Jet fuel: Difference between revisions
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'''Jet fuel''' is a type of [[aviation fuel]] designed for use in [[Jet engine|jet-engined]] aircraft. |
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Jet fuel... it's fucking gas! |
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nuff said. |
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{| border=1 align=right class="wikitable" |
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| colspan=2 align=center | '''JET A-1''' |
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|- |
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|'''[[Flash point]]:''' || 38 °C |
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|- |
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|'''Autoignition temperature:''' || 210 °C |
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|- |
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|'''Freezing point:''' || −47 °C (−40 °C for ''JET A'') |
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|- |
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|'''[[Dirty burn|Open air burning]] temperatures:''' || 260–315 °C (500–599 °F) |
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|- |
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|'''Maximum burning temperature:''' || 980 °C (1796 °F) |
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|- |
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|'''Density at 15 °C (60 °F):''' || 0.775–0.840 kg/L |
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|} |
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== Description == |
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Aeroplane Fuel (Mostly used) |
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Aeroplane fuel is clear to straw colored. The most common fuel is an [[unleaded]]/paraffin oil-based fuel classified as ''Aeroplane A-1'', which is produced to an internationally standardized set of specifications. ''See the section for [[#Jet A|Jet A]] below''. |
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The only other Aeroplane fuel that is commonly used in civilian aviation is called ''Jet B'', a fuel in the [[naptha]]-[[kerosene]] region that is used for its enhanced cold-weather performance. However, Jet B's lighter composition makes it more dangerous to handle, and it is thus restricted only to areas where its cold-weather characteristics are absolutely necessary. |
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Aeroplane fuel is a mixture of a large number of different hydrocarbons, possibly as many as a thousand or more. The range of their sizes (molecular weights or carbon numbers) is restricted by the requirements for the product, for example, freezing point or smoke point. Kerosene-type Aeroplane fuel (including Jet A and Jet A-1) has a carbon number distribution between about 8 and 16 carbon numbers; wide-cut or naphtha-type Aeroplane fuel (including Jet B), between about 5 and 15 carbon numbers. <ref>{{cite web|url=http://www.chevron.com/products/prodserv/fuels/bulletin/aviationfuel/4_at_fuel_comp.shtm|title=Aviation Turbine Fuel Composition|author=Chevron Products Corporation}}</ref> |
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Both Aeroplanes (Jet A and Jet B) may contain a number of additives: |
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* [[Antioxidant]]s to prevent [[gumming]], usually based on [[alkylation|alkylated]] [[phenol]]s, eg. [[AO-30]], [[AO-31]], or [[AO-37]]; |
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* [[Antistatic agent]]s, to dissipate [[static electricity]] and prevent sparking; [[Stadis 450]], with [[dinonylnaphthylsulfonic acid]] (DINNSA) as the active ingredient, is an example |
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* [[Corrosion inhibitor]]s, e.g. [[DCI-4A]] used for civilian and military fuels, and [[DCI-6A]] used for military fuels; |
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* [[Fuel System Icing Inhibitor]] (FSII) agents, e.g. [[diethylene glycol monomethyl ether|Di-EGME]]; FSII is often mixed at the point-of-sale so that users with heated fuel lines do not have to pay the extra expense; |
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<!-- * [[Biocide]] additives. - unlikely... --> |
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Militaries around the world use a different classification system of JP numbers. Some are almost identical to their civilian counterparts and differ only by the amounts of a few additives; Jet A-1 is similar to [[JP-8]], Jet B is similar to [[JP-4]]. Other military fuels are highly specialized products and are developed for very specific applications. [[JP-5]] fuel is fairly common, and was introduced to reduce the risk of fire on aircraft carriers (has a higher flash point - a minimum of 60 °C). Other fuels were specific to one type of aircraft. [[JP-6]] was developed specifically for the [[XB-70 Valkyrie]] and [[JP-7]] for the [[SR-71 Blackbird]]. Both these fuels were engineered to have a high [[flash point]] to better cope with the heat and stresses of high speed supersonic flight. One aircraft-specific jet fuel still in use by the [[United States Air Force]] is [[JPTS]], which was developed in [[1956]] for the [[Lockheed U-2]] spy plane. |
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Jet fuels are sometimes classified as kerosene or naphtha-type. Kerosene-type fuels include Jet A, Jet A1, JP-5 and JP-8. Naphtha-type jets fuels, sometimes referred to as "wide-cut" jet fuel, include Jet B and JP-4. |
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===Jet A=== |
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[[Image:Shell Refueller.JPG|thumb|250px|[[Royal Dutch Shell|Shell]] [[Jet A-1]] refueller truck on the ramp at [[Vancouver International Airport]] (notice the 1863 Hazardous Material placard and "JET A-1" stickers)]] |
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Jet A is the standard jet fuel type in the [[United States|U.S.]] since the 1950s and is only available there. Jet A is similar to Jet-A1, except for its higher freezing point of −40 °C (vs −47 ° Jet A-1). Like Jet A-1, Jet A has a fairly high flash point of 38 °C, with an [[autoignition temperature]] of 410 °F (210 °C). Jet A can be identified in trucks and storage facilities by the [[UN number]], 1863, [[Hazardous Material]] placards. Jet A trucks, storage tanks, and pipes that carry Jet A will be marked with a black sticker with a white "Jet A" written over it, next to another black stripe. Jet A will have a clear to straw color if it is clean and free of contamination. Water is denser than Jet A, and will collect on the bottom of a tank. Jet A storage tanks must be sumped on a regular basis to check for water contamination. It is possible for water particles to become suspended in Jet A, which can be found by performing a "Clear and Bright" test. A hazy appearance can indicate water contamination beyond the acceptable limit of 30ppm ([[Parts-per notation|parts per million]]). |
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The U.S. commercial fuels are not required by law to contain antistatic additives, and generally do not{{Fact|date=July 2007}}. |
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The annual U.S. usage of jet fuel was 21 billion gallons (80 billion liters) in 2006. <ref>{{cite web|url=http://tonto.eia.doe.gov/dnav/pet/pet_cons_prim_dcu_nus_a.htm|title=U.S. Prime Supplier Sales Volumes of Petroleum Products|author=Energy Information Administration}}</ref> |
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A consortium consisting of [[Boeing]], [[NASA Glenn Research Center]], [[MTU Aero Engines]] (Germany), and the US [[Air Force Research Laboratory]] is investigating development of jet fuel blends containing a substantial percentage of bio-fuel. [http://www.boeing.com/commercial/environment/pdf/alt_fuels.pdf] |
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==History of jet fuel== |
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Fuel for a [[piston-engine]] powered aircraft (usually a high-[[Octane rating|octane]] [[gasoline]] known as [[Avgas]]) has a low [[flash point]] to improve its ignition characteristics. Turbine engines can operate with a wide range of fuels, and jet-aircraft engines typically use fuels with higher flash points, which are less flammable and therefore safer to transport and handle. The first jet fuels were based on [[kerosene]] or a gasoline-kerosene mix, and most jet fuels are still kerosene-based. |
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==Piston engine use== |
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Jet fuel is very similar to [[diesel fuel]], and a few aircraft engine manufacturers, most notably [[Thielert]], have begun offering [[piston engine]]s which run on jet fuel. The technology promises to be a way to provide light, powerful, and environmentally-friendly engines for the [[general aviation]] market while simplifying airport logistics and phasing out leaded [[avgas]]. |
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Jet fuel is often used in ground support vehicles at airports, instead of diesel. The United States military makes heavy use of JP-8, for instance. However, jet fuel tends to have poor lubricating ability in comparison to diesel, thereby increasing wear on fuel pumps and other related engine parts. Civilian vehicles tend to disallow its use, or require that an additive be mixed with the jet fuel in order to restore its [[lubricity]]. |
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==References== |
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<references /> |
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==See also== |
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* [[JP-1]] |
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* [[JP-4]] |
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* [[JP-5]] |
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* [[JP-6]] |
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* [[JP-7]] |
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* [[JP-8]] |
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* [[Aviation fuel]] |
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* [[JPTS]] |
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==External links== |
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* [http://www.chevron.com/products/prodserv/fuels/bulletin/aviationfuel/toc.shtm Aviation Fuels] (by [[Chevron Corporation|Chevron]]) |
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* Day, Dwayne A., [http://www.centennialofflight.gov/essay/Evolution_of_Technology/fuel/Tech21.htm Aviation Fuel] |
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* [http://www.csgnetwork.com/jetfuel.html Jet fuel information] |
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* [http://www.spragueenergy.com/documents/MSDS%20Jet%20A%20Aviation%20Fuel%2006.pdf Jet A MSDS] |
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[[Category:Aviation fuels]] |
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[[ca:Querosè]] |
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[[de:Kerosin]] |
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[[eo:Keroseno]] |
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[[es:Queroseno]] |
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[[fr:Kérosène]] |
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[[id:Minyak tanah]] |
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[[it:Cherosene]] |
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[[nl:Kerosine]] |
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[[pt:Combustível de jato]] |
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[[sv:Fotogen]] |
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[[zh:航空煤油]] |
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Revision as of 23:25, 27 December 2007
Jet fuel is a type of aviation fuel designed for use in jet-engined aircraft.
| JET A-1 | |
| Flash point: | 38 °C |
| Autoignition temperature: | 210 °C |
| Freezing point: | −47 °C (−40 °C for JET A) |
| Open air burning temperatures: | 260–315 °C (500–599 °F) |
| Maximum burning temperature: | 980 °C (1796 °F) |
| Density at 15 °C (60 °F): | 0.775–0.840 kg/L |
Description
Aeroplane Fuel (Mostly used)
Aeroplane fuel is clear to straw colored. The most common fuel is an unleaded/paraffin oil-based fuel classified as Aeroplane A-1, which is produced to an internationally standardized set of specifications. See the section for Jet A below.
The only other Aeroplane fuel that is commonly used in civilian aviation is called Jet B, a fuel in the naptha-kerosene region that is used for its enhanced cold-weather performance. However, Jet B's lighter composition makes it more dangerous to handle, and it is thus restricted only to areas where its cold-weather characteristics are absolutely necessary.
Aeroplane fuel is a mixture of a large number of different hydrocarbons, possibly as many as a thousand or more. The range of their sizes (molecular weights or carbon numbers) is restricted by the requirements for the product, for example, freezing point or smoke point. Kerosene-type Aeroplane fuel (including Jet A and Jet A-1) has a carbon number distribution between about 8 and 16 carbon numbers; wide-cut or naphtha-type Aeroplane fuel (including Jet B), between about 5 and 15 carbon numbers. [1]
Both Aeroplanes (Jet A and Jet B) may contain a number of additives:
- Antioxidants to prevent gumming, usually based on alkylated phenols, eg. AO-30, AO-31, or AO-37;
- Antistatic agents, to dissipate static electricity and prevent sparking; Stadis 450, with dinonylnaphthylsulfonic acid (DINNSA) as the active ingredient, is an example
- Corrosion inhibitors, e.g. DCI-4A used for civilian and military fuels, and DCI-6A used for military fuels;
- Fuel System Icing Inhibitor (FSII) agents, e.g. Di-EGME; FSII is often mixed at the point-of-sale so that users with heated fuel lines do not have to pay the extra expense;
Militaries around the world use a different classification system of JP numbers. Some are almost identical to their civilian counterparts and differ only by the amounts of a few additives; Jet A-1 is similar to JP-8, Jet B is similar to JP-4. Other military fuels are highly specialized products and are developed for very specific applications. JP-5 fuel is fairly common, and was introduced to reduce the risk of fire on aircraft carriers (has a higher flash point - a minimum of 60 °C). Other fuels were specific to one type of aircraft. JP-6 was developed specifically for the XB-70 Valkyrie and JP-7 for the SR-71 Blackbird. Both these fuels were engineered to have a high flash point to better cope with the heat and stresses of high speed supersonic flight. One aircraft-specific jet fuel still in use by the United States Air Force is JPTS, which was developed in 1956 for the Lockheed U-2 spy plane.
Jet fuels are sometimes classified as kerosene or naphtha-type. Kerosene-type fuels include Jet A, Jet A1, JP-5 and JP-8. Naphtha-type jets fuels, sometimes referred to as "wide-cut" jet fuel, include Jet B and JP-4.
Jet A
Jet A is the standard jet fuel type in the U.S. since the 1950s and is only available there. Jet A is similar to Jet-A1, except for its higher freezing point of −40 °C (vs −47 ° Jet A-1). Like Jet A-1, Jet A has a fairly high flash point of 38 °C, with an autoignition temperature of 410 °F (210 °C). Jet A can be identified in trucks and storage facilities by the UN number, 1863, Hazardous Material placards. Jet A trucks, storage tanks, and pipes that carry Jet A will be marked with a black sticker with a white "Jet A" written over it, next to another black stripe. Jet A will have a clear to straw color if it is clean and free of contamination. Water is denser than Jet A, and will collect on the bottom of a tank. Jet A storage tanks must be sumped on a regular basis to check for water contamination. It is possible for water particles to become suspended in Jet A, which can be found by performing a "Clear and Bright" test. A hazy appearance can indicate water contamination beyond the acceptable limit of 30ppm (parts per million).
The U.S. commercial fuels are not required by law to contain antistatic additives, and generally do not[citation needed].
The annual U.S. usage of jet fuel was 21 billion gallons (80 billion liters) in 2006. [2]
A consortium consisting of Boeing, NASA Glenn Research Center, MTU Aero Engines (Germany), and the US Air Force Research Laboratory is investigating development of jet fuel blends containing a substantial percentage of bio-fuel. [1]
History of jet fuel
Fuel for a piston-engine powered aircraft (usually a high-octane gasoline known as Avgas) has a low flash point to improve its ignition characteristics. Turbine engines can operate with a wide range of fuels, and jet-aircraft engines typically use fuels with higher flash points, which are less flammable and therefore safer to transport and handle. The first jet fuels were based on kerosene or a gasoline-kerosene mix, and most jet fuels are still kerosene-based.
Piston engine use
Jet fuel is very similar to diesel fuel, and a few aircraft engine manufacturers, most notably Thielert, have begun offering piston engines which run on jet fuel. The technology promises to be a way to provide light, powerful, and environmentally-friendly engines for the general aviation market while simplifying airport logistics and phasing out leaded avgas.
Jet fuel is often used in ground support vehicles at airports, instead of diesel. The United States military makes heavy use of JP-8, for instance. However, jet fuel tends to have poor lubricating ability in comparison to diesel, thereby increasing wear on fuel pumps and other related engine parts. Civilian vehicles tend to disallow its use, or require that an additive be mixed with the jet fuel in order to restore its lubricity.
References
- ^ Chevron Products Corporation. "Aviation Turbine Fuel Composition".
- ^ Energy Information Administration. "U.S. Prime Supplier Sales Volumes of Petroleum Products".
See also
External links
- Aviation Fuels (by Chevron)
- Day, Dwayne A., Aviation Fuel
- Jet fuel information
- Jet A MSDS