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1 experimental engine
XE, experimental engineEnglish-Russian dictionary of planing, cross-planing and slotting machines > experimental engine
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2 experimental engine
1) Техника: экспериментальный индукторный двигатель2) Космонавтика: опытный двигатель, экспериментальный двигатель -
3 experimental engine
Англо-русский словарь по машиностроению > experimental engine
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4 quiet STOL experimental engine
QSEE, quiet STOL experimental engineEnglish-Russian dictionary of planing, cross-planing and slotting machines > quiet STOL experimental engine
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5 quiet STOL experimental engine
Военный термин: экспериментальный малошумящий двигатель для СУВПУниверсальный англо-русский словарь > quiet STOL experimental engine
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6 engine
двигатель (внутреннего сгорания); машина; мотор- engine analyzer - engine and gearbox unit - engine area - engine assembly - engine assembly shop - engine bonnet - engine braking force - engine breathing - engine-building - engine capacity - engine cleansing agents - engine column - engine component - engine conk - engine control - engine-cooling - engine-cooling thermometer - engine cowl flap - engine cross-drive casing - engine cutoff - engine cycle - engine data - engine deck - engine department - engine details - engine diagnostic connector - engine-driven air compressor - engine-driven industrial shop truck - engine dry weight - engine efficiency - engine failure - engine fan pulley - engine flameout - engine flywheel - engine for different fuels - engine frame - engine front - engine front area - engine front support bracket - engine fuel - engine gearbox - engine-gearbox unit - engine-generator - engine-governed speed - engine governor - engine gum - engine hatch - engine hoist - engine hood - engine house - engine idles rough - engine in situ - engine installation - engine is smooth - engine is tractable - engine knock - engine lacquer - engine life - engine lifetime pecypc - engine lifting bracket - engine lifting fixture - engine lifting hook - engine location - engine lubrication system - engine lug - engine management - engine management system - engine map - engine misfires - engine model - engine motoring - engine mount - engine-mounted - engine mounted longitudinally - engine mounted transversally - engine mounting - engine-mounting bracket - engine nameplate - engine noise - engine number - engine off - engine oil - engine oil capacity - engine oil filler cap - engine oil filling cap - engine oil tank - engine on - engine operating temperature - engine out of work - engine output - engine overhaul - engine pan - engine peak speed - engine performance - engine picks up - engine pings - engine piston - engine plant - engine power - engine pressure - engine primer - engine rating - engine rear support - engine reconditioning - engine renovation - engine repair stand - engine retarder - engine revolution counter - engine rig test - engine room - engine roughness - engine rpm indicator - engine run-in - engine runs rough - engine runs roughly - engine shaft - engine shed - engine shield - engine shop - engine shorting-out - engine shutdown - engine sludge - engine snubber - engine speed - engine speed sensor - engine stability - engine stalls - engine start - engine starting system - engine starts per day - engine stroke - engine subframe - engine sump - engine sump well - engine support - engine temperature sensor - engine test stand - engine testing room - engine throttle - engine timing case - engine-to-cabin passthrough aperture - engine-transmission unit - engine torque - engine trends - engine trouble - engine tune-up - engine turning at peak revolution - engine under seat - engine unit - engine vacuum checking gauge - engine valve - engine varnish - engine vibration - engine wash - engine water inlet - engine water outlet - engine wear - engine weight - engine weight per horsepower - engine winterization system - engine with supercharger - engine wobble - engine works - engine yard - engine's flexibility - aero-engine - atmospheric engine - atmospheric steam engine - atomic engine - augmented engine - AV-1 engine - aviation engine - back-up engine - birotary engine - blast-injection diesel engine - blower-cooled engine - bored-out engine - boxer engine - bull engine - car engine - charge-cooled engine - crank engine - crankcase-scavenged engine - crude engine - crude-oil engine - diaphragm engine - diesel-electric engine - Diesel engine - Diesel engine with air cell - Diesel engine with antechamber - Diesel engine with direct injection - Diesel engine with mechanical injection - direct injection engine - divided-chamber engine - double-flow engine - double-overhead camshaft engine - drilling engine - driving engine - drop-valve engine - ducted-fan engine - duofuel engine - emergency engine - explosion engine - external combustion engine - external-internal combustion engine - F-head engine - failed engine - fan engine - federal engine - field engine - fire-engine - five-cylinder engine - fixed engine - flame engine - flat engine - flat-four engine - flat twin engine - flexibly mounted engine - forced-induction engine - four-cycle engine - four-cylinder engine - four-stroke engine - free-piston engine - free-piston gas generator engine - front-mounted engine - free-turbine engine - fuel-injection engine - full-load engine - gas engine - gas blowing engine - gas-power engine - gas-turbine engine - gasoline engine - geared engine - heat engine - heavy-duty engine - heavy-oil engine - high-by-pass-ratio turbofan engine - high-compression engine - high-efficiency engine - high-performance engine - high-power engine - high-speed engine - hoisting engine - hopped-up engine - horizontal engine - horizontally opposed engine - hot engine - hot-air engine - hot-bulb engine - hydrogen engine - I-head engine - in-line engine - inclined engine - indirect injection engine - individual-cylinder engine - industrial engine - inhibited engine - injection oil engine - injection-type engine - intercooled diesel engine - intermittent-cycle engine - internal combustion engine - inverted engine - inverted Vee-engine - jet engine - jet-propulsion engine - kerosene engine - knock test engine - L-head engine - launch engine - lean-burn engine - left-hand engine - lift engine - light engine - liquid-cooled engine - liquid propane engine - locomotive engine - longitudinal engine - long-stroke engine - low-compression engine - low-consumption engine - low-emission engine - low-performance engine - low-speed engine - marine engine - modular engine - monosoupape engine - motor engine - motor an engine round - motor-boat engine - motor-fire engine - motorcycle engine - motored engine - multibank engine - multicarburetor engine - multicrank engine - multicylinder engine - multifuel engine - multirow engine - naturally aspirated engine - non-compression engine - non-condensing engine - non-exhaust valve engine - non-poppet valve engine - non-reversible engine - nuclear engine - oil engine - oil-electric engine - oil well drilling engine - one-cylinder engine - operating engine - opposed engine - opposed cylinders engine - Otto engine - out-board engine - overcooled engine - overhead valve engine - oversquare engine - overstroke engine - pancake engine - paraffin engine - paraffine engine - petrol engine - Petter AV-1 Diesel engine - pilot engine - piston engine - piston blast engine - port engine - precombustion chamber engine - prime an engine - producer-gas engine - production engine - prototype engine - pumping engine - pushrod engine - quadruple-expansion engine - qual-cam engine - racing engine - radial engine - radial cylinder engine - radial second motion engine - railway engine - ram induction engine - ram-jet engine - reaction engine - rear-mounted engine - rebuilt engine - reciprocating engine - reciprocating piston engine - reconditioned engine - regenerative engine - regular engine - reheat engine - research-cylinder engine - reversible engine - reversing engine - right-hand engine - rocket engine - rotary engine - rough engine - row engine - run in an engine - scavenged gasoline engine - scavenging engine - sea-level engine - second-motion engine - self-ignition engine - semidiesel engine - series-wound engine - servo-engine - short-life engine - short-stroke engine - shorted-out engine - shunting engine - shunt-wound engine - side-by-side engine - side-valve engine - simple-expansion engine - single-acting engine - single-chamber rocket engine - single-cylinder engine - single-cylinder test engine - single-row engine - six-cylinder engine - skid engine - slanted engine - sleeve-valve engine - sleeveless engine - slide-valve engine - slope engine - slow-running engine - slow-speed engine - small-bore engine - small-displacement engine - solid-injection engine - spark-ignition engine - spark-ignition fuel-injection engine - split-compressor engine - square engine - square stroke engine - stalled engine - stand-by engine - start the engine cold - start the engine light - start the engine warm- hot- starting engine - static engine - stationary engine - steam engine - steering engine - Stirling engine - straight-eight engine - straight-line engine - straight-type engine - stratified charge engine - stripped engine - submersible engine - suction gas engine - supercharged engine - supercompression engine - supplementary engine - swash-plate engine - switching engine - tandem engine - tank engine - thermal engine - three-cylinder engine - traction engine - triple-expansion engine - tractor engine - transversally-mounted engine - truck engine - trunk-piston Diesel engine - turbine engine - turbo-jet engine - turbo-charged engine - turbo-compound engine - turbo-prop engine - turbo-ramjet engine - turbo-supercharged engine - turbocharged-and-aftercooled engine - turbofan engine - turboprop engine - twin engine - twin cam engine - twin crankshaft engine - twin six engine - two-bank engine - two-cycle engine - two-cylinder engine - two-spool engine - two-stroke engine - unblown engine - uncooled engine - underfloor engine - undersquare engine - uniflow engine - unsupercharged engine - uprated engine - V-engine - V-type engine - valve-in-the-head engine - valveless engine - vaporizer engine - vaporizing-oil engine - variable compression engine - variable-stroke engine - variable valve-timing engine - vee engine - vertical engine - vertical turn engine - vertical vortex engine - W-type engine - Wankel engine - warm engine - waste-heat engine - water-cooled engine - winding engine - windshield wiper engine - woolly-type engine - worn engine - X-engine - Y-engine - yard engine -
7 experimental rocket engine test station
Космонавтика: станция испытаний опытных образцов ракетных двигателейУниверсальный англо-русский словарь > experimental rocket engine test station
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8 Whittle, Sir Frank
SUBJECT AREA: Aerospace[br]b. 1 June 1907 Coventry, England[br]English engineer who developed the first British jet engine.[br]Frank Whittle enlisted in the Royal Air Force (RAF) as an apprentice, and after qualifying as a pilot he developed an interest in the technical aspects of aircraft propulsion. He was convinced that the gas-turbine engine could be adapted for use in aircraft, but he could not convince the Air Ministry, who turned down the proposal. Nevertheless, Whittle applied for a patent for his turbojet engine the following year, 1930. While still in the RAF, he was allowed time to study for a degree at Cambridge University and carry out postgraduate research (1934–7). By 1936 the official attitude had changed, and a company called Power Jets Ltd was set up to develop Whittle's jet engine. On 12 April 1937 the experimental engine was bench-tested. After further development, an official order was placed in March 1938. Whittle's engine had a centrifugal compressor, ten combustion chambers and a turbine to drive the compressor; all the power output came from the jet of hot gases.In 1939 an experimental aircraft was ordered from the Gloster Aircraft Company, the E 28/39, to house the Whittle W1 engine, and this made its first flight on 15 May 1941. A development of the W1 by Rolls-Royce, the Welland, was used to power the twin-engined Gloster Meteor fighter, which saw service with the RAF in 1944. Whittle retired from the RAF in 1948 and became a consultant. From 1977 he lived in the United States. Comparisons between the work of Whittle and Hans von Ohain show that each of the two engineers developed his engine without knowledge of the other's work. Whittle was the first to take out a patent, Ohain achieved the first flight; the Whittle engine and its derivatives, however, played a much greater role in the history of the jet engine.[br]Principal Honours and DistinctionsKnighted 1948. Commander of the Order of the Bath 1947. Order of Merit 1986. FRS 1947. Honorary Fellow of the Royal Aeronautical Society.Bibliography1953, Jet, London (an account not only of his technical problems, but also of the difficulties with civil servants, politicians and commercial organizations).Further ReadingJ.Golley, 1987, Whittle: The True Story, Shrewsbury (this author based his work on Jet, but carried out research, aided by Whittle, to give a fuller account with the benefit of hindsight).JDS -
9 QCSEE
1) Сокращение: Quiet, Clean, Short-haul Experimental Engine2) Воздухоплавание: Quiet Clean STOL Experimental Engine -
10 QSEE
Военный термин: quiet STOL experimental engine -
11 QSEE
QSEE, quiet STOL experimental engineEnglish-Russian dictionary of planing, cross-planing and slotting machines > QSEE
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12 XE
XE, experimental engineEnglish-Russian dictionary of planing, cross-planing and slotting machines > XE
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13 Smeaton, John
SUBJECT AREA: Civil engineering, Mechanical, pneumatic and hydraulic engineering, Steam and internal combustion engines[br]b. 8 June 1724 Austhorpe, near Leeds, Yorkshire, Englandd. 28 October 1792 Austhorpe, near Leeds, Yorkshire, England[br]English mechanical and civil engineer.[br]As a boy, Smeaton showed mechanical ability, making for himself a number of tools and models. This practical skill was backed by a sound education, probably at Leeds Grammar School. At the age of 16 he entered his father's office; he seemed set to follow his father's profession in the law. In 1742 he went to London to continue his legal studies, but he preferred instead, with his father's reluctant permission, to set up as a scientific instrument maker and dealer and opened a shop of his own in 1748. About this time he began attending meetings of the Royal Society and presented several papers on instruments and mechanical subjects, being elected a Fellow in 1753. His interests were turning towards engineering but were informed by scientific principles grounded in careful and accurate observation.In 1755 the second Eddystone lighthouse, on a reef some 14 miles (23 km) off the English coast at Plymouth, was destroyed by fire. The President of the Royal Society was consulted as to a suitable engineer to undertake the task of constructing a new one, and he unhesitatingly suggested Smeaton. Work began in 1756 and was completed in three years to produce the first great wave-swept stone lighthouse. It was constructed of Portland stone blocks, shaped and pegged both together and to the base rock, and bonded by hydraulic cement, scientifically developed by Smeaton. It withstood the storms of the English Channel for over a century, but by 1876 erosion of the rock had weakened the structure and a replacement had to be built. The upper portion of Smeaton's lighthouse was re-erected on a suitable base on Plymouth Hoe, leaving the original base portion on the reef as a memorial to the engineer.The Eddystone lighthouse made Smeaton's reputation and from then on he was constantly in demand as a consultant in all kinds of engineering projects. He carried out a number himself, notably the 38 mile (61 km) long Forth and Clyde canal with thirty-nine locks, begun in 1768 but for financial reasons not completed until 1790. In 1774 he took charge of the Ramsgate Harbour works.On the mechanical side, Smeaton undertook a systematic study of water-and windmills, to determine the design and construction to achieve the greatest power output. This work issued forth as the paper "An experimental enquiry concerning the natural powers of water and wind to turn mills" and exerted a considerable influence on mill design during the early part of the Industrial Revolution. Between 1753 and 1790 Smeaton constructed no fewer than forty-four mills.Meanwhile, in 1756 he had returned to Austhorpe, which continued to be his home base for the rest of his life. In 1767, as a result of the disappointing performance of an engine he had been involved with at New River Head, Islington, London, Smeaton began his important study of the steam-engine. Smeaton was the first to apply scientific principles to the steam-engine and achieved the most notable improvements in its efficiency since its invention by Newcomen, until its radical overhaul by James Watt. To compare the performance of engines quantitatively, he introduced the concept of "duty", i.e. the weight of water that could be raised 1 ft (30 cm) while burning one bushel (84 lb or 38 kg) of coal. The first engine to embody his improvements was erected at Long Benton colliery in Northumberland in 1772, with a duty of 9.45 million pounds, compared to the best figure obtained previously of 7.44 million pounds. One source of heat loss he attributed to inaccurate boring of the cylinder, which he was able to improve through his close association with Carron Ironworks near Falkirk, Scotland.[br]Principal Honours and DistinctionsFRS 1753.Bibliography1759, "An experimental enquiry concerning the natural powers of water and wind to turn mills", Philosophical Transactions of the Royal Society.Towards the end of his life, Smeaton intended to write accounts of his many works but only completed A Narrative of the Eddystone Lighthouse, 1791, London.Further ReadingS.Smiles, 1874, Lives of the Engineers: Smeaton and Rennie, London. A.W.Skempton, (ed.), 1981, John Smeaton FRS, London: Thomas Telford. L.T.C.Rolt and J.S.Allen, 1977, The Steam Engine of Thomas Newcomen, 2nd edn, Hartington: Moorland Publishing, esp. pp. 108–18 (gives a good description of his work on the steam-engine).LRD -
14 EEC
1) Общая лексика: Ассамблея Европейского экономического сообщества2) Компьютерная техника: Electronic Engine Control3) Авиация: электронный регулятор режимов работы двигателя4) Военный термин: East European Countries, Elements of Expense Code, Enhanced Explosives Charge, Enlisted Evaluation Center5) Техника: Electrical and Electronics Commission, Erosion Experimental Station, end-of-equilibrium cycle, engine electronic control6) Шутливое выражение: Either European Community7) Химия: Environmental Education Center, Equilibrium Equivalent Concentration, Evaporation Emission Control8) Железнодорожный термин: East Erie Commercial Railroad9) Экономика: ЕЭС, ЕврАзЭС (Eurasian Economic Community, хотя на официальном сайте дается EurAsEC см. http://www.evrazes.com/en/about), Общий рынок (1957 г.)10) Автомобильный термин: electronic engine control - электронное управление двигателем, electronic engine control (Ford)11) Сокращение: Electronic Engine Controls, European Economic Community Now European Union (EU), European Economic Council, Extended Exit Cone, High explosive, general-purpose, Extended Error Correction12) Шахматы: Emile's Evolutionary Chess13) Вычислительная техника: Комитет по электронной аппаратуре14) Нефть: european economic commission15) Банковское дело: Европейское экономическое сообщество (European Economic Community)16) Воздухоплавание: European Experimental Centre17) Фирменный знак: East Erie Commercial18) Деловая лексика: Европейское экономическое сообщество (ЕЭС, European Economic Community)19) Образование: Early Elementary Classroom20) Инвестиции: European Economic Community21) Сетевые технологии: Electronic Equipment Committee22) AMEX. Environmental Elements Corporation -
15 Wankel, Felix
[br]b. 13 August 1902 Lahr, Black Forest, Germanyd. 9 October 1988 Lindau, Bavaria, Germany[br]German internal combustion engineer, inventor of the Wankel rotary engine.[br]Wankel was first employed at the German Aeronautical Research Establishment, where he worked on rotary valves and valve sealing techniques in the early 1930s and during the Second World War. In 1951 he joined NSU Motorenwerk AG, a motor manufacturer based at Neckarsulm, near Stuttgart, and began work on his rotary engine; the idea for this had first occurred to Wankel as early as 1929. He had completed his first design by 1954, and in 1957 his first prototype was tested. The Wankel engine has a three-pointed rotor, like a prism of an equilateral triangle but with the sides bowed outwards. This rotor is geared to a driveshaft and rotates within a closely fitting and slightly oval-shaped chamber so that, on each revolution, the power stroke is applied to each of the three faces of the rotor as they pass a single spark plug. Two or more rotors may be mounted coaxially, their power strokes being timed sequentially. The engine has only two moving parts, the rotor and the output shaft, making it about a quarter less in weight compared with a conventional piston engine; however, its fuel consumption is high and its exhaust emissions are relatively highly pollutant. The average Wankel engine speed is 5,500 rpm. The first production car to use a Wankel engine was the NSU Ro80, though this was preceded by the experimental NSU Spyder prototype, an open two-seater. The Japanese company Mazda is the only other automobile manufacturer to have fitted a Wankel engine to a production car, although licences were taken by Alfa Romeo, Peugeot- Citroën, Daimler-Benz, Rolls-Royce, Toyota, Volkswagen-Audi (the company that bought NSU in the mid-1970s) and many others; Daimler-Benz even produced a Mercedes C-111 prototype with a three-rotor Wankel engine. The American aircraft manufacturer Curtiss-Wright carried out research for a Wankel aero-engine which never went into production, but the Austrian company Rotax produced a motorcycle version of the Wankel engine which was fitted by the British motorcycle manufacturer Norton to a number of its models.While Wankel became director of his own research establishment at Lindau, on Lake Constance in southern Germany, Mazda continued to improve the rotary engine and by the time of Wankel's death the Mazda RX-7 coupé had become a successful, if not high-selling, Wankel -engined sports car.[br]Further ReadingN.Faith, 1975, Wankel: The Curious Story Behind the Revolutionary Rotary Engine, New York: Stein \& Day.IMcN -
16 EDP
1) Общая лексика: Engine Driven Pump (Например, "low winged aircraft use an EDP to draw the fuel from the tanks". Речь идёт о лёгких самолётах. На больших EDP может обеспечивать энергией другие системы, например, гидросистему (одну из).), electric distribution point2) Авиация: engine development program3) Морской термин: процедура заблаговременного отправления, early departure procedure4) Американизм: Economic Diversification Program5) Военный термин: ELINT Data Processor, Emergency Defense Plan, US-Canada, effective directives and plans, electronic display panel, emergency defense plan, emergency defense position, engineering data plotting, engineering design plan, engineering design proposal, engineering development phase, environment determination program, equipment deadlined for parts, estimated date of publication, expeditious discharge program, experimental development plan6) Техника: Entrance Door Plate, electron decay profile, experimental dynamic processor, электронная дозирующая пипетка (electronic dispensing pipette)7) Юридический термин: Emotionally Disturbed Person8) Бухгалтерия: электронная обработка данных (ЭОД, electronic data processing)9) Страхование: electronic data processing coverage10) Сокращение: Emergency Defence Plan, Engagement Decision Point, Executive Development Program, Experimental Development, eau de parfum11) Текстиль: легко окрашиваемый полиэфир (easy dyeable polyester)12) Электроника: Educational Development Plan, Electron Diffraction Pattern, Ethylene Diamine Pyrocatechol13) Вычислительная техника: enhanced dot pitch, обработка данных с помощью компьютера, Enhanced Dot Pitch (Hitachi), процессор для электронной обработки данных14) Транспорт: Expedite Departure Path15) Фирменный знак: Elegant Darkness Productions16) Деловая лексика: Excellent Design Practiced, электронная обработка данных (electronic data processing)17) Глоссарий компании Сахалин Энерджи: Emergency Depressurizing (system)18) Образование: External Diploma Program19) Сетевые технологии: electronic data processing, electronic data processor, усовершенствованная технология тиражирования данных20) Автоматика: edge position control21) Сахалин А: emergency depressurization, installation emergency depressurizing22) Медицинская техника: end-diastolic pressure (ЭхоКГ)23) Фантастика Electronic Dream Plant24) Исследования и разработки (НИОКР): engineering development procedures25) Должность: Electronic Document Professional -
17 EPR
1) Общая лексика: Exploration and Production Russia (Shell), европейский реактор с водой под давлением (European Pressurised [Water nuclear] Reactor, иногда расшифровывают как evolutionary power reactor (реактор т.н. 3+ поколения, французско-немецкий проект. Есть вариант для США US-EPR)), evaporator pressure regulator2) Авиация: степень повышения давления в двигателе3) Военный термин: Enlisted Performance Report, Extended Planning Annex, emergency parts requisition, equipment performance report, essential performance requirements, experimental packet radio, explosion-proof relay4) Техника: electromechanical potentiokinetic reactivation, electronic parts reliability, emergency planning requirements, emergency planning review, enhanced participatory rulemaking, equipotential region, essential performance requirement, experimental power reactor5) Юридический термин: Evidence Processing Room6) Автомобильный термин: exhaust pressure regulator valve7) Оптика: electron parameter resonance8) Сокращение: Engine Pressure Ratio, этилен-пропиленовый каучук (Ethylene Propylene Rubber)9) Физиология: Electronic Patient Record10) Электроника: Ethylene- Propylene ( Copolymer) Resin11) Нефть: East Pacific Rise, Exxon production research company, electronic paramagnetic resonance, ethylene-propylene rubber conductor insulation, донесение об эксплуатационных качествах оборудования (equipment performance report)12) Космонавтика: Emergency Preparedness and Response Unit (WHO)13) Банковское дело: отношение чистой прибыли к цене акции (earnings-price ratio)14) Воздухоплавание: Engine Pressure Radio, Engine Pressure Ration15) Деловая лексика: Every Painter's Responsibility, Extended Producer Responsibility, Extended Product Responsibility16) Инвестиции: earnings-price ratio18) Программирование: Endpoint references, ссылки на оконечные точки19) Сахалин Р: Explosion Protection Review20) Кабельные производство: ethylene-propylene rubber22) NYSE. Entertainment Properties Trust -
18 epr
1) Общая лексика: Exploration and Production Russia (Shell), европейский реактор с водой под давлением (European Pressurised [Water nuclear] Reactor, иногда расшифровывают как evolutionary power reactor (реактор т.н. 3+ поколения, французско-немецкий проект. Есть вариант для США US-EPR)), evaporator pressure regulator2) Авиация: степень повышения давления в двигателе3) Военный термин: Enlisted Performance Report, Extended Planning Annex, emergency parts requisition, equipment performance report, essential performance requirements, experimental packet radio, explosion-proof relay4) Техника: electromechanical potentiokinetic reactivation, electronic parts reliability, emergency planning requirements, emergency planning review, enhanced participatory rulemaking, equipotential region, essential performance requirement, experimental power reactor5) Юридический термин: Evidence Processing Room6) Автомобильный термин: exhaust pressure regulator valve7) Оптика: electron parameter resonance8) Сокращение: Engine Pressure Ratio, этилен-пропиленовый каучук (Ethylene Propylene Rubber)9) Физиология: Electronic Patient Record10) Электроника: Ethylene- Propylene ( Copolymer) Resin11) Нефть: East Pacific Rise, Exxon production research company, electronic paramagnetic resonance, ethylene-propylene rubber conductor insulation, донесение об эксплуатационных качествах оборудования (equipment performance report)12) Космонавтика: Emergency Preparedness and Response Unit (WHO)13) Банковское дело: отношение чистой прибыли к цене акции (earnings-price ratio)14) Воздухоплавание: Engine Pressure Radio, Engine Pressure Ration15) Деловая лексика: Every Painter's Responsibility, Extended Producer Responsibility, Extended Product Responsibility16) Инвестиции: earnings-price ratio18) Программирование: Endpoint references, ссылки на оконечные точки19) Сахалин Р: Explosion Protection Review20) Кабельные производство: ethylene-propylene rubber22) NYSE. Entertainment Properties Trust -
19 Symington, William
SUBJECT AREA: Ports and shipping[br]b. 1764 Leadhills, Lanarkshire, Scotlandd. 22 March 1831 Wapping, London, England[br]Scottish pioneer of steam navigation.[br]Symington was the son of the Superintendent of the Mines Company in Lanarkshire, and attended the local school. When he was 22 years old he was sent by Gilbert Meason, Manager of the Wanlockhead mines, to Edinburgh University. In 1779 he was working on the assembly of a Watt engine as an apprentice to his brother, George, and in 1786 he started experiments to modify a Watt engine in order to avoid infringing the separate condenser patent. He sought a patent for his alternative, which was paid for by Meason. He constructed a model steam road carriage which was completed in 1786; it was shown in Edinburgh by Meason, attracting interest but inadequate financial support. It had a horizontal cylinder and was non-condensing. No full-sized engine was ever built but the model secured the interest of Patrick Miller, an Edinburgh banker, who ordered an engine from Symington to drive an experimental boat, 25 ft (7.6 m) long with a dual hull, which performed satisfactorily on Dalswinton Loch in 1788. In the following year Miller ordered a larger engine for a bigger boat which was tried on the Forth \& Clyde Canal in December 1789, the component parts having been made by the Carron Company. The engine worked perfectly but had the effect of breaking the paddle wheels. These were repaired and further trials were successful but Miller lost interest and his experiments lapsed. Symington devoted himself thereafter to building stationary engines. He built other engines for mine pumping at Sanquhar and Leadhills before going further afield. In all, he built over thirty engines, about half of them being rotary. In 1800–1 he designed the engine for a boat for Lord Dundas, the Charlotte Dundas; this was apparently the first boat of that name and sailed on both the Forth and Clyde rivers. A second Charlotte Dundas with a horizontal cylinder was to follow and first sailed in January 1803 for the Forth \& Clyde Canal Company. The speed of the boat was only 2 mph (3 km/h) and much was made by its detractors of the damage said to be caused to the canal banks by its wash. Lord Dundas declined to authorize payment of outstanding accounts; Symington received little reward for his efforts. He died in the house of his son-in-law, Dr Robert Bowie, in Wapping, amidst heated controversy about the true inventor of steam navigation.[br]Further ReadingW.S.Harvey and G.Downs-Rose, 1980, William Symington, Inventor and Engine- Builder, London: Mechanical Engineering Publications.IMcN -
20 operation
1) работа; функционирование2) матем. действие3) эксплуатация4) (технологическая) операция; процесс; цикл ( обработки)6) управление7) вчт. операция; команда8) предприятие•-
abnormal operation
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acquisition operation
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aerial operation
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aerial survey operation
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aerial work operation
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aerobatics operation
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aerospace operations
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air-bumped-and-rinse operation
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aircraft operations
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air-lift well operation
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airport facilities operation
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alignment operation
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all-weather operations
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AND operation
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approach operation
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arithmetic operation
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artificial-lift well operation
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associated fire control operation
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asynchronous operation
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attached operation
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attempted operation
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attended operation
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authorized operation
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automated operation
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automatic block operation
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averaging operation
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background operation
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batch operation
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bidirectional operation
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bilevel operation
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binary operation
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bistable operation
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bitwise operation
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bit operation
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blanking operation
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blasting operation
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blocking-off operation
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bookkeeping operations
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Boolean operation
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both-way operation
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brake test operation
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braking operation
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branch operation
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breaking operation
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bytewise operation
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byte operation
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cable operation
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Carnot operation
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carrier-recovery operation
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cation-anion operation
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caving operations
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cavitation-free operation
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centralized operation
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channel operation
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check operation
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chipping-and-hauling operation
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class A operation
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class B operation
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class C operation
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climb to cruise operation
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closing operation
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CNC operation
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cocurrent operation
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coded operation
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co-frequency operation
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cold end operation
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commercial operation
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comparison operation
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complete operation
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concurrent operation
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conjunction operation
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continual harvesting operations
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continuous operation
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continuous-wave operation
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control operation
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counter-current operation
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critical operation
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cutting operation
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cycle operation
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declarative operation
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decrement operation
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demonstration operation
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dependent manual operation
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dependent power operation
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diplex operation
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disjunction operation
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diversity operation
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docked operation
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docking operations
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domestic operations
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double-track operation
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dredging operations
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dressing operation
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drifting operation
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drilling and blasting operations
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drilling operation
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dual operation
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dual-point operation
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duplex operation
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dyadic operation
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emergency operation
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engine run-up operation
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en-route operation
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except operation
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exclusive OR operation
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experimental operation
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explosionproof operation
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face operations
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fail-safe operation
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fail-soft operation
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failure-free operation
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false operation
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fault tolerant operation
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faulty operation
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felling operation
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ferry operation
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field operation
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final felling operations
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finite reflux operation
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fire control operation
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fixed-cycle operation
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fixed-point operation
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flashing operation
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floating-point operation
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flowing well operation
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foreground operation
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forest harvesting operations
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free-flier operation
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free-flying operation
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freight operation
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fretting operation
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fringe operation
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full tree operations
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full-duplex operation
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gas-lift well operation
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gate operation
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general aviation operations
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generic operation
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get-home engine operation
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half-duplex operation
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hands-off operation
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harvesting operations
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hauling operation
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helicopter logging operation
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high-gain operation
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high-speed operation
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hot end operation
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hot-stick operation
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housekeeping operation
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hydropacker plunger lift well operation
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idling engine operation
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IF-THEN operation
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illegal operation
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impeded harmonic operation
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implication operation
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in-channel operation
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increment operation
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independent manual operation
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individual-point operation
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indoor operation
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infinite reflux operation
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in-phase operation
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input/output operation
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instruction operation
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instrument flight rules operation
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integer operation
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international operations
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iterative operation
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jump operation
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kernel operation
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kiln operation
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lagging power factor operation
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landing operation
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large-scale space operations
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large-signal operation
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leading power factor operation
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leveling operation
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level-off operation
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linear operation
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lock-on operation
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logging operations
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logical operation
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loop operation
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low flying operation
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low-effort operation
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low-gain operation
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lumbering operation
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machine operation
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machining operation
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maintenance operation
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manual operation
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marginal operation
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measuring operation
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mechanical operation
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mechanized logging operations
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melting operation
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mill operation
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minimally-manned operation
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minimal operation
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model operation
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monadic operation
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monostable operation
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move operation
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multicarrier operation
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multimode operation
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multiple operation
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multiple-stream operation
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multiple-unit operation
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multiplex operation
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NAND operation
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no operation
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no-load operation
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noncentralized operation
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noncommercial operations
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noncondensing operation
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nonextraction operation
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nonfailure operation
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nonresiduum operation
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nonscheduled operations
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nonslagging operation
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NOR operation
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normal pump operation
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NOT operation
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NOT-AND operation
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NOT-OR operation
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off-design operation
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off-line operation
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one-shot operation
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one-step operation
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on-line operation
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on-off operation
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open-air operation
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open-hearth operation
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opening operation
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OR operation
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outdoor operation
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overburden operations
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packet-mode operation
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packet-switching operation
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parallel operation
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partial reflux operation
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passenger operations
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peak load operation
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pleasure operation
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point operation
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point-to-point operation
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positioning operation
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post-drill operation
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post-fault operation
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power patrol operation
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power station operation
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power system operation
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practice operation
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predrill operation
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primitive operation
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products pipeline operation
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pull-in operation
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pulse laser operation
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pulsed operation
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punched tape operation
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push-pull operation
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push-push operation
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quadrature operation
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quantizing operation
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quarry operation
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rafting operation
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read operation
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real-time operation
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refusing operation
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remote operation
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rendezvous operations
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repetitive operation
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rescue operations
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reservoir operation
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retarder operation
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rotorcraft operations
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rough engine operation
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run-of-river operation
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scale operation
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scheduled operation
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search operation
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self-contained and self-monitored operation
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semifinish operation
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sensory operation
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settling operation
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shift operation
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shunting operation
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signal operation
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simplex operation
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simultaneous operation
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single-block operation
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single-contact operation
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single-mode operation
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single-pulse operation
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single-step operation
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sinking operation
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slag-free operation
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slag-tap operation
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slightly manned operation
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small-signal operation
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solo supervised operation
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solo operation
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speed range operation
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spike operation
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stable operation
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staggered-parallel operation
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standby operation
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starting engine operation
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start-stop operation
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staying operation
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steady operation
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steaming operation
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steelmaking operation
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step-and-repeat operation
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step-by-step operation
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stitch transfer operation
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stone-free operation
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storage operation
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straight gas-lift well operation
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string operation
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studio operation
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stump wood operation
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suppressed-carrier operation
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switch operation
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switching operation
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synchronous operation
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tap-change operation
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taxing operation
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terminal operation
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test operation
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thinning operations
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threading operation
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throttled engine operation
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timber-harvesting operations
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total reflux operation
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touchdown operation
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track-while-scan operation
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training operation
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transfer operation
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transient operation
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tree length operations
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trial operation
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trouble-free operation
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turbine operation
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two-shift operation
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two-vessel operation
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typical operation
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unary operation
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unattended operation
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unauthorized operation
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underground operation
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undocked operation
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undocking operations
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uninterrupted operation
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unmanned operation
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unthrottled engine operation
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variable-load operation
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vertical rotorcraft operation
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water-system operation
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well operation
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whole tree operations
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wide-open throttle operation
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word operation
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working operation
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write operation
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yard operation
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year-round operations
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