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Gas cylinder Wikipedia

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Gas cylinder
A gas cylinder is a pressure vessel for storage and containment of
gases at above atmospheric pressure. High-pressure gas cylinders
are also called bottles. Inside the cylinder the stored contents may
be in a state of compressed gas, vapor over liquid, supercritical
fluid, or dissolved in a substrate material, depending on the physical
characteristics of the contents. A typical gas cylinder design is
elongated, standing upright on a flattened bottom end, with the
valve and fitting at the top for connecting to the receiving apparatus.
The term cylinder in this context is not to be confused with tank, the
latter being an open-top or vented container that stores liquids under
gravity, though the term scuba tank is commonly used to refer to a
cylinder used for breathing gas supply to an underwater breathing
apparatus.
Nomenclature
Industrial compressed gas cylinders
used for oxy-fuel welding and cutting
of steel.
In the United States, "bottled gas" typically refers to liquefied petroleum gas. "Bottled gas" is sometimes
used in medical supply, especially for portable oxygen tanks. Packaged industrial gases are frequently called
"cylinder gas", though "bottled gas" is sometimes used. The term propane tank is also used for cylinders
with propane.
The United Kingdom and other parts of Europe more commonly refer to "bottled gas" when discussing any
usage, whether industrial, medical, or liquefied petroleum. In contrast, what is called liquefied petroleum
gas in the United States is known generically in the United Kingdom as "LPG" and it may be ordered by
using one of several trade names, or specifically as butane or propane, depending on the required heat
output.
Materials
Design codes and application standards and the cost of materials dictated the choice of steel with no welds
for most gas cylinders; the steel is treated to resist corrosion. Some newly developed lightweight gas
cylinders are made from stainless steel and composite materials. Due to the very high tensile strength of
carbon fiber reinforced polymer, these vessels can be very light, but are more difficult to manufacture.[1]
Cylinders reinforced or built-up with a fibre material usually must be inspected more frequently than metal
cylinders, e.g., every 5 instead of 10 years, and must be inspected more thoroughly than metal cylinders.
They may have a limited service life.
The inspection interval of steel cylinders has increased from 5 or 6 years to 10 years. Diving cylinders that
are used in water must be inspected more often. When they were found to have inherent structural
problems, certain steel and aluminium alloys have been withdrawn from service.
Fibre composite cylinders were originally specified for a limited life span of 15, 20 or 30 years, while steel
cylinders are nowadays typically withdrawn after 70 years, or may continue to be used indefinitely
providing they pass periodic inspection and testing. Since some years there exist composite cylinders that
are nominated for a non-limited-life (NLL), as long as no damage is to be seen.
Types
Since glass-fibre-composite materials were used to reinforce cylinders, there are various types of
construction of high-pressure vessels:
1. Metal only. Mostly seamless forged metal. But for lower working pressure, e.g., liquefied
butane, there are welded steel vessels, too.
2. Metal vessel, hoop wrapped with a fibre composite only around the cylindrical part of the
"cylinder". (Geometrically there is a need for twice the tensile strength on the cylindrical
region in comparison to the spherical caps of the cylinder.)
3. Thin metal liner (that keeps the vessel tight, but does not contribute to the working pressure)
fully wrapped with fibre in the matrix material.
4. Metal-free liner from plastics, fully wrapped with fibre material. The boss, the centre of the
head(s) of the cylinder is still from metal and includes the thread for the valve.
Pressure vessels for gas storage may also be classified by volume. In South Africa, a gas storage cylinder
implies a refillable transportable container with a water capacity volume of up to 150 litres. Refillable
transportable cylindrical containers from 150 to 3,000 litres water capacity are referred to as tubes.[2]
Regulations and testing
The transportation of high-pressure cylinders is regulated by many governments throughout the world.
Various levels of testing are generally required by the governing authority for the country in which it is to be
transported. In the United States, this authority is the United States Department of Transportation (DOT).
Similarly in the UK, the European transport regulations (ADR) are implemented by the Department for
Transport (DfT). For Canada, this authority is Transport Canada (TC). Cylinders may have additional
requirements placed on design and or performance from independent testing agencies such as Underwriters
Laboratories (UL). Each manufacturer of high-pressure cylinders is required to have an independent quality
agent that will inspect the product for quality and safety.
Within the UK the "competent authority" — the Department for Transport (DfT) — implements the
regulations and appointment of authorised cylinder testers is conducted by United Kingdom Accreditation
Service (UKAS), who make recommendations to the Vehicle Certification Agency (VCA) for approval of
individual bodies.
There are a variety of tests that may be performed on various cylinders. Some of the most common types of
tests are hydrostatic test, burst test, ultimate tensile strength, Charpy impact test and pressure cycling.
During the manufacturing process, vital information is usually stamped or permanently marked on the
cylinder. This information usually includes the type of cylinder, the working or service pressure, the serial
number, date of manufacture, the manufacture's registered code and sometimes the test pressure. Other
information may also be stamped, depending on the regulation requirements.
High-pressure cylinders that are used multiple times — as most are — can be hydrostatically or
ultrasonically tested and visually examined every few years.[3] In the United States, hydrostatic/ultrasonic
testing is required either every five years or every ten years, depending on cylinder and its service.
Valve connections
Valve
Gas cylinders usually have a stop angle valve at one end, and the
cylinder is usually oriented so the valve is on top. During storage,
transportation, and handling when the gas is not in use, a cap may
be screwed over the protruding valve to protect it from damage or
breaking off in case the cylinder were to fall over. Instead of a cap,
cylinders sometimes have a protective collar or neck ring around the
valve assembly.
Connection
A gas regulator attached to a
nitrogen cylinder. From right —
cylinder valve, cylinder pressure
gauge, pressure control valve
(yellow) on regulator (green), outlet
pressure gauge, 3-way outlet
terminated by needle valves.
The valves on industrial, medical and diving cylinders usually have
threads of different handedness, sizes and types that depend on the
category of gas, making it more difficult to mistakenly misuse a gas.
For example, a hydrogen cylinder does not fit an oxygen regulator
and supply line, which could result in catastrophe. Some fittings use a right-hand thread, while others use a
left-hand thread; left-hand thread fittings are usually identifiable by notches or grooves cut into them.
In the United States, valve connections are sometimes referred to as CGA connections, since the
Compressed Gas Association (CGA) publishes guidelines on what connections to use for what gasses. For
example, an argon cylinder has a "CGA 580" connection on the valve. High purity gases sometimes use
CGA-DISS ("Diameter Index Safety System") connections.
Common cylinder valve connections
Gas type
CGA valve outlet (USA)
Acetylene
510
Air, breathing
346, 347
Air, industrial
590
Argon
580, 718, 680 (3,500 psi), 677 (6,000 psi)
Butane
510
Carbon dioxide
320, 716
Carbon monoxide
350, 724
Chlorine
660, 728
Helium
580, 718, 680 (3,500 psi)
Hydrogen
350, 724, 695 (3,500 psi)
Methane
350
Neon
580, 718
Nitrogen
580, 718, 680 (3,500 psi), 677 (6,000 psi)
Nitrous oxide
326, 712
Oxygen
540, 714
Oxygen mixtures (>23.5%)
296
Propane
510
Xenon
580, 718
Medical gases may use the pin index safety system to prevent incorrect connection of gases to services.
In the European Union, DIN connections are more common than in the United States.
In the UK, the British Standards Institution sets the standards. Included among the standards is the use lefthand threaded valves for flammable gas cylinders (most commonly brass, BS4, valves for non-corrosive
cylinder contents or stainless steel, BS15, valves for corrosive contents). Non flammable gas cylinders are
fitted with right-hand threaded valves (most commonly brass, BS3, valves for non-corrosive components or
stainless steel, BS14, valves for corrosive components).[4]
Common cylinder valve connections
Gas type
BS valve outlet (UK)[4]
Acetylene
2, 4
Air, breathing
3
Air, industrial
3
Argon
3
Butane
4
Carbon dioxide
8
Carbon monoxide
4
Chlorine
6
Helium
3
Hydrogen
4
Methane
4
Neon
3
Nitrogen
3
Nitrous oxide
13
Oxygen
3
Oxygen mixtures (>23.5%)
Other guides apply
Propane
4
Xenon
3
Regulator
When the gas in the cylinder is to be used at low pressure, the cap is taken off and a pressure-regulating
assembly is attached to the stop valve. This attachment typically has a pressure regulator with upstream
(inlet) and downstream (outlet) pressure gauges and a further downstream needle valve and outlet
connection. For gases that remain gaseous under ambient storage conditions, the upstream pressure gauge
can be used to estimate how much gas is left in the cylinder according to pressure. For gases that are liquid
under storage, e.g., propane, the outlet pressure is dependent on the vapor pressure of the gas, and does not
fall until the cylinder is nearly exhausted, although it will vary according to the temperature of the cylinder
contents. The regulator is adjusted to control the downstream pressure, which will limit the maximum flow
of gas out of the cylinder at the pressure shown by the downstream gauge. For some purposes, such as
shielding gas for arc welding, the regulator will also have a flowmeter on the downstream side.
The regulator outlet connection is attached to whatever needs the gas supply.
Safety and standards
Because the contents are under pressure and are sometimes hazardous materials, handling bottled gases is
regulated. Regulations may include chaining bottles to prevent falling and damaging the valve, proper
ventilation to prevent injury or death in case of leaks and signage to indicate the potential hazards If a
compressed gas cylinder tips over, causing the valve block to be sheared off, the rapid release of high-
pressure gas may cause the cylinder to be violently accelerated,
potentially causing property damage, injury, or death. To prevent
this, cylinders are normally secured to a fixed object or transport
cart with a strap or chain. They can also be stored in a safety
cabinet.
In a fire, the pressure in a gas cylinder rises in direct proportion to
its temperature. If the internal pressure exceeds the mechanical
limitations of the cylinder and there are no means to safely vent the
pressurized gas to the atmosphere, the vessel will fail mechanically.
If the vessel contents are flammable, this event may result in a
"fireball".[5] Oxidisers such as oxygen and fluorine will produce a
similar effect by accelerating combustion in the area affected. If the
cylinder's contents are liquid, but become a gas at ambient
conditions, this is commonly referred to as a boiling liquid
expanding vapour explosion (BLEVE).
Medical gas cylinders in the UK and some other countries have a
fusible plug of Wood's metal in the valve block between the valve
seat and the cylinder. This plug melts at a comparatively low
temperature (70 °C) and allows the contents of the cylinder to
escape to the surroundings before the cylinder is significantly
weakened by the heat, lessening the risk of explosion.
It would be safer to have cylinders
individually anchored in a cool place,
rather than chained in a cluster in the
sun, as seen here.
Gas cylinders found in hot air balloons have to be checked once a year as part of an annual inspection by a
CAA approved inspector ensuring no dents or scratches pose a risk to the cylinder. Pressure relief valves on
balloon cylinders are replaced after 10 years or sooner if there are signs of damage to them along with an
internal inspection of the cylinders to check for corrosion and foreign elements within the cylinder.[6]
More common pressure relief devices are a simple burst disc installed in the base of the valve between the
cylinder and the valve seat. A burst disc is a small metal gasket engineered to rupture at a pre-determined
pressure. Some burst discs are backed with a low-melting-point metal, so that the valve must be exposed to
excessive heat before the burst disc can rupture.
The Compressed Gas Association publishes a number of booklets and pamphlets on safe handling and use
of bottled gases.
International and national standards
There is a wide range of standards relating to the manufacture, use and testing of pressurised gas cylinders
and related components. Some examples are listed here.
ISO 11439: Gas cylinders — High-pressure cylinders for the on-board storage of natural gas
as a fuel for automotive vehicles[7]
ISO 15500-5: Road vehicles — Compressed natural gas (CNG) fuel system components —
Part 5: Manual cylinder valve[8][9]
US DOT CFR Title 49, part 178, Subpart C — Specification for Cylinders[10]
US DOT Aluminum Tank Alloy 6351-T6 amendment for SCUBA, SCBA, Oxygen Service —
Visual Eddy inspection[11]
AS 2896-2011:Medical gas systems—Installation and testing of non-flammable medical gas
pipeline systems pipeline systems (Australian Standards).
Color coding
Gas cylinders are often color-coded, but the codes are not standard across different jurisdictions, and
sometimes are not regulated. Cylinder color can not safely be used for positive product identification;
cylinders have labels to identify the gas they contain.
Common cylinder sizes
The below are example cylinder sizes and do not constitute an industry standard.
Cyl. size
Diameter × height,
including 5.5 inches for
valve and cap (inches)
Nominal tare
weight,
including 4.5 lb for
valve and cap (lb)
Water
capacity
(lb)
Internal volume,
70 °F (21 °C),
1 atm
(liters)
(cu. ft)
U.S. DOT
specs
2HP
9 by 51 inches (230 mm
× 1,300 mm)
187 pounds (85 kg)
95.5
43.3
1.53
3AA3500
K
9.25 by 60 inches (235 mm
× 1,524 mm)
135 pounds (61 kg)
110
49.9
1.76
3AA2400
A
9 by 51 inches (230 mm
× 1,300 mm)
115 pounds (52 kg)
96
43.8
1.55
3AA2015
B
8.5 by 31 inches (220 mm
× 790 mm)
60 pounds (27 kg)
37.9
17.2
0.61
3AA2015
C
6 by 24 inches (150 mm
× 610 mm)
27 pounds (12 kg)
15.2
6.88
0.24
3AA2015
D
4 by 18 inches (100 mm
× 460 mm)
12 pounds (5.4 kg)
4.9
2.24
0.08
3AA2015
AL
8 by 53 inches (200 mm
× 1,350 mm)
52 pounds (24 kg)
64.8
29.5
1.04
3AL2015
BL
7.25 by 39 inches (184 mm
× 991 mm)
33 pounds (15 kg)
34.6
15.7
0.55
3AL2216
CL
6.9 by 21 inches (180 mm
× 530 mm)
19 pounds (8.6 kg)
13
5.9
0.21
3AL2216
XL
14.5 by 50 inches (370 mm
× 1,270 mm)
75 pounds (34 kg)
238
108
3.83
4BA240
SSB
8 by 37 inches (200 mm
× 940 mm)
95 pounds (43 kg)
41.6
18.9
0.67
3A1800
10S
4 by 31 inches (100 mm
× 790 mm)
21 pounds (9.5 kg)
8.3
3.8
0.13
3A1800
LB
2 by 15 inches (51 mm
× 381 mm)
4 pounds (1.8 kg)
1
0.44
0.016
3E1800
XF
12 by 46 inches (300 mm
× 1,170 mm)
180 pounds (82 kg)
134.3
60.9
2.15
8AL
XG
15 by 56 inches (380 mm
× 1,420 mm)
149 pounds (68 kg)
278
126.3
4.46
4AA480
XM
10 by 49 inches (250 mm
× 1,240 mm)
90 pounds (41 kg)
120
54.3
1.92
3A480
XP
10 by 55 inches (250 mm
× 1,400 mm)
55 pounds (25 kg)
124
55.7
1.98
4BA300
QT
3 by 14 inches (76 mm
× 356 mm) (includes
4.5 inches for valve)
2.5 pounds (1.1 kg)
(includes 1.5 lb for
valve)
2.0
0.900
0.0318
4B-240ET
LP5
12.25 by 18.25 inches
(311 mm × 464 mm)
18.5 pounds (8.4 kg)
47.7
21.68
0.76
4BW240
Medical E
4 by 26 inches (100 mm
× 660 mm) (excludes valve
and cap)
14 pounds (6.4 kg)
(excludes valve and
cap)
9.9
4.5
0.16
3AA2015
(US DOT specs define material, making, and maximum pressure in psi. They are comparable to Transport
Canada specs, which shows pressure in bars. A 3E-1800 in DOT nomenclature would be a TC 3EM 124 in
Canada.[12])
Gas storage tubes
For larger volume high pressure gas storage units, known as tubes, are available. They generally have a
larger diameter and length than high pressure cylinders, and usually have a tapped neck at both ends. They
may be mounted alone or in groups on trailers, permanent bases, or intermodal transport frames. Due to
their length, they are mounted horizontally on mobile structures. In general usage they are often manifolded
together and managed as a unit.
Gas storage banks
Groups of similar size cylinders may be mounted together and
connected to a common manifold system to provide larger storage
capacity than a single standard cylinder. This is commonly called a
cylinder bank or a gas storage bank. The manifold may be arranged
to allow simultaneous flow from all the cylinders, or, for a cascade
filling system, where gas is tapped off cylinders according to the
lowest positive pressure difference between storage and destination
cylinder, being a more efficient use of pressurised gas.
Gas storage quads
Hydrogen storage cylinders in a
cascade filling system
A gas quad is a group of high pressure cylinders mounted on a
transport and storage frame. There are commonly 16 cylinders, each
of about 50 litres capacity mounted upright in four rows of four, on
a square base with a square plan frame with lifting points on top
and may have fork-lift slots in the base. The cylinders are usually
interconnected as a manifold for use as a unit, but many variations
in layout and structure are possible.
See also
Bottled gas – Gas compressed and stored in cylinders
Composite overwrapped pressure vessel – Pressure
vessel with a non-structural liner wrapped with a
structural fiber composite
Filling carousel – Device for filling liquefied petroleum
gas cylinders
Helium quad for surface-supplied
Lecture bottle – Small gas cylinder typically used for
diving gas
specialty gasses
Powerlet – a small, inexpensive, disposable metal gas
cylinder for providing pneumatic power
Storage tank – Container for liquids or compressed gas
UN Recommendations on the Transport of Dangerous Goods – United Nations Model
Regulations
References
1. See Composite overwrapped pressure vessel for details
2. South African National Standard SANS 10019:2008 Transportable containers for
compressed, dissolved and liquefied gases – Basic design,manufacture, use and
maintenance (6th ed.). Pretoria, South Africa: Standards South Africa. 2008. ISBN 978-0626-19228-0.
3. Henderson, N. C.; Berry, W. E.; Eiber, R. J.; Frink, D. W. (1970). "Investigation of scuba
cylinder corrosion, Phase 1" (https://archive.today/20130415190711/http://archive.rubicon-fo
undation.org/9293). National Underwater Accident Data Center Technical Report Number 1.
University of Rhode Island. Archived from the original on 15 April 2013. Retrieved
11 January 2016.
4. BS 341-3:2002, British Standards Institution, 389 Chiswick High Road, London, W4 4AL.
5. "Incident Insights – Trust But Verify" (https://www.diversalertnetwork.org/diving-incidents/trust
-but-verify). Divers Alert Network.
6. "Kubicek Fuel Cylinder Systems in use for Hot air Balloons" (https://www.kubicekballoons.c
o.uk/fuel-cylinders).
7. "ISO 11439:2000 — Gas cylinders – High pressure cylinders for the on-board storage of
natural gas as a fuel for automotive vehicles" (http://www.iso.org/iso/catalogue_detail?csnum
ber=33298).
8. "ISO 15500-5:2001 — Road vehicles – Compressed natural gas (CNG) fuel system
components – Part 5: Manual cylinder valve" (http://www.iso.org/iso/iso_catalogue/catalogue
_tc/catalogue_detail.htm?csnumber=30452).
9. "CNG Cylinder Valve ISO 15500 -" (http://www.iso15500.com/).
10. US DOT e-CFR (Electronic Code of Federal Regulations) Title 49, part 178, Subpart C —
Specification for Cylinders — eg DOT 3AL = seamless aluminum (https://www.ecfr.gov/curre
nt/title-49/part-178/subpart-C)
11. Federal Register / Vol. 71, No. 167 / Tuesday, August 29, 2006 / Rules and Regulations Title
49 CFR Parts 173 and 180 Visual Edddy (http://edocket.access.gpo.gov/2006/pdf/E6-14255.
pdf)
12. "Sample Cylinders SC and MC Series" (https://www.tgcigroup.com/wp-content/uploads/201
6/01/Sample-Cylinders.pdf?) (PDF). FITOK. Retrieved 1 February 2023.
External links
NASA — Safety Standards for Oxygen and Oxygen Handling (https://web.archive.org/web/2
0041104014946/http://www.hq.nasa.gov/office/codeq/doctree/canceled/1740151.pdf)
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