Mines and Energy

Ministry of Industry, Mines and Energy

Внешняя политика: Министерство промышленности, разработки недр и энергетики (LPDR, MIME)

Queensland Department of Mines and Energy

Политика: Департамент горной промышленности и энергетики Квинсленда

Ministry of Industry, Mines and Energy

External policy: MIME

department of energy, mines and resources

министерство энергетики, шахт и ресурсов

Department of Energy, Mines and Resources

Министерство энергетики, горнорудной промышленности и ресурсов ( Канада)

MIME

1) Авиация: Снижение последствий для окружающей среды в условиях рыночной экономики (http://moscow-translator.ru/techtranslation-english)

2) Телекоммуникации: Multipurpose Internet Mail Extensions (IETF)

3) Вычислительная техника: Multipurpose Internet Mail Extension, Multipurpose Internet Mail Extensions (Протокол передачи звука, графики и других двоичных данных. Применяется при передаче почтовых сообщений. И как только этот MIME не интерпретируют!), Multipurpose Internet Mail Extensions (RFC 2045/2046/2047/2048/2049, IETF)

4) Сетевые технологии: Multipurpose Internet Mail Extensions, Multipurpose Internet Messaging Extensions, многоцелевые расширения межсетевой электронной почты, многоцелевые расширения электронной почты в Internet

5) Внешняя политика: Ministry of Industry, Mines and Energy

6) Интернет: многоцелевое расширение функций электронной почты (http://moscow-translator.ru/techtranslation-english)

7) Расширение файла: Multimedia Internet Message Extensions, Message in MIME format (RFC822)

mime

1) Авиация: Снижение последствий для окружающей среды в условиях рыночной экономики (http://moscow-translator.ru/techtranslation-english)

2) Телекоммуникации: Multipurpose Internet Mail Extensions (IETF)

3) Вычислительная техника: Multipurpose Internet Mail Extension, Multipurpose Internet Mail Extensions (Протокол передачи звука, графики и других двоичных данных. Применяется при передаче почтовых сообщений. И как только этот MIME не интерпретируют!), Multipurpose Internet Mail Extensions (RFC 2045/2046/2047/2048/2049, IETF)

4) Сетевые технологии: Multipurpose Internet Mail Extensions, Multipurpose Internet Messaging Extensions, многоцелевые расширения межсетевой электронной почты, многоцелевые расширения электронной почты в Internet

5) Внешняя политика: Ministry of Industry, Mines and Energy

6) Интернет: многоцелевое расширение функций электронной почты (http://moscow-translator.ru/techtranslation-english)

7) Расширение файла: Multimedia Internet Message Extensions, Message in MIME format (RFC822)

Департамент горной промышленности и энергетики Квинсленда

Politics: Queensland Department of Mines and Energy

Министерство промышленности, разработки недр и энергетики

External policy: Ministry of Industry, Mines and Energy (LPDR, MIME)

недра

1) General subject: bosom, bowels, entrails, mineral, mineral resources ( wealth), mines and carriers

2) Geology: bowel, interior, mineral resources, royalty, subsurface resources, subsoil riches

3) Mathematics: depths, womb

4) Law: subsoil

5) Economy: mines-and-carriers (месторождения полезных ископаемых), subsoil assets

6) Accounting: mines-and-carriers (месторождения. полезных ископаемых), subsoil asset

7) Forestry: bosom (земли)

8) Oil: resources, subsurface

9) Sakhalin energy glossary: sub-soil assets, underground resources

10) leg.N.P. sub-soil

11) Makarov: mineral wealth

12) oil&gas: bowels of the earth, depths of the earth, earth depths

использование

. для использования; мирное использование атомной энергии; область использования; по мере использования; повторное использование; при использовании; пригодный для использования; применение; с использованием

•

Harnessing fission processes for production of electric energy...

•

The harnessing of the steam engine in British mines and mills...

•

The time required for half of the reactant to be used up is independent of...

•

The tapping of solar energy...

•

Alleviation of... may be achieved by adoption of laminar-flow airfoil of small thickness.

•

The analysis is dependent on the employment of a satisfactory mixture law.

•

Another use of beryllium oxide is as a slurry for...

•

One of the uses of these plastics is in instrument lenses.

•

Bombers may be of different types, depending on the use to which they are put.

•

Agriculturists showed a keen interest in harnessing isotopes and radiation for improving the production and protection of food.

•

The tapping of the world's oil resources.

использование

. для использования; мирное использование атомной энергии; область использования; по мере использования; повторное использование; при использовании; пригодный для использования; применение; с использованием

•

Harnessing fission processes for production of electric energy...

•

The harnessing of the steam engine in British mines and mills...

•

The time required for half of the reactant to be used up is independent of...

•

The tapping of solar energy...

•

Alleviation of... may be achieved by adoption of laminar-flow airfoil of small thickness.

•

The analysis is dependent on the employment of a satisfactory mixture law.

•

Another use of beryllium oxide is as a slurry for...

•

One of the uses of these plastics is in instrument lenses.

•

Bombers may be of different types, depending on the use to which they are put.

•

Agriculturists showed a keen interest in harnessing isotopes and radiation for improving the production and protection of food.

•

The tapping of the world's oil resources.

* * *

Использование -- use, using, utilization; employment, application (применение); incorporation (учёт)

 The utilization of fat closely parallels the synthesis of sugars.

 Incorporation of these findings into the design of large scale magnets poses several problems.

— аналогичное использование

— без использования

— бороться путем использования

— в обязанности подрядчика входит использование

— в периоды между использованиями хранить в закрытых контейнерах

— в последнее время возродился интерес к использованию

— внедрять использование... на отдельных

— вносит не меньшую путаницу, чем использование

— возможности использования

— выигрыш от использования

— диапазон предполагаемого использования

— для использования

— для повторного использования

— для последующего использования

— доведение изобретения до практического использования

— запатентовать использование... в

— запрещать использование

— идеален для использования в

— использование... не приводит к значительному улучшению

— использование в больших масштабах

— использование вместо

— использование... вызвано желанием

— использование выражения для... оправдано, потому что

— использование... неудачно

— использование одной общей кривой

— использование посторонними лицами

— использование... привело бы к

— использованию не подлежат

— как при использовании..., так и без него

— контроль за правильным использованием

— многократное использование

— недостаток использования

— некоторые из трудностей, которые могут возникнуть при использовании

— некритический подход к использованию

— неосторожное использование

— непригодный для использования

— непригодный для практического использования

— область использования

— ограничиваться лишь случаями использования

— определять порядок использования

— перед использованием

— планируется ли какая-либо дальнейшая работа с использованием...

— по мере использования

— повторное использование при строительстве

— полная свобода действий в области использования

— последующее использование

— появилась заметная тенденция к использованию

— предназначаться специально для использования при

— предполагаемое использование

— преимущество использования... состоит в том, что

— преимущество, получаемое в результате использования

— прекращать использование

— при... использовании

— при использовании таких координат

— при условии правильного использования

— пригоден для использования согласно техусловиям

— пригодность для практического использования

— пригодный для использования в космических условиях

— пригодный для непосредственного использования

— пригодный для практического использования

— принципы, лежащие в основе использования

— промышленное использование

— рассматривать возможность использования

— рассматривая возможность использования

— реальные возможности использования

— с использованием

— с теми же самыми проблемами приходится сталкиваться при использовании

— сделать непригодным для дальнейшего использования

— слишком необычный для практического использования

— требовать использования

— упорно противиться использованию

— характер использования

— чтобы внести ясность в использовании термина

— это не исключает возможности использования

Ericsson, John

SUBJECT AREA: Ports and shipping, Railways and locomotives

[br]

b. 31 July 1803 Farnebo, Sweden

d. 8 March 1899 New York, USA

[br]

Swedish (naturalized American 1848) engineer and inventor.

[br]

The son of a mine owner and inspector, Ericsson's first education was private and haphazard. War with Russia disrupted the mines and the father secured a position on the Gotha Canal, then under construction. He enrolled John, then aged 13, and another son as cadets in a corps of military engineers engaged on the canal. There John was given a sound education and training in the physical sciences and engineering. At the age of 17 he decided to enlist in the Army, and on receiving a commission he was drafted to cartographic survey duties. After some years he decided that a career outside the Army offered him the best opportunities, and in 1826 he moved to London to pursue a career of mechanical invention.

Ericsson first developed a heat (external combustion) engine, which proved unsuccessful. Three years later he designed and constructed the steam locomotive Novelty, which he entered in the Rainhill locomotive trials on the new Liverpool \& Manchester Railway. The engine began by performing promisingly, but it later broke down and failed to complete the test runs. Later he devised a self-regulating lead (1835) and then, more important and successful, he invented the screw propeller, patented in 1835 and installed in his first screw-propelled ship of 1839. This work was carried out independently of Sir Francis Pettit Smith, who contemporaneously developed a four-bladed propeller that was adopted by the British Admiralty. Ericsson saw that with screw propulsion the engine could be below the waterline, a distinct advantage in warships. He crossed the Atlantic to interest the American government in his ideas and became a naturalized citizen in 1848. He pioneered the gun turret for mounting heavy guns on board ship. Ericsson came into his own during the American Civil War, with the construction of the epoch-making warship Monitor, a screw-propelled ironclad with gun turret. This vessel demonstrated its powers in a signal victory at Hampton Roads on 9 March 1862.

Ericsson continued to design warships and torpedoes, pointing out to President Lincoln that success in war would now depend on technological rather than numerical superiority. Meanwhile he continued to pursue his interest in heat engines, and from 1870 to 1888 he spent much of his time and resources in pursuing research into alternative energy sources, such as solar power, gravitation and tidal forces.

[br]

Further Reading

W.C.Church, 1891, Life of John Ericsson, 2 vols, London.

LRD

warhead

боевая часть, БЧ; боеголовка; головная часть, ГЧ; боевое зарядное отделение ( торпеды)

antimissile spectrum (charge) warhead — противоракетная спектральная БЧ (поражающая рентгеновским излучением)

megaton (blast value) warhead — БЧ с ядерным зарядом мегатонной мощности

separated nuclear (explosive) warhead — ядерная РГЧ

— active AT salvo fire multiple warhead

— active warhead

— adaptive multiple warhead

— aimable warhead

— aimed quadrant warhead

— aimed warhead

— air target warhead

— annihilation bomb warhead

— annular blast fragmentation warhead

— annular warhead

— antiarmor multiple warhead

— antimissile warhead

— antipersonnel and antimateriel fragmentation warhead

— antipersonnel and antimateriel warhead

— antipersonnel bomblet warhead

— antipersonnel mine scattering warhead

— antipersonnel multiple charge warhead

— antiradar warhead

— antiradiation warhead

— AP beyond-armor high effects warhead

— AP rod warhead

— area destroying warhead

— armor detecting warhead

— armored warhead

— AT bomblet dispensing warhead

— AT bomblet scattering warhead

— AT homing submissile warhead

— AT IR homing submissile scattering multiple warhead

— AT multiple charge warhead

— attacking warhead

— bacteriological warhead

— ballistic warhead

— ball-scattering warhead

— bidirectional focus warhead

— binary chemical warhead

— binary warhead

— biological warhead

— blast fragmentation warhead

— blast warhead

— bomb live unit submunition warhead

— bomblet dispensing warhead

— bomblet-scattering cluster warhead

— bomblet-scattering warhead

— boundary-layer control warhead

— bus warhead

— chaff warhead

— chaff-protected warhead

— chemical energy warhead

— chemical explosive warhead

— chemical warhead

— cluster bomb warhead

— cluster warhead

— configured blast fragmentation warhead

— continuous radiation rod warhead

— controlled fragmentation warhead

— conventional capable warhead

— cylindrical fragmentation warhead

— delay action-fuzed nuclear warhead

— deliver the warhead to the target

— deployed BM warheads

— destructive warhead

— directional warhead

— disintegrating warhead

— disk-type warhead

— dispensing warhead

— dispersion warhead

— distributed fragmentation warhead

— dual mode warhead

— dummy warhead

— earth-penetrating warhead

— earth-penetrator warhead for engineer works

— ECM decoy warhead

— ECM-protected warhead

— elliptical warhead

— end-projection warhead

— engine interference warhead

— enhanced-radiation warhead

— explosive pellet warhead

— explosive warhead

— extendable probe warhead

— external blast warhead

— fission warhead

— flare warhead

— flechette warhead

— focused warhead

— forging fragment warhead

— forward firing shaped-charge jet and blast warhead

— fractionated nuclear warhead

— fractionated warhead

— fragment core warhead

— fragmentation warhead

— fuel-air explosive warhead

— fusion warhead

— gamma and neutron radiation warhead

— gamma radiation warhead

— gas-injection adjustable plasma envelope warhead

— grenade warhead

— ground-penetrating warhead

— HE dual purpose warhead

— HE shaped-charge AP warhead

— HE warhead

— HE/fragmentation warhead

— HEAT mine-seatterable warhead

— HEAT warhead

— heated AA gun barrel IR-radiation homing warhead

— HEAT-fragmentation missile scattering warhead

— heat-seeking warhead

— heat-vision thermic imaging homing system warhead

— high-angle trajectory warhead

— high-effect HE warhead

— high-energy warhead

— high-penetration nuclear warhead

— high-precision MIRVed warhead

— high-thrust multiple warhead

— high-yield warhead

— high-yield-to-weight ratio nuclear warhead

— hollow-charge warhead

— homing HEAT submissile scattering cluster warhead

— homing submunition cluster warhead

— ICBM warhead

— impact fuzed warhead

— incendiary warhead

— incoming warhead

— independently targetable warhead

— independently targeted warhead

— inert warhead

— ion particles projector warhead

— IR-guided warhead

— IR-homing warhead

— isotropic warhead

— jammer-ejecting cluster warhead

— jammer-protected warhead

— kiloton warhead

— kinetic energy warhead

— large-yield nuclear warhead

— laser homing warhead

— laser warhead

— linear arrangement shaped charge warhead

— live nuclear warhead

— live warhead

— low-angle trajectory warhead

— low-collateral damage warhead

— low-kiloton range warhead

— low-kiloton yield warhead

— low-yield warhead

— maneuverable multiple warhead

— mass-focus warhead

— mate the warhead to the missile

— medium-yield warhead

— mid-trajectory maneuvering warhead

— minelet-scattering cluster warhead

— minelet-scattering multiple warhead

— mine-scattering warhead

— mine-spreading warhead

— mini-nuke warhead

— MIRVed warhead

— monotachic warhead

— mother/daughter AT warhead

— multicharge warhead

— multiple antiarmor warhead

— multiple AT warhead

— multiple bomblet warhead

— multiple charge warhead

— multiple independently targetable warhead

— multiple nuclear warhead

— multiple submunition warhead

— multiple warhead

— multishaped charge warhead

— neutron enhanced-radiation warhead

— neutron warhead

— newly deployed warheads

— nonisotropic warhead

— non-nuclear warhead

— nuclear-armed warhead

— ogive warhead

— optional yield nuclear warhead

— pellet multiple warhead

— penetrating rod warhead

— pinpoint warhead

— point-detonating warhead

— polytachic warhead

— preformed fragmentation warhead

— prefragmentation warhead

— pressure warhead

— proximity fuzed warhead

— quadrant warhead

— radar homing warhead

— radar seeking warhead

— radar/heat homing warhead

— radar/heat seeking warhead

— radar-guided warhead

— radiation warhead

— radiological warhead

— reduced blast enhanced radiation warhead

— reduced blast increased radiation warhead

— reentry warhead

— rod fuze warhead

— scatterable mines warhead

— scattered mines warhead

— scattering warhead

— second echelon target interdiction warhead

— selectively aimable warhead

— self-forging fragment warhead

— self-guided submissile cluster warhead

— semi-AP warhead

— semi-AP/HE/fragmentation warhead

— semiarmored warhead

— separable warhead

— shaped-charge antiarmor warhead

— shaped-charge warhead

— shaped-charge/fragmentation warhead

— shielded nuclear warhead

— side-radiation homing warhead

— side-radiation seeking warhead

— sideways firing warhead

— simulated warhead

— single warhead

— small-yield nuclear warhead

— specialized warhead

— spherical warhead

— strategic defensive warhead

— strategic nuclear warhead

— strategic offensive warhead

— subkiloton yield warhead

— submissile dispensing warhead

— submissile scattering warhead

— submunition warhead

— subnominal nuclear warhead

— supernumerary nuclear warhead

— super-yield nuclear warhead

— switchable IR and radar-guided warhead

— tactical nuclear warhead

— tactical warhead

— tandem charge warhead

— tandem HEAT/fragmentation charge warhead

— target warhead

— targetable warhead

— terminal guidance warhead

— terminal homing AT warhead

— terminal radar homing maneuverable warhead

— terminally guided submissile warhead

— thermal warhead

— thermonuclear warhead

— training warhead

— triple maneuverable warhead

— triple MIRV warhead

— unarmed warhead

— unguided warhead

— variable yield nuclear warhead

— very high-yield warhead

— very low yield warhead

— X-ray radiation warhead

Charpy, Augustin Georges Albert

SUBJECT AREA: Metallurgy

[br]

b. 1 September 1865 Ouillins, Rhône, France

d. 25 November 1945 Paris, France

[br]

French metallurgist, originator of the Charpy pendulum impact method of testing metals.

[br]

After graduating in chemistry from the Ecole Polytechnique in 1887, Charpy continued to work there on the physical chemistry of solutions for his doctorate. He joined the Laboratoire d'Artillerie de la Marine in 1892 and began to study the structure and mechanical properties of various steels in relation to their previous heat treatment. His first memoir, on the mechanical properties of steels quenched from various temperatures, was published in 1892 on the advice of Henri Le Chatelier. He joined the Compagnie de Chatillon Commentry Fourchamboult et Decazeville at their steelworks in Imphy in 1898, shortly after the discovery of Invar by G.E. Guillaume. Most of the alloys required for this investigation had been prepared at Imphy, and their laboratories were therefore well equipped with sensitive and refined dilatometric facilities. Charpy and his colleague L.Grenet utilized this technique in many of their earlier investigations, which were largely concerned with the transformation points of steel. He began to study the magnetic characteristics of silicon steels in 1902, shortly after their use as transformer laminations had first been proposed by Hadfield and his colleagues in 1900. Charpy was the first to show that the magnetic hysteresis of these alloys decreased rapidly as their grain size increased.

The first details of Charpy's pendulum impact testing machine were published in 1901, about two years before Izod read his paper to the British Association. As with Izod's machine, the energy of fracture was measured by the retardation of the pendulum. Charpy's test pieces, however, unlike those of Izod, were in the form of centrally notched beams, freely supported at each end against rigid anvils. This arrangement, it was believed, transmitted less energy to the frame of the machine and allowed the energy of fracture to be more accurately measured. In practice, however, the blow of the pendulum in the Charpy test caused visible distortion in the specimen as a whole. Both tests were still widely used in the 1990s.

In 1920 Charpy left Imphy to become Director-General of the Compagnie des Aciéries de la Marine et Homecourt. After his election to the Académie des Sciences in 1918, he came to be associated with Floris Osmond and Henri Le Chatelier as one of the founders of the "French School of Physical Metallurgy". Around the turn of the century he had contributed much to the development of the metallurgical microscope and had helped to introduce the Chatelier thermocouple into the laboratory and to industry. He also popularized the use of platinum-wound resistance furnaces for laboratory purposes. After 1920 his industrial responsibilities increased greatly, although he continued to devote much of his time to teaching at the Ecole Supérieure des Mines in Paris, and at the Ecole Polytechnique. His first book, Leçons de Chimie (1892, Paris), was written at the beginning of his career, in association with H.Gautier. His last, Notions élémentaires de sidérurgie (1946, Paris), with P.Pingault as co-author, was published posthumously.

[br]

Bibliography

Charpy published important metallurgical papers in Comptes rendus… Académie des Sciences, Paris.

Further Reading

R.Barthélémy, 1947, "Notice sur la vie et l'oeuvre de Georges Charpy", Notices et discours, Académie des Sciences, Paris (June).

M.Caullery, 1945, "Annonce du décès de M.G. Charpy" Comptes rendus Académie des Sciences, Paris 221:677.

P.G.Bastien, 1963, "Microscopic metallurgy in France prior to 1920", Sorby Centennial Symposium on the History of Metallurgy, AIME Metallurgical Society Conference Vol.27, pp. 171–88.

ASD

Dörell, Georg Ludwig Wilhelm

SUBJECT AREA: Mining and extraction technology

[br]

b. 17 December 1793 Clausthal, Harz, Germany

d. 30 October 1854 Zellerfeld, Harz, Germany

[br]

German mining engineer who introduced the miner's elevator into the Harz Mountains.

[br]

After studying at the Freiberg Mining Academy he returned to his home region to serve in the mining administration, first at Clausthal. In 1848 he became an inspector of mines in Zellerfeld. He had become aware that in the early nineteenth century, when 500 m (1,640 ft) shafts were no longer unusual, devices other than ladders were needed for access to mines. Dörell found out that miners, in terms of physical strength, had to consume almost one-third more of their energy to climb up the shaft than they had to spend at work during the shift in the mine. Accordingly, in 1833 he constructed the miner's elevator. Two timbered bars, similar to those used for pumps, were installed in the shaft and were driven by water-wheel and moved in opposite directions. They were placed at such a distance from each other that the miners could easily step from one to the other in order to go up or down the shaft as desired.

Dörell's elevators worked with great success and their use soon became widespread among Central European mining districts. Their use is particularly associated with Cornish tin-mines, where several such elevators operated over considerable distances.

[br]

Bibliography

1837, "Über die seit dem Jahre 1833 beim Oberharzischen Bergbau angewendeten Fahrmaschinen", Die Bergwerks-Verwaltung des Hannoverschen Ober-Harzes in den Jahren 1831–1836, ed. W.A.J.Albert, Berlin, pp. 199–214.

Further Reading

C.Bartels, 1992, Vom frühneuzeitlichen Montangewerbe zur Bergbauindustrie. Erzbergbau im Oberharz 1635–1880, Bochum: Deutsches Bergbau-Museum, esp. pp. 382–411 (elaborates upon the context of contemporary technological innovations in Harz ore mining).

WK

ECO

1) Авиация: генератор с электронной связью

2) Военный термин: Electronic Collection Outstations, Employment Coordination Office, emergency commissioned officer, engineering change order, equipment control officer, exempted by commanding officer

3) Техника: equipment checkout, оптимизация энергозатрат (http://moscow-translator.ru/technical-translation Energy Cost Optimization), приказ на изменение конструкторской документации (Elsevier's Dictionary of Technical Abbreviations), доработка проекта в связи с выявлением ошибки (Elsevier's Dictionary of Technical Abbreviations), конструкторское изменение (Elsevier's Dictionary of Technical Abbreviations), указание о техническом изменении (Elsevier's Dictionary of Technical Abbreviations)

4) Юридический термин: Energy Committed To Offenders

5) Автомобильный термин: electronically controlled orifice (power steering)

6) Сокращение: Earth-Crossing Orbit, Electron-Coupled Oscillator, Electronic Central Office, Electronic Combat Officer, European Coal Organization, electronic checkout

7) Текстиль: Environmental Caring Organization

8) Университет: English And Cultural Orientation

9) Фото: Ektachrome Commercial

10) Шахматы: Encyclopedia Of Chess Openings

11) Деловая лексика: Enterprise Customer Optimization

12) Образование: Energy Cost Optimization

13) Сетевые технологии: Embedded Communication Object

14) Полимеры: этиленоксид-эпихлоргидрин-каучук

15) Контроль качества: electronic check-out, equipment check-out

16) Пластмассы: Epichlorohydrin Rubber (Ethylene Oxide Copolymer)

17) Макаров: engine cutoff

18) Пожарное дело: пожарный отвечающий за личный состав, работающий в дыхательных аппаратах (entry control officer)

19) НАСА: Earth Communications Office, Earth Crossing Objects

20) AMEX. Echo Bay Mines, LTD.

eco

1) Авиация: генератор с электронной связью

2) Военный термин: Electronic Collection Outstations, Employment Coordination Office, emergency commissioned officer, engineering change order, equipment control officer, exempted by commanding officer

3) Техника: equipment checkout, оптимизация энергозатрат (http://moscow-translator.ru/technical-translation Energy Cost Optimization), приказ на изменение конструкторской документации (Elsevier's Dictionary of Technical Abbreviations), доработка проекта в связи с выявлением ошибки (Elsevier's Dictionary of Technical Abbreviations), конструкторское изменение (Elsevier's Dictionary of Technical Abbreviations), указание о техническом изменении (Elsevier's Dictionary of Technical Abbreviations)

4) Юридический термин: Energy Committed To Offenders

5) Автомобильный термин: electronically controlled orifice (power steering)

6) Сокращение: Earth-Crossing Orbit, Electron-Coupled Oscillator, Electronic Central Office, Electronic Combat Officer, European Coal Organization, electronic checkout

7) Текстиль: Environmental Caring Organization

8) Университет: English And Cultural Orientation

9) Фото: Ektachrome Commercial

10) Шахматы: Encyclopedia Of Chess Openings

11) Деловая лексика: Enterprise Customer Optimization

12) Образование: Energy Cost Optimization

13) Сетевые технологии: Embedded Communication Object

14) Полимеры: этиленоксид-эпихлоргидрин-каучук

15) Контроль качества: electronic check-out, equipment check-out

16) Пластмассы: Epichlorohydrin Rubber (Ethylene Oxide Copolymer)

17) Макаров: engine cutoff

18) Пожарное дело: пожарный отвечающий за личный состав, работающий в дыхательных аппаратах (entry control officer)

19) НАСА: Earth Communications Office, Earth Crossing Objects

20) AMEX. Echo Bay Mines, LTD.

Ilgner, Karl

SUBJECT AREA: Electricity

[br]

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

d. 18 January 1921 Berthelsdorf, Silesia

[br]

German electrical engineer, inventor of a transformer for electromotors.

[br]

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.

[br]

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).

WK

niveau

niveau (plural niveaux) [nivo]

1. masculine noun

   a. level

• le niveau de l'eau the water level

• cent mètres au-dessus du niveau de la mer a hundred metres above sea level

• de niveau level

• de niveau avec level with

• au même niveau que level with

• mettre qch de niveau to make sth level

• il faut se mettre au niveau des enfants you have to put yourself on the same level as the children

• au niveau européen at the European level

• négociations au plus haut niveau top-level negotiations

• athlète de haut niveau top athlete

• des candidats ayant le niveau licence candidates at degree level

• le euro a atteint son niveau le plus haut depuis trois ans the euro has reached its highest point for three years

► au niveau de

• au niveau du sol at ground level

• la neige m'arrivait au niveau des genoux the snow came up to my knees

• une tache au niveau du coude a mark on the elbow

• il s'arrêta au niveau du village he stopped once he got to the village

   b. [de connaissances, études] standard

• le niveau d'instruction baisse educational standards are falling

• cet élève est d'un bon niveau this pupil's work is of a high standard

• il n'est pas au niveau he isn't up to standard

• ils ne sont pas du même niveau they're not of the same standard

• il n'y a pas de cours à son niveau there are no courses at his level

• remettre à niveau to bring up to standard

• stage de remise à niveau refresher course

• les préparatifs de passage à l'euro au niveau de l'entreprise preparations at company level for adopting the euro

   c. ( = instrument) level ; ( = jauge) gauge

2. compounds

► niveau de langue register

► niveau social social standing

► niveau sonore noise level

► niveau de vie standard of living

* * *

pl niveaux nivo nom masculin

1) ( hauteur) level

niveau de l'eau/d'huile — water/oil level

au niveau du sol — at ground level

être de niveau — to be level

arrivé au niveau du bus — when he drew level with the bus

au niveau du cou — [blessures] in the neck region

accroc au niveau du genou — tear at the knee

2) ( étage) storey GB, story US

bâtiment sur deux niveaux — two-storey GB ou two-story US building

3) ( degré) ( d'intelligence) level; ( de connaissances) standard

niveau intellectuel — intellectual level

‘niveau bac + 3’ — baccalaureate or equivalent plus 3 years' higher education

remettre quelqu'un à niveau — to bring somebody up to the required standard

de haut niveau — [athlète] top (épith); [candidat] high-calibre [BrE] (épith)

niveau des salaires — wage levels (pl)

4) ( échelon) level

au plus haut niveau — [discussion] top-level (épith)

les négociations se dérouleront au plus haut niveau — there will be negotiations at the highest level

5) Linguistique register

6) ( instrument) level

•

Phrasal Verbs:

- niveau de langue

- niveau social

- niveau sonore

- niveau de vie

* * *

nivo

niveaux pl nm

1) (spatialement, d'un taux) level

Le niveau de l'eau a baissé. — The water level has gone down.

de niveau — level

de niveau avec — level with

au niveau de — at the level of

le niveau de la mer — sea level

2) (= étage) level

parking à plusieurs niveaux — multistorey car park

3) (qualitatif) level

Ces deux enfants n'ont pas le même niveau. — These two children aren't at the same level.

au niveau de (personne, travail) — on a level with

au niveau national — at national level

au niveau régional — at regional level

4) [programme, enseignement] standard

niveau d'études — level of qualifications

avoir le niveau bac + 2 — to have the baccalauréat plus 2 years' higher education

5) (= outil) level

* * *

niveau, pl niveaux nm

1 ( hauteur) level; niveau de l'eau/d'huile water/oil level; au niveau du sol/de la chaussée at ground/street level; être de niveau to be level; mettre de niveau to make [sth] level; dix mètres au-dessus/au-dessous du niveau de la mer ten metres^GB above/below sea level; être au même niveau que to be level with; arrivé au niveau du car when he drew level with the coach GB ou bus; l'eau nous arrivait au niveau des chevilles/genoux the water came up to our ankles/knees; au niveau du cou/de l'abdomen [blessures] in the neck/abdominal region; accroc au niveau du genou tear at the knee;

2 ( étage) storey GB, story US; bâtiment sur deux niveaux two-storey GB ou two-story US building;

3 ( degré) ( d'intelligence) level; ( de connaissances) standard; niveau culturel/intellectuel cultural/intellectual level; niveau d'éducation/de formation standard of education/of training; niveau bac○ baccalaureate or equivalent; ‘niveau bac + 3’ baccalaureate or equivalent plus 3 years' higher education; au-dessous du niveau exigé pour below the required standard for; niveau de production/d'inflation level of production/of inflation; d'un bon niveau of a good standard; mettre à niveau Ordinat to upgrade; mise à niveau Ordinat upgrade; remise à niveau ( d'élève) recap, refresher; remettre qn à niveau to bring sb up to the required standard; se mettre au niveau de qn to put oneself on the same level as sb; de haut niveau [équipe, athlète] top ( épith); [candidat] high-calibre^GB ( épith); niveau des revenus/salaires income/wage levels (pl);

4 ( échelon) level; à tous les niveaux at every level; au niveau national/européen at national/European level; au plus haut niveau [discussion, intervention] top-level ( épith); les négociations se dérouleront au plus haut niveau there will be negotiations at the highest level; au niveau de la commercialisation/des investissements controv as regards marketing/investment;

5 Ling register; niveau familier/soutenu informal/formal register;

6 Tech ( instrument) level.

Composés

niveau (à bulle d'air) spirit level; niveau de langue Ling register; niveau à lunette theodolite; niveau de maçon mason's level; niveau de rémunération wage level; niveau social social status; niveau sonore Audio sound level; niveau de vie Écon standard of living, living standards.

( pluriel masculin niveaux) [nivo] nom masculin

1. [hauteur] level

vérifie les niveaux d'eau et d'huile check the oil and water levels

fixer les étagères au même niveau que la cheminée put up the shelves level with ou on the same level as the mantelpiece

2. [étage] level, storey

un parking à trois niveaux a car park on three levels

3. [degré] level

la production atteint son plus haut niveau production is reaching its peak

la natalité n'est jamais tombée à un niveau aussi bas the birth rate is at an all-time low ou at its lowest level ever

la décision a été prise au plus haut niveau the decision was made at the highest level

niveau social social level

niveau de langue LINGUISTIQUE register

4. [étape] level, stage

5. [qualité] level, standard

son niveau scolaire est-il bon? is she doing well at school?

j'ai un bon niveau/un niveau moyen en russe I'm good/average at Russian

les élèves sont tous du même niveau the pupils are all on a par ou on the same level

vous n'avez pas le niveau requis you don't have the required standard

la recherche de haut niveau high-level research

niveau de vie standard of living

6. GÉOGRAPHIE level

niveau de la mer sea level

7. MINES level, drift

[galerie] gallery, flat slope

8. INDUSTRIE DU PÉTROLE level

9. PHYSIQUE level

niveau (d'énergie) energy level

10. TÉLÉCOMMUNICATIONS

niveau d'un signal signal level

11. [instrument] level (tube)

niveau à bulle (d'air) spirit level

niveau d'eau water level

————————

au niveau locution adjectivale

up to standard, of the required level

dans deux mois, vous serez au niveau in two months' time you'll have caught up

————————

au niveau locution adverbiale

se mettre au niveau to catch up

————————

au niveau de locution prépositionnelle

1. [dans l'espace]

au niveau de la mer at sea level

l'eau lui arrivait au niveau du genou the water came up to his knees

je ressens une douleur au niveau de la hanche I've got a pain in my hip

au niveau du carrefour vous tournez à droite when you come to the crossroads, turn right

j'habite à peu près au niveau de l'église I live by the church

2. [dans une hiérarchie] on a par with, at the level of

ce problème sera traité au niveau du syndicat this problem will be dealt with at union level

————————

de niveau locution adjectivale

level

les deux terrains ne sont pas de niveau the two plots of land are not level (with each other)

la terrasse est de niveau avec le salon the terrace is (on a) level with ou on the same level as the lounge