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1 на катоде
Русско-английский научно-технический словарь переводчика > на катоде
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2 на катоде
Русско-английский научно-технический словарь переводчика > на катоде
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3 Bacon, Francis Thomas
SUBJECT AREA: Aerospace[br]b. 21 December 1904 Billericay, Englandd. 24 May 1992 Little Shelford, Cambridge, England[br]English mechanical engineer, a pioneer in the modern phase of fuel-cell development.[br]After receiving his education at Eton and Trinity College, Cambridge, Bacon served with C.A. Parsons at Newcastle upon Tyne from 1925 to 1940. From 1946 to 1956 he carried out research on Hydrox fuel cells at Cambridge University and was a consultant on fuel-cell design to a number of organizations throughout the rest of his life.Sir William Grove was the first to observe that when oxygen and hydrogen were supplied to platinum electrodes immersed in sulphuric acid a current was produced in an external circuit, but he did not envisage this as a practical source of electrical energy. In the 1930s Bacon started work to develop a hydrogen-oxygen fuel cell that operated at moderate temperatures and pressures using an alkaline electrolyte. In 1940 he was appointed to a post at King's College, London, and there, with the support of the Admiralty, he started full-time experimental work on fuel cells. His brief was to produce a power source for the propulsion of submarines. The following year he was posted as a temporary experimental officer to the Anti-Submarine Experimental Establishment at Fairlie, Ayrshire, and he remained there until the end of the Second World War.In 1946 he joined the Department of Chemical Engineering at Cambridge, receiving a small amount of money from the Electrical Research Association. Backing came six years later from the National Research and Development Corporation (NRDC), the development of the fuel cell being transferred to Marshalls of Cambridge, where Bacon was appointed Consultant.By 1959, after almost twenty years of individual effort, he was able to demonstrate a 6 kW (8 hp) power unit capable of driving a small truck. Bacon appreciated that when substantial power was required over long periods the hydrogen-oxygen fuel cell associated with high-pressure gas storage would be more compact than conventional secondary batteries.The development of the fuel-cell system pioneered by Bacon was stimulated by a particular need for a compact, lightweight source of power in the United States space programme. Electro-chemical generators using hydrogen-oxygen cells were chosen to provide the main supplies on the Apollo spacecraft for landing on the surface of the moon in 1969. An added advantage of the cells was that they simultaneously provided water. NRDC was largely responsible for the forma-tion of Energy Conversion Ltd, a company that was set up to exploit Bacon's patents and to manufacture fuel cells, and which was supported by British Ropes Ltd, British Petroleum and Guest, Keen \& Nettlefold Ltd at Basingstoke. Bacon was their full-time consultant. In 1971 Energy Conversion's operation was moved to the UK Atomic Energy Research Establishment at Harwell, as Fuel Cells Ltd. Bacon remained with them until he retired in 1973.[br]Principal Honours and DistinctionsOBE 1967. FRS 1972. Royal Society S.G. Brown Medal 1965. Royal Aeronautical Society British Silver Medal 1969.Bibliography27 February 1952, British patent no. 667,298 (hydrogen-oxygen fuel cell). 1963, contribution in W.Mitchell (ed.), Fuel Cells, New York, pp. 130–92.1965, contribution in B.S.Baker (ed.), Hydrocarbon Fuel Cell Technology, New York, pp. 1–7.Further ReadingObituary, 1992, Daily Telegraph (8 June).A.McDougal, 1976, Fuel Cells, London (makes an acknowledgement of Bacon's contribution to the design and application of fuel cells).D.P.Gregory, 1972, Fuel Cells, London (a concise introduction to fuel-cell technology).GW -
4 Grove, Sir William Robert
SUBJECT AREA: Electricity[br]b. 11 July 1811 Swansea, Walesd. 1 August 1896 London, England[br]Welsh chemist and physicist, inventor of the Grove electrochemical primary cell.[br]After education at Brasenose College, Oxford, Grove was called to the Bar in 1835. Instead of immediately practising, he became involved in electrical research, devising in 1839 the cell that bears his name. He became Professor of Experimental Philosophy at the London Institution from 1840 to 1845; it was during this period that he built up his high reputation among physicists. In 1846 he published On the Correlation of Physical Forces, which was based on a course of his lectures. He returned to the practice of law, becoming a judge in 1871, but retained his interest in scientific research during his sixteen-year occupancy of the Bench. He served as a member of the Council of the Royal Society in 1846 and 1847 and played a leading part in its reform. Contributing to the science of electrochemistry, he invented the Grove cell, which together with its modification by Bunsen became an important source of electrical energy during the middle of the nineteenth century, before mechanically driven generators became available. The Grove cell had a platinum electrode immersed in strong nitric acid, separated by a porous diaphragm from a zinc electrode in weak sulphuric acid. The hydrogen formed at the platinum electrode was immediately oxidized by the acid, turning it into water. This avoided the polarization which occurred in the early copper-zinc cells. It was a very powerful primary cell with a high voltage and a low internal resistance, but it produced objectionable fumes. Grove also invented his "gas battery", the earliest fuel cell, in which a current resulted from the chemical energy released from combining oxygen and hydrogen. This was developed by Rawcliffe and others, and found applications as a power source in manned spacecraft.[br]Principal Honours and DistinctionsKnighted 1872. FRS 1840. Fellow of the Chemistry Society 1841. Royal Society Royal Medal 1847.Bibliography1846, On the Correlation of Physical Forces, London; 1874, 6th edn, with reprints of many of Grove's papers (his only book, an early view on the conservation of energy).1839, "On a small voltaic battery of great energy", Philosophical Magazine 15:287–93 (his account of his cell).Further ReadingObituary, 1896, Electrician 37:483–4.K.R.Webb, 1961, "Sir William Robert Grove (1811–1896) and the origin of the fuel cell", Journal of the Royal Institute of Chemistry 85: 291–3 (for the present-day significance of Grove's experiments).C.C.Gillispie (ed.), 1972, Dictionary of Scientific Biography, Vol. V, New York, pp. 559–61.GWBiographical history of technology > Grove, Sir William Robert
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5 Yost, Paul Edward
SUBJECT AREA: Aerospace[br]b. 30 June 1919 Bristow, Iowa, USA[br]American designer of balloons who reintroduced the hot-air balloon.[br]After the early hot-air balloons of the Montgolfier brothers in the 1780s, this branch of ballooning was superseded by hydrogen, coal gas and helium balloons. Following the research by Auguste Piccard into cosmic radiation during the 1930s, a renewed interest in this branch of research arose in the United States from 1947 onwards, using helium-filled balloons. Modern plastics were available by this time, and polythene was used for the envelopes.Paul E.Yost developed an improved form of envelope using nylon fabric laminated with mylar plastic film. This provided a strong impermeable material that was ideal for balloons. Using this material for the envelope, Yost produced the Vulcoon in 1960. He also reintroduced the use of hot air to inflate his balloon and developed an easily controlled gas burner fuelled by propane gas, which was readily available in cylinders for portable cooking stoves. Yost's company, Raven Industries, developed these very basic balloons as a military project. The pilot was suspended in a sling, but they improved the design by fitting wicker or aluminium baskets and turned to a market in the field of sport. After a slow start, hot-air ballooning became popular as a sport. In 1963 Yost made the first crossing of the English Channel in a hot-air balloon, accompanied by Donald Piccard, nephew of the balloonist Auguste Piccard, and Charles Dollfus, the eminent French aviation historian. Yost's attempt to cross the Atlantic in his balloon Silver Fox during 1976 failed and he was rescued from the sea near the Azores. The popularity of hot-air ballooning increased during the 1970s, and evolved into a very original form of advertising with unusual shapes for the envelopes, including a house, a bottle and an elephant.JDS -
6 engine
двигатель; мотор; машинаbuzz up an engine — жарг. запускать двигатель
clean the engine — прогазовывать [прочищать] двигатель (кратковременной даней газа)
engine of bypass ratio 10: 1 — двигатель с коэффициентом [степенью] двухконтурности 10:1
flight discarded jet engine — реактивный двигатель, отработавший лётный ресурс
kick the engine over — разг. запускать двигатель
lunar module ascent engine — подъёмный двигатель лунного модуля [отсека]
monofuel rocket engine — ЖРД на однокомпонентном [унитарном] топливе
open the engine up — давать газ, увеличивать тягу или мощность двигателя
prepackaged liquid propellant engine — ЖРД на топливе длительного хранения; заранее снаряжаемый ЖРД
production(-standard, -type) engine — серийный двигатель, двигатель серийного образца [типа]
return and landing engine — ксм. двигатель для возвращения и посадки
reversed rocket engine — тормозной ракетный двигатель; ксм. тормозная двигательная установка
run up the engine — опробовать [«гонять»] двигатель
secure the engine — выключать [останавливать, глушить] двигатель
shut down the engine — выключать [останавливать, глушить] двигатель
shut off the engine — выключать [останавливать, глушить] двигатель
solid(-fuel, -grain) rocket engine — ракетный двигатель твёрдого топлива
turn the engine over — проворачивать [прокручивать] двигатель [вал двигателя]
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7 Cecil, Revd William
SUBJECT AREA: Steam and internal combustion engines[br]b. 1792 Englandd. 1882 England[br]English inventor of a gas vacuum engine.[br]Admitted to Magdalene College, Cambridge, in 1810, Cecil was elected a Fellow in 1814. The son of an Anglican priest, he was himself ordained in 1820; he devoted his life to the Church of England, but he also showed a commendable aptitude for technical matters. His paper on a means of motive power, presented to the Cambridge Philosophical Society in 1820, created immense interest. A working model of his engine, using hydrogen as fuel, was demonstrated during the presentation. The operating principle required that a vacuum be produced in a closed cylinder by quenching a burning flame, the pressure difference between the vacuum and atmosphere then being used to produce the working stroke. Cecil's engine was never manufactured in any number, but the working principle was adapted by other pioneers, namely Samuel Brown, in 1824, and, more successfully, Otto- Langen in 1867.[br]Bibliography1820, "On the application of hydrogen gas to produce a moving power in machinery", Transactions of the Cambridge Philosophical Society 1(2):217–39.Further ReadingJohn Venn, Alumni Cantabrienses Part II (1752–1900): p. 567.KAB -
8 Bergius, Friedrich Carl Rudolf
[br]b. 11 October 1884 Goldschmieden, near Breslau, Germanyd. 31 March Buenos Aires, Argentina[br][br]After studying chemistry in Breslau and Leipzig and assisting inter alia at the institute of Fritz Haber in Karlsruhe on the catalysis of ammonia under high pressure, in 1909 he went to Hannover to pursue his idea of turning coal into liquid hydrocarbon under high hydrogen pressure (200 atm) and high temperatures (470° C). As experiments with high pressure in chemical processes were still in their initial stages and the Technical University could not support him sufficiently, he set up a private laboratory to develop the methods and to construct the equipment himself. Four years later, in 1913, his process for producing liquid or organic compounds from coal was patented.The economic aspects of this process were apparent as the demand for fuels and lubricants increased more rapidly than the production of oil, and Bergius's process became even more important after the outbreak of the First World War. The Th. Goldschmidt company of Essen contracted him and tried large-scale production near Mannheim in 1914, but production failed because of the lack of capital and experience to operate with high pressure on an industrial level. Both capital and experience were provided jointly by the BASF company, which produced ammonia at Merseburg, and IG Farben, which took over the Bergius process in 1925, the same year that the synthesis of hydrocarbon had been developed by Fischer-Tropsch. Two years later, at the Leuna works, almost 100,000 tonnes of oil were produced from coal; during the following years, several more hydrogenation plants were to follow, especially in the eastern parts of Germany as well as in the Ruhr area, while the government guaranteed the costs. The Bergius process was extremely important for the supply of fuels to Germany during the Second World War, with the monthly production rate in 1943–4 being more than 700,000 tonnes. However, the plants were mostly destroyed at. the end of the war and were later dismantled.As a consequence of this success Bergius, who had gained an international reputation, went abroad to work as a consultant to several foreign governments. Experiments aiming to reduce the costs of production are still continued in some countries. By 1925, after he had solved all the principles of his process, he had turned to the production of dextrose by hydrolyzing wood with highly concentrated hydrochloric acid.[br]Principal Honours and DistinctionsNobel Prize 1931. Honorary doctorates, Heidelberg, Harvard and Hannover.Bibliography1907, "Über absolute Schwefelsäure als Lösungsmittel", unpublished thesis, Weida. 1913, Die Anwendung hoher Drucke bei chemischen Vorgängen und eine Nachbildungdes Entstehungsprozesses der Steinkohle, Halle. 1913, DRP no. 301, 231 (coal-liquefaction process).1925, "Verflüssigung der Kohle", Zeitschrift des Vereins Deutscher Ingenieure, 69:1313–20, 1359–62.1933, "Chemische Reaktionen unter hohem Druck", Les Prix Nobel en 1931, Stockholm, pp. 1–37.Further ReadingDeutsches Bergbau-Museum, 1985, Friedrich Bergius und die Kohleverflüssigung. Stationen einer Entwicklung, Bochum (gives a comprehensive and illustrated description of the man and the technology).H.Beck, 1982, Friedrich Bergius, ein Erfinderschicksal, Munich: Deutsches Museum (a detailed biographical description).W.Birkendfeld, 1964, Der synthetische Treibstoff 1933–1945. Ein Beitragzur nationalsozialistischen Wirtschafts-und Rüstungspolitik, Göttingen, Berlin and Frankfurt (describes the economic value of synthetic fuels for the Third Reich).WKBiographical history of technology > Bergius, Friedrich Carl Rudolf
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9 oil
1. нефть || нефтяной2. масло ( растительное или минеральное) || масляный3. жидкая смазка, смазочное масло || смазыватьoil struck at... — нефть встречена на глубине...
— hot oil— base oil— cut oil— dead oil— form oil— fuel oil— lean oil— live oil— load oil— lock oil— net oil— oil in— raw oil— rich oil— rock oil— seep oil— sour oil— tank oil— tar oil— wet oil
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нефть (все жидкие углеводороды, получаемые из скважин, и конденсаты, извлекаемые из природного газа)pipeline quality crude oil — нефть, соответствующая требованиям транспортирования по трубопроводу (упругость паров по Рейду в подвижном состоянии -100)
tanker specification crude oil — нефть, соответствующая требованиям транспортирования танкерами (упругость паров по Рейду в подвешенном состоянии -10)
to hold back oil in the reservoir — удерживать нефть в коллекторе;
— bad oil— base oil— cut oil— dead oil— dry oil— dump oil— fuel oil— hot oil— live oil— load oil— raw oil— rock oil— sour oil— tank oil— wet oil— wild oil
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1. нефть
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нефть (<<жидкие углеводороды, извлекаемые из природного газа) || нефтянойoil in bulk — 1) нефть наливом; нефтепродукты наливом 2) нефть в резервуаре;
oil in hole — нефть в стволе скважины;
oil in place — нефть в пласте; пластовая нефть; нефть, предположительно находящаяся в коллекторе;
oil in reserve — 1) нефть, заполняющая трубопроводы и резервуары 2) нефтепродукт, заполняющий систему заводских резервуаров и трубопроводов;
oil in sight — видимые запасы нефти;
oil in situ — нефть в пласте;
oil in storage — 1) нефть в трубопроводах 2) избыточная ( не отправленная потребителям) нефть на нефтебазах;
oil initially in place — первоначальные запасы нефти в коллекторе;
oil originally in reservoir — начальное содержание нефти в пласте;
to carry oil — содержать нефть;
to flood oil toward production well — вытеснять нефть ( водой) к добывающей скважине;
to hold back oil in the reservoir — удерживать нефть в коллекторе;
to make oil — добывать нефть;
to run the oil — 1) измерять количество нефти в промысловых резервуарах 2) перекачивать нефть из промысловых резервуаров по трубопроводу;
to skim off oil — собирать нефть, разлившуюся на поверхности воды;
to strike oil — обнаруживать месторождение нефти;
- oil of paraffinoil to surface — нефть, поступающая на поверхность;
- abandoned oil
- absorbent oil
- adsorbed oil
- absorption oil
- acid oil
- acid-refined oil
- acid-stage oil
- additive blended oil
- additive motor oil
- additive treated oil
- additive-type oil
- admiralty fuel oil
- aeroengine oil
- air filter oil
- aircraft oil
- airplane oil
- all-purpose engine oil
- alpha oil
- American paraffin oil
- Appalachian oil
- aqueous-soluble oil
- Arctic oil
- aromatic-base crude oil
- asphalt-base oil
- asphalt-free oil
- asphaltic road oil
- asphaltum oil
- automobile oil
- average-quality oil
- axle oil
- bad oil
- base oil
- batch oil
- Beaumont oil
- bentonite diesel oil
- benzolized oil
- benzyl mustard oil
- black oil
- blasting oil
- blended fuel oil
- blue oil
- bobbin oil
- bodied oil
- boiler oil
- branded oil
- break-in oil
- bright oil
- bubble point oil
- burner oil
- burning oil
- by-passed oil
- capacitor oil
- car oil
- carbon oil
- cargo oil
- catalytic gas oil
- circuit-breaker oil
- clay-filtered oil
- clean oil
- cleaning oil
- cleansing oil
- coal oil
- coastal oil
- coker gas oil
- cold-settled oil
- cold-test oil
- commercial oil
- compressor oil
- concrete form oil
- condensed oil
- condenser oil
- conventional oil
- cordage oil
- corrected oil
- crankcase oil
- crevice oil
- crude oil
- crude mineral oil
- crude petroleum fuel oil
- crude shale oil
- crystal oil
- cut oil
- cutter oil
- cutting oil
- cycle oil
- cycle gas oil
- cylinder oil
- dangerous oil
- dead oil
- debenzolized oil
- degassed oil
- denuded oil
- desalinized oil
- development oil
- dielectrical oil
- diesel oil
- diesel-fuel oil
- dispersed oil
- dissolved oil
- distillate oil
- distillate fuel oil
- domestic oil
- doped oil
- dry oil
- dual-purpose oil
- dump oil
- earth oil
- economically recoverable oil
- electrical switch oil
- emulsified crude oil
- emulsion oil
- engine oil
- enriched oil
- entrained oil
- equilibrium oil
- estimated original oil in place
- explosive oil
- extra-heavy crude oil
- first-quality oil
- fluid oil
- flush oil
- fluxing oil
- foam oil
- foot's oil
- foreign oil
- form oil
- fossil oil
- free oil
- fuel oil
- furnace oil
- gaged oil
- gas oil
- gas absorber oil
- gas and mud-cut oil
- gas-cut oil
- gas-cut load oil
- gear oil
- gearbox oil
- gearcase oil
- gelled oil
- graphite lubrication oil
- grease oil
- grease-spoiled oil
- green bloom oil
- green cast oil
- hard oil
- heating oil
- heavy oil
- heavy-cycle gas oil
- heavy-duty supplement oil
- heavy gas oil
- heavy lubricating oil
- heavy neutral oil
- high-gravity oil
- high-pour-point oil
- high-pour-test oil
- high-pressure oil
- high-temperature shale oil
- highly detergent oil
- highly refined oil
- highly resinous oil
- hot oil
- hybrid-base oil
- hydraulic oil
- hydraulic system oil
- hydrocarbon oils
- hydrofined oil
- hydrogen-deficient gas oil
- illuminating oil
- imported oil
- inactive oil
- incremental oil
- industrial white oil
- initial oil in place
- initial oil in reservoir
- in-place oil
- inspissated oil
- instrument oil
- insulating oil
- intermediate oil
- irreducible oil
- kerosene oil
- lake oil
- lamp oil
- lean oil
- lease oil
- light oil
- light crude oil
- light cycle gas oil
- light engine oil
- light fuel oil
- light gas oil
- light viscosity oil
- lightwood oil
- limestone oil
- live oil
- livered oil
- load oil
- lock oil
- long-time burning oil
- loom oil
- low-gravity oil
- low-viscosity oil
- lubricating oil
- machinery oil
- make-up oil
- marine oil
- marine engine oil
- merchantable oil
- middle oil
- Middle East oil
- migratory oil
- mineral oil
- mineral earth oil
- mineral seal oil
- miner's oil
- mixed asphaltic base oil
- mixed-base oil
- mother oil
- motor oil
- moveable oil
- mud oil
- mud-cut oil
- multigrade oil
- noncongealable oil
- nondrying oil
- opal oil
- naphthalene oil
- naphthene oil
- natural oil
- net oil
- net residual oil
- nonabsorbent oil
- nonfoaming oil
- nonrecoverable oil
- nonresinous oil
- nonsulfurous oil
- occluded oil
- offshore oil
- original oil in place
- original stock tank oil in place
- oxydized oil
- oxygenated oil
- pale oil
- paraffin-base oil
- paraffin-base crude oil
- paraffinic oil
- pattern oil
- penetrating oil
- petrolatum oil
- petroleum fuel oil
- petroleum gas oil
- pilot oil
- piped oil
- pipeline oil
- pipeline quality crude oil
- polybase oil
- power oil
- primary oil
- produced oil
- prospective oil
- pumping load oil
- pure oil
- range oil
- raw oil
- recirculating oil
- reclaimed lubricating oil
- recoverable oil
- recovered oil
- red oil
- reduced oil
- reduced fuel oil
- refined oil
- residual oil
- retained oil
- returning circulation oil
- rich oil
- road oil
- rock oil
- roily oil
- rustproof oil
- saturated oil
- scavenge oil
- scrubbing oil
- secondary oil
- seep oil
- selective solvent-extracted oil
- selective solvent-refined oil
- separator oil
- service DG oil
- service DM oil
- service DS oil
- service ML oil
- service MM oil
- service MS oil
- shafting oil
- shale oil
- Sherwood oil
- short oil
- shrinked oil
- skunk oil
- slightly gas-cut oil
- sludge oil
- slurry oil
- slush oil
- slushing oil
- solar oil
- solid oil
- solidified oil
- soluble oil
- sorbed oil
- sour oil
- spindle oil
- steam-distillable oil
- steam-refined oil
- stock-tank oil
- stock-tank oil in place
- stoker's oil
- stone oil
- stove oil
- straight mineral oil
- straw oil
- stripped oil
- stripping oil
- subzero oil
- sulfonated oil
- sulfur-bearing oil
- sulfurous oil
- summer oil
- surplus oil
- sweat oil
- sweet oil
- switch oil
- tank oil
- tanker specification crude oil
- tar oil
- tarry oil
- tertiary oil
- thin oil
- thinned oil
- topped oil
- torch oil
- tractor oil
- transformer oil
- trapped oil
- trimming oil
- trolly oil
- turkey-red oil
- undiluted engine oil
- univis oil
- unrecovered oil
- unrefinable oil
- unrefinable crude oil
- unstripped oil
- untreated oil
- vaporizing oil
- vulcan oil
- washed blue oil
- waste oil
- water-cut oil
- watered oil
- watery oil
- wax oil
- wet oil
- white oil
- wild oil
- winter oil
- wirerope oil* * *• нефть• нефтяной -
10 gas
1. газ, газообразное вещество || выделять газ; наполнять газом, насыщать газом2. горючее; газолин; бензин || заправлять горючим— acid gas— dry gas— end gas— exit gas— fat gas— flue gas— free gas— fuel gas— lean gas— net gas— oil gas— rich gas— rock gas— sour gas— town gas— trip gas— wet gas
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high altitude liquid petroleum gas — сжиженный нефтяной газ с повышенным содержанием бутана (для применения в условиях пониженного атмосферного давления)
— dry gas— foul gas— lean gas— lift gas— oil gas— rich gas— rock gas— sour gas— tank gas— wet gas
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1. газ2. горючее, бензин
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1) газ, газообразное вещество || выделять газ; наполнять газом, насыщать газом2) горючее; газолин; бензин || заправлять горючим•gas in place — запасы газа в коллекторе;
gas in reservoir — пластовой газ;
gas in-situ — газ в пластовых условиях;
gas in solution — растворённый газ;
no gas to surface — газ на поверхность не поступает;
gas originally in place — первоначальные запасы газа в коллекторе;
to boost gas along to its destination — повышать давление газа для доставки его к месту назначения;
to make the gas — выделять газ;
to sweeten gas — удалять из газа соединения серы;
- gas of radiation-chemical originto take-off casing-head gas — отбирать нефтяной газ на устье скважины;
- gas of stratal water
- absorbed gas
- accompanying gas
- acid gas
- active gas
- actual gas
- adsorbed gas
- aerogen gas
- air gas
- air-free gas
- air-producer gas
- alky gas
- all-weather liquefied petroleum gas
- ammonia synthesis gas
- annular gas
- artificial gas
- associated gas
- associated dissolved gas
- associated petroleum gas
- aviation gas
- background gas
- biochemical natural gas
- blanket gas
- blowdown gas
- blue gas
- bottled gas
- Braden head gas
- burned gas
- burning gas
- butane-enriched water gas
- butane-propane gas
- by-product gas
- cap gas
- carbon-dioxide gas
- carbureted gas
- carbureted hydrogen gas
- carbureted water gas
- carrier gas
- casing-head gas
- city gas
- coercible gas
- coke oven gas
- combination gas
- combustible gas
- combustion gas
- commercial gas
- commercial rock gas
- compressed gas
- compressed natural gas
- condensed gas
- condensed natural gas
- conditioned gas
- consumer gas
- conventional gas
- converted gas
- corrosive gas
- crude gas
- cumulative gas injected
- cushion gas
- cylinder gas
- dehydrated petroleum gas
- diluted gas
- dispersed gas
- dissolved gas
- distillation gas
- domestic gas
- drive gas
- dry gas
- dry petroleum gas
- dump gas
- end gas
- enriched gas
- entrained gas
- escaping gas
- exhaust gas
- exit gas
- expansion gas
- extraneous gas
- extremely dry gas
- fat gas
- filtered flue gas
- fire gas
- fixed gas
- flammable gas
- flare gas
- flash gas
- flue gas
- fluorocarbon gas
- flush gas
- formation gas
- formation water gas
- foul gas
- free gas
- fuel gas
- full-stream gas
- fume-laden gas
- furnace gas
- gaslift gas
- gas-well gas
- green gas
- heating gas
- helium-bearing natural gas
- high gas
- high-altitude liquid petroleum gas
- high-BTU gas
- high-calorific gas
- high-line gas
- highly corrosive gas
- high-pressure gas
- high-purity gas
- household fuel gas
- humid gas
- hydrocarbon gas
- ideal gas
- illuminating gas
- immobile gas
- imperfect gas
- imported gas
- inactive gas
- included gas
- incoming gas
- indifferent gas
- industrial gas
- inert gas
- inflammable gas
- initial gas in reservoir
- injected gas
- in-place petroleum gas
- ionized gas
- kerosene gas
- kiln gas
- lean gas
- lean petroleum gas
- liberated gas
- lift gas
- lighting gas
- liquefied gas
- liquefied hydrocarbon gas
- liquefied natural gas
- liquefied petroleum gas
- liquid gas
- liquid natural gas
- liquid petroleum gas
- live gas
- low-boiling gas
- low-calorific gas
- low-pressure petroleum gas
- low-thermal-value fuel gas
- makeup gas
- manufactured gas
- manure gas
- marsh gas
- medium-energy coal-derived gas
- metamorphic natural gas
- methane-rich gas
- mixed gas
- mud gas
- naphtha gas
- native gas
- natural gas
- net gas
- noble gas
- nonassociated gas
- nonassociated natural gas
- noncondensable gas
- noncorrosive gas
- nonhydrocarbon gas
- nonpurified gas
- nonrecoverable gas
- nonstripped petroleum gas
- noxious gas
- occluded gas
- off gas
- oil gas
- oil-dissolved gas
- oil-water gas
- oil-well gas
- olefiant gas
- onboard-stored gas
- oxyhydrogen gas
- paraffin gas
- peat gas
- perfect gas
- petroleum gas
- pipeline gas
- poor gas
- power gas
- processed gas
- produced gas
- producer gas
- product gas
- purchased gas
- purge gas
- radiogenic gas
- purifield gas
- quenching gas
- radioactive gas
- radon gas
- raw natural gas
- reactivation gas
- receiver gas
- recirculated gas
- recoverable gas
- recoverable petroleum gas
- refinery gas
- regeneration gas
- residual gas
- residue gas
- retained gas
- rich gas
- rich petroleum gas
- rock gas
- sales gas
- sedimentary natural gas
- separator gas
- shale gas
- shallow gas
- shocked gas
- sludge gas
- solute gas
- solution gas
- sour gas
- sour petroleum gas
- spent gas
- stabilizer gas
- stack gas
- stillage gas
- stripped gas
- stripped petroleum gas
- stripper gas
- substitute natural gas
- sulfur dioxide gas
- sulfurous gas
- sweet gas
- synthetic gas
- tail gas
- tank gas
- town gas
- toxic gas
- transborder gas
- transcontinental gas
- transported gas
- trapped gas
- treated gas
- trip gas
- unassociated gas
- underground storage gas
- undissolved gas
- unstripped gas
- vadose gas
- washed gas
- waste gas
- water gas
- water-dissolved gas
- well head gas
- wet gas
- wet field gas
- wet petroleum gas
- zero-hydrogen-index gas* * * -
11 Giffard, Baptiste Henry Jacques (Henri)
[br]b. 8 February 1825 Paris, Franced. 14 April 1882 Paris, France[br]French pioneer of airships and balloons, inventor of an injector for steam-boiler feedwater.[br]Giffard entered the works of the Western Railway of France at the age of 16 but became absorbed by the problem of steam-powered aerial navigation. He proposed a steam-powered helicopter in 1847, but he then turned his attention to an airship. He designed a lightweight coke-burning, single-cylinder steam engine and boiler which produced just over 3 hp (2.2 kW) and mounted it below a cigar-shaped gas bag 44 m (144 ft) in length. A triangular rudder was fitted at the rear to control the direction of flight. On 24 September 1852 Giffard took off from Paris and, at a steady 8 km/h (5 mph), he travelled 28 km (17 miles) to Trappes. This can be claimed to be the first steerable lighter-than-air craft, but with a top speed of only 8 km/h (5 mph) even a modest headwind would have reduced the forward speed to nil (or even negative). Giffard built a second airship, which crashed in 1855, slightly injuring Giffard and his companion; a third airship was planned with a very large gas bag in order to lift the inherently heavy steam engine and boiler, but this was never built. His airships were inflated by coal gas and refusal by the gas company to provide further supplies brought these promising experiments to a premature end.As a draughtsman Giffard had the opportunity to travel on locomotives and he observed the inadequacies of the feed pumps then used to supply boiler feedwater. To overcome these problems he invented the injector with its series of three cones: in the first cone (convergent), steam at or below boiler pressure becomes a high-velocity jet; in the second (also convergent), it combines with feedwater to condense and impart high velocity to it; and in the third (divergent), that velocity is converted into pressure sufficient to overcome the pressure of steam in the boiler. The injector, patented by Giffard, was quickly adopted by railways everywhere, and the royalties provided him with funds to finance further experiments in aviation. These took the form of tethered hydrogen-inflated balloons of successively larger size. At the Paris Exposition of 1878 one of these balloons carried fifty-two passengers on each tethered "flight". The height of the balloon was controlled by a cable attached to a huge steam-powered winch, and by the end of the fair 1,033 ascents had been made and 35,000 passengers had seen Paris from the air. This, and similar balloons, greatly widened the public's interest in aeronautics. Sadly, after becoming blind, Giffard committed suicide; however, he died a rich man and bequeathed large sums of money to the State for humanitarian an scientific purposes.[br]Principal Honours and DistinctionsCroix de la Légion d'honneur 1863.Bibliography1860, Notice théorique et pratique sur l'injecteur automoteur.1870, Description du premier aérostat à vapeur.Further ReadingDictionnaire de biographie française.Gaston Tissandier, 1872, Les Ballons dirigeables, Paris.—1878, Le Grand ballon captif à vapeur de M. Henri Giffard, Paris.W.de Fonvielle, 1882, Les Ballons dirigeables à vapeur de H.Giffard, Paris. Giffard is covered in most books on balloons or airships, e.g.: Basil Clarke, 1961, The History of Airships, London. L.T.C.Rolt, 1966, The Aeronauts, London.Ian McNeill (ed.), 1990, An Encyclopaedia of the History of Technology, London: Routledge, pp. 575 and 614.J.T.Hodgson and C.S.Lake, 1954, Locomotive Management, Tothill Press, p. 100.PJGR / JDSBiographical history of technology > Giffard, Baptiste Henry Jacques (Henri)
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12 Goddard, Dr Robert Hutchings
SUBJECT AREA: Aerospace[br]b. 5 October 1882 Worcester, Massachusetts, USAd. 10 August 1945 Baltimore, Maryland, USA[br]American inventory developer of rocket propulsion.[br]At the age of seventeen Goddard climbed a tree and, seeing the view from above, he became determined to make some device with which to ascend towards the planets. In an autobiography, published in 1959 in the journal Astronautics, he stated, "I was a different boy when I descended the ladder. Life now had a purpose for me." His first idea was to launch a projectile by centrifugal force, but in 1909 he started to design a rocket that was to be multi-stage and fuelled by liquid oxygen and hydrogen. Not long before the First World War he produced a report, "A method of reaching extreme altitudes", which was for the Smithsonian Institution and was published in book form in 1919. During the war he worked on solid-fuelled rockets as weapons. His book contained notes on the amount of fuel required to raise 1 lb (454 g) of payload to an infinite altitude. He incurred ridicule as "the moon man" when he proposed the use of flash powder to indicate successful arrival on the moon. In 1923 he severed his connections with military work and returned to the University of Massachusetts. On 16 March 1926 he launched the world's first liquid-fuelled rocket from his aunt's farm in Auburn, Massachusetts; powered by gasoline and liquid oxygen, it flew to a height of 12 m (40 ft) and travelled 54 m (177 ft) in 2.4 seconds.In November 1929 he met the aviator Charles Lindbergh, who persuaded both the Guggenheim Foundation and the Carnegie Institute to support Goddard's experiments financially. He moved to the more suitable location of the Mescalere Ranch, near Roswell, New Mexico, where he worked until 1941. His liquid-fuelled rockets reached speeds of 1,100 km/h (700 mph) and heights of 2,500 m (8,000ft). He investigated the use of the gyroscope to steady his rockets and the assembly of power units in clusters to increase the total thrust. In 1941 he moved to the naval establishment at Annapolis, Maryland, working on liquid-fuelled rockets to assist the take-off of aircraft from carriers. He worked for the US Government on this and the development of military rockets until his death from throat cancer in 1945. In all, he was granted 214 patents, roughly three per year of his life.In 1960 the US Government admitted infringement of Goddard's patents during the rocket programme of the 1950s and awarded his widow a payment of $1,000,000, while the National Aeronautics and Space Administration (NASA) honoured him by naming the Goddard Spaceflight Center near Washington, DC, after him. The Goddard Memorial Library at Clark University, in his home town of Worcester, Massachusetts, was also named in his honour.[br]Further ReadingA.Osman, 1983, Space History, London: Michael Joseph. P.Marsh, 1985, The Space Business, Harmondsworth: Penguin.K.C.Parley, 1991, Robert H.Goddard, Englewood Cliffs, NJ: Silver Burdett Press. T.Streissguth, 1994, Rocket Man: The Story of Robert Goddard, Minneapolis: Carolrhoda Books.IMcNBiographical history of technology > Goddard, Dr Robert Hutchings
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13 когда
•The fuel material is cooled as (or while, or when) it passes down through the steam generator.
•Once these operating requirements have been established, the engineer should consult a porcelain enameller.
•Where really large moulds are to be produced, a vertical band saw can be used advantageously.
* * *Когда -- when, where; once (как только); as (по мере того как; если); at the time, while (в то время, когда)Where fatigue is a consideration, peak stresses will have to be compared with allowable values.Once the vapor reaches the atmosphere, however, it condenses on solid particles.As hydrogen content is reduced below the currently typical value of 14 percent, there is a pronounced increase in linear temperatures.At the time it started its cost reduction program, the company was in financial difficulty.Do not attempt to dismantle the decanter while the drum is rotating.Русско-английский научно-технический словарь переводчика > когда
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14 образовываться
•Neutrons are generated by the reaction between...
•A potential difference is set up at the membrane.
•When hydrogen sulphate is passed into cold concentrated nitric acid, considerable heat is developed.
•A laminar layer builds up (or is built up, or forms) near the leading edge.
•If a defect should develop in the cladding,...
•Too hard a wheel develops a smooth, glazed surface that will not cut.
•The West Antarctica ice mass originated as two separate icecaps.
•As a result, a black precipitate of silver nitride is produced.
•A fog may appear in the gas if condensation nuclei are present.
Русско-английский научно-технический словарь переводчика > образовываться
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15 геотермальная энергия
геотермальная энергия
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[ http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]EN
geothermal energy
An energy produced by tapping the earth's internal heat. At present, the only available technologies to do this are those that extract heat from hydrothermal convection systems, where water or steam transfer the heat from the deeper part of the earth to the areas where the energy can be tapped. The amount of pollutants found in geothermal vary from area to area but may contain arsenic, boron, selenium, lead, cadmium, and fluorides. They also may contain hydrogen sulphide, mercury, ammonia, radon, carbon dioxide, and methane. (Source: KOREN)
[http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]Тематики
EN
DE
FR
Русско-немецкий словарь нормативно-технической терминологии > геотермальная энергия
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16 énergie géothermique
геотермальная энергия
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[ http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]EN
geothermal energy
An energy produced by tapping the earth's internal heat. At present, the only available technologies to do this are those that extract heat from hydrothermal convection systems, where water or steam transfer the heat from the deeper part of the earth to the areas where the energy can be tapped. The amount of pollutants found in geothermal vary from area to area but may contain arsenic, boron, selenium, lead, cadmium, and fluorides. They also may contain hydrogen sulphide, mercury, ammonia, radon, carbon dioxide, and methane. (Source: KOREN)
[http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]Тематики
EN
DE
FR
Франко-русский словарь нормативно-технической терминологии > énergie géothermique
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17 Erdwärme
геотермальная энергия
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[ http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]EN
geothermal energy
An energy produced by tapping the earth's internal heat. At present, the only available technologies to do this are those that extract heat from hydrothermal convection systems, where water or steam transfer the heat from the deeper part of the earth to the areas where the energy can be tapped. The amount of pollutants found in geothermal vary from area to area but may contain arsenic, boron, selenium, lead, cadmium, and fluorides. They also may contain hydrogen sulphide, mercury, ammonia, radon, carbon dioxide, and methane. (Source: KOREN)
[http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]Тематики
EN
DE
FR
Немецко-русский словарь нормативно-технической терминологии > Erdwärme
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18 геотермальная энергия
геотермальная энергия
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[ http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]EN
geothermal energy
An energy produced by tapping the earth's internal heat. At present, the only available technologies to do this are those that extract heat from hydrothermal convection systems, where water or steam transfer the heat from the deeper part of the earth to the areas where the energy can be tapped. The amount of pollutants found in geothermal vary from area to area but may contain arsenic, boron, selenium, lead, cadmium, and fluorides. They also may contain hydrogen sulphide, mercury, ammonia, radon, carbon dioxide, and methane. (Source: KOREN)
[http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]Тематики
EN
DE
FR
Русско-английский словарь нормативно-технической терминологии > геотермальная энергия
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19 геотермальная энергия
геотермальная энергия
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[ http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]EN
geothermal energy
An energy produced by tapping the earth's internal heat. At present, the only available technologies to do this are those that extract heat from hydrothermal convection systems, where water or steam transfer the heat from the deeper part of the earth to the areas where the energy can be tapped. The amount of pollutants found in geothermal vary from area to area but may contain arsenic, boron, selenium, lead, cadmium, and fluorides. They also may contain hydrogen sulphide, mercury, ammonia, radon, carbon dioxide, and methane. (Source: KOREN)
[http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]Тематики
EN
DE
FR
Русско-французский словарь нормативно-технической терминологии > геотермальная энергия
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20 geothermal energy
геотермальная энергия
—
[ http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]EN
geothermal energy
An energy produced by tapping the earth's internal heat. At present, the only available technologies to do this are those that extract heat from hydrothermal convection systems, where water or steam transfer the heat from the deeper part of the earth to the areas where the energy can be tapped. The amount of pollutants found in geothermal vary from area to area but may contain arsenic, boron, selenium, lead, cadmium, and fluorides. They also may contain hydrogen sulphide, mercury, ammonia, radon, carbon dioxide, and methane. (Source: KOREN)
[http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]Тематики
EN
DE
FR
Англо-русский словарь нормативно-технической терминологии > geothermal energy
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