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1 commercially produced instrument
Большой англо-русский и русско-английский словарь > commercially produced instrument
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2 commercially produced instrument
1) Техника: серийное средство измерений, серийный измерительный прибор2) Метрология: серийный приборУниверсальный англо-русский словарь > commercially produced instrument
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3 instrument
1) метр. средство измерений3) инструмент; инструментальное средство•instrument calibrated in logarithmic steps — прибор с логарифмической шкалой;instrument labeled with... — прибор, отградуированный в...;to check an instrument — 1. проверять исправность прибора 2. поверять прибор;to read an instrument — снимать показания прибора-
absolute instrument
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ac instrument
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accepted instrument
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accessory instrument
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ac-dc instrument
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active-measuring instrument
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active instrument
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airborne instrument
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airspeed instrument
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all-solid state instrument
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analog instrument
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angular instrument
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aperiodic instrument
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astatic instrument
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aviation instruments
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batch-type instrument
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battery-operated instrument
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bench-top instrument
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bench instrument
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bore measuring instrument
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Bragg instrument
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calibrating instrument
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center-zero instrument
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certified instrument
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chart-recording instrument
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colorimetric instrument
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commercially produced instrument
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commercial instrument
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comparative instrument
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contactless instrument
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contact-type instrument
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continuously reading instrument
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crossed-field instrument
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cross-field instrument
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cross-coil instrument
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D'Arsonval instrument
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dc instrument
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dead-beat instrument
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deflection instrument
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diagnostic test instrument
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dial instrument
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digital instrument
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direct-acting instrument
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direct-reading instrument
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distant-indicating instrument
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downhole instrument
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draught instrument
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drawing instrument
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dropwindsonde instrument
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echo-sounding instrument
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edgewise instrument
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electric staff instrument
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electrically measuring instrument
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electrical measuring instrument
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electrical-type instrument
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electrodynamic instrument
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electromagnetic instrument
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electronic instrument
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electrostatic instrument
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end instrument
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extended-range instrument
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ferrodynamic instrument
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ferromagnetic instrument
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fluidic instrument
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flush-type instrument
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go-devil instrument
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grading instrument
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graphic instrument
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grating instrument
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hardness measuring instrument
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health-monitoring instrument
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hook-on instrument
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hot-wire instrument
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humidity control instrument
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indicating instrument
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induction-type instrument
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induction instrument
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integrating instrument
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iron-cored type instrument
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iron-cored instrument
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laboratory instrument
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leveling instrument
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light-beam instrument
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lighting instrument
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light-spot instrument
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linear-measuring instrument
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line-powered instrument
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loop-forming instruments
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mains-operated instrument
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manual-balance instrument
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measuring instrument
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mine-surveying instrument
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monitoring instrument
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moored instrument
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motion picture instrument
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moving-coil instrument
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moving-iron instrument
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moving-magnet instrument
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multimeter instrument
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multiple-range instrument
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noncontact instrument
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null-indicating instrument
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numerical-reading instrument
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optical instrument
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passive-measuring instrument
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passive instrument
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permanent-magnet moving-iron instrument
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pH instrument
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photoelectrical instrument
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photoelectric instrument
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plunger-type instrument
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pointer-and-scale instrument
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polarized-vane instrument
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portable instrument
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presetting instrument
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primary instrument
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printing instrument
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production control instrument
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programmable instrument
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projected-moving-pointer instrument
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projection instrument
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rack-mounted instrument
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rack-mount instrument
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recording instrument
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rectifier-type instrument
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rectifier instrument
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reference instrument
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registering instrument
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remote-reading instrument
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remote-sensing instrument
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robust instrument
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sampling instrument
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schlieren instrument
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Schopper-Rieger instrument
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self-calibrating instrument
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self-contained instrument
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sensing instrument
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service measuring instrument
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shadow column instrument
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shop floor measuring instrument
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shop measuring instrument
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signal-tracing instrument
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solar radiation instrument
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solid-state instrument
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sonic depth-finding instrument
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sound editing instrument
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spaceborne instrument
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speed measuring instrument
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standard instrument
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standardizing instrument
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stylus instrument
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summation instrument
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suppressed-zero instrument
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surveying instrument
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survey instrument
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switchboard instrument
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tabletop instrument
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test instrument
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thermal instrument
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thermistor instrument
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thermocouple-type instrument
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thermocouple instrument
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token instrument
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tower instrument
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track instrument
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transfer instrument
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transfer quality instrument
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transient instrument
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troubleshooting instrument
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ultrasonic instrument
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verifiable instrument
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verifying instrument
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vibrating-reed instrument
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viewing instrument
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visual instrument
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warning instrument
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well surveying instrument
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wireline instrument
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working measuring instrument
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zero instrument
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zero-center instrument -
4 серийное средство измерений
Engineering: commercial instrument, commercially produced instrumentУниверсальный русско-английский словарь > серийное средство измерений
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5 серийный измерительный прибор
Engineering: commercial instrument, commercially produced instrumentУниверсальный русско-английский словарь > серийный измерительный прибор
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6 серийный прибор
1) Engineering: off-the-shelf device2) Metrology: commercially produced instrument -
7 Weston, Edward
SUBJECT AREA: Electricity[br]b. 9 May 1850 Oswestry, Englandd. 20 August 1936 Montclair, New Jersey, USA[br]English (naturalized American) inventor noted for his contribution to the technology of electrical measurements.[br]Although he developed dynamos for electroplating and lighting, Weston's major contribution to technology was his invention of a moving-coil voltmeter and the standard cell which bears his name. After some years as a medical student, during which he gained a knowledge of chemistry, he abandoned his studies. Emigrating to New York in 1870, he was employed by a manufacturer of photographic chemicals. There followed a period with an electroplating company during which he built his first dynamo. In 1877 some business associates financed a company to build these machines and, later, arc-lighting equipment. By 1882 the Weston Company had been absorbed into the United States Electric Lighting Company, which had a counterpart in Britain, the Maxim Weston Company. By the time Weston resigned from the company, in 1886, he had been granted 186 patents. He then began the work in which he made his greatest contribution, the science of electrical measurement.The Weston meter, the first successful portable measuring instrument with a pivoted coil, was made in 1886. By careful arrangement of the magnet, coil and control springs, he achieved a design with a well-damped movement, which retained its calibration. These instruments were produced commercially on a large scale and the moving-coil principle was soon adopted by many manufacturers. In 1892 he invented manganin, an alloy with a small negative temperature coefficient, for use as resistances in his voltmeters.The Weston standard cell was invented in 1892. Using his chemical knowledge he produced a cell, based on mercury and cadmium, which replaced the Clark cell as a voltage reference source. The Weston cell became the recognized standard at the International Conference on Electrical Units and Standards held in London in 1908.[br]Principal Honours and DistinctionsPresident, AIEE 1888–9. Franklin Institute Elliott Cresson Medal 1910, Franklin medal 1924.Bibliography29 April 1890, British patent no. 6,569 (the Weston moving-coil instrument). 6 February 1892, British patent no. 22,482 (the Weston standard cell).Further ReadingD.O.Woodbury, 1949, A Measure of Greatness. A Short Biography of Edward Weston, New York (a detailed account).C.N.Brown, 1988, in Proceedings of the Meeting on the History of Electrical Engineering, IEE, 17–21 (describes Weston's meter).H.C.Passer, 1953, The Electrical Manufacturers: 1875–1900, Cambridge, Mass.GW -
8 Siemens, Dr Ernst Werner von
[br]b. 13 December 1816 Lenthe, near Hanover, Germanyd. 6 December 1892 Berlin, Germany[br]German pioneer of the dynamo, builder of the first electric railway.[br]Werner von Siemens was the eldest of a large family and after the early death of his parents took his place at its head. He served in the Prussian artillery, being commissioned in 1839, after which he devoted himself to the study of chemistry and physics. In 1847 Siemens and J.G. Halske formed a company, Telegraphen-Bauanstalt von Siemens und Halske, to manufacture a dial telegraph which they had developed from an earlier instrument produced by Charles Wheatstone. In 1848 Siemens obtained his discharge from the army and he and Halske constructed the first long-distance telegraph line on the European continent, between Berlin and Frankfurt am Main.Werner von Siemens's younger brother, William Siemens, had settled in Britain in 1844 and was appointed agent for the Siemens \& Halske company in 1851. Later, an English subsidiary company was formed, known from 1865 as Siemens Brothers. It specialized in manufacturing and laying submarine telegraph cables: the specialist cable-laying ship Faraday, launched for the purpose in 1874, was the prototype of later cable ships and in 1874–5 laid the first cable to run direct from the British Isles to the USA. In charge of Siemens Brothers was another brother, Carl, who had earlier established a telegraph network in Russia.In 1866 Werner von Siemens demonstrated the principle of the dynamo in Germany, but it took until 1878 to develop dynamos and electric motors to the point at which they could be produced commercially. The following year, 1879, Werner von Siemens built the first electric railway, and operated it at the Berlin Trades Exhibition. It comprised an oval line, 300 m (985 it) long, with a track gauge of 1 m (3 ft 3 1/2 in.); upon this a small locomotive hauled three small passenger coaches. The locomotive drew current at 150 volts from a third rail between the running rails, through which it was returned. In four months, more than 80,000 passengers were carried. The railway was subsequently demonstrated in Brussels, and in London, in 1881. That same year Siemens built a permanent electric tramway, 1 1/2 miles (2 1/2 km) long, on the outskirts of Berlin. In 1882 in Berlin he tried out a railless electric vehicle which drew electricity from a two-wire overhead line: this was the ancestor of the trolleybus.In the British Isles, an Act of Parliament was obtained in 1880 for the Giant's Causeway Railway in Ireland with powers to work it by "animal, mechanical or electrical power"; although Siemens Brothers were electrical engineers to the company, of which William Siemens was a director, delays in construction were to mean that the first railway in the British Isles to operate regular services by electricity was that of Magnus Volk.[br]Principal Honours and DistinctionsHonorary doctorate, Berlin University 1860. Ennobled by Kaiser Friedrich III 1880, after which he became known as von Siemens.Further ReadingS.von Weiher, 1972, "The Siemens brothers, pioneers of the electrical age in Europe", Transactions of the Newcomen Society 45 (describes the Siemens's careers). C.E.Lee, 1979, The birth of electric traction', Railway Magazine (May) (describes Werner Siemens's introduction of the electric railway).Transactions of the Newcomen Society (1979) 50: 82–3 (describes Siemens's and Halske's early electric telegraph instruments).Transactions of the Newcomen Society (1961) 33: 93 (describes the railless electric vehicle).PJGRBiographical history of technology > Siemens, Dr Ernst Werner von
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9 Chevenard, Pierre Antoine Jean Sylvestre
SUBJECT AREA: Metallurgy[br]b. 31 December 1888 Thizy, Rhône, Franced. 15 August 1960 Fontenoy-aux-Roses, France[br]French metallurgist, inventor of the alloys Elinvar and Platinite and of the method of strengthening nickel-chromium alloys by a precipitate ofNi3Al which provided the basis of all later super-alloy development.[br]Soon after graduating from the Ecole des Mines at St-Etienne in 1910, Chevenard joined the Société de Commentry Fourchambault et Decazeville at their steelworks at Imphy, where he remained for the whole of his career. Imphy had for some years specialized in the production of nickel steels. From this venture emerged the first austenitic nickel-chromium steel, containing 6 per cent chromium and 22–4 per cent nickel and produced commercially in 1895. Most of the alloys required by Guillaume in his search for the low-expansion alloy Invar were made at Imphy. At the Imphy Research Laboratory, established in 1911, Chevenard conducted research into the development of specialized nickel-based alloys. His first success followed from an observation that some of the ferro-nickels were free from the low-temperature brittleness exhibited by conventional steels. To satisfy the technical requirements of Georges Claude, the French cryogenic pioneer, Chevenard was then able in 1912 to develop an alloy containing 55–60 per cent nickel, 1–3 per cent manganese and 0.2–0.4 per cent carbon. This was ductile down to −190°C, at which temperature carbon steel was very brittle.By 1916 Elinvar, a nickel-iron-chromium alloy with an elastic modulus that did not vary appreciably with changes in ambient temperature, had been identified. This found extensive use in horology and instrument manufacture, and even for the production of high-quality tuning forks. Another very popular alloy was Platinite, which had the same coefficient of thermal expansion as platinum and soda glass. It was used in considerable quantities by incandescent-lamp manufacturers for lead-in wires. Other materials developed by Chevenard at this stage to satisfy the requirements of the electrical industry included resistance alloys, base-metal thermocouple combinations, magnetically soft high-permeability alloys, and nickel-aluminium permanent magnet steels of very high coercivity which greatly improved the power and reliability of car magnetos. Thermostatic bimetals of all varieties soon became an important branch of manufacture at Imphy.During the remainder of his career at Imphy, Chevenard brilliantly elaborated the work on nickel-chromium-tungsten alloys to make stronger pressure vessels for the Haber and other chemical processes. Another famous alloy that he developed, ATV, contained 35 per cent nickel and 11 per cent chromium and was free from the problem of stress-induced cracking in steam that had hitherto inhibited the development of high-power steam turbines. Between 1912 and 1917, Chevenard recognized the harmful effects of traces of carbon on this type of alloy, and in the immediate postwar years he found efficient methods of scavenging the residual carbon by controlled additions of reactive metals. This led to the development of a range of stabilized austenitic stainless steels which were free from the problems of intercrystalline corrosion and weld decay that then caused so much difficulty to the manufacturers of chemical plant.Chevenard soon concluded that only the nickel-chromium system could provide a satisfactory basis for the subsequent development of high-temperature alloys. The first published reference to the strengthening of such materials by additions of aluminium and/or titanium occurs in his UK patent of 1929. This strengthening approach was adopted in the later wartime development in Britain of the Nimonic series of alloys, all of which depended for their high-temperature strength upon the precipitated compound Ni3Al.In 1936 he was studying the effect of what is now known as "thermal fatigue", which contributes to the eventual failure of both gas and steam turbines. He then published details of equipment for assessing the susceptibility of nickel-chromium alloys to this type of breakdown by a process of repeated quenching. Around this time he began to make systematic use of the thermo-gravimetrie balance for high-temperature oxidation studies.[br]Principal Honours and DistinctionsPresident, Société de Physique. Commandeur de la Légion d'honneur.Bibliography1929, Analyse dilatométrique des matériaux, with a preface be C.E.Guillaume, Paris: Dunod (still regarded as the definitive work on this subject).The Dictionary of Scientific Biography lists around thirty of his more important publications between 1914 and 1943.Further Reading"Chevenard, a great French metallurgist", 1960, Acier Fins (Spec.) 36:92–100.L.Valluz, 1961, "Notice sur les travaux de Pierre Chevenard, 1888–1960", Paris: Institut de France, Académie des Sciences.ASDBiographical history of technology > Chevenard, Pierre Antoine Jean Sylvestre
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10 Shortt, William Hamilton
SUBJECT AREA: Horology[br]b. 28 September 1881d. 4 February 1971[br]British railway engineer and amateur horologist who designed the first successful free-pendulum clock.[br]Shortt entered the Engineering Department of the London and South Western Railway as an engineering cadet in 1902, remaining with the company and its successors until he retired in 1946. He became interested in precision horology in 1908, when he designed an instrument for recording the speed of trains; this led to a long and fruitful collaboration with Frank HopeJones, the proprietor of the Synchronome Company. This association culminated in the installation of a free-pendulum clock, with an accuracy of the order of one second per year, at Edinburgh Observatory in 1921. The clock's performance was far better than that of existing clocks, such as the Riefler, and a slightly modified version was produced commercially by the Synchronome Company. These clocks provided the time standard at Greenwich and many other observatories and scientific institutions across the world until they were supplanted by the quartz clock.The period of a pendulum is constant if it swings freely with a constant amplitude in a vacuum. However, this ideal state cannot be achieved in a clock because the pendulum must be impulsed to maintain its amplitude and the swings have to be counted to indicate time. The free-pendulum clock is an attempt to approach this ideal as closely as possible. In 1898 R.J. Rudd used a slave clock, synchronized with a free pendulum, to time the impulses delivered to the free pendulum. This clock was not successful, but it provided the inspiration for Shortt's clock, which operates on the same principle. The Shortt clock used a standard Synchronome electric clock as the slave, and its pendulum was kept in step with the free pendulum by means of the "hit and miss" synchronizer that Shortt had patented in 1921. This allowed the pendulum to swing freely (in a vacuum), apart from the fraction of a second in which it received an impulse each half-minute.[br]Principal Honours and DistinctionsMaster of the Clockmakers' Company 1950. British Horological Society Gold Medal 1931. Clockmakers' Company Tompion Medal 1954. Franklin Institute John Price Wetherill Silver Medal.Bibliography1929, "Some experimental mechanisms, mechanical and otherwise, for the maintenance of vibration of a pendulum", Horological Journal 71:224–5.Further ReadingObituary, 1971, Proceedings of the Institution of Civil Engineers 56:396–7.F.Hope-Jones, 1949, Electrical Timekeeping, 2nd edn, London (a detailed but not entirely impartial account of the development of the free-pendulum clock).See also: Marrison, Warren AlvinDVBiographical history of technology > Shortt, William Hamilton
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