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101 pump
1) насос, помпа2) водочерпалка3) качать; нагнетать; накачивать•- air pump- gas pump- mud pump- oil-vapor vacuum pump -
102 conditioning
4) выдержка (напр. древесины)5) пищ. приведение ( продукта) в соответствие с нормами6) пищ. отволаживание8) (предварительное) формирование (напр. сигнала)•-
air conditioning
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air-cycle air conditioning
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borehole conditioning
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circuit conditioning
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drilling mud conditioning
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feed-water conditioning
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heat pump air conditioning
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high-pressure air conditioning
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hot conditioning
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ingot conditioning
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line conditioning
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lithium bromide air conditioning
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low-pressure air conditioning
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mechanical air conditioning
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mine air conditioning
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reciprocating air conditioning
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sand conditioning
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signal conditioning
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solar-assisted comfort conditioning
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sound conditioning
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spectral conditioning
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steel conditioning
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thermoelectric air conditioning
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water conditioning
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well conditioning -
103 скважина с высоким пластовым давлением
1) Oil: high-pressure hole2) Oil&Gas technology abnormal-pressure wellУниверсальный русско-английский словарь > скважина с высоким пластовым давлением
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104 chamber
1) камера (1. помещение специального назначения 2. замкнутый объём; замкнутая полость 3. название ряда измерительных приборов и приборов для научных исследований с рабочим телом внутри замкнутой полости) || камерный3) отсек; секция•- acceleration chamber
- acoustic chamber
- air-equivalent ionization chamber
- air-wall ionization chamber
- air-filled chamber
- alpha chamber
- altitude chamber
- anechoic chamber
- back-to-back ionization chamber
- boron chamber
- boron-lined ionization chamber
- Bragg-Gray cavity ionization chamber
- bubble chamber
- burn-in chamber
- capacitor ionization chamber
- chromatographic chamber
- climatic chamber
- cloud chamber
- coating chamber
- compensated ionization chamber
- counting ionization chamber
- current ionization chamber
- deposition chamber
- differential ionization chamber
- diffusion chamber
- diffusion cloud chamber
- echo chamber
- electron-collection pulse chamber
- environmental chamber
- evacuated chamber
- evaporation chamber
- exhaust chamber
- expansion chamber
- expansion cloud chamber
- extrapolation ionization chamber
- fission ionization chamber
- fog chamber
- free-air ionization chamber
- gamma-ray chamber
- gas-flow ionization chamber
- high-pressure cloud chamber
- hodoscope chamber
- integrating ionization chamber
- integration ionization chamber
- ion chamber
- ion-collection pulse chamber
- ion-implantation chamber
- ionization chamber
- ionization chamber with internal gas source
- jet chamber
- laser welding chamber
- liquid-wall ionization chamber
- low-pressure cloud chamber
- mixing chamber
- monitor ionization chamber
- narrow-gap spark chamber
- open-air ionization chamber
- optical-fiber scintillation chamber
- parallel-plate counter chamber
- pocket chamber
- positron chamber
- projection chamber
- proportional ionization chamber
- pulse ionization chamber
- recoil proton ionization chamber
- resonance chamber
- resonant chamber
- reverberation chamber
- sampling chamber
- scintillation chamber
- sorting chamber
- sound chamber
- sputtering chamber
- standard ionization chamber
- streamer chamber
- temperature chamber
- test chamber
- thimble ionization chamber
- tissue-equivalent ionization chamber
- toroidal vacuum chamber
- track chamber
- vacuum chamber
- wall-less ionization chamber
- water-brushing chamber
- well-type ionization chamber
- Wilson chamber
- Wilson cloud chamber -
105 chamber
1) камера (1. помещение специального назначения 2. замкнутый объём; замкнутая полость 3. название ряда измерительных приборов и приборов для научных исследований с рабочим телом внутри замкнутой полости) || камерный3) отсек; секция•- acceleration chamber
- acoustic chamber
- air-equivalent ionization chamber
- air-filled chamber
- air-wall ionization chamber
- alpha chamber
- altitude chamber
- anechoic chamber
- back-to-back ionization chamber
- boron chamber
- boron-lined ionization chamber
- Bragg-Gray cavity ionization chamber
- bubble chamber
- burn-in chamber
- capacitor ionization chamber
- chromatographic chamber
- climatic chamber
- cloud chamber
- coating chamber
- compensated ionization chamber
- counting ionization chamber
- current ionization chamber
- deposition chamber
- differential ionization chamber
- diffusion chamber
- diffusion cloud chamber
- echo chamber
- electron-collection pulse chamber
- environmental chamber
- evacuated chamber
- evaporation chamber
- exhaust chamber
- expansion chamber
- expansion cloud chamber
- extrapolation ionization chamber
- fission ionization chamber
- fog chamber
- free-air ionization chamber
- gamma-ray chamber
- gas-flow ionization chamber
- high-pressure cloud chamber
- hodoscope chamber
- integrating ionization chamber
- integration ionization chamber
- ion chamber
- ion-collection pulse chamber
- ion-implantation chamber
- ionization chamber with internal gas source
- ionization chamber
- jet chamber
- laser welding chamber
- liquid-wall ionization chamber
- low-pressure cloud chamber
- mixing chamber
- monitor ionization chamber
- narrow-gap spark chamber
- open-air ionization chamber
- optical-fiber scintillation chamber
- parallel-plate counter chamber
- pocket chamber
- positron chamber
- projection chamber
- proportional ionization chamber
- pulse ionization chamber
- recoil proton ionization chamber
- resonance chamber
- resonant chamber
- reverberation chamber
- sampling chamber
- scintillation chamber
- sorting chamber
- sound chamber
- sputtering chamber
- standard ionization chamber
- streamer chamber
- temperature chamber
- test chamber
- thimble ionization chamber
- tissue-equivalent ionization chamber
- toroidal vacuum chamber
- track chamber
- vacuum chamber
- wall-less ionization chamber
- water-brushing chamber
- well-type ionization chamber
- Wilson chamber
- Wilson cloud chamberThe New English-Russian Dictionary of Radio-electronics > chamber
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106 скважина с высоким пластовым давлением
Русско-английский словарь по нефти и газу > скважина с высоким пластовым давлением
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107 Adamson, Daniel
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering, Metallurgy, Steam and internal combustion engines[br]b. 1818 Shildon, Co. Durham, Englandd. January 1890 Didsbury, Manchester, England[br]English mechanical engineer, pioneer in the use of steel for boilers, which enabled higher pressures to be introduced; pioneer in the use of triple-and quadruple-expansion mill engines.[br]Adamson was apprenticed between 1835 and 1841 to Timothy Hackworth, then Locomotive Superintendent on the Stockton \& Darlington Railway. After this he was appointed Draughtsman, then Superintendent Engineer, at that railway's locomotive works until in 1847 he became Manager of Shildon Works. In 1850 he resigned and moved to act as General Manager of Heaton Foundry, Stockport. In the following year he commenced business on his own at Newton Moor Iron Works near Manchester, where he built up his business as an iron-founder and boilermaker. By 1872 this works had become too small and he moved to a 4 acre (1.6 hectare) site at Hyde Junction, Dukinfield. There he employed 600 men making steel boilers, heavy machinery including mill engines fitted with the American Wheelock valve gear, hydraulic plant and general millwrighting. His success was based on his early recognition of the importance of using high-pressure steam and steel instead of wrought iron. In 1852 he patented his type of flanged seam for the firetubes of Lancashire boilers, which prevented these tubes cracking through expansion. In 1862 he patented the fabrication of boilers by drilling rivet holes instead of punching them and also by drilling the holes through two plates held together in their assembly positions. He had started to use steel for some boilers he made for railway locomotives in 1857, and in 1860, only four years after Bessemer's patent, he built six mill engine boilers from steel for Platt Bros, Oldham. He solved the problems of using this new material, and by his death had made c.2,800 steel boilers with pressures up to 250 psi (17.6 kg/cm2).He was a pioneer in the general introduction of steel and in 1863–4 was a partner in establishing the Yorkshire Iron and Steel Works at Penistone. This was the first works to depend entirely upon Bessemer steel for engineering purposes and was later sold at a large profit to Charles Cammell \& Co., Sheffield. When he started this works, he also patented improvements both to the Bessemer converters and to the engines which provided their blast. In 1870 he helped to turn Lincolnshire into an important ironmaking area by erecting the North Lincolnshire Ironworks. He was also a shareholder in ironworks in South Wales and Cumberland.He contributed to the development of the stationary steam engine, for as early as 1855 he built one to run with a pressure of 150 psi (10.5 kg/cm) that worked quite satisfactorily. He reheated the steam between the cylinders of compound engines and then in 1861–2 patented a triple-expansion engine, followed in 1873 by a quadruple-expansion one to further economize steam. In 1858 he developed improved machinery for testing tensile strength and compressive resistance of materials, and in the same year patents for hydraulic lifting jacks and riveting machines were obtained.He was a founding member of the Iron and Steel Institute and became its President in 1888 when it visited Manchester. The previous year he had been President of the Institution of Civil Engineers when he was presented with the Bessemer Gold Medal. He was a constant contributor at the meetings of these associations as well as those of the Institution of Mechanical Engineers. He did not live to see the opening of one of his final achievements, the Manchester Ship Canal. He was the one man who, by his indomitable energy and skill at public speaking, roused the enthusiasm of the people in Manchester for this project and he made it a really practical proposition in the face of strong opposition.[br]Principal Honours and DistinctionsPresident, Institution of Civil Engineers 1887.President, Iron and Steel Institute 1888. Institution of Civil Engineers Bessemer Gold Medal 1887.Further ReadingObituary, Engineer 69:56.Obituary, Engineering 49:66–8.Obituary, Proceedings of the Institution of Civil Engineers 100:374–8.H.W.Dickinson, 1938, A Short History of the Steam Engine, Cambridge University Press (provides an illustration of Adamson's flanged seam for boilers).R.L.Hills, 1989, Power from Steam. A History of the Stationary Steam Engine, Cambridge University Press (covers the development of the triple-expansion engine).RLH -
108 Bousquet, Gaston du
[br]b. 20 August 1839 Paris, Franced. 24 March 1910 Paris, France[br]French locomotive engineer noted for the successful development of compound locomotives.[br]Bousquet spent his entire working life with the Northern Railway of France, reaching the position of Chief Engineer of Rolling Stock and Motive Power in 1890. In 1886 he was associated with Alfred de Glehn, technical head of locomotive builder Société Alsacienne de Constructions Mécaniques, in the building of a four-cylinder, four-crank, compound 2–2–2–0 partly derived from the work of F.W. Webb. In continuing association with de Glehn, Bousquet then designed a four-cylinder, compound 440 with the low-pressure cylinders beneath the smokebox and the high-pressure ones outside the frames; the first was completed in 1891. The details were well designed and the locomotive was the forerunner of a highly successful series. It was developed into 4–6–0, 4–4–2 and 4–6–2 types, and examples were used in quantity by all the principal French railways and by some in Germany, while G.J. Churchward brought three of the 4–4–2s to the Great Western Railway in England for comparison with his own locomotives. In 1905 Bousquet introduced an articulated 0–6–2+2–6–0 compound tank locomotive for freight trains: the two driving bogies supported a frame carrying boiler, tanks, etc. At the time of his death he was working on compound 4–6–4 locomotives.[br]Further ReadingJ.T.van Riemsdijk, 1970, "The compound locomotive (Part 1)", Transactions of the New comen Society 43; 1972, Part 2, Transactions of the New comen Society 44 (fully describes Bousquet's locomotives).See also: Mallet, Jules Théodore AnatolePJGR -
109 Edwards, Humphrey
SUBJECT AREA: Steam and internal combustion engines[br]fl. c.1808–25 London (?), Englandd. after 1825 France (?)[br]English co-developer of Woolf s compound steam engine.[br]When Arthur Woolf left the Griffin Brewery, London, in October 1808, he formed a partnership with Humphrey Edwards, described as a millwright at Mill Street, Lambeth, where they started an engine works to build Woolf's type of compound engine. A number of small engines were constructed and other ordinary engines modified with the addition of a high-pressure cylinder. Improvements were made in each succeeding engine, and by 1811 a standard form had been evolved. During this experimental period, engines were made with cylinders side by side as well as the more usual layout with one behind the other. The valve gear and other details were also improved. Steam pressure may have been around 40 psi (2.8 kg/cm2). In an advertisement of February 1811, the partners claimed that their engines had been brought to such a state of perfection that they consumed only half the quantity of coal required for engines on the plan of Messrs Boulton \& Watt. Woolf visited Cornwall, where he realized that more potential for his engines lay there than in London; in May 1811 the partnership was dissolved, with Woolf returning to his home county. Edwards struggled on alone in London for a while, but when he saw a more promising future for the engine in France he moved to Paris. On 25 May 1815 he obtained a French patent, a Brevet d'importation, for ten years. A report in 1817 shows that during the previous two years he had imported into France fifteen engines of different sizes which were at work in eight places in various parts of the country. He licensed a mining company in the north of France to make twenty-five engines for winding coal. In France there was always much more interest in rotative engines than pumping ones. Edwards may have formed a partnership with Goupil \& Cie, Dampierre, to build engines, but this is uncertain. He became a member of the firm Scipion, Perrier, Edwards \& Chappert, which took over the Chaillot Foundry of the Perrier Frères in Paris, and it seems that Edwards continued to build steam engines there for the rest of his life. In 1824 it was claimed that he had made about 100 engines in England and another 200 in France, but this is probably an exaggeration.The Woolf engine acquired its popularity in France because its compound design was more economical than the single-cylinder type. To enable it to be operated safely, Edwards first modified Woolf s cast-iron boiler in 1815 by placing two small drums over the fire, and then in 1825 replaced the cast iron with wrought iron. The modified boiler was eventually brought back to England in the 1850s as the "French" or "elephant" boiler.[br]Further ReadingMost details about Edwards are to be found in the biographies of his partner, Arthur Woolf. For example, see T.R.Harris, 1966, Arthur Woolf, 1766–1837, The Cornish Engineer, Truro: D.Bradford Barton; Rhys Jenkins, 1932–3, "A Cornish Engineer, Arthur Woolf, 1766–1837", Transactions of the Newcomen Society 13. These use information from the originally unpublished part of J.Farey, 1971, A Treatise on the Steam Engine, Vol. II, Newton Abbot: David \& Charles.RLH -
110 Haber, Fritz
SUBJECT AREA: Chemical technology[br]b. 9 December 1868 Breslau, Germany (now Wroclaw, Poland)d. 29 January 1934 Basel, Switzerland[br]German chemist, inventor of the process for the synthesis of ammonia.[br]Haber's father was a manufacturer of dyestuffs, so he studied organic chemistry at Berlin and Heidelberg universities to equip him to enter his father's firm. But his interest turned to physical chemistry and remained there throughout his life. He became Assistant at the Technische Hochschule in Karlsruhe in 1894; his first work there was on pyrolysis and electrochemistry, and he published his Grundrisse der technischen Electrochemie in 1898. Haber became famous for thorough and illuminating theoretical studies in areas of growing practical importance. He rose through the academic ranks and was appointed a full professor in 1906. In 1912 he was also appointed Director of the Institute of Physical Chemistry and Electrochemistry at Dahlem, outside Berlin.Early in the twentieth century Haber invented a process for the synthesis of ammonia. The English chemist and physicist Sir William Crookes (1832–1919) had warned of the danger of mass hunger because the deposits of Chilean nitrate were becoming exhausted and nitrogenous fertilizers would not suffice for the world's growing population. A solution lay in the use of the nitrogen in the air, and the efforts of chemists centred on ways of converting it to usable nitrate. Haber was aware of contemporary work on the fixation of nitrogen by the cyanamide and arc processes, but in 1904 he turned to the study of ammonia formation from its elements, nitrogen and hydrogen. During 1907–9 Haber found that the yield of ammonia reached an industrially viable level if the reaction took place under a pressure of 150–200 atmospheres and a temperature of 600°C (1,112° F) in the presence of a suitable catalyst—first osmium, later uranium. He devised an apparatus in which a mixture of the gases was pumped through a converter, in which the ammonia formed was withdrawn while the unchanged gases were recirculated. By 1913, Haber's collaborator, Carl Bosch had succeeded in raising this laboratory process to the industrial scale. It was the first successful high-pressure industrial chemical process, and solved the nitrogen problem. The outbreak of the First World War directed the work of the institute in Dahlem to military purposes, and Haber was placed in charge of chemical warfare. In this capacity, he developed poisonous gases as well as the means of defence against them, such as gas masks. The synthetic-ammonia process was diverted to produce nitric acid for explosives. The great benefits and achievement of the Haber-Bosch process were recognized by the award in 1919 of the Nobel Prize in Chemistry, but on account of Haber's association with chemical warfare, British, French and American scientists denounced the award; this only added to the sense of bitterness he already felt at his country's defeat in the war. He concentrated on the theoretical studies for which he was renowned, in particular on pyrolysis and autoxidation, and both the Karlsruhe and the Dahlem laboratories became international centres for discussion and research in physical chemistry.With the Nazi takeover in 1933, Haber found that, as a Jew, he was relegated to second-class status. He did not see why he should appoint staff on account of their grandmothers instead of their ability, so he resigned his posts and went into exile. For some months he accepted hospitality in Cambridge, but he was on his way to a new post in what is now Israel when he died suddenly in Basel, Switzerland.[br]Bibliography1898, Grundrisse der technischen Electrochemie.1927, Aus Leben und Beruf.Further ReadingJ.E.Coates, 1939, "The Haber Memorial Lecture", Journal of the Chemical Society: 1,642–72.M.Goran, 1967, The Story of Fritz Haber, Norman, OK: University of Oklahoma Press (includes a complete list of Haber's works).LRD -
111 pump
насос; помпа; качать, накачивать, откачивать, нагнетать•
- air pump
- air lift pump
- air-plunger pump
- booster pump
- bore-hole pump
- boring pump
- bull pump
- cam pump
- centrifugal pump
- compression pump
- concrete pump
- condencate pump
- deep-well pump
- delivery pump
- displacement pump
- double-acting pump
- drainage pump
- dredge pump
- ejector pump
- ejector air pump
- ever-primed pump
- excavating pump
- extraction pump
- feed pump
- flue-gas pump
- force pump
- gear pump
- gravel pump
- grease pump
- high-head pump
- high-pressure pump
- hydraulic pump
- immersible pump
- impeller pump
- infusion pump
- jet pump
- low-head pump
- lubrication pump
- make-up pump
- medium pump
- membrane pump
- mud pump
- multiplunger pump
- multistage pump
- piston pump
- piston-type pump
- plunger pump
- ram pump
- ram-type pump
- reciprocating pump
- rotary pump
- screw pump
- self-priming pump
- single-acting pump
- slime pump
- sludge pump
- slurry pump
- slush pump
- solid pump
- spiral pump
- station pump
- stationary pump
- submersible pump
- suspended pump
- three-ram pump
- triple-acting pump
- turbine pump
- two-stage pump
- vacseal pump
- vacuum pump
- vane pump
- variable-stroke pump
- volute pump
- water-jet pump
- wing pump -
112 area
площадь, район, область— direct irrigation area -
113 cuña
f.1 cot, cradle (for child).2 cradle.3 birthplace.4 lineage.pres.indicat.3rd person singular (él/ella/ello) present indicative of spanish verb: cunar.imperat.2nd person singular (tú) Imperative of Spanish verb: cunar.* * *1 (cama) cradle2 (linaje) birth, lineage, stock4 (lugar de nacimiento) birthplace* * *noun f.1) cradle2) birthplace* * *SF1) [de bebé] cot, crib (EEUU); [con balancines] cradle2) (=lugar de nacimiento) [de persona] birthplace; [de tendencia, movimiento] cradleMálaga, la cuna de Picasso — Málaga, the birthplace of Picasso
Atenas, la cuna de las olimpiadas — Athens, the birthplace of the Olympics
Escocia, la cuna del golf — Scotland, the home of golf
3) (=linaje)de cuna humilde — of humble birth o stock o origin
* * *a) ( tradicional) cradle; ( cama con barandas) crib (AmE), cot (BrE); ( portabebé) portacrib (AmE), carrycot (BrE)b) (liter) (estirpe, linaje)ser de ilustre/humilde cuna — to be of noble/humble birth (liter)
c) ( lugar de nacimiento) birthplaced) (origen de filosofía, movimiento) birthplace* * *= wedge.Ex. Oak was shaped by splitting with wooden wedges, and by hewing with axes or adzes.----* cuña anticiclónica = ridge of high pressure.* cuña automática = mechanical quoin.* cuña de fijación = quoin.* cuña de madera = wooden quoin.* en forma de cuña = wedge-shaped.* * *a) ( tradicional) cradle; ( cama con barandas) crib (AmE), cot (BrE); ( portabebé) portacrib (AmE), carrycot (BrE)b) (liter) (estirpe, linaje)ser de ilustre/humilde cuna — to be of noble/humble birth (liter)
c) ( lugar de nacimiento) birthplaced) (origen de filosofía, movimiento) birthplace* * *= cradle, crib, seedbed, cot.Ex: This is the cradle of Shangri-la and one of the deepest river gorges on earth = Ésta es la cuna del Shangrilá y uno de los desfiladeros más profundos de la tierra.
Ex: The same set of toys, which included a doll, a saucepan, a baby bottle, coffee mug, teacup, teaspoon, doll crib, blanket, toy phone and dump truck, was presented to children of all ages during individual 10-minute sessions.Ex: The article has the title 'The last thirty years as the seedbed of the future'.Ex: Infants and young children may be exposed to a variety of dangerous situations when left sleeping in cots.* canción de cuna = lullaby.* cuna de la civilización = cradle of civilisation.* cuna de la humanidad = cradle of mankind.* de alta cuna = well-born.* la mano que mece la cuna gobierna el mundo = the hand that rocks the cradle rules the world, the hand that rocks the cradle rules the world.* * *1 (tradicional) cradle; (cama con barandas) crib ( AmE), cot ( BrE); (portabebé) portacrib ( AmE), carrycot ( BrE)2 ( liter)(estirpe, linaje): un joven de ilustre/humilde cuna a young man of noble/humble birth ( liter)3 (lugar de nacimiento) birthplace4 (origen, principio) birthplace, cradlela cuna de la civilización the cradle of civilization5 (juego) cat's cradle(jugar a) hacer cunitas to do o play cat's cradle* * *
Multiple Entries:
cuna
cuña
cuna sustantivo femenino
( cama con barandas) crib (AmE), cot (BrE);
( portabebé) portacrib (AmE), carrycot (BrE)
cuña sustantivo femenino
1
◊ en cuña in a V-formation o wedge formation
2 (CS fam) See Also→ palanca 2
cuna sustantivo femenino
1 cot
2 figurado (linaje) cradle
cuña sustantivo femenino wedge
cuña publicitaria, commercial break
' cuña' also found in these entries:
Spanish:
anticiclónica
- anticiclónico
- barrote
- canción
- cuna
- extracción
- pegar
- vaivén
- calza
- inclinar
- mecer
- moisés
- muerte
- nana
- sala
English:
born
- burble
- cot
- cradle
- crib
- lullaby
- ridge
- rock
- wedge
- bed
- birth
- carry
- door
* * *cuna nf1. [de niño] cot, cradleMéx cuna viajera Br carrycot, US portacrib2. [de movimiento, civilización] cradle;[de persona] birthplace3. [linaje]es de cuna noble/humilde he is of noble/humble birth* * *f cama crib, Brcradle* * *cuna nf1) : cradle2) : birthplacePuerto Rico es la cuna de la música salsa: Puerto Rico is the birthplace of salsa music* * * -
114 reactor
1) (хімічний) реактор 2) котушка індуктивності; конденсатор - batch-loaded reactor
- chemical vapor deposition reactor
- cylindrical plasma etching reactor
- cylindrical plasma reactor
- EPI epitaxial reactor
- EPI reactor
- epitaxial reactor
- etching reactor
- high-pressure reactor
- hot-well reactor
- laboratory-scale reactor
- LPCVD reactor
- LPE reactor
- MO-CVD reactor
- MOVPE reactor
- multifacet reactor
- multiwafer plasma reactor
- nitride-охide NITROX reactor
- nitride-охide reactor
- oxide reactor
- “pancake” reactor
- parallel-plate reactor
- planar plasma etching reactor
- planar plasma reactor
- plasma etching reactor
- plasma reactor
- radial-flow plasma etching reactor
- sputteringreactor
- sputterreactor -
115 utrwal|ić
pf — utrwal|ać impf Ⅰ vt 1. (umocnić) to strengthen, to consolidate [więź, pozycję, stosunki] 2. (upamiętnić) to commemorate [osobę, wydarzenie] 3. (zarejestrować) to record- utrwalać na taśmie głosy ptaków to tape bird calls- utrwalać w pamiętniku swoje przeżycia to record one’s experiences in a diary4. (zachować) to retain [fakt]; to consolidate [wiadomości, wiedzę, materiał] 5. Chem., Fot. (nadać trwałość) to fix 6. (zakonserwować) to preserve [żywność] Ⅱ utrwalić się — utrwalać się to become established- w naszej rodzinie utrwalił się zwyczaj codziennego czytania prasy the custom of reading newspapers every day is well established in our family- wyż utrwalił się nad Polską a high pressure area has set in over Poland■ utrwaliło mi się to w pamięci it stayed in my memoryThe New English-Polish, Polish-English Kościuszko foundation dictionary > utrwal|ić
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116 chouette
I.n. m.1. Le chouette de¼ The great thing about¼ Le chouette de l'affaire, c'est qu'on lui a prêté son propre fric: The really hilarious thing about it all was that we lent him his own money.3. (pl.): Genuine I.D. papers. Marcher sous ses chouettes: To go about under one's true identity.4. Prendre du chouette: To indulge in sodomous intercourse.II.n. f. Il était tout à la chouette à l'idée de revoir sa bonne femme: He was full of the joys of spring at the thought of seeing his missus again.III.adj.1. 'Swell', 'great', fine. C'est une chouette personne, ta frangine: Your sister is a really nice person.a To be 'in someone's good books', to be held in esteem by someone.b To 'have a crush on someone', to be enamoured with someone.IV.interj. Good-ho! — Smashing! — Great! Chouette alors! Well, that's really super! (The French and English are equally twee.) -
117 Kirkaldy, David
[br]b. 4 April 1820 Mayfield, Dundee, Scotlandd. 25 January 1897 London, England[br]Scottish engineer and pioneer in materials testing.[br]The son of a merchant of Dundee, Kirkaldy was educated there, then at Merchiston Castle School, Edinburgh, and at Edinburgh University. For a while he worked in his father's office, but with a preference for engineering, in 1843 he commenced an apprenticeship at the Glasgow works of Robert Napier. After four years in the shops he was transferred to the drawing office and in a very few years rose to become Chief. Here Kirkaldy demonstrated a remarkable talent both for the meticulous recording of observations and data and for technical drawing. His work also had an aesthetic appeal and four of his drawings of Napier steamships were shown at the Paris Exhibition of 1855, earning both Napier and Kirkaldy a medal. His "as fitted" set of drawings of the Cunard Liner Persia, which had been built in 1855, is now in the possession of the National Maritime Museum at Greenwich, London; it is regarded as one of the finest examples of its kind in the world, and has even been exhibited at the Royal Academy in London.With the impending order for the Royal Naval Ironclad Black Prince (sister ship to HMS Warrior, now preserved at Portsmouth) and for some high-pressure marine boilers and engines, there was need for a close scientific analysis of the physical properties of iron and steel. Kirkaldy, now designated Chief Draughtsman and Calculator, was placed in charge of this work, which included comparisons of puddled steel and wrought iron, using a simple lever-arm testing machine. The tests lasted some three years and resulted in Kirkaldy's most important publication, Experiments on Wrought Iron and Steel (1862, London), which gained him wide recognition for his careful and thorough work. Napier's did not encourage him to continue testing; but realizing the growing importance of materials testing, Kirkaldy resigned from the shipyard in 1861. For the next two and a half years Kirkaldy worked on the design of a massive testing machine that was manufactured in Leeds and installed in premises in London, at The Grove, Southwark.The works was open for trade in January 1866 and engineers soon began to bring him specimens for testing on the great machine: Joseph Cubitt (son of William Cubitt) brought him samples of the materials for the new Blackfriars Bridge, which was then under construction. Soon The Grove became too cramped and Kirkaldy moved to 99 Southwark Street, reopening in January 1874. In the years that followed, Kirkaldy gained a worldwide reputation for rigorous and meticulous testing and recording of results, coupled with the highest integrity. He numbered the most distinguished engineers of the time among his clients.After Kirkaldy's death, his son William George, whom he had taken into partnership, carried on the business. When the son died in 1914, his widow took charge until her death in 1938, when the grandson David became proprietor. He sold out to Treharne \& Davies, chemical consultants, in 1965, but the works finally closed in 1974. The future of the premises and the testing machine at first seemed threatened, but that has now been secured and the machine is once more in working order. Over almost one hundred years of trading in South London, the company was involved in many famous enquiries, including the analysis of the iron from the ill-fated Tay Bridge (see Bouch, Sir Thomas).[br]Principal Honours and DistinctionsInstitution of Engineers and Shipbuilders in Scotland Gold Medal 1864.Bibliography1862, Results of an Experimental Inquiry into the Tensile Strength and Other Properties of Wrought Iron and Steel (originally presented as a paper to the 1860–1 session of the Scottish Shipbuilders' Association).Further ReadingD.P.Smith, 1981, "David Kirkaldy (1820–97) and engineering materials testing", Transactions of the Newcomen Society 52:49–65 (a clear and well-documented account).LRD / FMW -
118 Savery, Thomas
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering[br]b. c. 1650 probably Shilston, near Modbury, Devonshire, Englandd. c. 15 May 1715 London, England[br]English inventor of a partially successful steam-driven pump for raising water.[br]Little is known of the early years of Savery's life and no trace has been found that he served in the Army, so the title "Captain" is thought to refer to some mining appointment, probably in the West of England. He may have been involved in the Glorious Revolution of 1688, for later he was well known to William of Orange. From 1705 to 1714 he was Treasurer for Sick and Wounded Seamen, and in 1714 he was appointed Surveyor of the Water Works at Hampton Court, a post he held until his death the following year. He was interested in mechanical devices; amongst his early contrivances was a clock.He was the most prolific inventor of his day, applying for seven patents, including one in 1649, for polishing plate glass which may have been used. His idea for 1697 for propelling ships with paddle-wheels driven by a capstan was a failure, although regarded highly by the King, and was published in his first book, Navigation Improved (1698). He tried to patent a new type of floating mill in 1707, and an idea in 1710 for baking sea coal or other fuel in an oven to make it clean and pure.His most famous invention, however, was the one patented in 1698 "for raising water by the impellent force of fire" that Savery said would drain mines or low-lying land, raise water to supply towns or houses, and provide a source of water for turning mills through a water-wheel. Basically it consisted of a receiver which was first filled with steam and then cooled to create a vacuum by having water poured over the outside. The water to be pumped was drawn into the receiver from a lower sump, and then high-pressure steam was readmitted to force the water up a pipe to a higher level. It was demonstrated to the King and the Royal Society and achieved some success, for a few were installed in the London area and a manufactory set up at Salisbury Court in London. He published a book, The Miner's Friend, about his engine in 1702, but although he made considerable improvements, due to excessive fuel consumption and materials which could not withstand the steam pressures involved, no engines were installed in mines as Savery had hoped. His patent was extended in 1699 until 1733 so that it covered the atmospheric engine of Thomas Newcomen who was forced to join Savery and his other partners to construct this much more practical engine.[br]Principal Honours and DistinctionsFRS 1706.Bibliography1698, Navigation Improved.1702, The Miner's Friend.Further ReadingThe entry in the Dictionary of National Biography (1897, Vol. L, London: Smith Elder \& Co.) has been partially superseded by more recent research. The Transactions of the Newcomen Society contain various papers; for example, Rhys Jenkins, 1922–3, "Savery, Newcomen and the early history of the steam engine", Vol. 3; A.Stowers, 1961–2, "Thomas Newcomen's first steam engine 250 years ago and the initial development of steam power", Vol. 34; A.Smith, 1977–8, "Steam and the city: the committee of proprietors of the invention for raising water by fire", 1715–1735, Vol. 49; and J.S.P.Buckland, 1977–8, "Thomas Savery, his steam engine workshop of 1702", Vol. 49. Brief accounts may be found in H.W. Dickinson, 1938, A Short History of the Steam Engine, Cambridge University Press, and R.L. Hills, 1989, Power from Steam. A History of the Stationary Steam Engine, Cambridge University Press. There is another biography in T.I. Williams (ed.), 1969, A Biographical Dictionary of Scientists, London: A. \& C.Black.RLH -
119 Wenham, Francis Herbert
SUBJECT AREA: Aerospace[br]b. 1824 London, Englandd. 11 August 1908 Folkestone, England[br]English engineer, inventor and pioneer aerodynamicist who built the first wind tunnel.[br]Wenham trained as a marine engineer and later specialized in screw propellers and high-pressure engines. He had many interests. He took his steamboat to the Nile and assisted the photographer F.Frith to photograph Egyptian tombs by devising a series of mirrors to deflect sunlight into the dark recesses. He experimented with gas engines and produced a hot-air engine. Wenham was a leading, if controversial, figure in the Microscopical Society and a member of the Royal Photographic Society; he developed an enlarger.Wenham was interested in both mechanical and lighter-than-air flight. One of his friends was James Glaisher, a well-known balloonist who made many ascents to gather scientific information. When the (Royal) Aeronautical Society of Great Britain was founded in 1866, the Rules were drawn up by Wenham, Glaisher and the Honorary Secretary, F.W.Brearey. At the first meeting of the Society, on 27 June 1866, "On aerial locomotion and the laws by which heavy bodies impelled through the air are sustained" was read by Wenham. In his paper Wenham described his experiments with a whirling arm (used earlier by Cayley) to measure lift and drag on flat surfaces inclined at various angles of incidence. His studies of birds' wings and, in particular, their wing loading, showed that they derived most of their lift from the front portion, hence a long, thin wing was better than a short, wide one. He published illustrations of his glider designs covering his experiments of c. 1858–9. One of these had five slender wings one above the other, an idea later developed by Horatio Phillips. Wenham had some success with a model, but no real success with his full-size gliders.In 1871, Wenham and John Browning constructed the first wind tunnel designed for aeronautical research. It utilized a fan driven by a steam engine to propel the air and had a working section of 18 in. (116 cm). Wenham continued to play an important role in aeronautical matters for many years, including a lengthy exchange of ideas with Octave Chanute from 1892 onwards.[br]Principal Honours and DistinctionsHonorary Member of the (Royal) Aeronautical Society.BibliographyWenham published many reports and papers. These are listed, together with a reprint of his paper "Aerial locomotion", in the Journal of the Royal Aeronautical Society (August 1958).Further ReadingTwo papers by J.Laurence Pritchard, 1957, "The dawn of aerodynamics" Journal of the Royal Aeronautical Society (March); 1958, "Francis Herbert Wenham", Journal of the Royal Aeronautical Society (August) (both papers describe Wenham and his work).J.E.Hodgson, 1924, History of Aeronautics in Great Britain, London.JDSBiographical history of technology > Wenham, Francis Herbert
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120 drilling
бурение; сверление; высверливаниеbottom supported marine drilling — бурение скважин с опорой на дно (со стационарной свайной платформы)
* * *
1. бурение2. pl. буровой шлам, буровая мелочь
* * *
* * *
1) бурение; сверление; высверливание || буровой; бурильный2) pl выбуренная порода3) pl буровой шлам, буровая мука; буровая мелочь4) pl скважины5) pl алмазы величиной от 4 до 23 штук на карат•drilling afloat — бурение наплаву;
drilling ahead — 1) бурение ниже башмака обсадной колонны ( на значительную глубину) 2) бурение, опережающее проходку горной выработки;
drilling by flame — 1) термическое бурение 2) прожигание скважин;
drilling by jetting method — 1) бурение гидравлическим способом 2) гидромониторное бурение;
drilling deeper — углубка скважины;
drilling for gas — бурение на газ;
drilling for oil — бурение на нефть;
drilling for structure — картировочное бурение;
drilling for water — бурение на воду;
drilling from floating vessel — бурение с плавучего основания;
drilling in cramped quarter — бурение глубоких скважин из выработки малого сечения;
drilling into abnormal pressure zone — бурение в зоне высокого давления;
not drilling — простаивающий ();
drilling off the whipstock — бурение со стационарного отклонителя;
drilling on the bottom — чистое бурение;
drilling out of cement plug — разбуривание цементной пробки;
drilling suspended indefinitely — бурение прекращено на неопределённое время;
drilling the pay — разбуривание продуктивного пласта;
drilling to completion — бурение до проектной глубины;
drilling to predetermined depth — бурение до проектной глубины;
drilling to projected depth — бурение до проектной глубины;
drilling with aerated fluid — бурение с промывкой аэрированной жидкостью;
drilling with aerated formation water — бурение с промывкой аэрированными пластовыми водами;
drilling with air — бурение с очисткой забоя воздухом;
drilling with counterflow — бурение с обратной промывкой;
drilling with explosives — взрывное бурение;
drilling with localized mud circulation — бурение с местной промывкой;
drilling with mud — бурение с промывкой буровым раствором;
drilling with oil — бурение с промывкой раствором на углеводородной основе;
drilling with salt water — бурение с промывкой солёной водой;
drilling with sound vibration — вибробурение со звуковыми частотами;
- drilling of submarine wellsdrilling without drill pipe — беструбное бурение;
- abrasive jet drilling
- aerated-fluid drilling
- aerated-mud drilling
- aeration drilling
- air drilling
- air-and-gas drilling
- air-and-stable-foam drilling
- air-flush drilling
- air-hammer drilling
- air-hammer rotary drilling
- air-motor drilling
- air-percussion drilling
- air-reverse-circulation drilling
- angled drilling
- angular drilling
- anomaly drilling
- appraisal drilling
- arc drilling
- auger drilling
- balanced drilling
- barge drilling
- bench drilling
- blasthole drilling
- blind drilling
- borehole drilling
- bottom supported marine drilling
- bottomhole circulation drilling
- bottom-supported offshore drilling
- branched-hole drilling
- cable drilling
- cable-churn drilling
- cable-Pennsylvanian drilling
- cable-rotary drilling
- cable-tool drilling
- calibration drilling
- Calyx drilling
- Canadian drilling
- carbide percussion drilling
- chain bit drilling
- checkerboard drilling
- chemical drilling
- chilled-shot drilling
- churn drilling
- churn flame drilling
- city-lot drilling
- clean drilling
- close drilling
- close-spaced surface drilling
- close-spaced underground drilling
- cluster drilling
- cluster directional drilling of slant
- combination drilling
- compressed air drilling
- continuous penetration drilling
- contract drilling
- control angle drilling
- controlled drilling
- controlled-angle drilling
- core drilling
- counterflush drilling
- counterflush core drilling
- cover drilling
- Craelius method drilling
- deep drilling
- deep-hole drilling
- deep-water drilling
- deep-well drilling
- definition drilling
- dense drilling
- development drilling
- diamond drilling
- diamond core drilling
- direct-air-circulation drilling
- direct-circulation drilling
- directed drilling
- directional drilling
- directional drilling of slant holes
- double-barreled drilling
- double-directional drilling
- double-hand drilling
- double-inclinated drilling
- double-simultaneous drilling
- double-tube drilling
- downhole drilling
- downhole electrical motor drilling
- downhole hammer drilling
- downhole percussion drilling
- downhole turbine motor drilling
- down-the-hole drilling
- drainhole drilling
- drive-pipe drilling
- dry drilling
- dry-hole drilling
- dry percussive drilling
- dual-bore cluster drilling
- dual-hole simultaneous drilling
- dust-free drilling
- dustless drilling
- easy drilling
- electrical drilling
- electrical arc drilling
- electrical bottomhole drilling
- electrohydraulic drilling
- electrojet drilling
- electron beam drilling
- erosion drilling
- erosion jet drilling
- exhaust gas drilling
- exploration drilling
- exploratory drilling
- explosion drilling
- extended reach drilling
- failure-free drilling
- fan drilling
- flame drilling
- flame-jet drilling
- floating drilling
- fluid circulating drilling
- fluid core drilling
- flush drilling
- foam drilling
- formation drilling
- full-diameter drilling
- full-hole drilling
- gas drilling
- gas-well drilling
- geological drilling
- group drilling
- grout-hole drilling
- guided drilling
- hand drilling
- hand churn drilling
- hand hammer drilling
- hard-rock drilling
- heavy weight drilling
- high-frequency drilling
- high-frequency percussion drilling
- high-velocity jet drilling
- hooded dry drilling
- horizontal drilling
- horizontal branched-hole drilling
- horizontal-drainhole drilling
- horizontal-radial diamond drilling
- horizontal-ring drilling
- hydraulical drilling
- hydraulical percussion drilling
- hydraulical rotary drilling
- hydrodynamical drilling
- hydropercussion drilling
- hydropercussion rotary drilling
- hydroturbine downhole motor drilling
- implosion drilling
- inclination drilling
- induction drilling
- infill drilling
- injection drilling
- instrumental drilling
- intermediate hole drilling
- inverted oil emulsion drilling
- jet drilling
- jet-bit drilling
- jet-erosion drilling
- jet-piercer drilling
- jet-piercing drilling
- jetted-particle drilling
- jetting drilling
- jump drilling
- key well drilling
- large-hole drilling
- laser drilling
- lateral drilling
- line drilling
- line-hole drilling
- line-well drilling
- long-hole drilling
- machine drilling
- magnetostriction drilling
- magnetostriction rotary drilling
- marine drilling
- mechanical drilling
- mechanized drilling
- Mesabi structural drilling
- microbit drilling
- mist drilling
- moderate drilling
- mud-circulating drilling
- mud-powered hammer drilling
- multidirectional drilling
- multihole drilling
- multiple drilling
- multiple-plan drilling
- noncore drilling
- nonpressure drilling
- offset drilling
- offshore drilling
- oil-emulsion drilling
- oil-mud drilling
- oil-well drilling
- old-well deeper drilling
- one-man drilling
- on-land drilling
- optimized drilling
- oriented drilling
- original drilling
- outstep drilling
- overbalanced drilling
- overburden drilling
- overhead drilling
- parallel hole drilling
- pay drilling
- pellet impact drilling
- Pennsylvanian drilling
- percussion drilling
- percussion-air drilling
- percussion-rod drilling
- percussion-rotation drilling
- percussive drilling
- percussive-machine drilling
- percussive-rotary drilling
- performance drilling
- permafrost drilling
- petroleum drilling
- pier drilling
- pillar extraction drilling
- pilot drilling
- pipe-driving drilling
- pipeless drilling
- pipeless downhole electrical motor drilling
- placer drilling
- plasma drilling
- plug drilling
- pneumatical drilling
- preliminary drilling
- pressure drilling
- probe drilling
- production drilling
- prospect drilling
- pulsed jet drilling
- push-button drilling
- push-feed drilling
- quick-blow drilling
- radial drilling
- random drilling
- rapid-blow drilling
- reduced-pressure drilling
- remote automated drilling
- reverse-circulation core drilling
- ring drilling
- rock drilling
- rocket drilling
- rod drilling
- rod-tool drilling
- roller-bit drilling
- rope drilling
- rotary drilling
- rotary-percussion drilling
- rotary-turbine drilling
- rotation drilling
- rotation-vibropercussion drilling
- rough drilling
- run-to-waste drilling
- safe drilling
- salt-dome drilling
- sample drilling
- scattered drilling
- seam drilling
- secondary drilling
- sectional steel drilling
- self-cleaning drilling
- shaft drilling
- shallow drilling
- shaped charge drilling
- shelf drilling
- ship-side drilling
- shock-wave drilling
- shot drilling
- shot core drilling
- shothole drilling
- simultaneous drilling
- single-hand drilling
- single-pass drilling
- single-row drilling
- slant-hole drilling
- slim-hole drilling
- sonic combination drilling
- spark drilling
- spindle feed drilling
- spring-pole drilling
- steel-shot drilling
- straight-ahead drilling
- straight-hole drilling
- straight-hole directional drilling
- stratigraphic test drilling
- structure drilling
- subgrade drilling
- submarine drilling
- subsurface drilling
- superdeep drilling
- surface drilling
- surface blasthole drilling
- surface hole drilling
- tension drilling
- test drilling
- test-hole drilling
- test-well drilling
- thermal drilling
- top hammer drilling
- top hole drilling
- tough drilling
- town-lot drilling
- triple-hole simultaneous drilling
- trouble-free drilling
- tungsten-carbide drilling
- turbine motor drilling
- ultradeep drilling
- ultrasonic drilling
- underbalanced drilling
- underground drilling
- underwater drilling
- up-hole drilling
- upper-hole drilling
- vacuum drilling
- vertical drilling
- vertical ring drilling
- vibration drilling
- vibratory drilling
- vibratory-percussion drilling
- vibratory-rotary drilling
- vibropercussion drilling
- vibropercussion rotary drilling
- wash drilling
- water drilling
- water-assisted drilling
- water-flush drilling
- water-jet drilling
- water-well drilling
- well drilling
- wet drilling
- wild-cat drilling
- wireline drilling* * *Англо-русский словарь нефтегазовой промышленности > drilling
См. также в других словарях:
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