29 C.F.R. § 1910.111
(a) General—(1) Scope.
(ii) This standard does not apply to:
(a) Ammonia manufacturing plants.
(b) Refrigeration plants where ammonia is used solely as a refrigerant.
(2) Definitions. As used in this section.
(b) Basic rules. This paragraph applies to all paragraphs of this section unless otherwise noted.
(1) Approval of equipment and systems. Each appurtenance shall be approved in accordance with paragraph (b)(1) (i), (ii), (iii), or (iv) of this section.
(2) Requirements for construction, original test and requalification of nonrefrigerated containers.
(iii) Containers exceeding 36 inches in diameter or 250 gallons water capacity shall be constructed to comply with one or more of the following:
(a) Containers shall be stress relieved after fabrication in accordance with the Code, or
(b) Cold-form heads when used, shall be stress relieved, or
(c) Hot-formed heads shall be used.
(3) Marking nonrefrigerated containers.
(ii) Each container or system covered in paragraphs (c), (f), (g), and (h) of this section shall be marked as specified in the following:
(a) With a notation “Anhydrous Ammonia.”
(b) With a marking identifying compliance with the rules of the Code under which the container is constructed.
Under ground: Container and system nameplate. Above ground: Container.
(c) With a notation whether the system is designed for underground or aboveground installation or both.
(d) With the name and address of the supplier of the system or the trade name of the system and with the date of fabrication.
Under ground and above ground: System nameplate.
(e) With the water capacity of the container in pounds at 60 °F. or gallons, U.S. Standard.
Under ground: Container and system nameplate. Above ground: Container.
(f) With the design pressure in pounds per square inch.
Under ground: Container and system nameplate. Above ground: Container.
(g) With the wall thickness of the shell and heads.
Under ground: Container and system nameplate. Above ground: Container.
(h) With marking indicating the maximum level to which the container may be filled with liquid anhydrous ammonia at temperatures between 20 °F. and 130 °F. except on containers provided with fixed level indicators, such as fixed length dip tubes, or containers that are filled with weight. Markings shall be in increments of not more than 20 °F.
Above ground and under ground: System nameplate or on liquid-level gaging device.
(i) With the total outside surface area of the container in square feet.
Under ground: System nameplate. Above ground: No requirement.
(j) Marking specified on the container shall be on the container itself or on a nameplate permanently attached to it.
(4) Marking refrigerated containers. Each refrigerated container shall be marked with nameplate on the outer covering in an accessible place as specified in the following:
(5) Location of containers.
(6) Container appurtenances.
(7) Piping, tubing, and fittings.
(8) Hose specifications.
(v) On all hose one-half inch outside diameter and larger, used for the transfer of anhydrous ammonia liquid or vapor, there shall be etched, cast, or impressed at 5-foot intervals the following information.
“Anhydrous Ammonia” xxx p.s.i.g. (maximum working pressure), manufacturer's name or trademark, year of manufacture.
In lieu of this requirement the same information may be contained on a nameplate permanently attached to the hose.
| Surface area (sq. ft.) | Flow rate CFM air |
|---|---|
| 20 | 258 |
| 25 | 310 |
| 30 | 360 |
| 35 | 408 |
| 40 | 455 |
| 45 | 501 |
| 50 | 547 |
| 55 | 591 |
| 60 | 635 |
| 65 | 678 |
| 70 | 720 |
| 75 | 762 |
| 80 | 804 |
| 85 | 845 |
| 90 | 885 |
| 95 | 925 |
| 100 | 965 |
| 105 | 1,010 |
| 110 | 1,050 |
| 115 | 1,090 |
| 120 | 1,120 |
| 125 | 1,160 |
| 130 | 1,200 |
| 135 | 1,240 |
| 140 | 1,280 |
| 145 | 1,310 |
| 150 | 1,350 |
| 155 | 1,390 |
| 160 | 1,420 |
| 165 | 1,460 |
| 170 | 1,500 |
| 175 | 1,530 |
| 180 | 1,570 |
| 185 | 1,600 |
| 190 | 1,640 |
| 195 | 1,670 |
| 200 | 1,710 |
| 210 | 1,780 |
| 220 | 1,850 |
| 230 | 1,920 |
| 240 | 1,980 |
| 250 | 2,050 |
| 260 | 2,120 |
| 270 | 2,180 |
| 280 | 2,250 |
| 290 | 2,320 |
| 300 | 2,380 |
| 310 | 2,450 |
| 320 | 2,510 |
| 330 | 2,570 |
| 340 | 2,640 |
| 350 | 2,700 |
| 360 | 2,760 |
| 370 | 2,830 |
| 380 | 2,890 |
| 390 | 2,950 |
| 400 | 3,010 |
| 450 | 3,320 |
| 500 | 3,620 |
| 550 | 3,910 |
| 600 | 4,200 |
| 650 | 4,480 |
| 700 | 4,760 |
| 750 | 5,040 |
| 800 | 5,300 |
| 850 | 5,590 |
| 900 | 5,850 |
| 950 | 6,120 |
| 1,000 | 6,380 |
| 1,050 | 6,640 |
| 1,100 | 6,900 |
| 1,150 | 7,160 |
| 1,200 | 7,410 |
| 1,250 | 7,660 |
| 1,300 | 7,910 |
| 1,350 | 8,160 |
| 1,400 | 8,410 |
| 1,450 | 8,650 |
| 1,500 | 8,900 |
| 1,550 | 9,140 |
| 1,600 | 9,380 |
| 1,650 | 9,620 |
| 1,700 | 9,860 |
| 1,750 | 10,090 |
| 1,800 | 10,330 |
| 1,850 | 10,560 |
| 1,900 | 10,800 |
| 1,950 | 11,030 |
| 2,000 | 11,260 |
| 2,050 | 11,490 |
| 2,100 | 11,720 |
| 2,150 | 11,950 |
| 2,200 | 12,180 |
| 2,250 | 12,400 |
| 2,300 | 12,630 |
| 2,350 | 12,850 |
| 2,400 | 13,080 |
| 2,450 | 13,300 |
| 2,500 | 13,520 |
Surface Area = total outside surface area of container in square feet. When the surface area is not stamped on the nameplate or when the marking is not legible the area can be calculated by using one of the following formulas: (1) Cylindrical container with hemispherical heads: Area = overall length in feet times outside diameter in feet times 3.1416. (2) Cylindrical container with other than hemispherical heads: Area = (overall length in feet plus 0.3 outside diameter in feet) times outside diameter in feet times 3.1416. (3) Spherical container: Area = outside diameter in feet squared times 3.1416. Flow Rate—CFM Air = cubic feet per minute of air required at standard conditions, 60 °F. and atmospheric pressure (14.7 p.s.i.a.). The rate of discharge may be interpolated for intermediate values of surface area. For containers with total outside surface area greater than 2,500 square feet, the required flow rate can be calculated using the formula: Flow Rate CFM Air = 22.11 A 0 82, where A = outside surface area of the container in square feet.
(9) Safety relief devices.
(ii) Container safety-relief valves shall be set to start-to-discharge as follows, with relation to the design pressure of the container:
| Containers | Minimum (percent) | Maximum (percent) |
|---|---|---|
| ASME-U-68, U-69 | 110 | 125 |
| ASME-U-200, U-201 | 95 | 100 |
| ASME 1959, 1956, 1952, or 1962 | 95 | 100 |
| API-ASME | 95 | 100 |
| U.S. Coast Guard | 95 | 100 |
As required by DOT Regulations.
(10) General.
(11) Charging of containers.
(i) The filling densities for containers that are not refrigerated shall not exceed the following:
| Type of container | Percent by weight | Percent by volume |
|---|---|---|
| Aboveground-Uninsulated | 56 | 82 |
| Aboveground-Uninsulated | 87.5 | |
| Aboveground-Insulated | 57 | 83.5 |
| Underground-Uninsulated | 58 | 85 |
| DOT—In accord with DOT regulations. |
(12) Transfer of liquids.
(v) Pumps used for transferring ammonia shall be those manufactured for that purpose.
(a) Pumps shall be designed for at least 250 p.s.i.g. working pressure.
(b) Positive displacement pumps shall have, installed off the discharged port, a constant differential relief valve discharging into the suction port of the pump through a line of sufficient size to carry the full capacity of the pump at relief valve setting, which setting and installation shall be according to the pump manufacturer's recommendations.
(c) On the discharge side of the pump, before the relief valve line, there shall be installed a pressure gage graduated from 0 to 400 p.s.i.
(d) Plant piping shall contain shutoff valves located as close as practical to pump connections.
(vi) Compressors used for transferring or refrigerating ammonia shall be recommended for ammonia service by the manufacturer.
(a) Compressors shall be designed for at least 250 p.s.i.g. working pressure.
(b) Plant piping shall contain shutoff valves located as close as practical to compressor connections.
(c) A relief valve large enough to discharge the full capacity of the compressor shall be connected to the discharge before any shutoff valve.
(d) Compressors shall have pressure gages at suction and discharge graduated to at least one and one-half times the maximum pressure that can be developed.
(e) Adequate means, such as drainable liquid trap, shall be provided on the compressor suction to minimize the entry of liquid into the compressor.
(13) Tank car unloading points and operations.
(14) Liquid-level gaging device.
(16) Electrical equipment and wiring.
(c) Systems utilizing stationary, nonrefrigerated storage containers. This paragraph applies to stationary, nonrefrigerated storage installations utilizing containers other than those covered in paragraph (e) of this section. Paragraph (b) of this section applies to this paragraph unless otherwise noted.
(2) Container valves and accessories, filling and discharge connections.
(3) Safety-relief devices.
(4) Reinstallation of containers.
(5) Installation of storage containers.
(6) Protection of appurtenances.
(d) Refrigerated storage systems. This paragraph applies to systems utilizing containers with the storage of anhydrous ammonia under refrigerated conditions. All applicable rules of paragraph (b) of this section apply to this paragraph unless otherwise noted.
(1) Design of containers.
(2) Installation of refrigerated storage containers.
(4) Safety relief devices.
(ii) The total relieving capacity shall be the larger of:
(a) Possible refrigeration system upset such as (1) cooling water failure, (2) power failure, (3) instrument air or instrument failure, (4) mechanical failure of any equipment, (5) excessive pumping rates.
(b) Fire exposure determined in accordance with Compressed Gas Association (CGA) S-1, part 3, Safety Relief Device Standards for Compressed Gas Storage Containers, 1959, which is incorporated by reference as specified in § 1910.6, except that “A” shall be the total exposed surface area in square feet up to 25 foot above grade or to the equator of the storage container if it is a sphere, whichever is greater. If the relieving capacity required for fire exposure is greater than that required by (a) of this subdivision, the additional capacity may be provided by weak roof to shell seams in containers operating at essentially atmospheric pressure and having an inherently weak roof-to-shell seam. The weak roof-to-shell seam is not to be considered as providing any of the capacity required in (a) of this subdivision.
(8) Refrigeration load and equipment.
(i) The total refrigeration load shall be computed as the sum of the following:
(a) Load imposed by heat flow into the container caused by the temperature differential between design ambient temperature and storage temperature.
(b) Load imposed by heat flow into the container caused by maximum sun radiation.
(c) Maximum load imposed by filling the container with ammonia warmer than the design storage temperature.
(9) Compressors.
(10) Compressor drives.
(11) Automatic control equipment.
(12) Separators for compressors.
(f) Tank motor vehicles for the transportation of ammonia.
(1) This paragraph applies to containers and pertinent equipment mounted on tank motor vehicles including semitrailers and full trailers used for the transportation of ammonia. This paragraph does not apply to farm vehicles. For requirements covering farm vehicles, refer to paragraphs (g) and (h) of this section.
Paragraph (b) of this section applies to this paragraph unless otherwise noted. Containers and pertinent equipment for tank motor vehicles for the transportation of anhydrous ammonia, in addition to complying with the requirements of this section, shall also comply with the requirements of DOT.
(2) Design pressure and construction of containers.
(3) Container appurtenances.
(4) Piping and fittings.
(5) Safety relief devices.
(6) Transfer of liquids.
(2) Design pressure and classification of containers.
(3) Mounting containers.
(4) Container appurtenances.
(6) Farm vehicles.
(h) Systems mounted on farm vehicles for the application of ammonia.
(4) Container valves and accessories.
[39 FR 23502, June 27, 1974, as amended at 43 FR 49748, Oct. 24, 1978; 49 FR 5322, Feb. 10, 1984; 53 FR 12122, Apr. 12, 1988; 61 FR 9238, Mar. 7, 1996; 63 FR 1269, Jan. 8, 1998; 63 FR 33466, June 18, 1998; 72 FR 71069, Dec. 14, 2007]