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61 corps
корпус ( соединение) ; род войск; служба; корпуснойCivil Support corps (US EUCOM) — гражданский корпус охраны тыловых объектов (ВС США в Европейской зоне)
US Marine corps, Women — женский контингент МП США
— AG corps— amphibious corps marine— QM corps -
62 Merz, Charles Hesterman
[br]b. 5 October 1874 Gateshead, Englandd. 14 October 1940 London, England[br]English engineer who pioneered large-scale integration of electricity-supply networks, which led to the inauguration of the British grid system.[br]Merz was educated at Bootham School in York and Armstrong College in Newcastle. He served an apprenticeship with the Newcastle Electric Supply Company at their first power station, Pandon Dene, and part of his training was at Robey and Company of Lincoln, steam engine builders, and the British Thomson-Houston Company, electrical equipment manufacturers. After working at Bankside in London and at Croydon, he became Manager of the Croydon supply undertaking. In 1898 he went to Cork on behalf of BTH to build and manage a tramway and electricity company. It was there that he met William McLellan, who later joined him in establishing a firm of consulting engineers. Merz, with his vision of large-scale electricity supply, pioneered an integrated traction and electricity scheme in north-eastern England. He was involved in the reorganization of electricity schemes in many countries and established a reputation as a leading parliamentary witness. Merz was appointed Director of Experiments and Research at the Admiralty, where his main contribution was the creation of an organization of outstanding engineers and scientists during the First World War. In 1925 he was largely responsible for a report of the Weir Committee which led to the Electricity (Supply) Act of 1926, the formation of the Central Electricity Board and the construction of the National Grid. The choice of 132 kV as the original grid voltage was that of Merz and his associates, as was the origin of the term "grid". Merz and his firm produced many technical innovations, including the first power-system control room and Merz-Price and Merz-Hunter forms of cable and transformer protection.[br]Principal Honours and DistinctionsInstitution of Electrical Engineers Faraday Medal 1931.Bibliography1903–4, with W.McLennan, "Power station design", Journal of the Institution of Electrical Engineers 33:696–742 (a classic on its subject).1929, "The national scheme of electricity supply in Great Britain", Proceedings of the British Association, Johannesburg.Further ReadingJ.Rowland, 1960, Progress in Power. The Contribution of Charles Merz and His Associates to Sixty Years of Electrical Development 1899–1959, London (the most detailed account).L.Hannah, 1979, Electricity Before Nationalisation, London.——, 1985, Dictionary of Business Biography, ed. J.Jeremy, London, pp. 221–7 (a short account).GWBiographical history of technology > Merz, Charles Hesterman
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63 Palmer, Henry Robinson
[br]b. 1795 Hackney, London, Englandd. 12 September 1844[br]English civil engineer and monorail pioneer.[br]Palmer was an assistant to Thomas Telford for ten years from 1816. In 1818 he arranged a meeting of young engineers from which the Institution of Civil Engineers originated. In the early 1820s he invented a monorail system, the first of its kind, in which a single rail of wood, with an iron strip spiked on top to form a running surface, was supported on posts. Wagon bodies were supported pannier fashion from a frame attached to grooved wheels and were propelled by men or horses. An important object was to minimize friction, and short lines were built on this principle at Deptford and Cheshunt. In 1826 Palmer was appointed Resident Engineer to the London Docks and was responsible for the construction of many of them. He was subsequently consulted about many important engineering works.[br]Principal Honours and DistinctionsFRS 1831. Vice-President, Institution of Civil Engineers.Bibliography1821, British patent no. 4,618 (monorail).1823, Description of a Railway on a New Principle…, London (describes his monorail).Further ReadingObituary, 1845, Minutes of Proceedings of the Institution of Civil Engineers 4. C.von Oeynhausen and H.von Dechen, 1971, Railways in England 1826 and 1827, London: Newcomen Society (a contemporary description of the monorails). M.J.T.Lewis, 1970, Early Wooden Railways, London: Routledge \& Kegan Paul.See also: Lartigue, Charles François Marie-ThérèsePJGR -
64 Preece, Sir William Henry
[br]b. 15 February 1834 Bryn Helen, Gwynedd, Walesd. 6 November 1913 Penrhos, Gwynedd, Wales[br]Welsh electrical engineer who greatly furthered the development and use of wireless telegraphy and the telephone in Britain, dominating British Post Office engineering during the last two decades of the nineteenth century.[br]After education at King's College, London, in 1852 Preece entered the office of Edwin Clark with the intention of becoming a civil engineer, but graduate studies at the Royal Institution under Faraday fired his enthusiasm for things electrical. His earliest work, as connected with telegraphy and in particular its application for securing the safe working of railways; in 1853 he obtained an appointment with the Electric and National Telegraph Company. In 1856 he became Superintendent of that company's southern district, but four years later he moved to telegraph work with the London and South West Railway. From 1858 to 1862 he was also Engineer to the Channel Islands Telegraph Company. When the various telegraph companies in Britain were transferred to the State in 1870, Preece became a Divisional Engineer in the General Post Office (GPO). Promotion followed in 1877, when he was appointed Chief Electrician to the Post Office. One of the first specimens of Bell's telephone was brought to England by Preece and exhibited at the British Association meeting in 1877. From 1892 to 1899 he served as Engineer-in-Chief to the Post Office. During this time he made a number of important contributions to telegraphy, including the use of water as part of telegraph circuits across the Solent (1882) and the Bristol Channel (1888). He also discovered the existence of inductive effects between parallel wires, and with Fleming showed that a current (thermionic) flowed between the hot filament and a cold conductor in an incandescent lamp.Preece was distinguished by his administrative ability, some scientific insight, considerable engineering intuition and immense energy. He held erroneous views about telephone transmission and, not accepting the work of Oliver Heaviside, made many errors when planning trunk circuits. Prior to the successful use of Hertzian waves for wireless communication Preece carried out experiments, often on a large scale, in attempts at wireless communication by inductive methods. These became of historic interest only when the work of Maxwell and Hertz was developed by Guglielmo Marconi. It is to Preece that credit should be given for encouraging Marconi in 1896 and collaborating with him in his early experimental work on radio telegraphy.While still employed by the Post Office, Preece contributed to the development of numerous early public electricity schemes, acting as Consultant and often supervising their construction. At Worcester he was responsible for Britain's largest nineteenth-century public hydro-electric station. He received a knighthood on his retirement in 1899, after which he continued his consulting practice in association with his two sons and Major Philip Cardew. Preece contributed some 136 papers and printed lectures to scientific journals, ninety-nine during the period 1877 to 1894.[br]Principal Honours and DistinctionsCB 1894. Knighted (KCB) 1899. FRS 1881. President, Society of Telegraph Engineers, 1880. President, Institution of Electrical Engineers 1880, 1893. President, Institution of Civil Engineers 1898–9. Chairman, Royal Society of Arts 1901–2.BibliographyPreece produced numerous papers on telegraphy and telephony that were presented as Royal Institution Lectures (see Royal Institution Library of Science, 1974) or as British Association reports.1862–3, "Railway telegraphs and the application of electricity to the signaling and working of trains", Proceedings of the ICE 22:167–93.Eleven editions of Telegraphy (with J.Sivewright), London, 1870, were published by 1895.1883, "Molecular radiation in incandescent lamps", Proceedings of the Physical Society 5: 283.1885. "Molecular shadows in incandescent lamps". Proceedings of the Physical Society 7: 178.1886. "Electric induction between wires and wires", British Association Report. 1889, with J.Maier, The Telephone.1894, "Electric signalling without wires", RSA Journal.1898, "Aetheric telegraphy", Proceedings of the Institution of Electrical Engineers.Further ReadingJ.J.Fahie, 1899, History of Wireless Telegraphy 1838–1899, Edinburgh: Blackwood. E.Hawkes, 1927, Pioneers of Wireless, London: Methuen.E.C.Baker, 1976, Sir William Preece, F.R.S. Victorian Engineer Extraordinary, London (a detailed biography with an appended list of his patents, principal lectures and publications).D.G.Tucker, 1981–2, "Sir William Preece (1834–1913)", Transactions of the Newcomen Society 53:119–36 (a critical review with a summary of his consultancies).GW / KFBiographical history of technology > Preece, Sir William Henry
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65 Whitworth, Sir Joseph
[br]b. 21 December 1803 Stockport, Cheshire, Englandd. 22 January 1887 Monte Carlo, Monaco[br]English mechanical engineer and pioneer of precision measurement.[br]Joseph Whitworth received his early education in a school kept by his father, but from the age of 12 he attended a school near Leeds. At 14 he joined his uncle's mill near Ambergate, Derbyshire, to learn the business of cotton spinning. In the four years he spent there he realized that he was more interested in the machinery than in managing a cotton mill. In 1821 he obtained employment as a mechanic with Crighton \& Co., Manchester. In 1825 he moved to London and worked for Henry Maudslay and later for the Holtzapffels and Joseph Clement. After these years spent gaining experience, he returned to Manchester in 1833 and set up in a small workshop under a sign "Joseph Whitworth, Tool Maker, from London".The business expanded steadily and the firm made machine tools of all types and other engineering products including steam engines. From 1834 Whitworth obtained many patents in the fields of machine tools, textile and knitting machinery and road-sweeping machines. By 1851 the company was generally regarded as the leading manufacturer of machine tools in the country. Whitworth was a pioneer of precise measurement and demonstrated the fundamental mode of producing a true plane by making surface plates in sets of three. He advocated the use of the decimal system and made use of limit gauges, and he established a standard screw thread which was adopted as the national standard. In 1853 Whitworth visited America as a member of a Royal Commission and reported on American industry. At the time of the Crimean War in 1854 he was asked to provide machinery for manufacturing rifles and this led him to design an improved rifle of his own. Although tests in 1857 showed this to be much superior to all others, it was not adopted by the War Office. Whitworth's experiments with small arms led on to the construction of big guns and projectiles. To improve the quality of the steel used for these guns, he subjected the molten metal to pressure during its solidification, this fluid-compressed steel being then known as "Whitworth steel".In 1868 Whitworth established thirty annual scholarships for engineering students. After his death his executors permanently endowed the Whitworth Scholarships and distributed his estate of nearly half a million pounds to various educational and charitable institutions. Whitworth was elected an Associate of the Institution of Civil Engineers in 1841 and a Member in 1848 and served on its Council for many years. He was elected a Member of the Institution of Mechanical Engineers in 1847, the year of its foundation.[br]Principal Honours and DistinctionsBaronet 1869. FRS 1857. President, Institution of Mechanical Engineers 1856, 1857 and 1866. Hon. LLD Trinity College, Dublin, 1863. Hon. DCL Oxford University 1868. Member of the Smeatonian Society of Civil Engineers 1864. Légion d'honneur 1868. Society of Arts Albert Medal 1868.Bibliography1858, Miscellaneous Papers on Mechanical Subjects, London; 1873, Miscellaneous Papers on Practical Subjects: Guns and Steel, London (both are collections of his papers to technical societies).1854, with G.Wallis, The Industry of the United States in Machinery, Manufactures, andUseful and Ornamental Arts, London.Further ReadingF.C.Lea, 1946, A Pioneer of Mechanical Engineering: Sir Joseph Whitworth, London (a short biographical account).A.E.Musson, 1963, "Joseph Whitworth: toolmaker and manufacturer", Engineering Heritage, Vol. 1, London, 124–9 (a short biography).D.J.Jeremy (ed.), 1984–6, Dictionary of Business Biography, Vol. 5, London, 797–802 (a short biography).W.Steeds, 1969, A History of Machine Tools 1700–1910, Oxford (describes Whitworth's machine tools).RTS -
66 estudio de arquitectos
(n.) = architecture firm, architectural firmEx. The purpose of the system is to assist architecture firms under contract with the Army Corps Engineers in locating regulations or guidelines on the planning, design or construction of army facilities.Ex. This is an interview with Hugh Hard of Hardy Holmzan Pfeiffer Associates, an architectural firm specializing in library design and renovation.* * *(n.) = architecture firm, architectural firmEx: The purpose of the system is to assist architecture firms under contract with the Army Corps Engineers in locating regulations or guidelines on the planning, design or construction of army facilities.
Ex: This is an interview with Hugh Hard of Hardy Holmzan Pfeiffer Associates, an architectural firm specializing in library design and renovation. -
67 Donkin, Bryan II
[br]b. 29 April 1809 London, Englandd. 4 December 1893 Blackheath, Kent, England[br]English mechanical engineer.[br]Bryan Donkin was the fifth son of Bryan Donkin I (1768–1855) and was educated at schools in Bromley (Kent), London, Paris and Nantes. He was an apprentice in his father's Bermondsey works and soon became an active and valuable assistant in the design and construction of papermaking, printing, pumping and other machinery. In 1829 he was sent to France to superintend the construction of paper mills and other machinery at Nantes. He later became a partner in the firm which in 1858 received an order to construct and set up a large paper mill at St Petersburg. This work took him to Russia several times before its completion in 1862. He obtained several patents relating to paper-making and steam engines. He was elected an associate of the Institution of Civil Engineers in 1835 and a member in 1840.[br]Principal Honours and DistinctionsMember, Smeatonian Society of Civil Engineers 1859; President 1872.RTS -
68 Elgar, Francis
SUBJECT AREA: Ports and shipping[br]b. April 1845 Portsmouth, Englandd. 16 January 1909 Monte Carlo, Monaco[br]English naval architect and shipbuilder.[br]Elgar enjoyed a fascinating professional life, during which he achieved distinction in the military, merchant, academic and political aspects of his profession. At the age of 14 he was apprenticed as a shipwright to the Royal Dockyard at Portsmouth but when he was in his late teens he was selected as one of the Admiralty students to further his education at the Royal School of Naval Architecture at South Kensington, London. On completion of the course he was appointed to Birkenhead, where the ill-fated HMS Captain was being built, and then to Portsmouth Dockyard. In 1870 the Captain was lost at sea and Francis Elgar was called on to prepare much of the evidence for the Court Martial. This began his life-long interest in ship stability and in ways of presenting this information in an easily understood form to ship operators.In 1883 he accepted the John Elder Chair of Naval Architecture at Glasgow University, an appointment which formalized the already well-established teaching of this branch of engineering at Glasgow. However, after only three years he returned to public service in the newly created post of Director of Royal Dockyards, a post that he held for a mere six years but which brought about great advances in the speed of warship construction, with associated reductions in cost. In 1892 he was made Naval Architect and Director of the Fairfield Shipbuilding Company in Glasgow, remaining there until he retired in 1907. The following year he accepted the post of Chairman of the Birkenhead shipyard of Cammell Laird \& Co.; this was a recent amalgamation of two companies, and he retained this position until his death. Throughout his life, Elgar acted on many consultative bodies and committees, including the 1884 Ship Load Line Enquiry. His work enabled him to keep abreast of all current thinking in ship design and construction.[br]Principal Honours and DistinctionsFRS. FRSE. Chevalier de la Légion d'honneur.BibliographyElgar produced some remarkable papers, which were published by the Institutions of Naval Architects, Civil Engineers and Engineers and Shipbuilders in Scotland as well as by the Royal Society. He published several books on shipbuilding.FMW -
69 Polhem, Christopher
SUBJECT AREA: Mining and extraction technology[br]b. 18 December 1661 Tingstade, Gotland, Sweden d. 1751[br]Swedish engineer and inventor.[br]He was the eldest son of Wolf Christopher Polhamma, a merchant. The father died in 1669 and the son was sent by his stepfather to an uncle in Stockholm who found him a place in the Deutsche Rechenschule. After the death of his uncle, he was forced to find employment, which he did with the Biorenklou family near Uppsala where he eventually became a kind of estate bailiff. It was during this period that he started to work with a lathe, a forge and at carpentry, displaying great technical ability. He realized that without further education he had little chance of making anything of his life, and accordingly, in 1687, he registered at the University of Uppsala where he studied astronomy and mathematics, remaining there for three years. He also repaired two astronomical pendulum clocks as well as the decrepit medieval clock in the cathedral. After a year's work he had this clock running properly: this was his breakthrough. He was summoned to Stockholm where the King awarded him a salary of 500 dalers a year as an encouragement to further efforts. Around this time, one of increasing mechanization and when mining was Sweden's principal industry, Pohlem made a model of a hoist frame for mines and the Mines Authority encouraged him to develop his ideas. In 1693 Polhem completed the Blankstot hoist at the Stora Kopparberg mine, which attracted great interest on the European continent.From 1694 to 1696 Polhem toured factories, mills and mines abroad in Germany, Holland, England and France, studying machinery of all kinds and meeting many foreign engineers. In 1698 he was appointed Director of Mining Engineering in Sweden, and in 1700 he became Master of Construction in the Falu Mine. He installed the Karl XII hoist there, powered by moving beams from a distant water-wheel. His plan of 1697 for all the machinery at the Falu mine to be driven by three large and remote water-wheels was never completed.In 1707 he was invited by the Elector of Hanover to visit the mines in the Harz district, where he successfully explained many of his ideas which were adopted by the local engineers. In 1700, in conjunction with Gabriel Stierncrona, he founded the Stiersunds Bruk at Husby in Southern Dalarna, a factory for the mass production of metal goods in iron, steel and bronze. Simple articles such as pans, trays, bowls, knives, scissors and mirrors were made there, together with the more sophisticated Polhem lock and the Stiersunds clock. Production was based on water power. Gear cutting for the clocks, shaping hammers for plates, file cutting and many other operations were all water powered, as was a roller mill for the sheet metal used in the factory. He also designed textile machinery such as stocking looms and spinning frames and machines for the manufacture of ribbons and other things.In many of his ideas Polhem was in advance of his time and Swedish country society was unable to absorb them. This was largely the reason for the Stiersund project being only a partial success. Polhem, too, was of a disputatious nature, self-opinionated almost to the point of conceit. He was a prolific writer, leaving over 20,000 pages of manuscript notes, drafts, essays on a wide range of subjects, which included building, brick-making, barrels, wheel-making, bell-casting, organ-building, methods of stopping a horse from bolting and a curious tap "to prevent serving maids from sneaking wine from the cask", the construction of ploughs and threshing machines. His major work, Kort Berattelse om de Fornamsta Mechaniska Inventioner (A Brief Account of the Most Famous Inventions), was printed in 1729 and is the main source of knowledge about his technological work. He is also known for his "mechanical alphabet", a collection of some eighty wooden models of mechanisms for educational purposes. It is in the National Museum of Science and Technology in Stockholm.[br]Bibliography1729, Kort Berattelse om de Fornamsta Mechaniska Inventioner (A Brief Account of the Most Famous Inventions).Further Reading1985, Christopher Polhem, 1661–1751, TheSwedish Daedalus' (catalogue of a travelling exhibition from the Swedish Institute in association with the National Museum of Science and Technology), Stockholm.IMcN -
70 Stephenson, Robert
[br]b. 16 October 1803 Willington Quay, Northumberland, Englandd. 12 October 1859 London, England[br]English engineer who built the locomotive Rocket and constructed many important early trunk railways.[br]Robert Stephenson's father was George Stephenson, who ensured that his son was educated to obtain the theoretical knowledge he lacked himself. In 1821 Robert Stephenson assisted his father in his survey of the Stockton \& Darlington Railway and in 1822 he assisted William James in the first survey of the Liverpool \& Manchester Railway. He then went to Edinburgh University for six months, and the following year Robert Stephenson \& Co. was named after him as Managing Partner when it was formed by himself, his father and others. The firm was to build stationary engines, locomotives and railway rolling stock; in its early years it also built paper-making machinery and did general engineering.In 1824, however, Robert Stephenson accepted, perhaps in reaction to an excess of parental control, an invitation by a group of London speculators called the Colombian Mining Association to lead an expedition to South America to use steam power to reopen gold and silver mines. He subsequently visited North America before returning to England in 1827 to rejoin his father as an equal and again take charge of Robert Stephenson \& Co. There he set about altering the design of steam locomotives to improve both their riding and their steam-generating capacity. Lancashire Witch, completed in July 1828, was the first locomotive mounted on steel springs and had twin furnace tubes through the boiler to produce a large heating surface. Later that year Robert Stephenson \& Co. supplied the Stockton \& Darlington Railway with a wagon, mounted for the first time on springs and with outside bearings. It was to be the prototype of the standard British railway wagon. Between April and September 1829 Robert Stephenson built, not without difficulty, a multi-tubular boiler, as suggested by Henry Booth to George Stephenson, and incorporated it into the locomotive Rocket which the three men entered in the Liverpool \& Manchester Railway's Rainhill Trials in October. Rocket, was outstandingly successful and demonstrated that the long-distance steam railway was practicable.Robert Stephenson continued to develop the locomotive. Northumbrian, built in 1830, had for the first time, a smokebox at the front of the boiler and also the firebox built integrally with the rear of the boiler. Then in Planet, built later the same year, he adopted a layout for the working parts used earlier by steam road-coach pioneer Goldsworthy Gurney, placing the cylinders, for the first time, in a nearly horizontal position beneath the smokebox, with the connecting rods driving a cranked axle. He had evolved the definitive form for the steam locomotive.Also in 1830, Robert Stephenson surveyed the London \& Birmingham Railway, which was authorized by Act of Parliament in 1833. Stephenson became Engineer for construction of the 112-mile (180 km) railway, probably at that date the greatest task ever undertaken in of civil engineering. In this he was greatly assisted by G.P.Bidder, who as a child prodigy had been known as "The Calculating Boy", and the two men were to be associated in many subsequent projects. On the London \& Birmingham Railway there were long and deep cuttings to be excavated and difficult tunnels to be bored, notoriously at Kilsby. The line was opened in 1838.In 1837 Stephenson provided facilities for W.F. Cooke to make an experimental electrictelegraph installation at London Euston. The directors of the London \& Birmingham Railway company, however, did not accept his recommendation that they should adopt the electric telegraph and it was left to I.K. Brunel to instigate the first permanent installation, alongside the Great Western Railway. After Cooke formed the Electric Telegraph Company, Stephenson became a shareholder and was Chairman during 1857–8.Earlier, in the 1830s, Robert Stephenson assisted his father in advising on railways in Belgium and came to be increasingly in demand as a consultant. In 1840, however, he was almost ruined financially as a result of the collapse of the Stanhope \& Tyne Rail Road; in return for acting as Engineer-in-Chief he had unwisely accepted shares, with unlimited liability, instead of a fee.During the late 1840s Stephenson's greatest achievements were the design and construction of four great bridges, as part of railways for which he was responsible. The High Level Bridge over the Tyne at Newcastle and the Royal Border Bridge over the Tweed at Berwick were the links needed to complete the East Coast Route from London to Scotland. For the Chester \& Holyhead Railway to cross the Menai Strait, a bridge with spans as long-as 460 ft (140 m) was needed: Stephenson designed them as wrought-iron tubes of rectangular cross-section, through which the trains would pass, and eventually joined the spans together into a tube 1,511 ft (460 m) long from shore to shore. Extensive testing was done beforehand by shipbuilder William Fairbairn to prove the method, and as a preliminary it was first used for a 400 ft (122 m) span bridge at Conway.In 1847 Robert Stephenson was elected MP for Whitby, a position he held until his death, and he was one of the exhibition commissioners for the Great Exhibition of 1851. In the early 1850s he was Engineer-in-Chief for the Norwegian Trunk Railway, the first railway in Norway, and he also built the Alexandria \& Cairo Railway, the first railway in Africa. This included two tubular bridges with the railway running on top of the tubes. The railway was extended to Suez in 1858 and for several years provided a link in the route from Britain to India, until superseded by the Suez Canal, which Stephenson had opposed in Parliament. The greatest of all his tubular bridges was the Victoria Bridge across the River St Lawrence at Montreal: after inspecting the site in 1852 he was appointed Engineer-in-Chief for the bridge, which was 1 1/2 miles (2 km) long and was designed in his London offices. Sadly he, like Brunel, died young from self-imposed overwork, before the bridge was completed in 1859.[br]Principal Honours and DistinctionsFRS 1849. President, Institution of Mechanical Engineers 1849. President, Institution of Civil Engineers 1856. Order of St Olaf (Norway). Order of Leopold (Belgium). Like his father, Robert Stephenson refused a knighthood.Further ReadingL.T.C.Rolt, 1960, George and Robert Stephenson, London: Longman (a good modern biography).J.C.Jeaffreson, 1864, The Life of Robert Stephenson, London: Longman (the standard nine-teenth-century biography).M.R.Bailey, 1979, "Robert Stephenson \& Co. 1823–1829", Transactions of the Newcomen Society 50 (provides details of the early products of that company).J.Kieve, 1973, The Electric Telegraph, Newton Abbot: David \& Charles.PJGR -
71 battalion
батальон; арт. дивизионAA artillery automatic weapons battalion, SP — дивизион ЗСУ
forward operations battalion, Intelligence and Security Command — передовой оперативный батальон командования разведки и безопасности
LIS Army, Europe battalion — батальон в составе СВ США в Европейской зоне (особой структуры)
operations battalion, Intelligence and Security Command — оперативный батальон командования разведки и безопасности
ordnance (nuclear) ammunition battalion — артиллерийско-технический батальон обеспечения (ядерными) боеприпасами
— AT artillery battalion— Commandos battalion— composite artillery battalion— light arrnored battalion— light artillery battalion— logistic support battalion— mechanized infantry battalion— mixed artillery battalion— petroleum supply battalion— Rangers battalion -
72 Ayrton, William Edward
[br]b. 14 September 1847 London, Englandd. 8 November 1908 London, England[br]English physicist, inventor and pioneer in technical education.[br]After graduating from University College, London, Ayrton became for a short time a pupil of Sir William Thomson in Glasgow. For five years he was employed in the Indian Telegraph Service, eventually as Superintendent, where he assisted in revolutionizing the system, devising methods of fault detection and elimination. In 1873 he was invited by the Japanese Government to assist as Professor of Physics and Telegraphy in founding the Imperial College of Engineering in Tokyo. There he created a teaching laboratory that served as a model for those he was later to organize in England and which were copied elsewhere. It was in Tokyo that his joint researches with Professor John Perry began, an association that continued after their return to England. In 1879 he became Professor of Technical Physics at the City and Guilds Institute in Finsbury, London, and later was appointed Professor of Physics at the Central Institution in South Kensington.The inventions of Avrton and Perrv included an electric tricycle in 1882, the first practicable portable ammeter and other electrical measuring instruments. By 1890, when the research partnership ended, they had published nearly seventy papers in their joint names, the emphasis being on a mathematical treatment of subjects including electric motor design, construction of electrical measuring instruments, thermodynamics and the economical use of electric conductors. Ayrton was then employed as a consulting engineer by government departments and acted as an expert witness in many important patent cases.[br]Principal Honours and DistinctionsFRS 1881. President, Physical Society 1890–2. President, Institution of Electrical Engineers 1892. Royal Society Royal Medal 1901.Bibliography28 April 1883, British patent no. 2,156 (Ayrton and Perry's ammeter and voltmeter). 1887, Practical Electricity, London (based on his early laboratory courses; 7 edns followed during his lifetime).1892, "Electrotechnics", Journal of the Institution of Electrical Engineers 21, 5–36 (for a survey of technical education).Further ReadingD.W.Jordan, 1985, "The cry for useless knowledge: education for a new Victorian technology", Proceedings of the Institution of Electrical Engineers, 132 (Part A): 587– 601.G.Gooday, 1991, History of Technology, 13: 73–111 (for an account of Ayrton and the teaching laboratory).GW -
73 Bateman, John Frederick La Trobe
[br]b. 30 May 1810 Lower Wyke, near Halifax, Yorkshire, Englandd. 10 June 1889 Moor Park, Farnham, Surrey, England[br]English civil engineer whose principal works were concerned with reservoirs, water-supply schemes and pipelines.[br]Bateman's maternal grandfather was a Moravian missionary, and from the age of 7 he was educated at the Moravian schools at Fairfield and Ockbrook. At the age of 15 he was apprenticed to a "civil engineer, land surveyor and agent" in Oldham. After this apprenticeship, Bateman commenced his own practice in 1833. One of his early schemes and reports was in regard to the flooding of the river Medlock in the Manchester area. He came to the attention of William Fairbairn, the engine builder and millwright of Canal Street, Ancoats, Manchester. Fairbairn used Bateman as his site surveyor and as such he prepared much of the groundwork for the Bann reservoirs in Northern Ireland. Whilst the reports on the proposals were in the name of Fairbairn, Bateman was, in fact, appointed by the company as their engineer for the execution of the works. One scheme of Bateman's which was carried forward was the Kendal Reservoirs. The Act for these was signed in 1845 and was implemented not for the purpose of water supply but for the conservation of water to supply power to the many mills which stood on the river Kent between Kentmere and Morecambe Bay. The Kentmere Head dam is the only one of the five proposed for the scheme to survive, although not all the others were built as they would have retained only small volumes of water.Perhaps the greatest monument to the work of J.F.La Trobe Bateman is Manchester's water supply; he was consulted about this in 1844, and construction began four years later. He first built reservoirs in the Longdendale valley, which has a very complicated geological stratification. Bateman favoured earth embankment dams and gravity feed rather than pumping; the five reservoirs in the valley that impound the river Etherow were complex, cored earth dams. However, when completed they were greatly at risk from landslips and ground movement. Later dams were inserted by Bateman to prevent water loss should the older dams fail. The scheme was not completed until 1877, by which time Manchester's population had exceeded the capacity of the original scheme; Thirlmere in Cumbria was chosen by Manchester Corporation as the site of the first of the Lake District water-supply schemes. Bateman, as Consulting Engineer, designed the great stone-faced dam at the west end of the lake, the "gothic" straining well in the middle of the east shore of the lake, and the 100-mile (160 km) pipeline to Manchester. The Act for the Thirlmere reservoir was signed in 1879 and, whilst Bateman continued as Consulting Engineer, the work was supervised by G.H. Hill and was completed in 1894.Bateman was also consulted by the authorities in Glasgow, with the result that he constructed an impressive water-supply scheme derived from Loch Katrine during the years 1856–60. It was claimed that the scheme bore comparison with "the most extensive aqueducts in the world, not excluding those of ancient Rome". Bateman went on to superintend the waterworks of many cities, mainly in the north of England but also in Dublin and Belfast. In 1865 he published a pamphlet, On the Supply of Water to London from the Sources of the River Severn, based on a survey funded from his own pocket; a Royal Commission examined various schemes but favoured Bateman's.Bateman was also responsible for harbour and dock works, notably on the rivers Clyde and Shannon, and also for a number of important water-supply works on the Continent of Europe and beyond. Dams and the associated reservoirs were the principal work of J.F.La Trobe Bateman; he completed forty-three such schemes during his professional career. He also prepared many studies of water-supply schemes, and appeared as professional witness before the appropriate Parliamentary Committees.[br]Principal Honours and DistinctionsFRS 1860. President, Institution of Civil Engineers 1878, 1879.BibliographyAmong his publications History and Description of the Manchester Waterworks, (1884, London), and The Present State of Our Knowledge on the Supply of Water to Towns, (1855, London: British Association for the Advancement of Science) are notable.Further ReadingObituary, 1889, Minutes of the Proceedings of the Institution of Civil Engineers 97:392– 8.Obituary, 1889, Proceedings of the Royal Society 46:xlii-xlviii. G.M.Binnie, 1981, Early Victorian Water Engineers, London.P.N.Wilson, 1973, "Kendal reservoirs", Transactions of the Cumberland and Westmorland Antiquarian and Archaeological Society 73.KM / LRDBiographical history of technology > Bateman, John Frederick La Trobe
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74 Ferranti, Sebastian Ziani de
[br]b. 9 April 1864 Liverpool, Englandd. 13 January 1930 Zurich, Switzerland[br]English manufacturing engineer and inventor, a pioneer and early advocate of high-voltage alternating-current electric-power systems.[br]Ferranti, who had taken an interest in electrical and mechanical devices from an early age, was educated at St Augustine's College in Ramsgate and for a short time attended evening classes at University College, London. Rather than pursue an academic career, Ferranti, who had intense practical interests, found employment in 1881 with the Siemens Company (see Werner von Siemens) in their experimental department. There he had the opportunity to superintend the installation of electric-lighting plants in various parts of the country. Becoming acquainted with Alfred Thomson, an engineer, Ferranti entered into a short-lived partnership with him to manufacture the Ferranti alternator. This generator, with a unique zig-zag armature, had an efficiency exceeding that of all its rivals. Finding that Sir William Thomson had invented a similar machine, Ferranti formed a company with him to combine the inventions and produce the Ferranti- Thomson machine. For this the Hammond Electric Light and Power Company obtained the sole selling rights.In 1885 the Grosvenor Gallery Electricity Supply Corporation was having serious problems with its Gaulard and Gibbs series distribution system. Ferranti, when consulted, reviewed the design and recommended transformers connected across constant-potential mains. In the following year, at the age of 22, he was appointed Engineer to the company and introduced the pattern of electricity supply that was eventually adopted universally. Ambitious plans by Ferranti for London envisaged the location of a generating station of unprecedented size at Deptford, about eight miles (13 km) from the city, a departure from the previous practice of placing stations within the area to be supplied. For this venture the London Electricity Supply Corporation was formed. Ferranti's bold decision to bring the supply from Deptford at the hitherto unheard-of pressure of 10,000 volts required him to design suitable cables, transformers and generators. Ferranti planned generators with 10,000 hp (7,460 kW)engines, but these were abandoned at an advanced stage of construction. Financial difficulties were caused in part when a Board of Trade enquiry in 1889 reduced the area that the company was able to supply. In spite of this adverse situation the enterprise continued on a reduced scale. Leaving the London Electricity Supply Corporation in 1892, Ferranti again started his own business, manufacturing electrical plant. He conceived the use of wax-impregnated paper-insulated cables for high voltages, which formed a landmark in the history of cable development. This method of flexible-cable manufacture was used almost exclusively until synthetic materials became available. In 1892 Ferranti obtained a patent which set out the advantages to be gained by adopting sector-shaped conductors in multi-core cables. This was to be fundamental to the future design and development of such cables.A total of 176 patents were taken out by S.Z. de Ferranti. His varied and numerous inventions included a successful mercury-motor energy meter and improvements to textile-yarn produc-tion. A transmission-line phenomenon where the open-circuit voltage at the receiving end of a long line is greater than the sending voltage was named the Ferranti Effect after him.[br]Principal Honours and DistinctionsFRS 1927. President, Institution of Electrical Engineers 1910 and 1911. Institution of Electrical Engineers Faraday Medal 1924.Bibliography18 July 1882, British patent no. 3,419 (Ferranti's first alternator).13 December 1892, British patent no. 22,923 (shaped conductors of multi-core cables). 1929, "Electricity in the service of man", Journal of the Institution of Electrical Engineers 67: 125–30.Further ReadingG.Z.de Ferranti and R. Ince, 1934, The Life and Letters of Sebastian Ziani de Ferranti, London.A.Ridding, 1964, S.Z.de Ferranti. Pioneer of Electric Power, London: Science Museum and HMSO (a concise biography).R.H.Parsons, 1939, Early Days of the Power Station Industry, Cambridge, pp. 21–41.GWBiographical history of technology > Ferranti, Sebastian Ziani de
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75 Kirkaldy, David
[br]b. 4 April 1820 Mayfield, Dundee, Scotlandd. 25 January 1897 London, England[br]Scottish engineer and pioneer in materials testing.[br]The son of a merchant of Dundee, Kirkaldy was educated there, then at Merchiston Castle School, Edinburgh, and at Edinburgh University. For a while he worked in his father's office, but with a preference for engineering, in 1843 he commenced an apprenticeship at the Glasgow works of Robert Napier. After four years in the shops he was transferred to the drawing office and in a very few years rose to become Chief. Here Kirkaldy demonstrated a remarkable talent both for the meticulous recording of observations and data and for technical drawing. His work also had an aesthetic appeal and four of his drawings of Napier steamships were shown at the Paris Exhibition of 1855, earning both Napier and Kirkaldy a medal. His "as fitted" set of drawings of the Cunard Liner Persia, which had been built in 1855, is now in the possession of the National Maritime Museum at Greenwich, London; it is regarded as one of the finest examples of its kind in the world, and has even been exhibited at the Royal Academy in London.With the impending order for the Royal Naval Ironclad Black Prince (sister ship to HMS Warrior, now preserved at Portsmouth) and for some high-pressure marine boilers and engines, there was need for a close scientific analysis of the physical properties of iron and steel. Kirkaldy, now designated Chief Draughtsman and Calculator, was placed in charge of this work, which included comparisons of puddled steel and wrought iron, using a simple lever-arm testing machine. The tests lasted some three years and resulted in Kirkaldy's most important publication, Experiments on Wrought Iron and Steel (1862, London), which gained him wide recognition for his careful and thorough work. Napier's did not encourage him to continue testing; but realizing the growing importance of materials testing, Kirkaldy resigned from the shipyard in 1861. For the next two and a half years Kirkaldy worked on the design of a massive testing machine that was manufactured in Leeds and installed in premises in London, at The Grove, Southwark.The works was open for trade in January 1866 and engineers soon began to bring him specimens for testing on the great machine: Joseph Cubitt (son of William Cubitt) brought him samples of the materials for the new Blackfriars Bridge, which was then under construction. Soon The Grove became too cramped and Kirkaldy moved to 99 Southwark Street, reopening in January 1874. In the years that followed, Kirkaldy gained a worldwide reputation for rigorous and meticulous testing and recording of results, coupled with the highest integrity. He numbered the most distinguished engineers of the time among his clients.After Kirkaldy's death, his son William George, whom he had taken into partnership, carried on the business. When the son died in 1914, his widow took charge until her death in 1938, when the grandson David became proprietor. He sold out to Treharne \& Davies, chemical consultants, in 1965, but the works finally closed in 1974. The future of the premises and the testing machine at first seemed threatened, but that has now been secured and the machine is once more in working order. Over almost one hundred years of trading in South London, the company was involved in many famous enquiries, including the analysis of the iron from the ill-fated Tay Bridge (see Bouch, Sir Thomas).[br]Principal Honours and DistinctionsInstitution of Engineers and Shipbuilders in Scotland Gold Medal 1864.Bibliography1862, Results of an Experimental Inquiry into the Tensile Strength and Other Properties of Wrought Iron and Steel (originally presented as a paper to the 1860–1 session of the Scottish Shipbuilders' Association).Further ReadingD.P.Smith, 1981, "David Kirkaldy (1820–97) and engineering materials testing", Transactions of the Newcomen Society 52:49–65 (a clear and well-documented account).LRD / FMW -
76 Maudslay, Henry
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering[br]b. 22 August 1771 Woolwich, Kent, Englandd. 15 February 1831 Lambeth, London, England[br]English precision toolmaker and engineer.[br]Henry Maudslay was the third son of an ex-soldier and storekeeper at Woolwich Arsenal. At the age of 12 he was employed at the Arsenal filling cartridges; two years later he was transferred to the woodworking department, adjacent to the smithy, to which he moved when 15 years old. He was a rapid learner, and three years later Joseph Bramah took him on for the construction of special tools required for the mass-production of his locks. Maudslay was thus employed for the next eight years. He became Bramah's foreman, married his housekeeper, Sarah Tindale, and, unable to better himself, decided to leave and set up on his own. He soon outgrew his first premises in Wells Street and moved to Margaret Street, off Oxford Street, where some examples of his workmanship were displayed in the window. These caught the attention of a visiting Frenchman, de Bacquancourt; he was a friend of Marc Isambard Brunel, who was then in the early stages of designing the block-making machinery later installed at Portsmouth dockyard.Brunel wanted first a set of working models, as he did not think that the Lords of the Admiralty would be capable of understanding engineering drawings; Maudslay made these for him within the next two years. Sir Samuel Bentham, Inspector-General of Naval Works, agreed that Brunel's system was superior to the one that he had gone some way in developing; the Admiralty approved, and an order was placed for the complete plant. The manufacture of the machinery occupied Maudslay for the next six years; he was assisted by a draughtsman whom he took on from Portsmouth dockyard, Joshua Field (1786–1863), who became his partner in Maudslay, Son and Field. There were as many as eighty employees at Margaret Street until, in 1810, larger premises became necessary and a new works was built at Lambeth Marsh where, eventually, there were up to two hundred workers. The new factory was flanked by two houses, one of which was occupied by Maudslay, the other by Field. The firm became noted for its production of marine steam-engines, notably Maudslay's table engine which was first introduced in 1807.Maudslay was a consummate craftsman who was never happier than when working at his bench or at a machine tool; he was also one of the first engineers to appreciate the virtues of standardization. Evidence of this appreciation is to be found in his work in the development of the Bramah lock and then on the machine tools for the manufacture of ship's blocks to Marc Brunel's designs; possibly his most important contribution was the invention in 1797 of the metal lathe. He made a number of surface plates of the finest quality. The most celebrated of his numerous measuring devices was a micrometer-based machine which he termed his "Lord Chancellor" because, in the machine shop, it represented the "final court of appeal", measuring to one-thousandth of an inch.[br]Further Reading1934–5, "Maudslay, Sons \& Field as general engineers", Transactions of the Newcomen Society 15, London.1963, Engineering Heritage, Vol. 1, London: Institution of Mechanical Engineers. L.T.C.Rolt, 1965, Tools for the Job, London: Batsford.W.Steeds, 1969, A History of Machine Tools 1700–1910, Oxford: Oxford University Press.IMcN -
77 CE
CE, Canadian Engineers————————CE, carrying equipment————————CE, Central Europe————————CE, chemical energy (shell)фугасный [кумулятивный] снаряд————————CE, chemical engineer————————CE, Chief of Engineers————————CE, circular errorкруговая ошибка [отклонение]————————CE, civil emergency————————CE, civil engineeringпроектирование и строительство гражданских объектов; инженерно-строительное обеспечение [работы]————————CE, compass errorпогрешность [поправка] показаний компаса————————CE, composition exploding————————CE, construction equipment————————CE, control elementгруппа [пункт] управления————————CE, control equipmentаппаратура контроля [управления]————————CE, controller error————————CE, Corps of Engineers————————CE, counterespionageконтршпионаж; контрразведка————————CE, crew errorошибка экипажа [расчета]————————CE, crew evaluatorустановка для оценки уровня подготовки экипажа [расчета]————————CE, critical examination————————CE, cumulative expenditures————————CE, communications equipmentаппаратура [оборудование] связи; средства связи————————CE; C & E; C-E, communications/electronics————————CE; C/E, cost-effectiveness"стоимость - эффективность" (критерий)————————CE; C/E, cost effectiveсоответствующий критерию "стоимость - эффективность"English-Russian dictionary of planing, cross-planing and slotting machines > CE
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78 AEC
1) Общая лексика: hum. сокр. Atomic Energy Commission, Atlantic and East Carolina Railway Company ( сокр.) (наименование американской железнодорожной компании)2) Военный термин: Area Equipment Compound, Army Education Center, Army Educational Corps, Army Establishment Committee, Army Establishment Committee AEB, Airborne and Electronics Board, Army extension courses, Aviation Engineer Command, aerial embarkation center, aerial exploitation company, analog electronic computer, area equipment compounds3) Техника: Alternative Energy Coalition, Army electronics command, Autocorrelation Functions, arithmetic element controller, automatic exciter control, automatic exposure control, average electrode current, adaptive echo canceller (адаптивный эхокомпенсатор), (Architecture Engineering Construction) архитектура, инженерные системы, строительство4) Сельское хозяйство: anion exchange capacity5) Религия: Antilles Episcopal Conference6) Железнодорожный термин: Atlantic and East Carolina Railway Company7) Сокращение: ASARS Exploitation Cell, American Engineering Council, Army Environmental Center (USA), Associated Equipment Company, Atomic Energy Commission (USA), Automated Element Correction (address correction subsystem 2003), Aviation Electronic Combat, Европейская ассоциация по керамике (франц.яз.), АЭС (Африканское экономическое сообщество)8) Фото: automatic exposure control( сокр.) (1. автоматическая установка экспозиции 2. автоматическое экспонометрическое устройство)9) Вычислительная техника: Atomic Energy Commission, architectural or engineering construction, architecture, engineering and construction, Advanced Error Correction (CD), авторизованный учебный центр10) Нефть: Африканское экономическое сообщество11) Биохимия: Aminoethyl Cellulose, Aminoethyl-Cysteine12) Фирменный знак: Architects Engineers Contractors13) Экология: area of environmental concern14) Образование: Authorized Education Centre15) Сетевые технологии: Authorized Education Center, automatic error correction, автоматическое исправление ошибок16) Полимеры: Atomic Energy Corporation17) Автоматика: automatic editing control18) Ядерная физика: Atomic Energy Commission (US)19) Медицинская техника: American Endosonography Club20) Химическое оружие: Ammunition Equipment Directorate, Army Environmental Center21) Военно-морской флот: Chief Aviation Electrician's Mate (сокр.) (главный старшина — авиационный электрик)22) Расширение файла: Architecture, Engineering, Construction23) Электротехника: automatic excitation control24) NYSE. Associated Estates Realty Corporation -
79 group
army group, Royal Artillery — Бр. армейская группа ПА
army group, Royal Engineers — Бр. армейская инженерная группа
C3 Countermeasures Working group — рабочая группа по вопросам РЭП систем оперативного управления и связи
combat equipment group, Europe — группа обеспечения войск оружием и военной техникой в Европейской зоне (для сил двойного базирования)
European Interdepartment group, NSC — Европейская межведомственная группа СНБ
intelligence data (technical) processing group — группа (технической) обработки разведывательных данных
Standing group, Military Committee — постоянная группа военного комитета НАТО
tactical air (control) group — мор. группа наведения авиации
— address indicating group— FA group— HQ group— launching control group* * *• 1) группа; 2) дивизия• 1) группироваться; 2) группировать -
80 Greathead, James Henry
[br]b. 6 August 1844 Grahamstown, Cape Colony (now South Africa)d. 21 October 1896 Streatham, London, England[br]British civil engineer, inventor of the Greathead tunnelling shield.[br]Greathead came to England in 1859 to complete his education. In 1864 he began a three-year pupillage with the civil engineer Peter W. Barlow, after which he was engaged as an assistant engineer on the extension of the Midland Railway from Bedford to London. In 1869 he was entrusted with the construction of the Tower Subway under the River Thames; this was carried out using a cylindrical wrought-iron shield which was forced forward by six large screws as material was excavated in front of it. This work was completed the same year. In 1870 he set himself up as a consulting engineer, and from 1873 he was Resident Engineer on the Hammersmith and Richmond extensions of the Metropolitan District Railway. He assisted in the preparation of several other railway projects including the Regent's Canal Railway in 1880, the Dagenham Dock and the Metropolitan Outer Circle Railways in 1881, a new line from London to Eastbourne and a number of Irish light railways. He worked on a bill for the City and South London Railway, which was built between 1886 and 1890; here compressed air was used to prevent the inrush of water, a method for tunnelling which was generally adopted from then on. He invented apparatus for the application of water to excavate in front of the shield as well as for injecting cement-grout behind the lining of the tunnel.He was joint engineer with Sir Douglas Fox for the construction of the Liverpool Overhead Railway, and held the same post with W.R.Galbraith on the Waterloo and City Railway; he was also associated with Sir John Fowler and Sir Benjamin Baker in the construction of the Central London Railway. He died, aged 52, before the completion of some of these projects.[br]Further ReadingObituary, 1896, Proceedings of the Institution of Mechanical Engineers.O.Green, 1987, The London Underground: An Illustrated History', London: Ian Allan (in association with the London Transport Museum).P.P.Holman, 1990, The Amazing Electric Tube: A History of the City and South LondonRailway, London: London Transport Museum.IMcN
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