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1 mechanical transport company
MTC, Бр mechanical transport companyEnglish-Russian dictionary of planing, cross-planing and slotting machines > mechanical transport company
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2 mechanical transport company
Военный термин: автотранспортная ротаУниверсальный англо-русский словарь > mechanical transport company
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3 mechanical transport company
English-Russian military dictionary > mechanical transport company
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4 company
bulk petrol (transport) company — Бр. рота подвоза наливного (бестарного) горючего
Commando (oil gas extraction area) company — рота охраны и защиты (нефтегазовых промыслов), рота «команчо»
field company, RE — Бр. саперная рота
field survey company, RE — Бр. полевая топографическая рота инженерных войск
HQ company, US Army — штабная рота штаба СВ США
long-range (reconnaissance) patrol company — рота дальней [глубинной] разведки
special boat company, Royal Marines — Бр. особая [отдельная] рота десантных катеров МП
— AG's company— airborne infantry company— air-mission company light— commandos company— Rangers company— smoke generator company -
5 MTC
1) Общая лексика: (abbr., Military-Technical Cooperation) В (также можно встретить англ. сокр. FSMTC ( Federal Service of Military-Technical Cooperation) - русск. сокр. ФСМТС (Федеральная служба по военно-техническому сотрудничеству))2) Американизм: More Than Conquerors3) Военный термин: Maneuver Training Command, Materiel Testing Command, Mechanical Transport Corps, Mercenary Training Center, Military Technical College, Military Transportation Committee, Motor Transport Corps, materiel testing center, mechanical transport company, medical training center, meteorological training center, missile test center, missile transfer car, missile tube control, mobile target carrier4) Техника: main trunk circuit, maintenance time constraint, master tape control, mean time to crash, mobile transfer conveyor, moderator temperature coefficient, multi-assembly transfer cask, multilead thermocouple, ручная смена инструмента (manual tool change), Machine Tool Control5) Религия: Mission To Catholics International, Inc.6) Фармакология: минимальная токсическая концентрация (Minimal Toxic Concentration)7) Музыка: Music Takes Control8) Телекоммуникации: Mobile Terminating Call, мобильные телекоммуникации9) Сокращение: Man Tended Capability, Managing through Challenges communication plan (USPS emergencies, 2004), Master Timing Center, Military Technical Co-operation, Mini Tele-Copter (Germany), Mission and Traffic Control, memory test computer10) Театр: Manhattan Theatre Club11) Физиология: Minimum Toxic Concentration12) Электроника: Main Test Component13) Вычислительная техника: MIDI Time Code, Master Test Component (ISO 9646-3, TTCN), MIDI Time Code (MIDI), Man Tended Capability (Space)14) Нефть: ограничение на продолжительность технического обслуживания (maintenance time constraint), средняя наработка до разрушения (mean time to crash)15) Онкология: Medullary Thyroid Carcinoma16) Транспорт: Multi Towing Craft17) Фирменный знак: Management & Training Corporation18) СМИ: More To Come19) Программирование: MIDI timecode, Maintenance Controller20) Химическое оружие: Munition test chamber, mustard thaw container21) Нефть и газ: material test certificate( сертификат испытания материала)22) Общественная организация: Mission To Children23) NYSE. Monsanto Company24) НАСА: Mission Training Center25) Единицы измерений: Metric Ton Of Carbon -
6 mtc
1) Общая лексика: (abbr., Military-Technical Cooperation) В (также можно встретить англ. сокр. FSMTC ( Federal Service of Military-Technical Cooperation) - русск. сокр. ФСМТС (Федеральная служба по военно-техническому сотрудничеству))2) Американизм: More Than Conquerors3) Военный термин: Maneuver Training Command, Materiel Testing Command, Mechanical Transport Corps, Mercenary Training Center, Military Technical College, Military Transportation Committee, Motor Transport Corps, materiel testing center, mechanical transport company, medical training center, meteorological training center, missile test center, missile transfer car, missile tube control, mobile target carrier4) Техника: main trunk circuit, maintenance time constraint, master tape control, mean time to crash, mobile transfer conveyor, moderator temperature coefficient, multi-assembly transfer cask, multilead thermocouple, ручная смена инструмента (manual tool change), Machine Tool Control5) Религия: Mission To Catholics International, Inc.6) Фармакология: минимальная токсическая концентрация (Minimal Toxic Concentration)7) Музыка: Music Takes Control8) Телекоммуникации: Mobile Terminating Call, мобильные телекоммуникации9) Сокращение: Man Tended Capability, Managing through Challenges communication plan (USPS emergencies, 2004), Master Timing Center, Military Technical Co-operation, Mini Tele-Copter (Germany), Mission and Traffic Control, memory test computer10) Театр: Manhattan Theatre Club11) Физиология: Minimum Toxic Concentration12) Электроника: Main Test Component13) Вычислительная техника: MIDI Time Code, Master Test Component (ISO 9646-3, TTCN), MIDI Time Code (MIDI), Man Tended Capability (Space)14) Нефть: ограничение на продолжительность технического обслуживания (maintenance time constraint), средняя наработка до разрушения (mean time to crash)15) Онкология: Medullary Thyroid Carcinoma16) Транспорт: Multi Towing Craft17) Фирменный знак: Management & Training Corporation18) СМИ: More To Come19) Программирование: MIDI timecode, Maintenance Controller20) Химическое оружие: Munition test chamber, mustard thaw container21) Нефть и газ: material test certificate( сертификат испытания материала)22) Общественная организация: Mission To Children23) NYSE. Monsanto Company24) НАСА: Mission Training Center25) Единицы измерений: Metric Ton Of Carbon -
7 MTC
MTC, Maneuver Training Commandкомандование [управление] подготовки к войсковым маневрам и учениям (СВ)————————MTC, materiel testing center————————MTC, Materiel Testing Commandкомандование [управление] испытаний оружия и военной техники (СВ)————————MTC, Бр mechanical transport company————————MTC, Mechanical Transport Corps————————MTC, medical training center————————MTC, meteorological training center————————MTC, Бр Military Technical College————————MTC, Military Transportation Committee————————MTC, missile test center————————MTC, missile transfer car————————MTC, missile tube control————————MTC, mobile target carrier————————MTC, Motor Transport CorpsEnglish-Russian dictionary of planing, cross-planing and slotting machines > MTC
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8 MET
1) Компьютерная техника: master earth terminal, multibutton electronic telephone2) Медицина: метаболический эквивалент нагрузки (metabolic equivalent of task), meta-analysis (мета-анализ), метаболический эквивалент, medical emergency team3) Военный термин: MILSTAR Engineering Development Model Terminal, Materials Energy Toxicity, Mobile Exploitation Team, maintenance equipment training, management engineering team, mechanical transport, medium equipment transporter, meteorological station, minimum exposure time, missile electrical technician, missile escort team, mobile equipment transporter, multienvironmental trainer, Medium Earth Terminal (w/in CARS)4) Техника: metallurgist, metallurgy, meteorological broadcast, multienvironment trainer5) Общая лексика: НДПИ (Mineral Extraction Tax)6) Метеорология: Mobile Environmental Teams7) Железнодорожный термин: Modesto and Empire Traction Company8) Автомобильный термин: Mechanical, Electrical and Trim9) Сокращение: Marksmanship Expert Trainer, Mean European Time, Mission Event Timer, Mobile Electronic warfare Test, metallurgical, meteorological broadcasts, meteorology, Middle European Time (GMT + 0100), Mesh-Emitter Transistor, Methionine aminoacid10) Физиология: Metabolic Equivalent11) Вычислительная техника: Memory Enhancement Technology (Hewlett-Packard), Middle European Time-1:00, расширение файлов в формате IBM Presentation, Middle European Time (+0100, TZ, CET, METDST, MEZ), Memory Enhancement Technology (HP)12) Нефть: mineral extraction tax13) Иммунология: Microbial Exploration Technology14) Фирменный знак: Meridian Energy Therapies15) Деловая лексика: Multidisciplinary Evaluation Team16) Образование: Metropolitan Educational Theatre, Mobile Education Team, Motivation Education And Training17) Расширение файла: Middle European Time (+1:00), Memory Enhancement Technology (Hewlett-Packard), Graphics metafile (OS/2), Metafile (OS/2), Document (Omnipage Pro), OS/2 graphics metafile (PICVIEW.EXE), Macro Editor top overflow file (WordPerfect Library)18) Электротехника: maximum electrical torque19) Аэропорты: Moreton, Queensland, Australia20) НАСА: Mission Elapsed Time -
9 Met
1) Компьютерная техника: master earth terminal, multibutton electronic telephone2) Медицина: метаболический эквивалент нагрузки (metabolic equivalent of task), meta-analysis (мета-анализ), метаболический эквивалент, medical emergency team3) Военный термин: MILSTAR Engineering Development Model Terminal, Materials Energy Toxicity, Mobile Exploitation Team, maintenance equipment training, management engineering team, mechanical transport, medium equipment transporter, meteorological station, minimum exposure time, missile electrical technician, missile escort team, mobile equipment transporter, multienvironmental trainer, Medium Earth Terminal (w/in CARS)4) Техника: metallurgist, metallurgy, meteorological broadcast, multienvironment trainer5) Общая лексика: НДПИ (Mineral Extraction Tax)6) Метеорология: Mobile Environmental Teams7) Железнодорожный термин: Modesto and Empire Traction Company8) Автомобильный термин: Mechanical, Electrical and Trim9) Сокращение: Marksmanship Expert Trainer, Mean European Time, Mission Event Timer, Mobile Electronic warfare Test, metallurgical, meteorological broadcasts, meteorology, Middle European Time (GMT + 0100), Mesh-Emitter Transistor, Methionine aminoacid10) Физиология: Metabolic Equivalent11) Вычислительная техника: Memory Enhancement Technology (Hewlett-Packard), Middle European Time-1:00, расширение файлов в формате IBM Presentation, Middle European Time (+0100, TZ, CET, METDST, MEZ), Memory Enhancement Technology (HP)12) Нефть: mineral extraction tax13) Иммунология: Microbial Exploration Technology14) Фирменный знак: Meridian Energy Therapies15) Деловая лексика: Multidisciplinary Evaluation Team16) Образование: Metropolitan Educational Theatre, Mobile Education Team, Motivation Education And Training17) Расширение файла: Middle European Time (+1:00), Memory Enhancement Technology (Hewlett-Packard), Graphics metafile (OS/2), Metafile (OS/2), Document (Omnipage Pro), OS/2 graphics metafile (PICVIEW.EXE), Macro Editor top overflow file (WordPerfect Library)18) Электротехника: maximum electrical torque19) Аэропорты: Moreton, Queensland, Australia20) НАСА: Mission Elapsed Time -
10 met
1) Компьютерная техника: master earth terminal, multibutton electronic telephone2) Медицина: метаболический эквивалент нагрузки (metabolic equivalent of task), meta-analysis (мета-анализ), метаболический эквивалент, medical emergency team3) Военный термин: MILSTAR Engineering Development Model Terminal, Materials Energy Toxicity, Mobile Exploitation Team, maintenance equipment training, management engineering team, mechanical transport, medium equipment transporter, meteorological station, minimum exposure time, missile electrical technician, missile escort team, mobile equipment transporter, multienvironmental trainer, Medium Earth Terminal (w/in CARS)4) Техника: metallurgist, metallurgy, meteorological broadcast, multienvironment trainer5) Общая лексика: НДПИ (Mineral Extraction Tax)6) Метеорология: Mobile Environmental Teams7) Железнодорожный термин: Modesto and Empire Traction Company8) Автомобильный термин: Mechanical, Electrical and Trim9) Сокращение: Marksmanship Expert Trainer, Mean European Time, Mission Event Timer, Mobile Electronic warfare Test, metallurgical, meteorological broadcasts, meteorology, Middle European Time (GMT + 0100), Mesh-Emitter Transistor, Methionine aminoacid10) Физиология: Metabolic Equivalent11) Вычислительная техника: Memory Enhancement Technology (Hewlett-Packard), Middle European Time-1:00, расширение файлов в формате IBM Presentation, Middle European Time (+0100, TZ, CET, METDST, MEZ), Memory Enhancement Technology (HP)12) Нефть: mineral extraction tax13) Иммунология: Microbial Exploration Technology14) Фирменный знак: Meridian Energy Therapies15) Деловая лексика: Multidisciplinary Evaluation Team16) Образование: Metropolitan Educational Theatre, Mobile Education Team, Motivation Education And Training17) Расширение файла: Middle European Time (+1:00), Memory Enhancement Technology (Hewlett-Packard), Graphics metafile (OS/2), Metafile (OS/2), Document (Omnipage Pro), OS/2 graphics metafile (PICVIEW.EXE), Macro Editor top overflow file (WordPerfect Library)18) Электротехника: maximum electrical torque19) Аэропорты: Moreton, Queensland, Australia20) НАСА: Mission Elapsed Time -
11 Stevens, John
[br]b. 1749 New York, New York, USAd. 6 March 1838 Hoboken, New Jersey, USA[br]American pioneer of steamboats and railways.[br]Stevens, a wealthy landowner with an estate at Hoboken on the Hudson River, had his attention drawn to the steamboat of John Fitch in 1786, and thenceforth devoted much of his time and fortune to developing steamboats and mechanical transport. He also had political influence and it was at his instance that Congress in 1790 passed an Act establishing the first patent laws in the USA. The following year Stevens was one of the first recipients of a US patent. This referred to multi-tubular boilers, of both watertube and firetube types, and antedated by many years the work of both Henry Booth and Marc Seguin on the latter.A steamboat built in 1798 by John Stevens, Nicholas J.Roosevelt and Stevens's brother-in-law, Robert R.Livingston, in association was unsuccessful, nor was Stevens satisfied with a boat built in 1802 in which a simple rotary steam-en-gine was mounted on the same shaft as a screw propeller. However, although others had experimented earlier with screw propellers, when John Stevens had the Little Juliana built in 1804 he produced the first practical screw steamboat. Steam at 50 psi (3.5 kg/cm2) pressure was supplied by a watertube boiler to a single-cylinder engine which drove two contra-rotating shafts, upon each of which was mounted a screw propeller. This little boat, less than 25 ft (7.6 m) long, was taken backwards and forwards across the Hudson River by two of Stevens's sons, one of whom, R.L. Stevens, was to help his father with many subsequent experiments. The boat, however, was ahead of its time, and steamships were to be driven by paddle wheels until the late 1830s.In 1807 John Stevens declined an invitation to join with Robert Fulton and Robert R.Living-ston in their development work, which culminated in successful operation of the PS Clermont that summer; in 1808, however, he launched his own paddle steamer, the Phoenix. But Fulton and Livingston had obtained an effective monopoly of steamer operation on the Hudson and, unable to reach agreement with them, Stevens sent Phoenix to Philadelphia to operate on the Delaware River. The intervening voyage over 150 miles (240 km) of open sea made Phoenix the first ocean-going steamer.From about 1810 John Stevens turned his attention to the possibilities of railways. He was at first considered a visionary, but in 1815, at his instance, the New Jersey Assembly created a company to build a railway between the Delaware and Raritan Rivers. It was the first railway charter granted in the USA, although the line it authorized remained unbuilt. To demonstrate the feasibility of the steam locomotive, Stevens built an experimental locomotive in 1825, at the age of 76. With flangeless wheels, guide rollers and rack-and-pinion drive, it ran on a circular track at his Hoboken home; it was the first steam locomotive to be built in America.[br]Bibliography1812, Documents Tending to Prove the Superior Advantages of Rail-ways and Steam-carriages over Canal Navigation.He took out patents relating to steam-engines in the USA in 1791, 1803, and 1810, and in England, through his son John Cox Stevens, in 1805.Further ReadingH.P.Spratt, 1958, The Birth of the Steamboat, Charles Griffin (provides technical details of Stevens's boats).J.T.Flexner, 1978, Steamboats Come True, Boston: Little, Brown (describes his work in relation to that of other steamboat pioneers).J.R.Stover, 1961, American Railroads, Chicago: University of Chicago Press.Transactions of the Newcomen Society (1927) 7: 114 (discusses tubular boilers).J.R.Day and B.G.Wilson, 1957, Unusual Railways, F.Muller (discusses Stevens's locomotive).PJGR -
12 Sperry, Elmer Ambrose
[br]b. 21 October 1860 Cincinnatus, Cortland County, New York, USAd. 16 June 1930 Brooklyn, New York, USA[br]American entrepreneur who invented the gyrocompass.[br]Sperry was born into a farming community in Cortland County. He received a rudimentary education at the local school, but an interest in mechanical devices was aroused by the agricultural machinery he saw around him. His attendance at the Normal School in Cortland provided a useful theoretical background to his practical knowledge. He emerged in 1880 with an urge to pursue invention in electrical engineering, then a new and growing branch of technology. Within two years he was able to patent and demonstrate his arc lighting system, complete with its own generator, incorporating new methods of regulating its output. The Sperry Electric Light, Motor and Car Brake Company was set up to make and market the system, but it was difficult to keep pace with electric-lighting developments such as the incandescent lamp and alternating current, and the company ceased in 1887 and was replaced by the Sperry Electric Company, which itself was taken over by the General Electric Company.In the 1890s Sperry made useful inventions in electric mining machinery and then in electric street-or tramcars, with his patent electric brake and control system. The patents for the brake were important enough to be bought by General Electric. From 1894 to 1900 he was manufacturing electric motor cars of his own design, and in 1900 he set up a laboratory in Washington, where he pursued various electrochemical processes.In 1896 he began to work on the practical application of the principle of the gyroscope, where Sperry achieved his most notable inventions, the first of which was the gyrostabilizer for ships. The relatively narrow-hulled steamship rolled badly in heavy seas and in 1904 Ernst Otto Schuck, a German naval engineer, and Louis Brennan in England began experiments to correct this; their work stimulated Sperry to develop his own device. In 1908 he patented the active gyrostabilizer, which acted to correct a ship's roll as soon as it started. Three years later the US Navy agreed to try it on a destroyer, the USS Worden. The successful trials of the following year led to widespread adoption. Meanwhile, in 1910, Sperry set up the Sperry Gyroscope Company to extend the application to commercial shipping.At the same time, Sperry was working to apply the gyroscope principle to the ship's compass. The magnetic compass had worked well in wooden ships, but iron hulls and electrical machinery confused it. The great powers' race to build up their navies instigated an urgent search for a solution. In Germany, Anschütz-Kämpfe (1872–1931) in 1903 tested a form of gyrocompass and was encouraged by the authorities to demonstrate the device on the German flagship, the Deutschland. Its success led Sperry to develop his own version: fortunately for him, the US Navy preferred a home-grown product to a German one and gave Sperry all the backing he needed. A successful trial on a destroyer led to widespread acceptance in the US Navy, and Sperry was soon receiving orders from the British Admiralty and the Russian Navy.In the rapidly developing field of aeronautics, automatic stabilization was becoming an urgent need. In 1912 Sperry began work on a gyrostabilizer for aircraft. Two years later he was able to stage a spectacular demonstration of such a device at an air show near Paris.Sperry continued research, development and promotion in military and aviation technology almost to the last. In 1926 he sold the Sperry Gyroscope Company to enable him to devote more time to invention.[br]Principal Honours and DistinctionsJohn Fritz Medal 1927. President, American Society of Mechanical Engineers 1928.BibliographySperry filed over 400 patents, of which two can be singled out: 1908. US patent no. 434,048 (ship gyroscope); 1909. US patent no. 519,533 (ship gyrocompass set).Further ReadingT.P.Hughes, 1971, Elmer Sperry, Inventor and Engineer, Baltimore: Johns Hopkins University Press (a full and well-documented biography, with lists of his patents and published writings).LRD -
13 Stephenson, George
[br]b. 9 June 1781 Wylam, Northumberland, Englandd. 12 August 1848 Tapton House, Chesterfield, England[br]English engineer, "the father of railways".[br]George Stephenson was the son of the fireman of the pumping engine at Wylam colliery, and horses drew wagons of coal along the wooden rails of the Wylam wagonway past the house in which he was born and spent his earliest childhood. While still a child he worked as a cowherd, but soon moved to working at coal pits. At 17 years of age he showed sufficient mechanical talent to be placed in charge of a new pumping engine, and had already achieved a job more responsible than that of his father. Despite his position he was still illiterate, although he subsequently learned to read and write. He was largely self-educated.In 1801 he was appointed Brakesman of the winding engine at Black Callerton pit, with responsibility for lowering the miners safely to their work. Then, about two years later, he became Brakesman of a new winding engine erected by Robert Hawthorn at Willington Quay on the Tyne. Returning collier brigs discharged ballast into wagons and the engine drew the wagons up an inclined plane to the top of "Ballast Hill" for their contents to be tipped; this was one of the earliest applications of steam power to transport, other than experimentally.In 1804 Stephenson moved to West Moor pit, Killingworth, again as Brakesman. In 1811 he demonstrated his mechanical skill by successfully modifying a new and unsatisfactory atmospheric engine, a task that had defeated the efforts of others, to enable it to pump a drowned pit clear of water. The following year he was appointed Enginewright at Killingworth, in charge of the machinery in all the collieries of the "Grand Allies", the prominent coal-owning families of Wortley, Liddell and Bowes, with authorization also to work for others. He built many stationary engines and he closely examined locomotives of John Blenkinsop's type on the Kenton \& Coxlodge wagonway, as well as those of William Hedley at Wylam.It was in 1813 that Sir Thomas Liddell requested George Stephenson to build a steam locomotive for the Killingworth wagonway: Blucher made its first trial run on 25 July 1814 and was based on Blenkinsop's locomotives, although it lacked their rack-and-pinion drive. George Stephenson is credited with building the first locomotive both to run on edge rails and be driven by adhesion, an arrangement that has been the conventional one ever since. Yet Blucher was far from perfect and over the next few years, while other engineers ignored the steam locomotive, Stephenson built a succession of them, each an improvement on the last.During this period many lives were lost in coalmines from explosions of gas ignited by miners' lamps. By observation and experiment (sometimes at great personal risk) Stephenson invented a satisfactory safety lamp, working independently of the noted scientist Sir Humphry Davy who also invented such a lamp around the same time.In 1817 George Stephenson designed his first locomotive for an outside customer, the Kilmarnock \& Troon Railway, and in 1819 he laid out the Hetton Colliery Railway in County Durham, for which his brother Robert was Resident Engineer. This was the first railway to be worked entirely without animal traction: it used inclined planes with stationary engines, self-acting inclined planes powered by gravity, and locomotives.On 19 April 1821 Stephenson was introduced to Edward Pease, one of the main promoters of the Stockton \& Darlington Railway (S \& DR), which by coincidence received its Act of Parliament the same day. George Stephenson carried out a further survey, to improve the proposed line, and in this he was assisted by his 18-year-old son, Robert Stephenson, whom he had ensured received the theoretical education which he himself lacked. It is doubtful whether either could have succeeded without the other; together they were to make the steam railway practicable.At George Stephenson's instance, much of the S \& DR was laid with wrought-iron rails recently developed by John Birkinshaw at Bedlington Ironworks, Morpeth. These were longer than cast-iron rails and were not brittle: they made a track well suited for locomotives. In June 1823 George and Robert Stephenson, with other partners, founded a firm in Newcastle upon Tyne to build locomotives and rolling stock and to do general engineering work: after its Managing Partner, the firm was called Robert Stephenson \& Co.In 1824 the promoters of the Liverpool \& Manchester Railway (L \& MR) invited George Stephenson to resurvey their proposed line in order to reduce opposition to it. William James, a wealthy land agent who had become a visionary protagonist of a national railway network and had seen Stephenson's locomotives at Killingworth, had promoted the L \& MR with some merchants of Liverpool and had carried out the first survey; however, he overreached himself in business and, shortly after the invitation to Stephenson, became bankrupt. In his own survey, however, George Stephenson lacked the assistance of his son Robert, who had left for South America, and he delegated much of the detailed work to incompetent assistants. During a devastating Parliamentary examination in the spring of 1825, much of his survey was shown to be seriously inaccurate and the L \& MR's application for an Act of Parliament was refused. The railway's promoters discharged Stephenson and had their line surveyed yet again, by C.B. Vignoles.The Stockton \& Darlington Railway was, however, triumphantly opened in the presence of vast crowds in September 1825, with Stephenson himself driving the locomotive Locomotion, which had been built at Robert Stephenson \& Co.'s Newcastle works. Once the railway was at work, horse-drawn and gravity-powered traffic shared the line with locomotives: in 1828 Stephenson invented the horse dandy, a wagon at the back of a train in which a horse could travel over the gravity-operated stretches, instead of trotting behind.Meanwhile, in May 1826, the Liverpool \& Manchester Railway had successfully obtained its Act of Parliament. Stephenson was appointed Engineer in June, and since he and Vignoles proved incompatible the latter left early in 1827. The railway was built by Stephenson and his staff, using direct labour. A considerable controversy arose c. 1828 over the motive power to be used: the traffic anticipated was too great for horses, but the performance of the reciprocal system of cable haulage developed by Benjamin Thompson appeared in many respects superior to that of contemporary locomotives. The company instituted a prize competition for a better locomotive and the Rainhill Trials were held in October 1829.Robert Stephenson had been working on improved locomotive designs since his return from America in 1827, but it was the L \& MR's Treasurer, Henry Booth, who suggested the multi-tubular boiler to George Stephenson. This was incorporated into a locomotive built by Robert Stephenson for the trials: Rocket was entered by the three men in partnership. The other principal entrants were Novelty, entered by John Braithwaite and John Ericsson, and Sans Pareil, entered by Timothy Hackworth, but only Rocket, driven by George Stephenson, met all the organizers' demands; indeed, it far surpassed them and demonstrated the practicability of the long-distance steam railway. With the opening of the Liverpool \& Manchester Railway in 1830, the age of railways began.Stephenson was active in many aspects. He advised on the construction of the Belgian State Railway, of which the Brussels-Malines section, opened in 1835, was the first all-steam railway on the European continent. In England, proposals to link the L \& MR with the Midlands had culminated in an Act of Parliament for the Grand Junction Railway in 1833: this was to run from Warrington, which was already linked to the L \& MR, to Birmingham. George Stephenson had been in charge of the surveys, and for the railway's construction he and J.U. Rastrick were initially Principal Engineers, with Stephenson's former pupil Joseph Locke under them; by 1835 both Stephenson and Rastrick had withdrawn and Locke was Engineer-in-Chief. Stephenson remained much in demand elsewhere: he was particularly associated with the construction of the North Midland Railway (Derby to Leeds) and related lines. He was active in many other places and carried out, for instance, preliminary surveys for the Chester \& Holyhead and Newcastle \& Berwick Railways, which were important links in the lines of communication between London and, respectively, Dublin and Edinburgh.He eventually retired to Tapton House, Chesterfield, overlooking the North Midland. A man who was self-made (with great success) against colossal odds, he was ever reluctant, regrettably, to give others their due credit, although in retirement, immensely wealthy and full of honour, he was still able to mingle with people of all ranks.[br]Principal Honours and DistinctionsPresident, Institution of Mechanical Engineers, on its formation in 1847. Order of Leopold (Belgium) 1835. Stephenson refused both a knighthood and Fellowship of the Royal Society.Bibliography1815, jointly with Ralph Dodd, British patent no. 3,887 (locomotive drive by connecting rods directly to the wheels).1817, jointly with William Losh, British patent no. 4,067 (steam springs for locomotives, and improvements to track).Further ReadingL.T.C.Rolt, 1960, George and Robert Stephenson, Longman (the best modern biography; includes a bibliography).S.Smiles, 1874, The Lives of George and Robert Stephenson, rev. edn, London (although sycophantic, this is probably the best nineteenthcentury biography).PJGR -
14 Haynes, Elwood
[br]b. 14 October 1857 Portland, Indiana, USAd. 13 April 1925 Kokomo, Indiana, USA[br]American inventor ofStellite cobalt-based alloys, early motor-car manufacturer and pioneer in stainless steels.[br]From his early years, Haynes was a practising Presbyterian and an active prohibitionist. He graduated in 1881 at Worcester, Massachusetts, and a spell of teaching in his home town was interrupted in 1884–5 while he attended the Johns Hopkins University in Baltimore. In 1886 he became permanently diverted by the discovery of natural gas in Portland. He was soon appointed Superintendent of the local gas undertaking, and then in 1890 he was hired by the Indiana Natural Gas \& Oil Company. While continuing his gas-company employment until 1901, Haynes conducted numerous metallurgical experiments. He also designed an automobile: this led to the establishment of the Haynes- Apperson Company at Kokomo as one of the earliest motor-car makers in North America. From 1905 the firm traded as the Haynes Automobile Company, and before its bankruptcy in 1924 it produced more than 50,000 cars. After 1905, Haynes found the first "Stellite" alloys of cobalt and chromium, and in 1910 he was publicizing the patented material. He then discovered the valuable hardening effect of tungsten, and in 1912 began applying the "improved" Stellite to cutting tools. Three years later, the Haynes Stellite Company was incorporated, with Haynes as President, to work the patents. It was largely from this source that Haynes became a millionaire in 1920. In April 1912, Haynes's attempt to patent the use of chromium with iron to render the product rustless was unsuccessful. However, he re-applied for a US patent on 12 March 1915 and, although this was initially rejected, he persevered and finally obtained recognition of his modified claim. The American Stainless Steel Company licensed the patents of Brearley and Haynes jointly in the USA until the 1930s.[br]Principal Honours and DistinctionsJohn Scott Medal 1919 (awarded for useful inventions).BibliographyHaynes was the author of more than twenty published papers and articles, among them: 1907, "Materials for automobiles", Proceedings of the American Society of MechanicalEngineers 29:1,597–606; 1910, "Alloys of nickel and cobalt with chromium", Journal of Industrial Engineeringand Chemistry 2:397–401; 1912–13, "Alloys of cobalt with chromium and other metals", Transactions of the American Institute of 'Mining Engineers 44:249–55;1919–20, "Stellite and stainless steel", Proceedings of the Engineering Society of WestPennsylvania 35:467–74.1 April 1919, US patent no. 1,299,404 (stainless steel).The four US patents worked by the Haynes Stellite Company were: 17 December 1907, patent no. 873,745.1 April 1913, patent no. 1,057,423.1 April 1913, patent no. 1,057, 828.17 August 1915, patent no. 1,150, 113.Further ReadingR.D.Gray, 1979, Alloys and Automobiles. The Life of Elwood Haynes, Indianapolis: Indiana Historical Society (a closely documented biography).JKA -
15 Wolseley, Frederick York
[br]b. 1837 Co. Dublin, Irelandd. 1899 England[br]Irish inventor who developed the first practical sheep shears and was also involved in the development of the car which bore his name.[br]The credit for the first design of sheep shears lies with James Higham, who patented the idea in 1868. However, its practical and commercial success lay in the work of a number of people, to each of whom Frederick Wolseley provides the connecting link.One of three brothers, he emigrated to Australia in 1854 and worked in New South Wales for five years. In 1867 he produced a working model of mechanical sheep shears, but it took a further five years before he actually produced a machine, whilst working as Manager of a sheep station in Victoria. In the intervening period it is possible that he visited America and Britain. On returning to Australia in 1872 he and Robert Savage produced another working model in a workshop in Melbourne. Four years later, by which time Wolseley had acquired the "Euroka" sheep station at Walgett, they tested the model and in 1877 acquired joint patent rights. The machine was not successful, and in 1884 another joint patent, this time with Robert Pickup, was taken out on a cog-gear universal joint. Development was to take several more years, during which a highly skilled blacksmith by the name of George Gray joined the team. It is likely that he was the first person to remove a fleece from a sheep mechanically. Finally, the last to be involved in the development of the shears was another Englishman, John Howard, who emigrated to Australia in 1883 with the intention of developing a shearing machine based on his knowledge of existing horse clippers. Wolseley purchased Howard's patent rights and gave him a job. The first public demonstration of the shears was held at the wool stores of Goldsborough \& Co. of Melbourne. Although the hand shearers were faster, when the three sheep that had been clipped by them were re-shorn using the mechanical machine, a further 2 lb (900 g) of wool was removed.Wolseley placed the first manufacturing order with A.P.Parks, who employed a young Englishman by the name of Herbert Austin. A number of improvements to the design were suggested by Austin, who acquired patents and assigned them to Wolseley in 1895 in return for shares in the company. Austin returned to England to run the Wolseley factory in Birmingham. He also built there the first car to carry the Wolseley name, and subsequently opened a car factory carrying his own name.Wolseley resigned as Managing Director of the company in 1894 and died five years later.[br]Further ReadingF.Wheelhouse, 1966, Digging Stock to Rotary Hoe: Men and Machines in Rural Australia (provides a detailed account of Wolseley's developments).APBiographical history of technology > Wolseley, Frederick York
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16 Lanchester, Frederick William
[br]b. 28 October 1868 Lewisham, London, Englandd. 8 March 1946 Birmingham, England[br]English designer and builder of the first all-British motor car.[br]The fourth of eight children of an architect, he spent his childhood in Hove and attended a private preparatory school, from where, aged 14, he went to the Hartley Institution (the forerunner of Southampton University). He was then granted a scholarship to the Royal College of Science, South Kensington, and also studied practical engineering at Finsbury Technical College, London. He worked first for a draughtsman and pseudo-patent agent, and was then appointed Assistant Works Manager of the Forward Gas Engine Company of Birmingham, with sixty men and a salary of £1 per week. He was then aged 21. His younger brother, George, was apprenticed to the same company. In 1889 and 1890 he invented a pendulum governor and an engine starter which earned him royalties. He built a flat-bottomed river craft with a stern paddle-wheel and a vertical single-cylinder engine with a wick carburettor of his own design. From 1892 he performed a number of garden experiments on model gliders relating to problems of lift and drag, which led him to postulate vortices from the wingtips trailing behind, much of his work lying behind the theory of modern aerodynamics. The need to develop a light engine for aircraft led him to car design.In February 1896 his first experimental car took the road. It had a torsionally rigid chassis, a perfectly balanced and almost noiseless engine, dynamically stable steering, epicyclic gear for low speed and reverse with direct drive for high speed. It turned out to be underpowered and was therefore redesigned. Two years later an 8 hp, two-cylinder flat twin appeared which retained the principle of balancing by reverse rotation, had new Lanchester valve-gear and a new method of ignition based on a magneto generator. For the first time a worm and wheel replaced chain-drive or bevel-gear transmission. Lanchester also designed the machinery to make it. The car was capable of about 18 mph (29 km/h): future cars of his travelled at twice that speed. From 1899 to 1904 cars were produced for sale by the Lanchester Engine Company, which was formed in 1898. The company had to make every component except the tyres. Lanchester gave up the managership but remained as Chief Designer, and he remained in this post until 1914.In 1907–8 his two-volume treatise Aerial Flight was published; it included consideration of skin friction, boundary-layer theory and the theory of stability. In 1909 he was appointed to the Government's Committee for Aeronautics and also became a consultant to the Daimler Company. At the age of 51 he married Dorothea Cooper. He remained a consultant to Daimler and worked also for Wolseley and Beardmore until 1929 when he started Lanchester Laboratories, working on sound reproduction. He also wrote books on relativity and on the theory of dimensions.[br]Principal Honours and DistinctionsFRS.Bibliographybht=1907–8, Aerial Flight, 2 vols.Further ReadingP.W.Kingsford, 1966, F.W.Lanchester, Automobile Engineer.E.G.Semler (ed.), 1966, The Great Masters. Engineering Heritage, Vol. II, London: Institution of Mechanical Engineers/Heinemann.IMcNBiographical history of technology > Lanchester, Frederick William
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17 Reichenbach, Georg Friedrich von
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering, Photography, film and optics, Public utilities[br]b. 24 August 1772 Durlach, Baden, Germanyd. 21 May 1826 Munich, Germany[br]German engineer.[br]While he was attending the Military School at Mannheim, Reichenbach drew attention to himself due to the mathematical instruments that he had designed. On the recommendation of Count Rumford in Munich, the Bavarian government financed a two-year stay in Britain so that Reichenbach could become acquainted with modern mechanical engineering. He returned to Mannheim in 1793, and during the Napoleonic Wars he was involved in the manufacture of arms. In Munich, where he was in the service of the Bavarian state from 1796, he started producing precision instruments in his own time. His basic invention was the design of a dividing machine for circles, produced at the end of the eighteenth century. The astronomic and geodetic instruments he produced excelled all the others for their precision. His telescopes in particular, being perfect in use and of solid construction, soon brought him an international reputation. They were manufactured at the MathematicMechanical Institute, which he had jointly founded with Joseph Utzschneider and Joseph Liebherr in 1804 and which became a renowned training establishment. The glasses and lenses were produced by Joseph Fraunhofer who joined the company in 1807.In the same year he was put in charge of the technical reorganization of the salt-works at Reichenhall. After he had finished the brine-transport line from Reichenhall to Traunstein in 1810, he started on the one from Berchtesgaden to Reichenhall which was an extremely difficult task because of the mountainous area that had to be crossed. As water was the only source of energy available he decided to use water-column engines for pumping the brine in the pipes of both lines. Such devices had been in use for pumping purposes in different mining areas since the middle of the eighteenth century. Reichenbach knew about the one constructed by Joseph Karl Hell in Slovakia, which in principle had just been a simple piston-pump driven by water which did not work satisfactorily. Instead he constructed a really effective double-action water-column engine; this was a short time after Richard Trevithick had constructed a similar machine in England. For the second line he improved the system and built a single-action pump. All the parts of it were made of metal, which made them easy to produce, and the pumps proved to be extremely reliable, working for over 100 years.At the official opening of the line in 1817 the Bavarian king rewarded him generously. He remained in the state's service, becoming head of the department for roads and waterways in 1820, and he contributed to the development of Bavarian industry as well as the public infrastructure in many ways as a result of his mechanical skill and his innovative engineering mind.[br]Further ReadingBauernfeind, "Georg von Reichenbach" Allgemeine deutsche Biographie 27:656–67 (a reliable nineteenth-century account).W.Dyck, 1912, Georg v. Reichenbach, Munich.K.Matschoss, 1941, Grosse Ingenieure, Munich and Berlin, 3rd edn. 121–32 (a concise description of his achievements in the development of optical instruments and engineering).WKBiographical history of technology > Reichenbach, Georg Friedrich von
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18 Lartigue, Charles François Marie-Thérèse
[br]b. 1834 Toulouse, France d. 1907[br]French engineer and businessman, inventor of the Lartigue monorail.[br]Lartigue worked as a civil engineer in Algeria and while there invented a simple monorail for industrial or agricultural use. It comprised a single rail carried on trestles; vehicles comprised a single wheel with two tubs suspended either side, like panniers. These were pushed or pulled by hand or, occasionally, hauled by mule. Such lines were used in Algerian esparto-grass plantations.In 1882 he patented a monorail system based on this arrangement, with important improvements: traction was to be mechanical; vehicles were to have two or four wheels and to be able to be coupled together; and the trestles were to have, on each side, a light guide rail upon which horizontal rollers beneath the vehicles would bear. Early in 1883 the Lartigue Railway Construction Company was formed in London and two experimental prototype monorails were subsequently demonstrated in public. One, at the Paris Agricultural Exhibition, had an electric locomotive that was built in two parts, one either side of the rail to maintain balance, hauling small wagons. The other prototype, in London, had a small, steam locomotive with two vertical boilers and was designed by Anatole Mallet. By now Lartigue had become associated with F.B. Behr. Behr was Managing Director of the construction company and of the Listowel \& Ballybunion Railway Company, which obtained an Act of Parliament in 1886 to built a Lartigue monorail railway in the South West of Ireland between those two places. Its further development and successful operation are described in the article on Behr in this volume.A much less successful attempt to establish a Lartigue monorail railway took place in France, in the départment of Loire. In 1888 the council of the département agreed to a proposal put forward by Lartigue for a 10 1/2 mile (17 km) long monorail between the towns of Feurs and Panissières: the agreement was reached on the casting vote of the Chairman, a contact of Lartigue. A concession was granted to successive companies with which Lartigue was closely involved, but construction of the line was attended by muddle, delay and perhaps fraud, although it was completed sufficiently for trial trains to operate. The locomotive had two horizontal boilers, one either side of the track. But the inspectors of the department found deficiencies in the completeness and probable safety of the railway; when they did eventually agree to opening on a limited scale, the company claimed to have insufficient funds to do so unless monies owed by the department were paid. In the end the concession was forfeited and the line dismantled. More successful was an electrically operated Lartigue mineral line built at mines in the eastern Pyrenees.It appears to have reused equipment from the electric demonstration line, with modifications, and included gradients as steep as 1 in 12. There was no generating station: descending trains generated the electricity to power ascending ones. This line is said to have operated for at least two years.[br]Bibliography1882, French patent no. 149,301 (monorail system). 1882, British patent no. 2,764 (monorail system).Further ReadingD.G.Tucker, 1984, "F.B.Behr's development of the Lartigue monorail", Transactions of the Newcomen Society 55 (describes Lartigue and his work).P.H.Chauffort and J.-L.Largier, 1981, "Le monorail de Feurs à Panissières", Chemin defer régionaux et urbains (magazine of the Fédération des Amis des Chemins de FerSecondaires) 164 (in French; describes Lartigue and his work).PJGRBiographical history of technology > Lartigue, Charles François Marie-Thérèse
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19 Moulton, Alexander
[br]b. 9 April 1920 Stratford-on-Avon[br]English inventor of vehicle suspension systems and the Moulton bicycle.[br]He spent his childhood at The Hall in Bradfordon-Avon. He was educated at Marlborough College, and in 1937 was apprenticed to the Sentinel Steam Wagon Company of Shrewsbury. About that same time he went to King's College, Cambridge, where he took the Mechanical Sciences Tripos. It was then wartime, and he did research on aero-engines at the Bristol Aeroplane Company, where he became Personal Assistant to Sir Roy Fedden. He left Bristol's in 1945 to join his family firm, Spencer \& Moulton, of which he eventually became Technical Director and built up the Research Department. In 1948 he invented his first suspension unit, the "Flexitor", in which an inner shaft and an outer shell were separated by an annular rubber body which was bonded to both.In 1848 his great-grandfather had founded the family firm in an old woollen mill, to manufacture vulcanized rubber products under Charles Goodyear's patent. The firm remained a family business with Spencer's, consultants in railway engineering, until 1956 when it was sold to the Avon Rubber Company. He then formed Moulton Developments to continue his work on vehicle suspensions in the stables attached to The Hall. Sponsored by the British Motor Corporation (BMC) and the Dunlop Rubber Company, he invented a rubber cone spring in 1951 which was later used in the BMC Mini (see Issigonis, Sir Alexander Arnold Constantine): by 1994 over 4 million Minis had been fitted with these springs, made by Dunlop. In 1954 he patented the Hydrolastic suspension system, in which all four wheels were independently sprung with combined rubber springs and damper assembly, the weight being supported by fluid under pressure, and the wheels on each side being interconnected, front to rear. In 1962 he formed Moulton Bicycles Ltd, having designed an improved bicycle system for adult use. The conventional bicycle frame was replaced by a flat-sided oval steel tube F-frame on a novel rubber front and rear suspension, with the wheel size reduced to 41 cm (16 in.) with high-pressure tyres. Raleigh Industries Ltd having refused his offer to produce the Moulton Bicycle under licence, he set up his own factory on his estate, producing 25,000 bicycles between 1963 and 1966. In 1967 he sold out to Raleigh and set up as Bicycle Consultants Ltd while continuing the suspension development of Moulton Developments Ltd. In the 1970s the combined firms employed some forty staff, nearly 50 per cent of whom were graduates.He won the Queen's Award for Industry in 1967 for technical innovation in Hydrolastic car suspension and the Moulton Bicycle. Since that time he has continued his innovative work on suspensions and the bicycle. In 1983 he introduced the AM bicycle series of very sophisticated space-frame design with suspension and 43 cm (17 in.) wheels; this machine holds the world speed record fully formed at 82 km/h (51 mph). The current Rover 100 and MGF use his Hydragas interconnected suspension. By 1994 over 7 million cars had been fitted with Moulton suspensions. He has won many design awards and prizes, and has been awarded three honorary doctorates of engineering. He is active in engineering and design education.[br]Principal Honours and DistinctionsQueen's Award for Industry 1967; CBE; RDI. Fellow of the Royal Academy of Engineering.Further ReadingP.R.Whitfield, 1975, Creativity in Industry, London: Penguin Books.IMcN -
20 Reynolds, Edwin
[br]b. 1831 Mansfield, Connecticut, USAd. 1909 Milwaukee, Wisconsin, USA[br]American contributor to the development of the Corliss valve steam engine, including the "Manhattan" layout.[br]Edwin Reynolds grew up at a time when formal engineering education in America was almost unavailable, but through his genius and his experience working under such masters as G.H. Corliss and William Wright, he developed into one of the best mechanical engineers in the country. When he was Plant Superintendent for the Corliss Steam Engine Company, he built the giant Corliss valve steam engine displayed at the 1876 Centennial Exhibition. In July 1877 he left the Corliss Steam Engine Company to join Edward Allis at his Reliance Works, although he was offered a lower salary. In 1861 Allis had moved his business to the Menomonee Valley, where he had the largest foundry in the area. Immediately on his arrival with Allis, Reynolds began desig-ning and building the "Reliance-Corliss" engine, which becamea symbol of simplicity, economy and reliability. By early 1878 the new engine was so successful that the firm had a six-month backlog of orders. In 1888 he built the first triple-expansion waterworks-pumping engine in the United States for the city of Milwaukee, and in the same year he patented a new design of blowing engine for blast furnaces. He followed this in March 1892 with the first steam engine sets coupled directly to electric generators when Allis-Chalmers contracted to build two Corliss cross-compound engines for the Narragansett Light Company of Providence, Rhode Island. In 1893, one of the impressive attractions at the World's Columbian Exposition in Chicago was the 3,000 hp (2,200 kW) quadruple-expansion Reynolds-Corliss engine designed by Reynolds, who continued to make significant improvements and gained worldwide recognition of his outstanding achievements in engine building.Reynolds was asked to go to New York in 1898 for consultation about some high-horsepower engines for the Manhattan transport system. There, 225 railway locomotives were to be replaced by electric trains, which would be supplied from one generating station producing 60,000 hp (45,000 kW). Reynolds sketched out his ideas for 10,000 hp (7,500 kW) engines while on the train. Because space was limited, he suggested a four-cylinder design with two horizontal-high-pressure cylinders and two vertical, low-pressure ones. One cylinder of each type was placed on each side of the flywheel generator, which with cranks at 135° gave an exceptionally smooth-running compact engine known as the "Manhattan". A further nine similar engines that were superheated and generated three-phase current were supplied in 1902 to the New York Interborough Rapid Transit Company. These were the largest reciprocating steam engines built for use on land, and a few smaller ones with a similar layout were installed in British textile mills.[br]Further ReadingConcise Dictionary of American Biography, 1964, New York: C.Scribner's Sons (contains a brief biography).R.L.Hills, 1989, Power from Steam. A History of the Stationary Steam Engine, Cambridge University Press (provides a brief account of the Manhattan engines) Part of the information for this biography is derived from a typescript in the Smithsonian Institution, Washington, DC: T.H.Fehring, "Technological contributions of Milwaukee's Menomonee Valley industries".RLH
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