Self-contained breathing apparatus

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A self-contained breathing apparatus, or SCBA, sometimes referred to as a compressed air breathing apparatus (CABA), or simply breathing apparatus (BA), is a device worn by rescue workers, firefighters, and others to provide breathable air in an "Immediately Dangerous to Life or Health" atmosphere (IDLH). When not used underwater, they are sometimes called industrial breathing sets. The term "self-contained" means that the breathing set is not dependent on a remote supply (e.g., through a long hose). If designed for use under water, it is called SCUBA (self-contained underwater breathing apparatus).

An SCBA typically has three main components: a high-pressure tank (e.g., 2,216 to 4,500 psi (15,280 to 31,030 kPa), about 150 to 300 atmospheres), a pressure regulator, and an inhalation connection (mouthpiece, mouth mask or face mask), connected together and mounted to a carrying frame.^[1]

A self-contained breathing apparatus may fall into two different categories. These are open circuit and closed circuit.^[2]

Closed-circuit SCBAs

Siebe Gorman Savox in a coal mining museum

The closed-circuit type filters, supplements, and recirculates exhaled gas: see rebreather for more information. It is used when a longer-duration supply of breathing gas is needed, such as in mine rescue and in long tunnels, and going through passages too narrow for a big open-circuit air cylinder. Before open-circuit SCBA's were developed, most industrial breathing sets were rebreathers, such as the Siebe Gorman Proto, Siebe Gorman Savox, or Siebe Gorman Salvus. An example of modern rebreather SCBAs would be the SEFA. Rebreathers used underwater have the advantage of not releasing tell-tale bubbles, making it more difficult to detect divers involved in covert operations (see frogman).

Open-circuit

For underwater open-circuit breathing sets see Scuba set#Types.

Open-circuit industrial breathing sets are filled with filtered, compressed air, rather than pure oxygen. Typical open-circuit systems have two regulators; a first stage to reduce the pressure of air to allow it to be carried to the mask, and a second stage regulator to reduce it even further to a level just above standard atmospheric pressure. This air is then fed to the mask via either a demand valve (activating only on inhalation) or a continuous positive pressure valve (providing constant airflow to the mask).

An open-circuit rescue or firefighter SCBA has a fullface mask, regulator, air cylinder, cylinder pressure gauge, and a harness with adjustable shoulder straps and waist belt which lets it be worn on the back. The air cylinder usually comes in one of three standard sizes: 4 liter, 6 liter, or 6.8 liter. The duration of the cylinder can be calculated with this formula: volume (in liters) * pressure (in bars) / 40 - 10 in minutes (the 10 is subtracted to provide a safety margin), so a 6-liter cylinder, of 300bar, is 6 X 300 / 40 - 10 = 35 minutes working duration. The relative fitness, and especially the level of exertion of the wearer, often results in variations of the actual usable time that the SCBA can provide air, often reducing the working time by 25% to 50%.

Air cylinders are made of aluminium, steel, or of a composite construction (usually carbon-fiber wrapped.) The composite cylinders are the lightest in weight and are therefore preferred by fire departments (UK: fire and rescue services previously called fire brigades), but they also have the shortest lifespan and must be taken out of service after 15 years. Air cylinders must be hydrostatically tested every 5 years. During extended operations, empty air cylinders can be quickly replaced with fresh ones and then refilled from larger tanks in a cascade storage system or from an air compressor brought to the scene.

Fullface masks

The fullface masks of breathing apparatus designed for use out of water are sometimes designed in a way that makes them unsuitable for scuba diving, although some may allow emergency very shallow submersion:

• The seal at the edge of the mask is a wide tube with thin, flexible walls running around the edge of the mask, full of air at atmospheric pressure. On the surface it pushes against the edges of the wearer's face, causing a tight seal despite small variations in head shape. At more than a few feet depth pressure (underwater or in a caisson) this tube collapses, destroying the seal and making the mask leak.
• Curved window which underwater would severely distort the image by refraction.

The mask can have a big fullface window, or small eye windows.^{[citation needed]}

The mask might have a small orinasal breathing mask inside, reducing breathing deadspace.^{[citation needed]}

• • Link to image and description of a negative-pressure fullface mask^{[dead link]}

The mask can also incorporate a two-way radio communicator.^{[citation needed]}

• See also Full face diving mask

Some old industrial rebreathers (e.g., the Siebe Gorman Proto) had a mouthpiece and attached noseclip instead.^{[citation needed]}

Positive pressure (preventing inward leaking)

Open circuit SCBAs utilize either "positive pressure" or "negative pressure" operation.

• A "negative pressure" SCBA may be used with a type of fullface mask which could be used as a gasmask (with a filter canister on the facepiece's air inlet) or with an open-circuit breathing set connected to the air inlet. Air is delivered to the wearer when she breathes in, or in other words, reduces the pressure in the mask to less than outside pressure, hence the name "negative pressure". The limitations of this are obvious, as any leaks in the device or the interface between the mask and the face of the wearer (caused for example by small face skin wrinkles) would reduce the protection offered.
• "Positive pressure" SCBA addresses this limitation. By careful design, the device is set to maintain a small pressure in excess of the surrounding air pressure inside the facepiece. Although the pressure drops when the wearer breathes in, the device always maintains a higher pressure inside the mask than outside of the mask. Thus, even if the mask leaks slightly, there is a flow of clean air out of the device, automatically preventing inward leakage under most circumstances. Although the performance of both types of SCBA may be similar under optimum conditions, this "fail safe" behaviour makes a "Positive pressure" SCBA preferable for most applications. As there is usually no air usage penalty in providing positive pressure, the older "Negative pressure" type is, in most cases, an obsolete configuration and is only seen with older equipment. However some users refuse to use this technology as in case of a damage or loss of the facepiece the air will be released uncontrolled. The leakage rate can be so high that a fully charged SCBA will be drained in less than three minutes, a problem that does not happen with "negative pressure" SCBA systems.

Types of use

There are two major application areas for SCBA: fire fighting; and industrial use.^{[citation needed]} A third use now coming into practice is medical; for example, the American National Institutes of Health prescribe use of SCBAs for medical staff during treatment of ebola.

For fire fighting, the design emphasis is on heat and flame resistance above cost. SCBA designed for fire fighting tend to be expensive because of the exotic materials used to provide the flame resistance and to a lesser extent, to reduce the weight penalty on the fire fighter. In addition, modern firefighting SCBAs incorporate a PASS device (Personal Alert Safety System) or an ADSU (Automatic Distress Signal Unit) into their design. These units emit distinctive high pitched alarm tones to help locate firefighters in distress by automatically activating if movement is not sensed for a certain length of time (typically between 15 and 30 seconds), also allowing for manual activation should the need arise. In firefighting use, the layout of this breathing set should not interfere with ability to carry a rescued person over the firefighter's shoulders.

The other major application is for industrial users of various types. Historically, mining was an important area, and in Europe this is still reflected by limitations on use in the construction of SCBAs of metals that can cause sparks. Other important users are petrochemical, chemical, and nuclear industries. The design emphasis for industrial users depends on the precise application and extends from the bottom end which is cost critical, to the most severe environments where the SCBA is one part of an integrated protective environment which includes gas tight suits for whole body protection and ease of decontamination. Industrial users will often be supplied with air via an air line, and only carry compressed air for escape or decontamination purposes.

Safety specifications

In the United States and Canada, SCBAs used in firefighting must meet guidelines established by the National Fire Protection Association, NFPA Standard 1981. If an SCBA is labeled as "1981 NFPA compliant", it is designed for firefighting. The current version of the standard was published in 2007. These standards are revised every five years. Similarly, the National Institute for Occupational Safety and Health (NIOSH) has a certification program for SCBA that are intended to be used in chemical, biological, radiological, and nuclear (CBRN) environments. See NIOSH Approved SCBAs.

Any SCBA supplied for use in Europe must comply with the requirements of the Personal Protective Equipment Directive (89/686/EEC). In practice this usually means that the SCBA must comply with the requirements of the European Standard EN 137 : 2006. This includes detailed requirements for the performance of the SCBA, the marking required, and the information to be provided to the user. Two classes of SCBA are recognised, Type 1 for industrial use and Type 2 for fire fighting. Any SCBA conforming to this standard will have been verified to reliably operate and protect the user from -30 °C to +60 °C under a wide range of severe simulated operational conditions.

The Royal Australian Navy uses the Open Circuit Compressed Air Breathing Apparatus (OCCABA), a backpack-style, positive pressure breathing apparatus, for fire-fighting roles.

Effect of temperature on pressure gauge readings

The pressure gauge's indicated gas pressure changes with ambient temperature. As temperature decreases, the pressure inside the cylinder decreases. The relationship between the temperature and the pressure of a gas is estimated by using the formula PV = nRT. (See Universal gas constant.) What is particularly important to understand from the formula is that the temperature is in kelvins, not degrees Fahrenheit. Consider the freezing point of water at 32 degrees Fahrenheit (0 degrees Celsius, 273.15 kelvin) and compare it to 96 °F (35.6 °C or 308.71K; normal human body temperature is 37 °C). While 96 is arithmetically three times 32, the difference in temperature from a scientific point of view is not threefold. Instead of comparing 32 °F to 96 °F, temperatures of 273.15K and 308.71K should be compared.^[3] The actual scientifically valid change in temperature from 32 to 96 °F (0 to 36 °C) is by a factor of 1.13 (308.71K/273.15K), not 3. If an air cylinder is pressurized to 4,500 psi at 96 °F and later the temperature drops to 32 °F, the pressure gauge will indicate 4,000 psi (4,500/1.13). Stated differently, a drop in temperature of 10 degrees Fahrenheit (5.5 degrees Celsius) causes a pressure decrease of about 82 psi. Failure to accurately account for the effect of temperature on pressure readings can result in underfilled air bottles, which in turn could lead to a firefighter running out of air prematurely.

Types

Among the leading manufacturers of SCBA for the North American fire service are:^{[citation needed]}

• Scott Health and Safety
• Avon-ISI
• MSA Fire
• Draeger
• Survivair
• Interspiro
• ISI (International Safety Instruments).

Among the leading manufacturers of SCBA for the European fire service and industrial safety:

• Honeywell Safety Products
• Scott Health and Safety
• Spasciani
• Interspiro
• MSA
• Draeger

Siebe Gorman produced these makes of open-circuit SCBA units:

• Airmaster MK 1 (blue back plate)
• Airmaster MK 2 (chrome plated back plate)
• Firefighter
• Specials for the armed forces

Also known as

In Australia, different firefighting agencies refer to SCBA by different acronyms in general terms. For example:

• In South Australia both the Country Fire Service and the Metropolitan Fire Service refer to SCBA as "CABA" or Compressed Air Breathing Apparatus during training and in the field they refer to SCBA as simply BA or Breathing Apparatus. The New South Wales Rural Fire Service follow the same principles as South Australia
• The Fire and Emergency Services Authority of Western Australia Brigades, New South Wales Fire Brigades and Queensland Fire and Rescue Service call it BA, Breathing Apparatus.

All these initials mean the same type of open-circuit equipment.

In New Zealand, SCBA is generally referred to by New Zealand Fire Service personnel as BA, Breathing Apparatus.

Unofficial names include "air pack" "air tank" or simply "pack" mostly used in firefighting as in a firefighter "packing up".

See also

• Glossary of firefighting terms
• Oxygen mask
• PASS device (Personal Alert Safety System), also known as ADSU (Automatic Distress Signal Unit) - which is often integrated into an SCBA system
• SCUBA - Self-Contained Underwater Breathing Apparatus
• STAS - short-term air supply for self-rescue

Notes

References

• IFSTA (2008). "Essentials of Fire Fighting and Fire Department Operations 5th Edition"

External links

Wikimedia Commons has media related to Self-contained breathing apparatus.

• These references are related to NIOSH-certified SCBA with chemical, biological, radiological, and nuclear (CBRN) protection (SC/PD/CBRN):
  • CBRN SCBA interim user guide and list of approved CBRN SCBA
  • CBRN SCBA standard development and publication leading to the first NIOSH-Certified SCBA with CBRN protection offered by the US DHHS/CDC/NIOSH/NPPTL on June 3, 2002
  • Image of 2-cylinder open-circuit SCBA
• Literature
  • Study of the physiological effects of wearing breathing apparatus by RG Love and others. Institute of Occupational Medicine Research Report TM/94/05