subject+terms

Blackett, William Cuthbert

SUBJECT AREA: Mining and extraction technology

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b. 18 November 1859 Durham, England

d. 13 June 1935 Durham, England

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English mine manager, expert in preventing mine explosions and inventor of a coal-face conveyor.

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After leaving Durham college of Physical Science and having been apprenticed in different mines, he received the certificate for colliery managers and subsequently, in 1887, was appointed Manager of all the mines of Charlaw and Sacriston collieries in Durham. He remained in this position for the rest of his working life.

Frequent explosions in mines led him to investigate the causes. He was among the first to recognize the role contributed by coal-dust on mine roads, pioneered the use of inert rock-or stone-dust to render the coal-dust harmless and was the originator of many technical terms on the subject. He contributed many papers on explosion and was appointed a member of many advisory committees on prevention measures. A liquid-air rescue apparatus, designed by him and patented in 1910, was installed in various parts of the country.

Blackett also developed various new devices in mining machinery. He patented a wire-rope socket which made use of a metal wedge; invented a rotary tippler driven by frictional contact instead of gearing and which stopped automatically; and he designed a revolving cylindrical coal-washer, which also gained interest among German mining engineers. His most important invention, the first successful coal-face conveyor, was patented in 1902. It was driven by compressed air and consisted of a trough running along the length of the race through which ran an endless scraper chain. Thus fillers cast the coal into the trough, and the scraper chain drew it to the main gate to be loaded into trams.

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Principal Honours and Distinctions

Knight of Grace of the Order of St John of Jerusalem. OBE. Honorary MSc University of Durham; Honorary LLD University of Birmingham. Honorary Member, Institution of Mining and Metallurgy. Honorary Member, American Institute of Mining and Metallurgical Engineers. Royal Humane Society Medal.

Further Reading

Transactions of the Institution of Mining Engineers (1934–5) 89:339–41.

Mining Association of Great Britain (ed.), 1924, Historical Review of Coal Mining London (describes early mechanical devices for the extraction of coal).

WK

Taylor, John

SUBJECT AREA: Medical technology

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b. 16 August 1703 Norwich, England

d. 17 September 1772 Prague, Bohemia

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English oculist and exponent of surgical treatment of squint and cataract.

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In 1722, employed as an apothecary's assistant, he studied surgery and especially diseases of the eye under Cheselden at St Thomas's Hospital, London. He returned to Norwich to practise, but in 1727 he assumed the role of itinerant surgeon oculist, with a particular reputation for putting eyes straight; at first he covered the major part of the British Isles and then he extended his activities to Europe.

He obtained MDs from Basle in 1733, and from Liège and Cologne in 1734. In 1736 he was appointed Oculist to George II. It is likely that he was responsible for Johann Sebastian Bach's blindness, and Gibbon was one of his patients. The subject of considerable obloquy on account of his self-advertisement in the crudest and most bombastic terms, it is none the less certain that he had developed a technique, probably related to couching, which was considerably in advance of that of other practitioners and at least offered a prospect of assistance where none had been available.

Dr Johnson declared him "an instance of how far impudence will carry ignorance". Without justification, he styled himself "Chevalier". He is said, not improbably having regard to his age, to have become blind himself later in life. His son carried on his practice.

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Bibliography

1727, An Account of the Mechanism of the Eye, Norwich.

1736, Treatise on the Chrystalline Humour of the Human Eye, London. 1739, De vera causi strabismi, Lisbon.

Further Reading

1761, The History of the Travels and Adventures of the Chevalier John Taylor, Ophthalmiater, London.

MG

prema uslovima i odredbama ugovora

• subject to terms and conditions of the contract

в соответствии со сроками и условиями

subject to the terms and conditions

в зависимости от условий

subject to terms and conditions

с соблюдением всех условий, положений и оговорок

subject to all conditions, terms and clauses

на всех условиях

subject to the terms and conditions

Agricola, Georgius (Georg Bauer)

SUBJECT AREA: Metallurgy

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b. 24 March 1494 Glauchau, Saxony

d. 21 November 1555 Chemnitz, Germany

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German metallurgist, who wrote the book De Re Metallica under the latinized version of his name.

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Agricola was a physician, scientist and metallurgist of note and it was this which led to the publication of De Re Metallica. He studied at Leipzig University and between 1518 and 1522 he was a school teacher in Zwickau. Eventually he settled as a physician in Chemnitz. Later he continued his medical practice at Joachimstal in the Erzgebirge. This town was newly built to serve the mining community in what was at the time the most important ore-mining field in both Germany and Europe.

As a physician in the sixteenth century he would naturally have been concerned with the development of medicines, which would have led him to research the medical properties of ores and base metals. He studied the mineralogy of his area, and the mines, and the miners who were working there. He wrote several books in Latin on geology and mineralogy. His important work during that period was a glossary of mineralogical and mining terms in both Latin and German. It is, however, De Re Metallica for which he is best known. This large volume contains twelve books which deal with mining and metallurgy, including an account of glassmaking. Whilst one can understand the text of this book very easily, the quality of the illustrative woodcuts should not be neglected. These illustrations detail the mines, furnaces, forges and the plant associated with them, unfortunately the name of the artist is unknown. The importance of the work lies in the fact that it is an assemblage of information on all the methods and practices current at that time. The book was clearly intended as a textbook of mining and mineralogy and as such it would have been brought to England by German engineers when they were employed by the Mines Royal in the Keswick area in the late sixteenth century. In addition to his studies in preparation for De Re Metallica, Agricola was an "adventurer" holding shares in the Gottesgab mine in the Erzegebirge.

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Principal Honours and Distinctions Bibliography

1556, De Re Metallica, Basel; 1912, trans. H. Hoover and L.H.Hoover, London.

KM

Behr, Fritz Bernhard

SUBJECT AREA: Land transport, Railways and locomotives

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b. 9 October 1842 Berlin, Germany

d. 25 February 1927

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German (naturalized British in 1876) engineer, promoter of the Lartigue monorail system.

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Behr trained as an engineer in Britain and had several railway engineering appointments before becoming associated with C.F.M.-T. Lartigue in promoting the Lartigue monorail system in the British Isles. In Lartigue's system, a single rail was supported on trestles; vehicles ran on the rail, their bodies suspended pannier-fashion, stabilized by horizontal rollers running against light guide rails fixed to the sides of the trestles. Behr became Managing Director of the Listowel \& Ballybunion Railway Company, which in 1888 opened its Lartigue system line between those two places in the south-west of Ireland. Three locomotives designed by J.T.A. Mallet were built for the line by Hunslet Engine Company, each with two horizontal boilers, one either side of the track. Coaches and wagons likewise were in two parts. Technically the railway was successful, but lack of traffic caused the company to go bankrupt in 1897: the railway continued to operate until 1924.

Meanwhile Behr had been thinking in terms far more ambitious than a country branch line. Railway speeds of 150mph (240km/h) or more then lay far in the future: engineers were uncertain whether normal railway vehicles would even be stable at such speeds. Behr was convinced that a high-speed electric vehicle on a substantial Lartigue monorail track would be stable. In 1897 he demonstrated such a vehicle on a 3mile (4.8km) test track at the Brussels International Exhibition. By keeping the weight of the motors low, he was able to place the seats above rail level. Although the generating station provided by the Exhibition authorities never operated at full power, speeds over 75mph (120 km/h) were achieved.

Behr then promoted the Manchester-Liverpool Express Railway, on which monorail trains of this type running at speeds up to 110mph (177km/h) were to link the two cities in twenty minutes. Despite strong opposition from established railway companies, an Act of Parliament authorizing it was made in 1901. The Act also contained provision for the Board of Trade to require experiments to prove the system's safety. In practice this meant that seven miles of line, and a complete generating station to enable trains to travel at full speed, must be built before it was known whether the Board would give its approval for the railway or not. Such a condition was too severe for the scheme to attract investors and it remained stillborn.

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Further Reading

H.Fayle, 1946, The Narrow Gauge Railways of Ireland, Greenlake Publications, Part 2, ch. 2 (describes the Listowel \& Ballybunion Railway and Behr's work there).

D.G.Tucker, 1984, "F.B.Behr's development of the Lartigue monorail", Transactions of

the Newcomen Society 55 (covers mainly the high speed lines).

See also: Brennan, Louis

PJGR

Case, Jerome Increase

SUBJECT AREA: Agricultural and food technology

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b. 1819 Williamstown, Oswego County, New York, USA

d. 1891 USA

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American manufacturer and founder of the Case company of agricultural engineers.

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J.I.Case was the son of a former and began his working life operating the family's Groundhog threshing machine. He moved into contract threshing, and used the money he earned to pay his way through a business academy. He became the agent for the Groundhog thresher in his area and at the age of 23 decided to move west, taking six machines with him. He sold five of these to obtain working capital, and in 1842 moved from Williamstown, New York, to Rochester, Wisconsin, where he established his manufacturing company. He produced the first combined thresher-winnower in the US in 1843. Two years later he moved to Racine, on the shores of Lake Michigan in the same state. Within four years the Case company became Racine's biggest company and largest employer, a position it was to retain into the twentieth century. As early as 1860 Case was shipping threshing machines around the Horn to California.

Apart from having practical expertise Case was also a skilled demonstrator, and it was this combination which resulted in the sure growth of his company. In 1869 he produced his first portable steam engine and in 1876 his first traction engine. By the mid 1870s he was selling a significant proportion of the machines in use in America. By 1878 Case threshing machines had penetrated the European market, and in 1885 sales to South America began. Case also became the world's largest manufacturer of steam engines.

J.I.Case himself, whilst still actively involved with the company, also became involved in politics. He was Mayor of Racine for three terms and State Senator for two. He was also President of the Manufacturers' National Bank of Racine and Founder of the First National Bank of Burlington. He founded the Wisconsin Academy of Science, Arts and Letters and was President of the Racine County Agricultural Society. He had time for sport and was owner of the world's all-time champion trotter-pacer.

Continued expansion of the company after J.I. Case's death led eventually to its acquisition by Tenneco in 1967, and in 1985 the company took over International Harvester. As Case I.H. it continues to produce a full range of agricultural, earth-moving and heavy-transport equipment.

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Further Reading

Despite the size and importance of the company he created, very little has been written about Case. On particular anniversaries the company has produced celebratory publications, and surprisingly these still seem to be the main source of information about him.

R.B.Gray, 1975, The Agricultural Tractor 1855–1950, American Society of Agricultural Engineers (traces the history of power on the farm, in which Case and his machines played such an important role).

AP

Doane, Thomas

SUBJECT AREA: Civil engineering, Mechanical, pneumatic and hydraulic engineering, Railways and locomotives

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b. 20 September 1821 Orleans, Massachusetts, USA

d. 22 October 1897 West Townsend, Massachusetts, USA

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American mechanical engineer.

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The son of a lawyer, he entered an academy in Cape Cod and, at the age of 19, the English Academy at Andover, Massachusetts, for five terms. He was then in the employ of Samuel L. Fenton of Charlestown, Massachusetts. He served a three-year apprenticeship, then went to the Windsor White River Division of the Vermont Central Railroad. He was Resident Engineer of the Cheshire Railroad at Walpote, New Hampshire, from 1847 to 1849, and then worked in independent practice as a civil engineer and surveyor until his death. He was involved with nearly all the railroads running out of Boston, especially the Boston \& Maine. In April 1863 he was appointed Chief Engineer of the Hoosac Tunnel, which was already being built. He introduced new engineering methods, relocated the line of the tunnel and achieved great accuracy in the meeting of the borings. He was largely responsible for the development in the USA of the advanced system of tunnelling with machinery and explosives, and pioneered the use of compressed air in the USA. In 1869 he was Chief Engineer of the Burlington \& Missouri River Railroad in Nebraska, laying down some 240 miles (386 km) of track in four years. During this period he became interested in the building of a Congregational College at Crete, Nebraska, for which he gave the land and which was named after him. In 1873 he returned to Charlestown and was again appointed Chief Engineer of the Hoosac Tunnel. At the final opening of the tunnel on 9 February 1875 he drove the first engine through. He remained in charge of construction for a further two years.

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Principal Honours and Distinctions

President, School of Civil Engineers.

Further Reading

Duncan Malone (ed.), 1932–3, Dictionary of American Biography, New York: Charles Scribner.

IMcN

Dörell, Georg Ludwig Wilhelm

SUBJECT AREA: Mining and extraction technology

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b. 17 December 1793 Clausthal, Harz, Germany

d. 30 October 1854 Zellerfeld, Harz, Germany

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German mining engineer who introduced the miner's elevator into the Harz Mountains.

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After studying at the Freiberg Mining Academy he returned to his home region to serve in the mining administration, first at Clausthal. In 1848 he became an inspector of mines in Zellerfeld. He had become aware that in the early nineteenth century, when 500 m (1,640 ft) shafts were no longer unusual, devices other than ladders were needed for access to mines. Dörell found out that miners, in terms of physical strength, had to consume almost one-third more of their energy to climb up the shaft than they had to spend at work during the shift in the mine. Accordingly, in 1833 he constructed the miner's elevator. Two timbered bars, similar to those used for pumps, were installed in the shaft and were driven by water-wheel and moved in opposite directions. They were placed at such a distance from each other that the miners could easily step from one to the other in order to go up or down the shaft as desired.

Dörell's elevators worked with great success and their use soon became widespread among Central European mining districts. Their use is particularly associated with Cornish tin-mines, where several such elevators operated over considerable distances.

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Bibliography

1837, "Über die seit dem Jahre 1833 beim Oberharzischen Bergbau angewendeten Fahrmaschinen", Die Bergwerks-Verwaltung des Hannoverschen Ober-Harzes in den Jahren 1831–1836, ed. W.A.J.Albert, Berlin, pp. 199–214.

Further Reading

C.Bartels, 1992, Vom frühneuzeitlichen Montangewerbe zur Bergbauindustrie. Erzbergbau im Oberharz 1635–1880, Bochum: Deutsches Bergbau-Museum, esp. pp. 382–411 (elaborates upon the context of contemporary technological innovations in Harz ore mining).

WK

Ducos du Hauron, Arthur-Louis

SUBJECT AREA: Photography, film and optics

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b. 1837 Langon, Bordeaux, France

d. 19 August 1920 Agen, France

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French scientist and pioneer of colour photography.

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The son of a tax collector, Ducos du Hauron began researches into colour photography soon after the publication of Clerk Maxwell's experiment in 1861. In a communication sent in 1862 for presentation at the Académie des Sciences, but which was never read, he outlined a number of methods for photography of colours. Subsequently, in his book Les Couleurs en photographie, published in 1869, he outlined most of the principles of additive and subtractive colour photography that were later actually used. He covered additive processes, developed from Clerk Maxwell's demonstrations, and subtractive processes which could yield prints. At the time, the photographic materials available prevented the processes from being employed effectively. The design of his Chromoscope, in which transparent reflectors could be used to superimpose three additive images, was sound, however, and formed the basis of a number of later devices. He also proposed an additive system based on the use of a screen of fine red, yellow and blue lines, through which the photograph was taken and viewed. The lines blended additively when seen from a certain distance. Many years later, in 1907, Ducos du Hauron was to use this principle in an early commercial screen-plate process, Omnicolore. With his brother Alcide, he published a further work in 1878, Photographie des Couleurs, which described some more-practical subtractive processes. A few prints made at this time still survive and they are remarkably good for the period. In a French patent of 1895 he described yet another method for colour photography. His "polyfolium chromodialytique" involved a multiple-layer package of separate red-, green-and blue-sensitive materials and filters, which with a single exposure would analyse the scene in terms of the three primary colours. The individual layers would be separated for subsequent processing and printing. In a refined form, this is the principle behind modern colour films. In 1891 he patented and demonstrated the anaglyph method of stereoscopy, using superimposed red and green left and right eye images viewed through green and red filters. Ducos du Hauron's remarkable achievement was to propose theories of virtually all the basic methods of colour photography at a time when photographic materials were not adequate for the purpose of proving them correct. For his work on colour photography he was awarded the Progress Medal of the Royal Photographic Society in 1900, but despite his major contributions to colour photography he remained in poverty for much of his later life.

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Further Reading

B.Coe, 1978, Colour Photography: The First Hundred Years, London. J.S.Friedman, 1944, History of Colour Photography, Boston. E.J.Wall, 1925, The History of Three-Colour Photography, Boston. See also Cros, Charles.

BC

Dudley, Dud

SUBJECT AREA: Metallurgy

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b. 1599

d. 25 October 1684 Worcester, England

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English ironmaster who drew attention to the need to change from charcoal to coal as a fuel for iron smelting.

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Dudley was the fourth natural son of Edward Sutton, fifth Baron Dudley. In 1619 he was summoned from Balliol College, Oxford, to superintend his father's ironworks at Pensnet in Worcestershire. There had long been concern at the destruction of the forests in order to make charcoal for the smelting of iron ore, and unsuccessful attempts had been made to substitute coal as a fuel. Finding that charcoal was in short supply and coal plentiful near Pensnet, Dudley was stimulated by these attempts to try the process for himself. He claimed to have made good, marketable iron and in 1621 his father obtained a patent from the King to protect his process for thirty-one years. After a serious flood, Dudley moved to Staffordshire and continued his efforts there. In 1639 he was granted a further patent for making iron with coal. Although he probably made some samples of good iron, more by luck than judgement, it is hardly possible that he achieved consistent success. He blamed this on the machinations of other ironmasters. The day that King Charles II landed in England to assume his throne', Dudley petitioned him to renew his patents, but he was refused and he ceased to promote his invention. In 1665, however, he published his celebrated book Metallum Martis, Iron Made with Pit-Coaky Sea-Coale…. In this he described his efforts in general terms, but neither there nor in his patents does he give any technical details of his methods. He implied the use of slack or small coal from the Staffordshire Thick or Ten Yard coal, but this has a sulphur content that would have rendered the iron unusable; in addition, this coal would not have been suitable for converting to coke in order to remove the sulphur. Nevertheless, Dudley recognized the need to change from charcoal to coal as a fuel for iron smelting and drew attention to it, even though he himself achieved little success.

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Further Reading

H.R.Schubert, 1957, History of the British Iron and Steel Industry AD 430 to AD 1775, London: Routledge \& Kegan Paul.

W.K.V.Gale, 1967, The British Iron and Steel Industry: A Technical History, London (provides brief details of Dudley's life in relation to the history of ironmaking).

LRD

Essen, Louis

SUBJECT AREA: Horology

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b. 6 September 1908 Nottingham, England

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English physicist who produced the first practical caesium atomic clock, which was later used to define the second.

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Louis Essen joined the National Physical Laboratory (NPL) at Teddington in 1927 after graduating from London University. He spent his whole working life at the NPL and retired in 1972; his research there was recognized by the award of a DSc in 1948. At NPL he joined a team working on the development of frequency standards using quartz crystals and he designed a very successful quartz oscillator, which became known as the "Essen ring". He was also involved with radio frequency oscillators. His expertise in these fields was to play a crucial role in the development of the caesium clock. The idea of an atomic clock had been proposed by I.I.Rabbi in 1945, and an instrument was constructed shortly afterwards at the National Bureau of Standards in the USA. However, this device never realized the full potential of the concept, and after seeing it on a visit to the USA Essen was convinced that a more successful instrument could be built at Teddington. Assisted by J.V.L.Parry, he commenced work in the spring of 1953 and by June 1955 the clock was working reliably, with an accuracy that was equivalent to one second in three hundred years. This was significantly more accurate than the astronomical observations that were used at that time to determine the second: in 1967 the second was redefined in terms of the value for the frequency of vibration of caesium atoms that had been obtained with this clock.

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Principal Honours and Distinctions

FRS 1960. Clockmakers' Company Tompion Gold Medal 1957. Physical Society C.V.Boys Prize 1957. USSR Academy of Science Popov Gold Medal 1959.

Bibliography

1957, with J.V.L.Parry, "The caesium resonator as a standard of frequency and time", Philosophical Transactions of the Royal Society (Series A) 25:45–69 (the first comprehensive description of the caesium clock).

Further Reading

P.Forman, 1985, "Atomichron: the atomic clock from concept to commercial product", Proceedings of the IEEE 75:1,181–204 (an authoritative critical review of the development of the atomic clock).

N.Cessons (ed.), 1992, The Making of the Modern World, London: Science Museum, pp.

190–1 (contains a short account).

See also: Marrison, Warren Alvin

DV

Halske, Johann Georg

SUBJECT AREA: Electricity, Telecommunications

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b. 30 July 1814 Hamburg, Germany

d. 18 March 1890 Berlin, Germany

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German engineer who introduced precision methods into the manufacture of electrical equipment; co-founder of Siemens \& Halske.

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Halske moved to Berlin when he was a young man, and in 1844 was working for the university, at first independently and then jointly with F. Bötticher, developing and building electric medical appliances. In 1845 he met Werner von Siemens and together they became founder members of the Berlin Physics Society. It was in Halske's workshop that Siemens, assisted by the skill of the former, was able to work out his inventions in telegraphy. In 1847 the two men entered into partnership to manufacture telegraph equipment, laying the foundations of the successful firm of Siemens \& Halske. At the outset, before Werner von Siemens gave up his army career, Halske acted as the sole manager of the firm and was also involved in testing the products. Inventions they developed included electric measuring instruments and railway signalling equipment, and they installed many telegraph lines, notably those for the Russian Government. When gutta-percha became available on the market, the two men soon developed an extrusion process for applying this new material to copper conductors. To the disappointment of Halske, who was opposed to mass production, the firm introduced series production and piece wages in 1857. The expansion of the business, particularly into submarine cable laying, caused some anxiety to Halske, who left the firm on amicable terms in 1867. He then worked for a few years developing the Arts and Crafts Museum in Berlin and became a town councillor.

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Further Reading

S. von Weihr and H.Götzeler, 1983, The Siemens Company. Its Historical Role in the Progress of Electrical Engineering 1847–1983, Berlin (provides a full account).

Neue Deutsche Biographie, 1966, Vol. 7, Berlin, pp. 572–3.

S.von Weiher, 1972–3, "The Siemens brothers, pioneers of the electrical age in Europe", Transactions of the Newcomen Society 45:1–11.

GW

Hurter, Ferdinand

SUBJECT AREA: Photography, film and optics

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b. 15 March 1844 Schaffhausen, Switzerland

d. 5 March 1898

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Swiss chemist who, with Vero Charles Driffield, established the basis of modern sensitometry in England.

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Ferdinand Hurter worked for three years as a dyer's apprentice before entering the Polytechnic in Zurich; he transferred to Heidelberg, where he graduated in 1866. A year later he secured an appointment as a chemist for the British alkali manufacturing company, Gaskell, Deacon \& Co. of Widnes, Cheshire. In 1871 he was joined at the company by the young engineer Vero Charles Driffield, who was to become his co-worker. Driffield had worked for a professional photographer before beginning his engineering apprenticeship and it was in 1876, when Hurter sought to draw on this experience, that the partnership began. At this time the speed of the new gelatine halide dry plates was expressed in terms of the speed of a wet-collodion plate, an almost worthless concept as the speed of a collodion plate was itself variable. Hurter and Driffield sought to place the study of photographic emulsions on a more scientific basis. They constructed an actinometer to measure the intensity of sunlight and in 1890 published the first of a series of papers on the sensitivity of photographic plates. They suggested methods of exposing a plate to lights of known intensities and measuring the densities obtained on development. They were able to plot curves based on density and exposure which became known as the H \& D curve. Hurter and Driffield's work allowed them to express the characteristics of an emulsion with a nomenclature which was soon adopted by British plate manufacturers. From the 1890s onwards most British-made plates were identified with H \& D ratings. Hurter and Driffield's partnership was ended by the former's death in 1898.

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Further Reading

W.B.Ferguson (ed.), 1920, The Photographic Researches of Ferdinand Hurter \& Vero C. Driffield, London: Royal Photographic Society reprinted in facsimile, with a new introd. by W.Clark, 1974, New York (a memorial volume; the most complete account of Hurter and Driffield's work, includes a reprint of all their published papers).

JW

McCormick, Cyrus

SUBJECT AREA: Agricultural and food technology

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b. 1809 Walnut Grove, Virginia, USA

d. 1884 USA

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American inventor of the first functionally and commercially successful reaping machine; founder of the McCormick Company, which was to become one of the founding companies of International Harvester.

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Cyrus McCormick's father, a farmer, began to experiment unsuccessfully with a harvesting machine between 1809 and 1816. His son took up the challenge and gave his first public demonstration of his machine in 1831. It cut a 4 ft swathe, but, wanting to perfect the machine, he waited until 1834 before patenting it, by which time he felt that his invention was threatened by others of similar design. In the same year he entered an article in the Mechanics Magazine, warning competitors off his design. His main rival was Obed Hussey who contested McCormick's claim to the originality of the idea, having patented his own machine six months before McCormick.

A competition between the two machines was held in 1843, the judges favouring McCormick's, even after additional trials were conducted after objections of unfairness from Hussey. The rivalry continued over a number of years, being avidly reported in the agricultural press. The publicity did no harm to reaper sales, and McCormick sold twenty-nine machines in 1843 and fifty the following year.

As the westward settlement movement progressed, so the demand for McCormick's machine grew. In order to be more central to his markets, McCormick established himself in Chicago. In partnership with C.M.Gray he established a factory to produce 500 harvesters for the 1848 season. By means of advertising and offers of credit terms, as well as production-line assembly, McCormick was able to establish himself as sole owner and also control all production, under the one roof. By the end of the decade he dominated reaper production but other developments were to threaten this position; however, foreign markets were appearing at the same time, not least the opportunities of European sales stimulated by the Great Exhibition in 1851. In the trials arranged by the Royal Agricultural Society of England the McCormick machine significantly outperformed that of Hussey's, and as a result McCormick arranged for 500 to be made under licence in England.

In 1874 McCormick bought a half interest in the patent for a wire binder from Charles Withington, a watchmaker from Janesville, Wisconsin, and by 1885 a total of 50,000 wire binders had been built in Chicago. By 1881 McCormick was producing twine binders using Appleby's twine knotter under a licence agreement, and by 1885 the company was producing only twine binders. The McCormick Company was one of the co-founders of the International Harvester Company in 1901.

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Bibliography

1972, The Century of the Reaper, Johnson Reprint (the original is in the New York State Library).

Further Reading

Graeme Quick and Wesley Buchele, 1978, The Grain Harvesters, American Society of Agricultural Engineers (deals in detail with McCormick's developments).

G.H.Wendell, 1981, 150 Years of International Harvester, Crestlink (though more concerned with the machinery produced by International Harvester, it gives an account of its originating companies).

T.W.Hutchinson, 1930, Cyrus Hall McCormick, Seedtime 1809–1856; ——1935, Cyrus Hall McCormick, Harvest 1856–1884 (both attempt to unravel the many claims surrounding the reaper story).

Herbert N.Casson, 1908, The Romance of the Reaper, Doubleday Page (deals with McCormick, Deering and the formation of International Harvester).

AP

Napier (Neper), John

SUBJECT AREA: Electronics and information technology

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b. 1550 Merchiston Castle, Edinburgh, Scotland

d. 4 April 1617 Merchiston Castle, Edinburgh, Scotland

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Scottish mathematician and theological writer noted for his discovery of logarithms, a powerful aid to mathematical calculations.

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Born into a family of Scottish landowners, at the early age of 13 years Napier went to the University of St Andrews in Fife, but he apparently left before taking his degree. An extreme Protestant, he was active in the struggles with the Roman Catholic Church and in 1594 he dedicated to James VI of Scotland his Plaine Discovery of the Whole Revelation of St John, an attempt to promote the Protestant case in the guise of a learned study. About this time, as well as being involved in the development of military equipment, he devoted much of his time to finding methods of simplifying the tedious calculations involved in astronomy. Eventually he realized that by representing numbers in terms of the power to which a "base" number needed to be raised to produce them, it was possible to perform multiplication and division and to find roots, by the simpler processes of addition, substraction and integer division, respectively.

A description of the principle of his "logarithms" (from the Gk. logos, reckoning, and arithmos, number), how he arrived at the idea and how they could be used was published in 1614 under the title Mirifici Logarithmorum Canonis Descriptio. Two years after his death his Mirifici Logarithmorum Canonis Constructio appeared, in which he explained how to calculate the logarithms of numbers and gave tables of them to eight significant figures, a novel feature being the use of the decimal point to distinguish the integral and fractional parts of the logarithm. As originally conceived, Napier's tables of logarithms were calculated using the natural number e(=2.71828…) as the base, not directly, but in effect according to the formula: Naperian logx= 107(log e 107-log e x) so that the original Naperian logarithm of a number decreased as the number increased. However, prior to his death he had readily acceded to a suggestion by Henry Briggs that it would greatly facilitate their use if logarithms were simply defined as the value to which the decimal base 10 needed to be raised to realize the number in question. He was almost certainly also aware of the work of Joost Burgi.

No doubt as an extension of his ideas of logarithms, Napier also devised a means of manually performing multiplication and division by means of a system of rods known as Napier's Bones, a forerunner of the modern slide-rule, which evolved as a result of successive developments by Edmund Gunther, William Oughtred and others. Other contributions to mathematics by Napier include important simplifying discoveries in spherical trigonometry. However, his discovery of logarithms was undoubtedly his greatest achievement.

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Bibliography

Napier's "Descriptio" and his "Constructio" were published in English translation as Description of the Marvelous Canon of Logarithms (1857) and W.R.MacDonald's Construction of the Marvelous Canon of Logarithms (1889), which also catalogues all his works. His Rabdologiae, seu Numerationis per Virgulas Libri Duo (1617) was published in English as Divining Rods, or Two Books of Numbering by Means of Rods (1667).

Further Reading

D.Stewart and W.Minto, 1787, An Account of the Life Writings and Inventions of John Napier of Merchiston (an early account of Napier's work).

C.G.Knott (ed.), 1915, Napier Tercentenary Memorial Volume (the fullest account of Napier's work).

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Ohm, Georg Simon

SUBJECT AREA: Electricity

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b. 16 March 1789 Erlangen, near Nuremberg, Germany

d. 6 July 1854 Munich, Germany

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German physicist who laid the foundations of electrical science with his discovery of Ohm's Law.

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Given the same first name as his father, Johann, at his baptism, Ohm was generally known by the name of Georg to avoid confusion. While still a child he became interested in science and learned many of his basic skills from his father, a mechanical engineer. After basic education he attended the Gymnasium at Erlangen for a year, then in 1805 he entered the University of Erlangen. Probably for financial reasons, he left after three terms in 1806 and obtained a post as a mathematics tutor at a school in Gottstadt, Switzerland, where he may well have begun to experiment with electrical circuits. In 1811 he returned to Erlangen. He appears to have obtained his doctorate in the same year. After studying physics for a year, he became a tutor at the Studienanstalt (girls' secondary school) at Bamberg in Bavaria. There, in 1817, he wrote a book on the teaching of geometry in schools, as a result of which King Freidrich Wilhelm III of Prussia had him appointed Oberlehrer (Senior Master) in Mathematics and Physics at the Royal Consistory in Cologne. He continued his electrical experiments and in 1826 was given a year's leave of absence to concentrate on this work, which culminated the following year in publication of his "Die galvanische Kette", in which he demonstrated his now-famous Law, that the current in a resistor is proportional to the applied voltage and inversely proportional to the resistance. Because he published only a theoretical treatment of his Law, without including the supporting experimental evidence, his conclusions were widely ignored and ridiculed by the eminent German scientists of his day; bitterly disappointed, he was forced to resign his post at the Consistory. Reduced to comparative poverty he took a position as a mathematics teacher at the Berlin Military School. Fortunately, news of his discovery became more widely known, and in 1833 he was appointed Professor at the Nuremberg Polytechnic School. Two years later he was given the Chair of Higher Mathematics at the University of Erlangen and the position of State Inspector of Scientific Education. Honoured by the Royal Society of London in 1841 and 1842, in 1849 he became Professor of Physics at Munich University, apost he held until his death.

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Principal Honours and Distinctions

Royal Society Copley Medal 1841. FRS 1842.

Bibliography

1817, "Grundlinien zu einer zweckmàssigen Behandlung der Geometric als hohern Bildungsmittels an vorbereitenden Lehranstalt".

1827, "Die galvanische Kette, mathematische bearbeit".

Further Reading

F.E.Terman, 1943, Radio Engineers' Handbook, New York: McGraw-Hill, Section 3 (for circuit theory based on Ohm's Law).

See also: Thévénin, Léon Charles

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