Section

[Code of Federal Regulations]

[Title 49, Volume 2]

[Revised as of October 1, 2005]

From the U.S. Government Printing Office via GPO Access

[CITE: 49CFR178.58]

[Page 856-859]

TITLE 49--TRANSPORTATION

CHAPTER I--PIPELINE AND HAZARDOUS MATERIALS SAFETY ADMINISTRATION,

DEPARTMENT OF TRANSPORTATION

PART 178_SPECIFICATIONS FOR PACKAGINGS--Table of Contents

Subpart C_Specifications for Cylinders

Sec. 178.58 Specification 4DA welded steel cylinders for aircraft use.

(a) Type, size, and service pressure. A DOT 4DA is a welded steel

sphere (two seamless hemispheres) or a circumferentially welded cylinder

(two seamless drawn shells) with a water capacity not over 100 pounds

and a service pressure of at least 500 but not over 900 psig.

(b) Steel. Open-hearth or electric steel of uniform quality must be

used. A heat of steel made under table 1 in this paragraph (b), check

chemical analysis of which is slightly out of the specified range, is

acceptable, if satisfactory in all other respects, provided the

tolerances shown in table 2 in this paragraph (b) are not exceeded

except as approved by the Associate Administrator. The following

chemical analyses are authorized:

Table 1--Authorized Materials

------------------------------------------------------------------------

4130 Percent

------------------------------------------------------------------------

Carbon.................................... 0.28/0.33.

Manganese................................. 0.40/0.60.

Phosphorus................................ 0.040 max.

Sulfur.................................... 0.040 max.

Silicon................................... 0.15/0.35.

Chromium.................................. 0.80/1.10.

Molybdenum................................ 0.15/0.25.

------------------------------------------------------------------------

Table 2--Check Analysis Tolerances

----------------------------------------------------------------------------------------------------------------

Tolerance (percent) over the maximum limit or

Limit or maximum under the minimum limit

Element specified (percent) -------------------------------------------------

Under minimum limit Over maximum limit

----------------------------------------------------------------------------------------------------------------

Carbon............................... Over 0.15 to 0.40 incl. .03.................... .04

Manganese............................ To 0.60 incl........... .03.................... .03

Phosphorus\1\........................ All ranges............. ....................... .01

Sulphur.............................. All ranges............. ....................... .01

Silicon.............................. To 0.30 incl........... .02.................... .03

Over 0.30 to 1.00 incl. .05.................... .05

Chromium............................. To 0.90 incl........... .03.................... .03

Over 0.90 to 2.10 incl. .05.................... .05

Molybdenum........................... To 0.20 incl........... .01.................... .01

Over 0.20 to 0.40, incl .02.................... .02

----------------------------------------------------------------------------------------------------------------

\1\ Rephosphorized steels not subject to check analysis for phosphorus.

suitable method except that plates and billets for hot-drawn containers

must be marked with the heat number.

(d) Manufacture. Cylinders must be manufactured in accordance with

the following requirements:

(1) By best appliances and methods. No defect is acceptable that is

likely to weaken the finished container appreciably. A reasonably smooth

and uniform surface finish is required. No abrupt change in wall

thickness is permitted. Welding procedures and operators must be

qualified in accordance with CGA Pamphlet C-3 (IBR, see Sec. 171.7 of

this subchapter).

(2) All seams of the sphere or cylinders must be fusion welded.

Seams

[[Page 857]]

must be of the butt or joggle butt type and means must be provided for

accomplishing complete penetration of the joint.

(e) Welding. Attachments to the container are authorized by fusion

welding provided that such attachments are made of weldable steel, the

carbon content of which may not exceed 0.25 percent except in the case

of 4130 steel.

(f) Wall thickness. The minimum wall thickness must be such that the

wall stress at the minimum specified test pressure may not exceed 67

percent of the minimum tensile strength of the steel as determined from

the physical and burst tests required and may not be over 70,000 p.s.i.

For any diameter container, the minimum wall thickness is 0.040 inch.

Calculations must be made by the formulas in (f)(1) or (f)(2) of this

section:

(1) Calculation for a sphere must be made by the following formula:

S = PD / 4tE

Where:

S = wall stress in pounds psi;

P = test pressure prescribed for water jacket test, i.e., at least 2

times service pressure, in psig;

D = outside diameter in inches;

t = minimum wall thickness in inches;

E = 0.85 (provides 85 percent weld efficiency factor which must be

applied in the girth weld area and heat affected zones which zone must

extend a distance of 6 times wall thickness from center line of weld);

E = 1.0 (for all other areas).

(2) Calculation for a cylinder must be made by the following

formula:

S = [P(1.3D ² + 0.4d ²)] / (D ² - d

²)

Where:

S = wall stress in pounds psi;

P = test pressure prescribed for water jacket test, i.e., at least 2

times service pressure, in psig;

D = outside diameter in inches;

d = inside diameter in inches.

(g) Heat treatment. The completed containers must be uniformly and

properly heat-treated prior to tests. Heat-treatment of containers of

the authorized analysis must be as follows:

(1) All containers must be quenched by oil, or other suitable medium

except as provided in paragraph (g)(4) of this section.

(2) The steel temperature on quenching must be that recommended for

the steel analysis, but may not exceed 1,750 [deg]F.

(3) The steel must be tempered at the temperature most suitable for

the analysis except that in no case shall the tempering temperature be

less than 1,000 [deg]F.

(4) The steel may be normalized at a temperature of 1,650 [deg]F

instead of being quenched, and containers so normalized need not be

tempered.

(5) All cylinders, if water quenched or quenched with a liquid

producing a cooling rate in excess of 80 percent of the cooling rate of

water, must be inspected by the magnetic particle or dye penetrant

method to detect the presence of quenching cracks. Any cylinder found to

have a quench crack must be rejected and may not be requalified.

(h) Openings in container. Openings in the container must comply

with the following requirements:

(1) Each opening in the container must be provided with a fitting,

boss, or pad of weldable steel securely attached to the container by

fusion welding.

(2) Attachments to a fitting, boss, or pad must be adequate to

prevent leakage. Threads must comply with the following:

(i) Threads must be clean cut, even, without checks, and tapped to

gauge.

(ii) Taper threads to be of length not less than as specified for

American Standard taper pipe threads.

(iii) Straight threads, having at least 4 engaged threads, to have

tight fit and calculated shear strength at least 10 times the test

pressure of the container; gaskets required, adequate to prevent

leakage.

(i) Hydrostatic test. Each cylinder must successfully withstand a

hydrostatic test as follows:

(1) The test must be by water-jacket, or other suitable method,

operated so as to obtain accurate data. The pressure gauge must permit

reading to an accuracy of 1 percent. The expansion gauge must permit

reading of total expansion to accuracy either of 1 percent or 0.1 cubic

centimeter.

(2) Pressure must be maintained for at least 30 seconds and

sufficiently longer to ensure complete expansion.

[[Page 858]]

Any internal pressure applied after heat-treatment and previous to the

official test may not exceed 90 percent of the test pressure. If, due to

failure of the test apparatus, the test pressure cannot be maintained,

the test may be repeated at a pressure increased by 10 percent or 100

psig, whichever is the lower.

(3) Permanent volumetric expansion may not exceed 10 percent of

total volumetric expansion at test pressure.

(4) Each container must be tested to at least 2 times service

pressure.

(j) Burst test. One container taken at random out of 200 or less

must be hydrostatically tested to destruction. The rupture pressure must

be included as part of the inspector's report.

(k) Flattening test. Spheres and cylinders must be subjected to a

flattening test as follows:

(1) Flattening test for spheres. One sphere taken at random out of

each lot of 200 or less must be subjected to a flattening test as

follows:

(i) The test must be performed after the hydrostatic test.

(ii) The test must be at the weld between the parallel steel plates

on a press with a welded seam, at right angles to the plates. Any

projecting appurtenances may be cut off (by mechanical means only) prior

to crushing.

(2) Flattening test for cylinders. One cylinder taken at random out

of each lot of 200 or less, must be subjected to a flattening test as

follows:

(i) The test must be performed after the hydrostatic test.

(ii) The test cylinder must be placed between wedge-shaped knife

edges having a 60[deg] angle, rounded to a \1/2\-inch radius.

(l) Radiographic inspection. Radiographic examinations is required

on all welded joints which are subjected to internal pressure, except

that at the discretion of the disinterested inspector, openings less

than 25 percent of the sphere diameter need not be subjected to

radiographic inspection. Evidence of any defects likely to seriously

weaken the container must be cause for rejection.

(m) Physical test and specimens for spheres and cylinders. Spheres

and cylinders must be subjected to a physical test as follows:

(1) A physical test for a sphere is required on 2 specimens cut from

a flat representative sample plate of the same heat taken at random from

the steel used to produce the sphere. This flat steel from which the 2

specimens are to be cut must receive the same heat-treatment as the

spheres themselves. Sample plates to be taken for each lot of 200 or

less spheres.

(2) Specimens for spheres have a gauge length of 2 inches with a

width not over 1\1/2\ inches, or a gauge length at least 24 times

thickness with a width not over 6 times thickness is authorized when

wall of sphere is not over \3/16\ inch thick.

(3) A physical test for cylinders is required on 2 specimens cut

from 1 cylinder taken at random out of each lot of 200 or less.

(4) Specimens for cylinder must conform to the following:

(i) A gauge length of 8 inches with a width not over 1\1/2\ inches,

a gauge length of 2 inches with a width not over 1\1/2\ inches, a gauge

length at least 24 times thickness with a width not over 6 times

thickness is authorized when a cylinder wall is not over \3/16\ inch

thick.

(ii) The specimen, exclusive of grip ends, may not be flattened.

Grip ends may be flattened to within 1 inch of each end of the reduced

section.

(iii) Heating of a specimen for any purpose is not authorized.

(5) The yield strength in tension must be the stress corresponding

to a permanent strain of 0.2 percent of the gauge length. The following

conditions apply:

(i) The yield strength must be determined by either the ``offset''

method or the ``extension under load'' method as prescribed in ASTM E 8

(IBR, see Sec. 171.7 of this subchapter).

(ii) In using the ``extension under load'' method, the total strain

(or ``extension under load'') corresponding to the stress at which the

0.2 percent permanent strain occurs may be determined with sufficient

accuracy by calculating the elastic extension of the gauge length under

appropriate load and adding thereto 0.2 percent of the gauge length.

Elastic extension calculations must be based on an elastic modulus of

30,000,000. In the event of

[[Page 859]]

controversy, the entire stress-strain diagram must be plotted and the

yield strength determined from the 0.2 percent offset.

(iii) For the purpose of strain measurement, the initial strain must

be set while the specimen is under a stress of 12,000 psi and the strain

indicator reading being set at the calculated corresponding strain.

(iv) Cross-head speed of the testing machine may not exceed \1/8\

inch per minute during yield strength determination.

(n) Acceptable results for physical, flattening, and burst tests.

The following are acceptable results of the physical, flattening and

burst test:

(1) Elongation must be at least 20 percent for a 2-inch gauge length

or 10 percent in other cases.

(2) Flattening is required to 50 percent of the original outside

diameter without cracking.

(3) Burst pressure must be at least 3 times service pressure.

(o) Rejected containers. Reheat-treatment of rejected cylinders is

authorized. Subsequent thereto, containers must pass all prescribed

tests to be acceptable. Repair of welded seams by welding prior to

reheat-treatment is authorized.

(p) Marking. Markings on each container must be stamped plainly and

permanently on a permanent attachment or on a metal nameplate

permanently secured to the container by means other than soft solder.

[Amdt. 178-114, 61 FR 25942, May 23, 1996, as amended at 66 FR 45386,

45388, Aug. 28, 2001; 67 FR 51654, Aug. 8, 2002; 67 FR 61015, Sept. 27,

2002; 68 FR 75748, Dec. 31, 2003]