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121 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 -
122 Norton, Charles Hotchkiss
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering[br]b. 23 November 1851 Plainville, Connecticut, USAd. 27 October 1942 Plainville, Connecticut, USA[br]American mechanical engineer and machine-tool designer.[br]After an elementary education at the public schools of Plainville and Thomaston, Connecticut, Charles H.Norton started work in 1866 at the Seth Thomas Clock Company in Thomaston. He was soon promoted to machinist, and further progress led to his successive appointments as Foreman, Superintendent of Machinery and Manager of the department making tower clocks. He designed many public clocks.In 1886 he obtained a position as Assistant Engineer with the Brown \& Sharpe Manufacturing Company at Providence, Rhode Island, and was engaged in redesigning their universal grinding machine to give it more rigidity and make it more suitable for use as a production machine. In 1890 he left to become a partner in a newly established firm, Leland, Faulconer \& Norton Company at Detroit, Michigan, designing and building machine tools. He withdrew from this firm in 1895 and practised as a consulting mechanical engineer for a short time before returning to Brown \& Sharpe in 1896. There he designed a grinding machine incorporating larger and wider grinding wheels so that heavier cuts could be made to meet the needs of the mass-production industries, especially the automobile industry. This required a heavier and more rigid machine and greater power, but these ideas were not welcomed at Brown \& Sharpe and in 1900 Norton left to found the Norton Grinding Company in Worcester, Massachusetts. Here he was able to develop heavy-production grinding machines, including special machines for grinding crank-shafts and camshafts for the automobile industry.In setting up the Norton Grinding Company, Charles H.Norton received financial support from members of the Norton Emery Wheel Company (also of Worcester and known after 1906 as the Norton Company), but he was not related to the founder of that company. The two firms were completely independent until 1919 when they were merged. From that time Charles H.Norton served as Chief Engineer of the machinery division of the Norton Company, until 1934 when he became their Consulting Engineer.[br]Principal Honours and DistinctionsCity of Philadelphia, John Scott Medal 1925.BibliographyNorton was granted more than one hundred patents and was author of Principles of Cylindrical Grinding, 1917, 1921, Worcester, Mass.Further ReadingRobert S.Woodbury, 1959, History of the Grinding Machine, Cambridge, Mass, (contains biographical information and details of the machines designed by Norton).RTSBiographical history of technology > Norton, Charles Hotchkiss
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123 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 -
124 piston
поршень (рис. 3); плунжер (рис. 144,7) ; пистон; шток поршня; ныряло; клапан; нфт. плавающая (понтонная) крыша резервуара - piston action - piston-actuated - piston actuated clutch - piston-actuated pressure switch - piston actuator - piston-air drill - piston air valve - piston alloy - piston-and-valve arrangement - piston area - piston attenuator - piston barrel - piston base plate - piston bearing - piston cam plate - piston cooling jet - piston cooling valve - piston core - piston crucible growth - piston cylinder - piston-cylinder assembly - piston damper - piston drill - piston-face area - piston force - piston face - piston filler - piston filling machine - piston flow - piston follower - piston groove - piston hydropneumatic accumulator - piston-in-cylinder clearance - piston knocking - piston-like - piston manometer - piston manufacturing line - piston meter - piston mirror - piston motor - piston nut - piston oil ring rails - piston-operated spool valve - piston operated valve - piston pin boss - piston pin circlip - piston pin drift - piston pin end cap - piston pin knock - piston pin lock ring - piston pin locking screw - piston pin set screw - piston pin with taper bore - piston play - piston ported engine - piston pressure - piston pressure gage - piston pressure gauge - piston puller - piston pull scale - piston pump - piston pump with cam drive - piston relief valve - piston-ring carrier - piston ring casting - piston-ring clamp - piston ring expander - piston ring gap in bore - piston ring grinding machine - piston ring groove - piston ring joint - piston ring side clearance - piston ring slot - piston-ring spreader - piston ring sticking - piston-ring tension - piston-ring width - piston rod - piston rod end - piston scaler - piston seal - piston seizure - piston separator - piston shoe - piston side thrust - piston skirt - piston skirt clearance - piston skirt expander - piston slap - piston slipper - piston speed - piston sticking - piston stripping - piston stroke - piston-suction sampler - piston supercharger - piston support washer - piston-swept volume - piston throttle - piston thrust - piston-to-head clearance - piston-to-wall clearance - piston top - piston travel - piston-turning lathe - piston-turning machine - piston-type compressor - piston-type damper - piston-type drill - piston-type pump - piston-type relief device - piston-type unit - piston valve - piston valve cylinder - piston varnish rating - piston with slipper - piston with struts - piston wrench - buffer piston - cast piston - choke piston - close-fitting piston - compensating piston - contact piston - contractor piston - control piston - dividing piston - dome-head piston - double-acting piston - dual area piston - flat-crown piston - forged piston - free piston - ground-in piston - high-pressure piston - hollow piston - hammer piston - intensifier piston - intermediate piston - lubricator piston - magnetic piston - mud piston - operating piston - pent crown piston - plunger piston - pot-type piston - pressure piston - pump piston - raised-crown piston - ramming piston - reaction piston - reciprocating piston - ribbed piston - rotary piston - rubber piston - sand piston - secondary piston - seized piston - seizing of piston rings - separating piston - shock absorber piston - short-circuiting piston - single-rod piston - skeleton-skirt piston - slack piston - sliding piston - slipper piston - slit-skirt piston - solid piston - spherical head piston - split piston - split skirt piston - standard piston - steel piston - steel-belted piston - steel-strut piston - step-head piston - step piston - stepped piston - sticking of piston rings - stock piston - strut-type piston - supported piston - suspended piston - T-slot piston - trunk piston - trunk-type piston - two-diameter piston - two-piece piston - U-slot piston - unsuspended piston - valve piston - vertical slot piston - waveguide piston -
125 Spencer, Christopher Miner
[br]b. 10 June 1833 Manchester, Connecticut, USAd. 14 January 1922 Hartford, Connecticut, USA[br]American mechanical engineer and inventor.[br]Christopher M.Spencer served an apprenticeship from 1847 to 1849 in the machine shop at the silk mills of Cheney Brothers in his native town and remained there for a few years as a journeyman machinist. In 1853 he went to Rochester, New York, to obtain experience with machinery other than that used in the textile industry. He then spent some years with the Colt Armory at Hartford, Connecticut, before returning to Cheney Brothers, where he obtained his first patent, which was for a silk-winding machine.Spencer had long been interested in firearms and in 1860 he obtained a patent for a repeating rifle. The Spencer Repeating Rifle Company was organized for its manufacture, and before the end of the American Civil War about 200,000 rifles had been produced. He patented a number of other improvements in firearms and in 1868 was associated with Charles E.Billings (1835–1920) in the Roper Arms Company, set up at Amherst, Massachusetts, to manufacture Spencer's magazine gun. This was not a success, however, and in 1869 they moved to Hartford, Connecticut, and formed the Billings \& Spencer Company. There they developed the technology of the drop hammer and Spencer continued his inventive work, which included an automatic turret lathe for producing metal screws. The patent that he obtained for this in 1873 inexplicably failed to protect the essential feature of the machine which provided the automatic action, with the result that Spencer received no patent right on the most valuable feature of the machine.In 1874 Spencer withdrew from active connection with Billings \& Spencer, although he remained a director, and in 1876 he formed with others the Hartford Machine Screw Company. However, he withdrew in 1882 to form the Spencer Arms Company at Windsor, Connecticut, for the manufacture of another of his inventions, a repeating shotgun. But this company failed and Spencer returned to the field of automatic lathes, and in 1893 he organized the Spencer Automatic Machine Screw Company at Windsor, where he remained until his retirement.[br]Further ReadingJ.W.Roe, 1916, English and American Tool Builders, New Haven; reprinted 1926, New York, and 1987, Bradley, Ill. (briefly describes his career and his automatic lathes).L.T.C.Rolt, 1965, Tools for the Job, London; repub. 1986 (gives a brief description of Spencer's automatic lathes).RTSBiographical history of technology > Spencer, Christopher Miner
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126 tool
1) инструмент
2) инструментальный
3) рабочий орган
4) резцовой
5) резцовый
6) орудие
7) средство
8) снаряд
9) приспособление
– abrasive tool
– beating tool
– bench tool
– bending tool
– blacksmith's tool
– blanking tool
– book-binding tool
– boring tool
– cemented-carbide tool
– cermet tool
– chain tool
– chasing tool
– clamping tool
– compression tool
– currier's tool
– cutting tool
– diamond tool
– erection tool
– finishing tool
– firing tool
– forge tool
– furnace tool
– grind a tool
– hand tool
– hard-tipped tool
– heated tool
– impact tool
– inspection tool
– ironing tool
– lapping tool
– lathe tool
– machine tool
– machining tool
– marking tool
– measuring tool
– molder tool
– pneumatic tool
– point tool
– polishing tool
– power tool
– precision tool
– profiling tool
– rack-tooth tool
– safety tool
– spinning tool
– thread-cutting tool
– thread-rolling tool
– tinning tool
– tool angle
– tool bag
– tool bit holder
– tool carrier
– tool crib
– tool head
– tool holder
– tool joint
– tool kit
– tool man
– tool material
– tool nose
– tool offset
– tool setter-up
– tool shop
– tool slide
– tool steel
– tool stock
– tool tray
– tool up
– universal tool
electric-erosion tool grinding — электроискровое затачивание
message tool service — международная служба передачи сообщений
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127 cell
1) гибкий производственный модуль, ГПМ2) гибкая производственная ячейка, ГПЯ4) камера; секция; ячейка5) элемент, гальванический элемент•- automated manufacturing cell
- automated turning cell
- automated work cell
- circular sawing cell
- CNC machining center cell
- combined cell
- complex part cell
- component cells
- computer-controlled cell
- computer-driven cell
- counter cell
- crankshaft cell
- creep feed cell
- damped cell
- design-to-manufacturing cell
- desired-value cell
- dew cell
- discrete cell
- DNC flexible machining cell
- drilling cell
- dry cell
- dual-robot cell
- duplex machining cell
- EDM FMS cell
- electrical discharge machining cell
- electrochemical cell
- electrochemical machining cell
- emission cell
- extrusion trim cell
- family-of-parts manufacturing cell
- FFS cell
- final machining cell
- fir-tree grinding cell
- fir-tree milling cell
- flexible assembly cell
- flexible bending cell
- flexible drilling-and-milling manufacturing cell
- flexible fabricating cell
- flexible machining cell
- flexible manufacturing cell
- flexible production cell
- flexible turning cell
- FMS sheet metal cell
- FMT cell
- focused-layout cell
- force load cell
- forming cell
- gear hobbing cell
- gear manufacturing cell
- gear shaping cell
- grinding cell
- group technology cell
- group technology-based cell
- GT cell
- heat-treatment cell
- HMC cell
- honing cell
- horizontal machining cell
- inspection cell
- integrated cell
- integrated turning cells
- lathe cell
- lathe machining cell
- light-sensitive cell
- limited-manned cell
- load cell
- machine tool cell
- machining cell
- machining-center cell
- magnetic cell
- manned cell
- manufacturing cell
- measuring cell
- memory cell
- metalforming production cell
- milling and boring cell
- milling cell
- minimum manned cell
- mixed GT cell
- modular FMS cell
- multiaxis cell
- multirobot cell
- NC cell
- NC machine tool cell
- near-term cell
- noise testing cell
- one-machine cell
- on-line inspection cell
- operating cell
- opposed-spindle turning cell
- optimum work cell
- palletizing cell
- partially-manned flexible machining cell
- part-processing cell
- part-washing cell
- photoconductive cell
- photovoltaic cell
- piezoelectric crystal-type load cell
- pilot cell
- pneumatic cell
- position-sensitive photoelectric cell
- pressure cell
- processing cell
- production cell
- rechargeable cell
- reverse-engineering cell
- RGV-served cell
- robot-controlled machining cell
- robotic assembly cell
- robotic cell
- robotic machining cell
- robotic work cell
- robot-integrated cell
- robotized measuring cell
- robot-loaded cell
- robot-welding cell
- sandwiched liquid crystal cell
- sawing cell
- sealant cell
- secondary cell
- self-contained machining cell
- self-sufficient cell
- semimanned cell
- shallow-junction solar cells
- sheet-metal cell
- single-machine cell
- single-manufacturing cell
- spur helical bevel gear cell
- stand-alone cell
- standard cell
- storage cell
- store cell
- strain-gage load cell
- superconductor memory cell
- target cell
- test cell
- testing cell
- thermoelectric cell
- three-core cell
- three-unit flexible manufacturing cell
- time cell
- total parts-processing cell
- turned parts cell
- turning cell
- turning/milling cell
- two-machining-center cell
- two-unit flexible manufacturing cell
- unattended machining cell
- unattended production cell
- unmanned machining cell
- unmanned production cell
- versatile machining cell
- versatile manufacturing cell
- vertical internal milling machine cell
- VMC cell
- work cellEnglish-Russian dictionary of mechanical engineering and automation > cell
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128 control
1) управление; регулирование || управлять; регулировать2) контроль || контролировать3) управляющее устройство; устройство управления; регулятор4) профессиональное мастерство, квалификация, техническая квалификация5) pl органы управления•"in control" — "в поле допуска" ( о результатах измерения)
to control closed loop — управлять в замкнутой системе; регулировать в замкнутой системе
- 2-handed controlsto control open loop — управлять в разомкнутой системе; регулировать в разомкнутой системе
- 32-bit CPU control
- acceptance control
- access control
- acknowledge control
- active process control
- adaptable control
- adaptive constraint control
- adaptive control for optimization
- adaptive control
- adaptive feed rate control
- adaptive quality control
- adjustable feed control
- adjustable rotary control
- adjustable speed control
- adjusting control
- adjustment control
- AI control
- air logic control
- analog data distribution and control
- analogical control
- analytical control
- application control
- arrows-on-curves control
- autodepth control
- autofeed control
- automated control of a document management system
- automated technical control
- automatic backlash control
- automatic control
- automatic editing control
- automatic gain control
- automatic gripper control
- automatic level control
- automatic process closed loop control
- automatic remote control
- automatic sensitivity control
- automatic sequence control
- automatic speed control
- automatic stability controls
- auxiliaries control
- balanced controls
- band width control
- bang-bang control
- bang-bang-off control
- basic CNC control
- batch control
- bibliographic control
- bin level control
- boost control
- built-in control
- button control
- cam control
- cam throttle control
- camshaft control
- carriage control
- Cartesian path control
- Cartesian space control
- cascade control
- C-axis spindle control
- cell control
- center control
- central control
- central supervisory control
- centralized control
- centralized electronic control
- central-station control
- changeover control
- chip control
- circumferential register control
- close control
- closed cycle control
- closed loop control
- closed loop machine control
- closed loop manual control
- closed loop numerical control
- closed loop position control
- clutch control
- CNC control
- CNC indexer control
- CNC programmable control
- CNC symbolic conversational control
- CNC/CRT control
- CNC/MDI control
- coarse control
- coded current control
- coded current remote control
- color control
- combination control
- command-line control
- compensatory control
- composition control
- compound control
- computed-current control
- computed-torque control
- computer control
- computer numerical control
- computer process control
- computer-aided measurement and control
- computer-integrated manufacturing control
- computerized control
- computerized numerical control
- computerized process control
- constant surface speed control
- constant value control
- contactless control
- contact-sensing control
- contamination control
- continuous control
- continuous path control
- continuous process control
- contour profile control
- contouring control
- conventional hardware control
- conventional numerical control
- conventional tape control
- convergent control
- conversational control
- conversational MDI control
- coordinate positioning control
- coordinate programmable control
- copymill control
- counter control
- crossed controls
- current control
- cycle control
- dash control
- data link control
- data storage control
- deadman's handle controls
- depth control
- derivative control
- dial-in control
- differential control
- differential gaging control
- differential gain control
- differential temperature control
- digital brushless servo control
- digital control
- digital position control
- digital readout controls
- dimensional control
- direct computer control
- direct control
- direct digital control
- direct numerical control
- direction control
- directional control
- dirt control
- discontinuous control
- discrete control
- discrete event control
- discrete logic controls
- dispatching control
- displacement control
- distance control
- distant control
- distributed control
- distributed numerical control
- distributed zone control
- distribution control
- dog control
- drum control
- dual control
- dual-mode control
- duplex control
- dust control
- dynamic control
- eccentric control
- edge position control
- EDP control
- electrical control
- electrofluidic control
- electromagnetic control
- electronic control
- electronic level control
- electronic speed control
- electronic swivel control
- elevating control
- emergency control
- end-point control
- engineering change control
- engineering control
- entity control
- environmental control
- error control
- error plus error-rate control
- error-free control
- external beam control
- factory-floor control
- false control
- feed control
- feed drive controls
- feedback control
- feed-forward control
- field control
- fine control
- finger-tip control
- firm-wired numerical control
- fixed control
- fixed-feature control
- fixture-and-tool control
- flexible-body control
- floating control
- flow control
- fluid flow control
- follow-up control
- foot pedal control
- force adaptive control
- forecasting compensatory control
- fork control
- four quadrant control
- freely programmable CNC control
- frequency control
- FROG control
- full computer control
- full order control
- full spindle control
- gage measurement control
- gain control
- ganged control
- gap control
- gear control
- generative numerical control
- generic path control
- geometric adaptive control
- graphic numerical control
- group control
- grouped control
- guidance control
- hairbreath control
- hand control
- hand feed control
- hand wheel control
- hand-held controls
- handle-type control
- hand-operated controls
- hardened computer control
- hardwared control
- hardwared numerical control
- heating control
- heterarchical control
- hierarchical control
- high-integrity control
- high-level robot control
- high-low control
- high-low level control
- high-technology control
- horizontal directional control
- humidity control
- hybrid control
- hydraulic control
- I/O control
- immediate postprocess control
- inching control
- in-cycle control
- independent control
- indexer control
- indirect control
- individual control
- industrial processing control
- industrial-style controls
- infinite control
- infinite speed control
- in-process control
- in-process size control
- in-process size diameters control
- input/output control
- integral CNC control
- integral control
- integrated control
- intelligent control
- interacting control
- interconnected controls
- interlinking control
- inventory control
- job control
- jogging control
- joint control
- joystick control
- just-in-time control
- language-based control
- laser health hazards control
- latching control
- lead control
- learning control
- lever control
- lever-operated control
- line motion control
- linear control
- linear path control
- linearity control
- load control
- load-frequency control
- local control
- local-area control
- logic control
- lubricating oil level control
- machine control
- machine programming control
- machine shop control
- macro control
- magnetic control
- magnetic tape control
- main computer control
- malfunction control
- management control
- manual control
- manual data input control
- manual stop control
- manually actuatable controls
- manufacturing change control
- manufacturing control
- master control
- material flow control
- MDI control
- measured response control
- mechanical control
- memory NC control
- memory-type control
- metering control
- metrological control of production field
- microbased control
- microcomputer CNC control
- microcomputer numerical control
- microcomputer-based sequence control
- microprocessor control
- microprocessor numerical control
- microprogrammed control
- microprogramming control
- milling control
- model reference adaptive control
- model-based control
- moisture control
- motion control
- motor control
- motor speed control
- mouse-driven control
- movable control
- multicircuit control
- multidiameter control
- multilevel control
- multimachine tool control
- multiple control
- multiple-processor control
- multiposition control
- multistep control
- multivariable control
- narrow-band proportional control
- navigation control
- NC control
- neural network adaptive control
- noise control
- noncorresponding control
- noninteracting control
- noninterfacing control
- nonreversable control
- nonsimultaneous control
- numerical contouring control
- numerical control
- numerical program control
- odd control
- off-line control
- oligarchical control
- on-board control
- one-axis point-to-point control
- one-dimensional point-to-point control
- on-line control
- on-off control
- open loop control
- open loop manual control
- open loop numerical control
- open-architecture control
- operating control
- operational control
- operator control
- optical pattern tracing control
- optimal control
- optimalizing control
- optimizing control
- oral numerical control
- organoleptic control
- overall control
- overheat control
- override control
- p. b. control
- palm control
- parameter adaptive control
- parameter adjustment control
- partial d.o.f. control
- path control
- pattern control
- pattern tracing control
- PC control
- PC-based control
- peg board control
- pendant control
- pendant-actuated control
- pendant-mounted control
- performance control
- photoelectric control
- physical alignment control
- PIC control
- PID control
- plugboard control
- plug-in control
- pneumatic control
- point-to-point control
- pose-to-pose control
- position/contouring numerical control
- position/force control
- positional control
- positioning control
- positive control
- postprocess quality control
- power adaptive control
- power control
- power feed control
- power-assisted control
- powered control
- power-operated control
- precision control
- predictor control
- preselective control
- preset control
- presetting control
- pressbutton control
- pressure control
- preview control
- process control
- process quality control
- production activity control
- production control
- production result control
- programmable adaptive control
- programmable cam control
- programmable control
- programmable logic adaptive control
- programmable logic control
- programmable machine control
- programmable microprocessor control
- programmable numerical control
- programmable sequence control
- proportional plus derivative control
- proportional plus floating control
- proportional plus integral control
- prototype control
- pulse control
- pulse duration control
- punched-tape control
- purpose-built control
- pushbutton control
- quality control
- radio remote control
- radium control
- rail-elevating control
- ram stroke control
- ram-positioning control
- rapid-traverse controls for the heads
- rate control
- ratio control
- reactive control
- real-time control
- reduced-order control
- register control
- registration control
- relay control
- relay-contactor control
- remote control
- remote program control
- remote switching control
- remote valve control
- remote-dispatch control
- resistance control
- resolved motion rate control
- retarded control
- reversal control
- revolution control
- rigid-body control
- robot control
- robot perimeter control
- robot teach control
- rod control
- safety control
- sampled-data control
- sampling control
- schedule control
- SCR's control
- second derivative control
- selective control
- selectivity control
- self-acting control
- self-adaptive control
- self-adjusting control
- self-aligning control
- self-operated control
- self-optimizing control
- self-programming microprocessor control
- semi-automatic control
- sensitivity control
- sensor-based control
- sequence control
- sequence-type control
- sequential control
- series-parallel control
- servo control
- servo speed control
- servomotor control
- servo-operated control
- set value control
- shaft speed control
- shape control
- shift control
- shop control
- shower and high-pressure oil temperature control
- shut off control
- sight control
- sign control
- single variable control
- single-flank control
- single-lever control
- size control
- slide control
- smooth control
- software-based NC control
- softwared numerical control
- solid-state logic control
- space-follow-up control
- speed control
- stabilizing control
- stable control
- standalone control
- start controls
- static control
- station control
- statistical quality control
- steering control
- step-by-step control
- stepless control
- stepped control
- stick control
- stock control
- stop controls
- stop-point control
- storage assignment control
- straight cut control
- straight line control
- stroke control
- stroke length control
- supervisor production control
- supervisory control
- swarf control
- switch control
- symbolic control
- synchronous data link control
- table control
- tap-depth controls
- tape control
- tape loop control
- teach controls
- temperature control
- temperature-humidity air control
- template control
- tension control
- test control
- thermal control
- thermostatic control
- three-axis contouring control
- three-axis point-to-point control
- three-axis tape control
- three-mode control
- three-position control
- throttle control
- thumbwheel control
- time control
- time cycle control
- time optimal control
- time variable control
- time-critical control
- time-proportional control
- timing control
- token-passing access control
- tool life control
- tool run-time control
- torque control
- total quality control
- touch-panel NC control
- touch-screen control
- tracer control
- tracer numerical control
- trajectory control
- triac control
- trip-dog control
- TRS/rate control
- tuning control
- turnstile control
- two-axis contouring control
- two-axis point-to-point control
- two-dimension control
- two-hand controls
- two-position control
- two-position differential gap control
- two-step control
- undamped control
- user-adjustable override controls
- user-programmable NC control
- variable flow control
- variable speed control
- variety control
- varying voltage control
- velocity-based look-ahead control
- vise control
- vision responsive control
- visual control
- vocabulary control
- vocal CNC control
- vocal numerical control
- voltage control
- warehouse control
- washdown control
- water-supply control
- welding control
- wheel control
- wide-band control
- zero set control
- zoned track controlEnglish-Russian dictionary of mechanical engineering and automation > control
См. также в других словарях:
pneumatic machine — pneumatinė mašina statusas T sritis fizika atitikmenys: angl. pneumatic machine vok. pneumatische Anlage, f rus. пневматическая машина, f pranc. machine pneumatique, f … Fizikos terminų žodynas
machine pneumatique — pneumatinė mašina statusas T sritis fizika atitikmenys: angl. pneumatic machine vok. pneumatische Anlage, f rus. пневматическая машина, f pranc. machine pneumatique, f … Fizikos terminų žodynas
Pneumatic — Pneu*mat ic, Pneumatical Pneu*mat ic*al, a. [L. pneumaticus, Gr. ?, fr. ?, ?, wind, air, ? to blow, breathe; cf. OHG. fnehan: cf. F. pneumatique. Cf. {Pneumonia}.] 1. Consisting of, or resembling, air; having the properties of an elastic fluid;… … The Collaborative International Dictionary of English
Pneumatic action — Pneumatic Pneu*mat ic, Pneumatical Pneu*mat ic*al, a. [L. pneumaticus, Gr. ?, fr. ?, ?, wind, air, ? to blow, breathe; cf. OHG. fnehan: cf. F. pneumatique. Cf. {Pneumonia}.] 1. Consisting of, or resembling, air; having the properties of an… … The Collaborative International Dictionary of English
Pneumatic dispatch — Pneumatic Pneu*mat ic, Pneumatical Pneu*mat ic*al, a. [L. pneumaticus, Gr. ?, fr. ?, ?, wind, air, ? to blow, breathe; cf. OHG. fnehan: cf. F. pneumatique. Cf. {Pneumonia}.] 1. Consisting of, or resembling, air; having the properties of an… … The Collaborative International Dictionary of English
Pneumatic elevator — Pneumatic Pneu*mat ic, Pneumatical Pneu*mat ic*al, a. [L. pneumaticus, Gr. ?, fr. ?, ?, wind, air, ? to blow, breathe; cf. OHG. fnehan: cf. F. pneumatique. Cf. {Pneumonia}.] 1. Consisting of, or resembling, air; having the properties of an… … The Collaborative International Dictionary of English
Pneumatic lever — Pneumatic Pneu*mat ic, Pneumatical Pneu*mat ic*al, a. [L. pneumaticus, Gr. ?, fr. ?, ?, wind, air, ? to blow, breathe; cf. OHG. fnehan: cf. F. pneumatique. Cf. {Pneumonia}.] 1. Consisting of, or resembling, air; having the properties of an… … The Collaborative International Dictionary of English
Pneumatic pile — Pneumatic Pneu*mat ic, Pneumatical Pneu*mat ic*al, a. [L. pneumaticus, Gr. ?, fr. ?, ?, wind, air, ? to blow, breathe; cf. OHG. fnehan: cf. F. pneumatique. Cf. {Pneumonia}.] 1. Consisting of, or resembling, air; having the properties of an… … The Collaborative International Dictionary of English
Pneumatic pump — Pneumatic Pneu*mat ic, Pneumatical Pneu*mat ic*al, a. [L. pneumaticus, Gr. ?, fr. ?, ?, wind, air, ? to blow, breathe; cf. OHG. fnehan: cf. F. pneumatique. Cf. {Pneumonia}.] 1. Consisting of, or resembling, air; having the properties of an… … The Collaborative International Dictionary of English
Pneumatic railway — Pneumatic Pneu*mat ic, Pneumatical Pneu*mat ic*al, a. [L. pneumaticus, Gr. ?, fr. ?, ?, wind, air, ? to blow, breathe; cf. OHG. fnehan: cf. F. pneumatique. Cf. {Pneumonia}.] 1. Consisting of, or resembling, air; having the properties of an… … The Collaborative International Dictionary of English
Pneumatic syringe — Pneumatic Pneu*mat ic, Pneumatical Pneu*mat ic*al, a. [L. pneumaticus, Gr. ?, fr. ?, ?, wind, air, ? to blow, breathe; cf. OHG. fnehan: cf. F. pneumatique. Cf. {Pneumonia}.] 1. Consisting of, or resembling, air; having the properties of an… … The Collaborative International Dictionary of English