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1 corrosion engineer
Англо-русский словарь нормативно-технической терминологии > corrosion engineer
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2 corrosion engineer
Большой англо-русский и русско-английский словарь > corrosion engineer
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3 corrosion engineer
Англо-русский словарь технических терминов > corrosion engineer
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4 corrosion engineer
* * *Англо-русский словарь нефтегазовой промышленности > corrosion engineer
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5 corrosion engineer
1) Техника: инженер-коррозионист -
6 corrosion engineer
The English-Russian dictionary on reliability and quality control > corrosion engineer
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7 engineer
1. инженер2. механик3. машинист4. сапёр
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инженер; конструктор; pl. инженерно-технические работники
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инженер; конструктор; pl инженерно-технические работники- cementing engineer
- certified reliability engineer
- chemical engineer
- chief reliability engineer
- corrosion engineer
- defect analysis engineer
- directional engineer
- drilling engineer
- drilling mud engineer
- electrical engineer
- failure analysis engineer
- field engineer
- field service engineer
- gas engineer
- geological engineer
- health-and-safety engineer
- hydraulic engineer
- inspecting engineer
- logging engineer
- maintainability engineer
- maintenance engineer
- maintenance-mechanical engineer
- mechanical engineer
- mining engineer
- mud engineer
- oil engineer
- operating engineer
- operation engineer
- petroleum engineer
- piping mechanical engineer
- principal project engineer
- product assurance engineer
- refinery engineer
- reliability engineer
- reliability group engineer
- reliability methods engineer
- reliability testing engineer
- reservoir engineer
- safety engineer
- service engineer
- superintendent engineer
- testing engineerАнгло-русский словарь нефтегазовой промышленности > engineer
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8 engineer
1) инженер; мн. ч. инженерно-технический персонал2) механик4) разрабатывать; проектировать; конструировать•-
advisory engineer
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aeronautical engineer
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air-conditioning engineer
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aircraft maintenance engineer
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application engineer
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automatic control engineer
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automation engineer
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balance engineer
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blast-furnace engineer
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ceramic engineer
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chemical engineer
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chief engineer
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civil engineer
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coal preparation engineer
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coke-chemical engineer
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coking engineer
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combustion engineer
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computer engineer
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consulting engineer
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corrosion engineer
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customer engineer
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design engineer
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development engineer
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district engineer
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drilling engineer
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efficiency engineer
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electrical engineer
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electronics engineer
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electronic engineer
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environmental engineer
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equipment engineer
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field engineer
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fleet engineer
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flight engineer
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fluid power engineer
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food engineer
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gas engineer
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geotechnical engineer
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grade control engineer
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grid-control engineer
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hardware design engineer
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hardware engineer
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health and safety engineer
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heating and ventilation engineer
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hydraulic engineer
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industrial engineer
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instrument-maintenance engineer
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junior engineer
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knowledge engineer
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lighting engineer
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locating engineer
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logging engineer
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machine engineer
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maintenance engineer
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maintenance-mechanical engineer
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manufacturing engineer
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material engineer
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mechanical engineer
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metallurgical engineer
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mining engineer
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motion-picture engineer
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municipal engineer
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nuclear engineer
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oil engineer
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operating engineer
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operating-refrigerating engineer
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operation engineer
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patent engineer
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petroleum engineer
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planning engineer
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plant engineer
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plant-communication engineer
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plant-operating engineer
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plumbing engineer
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pneumatic engineer
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power engineer
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principal engineer
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process engineer
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protection engineer
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quality engineer
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quarry engineer
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radio engineer
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railway-service engineer
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rate-setting engineer
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raw-materials engineer
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reclamation engineer
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recording engineer
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refinery engineer
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refractories engineer
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refrigeration engineer
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research engineer
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reservoir engineer
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resident engineer
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safety engineer
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sales engineer
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sanitary engineer
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scrap-processing engineer
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second engineer
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senior engineer
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service engineer
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shift engineer
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software engineer
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steelmaking engineer
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structural engineer
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studio engineer
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supplies engineer
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systems design engineer
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systems engineer
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testing engineer
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test engineer
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tool engineer
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tooling engineer
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traction engineer
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training flight engineer
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utility engineer
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vacuum engineer
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ventilation engineer
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video engineer
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vision-control engineer
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vision engineer
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vision-mixing engineer
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works-traffic engineer
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yarder engineer -
9 инженер-коррозионист
Большой англо-русский и русско-английский словарь > инженер-коррозионист
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10 инженер-коррозионист
Англо-русский словарь технических терминов > инженер-коррозионист
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11 Stanley, Robert Crooks
[br]b. 1 August 1876 Little Falls, New Jersey, USAd. 12 February 1951 USA[br]American mining engineer and metallurgist, originator of Monel Metal[br]Robert, the son of Thomas and Ada (Crooks) Stanley, helped to finance his early training at the Stevens Institute of Technology, Hoboken, New Jersey, by working as a manual training instructor at Montclair High School. After graduating in mechanical engineering from Stevens in 1899, and as a mining engineer from the Columbia School of Mines in 1901, he accepted a two-year assignment from the S.S.White Dental Company to investigate platinum-bearing alluvial deposits in British Columbia. This introduced him to the International Nickel Company (Inco), which had been established on 29 March 1902 to amalgamate the major mining companies working the newly discovered cupro-nickel deposits at Sudbury, Ontario. Ambrose Monell, President of Inco, appointed Stanley as Assistant Superintendent of its American Nickel Works at Camden, near Philadelphia, in 1903. At the beginning of 1904 Stanley was General Superintendent of the Orford Refinery at Bayonne, New Jersey, where most of the output of the Sudbury mines was treated.Copper and nickel were separated there from the bessemerized matte by the celebrated "tops and bottoms" process introduced thirteen years previously by R.M.Thompson. It soon occurred to Stanley that such a separation was not invariably required and that, by reducing directly the mixed matte, he could obtain a natural cupronickel alloy which would be ductile, corrosion resistant, and no more expensive to produce than pure copper or nickel. His first experiment, on 30 December 1904, was completely successful. A railway wagon full of bessemerized matte, low in iron, was calcined to oxide, reduced to metal with carbon, and finally desulphurized with magnesium. Ingots cast from this alloy were successfully forged to bars which contained 68 per cent nickel, 23 per cent copper and about 1 per cent iron. The new alloy, originally named after Ambrose Monell, was soon renamed Monel to satisfy trademark requirements. A total of 300,000 ft2 (27,870 m2) of this white, corrosion-resistant alloy was used to roof the Pennsylvania Railway Station in New York, and it also found extensive applications in marine work and chemical plant. Stanley greatly increased the output of the Orford Refinery during the First World War, and shortly after becoming President of the company in 1922, he established a new Research and Development Division headed initially by A.J.Wadham and then by Paul D. Merica, who at the US Bureau of Standards had first elucidated the mechanism of age-hardening in alloys. In the mid- 1920s a nickel-ore body of unprecedented size was identified at levels between 2,000 and 3,000 ft (600 and 900 m) below the Frood Mine in Ontario. This property was owned partially by Inco and partially by the Mond Nickel Company. Efficient exploitation required the combined economic resources of both companies. They merged on 1 January 1929, when Mond became part of International Nickel. Stanley remained President of the new company until February 1949 and was Chairman from 1937 until his death.[br]Principal Honours and DistinctionsAmerican Society for Metals Gold Medal. Institute of Metals Platinum Medal 1948.Further ReadingF.B.Howard-White, 1963, Nickel, London: Methuen (a historical review).ASD -
12 Brotan, Johann
SUBJECT AREA: Railways and locomotives[br]b. 24 June 1843 Kattau, Bohemia (now in the Czech Republic)d. 20 November 1923 Vienna, Austria[br]Czech engineer, pioneer of the watertube firebox for steam locomotive boilers.[br]Brotan, who was Chief Engineer of the main workshops of the Royal Austrian State Railways at Gmund, found that locomotive inner fireboxes of the usual type were both expensive, because the copper from which they were made had to be imported, and short-lived, because of corrosion resulting from the use of coal with high sulphur content. He designed a firebox of which the side and rear walls comprised rows of vertical watertubes, expanded at their lower ends into a tubular foundation ring and at the top into a longitudinal water/steam drum. This projected forward above the boiler barrel (which was of the usual firetube type, though of small diameter), to which it was connected. Copper plates were eliminated, as were firebox stays.The first boiler to incorporate a Brotan firebox was built at Gmund under the inventor's supervision and replaced the earlier boiler of a 0−6−0 in 1901. The increased radiantly heated surface was found to produce a boiler with very good steaming qualities, while the working pressure too could be increased, with consequent fuel economies. Further locomotives in Austria and, experimentally, elsewhere were equipped with Brotan boilers.Disadvantages of the boiler were the necessity of keeping the tubes clear of scale, and a degree of structural weakness. The Swiss engineer E. Deffner improved the latter aspect by eliminating the forward extension of the water/steam drum, replacing it with a large-diameter boiler barrel with the rear section of tapered wagon-top type so that the front of the water/steam drum could be joined directly to the rear tubeplate. The first locomotives to be fitted with this Brotan-Deffner boiler were two 4−6−0s for the Swiss Federal Railways in 1908 and showed very favourable results. However, steam locomotive development ceased in Switzerland a few years later in favour of electrification, but boilers of the Brotan-Deffner type and further developments of it were used in many other European countries, notably Hungary, where more than 1,000 were built. They were also used experimentally in the USA: for instance, Samuel Vauclain, as President of Baldwin Locomotive Works, sent his senior design engineer to study Hungarian experience and then had a high-powered 4−8−0 built with a watertube firebox. On stationary test this produced the very high figure of 4,515 ihp (3,370 kW), but further development work was frustrated by the trade depression commencing in 1929. In France, Gaston du Bousquet had obtained good results from experimental installations of Brotan-Deffner-type boilers, and incorporated one into one of his high-powered 4−6−4s of 1910. Experiments were terminated suddenly by his death, followed by the First World War, but thirty-five years later André Chapelon proposed using a watertube firebox to obtain the high pressure needed for a triple-expansion, high-powered, steam locomotive, development of which was overtaken by electrification.[br]Further ReadingG.Szontagh, 1991, "Brotan and Brotan-Deffner type fireboxes and boilers applied to steam locomotives", Transactions of the Newcomen Society 62 (an authoritative account of Brotan boilers).PJGR -
13 test
испытание; исследование; опыт, проба; проверка; обнаружение; определение; показатель пробы; характеристика продукта (результат пробы); II испытывать; подвергать испытанию; пробовать; исследовать; делать опыты- test bar- test bed- test by bending and unbending- test car- test conditions - test cubicle - test facilities - test fan - test figures - test for durability - test for ground - test for parallelism - test for short - test gauge - test glass - test hause - test lamp - test method - test miles per day - test mixer - test period - test pick - test pressure - test prod - test pulse - test results- test rig- test-room- test run- test to destruction - test tunnel - test unit - test vehicle - test work- air test- break down test - color test - crash test - exaggerated test - exhaustive test - exposure test - heavy duty test - hill climbing test- hot test- odd test- oil-immersion test - paint rub test - palm test - percentage test - percussion test - performance test - periodic test - physical test - pitting corrosion test - plasticity test - porosity test - pour test - pouring test - preliminaryt test - pressure test - production test - production typical test - programme test - proof test - protracted test - psychotechnic test - pull test - pulling test - punching test - qualification test - quality test - quantitative test - quick test - rebound hardness test - reception test - recovery test - red-heat test - repair test - repeated test - repeated bending stress test - repeated compression test - repeated direct stress test - repeated dynamic stress test - repeated impact test - repeated impact tension test - repeated stress test - repeated tensile stress test - repeated tension test - repeated torsion test - repetition test - replicated field test - resilience test - retardation test - reverse bend test - rig test - rigid test - road test - roll-over test - rolling acceleration test - rotating bar fatigue test - rotating beam fatigue test - rough test - rough-track test - routine test - running test - rupture test - safety test - scratch test - scratch oil test - screening test - scuffing test - separation test - service test - shake test - shock test - short-circuit test - short-time test - simulated test - single test - skid test - skid pad test - roadability test - slow-speed test - small-scale test - soil test - sonic test - standard distillation test - starting test - static test - static torsional test - steering test - step test - stiffness test - stop-and-go test - stop-start test - stopping and starting test - stroking test - structure test - tactical test - tensile and compression test - tensile fatigue test - test tensile impact test - tensile shock test - thermal test - tilting test - torque test - torsion test - torsion impact test - toughness test - towing test - transverse test - transverse bending test - trial test - triaxial compression test - twisting test - type test - ultrasonic test - understandability test - underwater test - vehicle drag test - vehicle road test - vibration test - vibratory test - visibility test - volatility test - warpage test - warranty test - water test - water-absorption test - water-resistance test - wear test - wearing test - weather-exposure test - weather-resistance test - weathering test - wheel test - whirling test - wind-tunnel test -
14 CRE
1) Медицина: cAMP response element, кумулятивный радиационный эффект2) Военный термин: Chemical Research Establishment, Classification, Recovery and Evacuation, Commander, Royal Engineers, Control and Reporting Element, combat readiness evaluation, command receiver equipment, cumulative radiation effect3) Техника: certified reliability engineer, collective radiation exposure, computers and related equipment, control room envelope, controlled residual element, corrosion-resistant, cosmic ray experiment4) Железнодорожный термин: Consolidated Rail Corporation (Eastern District)5) Юридический термин: Court Reporter Extensions, Court Reporting Extensions6) Сокращение: Commander Royal Engineers (UK), Commission for Racial Equality, Communications Radar Exciter, Cree7) Физиология: Cream9) Фирменный знак: Center for Regulatory Effectiveness10) Образование: Common Reading Experience, Coordinated Review Effort11) Расширение файла: Current Ring End, Infinity Game Engine Monster Description file12) Общественная организация: Center for Resource Economics, Council for Race and Emigration13) Должность: Coordinator For Residential Education, Counselor Of Real Estate -
15 Cre
1) Медицина: cAMP response element, кумулятивный радиационный эффект2) Военный термин: Chemical Research Establishment, Classification, Recovery and Evacuation, Commander, Royal Engineers, Control and Reporting Element, combat readiness evaluation, command receiver equipment, cumulative radiation effect3) Техника: certified reliability engineer, collective radiation exposure, computers and related equipment, control room envelope, controlled residual element, corrosion-resistant, cosmic ray experiment4) Железнодорожный термин: Consolidated Rail Corporation (Eastern District)5) Юридический термин: Court Reporter Extensions, Court Reporting Extensions6) Сокращение: Commander Royal Engineers (UK), Commission for Racial Equality, Communications Radar Exciter, Cree7) Физиология: Cream9) Фирменный знак: Center for Regulatory Effectiveness10) Образование: Common Reading Experience, Coordinated Review Effort11) Расширение файла: Current Ring End, Infinity Game Engine Monster Description file12) Общественная организация: Center for Resource Economics, Council for Race and Emigration13) Должность: Coordinator For Residential Education, Counselor Of Real Estate -
16 cre
1) Медицина: cAMP response element, кумулятивный радиационный эффект2) Военный термин: Chemical Research Establishment, Classification, Recovery and Evacuation, Commander, Royal Engineers, Control and Reporting Element, combat readiness evaluation, command receiver equipment, cumulative radiation effect3) Техника: certified reliability engineer, collective radiation exposure, computers and related equipment, control room envelope, controlled residual element, corrosion-resistant, cosmic ray experiment4) Железнодорожный термин: Consolidated Rail Corporation (Eastern District)5) Юридический термин: Court Reporter Extensions, Court Reporting Extensions6) Сокращение: Commander Royal Engineers (UK), Commission for Racial Equality, Communications Radar Exciter, Cree7) Физиология: Cream9) Фирменный знак: Center for Regulatory Effectiveness10) Образование: Common Reading Experience, Coordinated Review Effort11) Расширение файла: Current Ring End, Infinity Game Engine Monster Description file12) Общественная организация: Center for Resource Economics, Council for Race and Emigration13) Должность: Coordinator For Residential Education, Counselor Of Real Estate -
17 CRE
1. certified reliability engineer - дипломированный инженер по надёжности;2. collective radiation exposure - коллективное облучение;3. computers and related equipment - ЭВМ и периферийное оборудование;4. control room envelope - защитная оболочка помещения пульта управления;5. controlled residual element - контролируемый остаточный элемент;6. cosmic ray experiment - исследование космического излучения;7. corrosion-resistant - коррозионно-стойкий -
18 seat
1. кресло; сиденье ( члена экипажа или пассажира)2. седло, гнездо (напр. клапана)3. очаг (напр. коррозии) -
19 Monell, Ambrose
SUBJECT AREA: Metallurgy[br]b. 1874 New York, USAd. 2 May 1921 Beacon, New York, USA[br]American metallurgist who gave his name to a successful nickel-copper alloy.[br]After graduating from Columbia University in 1896. Monell became a metallurgical engineer to the Carnegie Steel Company, rising in six years to be Assistant to the President. In 1900, while Manager of the company's open-hearth steelworks at Pittsburg, he patented a procedure for making high-carbon steel in basic conditions on the hearth of a fixed/stationary furnace; the method was intended to refine pig-iron containing substantial proportions of phosphorus and to do so relatively quickly. The process was introduced at the Homestead Works of the Carnegie Steel Company in February 1900, where it continued in use for some years. In April 1902 Monell was among those who launched the International Nickel Company of New Jersey in order to bring together a number of existing nickel interests; he became the new company's President. In 1904–5, members of the company's metallurgical staff produced an alloy of about 70 parts nickel and 30 copper which seemed to show great commercial promise on account of its high resistance to corrosion and its good appearance. Monell agreed to the suggestion that the new alloy should be given his name; for commercial reasons it was marketed as "Monel metal". In 1917, following the entry of the USA into the First World War, Monell was commissioned Colonel in the US Army (Aviation) for overseas service, relinquishing his presidency of the International Nickel Company but remaining as a director. At the time of his death he was also a director in several other companies in the USA.[br]Bibliography1900, British patent no. 5506 (taken out by O. Imray on behalf of Monell).Monell insinuated an account of his steel-making procedure at a meeting of the Iron and Steel Institute held in London and reported in The Journal of the Iron and SteelInstitute (1900) 1:71–80; some of the comments made by other speakers, particularly B.Talbot, were adverse. The following year (1901) Monell produced a general historical review: "A summary of development in open-hearth steel", Iron TradeReview 14(14 November):39–47.Further ReadingA.J.Wadhams, 1931, "The story of the nickel industry", Metals and Alloys 2(3):166–75 (mentions Monell among many others, and includes a portrait (p. 170)).JKA -
20 seat
seat nкреслоseating vкомпоновка кресел(на воздушном судне) adjustable seatрегулируемое сиденьеaft facing seatкресло, расположенное против направления полетаaircraft seating densityплотность размещения кресел на воздушном суднеautomatic seat reservationавтоматическое бронирование местbook a seatбронировать местоcabin attendants seatсиденье бортпроводникаcaptain's seatкресло командира корабляco-pilot's seatкресло второго пилотаcorrosion seatочаг коррозииeconomy-class seatingкомпоновка кресел в салоне туристического классаfasten seat beltпристегивать привязные ремниfirst-class seatingкомпоновка кресел в салоне первого классаflight engineer's seatкресло бортинженераfolding seatоткидное сиденьеforward facing seatкресло, расположенное по направлению полетаhigh-density seatingкомпоновка кресел с минимальным шагомhigh-density seating layoutэкономичная компоновкаmixed-class seatingкомпоновка кресел в салоне смешанного классаnonbooked seatнезабронированное местоoutboard facing seatкресло, расположенное перпендикулярно направлению полетаpacking gland seatгнездо сальникаpassenger seatпассажирское креслоpilot seatкресло пилотаreclining seatкресло с отклоняющейся спинкойreservation of a seatбронирование местаseat beltsпривязные ремниseat cushionподушка креслаseating arrangementразмещение пассажирских креселseating capacityпассажировместимостьseat installationустановка креселseat pack parachuteпарашют - сиденьеseat pitchшаг креселseat the brushпритирать щеткуsleeper seatспальное местоswivel seatкресло на поворотном кронштейнеtourist-version seatкресло пассажира туристического классаunit seat priceсредняя стоимость одного местаvalve seatседло клапана
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