemental PRE has taken into account Boeing's voluntary installation
of this equipment on all its 737s since August 2000, indicating that
the SNPRM would impose no compliance costs on production 737s.
Benefit-Cost Comments
In the NPRM, the FAA estimated that the expected present value of
the benefits ($156 million) would have been less than the present value
of the quantifiable total compliance costs ($214 million). However, the
FAA noted there is considerable uncertainty about the potential number
of future accidents. As a result, the FAA concluded that it was in
general agreement with the NTSB recommendations that this information
is needed.
Boeing disagreed with an aggregated benefit-cost approach and
commented that an appropriate analysis should be based on an individual
provision-by-provision (or, in this case, flight data parameter by
flight data parameter) evaluation. In principle, the FAA agrees with
the Boeing comment. However, the FAA has no data that can support a
parameter-by-parameter cost calculation. All of the submitted
retrofitting cost data were block costs in which no individual flight
data parameter costs were provided. In practice, such a detailed
benefits analysis presupposes the existence of an objective probability
function based on an engineering analysis for each flight data
parameter of the potential for the additional information to lead
accident investigators to the cause of an accident. It is precisely
because engineering analyses have been unable to determine the causes
of these accidents that such individual probabilities cannot be
determined. At best, current engineering analyses have established that
one of this group of several flight data parameters, if recorded, may
help to determine the causes of future accidents. As a result, the FAA
has decided against reevaluating its benefit-cost analysis in the
Supplemental PRE based on the individual flight data parameters.
Finally, Boeing commented that the FAA should analyze the proposed
rule for individual airplanes based on their expected remaining service
life with a possible view of exempting older 737s. The justification is
that the potential benefits to any individual 737 airplane would be
lower the shorter its remaining service life while the costs would not
be similarly reduced. Although the FAA agrees that, for an individual
737, the incremental benefits received from a dollar of cost are lower
for older airplanes, the FAA disagrees that this is an appropriate
framework to analyze the recording requirements. The primary benefits
attributable to this proposed rule do not accrue to the 737 that would
have an accident, but, rather, to every other 737 that would not have a
similar accident because engineering or operational changes that would
prevent such future accidents would be developed from the flight data
recorded from the accident or incident. The FAA is not able to
correlate the potential probability of such an accident to the age of a
737. Accordingly, in any year, the FAA assumes that all 737s face an
equal probability that an accident may occur to any one of them. If
some 737s were exempted from the rule and if an uncontrolled rudder
movement accident were to happen to one of those exempted airplanes,
then no such future accident would be prevented for the 737 fleet
because the necessary flight data would not have been recorded and no
appropriate engineering or operational changes could have been made.
However, in recognition of the potential economic impact, the FAA
agrees with Boeing's suggestion that it is appropriate to limit the
applicability of this rule to not include those 737s that have a
limited remaining service life. Thus, this proposed rule would apply
only to 737s that would be in service 4 years after the promulgation of
the final rule.
Regulatory Flexibility Determination
The Regulatory Flexibility Act of 19805 U.S.C. 601-612, directs the
FAA to fit regulatory requirements to the scale of the businesses,
organizations, and governmental jurisdictions subject to the
regulation. The FAA is required to determine whether a proposed or
final action will have a ``significant economic impact on a substantial
number of small entities'' as defined in the ACT. If the FAA finds that
the action will have a significant impact, the FAA must perform a
``regulatory flexibility analysis.'' However, if an agency determines
that a proposed or final rule is not expected to have a significant
economic impact on a substantial number of small entities, section
605(b) of the Act provides that the head of the agency may so certify,
and a regulatory flexibility analysis is not required. The
certification must include a statement providing the factual basis for
this determination, and the reasoning should be clear.
In the NPRM, the FAA prepared a Preliminary Regulatory Flexibility
Analysis because the proposed rule might have had a significant
economic impact upon a substantial number of small entities. The FAA
had concluded, after that preliminary analysis, that the proposed rule
may not have met that
[[Page 52398]]
criterion, but it reported its analysis and requested public comments.
The FAA received no comments about the Preliminary Regulatory
Flexibility Analysis.
However, subsequent to publication of the NPRM, the Office of
Advocacy of the Small Business Administration published new guidelines
that defined a small airline as one that has fewer than 1,500
employees. In 2003, the FAA performed a new Regulatory Flexibility
Analysis for this SNPRM. In that analysis, of the 20 airlines that
would be affected by the SNPRM, 12 have fewer than 1,500 employees and
are small entities. Of these 12 airlines, one had a positive net
operating income, seven had negative net operating income, and net
operating income data were not available for four airlines. Twelve
airlines is a substantial number of airlines and the cost per airplane
is significant--particularly when the airline has negative net
operating income.
Therefore, based on that information available at that time and the
definition of a small business, the FAA Administrator has determined
that the proposed rule could have a significant economic effect on a
substantial number of small entities. Under the new definition, our
preliminary conclusion is that it will have a significant economic
impact.
This determination is explained in more detail in the Regulatory
Flexibility Section of the Supplemental PRE. However, since the results
of that evaluation are based on data that are not current, we are
requesting that affected operators provide us with more current data to
be used to update the Regulatory Flexibility Evaluation before any
final rule is issued.
Trade Impact Assessment
The Trade Agreement Act of 1979 prohibits Federal agencies from
establishing any standards or engaging in related activities that
create unnecessary obstacles to the foreign commerce of the United
States. Legitimate domestic objectives, such as safety, are not
considered unnecessary obstacles. The statute also requires
consideration of international standards and, where appropriate, that
they be the basis for U.S. standards. The FAA has assessed the
potential effect of this rulemaking and determined that it would have
only a domestic impact and, therefore, no affect on any trade-sensitive
activity.
Unfunded Mandates Assessment
The Unfunded Mandates Reform Act of 1995 (the Act) is intended,
among other things, to curb the practice of imposing unfunded Federal
mandates on State, local, and tribal governments or on the private
sector.
Section 202(a) (2 U.S.C. 1532) of Title II of the Act requires that
each Federal agency, to the extent permitted by law, prepare a written
statement assessing the effects of any Federal mandate in a proposed or
final agency rule that may result in the expenditure by State, local,
and tribal governments, in the aggregate, or by the private sector, of
$100 million or more (adjusted annually for inflation) in any one year;
such a mandate is deemed to be a ``significant regulatory action.'' The
FAA currently uses an inflation-adjusted value of $128.1 million in
lieu of $100 million. Section 203(a) of the Act (2 U.S.C. 1533)
provides that before establishing any regulatory requirements that
might significantly or uniquely affect small governments, an agency
shall have developed a plan under which the agency shall:
(1) Provide notice of the requirements to potentially affected
small governments, if any;
(2) Enable officials of affected small governments to provide
meaningful and timely input in the development of regulatory proposals
containing significant Federal intergovernmental mandates; and,
(3) Inform, educate, and advise small governments on compliance
with the requirements.
With respect to (2), Section 204(a) of the Act (2 U.S.C. 1534)
requires the Federal agency to develop an effective process to permit
elected officers of State, local, and tribal governments (or their
designees) to provide the input described.
This rulemaking does not contain a significant Federal
intergovernmental or private sector mandate because the compliance
costs to the private sector would be about $48 million in each of the
years 2005, 2006, and 2007, and no more than $3 million in any
following year. Therefore, the requirements of Title II do not apply.
Executive Order 13132, Federalism
The FAA has analyzed this rulemaking under the principles and
criteria of Executive Order 13132, Federalism. We determined that this
action will not have a substantial direct effect on the States, or the
relationship between the national Government and the States, or on the
distribution of power and responsibilities among the various levels of
government, and therefore does not have federalism implications.
IX. Environmental Analysis
FAA Order 1050.1E identifies FAA actions that are categorically
excluded from preparation of an environmental assessment or
environmental impact statement under the National Environmental Policy
Act in the absence of extraordinary circumstances. The FAA has
determined this rulemaking action qualifies for the categorical
exclusion identified in paragraph 312d and involves no extraordinary
circumstances.
X. Regulations That Significantly Affect Energy Supply, Distribution,
or Use
The FAA has analyzed this SNPRM under Executive Order 13211,
Actions Concerning Regulations that Significantly Affect Energy Supply,
Distribution, or Use (May 18, 2001). We have determined that it is not
a ``significant energy action'' under the executive order because it is
not a ``significant regulatory action'' under Executive Order 12866,
and it is not likely to have a significant adverse effect on the
supply, distribution, or use of energy.
List of Subjects
14 CFR Part 91
Aircraft, Aviation safety, Reporting and recordkeeping
requirements.
14 CFR Part 121
Air carriers, Aircraft, Aviation safety, Reporting and
recordkeeping requirements, Safety, Transportation.
14 CFR Part 125
Aircraft, Aviation safety, Reporting and recordkeeping
requirements.
The Amendment
In consideration of the foregoing, the Federal Aviation
Administration proposes amending Chapter I of Title 14, Code of Federal
Regulations as follows:
PART 91--GENERAL OPERATING AND FLIGHT RULES
1. The authority citation for part 91 continues to read as follows:
Authority: 49 U.S.C. 106(g), 1155, 40103, 40113, 40120, 44101,
44111, 44701, 44709, 44711, 44712, 44715, 44716, 44717, 44722,
46306, 46315, 46316, 46504, 46506-46507, 47122, 47508, 47528-47531,
articles 12 and 29 of the Convention on International Civil Aviation
(61 stat. 1180).
2. Amend Sec. 91.609 by adding a new paragraph (h) as follows:
Sec. 91.609 Flight recorders and cockpit voice recorders.
* * * * *
[[Page 52399]]
(h) An aircraft operated under this part under deviation authority
from part 125 of this chapter must comply with all of the applicable
flight data recorder requirements of part 125 applicable to the
aircraft, notwithstanding such deviation authority.
PART 121--OPERATING REQUIREMENTS: DOMESTIC, FLAG, AND SUPPLEMENTAL
OPERATIONS
3. The authority citation for part 121 continues to read as
follows:
Authority: 49 U.S.C. 106(g), 40113, 40119, 41706, 44101, 44701-
44702, 44705, 44709-44711, 44713, 44716-44717, 44722, 44901, 44903-
44904, 44912, 45101-45105, 46105, 46301.
4. Amend Sec. 121.344 by removing the word ``and'' after paragraph
(a)(87); by removing the period after paragraph (a)(88) and adding a
semicolon in its place; by adding new paragraphs (a)(89), (90) and
(91), (b)(4), (c)(4), (d)(3), (e)(3) and (m); and by revising paragraph
(f) to read as follows:
Sec. 121.344 Digital flight data recorders for transport category
airplanes.
(a) * * *
(89) Yaw damper status;
(90) Yaw damper command; and
(91) Standby rudder valve status.
(b) * * *
(4) In addition to the requirements of paragraphs (b)(1) through
(b)(3) of this section, all Boeing 737 model airplanes must comply with
the requirements of paragraph (m) of this section, as applicable.
(c) * * *
(4) In addition to the requirements of paragraphs (c)(1) through
(c)(3) of this section, all Boeing 737 model airplanes must comply with
the requirements of paragraph (m) of this section, as applicable.
(d) * * *
(3) In addition to the requirements of paragraphs (d)(1) and (d)(2)
of this section, all Boeing 737 model airplanes also must comply with
the requirements of paragraph (m) of this section, as applicable.
(e) * * *
(3) In addition to the requirements of paragraphs (e)(1) and (e)(2)
of this section, all Boeing 737 model airplanes, also must comply with
the requirements of paragraph (m) of this section, as applicable.
(f) For all turbine-engine-powered transport category airplanes
manufactured after August 19, 2002--
(1) The parameters listed in paragraphs (a)(1) through (a)(88) of
this section must be recorded within the ranges, accuracies,
resolutions, and recording intervals specified in appendix M to this
part.
(2) In addition to the requirements of paragraphs (f)(1) of this
section, all Boeing 737 model airplanes must also comply with the
requirements of paragraph (m) of this section.
* * * * *
(m) In addition to all other applicable requirements of this
section, all Boeing 737 model airplanes must record the parameters
listed in paragraph (a)(1) through (a)(22) and (a)(88) through (a)(91)
of this section within the ranges, accuracies, resolutions, and
recording intervals specified in Appendix M to this part. The approved
recorder and all equipment necessary to record the parameters required
by this paragraph must be installed no later than the installation of
the redesigned rudder system required by one or more Airworthiness
Directives issued under part 39 of this chapter. The single-source
recording provisions of paragraphs (b)(1)(ii), (c)(1), and (d)(1) of
this section may be used for airplanes otherwise subject to those
paragraphs.
5. Amend Appendix M to part 121 by revising item 88 and adding
items 89 through 91 to read as follows:
Appendix M to Part 121--Airplane Flight Recorder Specifications--
Continued
* * * * *
--------------------------------------------------------------------------------------------------------------------------------------------------------
Seconds per
Parameter Range Accuracy (sensor input) sampling Resolution Remarks
interval
--------------------------------------------------------------------------------------------------------------------------------------------------------
88. All cockpit flight control Full range......... 5%.......... 1 0.2% of full range.............. For fly-by-wire flight
input forces (control wheel, Control wheel < plus- control systems, where
control column, rudder minus>70 lbs.. flight control surface
pedal).\18\ \19\ Control column position is a function
85 of the control input
lbs.. device only, it is not
Rudder pedal < plus- necessary to record
minus>165 lbs.. this parameter. For
airplanes that have a
flight control break
away capability that
allows either pilot to
operate the control
independently, record
both control force
inputs. The control
force inputs may be
sampled alternately
once per 2 seconds to
produce the sampling
interval of 1.
89. Yaw damper status........... Discrete (on/off).. ........................ 0.5
90. Yaw damper command.......... Full range......... As installed............ 0.5 1% of full range...............
91. Standby rudder valve status. Discrete........... ........................ 0.5
--------------------------------------------------------------------------------------------------------------------------------------------------------
\18\ For all 737 model airplanes: the seconds per sampling interval is 0.5 per control input; the remarks regarding the sampling rate do not apply; a
single control wheel force transducer installed on the left cable control is acceptable provided the left and right control wheel positions also are
recorded.
\19\ For all 737 model airplanes manufactured on or before January 31, 2001, Range values are: Full Range; Control wheel 15 lbs.; Control
column 40 lbs.; and Rudder pedal 165 lbs.
[[Page 52400]]
PART 125--CERTIFICATION AND OPERATIONS: AIRPLANES HAVING A SEATING
CAPACITY OF 20 OR MORE PASSENGERS OR A MAXIMUM PAYLOAD CAPACITY OF
6,000 POUNDS OR MORE
6. The authority citation for part 125 continues to read as
follows:
Authority: 49 U.S.C. 106(g), 40113, 44701-44702, 44705, 44710-
44711, 44713, 44716-44717, 44722.
7. Amend Sec. 125.3 by adding a new paragraph (d) to read as
follows:
Sec. 125.3 Deviation authority.
* * * * *
(d) No deviation authority from the flight data recorder
requirements of this part will be granted. Any previously issued
deviation from the flight data recorder requirements of this part is no
longer valid.
8. Amend Sec. 125.226 by removing the word ``and'' after paragraph
(a)(87); by removing the period after paragraph (a)(88) and adding a
semicolon in its place; by adding new paragraphs (a)(89), (90), and
(91), (b)(4), (d)(3), (e)(3), and (m); and by revising paragraph (f) to
read as follows:
Sec. 125.226 Digital flight data recorders.
(a) * * *
(89) Yaw damper status;
(90) Yaw damper command; and
(91) Standby rudder valve status.
(b) * * *
(4) In addition to the requirements of paragraphs (b)(1) through
(b)(3) of this section, all Boeing 737 model airplanes also must comply
with the requirements of paragraph (m) of this section.
(c) * * *
(4) In addition to the requirements of paragraphs (c)(1) through
(c)(3) of this section, all Boeing 737 model airplanes must comply with
the requirements of paragraph (m) of this section, as applicable.
(d) * * *
(3) In addition to the requirements of paragraphs (d)(1) and (d)(2)
of this section, all Boeing 737 model airplanes also must comply with
the requirements of paragraph (m) of this section, as applicable.
(e) * * *
(3) In addition to the requirements of paragraphs (e)(1) and (e)(2)
of this section, all Boeing 737 model airplanes, also must comply with
the requirements of paragraph (m) of this section, as applicable.
(f) For all turbine-engine-powered transport category airplanes
manufactured after August 19, 2002--
(1) The parameters listed in paragraphs (a)(1) through (a)(88) of
this section must be recorded within the ranges, accuracies,
resolutions and recording intervals specified in appendix E to this
part.
(2) In addition to the requirements of paragraph (f)(1) of this
section, all Boeing 737 model airplanes must also comply with the
requirements of paragraph (m) of this section.
* * * * *
(m) In addition to all other applicable requirements of this
section, all Boeing 737 model airplanes must record the parameters
listed in paragraph (a)(1) through (a)(22) and (a)(88) through (a)(91)
of this section within the ranges, accuracies, resolutions, and
recording intervals specified in Appendix E to this part. The approved
recorder and all equipment necessary to record the parameters required
by this paragraph must be installed no later than the installation of
the redesigned rudder system required by one or more Airworthiness
Directives issued under part 39 of this chapter. The single-source
recording provisions of paragraphs (b)(1)(ii), (c)(1), and (d)(1) of
this section may be used for airplanes otherwise subject to those
paragraphs.
9. Amend Appendix E to part 125 by revising item 88, and adding
items 89 through 91 to read as follows:
Appendix E to Part 125--Airplane Flight Recorder Specifications--
Continued
* * * * *
--------------------------------------------------------------------------------------------------------------------------------------------------------
Seconds per
Parameter Range Accuracy (sensor input) sampling Resolution Remarks
interval
--------------------------------------------------------------------------------------------------------------------------------------------------------
88. All cockpit flight control Full range......... 5%.......... 1 0.2% of full range.............. For fly-by-wire flight
input forces (control wheel, Control wheel < plus- control systems, where
control column, rudder minus>70 lbs.. flight control surface
pedal).\18\ \19\ Control column position is a function
85 of the displacement of
lbs.. the control input
Rudder pedal < plus- device only, it is not
minus>65 lbs.. necessary to record
this parameter. For
airplanes that have a
flight control break
away capability that
allows either pilot to
operate the control
independently, record
both control force
inputs. The control
force inputs may be
sampled alternately
once per 2 seconds to
produce the sampling
interval of 1.
89. Yaw damper status........... Discrete (on/off).. ........................ 0.5
90. Yaw damper command.......... Full range......... As installed............ 0.5 1% of full range.
91. Standby rudder valve status. Discrete........... ........................ 0.5
--------------------------------------------------------------------------------------------------------------------------------------------------------
\18\ For all 737 model airplanes: the seconds per sampling interval is 0.5 per control input; the remarks regarding the sampling rate do not apply; a
single control wheel force transducer installed on the left cable control is acceptable provided the left and right control wheel positions also are
recorded.
\19\ For all 737 model airplanes manufactured on or before January 31, 2001, Range values are: Full Range; Control wheel 15 lbs.; Control
column 40 lbs.; and Rudder pedal 165 lbs.
[[Page 52401]]
* * * * *
Issued in Washington, DC, on August 25, 2006.
John J. Hickey,
Director, Aircraft Certification Service.
[FR Doc. 06-7406 Filed 9-1-06 8:45 am]
BILLING CODE 4910-13-P