-
1 increase
1. ['ɪnkriːs] сущ.1) возрастание, рост; прибавление, прирост, размножение, разрастание, расширение, увеличениеconsiderable / large / sharp / sizable / substantial increase — значительный рост
to be on the increase — расти, увеличиваться
Syn:2) увеличенное количество, прирост, надбавкаSyn:2. [ɪn'kriːs] гл.1) возрастать, увеличиваться; расти; усиливатьсяto increase by 10% — увеличиться на 10%
to increase in number / size / volume — увеличиваться в числе, размере, объёме
Syn:2) увеличивать; усиливатьThe physician increased the dosage from one to four pills. — Врач увеличил дозу с одной таблетки до четырёх.
Syn: -
2 Kohlenabbau
Kohlenabbau
coal mining;
• Kohlenabbaugerechtigkeit royalty;
• Kohlenabgabe coal levy;
• nicht mit größeren Kohlenanforderungen von den Versorgungsbetrieben rechnen not to expect coal demand from the utilities;
• Kohlenausfuhr coal export;
• Kohlenbergarbeiterstreik coal strike;
• Kohlenbergbau coal[-mining] industry;
• Kohlenbergwerk coal mine, pit, colliery;
• Kohlenbewirtschaftung coal control;
• Kohlenbunker coal bunker;
• Kohlendeputat allowance of free coal;
• Kohlendioxid auf dem Stand von 2002 halten to freeze emissions of carbon dioxide at 2002 level;
• Kohlendistrikt coal field;
• Kohlenfeld ausbeuten to work a coal field;
• Kohlenförderung coal output;
• tägliche Kohlenförderung pro Kopf coal output per man per day;
• Kohlenförderung steigern to increase the output of coal;
• Kohlengebiet coal-mining district, coal area;
• Kohlengrube coalpit;
• Kohlengrube ausbeuten to mine coal;
• Kohlenhafen coaling port (station);
• Kohlenhalde coal bank (stockpile), pithead stocks;
• Kohlenhändler dealer in coal, coal merchant (factor, Br.);
• Kohlenindustrie coal industry;
• Kohlenknappheit coal shortage;
• Kohlenladung load of coal;
• Kohlenlager coal field (depot, yard, bank, US);
• Kohlenlieferant coal contractor (supplier);
• Kohlenlieferungen coal supply;
• Kohlenlieferungsvertrag abschließen to make a contract for supply of coal;
• Kohlenmangel coal famine;
• Kohlennebenprodukte gewinnen to recover byproducts from coal;
• abbauwürdige Kohlenreserven workable reserves of coal;
• Kohlenrevier coal area (field), coal-mining district;
• Kohlenschätze eines Gebiets erschließen to develop a coal area;
• Kohlenschiff coal ship, collier;
• Kohlensorte grade of coal;
• Kohlenstofffaser carbon fibre (Br.) (fiber, US);
• Kohlentransport coal transport;
• Kohlenüberhang coal glut;
• Kohlenübernahme coaling;
• Kohlenverbrauch coal consumption;
• Kohlenverkaufsbüro coal sales office;
• Kohlenversorgung coal supplies;
• Kohlenvorkommen coal deposit[s];
• Kohlenvorrat ergänzen to recoal;
• Kohlenwaggon coal wag(g)on (truck, car, US);
• Kohlenwirtschaftsjahr coal production year;
• Kohlenzeche coal mine, colliery;
• Kohlenzug coal train, coaler, black snake (sl.). -
3 Chapelon, André
[br]b. 26 October 1892 Saint-Paul-en-Cornillon, Loire, Franced. 29 June 1978 Paris, France[br]French locomotive engineer who developed high-performance steam locomotives.[br]Chapelon's technical education at the Ecole Centrale des Arts et Manufactures, Paris, was interrupted by extended military service during the First World War. From experience of observing artillery from the basket of a captive balloon, he developed a method of artillery fire control which was more accurate than that in use and which was adopted by the French army.In 1925 he joined the motive-power and rolling-stock department of the Paris-Orléans Railway under Chief Mechanical Engineer Maurice Lacoin and was given the task of improving the performance of its main-line 4–6–2 locomotives, most of them compounds. He had already made an intensive study of steam locomotive design and in 1926 introduced his Kylchap exhaust system, based in part on the earlier work of the Finnish engineer Kyläla. Chapelon improved the entrainment of the hot gases in the smokebox by the exhaust steam and so minimized back pressure in the cylinders, increasing the power of a locomotive substantially. He also greatly increased the cross-sectional area of steam passages, used poppet valves instead of piston valves and increased superheating of steam. PO (Paris-Orléans) 4–6–2s rebuilt on these principles from 1929 onwards proved able to haul 800-ton trains, in place of the previous 500-ton trains, and to do so to accelerated schedules with reduced coal consumption. Commencing in 1932, some were converted, at the time of rebuilding, into 4–8–0s to increase adhesive weight for hauling heavy trains over the steeply graded Paris-Toulouse line.Chapelon's principles were quickly adopted on other French railways and elsewhere.H.N. Gresley was particularly influenced by them. After formation of the French National Railways (SNCF) in 1938, Chapelon produced in 1941 a prototype rebuilt PO 2–10–0 freight locomotive as a six-cylinder compound, with four low-pressure cylinders to maximize expansive use of steam and with all cylinders steam-jacketed to minimize heat loss by condensation and radiation. War conditions delayed extended testing until 1948–52. Meanwhile Chapelon had, by rebuilding, produced in 1946 a high-powered, three-cylinder, compound 4–8–4 intended as a stage in development of a proposed range of powerful and thermally efficient steam locomotives for the postwar SNCF: a high-speed 4–6–4 in this range was to run at sustained speeds of 125 mph (200 km/h). However, plans for improved steam locomotives were then overtaken in France by electriflcation and dieselization, though the performance of the 4–8–4, which produced 4,000 hp (3,000 kW) at the drawbar for the first time in Europe, prompted modification of electric locomotives, already on order, to increase their power.Chapelon retired from the SNCF in 1953, but continued to act as a consultant. His principles were incorporated into steam locomotives built in France for export to South America, and even after the energy crisis of 1973 he was consulted on projects to build improved, high-powered steam locomotives for countries with reserves of cheap coal. The eventual fall in oil prices brought these to an end.[br]Bibliography1938, La Locomotive à vapeur, Paris: J.B.Bailière (a comprehensive summary of contemporary knowledge of every function of the locomotive).Further ReadingH.C.B.Rogers, 1972, Chapelon, Genius of French Steam, Shepperton: Ian Allan.1986, "André Chapelon, locomotive engineer: a survey of his work", Transactions of the Newcomen Society 58 (a symposium on Chapelon's work).Obituary, 1978, Railway Engineer (September/October) (makes reference to the technical significance of Chapelon's work).PJGR -
4 воздействие производства энергии на окружающую среду
воздействие производства энергии на окружающую среду
—
[ http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]EN
environmental impact of energy
Energy and environmental problems are closely related, since it is nearly impossible to produce, transport, or consume energy without significant environmental impact. The environmental problems directly related to energy production and consumption include air pollution, water pollution, thermal pollution, and solid waste disposal. The emission of air pollutants from fossil fuel combustion is the major cause of urban air pollution. Diverse water pollution problems are associated with energy usage. One major problem is oil spills. In all petroleum-handling operations, there is a finite probability of spilling oil either on the earth or in a body of water. Coal mining can also pollute water. Changes in groundwater flow produced by mining operations often bring otherwise unpolluted waters into contact with certain mineral materials which are leached from the soil and produce an acid mine drainage. Solid waste is also a by-product of some forms of energy usage. Coal mining requires the removal of large quantities of earth as well as coal. In general, environmental problems increase with energy use and this combined with the limited energy resource base is the crux of the energy crisis. An energy impact assessment should compare these costs with the benefits to be derived from energy use. (Source: RAU)
[http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]Тематики
EN
DE
FR
Русско-немецкий словарь нормативно-технической терминологии > воздействие производства энергии на окружающую среду
-
5 impact de l'énergie sur l'environnement
воздействие производства энергии на окружающую среду
—
[ http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]EN
environmental impact of energy
Energy and environmental problems are closely related, since it is nearly impossible to produce, transport, or consume energy without significant environmental impact. The environmental problems directly related to energy production and consumption include air pollution, water pollution, thermal pollution, and solid waste disposal. The emission of air pollutants from fossil fuel combustion is the major cause of urban air pollution. Diverse water pollution problems are associated with energy usage. One major problem is oil spills. In all petroleum-handling operations, there is a finite probability of spilling oil either on the earth or in a body of water. Coal mining can also pollute water. Changes in groundwater flow produced by mining operations often bring otherwise unpolluted waters into contact with certain mineral materials which are leached from the soil and produce an acid mine drainage. Solid waste is also a by-product of some forms of energy usage. Coal mining requires the removal of large quantities of earth as well as coal. In general, environmental problems increase with energy use and this combined with the limited energy resource base is the crux of the energy crisis. An energy impact assessment should compare these costs with the benefits to be derived from energy use. (Source: RAU)
[http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]Тематики
EN
DE
FR
Франко-русский словарь нормативно-технической терминологии > impact de l'énergie sur l'environnement
-
6 energiebedingte Umweltbelastung
воздействие производства энергии на окружающую среду
—
[ http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]EN
environmental impact of energy
Energy and environmental problems are closely related, since it is nearly impossible to produce, transport, or consume energy without significant environmental impact. The environmental problems directly related to energy production and consumption include air pollution, water pollution, thermal pollution, and solid waste disposal. The emission of air pollutants from fossil fuel combustion is the major cause of urban air pollution. Diverse water pollution problems are associated with energy usage. One major problem is oil spills. In all petroleum-handling operations, there is a finite probability of spilling oil either on the earth or in a body of water. Coal mining can also pollute water. Changes in groundwater flow produced by mining operations often bring otherwise unpolluted waters into contact with certain mineral materials which are leached from the soil and produce an acid mine drainage. Solid waste is also a by-product of some forms of energy usage. Coal mining requires the removal of large quantities of earth as well as coal. In general, environmental problems increase with energy use and this combined with the limited energy resource base is the crux of the energy crisis. An energy impact assessment should compare these costs with the benefits to be derived from energy use. (Source: RAU)
[http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]Тематики
EN
DE
FR
Немецко-русский словарь нормативно-технической терминологии > energiebedingte Umweltbelastung
-
7 воздействие производства энергии на окружающую среду
воздействие производства энергии на окружающую среду
—
[ http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]EN
environmental impact of energy
Energy and environmental problems are closely related, since it is nearly impossible to produce, transport, or consume energy without significant environmental impact. The environmental problems directly related to energy production and consumption include air pollution, water pollution, thermal pollution, and solid waste disposal. The emission of air pollutants from fossil fuel combustion is the major cause of urban air pollution. Diverse water pollution problems are associated with energy usage. One major problem is oil spills. In all petroleum-handling operations, there is a finite probability of spilling oil either on the earth or in a body of water. Coal mining can also pollute water. Changes in groundwater flow produced by mining operations often bring otherwise unpolluted waters into contact with certain mineral materials which are leached from the soil and produce an acid mine drainage. Solid waste is also a by-product of some forms of energy usage. Coal mining requires the removal of large quantities of earth as well as coal. In general, environmental problems increase with energy use and this combined with the limited energy resource base is the crux of the energy crisis. An energy impact assessment should compare these costs with the benefits to be derived from energy use. (Source: RAU)
[http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]Тематики
EN
DE
FR
Русско-английский словарь нормативно-технической терминологии > воздействие производства энергии на окружающую среду
-
8 воздействие производства энергии на окружающую среду
воздействие производства энергии на окружающую среду
—
[ http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]EN
environmental impact of energy
Energy and environmental problems are closely related, since it is nearly impossible to produce, transport, or consume energy without significant environmental impact. The environmental problems directly related to energy production and consumption include air pollution, water pollution, thermal pollution, and solid waste disposal. The emission of air pollutants from fossil fuel combustion is the major cause of urban air pollution. Diverse water pollution problems are associated with energy usage. One major problem is oil spills. In all petroleum-handling operations, there is a finite probability of spilling oil either on the earth or in a body of water. Coal mining can also pollute water. Changes in groundwater flow produced by mining operations often bring otherwise unpolluted waters into contact with certain mineral materials which are leached from the soil and produce an acid mine drainage. Solid waste is also a by-product of some forms of energy usage. Coal mining requires the removal of large quantities of earth as well as coal. In general, environmental problems increase with energy use and this combined with the limited energy resource base is the crux of the energy crisis. An energy impact assessment should compare these costs with the benefits to be derived from energy use. (Source: RAU)
[http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]Тематики
EN
DE
FR
Русско-французский словарь нормативно-технической терминологии > воздействие производства энергии на окружающую среду
-
9 environmental impact of energy
воздействие производства энергии на окружающую среду
—
[ http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]EN
environmental impact of energy
Energy and environmental problems are closely related, since it is nearly impossible to produce, transport, or consume energy without significant environmental impact. The environmental problems directly related to energy production and consumption include air pollution, water pollution, thermal pollution, and solid waste disposal. The emission of air pollutants from fossil fuel combustion is the major cause of urban air pollution. Diverse water pollution problems are associated with energy usage. One major problem is oil spills. In all petroleum-handling operations, there is a finite probability of spilling oil either on the earth or in a body of water. Coal mining can also pollute water. Changes in groundwater flow produced by mining operations often bring otherwise unpolluted waters into contact with certain mineral materials which are leached from the soil and produce an acid mine drainage. Solid waste is also a by-product of some forms of energy usage. Coal mining requires the removal of large quantities of earth as well as coal. In general, environmental problems increase with energy use and this combined with the limited energy resource base is the crux of the energy crisis. An energy impact assessment should compare these costs with the benefits to be derived from energy use. (Source: RAU)
[http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]Тематики
EN
DE
FR
Англо-русский словарь нормативно-технической терминологии > environmental impact of energy
-
10 увеличиваться
•The particles must cover greater distances, which means that the period of revolution mounts.
•The supply of water has been augmented in many parts of...
•Resolution is maximized (антон. minimized) by applying...
•The proportion of volatiles undergoes (or shows) a rise from lignite to bituminous coal.
•This pressure can build up (or grow, or rise, or increase) to high values. Acceleration is expected to climb to four or more times the present 50 . Cleaners used in metal finishing are growing in complexity and number.
•The vapour increases in transparency.
•Domestic oil consumption will soar (or rise) to...
•The reaction increases (or shows an increase) in velocity.
Русско-английский научно-технический словарь переводчика > увеличиваться
-
11 fuel
1. noun2. transitive verb,add fuel to the flames or fire — (fig.) Öl ins Feuer gießen
(Brit.) - ll- auftanken [Schiff, Flugzeug]; (fig.): (stimulate) Nahrung geben (+ Dat.) [Verdacht, Spekulationen]; anheizen [Inflation]* * *['fjuəl] 1. noun(any substance by which a fire, engine etc is made to work (eg coal, oil, petrol): The machine ran out of fuel.) der Brennstoff2. verb(to give or take fuel: The tanker will leave when it has finished fuelling / being fuelled.) auftanken,bunkern* * *I. nnuclear \fuel reprocessing plant atomare Wiederaufbereitungsanlageleaded/unleaded \fuel verbleites/bleifreies BenzinII. vtto \fuel sb's hatred/resentment jds Hass/Unmut schüren gehto \fuel speculation Spekulationen anheizen* * *[fjʊəl]1. nBrennstoff m, Brennmaterial nt; (for vehicle) Kraftstoff m; (= petrol) Benzin nt; (AVIAT, SPACE) Treibstoff m; (fig) Nahrung fto add fuel to the flames or fire (fig) — Öl in die Flammen or ins Feuer gießen
See:→ solid fuel2. vt(= fill) stove, furnace etc mit Brennstoff versorgen; ships etc auftanken, betanken; (= use for fuel) betreiben; (= drive, propel) antreiben; (fig) conflict schüren; debate anfachen; inflation anheizen; speculation Nahrung geben (+dat)by oil —
3. vi(ship, engine, aircraft) auftanken, Brennstoff/Treibstoff etc aufnehmenfuelling stop — Landung f zum Auftanken
* * *fuel [ˈfjʊəl]A v/t prät und pperf -eled, besonders Br -elled2. die Inflation etc anheizen, Gerüchte etc schürenB v/i1. Brennstoff nehmenC s1. Brennstoff m:a) Heiz-, Brennmaterial n, Feuerung(smaterial) f(n)b) AUTO etc Betriebs-, Treib-, Kraftstoff m:fuel-air mixture Kraftstoff-Luft-Gemisch n;fuel consumption Kraftstoff-, Benzinverbrauch m;fuel-efficient Benzin sparend (Motor etc);fuel feed Brennstoffzuleitung f;fuel filter Kraftstoff-, Benzinfilter n/m;fuel injection Kraftstoffeinspritzung f;fuel-injection engine Einspritzmotor m;fuel jet, fuel nozzle Kraftstoffdüse f;fuel oil Heizöl n;fuel pipe Benzinleitung f;fuel pump Kraftstoff-, Benzinpumpe f;fuel-thrifty Benzin sparend (Motor etc)2. fig Nahrung f:add fuel to → A 2;add fuel to the flames Öl ins Feuer gießen* * *1. nounBrennstoff, der; (for vehicle) Kraftstoff, der; (for ship, aircraft, spacecraft) Treibstoff, der2. transitive verb,add fuel to the flames or fire — (fig.) Öl ins Feuer gießen
(Brit.) - ll- auftanken [Schiff, Flugzeug]; (fig.): (stimulate) Nahrung geben (+ Dat.) [Verdacht, Spekulationen]; anheizen [Inflation]* * *n.Brennmaterial n.Brennstoff m.Kraftstoff m.Treibgas -e n.Treibstoff m. v.tanken v.
См. также в других словарях:
increase — I n. 1) a considerable, large, sharp, sizable, substantial; moderate; slight; steady increase 2) a rate increase 3) an increase in (an increase in coal consumption) 4) on the increase II v. 1) (D; intr., tr.) to increase by (production increased… … Combinatory dictionary
Coal — Sedimentary Rock Anthracite coal Composition Primary carbon Secondary hydrogen, sulfur … Wikipedia
Coal power in the People's Republic of China — Entrance to a small coal mine in China. A coal shipme … Wikipedia
Coal mining — Men leaving a UK colliery at the close of a shift Surface coal mining in Wyo … Wikipedia
Coal in South Africa — South Africa produces in excess of 260 million tonnes of coal (2003 estimate) and consumes almost three quarters of that domestically.[1] Around 77% of South Africa s energy needs are directly derived from coal[2] and 92% of coal consumed on the… … Wikipedia
Coal in the United States — Utilities buy more than 90 percent of the coal mined in the United States [http://www.pittsburghlive.com/x/pittsburghtrib/news/cityregion/s 586978.html] .Since the presidency of George W. Bush began in January 2001, coal fired power generation… … Wikipedia
Consumption of fixed capital — (CFC) is a term used in business accounts, tax assessments and national accounts for depreciation of fixed assets. CFC is used in preference to depreciation to emphasize that fixed capital is used up in the process of generating new output, and… … Wikipedia
coal — coalless, adj. /kohl/, n. 1. a black or dark brown combustible mineral substance consisting of carbonized vegetable matter, used as a fuel. Cf. anthracite, bituminous coal, lignite. 2. a piece of glowing, charred, or burned wood or other… … Universalium
coal utilization — Introduction combustion of coal or its conversion into useful solid, gaseous, and liquid products. By far the most important use of coal is in combustion, mainly to provide heat to the boilers of electric power plants. Metallurgical coke… … Universalium
Coal gas — Towngas redirects here. For the company in Hong Kong trading as Towngas , see The Hong Kong and China Gas Company Limited. See also: Coal gasification and Coal seam gas Coal gas (also town gas and illumination gas) is a flammable gaseous… … Wikipedia
World energy resources and consumption — In order to directly compare world energy resources and consumption of energy, this article uses SI units and prefixes and measures energy rate (or power) in watts (W) and amounts of energy in joules (J). One watt is one joule per second. In 2005 … Wikipedia