Gas cylinder

For the mechanical devices used to impart a force from a pressurized liquid or gas, see pneumatic cylinder. For the large structures used to store town gas, see gas holder.
Industrial compressed gas cylinders used for oxy-fuel welding and cutting of steel.

A gas cylinder or tank is a pressure vessel used to store gases at above atmospheric pressure. High-pressure gas cylinders are also called bottles.

Nomenclature differences

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 United Kingdom and other parts of Europe more commonly refer to "bottled gas" when discussing any usage whether industrial, medical or liquefied petroleum. However, in contrast, what the United States calls liquefied petroleum gas 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

For a detailed discussion about the materials for gas cylinders see pressure vessel.

Design codes and application standards along with the cost of materials dictated the choice of steel with no welds for most gas cylinders, treated to be anti corrosive. There have been some newly developed lightweight gas cylinders from composite materials. Due to the very high tensile strength of carbon fiber, these vessels can be very light, but are much more difficult to manufacture.[1]

Regulations and cylinder 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 Underwriter's Laboratory (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 DfT — implements the regulations and appointment of authorised cylinder testers is conducted by UKAS, who make recommendations to the 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, 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.[2] In the United States, hydrostatic/ultrasonic testing is required either every five years or every ten years, depending on cylinder and its service. Helium gas cylinders have the highest pressures possible when full, around 1000 atmospheres.

Valve connections

A gas regulator attached to a nitrogen cylinder. From right — main valve, cylinder pressure gauge, low-pressure valve, outlet pressure gauge, 3-way outlet terminated by needle valves.

When gases are supplied in gas cylinders, the cylinders have a stop angle valve at the end on top. Often, gas cylinders are somewhat long and narrow and may stand upright on a flattened bottom at one end with the valve at the 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 commonly have a protective collar or neck ring around the service valve assembly.

When the gas in the cylinder is ready to be used, 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. The regulator could be adjusted to control the flow of gas out of the cylinder according to pressure shown by the downstream gauge. The outlet connection is attached to whatever needs the gas supply, such as a balloon for example.

The valves on industrial, medical and diving cylinders are usually of different size and type, as are the valves for different products, making it more difficult to mistakenly misuse a gas. 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 products, e.g., In the United States, an argon cylinder will have a CGA 580 connection on the valve.

High purity gases will sometimes use CGA-DISS ("Diameter Index Safety System") connections.

In the EU, DIN connections are more common than in the United States.

Safety and standards

Improper/dangerous handling: Gas cylinders should be chained to a wall for safety, but cylinders are best chained individually to the wall to allow one to be selected without unsecuring the rest. Cylinders should never be stored in direct sunlight or places where high temperatures may occur.

Because the contents are under pressure and are sometimes hazardous, there are special safety regulations for handling bottled gases. These include chaining bottles to prevent falling and breaking, proper ventilation to prevent injury or death in case of leaks and signage to indicate the potential hazards. Installing and replacing gas cylinders should be done by trained personnel. 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.

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 ignitable, this event may result in a "fireball".[3] 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 other countries have a seal of Wood's metal between the valve block and the cylinder body. This seal melts at a comparatively low temperature (70 °C) and allows the contents of the cylinder to escape in a controlled fashion, lessening the risk of explosion.

More common pressure relief devices are of a simple burst disc type. In these, a small burst disc is installed in the back of the valve. 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 sells a number of booklets and pamphlets on safe handling and use of bottled gases.

Cylinders should be properly labeled and securely stored. Substances that may react with each other, e.g., oxidizers and flammable materials, should not be stored in close proximity.

International and US 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 and the label alone should be used for positive identification.

Common cylinder sizes

In scuba diving, the United States measures cylinder volume by the amount of free air that can be compressed into the cylinder; Europe and most of the rest of the world measure the cylinder volume as the internal volume of the cylinder: e.g. United States 19 cubic feet = European 3 liter at 180 bar.

The below are example cylinder sizes and do not constitute an industry standard.

Cyl. size Diameter × height (inches), includes 5.5 inches for valve and cap Nominal tare weight (lb), includes 4.5 lb for valve and cap Water capacity (lb) Internal volume @ 70 °F (21 °C), 1 atm liters (cubic feet) U.S. DOT Specs
2HP 9 × 51 187 43.3 (1.53) 3AA3500
K 9.25 × 60 135 110 49.9 (1.76) 3AA2400
A 9 × 51 115 96 43.8 (1.55) 3AA2015
B 8.5 × 31 60 37.9 17.2 (0.61) 3AA2015
C 6 × 24 27 15.2 6.88 (0.24) 3AA2015
D 4 × 18 12 4.9 2.24 (0.08) 3AA2015
AL 8 × 53 52 64.8 29.5 (1.04) 3AL2015
BL 7.25 × 39 33 34.6 15.7 (0.55) 3AL2216
CL 6.9 × 21 19 13 5.9 (0.21) 3AL2216
XL 14.5 × 50 75 238 108 (3.83) 4BA240
SSB 8 × 37 95 41.6 18.9 (0.67) 3A1800
10S 4 × 31 21 8.3 3.8 (0.13) 3A1800
LB 2 × 15 4 1 0.44 (0.016) 3E1800
XF 12 × 46 180 60.9 (2.15) 8AL
XG 15 × 56 149 278 126.3 (4.46) 4AA480
XM 10 × 49 90 120 54.3 (1.92) 3A480
XP 10 × 55 55 124 55.7 (1.98) 4BA300
QT 3 × 14 (includes 4.5 inches for valve) 2.5 (includes 1.5 lb for valve) 2.0 0.900 (0.0318) 4B-240ET
LP5 12.25 × 18.25 18.5 47.7 21.68 (0.76) 4BW240
Medical E 4 × 26 (excludes valve and cap) 14 (excludes valve and cap) 4.5 (0.16) 3AA2015

Common cylinder valves

With the exception of lecture bottles, gas cylinders are often outfitted with non interchangeable fittings. These are specified by the Compressed Gas Association (CGA) in the United States and by the British Standards Institution in the UK. Incompatible connectors help to prevent accidental mis-connections of gasses (e.g. a hydrogen cylinder does not fit an oxygen supply line which would end in catastrophic failure). In the British Standard system, this is effected by fitting flammable gas cylinders with left-hand threaded valves (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).[9]

Gas type CGA Valve Outlet (USA) BS Valve Outlet (UK)[9]
Acetylene 510 2,4
Air, Breathing 346 3
Air, Industrial 590 3
Argon 580,718,680(3500 psi),677(6000 psi) 3
Butane 510 4
Carbon dioxide 320,716 8
Carbon monoxide 350,724 4
Chlorine 660,728 6
Helium 580,718,680(3500psi) 3
Hydrogen 350,724,695(3500psi) 4
Methane 350 4
Neon 580,718 3
Nitrogen 580,718,680(3500 psi),677(6000 psi) 3
Nitrous oxide 726,712 13
Oxygen 540,714 3
Oxygen mixtures (>23.5%) 296 Other guides apply
Propane 510 4
Xenon 580,718 3

See also

Wikimedia Commons has media related to Gas cylinders.

References

External links

This article is issued from Wikipedia - version of the Sunday, January 31, 2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.