twin engines

twin engines

twin engines спаренныйnмотор

twin engines

спаренный мотор

coupled engines — спаренные двигатели

twin engines

спаренныйnмотор

twin engines

Военный термин: спаренные двигатели

twin engines

pl

zwei Motoren pl

twin engines

• двуреден двигател

twin engines

n pl

MECH ENG motores gemelos m pl

twin

1

twin-engined

2 n

C&G gemelo m

CRYSTALL, METALL macla f

twin-axial cable

twin-bagging system

twin-barreled carburetor

twin-barrelled carburettor

twin boundary

twin cable

twin carburetor

twin carburettor

twin cards

twin-choke carburetor

twin-choke carburettor

twin cock

twin-cylinder engine

twin ends

twin engine

twin-engine jet aircraft

twin engines

twin formation

twin grinder

twin-ground plate

twin-hull ship

twin interlaced scanning

twin-jet injection nozzle

twin lamella

twin-lens reflex

twin-lens reflex camera

twin-line brake

twin magazine

twin pack

twin paradox

twin-piston engine

twin pole

twin polisher

twin polishing

twin post

twin projectors

twin-reactor station

twin-ribbon cable

twin-rotor helicopter

twin-screw lathe

twin-screw steamer

twin-spindle lathe

twin-stream collator

twin-tail unit

twin wheels

twin-wire board machine

twin-wire paper machine

twin-T network

twin

twin

noun

1) (one of two children or animals born of the same mother at the same time: She gave birth to twins; (also adjective) They have twin daughters.) gemelo

2) (one of two similar or identical things: Her dress is the exact twin of mine.) copia

twin n gemelo / mellizo

twin

tr[twɪn]

noun

1 gemelo,-a, mellizo,-a

adjective

1 gemelo,-a, mellizo,-a

transitive verb (pt & pp twinned, ger twinning)

1 hermanar

■ Cambridge is twinned with Heidelberg Cambridge está hermanada con Heidelberg

\

SMALLIDIOMATIC EXPRESSION/SMALL

twin bed cama gemela

twin set conjunto de jersey y chaqueta

twin town ciudad nombre femenino hermanada

twin ['twɪn] adj

: gemelo, mellizo

twin n

: gemelo m, -la f; mellizo m, -za f

twin

adj.

• gemelo, -a adj.

n.

• gemelo s.m.

• hermano s.m.

I twɪn

noun mellizo, -za m,f, gemelo, -la m,f (esp Esp); [in Latin America gemelo tends to be used to refer to an identical twin] cuate mf (Méx)

identical twins — gemelos idénticos or (téc) univitelinos, gemelos (AmL)

II

adjective

a) <brother/sister> mellizo, gemelo (esp Esp); see twin I

b) ( paired)

the twin evils of poverty and violence — la pobreza y la violencia, dos males que siempre van de la mano

twin beds — camas fpl gemelas

twin town — ciudad f hermana

III

transitive verb - nn- (BrE) (usu pass)

to be twinned WITH something — estar* hermanado con algo

[twɪn]

1.

N (identical) gemelo(-a) m / f ; (non-identical) mellizo(-a) m / f

they are twins — son gemelos, son mellizos

a pair of twins — un par de gemelos, un par de mellizos

identical, Siamese

2. ADJ

1) [brother, sister] (identical) gemelo; (non-identical) mellizo

she has twin daughters — tiene dos hijas gemelas, tiene dos hijas mellizas

2) (=linked) [town, city] hermano

Newlyn's twin town is Concarneau — la ciudad hermana de Newlyn es Concarneau, Newlyn está hermanada con Concarneau

3) (=double) [towers, peaks, engines] gemelo; [propellers] doble; [concepts] hermano

the twin aims or goals of sth — el doble objetivo de algo

the twin evils of malnutrition and disease — la malnutrición y la enfermedad, dos males que siempre van juntos

the twin pillars of — (fig) el doble pilar de

twin souls — almas fpl gemelas

3. VT

1) (=link) [+ towns, cities, institutions] hermanar ( with con)

Manchester is twinned with St Petersburg — Manchester está hermanada con San Petersburgo

2) (=combine) [+ clothes] combinar

4.

CPD

twin beds NPL — camas fpl gemelas

twin city N — (Brit) ciudad f hermana or hermanada

twin cylinder N — bicilindro m

twin-cylinder

twin jet N — birreactor m

twin-jet

twin town N — (Brit) ciudad f hermana or hermanada

* * *

I [twɪn]

noun mellizo, -za m,f, gemelo, -la m,f (esp Esp); [in Latin America gemelo tends to be used to refer to an identical twin] cuate mf (Méx)

identical twins — gemelos idénticos or (téc) univitelinos, gemelos (AmL)

II

adjective

a) <brother/sister> mellizo, gemelo (esp Esp); see twin I

b) ( paired)

the twin evils of poverty and violence — la pobreza y la violencia, dos males que siempre van de la mano

twin beds — camas fpl gemelas

twin town — ciudad f hermana

III

transitive verb - nn- (BrE) (usu pass)

to be twinned WITH something — estar* hermanado con algo

twin independent variable cam timing

авто двойная независимая регулируемая установка фаз клапанного распределения (угла впрыска)*

These lightweight, all-aluminium Ford EcoBoost engines combine three technologies - a centrally-mounted high-pressure direct injection system, low-inertia turbocharging and twin independent variable cam timing to create an advanced combustion system which brings new levels of performance and fuel efficiency to petrol engines in this power range. — Эти облегчённые, полностью алюминиевые двигатели Ford EcoBoost комбинируют три технологии — центрально установленную систему прямого впрыска под высоким давлением, низкоинерционный турбонаддув и двойную независимую регулируемую установку фаз клапанного распределения (угла впрыска), чтобы создать продвинутую систему сгорания, которая дает бензиновым двигателям этого диапазона мощностей новые уровни производительности и топливной экономичности.

twin independent variable camshaft timing

авто двойная независимая регулируемая установка фаз клапанного распределения (угла впрыска)*

These lightweight, all-aluminium Ford EcoBoost engines combine three technologies - a centrally-mounted high-pressure direct injection system, low-inertia turbocharging and twin independent variable cam timing to create an advanced combustion system which brings new levels of performance and fuel efficiency to petrol engines in this power range. — Эти облегчённые, полностью алюминиевые двигатели Ford EcoBoost комбинируют три технологии — центрально установленную систему прямого впрыска под высоким давлением, низкоинерционный турбонаддув и двойную независимую регулируемую установку фаз клапанного распределения (угла впрыска), чтобы создать продвинутую систему сгорания, которая дает бензиновым двигателям этого диапазона мощностей новые уровни производительности и топливной экономичности.

twin-crankshaft engines

• двигател с два колянови вала

спаренный мотор

twin engines

engine

двигатель; мотор; машина

bank into the dead engine — накреняться в сторону неработающего двигателя

bring the engine up to full power — выводить двигатель на режим полной тяги

buzz up an engine — жарг. запускать двигатель

clean the engine — прогазовывать [прочищать] двигатель (кратковременной даней газа)

close down the engine — полностью убирать газ

continuous flow gas turbine engine — двигатель с осевым компрессором

engine engine in military — двигатель на боевом режиме

engine of bypass ratio 10: 1 — двигатель с коэффициентом [степенью] двухконтурности 10:1

equivalent engine in parts — комплект деталей для одного двигателя

flight discarded jet engine — реактивный двигатель, отработавший лётный ресурс

fluorine(-propel lant rocket) engine — ЖРД на жидком фторе

kick the engine over — разг. запускать двигатель

knock out the engine — выводить двигатель из строя

liquid-hydrogen(-fueled) rocket engine — водородный ЖРД

lunar module ascent engine — подъёмный двигатель лунного модуля [отсека]

monofuel rocket engine — ЖРД на однокомпонентном [унитарном] топливе

multibarreled rocket engine — многокамерный ЖРД

open the engine up — давать газ, увеличивать тягу или мощность двигателя

prepackaged liquid propellant engine — ЖРД на топливе длительного хранения; заранее снаряжаемый ЖРД

production(-standard, -type) engine — серийный двигатель, двигатель серийного образца [типа]

pull the engine out of afterburner — выключать форсаж

rear fuselage (mounted) engine — двигатель в хвостовой части фюзеляжа

return and landing engine — ксм. двигатель для возвращения и посадки

reversed rocket engine — тормозной ракетный двигатель; ксм. тормозная двигательная установка

run up the engine — опробовать [«гонять»] двигатель

secure the engine — выключать [останавливать, глушить] двигатель

shut down the engine — выключать [останавливать, глушить] двигатель

shut off the engine — выключать [останавливать, глушить] двигатель

solid(-fuel, -grain) rocket engine — ракетный двигатель твёрдого топлива

stability guidance jet engine — двигатель реактивной системы стабилизации и управления

throttle back the engine — (за)дросселировать двигатель

turn the engine over — проворачивать [прокручивать] двигатель [вал двигателя]

twin-spool compressor turbojet engine — ТРД с двухкаскадным компрессором

two-thrust chamber rocket engine — двухкамерный ЖРД

with one engine cut — с одним неработающим двигателем

with one engine out — с одним неработающим двигателем

with the engine running — с работающим двигателем

with two engines lost — при двух отказавших двигателях

— ablation-protected engine

— ablative engine

— abort engine

— accelerating rocket engine

— acid-cooled rocket engine

— actual engine

— adjustable-thrust rocket engine

— aerojet engine

— aeropulse engine

— aerothermodynamic integration engine

— afterburning engine

— aft-fan engine

— ailing engine

— air engine

— airborne rocket engine

— air-breathing engine

— air-burning engine

— air-collection engine

— air-feed engine

— air-jet engine

— airline engine

— airplane engine

— airstream engine

— alcohol engine

— all-attitude engine

— all-fuel engine

— ancillary engine

— annihilation rocket engine

— antispin rocket engine

— apogee engine

— arcjet engine

— arresting engine

— ascent engine

— assist-climb rocket engine

— assisted takeoff engine

— atmospheric jet engine

— attitude-control engine

— augmented turbofan engine

— auxiliary rocket engine

— axial engine

— axial-centrifugal-flow engine

— axial-flow engine

— bare engine

— barrel engine

— basic engine

— below-wing engine

— bench engine

— bifuel rocket engine

— bipropellant rocket engine

— bleedoff rocket engine

— block-cast engine

— booster engine

— bottom engine

— brake engine

— braking engine

— buried engine

— burned engine

— bypass engine

— calibrated engine

— calibrated-thrust engine

— capacitative-cooled engine

— capsular engine

— carburetted engine

— carburettor engine

— center engine

— centrifugal-flow engine

— ceramic-coated engine

— cesium-ion engine

— chemical fuel engine

— chemical-ignition engine

— cigarette-burning rocket engine

— clear the engine

— closed-cycle engine

— clustered engine

— coaxial plasma engine

— cold engine

— cold-jet engine

— cold-reaction engine

— combustion engine

— composite engine

— compound engine

— compressorless engine

— conk-out engine

— constant-duty engine

— constant-speed engine

— constant-thrust engine

— control engine

— controllable-thrust engine

— cooled engine

— core engine

— coupled engines

— cowled engine

— critical engine

— cruise engine

— cruising engine

— cryogenic engine

— cut the engine

— dead engine

— deflected-thrust engine

— demonstrator engine

— deorbit engine

— descent engine

— development engine

— direct-drive engine

— direct-injection engine

— direct-lift engine

— disintegrating engine

— diverted-jet engine

— docking engine

— double-flow engine

— double-nozzled engine

— double-row engine

— double-unit engine

— down-rated engine

— downwind engine

— driving engine

— droppable engine

— dry engine

— dry-fuel rocket engine

— dry-sump engine

— dual function engine

— dual-chamber rocket engine

— dual-flow engine

— dual-thrust rocket engine

— ducted rocket engine

— ducted-fan engine

— duplex engine

— earth-satellite engine

— ejection-seat rocket engine

— ejector-seat rocket engine

— electrical rocket engine

— electric-ignition engine

— electromagnetic jet engine

— electrostatic rocket engine

— electrothermal jet engine

— end-burning rocket engine

— engine got sick

— engine out

— environmental engine

— escape rocket engine

— evaporative-cooled engine

— expendable engine

— expended engine

— explosive engine

— external engine

— external-burning engine

— failed engine

— fan engine

— fan-afterburner engine

— fan-burning jet engine

— fast-response rocket engine

— feathered engine

— film-cooled engine

— final-stage rocket engine

— finite-thrust engine

— finned-rocket engine

— first-stage engine

— fixed-geometry engine

— flame-ignition rocket engine

— flameout engine

— flat engine

— flat-rated engine

— flat-rating engine

— flight-cleared engine

— flight-qualified engine

— flight-type engine

— flightworthy engine

— flyable engine

— forced-induction engine

— forward-facing rocket engine

— forward-firing rocket engine

— forward-thrust jet engine

— four-chamber engine

— four-stroke engine

— free-turbine engine

— front-fan engine

— fuel-optimal engine

— full-scale engine

— full-sized engine

— fuselage-mounted engine

— gas-generator engine

— gasoline engine

— gas-pressurized rocket engine

— gas-turbine engine

— geared engine

— gearless engine

— good engine

— gun an engine

— healthy engine

— heat engine

— heat-sponge engine

— helicopter engine

— helium-injection engine

— high-bypass ratio engine

— high-compression-ratio engine

— higher-powered engine

— highly developed engine

— high-performance engine

— high-power engine

— high-pressure engine

— high-speed engine

— high-thrust engine

— high-time engine

— honeycomb engine

— horizontal-mounted engine

— hot engine

— hot peroxide engine

— hot-reaction rocket engine

— hybrid engine

— hybrid-propellant engine

— hydrazine engine

— hydrogen-burning engine

— hydrogen-electrothermal engine

— hydrogen-fluorine engine

— hydrogen-oxygen engine

— hydrogen-peroxide engine

— hydrojet engine

— hypergolic engine

— hypersonic engine

— hypothetical engine

— ideal-cycle engine

— idling engine

— ignite the engine

— impulse-duct engine

— impulse-rocket engine

— inboard engine

— inhibited engine

— injected engine

— in-line engine

— inoperative engine

— installed engine

— intermittent-cycle engine

— intermittent-detonation engine

— internal engine

— internal-combustion engine

— interplanetary engine

— inverted vee engine

— ionic engine

— ionospheric ramjet engine

— isentropic engine

— jato engine

— jet attitude engine

— jet-propulsion engine

— jet transport engine

— jet-control engine

— jet-lift engine

— jettison engine

— jumbo engine

— kerosene-burning engine

— kerosene-fueled engine

— kick engine

— kill the engine

— lander engine

— lateral-burning rocket engine

— launch vehicle engine

— launching rocket engine

— left-handed engine

— lift jet engine

— lift/propulsion engine

— lift/thrust engine

— lift-cruise engine

— liftoff engine

— lightweight engine

— limited-life engine

— limited-thrust engine

— liquid-air engine

— liquid-chemical rocket engine

— liquid-cooled engine

— liquid-fuelrocket engine

— liquid-oxygen rocket engine

— liquid-propellant rocket engine

— liquid-solid rocket engine

— liquid-sustainer engine

— live engine

— long-burning engine

— long-duration engine

— long-life engine

— long-period engine

— long-stroke engine

— low-altitude engine

— low-consumption engine

— lower-powered engine

— low-mounted engine

— low-noise-level engine

— low-performance engine

— low-pressure engine

— low-thrust engine

— lox/liquid hydrogen engine

— lunar engine

— lunar module engine

— lunar rover engine

— lunar-descent engine

— lunar-takeoff engine

— magnetic-pinch plasma engine

— magnetogasdynamie engine

— magnetohydrodynamic engine

— main engine

— main propulsion engine

— malfunctioning engine

— maneuvering engine

— master engine

— matched engine

— microrocket engine

— midcourse correction engine

— middle engine

— military engine

— missile engine

— modular engine

— monopropellant rocket engine

— monopropellant-plus-fuel engine

— movable engine

— multibank engine

— multichamber rocket engine

— multifuel engine

— multilift engines

— multiple engine

— multiple-beam ion engine

— multiple-chamber rocket engine

— multiple-nozzle engine

— multirow engine

— multi-unit rocket engine

— nacelle-mounted engine

— nameplate engine

— nonafterburning engine

— noncryogenic engine

— nonexpendable engine

— nonregenerative engine

— non-supercharged engine

— nonthrottleable engine

— nonthrust rocket engine

— nuclear-electric engine

— nuclear-fission engine

— one-flow engine

— one-shaft engine

— one-shot engine

— one-spool engine

— open-cycle engine

— operational engine

— opposed-cylinder engine

— opposed-piston engine

— orbital module engine

— orbiter engine

— orbiting ramjet engine

— ordnance turbojet engine

— orienting-thrust engine

— outboard engine

— outer engine

— outer-space engine

— overcooled engine

— oversized engine

— oxidizer-cooled rocket engine

— paired engine

— paper engine

— parallel booster engines

— peroxide engine

— petrol engine

— photon engine

— pickle an engine

— pilot engine

— piston-driven engine

— pitch-control jet engine

— pivoted engine

— plasma engine

— plasmajet engine

— plenum-chamber-burning engine

— plug-in engine

— plug-nozzle engine

— podded engine

— pod-mounted engine

— porous-cooled engine

— powder rocket engine

— powerful engine

— power-limited engine

— preproduction engine

— pressure-feed engine

— propellant-cooled engine

— propulsion engine

— propulsive jet engine

— pulse reaction engine

— pulsejet engine

— pump-fed rocket engine

— pure lift engine

— pylon-mounted engine

— quadruple-chamber rocket engine

— quantum engine

— quiet engine

— race the engine

— radial engine

— radioisotope engine

— ramjet engine

— rato engine

— RCS engine

— reaction propulsion engine

— real engine

— reciprocating engine

— recombination ramjet engine

— refractory-liner rocket engine

— regenerative engine

— regeneratively-cooled engine

— reheated engine

— relight the engine

— rematched engine

— remotely-controlled engine

— replace the engine

— replacement engine

— research engine

— resonant jet engine

— restartable engine

— restricted-burning rocket engine

— retarding rocket engine

— retractable engine

— retrofire rocket engine

— retrograde rocket engine

— retrorocket engine

— retrothrust engine

— return engine

— reusable engine

— reversed engine

— reverse-thrust rocket engine

— right-handed engine

— ring engine

— rocket engine

— rocket-ramjet engine

— roll-control jet engine

— rotary engine

— rotatable-nozzles engine

— rough-running engine

— rubber engine

— run down engine

— running engine

— satellite-like engine

— scaled-down engine

— scaled-up engine

— sealed rocket engine

— sea-level engine

— secondary engine

— second-stage engine

— segmented-rocket engine

— selfcontained-rocket engine

— separable engine

— separation engine

— series-produced engine

— service engine

— service propulsion engine

— shaft-turbine engine

— short-burning engine

— short-duration engine

— short-life engine

— short-period engine

— short-stroke engine

— shut-down engine

— shuttle engine

— side engine

— side-burning rocket engine

— simulated failed engine

— single-barrelled rocket engine

— single-chamber rocket engine

— single-nozzle engine

— single-row engine

— single-shaft engine

— single-shot engine

— single-start engine

— sleeve-valve engine

— smoke-free engine

— smokeless engine

— smoky engine

— solar engine

— solid sustainer engine

— solid-liquid rocket engine

— solid-propellant boost engine

— solid-propellant rocket engine

— space engine

— space shuttle engine

— space vehicle engine

— spaceborne engine

— spacecraft engine

— spare engine

— spark-ignition engine

— spindown engine

— spinup engine

— split-compressor engine

— stage engine

— stage-one engine

— start the engine

— starting engine

— station-keeping engine

— steam-burning rocket engine

— steerable rocket engine

— steering engine

— stopcock the engine

— storable liquid-propellant engine

— straight-jet engine

— strap-on engine

— study engine

— submerged engine

— subscale engine

— subsonic jet engine

— supercharged engine

— supercompression engine

— superperformance engine

— supersonic combustion engine

— supersonic jet engine

— supplementary engine

— surge-free engine

— sustainer engine

— sustaining engine

— sweat-cooled engine

— swiveling engine

— swiveling-nozzle engine

— symmetrically opposite engine

— tail-mounted engine

— takeoff rocket engine

— tandem boost engine

— test engine

— testbed engine

— thermal-jet engine

— thermionic engine

— thermochemical rocket engine

— thermojet engine

— thermonuclear rocket engine

— three-barreled engine

— three-chambered engine

— three-shaft engine

— three-spool engine

— throttleable engine

— throttled back engine

— thrust engine

— tiltable engine

— tilting engine

— tiny engine

— tip engine

— trajectory-correction engine

— transonic engine

— transpiration-cooled rocket engine

— transtage engine

— traveling-wave plasma engine

— tri-chamber engine

— trim rocket engine

— triple-barreled engine

— triple-chamber engine

— turbine engine

— turboelectric engine

— turbofan engine

— turbofanramjet engine

— turbofed engine

— turbojet engine

— turboprop engine

— turbopump rocket engine

— turboram rocket engine

— turboramjet engine

— turborocket engine

— turbosupercharged engine

— twin-combustion-chamber engine

— twin-shaft engine

— two-chamber engine

— two-dimensional-ion engine

— two-propellants rocket engine

— two-row engine

— two-segment engine

— two-shaft engine

— two-spool engine

— uncooled rocket engine

— underslung engine

— underwing engine

— unreheated engine

— unrestricted-burning rocket engine

— unsegmented engine

— unsilenced engine

— unsupercharged engine

— upper-stage engine

— uprated engine

— upwind engine

— V/STOL engine

— valveless engine

— vapor-cycle-cooled engine

— vaporization-cooled engine

— variable-geometry engine

— variable-thrust engine

— vectorable engine

— vectored-thrust engine

— vee engine

— vernier engine

— vertical lift engine

— vertical-mounted engine

— vibration-free engine

— Wankel engine

— warmed engine

— water-cooled engine

— water-injection engine

— wet-sump engine

— widely-throttleable engine

— wing pod engine

— wing-mounted engine

— wing-root-buried engine

— wingtip-mounted engine

— wlndmllling engine

— wraparound boost engine

— zero-stage engine

Messerschmitt, Willi E.

SUBJECT AREA: Aerospace

[br]

b. 26 June 1898 Frankfurt-am-Main, Germany

d. 17 September 1978 Munich, Germany

[br]

German aircraft designer noted for successful fighters such as the Bf 109, one of the world's most widely produced aircraft.

[br]

Messerschmitt studied engineering at the Munich Institute of Tchnology and obtained his degree in 1923. By 1926 he was Chief Designer at the Bayerische Flugzeugwerke in Augsburg. Due to the ban on military aircraft in Germany following the First World War, his early designs included gliders, light aircraft, and a series of high-wing airliners. He began to make a major impact on German aircraft design once Hitler came to power and threw off the shackles of the Treaty of Versailles, which so restricted Germany's armed forces. In 1932 he bought out the now-bankrupt Bayerische Flugzeugwerke, but initially, because of enmity between himself and the German aviation minister, was not invited to compete for an air force contract for a single-engined fighter. However, in 1934 Messerschmitt designed the Bf 108 Taifun, a small civil aircraft with a fighter-like appearance. This displayed the quality of his design and the German air ministry was forced to recognize him. As a result, he unveiled the famous Bf 109 fighter which first flew in August 1935; it was used during the Spanish Civil War in 1936–9, and was to become one of the foremost combat aircraft of the Second World War. In 1938, after several name changes, the company became Messerschmitt Aktien-Gesellschaft (and hence a change of prefix from Bf to Me). During April 1939 a Messerschmitt aircraft broke the world air-speed record at 755.14 km/h (469.32 mph): it was entered in the FAI records as a Bf 109R, but was more accurately a new design designated Me 209V-1.

During the Second World War, the 5/70P was progressively improved, and eventually almost 35,000 were built. Other successful fighters followed, such as the twin-engined Me 110 which also served as a bomber and night fighter. The Messerschmitt Me 262 twin-engined jet fighter, the first jet aircraft in the world to enter service, flew during the early years of the war, but it was never given a high priority by the High Command and only a small number were in service when the war ended. Another revolutionary Messerschmitt AG design was the Me 163 Komet, the concept of Professor Alexander Lippisch who had joined Messerschmitt's company in 1939; this was the first rocket-propelled fighter to enter service. It was a small tailless design capable of 880 km/hr (550 mph), but its duration under power was only about 10 minutes and it was very dangerous to fly. From late 1944 onwards it was used to intercept the United States Air Force bombers during their daylight raids. At the other end of the scale, Messerschmitt produced the Me 321 Gigant, a huge transport glider which was towed behind a flight of three Me 110s. Later it was equipped with six engines, but it was an easy target for allied fighters. This was a costly white elephant, as was his high-speed twin-engined Me 210 fighter-bomber project which nearly made his company bankrupt. Nevertheless, he was certainly an innovator and was much admired by Hitler, who declared that he had "the skull of a genius", because of the Me 163 Komet rocket-powered fighter and the Me 262.

At the end of the war Messerschmitt was detained by the Americans for two years. In 1952 Messerschmitt became an aviation adviser to the Spanish government, and his Bf109 was produced in Spain as the Hispano Buchon for a number of years and was powered by Rolls-Royce Merlin engines. A factory was also constructed in Egypt to produce aircraft to Messerschmitt's designs. His German company, banned from building aircraft, produced prefabricated houses, sewing machines and, from 1953 to 1962, a series of bubble-cars: the KR 175 (1953–55) and the KR 200 (1955–62) were single-cylinder three-wheeled bubble-cars, and the Tiger (1958–62) was a twin-cylinder, 500cc four-wheeler. In 1958 Messerschmitt resumed aircraft construction in Germany and later became the Honorary Chairman of the merged Messerschmitt-Bölkow-Blohm company (now part of the Franco-German Eurocopter company).

[br]

Further Reading

van Ishoven, 1975, Messerschmitt. Aircraft Designer, London. J.Richard Smith, 1971, Messerschmitt. An Air-craft Album, London.

Anthony Pritchard, 1975, Messerschmitt, London (describes Messerschmitt aircraft).

JDS / CM

Priestman, William Dent

SUBJECT AREA: Steam and internal combustion engines

[br]

b. 23 August 1847 Sutton, Hull, England

d. 7 September 1936 Hull, England

[br]

English oil engine pioneer.

[br]

William was the second son and one of eleven children of Samuel Priestman, who had moved to Hull after retiring as a corn miller in Kirkstall, Leeds, and who in retirement had become a director of the North Eastern Railway Company. The family were strict Quakers, so William was sent to the Quaker School in Bootham, York. He left school at the age of 17 to start an engineering apprenticeship at the Humber Iron Works, but this company failed so the apprenticeship was continued with the North Eastern Railway, Gateshead. In 1869 he joined the hydraulics department of Sir William Armstrong \& Company, Newcastle upon Tyne, but after a year there his father financed him in business at a small, run down works, the Holderness Foundry, Hull. He was soon joined by his brother, Samuel, their main business being the manufacture of dredging equipment (grabs), cranes and winches. In the late 1870s William became interested in internal combustion engines. He took a sublicence to manufacture petrol engines to the patents of Eugène Etève of Paris from the British licensees, Moll and Dando. These engines operated in a similar manner to the non-compression gas engines of Lenoir. Failure to make the two-stroke version of this engine work satisfactorily forced him to pay royalties to Crossley Bros, the British licensees of the Otto four-stroke patents.

Fear of the dangers of petrol as a fuel, reflected by the associated very high insurance premiums, led William to experiment with the use of lamp oil as an engine fuel. His first of many patents was for a vaporizer. This was in 1885, well before Ackroyd Stuart. What distinguished the Priestman engine was the provision of an air pump which pressurized the fuel tank, outlets at the top and bottom of which led to a fuel atomizer injecting continuously into a vaporizing chamber heated by the exhaust gases. A spring-loaded inlet valve connected the chamber to the atmosphere, with the inlet valve proper between the chamber and the working cylinder being camoperated. A plug valve in the fuel line and a butterfly valve at the inlet to the chamber were operated, via a linkage, by the speed governor; this is believed to be the first use of this method of control. It was found that vaporization was only partly achieved, the higher fractions of the fuel condensing on the cylinder walls. A virtue was made of this as it provided vital lubrication. A starting system had to be provided, this comprising a lamp for preheating the vaporizing chamber and a hand pump for pressurizing the fuel tank.

Engines of 2–10 hp (1.5–7.5 kW) were exhibited to the press in 1886; of these, a vertical engine was installed in a tram car and one of the horizontals in a motor dray. In 1888, engines were shown publicly at the Royal Agricultural Show, while in 1890 two-cylinder vertical marine engines were introduced in sizes from 2 to 10 hp (1.5–7.5 kW), and later double-acting ones up to some 60 hp (45 kW). First, clutch and gearbox reversing was used, but reversing propellers were fitted later (Priestman patent of 1892). In the same year a factory was established in Philadelphia, USA, where engines in the range 5–20 hp (3.7–15 kW) were made. Construction was radically different from that of the previous ones, the bosses of the twin flywheels acting as crank discs with the main bearings on the outside.

On independent test in 1892, a Priestman engine achieved a full-load brake thermal efficiency of some 14 per cent, a very creditable figure for a compression ratio limited to under 3:1 by detonation problems. However, efficiency at low loads fell off seriously owing to the throttle governing, and the engines were heavy, complex and expensive compared with the competition.

Decline in sales of dredging equipment and bad debts forced the firm into insolvency in 1895 and receivers took over. A new company was formed, the brothers being excluded. However, they were able to attend board meetings, but to exert no influence. Engine activities ceased in about 1904 after over 1,000 engines had been made. It is probable that the Quaker ethics of the brothers were out of place in a business that was becoming increasingly cut-throat. William spent the rest of his long life serving others.

[br]

Further Reading

C.Lyle Cummins, 1976, Internal Fire, Carnot Press.

C.Lyle Cummins and J.D.Priestman, 1985, "William Dent Priestman, oil engine pioneer and inventor: his engine patents 1885–1901", Proceedings of the Institution of

Mechanical Engineers 199:133.

Anthony Harcombe, 1977, "Priestman's oil engine", Stationary Engine Magazine 42 (August).

JB

engine

двигатель (внутреннего сгорания); машина; мотор

- engine accessories

- engine analyzer - engine and gearbox unit - engine area - engine assembly - engine assembly shop

- engine balance

- engine base

- engine bay

- engine bearer

- engine bed

- engine behavior

- engine block

- engine block heater

- engine bonnet

- engine bracket

- engine brake

- engine braking

- engine braking effect

- engine braking force - engine breathing - engine-building - engine capacity

- engine case

- engine casing

- engine cleansing agents

- engine clutch

- engine clutch housing

- engine column

- engine compartment

- engine compartment lamp

- engine component - engine conk - engine control

- engine controls

- engine cooler

- engine-cooling - engine-cooling thermometer - engine cowl flap

- engine cowling

- engine cradle

- engine cranking

- engine cross-drive

- engine cross-drive casing - engine cutoff - engine cycle - engine data - engine deck - engine department - engine details - engine diagnostic connector

- engine displacement

- engine drive

- engine-driven

- engine-driven air compressor

- engine-driven compressor

- engine-driven industrial truck

- 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 dead

- engine is running rough

- 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 mount damper

- engine mount system

- 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 support cushion

- engine suspension

- engine temperature sensor

- engine test bed

- engine test rig

- 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

- adiabatic engine

- agricultural engine

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- air engine

- air-cell diesel engine

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- alcohol engine

- aluminium engine

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- Armstrong-Whitworth variable compression knocktesting engine

- arrow engine

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- atmospheric engine - atmospheric steam engine - atomic engine - augmented engine

- automobile engine

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- AV-1 engine - aviation engine

- axial engine

- B-type engine

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- basic engine

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- blast-injection diesel engine - blower-cooled engine

- blowing engine

- blown engine

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- broad-arrow engine

- build up an engine

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- cold engine

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- cold-starting heavy-oil engine

- combustion engine

- compound engine

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- condensating engine

- constant-duty engine

- counterbalanced engine

- coupled engines

- cowled engine

- crank engine - crankcase-scavenged engine

- crosshead engine

- crosswise engine

- crude engine - crude-oil engine

- dead engine

- derated 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

- differential engine

- direct-drive engine

- direct injection engine - divided-chamber engine

- donkey engine

- door engine

- double-acting engine

- double-acting rotary engine

- double-acting steam engine

- double-bank radial engine

- double-cylinder engine

- double-expansion engine

- double-flow engine - double-overhead camshaft engine

- double-piston engine

- double-pistontype engine

- double-row engine

- double-V engine

- dredge engine

- drilling engine - driving engine - drop-valve engine

- dry sump engine

- dual-fuel engine

- ducted-fan engine - duofuel engine - emergency engine

- eight-cylinder engine

- experimental 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

- start up the engine in gear

- 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

- swirl-chamber diesel engine

- switch 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

Ohain, Hans Joachim Pabst von

SUBJECT AREA: Aerospace

[br]

b. 14 December 1911 Dessau, Germany

[br]

German engineer who designed the first jet engine to power an aeroplane successfully.

[br]

Von Ohain studied engineering at the University of Göttingen, where he carried out research on gas-turbine engines, and centrifugal compressors in particular. In 1935 he patented a design for a jet engine (in Britain, Frank Whittle patented his jet-engine design in 1930). Von Ohain was recruited by the Heinkel company in 1936 to develop an engine for a jet aircraft. Ernst Heinkel was impressed by von Ohain's ideas and gave the project a high priority. The first engine was bench tested in September 1937. A more powerful version was developed and tested in air, suspended beneath a Heinkel dive-bomber, during the spring of 1939. A new airframe was designed to house the revolutionary power plant and designated the Heinkel He 178. A short flight was made on 24 August 1939 and the first recognized flight on 27 August. This important achievement received only a lukewarm response from the German authorities. Von Ohain's turbojet engine had a centrifugal compressor and developed a thrust of 380 kg (837 lb). An improved, more powerful, engine was developed and installed in a new twin-engined fighter design, the He 280. This flew on 2 April 1941 but never progressed beyond the prototype stage. By this time two other German companies, BMW and Junkers, were constructing successful turbojets with axial compressors: luckily for the Allies, Hitler was reluctant to pour his hard-pressed resources into this new breed of jet fighters. After the war, von Ohain emigrated to the United States and worked for the Air Force there.

[br]

Bibliography

1929, "The evolution and future of aeropropulsion system", The Jet Age. 40 Years of Jet Aviation, Washington, DC: National Air \& Space Museum, Smithsonian Institution.

Further Reading

Von Ohain's work is described in many books covering the history of aviation, and aero engines in particular, for example: R.Schlaifer and S.D.Heron, 1950, Development of Aircraft Engines and fuels, Boston. G.G.Smith, 1955, Gas Turbines and Jet Propulsion.

Grover Heiman, 1963, Jet Pioneers.

JDS

all-aluminium

прил.

целиком из алюминия

полностью алюминиевый

These lightweight, all-aluminium Ford EcoBoost engines combine three technologies - a centrally-mounted high-pressure direct injection system, low-inertia turbocharging and twin independent variable cam timing to create an advanced combustion system which brings new levels of performance and fuel efficiency to petrol engines in this power range.

ETOPS

1) Авиация: Extended Twin-Engine Operations

2) Транспорт: Engines Turn Or Passengers Swim, Extended Twin-Engine Over Water Operations