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41 industry
1. n промышленность, индустрия2. n отрасль промышленности; отрасль экономики3. n трудолюбие, усердие, прилежаниеin a few years he had bettered himself considerably by his talents and industry — за несколько лет он значительно продвинулся по службе благодаря своим способностям и трудолюбию
Синонимический ряд:1. activity (noun) activity; application; assiduity; assiduousness; diligence; energy; hard work; industriousness; perseverance; sedulousness; work; zeal2. sector of commerce (noun) branch; building trades; business; business activity; commerce; enterprise; manufacturing; sector; sector of commerce; trade; trafficАнтонимический ряд: -
42 facility
объект, сооружение; установка; pl. сооружения и службы; ( капитальное) оборудование; средства; см. тж. equipmentatmospheric entry test facilities — оборудование для исследования условий входа в плотные слои атмосферы
double-reverberant chamber test facility — испытательная установка с двумя реверберационными камерами
high-energy molecular beam facility — аэрд. установка с молекулярным пучком высокой интенсивности
low-cycle fatigue testing facility — установка для испытаний на малоцикловую усталость [выносливость]
plasma-arc jet test facility — плазменная установка [аэродинамическая труба] с электродуговым подогревателем
rocket engine test facility — установка [стенд] для испытания ракетных двигателей
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43 Breguet, Louis
SUBJECT AREA: Aerospace[br]b. 2 January 1880 Paris, Franced. 4 May 1955 Paris, France[br]French aviation pioneer who built a helicopter in 1907 and designed many successful aircraft.[br]The Breguet family had been manufacturing fine clocks since before the French Revolution, but Louis Breguet and his brother Jacques used their mechanical skills to produce a helicopter, or "gyroplane" as they named it. It was a complex machine with four biplane rotors (i.e. thirty-two lifting surfaces). Louis Breguet had carried out many tests to determine the most suitable rotor design. The Breguet brothers were assisted by Professor Charles Richet and the Breguet-Richet No. 1 was tested in September 1907 when it succeeded in lifting itself, and its pilot, to a height of 1.5 metres. Unfortunately, the gyroplane was rather unstable and four helpers had to steady it; consequently, the flight did not qualify as a "free" flight. This was achieved two months later, also in France, by Paul Cornu who made a 20-second free flight.Louis Breguet turned his attention to aeroplane design and produced a tractor biplane when most other biplanes followed the Wright brothers' layout with a forward elevator and pusher propeller. The Breguet I made quite an impression at the 1909 Reims meeting, but the Breguet IV created a world record the following year by carrying six people. During the First World War the Breguet Type 14 bomber was widely used by French and American squadrons. Between the First and Second World Wars a wide variety of designs were produced, including flying boats and another helicopter, the Breguet- Dorand Gyroplane which flew for over one hour in 1936. The Breguet company survived World War II and in the late 1940s developed a successful four-engined airliner/transport, the Deux-Ponts, which had a bulbous double-deck fuselage.Breguet was an innovative designer, although his designs were functional rather than elegant. He was an early advocate of metal construction and developed an oleo- (oil-spring) undercarriage leg.[br]Bibliography1925, Le Vol à voile dynamique des oiseaux. Analyse des effets des pulsations du vent sur la résultante aérodynamique moyenne d'un planeur, Paris.Further ReadingP.Faure, 1938, Louis Breguet, Paris (biography).C.H.Gibbs-Smith, 1965, The Invention of the Aeroplane 1799–1909, London (provides a careful analysis of Breguet's early aircraft).JDS -
44 de Havilland, Sir Geoffrey
SUBJECT AREA: Aerospace[br]b. 27 July 1882 High Wycombe, Buckinghamshire, Englandd. 21 May 1965 Stanmore, Middlesex, England[br]English designer of some eighty aircraft from 1909 onwards.[br]Geoffrey de Havilland started experimenting with aircraft and engines of his own design in 1908. In the following year, with the help of his friend Frank Hearle, he built and flew his first aircraft; it crashed on its first flight. The second aircraft used the same engine and made its first flight on 10 September 1910, and enabled de Havilland to teach himself to fly. From 1910 to 1914 he was employed at Farnborough, where in 1912 the Royal Aircraft Factory was established. As Chief Designer and Chief Test Pilot he was responsible for the BE 2, which was the first British military aircraft to land in France in 1914.In May 1914 de Havilland went to work for George Holt Thomas, whose Aircraft Manufacturing Company Ltd (Airco) of Hendon was expanding to design and build aircraft of its own design. However, because de Havilland was a member of the Royal Flying Corps Reserve, he had to report for duty when war broke out in August. His value as a designer was recognized and he was transferred back to Airco, where he designed eight aircraft in four years. Of these, the DH 2, DH 4, DH 5, DH 6 and DH 9 were produced in large numbers, and a modified DH 4A operated the first British cross- Channel air service in 1919.On 25 September 1920 de Havilland founded his own company, the De Havilland Aircraft Company Ltd, at Stag Lane near Edgware, London. During the 1920s and 1930s de Havilland concentrated on civil aircraft and produced the very successful Moth series of small biplanes and monoplanes, as well as the Dragon, Dragon Rapide, Albatross and Flamingo airliners. In 1930 a new site was acquired at Hatfield, Hertfordshire, and by 1934 a modern factory with a large airfield had been established. His Comet racer won the England-Australia air race in 1934 using de Havilland engines. By this time the company had established very successful engine and propeller divisions. The Comet used a wooden stressed-skin construction which de Havilland developed and used for one of the outstanding aircraft of the Second World War: the Mosquito. The de Havilland Engine Company started work on jet engines in 1941 and their Goblin engine powered the Vampire jet fighter first flown by Geoffrey de Havilland Jr in 1943. Unfortunately, Geoffrey Jr and his brother John were both killed in flying accidents. The Comet jet airliner first flew in 1949 and the Trident in 1962, although by 1959 the De Havilland Company had been absorbed into Hawker Siddeley Aviation.[br]Principal Honours and DistinctionsKnight Bachelor 1944. Order of Merit 1962. CBE 1934. Air Force Cross 1919. (A full list is contained in R.M.Clarkson's paper (see below)).Bibliography1961, Sky Fever, London; repub. 1979, Shrewsbury (autobiography).Further ReadingR.M.Clarkson, 1967, "Geoffrey de Havilland 1882–1965", Journal of the Royal Aeronautical Society (February) (a concise account of de Havilland, his achievements and honours).C.M.Sharp, 1960, D.H.—An Outline of de Havilland History, London (mostly a history of the company).A.J.Jackson, 1962, De Havilland Aircraft since 1915, London.JDSBiographical history of technology > de Havilland, Sir Geoffrey
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45 Ellehammer, Jacob Christian Hansen
SUBJECT AREA: Aerospace[br]b. 14 June 1871 South Zealand, Denmarkd. b. 20 May 1946 Copenhagen, Denmark[br]Danish inventor who took out some four hundred patents for his inventions, including aircraft.[br]Flying kites as a boy aroused Ellehammer's interest in aeronautics, and he developed a kite that could lift him off the ground. After completing an apprenticeship, he started his own manufacturing business, whose products included motor cycles. He experimented with model aircraft as a sideline and used his mo tor-cycle experience to build an aero engine during 1903–4. It had three cylinders radiating from the crankshaft, making it, in all probability, the world's first air-cooled radial engine. Ellehammer built his first full-size aircraft in 1905 and tested it in January 1906. It ran round a circular track, was tethered to a central mast and was unmanned. A more powerful engine was needed, and by September Ellehammer had improved his engine so that it was capable of lifting him for a tethered flight. In 1907 Ellehammer produced a new five-cylinder radial engine and installed it in the first manned tri-plane, which made a number of free-flight hops. Various wing designs were tested and during 1908–9 Ellehammer developed yet another radial engine, which had six cylinders arranged in two rows of three. Ellehammer's engines had a very good power-to-weight ratio, but his aircraft designs lacked an understanding of control; consequently, he never progressed beyond short hops in a straight line. In 1912 he built a helicopter with contra-rotating rotors that was a limited success. Ellehammer turned his attention to his other interests, but if he had concentrated on his excellent engines he might have become a major aero engine manufacturer.[br]Bibliography1931, Jeg fløj [I Flew], Copenhagen (Ellehammer's memoirs).Further ReadingC.H.Gibbs-Smith, 1965, The Invention of the Aeroplane 1799–1909, London (contains concise information on Ellehammer's aircraft and their performance).J.H.Parkin, 1964, Bell and Baldwin, Toronto (provides more detailed descriptions).JDSBiographical history of technology > Ellehammer, Jacob Christian Hansen
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46 Farman, Henri
SUBJECT AREA: Aerospace[br]b. 26 May 1874 Paris, Franced. 17 July 1958 Paris, France[br]French aeroplane designer who modified Voisin biplanes and later, with his brother Maurice (b. 21 March 1877 Paris, France; d. 26 February 1964 Paris, France), created a major aircraft-manufacturing company.[br]The parents of Henri and Maurice Farman were British subjects living in Paris, but their sons lived all their lives in France and became French citizens. As young men, both became involved in cycle and automobile racing. Henri (or Henry—he used both versions) turned his attention to aviation in 1907 when he bought a biplane from Gabriel Voisin. Within a short time he had established himself as one of the leading pilots in Europe, with many record-breaking flights to his credit. Farman modified the Voisin with his own improvements, including ailerons, and then in 1909 he designed the first Farman biplane. This became the most popular biplane in Europe from the autumn of 1909 until well into 1911 and is one of the classic aeroplanes of history. Meanwhile, Maurice Farman had also begun to design and build biplanes; his first design of 1909 was not a great success but from it evolved two robust biplanes nicknamed the "Longhorn" and the "Shorthorn", so called because of their undercarriage skids. In 1912 the brothers joined forces and set up a very large factory at Billancourt. The "Longhorn" and "Shorthorn" became the standard training aircraft in France and Britain during the early years of the First World War. The Farman brothers went on to produce a number of other wartime designs, including a large bomber. After the war the Farmans produced a series of large airliners which played a key role in establishing France as a major airline operator. Most famous of these was the Goliath, a twin-engined biplane capable of carrying up to twelve passengers. This was produced from 1918 to 1929 and was used by many airlines, including the Farman Line. The brothers retired when their company was nationalized in 1937.[br]Bibliography1910, The Aviator's Companion, London (with his brother Dick Farman).Further ReadingM.Farman, 1901, 3,000 kilomètres en ballon, Paris (an account of several balloon flights from 1894 to 1900).J.Liron, 1984, Les Avions Farman, Paris (provides comprehensive descriptions of all Farman aircraft).Jane's Fighting Aircraft of World War I, 1990, London (reprint) (gives details of all early Farman aircraft).J.Stroud, 1966, European Aircraft since 1910, London (provides details about Farman air-liners).JDS -
47 Handley Page, Sir Frederick
SUBJECT AREA: Aerospace[br]b. 15 November 1885 Cheltenham, Englandd. 21 April 1962 London, England[br]English aviation pioneer, specialist in large aircraft and developer of the slotted wing for safer slow flying.[br]Frederick Handley Page trained as an electrical engineer but soon turned his attention to the more exciting world of aeronautics. He started by manufacturing propellers for aeroplanes and airships, and then in 1909 he founded a public company. His first aeroplane, the Bluebird, was not a success, but an improved version flew well. It was known as the "Yellow Peril" because of its yellow doped finish and made a notable flight across London from Barking to Brooklands. In 1910 Handley Page became one of the first college lecturers in aeronautical engineering. During the First World War Handley Page concentrated on the production of large bombers. The 0/100 was a biplane with a wing span of 100 ft (30 m) and powered by two engines: it entered service in 1916. In 1918 an improved version, the 0/400, entered service and a larger four-engined bomber made its first flight. This was the V/1500, which was designed to bomb Berlin, but the war ended before this raid took place. After the war, Handley Page turned his attention to airline operations with the great advantage of having at his disposal large bombers which could be adapted to carry passengers. Handley Page Air Transport Ltd was formed in 1919 and provided services to several European cities. Eventually this company became part of Imperial Airways, but Handley Page continued to supply them with large airliners. Probably the most famous was the majestic HP 42 four-engined biplane, which set very high standards of comfort and safety. Safety was always important to Handley Page and in 1920 he developed a wing with a slot along the leading edge: this made slow flying safer by delaying the stall. Later versions used separate aerofoil-shaped slats on the leading edge that were sometimes fixed, sometimes retractable. The HP 42 was fitted with these slats. From the 1930s Handley Page produced a series of bombers, such as the Heyford, Hampden, Harrow and, most famous of all, the Halifax, which played a major role in the Second World War. Then followed the Victor V-bomber of 1952 with its distinctive "crescent" wing and high tailplane. Sir Frederick's last venture was the Herald short-haul airliner of 1955; designed to replace the ubiquitous Douglas DC-3, it was only a limited success.[br]Principal Honours and DistinctionsKnighted 1942. CBE 1918. Lord Lieutenant of the County of Middlesex 1956–60. Honorary Fellow of the Royal Aeronautical Society.Bibliography1950, "Towards slower and safer flying, improved take-off and landing and cheaper airports", Journal of the Royal Aeronautical Society.Further ReadingTwo accounts of Handley Page's life and work were published in the Journal of the Royal Aeronautical Society December 1962 and July 1964.D.C.Clayton, 1970, Handley Page: An Aircraft Album, London (for details of his aircraft).C.H.Barnes, 1976, Handley Page Aircraft since 1907, London.JDSBiographical history of technology > Handley Page, Sir Frederick
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48 Sperry, Elmer Ambrose
[br]b. 21 October 1860 Cincinnatus, Cortland County, New York, USAd. 16 June 1930 Brooklyn, New York, USA[br]American entrepreneur who invented the gyrocompass.[br]Sperry was born into a farming community in Cortland County. He received a rudimentary education at the local school, but an interest in mechanical devices was aroused by the agricultural machinery he saw around him. His attendance at the Normal School in Cortland provided a useful theoretical background to his practical knowledge. He emerged in 1880 with an urge to pursue invention in electrical engineering, then a new and growing branch of technology. Within two years he was able to patent and demonstrate his arc lighting system, complete with its own generator, incorporating new methods of regulating its output. The Sperry Electric Light, Motor and Car Brake Company was set up to make and market the system, but it was difficult to keep pace with electric-lighting developments such as the incandescent lamp and alternating current, and the company ceased in 1887 and was replaced by the Sperry Electric Company, which itself was taken over by the General Electric Company.In the 1890s Sperry made useful inventions in electric mining machinery and then in electric street-or tramcars, with his patent electric brake and control system. The patents for the brake were important enough to be bought by General Electric. From 1894 to 1900 he was manufacturing electric motor cars of his own design, and in 1900 he set up a laboratory in Washington, where he pursued various electrochemical processes.In 1896 he began to work on the practical application of the principle of the gyroscope, where Sperry achieved his most notable inventions, the first of which was the gyrostabilizer for ships. The relatively narrow-hulled steamship rolled badly in heavy seas and in 1904 Ernst Otto Schuck, a German naval engineer, and Louis Brennan in England began experiments to correct this; their work stimulated Sperry to develop his own device. In 1908 he patented the active gyrostabilizer, which acted to correct a ship's roll as soon as it started. Three years later the US Navy agreed to try it on a destroyer, the USS Worden. The successful trials of the following year led to widespread adoption. Meanwhile, in 1910, Sperry set up the Sperry Gyroscope Company to extend the application to commercial shipping.At the same time, Sperry was working to apply the gyroscope principle to the ship's compass. The magnetic compass had worked well in wooden ships, but iron hulls and electrical machinery confused it. The great powers' race to build up their navies instigated an urgent search for a solution. In Germany, Anschütz-Kämpfe (1872–1931) in 1903 tested a form of gyrocompass and was encouraged by the authorities to demonstrate the device on the German flagship, the Deutschland. Its success led Sperry to develop his own version: fortunately for him, the US Navy preferred a home-grown product to a German one and gave Sperry all the backing he needed. A successful trial on a destroyer led to widespread acceptance in the US Navy, and Sperry was soon receiving orders from the British Admiralty and the Russian Navy.In the rapidly developing field of aeronautics, automatic stabilization was becoming an urgent need. In 1912 Sperry began work on a gyrostabilizer for aircraft. Two years later he was able to stage a spectacular demonstration of such a device at an air show near Paris.Sperry continued research, development and promotion in military and aviation technology almost to the last. In 1926 he sold the Sperry Gyroscope Company to enable him to devote more time to invention.[br]Principal Honours and DistinctionsJohn Fritz Medal 1927. President, American Society of Mechanical Engineers 1928.BibliographySperry filed over 400 patents, of which two can be singled out: 1908. US patent no. 434,048 (ship gyroscope); 1909. US patent no. 519,533 (ship gyrocompass set).Further ReadingT.P.Hughes, 1971, Elmer Sperry, Inventor and Engineer, Baltimore: Johns Hopkins University Press (a full and well-documented biography, with lists of his patents and published writings).LRD -
49 Voisin, Gabriel
SUBJECT AREA: Aerospace[br]b. 5 February 1880 Belleville-sur-Saône, Franced. 25 December 1973 Ozenay, France[br]French manufacturer of aeroplanes in the early years of aviation.[br]Gabriel Voisin was one of a group of aviation pioneers working in France c. 1905. One of the leaders of this group was a rich lawyer-sportsman, Ernest Archdeacon. For a number of years they had been building gliders based on those of the Wright brothers. Archdeacon's glider of 1904 was flown by Voisin, who went on to assist in the design and manufacture of gliders for Archdeacon and Louis Blériot, including successful float-gliders. Gabriel Voisin was joined by his brother Charles in 1905 and they set up the first commercial aircraft factory. As the Voisins had limited funds, they had to seek customers who could afford to indulge in the fashionable hobby of flying. One was Santos- Dumont, who commissioned Voisin to build his "14 bis" aeroplane in 1906.Early in 1907 the Voisins built their first powered aeroplane, but it was not a success.Later that year they completed a biplane for a Paris sculptor, Léon Delagrange, and another for Henri Farman. The basic Voisin was a biplane with the engine behind the pilot and a "pusher" propeller. Pitching was controlled by biplane elevators forward of the pilot and rudders were fitted to the box kite tail, but there was no control of roll.Improvements were gradually introduced by the Voisins and their customers, such as Farman. Incidentally, to flatter their clients the Voisins often named the aircraft after them, thus causing some confusion to historians. Many Voisins were built up until 1910, when the company's fortunes sank. Competition was growing, the factory was flooded, and Charles left. Gabriel started again, building robust biplanes of steel construction. Voisin bombers were widely used during the First World War, and a subsidiary factory was built in Russia.In August 1917, Voisin sold his business when the French Air Ministry decided that Voisin aeroplanes were obsolete and that the factory should be turned over to the building of engines. After the war he started another business making prefabricated houses, and then turned to manufacturing motor cars. From 1919 to 1939 his company produced various models, mainly for the luxury end of the market but also including a few sports and racing cars. In the early 1950s he designed a small two-seater, which was built by the Biscuter company in Spain. The Voisin company finally closed in 1958.[br]Principal Honours and DistinctionsChevalier de la Légion d'honneur 1909. Académie des Sciences Gold Medal 1909.Bibliography1961, Mes dix milles cerfs-volants, France; repub. 1963 as Men, Women and 10,000 Kites, London (autobiography; an eminent reviewer said, "it contains so many demonstrable absurdities, untruths and misleading statements, that one does not know how much of the rest one can believe").1962, Mes Mille et un voitures, France (covers his cars).Further ReadingC.H.Gibbs-Smith, 1965, The Invention of the Aeroplane 1799–1909, London (includes an account of Voisin's contribution to aviation and a list of his early aircraft).Jane's Fighting Aircraft of World War I, London; reprinted 1990 (provides details of Voisin's 1914–18 aircraft).E.Chadeau, 1987, L'Industrie aéronautique en France 1900–1950, de Blériot à Dassault, Paris.G.N.Georgano, 1968, Encyclopedia of Motor Cars 1885 to the Present, New York (includes brief descriptions of Voisin's cars).JDS -
50 environment
aerodynamic environment — аэродинамические условия
aerospace environment — окружающие условия в воздушно-космическом пространстве
artificial environment — искусственная среда, имитирующие условия
ascent environment — условия подъёма
ascent aerodynamic environment — условия аэродинамического подъёма
atmospheric environment — окружающие атмосферные условия
chemical environment — химическая среда
corrosion environment — коррозионная среда
corrosive environment — коррозионная среда
cryogenic environment — криогенные условия
elevated-temperature environment — условия при повышенной температуре, условия воздействия высоких температур
erosive environment — эрозионная среда
gaseous environment — газовая среда, условия воздействия газовой среды
heating environment — нагревающая среда, условия нагрева
high-temperature environment — условия при высоких температурах
high-temperature oxidative environment — окисляющая среда при высоких температурах
landing environment — условия приземления [посадки]
launch environment — условия пуска ( ракеты)
launch site environment — условия на пусковой установке
low-temperature environment — условия при низких температурах
manufacturing environment — производственные условия, условия производства
outer-space environment — внешние космические условия
oxidizing environment — окисляющая среда
penetrating-radiation environment — условия проникающей радиации
prelaunch environment — предпусковые условия
preorbital environment — предорбитальпые условия
radiation environment — радиационная среда
re-entry environment — условия входа в плотную атмосферу
salt environment — солевая среда
sea environment — морские условия
service environment — эксплуатационная среда
space environment — космические условия [среда]
temperature environment — температурные условия ( окружающей среды)
thermal environment — тепловые условия
transportation environment — условия транспортировки
tropical environment — тропические условия
vacuum environment — условия вакуума
vacuum radiation environment — условия излучения в вакууме
vibration environment — вибрационные условия
weather environment — погодные условия
zero-gravity environment — условия невесомости
English-Russian dictionary of aviation and space materials > environment
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51 AMD
AMD, administrative management division————————AMD, aerospace medical division————————AMD, air maintenance division————————AMD, air movement designator————————AMD, air movement directive————————AMD, aircraft manufacturing depot————————AMD, airmobile division————————AMD, Army Medical Department————————AMD, Assistant Military Deputy————————AMD, automated maintenance depotEnglish-Russian dictionary of planing, cross-planing and slotting machines > AMD
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