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Revision as of 22:19, 27 October 2019 edit Tom.Reding (talk \| contribs) Autopatrolled, Extended confirmed users, Page movers, Template editors 4,364,437 edits m MOS:JRSR; WP:GenFixes on; cleanup Tag: AWB ← Previous edit		Latest revision as of 18:07, 30 August 2025 edit undo 2600:1012:b1a1:c509:be0c:2720:af61:e6f (talk) Replaced "The candle had become contaminated with hydraulic oil" with "Likely had become contamined with hydraulic oil". . The contamination and specificly, oil contamination, could not be conclusivsely proven. It is fact however that the ingredients in the candles will explode when mixed with organic matter Tags: Visual edit Mobile edit Mobile web edit
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Line 1: {{short description\|Device that releases oxygen via a chemical reaction}} A '''chemical oxygen generator''' is a device that releases [[oxygen]] via a [[chemical reaction]]. The oxygen source is usually an inorganic [[superoxide]],<ref>Hayyan M., Hashim M.A., AlNashef I.M., Superoxide Ion: Generation and Chemical Implications, Chem. Rev., 2016, 116 (5), pp 3029–3085. [[DOI: 10.1021/acs.chemrev.5b00407]]</ref> [[chlorate]], or [[perchlorate]];. [[~~ozonide~~Ozonide]]s are a promising group of oxygen sources, as well. The generators are usually ignited by a [[firing pin]], and the chemical reaction is usually [[exothermic]], making the generator a potential [[fire hazard]]. [[Potassium superoxide]] was used as an oxygen source on early ~~manned~~ crewed missions of the [[Soviet space program]], in [[submarine]]s for use in emergency situations, for [[firefighting\|firefighters]], and for [[mine rescue]]. == In commercial airliners == Line 5 ⟶ 6: [[File:Chemical Oxygen Generator, Cut-away View.gif\|thumb\|Chemical Oxygen Generator, Cut-away View]] Commercial aircraft provide [[Emergency oxygen system\|emergency oxygen]] to passengers to protect them ~~from~~in ~~drops~~case inof loss of cabin pressure. Chemical oxygen generators are not used for the cockpit crew, who are typically supplied using [[oxygen cylinder\|compressed oxygen ~~canisters~~cylinders]], also known as oxygen bottles. In narrow body airliners, for each row of seats there ~~are~~were overhead [[oxygen mask]]s and oxygen generators. In some wide-body airliners, such as the [[DC-10]] and [[IL-96]], the ~~canisters~~oxygen generators and oxygen masks are mounted in the top portion of the seat backs, since the ceiling is too high above the passengers. If a decompression ~~occurs~~occurred, the panels ~~are~~were opened either by an automatic pressure switch or by a manual switch, and the masks are released. When the passengers pull down on the mask they ~~remove~~removed the retaining pins and ~~trigger~~triggered the production of oxygen. The oxidizer core is [[sodium chlorate]] ([[Sodium\|Na]][[Chlorine\|Cl]][[Oxygen\|O]]<sub>3</sub>), which is mixed with less than 5{{nbsp}}percent [[barium peroxide]] ([[barium\|Ba]][[Oxygen\|O]]<sub>2</sub>) and less than 1 percent [[potassium perchlorate]] ([[potassium\|K]][[chlorine\|Cl]][[oxygen\|O]]<sub>4</sub>). The explosives in the percussion cap are a [[lead styphnate]] and [[tetrazene explosive]] mixture. The chemical reaction is exothermic and the exterior temperature of the generator will reach {{convert\|260\|°C\|°F\|abbr=on}}. It will produce oxygen for 12 to 22 minutes.<ref>{{cite journal \|title=Functions of Barium Peroxide in Sodium Chlorate Chemical Oxygen \|author1=Yunchang Zhang \|author2=Girish Kshirsagar \|author3=James C. Cannon \|journal=Ind. Eng. Chem. Res. \|volume=32 \|issue=5 \|pages=966–969 \|year=1993 \|url= \|doi=10.1021/ie00017a028 }}</ref><ref>{{cite journal \|title=Chlorate Candles as a Source of Oxygen \|author1=William H. Schechter \|author2=R. R. Miller \|author3=Robert M. Bovard \|author4=C. B. Jackson \|author5=John R. Pappenheimer \|journal=Industrial & Engineering Chemistry \|volume=42 \|issue=11 \|pages=2348–2353 \|year=1950 \|url= \|doi=10.1021/ie50491a045}}</ref> The two-mask generator is approximately {{convert\|63\|mm\|in\|abbr=on}} in diameter and {{convert\|223\|mm\|in\|abbr=on}} long. The three-mask generator is approximately {{convert\|70\|mm\|in\|abbr=on}} in diameter and {{convert\|250\|mm\|in\|abbr=on}} long. ~~The oxidizer core is [[sodium chlorate]] ([[Sodium\|Na]][[Chlorine\|Cl]][[Oxygen\|O]]<sub>3</sub>), which is mixed with less than 5~~ percent [[barium peroxide]] ([[barium\|Ba]][[Oxygen\|O]]<sub>2</sub>) and less than 1 percent [[potassium perchlorate]] ([[potassium\|K]][[chlorine\|Cl]][[oxygen\|O]]<sub>4</sub>). The explosives in the percussion cap are a [[lead styphnate]] and [[tetrazene explosive]] mixture. The chemical reaction is exothermic and the exterior temperature of the canister will reach {{convert\|260\|°C\|°F\|abbr=on}}. It will produce oxygen for 12 to 22 minutes.<ref> ~~{{cite journal~~ ~~\| title = Functions of Barium Peroxide in Sodium Chlorate Chemical Oxygen~~ ~~\|author1=Yunchang Zhang \|author2=Girish Kshirsagar \|author3=James C. Cannon \| journal = Ind. Eng. Chem. Res.~~ ~~\| volume = 32~~ ~~\| issue = 5~~ ~~\| pages = 966–969~~ ~~\| year = 1993~~ ~~\| url =~~ ~~\| doi = 10.1021/ie00017a028 }}</ref><ref>{{cite journal~~ ~~\| title = Chlorate Candles as a Source of Oxygen~~ ~~\|author1=William H. Schechter \|author2=R. R. Miller \|author3=Robert M. Bovard \|author4=C. B. Jackson \|author5=John R. Pappenheimer \| journal = Industrial & Engineering Chemistry~~ ~~\| volume = 42~~ ~~\| issue = 11~~ ~~\| pages = 2348–2353;~~ ~~\| year = 1950~~ ~~\| url =~~ ~~\| doi = 10.1021/ie50491a045~~ }}</ref> The two-mask generator is approximately {{convert\|63\|mm\|in\|abbr=on}} in diameter and {{convert\|223\|mm\|in\|abbr=on}} long. The three-mask generator is approximately {{convert\|70\|mm\|in\|abbr=on}} in diameter and {{convert\|250\|mm\|in\|abbr=on}} long. ~~Accidental~~On May 11, 1996, accidental activation of improperly shipped expired generators, mistakenly labeled as empty "oxy canisters",<ref name=FAA-N904VJ>{{Cite web \|title=McDonnell Douglas DC-9-32 {{!}} ValuJet Airlines Flight 592, N904VJ \|work=[[Federal Aviation Administration]] \|date=19 December 2022 \|access-date=10 October 2024 \|url=https://www.faa.gov/lessons_learned/transport_airplane/accidents/N904VJ}}</ref> caused the [[ValuJet Flight 592]] crash, killing all on board.<ref>{{cite episode\|series=[[Mayday (Canadian TV series)\|Mayday]]\|title=Fire in the Hold\|season=12\|number=2\|date=10 August 2012}}</ref> An ATA DC-10, Flight 131, was also destroyed while parked at O'Hare Airport, on August 10, 1986. The cause was the accidental activation of an oxygen ~~canister~~generator, contained in the back of a broken DC-10 seat, being shipped in the cargo compartment to a repair station. There were no fatalities or injuries because the plane contained no passengers when the fire broke out.<ref>{{cite web \|title= OT McDonnell Douglas DC-10-40 N184AT \|url= https://asn.flightsafety.org/asndb/326951 \|work= [[Aviation Safety Network]] \|url-status= live \|archive-url= https://archive.today/20240621035329/https://asn.flightsafety.org/asndb/326951 \|archive-date= June 21, 2024}}</ref><ref>[http://www.airliners.net/photo/American-Trans-Air/McDonnell-Douglas-DC-10-40/0148751/L/&sid=faf57dd90832c5c13834020fb2255dc2 Airliners.net, Photograph, Dave Campbell]</ref> ==Oxygen candle== A ''chlorate candle'', or an '''oxygen candle''', is a cylindrical chemical oxygen generator that contains a mix of [[sodium chlorate]] and [[iron]] powder, which when ignited [[smoldering\|smolders]] at about {{convert\|600\|°C\|°F\|abbr=on\|sigfig=2}}, producing [[sodium chloride]], [[iron oxide]], and oxygen at a fixed rate of about 6.5 man-hours ~~of oxygen~~ per kilogram of the mixture. The mixture has an indefinite shelf life if stored properly: candles have been stored for 20 years without decreased oxygen output. [[Thermal decomposition]] releases the oxygen. The burning iron supplies the heat. The candle must be wrapped in [[thermal insulation]] to maintain the reaction temperature and to protect surrounding equipment. The key reaction is:<ref name=G&E>{{Greenwood&Earnshaw2nd}}</ref> :2 NaClO<sub>3</sub> → 2 NaCl + 3 O<sub>2</sub> [[potassium chlorate\|Potassium]] and [[lithium chlorate]], and [[sodium perchlorate\|sodium]], [[potassium perchlorate\|potassium]] and [[lithium perchlorate]]s can also be used in oxygen candles. In the [[Vika oxygen generator]] used on some spacecraft, [[lithium perchlorate]] is the source of [[oxygen]]. At {{convert\|400~~ ~~\|°C\|°F\|abbr=on\|sigfig=2}}, it releases 60% of its ~~weight~~mass as [[oxygen]]:<ref>{{cite journal\|title=Lithium Perchlorate Oxygen Candle. Pyrochemical Source of Pure Oxygen\|~~authors~~author1=M. M. Markowitz, \|author2=D. A. Boryta~~, and~~ \|author3=Harvey Stewart Jr. \|journal=Ind. Eng. Chem. Prod. Res. Dev.\|year=1964\|volume=3\|issue=4\|pages=321–330▼ An explosion caused by one of these candles killed two Royal Navy sailors on {{HMS\|Tireless\|S88}}, a nuclear-powered submarine, under the Arctic on 21 March 2007.<ref>{{cite web\|last1=Johnson\|first1=C. W.\|title=Degraded Modes and the ‘Culture of Coping’ in Military Operations: An Analysis of a Fatal Incident on-board HMS Tireless on 20/21 March 2007\|url=http://www.dcs.gla.ac.uk/~johnson/papers/JWSSC2009/Degraded_Modes.pdf}}</ref> The candle had become contaminated with hydraulic oil, which caused the mixture to explode rather than burn.<ref>{{cite web \|title = 'Oxygen candle' caused explosion\| url = https://www.theregister.co.uk/2007/03/22/sub_blast_oxy_candle/ \| publisher = The Register \| last = Page \| first = Lewis \| date = 22 March 2007 \| accessdate = 2013-09-04 }}</ref>▼ ▲In the [[Vika oxygen generator]] used on some spacecraft, [[lithium perchlorate]] is the source of [[oxygen]]. At 400 °C, it releases 60% of its weight as [[oxygen]]:<ref>{{cite journal\|title=Lithium Perchlorate Oxygen Candle. Pyrochemical Source of Pure Oxygen\|authors=M. M. Markowitz, D. A. Boryta, and Harvey Stewart Jr.\|journal=Ind. Eng. Chem. Prod. Res. Dev.\|year=1964\|volume=3\|pages=321–330 \|doi=10.1021/i360012a016}}</ref> :LiClO<sub>4</sub> → LiCl + 2 O<sub>2</sub> Line 44 ⟶ 24: ==Pressure swing adsorption (PSA) oxygen generators== {{Main\|Oxygen concentrator}} Advances in technology have provided industrial oxygen generator systems for use where air is available and a higher concentration of oxygen is desired. [[Pressure swing adsorption]] (PSA) incorporates a ~~material called~~ [[molecular sieve]] for gas separation. In the case of oxygen generation a zeolite-based sieve forces preferential adsorption for nitrogen.{{Citation needed\|date=September 2020}} Clean, dry air is passed through the sieve beds on the oxygen generator, producing an oxygen-enriched gas. [[Nitrogen separation membrane]] equipment is also used. ==Uses== Chemical oxygen generators are used in [[aircraft]], breathing apparatus for [[firefighter]]s and mine rescue crews, [[submarine]]s, and everywhere a compact emergency oxygen generator with long shelf life is needed. They usually contain a device for absorption of [[carbon dioxide]], sometimes a filter filled with [[lithium hydroxide]]; a kilogram of LiOH absorbs about half a kilogram of CO<sub>2</sub>. Self-contained oxygen generators (SCOGs) are used in submarines. * They were successfully used by the [[USS New Hampshire (SSN-778)\|USS ''New Hampshire'']], an American nuclear-powered submarine, in March 2011 when the submarine suffered an oxygen generator failure while under the [[Arctic ice cap]].<ref>{{cite news\| url= https://www.reuters.com/article/us-unitedtechnologies-submarine-idUSTRE72K7U420110321 \| work=Reuters \| title=Exclusive: UTC-built oxygen generator fails on U.S. submarine \| date=21 March 2011 \|access-date=21 February 2021 }}</ref> ▲** An explosion caused by ~~one~~a ofso-called ~~these~~oxygen ~~candles~~candle killed two Royal Navy sailors on {{HMS\|Tireless\|S88}}, a nuclear-powered submarine, under the Arctic on 21~~ ~~ March 2007.<ref>{{cite web\|last1=Johnson\|first1=C. W.\|title=Degraded Modes and the ~~‘Culture~~'Culture of ~~Coping’~~Coping' in Military Operations: An Analysis of a Fatal Incident on-board HMS Tireless on 20/21 March 2007\|url=http://www.dcs.gla.ac.uk/~johnson/papers/JWSSC2009/Degraded_Modes.pdf}}</ref> The candle had likely become contaminated with hydraulic oil, which would have caused the mixture to explode rather than burn.<ref>{{cite web \|title = 'Oxygen candle' caused explosion\| url = https://www.theregister.co.uk/2007/03/22/sub_blast_oxy_candle/ \| publisher = The Register \| last = Page \| first = Lewis \| date = 22 March 2007 \| accessdate = 2013-09-04 }}</ref>{{Failed verification\|date=April 2024}} [[Self-contained self-rescue device]]s (SCSRs) are used to facilitate escape from [[mining\|mines]]. On the [[International Space Station]], chemical oxygen generators are used as a backup supply. Each ~~canister~~Vika oxygen generator can produce enough oxygen for one crewmember for one day.<ref>{{cite web\|last=Barry\|first=Patrick\|title=Breathing Easy on the Space Station\|url=https://science.nasa.gov/science-news/science-at-nasa/2000/ast13nov_1/\|accessdate=9 September 2012\|year=2000\|publisher=[[National Aeronautics and Space Administration]]\|archive-date=11 March 2019\|archive-url=https://web.archive.org/web/20190311204439/https://science.nasa.gov/science-news/science-at-nasa/2000/ast13nov_1\|url-status=dead}}</ref> ==See also== [[Oxygen storage]] [[SolidOx (welding)]] ==References==