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1 absorbed gas
Англо-русский словарь нормативно-технической терминологии > absorbed gas
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2 absorbed gas
infrared absorbing gas — газ, поглощающий инфракрасные лучи
The English-Russian dictionary general scientific > absorbed gas
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3 absorbed gas
абсорбированный газ, поглощенный газБольшой англо-русский и русско-английский словарь > absorbed gas
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4 absorbed gas
* * *
абсорбированный газ, поглощённый газ* * *Англо-русский словарь нефтегазовой промышленности > absorbed gas
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5 absorbed gas
Нефть: абсорбированный газ, поглощённый газ -
6 absorbed gas
абсорбированный газ, поглощенный газ.English-Russian dictionary of terms for geological exploration drilling > absorbed gas
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7 absorbed gas
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8 absorbed gas
(fiz, termo) gaz absorbit -
9 absorbed gas
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10 gas
1. газ, газообразное вещество || выделять газ; наполнять газом, насыщать газом2. горючее; газолин; бензин || заправлять горючим— acid gas— dry gas— end gas— exit gas— fat gas— flue gas— free gas— fuel gas— lean gas— net gas— oil gas— rich gas— rock gas— sour gas— town gas— trip gas— wet gas
* * *
high altitude liquid petroleum gas — сжиженный нефтяной газ с повышенным содержанием бутана (для применения в условиях пониженного атмосферного давления)
— dry gas— foul gas— lean gas— lift gas— oil gas— rich gas— rock gas— sour gas— tank gas— wet gas
* * *
1. газ2. горючее, бензин
* * *
* * *
1) газ, газообразное вещество || выделять газ; наполнять газом, насыщать газом2) горючее; газолин; бензин || заправлять горючим•gas in place — запасы газа в коллекторе;
gas in reservoir — пластовой газ;
gas in-situ — газ в пластовых условиях;
gas in solution — растворённый газ;
no gas to surface — газ на поверхность не поступает;
gas originally in place — первоначальные запасы газа в коллекторе;
to boost gas along to its destination — повышать давление газа для доставки его к месту назначения;
to make the gas — выделять газ;
to sweeten gas — удалять из газа соединения серы;
- gas of radiation-chemical originto take-off casing-head gas — отбирать нефтяной газ на устье скважины;
- gas of stratal water
- absorbed gas
- accompanying gas
- acid gas
- active gas
- actual gas
- adsorbed gas
- aerogen gas
- air gas
- air-free gas
- air-producer gas
- alky gas
- all-weather liquefied petroleum gas
- ammonia synthesis gas
- annular gas
- artificial gas
- associated gas
- associated dissolved gas
- associated petroleum gas
- aviation gas
- background gas
- biochemical natural gas
- blanket gas
- blowdown gas
- blue gas
- bottled gas
- Braden head gas
- burned gas
- burning gas
- butane-enriched water gas
- butane-propane gas
- by-product gas
- cap gas
- carbon-dioxide gas
- carbureted gas
- carbureted hydrogen gas
- carbureted water gas
- carrier gas
- casing-head gas
- city gas
- coercible gas
- coke oven gas
- combination gas
- combustible gas
- combustion gas
- commercial gas
- commercial rock gas
- compressed gas
- compressed natural gas
- condensed gas
- condensed natural gas
- conditioned gas
- consumer gas
- conventional gas
- converted gas
- corrosive gas
- crude gas
- cumulative gas injected
- cushion gas
- cylinder gas
- dehydrated petroleum gas
- diluted gas
- dispersed gas
- dissolved gas
- distillation gas
- domestic gas
- drive gas
- dry gas
- dry petroleum gas
- dump gas
- end gas
- enriched gas
- entrained gas
- escaping gas
- exhaust gas
- exit gas
- expansion gas
- extraneous gas
- extremely dry gas
- fat gas
- filtered flue gas
- fire gas
- fixed gas
- flammable gas
- flare gas
- flash gas
- flue gas
- fluorocarbon gas
- flush gas
- formation gas
- formation water gas
- foul gas
- free gas
- fuel gas
- full-stream gas
- fume-laden gas
- furnace gas
- gaslift gas
- gas-well gas
- green gas
- heating gas
- helium-bearing natural gas
- high gas
- high-altitude liquid petroleum gas
- high-BTU gas
- high-calorific gas
- high-line gas
- highly corrosive gas
- high-pressure gas
- high-purity gas
- household fuel gas
- humid gas
- hydrocarbon gas
- ideal gas
- illuminating gas
- immobile gas
- imperfect gas
- imported gas
- inactive gas
- included gas
- incoming gas
- indifferent gas
- industrial gas
- inert gas
- inflammable gas
- initial gas in reservoir
- injected gas
- in-place petroleum gas
- ionized gas
- kerosene gas
- kiln gas
- lean gas
- lean petroleum gas
- liberated gas
- lift gas
- lighting gas
- liquefied gas
- liquefied hydrocarbon gas
- liquefied natural gas
- liquefied petroleum gas
- liquid gas
- liquid natural gas
- liquid petroleum gas
- live gas
- low-boiling gas
- low-calorific gas
- low-pressure petroleum gas
- low-thermal-value fuel gas
- makeup gas
- manufactured gas
- manure gas
- marsh gas
- medium-energy coal-derived gas
- metamorphic natural gas
- methane-rich gas
- mixed gas
- mud gas
- naphtha gas
- native gas
- natural gas
- net gas
- noble gas
- nonassociated gas
- nonassociated natural gas
- noncondensable gas
- noncorrosive gas
- nonhydrocarbon gas
- nonpurified gas
- nonrecoverable gas
- nonstripped petroleum gas
- noxious gas
- occluded gas
- off gas
- oil gas
- oil-dissolved gas
- oil-water gas
- oil-well gas
- olefiant gas
- onboard-stored gas
- oxyhydrogen gas
- paraffin gas
- peat gas
- perfect gas
- petroleum gas
- pipeline gas
- poor gas
- power gas
- processed gas
- produced gas
- producer gas
- product gas
- purchased gas
- purge gas
- radiogenic gas
- purifield gas
- quenching gas
- radioactive gas
- radon gas
- raw natural gas
- reactivation gas
- receiver gas
- recirculated gas
- recoverable gas
- recoverable petroleum gas
- refinery gas
- regeneration gas
- residual gas
- residue gas
- retained gas
- rich gas
- rich petroleum gas
- rock gas
- sales gas
- sedimentary natural gas
- separator gas
- shale gas
- shallow gas
- shocked gas
- sludge gas
- solute gas
- solution gas
- sour gas
- sour petroleum gas
- spent gas
- stabilizer gas
- stack gas
- stillage gas
- stripped gas
- stripped petroleum gas
- stripper gas
- substitute natural gas
- sulfur dioxide gas
- sulfurous gas
- sweet gas
- synthetic gas
- tail gas
- tank gas
- town gas
- toxic gas
- transborder gas
- transcontinental gas
- transported gas
- trapped gas
- treated gas
- trip gas
- unassociated gas
- underground storage gas
- undissolved gas
- unstripped gas
- vadose gas
- washed gas
- waste gas
- water gas
- water-dissolved gas
- well head gas
- wet gas
- wet field gas
- wet petroleum gas
- zero-hydrogen-index gas* * * -
11 gas
1. n физ. газ, газообразное вещество2. n светильный газ3. n горн. метан, рудничный газinfrared absorbing gas — газ, поглощающий инфракрасные лучи
4. n воен. газ, отравляющее вещество5. n веселящий газ; закись азота; эфир6. n уст. газовое освещение7. n амер. сл. бензин; газолин; топливоwet natural gas — природный газ, богатый бензином
gas fuel — газовое топливо, горючий газ
8. n разг. болтовня, бахвальство, трёп9. n мед. газы, ветры10. n сл. сногсшибательная шуткаwe did it for a gas — мы это просто так сделали, ради шутки
11. n сл. нечто потрясающее12. a газовый; газообразный13. v воен. поражать, заражать отравляющими веществами; производить химическое нападениеwar gas — боевое отравляющее вещество, БОВ
poison gas — ядовитый газ; отравляющее вещество
14. v наполнять, насыщать газомflue gas heater — нагреватель, работающий на дымовых газах
fixed gas — газ, не конденсирующийся в нормальных условиях
15. v выделять газconfined the gas over — собрал газ над; собранный газ над
16. v амер. разг. заправляться горючим17. v разг. болтать, трепаться; бахвалиться; нести вздор18. v сл. потрясти, произвести огромное впечатление; блеснутьJulie sang and she gassed me, she was that good — Джули так хорошо пела, я был просто потрясён
Синонимический ряд:1. effluvium (noun) effluvium; fume; miasma2. general anesthetic (noun) chloroform; ether; general anaesthetic; general anesthetic; laughing gas; nitrous oxide3. motor fuel (noun) diesel; fuel; gasohol; gasoline; motor fuel; petrol; petroleum; propellant4. poison gas (noun) agent orange; benzyl; hydrocyanic acid; incendiary gas; mustard gas; phosgene; poison gas; systemic poison; tear gas5. vapor (noun) air; carbon dioxide; fumes; gaseous mixture; helium; hydrogen; oxygen; vapor; vapour; volatile substanceАнтонимический ряд:liquid; solid -
12 rare gas
1. инертный газ; благородный газ; редкий газinfrared absorbing gas — газ, поглощающий инфракрасные лучи
2. благородный газThe English-Russian dictionary general scientific > rare gas
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13 energy
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absorbed radiation energy
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absorbed-in-compression energy
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absorbed-in-fracture energy
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acoustic energy
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activation energy of friction
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activation energy
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active energy
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adhesive binding energy
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allowed energy
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alternative energy
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atomic energy
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average photon energy
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band-gap energy
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base-load energy
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base energy
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binding energy
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biomass energy
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bonding energy
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bond energy
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boundary energy
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braking energy
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break-up energy
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brittle fracture energy
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brittle shelf energy
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buoyancy energy
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bus-bar energy
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capillary energy
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charge energy
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Charpy impact energy
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Charpy V-notch shelf energy
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Charpy V-notch energy
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chemical energy
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clean energy
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cohesive binding energy
-
cohesive bonding energy
-
cohesive energy
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comfort energy
-
conduction band energy
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Coulomb energy
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crack closure energy
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crack energy
-
crude energy
-
cutoff energy
-
decay energy
-
derived energy
-
discharge energy
-
disintegration energy
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dissociation energy
-
distortion strain energy
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distortion energy
-
ductile fracture energy
-
elastic strain energy
-
elastic energy
-
electric energy
-
electric field energy
-
electrical potential energy
-
electrochemical free energy
-
electrokinetic energy
-
electrolytic dissociation energy
-
electromagnetic energy
-
electron energy
-
electrostatic energy
-
embrittling energy
-
epithermal energy
-
excess energy
-
exchange energy
-
excitation energy
-
exhaust energy
-
field energy
-
firm energy
-
fission energy
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fracture energy
-
free energy
-
free surface energy
-
frictional energy
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fusion energy
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fusion plasma energy
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gap energy
-
generating station auxiliary energy
-
generating station net output energy
-
geokinetic energy
-
geothermal energy
-
grain-boundary energy
-
heat energy
-
Helmholtz free energy
-
Helmholtz energy
-
hole-electron energy
-
hydration energy
-
hydraulic energy
-
hysteresis energy
-
impurity ionization energy
-
incident energy
-
incident solar energy
-
input energy
-
instantaneous strain energy
-
interaction energy
-
interface energy
-
interfacial energy
-
internal energy
-
ionization energy
-
kinetic energy
-
kink energy
-
latent energy
-
lattice energy
-
light energy
-
low-grade energy
-
luminous energy
-
magnetic energy
-
magnetic fusion energy
-
mechanical energy
-
misfit energy
-
motional energy
-
net energy
-
noise energy
-
nonfirm energy
-
nuclear energy
-
off-peak energy
-
on-peak energy
-
optical energy
-
particle energy
-
pattern energy
-
peak energy
-
peel energy
-
photon energy
-
plastic strain energy
-
plastic energy
-
portable energy
-
potential energy
-
pressure energy
-
primary energy
-
prompt gamma energy
-
pulse energy
-
pumping energy
-
quantum energy
-
radiant energy
-
radiant pulse energy
-
reactive energy
-
refuse-to-gas energy
-
released energy
-
reservoir energy
-
resilience energy
-
resonance-absorption energy
-
rest energy
-
run-of-river energy
-
seasonal storage energy
-
secondary energy
-
separation energy
-
sideband energy
-
soft energy
-
solar energy
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sound energy
-
specific energy
-
spike leakage energy
-
stacking fault energy
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stored energy
-
strain energy
-
stream energy
-
sun energy
-
surface energy
-
thermal energy
-
thermoelectric energy
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threshold energy
-
tidal energy
-
transient energy
-
translational energy
-
turbulent energy
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turbulent kinetic energy
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upper shelf energy
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up-the-ladder energy
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wake energy
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waste energy
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zero-point energy -
14 unit
организационная единица; боевая единица (напр. корабль, ЛА танк); подразделение; часть; соединение; расчетно-снабженческая единица; секция; орган; элемент; комплект; агрегат; установка; см. тж. elementbulk petrol (transport) unit — Бр. часть [подразделение] подвоза наливного (бестарного) горючего
counter C3 unit — часть [подразделение] подавления системы оперативного управления и связи
Fleet Marine (Corps) reconnaissance unit — разведывательное подразделение [часть] флотских сил МП
multisensor (AA) firing unit 3PK — с приборным комплексом из нескольких систем обнаружения и сопровождения
photo (graphic) reconnaissance unit — фоторазведывательная часть [подразделение]
surface-launched unit, fuel air explosive — установка дистанционного разминирования объемным взрывом
surface-launched unit, mine — установка дистанционного минирования
tactical (air) control unit — часть [подразделение] управления ТА
war (time) strength (TOE) unit — часть, укомплектованная по штатам военного времени
— air unit— ASA unit— BM unit— border operation unit— car unit— depot support unit— dry unit— EW unit— GM unit— host country unit— HQ unit— logistics support unit— manpack radio unit— marksmanship training unit— mechanized infantry unit— missile-armed unit— nuclear weapon unit— provisional unit— QM unit— Rangers unit— supported unit— TOE unit— transportation unit— truck transport unit— van unit— wet unit* * *1) часть; 2) единица -
15 Giffard, Baptiste Henry Jacques (Henri)
[br]b. 8 February 1825 Paris, Franced. 14 April 1882 Paris, France[br]French pioneer of airships and balloons, inventor of an injector for steam-boiler feedwater.[br]Giffard entered the works of the Western Railway of France at the age of 16 but became absorbed by the problem of steam-powered aerial navigation. He proposed a steam-powered helicopter in 1847, but he then turned his attention to an airship. He designed a lightweight coke-burning, single-cylinder steam engine and boiler which produced just over 3 hp (2.2 kW) and mounted it below a cigar-shaped gas bag 44 m (144 ft) in length. A triangular rudder was fitted at the rear to control the direction of flight. On 24 September 1852 Giffard took off from Paris and, at a steady 8 km/h (5 mph), he travelled 28 km (17 miles) to Trappes. This can be claimed to be the first steerable lighter-than-air craft, but with a top speed of only 8 km/h (5 mph) even a modest headwind would have reduced the forward speed to nil (or even negative). Giffard built a second airship, which crashed in 1855, slightly injuring Giffard and his companion; a third airship was planned with a very large gas bag in order to lift the inherently heavy steam engine and boiler, but this was never built. His airships were inflated by coal gas and refusal by the gas company to provide further supplies brought these promising experiments to a premature end.As a draughtsman Giffard had the opportunity to travel on locomotives and he observed the inadequacies of the feed pumps then used to supply boiler feedwater. To overcome these problems he invented the injector with its series of three cones: in the first cone (convergent), steam at or below boiler pressure becomes a high-velocity jet; in the second (also convergent), it combines with feedwater to condense and impart high velocity to it; and in the third (divergent), that velocity is converted into pressure sufficient to overcome the pressure of steam in the boiler. The injector, patented by Giffard, was quickly adopted by railways everywhere, and the royalties provided him with funds to finance further experiments in aviation. These took the form of tethered hydrogen-inflated balloons of successively larger size. At the Paris Exposition of 1878 one of these balloons carried fifty-two passengers on each tethered "flight". The height of the balloon was controlled by a cable attached to a huge steam-powered winch, and by the end of the fair 1,033 ascents had been made and 35,000 passengers had seen Paris from the air. This, and similar balloons, greatly widened the public's interest in aeronautics. Sadly, after becoming blind, Giffard committed suicide; however, he died a rich man and bequeathed large sums of money to the State for humanitarian an scientific purposes.[br]Principal Honours and DistinctionsCroix de la Légion d'honneur 1863.Bibliography1860, Notice théorique et pratique sur l'injecteur automoteur.1870, Description du premier aérostat à vapeur.Further ReadingDictionnaire de biographie française.Gaston Tissandier, 1872, Les Ballons dirigeables, Paris.—1878, Le Grand ballon captif à vapeur de M. Henri Giffard, Paris.W.de Fonvielle, 1882, Les Ballons dirigeables à vapeur de H.Giffard, Paris. Giffard is covered in most books on balloons or airships, e.g.: Basil Clarke, 1961, The History of Airships, London. L.T.C.Rolt, 1966, The Aeronauts, London.Ian McNeill (ed.), 1990, An Encyclopaedia of the History of Technology, London: Routledge, pp. 575 and 614.J.T.Hodgson and C.S.Lake, 1954, Locomotive Management, Tothill Press, p. 100.PJGR / JDSBiographical history of technology > Giffard, Baptiste Henry Jacques (Henri)
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16 pollution sink
поглотитель загрязнения
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[ http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]EN
pollution sink
Vehicle for removal of a chemical or gas from the atmosphere-biosphere-ocean system, in which the substance is absorbed into a permanent or semi-permanent repository, or else transformed into another substance. A carbon sink, for example, might be the ocean (which absorbs and holds carbon from other parts of carbon cycle) or photosynthesis (which converts atmospheric carbon into plant material). Sinks are a fundamental factor in the ongoing balance which determines the concentration of every greenhouse gas in the atmosphere. If the sink is greater than the sources of a gas, its concentration in the atmosphere will decrease; if the source is greater than the sink, the concentration will increase. (Source: GLOCHA)
[http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]Тематики
EN
DE
FR
Англо-русский словарь нормативно-технической терминологии > pollution sink
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17 rate
3) частота4) расход5) норма || нормировать6) тариф || тарифицировать7) степень8) отношение; коэффициент10) оценка || оценивать11) определять; устанавливать; подсчитывать; рассчитывать (напр. мощность, несущую способность)•rates to consumers — тарифы на отпуск (напр. электроэнергии) потребителям-
absolute disintegrate rate
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absorbed dose rate
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acceptance rate
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accident rate
-
adiabatic lapse rate
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advance rate
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aging rate
-
allowable leak rate
-
angular rate
-
annual depletion rate
-
application rate
-
area rate
-
arrival rate
-
ascensional rate
-
assessed failure rate
-
attenuation rate
-
autoconvective lapse rate
-
base wage rate
-
baud rate
-
bearer rate
-
beating rate
-
bit rate
-
bit-error rate
-
bit-transfer rate
-
block meter rate
-
block-error rate
-
boiling rate
-
boil-up rate
-
bonus rate
-
break flow rate
-
breeding rate
-
burning rate
-
calling rate
-
capture rate
-
carbonization rate
-
cargo rate
-
carrier-ionization rate
-
casting rate
-
catalyst circulation rate
-
charging rate
-
chipping rate
-
chip rate
-
chopping rate
-
circulation rate
-
class rate
-
climb rate
-
clock rate
-
closed rate
-
closure rate
-
coke rate
-
cold storage rates
-
collision rate
-
combustion rate
-
completion rate
-
concentration rate
-
containment leak rate
-
continuous rate
-
controlled rate
-
convective expansion rate
-
conversion rate
-
conveyance rate
-
cooling rate
-
core heat generation rate
-
corrosion rate
-
counting rate
-
crack growth rate
-
creep rate
-
crosshead rate
-
cure rate
-
cutter wear rate
-
daily consumptive use rate
-
data-transfer rate
-
data rate
-
decay rate
-
decompression rate
-
deflection rate
-
deionization rate
-
delivery rate
-
demand cost rate
-
demand rate
-
deposition rate
-
descent rate
-
development rate
-
deviation rate
-
differential rate
-
differentiated electricity rates
-
diffusion rate
-
directional rate
-
discharge rate
-
disposal rate
-
distance rate
-
dither rate
-
dosage rate
-
downtime rate
-
drainage rate
-
drawing rate
-
drift rate
-
drilling rate
-
droop rate
-
dry adiabatic lapse rate
-
electricity rate
-
electric rate
-
energy fluence rate
-
energy release rate
-
entropy production rate
-
entropy rate
-
erasing rate
-
erosion rate
-
error rate
-
etching rate
-
etch rate
-
evacuation rate
-
evaporating rate
-
excitation rate
-
exposure rate
-
failure rate
-
failure-per-mile rate
-
false alarm rate
-
fatal accident frequency rate
-
fatality rate
-
fault rate
-
feed rate
-
field germination rate
-
field-repetition rate
-
fieldwide rate of recovery
-
film rate
-
filtering rate
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finishing rate
-
fire-propagation rate
-
firing rate
-
fission rate
-
flat rate
-
flexible rates
-
flicker rate
-
flooding rate
-
flotation rate
-
flour extraction rate
-
flow rate
-
flush production rate
-
flutter rate
-
forced outgage rate
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frame rate
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frame-repetition rate
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freezing rate
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freight rate
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freight-all-kinds rates
-
frequency-sweep rate
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frequency-tuning rate
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fuel rate
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functional throughput rate
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gas leak rate
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gathering rate
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generation rate
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grinding rate
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growth rate
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gyro drift rate
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half-clock rate
-
hardening rate
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heat absorption rate
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heat dissipation rate
-
heat generation rate
-
heat rate
-
heat-flow rate
-
heating rate
-
heat-transfer rate
-
hit rate
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image refresh rate
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impact wear rate
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in-commission rate
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infiltration rate
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information rate
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injection rate
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instantaneous failure rate
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intermittent rate
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ionization rate
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irrigation rate
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iso-wear rates
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job rates
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kerma rate
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keying rate
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lapse rate
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leakage rate
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linear wear rate
-
line-of-sight rate
-
line-repetition rate
-
liquid efflux rate
-
lubrication rate
-
maintenance rate
-
mass flow rate
-
mass wear rate
-
maximum efficiency rate
-
maximum permissible rate
-
maximum stepping rate
-
medium rate
-
melting rate
-
melt-off rate
-
metal-removal rate
-
modulation rate
-
moist-adiabatic lapse rate
-
NC programmed feed rate
-
negative flow rate
-
nucleation rate
-
Nyquist rate
-
obturation rate
-
off-peak power rate
-
operating rate
-
optimal feed rate
-
outgassing rate
-
output rate
-
overall drilling rate
-
oxidation rate
-
paging rate
-
peak power rate
-
penetration rate
-
percolation rate
-
phase generation rate
-
phase rate
-
picture-taking rate
-
pitch rate
-
plastic strain rate
-
positive flow rate
-
potential rate of evaporation
-
pouring rate
-
power rate
-
precipitation rate
-
predetermined rate
-
predicted failure rate
-
priming rate
-
printout rate
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print rate
-
production decline rate
-
production rate
-
projection rate
-
proper feed rate
-
protection rate
-
pull rate
-
pulldown rate
-
pulse-recurrence rate
-
pulse rate
-
radiation rate
-
radioactive decay rate
-
range rate
-
rapid air cut feed rate
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rapid return rate
-
rate of acceleration
-
rate of angular motion
-
rate of attack
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rate of blowing
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rate of braking
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rate of carbon drop
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rate of convergence
-
rate of crack propagation
-
rate of deformation
-
rate of dilution
-
rate of discharge
-
rate of dive
-
rate of energy input
-
rate of exchange
-
rate of exposure
-
rate of fall
-
rate of film movement
-
rate of gain
-
rate of hole deviation change
-
rate of lancing
-
rate of linkage
-
rate of loading
-
rate of opening
-
rate of plant depreciation
-
rate of pulse rise
-
rate of rainfall
-
rate of rise
-
rate of roll
-
rate of sedimentation
-
rate of shear
-
rate of slope
-
rate of stirring
-
rate of surface runoff
-
rate or carbon oxidation
-
reactivity insertion rate
-
reading rate
-
read rate
-
recovery rate
-
recycle rate
-
reflood rate
-
refresh rate
-
refrigeration rate
-
repetition rate
-
reset rate
-
residential rate
-
respiration rate
-
retail charter rate
-
retail rate
-
retention rate
-
rigidity rate
-
rolling rate
-
runout rate
-
sample rate
-
saturated-adiabatic lapse rate
-
saturation rate
-
scrap generation rate
-
scrap rate
-
secondary creep rate
-
sectorial rate
-
self-discharge rate
-
setting rate
-
settled production rate
-
settling rate
-
signaling rate
-
silicon pulling rate
-
slew rate
-
snowmelt inflow rate
-
solidification rate
-
sparking rate
-
specific commodity rate
-
specific heat flow rate
-
specific rate of flow
-
specific rate of sediment transport
-
specific wear rate
-
spreading rate of jet
-
spring rate
-
squeeze rate
-
standard rate
-
starting rate
-
steam rate
-
stepping rate
-
stock removal rate
-
strain rate
-
stress rate
-
sub-Nyquist rate
-
success rate
-
superadiabatic lapse rate
-
supply rate
-
survival rate
-
sweep rate
-
taking rate
-
tariff rate
-
temperature lapse rate
-
testing rate
-
thermal transfer rate
-
through rate
-
throughput rate
-
time rate of change
-
time rate
-
time-of-day electricity rate
-
time-of-day rate
-
tool-wear rate
-
total mass rate
-
tracking rate
-
traffic flow rate
-
transfer rate
-
transmission rate
-
transport rate
-
turn rate
-
turnover rate
-
twenty-five ampere rate
-
undetected error rate
-
uniform quench rate
-
unit rate
-
unloading rate
-
update rate
-
vaporizing rate
-
vitrification rate
-
voidage rate
-
voltage recovery rate
-
volume erosion rate
-
volume wear rate
-
volumetric flow rate
-
volumetric rate
-
vulcanization rate
-
water application rate
-
water consumption rate
-
water use rate
-
wear rate
-
weft insertion rate
-
weight rate
-
wheel removal rate
-
wholesale charter rate
-
wholesale rate
-
withdrawal rate
-
write writing rate
-
write rate
-
yawing rate
-
yaw rate
-
zero-crossing rate -
18 heat
1. тепло, теплота; нагрев; подогрев; накал2. плавка
* * *
||тепло, теплота; нагрев, подогрев || нагревать; топить
* * *
1) тепло; теплота•- gas specific heat
- hardening heat
- oil specific heat
- phase transition heat
- setting heat
- specific heat
- specific heat at constant pressure
- specific heat at constant strain
- specific heat at constant stress
- specific heat at constant volume* * *• 1) нагреваться; 2) нагревать• подогрев• теплота -
19 Bosch, Carl
SUBJECT AREA: Chemical technology[br]b. 27 August 1874 Cologne, Germanyd. 26 April 1940 Heidelberg, Germany[br]German industrial chemist who developed the industrial synthesis of ammonia.[br]Bosch spent a year as a metalworker before studying chemistry at Leipzig University, obtaining his doctorate in 1898. The following year, he entered Badische Soda-, Anilin Fabrik (BASF), the leading German manufacturer of dyestuflfs. Between 1902 and 1907 he spent much time investigating processes for nitrogen fixation. In 1908 Fritz Haber told BASF of his laboratory-scale synthesis of ammonia from its constituent elements, and in the following year Bosch was assigned to developing it to the industrial scale. Leading a large team of chemists and engineers, Bosch designed the massive pressure converter and other features of the process and was the first to use the water gas shift reaction to produce the large quantities of hydrogen that were required. By 1913 Bosch had completed the largest chemical engineering plant at BASF's works at Oppau, and soon it was producing 36,000 tons of ammonium sulphate a year. Bosch enlarged the Oppau plant and went on to construct a larger plant at Leuna.In 1914 Bosch was appointed a Director of BASF. At the end of the First World War he became Technical Adviser to the German delegation at the peace conference. During the 1920s BASF returned to its position of pre-eminence in high-pressure technology, thanks largely to Bosch's leadership. Although increasingly absorbed in administrative matters, Bosch was able to support the synthesis of methane and the hydrogenation of coal tar and lignite to make petrol. In 1925 BASF merged with other companies to form the giant IG Farbenindustrie AG, of which Bosch became Chairman of the Managing Board. His achievements received international recognition in 1931 when he was awarded, with F. Bergius, the Nobel Prize in Chemistry for high-pressure synthesis.[br]Bibliography1932, Über die Entwicklung der chemischen Hochdruckindustrie bei der Aufbau der neuen Ammoniakindustrie.Further ReadingK.Holdermann, 1953, Carl Bosch, Leben und Werk.See also biographical memoir in Chemische Berichte 190 (1957), pp. xix–xxxix.LRD -
20 Gossage, William
SUBJECT AREA: Chemical technology[br]b. 1799 Burgh-in-the-Marsh, Lincolnshire, Englandd. 9 April 1877 Bowdon, Cheshire, England[br]English industrial chemist, inventor of the absorption tower.[br]At the age of 12 he was working for his father, who was a chemist and druggist. When he was old enough, he started in the same trade on his own account at Leamington, but soon turned to the making of salt and alkali at a works in Stoke Prior, Worcestershire. In 1850 he moved to Widnes, Lancashire, and established a plant for the manufacture of alkali and soap. Gossage's soap became famous, and some 200,000 tons of it were sold during the period 1862 to 1887. Gossage made important improvements to the Leblanc process. Hitherto, the large quantities of hydrogen chloride discharged into the atmosphere had been a considerable nuisance and a cause of much litigation from aggrieved parties. Gossage introduced the absorption tower, in which the ascending hydrogen chloride was absorbed by a descending stream of water. An outcome of this improvement was the Alkali Act of 1863, which required manufacturers to absorb up to 95 per cent of the offending gas. Gossage later took out many other industrial chemical patents, and for a time he was engaged in copper smelting with works in both Widnes and Neath, South Wales.[br]Further ReadingJ.Fenwick Allen, 1907, Some Founders of the Chemical Industry, London. D.W.F.Hardie, 1950, A History of the Chemical Industry in Widnes, London.LRD
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