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1 Precision Engine Parts
Trademark term: PEPУниверсальный русско-английский словарь > Precision Engine Parts
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2 Reichenbach, Georg Friedrich von
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering, Photography, film and optics, Public utilities[br]b. 24 August 1772 Durlach, Baden, Germanyd. 21 May 1826 Munich, Germany[br]German engineer.[br]While he was attending the Military School at Mannheim, Reichenbach drew attention to himself due to the mathematical instruments that he had designed. On the recommendation of Count Rumford in Munich, the Bavarian government financed a two-year stay in Britain so that Reichenbach could become acquainted with modern mechanical engineering. He returned to Mannheim in 1793, and during the Napoleonic Wars he was involved in the manufacture of arms. In Munich, where he was in the service of the Bavarian state from 1796, he started producing precision instruments in his own time. His basic invention was the design of a dividing machine for circles, produced at the end of the eighteenth century. The astronomic and geodetic instruments he produced excelled all the others for their precision. His telescopes in particular, being perfect in use and of solid construction, soon brought him an international reputation. They were manufactured at the MathematicMechanical Institute, which he had jointly founded with Joseph Utzschneider and Joseph Liebherr in 1804 and which became a renowned training establishment. The glasses and lenses were produced by Joseph Fraunhofer who joined the company in 1807.In the same year he was put in charge of the technical reorganization of the salt-works at Reichenhall. After he had finished the brine-transport line from Reichenhall to Traunstein in 1810, he started on the one from Berchtesgaden to Reichenhall which was an extremely difficult task because of the mountainous area that had to be crossed. As water was the only source of energy available he decided to use water-column engines for pumping the brine in the pipes of both lines. Such devices had been in use for pumping purposes in different mining areas since the middle of the eighteenth century. Reichenbach knew about the one constructed by Joseph Karl Hell in Slovakia, which in principle had just been a simple piston-pump driven by water which did not work satisfactorily. Instead he constructed a really effective double-action water-column engine; this was a short time after Richard Trevithick had constructed a similar machine in England. For the second line he improved the system and built a single-action pump. All the parts of it were made of metal, which made them easy to produce, and the pumps proved to be extremely reliable, working for over 100 years.At the official opening of the line in 1817 the Bavarian king rewarded him generously. He remained in the state's service, becoming head of the department for roads and waterways in 1820, and he contributed to the development of Bavarian industry as well as the public infrastructure in many ways as a result of his mechanical skill and his innovative engineering mind.[br]Further ReadingBauernfeind, "Georg von Reichenbach" Allgemeine deutsche Biographie 27:656–67 (a reliable nineteenth-century account).W.Dyck, 1912, Georg v. Reichenbach, Munich.K.Matschoss, 1941, Grosse Ingenieure, Munich and Berlin, 3rd edn. 121–32 (a concise description of his achievements in the development of optical instruments and engineering).WKBiographical history of technology > Reichenbach, Georg Friedrich von
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3 использовать
. воспользоваться; максимально использовать; можно использовать; наиболее эффективно использовать; пользоваться; применять; широко использовать•Advantage is taken of this fact in some turbojet engines.
•Unique processes and equipment have been successfully applied in the mining and refining of potash salts.
•The great majority of amplifiers are electronic and depend (or rely) upon transistors and chips for their operation.
•These projects can draw on the data from five tests.
•The new relay employs three sets of contacts.
•To harness atomic energy for peaceful uses,...
•This reaction may be harnessed to perform work.
•The power unit makes use of a standard electric starter.
•These vehicles rely on ambient air as a source of oxygen.
•This nonreciprocity has as yet not been turned to useful account in antennas.
•At present, these laboratories are being utilized to test timbers.
•Such high precision makes it possible to employ (or use, or utilize) laser radiation as a primary standard of length and time.
•With electricity farmers could run useful devices of all kinds.
•This offers the possibility of putting hydrides to work in heat pumps.
•These techniques take advantage of the laser's high spectral intensity.
•Lasers are exploited to heat plasmas with short pulses of light.
•Double-break or multibreak devices can exploit this effect even at higher voltages.
•The author's suggestions were picked up by the Japanese who ran some preliminary tests on eleven pure elements.
•The steam from a dry field can be put to use() other than power production.
•The newest accelerators exploit the same fundamental principles as the first ones.
•Simplifying assumptions have been invoked to separate the two processes for individual study.
•If this natural gas can be tapped, there would be a tremendous source of fuel.
II•When all the even (or odd) integers are used up, there will still be half the series...
* * *Использовать -- to use, to utilize, to apply, to employ, to exploit; to make use of; to draw on (с оттенком заимствования); to rely on (полагаться на)Under these circumstances, we can employ the data from this experiment to establish limits for heat fluxes.These diffusers exploit the centrifugal forces acting on a swirling throughflow to enhance mixing and combustion.Each engine will be provided with a control unit which makes use of modern electronic techniques (... в котором используется...).Two independent methods were applied to eliminate any possible error in fringe order determination.The work of L. [...] was drawn on for the design of turbine blades.However, the theoretical magnitude is far from correct and we must rely on experimental values for the coefficient C.Русско-английский научно-технический словарь переводчика > использовать
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4 прибор
instrument
(измерительный, регистрирующий, вычислительный)
- (указатель) — indicator
- (устройство) — unit
- автономный — independent instrument
- анероидно-манометрический — pressure instrument
- анероидный-мембранный — pressure instrument
-, анероидный — barometric instrument
-, бытовой — furnishing unit
- визуального отсчета — direct-reading instrument
an ohmmeter is a directreading instrument for measuring electric resistance.
-, девиационный — compass compensator
приспособление для компенсации магнитной девиации магнитного компаса — а device for compensating a magnetic compass.
-, директорный (рис. 72) — flight director indicator (fdi)
-, директорный (захода на посадку) — approach horizon
-, дистанционный — remote-reading indicator
- для измерения тока, напряжения и сопротивления, универсальный (авометр) — avorneter
- для выявления утечки газа — gas leak detector
- для измерения валичины сноса — drift meter
- для определения состояния среды (кислотный или щелочной раствор) — рн-meter
- для проверки герметизации кабины — cabin pressure test unit
-, дублирующий — duplicate instrument
-, измерительный — measuring instrument
- измерительный, дифференциальный (манометр) — differential pressure gauge
-, измерительный, пневматический (манометрического или ротаметричесного типа) — pneumatic /air/ gauge. device used to perform dimensional or functional comparisons by indicating the escapement of air between the air jets and the workpiece.
-, измерительный, работающий на принципе противодавления, пневматический — back-pressure air gauge. uses constant air pressure passing through a controlling orifice (of predetermined or adjustable size) and into the gaging element or tooling.
-, измерительный водяной (с водяным манометром) — water-column gauge
-, индикаторный часового типа (для замера отклонений от заданного размера, или радиальных люфтов) — dial test indicator (d.t.l.). d.t.l. or clock gage is used not for measuring the actual size but to indicate small differences in size, or for indicating the amount of eccentricity of revolving parts.
- (индиматорный), показывающий "натяг" — d.t. indicator (needle or pointer) indicating on the plus side (of the dial)
-' (индикаторный), показывающий заниженный размер — d.t. indicator (needle or pointer) indicating on the minus side (of the dial)
совмещать нулевое деление индикаторного п. со стрелкой. — set the dial zero under the pointer (by turning the bezel).
- индикации пространственного положения самолета — attitude indicator
-, интегрирующий измерительный — integrating measuring instrument
-, кислородный (общий термин) — oxygen apparatus /set/
-, кислородный (кп, регулятор) — oxygen (flow) regulator
устройство, регулирующее подачу кислорода к кислородной маске, — masks are designed for use with remotely located oxygen flow regulator.
-, кислородный, для оказания первой помощи (пассажирам) — first aid oxygen cylinder
-, кислородный жидкостный (кпж) — liquid oxygen converter
-, кислородный, индивидуального пользования — individual oxygen regulator
-, кислородный, парашютный (кп-23) — bailout /parachute/ oxygen apparatus
-, кислородный переносной (kп-19, kп-21) — portable oxygen cylinder (with regulator)
- кислородный, переносной (для бортпроводников и оказания первой помощи пассажирам) — cabin walkaround oxygen cylinder (with regulator and mask)
-, кислородный с подсосом воздуха — diluter demand oxygen regulator
-, кислородный (типа легочный автомат) — demand oxygen regulator
-, командно-пилотажный (кпп) (рис. 70) — flight director indicator (fdi), attitude director indicator
-, командный (нуль-прибор) — zero-reader flight director indicator, ils cross-pointer indicator
-, командный (пульт) — controller
-, командный пилотажный (кпп) — flight director indicator
-, комбинированный — combination /combined/ indicator
-, комбинированный (да-зо вариометр, указатель поворота и скольжения) — rate of climb and turn indicator (turn & climb ind)
-, комбинированный (поверочный типа ц4315 - ампервольтметр) — avometer
-, контрольно-поверочный (входящий в кпу) — tester
-, контрольный (эталонный) — reference instrument
- контроля нагрузки на шину no 1 кабин — cabin bus i load monitor
- контроля работы двигателя — engine instrument
-, курсовой счетно-решающий — course-line computer (clc)
- курсовой системы, комбинированный — flight compass
- легочно-автоматического типа, кислородный — automatic (pressure breathing) demand (-type) oxygen regulator, demand (-type) oxygen regulator
- легочно-автоматического типa с подсосом воздуха, кислородный — automatic (pressure breathing) diluter-demand oxygen regulator
-, манометрический — pressure measuring instrument
- мембранно-анероидный — pressure instrument
-, навигационна-пилотажный (общий термин) — flight-navigation instrument
-, навигационно-пилотажный (пo терминологии икао и фирмы коплинз) — track indicator (icao definition), course indicator (collins trade name)
-, навигационно-пилотажный (hпп) — horizontal situation indicator
индикация (угла) курса, кур. курса на крм, и глиссады. сигнапизация о входе в зону уверенного приема наземных маяков. сигнапы отклонения от зк в вычислитель сду (рис. 71). — the hsi presents aircraft displacement relative to vor radials and loc and gs beams, and heading references to either true or magnetic north.
-, навигационный комбинированный с индикацией сп (посадки по приборам) — flight compass
-, навигационный курсовой (нкп) (директорией системы) — course /track/ indicator, course deviation indicator (cdi)
-, переносный кислородный — walkaround oxygen cylinder
-, пилотажно-навигационный (общий термин) — flight-navigation instrument
каждый навигационно-пилотажный прибор должен быть хорошо виден летчику с его рабочего места. — each flight and navigation instrument for use by any pilot must be plainly visible to him from his station
-, пилотажный — flight instrument
приборы, служащие для индниации высоты, положения в пространстве, скорости, сноса и направления полета. — any aircraft instrument that indicates altitude, attitude, aispeed, drift and direction of an aircraft.
- пилотажный, командный (пкп) — flight director indicator (fdi), attitude director indicator (adi)
для индикации положения самолета в пространстве и выдачи командных сигналов пo курсу (крену) и тангажу (рис. 72). — the flight director (pd) indicater displays aircraft attitude and command information to achieve and maintain a desired flight profile.
-, пилотажный, электронно-лучевой — electronic flight instrument
-, плановый навигационный (пнп) — course /track/ indicator, horizontal situation indicator (hsi)
обеспечивает индикацию курса и путевого угла. имеет счетчики дальности и заданного путевого угла, указатели (планки) отклонения от курса и глиссады (рис. 73). — course indicator provides a plan view of aircraft horizontal navigation situation relative to enroute or terminal navigation aids. the course indicator displays aircraft position and heading with respect to the compass and selected heading. slant range (nautical miles) to a selected dme station, digital course readout, lateral deviation from a selected vor or loc course, and vertical deviation from the center of the glideslope are also displayed.
-, полупроводниковый (элемент) — semiconductor device. varistor is a two-electrode simiconductor device.
-, профильный (индикатор) — vertical scale indicator
-, профильный (прибор с вертикальной ленточной шкалой) (рис. 69) — vertical tape instrument /indicater/. vertical tape instruments is a trend away from conventional dial-and-pointer instruments.
- раскрытия парашюта — parachute release actuator /mechanism/
-, регистрирующий — recorder
- с вертикальной шкалой (в отличие от циферблатного) — vertical scale instrument /indicator/
- с вертикальной ленточной шкалой — vertical tape instrument /indicator/
-, сдвоенный — dual indicator
- слепой посадки (псп, директорный с крестообразными стрелками) (рис. 69) — ils cross-pointer indicator, zero-reader flight director indicator
- с непрерывной подачей, кислородный — continuous flow oxygen regulater
- с подвижной рамкой (измерительный, электрический) — moving-coil instrument
- с подсосом воздуха, кислородный — diluter demand oxygen regulator
-, стрелочный (циферблатный) — dial-and-pointer instrument /indicator/
-, счетно-решающий (срп) — computer (cmptr)
-, точный — precision instrument
- фотоаппарата, командный — camera controller
-, фотоконтрольный (фкп) — recording camera
-, фотоконтрольный, резупьтатов бомбометания — bomb strike camera
-, фотоконтропьный, резупьтатов стрельбы — camera gun
-, электроизмерительный — electric measuring instrument
-, эталонный — reference instrument.
отсчет по (показание) п. — instrument reading /display/
ошибка (погрешность) п. — instrument error
по п., по показаниям п. — by the instrument, as read on /from/ the instrument, as indicated (or displayed) on the instrument
задавать к-л. величину по прибору — select (value) with reference to /referring to/ indicator
наблюдать за показаниями п. — observe the instrument reading
отмечать показания п. — note the instrument readings
отсчитывать показания п. — read the instrument
устанавливать п. с задней стороны панели — install the instrument from back of the instrument panelРусско-английский сборник авиационно-технических терминов > прибор
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