development+engine

combustión

f.

1 combustion.

2 ambustion.

* * *

combustión

► nombre femenino

1 combustion, burning

* * *

SF combustion

combustión espontánea — spontaneous combustion

* * *

femenino combustion

* * *

= combustion, burning.

Ex. This article relates the development of an information storage and retrieval system for combustion research.

Ex. The author laments the demise of the paper card catalogue as a 'paroxysm of shortsightedness and antiintellectualism' on the part of over zealous librarians, wreaking destruction in a class with the burning of the library at Alexandria.

----

* cámara de combustión = combustion chamber.

* combustión espontánea = spontaneous combustion.

* combustión lenta = smouldering combustion.

* motor de combustión = combustion engine.

* motor de combustión interna = internal combustion engine.

* * *

femenino combustion

* * *

= combustion, burning.

Ex: This article relates the development of an information storage and retrieval system for combustion research.

Ex: The author laments the demise of the paper card catalogue as a 'paroxysm of shortsightedness and antiintellectualism' on the part of over zealous librarians, wreaking destruction in a class with the burning of the library at Alexandria.

* cámara de combustión = combustion chamber.

* combustión espontánea = spontaneous combustion.

* combustión lenta = smouldering combustion.

* motor de combustión = combustion engine.

* motor de combustión interna = internal combustion engine.

* * *

combustión

feminine

combustion

combustión espontánea spontaneous combustion

* * *

combustión sustantivo femenino
combustion
combustión sustantivo femenino combustion
' combustión' also found in these entries:
Spanish:
motor
English:
combustion
- combustion engine
- exhaust
- internal-combustion engine

* * *

combustión nf

combustion

Comp

combustión espontánea spontaneous combustion;

combustión lenta slow combustion;

combustión nuclear nuclear combustion

* * *

combustión

f combustion

* * *

combustión nf, pl - tiones : combustion

Adamson, Daniel

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering, Metallurgy, Steam and internal combustion engines

[br]

b. 1818 Shildon, Co. Durham, England

d. January 1890 Didsbury, Manchester, England

[br]

English mechanical engineer, pioneer in the use of steel for boilers, which enabled higher pressures to be introduced; pioneer in the use of triple-and quadruple-expansion mill engines.

[br]

Adamson was apprenticed between 1835 and 1841 to Timothy Hackworth, then Locomotive Superintendent on the Stockton \& Darlington Railway. After this he was appointed Draughtsman, then Superintendent Engineer, at that railway's locomotive works until in 1847 he became Manager of Shildon Works. In 1850 he resigned and moved to act as General Manager of Heaton Foundry, Stockport. In the following year he commenced business on his own at Newton Moor Iron Works near Manchester, where he built up his business as an iron-founder and boilermaker. By 1872 this works had become too small and he moved to a 4 acre (1.6 hectare) site at Hyde Junction, Dukinfield. There he employed 600 men making steel boilers, heavy machinery including mill engines fitted with the American Wheelock valve gear, hydraulic plant and general millwrighting. His success was based on his early recognition of the importance of using high-pressure steam and steel instead of wrought iron. In 1852 he patented his type of flanged seam for the firetubes of Lancashire boilers, which prevented these tubes cracking through expansion. In 1862 he patented the fabrication of boilers by drilling rivet holes instead of punching them and also by drilling the holes through two plates held together in their assembly positions. He had started to use steel for some boilers he made for railway locomotives in 1857, and in 1860, only four years after Bessemer's patent, he built six mill engine boilers from steel for Platt Bros, Oldham. He solved the problems of using this new material, and by his death had made c.2,800 steel boilers with pressures up to 250 psi (17.6 kg/cm²).

He was a pioneer in the general introduction of steel and in 1863–4 was a partner in establishing the Yorkshire Iron and Steel Works at Penistone. This was the first works to depend entirely upon Bessemer steel for engineering purposes and was later sold at a large profit to Charles Cammell \& Co., Sheffield. When he started this works, he also patented improvements both to the Bessemer converters and to the engines which provided their blast. In 1870 he helped to turn Lincolnshire into an important ironmaking area by erecting the North Lincolnshire Ironworks. He was also a shareholder in ironworks in South Wales and Cumberland.

He contributed to the development of the stationary steam engine, for as early as 1855 he built one to run with a pressure of 150 psi (10.5 kg/cm) that worked quite satisfactorily. He reheated the steam between the cylinders of compound engines and then in 1861–2 patented a triple-expansion engine, followed in 1873 by a quadruple-expansion one to further economize steam. In 1858 he developed improved machinery for testing tensile strength and compressive resistance of materials, and in the same year patents for hydraulic lifting jacks and riveting machines were obtained.

He was a founding member of the Iron and Steel Institute and became its President in 1888 when it visited Manchester. The previous year he had been President of the Institution of Civil Engineers when he was presented with the Bessemer Gold Medal. He was a constant contributor at the meetings of these associations as well as those of the Institution of Mechanical Engineers. He did not live to see the opening of one of his final achievements, the Manchester Ship Canal. He was the one man who, by his indomitable energy and skill at public speaking, roused the enthusiasm of the people in Manchester for this project and he made it a really practical proposition in the face of strong opposition.

[br]

Principal Honours and Distinctions

President, Institution of Civil Engineers 1887.

President, Iron and Steel Institute 1888. Institution of Civil Engineers Bessemer Gold Medal 1887.

Further Reading

Obituary, Engineer 69:56.

Obituary, Engineering 49:66–8.

Obituary, Proceedings of the Institution of Civil Engineers 100:374–8.

H.W.Dickinson, 1938, A Short History of the Steam Engine, Cambridge University Press (provides an illustration of Adamson's flanged seam for boilers).

R.L.Hills, 1989, Power from Steam. A History of the Stationary Steam Engine, Cambridge University Press (covers the development of the triple-expansion engine).

RLH

ход

1. (вървеж) walk, gait; pace; tread

(конски) pace

бавен ход slow march

бърз ход quick march

карам обикновен ход go at a walk

ускорявам хода go faster

забавям хода slow down

ускорявам/забавям хода (за кораб) gather/lose-way

2. (движение) motion, run

в пълен ход in full progress, (at) full blast, full tilt, (at) full pelt, flat out

прен. in full swing

заден ход reverse/backward motion

давам заден ход back (the engine), move into reverse, reverse, rev

ход на времето course/lapse of time в

в ход afoot; in progress

under way, ( за машина) running

давам ход на give effect to

давам ход на дело proceed with a case

не давам ход на дело nonsuit

давам ход на молба forward/consider a petition

пускам в ход start; set going; set in motion; put in operation

пускам в ход всички средства leave no stone unturned, move heaven and earth

3. (скорост) speed

4. тех. stroke, drive

работя на празен ход float

среден ход halfspeed

5. (развитие) (на събития) course, march, progress, tide, development; tenor

(намисли) train

(на болест) progress

ход на сражение course of action

ходът на събулите the course of events; the pattern of events

6. воен.

ход за съобщение communication trench

7. шах и прен. move

тайните ходове на политиката the shady side of politics

умел ход a clever move

правя погрешен ход play a wrong card

той знае всички ходове he is up to every move

* * *

ход,

м., -ове, (два) хо̀да 1. ( вървеж) walk, gait; pace; tread; ( конски) pace; бавен \ход slow march; бърз \ход quick march; забавям \хода slow down; ускорявам \хода go faster; ускорявам/забавям \хода (за кораб) gather/lose way;

2. ( движение) motion, run; в пълен \ход in full progress, (at) full blast, full tilt, (at) full pelt, flat out; прен. in full swing; в \ход afoot; in progress; under way, (за машина) running; давам заден \ход back (the engine), move into reverse, reverse, rev; давам \ход на give effect to; давам \ход на дело proceed with a case; давам \ход на молба consider/forward a petition; заден \ход reverse/backward motion; пускам в \ход всички средства leave no stone unturned, move heaven and earth; тайни \ходове на политиката the shady side of politics; \ход на времето course/lapse of time;

3. ( скорост) speed;

4. техн. stroke, drive; работя на празен \ход float; среден \ход halfspeed;

5. ( развитие) (на събития) course, march, progress, tide, development; tenor; (на мисли) train; (на болест) progress; \ходът на събитията the course of events; the pattern of events;

6. воен. ( такт) cadence; \ход за съобщение communication trench;

7. шах move (и прен.); правя погрешен \ход play a wrong card; умел \ход clever move.

* * *

walk ; gait ; going ; march: a slow ход - бавен ход, а quick ход - бърз ход; cadence (воен.); course: the ход of events - ходът на събитията; current: reverse ход - заден ход, set in ход - пускам в ход; move up ; operation ; pace {peis} (походка); ploy ; process ; rate {reit}; resource (напредък): the preparations are in full ход - приготовленията са в пълен ход; travel (тех.); tread ; walking ; proceed with a case - давам ход на дело (юр.)

* * *

1. (вървеж) walk, gait;pace;tread 2. (движение) motion, run 3. (конски) pace 4. (на болест) progress 5. (намисли) train 6. (развитие) (на събития) course, march, progress, tide, development;tenor 7. (скорост) speed 8. mex. stroke, drive 9. under way, (за машина) running 10. ХОД на времето course/lapse of timeв 11. ХОД на сражение course of action 12. ХОДът на събулите the course of events;the pattern of events 13. бавен ХОД slow march 14. бърз ХОД quick march 15. в ХОД afoot;in progress 16. в пълен ХОД in full progress, (at) full blast, full tilt, (at) full pelt, flat out 17. воен.: ХОД за съобщение communication trench 18. давам ХОД на give effect to 19. давам ХОД на дело proceed with a case 20. давам ХОД на молба forward/consider a petition 21. давам заден ХОД back (the engine), move into reverse, reverse, rev 22. забавям ХОДа slow down 23. заден ХОД reverse/backward motion 24. карам обикновен ХОД go at a walk 25. не давам ХОД на дело nonsuit 26. правя погрешен ХОД play a wrong card 27. прен. in full swing 28. пускам в ХОД start;set going;set in motion;put in operation 29. пускам в ХОД всички средства leave no stone unturned, move heaven and earth 30. работя на празен ХОД float 31. среден ХОД halfspeed 32. тайните ХОДове на политиката the shady side of politics 33. той знае всички ХОДове he is up to every move 34. умел ХОД a clever move 35. ускорявам ХОДа go faster 36. ускорявам/забавям ХОДа (за кораб) gather/lose -way 37. шах и прен. move

работа

work
(выполняемая человеком или совершаемая машиной) — instructions for accomplishing the work.
указания no выполнению работ(ы). содержание работы, тепловая энергия горячего воздуха, подаваемого в турбохолодильник, преобразуется в работу, вызывая охлажние воздуха на выходе из tх — description of work. h energy passing through the cooling turbine is converted into work, thus causing a temperature drop across the turbine.
- (нагруженного элемента конструкции) — stress carrying
"-" (надпись у выключателя противопожарной системы) — (fire) agent arm
- (обрабатываемая заготовка или деталь) тиски применяются для зажима обрабатываемого материала или работы. — job. vices are used to grip firmly the material or job upon which work is being done.
"-" (положение рычага останова двигателя) — run, fuel on, open
"-" (режим работы навигационной инерциальной системы) — navigate (nav) mode. set the ins mode selector switch to nav position.
- (фунхционирование, действие, операция) — operation, action
данная глава содержит щие сведения о принципе работы насоса. — this chapter contains general information on principle of the pump operation.
- абсу в штурвальном рожиме — afcs operation under manual control
-, автоматическая — automatic operation
-, автоматическая (двигателя после нар) — (engine) governed run
- агрегата — unit operation
-, безотказная (бееперебой — trouble-free operation
-, бесшумная — noise-free operation
- в автоматическом режиме — automatic operation
- (выполняемая) в заводских условиях или в мастерских — shop work
инструкции по ремонту составлены для механизмов, выполняющих работу в стационарных мастерских, а не дпя механиков-эксплуатационников. — the overhaul instructions are prepared for mechanic who normally performs shop work and not for the aircraft service mechanic.
-, внерегламентная — unscheduled maintenance check
-, внеочередная регламентная — unscheduled maintenance check
- в ручном режиме — manual operation
- выполняемая при нахождении самолета вне эксплуатации сроком до (одного) mесяца — maintenance of aircraft during an inaction period of (one) month
-, выполняемая своими силами (на своих базах) — work accomplished "in house"
работа, выполняется своими силами, вместо того, чтобы выполнять эту работу силами изготовителя. — work accomplished in house versus "return to vendor" philosophy.
- генераторов, непараллельная — unparalleled operation of generators
- генераторов, непараллельная (табло) — unparalleled generators: generators unparalleled (gen unparl'd)
- генераторов, параллельная — paralleled operation of generators, generators operating paral leled
- генераторов, параллельная (табло) — paralleled generators, generators paralleled (gen parl'd)
- генераторов, раздельная (в отличие от параллельной) — independent operation of generators
- двигателя — engine operation /running/
работа двигателя во всем диапазоне эксплуатационных (полетных) режимов, — the engine operation throughout the flight power range.
- двигателя (этап) — engine run
30-часовой этап работы двигателя на чередующихся режимах: взлетном и мпр. — 30-hour run (of engine) consisting of alternate periods at takeoff power and at maximum cruising power.
-, заключительная — conclusive operation
- летчика (нагрузка) — pilot work load
наличие автоматического включения реверса тяги облегчает работу летчика при посадке, — installation of automatic thrust reversal control reduces pilot work load during landing.
- на большом газе (двиг.) — engine run /operation/ at full throttle
- на валу — shaft work
- на взлетном режиме (двиг.) — (engine) operation at takeoff power, takeoff power operation
-, надежная — reliable /dependable/ operation
- на завышенных оборотах (двиг.) (этап испытаний) — overspeed run
работа двигателя на завыщенных оборотах должна чередоваться с работой на стабилизирующих режимах. — the overspeed runs must be alternated with stabilizing runs.
- на максимальном продолжительном режиме (мпр) (двиг.) — engine operation at maximum continuous power
- на малом газе (двиг.) — (engine) operation at idle power, idling
работа на возможно малых оборотах, не приводящая к останову двигателя, — engine running at lowest speed possible, without stopping.
- на малых оборотах (двиг.) — engine low speed operation
- на "номинальном" режиме (на mпp) (двиг.) — (engine) operation at maximum continuous power
- (вертолета) на привязи — (helicopter) tie-down run
-, научно-исследовательская — research work
-, на холостом ходу (двиг.) — idling
-, непрерывная — continuous operation
-, неустойчивая — unstable operation
-, осмотровая — inspection
-, плановая (оперативная по регламенту техобслуживания) — line maintenance
-, погрузочно-разгрузочная — cargo handling (operation)
-, подготовительная работа по подготовке обо_ рудования к установке на ла. — preparatory procedure
-, полезная — useful work
- по разработке бортового оборудования ла — development work on airborne equipment
- по техническому обслуживанию (осмотру) — inspection and maintenance work /action/
-, профилактическая (техобслуживания) — preventive maintenance operation
-, регламентная — scheduled maintenance action /check, inspection/
выполнение программы надежности является лучшим методом для обеспечения надежности работы систем в периоды между регламентными работами. — the reliability program is the best method of controlling the interval between scheduled maintenance actions.
-, регламентная (50-) часовая — (50-)hour scheduled maintenance check
-, регламентная (50-) часовая (в летных часах) — (50-)flight hour (fh) maintenаncе cheek
-, ремонтная (текущий ремонт) — repair work
-, совместная — work in unison

systems operate conjointly or in unison.
-, с перебоями (двиг.) — rough (engine) operation
двигатель работает с перебоями при неисправности системы зажигания или питания топливом, — an engine that is running or firing unevenly, usually due to а faulty condition in either the fuel or ignition systems.
-, строго регламентированная — hard-time (ht) process /action/
вид профилактической технической проверки в результате которой изделие (агрегат) должен быть снят с самолета и направлен в ремонт до истечения срока регламентных работ по данному изделию, — нт is а failure preventive primary maintenance (overhaul control) process which requires that the item be removed from the airplane and overhauled (or replaced) before exceeding the specified time (interval).
- схемы (раздел описания работы электр. схемы системы блока и т.п.) — detailed circuit description
-, текущая — current work
-, типовая — routine
- "уравновешивающая" (этап испытаний двиг.) — stabilizing run
работа двигателя на повышенном режиме должна чередоваться е работой на уравновешивающем режиме. — overspeed runs must be alternated with stabilizing runs.
- установившаяся — steady operation
-, устойчивая — stable operation
-, экспериментальная — experimental work
.нарушение нормальной р. (агрегата системы) — malfunction
объем р. — scope of work
описание и р. (раздел руководства) — description and operation
порядок выполнения р. (раздел бюллетеня) — accomplishment instructions
при р. с (на) прибором, (самелете) — when working on indicator (airplane)
схема р. — functional diagram
часы р. — hours of operation
выполнять р. — accomplish work
выполнять р. на агрегате (работать с агрегатом) — perform work on unit
зажимать р. в тисках — grip а job in the vice
нарушать нормальную р. (агрегата, системы) — cause malfunction
проводить р. на /с/... — work оп...

Reynolds, Edwin

SUBJECT AREA: Public utilities, Steam and internal combustion engines

[br]

b. 1831 Mansfield, Connecticut, USA

d. 1909 Milwaukee, Wisconsin, USA

[br]

American contributor to the development of the Corliss valve steam engine, including the "Manhattan" layout.

[br]

Edwin Reynolds grew up at a time when formal engineering education in America was almost unavailable, but through his genius and his experience working under such masters as G.H. Corliss and William Wright, he developed into one of the best mechanical engineers in the country. When he was Plant Superintendent for the Corliss Steam Engine Company, he built the giant Corliss valve steam engine displayed at the 1876 Centennial Exhibition. In July 1877 he left the Corliss Steam Engine Company to join Edward Allis at his Reliance Works, although he was offered a lower salary. In 1861 Allis had moved his business to the Menomonee Valley, where he had the largest foundry in the area. Immediately on his arrival with Allis, Reynolds began desig-ning and building the "Reliance-Corliss" engine, which becamea symbol of simplicity, economy and reliability. By early 1878 the new engine was so successful that the firm had a six-month backlog of orders. In 1888 he built the first triple-expansion waterworks-pumping engine in the United States for the city of Milwaukee, and in the same year he patented a new design of blowing engine for blast furnaces. He followed this in March 1892 with the first steam engine sets coupled directly to electric generators when Allis-Chalmers contracted to build two Corliss cross-compound engines for the Narragansett Light Company of Providence, Rhode Island. In 1893, one of the impressive attractions at the World's Columbian Exposition in Chicago was the 3,000 hp (2,200 kW) quadruple-expansion Reynolds-Corliss engine designed by Reynolds, who continued to make significant improvements and gained worldwide recognition of his outstanding achievements in engine building.

Reynolds was asked to go to New York in 1898 for consultation about some high-horsepower engines for the Manhattan transport system. There, 225 railway locomotives were to be replaced by electric trains, which would be supplied from one generating station producing 60,000 hp (45,000 kW). Reynolds sketched out his ideas for 10,000 hp (7,500 kW) engines while on the train. Because space was limited, he suggested a four-cylinder design with two horizontal-high-pressure cylinders and two vertical, low-pressure ones. One cylinder of each type was placed on each side of the flywheel generator, which with cranks at 135° gave an exceptionally smooth-running compact engine known as the "Manhattan". A further nine similar engines that were superheated and generated three-phase current were supplied in 1902 to the New York Interborough Rapid Transit Company. These were the largest reciprocating steam engines built for use on land, and a few smaller ones with a similar layout were installed in British textile mills.

[br]

Further Reading

Concise Dictionary of American Biography, 1964, New York: C.Scribner's Sons (contains a brief biography).

R.L.Hills, 1989, Power from Steam. A History of the Stationary Steam Engine, Cambridge University Press (provides a brief account of the Manhattan engines) Part of the information for this biography is derived from a typescript in the Smithsonian Institution, Washington, DC: T.H.Fehring, "Technological contributions of Milwaukee's Menomonee Valley industries".

RLH

puntal

m.

1 prop (madero).

2 snack. (Andean Spanish (Bolivia, Chilean Spanish, Colombia, Ecuador, Peru), Central American Spanish, Mexican Spanish)

* * *

puntal

► nombre masculino

1 prop

2 figurado support

* * *

noun m.

prop

* * *

SM

1) (=soporte) (Arquit) prop, support; (Agr) prop; (Téc) strut

2) (=persona) [que sirve de apoyo] chief supporter; [que ayuda a resistir] cornerstone; [que está al frente] leading light

3) LAm snack

* * *

masculino

a) (Const) ( vertical) prop, post; ( inclinado) prop, shore

b) (Náut) ( soporte de cubierta) stanchion; ( altura desde la quilla) height

c) (sostén, apoyo) mainstay

* * *

= mainstay, plank, prop, powerhouse, power engine, stilt.

Ex. Technology transfers between developed and underdeveloped nations have been the mainstays of economic development for over 30 years.

Ex. IFLA's annual conference, held at a different venue each year and attracting upwards of 3,000 participants, is a major plank in its professional programme.

Ex. The main props to any retrospective bibliography must be a well formed national library which has a long history of collecting the records of a nation's culture.

Ex. From a position of relative strength in the 1950s, when Central Europe was the hotbed of European sport, the region has suffered a relative decline compared to the powerhouses of Germany, Italy, Spain and the UK.

Ex. Knowledge management is also being recognized as a power engine through which educational institutions can address their need for innovation and creativity.

Ex. The huts are built on stilts to give the turtles access to the entire beach for nesting.

* * *

masculino

a) (Const) ( vertical) prop, post; ( inclinado) prop, shore

b) (Náut) ( soporte de cubierta) stanchion; ( altura desde la quilla) height

c) (sostén, apoyo) mainstay

* * *

= mainstay, plank, prop, powerhouse, power engine, stilt.

Ex: Technology transfers between developed and underdeveloped nations have been the mainstays of economic development for over 30 years.

Ex: IFLA's annual conference, held at a different venue each year and attracting upwards of 3,000 participants, is a major plank in its professional programme.

Ex: The main props to any retrospective bibliography must be a well formed national library which has a long history of collecting the records of a nation's culture.

Ex: From a position of relative strength in the 1950s, when Central Europe was the hotbed of European sport, the region has suffered a relative decline compared to the powerhouses of Germany, Italy, Spain and the UK.

Ex: Knowledge management is also being recognized as a power engine through which educational institutions can address their need for innovation and creativity.

Ex: The huts are built on stilts to give the turtles access to the entire beach for nesting.

* * *

puntal

masculine

1 ( Const) (vertical) prop, post; (inclinado) prop, shore

2 ( Náut) (soporte de cubierta) stanchion; (altura desde la quilla) height

3 (sostén, apoyo) mainstay

* * *

puntal sustantivo masculino

a) (Const) prop

b) (sostén, apoyo) mainstay

' puntal' also found in these entries:
English:
prop
- strut

* * *

puntal nm

1. [madero] prop

2. [en mina] shore, leg

3. [apoyo] mainstay;

el sector agrario es uno de los puntales de la región farming is one of the mainstays of the regional economy

4. Andes, CAm, Méx [aperitivo] snack

* * *

puntal nm

1) : prop, support

2) : stanchion

Bollée, Ernest-Sylvain

SUBJECT AREA: Automotive engineering, Mechanical, pneumatic and hydraulic engineering

[br]

b. 19 July 1814 Clefmont (Haute-Marne), France

d. 11 September 1891 Le Mans, France

[br]

French inventor of the rotor-stator wind engine and founder of the Bollée manufacturing industry.

[br]

Ernest-Sylvain Bollée was the founder of an extensive dynasty of bellfounders based in Le Mans and in Orléans. He and his three sons, Amédée (1844–1917), Ernest-Sylvain fils (1846–1917) and Auguste (1847-?), were involved in work and patents on steam-and petrol-driven cars, on wind engines and on hydraulic rams. The presence of the Bollées' car industry in Le Mans was a factor in the establishment of the car races that are held there.

In 1868 Ernest-Sylvain Bollée père took out a patent for a wind engine, which at that time was well established in America and in England. In both these countries, variable-shuttered as well as fixed-blade wind engines were in production and patented, but the Ernest-Sylvain Bollée patent was for a type of wind engine that had not been seen before and is more akin to the water-driven turbine of the Jonval type, with its basic principle being parallel to the "rotor" and "stator". The wind drives through a fixed ring of blades on to a rotating ring that has a slightly greater number of blades. The blades of the fixed ring are curved in the opposite direction to those on the rotating blades and thus the air is directed onto the latter, causing it to rotate at a considerable speed: this is the "rotor". For greater efficiency a cuff of sheet iron can be attached to the "stator", giving a tunnel effect and driving more air at the "rotor". The head of this wind engine is turned to the wind by means of a wind-driven vane mounted in front of the blades. The wind vane adjusts the wind angle to enable the wind engine to run at a constant speed.

The fact that this wind engine was invented by the owner of a brass foundry, with all the gear trains between the wind vane and the head of the tower being of the highest-quality brass and, therefore, small in scale, lay behind its success. Also, it was of prefabricated construction, so that fixed lengths of cast-iron pillar were delivered, complete with twelve treads of cast-iron staircase fixed to the outside and wrought-iron stays. The drive from the wind engine was taken down the inside of the pillar to pumps at ground level.

Whilst the wind engines were being built for wealthy owners or communes, the work of the foundry continued. The three sons joined the family firm as partners and produced several steam-driven vehicles. These vehicles were the work of Amédée père and were l'Obéissante (1873); the Autobus (1880–3), of which some were built in Berlin under licence; the tram Bollée-Dalifol (1876); and the private car La Mancelle (1878). Another important line, in parallel with the pumping mechanism required for the wind engines, was the development of hydraulic rams, following the Montgolfier patent. In accordance with French practice, the firm was split three ways when Ernest-Sylvain Bollée père died. Amédée père inherited the car side of the business, but it is due to Amédée fils (1867– 1926) that the principal developments in car manufacture came into being. He developed the petrol-driven car after the impetus given by his grandfather, his father and his uncle Ernest-Sylvain fils. In 1887 he designed a four-stroke single-cylinder engine, although he also used engines designed by others such as Peugeot. He produced two luxurious saloon cars before putting Torpilleur on the road in 1898; this car competed in the Tour de France in 1899. Whilst designing other cars, Amédée's son Léon (1870–1913) developed the Voiturette, in 1896, and then began general manufacture of small cars on factory lines. The firm ceased work after a merger with the English firm of Morris in 1926. Auguste inherited the Eolienne or wind-engine side of the business; however, attracted to the artistic life, he sold out to Ernest Lebert in 1898 and settled in the Paris of the Impressionists. Lebert developed the wind-engine business and retained the basic "stator-rotor" form with a conventional lattice tower. He remained in Le Mans, carrying on the business of the manufacture of wind engines, pumps and hydraulic machinery, describing himself as a "Civil Engineer".

The hydraulic-ram business fell to Ernest-Sylvain fils and continued to thrive from a solid base of design and production. The foundry in Le Mans is still there but, more importantly, the bell foundry of Dominique Bollée in Saint-Jean-de-Braye in Orléans is still at work casting bells in the old way.

[br]

Further Reading

André Gaucheron and J.Kenneth Major, 1985, The Eolienne Bollée, The International Molinological Society.

Cénomane (Le Mans), 11, 12 and 13 (1983 and 1984).

KM

Brayton, George Bailey

SUBJECT AREA: Steam and internal combustion engines

[br]

b. 1839 Rhode Island, USA

d. 1892 Leeds, England

[br]

American engineer, inventor of gas and oil engines.

[br]

During the thirty years prior to his death, Brayton devoted considerable effort to the development of internal-combustion engines. He designed the first commercial gas engine of American origin in 1872. An oil-burning engine was produced in 1875. An aptitude for mechanical innovation became apparent whilst he was employed at the Exeter Machine Works, New Hampshire, where he developed a successful steam generator for use in domestic and industrial heating systems. Brayton engines were distinguished by the method of combustion. A pressurized air-fuel mixture from a reservoir was ignited as it entered the working cylinder—a precursor of the constant-pressure cycle. A further feature of these early engines was a rocking beam. There exist accounts of Brayton engines fitted into river craft, and of one in a carriage which operated for a few months in 1872–3. However, the appearance of the four-stroke Otto engine in 1876, together with technical problems associated with backfiring into the fuel reservoir, prevented large-scale acceptance of the Brayton engine. Although Thompson Sterne \& Co. of Glasgow became licensees, the engine failed to gain usage in Britain. A working model of Brayton's gas engine is exhibited in the Museum of History and Technology in Washington, DC.

[br]

Bibliography

1872, US patent no. 125,166 (Brayton gas engine).

July 1890, British patent no. 11,062 (oil engine; under patent agent W.R.Lake).

Further Reading

D.Clerk, 1895, The Gas and Oil Engine, 6th edn, London, pp. 152–62 (includes a description and report of tests carried out on a Brayton engine).

KAB

Otto, Nikolaus August

SUBJECT AREA: Automotive engineering, Steam and internal combustion engines

[br]

b. 10 June 1832 Holzhausen, Nassau (now in Germany)

d. 26 January 1891 Cologne, Germany

[br]

German engineer, developer of the four-stroke internal combustion engine.

[br]

Otto's involvement in internal combustion engines was first prompted by his interest in Lenoir's coal-gas engine of 1860. He built his first engine in 1861; in 1864, Otto's engine came to the attention of Eugen Langen, who arranged for the capital to set up the world's first engine company, N.A.Otto and Company, in Cologne. In 1867 the Otto- Langen free-piston internal combustion engine was exhibited at the Paris Exposition, where it won the gold medal. The company continued to expand, and five years after the Paris triumph its name was changed to the Gasmotoren Fabrik; amongst Otto's colleagues at this time were Gottlieb Daimler and Wilhelm Maybach .

Otto is most famous for the development of the four-stroke cycle which was to bear his name. He patented his version of this in 1876, although the principle of the four-stroke cycle had been patented by Alphonse Beau de Rochas fourteen years previously; Otto was the first, however, to put the principle into practice with the "Otto Silent Engine". Many thousands of Otto fourstroke engines had already been built by 1886, when a German patent lawyer successfully claimed that Otto had infringed the Beau de Rochas patent, and Otto's patent was declared invalid.

[br]

Principal Honours and Distinctions

Médaille d'or, Paris Exposition 1867 (for the Otto-Langen engine).

Further Reading

1989, History of the Internal Combustion Engine, Detroit: Society of Automotive Engineers.

I.McNeil (ed.), 1990, An Encyclopaedia of the History of Technology, London and New York: Routledge, 306–7.

IMcN

Stuart, Herbert Akroyd

SUBJECT AREA: Steam and internal combustion engines

[br]

b. 1864 Halifax, England

d. 1927 Perth, Australia

[br]

English inventor of an oil internal-combustion engine.

[br]

Stuart's involvement with engines covered a period of less than ten years and was concerned with a means of vaporizing the heavier oils for use in the so-called oil engines. Leaving his native Yorkshire for Bletchley in Buckinghamshire, Stuart worked in his father's business, the Bletchley Iron and Tin Plate works. After finishing grammar school, he worked as an assistant in the Mechanical Engineering Department of the City and Guilds of London Technical College. He also formed a connection with the Finsbury Technical College, where he became acquainted with Professor William Robinson, a distinguished engineer eminent in the field of internal-combustion engines.

Resuming work at Bletchley, Stuart carried out experiments with engines. His first patent was concerned with new methods of vaporizing the fuel, scavenging systems and improvement of speed control. Two further patents, in 1890, specified substantial improvements and formed the basis of later engine designs. In 1891 Stuart joined forces with R.Hornsby and Sons of Grantham, a firm founded in 1815 for the manufacture of machinery and steam engines. Hornsby acquired all rights to Stuart's engine patents, and their superior technical resources ensured substantial improvements to Stuart's early design. The Hornsby-Ackroyd engines, introduced in 1892, were highly successful and found wide acceptance, particularly in agriculture. With failing health, Stuart's interest in his engine work declined, and in 1899 he emigrated to Australia, where in 1903 he became a partner in importing gas engines and gas-producing plants. Following his death in 1927, under the terms of his will he was interred in England; sadly, he also requested that all papers and materials pertaining to his engines be destroyed.

[br]

Bibliography

July 1886, British patent no. 9,866 (fuel vapourization methods, scavenging systems and improvement of speed control; the patent describes Stuart as Mechanical Engineer of Bletchley Iron Works).

1890, British patent no. 7,146 and British patent no. 15,994 (describe a vaporizing chamber connected to the working cylinder by a small throat).

Further Reading

D.Clerk, 1895, The Gas and Oil Engine, 6th edn, London, pp. 420–6 (provides a detailed description of the Hornsby-Ackroyd engine and includes details of an engine test).

T.Hornbuckle and A.K.Bruce, 1940, Herbert Akroyd Stuart and the Development of the Heavy Oil Engine, London: Diesel Engine Users'Association, p. 1.

KAB

Watt, James

SUBJECT AREA: Steam and internal combustion engines

[br]

b. 19 January 1735 Greenock, Renfrewshire, Scotland

d. 19 August 1819 Handsworth Heath, Birmingham, England

[br]

Scottish engineer and inventor of the separate condenser for the steam engine.

[br]

The sixth child of James Watt, merchant and general contractor, and Agnes Muirhead, Watt was a weak and sickly child; he was one of only two to survive childhood out of a total of eight, yet, like his father, he was to live to an age of over 80. He was educated at local schools, including Greenock Grammar School where he was an uninspired pupil. At the age of 17 he was sent to live with relatives in Glasgow and then in 1755 to London to become an apprentice to a mathematical instrument maker, John Morgan of Finch Lane, Cornhill. Less than a year later he returned to Greenock and then to Glasgow, where he was appointed mathematical instrument maker to the University and was permitted in 1757 to set up a workshop within the University grounds. In this position he came to know many of the University professors and staff, and it was thus that he became involved in work on the steam engine when in 1764 he was asked to put in working order a defective Newcomen engine model. It did not take Watt long to perceive that the great inefficiency of the Newcomen engine was due to the repeated heating and cooling of the cylinder. His idea was to drive the steam out of the cylinder and to condense it in a separate vessel. The story is told of Watt's flash of inspiration as he was walking across Glasgow Green one Sunday afternoon; the idea formed perfectly in his mind and he became anxious to get back to his workshop to construct the necessary apparatus, but this was the Sabbath and work had to wait until the morrow, so Watt forced himself to wait until the Monday morning.

Watt designed a condensing engine and was lent money for its development by Joseph Black, the Glasgow University professor who had established the concept of latent heat. In 1768 Watt went into partnership with John Roebuck, who required the steam engine for the drainage of a coal-mine that he was opening up at Bo'ness, West Lothian. In 1769, Watt took out his patent for "A New Invented Method of Lessening the Consumption of Steam and Fuel in Fire Engines". When Roebuck went bankrupt in 1772, Matthew Boulton, proprietor of the Soho Engineering Works near Birmingham, bought Roebuck's share in Watt's patent. Watt had met Boulton four years earlier at the Soho works, where power was obtained at that time by means of a water-wheel and a steam engine to pump the water back up again above the wheel. Watt moved to Birmingham in 1774, and after the patent had been extended by Parliament in 1775 he and Boulton embarked on a highly profitable partnership. While Boulton endeavoured to keep the business supplied with capital, Watt continued to refine his engine, making several improvements over the years; he was also involved frequently in legal proceedings over infringements of his patent.

In 1794 Watt and Boulton founded the new company of Boulton \& Watt, with a view to their retirement; Watt's son James and Boulton's son Matthew assumed management of the company. Watt retired in 1800, but continued to spend much of his time in the workshop he had set up in the garret of his Heathfield home; principal amongst his work after retirement was the invention of a pantograph sculpturing machine.

James Watt was hard-working, ingenious and essentially practical, but it is doubtful that he would have succeeded as he did without the business sense of his partner, Matthew Boulton. Watt coined the term "horsepower" for quantifying the output of engines, and the SI unit of power, the watt, is named in his honour.

[br]

Principal Honours and Distinctions

FRS 1785. Honorary LLD, University of Glasgow 1806. Foreign Associate, Académie des Sciences, Paris 1814.

Further Reading

H.W.Dickinson and R Jenkins, 1927, James Watt and the Steam Engine, Oxford: Clarendon Press.

L.T.C.Rolt, 1962, James Watt, London: B.T. Batsford.

R.Wailes, 1963, James Watt, Instrument Maker (The Great Masters: Engineering Heritage, Vol. 1), London: Institution of Mechanical Engineers.

IMcN

на

аварийная обстановка на аэродроме

aerodrome emergency

аварийный бюллетень на доработку

alert service bulletin

авиаперевозчик на короткие расстояния

commuter air carrier

автоматический заход на посадку

1. autoapproach

2. automatic approach азимутальная антенна захода на посадку

approach azimuth antenna

азимут захода на посадку

approach azimuth

азимут ухода на второй круг

missed approach azimuth

аэродинамическая труба для испытаний на сваливание в штопор

spin wind tunnel

аэродинамический гребень на крыле

wing fence

аэродром выхода на радиосвязь

aerodrome of call

аэродром на трассе полета

en-route aerodrome

аэродромные средства захода на посадку

aerodrome approach aids

балансировочный нож на задней кромке крыла

wing trim strip

билет на полет в одном направлении

single ticket

брать на борт

take aboard

брать ручку управления на себя

pull the control stick back

брать управление на себя

1. assume the control

2. take over the control брать штурвал на себя

1. pull the control column back

2. pull the aircraft out of бронирование на обратный рейс

return reservation

буксировка на земле

ground tow

введение поправки на снос

windage adjustment

вертолетная площадка на крыше здания

roof-top heliport

вести передачу на частоте

transmit on frequency of

ветер на определенном участке маршрута

stage wind

взлет на максимальном газе

full-throttle takeoff

взлет на режимах работы двигателей, составляющих наименьший шум

noise abatement takeoff

взятие ручки на себя

backward movement of the stick

видимость на ВПП

runway visibility

виза на промежуточную остановку

stop-over visa

визуальные средства захода на посадку

visual aids to approach

визуальный заход на посадку

1. contact approach

2. visual approach визуальный заход на посадку по упрощенной схеме

abbreviated visual approach

владелец сертификата на воздушное судно

aircraft certificate holder

влиять на безопасность

affect the safety

влиять на безопасность полетов

effect on operating safety

влиять на летную годность

affect airworthiness

влиять на летные характеристики

effect on flight characteristics

влиять на регулярность

affect the regularity

влиять на состояние воздушного судна

effect on an aircraft

вмятина на обшивке

dent in surface

внешняя подвеска на тросах

sling load

вносить поправку на снос

make drift correction

возвращаться на глиссаду

regain the glide path

возвращаться на заданный курс

regain the track

воздухозаборник, раздвоенный на выходе

bifurcated air intake

воздушная яма на пути полета

in flight bump

воздушное судно для полетов на большой высоте

high-altitude aircraft

воздушное судно, имеющее разрешение на полет

authorized aircraft

воздушное судно, летящее курсом на восток

eastbound aircraft

воздушное судно на подходе

in-coming aircraft

воздушное судно, находящееся на встречном курсе

oncoming aircraft

воздушное судно, оставшееся на плаву

stayed afloat aircraft

воздушное судно, совершающее заход на посадку

approaching aircraft

воздушный винт на режиме малого газа

idling propeller

восходящий поток воздуха на маршруте полета

en-route updraft

ВПП, не оборудованная для точного захода на посадку

nonprecision approach runway

ВПП, не соответствующая заданию на полет

wrong runway

ВПП, оборудованная для точного захода на посадку

precision approach runway

время захода на посадку

approach time

время налета по приборам на тренажере

instrument flying simulated time

время на подготовку к обратному рейсу

turnaround time

время нахождения на ВПП

run-down occupancy time

время нахождения на земле

wheels-on time

время, необходимое на полное обслуживание и загрузку

ground turn-around time

время опробования двигателя на земле

engine ground test time

время прекращения действия ограничения на воздушное движение

traffic release time

время простоя на земле

ground time

время простоя на техническим обслуживании

maintenance ground time

входное устройство с использованием сжатия воздуха на входе

internal-compression inlet

выбранная высота захода на посадку

selected approach altitude

выбранный наклон глиссады захода на посадку

selected approach slope

вывешивать воздушное судно на подъемниках

jack an aircraft

выводить воздушное судно из сваливания на крыло

unstall the aircraft

выводить воздушное судно на заданный курс

put the aircraft on the course

выводить на заданный курс

roll on the course

выводить на курс

track out

выводить на режим малого газа

set idle power

вывод на линию пути

tracking guidance

выдерживать воздушное судно на заданном курсе

hold the aircraft on the heading

выдерживать на заданном курсе

hold on the heading

вызов на связь

1. call-in

2. aircall 3. callup вынужденная посадка воздушного судна на воду

aircraft ditching

выполнение промежуточного этапа захода на посадку

intermediate approach operation

выполнять заход на посадку

1. complete approach

2. execute approach выполнять работу на воздушном судне

work on the aircraft

выполнять уход на второй круг

execute go-around

выруливание на исполнительный старт для взлета

1. taxiing to takeoff position

2. takeoff taxiing выруливать воздушное судно на исполнительный старт

line up the aircraft

выруливать на исполнительный старт

line up

высота начального этапа захода на посадку

initial approach altitude

высота полета вертолета при заходе на посадку

helicopter approach height

высота при заходе на посадку

approach height

высота разворота на посадочную прямую

final approach altitude

высота траектории начала захода на посадку

approach ceiling

высота установленная заданием на полет

specified altitude

высота хода поршня на такте всасывания

suction head

выходить на авиатрассу

enter the airway

выходить на взлетный режим

come to takeoff power

выходить на заданную высоту

take up the position

выходить на заданную траекторию

obtain the correct path

выходить на заданный курс

1. get on the course

2. put on the course 3. roll out on the heading выходить на критический угол

reach the stalling angle

выходить на курс с левым разворотом

roll left on the heading

выходить на курс с правым разворотом

roll right on the heading

выходить на ось луча

intercept the beam

выходить на посадочную прямую

1. enter the final approach track

2. roll into final выход на закритический угол атаки

exceeding the stalling angle

выход на посадку

1. loading gate

2. gate выход на посадочный курс отворотом на расчетный угол

teardrop procedure turn

вычислитель параметров автоматического ухода на второй круг

auto go around computer

вычислитель параметров захода на посадку

approach computer

вычислитель параметров ухода на второй круг

1. overshoot computer

2. go-around computer географическое положение на данный момент

current geographical position

глиссада захода на посадку

approach glide slope

глушитель шума на выхлопе

exhaust noise suppressor

гондола двигателя на пилоне

side engine nacelle

гонка двигателя на земле

ground runup

горизонтальный полет на крейсерском режиме

level cruise

груз на внешней подвеске

1. undersling load

2. suspended load грузовая ведомость на рейс

cargo boarding list

давать разрешение на взлет

clear for takeoff

давать разрешение на левый разворот

clear for the left-hand turn

давление на аэродроме

aerodrome pressure

давление на входе в воздухозаборник

air intake pressure

давление на срезе сопла

nozzle-exit pressure

дальность видимости на ВПП

1. runway visual range

2. runway visual length дальность полета на предельно малой высоте

on-the-deck range

дальность полета на режиме авторотации

autorotation range

датчик скольжения на крыло

side-slip sensor

двигатель на режиме малого газа

idling engine

двигатель, установленный на крыле

on-wing mounted engine

двигатель, установленный на пилоне

pylon-mounted engine

движение на авиационной трассе

airway traffic

движение на пересекающихся курсах

crossing traffic

движение на сходящихся курсах

coupling traffic

девиация на основных курсах

cardinal headings deviation

действия при уходе на второй круг

go-around operations

декларация экипажа на провоз багажа

crew baggage declaration

держаться на безопасном расстоянии от воздушного судна

keep clear of the aircraft

деталь, установленная на прессовой посадке

force-fit part

диспетчер захода на посадку

approach controller

диспетчерская служба захода на посадку

approach control service

диспетчерский пункт захода на посадку

approach control point

диспетчерский пункт управления заходом на посадку

approach control unit

дистанция при заходе на посадку

approach flight track distance

дозаправлять топливом на промежуточной посадке по маршруту

refuel en-route

доклад о развороте на обратный курс

turnaround report

документация на вылет

outbound documentation

документация на прилет

inbound documentation

допуск на испытания

test margin

допуск на максимальную высоту препятствия

dominant obstacle allowance

допуск на массу воздушного судна

aircraft weight tolerance

допуск на машинную обработку

machining allowance

допуск на погрешность

margin of error

допуск на размеры воздушного судна

aircraft dimension tolerance

допуск на снижение

degradation allowance

допуск на установку

installation tolerance

доход на единицу воздушной перевозки

revenue per traffic unit

единый тариф на полет в двух направлениях

two-way fare

жесткость крыла на кручение

1. wing torsional stiffness

2. wing torsion stiffness завал на крыло

1. wing dropping

2. wing drop зависать на высоте

hover at the height of

завихрение на конце лопасти

blade-tip vortex

задержка на маршруте

delay en-route

заканчивать регистрацию на рейс

close the flight

заливная горловина на крыле

overwing filler

замок выпущенного положения ставить на замок выпущенного положения

downlock

запас топлива на борту

on-board fuel

запас топлива на рейс

block fuel

запрашивать разрешение на сертификацию

request certification for

запрещение посадки на воду

waveoff

запрос на взлет

takeoff request

запрос на посадку

landing request

запрос на руление

taxi request

заруливать на место стоянки

taxi in for parking

заруливать на место стоянки воздушного судна

enter the aircraft stand

засветка на экране локатора

radar clutter

засечка объекта на экране локатора

radar fix

заход на посадку

1. approach operation

2. approach 3. land approach 4. approach landing заход на посадку без использования навигационных средств

no-aids used approach

заход на посадку без использования средств точного захода

nonprecision approach

заход на посадку в режиме планирования

gliding approach

заход на посадку в условиях ограниченной видимости

low-visibility approach

заход на посадку на посадку под контролем наземных средств

ground controlled approach

заход на посадку на установившемся режиме

steady approach

заход на посадку не с прямой

nonstraight-in approach

заход на посадку, нормированный по времени

timed approach

заход на посадку под углом

offset approach

заход на посадку под шторками

blind approach

заход на посадку по командам наземных станций

advisory approach

заход на посадку по коробочке

rectangular traffic pattern approach

заход на посадку по криволинейной траектории

curved approach

заход на посадку по кругу

circling approach

заход на посадку по крутой траектории

steep approach

заход на посадку по курсовому маяку

localizer approach

заход на посадку по маяку

beam approach

заход на посадку по обзорному радиолокатору

surveillance radar approach

заход на посадку по обычной схеме

normal approach

заход на посадку по осевой линии

center line approach

заход на посадку по полной схеме

long approach

заход на посадку по пологой траектории

flat approach

заход на посадку по приборам

1. instrument approach landing

2. instrument landing approach заход на посадку по прямому курсу

front course approach

заход на посадку по радиолокатору

radar approach

заход на посадку по сегментно-криволинейной схеме

segmented approach

заход на посадку после полета по кругу

circle-to-land

заход на посадку по укороченной схеме

short approach

заход на посадку по упрощенной схеме

simple approach

заход на посадку при боковом ветре

crosswind approach

заход на посадку при симметричной тяге

symmetric thrust approach

заход на посадку против ветра

upwind approach

заход на посадку с выпущенными закрылками

approach with flaps down

заход на посадку с использованием бортовых и наземных средств

coupled approach

заход на посадку с левым разворотом

left-hand approach

заход на посадку с непрерывным снижением

continuous descent approach

заход на посадку с обратным курсом

1. back course approach

2. one-eighty approach заход на посадку с отворотом на расчетный угол

teardrop approach

заход на посадку с правым разворотом

right-hand approach

заход на посадку с прямой

straight-in approach

заход на посадку с прямой по приборам

straight-in ILS-type approach

заход на посадку с уменьшением скорости

decelerating approach

заявка на полет

flight request

заявка на сертификацию

application for certification

зона захода на посадку

approach area

зона захода на посадку по кругу

circling approach area

зона разворота на обратный курс

turnaround area

изменение эшелона на маршруте

en-route change of level

измерение шума при заходе на посадку

approach noise measurement

изображение на экране радиолокатора

radar screen picture

индикатор глиссады захода на посадку

approach slope indicator

индикатор на лобовом стекле

head-up display

информация о заходе на посадку

approach information

испытание на аварийное приводнение

ditching test

испытание на амортизационный ресурс

service life test

испытание на вибрацию

vibration test

испытание на воспламеняемость

ignition test

испытание на герметичность

containment test

испытание на максимальную дальность полета

full-distance test

испытание на подтверждение

substantiating test

испытание на прочность

structural test

испытание на свободное падение

free drop test

испытание на скороподъемность

climbing test

испытание на соответствие

compliance test

испытание на ударную нагрузку

1. shock test

2. impact test испытание на шум

noise test

испытание на шум при взлете

takeoff noise test

испытание на шум при пролете

flyover noise test

испытание на эффективность торможения

braking action test

испытание по уходу на второй круг

go-around test

испытания воздушного судна на перегрузки

aircraft acceleration tests

испытания воздушного судна на переменные нагрузки

aircraft alternate-stress tests

испытания на соответствие заданным техническим условиям

1. proof-of-compliance tests

2. functional tests испытания на усталостное разрушение

fatigue tests

испытания на флаттер

flatter tests

исходная высота полета при заходе на посадку

reference approach height

исходный угол захода на посадку

reference approach angle

канал связи на маршруте

on-course channel

карта местности зоны точного захода на посадку

precision approach terrain chart

карта - наряд на выполнение регламентного технического обслуживания

scheduled maintenance record

карта - наряд на выполнение технического обслуживания

maintenance release

карта - наряд на техническое обслуживание

maintenance record

карта планирования полетов на малых высотах

low altitude flight planning chart

карта прогнозов на заданное время

fixed time prognostic chart

квитанция на платный багаж

excess baggage ticket

конец этапа захода на посадку

approach end

конечная прямая захода на посадку

approach final

конечный удлиненный заход на посадку с прямой

long final straight-in-approach operation

конечный этап захода на посадку

final approach

консультативное сообщение о воздушной обстановке, регистрируемой на первичной РЛС

traffic advisory against primary radar targets

контакт с объектами на земле

ground contact

контейнер для перевозки грузов и багажа на воздушном судне

aircraft container

контракт на воздушную перевозку

air carriage contract

контракт на обслуживание в аэропорту

airport handling contract

контракт на перевозку разносортных грузов

bulk contract

контрольная площадка на аэродроме

aerodrome checkpoint

контрольная точка замера шумов на участке захода на посадку

approach noise reference point

контрольная точка захода на посадку

approach fix

контрольная точка конечного этапа захода на посадку

final approach fix

контрольная точка на маршруте

en-route fix

контрольная точка начального этапа захода на посадку

initial approach fix

контрольная точка промежуточного этапа захода на посадку

intermediate approach fix

контрольная точка траектории захода на посадку

approach flight reference point

конфигурация при полете на маршруте

en-route configuration

коррекция угла захода на посадку

approach angle correction

крепление колеса на штоке амортизатора

wheel-to-shock strut suspension

(шасси) кресло на поворотном кронштейне

swivel seat

крышка заливной горловины на крыле

overwing filler cap

курс захода на посадку

1. approach course

2. approach heading курс захода на посадку по приборам

instrument approach course

курс на радиостанцию

radio directional bearing

летательный аппарат на воздушной подушке

air-cushion vehicle

летать на автопилоте

fly on the autopilot

летать на воздушном судне

fly by an aircraft

летать на заданной высоте

fly at the altitude

летать на тренажере

fly a simulator

летать на эшелоне

fly level

линия безопасности на перроне

apron safety line

линия заруливания воздушного судна на стоянку

aircraft stand lead-in line

линия руления на место стоянки

parking bay guideline

лицензия на коммерческие перевозки

commercial license

лицензия на производство

production certificate

луч захода на посадку

approach beam

луч наведения на цель

guidance beam

люк аварийного выхода на крыло

overwing emergency exit

люк для покидания при посадке на воду

ditching hatch

максимально допустимая масса при стоянке на перроне

maximum apron mass

маневр на летном поле

airfield manoeuvre

маневр разворота на посадочный курс

circle-to-land manoeuvre

маршрут захода на посадку

procedure approach track

маршрутная карта полетов на малых высотах

low altitude en-route chart

маршрут перехода в эшелона на участок захода на посадку

feeder route

маршрут ухода на второй круг

missed approach procedure track

масштаб развертки на экране радиолокационной станции

range marker spacing

мат на крыло

wing walk mat

меры на случай аварийной посадки

emergency landing provisions

меры на случай аварийных ситуаций

provisions for emergencies

место на крыле для выполнения технического обслуживания

overwing walkway

место ожидания на рулежной дорожке

taxi-holding position

метеообслуживание на маршруте

en-route meteorological service

метеоусловия на авиалинии

airway weather

метеоусловия на аэродроме посадки

terminal weather

метеоусловия на запасном аэродроме

alternate weather

метеоусловия на маршруте

en-route weather

метеоусловия на нулевой видимости

zero-zero weather

методика испытаний при заходе на посадку

approach test procedure

метод разбивки атмосферы на слои

atmospheric layering technique

механизм измерителя крутящего момента на валу двигателя

engine torquemeter mechanism

минимальные расходы на установку

minimum installation costs

монтировать на воздушном судне

install on the aircraft

монтировать на шпангоуте

mount on the frame

мощность на валу

shaft horsepower

мощность на преодоление аэродинамического сопротивления

induced drag power

мощность на преодоление профильного сопротивления

profile drag power

мощность на режиме полетного малого газа

flight idle power

мощность на чрезвычайном режиме

contingency power

мощность, поступающая на вал трансмиссии

transmission power input

наблюдение за дальностью видимости на ВПП

runway visual range observation

набор высоты на маршруте

en-route climb

набор высоты на начальном участке установленной траектории

normal initial climb operation

набор высоты после прерванного захода на посадку

discontinued approach climb

на борту

1. aboard

2. on board наведение по азимуту при заходе на посадку

approach azimuth guidance

наведение по глиссаде при заходе на посадку

approach slope guidance

на взлете

on takeoff

на втором круге

on go-around

нагрузка на единицу площади

load per unit area

нагрузка на колесо

wheel load

нагрузка на крыло

wing load

нагрузка на поверхность управления

control surface load

нагрузка при стоянке на земле

ground load

нажимать на педаль

depress the pedal

нажимать на тормоза

engage brakes

наземный ориентир на трассе полета

en-route ground mark

на исполнительном старте

at lineup

накладная на доставку

delivery bill

накладывать ограничения на полеты

restrict the operations

на курсе

on-course

на левом траверзе

1. abeam the left pilot position

2. left abeam на максимальном газе

at full throttle

на малом газе

at idle

на маршруте

1. on route

2. en-route на пересекающихся курсах

abeam

на полной скорости

at full speed

на посадочном курсе

on final

направление захода на посадку

direction of approach

на правом траверзе

1. abeam the right pilot position

2. right abeam на протяжении всего срока службы

throughout the service life

наработка на земле

ground operating time

на режиме малого газа

at idle power

на скорости

1. on the speed

2. at a speed of на уровне земли

at the ground level

на установленной высоте

at appropriate altitude

на участке

in segment

(полета) на участке маршрута в восточном направлении

on the eastbound leg

находясь на трассе

when making way

находящийся на земле

groundborne

начальный участок захода на посадку

initial approach segment

начальный участок ухода на второй круг

initial stage of go-around

начальный этап захода на посадку

initial approach

начинать уход на второй круг

initiate go-around

не использовать возможность ухода на второй круг

fail to initiate go-around

нервюра, воспринимающая нагрузку на сжатие

compression rib

номинальная траектория захода на посадку

nominal approach path

нормы шума при полетах на эшелоне

level flight noise requirements

обеспечивать заход на посадку

serve approach

оборудование для обеспечения захода на посадку

approach facilities

обратная тяга на режиме малого газа

reverse idle thrust

обратное давление на выходе газов

exhaust back pressure

обучение на рабочем месте

on-the-job training

общий налет на определенном типе воздушного судна

on-type flight experience

общий тариф на перевозку разносортных грузов

freight-all-kinds rate

огни зоны приземления на ВПП

runway touchdown lights

огни на трассе полета

airway lights

ограничения на воздушных трассах

air rote limitations

ожидать на месте

hold the position

опробование на привязи

tie-down run

орган обеспечения безопасности на воздушном транспорте

aviation security authority

орган управления движением на перроне

apron management unit

ориентировочный прогноз на полет

provisional flight forecast

особые явления погоды на маршруте полета

en-route weather phenomena

остановка на маршруте полета

en-route stop

останов при работе на малом газе

idle cutoff

отбирать мощность на вал

take off power to the shaft

отверстие для отсоса пограничного слоя на крыле

boundary layer bleed perforation

отвечать на запрос

respond to interrogation

Отдел обслуживания проектов на местах

Field Services Branch

Отдел осуществления проектов на местах

Field Operation Branch

отработка действий на случай аварийной обстановки в аэропорту

aerodrome emergency exercise

отрицательно влиять на характеристики

adversely affect performances

отсчет показаний при полете на глиссаде

on-slope indication

оценка способности принимать на слух

aural reception test

очаг пожара на воздушном судне

aircraft fire point

очередность захода на посадку

approach sequence

падение давления на фильтре

excessive pressure drop

переводить винт на отрицательную тягу

reverse the propeller

перевозимый на воздушном шаре

planeborne

перевозка пассажиров на короткое расстояние

passenger hop

перевозчик на договорных условиях

contract carrier

перевозчик на магистральной линии

trunk carrier

перекладка реверса на прямую тягу

thrust reverser stowage

переключать на прямую тягу

return to forward thrust

переходить на ручное управление

change-over to manual control

переходить на управление с помощью автопилота

switch to the autopilot

переход на другую частоту

frequency changeover

переход на кабрирование

nose-up pitching

переход на пикирование

nose-down pitching

переход на режим висения

reconversion hovering

плавно выводить на заданный курс

smooth on the heading

планирование при заходе на посадку

approach glide

плотность воздуха на уровне моря

sea level atmospheric density

плотность движения на маршруте

route traffic density

плотность размещения кресел на воздушном судне

aircraft seating density

повторный запуск на режиме авторотации

windmilling restart

подавать жалобу на компанию

make a complaint against the company

подавать электропитание на шину

energize the bus

подземные сооружения на аэродроме

underaerodrome utilities

подниматься на борт воздушного судна

board an aircraft

подтверждение разрешения на взлет

takeoff clearance confirmation

подтверждение разрешения на посадку

landing clearance confirmation

подъем на гидроподъемниках

jacking

позывной общего вызова на связь

net call sign

покидание при посадке на воду

evacuation in ditching

полет в направлении на станцию

flight inbound the station

полет в режиме ожидания на маршруте

holding en-route operation

полет на автопилоте

autocontrolled flight

полет на аэростате

ballooning

полет на буксире

aerotow flight

полет на дальность

distance flight

полет на конечном этапе захода на посадку

final approach operation

полет на короткое расстояние

1. flip

2. short-haul flight полет на крейсерском режиме

normal cruise operation

полет на критическом угле атаки

stall flight

полет на малой высоте

low flying operation

полет на малой скорости

low-speed flight

полет на малом газе

idle flight

полет на малых высотах

low flight

полет на номинальном расчетном режиме

with rated power flight

полет на одном двигателе

single-engined flight

полет на ориентир

directional homing

полет на полном газе

full-throttle flight

полет на продолжительность

endurance flight

полет на режиме авторотации

autorotational flight

полет на среднем участке маршрута

mid-course flight

полет на участке между третьим и четвертым разворотами

base leg operation

полет по индикации на стекле

head-up flight

полеты на высоких эшелонах

high-level operations

полеты на малых высотах

low flying

положение закрылков при заходе на посадку

flap approach position

положение на линии исполнительного старта

takeoff position

получать задания на полет

receive flight instruction

помещение на аэродроме для размещения дежурных экипажей

aerodrome alert room

поправка на ветер

wind correction

поправка на взлетную массу

takeoff mass correction

поправка на воздушную скорость

airspeed compensation

поправка на высоту

altitude correction

поправка на изменение угла атаки лопасти

blade-slap correction

поправка на массу

mass correction

поправка на массу при заходе на посадку

approach mass correction

поправка на продолжительность

1. duration correction

2. duration correction factor поправка на смещение

correction for bias

поправка на снос

drift correction

поправка на снос ветром

crosswind correction

поправка на температуру

temperature correction

поправка на уход курсового гироскопа

z-correction

порядок действий по тревоге на аэродроме

aerodrome alerting procedure

порядок набора высоты на крейсерском режиме

cruise climb technique

порядок перехода на другую частоту

frequency changeover procedure

порядок установки на место стоянки

docking procedure

посадка на авторотации

autorotation landing

посадка на воду

water landing

посадка на две точки

1. level landing

2. two-point landing посадка на критическом угле атаки

stall landing

посадка на маршруте полета

intermediate landing

посадка на палубу

deck landing

посадка на режиме малого газа

idle-power

посадка на точность приземления

spot landing

посадка на три точки

three-point landing

посадка на хвост

tail-down landing

потери на трение

friction losses

правила захода на посадку

approach to land procedures

право на передачу билетов

ticket transferability

предварительная заявка на полет

advance flight plan

предел скоростей на крейсерском режиме

cruising speeds range

предоставлять права на воздушные перевозки

grant traffic privileges

предохранительная металлическая окантовка на передней кромке лопасти

blade metal cap

предполагаемое время захода на посадку

expected approach time

препятствие в зоне захода на посадку

approach area hazard

препятствие на пути полета

air obstacle

прерванный заход на посадку

discontinued approach

прерывать заход на посадку

discontinue approach

прибор для проверки кабины на герметичность

cabin tightness testing device

прибор для проверки систем на герметичность

system leakage device

пригодность для полета на местных воздушных линиях

local availability

приземляться на аэродроме

get into the aerodrome

принимать груз на борт

1. uplift the freight

2. take on load 3. take up load принимать на себя ответственность

assume responsibility

принимать на хранение

receive for storage

принимать решение идти на посадку

commit landing

принимать решение об уходе на второй круг

make decision to go-around

пробег при посадке на воду

landing water run

проверка на герметичность

1. leak test

2. pressurized leakage test проверка на исполнительном старте

lineup inspection

проверка обеспечения полетов на маршруте

route-proving trial

проверять на наличие течи

check for leakage

проверять на наличие трещин

inspect for cracks

проверять на параллельность

check for parallelism

проверять шестерни на плавность зацепления

test gears for smooth

прогноз на вылет

flight forecast

прогноз на момент взлета

takeoff forecast

прогноз на момент посадки

landing forecast

продолжать полет на аэронавигационном запасе топлива

continue operating on the fuel reserve

продолжительность работы двигателя на взлетном режиме

full-thrust duration

происшествие на территории государства регистрации воздушного судна

domestic accident

происшествие на территории другого государства

international accident

прокладывать на карте маршрут

chart a course

промежуточный этап захода на посадку

intermediate approach

пропуск на вход в аэропорт

airport laissez-passer

профиль захода на посадку

approach profile

прочность на разрыв

tensile strength

прямая тяга на режиме малого газа

forward idle thrust

прямые расходы на техническое обслуживание

direct maintenance costs

пункт выхода на связь

point of call

пункт контроля на наличие металлических предметов

metal-detection gateway

пункт управления заходом на посадку

approach control tower

работа двигателя на режиме малого газа

idling engine operation

работа на малом газе

light running

работа на режиме холостого хода

idle running

работа на смежных диапазонах

cross-band operation

работать на малом газе

run idle

работать на полном газе

run at full throttle

работать на режиме малого газа

run at idle power

работать на режиме холостого хода

run idle

работать на топливе

operate on fuel

радиолокатор точного захода на посадку

precision approach radar

радиолокатор управления заходом на посадку

approach control radar

радиолокационная система захода на посадку

approach radar system

радиолокационная система точного захода на посадку

precision approach radar system

радиопеленг на маршруте

en-route radio fix

радиосредства захода на посадку

radio approach aids

разбивать на этапы

break down into steps

(траекторию полета) разбитый на участки профиль захода на посадку

measured approach profile

разворот на курс полета

joining turn

разворот на обратный курс

reverse turn

разворот на посадку

landing turn

разворот на посадочную площадку

base turn

разворот на посадочную прямую

1. final turn

2. turn to final разворот на посадочный курс

teardrop turn

размещение воздушных судно на стоянке

parking arrangement

размещение на аэродроме

on-aerodrome location

разработка мероприятий на случай аварийной обстановки на аэродроме

aerodrome emergency planning

разрешение на беспошлинный ввоз

duty-free admittance

разрешение на ввоз

import license

разрешение на взлет

1. takeoff clearance

2. clearance for takeoff разрешение на вход

1. entry clearance

2. clearance to enter разрешение на вывоз

export license

разрешение на вылет

1. departure clearance

2. outbound clearance разрешение на выполнение воздушных перевозок

operating permit

разрешение на выполнение плана полета

flight plan clearance

разрешение на выполнение полета

permission for operation

разрешение на запуск

start-up clearance

разрешение на заход на посадку

approach clearance

разрешение на заход на посадку с прямой

clearance for straight-in approach

разрешение на начало снижения

initial descent clearance

разрешение на полет

1. flight clearance

2. operational clearance разрешение на полет в зоне ожидания

holding clearance

разрешение на полет по приборам

instrument clearance

разрешение на посадку

landing clearance

разрешение на провоз багажа

baggage clearance

разрешение на проживание иностранного пассажира

alien resident permit

разрешение на пролет границы

border flight clearance

разрешение на руление

taxi clearance

разрешение на снижение

descent clearance

разрешение на эксплуатацию воздушной линии

route license

разрешенные полеты на малой высоте

authorized low flying

районный диспетчерский центр управления движением на авиатрассе

area control center

расстояние до точки измерения при заходе на посадку

approach measurement distance

расстояние от воздушного судна до объекта на земле

air-to-ground distance

расход на крейсерском режиме

cruise consumption

расходы на аренду воздушного судна

aircraft rental costs

расходы на единицу перевозки

expenses per traffic unit

расходы на изготовление

manufacturing costs

расходы на модернизацию

development costs

расходы на оперативное обслуживание

operational expenses

расходы на техническое обслуживание

maintenance costs

расчет удельной нагрузки на поверхность

area density calculation

реагировать на отклонение рулей

respond to controls

реакция на отклонение

response to deflection

режим малого газа при заходе на посадку

approach idle

режим стабилизации на заданной высоте

height-lock mode

резкий разворот на земле

ground loop

сближение на встречных курсах

head-on approach

сбор за аэронавигационное обслуживание на трассе полета

en-route facility charge

сборник пассажирских тарифов на воздушную перевозку

Air Passenger Tariff

сбрасывать топливо на вход

bypass fuel back

сваливаться на нос

drop the nose

связь на маршруте

en-route communication

сегментная траектория захода на посадку

segmented approach path

Сектор закупок на местах

Field Purchasing Unit

Сектор найма на местах

Field Recruitment Unit

Сектор обеспечения снабжения на местах

Field Procurement Services Unit

Сектор учета кадров на местах

Field Personal Administration Unit

Секция осуществления проектов на местах

Field Operations Section

(ИКАО) Секция снабжения на местах

Field Procurement Section

(ИКАО) Секция управления кадрами на местах

Field Personnel Section

(ИКАО) сертификация по шуму на взлетном режиме

take-off noise

сигнал отклонения от курса на маяк

localizer-error signal

система автоматического захода на посадку

automatic approach system

система захода на посадку

approach system

система объявления тревоги на аэродроме

aerodrome alert system

система огней точного захода на посадку

precision approach lighting system

система предупреждения о сдвиге ветра на малых высотах

low level wind-shear alert system

система управления воздушным судном при установке на стоянку

approach guidance nose-in to stand system

скольжение на крыло

1. squashing

2. wing slide скользить на крыло

squash

(о воздушном судне) скорость захода на посадку

1. approach speed

2. landing approach speed скорость захода на посадку с убранной механизацией крыла

no-flap - no-slat approach speed

скорость захода на посадку с убранными закрылками

no-flap approach speed

скорость захода на посадку с убранными предкрылками

no-slat approach speed

скорость истечения выходящих газов на срезе реактивного сопла

nozzle exhaust velocity

скорость на начальном участке набора высоты при взлете

speed at takeoff climb

скорость полета на малом газе

flight idle speed

скорость снижения при заходе на посадку

approach rate of descent

служебная дорога на аэродроме

aerodrome service road

снежные заносы на аэродроме

aerodrome snow windrow

снижение на крейсерском режиме

cruise descent

снижение на режиме авторотации

autorotative descend operation

снижение шума при опробовании двигателей на земле

ground run-up noise abatement

совершать посадку на борт воздушного судна

join an aircraft

совершать посадку на воду

land on water

согласованный пункт выхода на связь

agreed reporting point

способ захода на посадку

approach technique

способ ухода на второй круг

go-around mode

средняя нагрузка на одно колесо

equivalent wheel load

средняя тарифная ставка на пассажиро-милю

average fare per passenger-mile

средства захода на посадку

aids to approach

срок годности при хранении на складе

shelf life

срок представления плана на полет

flight plan submission deadline

срыв потока на лопасти

1. blade slap phenomenon

2. blade slap ставить воздушный винт на полетный упор

latch the propeller flight stop

ставить воздушный винт на упор

latch a propeller

ставить на тормоз

block the brake

ставить шасси на замки

lock the landing gear

ставить шасси на замок выпущенного положения

lock the landing gear down

ставить шасси на замок убранного положения

lock the landing gear up

стандартная система захода на посадку

standard approach system

стандартная система управления заходом на посадку по лучу

standard beam approach system

стандартный заход на посадку

standard approach

створка на выходе из радиатора

radiator exit shutter

стендовые испытания на выносливость

bench-run tests

степень перепада давления на срезе сопла

nozzle exhaust pressure ratio

стойка регистрации у выхода на перрон

gate check

столкновение на встречных курсах

head-on collision

ступенчатый заход на посадку

step-down approach

стыковка рейсов на полный маршрут

end-to-end connection

судно на воздушной подушке

hovercraft

схема визуального захода на посадку

visual approach streamline

схема захода на посадку

1. approach procedure

2. approach chart 3. approach pattern схема захода на посадку без применения радиолокационных средств

nonprecision approach procedure

схема захода на посадку по командам с земли

ground-controlled approach procedure

схема захода на посадку по коробочке

rectangular approach traffic pattern

схема захода на посадку по приборам

1. instrument approach chart

2. instrument approach procedure схема разворота на посадочный круг

base turn procedure

схема точного захода на посадку

precision approach procedure

схема ухода на второй круг

1. overshoot procedure

2. missed approach procedure таможенное разрешение на провоз

clearance of goods

тариф на воздушную перевозку пассажира

air fare

тариф на оптовую чартерную перевозку

wholesale charter rate

тариф на отдельном участке полета

sectorial rate

тариф на перевозку почты

mail rate

тариф на перевозку товаров

commodity rate

тариф на полет в ночное время суток

night fare

тариф на полет по замкнутому кругу

round trip fare

тариф на полет с возвратом в течение суток

day round trip fare

тариф на путешествие

trip fare

температура газов на входе в турбину

turbine entry temperature

температура на входе

inlet temperature

температура на входе в турбину

turbine inlet temperature

температура на выходе

outlet temperature

температура на выходе из компрессора

compressor delivery temperature

температура на уровне моря

sea-level temperature

тенденция сваливания на крыло

wing heaviness

территория зоны захода на посадку

approach terrain

техника пилотирования на крейсерском режиме

aeroplane cruising technique

топливный бак, устанавливаемый на конце крыла

wingtip fuel tank

топливо на опробование

run-up fuel

топливо расходуемое на выбор высоты

climb fuel

торможение на мокрой ВПП

wet braking acquisition

тормозное устройство на ВПП

runway arresting gear

точный заход на посадку

precision approach

траектория захода на посадку

approach path

траектория захода на посадку по азимуту

azimuth approach path

траектория захода на посадку по лучу курсового маяка

localizer approach track

траектория захода на посадку, сертифицированная по шуму

noise certification approach path

траектория захода на посадку с прямой

straight-in approach path

траектория конечного этапа захода на посадку

final approach path

траектория точного захода на посадку

precision approach path

тренировочный заход на посадку

practice low approach

тяга на взлетном режиме

takeoff thrust

тяга на максимально продолжительном режиме

maximum continuous thrust

тяга на режиме максимального газа

full throttle thrust

тяга на режиме малого газа

idling thrust

тяга на установившемся режиме

steady thrust

угломестная антенна захода на посадку

approach elevation antenna

угол захода на посадку

angle of approach

угол распространения шума при заходе на посадку

approach noise angle

удельное давление колеса на грунт

wheel specific pressure

удельное давление на поверхность ВПП

footprint pressure

удельный расход топлива на кг тяги в час

thrust specific fuel consumption

удлиненный конечный этап захода на посадку

long final

удостоверение на право полета по авиалинии

airline certificate

удостоверение на право полета по приборам

instrument certificate

указатель места ожидания на рулежной дорожке

taxi-holding position sign

указатель скорости снижения на ВПП

rising runway indicator

указатель траектории точного захода на посадку

precision approach path indicator

указатель угла захода на посадку

approach angle indicator

управление в зоне захода на посадку

approach control

управление воздушным движением на трассе полета

airways control

управление на переходном режиме

control in transition

управление при выводе на курс

roll-out guidance

уровень шума при заходе на посадку

approach noise level

усилие на органах управления от автомата загрузки

artificial feel

усилие на педали

pedal force

усилие на ручку управления

stick force

усилие на систему управления

control system load

усилие на штурвале

control wheel force

усилие пилота на органах управления

pilot-applied force

условия, моделируемые на тренажере

simulated conditions

условия на маршруте

en-route environment

условия посадки на воду

ditching conditions

устанавливать на борту

install aboard

устанавливать на борту воздушного судна

install in the aircraft

устанавливать на требуемый угол

set at the desired angle

устанавливать на упор шага

latch the pitch stop

(лопасти воздушного винта) устанавливать шасси на замки выпущенного положения

lock the legs

установка в положение для захода на посадку

approach setting

установка закрылков на взлетный угол

flaps takeoff setting

установка закрылков на посадочный угол

flaps landing setting

установка на замок выпущенного положения

lockdown

установка на замок убранного положения

lockup

установка на место обслуживания

docking manoeuvre

установка на место стоянки

1. docking

2. parking manoeuvre установленная схема ухода на второй круг по приборам

instrument missed procedure

установленный на воздушном судне

airborne

установленный на двигателе

engine-mounted

устойчивость на воде

stability on water

(после аварийной посадки воздушного судна) устойчивость на курсе

course keeping ability

устойчивость на траектории полета

arrow flight stability

устойчивость при заходе на посадку

steadiness of approach

устойчивость при скольжении на крыло

side slipping stability

устройство для транспортировки древесины на внешней подвеске

timber-carrying suspending device

утопленный огонь на поверхности ВПП

runway flush light

уточнение задания на полет

flight coordination

уходить на второй круг

1. go round again

2. miss approach уходить на второй круг по заданной схеме

take a missed-approach procedure

уход на второй круг

1. go-around flight manoeuvre

2. go-around 3. missed approach 4. balked landing уход на второй круг с этапа захода на посадку

missed approach operation

участок захода на посадку

1. approach leg

2. approach segment участок захода на посадку до первого разворота

upwind leg

участок разворота на ВПП

runway turning bay

флажок на рейке

tracking flag

характеристики на разворотах

turn characteristics

центр радиолокационного управления заходом на посадку

radar approach control

частота вызова на связь

calling frequency

частота на маршруте полета

en-route frequency

число оборотов двигателя на взлетном режиме

engine takeoff speed

шаблон схемы разворота на посадочный курс

base turn template

шасси выпущено и установлено на замки выпущенного положения

landing gear is down and locked

швартовка груза на воздушном судне

aircraft cargo lashing

штуцер для проверки наддува на земле

ground pressurization connection

штуцер для проверки на земле

ground testing connection

штырь фиксации на земле

ground locking pin

эквивалентная мощность на валу

equivalent shaft power

экзамен на получение квалификационной отметки

rating test

эксплуатационные расходы на воздушное судно

aircraft operating expenses

электропроводка высокого напряжения на воздушном судне

aircraft high tension wiring

электропроводка низкого напряжения на воздушном судне

aircraft low tension wiring

этап захода на посадку

approach phase

Allen, John F.

SUBJECT AREA: Steam and internal combustion engines

[br]

b. 1829 England

d. 2 October 1900 New York (?), USA

[br]

English inventor of the Allen valve used on his pioneering high-speed engines.

[br]

Allen was taken to the United States from England when he was 12 years old. He became an engineer on the Curlew, a freight boat running between New York and Providence. A defect which caused the engine to race in rough weather led Allen to invent a new valve gear, but he found it could not be fitted to the Corliss engine. In 1856 he patented an improved form of valve and operating gear to reduce back-pressure in the cylinder, which was in fact the reverse of what happened in his later engines. In 1860 he repaired the engines of a New York felt-hat manufacturer, Henry Burr, and that winter he was introduced to Charles Porter. Porter realized the potential of Allen's valves for his idea of a high-speed engine, and the Porter-Allen engine became the pioneer of high-speed designs.

Porter persuaded Allen to patent his new valves and two patents were obtained in 1862. These valves could be driven positively and yet the travel of the inlet could be varied to give the maximum expansion at different cut-offs. Also, the valves allowed an exceptionally good flow of steam. While Porter went to England and tried to interest manufacturers there, Allen remained in America and continued work on the engine. Within a few years he invented an inclined watertube boiler, but he seemed incapable of furthering his inventions once they had been placed on the market. Although he mortgaged his own house in order to help finance the factory for building the steam engine, in the early 1870s he left Porter and built a workshop of his own at Mott Haven. There he invented important systems for riveting by pneumatic machines through both percussion and pressure which led into the production of air compressors and riveting machines.

[br]

Further Reading

Obituaries appeared in engineering journals at the time of his death.

Dictionary of American Biography, 1928, Vol. I, New York: C.Scribner's Sons. C.T.Porter, 1908, Engineering Reminiscences, New York: J.Wiley \& Sons, reprint 1985, Bradley, Ill.: Lindsay Publications (provides details of Allen's valve design).

R.L.Hills, 1989, Power from Steam. A History of the Stationary Steam Engine, Cambridge University Press (covers the development of the Porter-Allen engine).

RLH

Savery, Thomas

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering

[br]

b. c. 1650 probably Shilston, near Modbury, Devonshire, England

d. c. 15 May 1715 London, England

[br]

English inventor of a partially successful steam-driven pump for raising water.

[br]

Little is known of the early years of Savery's life and no trace has been found that he served in the Army, so the title "Captain" is thought to refer to some mining appointment, probably in the West of England. He may have been involved in the Glorious Revolution of 1688, for later he was well known to William of Orange. From 1705 to 1714 he was Treasurer for Sick and Wounded Seamen, and in 1714 he was appointed Surveyor of the Water Works at Hampton Court, a post he held until his death the following year. He was interested in mechanical devices; amongst his early contrivances was a clock.

He was the most prolific inventor of his day, applying for seven patents, including one in 1649, for polishing plate glass which may have been used. His idea for 1697 for propelling ships with paddle-wheels driven by a capstan was a failure, although regarded highly by the King, and was published in his first book, Navigation Improved (1698). He tried to patent a new type of floating mill in 1707, and an idea in 1710 for baking sea coal or other fuel in an oven to make it clean and pure.

His most famous invention, however, was the one patented in 1698 "for raising water by the impellent force of fire" that Savery said would drain mines or low-lying land, raise water to supply towns or houses, and provide a source of water for turning mills through a water-wheel. Basically it consisted of a receiver which was first filled with steam and then cooled to create a vacuum by having water poured over the outside. The water to be pumped was drawn into the receiver from a lower sump, and then high-pressure steam was readmitted to force the water up a pipe to a higher level. It was demonstrated to the King and the Royal Society and achieved some success, for a few were installed in the London area and a manufactory set up at Salisbury Court in London. He published a book, The Miner's Friend, about his engine in 1702, but although he made considerable improvements, due to excessive fuel consumption and materials which could not withstand the steam pressures involved, no engines were installed in mines as Savery had hoped. His patent was extended in 1699 until 1733 so that it covered the atmospheric engine of Thomas Newcomen who was forced to join Savery and his other partners to construct this much more practical engine.

[br]

Principal Honours and Distinctions

FRS 1706.

Bibliography

1698, Navigation Improved.

1702, The Miner's Friend.

Further Reading

The entry in the Dictionary of National Biography (1897, Vol. L, London: Smith Elder \& Co.) has been partially superseded by more recent research. The Transactions of the Newcomen Society contain various papers; for example, Rhys Jenkins, 1922–3, "Savery, Newcomen and the early history of the steam engine", Vol. 3; A.Stowers, 1961–2, "Thomas Newcomen's first steam engine 250 years ago and the initial development of steam power", Vol. 34; A.Smith, 1977–8, "Steam and the city: the committee of proprietors of the invention for raising water by fire", 1715–1735, Vol. 49; and J.S.P.Buckland, 1977–8, "Thomas Savery, his steam engine workshop of 1702", Vol. 49. Brief accounts may be found in H.W. Dickinson, 1938, A Short History of the Steam Engine, Cambridge University Press, and R.L. Hills, 1989, Power from Steam. A History of the Stationary Steam Engine, Cambridge University Press. There is another biography in T.I. Williams (ed.), 1969, A Biographical Dictionary of Scientists, London: A. \& C.Black.

RLH

Lauf

m; -(e)s, Läufe

1. run; (Wettlauf) race; (Durchgang) run; (Vorrunde) heat; der 100-Meter-Lauf the 100 met|res (Am. -ers); einen Lauf haben Sl., fig. have a run of great form, be on a roll

2. nur Sg. (Laufen) running; sich in Lauf setzen break into a run, start running; im Lauf anhalten / innehalten stop running / stop running for a moment; in vollem Lauf umg. (at) full tilt

3. nur Sg. (Bewegung) movement, motion; des Wassers: flow; TECH. running, operation; die Maschine hat einen leisen Lauf the machine (MOT. engine) is very quiet ( oder quiet-running, quiet in operation)

4. nur Sg.; fig. (Verlauf, Entwicklung) course; seinen Lauf nehmen take its course; einer Sache / den Dingen freien Lauf lassen let s.th. take its course / let things take their course; seiner Fantasie / seinen Gefühlen freien Lauf lassen give free rein to one’s emotions / imagination; stärker: let one’s emotions / imagination run wild; seinem Zorn freien Lauf lassen give vent to one’s anger; der Lauf der Ereignisse the course of events; der Lauf der Geschichte the course ( oder tide) of history; das ist der Lauf der Dinge that’s the way things are, that’s life; den Dingen ihren Lauf lassen let things take their course; den Lauf der Dinge aufhalten stop the course of events; im Laufe des Monats / Gesprächs etc. in the course of ( oder during) the month / conversation etc.; im Laufe der nächsten Woche etc. some time next week etc.; im Laufe der Jahre over the years; im Laufe der Zeit in the course of time; Vergangenheit: auch as time went on

5. nur Sg. (Verlauf eines Wegs, Flusslauf) course; am oberen / unteren Lauf des Indus along the upper / lower reaches of the Indus; dem Lauf der Straße folgen follow the (course of the) road; der Lauf der Gestirne the orbit of the stars

6. MUS. run; Koloratur: auch roulade

7. von Schusswaffen: barrel; mit zwei Läufen double-barrel(l)ed; etw. vor den Lauf bekommen Jagd und fig.: get s.th. in one’s sights

8. Jägerspr. (Bein) leg

* * *

der Lauf

(Gewehr) barrel;

(Sport) running; run;

(Verlauf) course; progress; current

* * *

[lauf]

m -(e)s, Läufe

['lɔyfə]

1) (= schneller Schritt) run; (SPORT = Wettlauf, - fahrt) race; (= Durchgang) run, race, heat

sein Láúf wurde immer schneller — he ran faster and faster

im Láúf innehalten — to stop running for a moment

2) (= Verlauf) course

im Láúfe der Jahre — in the course of the years, over or through the years

im Láúfe der Zeit — in the course of time

im Láúfe des Gesprächs — in the course of the conversation, during the conversation

freien Láúf lassen — to allow a development to take its (own) course

seiner Fantasie freien Láúf lassen — to give free rein to one's imagination

sie ließ ihren Gefühlen freien Láúf — she gave way to her feelings

seinen Láúf nehmen — to take its course

den Dingen ihren Láúf lassen — to let matters or things take their course

das ist der Láúf der Dinge or der Welt — that's the way of the world, that's the way things go

3) (= Gang, Arbeit) running, operation; (COMPUT) run

4) (=Flusslauf AUCH ASTRON) course

der obere/untere Láúf der Donau — the upper/lower reaches of the Danube

5) (= Gewehrlauf) barrel

ein Tier vor den Láúf bekommen — to get an animal in one's sights

6) (HUNT = Bein) leg

7) (MUS) run

* * *

der

1) (a long, hollow, cylindrical shape, especially the tube-shaped part of a gun: The bullet jammed in the barrel of the gun.) barrel

2) (the progress or development of events: Things will run their normal course despite the strike.) course

3) (in cricket, a batsman's act of running from one end of the wicket to the other, representing a single score: He scored/made 50 runs for his team.) run

* * *

Lauf

<-[e]s, Läufe>

[lauf, pl ˈlɔyfə]

m

1. kein pl (das Laufen) run

2. SPORT (Durchgang) round; (Rennen) heat

3. kein pl (Gang) Maschine operation

der Motor hat einen unruhigen \Lauf the engine is not running smoothly

4. kein pl GEOG (Verlauf, Bahn) course

der obere/untere \Lauf eines Flusses the upper/lower course of a river

der \Lauf dieses Sterns the track [or path] of this star

5. (Verlauf, Entwicklung) course

das ist der \Lauf der Dinge that's the way things go

der \Lauf der Welt the way of the world

seinen \Lauf nehmen to take its course

die Ereignisse nehmen ihren \Lauf events take their course

im \Laufe einer S. gen in the course of [or during] sth

im \Laufe der Jahrhunderte over the centuries

6. (Gewehrlauf) barrel

ein Tier vor den \Lauf bekommen to have an animal in one's sights

7. JAGD (Bein) leg

8.

▶ etw dat freien [o ihren] \Lauf lassen to give free rein to sth

lasst eurer Fantasie freien \Lauf let your imagination run wild

man sollte den Dingen ihren \Lauf lassen one should let things take their course

* * *

der; Lauf[e]s, Läufe

1) o. Pl. running

2) (Sport): (Wettrennen) heat

3) o. Pl. (VerLauf, Entwicklung) course

im Lauf[e] der Zeit — in the course of time

im Lauf[e] der Jahre — over the years; as the years go/went by

im Lauf[e] des Tages — during the day

einer Sache (Dat.) ihren od. freien Lauf lassen — give free rein to something

der Lauf der Geschichte/Welt — the course of history/the way of the world

seinen Lauf nehmen — take its course

4) (von Schusswaffen) barrel

etwas vor den Lauf bekommen — get a shot at something

5) o. Pl. (eines Flusses, einer Straße) course

der obere/untere Lauf eines Flusses — the upper/lower reaches pl. of a river

6) (Musik) run

7) (Jägerspr.) leg

* * *

Lauf m; -(e)s, Läufe

1. run; (Wettlauf) race; (Durchgang) run; (Vorrunde) heat;

der 100-Meter-Lauf the 100 metres (US -ers);

einen Lauf haben sl, fig have a run of great form, be on a roll

2. nur sg (Laufen) running;

sich in Lauf setzen break into a run, start running;

im Lauf anhalten/innehalten stop running/stop running for a moment;

in vollem Lauf umg (at) full tilt

3. nur sg (Bewegung) movement, motion; des Wassers: flow; TECH running, operation;

die Maschine hat einen leisen Lauf the machine (AUTO engine) is very quiet ( oder quiet-running, quiet in operation)

4. nur sg; fig (Verlauf, Entwicklung) course;

seinen Lauf nehmen take its course;

einer Sache/den Dingen freien Lauf lassen let sth take its course/let things take their course;

seiner Fantasie/seinen Gefühlen freien Lauf lassen give free rein to one’s emotions/imagination; stärker: let one’s emotions/imagination run wild;

seinem Zorn freien Lauf lassen give vent to one’s anger;

der Lauf der Ereignisse the course of events;

der Lauf der Geschichte the course ( oder tide) of history;

das ist der Lauf der Dinge that’s the way things are, that’s life;

den Dingen ihren Lauf lassen let things take their course;

den Lauf der Dinge aufhalten stop the course of events;

im Laufe des Monats/Gesprächs etc in the course of ( oder during) the month/conversation etc;

im Laufe der nächsten Woche etc some time next week etc;

im Laufe der Jahre over the years;

im Laufe der Zeit in the course of time; Vergangenheit: auch as time went on

5. nur sg (Verlauf eines Wegs, Flusslauf) course;

am oberen/unteren Lauf des Indus along the upper/lower reaches of the Indus;

dem Lauf der Straße folgen follow the (course of the) road;

der Lauf der Gestirne the orbit of the stars

6. MUS run; Koloratur: auch roulade

7. von Schusswaffen: barrel;

mit zwei Läufen double-barrel(l)ed;

etwas vor den Lauf bekommen Jagd und fig: get sth in one’s sights

8. JAGD (Bein) leg

* * *

der; Lauf[e]s, Läufe

1) o. Pl. running

2) (Sport): (Wettrennen) heat

3) o. Pl. (VerLauf, Entwicklung) course

im Lauf[e] der Zeit — in the course of time

im Lauf[e] der Jahre — over the years; as the years go/went by

im Lauf[e] des Tages — during the day

einer Sache (Dat.) ihren od. freien Lauf lassen — give free rein to something

der Lauf der Geschichte/Welt — the course of history/the way of the world

seinen Lauf nehmen — take its course

4) (von Schusswaffen) barrel

etwas vor den Lauf bekommen — get a shot at something

5) o. Pl. (eines Flusses, einer Straße) course

der obere/untere Lauf eines Flusses — the upper/lower reaches pl. of a river

6) (Musik) run

7) (Jägerspr.) leg

* * *

-e m.

course n.

current n.

gun barrel n.

run n.

Laval, Carl Gustaf Patrik de

SUBJECT AREA: Agricultural and food technology, Electricity, Mechanical, pneumatic and hydraulic engineering, Steam and internal combustion engines

[br]

b. 9 May 1845 Orsa, Sweden

d. 2 February 1913 Stockholm, Sweden

[br]

Swedish inventor of an advanced cream separator and a steam turbine.

[br]

Gustaf de Laval was educated at the Stockholm Technical Institute and Uppsala University. He proved to have an unfailing vigour and variety in his inventive talent, for his interests ranged from electric lighting and electrometallurgy to aerodynamics. In the 1890s he employed over one hundred engineers to develop his inventions, but he was best known for two: the cream separator and a steam turbine. In 1877 he invented the high-speed centrifugal cream separator, which was probably the greatest advance in butter-making up to that time. By 1880 the separators were being successfully marketed all over the world, for they were quickly adopted in larger dairies where they effected enormous savings in labour and space. He followed this with various devices for the dairy industry, including a vacuum milking machine perfected in 1913. In c. 1882, de Laval invented a turbine on the principle of Hero's engine, but he quickly turned his attention to the impulse type, which was like Branca's, with a jet of steam impinging on a set of blades around the periphery of a wheel. He applied for a British patent in 1889. The steam was expanded in a single stage from the initial to the final pressure: to secure economy with the steam issuing at high velocity, the blades also had to rotate at high velocity. An early 5 hp (3.7 kW) turbine rotated at 30,000 rpm, so reduction gearing had to be introduced. Production started in Sweden in 1893 and in other countries at about the same time. In 1892 de Laval proposed employing one of his turbines of 15 hp (11 kW) in an experimental launch, but there is no evidence that it was ever actually installed in a vessel. However, his turbines were popular for powering electric generating sets for lighting textile mills and ships, and by 1900 were available in sizes up to 300 bhp (224 kW).

[br]

Bibliography

1889, British patent no. 7,143 (steam turbine).

Further Reading

T.Althin, 1943, Life of de Laval, Stockholm (a full biography).

T.I.Williams (ed.), 1969, A Biographical Dictionary of Scientists, London: A. \& C. Black (contains a brief biography).

R.M.Neilson, 1902, The Steam Turbine, London: Longmans, Green \& Co. (fully covers the development of de Laval's steam turbine).

H.W.Dickinson, 1938, A Short History of the Steam Engine, Cambridge University Press (contains a short account of the development of the steam turbine).

R.L.Hills, 1989, Power from Steam. A History of the Stationary Steam Engine, Cambridge University Press (contains a short account).

RLH

Murray, Matthew

SUBJECT AREA: Land transport, Mechanical, pneumatic and hydraulic engineering, Railways and locomotives, Steam and internal combustion engines

[br]

b. 1765 near Newcastle upon Tyne, England

d. 20 February 1826 Holbeck, Leeds, England

[br]

English mechanical engineer and steam engine, locomotive and machine-tool pioneer.

[br]

Matthew Murray was apprenticed at the age of 14 to a blacksmith who probably also did millwrighting work. He then worked as a journeyman mechanic at Stockton-on-Tees, where he had experience with machinery for a flax mill at Darlington. Trade in the Stockton area became slack in 1788 and Murray sought work in Leeds, where he was employed by John Marshall, who owned a flax mill at Adel, located about 5 miles (8 km) from Leeds. He soon became Marshall's chief mechanic, and when in 1790 a new mill was built in the Holbeck district of Leeds by Marshall and his partner Benyon, Murray was responsible for the installation of the machinery. At about this time he took out two patents relating to improvements in textile machinery.

In 1795 he left Marshall's employment and, in partnership with David Wood (1761– 1820), established a general engineering and millwrighting business at Mill Green, Holbeck. In the following year the firm moved to a larger site at Water Lane, Holbeck, and additional capital was provided by two new partners, James Fenton (1754–1834) and William Lister (1796–1811). Lister was a sleeping partner and the firm was known as Fenton, Murray \& Wood and was organized so that Fenton kept the accounts, Wood was the administrator and took charge of the workshops, while Murray provided the technical expertise. The factory was extended in 1802 by the construction of a fitting shop of circular form, after which the establishment became known as the "Round Foundry".

In addition to textile machinery, the firm soon began the manufacture of machine tools and steam-engines. In this field it became a serious rival to Boulton \& Watt, who privately acknowledged Murray's superior craftsmanship, particularly in foundry work, and resorted to some industrial espionage to discover details of his techniques. Murray obtained patents for improvements in steam engines in 1799, 1801 and 1802. These included automatic regulation of draught, a mechanical stoker and his short-D slide valve. The patent of 1801 was successfully opposed by Boulton \& Watt. An important contribution of Murray to the development of the steam engine was the use of a bedplate so that the engine became a compact, self-contained unit instead of separate components built into an en-gine-house.

Murray was one of the first, if not the very first, to build machine tools for sale. However, this was not the case with the planing machine, which he is said to have invented to produce flat surfaces for his slide valves. Rather than being patented, this machine was kept secret, although it was apparently in use before 1814.

In 1812 Murray was engaged by John Blenkinsop (1783–1831) to build locomotives for his rack railway from Middleton Colliery to Leeds (about 3 1/2 miles or 5.6 km). Murray was responsible for their design and they were fitted with two double-acting cylinders and cranks at right angles, an important step in the development of the steam locomotive. About six of these locomotives were built for the Middleton and other colliery railways and some were in use for over twenty years. Murray also supplied engines for many early steamboats. In addition, he built some hydraulic machinery and in 1814 patented a hydraulic press for baling cloth.

Murray's son-in-law, Richard Jackson, later became a partner in the firm, which was then styled Fenton, Murray \& Jackson. The firm went out of business in 1843.

[br]

Principal Honours and Distinctions

Society of Arts Gold Medal 1809 (for machine for hackling flax).

Further Reading

L.T.C.Rolt, 1962, Great Engineers, London (contains a good short biography).

E.Kilburn Scott (ed.), 1928, Matthew Murray, Pioneer Engineer, Leeds (a collection of essays and source material).

C.F.Dendy Marshall, 1953, A History of Railway Locomotives Down to the End of the

Year 1831, London.

L.T.C.Rolt, 1965, Tools for the Job, London; repub. 1986 (provides information on Murray's machine-tool work).

Some of Murray's correspondence with Simon Goodrich of the Admiralty has been published in Transactions of the Newcomen Society 3 (1922–3); 6(1925–6); 18(1937– 8); and 32 (1959–60).

RTS

Parsons, Sir Charles Algernon

SUBJECT AREA: Electricity, Ports and shipping

[br]

b. 13 June 1854 London, England

d. 11 February 1931 on board Duchess of Richmond, Kingston, Jamaica

[br]

English eingineer, inventor of the steam turbine and developer of the high-speed electric generator.

[br]

The youngest son of the Earl of Rosse, he came from a family well known in scientific circles, the six boys growing up in an intellectual atmosphere at Birr Castle, the ancestral home in Ireland, where a forge and large workshop were available to them. Charles, like his brothers, did not go to school but was educated by private tutors of the character of Sir Robert Ball, this type of education being interspersed with overseas holiday trips to France, Holland, Belgium and Spain in the family yacht. In 1871, at the age of 17, he went to Trinity College, Dublin, and after two years he went on to St John's College, Cambridge. This was before the Engineering School had opened, and Parsons studied mechanics and mathematics.

In 1877 he was apprenticed to W.G.Armstrong \& Co. of Elswick, where he stayed for four years, developing an epicycloidal engine that he had designed while at Cambridge. He then moved to Kitson \& Co. of Leeds, where he went half shares in a small experimental shop working on rocket propulsion for torpedoes.

In 1887 he married Katherine Bethell, who contracted rheumatic fever from early-morning outdoor vigils with her husband to watch his torpedo experiments while on their honeymoon! He then moved to a partnership in Clarke, Chapman \& Co. at Gateshead. There he joined the electrical department, initially working on the development of a small, steam-driven marine lighting set. This involved the development of either a low-speed dynamo, for direct coupling to a reciprocating engine, or a high-speed engine, and it was this requirement that started Parsons on the track of the steam turbine. This entailed many problems such as the running of shafts at speeds of up to 40,000 rpm and the design of a DC generator for 18,000 rpm. He took out patents for both the turbine and the generator on 23 April 1884. In 1888 he dissolved his partnership with Clarke, Chapman \& Co. to set up his own firm in Newcastle, leaving his patents with the company's owners. This denied him the use of the axial-flow turbine, so Parsons then designed a radial-flow layout; he later bought back his patents from Clarke, Chapman \& Co. His original patent had included the use of the steam turbine as a means of marine propulsion, and Parsons now set about realizing this possibility. He experimented with 2 ft (61 cm) and 6 ft (183 cm) long models, towed with a fishing line or, later, driven by a twisted rubber cord, through a single-reduction set of spiral gearing.

The first trials of the Turbinia took place in 1894 but were disappointing due to cavitation, a little-understood phenomenon at the time. He used an axial-flow turbine of 2,000 shp running at 2,000 rpm. His work resulted in a far greater understanding of the phenomenon of cavitation than had hitherto existed. Land turbines of up to 350 kW (470 hp) had meanwhile been built. Experiments with the Turbinia culminated in a demonstration which took place at the great Naval Review of 1897 at Spithead, held to celebrate Queen Victoria's Diamond Jubilee. Here, the little Turbinia darted in and out of the lines of heavy warships and destroyers, attaining the unheard of speed of 34.5 knots. The following year the Admiralty placed their first order for a turbine-driven ship, and passenger vessels started operation soon after, the first in 1901. By 1906 the Admiralty had moved over to use turbines exclusively. These early turbines had almost all been direct-coupled to the ship's propeller shaft. For optimum performance of both turbine and propeller, Parsons realized that some form of reduction gearing was necessary, which would have to be extremely accurate because of the speeds involved. Parsons's Creep Mechanism of 1912 ensured that any errors in the master wheel would be distributed evenly around the wheel being cut.

Parsons was also involved in optical work and had a controlling interest in the firm of Ross Ltd of London and, later, in Sir Howard Grubb \& Sons. He he was an enlightened employer, originating share schemes and other benefits for his employees.

[br]

Principal Honours and Distinctions

Knighted. Order of Merit 1927.

Further Reading

A.T.Bowden, 1966, "Charles Parsons: Purveyor of power", in E.G.Semler (ed.), The Great Masters. Engineering Heritage, Vol. II, London: Institution of Mechanical Engineers/Heinemann.

IMcN

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

Ricardo, Sir Harry Ralph

SUBJECT AREA: Aerospace, Steam and internal combustion engines

[br]

b. 26 January 1885 London, England

d. 18 May 1974 Graffham, Sussex, England

[br]

English mechanical engineer; researcher, designer and developer of internal combustion engines.

[br]

Harry Ricardo was the eldest child and only son of Halsey Ricardo (architect) and Catherine Rendel (daughter of Alexander Rendel, senior partner in the firm of consulting civil engineers that later became Rendel, Palmer and Tritton). He was educated at Rugby School and at Cambridge. While still at school, he designed and made a steam engine to drive his bicycle, and by the time he went up to Cambridge in 1903 he was a skilled craftsman. At Cambridge, he made a motor cycle powered by a petrol engine of his own design, and with this he won a fuel-consumption competition by covering almost 40 miles (64 km) on a quart (1.14 1) of petrol. This brought him to the attention of Professor Bertram Hopkinson, who invited him to help with research on turbulence and pre-ignition in internal combustion engines. After leaving Cambridge in 1907, he joined his grandfather's firm and became head of the design department for mechanical equipment used in civil engineering. In 1916 he was asked to help with the problem of loading tanks on to railway trucks. He was then given the task of designing and organizing the manufacture of engines for tanks, and the success of this enterprise encouraged him to set up his own establishment at Shoreham, devoted to research on, and design and development of, internal combustion engines.

Leading on from the work with Hopkinson were his discoveries on the suppression of detonation in spark-ignition engines. He noted that the current paraffinic fuels were more prone to detonation than the aromatics, which were being discarded as they did not comply with the existing specifications because of their high specific gravity. He introduced the concepts of "highest useful compression ratio" (HUCR) and "toluene number" for fuel samples burned in a special variable compression-ratio engine. The toluene number was the proportion of toluene in heptane that gave the same HUCR as the fuel sample. Later, toluene was superseded by iso-octane to give the now familiar octane rating. He went on to improve the combustion in side-valve engines by increasing turbulence, shortening the flame path and minimizing the clearance between piston and head by concentrating the combustion space over the valves. By these means, the compression ratio could be increased to that used by overhead-valve engines before detonation intervened. The very hot poppet valve restricted the advancement of all internal combustion engines, so he turned his attention to eliminating it by use of the single sleeve-valve, this being developed with support from the Air Ministry. By the end of the Second World War some 130,000 such aero-engines had been built by Bristol, Napier and Rolls-Royce before the piston aero-engine was superseded by the gas turbine of Whittle. He even contributed to the success of the latter by developing a fuel control system for it.

Concurrent with this was work on the diesel engine. He designed and developed the engine that halved the fuel consumption of London buses. He invented and perfected the "Comet" series of combustion chambers for diesel engines, and the Company was consulted by the vast majority of international internal combustion engine manufacturers. He published and lectured widely and fully deserved his many honours; he was elected FRS in 1929, was President of the Institution of Mechanical Engineers in 1944–5 and was knighted in 1948. This shy and modest, though very determined man was highly regarded by all who came into contact with him. It was said that research into internal combustion engines, his family and boats constituted all that he would wish from life.

[br]

Principal Honours and Distinctions

Knighted 1948. FRS 1929. President, Institution of Mechanical Engineers 1944–5.

Bibliography

1968, Memo \& Machines. The Pattern of My Life, London: Constable.

Further Reading

Sir William Hawthorne, 1976, "Harry Ralph Ricardo", Biographical Memoirs of Fellows of the Royal Society 22.

JB