-
1 Rankine engine
Большой англо-русский и русско-английский словарь > Rankine engine
-
2 Rankine engine
-
3 Rankine engine
Техника: двигатель Ренкина -
4 engine
1) двигатель, мотор2) ж.-д. локомотив3) машина4) процессор•to run up the engine — опробовать двигатель ( на режимах работы);to unreverse the engine — выводить двигатель из режима реверса-
light bulb engine
-
accelerating engine
-
adiabatic engine
-
air breathing engine
-
air engine
-
air-cell engine
-
air-chamber engine
-
air-cooled engine
-
aircraft engine
-
air-feed jet engine
-
air-injection engine
-
airless-injection engine
-
alcohol engine
-
analytical engine
-
anchor engine
-
apogee engine
-
approach-correcting engine
-
arc jet engine
-
arrow engine
-
ascent engine
-
assisted takeoff engine
-
AV-1 engine
-
aviation engine
-
axial-flow gas turbine engine
-
bare engine
-
baseline engine
-
basic engine
-
beating engine
-
bipropellant engine
-
bismuth ion engine
-
bleaching engine
-
blowing engine
-
blown engine
-
booster engine
-
boxer engine
-
brake engine
-
Brayton engine
-
breaker engine
-
bypass engine
-
catalytic engine
-
centrifugal expansion engine
-
ceramic engine
-
coaxial MPD engine
-
cogging engine
-
cold-reaction engine
-
commercial engine
-
compression ignition engine
-
computing engine
-
constant 1 engine
-
conventional engine
-
crankcase compression engine
-
crest engine
-
cross-compound blowing engine
-
cross-mounted engine
-
cryogenic expansion engine
-
cryogenic rocket engine
-
dead engine
-
derated engine
-
descent engine
-
diesel engine
-
diesel-electric engine
-
difference engine
-
digital engine
-
direct-injection engine
-
displacement engine
-
docking engine
-
donkey engine
-
double-row engine
-
double-row radial engine
-
down-rated engine
-
drilling engine
-
dual-flow turbojet engine
-
dual-mode engine
-
duct-burning bypass engine
-
ducted-fan engine
-
electric arcjet engine
-
electron-bombardment engine
-
emergency propulsion engine
-
energy-cell diesel engine
-
erosion engine
-
expansion engine
-
external combustion engine
-
F-head engine
-
fire engine with extension ladder
-
fire engine
-
fixed head engine
-
flat engine
-
flat-head engine
-
fluorine-hydrogen engine
-
four-barrel engine
-
four-cycle engine
-
Gardner engine
-
gas discharge ionizator electrostatic engine
-
gas engine
-
gas turbine engine
-
gas-driven blowing engine
-
gas blowing engine
-
gasoline engine
-
graphics engine
-
heat engine
-
heavy equipment diesel engine
-
heavy-duty engine
-
high bypass ratio engine
-
high-compression engine
-
high-efficiency engine
-
high-I engine
-
horizontal engine
-
horizontally opposed engine
-
Horning engine
-
hump engine
-
hybrid air-breathing engine
-
hybrid-propellant engine
-
hydrogen-fueled engine
-
I-head engine
-
impact volume ionization ion engine
-
inboard engine
-
indirect-injection engine
-
individual cylinder head engine
-
industrial application engine
-
inference engine
-
inlet over exhaust engine
-
in-line engine
-
ionic engine
-
ion engine
-
jet engine
-
ladle-car engine
-
laser air-jet engine
-
laser-driven rocket engine
-
laser-heated rocket engine
-
laser-propulsion rocket engine
-
Lauson engine
-
L-head engine
-
lift engine
-
lift jet engine
-
light duty diesel engine
-
linear MPD engine
-
liquid air cycle engine
-
liquid petroleum gases engine
-
liquid-propellant engine
-
long-stroke engine
-
low bypass ratio engine
-
low-I engine
-
LOX/HC engine
-
LOX/LH engine
-
magnetogasdynamic engine
-
maneuvering engine
-
marine application engine
-
marine engine
-
mercury ion engine
-
mid-flight engine
-
model diesel engine
-
monkey engine
-
motored engine
-
multifuel engine
-
nacelle-mounted engine
-
naturally aspirated engine
-
nonturbo engine
-
oil engine
-
oil-electric engine
-
OMS engine
-
one-shaft engine
-
open-cylinder engine
-
opposed-piston engine
-
Otto engine
-
outboard engine
-
overhead valve engine
-
oversquare engine
-
pancake engine
-
petrol engine
-
Petter AV-I Diesel engine
-
Petter W-1 engine
-
photon engine
-
piston ported engine
-
plasmajet rocket engine
-
plasma rocket engine
-
podded engine
-
pollution-free engine
-
potassium ion engine
-
prechamber engine
-
propulsion engine
-
pulping engine
-
pulsejet engine
-
pusher engine
-
quench-car engine
-
racing engine
-
radial engine
-
radiation-heated rocket engine
-
radio-frequency ion engine
-
ram engine
-
ramjet engine
-
Rankine engine
-
RCS engine
-
reciprocating solar engine
-
rectenna-powered ion engine
-
remanufactured engine
-
restartable engine
-
rotary engine
-
rubidium ion engine
-
separation engine
-
shaft-turbine engine
-
shunting engine
-
single-shaft gas turbine engine
-
six-cylinder in-line engine
-
solar Brayton engine
-
solar engine
-
solar photon rocket engine
-
solar-heated gas engine
-
solar gas engine
-
solar-powered engine
-
spacer plate engine
-
special arrangement engine
-
square engine
-
starting engine
-
steam-driven blowing engine
-
steam blowing engine
-
steering engine
-
Stirling engine
-
stock engine
-
subsonic engine
-
supercharged engine
-
surface ionization engine
-
swirl-chamber diesel engine
-
switch engine
-
take-home engine
-
tee engine
-
test bed engine
-
T-head engine
-
thermal arc engine
-
thermoelectronic engine
-
three-flow turbojet engine
-
towing engine
-
trans-rear engine
-
transverse engine
-
traveling wave plasma engine
-
trimmer engine
-
tripropellant engine
-
truck engine
-
turbine engine
-
turbine expansion engine
-
turbocharged engine
-
turbo engine
-
turbofan engine
-
turbojet engine
-
turboprop engine
-
turboshaft engine
-
turbulence-chamber engine
-
twin rotor engine
-
two-rotor engine
-
two-shaft gas turbine engine
-
two-spool engine
-
unblown engine
-
undersquare engine
-
variable compression engine
-
variable cycle engine
-
variable cylinder engine
-
vehicular engine
-
V-engine
-
volume collision ionization engine
-
Wankel engine
-
warmed-up engine
-
washing engine
-
waste-heat recovery Stirling engine
-
water-cooled engine
-
windmilling engine
-
wing engine
-
W-type engine
-
yard engine -
5 Rankine
-
6 Rankine, William John Macquorn
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering[br]b. 5 July 1820 Edinburgh, Scotlandd. 1872[br][br]Rankine was educated at Ayr Academy and Glasgow High School, although he appears to have learned much of his basic mathematics and physics through private study. He attended Edinburgh University and then assisted his father, who was acting as Superintendent of the Edinburgh and Dalkeith Railway. This introduction to engineering practice was followed in 1838 by his appointment as a pupil to Sir John MacNeill, and for the next four years he served under MacNeill on his Irish railway projects. While still in his early twenties, Rankine presented pioneering papers on metal fatigue and other subjects to the Institution of Civil Engineers, for which he won a prize, but he appears to have resigned from the Civils in 1857 after an argument because the Institution would not transfer his Associate Membership into full Membership. From 1844 to 1848 Rankine worked on various projects for the Caledonian Railway Company, but his interests were becoming increasingly theoretical and a series of distinguished papers for learned societies established his reputation as a leading scholar in the new science of thermodynamics. He was elected Fellow of the Royal Society in 1853. At the same time, he remained intimately involved with practical questions of applied science, in shipbuilding, marine engineering and electric telegraphy, becoming associated with the influential coterie of fellow Scots such as the Thomson brothers, Napier, Elder, and Lewis Gordon. Gordon was then the head of a large and successful engineering practice, but he was also Regius Professor of Engineering at the University of Glasgow, and when he retired from the Chair to pursue his business interests, Rankine, who had become his Assistant, was appointed in his place.From 1855 until his premature death in 1872, Rankine built up an impressive engineering department, providing a firm theoretical basis with a series of text books that he wrote himself and most of which remained in print for many decades. Despite his quarrel with the Institution of Civil Engineers, Rankine took a keen interest in the institutional development of the engineering profession, becoming the first President of the Institution of Engineers and Shipbuilders in Scotland, which he helped to establish in 1857. Rankine campaigned vigorously for the recognition of engineering studies as a full university degree at Glasgow, and he achieved this in 1872, the year of his death. Rankine was one of the handful of mid-nineteenth century engineers who virtually created engineering as an academic discipline.[br]Principal Honours and DistinctionsFRS 1853. First President, Institution of Engineers and Shipbuilders in Scotland, 1857.Bibliography1858, Manual of Applied Mechanics.1859, Manual of the Steam Engine and Other Prime Movers.1862, Manual of Civil Engineering.1869, Manual of Machinery and Millwork.Further ReadingJ.Small, 1957, "The institution's first president", Proceedings of the Institution of Engineers and Shipbuilders in Scotland: 687–97.H.B.Sutherland, 1972, Rankine. His Life and Times.ABBiographical history of technology > Rankine, William John Macquorn
-
7 Rankine-cycle engine
nHEAT, THERMO, TRANSP motor de ciclo Rankine m -
8 двигатель Ренкина
Большой англо-русский и русско-английский словарь > двигатель Ренкина
-
9 двигатель Ренкина
Англо-русский словарь технических терминов > двигатель Ренкина
-
10 двигатель Ренкина
Русско-английский политехнический словарь > двигатель Ренкина
-
11 двигатель Ренкина
Engineering: Rankine engine -
12 Elder, John
[br]b. 9 March 1824 Glasgow, Scotlandd. 17 September 1869 London, England[br]Scottish engineer who introduced the compound steam engine to ships and established an important shipbuilding company in Glasgow.[br]John was the third son of David Elder. The father came from a family of millwrights and moved to Glasgow where he worked for the well-known shipbuilding firm of Napier's and was involved with improving marine engines. John was educated at Glasgow High School and then for a while at the Department of Civil Engineering at Glasgow University, where he showed great aptitude for mathematics and drawing. He spent five years as an apprentice under Robert Napier followed by two short periods of activity as a pattern-maker first and then a draughtsman in England. He returned to Scotland in 1849 to become Chief Draughtsman to Napier, but in 1852 he left to become a partner with the Glasgow general engineering company of Randolph Elliott \& Co. Shortly after his induction (at the age of 28), the engineering firm was renamed Randolph Elder \& Co.; in 1868, when the partnership expired, it became known as John Elder \& Co. From the outset Elder, with his partner, Charles Randolph, approached mechanical (especially heat) engineering in a rigorous manner. Their knowledge and understanding of entropy ensured that engine design was not a hit-and-miss affair, but one governed by recognition of the importance of the new kinetic theory of heat and with it a proper understanding of thermodynamic principles, and by systematic development. In this Elder was joined by W.J.M. Rankine, Professor of Civil Engineering and Mechanics at Glasgow University, who helped him develop the compound marine engine. Elder and Randolph built up a series of patents, which guaranteed their company's commercial success and enabled them for a while to be the sole suppliers of compound steam reciprocating machinery. Their first such engine at sea was fitted in 1854 on the SS Brandon for the Limerick Steamship Company; the ship showed an improved performance by using a third less coal, which he was able to reduce still further on later designs.Elder developed steam jacketing and recognized that, with higher pressures, triple-expansion types would be even more economical. In 1862 he patented a design of quadruple-expansion engine with reheat between cylinders and advocated the importance of balancing reciprocating parts. The effect of his improvements was to greatly reduce fuel consumption so that long sea voyages became an economic reality.His yard soon reached dimensions then unequalled on the Clyde where he employed over 4,000 workers; Elder also was always interested in the social welfare of his labour force. In 1860 the engine shops were moved to the Govan Old Shipyard, and again in 1864 to the Fairfield Shipyard, about 1 mile (1.6 km) west on the south bank of the Clyde. At Fairfield, shipbuilding was commenced, and with the patents for compounding secure, much business was placed for many years by shipowners serving long-distance trades such as South America; the Pacific Steam Navigation Company took up his ideas for their ships. In later years the yard became known as the Fairfield Shipbuilding and Engineering Company Ltd, but it remains today as one of Britain's most efficient shipyards and is known now as Kvaerner Govan Ltd.In 1869, at the age of only 45, John Elder was unanimously elected President of the Institution of Engineers and Shipbuilders in Scotland; however, before taking office and giving his eagerly awaited presidential address, he died in London from liver disease. A large multitude attended his funeral and all the engineering shops were silent as his body, which had been brought back from London to Glasgow, was carried to its resting place. In 1857 Elder had married Isabella Ure, and on his death he left her a considerable fortune, which she used generously for Govan, for Glasgow and especially the University. In 1883 she endowed the world's first Chair of Naval Architecture at the University of Glasgow, an act which was reciprocated in 1901 when the University awarded her an LLD on the occasion of its 450th anniversary.[br]Principal Honours and DistinctionsPresident, Institution of Engineers and Shipbuilders in Scotland 1869.Further ReadingObituary, 1869, Engineer 28.1889, The Dictionary of National Biography, London: Smith Elder \& Co. W.J.Macquorn Rankine, 1871, "Sketch of the life of John Elder" Transactions of theInstitution of Engineers and Shipbuilders in Scotland.Maclehose, 1886, Memoirs and Portraits of a Hundred Glasgow Men.The Fairfield Shipbuilding and Engineering Works, 1909, London: Offices of Engineering.P.M.Walker, 1984, Song of the Clyde, A History of Clyde Shipbuilding, Cambridge: PSL.R.L.Hills, 1989, Power from Steam. A History of the Stationary Steam Engine, Cambridge: Cambridge University Press (covers Elder's contribution to the development of steam engines).RLH / FMW -
13 system
система; установка; устройство; ркт. комплекс"see to land" system — система посадки с визуальным приземлением
A.S.I. system — система указателя воздушной скорости
ablating heat-protection system — аблирующая [абляционная] система тепловой защиты
ablating heat-shield system — аблирующая [абляционная] система тепловой защиты
active attitude control system — ксм. активная система ориентации
aft-end rocket ignition system — система воспламенения заряда с задней части РДТТ [со стороны сопла]
aircraft response sensing system — система измерений параметров, характеризующих поведение ЛА
air-inlet bypass door system — дв. система перепуска воздуха на входе
antiaircraft guided missile system — ракетная система ПВО; зенитный ракетный комплекс
antiaircraft guided weapons system — ракетная система ПВО; зенитный ракетный комплекс
attenuated intercept satellite rendez-vous system — система безударного соединения спутников на орбите
attitude and azimuth reference system — система измерения или индикации углов тангажа, крена и азимута
automatic departure prevention system — система автоматического предотвращения сваливания или вращения после сваливания
automatic drift kick-off system — система автоматического устранения угла упреждения сноса (перед приземлением)
automatic hovering control system — верт. система автостабилизации на висении
automatic indicating feathering system — автоматическая система флюгирования с индикацией отказа (двигателя)
automatic mixture-ratio control system — система автоматического регулирования состава (топливной) смеси
automatic pitch control system — автомат тангажа; автоматическая система продольного управления [управления по каналу тангажа]
B.L.C. high-lift system — система управления пограничным слоем для повышения подъёмной силы (крыла)
backpack life support system — ксм. ранцевая система жизнеобеспечения
beam-rider (control, guidance) system — ркт. система наведения по лучу
biowaste electric propulsion system — электрический двигатель, работающий на биологических отходах
buddy (refueling, tank) system — (подвесная) автономная система дозаправки топливом в полете
closed(-circuit, -cycle) system — замкнутая система, система с замкнутым контуром или циклом; система с обратной связью
Cooper-Harper pilot rating system — система баллов оценки ЛА лётчиком по Куперу — Харперу
deployable aerodynamic deceleration system — развёртываемая (в атмосфере) аэродинамическая тормозная система
depressurize the fuel system — стравливать избыточное давление (воздуха, газа) в топливной системе
driver gas heating system — аэрд. система подогрева толкающего газа
dry sump (lubrication) system — дв. система смазки с сухим картером [отстойником]
electrically powered hydraulic system — электронасосная гидросистема (в отличие от гидросистемы с насосами, приводимыми от двигателя)
exponential control flare system — система выравнивания с экспоненциальным управлением (перед приземлением)
flywheel attitude control system — ксм. инерционная система ориентации
gas-ejection attitude control system — ксм. газоструйная система ориентация
gas-jet attitude control system — ксм. газоструйная система ориентация
ground proximity extraction system — система извлечения грузов из самолёта, пролетающего на уровне земли
hot-air balloon water recovery system — система спасения путем посадки на воду с помощью баллонов, наполняемых горячими газами
hypersonic air data entry system — система для оценки аэродинамики тела, входящего в атмосферу планеты с гиперзвуковой скоростью
igh-temperature fatigue test system — установка для испытаний на выносливость при высоких температурах
interceptor (directing, vectoring) system — система наведения перехватчиков
ion electrical propulsion system — ксм. ионная двигательная установка
isotope-heated catalytic oxidizer system — система каталитического окислителя с нагревом от изотопного источника
jet vane actuation system — ркт. система привода газового руля
laminar flow pumping system — система насосов [компрессоров] для ламинаризации обтекания
launching range safety system — система безопасности ракетного полигона; система обеспечения безопасности космодрома
leading edge slat system — система выдвижных [отклоняемых] предкрылков
low-altitude parachute extraction system — система беспосадочного десантирования грузов с малых высот с использованием вытяжных парашютов
magnetic attitude control system — ксм. магнитная система ориентации
magnetically slaved compass system — курсовая система с магнитной коррекцией, гироиндукционная курсовая система
mass-expulsion attitude control system — система ориентации за счёт истечения массы (газа, жидкости)
mass-motion attitude control system — ксм. система ориентации за счёт перемещения масс
mass-shifting attitude control system — ксм. система ориентации за счёт перемещения масс
monopropellant rocket propulsion system — двигательная установка с ЖРД на унитарном [однокомпонентном] топливе
nucleonic propellant gauging and utilization system — система измерения и регулирования подачи топлива с использованием радиоактивных изотопов
open(-circuit, -cycle) system — открытая [незамкнутая] система, система с незамкнутым контуром или циклом; система без обратной связи
plenum chamber burning system — дв. система сжигания топлива во втором контуре
positioning system for the landing gear — система регулирования высоты шасси (при стоянке самолёта на земле)
radar altimeter low-altitude control system — система управления на малых высотах с использованием радиовысотомера
radar system for unmanned cooperative rendezvous in space — радиолокационная система для обеспечения встречи (на орбите) беспилотных кооперируемых КЛА
range and orbit determination system — система определения дальностей [расстояний] и орбит
real-time telemetry processing system — система обработки радиотелеметрических данных в реальном масштабе времени
recuperative cycle regenerable carbon dioxide removal system — система удаления углекислого газа с регенерацией поглотителя, работающая по рекуперативному циклу
rendezvous beacon and command system — маячно-командная система обеспечения встречи («а орбите)
satellite automatic terminal rendezvous and coupling system — автоматическая система сближения и стыковки спутников на орбите
Schuler tuned inertial navigation system — система инерциальной навигации на принципе маятника Шулера
sodium superoxide carbon dioxide removal system — система удаления углекислого газа с помощью надперекиси натрия
space shuttle separation system — система разделения ступеней челночного воздушно-космического аппарата
stellar-monitored astroinertial navigation guidance system — астроинерциальная система навигации и управления с астрокоррекцией
terminal control landing system — система управления посадкой по траектории, связанной с выбранной точкой приземления
terminal descent control system — ксм. система управления на конечном этапе спуска [снижения]
terminal guidance system for a satellite rendezvous — система управления на конечном участке траектории встречи спутников
test cell flow system — ркт. система питания (двигателя) топливом в огневом боксе
vectored thrust (propulsion) system — силовая установка с подъёмно-маршевым двигателем [двигателями]
water to oxygen system — ксм. система добывания кислорода из воды
wind tunnel data acquisition system — система регистрации (и обработки) данных при испытаниях в аэродинамической трубе
— D system -
14 цикл
( годографа) circuit, cycle, ( обработки) operation, ( временного объединения цифровых сигналов) frame, loop вчт., nucleus, period, run, ring, sequence машиностр.* * *цикл м.1. ( временной или пространственный интервал повторения событий) cycle; ( промежуток времени) periodвосстана́вливать цикл — reset the cycleопи́сывать цикл в прямо́м или обра́тном направле́нии ( в термодинамике) — traverse a cycle in the direct or reverse senseопи́сывать цикл по часово́й стре́лке или про́тив часово́й стре́лки ( в термодинамике) — traverse a cycle clockwise or anticlockwiseрабо́тать ци́клами — to cycleсоверша́ть цикл — to cycle2. вчт. loop; loop of instructionsвыходи́ть из ци́кла — come out of a loopповторя́ть цикл — cycle a loop (of instructions)повторя́ть цикл многокра́тно — cycle round a loop repeatedlyцикл автома́та повто́рного включе́ния эл. — recloser sequenceбина́рный цикл — binary cycleвло́женный цикл — nested loopводоро́дный цикл яд. физ. — hydrogen-helium cycleцикл в ци́кле — loop-within-loopцикл вы́борки кома́нды вчт. — instruction cycleвы́емочный цикл горн. — cycle of goal getting, winning cycleцикл выполне́ния кома́нды вчт. — execution cycleцикл дви́гателя — engine cycleцикл движе́ния — cycle of motionцикл д. в. с. со сгора́нием при постоя́нном давле́нии — Diesel cycleцикл д. в. с. со сгора́нием при постоя́нном объё́ме — Otto cycleдвухта́ктный цикл — two(-stroke) cycleдействи́тельный цикл — actual [real] cycleза́мкнутый цикл1. closed cycleвключа́ть (обору́дование) в за́мкнутый цикл — run (a machine) in closed circuit with (another machine)рабо́тать в за́мкнутом ци́кле с … — be close-circuited with2. closed loopцикл за́писи вчт. — write cycleцикл за́пуска д. в. с. — cranking cycleидеа́льный цикл ( в термодинамике) — ideal cycleитерацио́нный цикл — iteration loopвыполня́ть итерацио́нный цикл — traverse an iteration loopцикл Карно́ ( в термодинамике) — Carnot cycleцикл Карно́, обра́тный ( в термодинамике) — reverse Carnot cycleцикл Карно́, прямо́й ( в термодинамике) — Carnot cycleкинемати́ческий цикл — kinematic cycleкома́ндный цикл вчт. — instruction cycleкриоге́нный цикл ( в термодинамике) — cryogenic cycleцикл ла́вы — wall cycleмагни́тный цикл — magnetic cycleмагнитогидродинами́ческий цикл ( в газодинамике) — magnetohydrodynamic [MHD] cycleмаши́нный цикл вчт. — machine cycleмаши́нный, основно́й цикл вчт. — basic machine cycleцикл нагре́ва ( в термодинамике) — heating cycleцикл намагни́чивания — cycle of magnetizationцикл намагни́чивания, преде́льный эл. — major cyclic hysteresis loopцикл напряже́ний мех. — stress cycleнеза́мкнутый цикл — open cycleнейтро́нный цикл яд. физ. — neutron cycleнеобрати́мый цикл ( в термодинамике) — irreversible cycleнепреры́вный цикл ( в термодинамике) — uninterrupted cycleобрати́мый цикл ( в термодинамике) — reversible cycleцикл обраще́ния к па́мяти вчт. — memory [storage] cycleокисли́тельно-восстанови́тельный цикл — oxidation-reduction cycleосновно́й цикл ( в термодинамике) — basic cycleохва́тывающий цикл — outer loonцикл охлажде́ния — cooling cycleпароводяно́й цикл — water-flow cycle; water-steam circuitпарово́й цикл — vapour cycleпарога́зовый цикл — supercharged boiler [exhaust-fired-boiler] cycleпаросилово́й цикл — steam power cycleпаротурби́нный цикл — steam turbine cycleцикл перемагни́чивания — cycle of magnetizationцикл пла́вки от вы́пуска до вы́пуска — tap-to-tap cycleповто́рный цикл — recycleцикл по́иска вчт. — search cycleпоса́дочный цикл горн. — cycle of caving, caving cycleпреде́льный цикл эл. — limit cycleцикл програ́ммы вчт. — loop of instructionsцикл програ́ммы, бесконе́чный (напр. в результате ошибки) вчт. — infinite loop (of instructions)прото́нный цикл — proton-proton chainпрохо́дческий цикл — sinking cycleцикл рабо́ты (напр. оборудования) — operation periodцикл рабо́ты вяза́льного аппара́та текст. — knotting cycleцикл рабо́ты запомина́ющего устро́йства вчт. — storage cycleрабо́чий цикл1. working [running] cycle2. вчт. machine cycleразо́мкнутый цикл1. open cycle2. open loopцикл Ра́нкина тепл. — Rankine cycleрегенерати́вный цикл тепл. — regenerative cycleрегенерати́вный, преде́льный цикл тепл. — complete regenerative cycleцикл Ре́нкина тепл. — Rankine cycleцикл с воспламене́нием от сжа́тия — Diesel cycleсло́жный цикл1. ( в термодинамике) compound cycle2. loop-within-loopцикл со втори́чным перегре́вом па́ра — reheat cycleцикл с одни́м отбо́ром па́ра — one-point extraction cycleцикл со сгора́нием при постоя́нном давле́нии — Diesel cycleцикл со сгора́нием при постоя́нном объё́ме — Otto cycleцикл с промежу́точным перегре́вом па́ра — reheat cycleцикл стира́ния вчт. — erase cycleсу́точный цикл — diurnal cycleцикл счи́тывания вчт. — read cycleцикл счи́тывания и за́писи вчт. — readwrite cycleтеорети́ческий цикл ( в термодинамике) — theoretical [ideal] cycleтеплово́й цикл — thermal cycleтермодинами́ческий цикл — thermodynamic cycleуглеро́дный цикл яд. физ. — carbon(-nitrogen) cycleхолоди́льный цикл — refrigeration cycleхолоди́льный, абсорбцио́нный цикл — absorption refrigeration cycleхолоди́льный, компрессио́нный цикл — compression refrigeration cycleцикл хрони́рования элк., вчт. — timing cycleчетырёхта́ктный цикл двс. — four-stroke cycle -
15 cycle
1) цикл
2) работать циклами
3) цикличный
4) период
5) такт
6) колебаться
7) цикловый
8) кольцо
– accumulation cycle
– boundary cycle
– Brayton cycle
– carbon cycle
– compound cycle
– cooking cycle
– cycle air
– cycle annealing
– cycle composition
– cycle curve
– cycle loop
– cycle of magnetization
– cycle of motion
– cycle per second
– cycle schedule
– cycle service
– cycle time
– Diesel cycle
– diurnal cycle
– duration of cycle
– engine cycle
– erase cycle
– essential cycle
– execution cycle
– four-stroke cycle
– heating cycle
– hydrogen-helium cycle
– instruction cycle
– iteration cycle
– knotting cycle
– limiting cycle
– magnetic cycle
– micro cycle
– minor cycle
– motor cycle
– open cycle
– pulse-repetition cycle
– Rankine cycle
– read cycle
– read-write cycle
– refrigeration cycle
– reheat cycle
– reset cycle
– scanning cycle
– sinking cycle
– timing cycle
– topping cycle
– Vietoris cycle
– wall cycle
– working cycle
– write cycle
complete regenerative cycle — предельный регенеративный цикл
cycle matching system — <aeron.> навигация воздушная импульсная, система навигационная импульсная
dissimilarity cycle basis — базис циклов относительно подобия
-
16 cycle
1) цикл, кольцо3) период; такт; цикл || работать циклами, периодически повторяться•over one cycle — матем. по замкнутому циклу
-
17 condition
1. условие2. состояние; положение; обстановка3. режимcondition for a nontrivial solutioncondition of optimality1-g condition20-deg angle-of-attack conditionaim conditionsairworthy conditionaltitude conditionapproach conditionsasymmetric wing sweep conditionsaustere conditionsbegin cruise conditionsbelow-stall conditionbest-range conditionsboundary conditionscaution conditionsceiling conditionsCFL conditionclimb conditioncontinuity conditionCourant-Friedrichs-Levi conditioncrossflow conditionscruise conditioncruise conditionsday conditionsdeep-stalled conditiondeparture conditionsDirichlet conditiondisplacement boundary conditionsdivergence conditiondivergent conditiondutch roll conditionelevator-free conditionengine-out conditionenvironmental conditionequilibrium conditionfailure conditionsfar-field boundary conditionfatigue conditionfinal conditionsflexural conditionsflight conditionflight conditionsflow conditionsflow tangency conditionflutter conditionsflutter onset conditionsflyaway conditionfoggy conditionsforce boundary conditionsfree-flight conditionfree-free boundary conditionsfreestream conditionfreestream conditionsfull-down conditionfull-scale conditionshigh conditionshigh-angle-of-attack conditionshigh-maneuver-lift conditionshigh-drag conditionhigh-g conditionshot conditionshover conditionhover-flight conditionicing conditionsinitial steady-flight conditionsinstrument conditionsinstrument meteorological conditionsKuhn-Tucker conditionsKutta conditionKutta-Zhukowsky conditionlanding conditionlanding conditionslaunch conditionslift conditionlift-equal-to-weight conditionlighting conditionslightning conditionslimit conditionload conditionsloading conditionslongitudinally trimmed conditionlow-angle-of-attack conditionslow-visibility conditionslow-light conditionslow-speed conditionsmaneuver conditionmaneuver entry conditionsmaneuvering conditionmaximum endurance conditionsmeteorological conditionsminimum drag conditionmission abort conditionsnear-field boundary conditionsNeumann boundary conditionneutral backside conditionno-slip conditionno-wind conditionsno-windshear conditionnonmaneuver conditionsnonpowered-lift conditionoff-design conditionsoff-nominal conditionsomega conditionoperating conditionoperational conditionoptimality conditionoscillatory conditionout-of-balance conditionout-of-trim conditionoverheat conditionoverload conditionsovertemperature conditionperiodicity conditionpost-stall conditionpostcrash conditionspowered-lift conditionpre-stall conditionpull-up conditionquasi-steady-state conditionRankine-Hugoniot conditionsresonant conditionrestraint conditionsrotating conditionsscaling conditionsea-level conditionsshock-on-lip conditionsimulator conditionssliding conditionslip conditionslow flight conditionsstalled conditionstalled conditionssteady-state conditionSTOL conditionsstraight-and-level conditionsstress conditionsubcritical conditionssupercritical conditionsupersonic conditionssupersonic leading-edge conditionsupport conditionssystem-off conditiontailwind conditionstakeoff conditionstask conditionstemperature jump conditionterminal conditiontip conditionstransient conditiontransonic conditiontranspiration conditiontransversality conditionTresca`s yield conditiontrim conditiontrimmed conditiontropical day conditionsunaugmented flutter conditionunstable conditionviewing conditionsvisibility conditionsvisual contact conditionswake conditionswashout conditionweather conditionswind conditionswind shear conditionswing-leveled conditionwing rock conditionwings-level conditionworking conditionszero-wind conditions
См. также в других словарях:
Rankine cycle engine — The Rankine cycle system uses a liquid that evaporates when heated and expands to produce work, such as turning a turbine, which when connected to a generator, produces electricity. The exhaust vapor expelled from the turbine condenses and the… … Energy terms
Rankine-cycle engine — [raŋ′kinsī′kəl] n. 〚see RANKINE〛 a type of steam engine involving a continuous cycle of vaporization of liquid and condensation back to liquid in a sealed system: developed experimentally for use in automobiles to reduce polluting emissions,… … Universalium
Rankine-cycle engine — [raŋ′kinsī′kəl] n. [see RANKINE] a type of steam engine involving a continuous cycle of vaporization of liquid and condensation back to liquid in a sealed system: developed experimentally for use in automobiles to reduce polluting emissions,… … English World dictionary
Rankine — may refer to: * Rankine cycle, a thermodynamic heat engine cycle * Rankine scale, an absolute temperature scale used mostly by US engineers * William John Macquorn Rankine (1820–1872), a Scottish engineer and physicist who proposed both of the… … Wikipedia
Rankine — (spr. ränkin), William John Macquorn, Ingenieur, geb. 5. Juli 1820 in Edinburg, gest. 24. Dez. 1872, studierte in Edinburg, lehrte mehrere Jahre in Glasgow und arbeitete über die Wärme und die Theorie der Motoren, die Erhaltung der Kraft und über … Meyers Großes Konversations-Lexikon
Rankine — (spr. rännkĭn), William John Macquorn, Ingenieur, geb. 5. Juli 1820 zu Edinburgh, seit 1855 Prof. in Glasgow, gest. 24. Dez. 1872, Mitbegründer der Thermodynamik; schrieb: »Manual of applied mecanics« (11. Aufl. 1885), »Manual of the steam… … Kleines Konversations-Lexikon
Rankine cycle — Thermodynam. the hypothetical cycle of a steam engine in which all heat transfers take place at constant pressure and in which expansion and compression occur adiabatically. Also called Clausius cycle. [1895 1900; named after W. J. M. RANKINE] *… … Universalium
Engine — This article is about a machine to convert energy into useful mechanical motion. For other uses of engine, see Engine (disambiguation). For other uses of motor, see Motor (disambiguation). A V6 internal combustion engine from a Mercedes car An… … Wikipedia
Rankine cycle — The Rankine cycle is a thermodynamic cycle which converts heat into work. The heat is supplied externally to a closed loop, which usually uses water as the working fluid. This cycle generates about 80% of all electric power used throughout the… … Wikipedia
Rankine, William John Macquorn — ▪ Scottish engineer born July 5, 1820, Edinburgh, Scot. died Dec. 24, 1872, Glasgow Scottish engineer and physicist and one of the founders of the science of thermodynamics, particularly in reference to steam engine theory. Trained as … Universalium
Rankine scale — For the idealized thermodynamic cycle for a steam engine, see Rankine cycle. For the scale measuring recovery after stroke, see modified Rankin scale. Rankine temperature conversion formulae from Rankine to Rankine Celsius… … Wikipedia