Bottled gas

There are four cases: either the substance remains a gas at standard temperature but increased pressure, the substance liquefies at standard temperature but increased pressure, the substance is dissolved in a solvent, or the substance is liquefied at reduced temperature and increased pressure. In the last case the bottle is constructed with an inner and outer shell separated by a vacuum (dewar flask) so that the low temperature can be maintained by evaporative cooling. Case I The substance remains a gas at standard temperature and increased pressure, its critical temperature being below standard temperature. Examples include: • air • argon • fluorine • helium • hydrogen • krypton • nitrogen • oxygen Case II The substance liquefies at standard temperature but increased pressure. Examples include: • ammonia • butane • carbon dioxide (also packaged as a cryogenic gas, Case IV) • chlorine • nitrous oxide • propane • sulfur dioxide Case III The substance is dissolved at standard temperature in a solvent. Examples include: • carbon dioxide in the form of a soft drink • sulfur trioxide in the form of fuming sulfuric acid • nitrogen dioxide in the form of red-fuming nitric acid • hydrogen chloride in the form of muriatic acid • Note: these four are most often found in containers other than metal bottles, and at low pressure, e.g. . • acetylene • Note: Acetylene cylinders contain an inert packing material, which may be agamassan, and are filled with a solvent such as acetone or dimethylformamide. The acetylene is pumped into the cylinder and it dissolves in the solvent. When the cylinder is opened the acetylene comes back out of solution, much like a carbonated beverage bubbles when opened. This is a workaround to acetylene's propensity to explode when pressurized above 200 kPa or liquified. Case IV The substance is liquefied at reduced temperature and increased pressure. These are also referred to as cryogenic gases. Examples include: • liquid nitrogen (LN2) • liquid hydrogen (LH2) • liquid oxygen (LOX) • carbon dioxide (also packaged as a liquefied gas, Case II) :Note: cryogenic gases are typically equipped with some type of 'bleed' device to prevent overpressure from rupturing the bottle and to allow evaporative cooling to continue. ==Expansion and volume==

The general rule is that one unit volume of liquid will expand to approximately 800 unit volumes of gas at standard temperature and pressure with some variation due to intermolecular force and molecule size compared to an ideal gas. Normal high pressure gas cylinders will hold gas at pressures from . An ideal gas pressurised to 200 bar in a cylinder would contain 200 times as much as the volume of the cylinder at atmospheric pressure, but real gases will contain less than that by a few percent. At higher pressures, the shortfall is greater. ==Special handling considerations==

Because the contents are under high 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. In the United States, the Compressed Gas Association (CGA) sells a number of booklets and pamphlets on safe handling and use of bottled gases. (Members of the CGA can get the pamphlets for free.) The European Industrial Gases Association and the British Compressed Gases Association provide similar facilities in Europe and the United Kingdom. ==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 using by one of several Trade names, or specifically as butane or propane depending on the required heat output. ==Colour coding==

Different countries have different gas colour codes but attempts are being made to standardise the colours of cylinder shoulders: • Colours of cylinders for Medical gases are covered by an International Organization for Standardization (ISO) standard, ISO 32; but not all countries use this standard. • Within Europe gas cylinders colours are being standardised according to EN 1089-3, the standard colours applying to the cylinder shoulder only; i.e., the top of the cylinder close to the pillar valve. • In the United States, colour-coding is not regulated by law. The user should not rely on the colour of a cylinder to indicate what it contains. The label or decal should always be checked for product identification. European cylinder colours The colours below are specific shades, defined in the European Standard in terms of RAL coordinates. The requirements are based on a combination of a few named gases, otherwise on the primary hazard associated with the gas contents: Specific gases Based on gas properties Gas mixtures, mostly for diving Diving cylinders are left unpainted (for aluminium), or painted to prevent corrosion (for steel), often in bright colors, most often fluorescent yellow, to increase visibility. This should not be confused with industrial gases, where a yellow shoulder means chlorine. ==See also==