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1 residual heat removal pump
- насос контура расхолаживания активной зоны ядерного реактора
- насос контура расхолаживания активной зоны при аварии ядерного реактора
насос контура расхолаживания активной зоны при аварии ядерного реактора
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[А.С.Гольдберг. Англо-русский энергетический словарь. 2006 г.]Тематики
EN
насос контура расхолаживания активной зоны ядерного реактора
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[А.С.Гольдберг. Англо-русский энергетический словарь. 2006 г.]Тематики
EN
Англо-русский словарь нормативно-технической терминологии > residual heat removal pump
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2 residual heat removal pump
Универсальный англо-русский словарь > residual heat removal pump
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3 residual heat removal pump
Engineering: RHRPУниверсальный русско-английский словарь > residual heat removal pump
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4 насос контура расхолаживания активной зоны ядерного реактора
насос контура расхолаживания активной зоны ядерного реактора
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[А.С.Гольдберг. Англо-русский энергетический словарь. 2006 г.]Тематики
EN
Русско-английский словарь нормативно-технической терминологии > насос контура расхолаживания активной зоны ядерного реактора
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5 RHRP
residual heat removal pump - насос отвода остаточного тепла, насос контура расхолаживания -
6 насос контура расхолаживания активной зоны при аварии ядерного реактора
насос контура расхолаживания активной зоны при аварии ядерного реактора
—
[А.С.Гольдберг. Англо-русский энергетический словарь. 2006 г.]Тематики
EN
Русско-английский словарь нормативно-технической терминологии > насос контура расхолаживания активной зоны при аварии ядерного реактора
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7 RHRP
Техника: residual heat removal pump -
8 насос контура расхолаживания
Engineering: residual heat removal pumpУниверсальный русско-английский словарь > насос контура расхолаживания
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9 насос отвода остаточного тепла
Engineering: residual heat removal pumpУниверсальный русско-английский словарь > насос отвода остаточного тепла
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10 RHRP
насос контура расхолаживания активной зоны при аварии ядерного реактора
—
[А.С.Гольдберг. Англо-русский энергетический словарь. 2006 г.]Тематики
EN
Англо-русский словарь нормативно-технической терминологии > RHRP
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11 time
1. время, продолжительность; период; срок || рассчитывать по времени; отмечать время; хронометрировать2. такт; темпtime of running in — время, требуемое на спуск бурового инструмента
wait on plastic time — время ожидания затвердевания пластмассы (при тампонировании скважины полимерами) (до получения прочности, равной 7 МПа)
— in unit time— rig time— set time
* * *
1. время; период; момент; срок; продолжительность2. наработкаmean time between complaints — среднее время между рекламациями; средняя наработка на рекламацию
time to repair completion — время до завершения ремонта;
— bad time
* * *
время; продолжительность; темп; такт
* * *
время, момент
* * *
1) время; период; момент; срок; продолжительность2) наработка•time at shot point — сейсм. вертикальное время;
time between defects — наработка между появлениями дефектов;
time between failures — наработка между отказами;
time between maintenance actions — наработка между операциями технического обслуживания;
time between overhauls — межремонтный срок службы; наработка между капитальными ремонтами;
time between repairs — межремонтный срок службы; наработка между ремонтами;
time between tests — время между испытаниями;
time on bottom — продолжительность нахождения инструмента в забое;
time on trip — время на спуско-подъёмные операции;
time since circulation — интервал времени между остановкой циркуляции бурового раствора и началом каротажа;
time since overhaul — наработка после капитального ремонта;
time to damage — наработка до повреждения;
time to failure — наработка до отказа;
time to first system failure — наработка до первого отказа системы;
time to locate a failure — время до обнаружения местонахождения неисправности;
time to repair — наработка до ремонта;
time to repair completion — время до завершения ремонта;
time to restore — наработка до восстановления;
- time of arrivaltime to system failure — наработка до отказа системы;
- time of ascend
- time of echo
- time of flight
- time of running-in
- time of service
- time of setting
- time transit
- active maintenance time
- active repair time
- active technician time
- actual casing cutting time
- actual drilling time
- administrative time
- alert time
- arrival time
- attendance time
- available time
- average time between maintenance
- average mooring time
- awaiting repair time
- bad time
- Barnaby time
- bedrock-reflection time
- bit time off-bottom
- bit time on-bottom
- bit run time
- boring time
- break time
- breakdown time
- casing-fluid decay time
- cement setting time
- cementing time
- changing time
- charging-up time
- circulation cycle time
- closed-in time
- composite delay time
- connection time
- coring time
- corrected travel time
- corrective maintenance time
- critical fault clearing time
- critical ray time
- cutting-in time
- datum-corrected time
- dead time
- delay technician time
- discharge time
- down time
- drainage time
- drilling time
- drilling time per bit
- drilling bit changing time
- effective repair time
- elapsed maintenance time
- end-to-end time
- engineering time
- equal travel time
- equipment repair time
- estimated time of repair
- estimated mean time to failure
- estimated repair time
- etching time
- expected time to first failure
- expected time to repair
- expected test time
- exponential failure time
- failed time
- failure time
- failure-detection time
- failure-free time
- failure-reaction time
- fault time
- fault-detection time
- fault-free time
- fault-inception time
- fill-up time
- filling time
- filtration time
- final cement setting time
- final setting time
- final test time
- first-arrival time
- first-break time
- first-event time
- fishing time
- flush time
- forward time
- general repair time
- geological time
- geometrical ray-path time
- geophone time
- ghost travel time
- gross drilling time
- guarantee time
- half-intercept time
- head-wave arrival time
- high-velocity time
- horizon time
- in-commission time
- infinite closed-in time
- infusion time
- initial setting time
- intercept time
- interfailure time
- interpolated time
- interrepair time
- interval time
- interval transit time
- jelling time
- lag time
- least travel time
- localization time
- lost time
- maintenance time
- makeup time
- malfunction repair time
- maximum repair time
- mean time
- mean time between complaints
- mean time between defects
- mean time between detectable failures
- mean time between malfunctions
- mean time between unscheduled removals
- mean time of repair
- mean time to crash
- mean time to diagnosis
- mean time to first failure
- mean time to isolate
- mean time to maintenance
- mean time to removal
- mean time to repair failures
- mean time to replacement
- mean time to restore
- mean time to return to service
- mean time to unscheduled removal
- mean corrective maintenance time
- mean diagnostic time
- mean maintenance time
- mean operating time
- mean repair time
- mean up time
- measured travel time
- median time to failure
- median maintenance time
- minimum time to repair
- mooring time
- moveout time
- moving time
- mud-path correction time
- net time on-bottom
- net drilling time
- nipple-down time
- nipple-up time
- nonactive maintenance time
- nonfailure operation time
- nonproductive rig time
- nonscheduled maintenance time
- normal arrival time
- observed travel time
- off-stream time
- oil field development time
- oil production time
- on-bottom time
- one-way time
- one-way travel time
- operating time
- operating time between failures
- operational use time
- out-of-commission time
- overall time
- overhaul time
- pipe abandoning time
- pipe recovery time
- pool formation time
- pressure build-up time
- pressure readjustment time
- preventive maintenance time
- production time
- productive time
- productive rig time
- propagation time
- proving time
- pulling-out time
- pulse time of arrival
- pumpability time
- pump-down time
- pumping time
- putting on production time
- raw time
- ray-path time
- readiness time
- ready time
- reciprocal time
- reciprocating time
- record time
- reflection arrival time
- reflection travel time
- refraction break time
- refraction travel time
- rejection operating time
- removal time
- repair time per failure
- repair-and-servicing time
- repair-delay time
- repair-to-repair time
- replacement time
- required time of operation
- residual time
- reversed time
- rig time
- rig-down time
- rig-up time
- round-trip time
- round-up time
- routine maintenance time
- running-in time
- sample deformation time
- scheduled engineering time
- scheduled operating time
- search time
- second-event time
- seismic interval time
- seismic record time
- service time
- service adequacy time
- servicing time
- setting time
- setting-up time
- setup time
- shooting time
- shot-hole time
- shot-to-receiver time
- shut-in time
- spending time
- standby time
- standby unattended time
- station time
- step-out time
- supplementary maintenance time
- surface-to-surface time
- survival time
- tank emptying time
- tear-down time
- technician delay time
- thickening time of cement
- total time on test
- total gaging time
- total maintenance time
- total path time
- total rig time
- total technician time
- transit time
- traveling time
- trip time
- troubleshooting time
- turnaround time
- turnover time
- two-way travel time
- unproductive time
- uphole time
- uphole-shooting time
- usable time
- vertical path time
- vertical travel time
- vibration time
- wait-before-repair time
- waiting-on-cement time
- waiting-on-plastic time
- water-break time
- wave arrival time
- wave transit time
- wave traveling time
- wavefront time
- wear-out time
- weathering time
- well building time
- well drilling time
- well shut-in time
- zero-offset arrival time
- zero-offset travel time
- zero-spread time* * *• момент -
12 capacity
1) основная характеристика (напр. станка)2) ёмкость, вместимость; объём3) мощность; производительность; пропускная способность4) наибольшие размеры, габаритные размеры5) эл. ёмкость6) информационная ёмкость (ЗУ)7) допустимый диапазон чисел (устройства, аппарата); разрядность8) способность; возможность9) нагрузка, допустимая нагрузка10) грузоподъёмность•- absorbing capacity
- absorption capacity
- absorptive capacity
- adhesive capacity
- adsorptive capacity
- aggregate capacity
- ATC capacity
- available capacity
- bar capacity
- bar stock capacity
- bearing capacity
- between centers capacity
- boring capacity
- breaking capacity
- broaching capacity
- bumped capacity
- capacity of planer
- capacity of press
- capacity of pump
- capacity of stroke
- card capacity
- carrying capacity
- centerhole capacity
- channel capacity
- chip-carrying capacity
- chip-receiving capacity
- chuck capacity
- chucking capacity
- collet capacity
- component capacity
- component weight capacity
- contact closing capacity
- contact interrupting capacity
- container capacity
- conveying capacity
- craft capacity
- crane capacity
- cube capacity
- current-making capacity
- cutting capacity
- cyclic capacity
- cylinder capacity
- daily capacity
- damping capacity
- deliverable capacity
- diameter capacity
- dirt-holding capacity
- distributed capacity
- drilling capacity
- elevating capacity
- emissive capacity
- flexible machining capacity
- front/back drilling capacity
- governing capacity
- grinding capacity
- gripper capacity
- gross capacity
- handling capacity
- hardening capacity
- heat capacity
- heat storage capacity
- heating capacity
- heat-transfer capacity
- heat-transmission capacity
- hoisting capacity
- horsepower capacity
- hourly capacity
- idle capacity
- information capacity
- intelligent capacity
- jaw capacity
- lifting capacity
- limiting breaking capacity
- limiting cycling capacity
- limiting making capacity
- live centers capacity
- load bearing capacity
- load capacity
- load carrying capacity
- machine capacity
- magazine capacity
- making capacity
- making-and-breaking capacity
- manufacturing capacity
- manufacturing-cell capacity
- maximum part-size capacity
- metal-removing capacity
- milling capacity
- net capacity
- net load capacity
- oil pump capacity
- opening capacity
- operating capacity
- optional magazine capacity
- overbed capacity
- overload capacity
- pallet capacity
- pallet-weight capacity
- payload capacity
- peak pulling capacity
- pipe capacity
- power capacity
- power transmission capacity
- production capacity
- productive capacity
- program capacity
- pulling capacity
- pump capacity per revolution
- pump capacity
- punching capacity
- radial capacity
- radiating capacity
- rated capacity
- rated load capacity
- reading capacity
- reserve capacity
- residual capacity
- running capacity
- shock-absorbing capacity
- spare capacity
- specific capacity
- specific thermal capacity
- specific thermal heat capacity
- static capacity
- step chuck capacity
- stock removal capacity
- storage capacity
- surface capacity
- surface load capacity
- swing overbed capacity
- table capacity
- table load capacity
- tank capacity
- tapping capacity
- theoretical capacity
- thermal capacity
- thermal heat capacity
- through capacity
- throughput capacity
- thru-hole capacity
- thrust capacity
- tool slot capacity
- tool storage capacity
- tooling capacity
- torque capacity
- total tool capacity
- transient overload capacity
- travel capacity
- turning capacity
- turret capacity
- ultimate capacity
- unit capacity
- usable capacity
- useful capacity
- volumetric capacity
- wearing capacity
- weight capacity
- weight handling capacity
- work size capacity
- work space capacity
- working capacity
- working load capacity
- workpiece capacity
- workpiece-carrying capacityEnglish-Russian dictionary of mechanical engineering and automation > capacity
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13 Swan, Sir Joseph Wilson
[br]b. 31 October 1828 Sunderland, Englandd. 27 May 1914 Warlingham, Surrey, England[br]English chemist, inventor in Britain of the incandescent electric lamp and of photographic processes.[br]At the age of 14 Swan was apprenticed to a Sunderland firm of druggists, later joining John Mawson who had opened a pharmacy in Newcastle. While in Sunderland Swan attended lectures at the Athenaeum, at one of which W.E. Staite exhibited electric-arc and incandescent lighting. The impression made on Swan prompted him to conduct experiments that led to his demonstration of a practical working lamp in 1879. As early as 1848 he was experimenting with carbon as a lamp filament, and by 1869 he had mounted a strip of carbon in a vessel exhausted of air as completely as was then possible; however, because of residual air, the filament quickly failed.Discouraged by the cost of current from primary batteries and the difficulty of achieving a good vacuum, Swan began to devote much of his attention to photography. With Mawson's support the pharmacy was expanded to include a photographic business. Swan's interest in making permanent photographic records led him to patent the carbon process in 1864 and he discovered how to make a sensitive dry plate in place of the inconvenient wet collodian process hitherto in use. He followed this success with the invention of bromide paper, the subject of a British patent in 1879.Swan resumed his interest in electric lighting. Sprengel's invention of the mercury pump in 1865 provided Swan with the means of obtaining the high vacuum he needed to produce a satisfactory lamp. Swan adopted a technique which was to become an essential feature in vacuum physics: continuing to heat the filament during the exhaustion process allowed the removal of absorbed gases. The inventions of Gramme, Siemens and Brush provided the source of electrical power at reasonable cost needed to make the incandescent lamp of practical service. Swan exhibited his lamp at a meeting in December 1878 of the Newcastle Chemical Society and again the following year before an audience of 700 at the Newcastle Literary and Philosophical Society. Swan's failure to patent his invention immediately was a tactical error as in November 1879 Edison was granted a British patent for his original lamp, which, however, did not go into production. Parchmentized thread was used in Swan's first commercial lamps, a material soon superseded by the regenerated cellulose filament that he developed. The cellulose filament was made by extruding a solution of nitro-cellulose in acetic acid through a die under pressure into a coagulating fluid, and was used until the ultimate obsolescence of the carbon-filament lamp. Regenerated cellulose became the first synthetic fibre, the further development and exploitation of which he left to others, the patent rights for the process being sold to Courtaulds.Swan also devised a modification of Planté's secondary battery in which the active material was compressed into a cellular lead plate. This has remained the central principle of all improvements in secondary cells, greatly increasing the storage capacity for a given weight.[br]Principal Honours and DistinctionsKnighted 1904. FRS 1894. President, Institution of Electrical Engineers 1898. First President, Faraday Society 1904. Royal Society Hughes Medal 1904. Chevalier de la Légion d'Honneur 1881.Bibliography2 January 1880, British patent no. 18 (incandescent electric lamp).24 May 1881, British patent no. 2,272 (improved plates for the Planté cell).1898, "The rise and progress of the electrochemical industries", Journal of the Institution of Electrical Engineers 27:8–33 (Swan's Presidential Address to the Institution of Electrical Engineers).Further ReadingM.E.Swan and K.R.Swan, 1968, Sir Joseph Wilson Swan F.R.S., Newcastle upon Tyne (a detailed account).R.C.Chirnside, 1979, "Sir Joseph Swan and the invention of the electric lamp", IEEElectronics and Power 25:96–100 (a short, authoritative biography).GWBiographical history of technology > Swan, Sir Joseph Wilson
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насос контура расхолаживания активной зоны при аварии ядерного реактора — — [А.С.Гольдберг. Англо русский энергетический словарь. 2006 г.] Тематики энергетика в целом EN residual heat removal pumpRHRP … Справочник технического переводчика
насос контура расхолаживания активной зоны ядерного реактора — — [А.С.Гольдберг. Англо русский энергетический словарь. 2006 г.] Тематики энергетика в целом EN residual heat removal pump … Справочник технического переводчика
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