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21 system
1) система
2) комплекс
3) совокупность
4) множество
5) область
6) схемный
7) устройство
8) системный
– adaptive system
– addressing system
– airdrop system
– antenna system
– arithmetic system
– blok system
– bus system
– c.m. system
– center-of-mass system
– classification system
– commutation system
– controlled system
– cooling system
– crossbar system
– cryoelectronic system
– deferlant system
– deflection system
– dial system
– distributed system
– double-current system
– doudecimal system
– draft system
– drainage system
– earth system
– ecological system
– encoder system
– energy system
– error-controlled system
– evaporator system
– exhaust system
– file system
– finder system
– floating-carrier system
– floating-point system
– focusing system
– fuel system
– gas-cleaning system
– gas-pressurized system
– ground system
– guidance system
– history of a system
– hot-water system
– hydraulic system
– identifiable system
– inertial system
– inteblock system
– Korsch system
– laboratory system
– Lesniewski system
– life-support system
– lightguiding system
– linear system
– monitoring system
– multimicroprocessor system
– multiple-data-set system
– non-autonomous system
– nondirector system
– number system
– parallel-feed system
– piece-rate system
– planetary system
– pneumatic system
– propulsion system
– prototype system
– public-address system
– quadrophonic system
– queuing system
– response of system
– right-handed system
– robot system
– safety-trip system
– sampled-data system
– scanning system
– sewage system
– shift system
– spraying system
– sprinkling system
– staff system
– stand-by system
– start-stop system
– start-up system
– storage system
– system behavior
– system check
– system debugging
– system design
– system failure
– system of equations
– system of imprimitivity
– system of wheels
– system reliability
– system topology
– tally system
– telephone system
– television system
– ten-step system
– timing system
– transmission system
– triangulation system
– triclinic system
– twelve-channel system
– two-particle system
– unattended system
– unstable system
– ventilation system
– video system
– warning system
– water-sludge system
– wellpoint system
aircraft electrical system — <aeron.> сеть бортовая электрическая
ample linear system — <math.> система линейная обильная
approach and docking system — <cosm.> система сближения и стыковки
automated/automatic landing system — <aeron.> система захода на посадку автоматизированная
automatic block system — < railways> автоблокировка
automatic deicing system — <aeron.> автомат противообледенительной системы
bang-bang control system — <comput.> система управления релейная
carrier frequency system — система передачи с частотным разделением каналов
Cartesian coordinate system — прямоугольная система координат
closed-circuit television system — <commun.> система телевидения невещательная
cycle matching system — <aeron.> навигация воздушная импульсная, система навигационная импульсная
differential selsyn system — дифсельсин, сельсин дифференциальный
digital counting system — <comput.> система отслеживающая цифровая
digital transmission system — <commun.> система передачи цифровая
disk operating system — <comput.> система операционная дисковая
dispatch telephone system — диспетчерская телефонная система
fiber-optics communication system — <commun.> система связи волоконно-оптическая
hereditarily generating system — наследственная система образующих
hexadecimal number system — шестнадцатиричная система счисления
information retrieval system — <comput.> система информационно-поисковая
integrated switching system — интегральная коммутационная система
itnegrated manufacturing system — комплексная автоматическая линия
jet engine starter system — <engin.> турбостартер
meteor-burst communication system — <commun.> система связи метеорная
microprocessor control system — микропроцессорная система управления
modular pneumatic-device system — система унифицированная агрегатная
modular programming system — <comput.> система модульного программирования
multipoint distribution system — многоадресная система распределения ТВ-программ
packet transmission system — система передачи с коммутацией пакетов сообщений
Pitot static system — <engin.> система ПВД
pulsed navigation system — <aeron.> навигация воздушная импульсная, система навигационная импульсная
quantum-mechanical readout system — <tech.> система считывающая квантовая
quasi-electronic switching system — квазиэлектронная система коммутации
reactor control system — <engin.> система управления и защиты
reactor protection system — <phys.> защита аварийная
receiver-amplifier crioelectric system — приемно-усилительная криоэлектронная система
remote-cylinder hydraulic system — раздельно—агрегатная гидросистема
resultant of system of forces — равнодействующая системы сил
satellite navigation system — <naut.> система навигационная космическая, система навигационная спутниковая
State System of Instruments — <engin.> система приборов Государственная
supervisory control system — <comput.> автодиспетчер
system of residual classes — <math.> система остаточных классов
telegraph block system — < railways> движение поездов по телеграфному соглашению
time interval system — < railways> разграничение поездов временем
time-division multiplex system — система передачи с временным разделением
unified radiotelemetry system — унифицированный радиотелеметрический комплекс
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22 system
1) система; комплекс2) совокупность•- absolutely consistent system - absolutely direct indecomposable system - absolutely free system - absolutely irreducible system - absolutely isolated system - allowable coordinate system - almost linear system - ample linear system - artificial feel system - automatic block system - automatic deicing system - binary relational system - binary-coded decimal system - block tooling system - Cartesian coordinate system - completely controllable system - completely ergodic system - completely hyperbolic system - completely identifiable system - completely integrable system - completely irreducible system - completely regular system - completely stable system - completely stratified system - complex number system - conical coordinate system - derivational formal system - differential equation system - differential selsyn system - digital counting system - digital transmission system - elliptic coordinate system - elliptic cylindrical coordinate system - externally inconsistent system - finite state system - finitely axiomatizable system - finitely presented system - fully characteristic quotient system - fundamental system of solutions - hydraulic lift system - integrated switching system - isomorphically embedded system - kernel normal system - linearly dependent system - linearly independent system - live hydraulic system - locking protection system - meteor-burst communication system - modular programming system - parabolic cylindrical coordinate system - permanent four-wheel drive system - pure independent system - radio telephone system - reactor protection system - real number system - receiver-amplifier crioelectric system - remote-cylinder hydraulic system - semantically consistent system - simply consistent system - simply incomplete system - simply ordered system - spherical coordinate system - strongly multiplicative system - structurally stable system - sufficiently general coordinate system - system of frequency curves - system of rational numbers - time multiplex system - time-division multiplex system - uniformly complete system - univalent system of notation - universal system of notation - weakly closed system - weighted number system -
23 engine
двигатель; моторautomatic adjustable volume turbulence (combustion) chamber (diesel) engine — (дизельный) двигатель с вихревой камерой (сгорания) с автоматически регулируемым объемом
divided (combustion) chamber multifuel engine — многотопливный двигатель с раздельной камерой сгорания
— antechamber diesel engine -
24 Ricardo, Sir Harry Ralph
[br]b. 26 January 1885 London, Englandd. 18 May 1974 Graffham, Sussex, England[br]English mechanical engineer; researcher, designer and developer of internal combustion engines.[br]Harry Ricardo was the eldest child and only son of Halsey Ricardo (architect) and Catherine Rendel (daughter of Alexander Rendel, senior partner in the firm of consulting civil engineers that later became Rendel, Palmer and Tritton). He was educated at Rugby School and at Cambridge. While still at school, he designed and made a steam engine to drive his bicycle, and by the time he went up to Cambridge in 1903 he was a skilled craftsman. At Cambridge, he made a motor cycle powered by a petrol engine of his own design, and with this he won a fuel-consumption competition by covering almost 40 miles (64 km) on a quart (1.14 1) of petrol. This brought him to the attention of Professor Bertram Hopkinson, who invited him to help with research on turbulence and pre-ignition in internal combustion engines. After leaving Cambridge in 1907, he joined his grandfather's firm and became head of the design department for mechanical equipment used in civil engineering. In 1916 he was asked to help with the problem of loading tanks on to railway trucks. He was then given the task of designing and organizing the manufacture of engines for tanks, and the success of this enterprise encouraged him to set up his own establishment at Shoreham, devoted to research on, and design and development of, internal combustion engines.Leading on from the work with Hopkinson were his discoveries on the suppression of detonation in spark-ignition engines. He noted that the current paraffinic fuels were more prone to detonation than the aromatics, which were being discarded as they did not comply with the existing specifications because of their high specific gravity. He introduced the concepts of "highest useful compression ratio" (HUCR) and "toluene number" for fuel samples burned in a special variable compression-ratio engine. The toluene number was the proportion of toluene in heptane that gave the same HUCR as the fuel sample. Later, toluene was superseded by iso-octane to give the now familiar octane rating. He went on to improve the combustion in side-valve engines by increasing turbulence, shortening the flame path and minimizing the clearance between piston and head by concentrating the combustion space over the valves. By these means, the compression ratio could be increased to that used by overhead-valve engines before detonation intervened. The very hot poppet valve restricted the advancement of all internal combustion engines, so he turned his attention to eliminating it by use of the single sleeve-valve, this being developed with support from the Air Ministry. By the end of the Second World War some 130,000 such aero-engines had been built by Bristol, Napier and Rolls-Royce before the piston aero-engine was superseded by the gas turbine of Whittle. He even contributed to the success of the latter by developing a fuel control system for it.Concurrent with this was work on the diesel engine. He designed and developed the engine that halved the fuel consumption of London buses. He invented and perfected the "Comet" series of combustion chambers for diesel engines, and the Company was consulted by the vast majority of international internal combustion engine manufacturers. He published and lectured widely and fully deserved his many honours; he was elected FRS in 1929, was President of the Institution of Mechanical Engineers in 1944–5 and was knighted in 1948. This shy and modest, though very determined man was highly regarded by all who came into contact with him. It was said that research into internal combustion engines, his family and boats constituted all that he would wish from life.[br]Principal Honours and DistinctionsKnighted 1948. FRS 1929. President, Institution of Mechanical Engineers 1944–5.Bibliography1968, Memo \& Machines. The Pattern of My Life, London: Constable.Further ReadingSir William Hawthorne, 1976, "Harry Ralph Ricardo", Biographical Memoirs of Fellows of the Royal Society 22.JBBiographical history of technology > Ricardo, Sir Harry Ralph
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25 panel
панель; распределительная доска [щит]; приборная доска; консоль ( крыла) ; клин ( полотнища парашютного купола) ; сигнальное полотнище; комиссия, рабочая группаa.c. power panel — щиток управления электросистемой переменного тока
d.c. power panel — щиток управления электросистемой постоянного тока
emergency flotation gear panel — верт. панель аварийных средств обеспечения плавучести
essential services circuit breaker panel — эл. щиток автоматов защиты важнейших потребителей
first officer's instrument panel — приборная доска [панель] второго лётчика [пилота]
hat section stiffened panel — панель, подкрепленная корытообразным профилем
navigation function selector panel — щиток переключения видов [режимов] работы навигационных средств
navigation mode selector panel — щиток переключения видов [режимов] работы навигационных средств
rack cartridge ground test panel — щиток наземной проверки пиропатронов. подвески
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26 pressure
давление; сжатие; прессование; герметичныйboundary layer induced pressure — давление, обусловленное пограничным слоем
computer unit output pressure — давление на выходе решающего гидроусилителя (автомата загрузки бустерного управления)
dump the pressure to return — стравливать [перепускать] давление в отводящую магистраль
forward (control) stick pressure — усилие (на ручке) в направлении «от себя», давящее [толкающее] усилие (на ручке)
partial pressure suit capstan pressure — давление в натяжных пневмокамерах высотного компенсирующего костюма
relax forward pressure on the stick — уменьшать усилие на ручке в направлении «от себя»: отпускать ручку назад
relieve the back pressure on the stick — уменьшать усилие на ручке в направлении «на себя»; отпускать ручку вперёд
saturated vapor pressure — упругость насыщающего пара; давление насыщенного пара
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27 start
start nстартstarting vзапуск(двигателя) air startingзапуск в воздухеair starting systemвоздушная система запуска двигателейall-engines startingодновременный запуск всех двигателейat the start of cycleв начале циклаat the start of segmentв начале участка(полета) cross-bleed startingперекрестный запускengine dry startingхолодная прокрутка двигателяengine false startingложный запуск двигателяengine hot startingзапуск двигателя с забросом температуры(выше допустимой) engine startingзапуск двигателяengine starting procedureпорядок запуска двигателяengine starting systemсистема запуска двигателейengine start modeработа в режиме запуска двигателяengine start systemсистема запуска двигателейengine start valveклапан запуска двигателяengine wet startingложный запуск двигателяfail startingнеудавшийся запускground air starting unitаэродромная установка для запускаground starting unitназемная установка для запускаheight at start of retractionвысота начала уборкиhot startingгорячий запускhydraulic starting systemгидравлическая пусковая система(двигателя) independent starting systemсистема автономного запуска(двигателя) inflight nonassisted startingзапуск в полете без включения стартераinflight startingзапуск в полетеprimary fuel starting manifoldпервый топливный коллекторready to startготовность к запускуrolling startвзлет без остановки(после выруливания на ВПП) rotor startingраскрутка несущего винтаself-contained starting systemавтономная система запускаsequence startingступенчатый запускstanding startисполнительный стартstart an engineзапускать двигательstart angleначальный уголstart cycleпериодичность запусковstarted fuel valveклапан пускового топливаstarting circuitцепь запускаstarting counterсчетчик количества запусковstarting currentпусковой токstarting cycleцикл запускаstarting engineпусковой двигательstarting engine operationзапуск двигателяstarting from an operating engineперекрестный запускstarting fuelпусковое топливоstarting fuel control unitавтомат подачи пускового топливаstarting fuel nozzleфорсунка пускового топливаstarting manifoldпусковой коллекторstarting on external powerзапуск от внешнего источникаstarting procedureпорядок запуска двигателяstarting runпервоначальный этап разбегаstarting systemсистема запускаstart of leveloffначало выравниванияstart of takeoffначало разбега при взлетеstart tracker unitдатчик курсовых углов астрокомпасаstart upзапускатьwindmill startingзапуск в режиме авторотации -
28 unit
unit nпунктacceleration control unitавтомат приемистостиacross track display unitблок индикатора отклонения от линии путиaerodrome control unitаэродромный диспетчерский пунктaileron servo unitрулевая машинка элероновaircraft step unitбортовой трапair-flow metering unitзаслонка дозировки расхода воздухаair-mileage unitавтомат счисления путиairport rescue unitспасательная команда аэропортаair traffic control unitпункт управления воздушным движениемair traffic services unitпункт обслуживания воздушного движенияair unitавиационное подразделениеalong track display unitблок индикатора оставшегося путиaltitude control unitвысотный корректорaltitude sensing unitблок датчика высотного корректораantenna-electronics unitэлектронный антенный блокantenna turning unitповоротный механизм антенныйapproach control unitдиспетчерский пункт управления заходом на посадкуapron management unitорган управления движением на перронеartificial feel unitзагрузочный механизмAudio Visual Aids UnitСектор аудиовизуальных средствautomatic range unitблок автоматического определения дальностиautopilot disengage unitблок отключения автопилотаautopilot servo unitрулевая машинка автопилотаautostart control unitавтомат запускаauxiliary power unitвспомогательная силовая установкаazimuth guidance unitблок азимутального наведенияbank-and-climb gyro unitгироавтомат крена и тангажаbleed valve control unitблок управления клапанами перепускаbrake unitмеханизм торможенияCartographic UnitКартографический секторcold-air unitхолодильная установкаcompass system coupling unitблок связи с курсовой системойconstant-speed unitрегулятор постоянных оборотовcontrol unitкомандный приборData Processing UnitСектор обработки данныхdeceleration control unitдроссельный механизмdisplay unit1. блок индикации2. блок управления Distribution UnitСектор распространения документацииDocument Control UnitСектор контроля за документациейelevation setting of light unitsустановка углов возвышения глиссадных огнейengine-driven unitагрегат с приводом от двигателяengine-propeller unitвинтомоторный блокexhaust unitвыхлопное устройствоexpenses per traffic unitрасходы на единицу перевозкиfare construction unitбазовый тарифfeel unitзагрузочный механизмField Personal Administration UnitСектор учета кадров на местахField Procurement Services UnitСектор обеспечения снабжения на местахField Purchasing UnitСектор закупок на местахField Recruitment UnitСектор найма на местахfire-protection unitпротивопожарный блокflight data storage unitблок сбора полетной информацииflight information service unitаэродромный диспетчерский пункт полетной информацииflushing unitустановка для прокачкиfree wheel unitмуфта свободного ходаfuel control unitкомандно-топливный агрегатfueling nose unitпистолет заправки топливомfuel metering unitагрегат дозировки топливаGeneral Services UnitСектор общего обслуживанияground air starting unitаэродромная установка для запускаground power unitаэродромный пусковой агрегатground starting unitназемная установка для запускаgyro unitгидроагрегатhydraulic unitгидроагрегатignition unitблок зажиганияinertial navigation unitинерциально-навигационный блокinformation service unitинформационно-справочная службаjacking control unitпульт управления подъемникамиlimit bank warning unitблок сигнализации предельного кренаload feel unitзагрузочный механизмload per unit areaнагрузка на единицу площадиoutside power unitвнешний источник питанияpipeline to tail unitтрубопровод подвода воздуха к хвостовому оперениюplug-and-socket unitсоединитель со штыревым разъемомpower unitсиловой агрегатpressure control unitавтомат давленияpropeller control unitрегулятор числа оборотов воздушного винтаpropulsion unitсиловая установкаprotection-and-control unitблок защиты и управленияpumping unitнасосная станцияPurchasing UnitСектор закупокQ-feel unitмеханизм усилий по скоростному напоруquick release unitбыстросъемный блокradar coupling unitблок связи с радиолокационным оборудованиемrange-indicator unitблок указателя дальностиrate construction unitединица при построении грузовых тарифовrate gyro unitблок датчиков угловых скоростей гироскопаrate-of-flow metering unitдатчик мгновенного расходаreceiver-processor unitприемник - процессорreclaim unitкарусель для выдачиrefuelling unitкомплект оборудования для заправки и слива топливаRegistry and Achieves UnitСектор регистрации и архивовrevenue per traffic unitдоход на единицу воздушной перевозкиrudder pedal unitпульт ножного управления рулем направленияrudder servo unitрулевая машинка руля направленияrudder unitвертикальное оперениеrunway lighting unitкомплект светотехнического оборудования ВППservo unitрулевая машинкаShopping and Mail UnitЭкспедицияsingle-point unitпульт централизованного управленияslot-type unitагрегат щелевого типаstandby power unitзапасной агрегатstarter unitпусковой блокstarting fuel control unitавтомат подачи пускового топливаstart tracker unitдатчик курсовых углов астрокомпасаswivel coupling unitгидрошарнирное соединениеsynchronizer unitблок согласованияsystem of unitsсистема единиц(измерения) tail unitхвостовое оперениеthree-pointer engine gage unitтрехстрелочный указательtotal flow metering unitдатчик суммарного расходаtraffic unitединица воздушной перевозкиunit fittingарматура крепленияunit loadукомплектованный грузunit load deviceсредство пакетирования грузовunit load device rateтариф за перевозку грузов в специальном приспособлении для комплектованияunit noise durationпродолжительность единичного звукового сигналаunit of measurementединица измеренияunit operating costsстоимость контейнерных перевозокunit seat priceсредняя стоимость одного местаunit tollспециальный тариф за перевозку транспортируемой единицыunit toll transportationперевозка по специальному тарифуvisual display unitтабло информацииwarning system control unitблок управления аварийной сигнализацииwindshield heat control unitавтомат обогрева стекол -
29 unit
1. ( командный) пункт2. комплект ( оборудования)4. аппарат; установка; блок5. узел; секция; звено— air unit -
30 switch
выключатель; переключатель; коммутатор; переход; переключение внимания ( лётчика) ; переходить ( с одного типа самолёта на другой) ; переносить ( испытания в другое место)autostart fuel sequence switch — дв. выключатель автоматики последовательности подачи топлива при запуске
cabin differential pressure selector switch — переключатель системы регулирования избыточного давления в кабине
cabin temperature selector switch — переключатель системы регулирования температуры воздуха в кабине
control-stick grip trigger switch — гашетка [боевая кнопка] на рукоятке ручки управления
demolition bomb release selector switch — селекторный переключатель ручного или автоматического сбрасывания фугасных авиационных бомб
engine fire detector system test switch — переключатель для проверки термоизвещателей в отсеках двигателей
flight control system radio input switch — тумблер подключения радиосредств к системе управления (самолётом)
hit the start switch — разг. включать тумблер запуска (двигателя)
pitch mechanical advantage switch — тумблер включения механизма изменения передаточного отношения в канале продольного управления
push-to-make, push-to-brake switch — нажимной переключатель на два фиксированных положения
stick grip override switch — тумблер управления триммерами независимо от переключения на ручке управления
switch A/B ignition switch — переключатель зажигания форсажной камеры
— G switch -
31 dual
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32 Hamilton, Harold Lee (Hal)
[br]b. 14 June 1890 Little Shasta, California, USAd. 3 May 1969 California, USA[br]American pioneer of diesel rail traction.[br]Orphaned as a child, Hamilton went to work for Southern Pacific Railroad in his teens, and then worked for several other companies. In his spare time he learned mathematics and physics from a retired professor. In 1911 he joined the White Motor Company, makers of road motor vehicles in Denver, Colorado, where he had gone to recuperate from malaria. He remained there until 1922, apart from an eighteenth-month break for war service.Upon his return from war service, Hamilton found White selling petrol-engined railbuses with mechanical transmission, based on road vehicles, to railways. He noted that they were not robust enough and that the success of petrol railcars with electric transmission, built by General Electric since 1906, was limited as they were complex to drive and maintain. In 1922 Hamilton formed, and became President of, the Electro- Motive Engineering Corporation (later Electro-Motive Corporation) to design and produce petrol-electric rail cars. Needing an engine larger than those used in road vehicles, yet lighter and faster than marine engines, he approached the Win ton Engine Company to develop a suitable engine; in addition, General Electric provided electric transmission with a simplified control system. Using these components, Hamilton arranged for his petrol-electric railcars to be built by the St Louis Car Company, with the first being completed in 1924. It was the beginning of a highly successful series. Fuel costs were lower than for steam trains and initial costs were kept down by using standardized vehicles instead of designing for individual railways. Maintenance costs were minimized because Electro-Motive kept stocks of spare parts and supplied replacement units when necessary. As more powerful, 800 hp (600 kW) railcars were produced, railways tended to use them to haul trailer vehicles, although that practice reduced the fuel saving. By the end of the decade Electro-Motive needed engines more powerful still and therefore had to use cheap fuel. Diesel engines of the period, such as those that Winton had made for some years, were too heavy in relation to their power, and too slow and sluggish for rail use. Their fuel-injection system was erratic and insufficiently robust and Hamilton concluded that a separate injector was needed for each cylinder.In 1930 Electro-Motive Corporation and Winton were acquired by General Motors in pursuance of their aim to develop a diesel engine suitable for rail traction, with the use of unit fuel injectors; Hamilton retained his position as President. At this time, industrial depression had combined with road and air competition to undermine railway-passenger business, and Ralph Budd, President of the Chicago, Burlington \& Quincy Railroad, thought that traffic could be recovered by way of high-speed, luxury motor trains; hence the Pioneer Zephyr was built for the Burlington. This comprised a 600 hp (450 kW), lightweight, two-stroke, diesel engine developed by General Motors (model 201 A), with electric transmission, that powered a streamlined train of three articulated coaches. This train demonstrated its powers on 26 May 1934 by running non-stop from Denver to Chicago, a distance of 1,015 miles (1,635 km), in 13 hours and 6 minutes, when the fastest steam schedule was 26 hours. Hamilton and Budd were among those on board the train, and it ushered in an era of high-speed diesel trains in the USA. By then Hamilton, with General Motors backing, was planning to use the lightweight engine to power diesel-electric locomotives. Their layout was derived not from steam locomotives, but from the standard American boxcar. The power plant was mounted within the body and powered the bogies, and driver's cabs were at each end. Two 900 hp (670 kW) engines were mounted in a single car to become an 1,800 hp (l,340 kW) locomotive, which could be operated in multiple by a single driver to form a 3,600 hp (2,680 kW) locomotive. To keep costs down, standard locomotives could be mass-produced rather than needing individual designs for each railway, as with steam locomotives. Two units of this type were completed in 1935 and sent on trial throughout much of the USA. They were able to match steam locomotive performance, with considerable economies: fuel costs alone were halved and there was much less wear on the track. In the same year, Electro-Motive began manufacturing diesel-electrie locomotives at La Grange, Illinois, with design modifications: the driver was placed high up above a projecting nose, which improved visibility and provided protection in the event of collision on unguarded level crossings; six-wheeled bogies were introduced, to reduce axle loading and improve stability. The first production passenger locomotives emerged from La Grange in 1937, and by early 1939 seventy units were in service. Meanwhile, improved engines had been developed and were being made at La Grange, and late in 1939 a prototype, four-unit, 5,400 hp (4,000 kW) diesel-electric locomotive for freight trains was produced and sent out on test from coast to coast; production versions appeared late in 1940. After an interval from 1941 to 1943, when Electro-Motive produced diesel engines for military and naval use, locomotive production resumed in quantity in 1944, and within a few years diesel power replaced steam on most railways in the USA.Hal Hamilton remained President of Electro-Motive Corporation until 1942, when it became a division of General Motors, of which he became Vice-President.[br]Further ReadingP.M.Reck, 1948, On Time: The History of the Electro-Motive Division of General Motors Corporation, La Grange, Ill.: General Motors (describes Hamilton's career).PJGRBiographical history of technology > Hamilton, Harold Lee (Hal)
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33 indicator
указатель, индикатор; прибор; стрелка ( прибора) ; ( визуальный) сигнализаторengine fuel flow indicator — расходомер двигателя, указатель расхода топлива двигателем
engine r.p.m. indicator — указатель числа оборотов [тахометр] двигателя
gross, cabin, and target altitude indicator — комбинированный указатель грубо отсчитываемой высоты полёта, «высоты» в кабине и высоты цели
heading-upward plan position indicator — рлк. индикатор кругового обзора, ориентированный по курсу ЛА
instantaneous vertical speed indicator — безынерционный вариометр, указатель мгновенной вертикальной скорости
intake spike position indicator — указатель положения иглы [конуса] воздухозаборника
leading-edge flaps position indicator — указатель положения носовых щитков [отклоняемых носков крыла]
north-stabilized plan position indicator — рлк. индикатор кругового обзора, ориентированный на север
north-upward plan position indicator — рлк. индикатор кругового обзора, ориентированный на север
off-center plan position indicator — рлк. индикатор кругового обзора со смещённым центром
offset plan position indicator — рлк. индикатор кругового обзора со смещённым центром
phase advance airspeed indicator — указатель воздушной скорости, измеряемой с опережением
r.p.m. indicator — указатель числа оборотов, тахометр
swivel boom airspeed indicator — указатель воздушной скорости, работающий от датчика давлений на поворотной выносной штанге
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34 Priestman, William Dent
SUBJECT AREA: Steam and internal combustion engines[br]b. 23 August 1847 Sutton, Hull, Englandd. 7 September 1936 Hull, England[br]English oil engine pioneer.[br]William was the second son and one of eleven children of Samuel Priestman, who had moved to Hull after retiring as a corn miller in Kirkstall, Leeds, and who in retirement had become a director of the North Eastern Railway Company. The family were strict Quakers, so William was sent to the Quaker School in Bootham, York. He left school at the age of 17 to start an engineering apprenticeship at the Humber Iron Works, but this company failed so the apprenticeship was continued with the North Eastern Railway, Gateshead. In 1869 he joined the hydraulics department of Sir William Armstrong \& Company, Newcastle upon Tyne, but after a year there his father financed him in business at a small, run down works, the Holderness Foundry, Hull. He was soon joined by his brother, Samuel, their main business being the manufacture of dredging equipment (grabs), cranes and winches. In the late 1870s William became interested in internal combustion engines. He took a sublicence to manufacture petrol engines to the patents of Eugène Etève of Paris from the British licensees, Moll and Dando. These engines operated in a similar manner to the non-compression gas engines of Lenoir. Failure to make the two-stroke version of this engine work satisfactorily forced him to pay royalties to Crossley Bros, the British licensees of the Otto four-stroke patents.Fear of the dangers of petrol as a fuel, reflected by the associated very high insurance premiums, led William to experiment with the use of lamp oil as an engine fuel. His first of many patents was for a vaporizer. This was in 1885, well before Ackroyd Stuart. What distinguished the Priestman engine was the provision of an air pump which pressurized the fuel tank, outlets at the top and bottom of which led to a fuel atomizer injecting continuously into a vaporizing chamber heated by the exhaust gases. A spring-loaded inlet valve connected the chamber to the atmosphere, with the inlet valve proper between the chamber and the working cylinder being camoperated. A plug valve in the fuel line and a butterfly valve at the inlet to the chamber were operated, via a linkage, by the speed governor; this is believed to be the first use of this method of control. It was found that vaporization was only partly achieved, the higher fractions of the fuel condensing on the cylinder walls. A virtue was made of this as it provided vital lubrication. A starting system had to be provided, this comprising a lamp for preheating the vaporizing chamber and a hand pump for pressurizing the fuel tank.Engines of 2–10 hp (1.5–7.5 kW) were exhibited to the press in 1886; of these, a vertical engine was installed in a tram car and one of the horizontals in a motor dray. In 1888, engines were shown publicly at the Royal Agricultural Show, while in 1890 two-cylinder vertical marine engines were introduced in sizes from 2 to 10 hp (1.5–7.5 kW), and later double-acting ones up to some 60 hp (45 kW). First, clutch and gearbox reversing was used, but reversing propellers were fitted later (Priestman patent of 1892). In the same year a factory was established in Philadelphia, USA, where engines in the range 5–20 hp (3.7–15 kW) were made. Construction was radically different from that of the previous ones, the bosses of the twin flywheels acting as crank discs with the main bearings on the outside.On independent test in 1892, a Priestman engine achieved a full-load brake thermal efficiency of some 14 per cent, a very creditable figure for a compression ratio limited to under 3:1 by detonation problems. However, efficiency at low loads fell off seriously owing to the throttle governing, and the engines were heavy, complex and expensive compared with the competition.Decline in sales of dredging equipment and bad debts forced the firm into insolvency in 1895 and receivers took over. A new company was formed, the brothers being excluded. However, they were able to attend board meetings, but to exert no influence. Engine activities ceased in about 1904 after over 1,000 engines had been made. It is probable that the Quaker ethics of the brothers were out of place in a business that was becoming increasingly cut-throat. William spent the rest of his long life serving others.[br]Further ReadingC.Lyle Cummins, 1976, Internal Fire, Carnot Press.C.Lyle Cummins and J.D.Priestman, 1985, "William Dent Priestman, oil engine pioneer and inventor: his engine patents 1885–1901", Proceedings of the Institution ofMechanical Engineers 199:133.Anthony Harcombe, 1977, "Priestman's oil engine", Stationary Engine Magazine 42 (August).JBBiographical history of technology > Priestman, William Dent
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35 jet
1) безнасадочный
2) бить струя
3) водомет
4) водометный
5) воздушно-реактивный
6) гагатовый
7) жиклер
8) <astr.> джет
9) реактивный двигатель
10) сопловой
11) форсунка
12) струйный
13) распыление
14) инжектор
15) пароструйный
16) насадка
17) патрубок
18) рожок
19) факел
20) сопло
– accelerating jet
– air jet
– air-breathing jet engine
– arc-heating jet engine
– atmospheric jet engine
– auxiliary jet
– blow jet
– cargo jet
– clog jet
– coherent jet
– control jet
– cutting jet
– deflect jet
– disturb jet
– fuel jet
– full-power jet
– gas turbine jet engine
– hydraulic jet
– idling jet
– ink jet printing
– ion rocket jet engine
– jet action
– jet airplane
– jet analysis
– jet blower
– jet burner
– jet casing cutter
– jet compressor
– jet control
– jet converges
– jet device
– jet diameter
– jet disintegrates
– jet diverges
– jet dredge
– jet engine
– jet engine fuel
– jet etching
– jet flap
– jet flow
– jet formation
– jet fuel
– jet loom
– jet machine
– jet mill
– jet mixer
– jet nozzle
– jet orifice
– jet propeller
– jet propulsion
– jet pump
– jet regulation
– jet sheet
– jet test
– jet thrust
– jet vacuum pump
– jet vane
– jet wash
– liquid-propellant jet engine
– plasma jet
– reaction jet
– starting jet
– steam jet booster
– steam jet injector
– swirl jet
– turbulent jet
– water jet
jet engine starter system — <engin.> турбостартер
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36 unit
2. установка; агрегат; устройство3. сборочная единица; узел; блок; модуль4. подразделение, (войсковая) частьactuator drive unitaerodynamic unit of timeair-cycle unitauxiliary power unitbomber unitcockpit interface unitcontrol display unitcrash-survivable memory unitdiagnostic unitdisplay unitdynamic unit of timeejector release unitencoding unitengine control unitengine cycle monitor unitenvironmental unitenvironmental control unitfault display unitfeel unitfighter unitfuel control unitfuel quantity unithose-drogue unitinterference blanker unitline replaceable unitmeasuring unitmixer uniton-system replaceable unitpipe pivoting unitpivoting unitpressurisation control unitshop replaceable unitsix-component measuring unitsteering control unitTCAS unitunderwing balancer unitvapor cycle unit -
37 electronic
1 adjELEC, ELECTRON electrónico2 -
38 jet
jet nреактивное воздушное судноacoustically lined jet pipeакустически облицованная реактивная трубаasymmetric jet nozzleасимметричное соплоatomizing jetраспылительaxisymmetric jet nozzleосесимметричное реактивное соплоbearing oil jet ringфорсуночное кольцо смазки опорыblowaway jetструйная защитаblowaway jet systemсистема гашения завихренияchocked jetзадросселированная реактивная струяcombined jet nozzleкомбинированное реактивное соплоcommercial jetкоммерческое реактивное воздушное судноconstant-geometry jet nozzleнерегулируемое реактивное соплоcore jet reversalреверс основной тягиejector jet nozzleэжекторное реактивное соплоexhaust jetвыходящая струяexhaust jet nozzleреактивный насадокfan jet reverserмеханизм реверса воздушного потока вентилятораfire extinguishing jetпротивопожарная форсункаfuel jetтопливный жиклерjet aerodromeаэродром для реактивных воздушных судовjet aircraftреактивное воздушное судноjet deflectorотражатель реактивной струиjet deviation control systemсистема управления отклонением реактивной струиjet engineреактивный двигательjet exhaustреактивное истечениеjet exhaust streamреактивная струя выходящих газовjet flameвыхлопной факелjet flapструйный закрылокjet fuelтопливо для реактивных двигателейjet linerреактивный лайнерjet noiseшум реактивной струиjet noise prediction techniqueметод прогнозирования шума реактивных двигателейjet nozzleреактивное соплоjet pipe temperatureтемпература выходящих газовjet pumpэжекторный насосjet separationразделение реактивной струиjet setреактивный аппаратjet silencerглушитель реактивной струиjet streamреактивный потокjet thrustреактивная тягаjet tip boosterконцевой реактивjet washзавихрение от реактивной струиjumbo jetширокофюзеляжное реактивное воздушное судноlift jet engineподъемный реактивный двигательmultitube jet nozzleмноготрубное реактивное соплоnotched jet nozzleгофрированное реактивное соплоoil jetмасляная форсункаplug jet nozzleреактивное сопло с центральным теломprop jetтурбовинтовое реактивное воздушное судноshaped jet nozzleпрофилированное реактивное соплоskewed jet nozzleсопло с косым срезомvectorable jet nozzleповоротное реактивное соплоwide-bodied jetширокофюзеляжное реактивное воздушное судно -
39 module
4) космонавт. отсек•module of package dimensions — модуль размеров тары-
access module
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albedocollecting solar module
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all-space module
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amorphous silicon power module
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analog divider module
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analog timing module
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antilock module
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applications software module
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applications module
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astronaut free-flying propulsion module
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basic building-block module
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basic module
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bifacial solar module
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biological module
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biomedical module
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buoyancy riser module
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CAE module
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CAM module
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card module
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carriage module
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ceiling module
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cell control module
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close-pack module
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computation module
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concentrating photovoltaic module
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control module
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controller module
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co-orbiting module
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coplanar module
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cordwood module
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core module
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crew module
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definition module
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descent module
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digital module
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docking module
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docking payload module
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dummy module
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EDP module
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electronic module
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engine module
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enlarged module
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final drive exchange module
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finite state-automata module
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flat-plate solar module
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flexible assembly module
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free-flying module
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fuel module
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full interchangeable modules
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functional module
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function module
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gas-compressor module
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habitable module
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hardware interface module
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hardware module
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hardware/software module
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horizontal baseline module
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hybrid module
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hydraulic module
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implementation module
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inference control module
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input/output control module
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instrumentation module
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instrument module
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instrument-assembly module
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instrumentation-propulsion module
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interface module
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irrigation module
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laboratory space module
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landing module
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laterally docked module
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linear module
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living quarter module
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loading module
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load module
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logistics module
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longitudinal docked module
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machining module
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man-tended module
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measurement module
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meteorological module
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microcircuit module
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microminiature module
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motorized pump module
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multistring photovoltaic module
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nuclear-power module
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number assignment module
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object module
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oceanographic module
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OMS module
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orbit transfer vehicle module
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orbital maneuvering system module
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OTV module
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payload module
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pellet module
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personality module
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personal module
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photovoltaic module
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pilot cell module
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plug-in module
-
point-focusing photovoltaic module
-
potted module
-
power module
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power shift transmission module
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prefabricated module
-
pressurized module
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probe module
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process execution module
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programmable module
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propulsion module
-
radially docked module
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RCS module
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reaction control system module
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redocked modules
-
reenterable module
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regulator module
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replaceable module
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replacement modules
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retro propulsion module
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robot grip module
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robot module
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robotic slip module
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scientific equipment module
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scientific research module
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self-contained module
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sensor module
-
service module
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shingle-type photovoltaic module
-
signal processing module
-
single-ended module
-
software module
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solar array module
-
solar battery module
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solar module
-
solar-power module
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source module
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space station module
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stacked module
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standard module
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subordinate module
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tanker module
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terrain monitoring module
-
three-dimensional module
-
transfer module
-
transmit-receive module
-
unmanned module
-
up-and-down module
-
utility module
-
working module -
40 wing
wing nкрылоwinged vс крыльямиair transport wingавиатранспортное подразделениеall-moving wingуправляемое крылоanhedral wingкрыло с отрицательным углом поперечного ВЭarrow-type wingстреловидное крылоaugmentor wingкрыло с управляемой циркуляциейbackswept boundary layer controlled wingкрыло с управляемым пограничным слоемbraced wingрасчаленное крылоcantilever wingсвободнонесущее крылоcenter wingцентропланcenter wing sectionцентроплан крылаclean wingаэродинамическое чистое крылоcontinuous wing beamнеразрезной лонжерон крылаcrescent wingсерповидное крылоdelta wingтреугольное крылоdesign wing areaрасчетная площадь крылаdetach the wingотстыковывать крылоdihedral wingкрыло с положительным углом поперечного ВЭelliptical wingэллиптическое крылоfixed wingнеподвижное крылоflow about wingобтекание крылаfolding wingскладывающееся крылоfolding wing aircraftвоздушное судно со складывающимся крыломforward-swept wingкрыло обратной стреловидностиfront wing sparпередний лонжерон крылаgross wing areaплощадь крыла, включая подфюзеляжную частьgull wingкрыло типа чайкаhigh-lift devices wingкрыло с механизацией для обеспечения большей подъемной силыhigh-lift wing devicesвысокоэффективная механизация крылаhigh wingвысокорасположенное крылоinfinite-span wingкрыло бесконечного размахаinner wingцентропланinverted-gull wingкрыло типа обратная чайкаlift wingнесущая расчалкаlow aspect wingкрыло малого удлиненияlower wingнижнее крылоlow wingнизкорасположенное крылоmiddle wing barсредний фланговый горизонтmid wingсреднерасположенное крылоmonospar wingоднолонжеронное крылоmovable wingкрыло изменяемой крылоouter wingотъемная часть крылаover the wingнад крыломpipeline to wing slatтрубопровод подвода воздуха к предкрылкуpivoting wingповоротное крылоrear wing sparзадний лонжерон крылаrectangular wingпрямоугольное крылоrigid wingжесткое крылоrocking wingsпокачивание крыльямиrotary wingнесущий винтshoulder wingвысокорасположенное крылоsingle-bay wingодностоечное крылоsingle-spar wingоднолонжеронное крылоslotted wingщелевое крылоsteady airflow about the wingустановившееся обтекание крыла воздушным потокомstressed-skin wingкрыло с работающей обшивкойsweptback wingкрыло прямой стреловидностиsweptforward wingкрыло обратной стреловидностиswept wingстреловидное крылоtapered wingтрапециевидное крылоtorsion box wingкрыло кессонной конструкцииtwo-spar wingдвухлонжеронное крылоupper wingверхнее крылоupwind wing barдальний фланговый горизонтvariable-area wingкрыло с изменяемой площадьюvariable-geometry wingкрыло изменяемой геометрииvariable-incidence wingкрыло с изменяемым углом установкиvariable-sweep wingкрыло переменной стреловидностиvariable-swept wingкрыло изменяемой стреловидностиwing aeroelasticityаэроупругость крылаwing anti-icing systemпротивообледенительная система крылаwing areaплощадь крылаwing aspect ratioотносительное удлинение крылаwing attachment fittingузел крепления крылаwing barфланговый горизонтwing bar lightsогни световых горизонтовwing base lineбазовая линия крылаwing bearing capacityнесущая способность крылаwing bending momentизгибающий момент крылаwing bending reliefразгрузка крылаwing boxотсек кессона крылаwing box panelпанель кессона крылаwing bucklingпродольный изгиб крылаwing buttingстыковка крылаwing butting wrenchключ для стыковки крылаwing chordхорда крылаwing chord lineлиния хорды крылаwing clearance lightгабаритный огонь крылаwing coveringобшивка крылаwing cradleложемент под крылоwing curvatureкривизна крылаwing devicesмеханизация крылаwing divergenceдивергенция крылаwing dogtooth extensionнаплыв крылаwing dragлобовое сопротивление крылаwing dropзавал на крылоwing droppingзавал на крылоwing engineкрыльевой двигательwing extendable devicesвыдвижная механизация крылаwing fenceаэродинамический гребень на крылеwing filletзализ крылаwing flapзакрылокwing flap control systemсистема управления закрылкамиwing flaps error transmitterдатчик рассогласования закрылковwing fuel tankтопливный крыльевой бакwing geometric twistгеометрическая крутка крылаwing heavinessтенденция сваливания на крылоwing horseкрыльевой ложементwing icing conditionsусловия обледенения крылаwing integral fuel tankтопливный отсек крылаwing jackподъемник крылаwing jacking pointгнездо под крыльевой подъемникwing jointразъем крылаwing leading edgeносок крылаwing liftподъемная сила крылаwing loadнагрузка на крылоwing longitudinal oscillationпродольное колебание крылаwing lower surfaceнижняя поверхность крылаwing manholeлюк в крылеwing outer panels jointстык консолей крылаwing planformформа крыла в планеwing polarполяра крылаwing pressure plottingраспределение давления по крылуwing ribкрыльевая нервюраwing rootкорневая часть крылаwing screw jackвинтовой подъемник крылаwing sectionпрофиль крылаwing settingустановка угла положения крылаwing setting angleугол заклинения крылаwing shapeпрофиль крылаwing skeletonостов крылаwing slideскольжение на крылоwing slotщель крыла(для обдува) wing slot doorстворка щели крылаwing spanразмах крылаwing sparлонжерон крылаwing spar capпояс лонжерона крылаwing split lineлиния разъема крылаwing spoiler systemсистема крыльевых интерцепторwing stall sensorдатчик критических углов атаки крылаwing static dischargerстатический разрядник крылаwing sweep angleугол стреловидности крылаwing tail filletхвостовой зализ крылаwing taperсужение крылаwing taper ratioотносительное сужение крылаwing tipзаконцовка крылаwing tip clearanceзапас высоты законцовки крылаwing tip clearance lineлиния ограничения безопасного расстояния до конца крылаwing torsional momentкрутящий момент крылаwing torsional stiffnessжесткость крыла на кручениеwing torsion stiffnessжесткость крыла на кручениеwing trestleподкрыльевой козелокwing trim stripбалансировочный нож на задней кромке крылаwing twistкрутка крылаwing upper surfaceверхняя поверхность крылаwing variable sweepизменяемая стреловидность крылаwing walkerсопровождающий у конца крылаwing walk matмат на крылоwing walkwayкрыльевой мат
См. также в других словарях:
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