Diving cylinder

A diving cylinder, scuba tank or diving tank is a gas cylinder used to store and transport high pressure breathing gas as a component of a scuba set. It provides gas to the scuba diver through the demand valve of a diving regulator.

Diving cylinders typically have an internal volume of between 3 and 18 litres (0.11 and 0.64 cu ft) and a maximum pressure rating from 200 to 300 bars (2,900 to 4,400 psi). The internal cylinder volume is also expressed as "water capacity" - the volume of water which could be contained by the cylinder. When pressurised, a cylinder carries a volume of gas greater than its water capacity because gas is compressible. 600 litres (21 cu ft) of gas at atmospheric pressure is compressed into a 3-litre cylinder when it is filled to 200 bar. Cylinders also come in smaller sizes, such as 0.2, 1.5 and 2 litres, however these are not generally used for breathing, instead being used for purposes such as Surface Marker Buoy, drysuit and buoyancy compensator inflation.

Divers use gas cylinders above water for many purposes including storage of gases for oxygen first aid treatment of diving disorders and as part of storage "banks" for diving air compressor stations. They are also used for many purposes not connected to diving. For these applications they are not diving cylinders.

The term "diving cylinder" tends to be used by gas equipment engineers, manufacturers, support professionals, and divers speaking British English. "Scuba tank" or "diving tank" is more often used colloquially by non-professionals and native speakers of American English. The term "oxygen tank" is commonly used by non-divers when referring to diving cylinders; however, this is a misnomer. These cylinders typically contain (atmospheric) breathing air, or an oxygen-enriched air mix. They rarely contain pure oxygen, except when used for rebreather diving, shallow decompression stops in technical diving or for oxygen therapy. Breathing oxygen at depths greater than 40 feet (12 m) can result in oxygen toxicity, a highly dangerous condition that can trigger seizures and thus lead to drowning.

Contents

Parts of a cylinder

The diving cylinder consists of several parts:

The pressure vessel

The pressure vessel is normally made of cold-extruded aluminium or forged steel. An especially common cylinder available at tropical dive resorts is an "aluminium-80" which is an aluminium cylinder with an internal volume of 0.39 cubic feet (11 L) rated to hold about 80 cubic feet (2,300 L) of atmospheric pressure gas at its rated pressure of 3,000 psi (210 bar). Aluminium cylinders are also often used where divers carry many cylinders, such as in technical diving in warm water where the dive suit does not provide much buoyancy, because the greater buoyancy of aluminium cylinders reduces the extra buoyancy the diver would need to achieve neutral buoyancy. They are also preferred when carried as "sidemount" or "sling" cylinders as the near neutral buoyancy allows them to hang comfotably along the sides of the diver's body, without disturbing trim, and can be handed off to another diver with a minimal effect on buoyancy. In cold water diving, where a diver wearing a highly buoyant thermally insulating dive suit has a large excess of buoyancy, steel cylinders are often used because they are denser than aluminium cylinders. Kevlar wrapped composite cylinders are used in fire fighting breathing apparatus and oxygen first aid equipment, but are rarely used for diving, due to their high positive buoyancy.

The aluminium alloys used for diving cylinders are 6061 and 6351. 6351 alloy is subject to sustained stress cracking and cylinders manufatured of this alloy should be periodically eddy current tested according to national legislation and manufacturer's recommendations.

The neck of the cylinder is internally threaded to fit a cylinder valve. There are several standards for neck threads , these include:

The shoulder of the cylinder carries stamp markings providing required information about the cylinder [5]

The cylinder valve

Optional accessories

Types of cylinder valve

Manifolds

A cylinder manifold is a tube which connects two cylinders together so that the contents of both can be supplied to one or more regulators. There are three commonly used configurations of manifold:

A relatively uncommon manifold system is a connection which screws directly into the neck threads of both cylinders, and has a single valve to release gas to a connector for a regulator. These manifolds can include a reserve valve, either in the main valve or at one cylinder. This system is mainly of historical interest.[6]

Cylinder bands

Cylinder bands are straps, usually of stainless steel, which are used to clamp two cylinders together as a twin set. The cylinders may be manifolded or independent. It is usual to use a cylinder band near the top of the cylinder, just below the shoulders, and one lower down. The standard distance beween centrelines for bolting to a backplate is 11 inches (280 mm).

Cylinder boot

A cylinder boot is a hard rubber or plastic cover which fits over the base of a diving cylinder to protect the paint from abrasion and impact, to protect the surface the cylinder stands on from impact with the cylinder, and in the case of round bottomed cylinders, to allow the cylinder to stand upright on its base.

Cylinder net

A cylinder net is a tubular net which is stretched over a cylinder and tied on at top and bottom. The function is to protect the paintwork from scratching, and on booted cylinders it also helps drain the surface between the boot and cylinder, which reduces corrosion problems under the boot. Mesh size is usually about 6 millimetres (0.24 in). Some divers will not use boots or nets as they can snag more easily than a bare cylinder and constitute an entrapment hazard in some enironments sich as caves and the interior of wrecks.

Cylinder handle

A cylinder handle may be fitted, usually clamped to the neck, to conveniently carry the cylinder. This can also increase the risk of snagging in an enclosed environment.

Cylinder capacity

There are two commonly used conventions for describing the capacity of a diving cylinder. One is based on the internal volume of the cylinder. The other is based on nominal volume of gas stored.

Internal volume

The internal volume is commonly quoted in most countries. It can be measured easily by filling the cylinder with fresh water. This has resulted in the term 'water capacity' (WC) which is often marked on the cylinder shoulder. It's almost always expressed as a volume but sometimes as weight of the water. Fresh water has a density close to one kilogram per litre so the numerical values will be similar.

The usual units are:

Nominal volume of gas stored

The nominal volume of gas stored is commonly quoted in the USA. It's a measure of the volume of gas that can be released from the cylinder at atmospheric pressure. Terms used for the volume include 'free gas' or 'free gas equivalent'. It depends on the internal volume and the working pressure of a cylinder. If the working pressure is higher, the cylinder will store more gas for the same volume.

The working pressure is not neccessarily the same as the actual pressure used. Some cylinders are permitted to exceed the nominal working pressure by 10% and this is indicated by a '+' symbol. This extra pressure allowance is dependant on the cylinder passing the appropriate periodical hydrostatic test and is not generally valid for US cylinders exported to countries with differing standards.

For example, common Al80 cylinder is an aluminum cylinder which has a nominal 'free gas' volume of 80 cubic feet (2,300 L) when pressurised to 3,000 pounds per square inch (210 bar). It has an internal volume of 10.94 litres (0.386 cu ft).

Types of pillar valve

There are three types of pillar valve in general use for Scuba cylinders containing air:

Adaptors are available to allow connection of DIN regulators to yoke cylinder valves (A-clamp or yoke adaptor), and to connect yoke regulators to DIN cylinder valves. (plug adaptors and block adaptors)

There are also cylinder valves for Scuba cylinders containing gases other than air:

Applications and configurations of diving cylinders

Divers may carry one cylinder or multiples, depending on the requirements of the dive. Where diving takes place in low risk areas, where the diver may safely make a free ascent, or where a buddy is available to provide an alternative air supply in an emergency, recreational divers usually carry only one cylinder. An example of this type is coral reef diving where it is possible to do an interesting dive without going deep or needing decompression. Where diving risks are higher, for example where the visibility is low or when recreational divers do deeper or decompression diving, divers routinely carry more than one gas source. An example of this type is north European diving where the temperature is often less than 15 °C (60 °F) and visibility less than 10 m (33 ft) and many interesting dive sites are shipwrecks in deeper water on the sea bed.

Diving cylinders may serve different purposes. One or two cylinders may be used as a primary breathing source which is intended to be breathed from for most of the dive. A smaller cylinder carried in addition to a larger cylinder is called a "pony bottle". A cylinder to be used purely as an independent safety reserve is called a "bailout bottle". A pony bottle is commonly used as a bailout bottle, but this would depend on the time required to surface.

Divers doing technical diving often carry different gases, each in a separate cylinder, for each phase of the dive:

Rebreathers may use internal cylinders:

Rebreathers may also be supplied from "off-board" cylinders, which are not permanently plumbed into the rebreather, but connected to it by a flexible hose and coupling and usually carried side slung. Rebreather divers also often carry a bailout cylinder if the internal diluent cylinder is too small for safe use for bailout.

For safety, divers sometimes carry an additional redundant aqualung (a second scuba tank and scuba valve) to mitigate out-of-air emergencies should the primary breathing source fail. For most common recreational diving (for example dives of 20 m (66 ft) to examine typical coral reefs), such extra equipment is usually not needed or used. This extra cylinder is known as a bail-out cylinder, and may be carried in several ways, and can be any size that can hold enough gas to get the diver safely back to the surface.

Open-circuit

For open-circuit divers, there are several options for the combined cylinder and regulator system:

Closed-circuit

Diving cylinders are used in closed-circuit diving in two roles:

Gas calculations

Breathing gas endurance

A commonly asked question is 'what is the underwater duration of a particular cylinder?'

There are two parts to this problem:

The cylinder's capacity to store gas

Two features of the cylinder determine its gas carrying capacity:

To calculate the quantity of gas:

Volume of gas at atmospheric pressure = (cylinder volume) x (cylinder pressure) / (atmospheric pressure)

So a 12 litre cylinder at 232 bar would hold almost 2,784 litres (98.3 cu ft) of air at atmospheric pressure.

In the US and in many diving resorts you might find aluminum cylinders with an internal capacity of 0.39 cubic feet (11 L) filled to 3,000 psi (210 bar); Taking air pressure as 14.7 psi, this gives 0.39 x 3000 / 14.7 = 80 ft³ These cylinders would be described by US convention as "80 cubic foot cylinders", (the common "aluminum-80") as the US normally refers to cylinder capacity as free-air equivalent at its working pressure, rather than the internal volume of the cylinder, which is the measure commonly used in metric countries.

Up to 200 bar the ideal gas law remains valid and the relationship between the pressure, size of the cylinder and gas contained in the cylinder is linear; at higher pressures there is proportionally less gas in the cylinder. A 3 litre, 300 bar cylinder can only carry up to 810 litres (29 cu ft) of atmospheric pressure gas and not the 900 litres expected from the ideal gas law.

Diver gas consumption

There are three factors at work here:

In the UK, a working breathing rate of 40 litres per minute is used for commercial diving, whilst a figure of 50 litres per minute is used for emergencies. (The Association of Diving Contractors)

To calculate the quantity of gas consumed:

gas consumed = breathing rate × time × ambient pressure

Thus, a diver with a breathing rate of 20 L/min will consume at 30 meters (4 bar) the equivalent of 80 L/min at 1 bar (e.g. at the surface). If this diver only had a 10 litre 200 bar cylinder to breathe from, the gas in the cylinder would be exhausted after 2000/80 = 25 minutes.

Keeping this in mind, it is not hard to see why technical divers who do long deep dives require multiple cylinders or rebreathers.

Breathing time

For metric users:

Absolute maximum breathing time (BT) can be calculated as

BT = available air / rate of consumption

which, using the ideal gas law, is

BT = (available cylinder pressure × cylinder volume) / (rate of air consumption at surface) × (ambient pressure)

This may be written as

(1) BT = \frac {(CP-AP)*CS} {BR*AP}

with

BT = Breathing Time (in minutes)
CP = Cylinder Pressure (in bars)
CS = Cylinder Size (in liters)
AP = Ambient Pressure (in bars)
BR = Breathing Rate (in liters per minute)

AP is deducted from CP, as the quantity of air represented by AP can in practice not be used for breathing by the diver as she needs it to overcome the pressure of the water (AP) when inhaling.

However, in normal diving usage, a reserve is always factored in. The reserve is a proportion of the cylinder pressure which a diver will not expect to use other than in case of emergency. The reserve may be a quarter or a third of the cylinder pressure or it may be a fixed pressure, common examples are 50 bar and 500 psi. The formula above is then modified to give the usable breathing time as

(2) BT = \frac {(CP-RP)*CS} {BR*AP}

where RP is the reserve pressure.

Ambient pressure (AP) is the surrounding water pressure at a given depth and is made up of the sum of the water pressure and the air pressure at the surface. It is calculated as

(3) AP = \frac {D*g*\rho} {100000} + atmospheric pressure

with

D = Depth (in meters)
g = Standard gravity (in meters per second squared)
ρ = Water Density (in kg per cube meter)

In practical terms, this formula can be approximated by

(4) AP = \frac {D} {10} %2B 1

For example (using the first formula (1) for absolute maximum breathing time), a diver at a depth of 15 meters in water with an average density of 1020 kg / m³ (typical salt water), who breathes at a rate of 20 liters per minute, using a dive cylinder of 18 liters pressurized at 200 bars, can breathe for a period of 72 minutes before the cylinder and supply line pressure has fallen so low as to prevent her from inhaling. In most open circuit scuba systems this happens quite suddenly, from a normal breath to the next abnormal breath, a breath which typically cannot be fully drawn. (There is never any difficulty exhaling). In such circumstances there remains air under pressure in the cylinder, but the diver is unable to breathe it. Some of it can be breathed if the diver ascends, and even without ascent, in some systems a bit of air from the cylinder is available to inflate BCD devices even after it no longer has pressure enough to actuate the mouthpiece valve.

Using the same conditions and a reserve of 50 bar, the formula (2) for usable breathing time is worked thus:

Ambient pressure = water pressure + atmospheric pressure = 15/10 + 1 = 2.5 bar
Usable air = usable pressure * cylinder capacity = (200-50) * 18 = 2700 liters
Rate of consumption = surface air consumption * ambient pressure = 20 * 2.5 = 50 liters/min
Usable breathing time = 2700 liters / 50 liters/min = 54 min

This would give a dive time of 54 min at 15 m before reaching the reserve of 50 bar.

Reserves

It is strongly recommended that a portion of the usable gas of the cylinder be held aside as a safety reserve. The reserve is designed to provide gas for longer than planned decompression stops or to provide time to resolve underwater emergencies.

The size of the reserve depends upon the risks involved during the dive. A deep or decompression dive warrants a greater reserve than a shallow or a no stop dive. In recreational diving for example, it is recommended that the diver plans to surface with a reserve remaining in the cylinder of 500 psi, 50 bar or 25% of the initial capacity, depending of the teaching of the diver training organisation. This is because recreational divers practicing within "no-decompression" limits can normally make a direct ascent in an emergency. On technical dives where a direct ascent is either impossible (due to overhead obstructions) or dangerous (due to the requirement to make decompression stops), divers plan larger margins of safety using the rule of thirds: one third of the gas supply is planned for the outward journey, one third is for the return journey and one third is a safety reserve.

Some training agencies teach the concept of minimum gas and provide a simple calculation that allows a diver to work out an acceptable reserve to get two divers in an emergency to the surface. See DIR diving for more information.

Weight of gas consumed

The loss of the weight of the gas taken from the cylinder makes the cylinder and diver more buoyant. This can be a problem if the diver is unable to remain neutrally buoyant towards the end of the dive because most of the gas has been breathed from the cylinder.

Table showing the buoyancy of diving cylinders in water when empty and full of air.

Assumes 1 litre of air at atmospheric pressure and 10°C weighs 1.25g.[9]

Cylinder Air Weight on land Buoyancy
Material Volume Pressure Volume Weight Empty Full Empty Full
  (litre) (bar) (litre) (kg) (kg) (kg) (kg) (kg)
Steel 12 200 2400 3.0 16.0 19.0 -1.2 -4.3
15 200 3000 3.8 20.0 23.8 -1.4 -5.2
16 (XS 130) 230 3680 4.7 19.5 23.9 -0.9 -5.3
2x7 200 2800 3.5 19.5 23.0 -2.0 -5.6
8 300 2400 3.0 13.0 16.0 -3.5 -6.5
10 300 3000 3.8 17.0 20.8 -4.0 -7.8
2x4 300 2400 3.0 15.0 18.0 -4.0 -7.0
2x6 300 3600 4.6 21.0 25.6 -5.0 -9.6
Aluminium 9 (AL 63) 203 1826 2.3 12.2 13.5 +1.8 -0.5
11 (AL 80) 203 2247 2.8 14.4 17.2 +1.8 -1.1
13 (AL100) 203 2584 3.2 17.1 20.3 +1.4 -1.7

Filling tanks

Tanks should only be filled with air from diving air compressors or with other breathing gases using gas blending techniques.[10] Both these services should be provided by reliable suppliers such as dive shops. Breathing industrial compressed gases can be lethal because the high pressure increases the effect of any impurities in them.

Special precautions need to be taken with gases other than air:

Contaminated air at depth can be fatal. Common contaminants are: carbon monoxide a by-product of combustion, carbon dioxide a product of metabolism, oil and lubricants from the compressor.[10]

Keeping the cylinder slightly pressurized at all times reduces the possibility of contaminating the inside of the cylinder with corrosive agents, such as sea water, or toxic material, such as oils, poisonous gases, fungi or bacteria.

The blast caused by a sudden release of the gas pressure inside a diving cylinder makes them very dangerous if mismanaged. The greatest risk of explosion exists at filling time and comes from thinning of the walls of the pressure vessel due to corrosion. Another cause of failure is damage or corrosion of the threads and neck of the cylinder where the pillar valve is screwed in. Aluminium cylinders have been observed occasionally to fail explosively, fragmenting the cylinder wall. Steel cylinders usually remain mostly intact, and tend to fail at the neck.

Manufacture and testing

Most countries require tanks to be checked on a regular basis, see gas cylinder. This usually consists of an internal visual inspection and a hydrostatic test.

A hydrostatic test involves pressurising the cylinder to its test pressure and measuring its volume before and after the test. A permanent increase in volume above the tolerated level means the cylinder fails the test and should be permanently removed from service.

When a cylinder is manufactured, its specification, including Working Pressure, Test Pressure, Data of Manufacture, Capacity and Weight are stamped on the cylinder. [13]

After a cylinder passes the test, the test date, (or the test expiry date in some countries such as Germany), is punched into the shoulder of the tank for easy verification at fill time. Note: this is a European requirement. There is an international standard for the stamp format [13]

Most compressor operators check these details before filling the cylinder and may refuse to fill non-standard or out-of-test cylinders. Note: this is a European requirement, a requirement of the USA DOT, and a South African requirement.

Safety

Before any cylinder is filled, verification of testing dates and a visual examination for external damage and corrosion are required by law in some jurisdictions[12], and are prudent even if not legally required at other places.

Before use the user should verify the contents of the cylinder and check the function of the cylinder valve. Pressure and gas mixture are critical information for the diver, and the valve should open freely without sticking or leaks from the spindle seals. Sniffing air bled from a cylinder may also reveal unpleasant surprises better left on land than discovered in the water.

Cylinders should not be left standing unattended unless secured[12] so that they can not fall in reasonable foreseeable circumstances as an impact could damage the cylinder valve mechanism, and cocievably fracture the valve at the neck threads. This is more likely with taper thread valves, and when it happens the energy of the compressed gas is released within a second, and can accelerate the cylinder to speeds which can caues severe injury or damage to the surroundings.

A neatly assembled setup, with regulators, gauges, and delicate computers butterflied inside the BCD, or clipped where they will not be walked on, and stowed under the boat bench or secured to a rack, is the practice of a competent diver.

As the scuba set is a life support system, one should not touch a fellow diver's gear, even to move it, without their knowledge and approval.

Full cylinders should not be exposed to temperatures above 65°C[12] and cylinders should not be filled to pressures greater than the developed pressure appropriate to the certified working pressure of the cylinder except by a test station performing a hydrostatic test[12].

Cylinders should be clearly labelled with their current contents. A generic "Nitrox" or "Trimix" label will alert the user that the contents may not be air, and must be analysed before use. In some parts of the world a label is required specifically indicating that the contents are air, and in other places a colour code without additional labels indicates by default that the contents are air.[12]

Cases of lateral epicondylitis are also reported from the handling of diving cylinders.[14]

Gas cylinder colour coding and labeling

European Union

In the European Union gas cylinders may be colour coded according to EN 1098-3. The "shoulder" is the top of the cylinder close to the pillar valve. For mixed gases, the colours can be either bands or "quarters".

Note: As of the end of 2006, the quartered parts is obsolete, and new cylinders are now with the band, and the old system is repainted.

In the European Union breathing gas cylinders must be labeled with their contents. The label should state the type of breathing gas contained by the cylinder.[15]

South Africa

Scuba cylinders are reqired to comply with the colors and markings specified in SANS 10019:2006.[12]

Worldwide

In many recreational diving settings where air and nitrox are the widely used gases, nitrox cylinders are colour-coded with a green stripe on yellow bottom. The normal colour of aluminium diving cylinders is their natural silver. Steel diving cylinders are often painted, to reduce corrosion, mainly yellow or white to increase visibility. In some industrial cylinder identification colour tables, yellow shoulders means chlorine and more generally within Europe it refers to cylinders with Toxic and/or Corrosive contents; but this is of no significance in SCUBA since gas fittings would not be compatible.

Cylinders that are subject to gas blending with pure oxygen also need an "oxygen service certificate" label indicating they have been prepared for use in an oxygen-rich environment.

References

  1. ^ International standard ISO 11116-1, First edition 1999
  2. ^ a b c International standard ISO 13341, Transportable gas cylinders - Fitting of valves to gas cylinders, First edition 1997.
  3. ^ British Standard 2779
  4. ^ a b Catalina cylinders, Technical support document, Valving of Scuba (air) cylinders, Nov 2005.
  5. ^ International Standard ISO 13769, Gas cylinders - Stamp markings. First edition 2002
  6. ^ a b c d Fred M. Roberts (1963); Basic Scuba: Self contained underwater breathing apparatus: Its operation, maintenance and use, Second edition, Van Nostrand Reinholdt, New York
  7. ^ "Spare Air". Submersible Systems. 2009-07-07. http://www.spareair.com/. Retrieved 2009-09-19. 
  8. ^ NOAA Diving Manual, 4th Edition CD-ROM prepared and distributed by the National Technical Information Service (NTIS)in partnership with NOAA and Best Publishing Company
  9. ^ http://www.gasdiving.co.uk/pages/misc/kit/cylinder.htm Gas Diving
  10. ^ a b Millar IL; Mouldey PG (2008). "Compressed breathing air – the potential for evil from within.". Diving and Hyperbaric Medicine. (South Pacific Underwater Medicine Society) 38: 145–51. http://archive.rubicon-foundation.org/7964. Retrieved 2009-02-28. 
  11. ^ Henderson, NC; Berry, WE; Eiber, RJ; Frink, DW (1970). "Investigation of scuba cylinder corrosion, Phase 1.". National Underwater Accident Data Center Technical Report Number 1 (University of Rhode Island). http://archive.rubicon-foundation.org/9293. Retrieved 2011-09-24. 
  12. ^ a b c d e f g South African National Standard SANS 10019:2008
  13. ^ a b International standard ISO 13769, 1st Ed.2002-07-01 Gas cylinders - Stamp marking
  14. ^ Barr, Lori L; Martin, Larry R (1991). "Tank carrier’s lateral epicondylitis: Case reports and a new cause for an old entity". Journal of the South Pacific Underwater Medicine Society 21 (1). http://archive.rubicon-foundation.org/9432. Retrieved 2011-11-21. 
  15. ^ "Identifying Cylinders". BOC UK. 2010. http://www.boconline.co.uk/health/gas_safety/identifying_gas_cylinders/identifying_cylinders.asp. Retrieved 13 November 2011. 

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