-
1 portable energy
нестационарные ( передвижные) установки для выработки энергииАнгло-русский словарь промышленной и научной лексики > portable energy
-
2 энергия от передвижных установок
энергия от передвижных установок
энергия от нестационарных установок
—
[Я.Н.Лугинский, М.С.Фези-Жилинская, Ю.С.Кабиров. Англо-русский словарь по электротехнике и электроэнергетике, Москва, 1999 г.]Тематики
- электротехника, основные понятия
Синонимы
EN
Русско-английский словарь нормативно-технической терминологии > энергия от передвижных установок
-
3 нестационарные (передвижные) установки для выработки энергии
Engineering: portable energyУниверсальный русско-английский словарь > нестационарные (передвижные) установки для выработки энергии
-
4 передвижные установки для выработки энергии
Makarov: portable energyУниверсальный русско-английский словарь > передвижные установки для выработки энергии
-
5 энергия от нестационарных установок
Engineering: portable energyУниверсальный русско-английский словарь > энергия от нестационарных установок
-
6 энергия от передвижных установок
Engineering: portable energyУниверсальный русско-английский словарь > энергия от передвижных установок
-
7 нестационарные установки для выработки энергии
Engineering: (передвижные) portable energyУниверсальный русско-английский словарь > нестационарные установки для выработки энергии
-
8 переносной анализатор возмущений мощности и энергии
переносной анализатор возмущений мощности и энергии
—
[А.С.Гольдберг. Англо-русский энергетический словарь. 2006 г.]Тематики
EN
Русско-английский словарь нормативно-технической терминологии > переносной анализатор возмущений мощности и энергии
-
9 Perry, John
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering[br]b. 14 February 1850 Garvagh, Co. Londonderry, Ireland (now Northern Ireland)d. 4 August 1920 London, England[br]Irish engineer, mathematician and technical-education pioneer.[br]Educated at Queens College, Belfast, Perry became Physics Master at Clifton College in 1870 until 1874. This was followed by a brief period of study under Sir William Thomson in Glasgow. He was then appointed Professor of Engineering at the Imperial College of Japan in Tokyo, where he formed a remarkable research partnership with W.E. Ayrton. On his return to England he became Professor of Engineering and Mathematics at City and Guilds College, Finsbury. Perry was the co-inventor with Ayrton of many electrical measuring instruments between 1880 and 1890, including an energy meter incorporating pendulum clocks and the first practicable portable ammeter and voltmeter, the latter being extensively used until superseded by instruments of greater accuracy. An optical indicator for high-speed steam engines was among Perry's many patents. Having made a notable contribution to education, particularly in the teaching of mathematics, he turned his attention in the latter period of his life to the improvement of the gyrostatic compass.[br]Principal Honours and DistinctionsFRS 1885. President, Institution of Electrical Engineers 1900. Whitworth Scholar 1870.Bibliography28 April 1883, jointly with Ayrton, British patent no. 2,156 (portable ammeter and voltmeter).1900, England's Neglect of Science, London (for Perry's collected papers on technical education).Further ReadingObituary, 1920, Journal of the Institution of Electrical Engineers 58:901–2.D.W.Jordan, 1985, "The cry for useless knowledge: education for a new Victorian technology", Proceedings of the Institution of Electrical Engineers 132 (Part A): 587– 601.GW -
10 в отличие от
•Active current:alternating current that part in the phase with the voltage or the effective energy, as differentiated (or distinguished, or distinct) from the wattless or useless energy.
•The transistor is a current-controlled device as opposed to [or as distinct from, or in distinction to, or in contradistinction to, or in contrast to (or with), or as contrasted to, or unlike] the vacuum tube, which is a voltage-controlled device.
•The company has achieved a 200% increase in productivity by using the robot as opposed to manual servicing.
•The ultrasonic welding machine is semi-portable. By contrast, the resistance welder is a relatively cumbersome unit to move to a new location.
•Unlike copper windings, permanent magnets never wear out.
•These reactors are called light-water reactors to distinguish them from the type that uses heavy water.
•Contrary to the usual practice of...
•Sediments deposited by contour currents are called contourites, to set them apart from turbidites.
* * *В отличие от -- as opposed to, as contrasted to, as contrasted with; in contrast with, in contrast to; as distinct from, as distinguished from; unlike, unlike for; did not... as did, had not ... as had (британская конструкция)Most fine-pitch gears are used to transmit motion as opposed to the transmission of power. (В отличие от силовых передач большинство...)This possible separation regime appears to be of the ordinary type ( as contrasted to singular separation).Corrosion is brought about through chemical or electrochemical action, as contrasted with erosion caused by mechanical action.In contrast with the thicker inlet boundary layer, there is a pronounced thinning of the layer across the rotor.Also in contrast to the torsion mode, the critical phase angle always represented a backward wave.In this context the term "flooded bearing" becomes akin to "pressurized" bearing as distinct from Mr. G.'s classification where "flooded" is associated with bearings having no supply flow rate.The simplified turbine acceptance test, as distinguished from the full ASME turbine acceptance test, measures feedwater flow directly.Another advantage is that, unlike thermocouples, all components of this system including sensors are reusable.Unlike for torsion, the critical phase angle for the bending modes varied with sweep.Two weeks float is currently shown for these facilities compared to the rest of the 1A topside facilities (... показан двухнедельный плавающий срок...)Русско-английский научно-технический словарь переводчика > в отличие от
-
11 в отличие от
•Active current:alternating current that part in the phase with the voltage or the effective energy, as differentiated (or distinguished, or distinct) from the wattless or useless energy.
•The transistor is a current-controlled device as opposed to [or as distinct from, or in distinction to, or in contradistinction to, or in contrast to (or with), or as contrasted to, or unlike] the vacuum tube, which is a voltage-controlled device.
•The company has achieved a 200% increase in productivity by using the robot as opposed to manual servicing.
•The ultrasonic welding machine is semi-portable. By contrast, the resistance welder is a relatively cumbersome unit to move to a new location.
•Unlike copper windings, permanent magnets never wear out.
•These reactors are called light-water reactors to distinguish them from the type that uses heavy water.
•Contrary to the usual practice of...
•Sediments deposited by contour currents are called contourites, to set them apart from turbidites.
Русско-английский научно-технический словарь переводчика > в отличие от
-
12 контейнер
1) General subject: carrier (для транспортировки радиоактивных веществ), case, casket (для радиоактивных материалов), container, lighter, package, pannier (с обеих сторон велосипеда или мотоцикла), skip3) Military: (складской) bin, box, cartridge, hopper, pack, (подвесной) pod, shelter, shelter (для оборудования), tank4) Engineering: canister, cartridge, cask (для ядерного топлива), casket (для ядерного топлива), coffin (для транспортировки радиоактивных веществ), filling chest, holder, repository, storage box (для катушки с видеолентой), vessel (для жидкостей или газов), steel building5) Agriculture: bin filler, pallet, pan6) Construction: refrigerated container (для образцов мёрзлого грунта), transport box, transport container7) Railway term: sling van8) Automobile industry: lift van, package (с радиоаппаратурой)9) Cinema: bin10) Forestry: jar12) Oil: pod13) Immunology: bag14) Special term: castle15) Astronautics: capsule, cocoon, locker, matrix, strongback16) Food industry: portable bin17) Silicates: van18) Mechanics: crate19) Ecology: receptacle, refuse receptacle20) Business: magazine21) Crystallography: crucible22) Sakhalin energy glossary: aerated container23) Solar energy: container device25) Programming: container format26) Automation: cassette27) Nuclear physics: rabbit28) Chemical weapons: one-ton containers (на 1 тонну)29) Aviation medicine: capsula, capsule( герметическая)30) Makarov: basket31) SAP.tech. container instance32) Logistics: cargo transporter, CTN33) Electrical engineering: core flux test infrared camera -
13 автокран
1) General subject: cranmobile2) Engineering: autocrane, automotive-type crane, breakdown truck, lorry-mounted crane, truck crane, truck-mounted crane3) Automobile industry: breakdown lorry, crane truck, lorry crane4) Forestry: automatic crane, automobile crane5) Astronautics: portable crane, rubber-wheeled crane, self-propelled rubber-wheel crane6) Sakhalin energy glossary: boom truck, rubber tire hydraulic crane7) Automation: motorized crane, truck( loaded) crane8) oil&gas: mobile crane -
14 жилой вагончик
1) General subject: portable cabin2) Oil: portacabin (cement*портландцемент)3) Sakhalin energy glossary: portacabin -
15 передвижная установка для приготовления сухих тампонажных смесей
Sakhalin energy glossary: portable bulk plantУниверсальный русско-английский словарь > передвижная установка для приготовления сухих тампонажных смесей
-
16 переносной пенный огнетушитель с СПП
Sakhalin energy glossary: AFFF portable fire extinguisherУниверсальный русско-английский словарь > переносной пенный огнетушитель с СПП
-
17 подвижный
1) General subject: agile, flexible, flexile, fluid, fly, interjetic, kinetic, light limbed, light on ( one's) feet, light-limbed, lightsome, long limbed, long-limbed, mercurial, mobile, nimble, quicksilver, spry, tittupy, versatile, volant, fast-paced2) Biology: motile3) Zoology: errant4) Medicine: floating, labile (функционально), wandering5) Colloquial: corky, dapper, pacey, quick of foot, tittuppy6) Dialect: wick7) American: kicky (о ребёнке и т.п.)8) Obsolete: quiver10) Military: light, mobile-based, mobile-loaded12) Chemistry: fluent14) Railway term: running15) Law: maneuverable16) Accounting: resilient (о рабочей силе)17) Automobile industry: movable18) Mining: manoeuvreable19) Forestry: assimilable, available( of nutrients)20) Metallurgy: transportable21) Oil: moveable22) Astronautics: trainable23) Atomic energy: nonfixed24) Metrology: traveling (например, о микроскопе), travelling (например, о микроскопе)26) Business: changeable, manoeuvrable27) Drilling: pumpable28) Polymers: nonstationary29) Arms production: portable30) Wood cutting: revolving31) Makarov: adjustable, free, free to move, live, moving (напр. о песке, дюне), moving (напр., о песке, дюне), shifting (о деталях приборов и установок), traveling, travelling, variable32) Hi-Fi. agile (описание характера звучания баса, отличающегося способностью к передаче быстрых тональных и динамических контрастов) -
18 портативное зарядное устройство аккумулятора
Solar energy: portable battery chargerУниверсальный русско-английский словарь > портативное зарядное устройство аккумулятора
-
19 Coolidge, William David
[br]b. 23 October 1873 Hudson, Massachusetts, USAd. 3 February 1975 New York, USA[br]American physicist and metallurgist who invented a method of producing ductile tungsten wire for electric lamps.[br]Coolidge obtained his BS from the Massachusetts Institute of Technology (MIT) in 1896, and his PhD (physics) from the University of Leipzig in 1899. He was appointed Assistant Professor of Physics at MIT in 1904, and in 1905 he joined the staff of the General Electric Company's research laboratory at Schenectady. In 1905 Schenectady was trying to make tungsten-filament lamps to counter the competition of the tantalum-filament lamps then being produced by their German rival Siemens. The first tungsten lamps made by Just and Hanaman in Vienna in 1904 had been too fragile for general use. Coolidge and his life-long collaborator, Colin G. Fink, succeeded in 1910 by hot-working directly dense sintered tungsten compacts into wire. This success was the result of a flash of insight by Coolidge, who first perceived that fully recrystallized tungsten wire was always brittle and that only partially work-hardened wire retained a measure of ductility. This grasped, a process was developed which induced ductility into the wire by hot-working at temperatures below those required for full recrystallization, so that an elongated fibrous grain structure was progressively developed. Sintered tungsten ingots were swaged to bar at temperatures around 1,500°C and at the end of the process ductile tungsten filament wire was drawn through diamond dies around 550°C. This process allowed General Electric to dominate the world lamp market. Tungsten lamps consumed only one-third the energy of carbon lamps, and for the first time the cost of electric lighting was reduced to that of gas. Between 1911 and 1914, manufacturing licences for the General Electric patents had been granted for most of the developed work. The validity of the General Electric monopoly was bitterly contested, though in all the litigation that followed, Coolidge's fibering principle was upheld. Commercial arrangements between General Electric and European producers such as Siemens led to the name "Osram" being commonly applied to any lamp with a drawn tungsten filament. In 1910 Coolidge patented the use of thoria as a particular additive that greatly improved the high-temperature strength of tungsten filaments. From this development sprang the technique of "dispersion strengthening", still being widely used in the development of high-temperature alloys in the 1990s. In 1913 Coolidge introduced the first controllable hot-cathode X-ray tube, which had a tungsten target and operated in vacuo rather than in a gaseous atmosphere. With this equipment, medical radiography could for the first time be safely practised on a routine basis. During the First World War, Coolidge developed portable X-ray units for use in field hospitals, and between the First and Second World Wars he introduced between 1 and 2 million X-ray machines for cancer treatment and for industrial radiography. He became Director of the Schenectady laboratory in 1932, and from 1940 until 1944 he was Vice-President and Director of Research. After retirement he was retained as an X-ray consultant, and in this capacity he attended the Bikini atom bomb trials in 1946. Throughout the Second World War he was a member of the National Defence Research Committee.[br]Bibliography1965, "The development of ductile tungsten", Sorby Centennial Symposium on the History of Metallurgy, AIME Metallurgy Society Conference, Vol. 27, ed. Cyril Stanley Smith, Gordon and Breach, pp. 443–9.Further ReadingD.J.Jones and A.Prince, 1985, "Tungsten and high density alloys", Journal of the Historical Metallurgy Society 19(1):72–84.ASDBiographical history of technology > Coolidge, William David
См. также в других словарях:
Energy storage — is the storing of some form of energy that can be drawn upon at a later time to perform some useful operation. A device that stores energy is sometimes called an accumulator. All forms of energy are either potential energy (eg. chemical,… … Wikipedia
Energy policy — is the manner in which a given entity (often governmental) has decided to address issues of energy development including energy production, distribution and consumption. The attributes of energy policy may include legislation, international… … Wikipedia
Portable electric heater — A heater that uses electricity and that can be picked up and moved. U.S. Dept. of Energy, Energy Information Administration s Energy Glossary … Energy terms
Portable fan — Box fans, oscillating fans, table or floor fans, or other fans that can be moved. U.S. Dept. of Energy, Energy Information Administration s Energy Glossary … Energy terms
Portable kerosene heater — A heater that uses kerosene and that can be picked up and moved. U.S. Dept. of Energy, Energy Information Administration s Energy Glossary … Energy terms
Energy (society) — The use of energy has been a key in the development of the human society by helping it to control and adapt to the environment. Managing the use of energy is inevitable in any functional society. In the industrialized world the development of… … Wikipedia
Portable sawmill — Portable sawmills became popular in the United States starting in the 1970s, when the 1973 energy crisis and the back to the land movement had led to renewed interest in small woodlots and in self sufficiency. History Prior to the advent of the… … Wikipedia
Energy drink — Energy drinks are beverages whose producers advertise that they boost energy. These advertisements usually do not emphasize energy derived from the sugar and caffeine they contain[1] but rather increased energy release due to a variety of… … Wikipedia
Energy density — For energy density in the sense of energy per unit mass, see specific energy. For energy density of foods, see specific energy. Energy density is a term used for the amount of energy stored in a given system or region of space per unit volume.… … Wikipedia
Portable stove — A Portable stove is a stove specially designed to be portable and lightweight, as for camping.The division of portable stoves into several broad categories is based on the type of fuel used in the stove: stoves that use solid or liquid fuel that… … Wikipedia
Grid energy storage — is used to manage the flow of electrical energy. For large scale load levelling on an interconnected electrical system, electric energy producers send low value off peak excess electricity over the electricity transmission grid to temporary… … Wikipedia