engine manufacturing industry

engine manufacturing industry

Авиация: двигателестроительная промышленность

Engine, Turbine, and Power Transmission Equipment Manufacturing

эк., стат., амер. производство двигателей, турбин и оборудования для передаточных устройств* (по NAICS 2002: отраслевая группа, в которую включены организации, занимающиеся производством турбин (кроме авиационных), генераторных турбин, двигателей внутреннего сгорания (кроме автомобильных), элементов коробок переключения скоростей (подшипников, муфт, передаточных цепей))

See:

North American Industry Classification System, Machinery Manufacturing

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

vehicle

сухопутное перевозочное средство (автомобиль, автобус, вагон, экипаж); средство передвижения; транспортное средство; средство доставки

- vehicle-actuated gauge

- vehicle anchor - vehicle capacity

- vehicle car

- vehicle clearance circle

- vehicle company

- vehicle drag test

- vehicle exhaust fan

- vehicle group - vehicle hoist - vehicle landing craft - vehicle laws - vehicle manufacturing industry - vehicle mobility - vehicle operation - vehicle repair depot - vehicle reserve depot - vehicle shed - vehicle shipment - vehicle shipping card - vehicle sinkage - vehicle taxes - vehicle traction coefficient - vehicle upkeep operation - vehicle weapon - air-cushion vehicle - ACV

- air-transportable vehicle

- all-equipped vehicle

- all-purpose vehicle

- all-service vehicle

- all-service military vehicle

- all-wheel drive vehicle

- ammunition vehicle

- amphibious vehicle - annular jet air-cushion vehicle - annular jet ACV

- armoured vehicle

- army tactical vehicle

- articulated vehicle

- battery-driven vehicle

- blitz vehicle

- break-down vehicle

- cab-forward type vehicle

- cab-over-engine vehicle

- captured vehicle

- cargo vehicle

- carrier vehicle

- civil vehicle

- combat vehicle

- command vehicle

- commercial vehicle

- commercial motor vehicle

- compressed gas vehicle

- convertible vehicle

- crawler-type vehicle

- cross-country vehicle

- cruising vehicle

- Diesel-powered vehicle

- emergency service vehicle

- endless-track vehicle

- excursion vehicle

- exempt vehicle - fire-fighting vehicle

- forward control vehicle

- frameless vehicle

- freight vehicle

- full-track vehicle

- gas-electric vehicle

- gas-producer vehicle

- general-purpose vehicle

- go-anywhere vehicle

- goods vehicle

- goods-carrying vehicle

- ground vehicle

- hackney vehicle

- half-track vehicle

- half-tracked vehicle

- heavy vehicle

- heavy traction vehicle

- high-wheeled vehicle

- hired vehicle

- horse vehicle

- industrial vehicle

- juvenile motor vehicle

- landing vehicle

- lead vehicle

- light-duty vehicle

- long-distance vehicle

- mechanical vehicle

- mechanically propelled vehicle

- medical vehicle

- military wheeled vehicle

- motor vehicle

- motor passenger vehicle

- motor transport vehicle

- motor-vehicle proving ground

- motor-vehicle proving grounds

- motor-vehicle testing track

- motor-vehicle testing course

- non-runner vehicle

- off-road vehicle

- on-coming vehicle - outing vehicle

- overhead-type vehicle

- oversize vehicle

- overweight vehicle

- parked vehicles

- passenger vehicle

- passenger service vehicle

- pedestrian-controlled vehicle

- private vehicle

- propane-powered vehicle

- public-service vehicle

- rail vehicle

- rear-loading vehicle

- recovery vehicle

- rescue vehicle

- sanding vehicle

- screening vehicle

- searchlight vehicle

- self-loading vehicle

- side-loading vehicle

- six-wheeled vehicle

- snow-fighting vehicle

- special-purpose vehicle

- sport utility vehicle

- SUV

- stationary vehicle

- sterilizing vehicle

- street vehicle

- street cleaning vehicle

- tactical vehicle

- test vehicle

- tool vehicle

- towed vehicle

- towing vehicle - toy motor vehicle

- tracked vehicle

- tracked cross-country vehicle

- track-laying vehicle

- track-type vehicle

- transport vehicle

- two-axle vehicle

- two-engined vehicle

- unauthorised vehicle

- undertyred vehicle - unmanned vehicle - utility vehicle - war-surplus vehicle - water purification vehicle - wheeled air-cushion vehicle - wheeled ACV - wheeled military vehicle - winterized vehicle - wire-laying vehicle

Sopwith, Sir Thomas (Tommy) Octave Murdoch

SUBJECT AREA: Aerospace

[br]

b. 18 January 1888 London, England

d. 27 January 1989 Stockbridge, Hampshire, England

[br]

English aeronautical engineer and industrialist.

[br]

Son of a successful mining engineer, Sopwith did not shine at school and, having been turned down by the Royal Navy as a result, attended an engineering college. His first interest was motor cars and, while still in his teens, he set up a business in London with a friend in order to sell them; he also took part in races and rallies.

Sopwith's interest in aviation came initially through ballooning, and in 1906 he purchased his own balloon. Four years later, inspired by the recent flights across the Channel to France and after a joy-ride at Brooklands, he bought an Avis monoplane, followed by a larger biplane, and taught himself to fly. He was awarded the Royal Aero Society's Aviator Certificate No. 31 on 21 November 1910, and he quickly distinguished himself in flying competitions on both sides of the Atlantic and started his own flying school. In his races he was ably supported by his friend Fred Sigrist, a former motor engineer. Among the people Sopwith taught to fly were an Australian, Harry Hawker, and Major Hugh Trenchard, who later became the "father" of the RAF.

In 1912, depressed by the poor quality of the aircraft on trial for the British Army, Sopwith, in conjunction with Hawker and Sigrist, bought a skating rink in Kingston-upon-Thames and, assisted by Fred Sigrist, started to design and build his first aircraft, the Sopwith Hybrid. He sold this to the Royal Navy in 1913, and the following year his aviation manufacturing company became the Sopwith Aviation Company Ltd. That year a seaplane version of his Sopwith Tabloid won the Schneider Trophy in the second running of this speed competition. During 1914–18, Sopwith concentrated on producing fighters (or "scouts" as they were then called), with the Pup, the Camel, the 1½ Strutter, the Snipe and the Sopwith Triplane proving among the best in the war. He also pioneered several ideas to make flying easier for the pilot, and in 1915 he patented his adjustable tailplane and his 1 ½ Strutter was the first aircraft to be fitted with air brakes. During the four years of the First World War, Sopwith Aviation designed thirty-two different aircraft types and produced over 16,000 aircraft.

The end of the First World War brought recession to the aircraft industry and in 1920 Sopwith, like many others, put his company into receivership; none the less, he immediately launched a new, smaller company with Hawker, Sigrist and V.W.Eyre, which they called the H.G. Hawker Engineering Company Ltd to avoid any confusion with the former company. He began by producing cars and motor cycles under licence, but was determined to resume aircraft production. He suffered an early blow with the death of Hawker in an air crash in 1921, but soon began supplying aircraft to the Royal Air Force again. In this he was much helped by taking on a new designer, Sydney Camm, in 1923, and during the next decade they produced a number of military aircraft types, of which the Hart light bomber and the Fury fighter, the first to exceed 200 mph (322 km/h), were the best known. In the mid-1930s Sopwith began to build a large aviation empire, acquiring first the Gloster Aircraft Company and then, in quick succession, Armstrong-Whitworth, Armstrong-Siddeley Motors Ltd and its aero-engine counterpart, and A.V.Roe, which produced Avro aircraft. Under the umbrella of the Hawker Siddeley Aircraft Company (set up in 1935) these companies produced a series of outstanding aircraft, ranging from the Hawker Hurricane, through the Avro Lancaster to the Gloster Meteor, Britain's first in-service jet aircraft, and the Hawker Typhoon, Tempest and Hunter. When Sopwith retired as Chairman of the Hawker Siddeley Group in 1963 at the age of 75, a prototype jump-jet (the P-1127) was being tested, later to become the Harrier, a for cry from the fragile biplanes of 1910.

Sopwith also had a passion for yachting and came close to wresting the America's Cup from the USA in 1934 when sailing his yacht Endeavour, which incorporated a number of features years ahead of their time; his greatest regret was that he failed in his attempts to win this famous yachting trophy for Britain. After his retirement as Chairman of the Hawker Siddeley Group, he remained on the Board until 1978. The British aviation industry had been nationalized in April 1977, and Hawker Siddeley's aircraft interests merged with the British Aircraft Corporation to become British Aerospace (BAe). Nevertheless, by then the Group had built up a wide range of companies in the field of mechanical and electrical engineering, and its board conferred on Sopwith the title Founder and Life President.

[br]

Principal Honours and Distinctions

Knighted 1953. CBE 1918.

Bibliography

1961, "My first ten years in aviation", Journal of the Royal Aeronautical Society (April) (a very informative and amusing paper).

Further Reading

A.Bramson, 1990, Pure Luck: The Authorized Biography of Sir Thomas Sopwith, 1888– 1989, Wellingborough: Patrick Stephens.

B.Robertson, 1970, Sopwith. The Man and His Aircraft, London (a detailed publication giving plans of all the Sopwith aircraft).

CM / JDS

MEP

1) Американизм: Major Emphasis Program, Migrant Employment Program

2) Военный термин: Management Engineering Plan, Master Evaluation Plan, Minuteman education program, Mission Essential Power, Multiple Entry Points, major electronics procurement, management engineering program, management evaluation program, medical education program, mission equipment package, mobile electric power, Mission Enhancement Program (AWACS), Ministry of Electronics Industry (FSU)

3) Техника: Member of European Parliament

4) Химия: Methanol Equivalent Productivity

5) Строительство: (mechanical, electrical, plumbing) инженерные сети

6) Математика: принцип максимальной энтропии (maximum entropy principle)

7) Сокращение: Mail Exit Point, Management Engineering Programme, Master of Engineering Physics, Medium External Pintle (Belgium), Member of the European Paliament, Member of the European Parliament, Microelectronics Package, Middle East Perspective, Multiple Equipment Package, mean probable error, men employed, moon-earth-plane, смежные (инженерные) разделы (mechanical, electrical, plumbing), Члены Европарламента (Members of the European Parliament)

8) Физиология: Maximum Expiratory Pressure, Motor Evoked Potentials

9) Фирменный знак: Mechanical Electrical Plumbing

10) Деловая лексика: Manufacturing Extension Partnership

11) Сетевые технологии: Message Exchange Pattern, Most Effective Profile

12) Полимеры: methylethylpyridine

13) Макаров: молекулярный электростатический потенциал

14) Должность: Multi Engine Pilot

mep

1) Американизм: Major Emphasis Program, Migrant Employment Program

2) Военный термин: Management Engineering Plan, Master Evaluation Plan, Minuteman education program, Mission Essential Power, Multiple Entry Points, major electronics procurement, management engineering program, management evaluation program, medical education program, mission equipment package, mobile electric power, Mission Enhancement Program (AWACS), Ministry of Electronics Industry (FSU)

3) Техника: Member of European Parliament

4) Химия: Methanol Equivalent Productivity

5) Строительство: (mechanical, electrical, plumbing) инженерные сети

6) Математика: принцип максимальной энтропии (maximum entropy principle)

7) Сокращение: Mail Exit Point, Management Engineering Programme, Master of Engineering Physics, Medium External Pintle (Belgium), Member of the European Paliament, Member of the European Parliament, Microelectronics Package, Middle East Perspective, Multiple Equipment Package, mean probable error, men employed, moon-earth-plane, смежные (инженерные) разделы (mechanical, electrical, plumbing), Члены Европарламента (Members of the European Parliament)

8) Физиология: Maximum Expiratory Pressure, Motor Evoked Potentials

9) Фирменный знак: Mechanical Electrical Plumbing

10) Деловая лексика: Manufacturing Extension Partnership

11) Сетевые технологии: Message Exchange Pattern, Most Effective Profile

12) Полимеры: methylethylpyridine

13) Макаров: молекулярный электростатический потенциал

14) Должность: Multi Engine Pilot

develop

1. I

abs

1) his character is developing его характер формируется; our friendship has developed наша дружба окрепла

2) new facts (some additional details, certain circumstances, etc.) have developed обнаружились /выяснились/ новые факты и т. д.; а new feature of the case developed a) обнаружилась /возникла/ еще одна сторона дела; б) дело приняло новый оборот; а rash (new symptoms, a fever, etc.) developed появилась сыпь и т. д., an ulcer developed образовалась язва

2. II

develop in some manner

1) develop harmoniously (gradually, physically, morally. culturally,.etc.) гармонично и т. д. развиваться; the boy has developed intellectually мальчик интеллектуально развился; the plot (the story, the play. etc.) develops rapidly сюжет и т. д. развивается /развёртывается/ стремительно; develop in every way (a lot, by leaps and bounds, etc.) развиваться всеми способами или во всех отношениях и т. д.

2) develop gradually (partially, etc.) проявляться постепенно и т. д.; this type of film develops quickly этот вид пленки проявляется быстро; these photographs haven't developed very well эти фотографии плохо вышли /проявились/

3. III

develop smth.

1) develop the country's industry (a district, a coal area, etc.) развивать промышленность страны и т. д., develop the natural resources of a country разрабатывать природные богатства страны; we shall develop this mine будем разрабатывать /осваивать/ эту шахту: they are developing a new manufacturing process они разрабатывают новый технологический процесс: he developed his business он расширил свое дело

2) develop different muscles (the strength of one's fingers. healthy bodies, one's memory, one's brain, the mind, etc.) укреплять /развивать, тренировать разные мышцы и т. д.

3) develop exotic flowers (hot house tomatoes, subtropical fruit, etc.) выращивать экзотические цветы и т. д.; develop new forms of the plant выводить новые сорта растения; heat and moisture develop seed тепло и влага способствуют росту /развитию/ семян; different conditions have developed different forms of life разные условия привели к появлению разных форм жизни; this engine develops a lot of heat Этот мотор сильно нагревается

4) develop new facts (new features, certain details, etc.) обнаруживать /вскрывать/ новые факты и т. д.; the inquiry developed unforeseen aspects of the case при расследовании обнаружились неожиданные стороны этого дела

5) he developed symptoms of consumption (of a fever, of a cough. of a tumour, etc.) у него появились симптомы чахотки и т. д.', he seems to be developing an illness он. кажется, заболевает; the child developed whooping cough у ребенка начался коклюш

6) develop a subject (the plot of a play, an argument, a plan, an idea. a line of thought, etc.) разрабатывать /развивать/ тему и т. д; you should develop this theme вам следует развить эту тему

7) develop one's films (the plates, a photograph, etc.) проявлять [отснятую] пленку и т. д.

4. IV

develop smth. in some manner develop this idea (this subject, the theme, etc.) a little more fully развить /разработать/ эту мысль и т. д. полнее

5. XI

1) be developed in some manner be rather poorly developed быть плохо развитым, отставать в развитии; he is well developed mentally умственно он хорошо развит; be developed at /in/ some place in this school children's gifts are developed в этой школе обращают особое внимание на развитие природных талантов у детей

2) be developed somewhere this plate may be developed at home эту пластинку можно проявлять в домашних условиях

6. XVI

develop from /out of/ smth. develop from a seed (from a simpler machine, from an acorn, etc.) развиваться из зерна и т. д., this town developed out of a fishing village этот город вырос из /на месте/ рыбацкого поселка; develop Into smth. develop into plants (into beautiful butterflies, etc.) превращаться в растения и т. д, their acquaintance has developed into friendship их знакомство перешло в дружбу; develop Into smb. the boy developed into a good man из мальчика вырос хороший человек; - in some place develop in the author's mind созревать /зреть/ в уме автора

7. XXI1

1) develop smth. for smth. develop a gift (a taste, a habit, etc.) for smth. развивать талант и т. д. к чему-л.

2) develop smth. in some time I shall develop the film in twenty minutes я проявлю эту пленку за двадцать минут

plant

1) установка; оборудование

2) агрегат; механизм; энергоблок

3) завод, фабрика, мастерская

4) электростанция

5) озеленять, сажать

•

plant and machinery register — реестр машин и оборудования (напр. строительной компании)

plant for technical ceramics and verified ceramics — установка для производства технической керамики и металлокерамики

plant for the preparation and transport of mastic asphalt — установка для подготовки и транспортировки литого асфальта

plant for the production of concrete polymer construction elements — установка для изготовления элементов из полимерного бетона

to reconstruct a plant — реконструировать завод

- accumulator plant

- activated sludge plant - aggregate batching plant - air-conditioning plant - air-supply plant - arc welding plant - asphalt plant - asphalt-mixing plant - asphalt preparation plant - asphalt-recycling plant - assembling plant - atomic power plant - automated concrete-mixing plant - automatic plant - batch plant - batch concrete mixing plant - batching plant - batch-weighing plant - biological treatment plant - bitumastic macadam mixing plant - bitumen-melting plant - bitumen-pumping plant - boiler plant - brick plant - facing brick plant - roof tile plant - brick-making plant - builder's plant - calcining plant - cement plant - central boiler plant - central mixing plant - chlorination plant - clarification plant - clay-drying plant - clay souring plant - coal grinding plant - coating plant - combined milling and burning plant - combined photovolcanic-deolian electric plant - compressor plant - concrete-mixing plant - concreting plant - construction plant - contractor's plant - crushing plant - crushing and screening plant - curing plants for the concrete block and precast concrete part industry - cutting plant - degreasing plant - desalination plant - diesel-engine power plant - disinfection plant - district heating plant - drying plant - earth freezing plant - earth-moving plant - effluent treatment plant - electric power plant - expanded clay plant - filter plant - final-screening plant - finish coat stacking and dry mixing mortar plant - fixed plant - flash-calcining plant - floating pile-driving plant - flotation plant - fuel-burning power plant - garbage-disposal plant - gas-fired plant - gravel plant - grinding wheel plant - grit-removal plant - heating plant - high head plant - hoisting plant - hydroelectric power plant - industrial plant - iron removal plant - light plant - lime-slaking plant - lime softening plant - loading plant - low head hydroelectric plant - manganese removal plant - milling plant - mixing plant - mixing plant and pavers for hydraulically bound base courses - mobile compressor plant - mobile concrete mixing plant - mobile crushing plant - mobile rock crushing and screening plant - mortar-mixing plant - multiple-arc welding plant - municipal sewage treatment plant - nuclear power plant - orbital power plant - ozone plant - ozone-ventilating plant - piling plant - pilot plant - placing plant - plaster plant - pontoon pile driving plant - portable compressor plant for painting work - power plant - primary treatment plant - proportioning plant - pump plant - pumping plant - pumped storage plant - purification plant - quarry plant - ready-mix plant - refrigerating plant - reverse osmosis plant - sand washing plant - sanitary ware plant - porcelain plant - secondary treatment plant - sedimentation plant - semi-mobile plant - semi-portable plant - sewage disposal plant - sewage pumping plant - sewage purification plant - sewage treatment plant - sintering plant - soil-mixing plant - solar plant - spraying plant - standby plant - steam plant - step-up plant - stoneware plant - tertiary plant - thermal power plant - tidal plant - tile-making plant - timber drying plant - tower-type concrete-mixing plant - transformer welding plant - travel plant - travelling mixing plant - treating plant - treatment plant - utility plant - vacuum-cleaning plant - vibration-rolled concrete plant - wall and floor tiles plant - washing plant - waste water treatment plant - water power plant - water softening plant - water treatment plant

* * *

1.   оборудование инженерных систем здания

2.   строительное оборудование (напр. землеройное, подъёмно-транспортное, для бетонных работ)

3.   установка; агрегат; энергоблок; технологическая установка [система] ( в инженерных системах зданий)

4.   электростанция

5.   завод, фабрика; мастерская

- acetylene producing plant
- activated sludge plant
- aeration plant
- aeration-degassing plant
- aggregate batching plant
- aggregate preparation plant
- air conditioning plant
- air handling plant
- air supply plant
- all-dry cement plant
- all-wet cement plant
- augering plant
- automatic batching plant
- bank-filtered river water plant
- barge-mounted concrete plant
- batch plant
- batch mixing plant
- biological treatment plant
- block-making plant
- block plant
- boiler plant
- booster pumping plant
- builder's plant
- builder's small powered plant
- cement plant
- central plant
- central air conditioning plant
- central air-handling plant
- central boiler plant
- central heating plant
- central refrigerating plant
- chemical feed plant
- chlorination plant
- civil-engineering plant
- coating plant
- cold-storage plant
- compressor plant
- computerized plant
- concentrating plant
- concrete plant
- concrete production plant
- concrete spouting plant
- concreting plant
- construction plant
- contact stabilization plant
- continuous-mix plant
- conveying plant
- cooling plant
- crushing plant
- desalination plant
- desalting plant
- disposal plant
- diversion power plant
- drying plant
- dust arrestor plant
- dust extracting plant
- earth moving plant
- electric plant
- exhaust plant
- extended aeration plant
- filter plant
- filtration plant
- floating concrete plant
- floating pile-driving plant
- flotation plant
- freezing plant
- gas plant
- gas-distribution plant
- gas washing plant
- generating plant
- grading plant
- heat generation plant
- heating plant
- heating water converter plant
- high-pressure air conditioning plant
- hydro-electric plant
- incineration plant
- indoor power plant
- industrial plant
- initial screening and washing plant
- lime softening plant
- low-head power plant
- low-level mixing plant
- low-pressure air conditioning plant
- manufacturing plant
- mechanical plant
- mixing plant
- mix-in-travel plant
- municipal treatment plant
- open-air plant
- open-air water power plant
- ozone plant
- package plant
- petrochemical plant
- piling plant
- placing plant
- power plant
- precast concrete plant
- precast plant
- proportioning plant
- pumping plant
- purification plant
- pyrolysis plant
- ready mixed concrete plant
- refrigerating plant
- refuse incineration plant
- refuse processing plant
- reinforcement cutting and bending plant
- river-run power plant
- river power plant
- road-making plant
- roadstone aggregate plant
- roof top plant
- screening plant
- secondary treatment plant
- sedimentation plant
- semioutdoor-type power plant
- sewage dispersal plant
- site mechanical plant
- sludge digestion plant
- sludge treating plant
- small powered plant
- solar plant
- spouting plant
- steam plant
- steam-power plant
- step-up plant
- structural steel plant
- tertiary plant
- tidal power plant
- transporting plant
- treatment plant
- vacuum dewatering plant
- ventilation plant
- volumetric batch plant
- washing and screening plant
- waste-disposal plant
- waste-heat utilization plant
- water-catchment plant
- water conversion plant
- water purification plant
- water softening plant
- water treatment plant
- weight batch plant
- zeolite water softening plant

Ilgner, Karl

SUBJECT AREA: Electricity

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b. 27 July 1862 Neisse, Upper Silesia (now Nysa, Poland)

d. 18 January 1921 Berthelsdorf, Silesia

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German electrical engineer, inventor of a transformer for electromotors.

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Ilgner graduated from the Gewerbeakademie (the forerunner of the Technical University) in Berlin. As the representative of an electric manufacturing company in Breslau (now Wroclaw, Poland) from 1897, he was confronted with the fact that there were no appropriate drives for hoisting-engines or rolling-plants in steelworks. Two problems prevented the use of high-capacity electric motors in the mining as well as in the iron and steel industry: the reactions of the motors on the circuit at the peak point of stress concentration; and the complicated handling of the control system which raised the risks regarding safety. Having previously been head of the department of electrical power transmission in Hannover, he was concerned with the development of low-speed direct-current motors powered by gas engines.

It was Harry Ward Leonard's switchgear for direct-current motors (USA, 1891) that permitted sudden and exact changes in the speed and direction of rotation without causing power loss, as demonstrated in the driving of a rolling sidewalk at the Paris World Fair of 1900. Ilgner connected this switchgear to a large and heavy flywheel which accumulated the kinetic energy from the circuit in order to compensate shock loads. With this combination, electric motors did not need special circuits, which were still weak, because they were working continuously and were regulated individually, so that they could be used for driving hoisting-engines in mines, rolling-plants in steelworks or machinery for producing tools and paper. Ilgner thus made a notable advance in the general progress of electrification.

His transformer for hoisting-engines was patented in 1901 and was commercially used inter alia by Siemens \& Halske of Berlin. Their first electrical hoisting-engine for the Zollern II/IV mine in Dortmund gained international reputation at the Düsseldorf exhibition of 1902, and is still preserved in situ in the original machine hall of the mine, which is now a national monument in Germany. Ilgner thereafter worked with several companies to pursue his conception, became a consulting engineer in Vienna and Breslau and had a government post after the First World War in Brussels and Berlin until he retired for health reasons in 1919.

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Bibliography

1901, DRP no. 138, 387 1903, "Der elektrische Antrieb von Reversier-Walzenstraßen", Stahl und Eisen 23:769– 71.

Further Reading

W.Kroker, "Karl Ilgner", Neue Deutsche Biographie, Vol. X, pp. 134–5. W.Philippi, 1924, Elektrizität im Bergbau, Leipzig (a general account).

K.Warmbold, 1925, "Der Ilgner-Umformer in Förderanlagen", Kohle und Erz 22:1031–36 (a detailed description).

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