(1862-1873)

новая серия сборника решений судебного комитета тайного совета, составитель Мур

Law: Moore's Privy Council Cases (New Series) (1862-1873), Moore's Privy Council Cases, New Series (1862-1873)

новая серия сборника решений судебного комитета тайного совета

Law: Moore's Privy Council Cases (составитель Мур, 1862-1873)

Chaudron, Joseph

SUBJECT AREA: Mining and extraction technology

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b. 29 November 1822 Gosselies, Belgium

d. 16 January 1905 Auderghem, Belgium

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Belgian mining engineer, pioneer in boring shafts.

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In 1842, as a graduate of the Ecole des Mines in Liège, he became a member of the Belgian Corps Royal des Mines, which he left ten years later as Chief Engineer. By that time he had become decisively influential in the Société Anglo-Belge des Mines du Rhin, founded in 1848. After it became the Gelsenkirchen-based Bergwerkgesellschaft Dahlbusch in 1873, he became President of its Board of Directors and remained in this position until his death. Thanks to his outstanding technical and financial abilities, the company developed into one of the largest in the Ruhr coal district.

When K.G. Kind practised his shaft-boring for the company in the early 1850s but did not overcome the difficulty of making the bottom of the bore-hole watertight, Chaudron joined forces with him to solve the problem and constructed a rotary heading which was made watertight with a box stuffed with moss; rings of iron tubing were placed on this as the sinking progressed, effectively blocking off the aquiferous strata as a result of the hydrostatic pressure which helped support the weight of the tubing until it was secured permanently. The Kind-Chaudron system of boring shafts in the full section marked an important advance upon existing methods, and was completely applied for the first time at a coalmine near Mons, Belgium, in 1854–6. In Brussels Chaudron and Kind founded the Société de Fonçage par le Procédé Kind et Chaudron in 1854, and Chaudron was granted a patent the next year. Foreign patents followed and the Kind-Chaudron system was the one most frequently applied in the latter part of the nineteenth century. Altogether, under Chaudron's control, there were more than eighty shafts sunk in wet strata in Germany, Belgium, France and England.

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Bibliography

1853–4, "Notice sur le procédé inventé par l'ingénieur Kind, pour l"établissement des puits de mines', Annales des travaux publics de Belgique 12:327–38.

1862, "Über die nach dem Kindschen Erdbohrverfahren in Belgien ausgefùhrten Schachtbohrarbeiten", Berg-und Hüttenmännische Zeitschrift 21:402−7, 419−21, 444−7.

1867, "Notice sur les travaux exécutés en France, en Belgique et en Westphalie de 1862– 1867", Annales des travaux publics de Belgique 25: 136–45.

1872, "Remplacement d'un cuvelage en bois par un cuvelage en fonte", Annales des

travaux publics de Belgique 30:77–91.

Further Reading

D.Hoffmann, 1962, Acht Jahrzehnte Gefrierverfahren nachPötsch, Essen, pp. 12–18 (evaluates the Kind-Chaudron system as a new era).

W.Kesten, 1952, Geschichte der Bergwerksgesellschaft Dahlbusch, Essen (gives a delineation of the mining company's flourishing as well as the technical measures under his influence).

T.Tecklenburg, 1914, Handbuch der Tiefbohrkunde, 2nd edn, Vol VI, Berlin, pp. 39–58 (provides a detailed description of Chaudron's tubing).

WK

Foyn, Svend

SUBJECT AREA: Ports and shipping

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b. 1809 Tønsberg, Norway

d. after 1873

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Norwegian founder of the modern whaling industry; sea captain and sealer.

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Svend Foyn's background typified the best of the Norwegian merchant marine: good seamanship, deep religious faith and an investigative and adventurous approach to life based on sound commercial judgement. After the period of training normal to his time, Foyn became a shipmaster and then followed the sealer's trade. By the early 1860s he had amassed a considerable sum of money and began to look around for an area of further conquest. He built whale catchers and operated them with scientific care, and by 1862 his work was recognized in Norway, Scotland and some other countries as personifying the whaling industry. Foyn's inventive approach to this new trade ensured that innovative ideas were accepted and that his inventions—such as the rubber accumulator, the recoil absorber and the harpoon braking system—became an accepted part of the whaler's trade. It is said that his first harpoon gun, invented in 1864, weighed 1 ton. Foyn designed a special whaling winch in 1873 that was protected by patent, the same year that the Norwegian Government granted him a ten-year monopoly on his system for catching whales.

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Further Reading

J.H.Harland, 1992, Catchers and Corvettes, the Steam Whalecatcher in Peace and War 1860–1960, Rotherfield, East Sussex: Jean Boudriot.

P.Budker, 1958, Whales and Whaling, London: Harrap.

FMW

Adamson, Daniel

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering, Metallurgy, Steam and internal combustion engines

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b. 1818 Shildon, Co. Durham, England

d. January 1890 Didsbury, Manchester, England

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English mechanical engineer, pioneer in the use of steel for boilers, which enabled higher pressures to be introduced; pioneer in the use of triple-and quadruple-expansion mill engines.

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Adamson was apprenticed between 1835 and 1841 to Timothy Hackworth, then Locomotive Superintendent on the Stockton \& Darlington Railway. After this he was appointed Draughtsman, then Superintendent Engineer, at that railway's locomotive works until in 1847 he became Manager of Shildon Works. In 1850 he resigned and moved to act as General Manager of Heaton Foundry, Stockport. In the following year he commenced business on his own at Newton Moor Iron Works near Manchester, where he built up his business as an iron-founder and boilermaker. By 1872 this works had become too small and he moved to a 4 acre (1.6 hectare) site at Hyde Junction, Dukinfield. There he employed 600 men making steel boilers, heavy machinery including mill engines fitted with the American Wheelock valve gear, hydraulic plant and general millwrighting. His success was based on his early recognition of the importance of using high-pressure steam and steel instead of wrought iron. In 1852 he patented his type of flanged seam for the firetubes of Lancashire boilers, which prevented these tubes cracking through expansion. In 1862 he patented the fabrication of boilers by drilling rivet holes instead of punching them and also by drilling the holes through two plates held together in their assembly positions. He had started to use steel for some boilers he made for railway locomotives in 1857, and in 1860, only four years after Bessemer's patent, he built six mill engine boilers from steel for Platt Bros, Oldham. He solved the problems of using this new material, and by his death had made c.2,800 steel boilers with pressures up to 250 psi (17.6 kg/cm²).

He was a pioneer in the general introduction of steel and in 1863–4 was a partner in establishing the Yorkshire Iron and Steel Works at Penistone. This was the first works to depend entirely upon Bessemer steel for engineering purposes and was later sold at a large profit to Charles Cammell \& Co., Sheffield. When he started this works, he also patented improvements both to the Bessemer converters and to the engines which provided their blast. In 1870 he helped to turn Lincolnshire into an important ironmaking area by erecting the North Lincolnshire Ironworks. He was also a shareholder in ironworks in South Wales and Cumberland.

He contributed to the development of the stationary steam engine, for as early as 1855 he built one to run with a pressure of 150 psi (10.5 kg/cm) that worked quite satisfactorily. He reheated the steam between the cylinders of compound engines and then in 1861–2 patented a triple-expansion engine, followed in 1873 by a quadruple-expansion one to further economize steam. In 1858 he developed improved machinery for testing tensile strength and compressive resistance of materials, and in the same year patents for hydraulic lifting jacks and riveting machines were obtained.

He was a founding member of the Iron and Steel Institute and became its President in 1888 when it visited Manchester. The previous year he had been President of the Institution of Civil Engineers when he was presented with the Bessemer Gold Medal. He was a constant contributor at the meetings of these associations as well as those of the Institution of Mechanical Engineers. He did not live to see the opening of one of his final achievements, the Manchester Ship Canal. He was the one man who, by his indomitable energy and skill at public speaking, roused the enthusiasm of the people in Manchester for this project and he made it a really practical proposition in the face of strong opposition.

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Principal Honours and Distinctions

President, Institution of Civil Engineers 1887.

President, Iron and Steel Institute 1888. Institution of Civil Engineers Bessemer Gold Medal 1887.

Further Reading

Obituary, Engineer 69:56.

Obituary, Engineering 49:66–8.

Obituary, Proceedings of the Institution of Civil Engineers 100:374–8.

H.W.Dickinson, 1938, A Short History of the Steam Engine, Cambridge University Press (provides an illustration of Adamson's flanged seam for boilers).

R.L.Hills, 1989, Power from Steam. A History of the Stationary Steam Engine, Cambridge University Press (covers the development of the triple-expansion engine).

RLH

Kind, Karl Gotthelf

SUBJECT AREA: Mining and extraction technology

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b. 6 June 1801 Linda, near Freiberg, Germany

d. 9 March 1873 Saarbrücken, Germany

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German engineer, pioneer in deep drilling.

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The son of an ore miner in Saxony, Kind was engaged in his father's profession for some years before he joined Glenck's drillings for salt at Stotternheim, Thuringia. There in 1835, after trying for five years, he self-reliantly put down a 340 m (1,100 ft) deep well; his success lay in his use of fish joints of a similar construction to those used shortly before by von Oeynhausen in Westphalia. In order to improve their operational possibilities in aquiferous wells, in 1842 he developed his own free-fall device between the rod and the drill, which enabled the chisel to reach the bottom of the hole without hindrance. His invention was patented in France. Four years later, at Mondorf, Luxembourg, he put down a 736 m (2,415 ft) deep borehole, the deepest in the world at that time.

Kind contributed further considerable improvements to deep drilling and was the first successfully to replace iron rods with wooden ones, on account of their buoyancy in water. The main reasons for his international reputation were his attempts to bore out shafts, which he carried out for the first time in the region of Forbach, France, in 1848. Three years later he was engaged in the Ruhr area by a Belgian-and English-financed mining company, later the Dahlbusch mining company in Gelsenkirchen, to drill a hole that was later enlarged to 4.4 m (14 1/2 ft) and made watertight by lining. Although he had already taken out a patent for boring and lining shafts in 1849 in Belgium, his wooden support did not qualify. It was the Belgian engineer Joseph Chaudron, in charge of the mining company, who overcame the difficulty of making the bottom of the borehole watertight. In 1854 they jointly founded a shaft-sinking company in Brussels which specialized in aquiferous formations and operated internationally.

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Principal Honours and Distinctions

Chevalier de la Légion d'honneur 1849.

Bibliography

1842, Anleitung zum Abteufen von Bohrlöchern, Luxembourg.

Further Reading

H.G.Conrad, "Carl Gotthelf Kind", Neue deutsche Biographie 10:613–14.

D.Hoffmann, 1959, 150 Jahre Tiefbohrungen in Deutschland, Vienna and Hamburg, pp. 20–5 (assesses his technological achievements).

T.Tecklenburg, 1914, Handbuch der Tiefbohrkunde, 2nd end, Vol. VI, Berlin, pp. 36–9 (provides a detailed description of his equipment).

J.Chaudron, 1862, "Über die nach dem Kindschen Erdbohrverfahren in Belgien ausgeführten Schachtbohrarbeiten", Berg-und Hüttenmännische Zeitung 21:402–4, (describes his contribution to making Kind's shafts watertight).

WK

Koepe, Friedrich

SUBJECT AREA: Mining and extraction technology

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b. 1 July 1835 Bergkamen, Westphalia, Germany

d. 12 September 1922 Bochum, Germany

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German mining engineer, inventor of the friction winder for shaft hoisting.

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After attending the School of Mines at Bochum, from 1862 he worked as an overseer in the coal-mining district of Ibbenbüren until he joined a mining company in the Ruhr area. There, as head of the machine shop, he was mainly concerned with sinking new shafts. In 1873 he became the Technical Director of the Hannover mine, near Bochum, which belonged to Krupp. When the shaft hoisting was to be extended to a lower level Koepe conceived the idea of applying a friction winder to the hoist instead of a drum, in order to save weight and costs. His method involved the use of an endless rope to which the cages were fixed without a safety catch. The rope passed over pulleys instead of coiling and uncoiling on a drum, and he consequently proposed to have the motor erected on top of the shaft rather than beside it, as had been the practice until then.

Koepe's innovation turned out to be highly effective for hoisting heavy loads from deep shafts and was still popular in many countries in the 1990s, although the Krupp company did not accept it for a long time. He had severe personal problems with the company, and as Krupp refused to have his system patented he had to take it out in his own name in 1877. However, Krupp did not pay for the extension of the patent, nor did they pass the dossiers over to him, so the patent expired two years later. It was not until 1888 that a hoisting engine equipped with a friction winder was erected for the first time in a head gear, above the new Hannover II shaft. The following year Koepe left the Krupp company and settled as a freelance consulting engineer in Bochum; he was successful in having his system introduced by other mining companies. Ironi-cally, in 1948 the world's first four-rope winding, based on his system, was installed at the Hannover mine.

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Further Reading

For detailed biographical information and an assessment of his technological achievements see: H.Arnold and W.Kroker, 1977, "100 Jahre Schachtförderung nach dem System Koepe", Der Anschnitt 29:235–42.

F.Lange, 1952, Die Vierseilförderung, Essen.

WK

Mouriés, Hippolyte Mège

SUBJECT AREA: Agricultural and food technology

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b. 24 October 1817 Draguignan, France

d. 1880 France

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French inventor of margarine.

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The son of a schoolmaster. Mouriés became a chemist's assistant in his home town at the age of 16. He then spent a period of training in Aix-enProvence, and in 1838 he moved to Paris, where he became Assistant to the Resident Pharmacist at the Hotel Dieu Hospital. He stayed there until 1846 but never sat his final exams. His main success during this period was with the drug Copahin, which was used against syphilis; he invented an oral formulation of the drug by treating it with nitric acid. In the 1840s he took out various patents relating to tanning and to sugar extraction, and in the 1850s he turned his attention to food research. He developed a health chocolate with his calcium phosphate protein, and also developed a method that made it possible to gain 14 per cent more white bread from a given quantity of wheat. He lectured on this process in Berlin and Brussels and was awarded two gold medals. After 1862 he concentrated his research on fats. His margarine process was based on the cold saponification of milk in fat emulsions and was patented in both France and Britain in 1869. These experiments were carried out at the Ferme Impériale de La Faisanderie in Vincennes, the personal property of the Emperor, and it is therefore likely that they were State-funded. He sold his knowledge to the Dutch firm Jurgens in 1871, and between 1873 and 1874 he also sold his British, American and Prussian rights. His final patent, in 1875, was for canned meat.

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Principal Honours and Distinctions

Napoleon III awarded him the Légion d'honneur for his work on wheat and bread.

Further Reading

J.H.van Stuyvenberg (ed.), Margarine: An Economic, Social and Scientific History, 1869–1969 (provides a brief outline of the life of Mouriés in a comprehensive history of his discovery).

AP

Petzval, Josef Max

SUBJECT AREA: Photography, film and optics

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b. 1807 Spisska-Beila, Hungary

d. 17 September 1891 Vienna, Austria

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Hungarian mathematician and photographic-lens designer, inventor of the first "rapid" portrait lens.

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Although born in Hungary, Petzval was the son of German schoolteacher. He studied engineering at the University of Budapest and after graduation was appointed to the staff as a lecturer. In 1835 he became the University's Professor of Higher Mathematics. Within a year he was offered a similar position at the more prestigious University of Vienna, a chair he was to occupy until 1884.

The earliest photographic cameras were fitted with lenses originally designed for other optical instruments. All were characterized by small apertures, and the long exposures required by the early process were in part due to the "slow" lenses. As early as 1839, Petzval began calculations with the idea of producing a fast achromatic objective for photographic work. For technical advice he turned to the Viennese optician Peter Voigtländer, who went on to make the first Petzval portrait lens in 1840. It had a short focal length but an extremely large aperture for the day, enabling exposure times to be reduced to at least one tenth of that required with other contemporary lenses. The Petzval portrait lens was to become the basic design for years to come and was probably the single most important development in making portrait photography possible; by capturing public imagination, portrait photography was to drive photographic innovation during the early years.

Petzval later fell out with Voigtländer and severed his connection with the company in 1845. When Petzval was encouraged to design a landscape lens in the 1850s, the work was entrusted to another Viennese optician, Dietzler. Using some early calculations by Petzval, Voigtländer was able to produce a similar lens, which he marketed in competition, and an acrimonious dispute ensued. Petzval, embittered by the quarrel and depressed by a burglary which destroyed years of records of his optical work, abandoned optics completely in 1862 and devoted himself to acoustics. He retired from his professorship on his seventieth birthday, respected by his colleagues but unloved, and lived the life of a recluse until his death.

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Principal Honours and Distinctions

Member of the Hungarian Academy of Science 1873.

Further Reading

J.M.Eder, 1945, History of Photography, trans. E. Epstean, New York (provides details of Petzval's life and work; Eder claims he was introduced to Petzval by mutual friends and succeeded in obtaining personal data).

Rudolf Kingslake, 1989, A History of the Photographic Lens, Boston (brief biographical details).

L.W.Sipley, 1965, Photography's Great Inventors, Philadelphia (brief biographical details).

JW

Plimsoll, Samuel

SUBJECT AREA: Ports and shipping

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b. 10 February 1824 Bristol, England

d. 8 June 1898 Folkestone, Kent, England

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English inventor of the Plimsoll Line on ships.

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Plimsoll was educated privately and at Dr Eadon's school in Sheffield. On leaving school he became Clerk to a solicitor and then to a brewery, where he rose to become Manager. In 1851 he acted as an honorary secretary to the Great Exhibition. Two years later he went to London and set up as a coal merchant: he published two pamphlets on the coal trade in 1862. After several unsuccessful attempts, he managed to be elected as Member of Parliament for Derby in 1868, in the Radical interest. He concerned himself with mercantile shipping and in 1870 he began his campaign to improve safety at sea, particularly by the imposition of a load-line on vessels to prevent dangerous overloading. In 1871 he introduced a resolution into the House of Commons and also a bill, the Government also having proposed one on the same subject, but strong opposition from the powerful shipping-business interest forced a withdrawal. Plimsoll published a pamphlet, Our Seamen, bitterly attacking the shipowners. This aroused public feeling and controversy, and under pressure the Government appointed a Royal Commission in 1873, under the chairmanship of the Duke of Somerset, to examine the matter. Their report did not support Plimsoll's proposal for a load-line, but that did not prevent him from bringing forward his own bill, which was narrowly defeated by only three votes. The Government then introduced its own merchant shipping bill in 1875, but it was so mauled by the Opposition that the Prime Minister, Disraeli, threatened to withdraw it. That provoked a violent protest from Plimsoll in the House, including a description of the shipowners which earned him temporary suspension from the House. He was allowed to return after an apology, but the incident served to heighten public feeling for the seamen. The Government were obliged to hustle through the Merchant Shipping Act 1876, which ensured, among other things, that ships should be marked with what has become universally known as the Plimsoll Line; Plimsoll himself became known as "The Seamen's Friend".

In 1880 he relinquished his parliamentary seat at Derby, but he continued his campaign to improve conditions for seamen and to ensure that the measures in the Act were properly carried out.

LRD

Rankine, William John Macquorn

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering

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b. 5 July 1820 Edinburgh, Scotland

d. 1872

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Scottish engineer and educator

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Rankine was educated at Ayr Academy and Glasgow High School, although he appears to have learned much of his basic mathematics and physics through private study. He attended Edinburgh University and then assisted his father, who was acting as Superintendent of the Edinburgh and Dalkeith Railway. This introduction to engineering practice was followed in 1838 by his appointment as a pupil to Sir John MacNeill, and for the next four years he served under MacNeill on his Irish railway projects. While still in his early twenties, Rankine presented pioneering papers on metal fatigue and other subjects to the Institution of Civil Engineers, for which he won a prize, but he appears to have resigned from the Civils in 1857 after an argument because the Institution would not transfer his Associate Membership into full Membership. From 1844 to 1848 Rankine worked on various projects for the Caledonian Railway Company, but his interests were becoming increasingly theoretical and a series of distinguished papers for learned societies established his reputation as a leading scholar in the new science of thermodynamics. He was elected Fellow of the Royal Society in 1853. At the same time, he remained intimately involved with practical questions of applied science, in shipbuilding, marine engineering and electric telegraphy, becoming associated with the influential coterie of fellow Scots such as the Thomson brothers, Napier, Elder, and Lewis Gordon. Gordon was then the head of a large and successful engineering practice, but he was also Regius Professor of Engineering at the University of Glasgow, and when he retired from the Chair to pursue his business interests, Rankine, who had become his Assistant, was appointed in his place.

From 1855 until his premature death in 1872, Rankine built up an impressive engineering department, providing a firm theoretical basis with a series of text books that he wrote himself and most of which remained in print for many decades. Despite his quarrel with the Institution of Civil Engineers, Rankine took a keen interest in the institutional development of the engineering profession, becoming the first President of the Institution of Engineers and Shipbuilders in Scotland, which he helped to establish in 1857. Rankine campaigned vigorously for the recognition of engineering studies as a full university degree at Glasgow, and he achieved this in 1872, the year of his death. Rankine was one of the handful of mid-nineteenth century engineers who virtually created engineering as an academic discipline.

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Principal Honours and Distinctions

FRS 1853. First President, Institution of Engineers and Shipbuilders in Scotland, 1857.

Bibliography

1858, Manual of Applied Mechanics.

1859, Manual of the Steam Engine and Other Prime Movers.

1862, Manual of Civil Engineering.

1869, Manual of Machinery and Millwork.

Further Reading

1873, Proceedings of the Institution of Civil Engineers 21.

J.Small, 1957, "The institution's first president", Proceedings of the Institution of Engineers and Shipbuilders in Scotland: 687–97.

H.B.Sutherland, 1972, Rankine. His Life and Times.

AB

Siemens, Sir Charles William

SUBJECT AREA: Electricity, Metallurgy, Public utilities, Telecommunications

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b. 4 April 1823 Lenthe, Germany

d. 19 November 1883 London, England

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German/British metallurgist and inventory pioneer of the regenerative principle and open-hearth steelmaking.

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Born Carl Wilhelm, he attended craft schools in Lübeck and Magdeburg, followed by an intensive course in natural science at Göttingen as a pupil of Weber. At the age of 19 Siemens travelled to England and sold an electroplating process developed by his brother Werner Siemens to Richard Elkington, who was already established in the plating business. From 1843 to 1844 he obtained practical experience in the Magdeburg works of Count Stolburg. He settled in England in 1844 and later assumed British nationality, but maintained close contact with his brother Werner, who in 1847 had co-founded the firm Siemens \& Halske in Berlin to manufacture telegraphic equipment. William began to develop his regenerative principle of waste-heat recovery and in 1856 his brother Frederick (1826–1904) took out a British patent for heat regeneration, by which hot waste gases were passed through a honeycomb of fire-bricks. When they became hot, the gases were switched to a second mass of fire-bricks and incoming air and fuel gas were led through the hot bricks. By alternating the two gas flows, high temperatures could be reached and considerable fuel economies achieved. By 1861 the two brothers had incorporated producer gas fuel, made by gasifying low-grade coal.

Heat regeneration was first applied in ironmaking by Cowper in 1857 for heating the air blast in blast furnaces. The first regenerative furnace was set up in Birmingham in 1860 for glassmaking. The first such furnace for making steel was developed in France by Pierre Martin and his father, Emile, in 1863. Siemens found British steelmakers reluctant to adopt the principle so in 1866 he rented a small works in Birmingham to develop his open-hearth steelmaking furnace, which he patented the following year. The process gradually made headway; as well as achieving high temperatures and saving fuel, it was slower than Bessemer's process, permitting greater control over the content of the steel. By 1900 the tonnage of open-hearth steel exceeded that produced by the Bessemer process.

In 1872 Siemens played a major part in founding the Society of Telegraph Engineers (from which the Institution of Electrical Engineers evolved), serving as its first President. He became President for the second time in 1878. He built a cable works at Charlton, London, where the cable could be loaded directly into the holds of ships moored on the Thames. In 1873, together with William Froude, a British shipbuilder, he designed the Faraday, the first specialized vessel for Atlantic cable laying. The successful laying of a cable from Europe to the United States was completed in 1875, and a further five transatlantic cables were laid by the Faraday over the following decade.

The Siemens factory in Charlton also supplied equipment for some of the earliest electric-lighting installations in London, including the British Museum in 1879 and the Savoy Theatre in 1882, the first theatre in Britain to be fully illuminated by electricity. The pioneer electric-tramway system of 1883 at Portrush, Northern Ireland, was an opportunity for the Siemens company to demonstrate its equipment.

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Principal Honours and Distinctions

Knighted 1883. FRS 1862. Institution of Civil Engineers Telford Medal 1853. President, Institution of Mechanical Engineers 1872. President, Society of Telegraph Engineers 1872 and 1878. President, British Association 1882.

Bibliography

27 May 1879, British patent no. 2,110 (electricarc furnace).

1889, The Scientific Works of C.William Siemens, ed. E.F.Bamber, 3 vols, London.

Further Reading

W.Poles, 1888, Life of Sir William Siemens, London; repub. 1986 (compiled from material supplied by the family).

S.von Weiher, 1972–3, "The Siemens brothers. Pioneers of the electrical age in Europe", Transactions of the Newcomen Society 45:1–11 (a short, authoritative biography). S.von Weihr and H.Goetler, 1983, The Siemens Company. Its Historical Role in the

Progress of Electrical Engineering 1847–1980, English edn, Berlin (a scholarly account with emphasis on technology).

GW