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121 Curr, John
[br]b. 1756 Kyo, near Lanchester, or in Greenside, near Ryton-on-Tyne, Durham, Englandd. 27 January 1823 Sheffield, England[br]English coal-mine manager and engineer, inventor of flanged, cast-iron plate rails.[br]The son of a "coal viewer", Curr was brought up in the West Durham colliery district. In 1777 he went to the Duke of Norfolk's collieries at Sheffield, where in 1880 he was appointed Superintendent. There coal was conveyed underground in baskets on sledges: Curr replaced the wicker sledges with wheeled corves, i.e. small four-wheeled wooden wagons, running on "rail-roads" with cast-iron rails and hauled from the coal-face to the shaft bottom by horses. The rails employed hitherto had usually consisted of plates of iron, the flange being on the wheels of the wagon. Curr's new design involved flanges on the rails which guided the vehicles, the wheels of which were unflanged and could run on any hard surface. He appears to have left no precise record of the date that he did this, and surviving records have been interpreted as implying various dates between 1776 and 1787. In 1787 John Buddle paid tribute to the efficiency of the rails of Curr's type, which were first used for surface transport by Joseph Butler in 1788 at his iron furnace at Wingerworth near Chesterfield: their use was then promoted widely by Benjamin Outram, and they were adopted in many other English mines. They proved serviceable until the advent of locomotives demanded different rails.In 1788 Curr also developed a system for drawing a full corve up a mine shaft while lowering an empty one, with guides to separate them. At the surface the corves were automatically emptied by tipplers. Four years later he was awarded a patent for using double ropes for lifting heavier loads. As the weight of the rope itself became a considerable problem with the increasing depth of the shafts, Curr invented the flat hemp rope, patented in 1798, which consisted of several small round ropes stitched together and lapped upon itself in winding. It acted as a counterbalance and led to a reduction in the time and cost of hoisting: at the beginning of a run the loaded rope began to coil upon a small diameter, gradually increasing, while the unloaded rope began to coil off a large diameter, gradually decreasing.Curr's book The Coal Viewer (1797) is the earliest-known engineering work on railway track and it also contains the most elaborate description of a Newcomen pumping engine, at the highest state of its development. He became an acknowledged expert on construction of Newcomen-type atmospheric engines, and in 1792 he established a foundry to make parts for railways and engines.Because of the poor financial results of the Duke of Norfolk's collieries at the end of the century, Curr was dismissed in 1801 despite numerous inventions and improvements which he had introduced. After his dismissal, six more of his patents were concerned with rope-making: the one he gained in 1813 referred to the application of flat ropes to horse-gins and perpendicular drum-shafts of steam engines. Curr also introduced the use of inclined planes, where a descending train of full corves pulled up an empty one, and he was one of the pioneers employing fixed steam engines for hauling. He may have resided in France for some time before his death.[br]Bibliography1788. British patent no. 1,660 (guides in mine shafts).1789. An Account of tin Improved Method of Drawing Coals and Extracting Ores, etc., from Mines, Newcastle upon Tyne.1797. The Coal Viewer and Engine Builder's Practical Companion; reprinted with five plates and an introduction by Charles E.Lee, 1970, London: Frank Cass, and New York: Augustus M.Kelley.1798. British patent no. 2,270 (flat hemp ropes).Further ReadingF.Bland, 1930–1, "John Curr, originator of iron tram roads", Transactions of the Newcomen Society 11:121–30.R.A.Mott, 1969, Tramroads of the eighteenth century and their originator: John Curr', Transactions of the Newcomen Society 42:1–23 (includes corrections to Fred Bland's earlier paper).Charles E.Lee, 1970, introduction to John Curr, The Coal Viewer and Engine Builder's Practical Companion, London: Frank Cass, pp. 1–4; orig. pub. 1797, Sheffield (contains the most comprehensive biographical information).R.Galloway, 1898, Annals of Coalmining, Vol. I, London; reprinted 1971, London (provides a detailed account of Curr's technological alterations).WK / PJGR -
122 Nobel, Immanuel
[br]b. 1801 Gävle, Swedend. 3 September 1872 Stockholm, Sweden[br]Swedish inventor and industrialist, particularly noted for his work on mines and explosives.[br]The son of a barber-surgeon who deserted his family to serve in the Swedish army, Nobel showed little interest in academic pursuits as a child and was sent to sea at the age of 16, but jumped ship in Egypt and was eventually employed as an architect by the pasha. Returning to Sweden, he won a scholarship to the Stockholm School of Architecture, where he studied from 1821 to 1825 and was awarded a number of prizes. His interest then leaned towards mechanical matters and he transferred to the Stockholm School of Engineering. Designs for linen-finishing machines won him a prize there, and he also patented a means of transforming rotary into reciprocating movement. He then entered the real-estate business and was successful until a fire in 1833 destroyed his house and everything he owned. By this time he had married and had two sons, with a third, Alfred (of Nobel Prize fame; see Alfred Nobel), on the way. Moving to more modest quarters on the outskirts of Stockholm, Immanuel resumed his inventions, concentrating largely on India rubber, which he applied to surgical instruments and military equipment, including a rubber knapsack.It was talk of plans to construct a canal at Suez that first excited his interest in explosives. He saw them as a means of making mining more efficient and began to experiment in his backyard. However, this made him unpopular with his neighbours, and the city authorities ordered him to cease his investigations. By this time he was deeply in debt and in 1837 moved to Finland, leaving his family in Stockholm. He hoped to interest the Russians in land and sea mines and, after some four years, succeeded in obtaining financial backing from the Ministry of War, enabling him to set up a foundry and arms factory in St Petersburg and to bring his family over. By 1850 he was clear of debt in Sweden and had begun to acquire a high reputation as an inventor and industrialist. His invention of the horned contact mine was to be the basic pattern of the sea mine for almost the next 100 years, but he also created and manufactured a central-heating system based on hot-water pipes. His three sons, Ludwig, Robert and Alfred, had now joined him in his business, but even so the outbreak of war with Britain and France in the Crimea placed severe pressures on him. The Russians looked to him to convert their navy from sail to steam, even though he had no experience in naval propulsion, but the aftermath of the Crimean War brought financial ruin once more to Immanuel. Amongst the reforms brought in by Tsar Alexander II was a reliance on imports to equip the armed forces, so all domestic arms contracts were abruptly cancelled, including those being undertaken by Nobel. Unable to raise money from the banks, Immanuel was forced to declare himself bankrupt and leave Russia for his native Sweden. Nobel then reverted to his study of explosives, particularly of how to adapt the then highly unstable nitroglycerine, which had first been developed by Ascanio Sobrero in 1847, for blasting and mining. Nobel believed that this could be done by mixing it with gunpowder, but could not establish the right proportions. His son Alfred pursued the matter semi-independently and eventually evolved the principle of the primary charge (and through it created the blasting cap), having taken out a patent for a nitroglycerine product in his own name; the eventual result of this was called dynamite. Father and son eventually fell out over Alfred's independent line, but worse was to follow. In September 1864 Immanuel's youngest son, Oscar, then studying chemistry at Uppsala University, was killed in an explosion in Alfred's laboratory: Immanuel suffered a stroke, but this only temporarily incapacitated him, and he continued to put forward new ideas. These included making timber a more flexible material through gluing crossed veneers under pressure and bending waste timber under steam, a concept which eventually came to fruition in the form of plywood.In 1868 Immanuel and Alfred were jointly awarded the prestigious Letterstedt Prize for their work on explosives, but Alfred never for-gave his father for retaining the medal without offering it to him.[br]Principal Honours and DistinctionsImperial Gold Medal (Russia) 1853. Swedish Academy of Science Letterstedt Prize (jointly with son Alfred) 1868.BibliographyImmanuel Nobel produced a short handwritten account of his early life 1813–37, which is now in the possession of one of his descendants. He also had published three short books during the last decade of his life— Cheap Defence of the Country's Roads (on land mines), Cheap Defence of the Archipelagos (on sea mines), and Proposal for the Country's Defence (1871)—as well as his pamphlet (1870) on making wood a more physically flexible product.Further ReadingNo biographies of Immanuel Nobel exist, but his life is detailed in a number of books on his son Alfred.CM -
123 Rateau, Auguste Camille-Edmond
[br]b. 13 October 1863 Royan, Franced. 13 January 1930 Neuilly-sur-Seine, France[br]French constructor of turbines, inventor of the turbo compressor and a centrifugal fan for mine ventilation.[br]A don of the Ecole Polytechnique and the Ecole Supérieure des Mines in Paris, Rateau joined the French Corps des Mines in 1887. Between 1888 and 1898 he taught applied mechanics and electro technics at the Ecole des Mines in St-Etienne. Trying to apply the results of his research to practise, he became into contact with commercial firms, before he was appointed Professor of Industrial Electricity at the Ecole Supérieure des Mines in Paris in 1902. He held this position until 1910, although he founded the Société Anonyme Rateau in Paris in 1903 which by the time of his death had subsidiaries in most of the industrial centres of Europe. By the middle of the nineteenth century, when the increasing problems of ventilation in coal mines had become evident and in many countries had led to several unsatisfactory mechanical constructions, Rateau concentrated on this problem soon after he began working in St-Etienne. The result of his research was the design of a centrifugal fan in 1887 with which he established the principles of mechanical ventilation on a general basis that led to future developments and helped, together with the ventilator invented by Capell in England, to pave the way for the use of electricity in mine ventilation.Rateau continued the study of fluid mechanics and the applications of rotating engines, and after he had published widely on this subject he began to construct many steam turbines, centrifugal compressors and centrifugal pumps. The multicellular Rateau turbine of 1901 became the prototype for many others constructors. During the First World War, when he was very active in the French armaments industry, he developed the invention of the automatic supercharger for aircraft engines and later diesel engines.[br]Principal Honours and DistinctionsAcadémie des Sciences, Prix Fourneyron 1899, Prix Poncelet 1911, Member 1918.Bibliography1892, Considérations sur les turbo-machines et en particulier sur les ventilateurs, St- Etienne.1900, Traité des turbo-machines, Paris.1907, Ventilateurs centrifuges à haute pression, Paris.1908. Développement des turbines à vapeur d'échappement, Paris. 1917, Notice sur les travaux scientifiques et techniques, Paris.Further ReadingH.H.Suplee, 1930, obituary, Mechanical Engineering 52:570–1.L.Leprince-Ringuet (ed.), 1951, Les inventeurs célèbres, Geneva: 151–2 (a comprehensive description of his life and the importance of his turbines).WKBiographical history of technology > Rateau, Auguste Camille-Edmond
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124 Thompson, Benjamin
[br]b. 11 April 1779 Eccleshall, Yorkshire, Englandd. 19 April 1867 Gateshead, England[br]English coal owner and railway engineer, inventor of reciprocal cable haulage.[br]After being educated at Sheffield Grammar School, Thompson and his elder brother established Aberdare Iron Works, South Wales, where he gained experience in mine engineering from the coal-and ironstone-mines with which the works were connected. In 1811 he moved to the North of England as Managing Partner in Bewicke's Main Colliery, County Durham, which was replaced in 1814 by a new colliery at nearby Ouston. Coal from this was carried to the Tyne over the Pelew Main Wagonway, which included a 1,992 yd (1,821 m) section where horses had to haul loaded wagons between the top of one cable-worked incline and the foot of the next. Both inclines were worked by stationary steam engines, and by installing a rope with a record length of nearly 1 1/2 miles (2.4 km), in 1821 Thompson arranged for the engine of the upper incline to haul the loaded wagons along the intervening section also. To their rear was attached the rope from the engine of the lower incline, to be used in due course to haul the empties back again.He subsequently installed this system of "reciprocal working" elsewhere, in particular in 1826 over five miles (8 km) of the Brunton \& Shields Railroad, a colliery line north of the Tyne, where trains were hauled at an average speed of 6 mph (10 km/h) including rope changes. This performance was better than that of contemporary locomotives. The directors of the Liverpool \& Manchester Railway, which was then being built, considered installing reciprocal cable haulage on their line, and then decided to stage a competition to establish whether an improved steam locomotive could do better still. This competition became the Rainhill Trials of 1829 and was decisively won by Rocket, which had been built for the purpose.Thompson meanwhile had become prominent in the promotion of the Newcastle \& Carlisle Railway, which, when it received its Act in 1829, was the longest railway so far authorized in Britain.[br]Bibliography1821, British patent no. 4602 (reciprocal working).1847, Inventions, Improvements and Practice of Benjamin Thompson, Newcastle upon Tyne: Lambert.Further ReadingW.W.Tomlinson, 1914, The North Eastern Railway, Newcastle upon Tyne: Andrew Reid (includes a description of Thompson and his work).R.Welford, 1895, Men of Mark twixt Tyne and Tweed, Vol. 3, 506–6.C.R.Warn, 1976, Waggonways and Early Railways of Northumberland, Newcastle upon Tyne: Frank Graham.——c. 1981, Rails between Wear \& Tyne, Newcastle upon Tyne: Frank Graham.PJGR -
125 vent
- факел для сжигания попутного газа
- удалять (воздух)
- продух
- канал в головке керноприёмной трубы
- выхлопная труба
- выпар
- воздушный клапан (в биотехнологии)
- воздушный клапан
- вентиляционное отверстие
вентиляционное отверстие
Отверстие для воздухообмена между внутренним пространством контейнера и внешней средой.
[ ГОСТ Р 52202-2004( ИСО 830-99)]
вентиляционное отверстие
-
[Лугинский Я. Н. и др. Англо-русский словарь по электротехнике и электроэнергетике. 2-е издание - М.: РУССО, 1995 - 616 с.]Тематики
- контейнеры грузовые
- электротехника, основные понятия
Обобщающие термины
- проемы, двери, запорные устройства и чехлы
EN
воздушный клапан
Устройство, обеспечивающее регулирование расхода воздуха.
[ ГОСТ 22270-76]EN
damper
device used to vary the volume of air passing through an outlet, inlet, or duct; or generally through a confined cross section by varying the cross-sectional area.
[ASHRAE Terminology of Heating, Ventilating, Air Conditioning, and Refrigeration]Трехстворчатый воздушный клапан со встречным врашением створок:
А - с реечным присоединением;
Б - с фланцевым присоединением.1 - Корпус клапана; 2 - Привод; 3 - Створки; 4 - Ось створки.
Примеры описания воздушного клапана
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Клапан предназначен для установки в системах приточной (вытяжной) вентиляции для предотвращения проникновения наружного воздуха в приточно-вытяжные камеры и помещения при неработающем вентиляторе, а также для регулирования количества воздуха в системах кондиционирования и вентиляции низкого давления (разность полных давлений до 140 кгс/м2) с температурой до +80 °С, не содержащих пыли и других твердых веществ в количестве более 100 мг/м3, липких и волокнистых материалов.
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Многостворчатые воздушные клапаны применяются в системах вентиляции и кондиционирования воздуха в качестве запорных, регулирующих и смесительных устройств.
-
Число створок, шт
-
Площадь живого сечения, м2
-
Время открывания, с
-
Время закрывания, с
-
Разность полных давлений, Па
Корпус изготовлен:
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из профилированной оцинкованной листовой стали
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из высококачественной стали
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из экструдированного алюминиевого профиля
Створки изготовлены:
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из профилированной оцинкованной листовой стали
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из высококачественной стали
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из экструдированного алюминиевого профиля
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разворачиваются в противоположные стороны.
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поворачиваются параллельно
Втулки оси створки изготовлены:
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из латуни
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из специальной пластмассы
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предназначен для подогрева мест соприкосновения створок при минусовых температурах, и включаются только на период пуска.
Тематики
EN
воздушный клапан (в биотехнологии)
входное отверстие (в биотехнологии)
—
[ http://www.dunwoodypress.com/148/PDF/Biotech_Eng-Rus.pdf]Тематики
Синонимы
EN
канал в головке керноприёмной трубы
—
[ http://slovarionline.ru/anglo_russkiy_slovar_neftegazovoy_promyishlennosti/]Тематики
EN
продух
Небольшое отверстие для естественной вентиляции покрытия или подполья
[Терминологический словарь по строительству на 12 языках (ВНИИИС Госстроя СССР)]Тематики
EN
DE
FR
удалять (воздух)
выпускать (газ)
—
[ http://slovarionline.ru/anglo_russkiy_slovar_neftegazovoy_promyishlennosti/]Тематики
Синонимы
EN
Англо-русский словарь нормативно-технической терминологии > vent
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126 pipe
- pipe
- nтруба
- air pipe
- antisiphonage pipe
- asbestos-cement pipe
- aspiration pipe
- balance pipe
- bare pipe
- bellmouth pipe
- bleed pipe
- bottom pipe
- Bourdon pipe
- branch pipe
- bypass pipe
- cast-iron drain pipe
- centrifugally-cast pipe
- circulation pipe
- clay pipe
- communication pipe
- concrete pipe
- condensate return pipe
- conductor pipe
- connecting pipe
- corrugated pipe
- customer's service pipe
- diminishing pipe
- discharge pipe
- distributing pipe
- double branch pipe
- drain pipe
- draw-off pipe
- dredging pipe
- drill pipe
- drive pipe
- drowning pipe
- dry condensate return pipe
- equivalent pipe
- exhaust steam pipe
- expansion pipe
- fall pipe
- filter pipe
- flexible pipe
- flow pipe
- flush pipe
- furred hot-water pipes
- furred pipes
- galvanized pipe
- gas pipe
- gas service pipe
- gilled pipe
- glazed stoneware pipe
- heat pipe
- ice pipe
- indirect drain pipe
- inspection pipe
- installation pipe
- instrument branch pipe
- intake pipe
- mantle pipe
- outfall pipe
- outlet pipe
- overflow pipe
- penstock pipe
- plain-ended pipe
- plastic pipe
- pressure pipe
- puff pipe
- pumpcrete pipe
- PVC pipe
- rainwater pipe
- ribbed pipe
- riser pipe
- sag pipe
- salt-glazed earthenware pipe
- screwed pipe
- seamless pipe
- service pipe
- sewer pipe
- shunt pipe
- single-hub pipe
- sludge extraction pipe
- sludge pipe
- snorer pipe
- socket pipe
- soil and vent pipe
- sparge pipe
- spray pipe
- stoneware pipe
- suction pipe
- sump pipe
- supply pipe
- supply pipe from source
- surge pipe
- tail pipe
- taper pipe
- thick-walled pipe
- thin-walled pipe
- vent pipe
- ventilating pipe
- ventilation pipe
- Venturi pipe
- vitrified ceramic drain pipe
- vitrified-clay pipe
- vitrified pipe
- warning pipe
- waste pipe
- water pipe
- water distributing pipe
- water service pipe
- well screen pipe
- wet condensate return pipe
- wood-stave pipe
Англо-русский строительный словарь. — М.: Русский Язык. С.Н.Корчемкина, С.К.Кашкина, С.В.Курбатова. 1995.
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127 column
1) архит. колонна2) стойка; колонка3) мех. сжатый стержень4) колонка5) колонна, аппарат колонного типа8) колонка, столбец; графа9) шахта ( шахтной зерносушилки)•-
absorbing column
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acoustical column
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adiabatic column
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adjustable steering column
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alcohol column
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aldehyde column
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analytical column
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anion column
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annulated column
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aspiration column
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attached column
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axially loaded column
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balance column
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barley-sugar column
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batten-plate column
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beer column
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bifurcated column
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blank column
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bone-char filter column
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box column
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bubble column
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bubble-cap column
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built-up column
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capillary column
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card column
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cascade-tray fractionating column
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cased column
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catalyst-packed column
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charge column
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check column
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chromatographic column
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clay column
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clear air column
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closed column
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clustered column
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coated capillary column
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coke column
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collapsible steering column
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column of matrix
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combination column
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compensating jacket column
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composite column
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concentric tube column
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contact column
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continuous plasma column
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control column
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core support column
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countercurrent column
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coupled columns
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curved plasma column
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depropanizing column
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diminished column
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distillation column
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drill column
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drying column
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eccentrically loaded column
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electrophoresis column
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encased column
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engaged column
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entasized column
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epuration column
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evaporating column
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extraction column
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extruded column
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fixed column
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fixed-bed column
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flooded-bubble column
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floor-fastened column
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flotation column
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fluted column
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fractionating column
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frame column
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fuel element column
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fuel column
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fuel-filling column
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fused silica column
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fusel-oil concentrating column
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geological column
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grain column
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grouped columns
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half-column
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H-column
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ion-exchange column
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laced column
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lattice column
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live column
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low-loaded column
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magnetic column
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mixco column
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mixed-bed column
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mixer-settler column
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molecular-sieve column
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movable lever operation column
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multiplate column
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naphtha column
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open-tubular column
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orifice column
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oxidation column
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packed capillary column
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packed column
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perforated plate column
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pinch column
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pin-ended column
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pin-joined column
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pinned column
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pipe column
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pivotal column
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pivot column
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plasma column
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plate-type column
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poison column
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porous layer open tubular column
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preparative column
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pressure column
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product concentrating column
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pulse column
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pulse-fed column
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punched column
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purifying column
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reaction column
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reactor column
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rectifying column
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reflux column
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rotating-cone distilling column
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Scheibel column
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SCOT column
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short column
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sieve-plate column
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slender column
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solid column
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sound column
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spiral column
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spirally rainforced column
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spiral-screen column
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spray column
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starred column
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steam-stripping column
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steering column
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steering levers column
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stock column
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stocky column
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stripping column
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support-coated open tubular column
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table column
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telescopic steering column
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thermal column
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traveling column
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tray column
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tubular column
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twin column
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two-product column
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universal column
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vacuum column
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walking column
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wall coated open tubular column
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water column
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WCOT column
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wreathed column -
128 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
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adiabatic lapse rate
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advance rate
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aging rate
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allowable leak rate
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angular rate
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annual depletion rate
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application rate
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area rate
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arrival rate
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ascensional rate
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assessed failure rate
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attenuation rate
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autoconvective lapse rate
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base wage rate
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baud rate
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bearer rate
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beating rate
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bit rate
-
bit-error rate
-
bit-transfer rate
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block meter rate
-
block-error rate
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boiling rate
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boil-up rate
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bonus rate
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break flow rate
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breeding rate
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burning rate
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calling rate
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capture rate
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carbonization rate
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cargo rate
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carrier-ionization rate
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casting rate
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catalyst circulation rate
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charging rate
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chipping rate
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chip rate
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chopping rate
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circulation rate
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class rate
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climb rate
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clock rate
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closed rate
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closure rate
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coke rate
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cold storage rates
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collision rate
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combustion rate
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completion rate
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concentration rate
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containment leak rate
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continuous rate
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controlled rate
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convective expansion rate
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conversion rate
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conveyance rate
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cooling rate
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core heat generation rate
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corrosion rate
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counting rate
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crack growth rate
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creep rate
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crosshead rate
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cure rate
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cutter wear rate
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daily consumptive use rate
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data-transfer rate
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data rate
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decay rate
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decompression rate
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deflection rate
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deionization rate
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delivery rate
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demand cost rate
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demand rate
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deposition rate
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descent rate
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development rate
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deviation rate
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differential rate
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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
-
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
-
frame rate
-
frame-repetition rate
-
freezing rate
-
freight rate
-
freight-all-kinds rates
-
frequency-sweep rate
-
frequency-tuning rate
-
fuel rate
-
functional throughput rate
-
gas leak rate
-
gathering rate
-
generation rate
-
grinding rate
-
growth rate
-
gyro drift rate
-
half-clock rate
-
hardening rate
-
heat absorption rate
-
heat dissipation rate
-
heat generation rate
-
heat rate
-
heat-flow rate
-
heating rate
-
heat-transfer rate
-
hit rate
-
image refresh rate
-
impact wear rate
-
in-commission rate
-
infiltration rate
-
information rate
-
injection rate
-
instantaneous failure rate
-
intermittent rate
-
ionization rate
-
irrigation rate
-
iso-wear rates
-
job rates
-
kerma rate
-
keying rate
-
lapse rate
-
leakage rate
-
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
-
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
-
rapid return rate
-
rate of acceleration
-
rate of angular motion
-
rate of attack
-
rate of blowing
-
rate of braking
-
rate of carbon drop
-
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
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