-
1 опыт горного производства
Mining: mining practiceУниверсальный русско-английский словарь > опыт горного производства
-
2 опыт разработки угольных месторождений
Mining: coal-mining practiceУниверсальный русско-английский словарь > опыт разработки угольных месторождений
-
3 практика горных разработок
Mining: mining practiceУниверсальный русско-английский словарь > практика горных разработок
-
4 технология добычи угля
Mining: coal-mining practiceУниверсальный русско-английский словарь > технология добычи угля
-
5 gruvdrift
mining operation, mining practice -
6 горное дело
-
7 горное производство
1) Mining: mining, mining practice2) Gold mining: mining recoveryУниверсальный русско-английский словарь > горное производство
-
8 родственный
•This group includes sugar, starches, and cellulose, along with many other related substances.
•Hydraulic jumps are akin to shock waves.
•This board is used in the building and allied (or related) industries.
•Papers on mining practice and kindred subjects...
•Gamma rays are electromagnetic radiation related to light rays and X-rays, but...
•There is an allied problem.
Русско-английский научно-технический словарь переводчика > родственный
-
9 практика рудничного подъёма
Mining: hoisting practiceУниверсальный русско-английский словарь > практика рудничного подъёма
-
10 техника цементационных работ
Mining: cementing practiceУниверсальный русско-английский словарь > техника цементационных работ
-
11 технология цементации
Mining: cementing practiceУниверсальный русско-английский словарь > технология цементации
-
12 цементация с помощью специального инжектора-контейнера
Универсальный русско-английский словарь > цементация с помощью специального инжектора-контейнера
-
13 способ
device, manner, mean, medium, method, mode, practice, process, system, technique, technology, theory, way* * *спо́соб м.1. fashion, manner, way2. ( технологический процесс) process, method, practiceспо́соб гидромеханиза́ции ( в строительстве плотин) — hydraulic fill methodграфи́ческий спо́соб (напр. решения или анализа) — graphical methodспо́соб до́ступа к да́нным ( не путать с ме́тодом до́ступа) вчт. — (data) access technique (not to confuse with access method)спо́соб защемле́ния стр. — form of constraintспо́соб испыта́ния — test(ing) techniqueспо́соб конфе́кции покры́шек, до́рновый — core-type building methodспо́соб конфе́кции покры́шек, полудо́рновый — shoulder-drum tyre building methodмо́крый спо́соб ( в производстве кирпича) — wet-mud processспо́соб очи́стки воды́, электромагни́тный — electromagnetic water treatmentспо́соб перево́да пигме́нтной ко́пии, мо́крый полигр. — wet layingспо́соб перево́да пигме́нтной ко́пии, сухо́й полигр. — dry layingпласти́ческий спо́соб ( в производстве кирпича) — soft-mud processспо́соб подстано́вки изм. — substitution methodполусухо́й спо́соб ( в производстве кирпича) — stiff-mud processспо́соб получе́ния желе́за, внедо́менный — nonblast-furnace (route of) iron-makingспо́соб получе́ния се́рной кислоты́, ба́шенный — tower sulphuric acid processспо́соб получе́ния се́рной кислоты́, ка́мерный — chamber sulphuric acid processспо́соб получе́ния се́рной кислоты́, конта́ктный — contact sulphuric acid processспо́соб получе́ния се́рной кислоты́, нитро́зный — nitrous sulphuric acid processспо́соб получе́ния со́ды, аммиа́чный — ammonium soda [Solvay] processспо́соб получе́ния ста́ли — steel-making process, steel-making technique, steel-making practiceспо́соб получе́ния ста́ли в электропеча́х — electric steel-makingспо́соб получе́ния ста́ли, кислоро́дно-конве́рторный — oxygen steel-makingспо́соб приготовле́ния те́ста, безопа́рный — straight dough methodспо́соб приготовле́ния те́ста, опа́рный — sponge dough methodспо́соб произво́дства — (production) process, technology, practiceспо́соб прока́тки, ба́лочный — beam (method of) rollingспо́соб прока́тки в закры́тых кали́брах — tongue-and-groove (rolling) methodспо́соб прока́тки в накло́нных кали́брах — diagonal (method of) rolling, angular (method of) rollingспо́соб прока́тки в прямы́х кали́брах — flat [slab-and-edging] (method of) rollingспо́соб прока́тки, паке́тный — pack rollingспо́соб прока́тки, плоскореброво́й — flat-and-edge [edging] (method of) rollingспо́соб прока́тки, руло́нный — coil rollingспо́соб прока́тки с изги́бом — butterfly (method of) rollingпротивото́чный спо́соб — counter-flow processспо́соб прохо́дки ствола́ — shaft sinking (method)спо́соб прохо́дки тунне́ля марчева́нами — poling-board method of tunnelingспо́соб прохо́дки тунне́ля, откры́тый — cut-and-cover method of tunnelingспо́соб прямо́го восстановле́ния ( железа из руды) — direct reduction processспо́соб разрабо́тки горн. — mining (method)спо́соб разрабо́тки, откры́тый — open-cut [open-cast] mining (method)спо́соб разрабо́тки, подзе́мный — underground mining (method)спо́соб регенера́ции рези́ны — rubber regeneration processспо́соб регенера́ции рези́ны, во́дно-нейтра́льный — water-cooking rubber regeneration processспо́соб регенера́ции рези́ны, щелочно́й — alkali rubber regeneration processспо́соб сва́рки — welding, process (см. тж. сварка)сокращё́нный спо́соб — short-cut methodспо́соб сухо́го прессова́ния ( в производстве кирпича) — dry-press processспо́соб шлифо́вки вреза́нием — plunge grinding -
14 Garforth, William Edward
SUBJECT AREA: Mining and extraction technology[br]b. 1845 Dukinfield, Cheshire, Englandd. 1 October 1921 Pontefract, Yorkshire, England[br]English colliery manager, pioneer in machine-holing and the safety of mines.[br]After Menzies conceived his idea of breaking off coal with machines in 1761, many inventors subsequently followed his proposals through into the practice of underground working. More than one century later, Garforth became one of the principal pioneers of machine-holing combined with the longwall method of working in order to reduce production costs and increase the yield of coal. Having been appointed agent to Pope \& Pearson's Collieries, West Yorkshire, in 1879, of which company he later became Managing Director and Chairman, he gathered a great deal of experience with different methods of cutting coal. The first disc machine was exhibited in London as early as 1851, and ten years later a pick machine was invented. In 1893 he introduced an improved type of deep undercutting machine, his "diamond" disc coal-cutter, driven by compressed air, which also became popular on the European continent.Besides the considerable economic advantages it created, the use of machinery for mining coal increased the safety of working in hard and thin seams. The improvement of safety in mining technology was always his primary concern, and as a result of his inventions and his many publications he became the leading figure in the British coal mining industry at the beginning of the twentieth century; safety lamps still carry his name. In 1885 he invented a firedamp detector, and following a severe explosion in 1886 he concentrated on coal-dust experiments. From the information he obtained of the effect of stone-dust on a coal-dust explosion he proposed the stone-dust remedy to prevent explosions of coal-dust. As a result of discussions which lasted for decades and after he had been entrusted with the job of conducting the British coal-dust experiments, in 1921 an Act made it compulsory in all mines which were not naturally wet throughout to treat all roads with incombustible dust so as to ensure that the dust always consisted of a mixture containing not more than 50 per cent combustible matter. In 1901 Garforth erected a surface gallery which represented the damaged roadways of a mine and could be filled with noxious fumes to test self-contained breathing apparata. This gallery formed the model from which all the rescue-stations existing nowadays have been developed.[br]Principal Honours and DistinctionsKnighted 1914. LLD Universities of Birmingham and Leeds 1912. President, Midland Institute 1892–4. President, The Institution of Mining Engineers 1911–14. President, Mining Association of Great Britain 1907–8. Chairman, Standing Committee on Mining, Advisory Council for Scientific and Industrial Research. Fellow of the Geological Society of London. North of England Institute of Mining and Mechanical Engineers Greenwell Silver Medal 1907. Royal Society of Arts Fothergill Gold Medal 1910. Medal of the Institution of Mining Engineers 1914.Bibliography1901–2, "The application of coal-cutting machines to deep mining", Transactions of the Federated Institute of Mining Engineers 23: 312–45.1905–6, "A new apparatus for rescue-work in mines", Transactions of the Institution of Mining Engineers 31:625–57.1902, "British Coal-dust Experiments". Paper communicated to the International Congress on Mining, Metallurgy, Applied Mechanics and Practical Geology, Dusseldorf.Further ReadingGarforth's name is frequently mentioned in connection with coal-holing, but his outstanding achievements in improving safety in mines are only described in W.D.Lloyd, 1921, "Memoir", Transactions of the Institution of Mining Engineers 62:203–5.WKBiographical history of technology > Garforth, William Edward
-
15 Lucas, Anthony Francis
SUBJECT AREA: Mining and extraction technology[br]b. 9 September 1855 Spalato, Dalmatia, Austria-Hungary (now Split, Croatia)d. 2 September 1921 Washington, DC, USA[br]Austrian (naturalized American) mining engineer who successfully applied rotary drilling to oil extraction.[br]A former Second Lieutenant of the Austrian navy (hence his later nickname "Captain") and graduate of the Polytechnic Institute of Graz, Lucas decided to stay in Michigan when he visited his relatives in 1879. He changed his original name, Lucie, into the form his uncle had adopted and became a naturalized American citizen at the age of 30. He worked in the lumber industry for some years and then became a consulting mechanical and mining engineer in Washington, DC. He began working for a salt-mining company in Louisiana in 1893 and became interested in the geology of the Mexican Gulf region, with a view to prospecting for petroleum. In the course of this work he came to the conclusion that the hills in this elevated area, being geological structures distinct from the surrounding deposits, were natural reservoirs of petroleum. To prove his unusual theory he subsequently chose Spindle Top, near Beaumont, Texas, where in 1899 he began to bore a first oil-well. A second drill-hole, started in October 1900, was put through clay and quicksand. After many difficulties, a layer of rock containing marine shells was reached. When the "gusher" came out on 10 January 1901, it not only opened up a new era in the oil and gas business, but it also led to the future exploration of the terrestrial crust.Lucas's boring was a breakthrough for the rotary drilling system, which was still in its early days although its principles had been established by the English engineer Robert Beart in his patent of 1884. It proved to have advantages over the pile-driving of pipes. A pipe with a simple cutter at the lower end was driven with a constantly revolving motion, grinding down on the bottom of the well, thus gouging and chipping its way downward. To deal with the quicksand he adopted the use of large and heavy casings successively telescoped one into the other. According to Fauvelle's method, water was forced through the pipe by means of a pump, so the well was kept full of circulating liquid during drilling, flushing up the mud. When the salt-rock was reached, a diamond drill was used to test the depth and the character of the deposit.When the well blew out and flowed freely he developed a preventer in order to save the oil and, even more importantly at the time, to shut the well and to control the oil flow. This assembly, patented in 1903, consisted of a combined system of pipes, valves and casings diverting the stream into a horizontal direction.Lucas's fame spread around the world, but as he had to relinquish the larger part of his interest to the oil company supporting the exploration, his financial reward was poor. One year after his success at Spindle Top he started oil exploration in Mexico, where he stayed until 1905, when he resumed his consulting practice in Washington, DC.[br]Bibliography1899, "Rock-salt in Louisiana", Transactions of the American Institution of Mining Engineers 29:462–74.1902, "The great oil-well near Beaumont, Texas", Transactions of the AmericanInstitution of Mining Engineers 31:362–74.Further ReadingR.S.McBeth, 1918, Pioneering the Gulf Coast, New York (a very detailed description of Lucas's important accomplishments in the development of the oil industry).R.T.Hill, 1903, "The Beaumont oil-field, with notes on other oil-fields of the Texas region", Transactions of the American Institution of Mining Engineers 33:363–405;Transactions of the American Institution of Mining Engineers 55:421–3 (contain shorter biographical notes).WK -
16 Agricola, Georgius (Georg Bauer)
SUBJECT AREA: Metallurgy[br]b. 24 March 1494 Glauchau, Saxonyd. 21 November 1555 Chemnitz, Germany[br]German metallurgist, who wrote the book De Re Metallica under the latinized version of his name.[br]Agricola was a physician, scientist and metallurgist of note and it was this which led to the publication of De Re Metallica. He studied at Leipzig University and between 1518 and 1522 he was a school teacher in Zwickau. Eventually he settled as a physician in Chemnitz. Later he continued his medical practice at Joachimstal in the Erzgebirge. This town was newly built to serve the mining community in what was at the time the most important ore-mining field in both Germany and Europe.As a physician in the sixteenth century he would naturally have been concerned with the development of medicines, which would have led him to research the medical properties of ores and base metals. He studied the mineralogy of his area, and the mines, and the miners who were working there. He wrote several books in Latin on geology and mineralogy. His important work during that period was a glossary of mineralogical and mining terms in both Latin and German. It is, however, De Re Metallica for which he is best known. This large volume contains twelve books which deal with mining and metallurgy, including an account of glassmaking. Whilst one can understand the text of this book very easily, the quality of the illustrative woodcuts should not be neglected. These illustrations detail the mines, furnaces, forges and the plant associated with them, unfortunately the name of the artist is unknown. The importance of the work lies in the fact that it is an assemblage of information on all the methods and practices current at that time. The book was clearly intended as a textbook of mining and mineralogy and as such it would have been brought to England by German engineers when they were employed by the Mines Royal in the Keswick area in the late sixteenth century. In addition to his studies in preparation for De Re Metallica, Agricola was an "adventurer" holding shares in the Gottesgab mine in the Erzegebirge.[br]Principal Honours and Distinctions Bibliography1556, De Re Metallica, Basel; 1912, trans. H. Hoover and L.H.Hoover, London.KMBiographical history of technology > Agricola, Georgius (Georg Bauer)
-
17 Koepe, Friedrich
SUBJECT AREA: Mining and extraction technology[br]b. 1 July 1835 Bergkamen, Westphalia, Germanyd. 12 September 1922 Bochum, Germany[br]German mining engineer, inventor of the friction winder for shaft hoisting.[br]After attending the School of Mines at Bochum, from 1862 he worked as an overseer in the coal-mining district of Ibbenbüren until he joined a mining company in the Ruhr area. There, as head of the machine shop, he was mainly concerned with sinking new shafts. In 1873 he became the Technical Director of the Hannover mine, near Bochum, which belonged to Krupp. When the shaft hoisting was to be extended to a lower level Koepe conceived the idea of applying a friction winder to the hoist instead of a drum, in order to save weight and costs. His method involved the use of an endless rope to which the cages were fixed without a safety catch. The rope passed over pulleys instead of coiling and uncoiling on a drum, and he consequently proposed to have the motor erected on top of the shaft rather than beside it, as had been the practice until then.Koepe's innovation turned out to be highly effective for hoisting heavy loads from deep shafts and was still popular in many countries in the 1990s, although the Krupp company did not accept it for a long time. He had severe personal problems with the company, and as Krupp refused to have his system patented he had to take it out in his own name in 1877. However, Krupp did not pay for the extension of the patent, nor did they pass the dossiers over to him, so the patent expired two years later. It was not until 1888 that a hoisting engine equipped with a friction winder was erected for the first time in a head gear, above the new Hannover II shaft. The following year Koepe left the Krupp company and settled as a freelance consulting engineer in Bochum; he was successful in having his system introduced by other mining companies. Ironi-cally, in 1948 the world's first four-rope winding, based on his system, was installed at the Hannover mine.[br]Further ReadingFor detailed biographical information and an assessment of his technological achievements see: H.Arnold and W.Kroker, 1977, "100 Jahre Schachtförderung nach dem System Koepe", Der Anschnitt 29:235–42.F.Lange, 1952, Die Vierseilförderung, Essen.WK -
18 на практике
1) General subject: as a matter of actual practice, in a real sense, in practice, in the real world, practically, in training, in the wild, as a matter of practice, when applied2) Mathematics: in action, used in the industry3) Law: as a practical matter4) Mining: in the field5) Automation: in actual practice6) Makarov: in practical work -
19 участок
1) General subject: allottee, block, branch, circuit, clot (породы), constabulary, district, district (горных работ, тж. mining district), extent, field, locality, location, lot (земли), nick, parcel (земли), piece (земли), plat, plot (земли), polling-center, practice (здравоохранение), precinct, region, section, sector, site (для строительства), station, strand (транспортера), tract, burial space (место захоронения, место на кладбище.), burial plot (место захоронения, место на кладбище), (в дополнение к дому) acreage2) Computers: bucket6) Medicine: division, locus (болезни или поражения), portion7) American: homestead (поселенца)8) Military: corner, front, ground (местности), phase, site, sub-district, subdistrict (района), window9) Engineering: arm (цепи), department, flight, floor, ground, island, land, part, place, project land, reach (реки или канала с однородными гидрологическими характеристиками), segment, spacing, span, spot, zone10) Agriculture: close (земли, преим. огороженный), (опытный) plot11) Construction: pipe run (трубопровода), pipe section (трубопровода), reach (реки, канала), run (трубопровода), section (трубопровода, дороги, канала и т. п.), stretch12) Mathematics: cell, site territory13) Railway term: canton, district (железной дороги), territory14) Law: polling station, precinct station15) Commerce: area salesman17) Accounting: segment (направление деятельности или зона ответственности внутри предприятия), site (для застройки)19) Mining: division (шахты), lease (на нефтяном промысле), panel, plot (под разработку или разведку), probable oil land, tract (месторождения нефти или газа)21) Metallurgy: dock22) Oil: division (напр. трубопровода), lease, pool, prospective oil land24) Astronautics: leg (траектории)25) Cartography: block (напр, леса, заповедника, угодий)26) Mechanics: bay27) Coolers: length28) Business: area30) Oil&Gas technology acreage31) Network technologies: slot32) Polymers: fragment33) Automation: bay (цеха), division (цеха), leg (цепи), line, (производственный) pod (напр. ГПС), (производственный) workshop, workshop section (цеха)36) Chemical weapons: bay (цеха, производства)37) Makarov: compartment (леса), cut, division (напр., трубопровода), estate, field (для какой-л. цели), field (кирпичной стены между проёмами или углами здания), interval, leg (маршрута полёта), length (напр., провода), limits, line (производственный), pad, path, reach (канала, реки), spacing (линии связи), span (линии связи), strand (транспортёра), stretch (водотока), subdivision, track (лесной)38) Taboo: beat39) Road traffic: (шоссе, дороги) portion (A portion of the Barnet Highway was closed for several hours Sunday evening due to a gas leak.)40) Gold mining: area (напр. areas referred to in this report; areas selected for future work), partially explored area41) Electrochemistry: speck42) Logistics: subarea43) Cement: property44) Coal: tenement (участок угольного месторождения, подлежащего разработке. Спец. в Австралии все подобные участки снимаются в аренду от государства.) -
20 Beaumont, Huntingdon
SUBJECT AREA: Mining and extraction technology[br]b. c.1560 Coleorton (?), Leicestershire, Englandd. 1624 Nottingham, England[br]English speculator in coal-mining, constructor of the first surface railway in Britain.[br]Huntingdon Beaumont was a younger son of a landed family whose estates included coal-mines at Coleorton and Bedworth. From these, no doubt, originated his great expertise in coal-mining and mine management. His subsequent story is a complex one of speculation in coal mines: agreements, partnerships, and debts, and, in trying to extricate himself from the last, attempts to improve profitability, and ever-greater enterprises. He leased mines in 1601 at Wollaton, near Nottingham, and in 1603 at Strelley, which adjoins Wollaton but is further from Nottingham, where lay the market for coal. To reduce the transport cost of Strelley coal, Beaumont laid a wooden wagonway for two miles or so to Wollaton Lane End, the point at which the coal was customarily sold. In earlier times wooden railways had probably been used in mines, following practice on the European continent, but Beaumont's was the first on the surface in Britain. The market for coal in Nottingham being limited, Beaumont, with partners, attempted to send coal to London by water, but the difficult navigation of the Trent at this period made the venture uneconomic. With a view still to supplying London, c.1605 they took leases of mines near Blyth, north of Newcastle upon Tyne. Here too Beaumont built wagonways, to convey coal to the coast, but despite considerable expenditure the mines could not be made economic and Beaumont returned to Strelley. Although he worked the mine night and day, he was unable to meet the demands of his creditors, who eventually had him imprisoned for debt. He died in gaol.[br]Further ReadingR.S.Smith, 1957, "Huntingdon Beaumont. Adventurer in coal mines", Renaissance \& Modern Studies 1; Smith, 1960, "England's first rails: a reconsideration", Renaissance\& Modern Studies 4, University of Nottingham (both are well-researched papers discussing Beaumont and his wagonways).PJGR
См. также в других словарях:
Mining in South Africa — has been the main driving force behind the history and development of Africa s most advanced and richest economy. Large scale and profitable mining started with the discovery of a diamond on the banks of the Orange River in 1867 by Erasmus Jacobs … Wikipedia
mining — /muy ning/, n. 1. the act, process, or industry of extracting ores, coal, etc., from mines. 2. the laying of explosive mines. [1250 1300; ME: undermining (walls in an attack); see MINE2, ING1] * * * I Excavation of materials from the Earth s… … Universalium
Mining — This article is about the extraction of geological materials from the Earth. For the municipality in Austria, see Mining, Austria. For the siege tactic, see Mining (military). For name of the Chinese emperor, see Daoguang Emperor. Simplified… … Wikipedia
Mining engineering — Surface coal mine with haul truck in foreground Mining engineering is an engineering discipline that involves the practice, the theory, the science, the technology, and application of extracting and processing minerals from a naturally occurring… … Wikipedia
Mining industry of the Democratic Republic of the Congo — The Democratic Republic of the Congo (abbreviated DR Congo or DRC), previously known as Zaire, is immensely rich in natural resources. However, mining activities have been closely linked to serious problems in the DRC. In September 2010, the… … Wikipedia
Mining in the Upper Harz — The headframe of the Emperor William Shaft in Clausthal is one of the oldest surviving winding towers in Germany … Wikipedia
Mining industry of South Africa — Premier Diamond Mine, Cullinan, Gauteng, South Africa Mining in South Africa has been the main driving force behind the history and development of Africa s most advanced and richest economy. Large scale and profitable mining started with the… … Wikipedia
Coal mining — Men leaving a UK colliery at the close of a shift Surface coal mining in Wyo … Wikipedia
Mountaintop removal mining — Mountaintop removal site Mountaintop removal in Martin County, Kentucky M … Wikipedia
Coal mining in Kentucky — Coal was discovered in Kentucky in 1750. Since the first commercial coal mine opened in 1820 coal has gained both economic importance and controversy regarding its environmental consequences. As of 2010 there are 442 operating coal mines in the… … Wikipedia
coal mining — Coal was very important in the economic development of Britain. It was used as fuel in the factories built during the Industrial Revolution and continued to be important until the 1980s. The main coalfields are in north east England, the north… … Universalium