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Breathing gas

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Breathing gas
Trimix scuba cylinder label
UsesGas used for human respiration
Related itemsAir, Heliox, Nitrox, Oxygen, Trimix, Gas blending for scuba diving, Diving cylinder, Scuba set, Rebreather
Sailors check breathing devices at sea.

A breathing gas is a mixture of gaseous chemical elements and compounds used for respiration. Air is the most common and only natural breathing gas, but other mixtures of gases, or pure oxygen, are also used in breathing equipment and enclosed habitats. Oxygen is the essential component for any breathing gas. Breathing gases for hyperbaric use have been developed to improve on the performance of ordinary air by reducing the risk of decompression sickness, reducing the duration of decompression, reducing nitrogen narcosis or allowing safer deep diving.

Description

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A breathing gas is a mixture of gaseous chemical elements and compounds used for respiration. Air is the most common and only natural breathing gas. Other mixtures of gases, or pure oxygen, are also used in breathing equipment and enclosed habitats such as scuba equipment, surface supplied diving equipment, recompression chambers, high-altitude mountaineering, high-flying aircraft, submarines, space suits, spacecraft, medical life support and first aid equipment, and anaesthetic machines.[1][2][3]

Contents

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Oxygen is the essential component for any breathing gas, at a partial pressure of between roughly 0.16 and 1.60 bar at the ambient pressure, occasionally lower for high altitude mountaineering, or higher for hyperbaric oxygen treatment. The oxygen is usually the only metabolically active component unless the gas is an anaesthetic mixture. Some of the oxygen in the breathing gas is consumed by the metabolic processes, and the inert components are unchanged, and serve mainly to dilute the oxygen to an appropriate concentration, and are therefore also known as diluent gases.

Most breathing gases therefore are a mixture of oxygen and one or more metabolically inert gases.[1][3] Breathing gases for hyperbaric use have been developed to improve on the performance of ordinary air by reducing the risk of decompression sickness, reducing the duration of decompression, reducing nitrogen narcosis or allowing safer deep diving.[1][3] The techniques used to fill diving cylinders with gases other than air are called gas blending.[4][5]

Breathing gases for use at ambient pressures below normal atmospheric pressure are usually pure oxygen or air enriched with oxygen to provide sufficient oxygen to maintain life and consciousness, or to allow higher levels of exertion than would be possible using air. It is common to provide the additional oxygen as a pure gas added to the breathing air at inhalation, or though a life-support system.

For diving and other hyperbaric use

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Exterior view of a closed bell, showing the side door to the left, with a 50-litre oxygen cylinder and two 50-litre heliox cylinders mounted to the frame to the side of the door.
A closed bell used for saturation diving showing emergency gas supply cylinders

A safe breathing gas for hyperbaric use has four essential features:

  • It must contain sufficient oxygen to support life, consciousness and work rate of the breather.[1][2][3]
  • It must not contain harmful contaminants. Carbon monoxide and carbon dioxide are common poisons which may contaminate breathing gases. There are many other possibilities.[1][2][3]
  • It must not become toxic when being breathed at high pressure such as when underwater. Oxygen and nitrogen are examples of gases that become toxic under pressure.[1][2][3]
  • It must not be too dense to breathe. Work of breathing increases with density and viscosity. Maximum ventilation drops by about 50% when density is equivalent to air at 30 msw, and carbon dioxide levels rise unacceptably for moderate exercise with a gas density exceeding 6 g/litre. Breathing gas density of 10 g/litre or more may cause runaway hypercapnia even at very low work levels, with potentially fatal effects.[6]

These common diving breathing gases are used:

  • Air is a mixture of 21% oxygen, 78% nitrogen, and approximately 1% other trace gases, primarily argon; to simplify calculations this last 1% is usually treated as if it were nitrogen. Being freely available and simple to use, it is the most common diving gas.[1][2][3] As its nitrogen component causes nitrogen narcosis, it is considered to have a safe depth limit of about 40 metres (130 feet) for most divers, although the maximum operating depth (MOD) of air taking an allowable oxygen partial pressure of 1,6 bar is 66.2 metres (217 feet).[1][3][7] Breathing air is air meeting specified standards for contaminants.
  • Pure oxygen is mainly used to speed the shallow decompression stops at the end of a military, commercial, or technical dive. Risk of acute oxygen toxicity increases rapidly at pressures greater than 6 metres sea water.[1][2][3][7] It was much used in frogmen's rebreathers, and is still used by attack swimmers.[2][7][8][9]
  • Nitrox is a mixture of oxygen and air, and generally refers to mixtures which are more than 21% oxygen. It can be used as a tool to accelerate in-water decompression stops or to decrease the risk of decompression sickness and thus prolong a dive (a common misconception is that the diver can go deeper, this is not true owing to a shallower maximum operating depth than on conventional air).[1][2][3][10]
  • Trimix is a mixture of oxygen, nitrogen and helium and is often used at depth in technical diving and commercial diving instead of air to reduce nitrogen narcosis and to avoid the dangers of oxygen toxicity.[1][2][3]
  • Heliox is a mixture of oxygen and helium and is often used in the deep phase of a commercial deep dive to eliminate nitrogen narcosis.[1][2][3][11] Heliox is the standard mixture type for deep offshore saturation diving.[12]
  • Heliair is a form of trimix that is easily blended from helium and air without using pure oxygen. It always has a 21:79 ratio of oxygen to nitrogen; the balance of the mix is helium.[3][13]
  • Hydreliox is a mixture of oxygen, helium, and hydrogen and is used for dives below 130 metres in commercial diving.[1][3][11][14][15]
  • Hydrox, a gas mixture of hydrogen and oxygen, is used as a breathing gas in very deep diving.[1][3][11][14][16]
  • Neox (also called neonox) is a mixture of oxygen and neon sometimes employed in deep commercial diving. It is rarely used due to its cost. Also, DCS symptoms produced by neon ("neox bends") have a poor reputation, being widely reported to be more severe than those produced by an exactly equivalent dive-table and mix with helium.[1][3][11][17]
Commonly accepted breathing gas container colour coding in the offshore diving industry.[18]
Gas Symbol Typical shoulder colours Cylinder shoulder Quad upper frame/
frame valve end
Medical oxygen O2
Illustration of cylinder shoulder painted white for medical oxygen
White White
Oxygen and helium mixtures
(Heliox)
O2/He Illustration of cylinder shoulder painted in brown and white quarters Illustration of cylinder shoulder painted in brown (lower) and white (upper) bands Brown and white
quarters or bands
Brown and white
short (8 inches (20 cm))
alternating bands
Oxygen, helium and nitrogen
mixtures (Trimix)
O2/He/N2 Illustration of cylinder shoulder painted in brown, black and white sixths for a mixture of helium, nitrogen and oxygen. Illustration of cylinder shoulder painted in brown, black and white bands for a mixture of helium, nitrogen and oxygen Black, white and brown
quarters or bands
Black, white and brown
short (8 inches (20 cm))
alternating bands
Oxygen and nitrogen mixtures
(Nitrox) including air
N2/O2 Illustration of cylinder shoulder painted in black and white quarters for a mixture of oxygen and nitrogen. Illustration of cylinder shoulder painted in black (lower) and white (upper) bands for a mixture of oxygen and nitrogen. Black and white
quarters or bands
Black and white
short (8 inches (20 cm))
alternating bands

Breathing air

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Breathing air is atmospheric air with a standard of purity suitable for human breathing in the specified application. For hyperbaric use, the partial pressure of contaminants is increased in proportion to the absolute pressure, and must be limited to a safe composition for the depth or pressure range in which it is to be used.

Classification by oxygen fraction

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Breathing gases for diving are classified by oxygen fraction. The boundaries set by authorities may differ slightly, as the effects vary gradually with concentration and between people, and are not accurately predictable.[citation needed]

Normoxic
where the oxygen content does not differ greatly from that of air and allows continuous safe use at atmospheric pressure.[19]
Hyperoxic, or oxygen enriched
where the oxygen content exceeds atmospheric levels, generally to a level where there is some measurable physiological effect over long term use, and sometimes requiring special procedures for handling due to increased fire hazard. The associated risks are oxygen toxicity at depth and fire, particularly in the breathing apparatus.[citation needed]
Hypoxic
where the oxygen content is less than that of air, generally to the extent that there is a significant risk of measurable physiological effect over the short term. The immediate risk is usually hypoxic incapacitation at or near the surface.[20]

Individual component gases

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Breathing gases for diving are mixed from a small number of component gases which provide special characteristics to the mixture which are not available from atmospheric air.

Oxygen

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Oxygen (O2) must be present in every breathing gas.[1][2][3] This is because it is essential to the human body's metabolic process, which sustains life. The human body cannot store oxygen for later use as it does with food. If the body is deprived of oxygen for more than a few minutes, unconsciousness and death result. The tissues and organs within the body (notably the heart and brain) are damaged if deprived of oxygen for much longer than four minutes.

Filling a diving cylinder with pure oxygen costs around five times more than filling it with compressed air. As oxygen supports combustion and causes rust in diving cylinders, it should be handled with caution when gas blending.[4][5]

Oxygen has historically been obtained by fractional distillation of liquid air, but is increasingly obtained by non-cryogenic technologies such as pressure swing adsorption (PSA) and vacuum swing adsorption (VSA) technologies.[21]

The fraction of the oxygen component of a breathing gas mixture is sometimes used when naming the mix:

  • hypoxic mixes, strictly, contain less than 21% oxygen, although often a boundary of 16% is used, and are designed only to be breathed at depth as a "bottom gas" where the higher pressure increases the partial pressure of oxygen to a safe level.[1][2][3] Trimix, Heliox and Heliair are gas blends commonly used for hypoxic mixes and are used in professional and technical diving as deep breathing gases.[1][3] A minimum operating depth may be assigned to a hypoxic gas mixture, based on the depth at which the partial pressure is equal to the minimum oxygen partial pressure acceptable to the person or organisation using the gas.
  • normoxic mixes have the same proportion of oxygen as air, 21%.[1][3] The maximum operating depth of a normoxic mix could be as shallow as 47 metres (154 feet). Trimix with between 17% and 21% oxygen is often described as normoxic because it contains a high enough proportion of oxygen to be safe to breathe at the surface.
  • hyperoxic mixes have more than 21% oxygen. Enriched Air Nitrox (EANx) is a typical hyperoxic breathing gas.[1][3][10] Hyperoxic mixtures, when compared to air, cause oxygen toxicity at shallower depths but can be used to shorten decompression stops by drawing dissolved inert gases out of the body more quickly.[7][10]

The fraction of the oxygen determines the greatest depth at which the mixture can safely be used to avoid oxygen toxicity. This depth is called the maximum operating depth.[1][3][7][10]

The concentration of oxygen in a gas mix depends on the fraction and the pressure of the mixture. It is expressed by the partial pressure of oxygen (PO2).[1][3][7][10]

The partial pressure of any component gas in a mixture is calculated as:

partial pressure = total absolute pressure × volume fraction of gas component

For the oxygen component,

PO2 = P × FO2

where:

PO2 = partial pressure of oxygen
P = total pressure
FO2 = volume fraction of oxygen content

The minimum safe partial pressure of oxygen in a breathing gas is commonly held to be 16 kPa (0.16 bar). Below this partial pressure the diver may be at risk of unconsciousness and death due to hypoxia, depending on factors including individual physiology and level of exertion. When a hypoxic mix is breathed in shallow water it may not have a high enough PO2 to keep the diver conscious. For this reason normoxic or hyperoxic "travel gases" are used at medium depth between the "bottom" and "decompression" phases of the dive.

The maximum safe PO2 in a breathing gas depends on exposure time, the level of exercise and the security of the breathing equipment being used. It is typically between 100 kPa (1 bar) and 160 kPa (1.6 bar); for dives of less than three hours it is commonly considered to be 140 kPa (1.4 bar), although the U.S. Navy has been known to authorize dives with a PO2 of as much as 180 kPa (1.8 bar).[1][2][3][7][10] At high PO2 or longer exposures, the diver risks oxygen toxicity which may result in a seizure.[1][2] Each breathing gas has a maximum operating depth that is determined by its oxygen content.[1][2][3][7][10] For therapeutic recompression and hyperbaric oxygen therapy partial pressures of 2.8 bar are commonly used in the chamber, but there is no risk of drowning if the occupant loses consciousness.[2] For longer periods such as in saturation diving, 0.4 bar can be tolerated over several weeks.

Oxygen analysers are used to measure the oxygen partial pressure in the gas mix.[4]

Divox is breathing grade oxygen labelled for diving use. In the Netherlands, pure oxygen for breathing purposes is regarded as medicinal as opposed to industrial oxygen, such as that used in welding, and is only available on medical prescription. The diving industry registered Divox as a trademark for breathing grade oxygen to circumvent the strict rules concerning medicinal oxygen thus making it easier for (recreational) scuba divers to obtain oxygen for blending their breathing gas. In most countries, there is no difference in purity in medical oxygen and industrial oxygen, as they are produced by exactly the same methods and manufacturers, but labeled and filled differently. The chief difference between them is that the record-keeping trail is much more extensive for medical oxygen, to more easily identify the exact manufacturing trail of a "lot" or batch of oxygen, in case problems with its purity are discovered. Aviation grade oxygen is similar to medical oxygen, but may have a lower moisture content.[4]

Diluent gases

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Gases which have no metabolic function in the breathing gas are used to dilute the gas, and are therefore classed as diluent gases. Some of them have a reversible narcotic effect at high partial pressure, and must therefore be limited to avoid excessive narcotic effects at the maximum pressure at which they are intended to be breathed. Diluent gases also affect the density of the gas mixture and thereby the work of breathing.

Nitrogen
[edit]

Nitrogen (N2) is a diatomic gas and the main component of air, the cheapest and most common breathing gas used for diving. It causes nitrogen narcosis in the diver, so its use is limited to shallower dives. Nitrogen can cause decompression sickness.[1][2][3][22]

Equivalent air depth is used to estimate the decompression requirements of a nitrox (oxygen/nitrogen) mixture. Equivalent narcotic depth is used to estimate the narcotic potency of trimix (oxygen/helium/nitrogen mixture). Many divers find that the level of narcosis caused by a 30 m (100 ft) dive, whilst breathing air, is a comfortable maximum.[1][2][3][23][24]

Nitrogen in a gas mix is almost always obtained by adding air to the mix.

Helium
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2% Heliox storage quad. 2% oxygen by volume is sufficient at pressures exceeding 90 msw.

Helium (He) is an inert gas that is less narcotic than nitrogen at equivalent pressure (in fact there is no evidence for any narcosis from helium at all), and it has a much lower density, so it is more suitable for deeper dives than nitrogen.[1][3] Helium is equally able to cause decompression sickness. At high pressures, helium also causes high-pressure nervous syndrome, which is a central nervous system irritation syndrome which is in some ways opposite to narcosis.[1][2][3][25]

Helium mixture fills are considerably more expensive than air fills due to the cost of helium and the cost of mixing and compressing the mix.[citation needed]

Helium is not suitable for dry suit inflation owing to its poor thermal insulation properties – compared to air, which is regarded as a reasonable insulator, helium has six times the thermal conductivity.[26] Helium's low molecular weight (monatomic MW=4, compared with diatomic nitrogen MW=28) increases the timbre of the breather's voice, which may impede communication.[1][3][27] This is because the speed of sound is faster in a lower molecular weight gas, which increases the resonance frequency of the vocal cords.[1][27] Helium leaks from damaged or faulty valves more readily than other gases because atoms of helium are smaller allowing them to pass through smaller gaps in seals.

Helium is found in significant amounts only in natural gas, from which it is extracted at low temperatures by fractional distillation.

Neon
[edit]

Neon (Ne) is an inert gas sometimes used in deep commercial diving but is very expensive.[1][3][11][17] Like helium, it is less narcotic than nitrogen, but unlike helium, it does not distort the diver's voice. Compared to helium, neon has superior thermal insulating properties.[28]

Hydrogen
[edit]

Hydrogen (H2) has been used in deep diving gas mixes but is very explosive when mixed with more than about 4 to 5% oxygen (such as the oxygen found in breathing gas).[1][3][11][14] This limits use of hydrogen to deep dives and imposes complicated protocols to ensure that excess oxygen is cleared from the breathing equipment before breathing hydrogen starts. Like helium, it raises the timbre of the diver's voice. The hydrogen-oxygen mix when used as a diving gas is sometimes referred to as Hydrox. Mixtures containing both hydrogen and helium as diluents are termed Hydreliox.

Unwelcome components of breathing gases for diving

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Many gases are not suitable for use in diving breathing gases.[5][29] Here is an incomplete list of gases commonly present in a diving environment:

Argon

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Argon (Ar) is an inert gas that is more narcotic than nitrogen, so is not generally suitable as a diving breathing gas.[30] Argox is used for decompression research.[1][3][31][32] It is sometimes used for dry suit inflation by divers whose primary breathing gas is helium-based, because of argon's good thermal insulation properties. Argon is more expensive than air or oxygen, but considerably less expensive than helium. Argon is a component of natural air, and constitutes 0.934% by volume of the Earth's atmosphere.[33]

Carbon dioxide

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Carbon dioxide (CO2) is produced by the metabolism in the human body and can cause carbon dioxide poisoning.[29][34][35] When breathing gas is recycled in a rebreather or life support system, the carbon dioxide is removed by scrubbers before the gas is re-used.

Carbon monoxide

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Carbon monoxide (CO) is a highly toxic gas that competes with dioxygen for binding to hemoglobin, thereby preventing the blood from carrying oxygen (see carbon monoxide poisoning). It is typically produced by incomplete combustion.[1][2][5][29] Four common sources are:

  • Internal combustion engine exhaust gas containing CO in the air being drawn into a diving air compressor. CO in the intake air cannot be stopped by any filter. The exhausts of all internal combustion engines running on petroleum fuels contain some CO, and this is a particular problem on boats, where the intake of the compressor cannot be arbitrarily moved as far as desired from the engine and compressor exhausts.
  • Heating of lubricants inside the compressor may vaporize them sufficiently to be available to a compressor intake or intake system line.
  • In some cases hydrocarbon lubricating oil may be drawn into the compressor's cylinder directly through damaged or worn seals, and the oil may (and usually will) then undergo combustion, being ignited by the immense compression ratio and subsequent temperature rise. Since heavy oils don't burn well – especially when not atomized properly – incomplete combustion will result in carbon monoxide production.
  • A similar process is thought[by whom?][original research?] to potentially happen to any particulate material, which contains "organic" (carbon-containing) matter, especially in cylinders which are used for hyperoxic gas mixtures. If the compressor air filter(s) fail, ordinary dust will be introduced to the cylinder, which contains organic matter (since it usually contains humus). A more severe danger is that air particulates on boats and industrial areas, where cylinders are filled, often contain carbon-particulate combustion products (these are what makes a dirt rag black), and these represent a more severe CO danger when introduced into a cylinder.[citation needed]

Carbon monoxide is generally avoided as far as is reasonably practicable by positioning of the air intake in uncontaminated air, filtration of particulates from the intake air, use of suitable compressor design and appropriate lubricants, and ensuring that running temperatures are not excessive. Where the residual risk is excessive, a hopcalite catalyst can be used in the high pressure filter to convert carbon monoxide into carbon dioxide, which is far less toxic.

Hydrocarbons

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Hydrocarbons (CxHy) are present in compressor lubricants and fuels. They can enter diving cylinders as a result of contamination, leaks,[clarification needed] or due to incomplete combustion near the air intake.[2][4][5][29][36]

  • They can act as a fuel in combustion increasing the risk of explosion, especially in high-oxygen gas mixtures.
  • Inhaling oil mist can damage the lungs and ultimately cause the lungs to degenerate with severe lipid pneumonia[37] or emphysema.

Moisture content

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The process of compressing gas into a diving cylinder removes moisture from the gas.[5][29] This is good for corrosion prevention in the cylinder but means that the diver inhales very dry gas. The dry gas extracts moisture from the diver's lungs while underwater contributing to dehydration, which is also thought to be a predisposing risk factor of decompression sickness. It is also uncomfortable, causing a dry mouth and throat and making the diver thirsty. This problem is reduced in rebreathers because the soda lime reaction, which removes carbon dioxide, also puts moisture back into the breathing gas,[9] and the relative humidity and temperature of exhaled gas is relatively high and there is a cumulative effect due to rebreathing.[38] In hot climates, open circuit diving can accelerate heat exhaustion because of dehydration. Another concern with regard to moisture content is the tendency of moisture to condense as the gas is decompressed while passing through the regulator; this coupled with the extreme reduction in temperature, also due to the decompression, can cause the moisture to solidify as ice. This icing up in a regulator can cause moving parts to seize and the regulator to fail or free flow. This is one of the reasons that scuba regulators are generally constructed from brass, and chrome plated (for protection). Brass, with its good thermal conductive properties, quickly conducts heat from the surrounding water to the cold, newly decompressed air, helping to prevent icing up.

Gas analysis

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Electro-galvanic fuel cell as used in a diving rebreather

Gas mixtures must generally be analysed either in process or after blending for quality control. This is particularly important for breathing gas mixtures where errors can affect the health and safety of the end user. It is difficult to detect most gases that are likely to be present in diving cylinders because they are colourless, odourless and tasteless. Electronic sensors exist for some gases, such as oxygen analysers, helium analyser, carbon monoxide detectors and carbon dioxide detectors.[2][4][5] Oxygen analysers are commonly found underwater in rebreathers.[9] Oxygen and helium analysers are often used on the surface during gas blending to determine the percentage of oxygen or helium in a breathing gas mix.[4] Chemical and other types of gas detection methods are not often used in recreational diving, but are used for periodic quality testing of compressed breathing air from diving air compressors.[4]

Breathing gas standards

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Standards for breathing gas quality are published by national and international organisations, and may be enforced in terms of legislation. In the UK, the Health and Safety Executive indicate that the requirements for breathing gases for divers are based on the BS EN 12021:2014. The specifications are listed for oxygen compatible air, nitrox mixtures produced by adding oxygen, removing nitrogen, or mixing nitrogen and oxygen, mixtures of helium and oxygen (heliox), mixtures of helium, nitrogen and oxygen (trimix), and pure oxygen, for both open circuit and reclaim systems, and for high pressure and low pressure supply (above and below 40 bar supply).[39]

Oxygen content is variable depending on the operating depth, but the tolerance depends on the gas fraction range, being ±0.25% for an oxygen fraction below 10% by volume, ±0.5% for a fraction between 10% and 20%, and ±1% for a fraction over 20%.[39]

Water content is limited by risks of icing of control valves, and corrosion of containment surfaces – higher humidity is not a physiological problem – and is generally a factor of dew point.[39]

Other specified contaminants are carbon dioxide, carbon monoxide, oil, and volatile hydrocarbons, which are limited by toxic effects. Other possible contaminants should be analysed based on risk assessment, and the required frequency of testing for contaminants is also based on risk assessment.[39]

In Australia breathing air quality is specified by Australian Standard 2299.1, Section 3.13 Breathing Gas Quality.[40]

Diving gas blending

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Air, oxygen and helium partial pressure gas blending system
Nitrox continuous blending compressor installation

Gas blending (or gas mixing) of breathing gases for diving is the filling of gas cylinders with non-air breathing gases.

Filling cylinders with a mixture of gases has dangers for both the filler and the diver. During filling there is a risk of fire due to use of oxygen and a risk of explosion due to the use of high-pressure gases. The composition of the mix must be safe for the depth and duration of the planned dive. If the concentration of oxygen is too lean the diver may lose consciousness due to hypoxia and if it is too rich the diver may develop oxygen toxicity. The concentration of inert gases, such as nitrogen and helium, are planned and checked to avoid nitrogen narcosis and decompression sickness.

Methods used include batch mixing by partial pressure or by mass fraction, and continuous blending processes. Completed blends are analysed for composition for the safety of the user. Gas blenders may be required by legislation to prove competence if filling for other persons.

Density

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Excessive density of a breathing gas can raise the work of breathing to intolerable levels, and can cause carbon dioxide retention at lower densities.[6] Helium is used as a component to reduce density as well as to reduce narcosis at depth. Like partial pressure, density of a mixture of gases is in proportion to the volumetric fraction of the component gases, and absolute pressure. The ideal gas laws are adequately precise for gases at respirable pressures.

The density of a gas mixture at a given temperature and pressure can be calculated as:

ρm = (ρ1 V1 + ρ2 V2 + .. + ρn Vn) / (V1 + V2 + ... + Vn)

where

ρm = density of the gas mixture
ρ1 ... ρn = density of each of the components
V1 ... Vn = partial volume of each of the component gases[41]

Since gas fraction Fi (volumetric fraction) of each gas can be expressed as Vi / (V1 + V2 + ... + Vn )

by substitution,

ρm = (ρ1 F1 + ρ2 F2 + .. + ρn Fn)

Hypobaric breathing gases

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Astronaut in an Orlan space suit, outside the International Space Station

Breathing gases for use at reduced ambient pressure are used for high altitude flight in unpressurised aircraft, in space flight, particularly in space suits, and for high altitude mountaineering. In all these cases, the primary consideration is providing an adequate partial pressure of oxygen. In some cases the breathing gas has oxygen added to make up a sufficient concentration, and in other cases the breathing gas may be pure or nearly pure oxygen. Closed circuit systems may be used to conserve the breathing gas, which may be in limited supply – in the case of mountaineering the user must carry the supplemental oxygen, and in space flight the cost of lifting mass into orbit is very high.

Medical breathing gases

[edit]

Medical use of breathing gases other than air include oxygen therapy and anesthesia applications.

Oxygen therapy

[edit]
A person wearing a simple face mask for oxygen therapy

Oxygen is required by people for normal cell metabolism.[42] Air is typically 21% oxygen by volume.[43] This is normally sufficient, but in some circumstances the oxygen supply to tissues is compromised.

Oxygen therapy, also known as supplemental oxygen, is the use of oxygen as a medical treatment.[44] This can include for low blood oxygen, carbon monoxide toxicity, cluster headaches, and to maintain enough oxygen while inhaled anesthetics are given.[45] Long term oxygen is often useful in people with chronically low oxygen such as from severe COPD or cystic fibrosis.[46][44] Oxygen can be given in a number of ways including nasal cannula, face mask, and inside a hyperbaric chamber.[47][48]

High concentrations of oxygen can cause oxygen toxicity such as lung damage or result in respiratory failure in those who are predisposed.[45][43] It can also dry out the nose and increase the risk of fires in those who smoke. The target oxygen saturation recommended depends on the condition being treated. In most conditions a saturation of 94-98% is recommended, while in those at risk of carbon dioxide retention saturations of 88-92% are preferred, and in those with carbon monoxide toxicity or cardiac arrest the saturation should be as high as possible.[44]

The use of oxygen in medicine become common around 1917.[49][50] It is on the World Health Organization's List of Essential Medicines.[51][52] The cost of home oxygen is about US$150 a month in Brazil and US$400 a month in the United States.[46] Home oxygen can be provided either by oxygen tanks or an oxygen concentrator.[44] Oxygen is believed to be the most common treatment given in hospitals in the developed world.[53][44]

Anaesthetic gases

[edit]
A vaporizer holds a liquid anesthetic and converts it to gas for inhalation (in this case sevoflurane)
An anaesthetic machine.
Bottles of sevoflurane, isoflurane, enflurane, and desflurane, the common fluorinated ether anaesthetics used in clinical practice. These agents are colour-coded for safety purposes. Note the special fitting for desflurane, which boils at room temperature.

The most common approach to general anaesthesia is through the use of inhaled general anesthetics. Each has its own potency which is correlated to its solubility in oil. This relationship exists because the drugs bind directly to cavities in proteins of the central nervous system,[clarification needed] although several theories of general anaesthetic action have been described. Inhalational anesthetics are thought to exact their effects on different parts of the central nervous system. For instance, the immobilizing effect of inhaled anesthetics results from an effect on the spinal cord whereas sedation, hypnosis and amnesia involve sites in the brain.[54]: 515 

An inhalational anaesthetic is a chemical compound possessing general anaesthetic properties that can be delivered via inhalation. Agents of significant contemporary clinical interest include volatile anaesthetic agents such as isoflurane, sevoflurane and desflurane, and anaesthetic gases such as nitrous oxide and xenon.

Administration

[edit]

Anaesthetic gases are administered by anaesthetists (a term which includes anaesthesiologists, nurse anaesthetists, and anaesthesiologist assistants) through an anaesthesia mask, laryngeal mask airway or tracheal tube connected to an anaesthetic vaporiser and an anaesthetic delivery system. The anaesthetic machine (UK English) or anesthesia machine (US English) or Boyle's machine is used to support the administration of anaesthesia. The most common type of anaesthetic machine in use in the developed world is the continuous-flow anaesthetic machine, which is designed to provide an accurate and continuous supply of medical gases (such as oxygen and nitrous oxide), mixed with an accurate concentration of anaesthetic vapour (such as isoflurane), and deliver this to the patient at a safe pressure and flow. Modern machines incorporate a ventilator, suction unit, and patient monitoring devices. Exhaled gas is passed through a scrubber to remove carbon dioxide, and the anaesthetic vapour and oxygen are replenished as required before the mixture is returned to the patient.[citation needed]

See also

[edit]

References

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  1. ^ a b c d e f g h i j k l m n o p q r s t u v w x y z aa ab ac ad ae af ag ah ai Brubakk, A. O.; T. S. Neuman (2003). Bennett and Elliott's physiology and medicine of diving (5th Rev ed.). United States: Saunders Ltd. p. 800. ISBN 978-0-7020-2571-6.
  2. ^ a b c d e f g h i j k l m n o p q r s t u v US Navy Diving Manual, 6th revision. United States: US Naval Sea Systems Command. 2006. Archived from the original on 2008-05-02. Retrieved 2008-08-29.
  3. ^ a b c d e f g h i j k l m n o p q r s t u v w x y z aa ab ac ad ae af ag Tech Diver. "Exotic Gases". Archived from the original on 14 September 2008. Retrieved 29 August 2008.
  4. ^ a b c d e f g h Harlow, V. (2002). Oxygen Hacker's Companion. Airspeed Press. ISBN 978-0-9678873-2-6.
  5. ^ a b c d e f g Millar, I.L.; Mouldey, P.G. (2008). "Compressed breathing air – the potential for evil from within". Diving and Hyperbaric Medicine. 38 (2). South Pacific Underwater Medicine Society: 145–51. PMID 22692708.
  6. ^ a b Mitchell, Simon (2015). "Respiratory failure in technical diving". www.youtube.com. DAN Southern Africa. Archived from the original on 2021-11-18. Retrieved 6 October 2021.
  7. ^ a b c d e f g h Acott, Chris (1999). "Oxygen toxicity: A brief history of oxygen in diving". South Pacific Underwater Medicine Society Journal. 29 (3). ISSN 0813-1988. OCLC 16986801.
  8. ^ Butler, F.K. (2004). "Closed-circuit oxygen diving in the U.S. Navy". Undersea Hyperb Med. 31 (1): 3–20. PMID 15233156.
  9. ^ a b c Richardson, Drew; Menduno, Michael; Shreeves, Karl, eds. (1996). Proceedings of Rebreather Forum 2.0. Diving Science and Technology Workshop. (Report). p. 286.
  10. ^ a b c d e f g Lang, M.A. (2001). DAN Nitrox Workshop Proceedings. Durham, NC: Divers Alert Network. p. 197.
  11. ^ a b c d e f Hamilton, Robert W. Jr.; Schreiner, Hans R., eds. (1975). Development of Decompression Procedures for Depths in Excess of 400 feet. Vol. 9th Undersea and Hyperbaric Medical Society Workshop. Bethesda, MD: Undersea and Hyperbaric Medical Society. p. 272.
  12. ^ Staff (February 2014). "IMCA International Code of Practice for Offshore Diving" (PDF). IMCA D 014 Rev. 2. London: International Marine Contractor's Association. Retrieved 22 July 2016.
  13. ^ Bowen, Curt. "Heliair: Poor man's mix" (PDF). DeepTech. Archived (PDF) from the original on 2016-05-13. Retrieved 2010-01-13.
  14. ^ a b c Fife, William P. (1979). "The use of Non-Explosive mixtures of hydrogen and oxygen for diving". Texas A&M University Sea Grant. TAMU-SG-79-201.
  15. ^ Rostain, J. C.; Gardette-Chauffour, M. C.; Lemaire, C.; Naquet, R. (1988). "Effects of a H2-He-O2 mixture on the HPNS up to 450 msw". Undersea Biomed. Res. 15 (4): 257–70. ISSN 0093-5387. OCLC 2068005. PMID 3212843.
  16. ^ Brauer, R.W., ed. (1985). Hydrogen as a Diving Gas. 33rd Undersea and Hyperbaric Medical Society Workshop. (Report). Undersea and Hyperbaric Medical Society. pp. 336 pages.
  17. ^ a b Hamilton, Robert W. Jr; Powell, Michael R.; Kenyon, David J.; Freitag, M. (1974). Neon Decompression (Report). Vol. CRL-T-797. Tarrytown Labs Ltd NY.
  18. ^ Staff (2007). Marking and Colour Coding of Gas Cylinders, Quads and Banks for Diving Applications IMCA D043 (PDF). London, UK: International Marine Contractors Association. Retrieved 1 February 2016.[permanent dead link]
  19. ^ "normoxic". Wiktionary. 4 April 2024. Archived from the original on 22 July 2024. Retrieved 22 July 2024.
  20. ^ Hausserman, Georgina (1 May 2017). "Breathing Gases". Divers Alert Network. Archived from the original on 2 December 2022. Retrieved 2 December 2022.
  21. ^ Universal Industrial Gases, Inc. (2003). "Non-Cryogenic Air Separation Processes". Archived from the original on 3 October 2018. Retrieved 29 August 2008.
  22. ^ Fowler, B.; Ackles, K.N.; Porlier, G. (1985). "Effects of inert gas narcosis on behavior—a critical review". Undersea Biomed. Res. 12 (4): 369–402. ISSN 0093-5387. OCLC 2068005. PMID 4082343.
  23. ^ Logan, J.A. (1961). An evaluation of the equivalent air depth theory. Technical Report NEDU-RR-01-61 (Report). United States Navy Experimental Diving Unit.
  24. ^ Berghage, T.E.; McCraken, T.M. (December 1979). "Equivalent air depth: fact or fiction". Undersea Biomed Res. 6 (4): 379–84. PMID 538866.
  25. ^ Hunger, W.L. Jr.; Bennett, P.B. (1974). "The causes, mechanisms and prevention of the high pressure nervous syndrome". Undersea Biomed. Res. 1 (1): 1–28. ISSN 0093-5387. OCLC 2068005. PMID 4619860.
  26. ^ "Thermal Conductivity of common Materials and Gases". Engineering Toolbox. Archived from the original on 2017-07-25. Retrieved 2017-02-18.
  27. ^ a b Ackerman, M.J.; Maitland, G (December 1975). "Calculation of the relative speed of sound in a gas mixture". Undersea Biomed Res. 2 (4): 305–10. PMID 1226588.
  28. ^ U.S. Navy Diving Manual (7 ed.). Washington, DC: U.S. Government. 1 December 2016. pp. 2–15.
  29. ^ a b c d e NAVSEA (2005). Cleaning and gas analysis for diving applications handbook. NAVSEA Technical Manual (Report). Vol. SS521-AK-HBK-010. NAVAL SEA SYSTEMS COMMAND.
  30. ^ Rahn, H.; Rokitka, M.A. (March 1976). "Narcotic potency of N2, A, and N2O evaluated by the physical performance of mouse colonies at simulated depths". Undersea Biomed Res. 3 (1): 25–34. PMID 1273982.
  31. ^ D'Aoust, B.G.; Stayton, L.; Smith, L.S. (September 1980). "Separation of basic parameters of decompression using fingerling salmon". Undersea Biomed Res. 7 (3): 199–209. PMID 7423658.
  32. ^ Pilmanis, A.A.; Balldin, U.I.; Webb, J.T.; Krause, K.M. (December 2003). "Staged decompression to 3.5 psi using argon-oxygen and 100% oxygen breathing mixtures". Aviat Space Environ Med. 74 (12): 1243–50. PMID 14692466.
  33. ^ "Argon (Ar)". Encyclopædia Britannica. Archived from the original on 4 August 2014. Retrieved 14 January 2014.
  34. ^ Lambertsen, C. J. (1971). Carbon Dioxide Tolerance and Toxicity (Report). Vol. IFEM Report No. 2-71. Philadelphia, PA: Environmental Biomedical Stress Data Center, Institute for Environmental Medicine, University of Pennsylvania Medical Center.
  35. ^ Glatte, H. A. Jr; Motsay, G. J.; Welch, B. E. (1967). "Carbon Dioxide Tolerance Studies". Brooks AFB, TX School of Aerospace Medicine Technical Report. SAM-TR-67-77.
  36. ^ Rosales, K.R.; Shoffstall, M.S.; Stoltzfus, J.M. (2007). Guide for Oxygen Compatibility Assessments on Oxygen Components and Systems (Report). Vol. NASA/TM-2007-213740. NASA, Johnson Space Center Technical Report.
  37. ^ Kizer, K.W.; Golden, JA (November 1987). "Lipoid pneumonitis in a commercial abalone diver". Undersea Biomedical Research. 14 (6): 545–52. PMID 3686744.
  38. ^ Mansour, Elias; Vishinkin, Rotem; Rihet, Stéphane; Saliba, Walaa; Fish, Falk; Sarfati, Patrice; Haick, Hossam (1 February 2020). "Measurement of temperature and relative humidity in exhaled breath". Sensors and Actuators B: Chemical. 304. Elsevier:Science Direct: 127371. doi:10.1016/j.snb.2019.127371. S2CID 209715398. Archived from the original on 16 October 2021. Retrieved 12 October 2021.
  39. ^ a b c d "Diver's breathing gas standard and the frequency of examination and tests: Diving Information Sheet No 9 (rev2)" (PDF). Health and Safety Executive. January 2018. Archived (PDF) from the original on 6 October 2018. Retrieved 6 October 2018.
  40. ^ Joint Technical Committee SF-017, Occupational Diving (21 December 2015). AS/NZS 2299.1:2015 Australian/New Zealand Standard Occupational diving operations, Part 1: Standard operational practice.
  41. ^ "Gas Mixture Properties: The Density of a Gas Mixture". www.engineeringtoolbox.com. Archived from the original on 8 October 2021. Retrieved 7 October 2021.
  42. ^ Peate, Ian; Wild, Karen; Nair, Muralitharan (2014). Nursing Practice: Knowledge and Care. John Wiley & Sons. p. 572. ISBN 9781118481363. Archived from the original on 2023-01-12. Retrieved 2020-05-27.
  43. ^ a b Martin, Lawrence (1997). Scuba Diving Explained: Questions and Answers on Physiology and Medical Aspects of Scuba Diving. Lawrence Martin. p. H-1. ISBN 9780941332569.
  44. ^ a b c d e British national formulary : BNF 69 (69 ed.). British Medical Association. 2015. pp. 217–218, 302. ISBN 9780857111562.
  45. ^ a b World Health Organization (2009). Stuart MC, Kouimtzi M, Hill SR (eds.). WHO Model Formulary 2008. World Health Organization. p. 20. hdl:10665/44053. ISBN 9789241547659.
  46. ^ a b Jamison, Dean T.; Breman, Joel G.; Measham, Anthony R.; Alleyne, George; Claeson, Mariam; Evans, David B.; Jha, Prabhat; Mills, Anne; Musgrove, Philip (2006). Disease Control Priorities in Developing Countries. World Bank Publications. p. 689. ISBN 9780821361801. Archived from the original on 2023-01-12. Retrieved 2020-05-27.
  47. ^ Macintosh, Michael; Moore, Tracey (1999). Caring for the Seriously Ill Patient 2E (2 ed.). CRC Press. p. 57. ISBN 9780340705827. Archived from the original on 2023-01-12. Retrieved 2020-05-27.
  48. ^ Dart, Richard C. (2004). Medical Toxicology. Lippincott Williams & Wilkins. pp. 217–219. ISBN 9780781728454. Archived from the original on 2023-01-12. Retrieved 2020-05-27.
  49. ^ Agasti, T. K. (2010). Textbook of Anesthesia for Postgraduates. JP Medical Ltd. p. 398. ISBN 9789380704944. Archived from the original on 2023-01-12. Retrieved 2020-05-27.
  50. ^ Rushman, Geoffrey B.; Davies, N. J. H.; Atkinson, Richard Stuart (1996). A Short History of Anaesthesia: The First 150 Years. Butterworth-Heinemann. p. 39. ISBN 9780750630665.
  51. ^ World Health Organization (2019). World Health Organization model list of essential medicines: 21st list 2019. Geneva: World Health Organization. hdl:10665/325771. WHO/MVP/EMP/IAU/2019.06. License: CC BY-NC-SA 3.0 IGO.
  52. ^ World Health Organization (2021). World Health Organization model list of essential medicines: 22nd list (2021). Geneva: World Health Organization. hdl:10665/345533. WHO/MHP/HPS/EML/2021.02.
  53. ^ Wyatt, Jonathan P.; Illingworth, Robin N.; Graham, Colin A.; Hogg, Kerstin; Robertson, Colin; Clancy, Michael (2012). Oxford Handbook of Emergency Medicine. Oxford, England: Oxford University Press. p. 95. ISBN 9780191016059. Archived from the original on 2023-01-12. Retrieved 2020-05-27.
  54. ^ Miller, Ronald D. (2010). Erikson, Lars I.; Fleisher, Lee A.; Wiener-Kronish, Jeanine P.; Young, William L (eds.). Miller's Anesthesia Seventh edition. Churchill Livingstone Elsevier. ISBN 978-0-443-06959-8.
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