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1 machine-tool area
= machine-tool use area станочный участок, участок механической обработкиEnglish-Russian dictionary of mechanical engineering and automation > machine-tool area
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2 machine-tool area
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3 machine-tool use area
English-Russian dictionary of mechanical engineering and automation > machine-tool use area
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4 machine-tool (use) area
Автоматика: станочный участок, участок механической обработкиУниверсальный англо-русский словарь > machine-tool (use) area
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5 machine-tool use area
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6 area
1) площадь; поверхность2) зона; участок3) область действия; область применения•- area of cut per unit time
- area of inefficiency
- area of instantaneous contact
- area of passage
- assembly area
- base area
- bearing area
- bearing surface area
- blade area
- buffer area
- cable area
- calculated area
- carrying area
- charging area
- chip area
- chucking area
- CIM area
- clearance area
- collar area
- common data area
- common service area
- communications area
- contact area
- control area
- controlled area
- cross-sectional area
- cumulative contact area
- cutting area
- danger area
- data area
- deviation area
- discharge area
- dual work area
- effective area
- elliptical contact area
- enclosed working area
- environmentally controlled area
- equivalent cross-section area
- equivalent cross-sectional area
- exclusion area
- exit area
- finished-tool-storage area
- fixture build area
- fixture load/unload area
- flow area
- focusing area
- forbidden area
- force-transfer area
- free-fall area for chips
- galvanizing area
- goods inwards area
- goods-receiving area
- grinding area
- gripping area
- guarded area of the machine
- hazard area
- hazardous area
- heating area
- high EMI area
- high RFI area
- high-rise storage area
- high-volume area
- high-wear area
- holding area
- image area
- inactive area
- interfacial area
- intermittent area
- internal/external communications area
- laser manufacturing production area
- laser-heated area
- lateral area
- lifting-surface area
- light-sensitive area
- load-and-unload area
- locating area
- low-volume area
- machine-tool area
- machine-tool use area
- machining area
- manned area
- manual machining area
- manual setting-up area
- manufacturing area
- mounting area
- net area
- no-go area
- nominal area
- nonexposed area
- nonirradiated area
- nonworking area
- nozzle area
- operating area of the machine
- operating area
- overstressed local area
- paint area
- painted area
- painting area
- pallet area
- pallet-loading area
- pallet-parking area
- piston area
- plan area
- plane area
- premachining area
- preparation-of-parts area
- problem area
- production area
- prohibited area
- racking area
- ready area
- reference area
- refurbishment area
- robot arm total working area
- robot operating area
- roof area
- rough hole area
- rupture area
- sectional area
- setting-up area
- set-up area
- shearing area
- slipping area
- specific application area
- staging area
- storage area
- superimposed area
- supporting area
- system control area
- table work area
- test area
- throat area
- tool service area
- tool-inventory area
- tool-presetting area
- tool-staging area
- transitional area
- treated area
- uncontrolled area
- unit area
- useful area
- user area
- wash area
- washing area
- weld area
- work area
- working area
- workpiece-staging area
- workplace areaEnglish-Russian dictionary of mechanical engineering and automation > area
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7 cutting
стружка; опилки; лоскутки; обрезки; обрезь; обрезок (пиломатериал); нарезание; насечка; резание; резка (напр. газовая); разрезка; разрезание; срезание; перерезание; строжка; обработка резанием; фрезерование; гранение; выемка (бульдозером); разъединение; разрыв; отсоединение; отключение; выключение; отсечка (тока); запирание (цепи); отсечение; вырезание; отбрасывание стр. выемка грунта; лес. подрубка; врубка; рубка; тесание; распиливание; с.х. косьба; кошение; покос; отросток; отводок; черенок- cutting accuracy - cutting amperage - cutting and bending - cutting-and-mixing machine - cutting-and-molding machine - cutting and shearing plant - cutting angle - cutting apparatus - cutting area - cutting area work - cutting assemblage - cutting axis - cutting-back - cutting band - cutting-bit head - cutting burrs - cutting by blowtorch - cutting by waterjet - cutting cam - cutting capability - cutting ceramics - cutting chain - cutting chute - cutting conditions - cutting coolant - cutting-cooling medium - cutting cycle - cutting depth - cutting device - cutting diamond - cutting die - cutting divider - cutting down - cutting-down - cutting drag - cutting drum - cutting-edge - cutting edge - cutting edge angle - cutting edge configuration - cutting edge form - cutting edge inclination - cutting edge length - cutting edge normal plane - cutting edge of a knife - cutting edge of machining technology - cutting edge package - cutting-edge seal - cutting edge sharpness - cutting edge technology - cutting-edge technology - cutting edge tip - cutting effect - cutting efficiency - cutting effort - cutting electrode - cutting emulsion - cutting end - cutting end shape - cutting energy - cutting engagement - cutting equipment - cutting face - cutting feed rate - cutting feed speed - cutting flame - cutting fluid - cutting-fluid recycling - cutting flute - cutting force - cutting force component - cutting force deflection - cutting force dynamometer - cutting force-induced error - cutting force per unit area of cut - cutting force per unit width of cut - cutting forceps - cutting frame - cutting from the solid - cutting gage - cutting gas - cutting geometry - cutting giant - cutting grade - cutting head - cutting head assembly - cutting-head-height-and-collision sensor - cutting heat - cutting height - cutting-in - cutting in a smooth pattern - cutting in a spiral pattern - cutting-in speed - cutting-in speed of over drive - cutting-in time - cutting inaccuracies - cutting insert - cutting installation - cutting instrument - cutting interval - cutting iron - cutting jet - cutting jib - cutting job - cutting knife - cutting laser tool - cutting length - cutting life - cutting line - cutting liquid - cutting load - cutting load signal - cutting-loading machine - cutting lubricant - cutting machine - cutting machine scratch - cutting machine tool technology - cutting machine with coordinate drive - cutting material - cutting mechanics - cutting mechanism - cutting medium - cutting member - cutting metal - cutting mode - cutting motion - cutting movement - cutting nippers - cutting noise - cutting nozzle - cutting of fuel oils - cutting-off-abrasive wheel - cutting-off - cutting-off bit tool - cutting-off EDM - cutting-off grinding - cutting-off lathe - cutting-off machine - cutting-off saw - cutting-off tool - cutting oil - cutting-oil deflector - cutting oil freshener - cutting oil separator - cutting operation - cutting orientation - cutting out - cutting-out - cutting-out of rivets - cutting out of square - cutting-out press - cutting oxygen - cutting oxygen tube - cutting parameters - cutting part - cutting pass - cutting path - cutting path supporting points - cutting pattern - cutting performance - cutting period - cutting perpendicular force - cutting pick - cutting plan - cutting plane - cutting plane line - cutting plate - cutting platform - cutting pliers - cutting point - cutting-point angle - cutting position - cutting power - cutting-practice rules - cutting press - cutting profile - cutting program - cutting prong - cutting propagation - cutting pulse - cutting punch - cutting quality - cutting radius - digging radius - cutting rate - cutting region - cutting relief angle - cutting resistance - cutting resistance per tooth - cutting rib - cutting right to size - cutting rim - cutting ring - cutting ring coupling - cutting roll - cutting room - cutting rotor - cutting rule - cutting run - cutting scallops - cutting sequence - cutting-shearing drilling bit - cutting shoe - cutting simulation - cutting size - cutting size of core diamond bit - cutting speed - cutting speed chart plate - cutting speed control mechanism - cutting speed for milling - cutting speed indicator - cutting spindle - cutting stretch - cutting stroke - cutting stroke drive - cutting surface - cutting table - cutting tap - cutting technology - cutting technology routine - cutting teeth - cutting temperature - cutting test - cutting the loop - cutting-through of a tunnel - cutting thrust - cutting thrust force - cutting time - cutting-time monitor - cutting tip - cutting to a shoulder - cutting to length - cutting to size - cutting tool - cutting tool assembly - cutting tool body - cutting tool cartridge - cutting tool collet - cutting tool contact indicator - cutting tool control macro - cutting tool data - utting tool edge - cutting tool engineering - cutting tool force - cutting tool holder - cutting tool industry - cutting tool insert - cutting tool lubricant - cutting tool materials - cutting tool measurement system - cutting tool outlet - cutting tool technology - cutting tool with inserted blades - cutting tooth - cutting torch - cutting torque - cutting-type core drilling bit - cutting-type drilling bit - cutting unit - cutting up - cutting-up line - cutting value - cutting waste - cutting wear - cutting wedge - cutting wheel - cutting wheel carrier - cutting width - cutting-winning machine - cutting with preheating - cutting work - cutting zone - abrasive cutting - abrasive cutting-off - abrasive waterjet cutting - accretion cutting - across cutting - adaptive control cutting - air-arc cutting - air plasma cutting - angle cutting - approach cutting - arc cutting - arc-oxygene cutting - back-off cutting - bottom cutting - burrless cutting - cable cutting - cam cutting - carbide cutting - carbon-arc cutting - cleaning cutting - climb cutting - composite cutting - consecutive tool cutting - creep cutting - cross-cutting - cryogenic cutting - curved cutting - 2D profile cutting - 3D profile cutting - deep cutting - deskill cutting - diagonal cutting - diamond cutting - double cutting - double-roll cutting - double-roll tooth cutting - drill cuttings - dry cutting - ED cutting-off - ED wire cutting - edge cutting - electric arc-gas jet cutting - electrochemical hole cutting - electrochemical wire cutting - electroerosion cutting - end cutting - fabric cutting - finishing cutting - flame cutting - flux injetion cutting - form cutting - form tooth cutting - friction cutting - fusion cutting - gas cutting - gas metal cutting - gas-shielded arc cutting - gas-shielded tungsten-arc cutting - gas tungsten cutting - gear cutting - grass cutting - groove cutting - guided hand cutting - hand cutting - heavy cutting - high-pressure water-assisted cutting - hoisting and drilling load cuttings - hydraulic cutting - hydrogene cutting - in-line cutting - inserted carbide cutting - internal cutting - internally fed wet cutting - interrupted cutting - irregular depth cutting - keyway cutting - lance cutting - laser cutting - lateral cutting - length cutting - light cutting - little-and-often cutting - low-rpm cutting - machine cutting - manual air-plasma jet cutting - measure cutting - metal cutting - metal-arc cutting - metal powder cutting - miter cutting - multipass cutting - multiple milling cutting - multiple thread cutting - multitool cutting - oblique cutting - orthogonal cutting - oxy-arc cutting - oxygene-arc cutting - oxy-fuel cutting - oxy-fuel gas cutting - oxyacetylene cutting - oxyacetylene flame cutting - oxygen arc cutting - oxygen assisted laser cutting - oxygene lance cutting - oxyhydrogen cutting - oxy-propane cutting - part cutting - percussion cutting - peritheral cutting - pipe cuttings - plasma arc cutting - plasma flame cutting - plasma-jet cutting - playback laser cutting - plunge cutting - press cutting - polygon cutting - polygonal cutting - profile cutting - punch cutting - railway cutting - right-angle cutting - rotary cutting - rough cutting - round cutting - sample cutting - screw cutting - scroll cutting - see-saw cutting - setable minimum cutting - shape cutting - shear cuttings - shear-speed cutting - shielded metal arc cutting - side cutting - sideways cutting - single-pass cutting - single-point cutting - single-point thread cutting - skip cutting - slice cutting - solid cutting - spark cutting - spiral cuttings - spiral-bevel-gear cutting - spur-gear cutting - stack cutting - steel cuttings - straight line cutting - taper cutting - thermal cutting - thread cutting - tooth cutting - torch cutting - transverse cutting - tungsten-arc cutting - two-way cutting - ultrasonic cutting - up cutting - waterjet cutting - waterjet-assisted mechanical cutting - wet cutting - wire cutting -
8 Brown, Joseph Rogers
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering[br]b. 26 January 1810 Warren, Rhode Island, USAd. 23 July 1876 Isles of Shoals, New Hampshire, USA[br]American machine-tool builder and co-founder of Brown \& Sharpe.[br]Joseph Rogers Brown was the eldest son of David Brown, who was modestly established as a maker of and dealer in clocks and watches. Joseph assisted his father during school vacations and at the age of 17 left to obtain training as a machinist. In 1829 he joined his father in the manufacture of tower clocks at Pawtucket, Rhode Island, and two years later went into business for himself in Pawtucket making lathes and small tools. In 1833 he rejoined his father in Providence, Rhode Island, as a partner in the manufacture of docks, watches and surveying and mathematical instruments. David Brown retired in 1841.J.R.Brown invented and built in 1850 a linear dividing engine which was the first automatic machine for graduating rules in the United States. In 1851 he brought out the vernier calliper, the first application of a vernier scale in a workshop measuring tool. Lucian Sharpe was taken into partnership in 1853 and the firm became J.R.Brown \& Sharpe; in 1868 the firm was incorporated as the Brown \& Sharpe Manufacturing Company.In 1855 Brown invented a precision gear-cutting machine to make clock gears. The firm obtained in 1861 a contract to make Wilcox \& Gibbs sewing machines and gave up the manufacture of clocks. At about this time F.W. Howe of the Providence Tool Company arranged for Brown \& Sharpe to make a turret lathe required for the manufacture of muskets. This was basically Howe's design, but Brown added a few features, and it was the first machine tool built for sale by the Brown \& Sharpe Company. It was followed in 1862 by the universal milling machine invented by Brown initially for making twist drills. Particularly for cutting gear teeth, Brown invented in 1864 a formed milling cutter which could be sharpened without changing its profile. In 1867 the need for an instrument for checking the thickness of sheet material became apparent, and in August of that year J.R.Brown and L.Sharpe visited the Paris Exhibition and saw a micrometer calliper invented by Jean Laurent Palmer in 1848. They recognized its possibilities and with a few developments marketed it as a convenient, hand-held measuring instrument. Grinding lathes were made by Brown \& Sharpe in the early 1860s, and from 1868 a universal grinding machine was developed, with the first one being completed in 1876. The patent for this machine was granted after Brown's sudden death while on holiday.[br]Further ReadingJ.W.Roe, 1916, English and American Tool Builders, New Haven: Yale University Press; repub. 1926, New York and 1987, Bradley, Ill.: Lindsay Publications Inc. (further details of Brown \& Sharpe Company and their products).R.S.Woodbury, 1958, History of the Gear-Cutting Machine, Cambridge, Mass.: MIT Press ——, 1959, History of the Grinding Machine, Cambridge, Mass.: MIT Press.——, 1960, History of the Milling Machine, Cambridge, Mass.: MIT Press.RTS -
9 Bullard, Edward Payson
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering[br]b. 18 April 1841 Uxbridge, Massachusetts, USAd. 22 December 1906 Bridgeport, Connecticut, USA[br]American mechanical engineer and machine-tool manufacturer who designed machines for boring.[br]Edward Payson Bullard served his apprenticeship at the Whitin Machine Works, Whitinsville, Massachusetts, and worked at the Colt Armory in Hartford, Connecticut, until 1863; he then entered the employ of Pratt \& Whitney, also in Hartford. He later formed a partnership with J.H.Prest and William Parsons manufacturing millwork and tools, the firm being known as Bullard \& Prest. In 1866 Bullard organized the Norwalk Iron Works Company of Norwalk, Connecticut, but afterwards withdrew and continued the business in Hartford. In 1868 the firm of Bullard \& Prest was dissolved and Bullard became Superintendent of a large machine shop in Athens, Georgia. He later organized the machine tool department of Post \& Co. at Cincinnati, and in 1872 he was made General Superintendent of the Gill Car Works at Columbus, Ohio. In 1875 he established a machinery business in Beekman Street, New York, under the name of Allis, Bullard \& Co. Mr Allis withdrew in 1877, and the Bullard Machine Company was organized.In 1880 Bullard secured entire control of the business and also became owner of the Bridgeport Machine Tool Works, Bridgeport, Connecticut. In 1883 he designed his first vertical boring and turning mill with a single head and belt feed and a 37 in. (94 cm) capacity; this was the first small boring machine designed to do the accurate work previously done on the face plate of a lathe. In 1889 Bullard gave up his New York interests and concentrated his entire attention on manufacturing at Bridgeport, the business being incorporated in 1894 as the Bullard Machine Tool Company. The company specialized in the construction of boring machines, the design being developed so that it became essentially a vertical turret lathe. After Bullard's death, his son Edward Payson Bullard II (b. 10 July 1872 Columbus, Ohio, USA; d. 26 June 1953 Fairfield, Connecticut, USA) continued as head of the company and further developed the boring machine into a vertical multi-spindle automatic lathe which he called the "Mult-au-matic" lathe. Both father and son were members of the American Society of Mechanical Engineers.[br]Further ReadingJ.W.Roe, 1916, English and American Tool Builders, New Haven: Yale University Press; repub. 1926, New York and 1987, Bradley, Ill.: Lindsay Publications Inc. (describes Bullard's machines).RTS -
10 Howe, Frederick Webster
[br]b. 28 August 1822 Danvers, Massachusetts, USAd. 25 April 1891 Providence, Rhode Island, USA[br]American mechanical engineer, machine-tool designer and inventor.[br]Frederick W.Howe attended local schools until the age of 16 and then entered the machine shop of Gay \& Silver at North Chelmsford, Massachusetts, as an apprentice and remained with that firm for nine years. He then joined Robbins, Kendall \& Lawrence of Windsor, Vermont, as Assistant to Richard S. Lawrence in designing machine tools. A year later (1848) he was made Plant Superintendent. During his time with this firm, Howe designed a profiling machine which was used in all gun shops in the United States: a barrel-drilling and rifling machine, and the first commercially successful milling machine. Robbins \& Lawrence took to the Great Exhibition of 1851 in London, England, a set of rifles built on the interchangeable system. The interest this created resulted in a visit of some members of the British Royal Small Arms Commission to America and subsequently in an order for 150 machine tools, jigs and fixtures from Robbins \& Lawrence, to be installed at the small-arms factory at Enfield. From 1853 to 1856 Howe was in charge of the design and building of these machines. In 1856 he established his own armoury at Newark, New Jersey, but transferred after two years to Middletown, Connecticut, where he continued the manufacture of small arms until the outbreak of the Civil War. He then became Superintendent of the armoury of the Providence Tool Company at Providence, Rhode Island, and served in that capacity until the end of the war. In 1865 he went to Bridgeport, Connecticut, to assist Elias Howe with the manufacture of his sewing machine. After the death of Elias Howe, Frederick Howe returned to Providence to join the Brown \& Sharpe Manufacturing Company. As Superintendent of that establishment he worked with Joseph R. Brown in the development of many of the firm's products, including machinery for the Wilcox \& Gibbs sewing machine then being made by Brown \& Sharpe. From 1876 Howe was in business on his own account as a consulting mechanical engineer and in his later years he was engaged in the development of shoe machinery and in designing a one-finger typewriter, which, however, was never completed. He was granted several patents, mainly in the fields of machine tools and firearms. As a designer, Howe was said to have been a perfectionist, making frequent improvements; when completed, his designs were always sound.[br]Further ReadingJ.W.Roe, 1916, English and American Tool Builders, New Haven; repub. 1926, New York, and 1987, Bradley, 111. (provides biographical details).R.S.Woodbury, 1960, History of the Milling Machine, Cambridge, Mass, (describes Howe's contribution to the development of the milling machine).RTSBiographical history of technology > Howe, Frederick Webster
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11 Murray, Matthew
SUBJECT AREA: Land transport, Mechanical, pneumatic and hydraulic engineering, Railways and locomotives, Steam and internal combustion engines[br]b. 1765 near Newcastle upon Tyne, Englandd. 20 February 1826 Holbeck, Leeds, England[br]English mechanical engineer and steam engine, locomotive and machine-tool pioneer.[br]Matthew Murray was apprenticed at the age of 14 to a blacksmith who probably also did millwrighting work. He then worked as a journeyman mechanic at Stockton-on-Tees, where he had experience with machinery for a flax mill at Darlington. Trade in the Stockton area became slack in 1788 and Murray sought work in Leeds, where he was employed by John Marshall, who owned a flax mill at Adel, located about 5 miles (8 km) from Leeds. He soon became Marshall's chief mechanic, and when in 1790 a new mill was built in the Holbeck district of Leeds by Marshall and his partner Benyon, Murray was responsible for the installation of the machinery. At about this time he took out two patents relating to improvements in textile machinery.In 1795 he left Marshall's employment and, in partnership with David Wood (1761– 1820), established a general engineering and millwrighting business at Mill Green, Holbeck. In the following year the firm moved to a larger site at Water Lane, Holbeck, and additional capital was provided by two new partners, James Fenton (1754–1834) and William Lister (1796–1811). Lister was a sleeping partner and the firm was known as Fenton, Murray \& Wood and was organized so that Fenton kept the accounts, Wood was the administrator and took charge of the workshops, while Murray provided the technical expertise. The factory was extended in 1802 by the construction of a fitting shop of circular form, after which the establishment became known as the "Round Foundry".In addition to textile machinery, the firm soon began the manufacture of machine tools and steam-engines. In this field it became a serious rival to Boulton \& Watt, who privately acknowledged Murray's superior craftsmanship, particularly in foundry work, and resorted to some industrial espionage to discover details of his techniques. Murray obtained patents for improvements in steam engines in 1799, 1801 and 1802. These included automatic regulation of draught, a mechanical stoker and his short-D slide valve. The patent of 1801 was successfully opposed by Boulton \& Watt. An important contribution of Murray to the development of the steam engine was the use of a bedplate so that the engine became a compact, self-contained unit instead of separate components built into an en-gine-house.Murray was one of the first, if not the very first, to build machine tools for sale. However, this was not the case with the planing machine, which he is said to have invented to produce flat surfaces for his slide valves. Rather than being patented, this machine was kept secret, although it was apparently in use before 1814.In 1812 Murray was engaged by John Blenkinsop (1783–1831) to build locomotives for his rack railway from Middleton Colliery to Leeds (about 3 1/2 miles or 5.6 km). Murray was responsible for their design and they were fitted with two double-acting cylinders and cranks at right angles, an important step in the development of the steam locomotive. About six of these locomotives were built for the Middleton and other colliery railways and some were in use for over twenty years. Murray also supplied engines for many early steamboats. In addition, he built some hydraulic machinery and in 1814 patented a hydraulic press for baling cloth.Murray's son-in-law, Richard Jackson, later became a partner in the firm, which was then styled Fenton, Murray \& Jackson. The firm went out of business in 1843.[br]Principal Honours and DistinctionsSociety of Arts Gold Medal 1809 (for machine for hackling flax).Further ReadingL.T.C.Rolt, 1962, Great Engineers, London (contains a good short biography).E.Kilburn Scott (ed.), 1928, Matthew Murray, Pioneer Engineer, Leeds (a collection of essays and source material).C.F.Dendy Marshall, 1953, A History of Railway Locomotives Down to the End of theYear 1831, London.L.T.C.Rolt, 1965, Tools for the Job, London; repub. 1986 (provides information on Murray's machine-tool work).Some of Murray's correspondence with Simon Goodrich of the Admiralty has been published in Transactions of the Newcomen Society 3 (1922–3); 6(1925–6); 18(1937– 8); and 32 (1959–60).RTS -
12 Herbert, Sir Alfred Edward
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering[br]b. 5 September 1866 Leicester, Englandd. 26 May 1957 Kings Somborne, Hampshire, England[br]English mechanical engineer and machine-tool manufacturer.[br]Alfred Herbert was educated at Stoneygate School, Leicester, and served an apprenticeship with Joseph Jessop \& Sons, also of Leicester, from 1881 to 1886. In 1887 he was engaged as Manager of a small engineering firm in Coventry, and before the end of that year he purchased the business in partnership with William Hubbard. They commenced the manufacture of machine-tools especially for the cycle industry. Hubbard withdrew from the partnership in 1890 and Herbert continued on his own account, the firm being established as a limited liability company, Alfred Herbert Ltd, in 1894. A steady expansion of the business continued, especially after the introduction of their capstan lathe, and by 1914 it was the largest manufacturer of machine-tools in Britain. In addition to making machine-tools of all types for the home and export market, the firm acted as an agent for the import of specialist machine-tools from abroad. During the First World War Alfred Herbert was in 1915 appointed head of machine-tool production at the War Office and when the Ministry of Munitions was set up he was transferred to that Ministry as Controller of Machine Tools. He was President of the Machine Tools Trades Association from 1919 to 1934. He was elected a member of the Institution of Mechanical Engineers in 1892 and in 1921 was a founder member of the Institution of Production Engineers. Almost to the end of his long life he continued to take an active part in the direction of his company. He expressed his views on current events affecting industry in the technical press and in his firm's house journal.[br]Principal Honours and DistinctionsKBE 1917. Officier de la Légion d'honneur 1917. Order of St Stanislas of Russia 1918. Order of Leopold of Belgium 1918. Freeman of the City of Coventry 1933. President, Institution of Production Engineers 1927–9. Honorary Member, Institution of Mechanical Engineers 1941.Bibliography1948, Shots at the Truth, Coventry (a selection of his speeches and writings).Further ReadingD.J.Jeremy (ed.), 1984–6, Dictionary of Business Biography, Vol. 3, London, pp. 174–7 (a useful account).Obituary, 1957, Engineering, 183:680.RTSBiographical history of technology > Herbert, Sir Alfred Edward
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13 data
данные; сведения; информацияto display the tooling data — выводить данные инструмента на дисплей-
AC data
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actual data
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actuation data
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adjusted data
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aeronautical data
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air data
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aircraft loading data
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aircraft main data
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aircraft operational data
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aircraft test data
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aircraft weight data
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air-derived data
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alphanumeric data
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alphameric data
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alphabetic data
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analog data
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angular data
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application-specific data
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area-averaged data
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arrayed data
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array data
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asynoptic data
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attributes data
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attribute data
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bearing preload data
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behavioral data
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biased data
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binary data
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binocular data
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blast data
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boundary data
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brightness data
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buoy data
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business data
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captioning data
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channel data
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characteristic data
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clear data
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CNC control data
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coded data
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combined data
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confidential data
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continuous data
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control data
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corrected profile data
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correction data
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current data
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cutting data
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decimal data
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delayed-mode data
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delayed data
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descriptive data
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design data
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digital data
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digital profile data
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digital program data
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digitized data
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dimensions data
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dimension data
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discrepant data
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discrete data
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disembodied data
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displayed data
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display data
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enciphered data
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encoded data
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engine performance data
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engineering data
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environmental data
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erroneous data
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error data
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failure analysis data
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field data
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fixed-point data
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flight data
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floating-point data
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geodetic data
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geological and engineering data
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gridded data
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grid data
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grid-point data
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ground truth data
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ground-derived data
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hemispheric data
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historical data
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hydroclime data
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hydrologic data
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ice data
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image data
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imagery data
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imaging data
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impure data
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incoming data
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indicative data
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infrared tracking data
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initial data
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input data
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input shape data
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in-reactor observational data
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in-situ data
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intensional data
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lithogeochemical data
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location data
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long-term data
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machinable data
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machine tool data
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machine-readable data
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marine data
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master data
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meaningful data
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meaning data
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meaningless data
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measuring data
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meta data
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metrological data
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missing data
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model data
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motion data
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multispectral data
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nadir-viewed data
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NC data
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noiseless data
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null data
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numerical data
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numeric data
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observational data
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observed data
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offset curve data
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on-line data
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operational data
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operator-entered data
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outgoing data
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output data
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packed data
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part-programming data
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past data
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performance data
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pictorial data
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plant data
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plotted data
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point data
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position data
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present-position data
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private data
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problem data
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pseudo-observed data
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public data
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published data
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raw data
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real-time data
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real-time tool data
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redundant data
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reference data
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refined data
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relevant data
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reliability data
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remotely-sensed data
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remote-sensed data
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reservoir engineering data
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sampled data
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sea truth data
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sensory data
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service data
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shareable data
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shipping data
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simulation data
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size data
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snap data
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source data
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space-acquired data
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space-based data
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spatial data
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standard sewing data
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static tool data
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status data
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streamflow data
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string data
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structured tool data
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summarized data
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supplier data
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surface-based data
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surface data
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tabular data
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tabulated data
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target data
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task data
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telemetry data
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test data
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tool condition data
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topo data
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torque data
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transaction data
-
transient response data
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transparent data
-
true data
-
unpacked data
-
valid data
-
verified data
-
video data
-
vision data
-
voice data
-
voice-band data
-
way-point data
-
workcycle data
-
workpiece shape data
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zero data -
14 Pratt, Francis Ashbury
[br]b. 15 February 1827 Woodstock, Vermont, USAd. 10 February 1902 Hartford, Connecticut, USA[br]American mechanical engineer and machine-tool manufacturer.[br]Francis A.Pratt served an apprenticeship as a machinist with Warren Aldrich, and on completing it in 1848 he entered the Gloucester Machine Works as a journeyman machinist. From 1852 to 1854 he worked at the Colt Armory in Hartford, Connecticut, where he met his future partner, Amos Whitney. He then became Superintendent of the Phoenix Iron Works, also at Hartford and run by George S.Lincoln \& Company. While there he designed the well-known "Lincoln" miller, which was first produced in 1855. This was a development of the milling machine built by Robbins \& Lawrence and designed by F.W. Howe, and incorporated a screw drive for the table instead of the rack and pinion used in the earlier machine.Whitney also moved to the Phoenix Iron Works, and in 1860 the two men started in a small way doing machine work on their own account. In 1862 they took a third partner, Monroe Stannard, and enlarged their workshop. The business continued to expand, but Pratt and Whitney remained at the Phoenix Iron Works until 1864 and in the following year they built their first new factory. The Pratt \& Whitney Company was incorporated in 1869 with a capital of $350,000, F.A.Pratt being elected President. The firm specialized in making machine tools and tools particularly for the armament industry. In the 1870s Pratt made no less than ten trips to Europe gaining orders for equipping armouries in many different countries. Pratt \& Whitney was one of the leading firms developing the system of interchangeable manufacture which led to the need to establish national standards of measurement. The Rogers-Bond Comparator, developed with the backing of Pratt \& Whitney, played an important part in the establishment of these standards, which formed the basis of the gauges of many various types made by the firm. Pratt remained President of the company until 1898, after which he served as their Consulting Engineer for a short time before retiring from professional life. He was granted a number of patents relating to machine tools. He was a founder member of the American Society of Mechanical Engineers in 1880 and was elected a vice-president in 1881. He was an alderman of the city of Hartford.[br]Principal Honours and DistinctionsVice-President, American Society of Mechanical Engineers 1881.Further ReadingJ.W.Roe, 1916, English and American Tool Builders, New Haven; reprinted 1926, New York, and 1987, Bradley, 111. (describes the origin and development of the Pratt \& Whitney Company).RTS -
15 станочный участок
1) Engineering: machining section, multimachine installation, workcenter2) Automation: cell, machine-tool (use) area, machining area, machining division, machining floor, machining line, manufacturing system, production line, work center3) Makarov: machine-tool use area -
16 controller
1) управляющее устройство, устройство управления2) контроллер, командоаппарат5) контрольно-измерительный прибор; контрольно-измерительное устройство•- AC controller
- adaptive controller
- adaptive variable structure controller
- adjustable controller
- adjustable-speed controller
- air-operated controller
- all-purpose controller
- analog-to-frequency controller
- area controller
- arm controller
- astatic controller
- automatic controller
- auxiliary controller
- axis controller
- behavior-based controller
- bubble memory controller
- bus-based controller
- camshaft controller
- cascade controller
- cell controller
- cell management controller
- center controller
- centering controller
- central controller
- central programmable controller
- CNC controller
- CNC/PC-backed controller
- combination controller
- communications capable controller
- compound controller
- computer-torque controller
- conductivity controller
- constant-pressure flow controller
- continuous controller
- continuous-action controller
- conventional CNC controller
- conventional numerical controller
- copy controller
- copying controller
- correlated controller
- cycle controller
- digital controller
- digital loop controller
- direct-acting controller
- discontinuous-action controller
- discrete action controller
- disk controller
- displacement controller
- distribution controller
- DNC controller
- draft controller
- dressing controller
- drum logic controller
- edge tracking controller
- elastic feedback controller
- electric contact controller
- electric controller
- electric hydraulic controller
- electromechanical controller
- electronic controller
- electropneumatic controller
- equipment level controller
- extremal controller
- factory automation controller
- feed controller
- feedback controller
- field controller
- finite-dimensional controller
- fixed-gain controller
- flexible automation controller
- flexible controller
- floating controller
- flow controller
- FMS cell controller
- FMS line controller
- follow-up controller
- freely programmable controller
- frequency controller
- gain controller
- gemdrive axis controller
- hardware controller
- hydraulic controller
- I/O controller
- IBM compatible controller
- inching controller
- indicating controller
- indirect action controller
- industrial sequence controller
- infinite-dimensional controller
- input/output controller
- integral controller
- interfaceable controller
- intermittent controller
- LAN controller
- limiting controller
- linear controller
- low-point speed controller
- machine controller
- machine tool controller
- management controller
- manual controller
- MAP/cell controller
- master controller
- master programmable controller
- material handling controller
- mechanically operated controller
- microcomputer controller
- microprocessor controller
- microprocessor-driven machine controller
- minimum error controller
- model reference adaptive process controller
- motion controller
- motor controller
- multiaction controller
- multichannel controller
- multiinput controller
- multilevel controller
- multimachine-tool controller
- multiposition controller
- multispeed controller
- multistep controller
- narrow-band controller
- NC controller
- network controller
- neural net controller
- numerical controller
- on-off controller
- open system controller
- open-cycle controller
- optimal controller
- optimizing peak-holding controller
- oscillating controller
- output sampling controller
- PC-backed controller
- pedestal controller
- Petri net controller
- photoelectric controller
- PID controller
- pilot-operated controller
- plugboard controller
- pneumatic controller
- pneumatic-hydraulic controller
- positioning controller
- power controller
- pressure controller
- probe controller
- process controller
- process cycle controller
- production controller
- production management controller
- professional graphics controller
- program controller
- programmable controller
- programmable CRT controller
- programmable industrial controller
- programmable interface controller
- programmable logic controller
- proportional action controller
- proportional controller with disturbance-variable compensation
- proportional controller
- proportional position action controller
- proportional-plus-derivative action controller
- proportional-plus-integral action controller
- proportional-plus-integral-plus-derivative controller
- protocol controller
- pulse controller
- PWM controller
- ratio controller
- relay controller
- remote controller
- rigid feedback controller
- robot arm controller
- robot cell controller
- robot/workcenter controller
- rotary and tilt controller
- sampled-data controller
- sampling controller
- secondary controller
- self-acting controller
- self-actuated controller
- self-operated controller
- semiautomatic controller
- sequential controller
- servo controller
- shift controller
- single-duty controller
- single-variable controller
- small sequential controller
- software controller
- software-based controller
- speed controller
- static controller
- stepping controller
- strip-width controller
- supervisory controller
- system's central controller
- tape controller
- teach controller
- teaching controller
- temperature controller
- thermostatic controller
- tool life controller
- torque controller
- turning controller
- two-level controller
- two-position controller
- two-speed controller
- two-stage controller
- two-step controller
- valve controller
- variable feedback controller
- vise controller
- volume controller
- wide-band controller
- wide-range controller
- workstation controllerEnglish-Russian dictionary of mechanical engineering and automation > controller
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17 Heald, James Nichols
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering[br]b. 21 September 1864 Barre, Massachusetts, USAd. 7 May 1931 Worcester, Massachusetts, USA[br]American mechanical engineer and machine-tool manufacturer who concentrated on grinding machines.[br]James N.Heald was the son of Leander S.Heald and was educated at the Worcester Polytechnic Institute, graduating with the degree of Bachelor of Science in 1884. He then joined the firm that had been established by his grandfather, Stephen Heald, in 1826; this was a machine shop and foundry then known as S.Heald \& Son. When his grandfather died in 1888, James Heald took over the management of the business, which then became known as L.S.Heald \& Son. He concentrated on the manufacture of grinding machines and in 1903 bought out his father's interest and organized the Heald Machine Company. James Heald then began the development of a series of grinding machines designed to meet the needs of the expanding automobile industry. Special machines were produced for grinding piston rings making use of the recently invented magnetic chuck, and for cylinder bores he introduced the planetary grinder. Heald was a member of the National Machine Tool Builders' Association and served as its Treasurer and on its Board of Directors. He was elected a member of the American Society of Mechanical Engineers in 1917 and was also a member of the Society of Automotive Engineers.[br]Further ReadingRobert S.Woodbury, 1959, History of the Grinding Machine, Cambridge, Mass (describes his grinding machines).L.T.C.Rolt, 1965, Tools for the Job, London; repub. 1986 (describes his grinding machines).RTS -
18 monitor
1) контрольное устройство; контрольно измерительное устройство2) видеоконтрольное устройство, ВКУ, (видео)монитор4) вчт. (программа-)монитор; диспетчер; управляющая программа5) экол. осуществлять мониторинг; наблюдать6) горн. гидромонитор7) машиностр. устройство адаптивного управления8) машиностр. монитор10) сварка фирм. монитор ( переносная газорезательная машина-тележка)•-
air activity monitor
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air monitor
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announcer monitor
-
area radiation monitor
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area monitor
-
atmospheric composition monitor
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background monitor
-
canvas monitor
-
coal pipe monitor
-
color picture monitor
-
color monitor
-
debug monitor
-
environmental noise monitor
-
failure monitor
-
feed-force monitor
-
frequency monitor
-
hands-and-feet contamination monitor
-
hydraulic monitor
-
leakage current monitor
-
limb infrared monitor of the stratosphere
-
low-power radiation monitor
-
machine tool monitor
-
machining monitor
-
methane monitor
-
modulation monitor
-
monochrome monitor
-
multichannel monitor
-
neutron monitor
-
outage monitor
-
output voltage monitor
-
ozone monitor
-
particle monitor
-
personal dust exposure monitor
-
personal monitor
-
phase monitor
-
picture monitor
-
pollution monitor
-
power level monitor
-
power monitor
-
process monitor
-
pulsed jet monitor
-
radiation monitor
-
real-time monitor
-
refreshed monitor
-
remote monitor
-
rock-burst monitor
-
ROM monitor
-
sequence monitor
-
spectrum monitor
-
system monitor
-
thread monitor
-
thunderstorm monitor
-
time-sharing monitor
-
tool breakage monitor
-
tool cycle time monitor
-
tool life monitor
-
video monitor
-
visual range monitor
-
voltage monitor
-
water monitor
-
waveform monitor -
19 участок механической обработки
1) Engineering: machining section2) Automation: cutting department, machine-tool (use) area, machining department, machining division3) Makarov: machine-tool use areaУниверсальный русско-английский словарь > участок механической обработки
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20 Whitney, Amos
[br]b. 8 October 1832 Biddeford, Maine, USAd. 5 August 1920 Poland Springs, Maine, USA[br]American mechanical engineer and machine-tool manufacturer.[br]Amos Whitney was a member of the same distinguished family as Eli Whitney. His father was a locksmith and machinist and he was apprenticed at the age of 14 to the Essex Machine Company of Lawrence, Massachusetts. In 1850 both he and his father were working at the Colt Armory in Hartford, Connecticut, where he first met his future partner, F.A. Pratt. They both subsequently moved to the Phoenix Iron Works, also at Hartford, and in 1860 they started in a small way doing machine work on their own account. In 1862 they took a third partner, Monroe Stannard, and enlarged their workshop. The business continued to expand, but Pratt and Whitney remained at the Phoenix Iron Works until 1864 and in the following year they built their first new factory. The Pratt \& Whitney Company was incorporated in 1869 with a capital of $350,000, Amos Whitney being appointed General Superintendent. The firm specialized in making machine tools and tools particularly for the armament industry. Pratt \& Whitney was one of the leading firms developing the system of interchangeable manufacture which led to the need to establish national standards of measurement. The Rogers-Bond Comparator, developed with the backing of Pratt \& Whitney, played an important part in the establishment of these standards, which formed the basis of the gauges of many various types made by the firm.Amos Whitney was made Vice-President of Pratt \& Whitney Company in 1893 and was President from 1898 until 1901, when the company was acquired by the Niles- Bement-Pond Company: he then remained as one of the directors. He was elected a Member of the American Society of Mechanical Engineers in 1913.[br]Further ReadingJ.W.Roe, 1916, English and American Tool Builders, New Haven; reprinted 1926, New York, and 1987, Bradley, Ill. (describes the origin and development of the Pratt \& Whitney Company).RTS
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