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1 multi-stage turbine
многоступенчатая турбина
Турбина ГТД, состоящая из нескольких последовательно расположенных ступеней.
Примечание
При конкретной конструкции турбины она может называться по числу ступеней.
[ ГОСТ 23851-79]Тематики
EN
DE
FR
95. Многоступенчатая турбина
D. Mehrstufige Turbine
E. Multi-stage turbine
F. Turbine à plusieurs étages
Турбина ГТД, состоящая из нескольких последовательно расположенных ступеней.
Примечание. При конкретной конструкции турбины она может называться по числу ступеней.
Источник: ГОСТ 23851-79: Двигатели газотурбинные авиационные. Термины и определения оригинал документа
Англо-русский словарь нормативно-технической терминологии > multi-stage turbine
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2 multi-stage turbine
Большой англо-русский и русско-английский словарь > multi-stage turbine
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3 multi-stage turbine
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4 multi-stage turbine
многоступенчатая турбинаАнгло-русский большой универсальный переводческий словарь > multi-stage turbine
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5 multi stage turbine
Газовые турбины: (d) многоступенчатая турбина -
6 multi-stage turbine
turbina wielostopniowaEnglish-Polish dictionary for engineers > multi-stage turbine
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7 multi-stage turbine
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8 multi-stage
ˈmʌltɪsteɪdʒ прил.
1) многостадийный, многоэтапный multistage decision process ≈ многошаговый процесс принятия решения Syn: multistage
2) многоступенчатый multi-stage rocket multi-stage turbine Syn: multi-step
3) многокамерный
4) многоэтажный Syn: many-storied, many-storeyed а
1) многоступенчатый;
~ rocket многоступенчатая ракета ;
2) многокамерный ;
3) многоэтажный multi-stage многокамерный ~ многоступенчатый;
multi-stage rocket многоступенчатая ракета ~ многоэтажный ~ многоступенчатый;
multi-stage rocket многоступенчатая ракетаБольшой англо-русский и русско-английский словарь > multi-stage
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9 multi-stage
1) многостадийный
2) многоступенчатый
3) многошаговый
4) многотактный
– multi-stage rocket
– multi-stage turbine -
10 multi-stage
<tech.gen> (e.g. pump, compressor, turbine, amplifier) ■ mehrstufig -
11 multi stage(d) turbine
Газовые турбины: многоступенчатая турбинаУниверсальный англо-русский словарь > multi stage(d) turbine
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12 turbine
1) турбина
2) турбинный
– ahead turbine
– astern turbine
– axial-flow turbine
– back-pressure turbine
– bleeder turbine
– condensing turbine
– extraction turbine
– extraction turbine
– Francis turbine
– gas turbine
– gas turbine jet engine
– gate-blade turbine
– high-pressure end of turbine
– high-pressure turbine
– house turbine
– impulse turbine
– impulse-reaction turbine
– Kaplan turbine
– marine turbine
– million-kilowatt turbine
– multi-cylinder turbine
– multi-stage turbine
– Pelton turbine
– radial-flow turbine
– reaction turbine
– steam turbine
– throttling turbine
– topping turbine
– turbine blower
– turbine casing
– turbine condensate
– turbine disk
– turbine flowmeter
– turbine oil
– turbine plant
– turbine room
– turbine runner
– turbine scutcher
– turbine setting
– turbine spindle
– turbine starter
– turbine wheel
– two-stage gas turbine
– water turbine
– wind turbine
adjustable-blade Francis turbine — диагональная гидротурбина
gas and steam turbine installation — <engin.> установка турбинная газо-паровая
parallel-flow reaction turbine — осевая реактивная гидротурбина
propeller-type wheel turbine — <engin.> пропеллерная турбина
wind turbine electro-generator — ветровой электрический агрегат
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13 многоступенчатая турбина
Большой англо-русский и русско-английский словарь > многоступенчатая турбина
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14 Baumann, Karl
SUBJECT AREA: Steam and internal combustion engines[br]b. 18 April 1884 Switzerlandd. 14 July 1971 Ilkley, Yorkshire[br]Swiss/British mechanical engineer, designer and developer of steam and gas turbine plant.[br]After leaving school in 1902, he went to the Ecole Polytechnique, Zurich, leaving in 1906 with an engineering diploma. He then spent a year with Professor A.Stodola, working on steam engines, turbines and internal combustion engines. He also conducted research in the strength of materials. After this, he spent two years as Research and Design Engineer at the Nuremberg works of Maschinenfabrik Augsburg-Nürnberg. He came to England in 1909 to join the British Westinghouse Co. Ltd in Manchester, and by 1912 was Chief Engineer of the Engine Department of that firm. The firm later became the Metropolitan-Vickers Electrical Co. Ltd (MV), and Baumann rose from Chief Mechanical Engineer through to, by 1929, Special Director and Member of the Executive Management Board; he remained a director until his retirement in 1949.For much of his career, Baumann was in the forefront of power station steam-cycle development, pioneering increased turbine entry pressures and temperatures, in 1916 introducing multi-stage regenerative feed-water heating and the Baumann turbine multi-exhaust. His 105 MW set for Battersea "A" station (1933) was for many years the largest single-axis unit in Europe. From 1938 on, he and his team were responsible for the first axial-flow aircraft propulsion gas turbines to fly in England, and jet engines in the 1990s owe much to the "Beryl" and "Sapphire" engines produced by MV. In particular, the design of the compressor for the Sapphire engine later became the basis for Rolls-Royce units, after an exchange of information between that company and Armstrong-Siddeley, who had previously taken over the aircraft engine work of MV.Further, the Beryl engine formed the basis of "Gatric", the first marine gas turbine propulsion engine.Baumann was elected to full membership for the Institution of Mechanical Engineers in 1929 and a year later was awarded the Thomas Hawksley Gold Medal by that body, followed by their James Clayton Prize in 1948: in the same year he became the thirty-fifth Thomas Hawksley lecturer. Many of his ideas and introductions have stood the test of time, being based on his deep and wide understanding of fundamentals.JB -
15 Griffith, Alan Arnold
[br]b. 13 June 1893 London, Englandd. 13 October 1963 Farnborough, England[br]English research engineer responsible for many original ideas, including jet-lift aircraft.[br]Griffith was very much a "boffin", for he was a quiet, thoughtful man who shunned public appearances, yet he produced many revolutionary ideas. During the First World War he worked at the Royal Aircraft Factory, Farnborough, where he carried out research into structural analysis. Because of his use of soap films in solving torsion problems, he was nicknamed "Soap-bubble".During the 1920s Griffith carried out research into gas-turbine design at the Royal Aircraft Establishment (RAE; as the Royal Aircraft Factory had become). In 1929 he made proposals for a gas turbine driving a propeller (a turboprop), but the idea was shelved. In the 1930s he was head of the Engine Department of the RAE and developed multi-stage axial compressors, which were later used in jet engines. This work attracted the attention of E.W. (later Lord) Hives of Rolls-Royce who persuaded Griffith to join Rolls-Royce in 1939. His first major project was a "contra-flow" jet engine, which was a good idea but a practical failure. However, Griffith's axial-flow compressor experience played an important part in the success of Rolls-Royce jet engines from the Avon onwards. He also proposed the bypass principle used for the Conway.Griffith experimented with suction to control the boundary layer on wings, but his main interest in the 1950s centred on vertical-take-off and -landing aircraft. He developed the remarkable "flying bedstead", which consisted of a framework (the bedstead) in which two jet engines were mounted with their jets pointing downwards, thus lifting the machine vertically. It first flew in 1954 and provided much valuable data. The Short SC1 aircraft followed, with four small jets providing lift for vertical take-off and one conventional jet to provide forward propulsion. This flew successfully in the late 1950s and early 1960s. Griffith proposed an airliner with lifting engines, but the weight of the lifting engines when not in use would have been a serious handicap. He retired in 1960.[br]Principal Honours and DistinctionsCBE 1948. FRS 1941. Royal Aeronautical Society Silver Medal 1955; Blériot Medal 1962.BibliographyGriffith produced many technical papers in his early days; for example: 1926, Aerodynamic Theory of Turbine Design, Farnborough.Further ReadingD.Eyre, 1966, "Dr A.A.Griffith, CBE, FRS", Journal of the Royal Aeronautical Society (June) (a detailed obituary).F.W.Armstrong, 1976, "The aero engine and its progress: fifty years after Griffith", Aeronautical Journal (December).O.Stewart, 1966, Aviation: The Creative Ideas, London (provides brief descriptions of Griffith's many projects).JDS -
16 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]
См. также в других словарях:
multi-stage turbine — daugiapakopė turbina statusas T sritis Energetika apibrėžtis Garo ar dujų turbina, kurioje garo ar dujų plėtimasis nuo pradinio iki galinio slėgio ir šilumos energijos virsmas mechaniniu darbu vyksta keliose nuosekliose pakopose, kurių kiekvieną… … Aiškinamasis šiluminės ir branduolinės technikos terminų žodynas
turbine à plusieurs étages — daugiapakopė turbina statusas T sritis Energetika apibrėžtis Garo ar dujų turbina, kurioje garo ar dujų plėtimasis nuo pradinio iki galinio slėgio ir šilumos energijos virsmas mechaniniu darbu vyksta keliose nuosekliose pakopose, kurių kiekvieną… … Aiškinamasis šiluminės ir branduolinės technikos terminų žodynas
Turbine de tesla — La turbine de Tesla est un type de turbine sans pales breveté par Nikola Tesla en 1913. Elle utilise l effet de couche limite, et pas l impact d un fluide contre des pales comme c est le cas dans une turbine conventionnelle. La turbine de Tesla… … Wikipédia en Français
Turbine — A turbine is a rotary engine that extracts energy from a fluid flow. Claude Burdin (1788 1873) coined the term from the Latin turbo , or vortex, during an 1828 engineering competition. Benoit Fourneyron (1802 1867), a student of Claude Burdin,… … Wikipedia
Turbine de Tesla — La turbine de Tesla est un type de turbine sans pales breveté par Nikola Tesla en 1913. Elle utilise l effet de couche limite et non l impact d un fluide contre des pales comme c est le cas dans une turbine conventionnelle. La turbine de Tesla… … Wikipédia en Français
Gas turbine — Microturbine redirects here. For turbines in electricity, see Small wind turbine. For turbines driven by the flow of gas, see Turbine. A typical axial flow gas turbine turbojet, the J85, sectioned for display. Flow is left to right, multistage… … Wikipedia
Tesla turbine — The Tesla turbine is a bladeless centrifugal flow turbine expander patented by Nikola Tesla in 1913. It is referred to as a bladeless turbine because it uses the boundary layer effect and not a fluid impinging upon the blades as in a conventional … Wikipedia
National Gas Turbine Establishment — Coordinates: 51°16′59″N 0°48′26″W / 51.282957°N 0.807098°W / 51.282957; 0.807098 The National Gas Turbine Establishment … Wikipedia
ГОСТ 23851-79: Двигатели газотурбинные авиационные. Термины и определения — Терминология ГОСТ 23851 79: Двигатели газотурбинные авиационные. Термины и определения оригинал документа: 293. Аварийное выключение ГТД Аварийное выключение Ндп. Аварийное отключение ГТД D. Notausschaltung Е. Emergency shutdown F. Arrêt urgent… … Словарь-справочник терминов нормативно-технической документации
Solar thermal energy — Solar thermal system for water heating in Santorini, Greece … Wikipedia
многоступенчатая турбина — Турбина ГТД, состоящая из нескольких последовательно расположенных ступеней. Примечание При конкретной конструкции турбины она может называться по числу ступеней. [ГОСТ 23851 79] Тематики двигатели летательных аппаратов EN multi stage turbine DE… … Справочник технического переводчика