Uncontrolled decompression

Uncontrolled decompression refers to an unplanned drop in the pressure of a sealed system, such as an aircraft cabin and typically results from human error, material fatigue, engineering failure or impact causing a pressure vessel to vent into its lower-pressure surroundings or fail to pressurize at all.

Such decompression may be classed as Explosive, Rapid or Slow:

• Explosive decompression (ED) is violent, the decompression being too fast for air to safely escape from the lungs.
• Rapid decompression, while still fast, is slow enough to allow the lungs to vent.
• Slow or gradual decompression occurs so slowly that it may not be sensed before hypoxia sets in.

Description

The term uncontrolled decompression here refers to the unplanned depressurisation of vessels that are occupied by people, for example an aircraft cabin at high altitude, a spacecraft, or a hyperbaric chamber. For the catastrophic failure of other pressure vessels used to contain gas, liquids, or reactants under pressure, the term explosion is more commonly used, or other specialised terms such as BLEVE may apply to particular situations.

Decompression can occur due to structural failure of the pressure vessel, or failure of the compression system itself.^[1][2] The speed and violence of the decompression is affected by the size of the pressure vessel, the differential pressure between the inside and outside of the vessel and the size of the leak hole.

The Federal Aviation Administration recognizes three distinct types of decompression events in aircraft:^[1][2]

• Explosive decompression
• Rapid decompression
• Gradual decompression

Explosive decompression

Explosive decompression occurs at a rate swifter than that at which air can escape from the lungs, typically in less than 0.1 to 0.5 seconds.^[1][3] The risk of lung trauma is very high, as is the danger from any unsecured objects that can become projectiles because of the explosive force, which may be likened to a bomb detonation.

After an explosive decompression within an aircraft, a heavy fog may immediately fill the interior as the relative humidity of cabin air rapidly changes as the air cools and condenses. Military pilots with oxygen masks have to pressure-breathe, whereby the lungs fill with air when relaxed, and effort has to be exerted to expel the air again.^[4]

Rapid decompression

Rapid decompression typically takes more than 0.1 to 0.5 seconds, allowing the lungs to decompress more quickly than the cabin.^[1][5] The risk of lung damage is still present, but significantly reduced compared with explosive decompression.

Slow decompression

Slow, or gradual, decompression occurs slowly enough to go unnoticed and might only be detected by instruments.^[1] This type of decompression may also come about from a failure to pressurize as an aircraft climbs to altitude. An example of this is the Helios Airways Flight 522 crash, in which the pilots failed to check the aircraft was pressurising automatically and then react to the warnings that the aircraft was depressurising.

Pressure vessel seals and testing

Seals in high-pressure vessels are also susceptible to explosive decompression; the O-rings or rubber gaskets used to seal pressurised pipelines tend to become saturated with high-pressure gases. If the pressure inside the vessel is suddenly released, then the gases within the rubber gasket may expand violently, causing blistering or explosion of the material. For this reason, it is common for military and industrial equipment to be subjected to an explosive decompression test before it is certified as safe for use.

Fallacies

Exposure to a vacuum causes the body to explode

This persistent myth is based on a failure to distinguish between two types of decompression: the first, from normal atmospheric pressure (one atmosphere) to a vacuum (zero atmospheres); the second, from an exceptionally high pressure (many atmospheres) to normal atmospheric pressure.

The first type, a sudden change from normal atmospheric pressure to a vacuum, is the more common. Research and experience in space exploration and high-altitude aviation have shown that while exposure to vacuum causes swelling, human skin is tough enough to withstand the drop of one atmosphere although the resulting hypoxia will cause unconsciousness after a few seconds.^[6][7] It is also possible that pulmonary barotrauma (lung rupture) will occur if the breath is forcibly held.

The second type is rare, since the only normal situation in which it can occur is during decompression after deep-sea diving. In fact, there is only a single well-documented occurrence: the Byford Dolphin incident, in which a catastrophic pressure drop of eight atmospheres caused massive, lethal, barotrauma, including the actual explosion of one diver. A similar but fictional death was shown in the film Licence to Kill, when a character's head explodes after his hyperbaric chamber is rapidly depressurized. Neither of these incidents would have been possible if the pressure drop had been only from normal atmosphere to a vacuum.

Bullets cause explosive decompression

Aircraft fuselages are designed with ribs to prevent tearing; the size of the hole is one of the factors that determines the speed of decompression, and a bullet hole is too small to cause rapid or explosive decompression.

A small hole will blow people out of a fuselage

The television program Mythbusters examined this belief informally using a pressurised aircraft and several scale tests. The Mythbusters approximations suggested that fuselage design does not allow this to happen.

Flight Attendant C.B. Lansing was blown from Aloha Airlines Flight 243 when a large section of cabin roof (about 18' x 25') detached; the report states she was swept overboard rather than sucked through the hole. The Air Crash Investigation documentary report on Flight 243 (season 3, 2005) notes that the 'tear line' construction was supposed to prevent such a large slab failure. Working from passenger accounts (including one report of the hostess' legs disappearing through the roof), forensic evidence including NTSB photographs, and stress calculations,^[8] experts speculated that the air hostess was sucked against the foot-square hole initially permitted by the tear strips, blocking it: this would have caused a 10 atmosphere pressure spike, hence the much greater material failure.^[9] One corrosion engineer takes the view that the tear straps could also have been defeated by the airstream impact through Lansing's body.^[10]

Decompression injuries

The following physical injuries may be associated with decompression incidents:

• Hypoxia is the most serious risk associated with decompression, especially as it may go undetected or incapacitate the aircrew.^{[11][12][13][14]}
• Barotrauma: an inability to equalize pressure in internal air spaces such as the middle ear or gastrointestinal tract, or more serious injury such as a burst lung.^[11]
• Decompression sickness.^{[11][12][15][16]}
• Physical trauma caused by the violence of explosive decompression, which can turn people and loose objects into projectiles.
• Altitude sickness
• Frostbite or hypothermia from exposure to freezing cold air at high altitude.

Notable decompression accidents and incidents

Decompression incidents are not uncommon on military and civilian aircraft, with approximately 40–50 rapid decompression events occurring worldwide annually.^[17] In the majority of cases the problem is relatively manageable for aircrew.^[11] Consequently where passengers and the aircraft do not suffer any ill-effects, the incidents tend not to be considered notable.^[11] Injuries resulting from decompression incidents are rare.^[11]

Decompression incidents do not occur solely in aircraft—the Byford Dolphin incident is an example of violent explosive decompression on an oil rig. A decompression event is an effect of a failure caused by another problem (such as an explosion or mid-air collision), but the decompression event may worsen the initial issue.

Event	Date	Pressure vessel	Event Type	Fatalities/number on board	Decompression Type	Cause
BOAC Flight 781	1954	de Havilland Comet	Accident	35/35	Explosive decompression	Metal fatigue
South African Airways Flight 201	1954	de Havilland Comet	Accident	21/21	Explosive decompression[18]	Metal fatigue
TWA Flight 2	1956	Lockheed L-1049 Super Constellation	Accident	70/70	Explosive decompression	Mid-air collision
1961 Yuba City B-52 crash	1961	B-52 Stratofortress	Accident	0/8	Gradual or rapid decompression	(Undetermined)
1965 spacesuit testing failure	1965	Space suit	Accident	0/1	Rapid decompression	Air leak in spacesuit[19]
Soyuz 11 re-entry	1971	Soyuz spacecraft	Accident	3/3	Gradual decompression	Damaged cabin ventilation valve
American Airlines Flight 96	1972	Douglas DC-10-10	Accident	0/67	Rapid decompression[20]	Cargo door failure
National Airlines Flight 27	1973	Douglas DC-10-10	Accident	1/116	Explosive decompression[21]	Crew tripping circuit breakers; engine overspeeding and disintegrating, pieces striking fuselage
Turkish Airlines Flight 981	1974	Douglas DC-10-10	Accident	346/346	Explosive decompression[22]	Cargo door failure
Tan Son Nhut C-5 accident	1975	C-5 Galaxy	Accident	155/330	Explosive decompression	Improper maintenance of rear doors, cargo door failure
Korean Air Lines Flight 902	1978	Boeing 707	Shootdown	2/109	Explosive decompression	Shootdown after straying into prohibited airspace over the Soviet Union.
Far Eastern Air Transport Flight 103	1981	Boeing 737	Accident	110/110	Explosive decompression	Corrosion
Byford Dolphin accident	1983	Diving bell	Accident	5/6	Explosive decompression	Human error, no fail-safe in the design
Korean Air Lines Flight 007	1983	Boeing 747-230B	Shootdown	269/269	Rapid decompression[23][24]	Intentionally fired air-to-air missile after aircraft strayed into prohibited airspace over the Soviet Union[25]
Japan Airlines Flight 123	1985	Boeing 747-SR46	Accident	520/524	Explosive decompression	Structural failure of rear pressure bulkhead
Air India Flight 182	1985	Boeing 747-237B	Terrorist bombing	329/329	Explosive decompression	Bomb explosion in cargo hold
Jordanian Airlines	1985	Lockheed L-1011 TriStar	Incident	0/?	Explosive decompression	Inflight fire which burnt though the rear pressure bulkhead[26]
Aloha Airlines Flight 243	1988	Boeing 737-297	Accident	1/95	Explosive decompression[27]	Metal fatigue
Pan Am Flight 103	1988	Boeing 747-121	Terrorist bombing	259/259	Explosive decompression	Bomb explosion in cargo hold
United Airlines Flight 811	1989	Boeing 747-122	Accident	9/355	Explosive decompression	Cargo door failure
UTA Flight 772	1989	McDonnell Douglas DC-10-30	Terrorist bombing	170/170	Explosive decompression	Bomb explosion in cargo hold
British Airways Flight 5390	1990	BAC One-Eleven	Incident	0/87	Rapid decompression[28]	Incorrect windscreen fasteners used
TWA Flight 800	1996	Boeing 747-131	Accident	230/230	Explosive decompression	Explosion in fuel tank
Progress M-34	1997	Spektr	Accident	0/?	Rapid decompression	Mid-air collision
Lionair Flight LN 602	1998	Antonov An-24RV	Shootdown	55/55	Rapid decompression	Probable MANPAD shootdown
South Dakota Learjet	1999	Learjet 35	Accident	6/6	Gradual or rapid decompression	(Undetermined)
Australia “Ghost Flight”	2000	Beechcraft Super King Air	Accident	8/8	Decompression suspected	(Undetermined)
Hainan Island incident	2001	Lockheed EP-3	Accident	0/24	Rapid decompression	Mid-air collision
TAM flight 9755	2001	Fokker 100	Accident	1/82	Rapid decompression	Window ruptured by shrapnel after engine failure[29]
China Airlines Flight 611	2002	Boeing 747-200B	Accident	225/225	Explosive decompression	Metal fatigue
Bashkirian Airlines Flight 2937	2002	Tupolev Tu-154M	Accident	69/69	Explosive decompression	Mid-air collision
Helios Airways Flight 522	2005	Boeing 737-31S	Accident	121/121	Gradual decompression	Pressurization system set to manual for the entire flight[30]
Alaska Airlines Flight 536	2005	McDonnell Douglas MD-80	Incident	0/140 + crew	Rapid decompression	Failure of operator to report collision involving a baggage loading cart at the departure gate
Qantas Flight 30	2008	Boeing 747-438	Incident	0/365	Rapid decompression[31]	Fuselage ruptured by explosion of an oxygen cylinder
Southwest Airlines Flight 2294	2009	Boeing 737-300	Incident	0/126 + 5 crew	Rapid decompression	Metal fatigue[32]
Southwest Airlines Flight 812	2011	Boeing 737-300	Incident	0/118 + crew	Rapid decompression	Metal fatigue[33]

Implications for aircraft design

Modern aircraft are specifically designed with longitudinal and circumferential reinforcing ribs in order to prevent localised damage from tearing the whole fuselage open during a decompression incident.^[34] However, decompression events have nevertheless proved fatal for aircraft in other ways. In 1974, explosive decompression onboard Turkish Airlines Flight 981 caused the floor to collapse, severing vital flight control cables in the process. The FAA issued an Airworthiness Directive the following year requiring manufacturers of wide-body aircraft to strengthen floors so that they could withstand the effects of in-flight decompression caused by an opening of up to 20 square feet (1.9 m²) in the lower deck cargo compartment.^[35] Manufacturers were able to comply with the Directive either by strengthening the floors and/or installing relief vents called "dado panels" between the passenger cabin and the cargo compartment.^[36]

Cabin doors are designed to make it almost impossible to lose pressurization through opening a cabin door in flight, either accidentally or intentionally. The plug door design ensures that when the pressure inside the cabin exceeds the pressure outside the doors are forced shut and will not open until the pressure is equalised. Cabin doors, including the emergency exits, but not all cargo doors, open inwards, or must first be pulled inwards and then rotated before they can be pushed out through the door frame because at least one dimension of the door is larger than the door frame.

Prior to 1996, approximately 6,000 large commercial transport airplanes were type certificated to fly up to 45,000 feet, without being required to meet special conditions related to flight at high altitude.^[37] In 1996, the FAA adopted Amendment 25-87, which imposed additional high-altitude cabin-pressure specifications, for new designs of aircraft types.^[38] For aircraft certificated to operate above 25,000 feet (FL 250), it "must be designed so that occupants will not be exposed to cabin pressure altitudes in excess of 15,000 feet after any probable failure condition in the pressurization system."^[39] In the event of a decompression which results from "any failure condition not shown to be extremely improbable," the aircraft must be designed so that occupants will not be exposed to a cabin altitude exceeding 25,000 feet for more than 2 minutes, nor exceeding an altitude of 40,000 feet at any time.^[39] In practice, that new FAR amendment imposes an operational ceiling of 40,000 feet on the majority of newly designed commercial aircraft.^{[40][41][Note 1]}

In 2004, Airbus successfully petitioned the FAA to allow cabin pressure of the A380 to reach 43,000 feet in the event of a decompression incident, and to exceed 40,000 feet for one minute. This special exemption allows that new aircraft to operate at a higher altitude than other newly-designed civilian aircraft, which have not yet been granted a similar exemption.^[40]

International standards

The Depressurization Exposure Integral (DEI) is a quantitative model that is used by the FAA to enforce compliance with decompression-related design directives. The model relies on the fact that the pressure that the subject is exposed to and the duration of that exposure are the two most important variables at play in a decompression event.^[42]

Other national and international standards for explosive decompression testing include:

• MIL-STD-810, 202
• RTCA/D0-160
• NORSOK M710
• API 17K and 17J
• NACE TM0192 and TM0297
• TOTALELFFINA SP TCS 142 Appendix H

See also

• Cabin pressurization
• Time of useful consciousness

Notes

1. ^ Notable exceptions include the Airbus A380, Boeing 787, and Concorde

References

1. ^ ^{a b c d e} "AC 61-107A - Operations of aircraft at altitudes above 25,000 feet msl and/or mach numbers (MMO) greater than .75" (PDF). Federal Aviation Administration. 2007-07-15. http://www.faa.gov/pilots/training/airman_education/media/ac%2061-107a.pdf. Retrieved 2008-07-29. 
2. ^ ^{a b} Dehart, R. L.; J. R. Davis (2002). Fundamentals Of Aerospace Medicine: Translating Research Into Clinical Applications, 3rd Rev Ed.. United States: Lippincott Williams And Wilkins. p. 720. ISBN 9780781728980. 
3. ^ Flight Standards Service, United States; Federal Aviation Agency, United States (1980). Flight Training Handbook. U.S. Dept. of Transportation, Federal Aviation Administration, Flight Standards Service. p. 250. http://books.google.com/?id=ioRTAAAAMAAJ. Retrieved 2007-07-28. 
4. ^ Robert V. Brulle (2008-09-11). "Engineering the Space Age: A Rocket Scientist Remembers" (PDF). AU Press. http://aupress.au.af.mil/digital/pdf/book/brulle_engineering_space_age.pdf. Retrieved 2010-12-01. 
5. ^ Kenneth Gabriel Williams (1959). The New Frontier: Man's Survival in the Sky. Thomas. http://books.google.com/?id=3hMZAAAAIAAJ. Retrieved 2008-07-28. 
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7. ^ "Flight Surgeon's Guide". United States Air Force. http://wwwsam.brooks.af.mil/af/files/fsguide/HTML/Chapter_02.html. 
8. ^ Matt Austin (2001). "Fluid Hammer calculations". http://www.disastercity.info/ghost/fhcalcs/. Retrieved 27 June 2011. 
9. ^ The Honolulu Advertiser (2001). "Engineer fears repeat of 1988 Aloha jet accident". http://the.honoluluadvertiser.com/2001/Jan/18/118localnews1.html. Retrieved 27 June 2011. 
10. ^ "Revisiting Aloha Airline Flight 243" (PDF). School of chemical and materials engineering, National University of Science and technology, Pakistan. pp. 26 et seq.. http://ntl.bts.gov/lib/38000/38500/38554/aloha_flight_243_a_new_direction.pdf. 
11. ^ ^{a b c d e f} Martin B. Hocking, Diana Hocking (2005). Air Quality in Airplane Cabins and Similar Enclosed Spaces. Springer Science & Business. ISBN 3540250190. http://books.google.com/?id=KzXPJ-p75QIC. Retrieved 2008-09-01. 
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13. ^ Brooks CJ (March 1987). "Loss of cabin pressure in Canadian Forces transport aircraft, 1963-1984". Aviat Space Environ Med 58 (3): 268–75. PMID 3579812. 
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19. ^ http://www.urban-astronomer.com/articles/questions-and-answers/will-an-astronaut-explode-if-he-takes-off-his-helmet
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21. ^ http://www.everything2.com/title/explosive%2520decompression
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23. ^ Brnes Warnock McCormick, M. P. Papadakis, Joseph J. Asselta (2003). Aircraft Accident Reconstruction and Litigation. Lawyers & Judges Publishing Company. ISBN 1930056613. http://books.google.com/?id=l5U1YwUMAJ4C. Retrieved 2008-09-05. 
24. ^ Alexander Dallin (1985). Black Box. University of California Press. ISBN 0520055152. http://books.google.com/?id=0XGGAAAAIAAJ. Retrieved 2008-09-06. 
25. ^ United States Court of Appeals for the Second Circuit Nos. 907, 1057 August Term, 1994 (Argued: April 5, 1995 Decided: July 12, 1995, Docket Nos. 94-7208, 94-7218
26. ^ http://www.fire.tc.faa.gov/pdf/fsr-0403.pdf
27. ^ "Aging airplane safety". Federal Aviation Administration. 2002-12-02. http://rgl.faa.gov/Regulatory_and_Guidance_Library/rgFinalRule.nsf/0/ceabe3247fab85f886256c8b0058461c!OpenDocument. Retrieved 2008-07-29. 
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31. ^ "Qantas Boeing 747-400 depressurisation and diversion to Manila on 25 July 2008" (Press release). Australian Transport Safety Bureau. 2008-07-28. http://www.atsb.gov.au/newsroom/2008/release/2008_24.aspx. Retrieved 2008-07-28. 
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34. ^ George Bibel (2007). Beyond the Black Box. JHU Press. pp. 141–142. ISBN 0801886317. http://books.google.com/?id=B3ng54W3sQ8C. Retrieved 2008-09-01. 
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36. ^ US 6273365 
37. ^ "Final Policy FAR Part 25 Sec. 25.841 07/05/1996|Attachment 4". http://rgl.faa.gov/Regulatory_and_Guidance_Library%5CrgPolicy.nsf/0/90AA20C2F35901D98625713F0056B1B8?OpenDocument. 
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External links

• Human Exposure to Vacuum