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File:Kerosene bottle.jpg
A kerosene bottle, containing blue dyed kerosene

Kerosene, sometimes spelled kerosine in scientific and industrial usage,[1] also known as paraffin in UK and South Africa, is a combustible hydrocarbon liquid. The name is derived from Greek keros (κηρός wax). The word Kerosene was registered as a trademark by Abraham Gesner in 1854 and for several years only the North American Gas Light Company and the Downer Company (to which Gesner had granted the right) were allowed to call their lamp oil kerosene.[2] It eventually became a genericized trademark.

It is usually called paraffin (sometimes paraffin oil) in the UK, South East Asia and South Africa (not to be confused with the much more viscous paraffin oil used as a laxative, or the waxy solid also called paraffin wax or just paraffin); the term kerosene is usual in much of Canada, the United States, Australia (where it is usually referred to colloquially as kero) and New Zealand.[3]

Kerosene is widely used to power jet-engined aircraft (jet fuel) and some rockets, but is also commonly used as a heating fuel and for fire toys such as poi. In parts of Asia, where the price of kerosene is subsidized, it fuels outboard motors rigged on small fishing craft.[citation needed]

Properties

Kerosene is a thin, clear liquid formed from hydrocarbons, with density of 0.78–0.81 g/cm3. It is obtained from the fractional distillation of petroleum between 150 °C and 275 °C, resulting in a mixture of carbon chains that typically contain between 6 and 16 carbon atoms per molecule.[4]

The flash point of kerosene is between 37 and 65 °C (100 and 150 °F) and its autoignition temperature is 220 °C (428 °F).[5]

The heat of combustion of kerosene is similar to that of diesel: its lower heating value is around 18,500 Btu/lb, or 43.1 MJ/kg, and its higher heating value is 46.2 MJ/kg.[6]

Kerosene is immiscible in water (cold or hot), but miscible in petroleum solvents.

History

The process of distilling crude oil/petroleum into kerosene, as well as other hydrocarbon compounds, was first written about in the mid 800's by the Persian scholar Rāzi (or Rhazes). Termed naft abyad ("white naphtha"), Razi produced kerosene and various other compounds using an apparatus called alembic. In his Kitab al-Asrar (Book of Secrets), the physician and chemist Razi described two methods for the production of kerosene. One method involved using clay as an absorbent, whereas the other method involved using ammonium chloride (sal ammoniac). The distillation process was to be repeated until the final product was perfectly clear and "safe to light," i.e. volatile hydrocarbon fractions had been mostly removed. Kerosene was also produced during the same period from oil shale and bitumen by heating the rock to extract the oil, which was then distilled.[7][unreliable source?]

In 1846 Canadian geologist Abraham Gesner gave a public demonstration in Charlottetown, Prince Edward Island of a new process he had discovered. He heated coal in a retort and distilled from it a clear, thin fluid which he showed made an excellent lamp fuel. He coined the name "Kerosene" for his fuel, a contraction of keroselaion, meaning wax-oil.[8] The cost of extracting kerosene from coal was, however, high. Fortunately, Gesner recalled from his extensive knowledge of New Brunswick's geology a naturally occurring asphaltum called Albertite. He was however blocked from using it by the New Brunswick coal conglomerate because they had coal extraction rights for the province and he lost a court case when their experts claimed that Albertite was in fact a form of coal.[9] Gesner subsequently moved to Newton Creek, Long Island, USA, in 1854, where he secured the backing of a group of businessmen. They formed the North American Gas Light Company, to which he assigned his patents. Despite clear priority of discovery, Gesner did not obtain his first kerosene patent until 1854, two years after James Young's US patent. Gesner's method of purifying the distillation products appears to have been superior to Young's, resulting in a cleaner and better smelling fuel. Manufacture of kerosene under the Gesner patents began in New York in 1854 and later in Boston, being distilled from bituminous coal and oil shale.[8]

In 1848 Scottish chemist James Young experimented with oil discovered seeping in a coal mine as a source of lubricating oil and illuminating fuel. When the seep became exhausted he experimented with the dry distillation of coal, especially the resinous "Boghead coal" (Torbanite). He extracted a number of useful liquids from it, one of which he named "paraffine oil" because at low temperatures it congealed into a substance resembling paraffin wax. Young took out a patent on his process and the resulting products in 1850, and built the first truly commercial oil-works in the world at Bathgate in 1851, using oil extracted from locally mined Torbanite, shale, and bituminous coal. In 1852 he took out a US patent for the same invention. These patents were subsequently upheld in both countries in a series of lawsuits and other producers were obliged to pay him royalties.[8] See also coal oil.

In 1851 Samuel Martin Kier began selling kerosene to local miners, under the name "Carbon Oil". He distilled this by a process of his own invention from crude oil. He also invented a new lamp to burn his product.[10] He has been dubbed the Grandfather of the American Oil Industry by historians.[11] Since the 1840s, Kier's salt wells were becoming fouled with petroleum. At first, Kier simply dumped the useless oil into the nearby Pennsylvania Main Line Canal, but later he began experimenting with several distillates of the crude oil along with a chemist from eastern Pennsylvania. [12]

Ignacy Lukasiewicz, a Polish pharmacist residing in Lvov had been experimenting with different kerosene distillation techniques, trying to improve on Gesner's process, using local seep oil. Many people knew of his work but paid little attention to it. On the night of July 31, 1853, doctors at the local hospital needed to perform an emergency operation, virtually impossible by candlelight. They therefore sent a messenger for Lukasiewicz and his new lamps. The lamp burned so brightly and cleanly that the hospital officials ordered several lamps plus a large supply of fuel. Lukasiewicz realized the potential of his work and quit the pharmacy to find a business partner and then travelled to Vienna to register his technique with the government. Lukasiewicz moved to the Gorlice region of Poland in 1854 and sank several wells across southern Poland over the following decade, setting up a refinery near Jasło in 1859.[13]

The widespread availability of cheaper kerosene was the principal factor in the precipitous decline in the whaling industry in the mid-to-late 19th century, as the leading product of whaling was oil for lamps.

Fuel uses

Heating and lighting

Fuels for heating

Heating oil
Wood pellet
Kerosene
Propane
Natural gas
Wood
Coal

At one time the fuel was widely used in kerosene lamps and lanterns. Although it replaced whale oil, the 1873 edition of Elements of Chemistry said that "The vapor of this substance [kerosene] mixed with air is as explosive as gunpowder."[14] This may have been due to the common practice of adulterating kerosene with other, more volatile hydrocarbons, such as the cheaper benzene.[15] Kerosene was also a fire risk; in 1880, nearly two out of every five New York City fires were caused by defective kerosene lamps.[16]

These were superseded by the electric light bulb and flashlights powered by dry cell batteries, which are still used to this day.

Its use as a cooking fuel is mostly restricted to some portable stoves for backpackers and to less developed countries, where it is usually less refined and contains impurities and even debris.

As a heating fuel, it is often used in portable stoves, and is sold in some filling stations. It is sometimes used as a heat source during power failures. The use of portable kerosene heaters is not recommended for closed indoor areas without a chimney due to the danger of build-up of carbon monoxide gas.

File:Kerosene truck Aichi Japan.jpg
A truck delivering kerosene in Japan

Kerosene is widely used in Japan as a home heating fuel for portable and installed kerosene heaters. In Japan, kerosene can be readily bought at any filling station or be delivered to homes.[citation needed]

In the United Kingdom and Ireland kerosene is often used as a heating fuel in areas that are unconnected to a gas pipeline network. It is used less for cooking, which has more commonly been LPG for some decades now, owing to its (LPG's) easier lighting.

The Amish, who abstain from the use of electricity, rely on kerosene for lighting at night.

More ubiquitous in the late 19th and early 20th centuries, kerosene space heaters were often built into kitchen ranges and kept many farm and fishing families warm and dry through the winter. At one time citrus growers used a smudge pot fueled by kerosene to create a pall of thick smoke over a grove in an effort to prevent freezing temperatures from damaging crops. Salamanders are kerosene space heaters used on construction sites to dry out building materials and to warm workers. Before the days of blinking electrically lighted road barriers, highway construction zones were marked at night by kerosene fired pot-bellied torches. Most of these uses of kerosene created thick black smoke because of the low temperature of combustion.

A notable exception, discovered in the early 19th century, is the use of a gas mantle above the wick on a kerosene lamp. Looking like a delicate woven bag above the woven cotton wick, the mantle is a residue of mineral materials (mostly thorium dioxide) which is heated to incandescence by the flame produced by the wick. The thorium and cerium oxide combination produces both a whiter light and a greater fraction of the energy in the form of visible light than a black body at the same temperature would. These types of lamps are still in use today in areas of the world without electricity, because they give a much better light than a simple wick-type lamp does.[citation needed]

Transportation

In the mid-20th century, kerosene or TVO (tractor vaporising oil) was used as a cheap fuel for tractors. The engine would start on gasoline, then switch over to kerosene once the engine warmed up. A heat valve on the manifold would route the exhaust gases around the intake pipe, heating the kerosene to the point where it was vaporized and could be ignited by an electrical spark.

During the fuel crisis of the 1970s Saab-Valmet developed and series-produced the Saab 99 Petro that ran on kerosene, turpentine or gasoline. The project codenamed "Project Lapponia" was headed by Simo Vuorinen, and towards the end of the 1970s a working prototype was produced based on the Saab 99GL. The car was designed to run on two fuels. Gasoline was used for cold starts and when extra power was needed, but normally it ran on kerosene or turpentine. The idea was that the gasoline could be made from peat using the Fischer-Tropsch process. Between 1980 and 1984, 3756 Saab 99 Petros and 2385 Talbot Horizons (a version of the Chrysler Horizon that integrated many Saab components) were made.[17]

Kerosene is used to fuel smaller horsepower outboard motors built by Yamaha Motors, Suzuki Marine, and Tohatsu. Primarily used on small fishing craft, these are bi-fuel engines that start on gasoline and then transition to kerosene once the engine reaches engine temperature. Multi-fuel Evinrude and Mercury Racing engines also burn kerosene, as well as jet fuel.[18]

Today kerosene is mainly used in fuel for jet engines (more technically Avtur, Jet A, Jet A-1, Jet B, JP-4, JP-5, JP-7 or JP-8). One form of the fuel known as RP-1 is burned with liquid oxygen as rocket fuel. These fuel grade kerosenes meet specifications for smoke points and freeze points. The combustion reaction can be approximated as follows, with the molecular formula C12H26 (dodecane):

C12H26(l) + 37/2 O2(g) → 12 CO2(g) + 13 H2O(g); H˚ = -7513 kJ

In the initial phase of liftoff the Saturn V launch vehicle was powered by the reaction of liquid oxygen with RP-1.[19] For the five 6.4 meganewton sea-level thrust F-1 rocket engines of the Saturn V, burning together, the reaction generated roughly 1.62 × 1011 watts (J/s) (162 Gigawatt) or 217 million horsepower.[19]

Kerosene is sometimes used as an additive in diesel fuel to prevent gelling or waxing in cold temperatures.[20]

Ultra-low sulfur kerosene is a custom-blended fuel used by the New York City Transit to power its bus fleet. The transit agency started using this fuel in 2004, prior to the widespread adoption of ultra-low sulfur diesel, which has since become the standard. In 2008, the suppliers of the custom fuel failed to tender for a renewal of the transit agency's contract, leading to a negotiated contract at a significantly increased cost.[21]

Cooking

In countries such as India, kerosene is the main fuel used for cooking, especially by the poor, and kerosene stoves have replaced traditional wood-based cooking appliances. As such, increase in the price of kerosene can have a major political and environmental consequence. The Indian government subsidizes the fuel to keep the price very low, to around 15 cents per liter as of February 2007, as lower prices discourage dismantling of forests for cooking fuel.[22]

Kerosene is used as a fuel in portable stoves, especially in Primus stoves invented in 1892. Portable kerosene stoves earn a reputation of reliable and durable stove in everyday use and perform especially well under adverse conditions. In outdoor activities and mountainering, a decisive advantage of pressurized kerosene stoves on gas cartridge stoves is their particularly high thermal output and their ability to operate at very low temperature in winter or at high altitude.

Entertainment

Kerosene is often used in the entertainment industry for fire performances such as fire breathing, fire juggling or poi, and fire dancing. Because of its low flame temperature when burnt in free air, risk is lower, should the performer come in contact with the flame. Kerosene is not usually used as fuel for indoor fire dancing as it produces an unpleasant odor, which becomes poisonous in sufficient concentration. Methanol was sometimes used instead, but the flames methanol produces look less impressive, and the lower flash point of methanol pose a high risk. Moreover methanol is highly toxic for the optical nerves and cause blindness when swallowed.

Other uses

  • Liquid pesticides have traditionally used kerosene or some other petroleum distillate as a carrier, though water has recently begun to replace kerosene
  • Kerosene has also been found effective in killing bed bugs upon direct spray.
  • Kerosene has been used to treat pools of standing water to prevent mosquitoes from breeding, notably in the yellow fever outbreak of 1905 in New Orleans.
  • It can be used to remove lice from hair, but this practice is painful and potentially very dangerous. Also, this practice removes all natural oils and fats from the scalp.
  • Since kerosene is chemically stable, it is used to store substances with redox tendencies within to prevent unwanted reactions, such as alkali metals.
  • It is used in the packaging and storing of white phosphorus to prevent contact with oxygen, which would lead to immediate combustion.
  • In x-ray crystallography, kerosene can be used to store crystals. When a hydrated crystal is left in air, dehydration may occur slowly. This makes the colour of the crystal become dull. Kerosene can keep air from the crystal.
  • It is sometimes used as a solvent.
    • Kerosene can be applied topically to hard-to-remove mucilage or adhesive left by stickers on a glass surface (such as in show windows of stores).
    • Kerosene can be used to remove candle wax that has dripped onto a glass surface; it is recommended that the excess wax be scraped off prior to applying kerosene via a soaked cloth or tissue paper.
    • Kerosene can be used to clean bicycle and motorcycle chains of old lubricant before relubrication.
  • It can be used in conjunction with cutting oil as a thread cutting and reaming lubricant. When machining aluminium and its alloys, kerosene on its own is an excellent cutting lubricant.
  • Military applications—kerosene is a primary component in the explosive ANFO, which has widespread use in the mining and agricultural industries.
  • Kerosene-based diluent is commonly used as a component of the organic solvent in SX/EW copper refining.[23]
  • Hydrotreated kerosene can be used as a starting material to produce high purity linear paraffins which are subsequently dehydrogenated to linear olefins, and when the latter are reacted with benzene in the presence of a catalyst result in the production of linear alkyl benzene.
  • Kerosene is used as a lubricant for the cutting of glass. It prevents chipping of the glass as the cutting tool is drawn along the surface and it prevents the surface of the glass from resealing along the scored line which would cause an uneven and jagged cut.

Toxicity

Ingestion of kerosene is harmful or fatal.[24][25]

Retail cost

United States

In 2008, kerosene cost was $39.92 per million BTUs ($37.84/GJ) for heating.[26]

See also

Notes

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External links

zh-min-nan:Chhàu-iû ca:Querosè cs:Petrolej da:Petroleum de:Petroleum es:Queroseno eo:Keroseno fr:Kérosène hi:केरोसीन hr:Petrolej id:Minyak tanah it:Cherosene he:קרוסין hu:Petróleum nl:Kerosine ja:ケロシン no:Parafin nn:Parafin pl:Nafta pt:Querosene ro:Petrol lampant qu:Kirusini ru:Керосин scn:Cheroseni simple:Kerosene sk:Petrolej fi:Petroli sv:Fotogen ta:மண்ணெண்ணெய் th:น้ำมันก๊าด tr:Gaz yağı uk:Гас vi:Dầu hỏa yo:Kẹrosínì zh-yue:火水

zh:煤油
  1. Webster's New World College Dictionary, kerosene.
  2. Asbury, Herbert (1942). The golden flood: an informal history of America's first oil field. Alfred A. Knopf. p. 35. 
  3. Oxford English Dictionary, kerosene.
  4. Chris Collins (2007), “Implementing Phytoremediation of Petroleum Hydrocarbons, Methods in Biotechnology 23:99-108. Humana Press. ISBN 1588295419.
  5. "Kerosene". Retrieved 2009-06-10. 
  6. Lua error in package.lua at line 80: module 'Module:Citation/CS1/Suggestions' not found.
  7. Bilkadi, Zayn. "The Oil Weapons". Saudi Aramco World. 46 (1): 20–27. 
  8. 8.0 8.1 8.2 Russell, Loris S. (2003). A Heritage of Light: Lamps and Lighting in the Early Canadian Home. University of Toronto Press. ISBN 0802037658. 
  9. Black, Harry (1997). Canadian Scientists and Inventors. Pembroke Publishers. ISBN 1551380811. 
  10. World, American Manufacturer and Iron (1901). Greater Pittsburgh and Allegheny County, Past, Present, Future; The Pioneer Oil Refiner. The American Manufacturer and Iron World. 
  11. McInnis, Karen. "Kier, Samuel Martin- Bio". biography. The Pennsylvania State University. Retrieved 2008-12-12. 
  12. Harper, J. A. (1995). "Samuel Kier - Medicine Man & Refiner". Excerpt from Yo-Ho-Ho and a Bottle of Unrefined Complex Liquid Hydrocarbons. Pennsylvania Geology, v. 26, No. 1, p. Oil Region Alliance of Business, Industry & Tourism. Retrieved 2008-12-12. 
  13. Steil, Tim; Luning, Jim (2002). Fantastic Filling Stations. MBI Publishing. pp. 19–20. ISBN 0760310645. 
  14. Cooley, Le Roy Clark (1873). Elements of Chemistry: for Common and High Schools. Scribner, Armstrong. p. 98. 
  15. Crew, Benjamin Johnson; Ashburner, Charles Albert (1887). A Practical Treatise on Petroleum. Baird. p. 395. 
  16. Bettmann, Otto (1974). The Good Old Days & ndash; They Were Terrible!. Random House. p. 34. ISBN 9780394709413. 
  17. Bakrutan: "Saab 99 Petro" by Petri Tyrkös, nr 4, 2008
  18. Banse, Timothy (7 July 2010). "Kerosene Outboards: An Alternative Fuel?". Marine Engine Digest. 
  19. 19.0 19.1 Ebbing, D. D.; Gammon, S. D. (2005). General Chemistry (8th ed.). New York: Houghton Mifflin. 
  20. Kerosene blending, (pdf from EPA)
  21. How a Plan for Bus Fuel Grew Expensive, The New York Times, 2008-09-25.
  22. Bradsher, Keith (28 July 2008). "Fuel Subsidies Overseas Take a Toll on U.S." New York Times. 
  23. http://www.meab-mx.se/en/sx_principles.htm
  24. Lua error in package.lua at line 80: module 'Module:Citation/CS1/Suggestions' not found.
  25. Mahdi, Awad Hassan (1988). "Kerosene Poisoning in Children in Riyadh". Journal of Tropical Pediatrics. Oxford University Press. 34 (6): 316–318. doi:10.1093/tropej/34.6.316. PMID 3221417. Retrieved 1 December 2009. Radiological signs of pneumonia were shown in nine out of 27 patients who had chest X-rays. There was one death. 
  26. Ryan, Matt (June 20, 2008). "Homeowners seek cheaper winter heat". Burlington Free Press. Burlington, Vermont.