blast-furnace ironmaking

blast-furnace ironmaking

1. передел первый

 

передел первый
Получение чугуна из железной руды в доменных печах.
[ http://www.manual-steel.ru/eng-a.html]

Тематики

• металлургия в целом

EN

• blast-furnace ironmaking

blast-furnace ironmaking

• производство n доменное

blast-furnace practice

доменное производство

mining practice — горное производство

ironmaking practice — технология производства чугуна

process in practice — судебный приказ, изданный в процессе производства по делу

передел первый

1. blast-furnace ironmaking

 

передел первый
Получение чугуна из железной руды в доменных печах.
[ http://www.manual-steel.ru/eng-a.html]

Тематики

• металлургия в целом

EN

• blast-furnace ironmaking

производство доменное

• производство n доменное

english: blast-furnace ironmaking

deutsch: Hochofenbetrieb

français: production f de la fonte dans le haut fourneau

wielkopiecownictwo

• blast-furnace practice

• ironmaking

доменное производство

blast-furnace practice

технология производства чугуна — ironmaking practice

Gibbons, John

SUBJECT AREA: Metallurgy

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fl. 1800–50 Staffordshire, England

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English ironmaster who introduced the round hearth in the blastfurnace.

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Gibbons was an ironmaster in the Black Country, South Staffordshire, in charge of six blast furnaces owned by the family business. Until Gibbons's innovation in 1832, small changes in the form of the furnace had at times been made, but no one had seriously questioned the square shape of the hearth. Gibbons noticed that a new furnace often worked poorly by improved as time went on. When it was "blown out", i.e. taken out of commission, he found that the corners of the hearth had been rounded off and the sides gouged out, so that it was roughly circular in shape. Gibbons wisely decided to build a blast furnace with a round hearth alongside an existing one with a traditionally shaped hearth and work them in exactly the same conditions. The old furnace produced 75 tons of iron in a week, about normal for the time, while the new one produced 100 tons. Further improvements followed and in 1838 a fellow ironmaster in the same district, T. Oakes, considerably enlarged the furnace, its height attaining no less than 60ft (18m). As a result, output soared to over 200 tons a week. Most other ironmasters adopted the new form with enthusiasm and it proved to be the basis for the modern blast furnace. Gibbons made another interesting innovation: he began charging his furnace with the "rubbish", slag or cinder, from earlier ironmaking operations. It contained a significant amount of iron and was cheaper to obtain than iron ore, as it was just lying around in heaps. Some ironmasters scorned to use other people's throw-outs, but Gibbons sensibly saw it as a cheap source of iron; it was a useful source for some years during the nineteenth century but its use died out when the heaps were used up. Gibbons published an account of his improvements in ironmaking in a pamphlet entitled Practical Remarks on the Construction of the Staffordshire Blast Furnace.

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Bibliography

1839, Practical Remarks on the Construction of the Staffordshire Blast Furnace, Birmingham; reprinted 1844.

Further Reading

J.Percy, 1864, Metallurgy. Iron and Steel, London, p. 476. W.K.V.Gale, 1969, Iron and Steel, London: Longmans, pp. 44–6.

LRD

Cowper, Edward Alfred

SUBJECT AREA: Metallurgy

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b. 10 December 1819 London, England

d. 9 May 1893 Weybridge, Surrey, England

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English inventor of the hot-blast stove used in ironmaking.

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Cowper was apprenticed in 1834 to John Braithwaite of London and in 1846 obtained employment at the engineers Fox \& Henderson in Birmingham. In 1851 he was engaged in the contract drawings for the Crystal Palace housing the Great Exhibition, and in the same year he set up in London as a consulting engineer. Cowper designed the 211 ft (64.3 m) span roof of Birmingham railway station, the first large-span station roof to be constructed. Cowper had an inventive turn of mind. While still an apprentice, he devised the well-known railway fog-signal and, at Fox \& Henderson, he invented an improved method of casting railway chairs. Other inventions included a compound steam-engine with receiver, patented in 1857; a bicycle wheel with steel spokes and rubber tyre (1868); and an electric writing telegraph (1879). Cowper's most important invention by far was the hot-blast stove, the first application of C.W. Siemens's regenerative principle to ironmaking, patented in 1857. Waste gases from the blast furnace were burnt in an iron chamber lined with a honeycomb of firebricks. When they were hot, the gas was directed to a second similar chamber while the incoming air blast for the blast furnace was heated by passing it through the first chamber. The stoves alternatively received and gave up heat and the heated blast, introduced by J.B. Neilson, led to considerable fuel economies in blast-furnace operation; the system is still in use. Cowper played an active part in the engineering institutions of his time, becoming President of the Institution of Mechanical Engineers in 1880–1. He was commissioned by the Science and Art Department to catalogue the collections of machinery and inventions at the South Kensington Museum, whose science collections now form the Science Museum, London.

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Principal Honours and Distinctions

President, Institution of Mechanical Engineers 1880–1.

Further Reading

Obituary, 1893, Journal of the Iron and Steel Institute: 172–3, London.

W.K.V.Gale, 1969, Iron and Steel, London: Longmans, pp. 42, 75 (describes his hot-blast stoves).

LRD

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

Macintosh, Charles

SUBJECT AREA: Chemical technology, Textiles

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b. 29 December 1766 Glasgow, Scotland

d. 25 July 1843 Dunchattan, near Glasgow, Scotland

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Scottish inventor of rubberized waterproof clothing.

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As the son of the well-known and inventive dyer George Macintosh, Charles had an early interest in chemistry. At the age of 19 he gave up his work as a clerk with a Glasgow merchant to manufacture sal ammoniac (ammonium chloride) and developed new processes in dyeing. In 1797 he started the first Scottish alum works, finding the alum in waste shale from coal mines. His first works was at Hurlet, Renfrewshire, and was followed later by others. He then formed a partnership with Charles Tennant, the proprietor of a chemical works at St Rollox, near Glasgow, and sold "lime bleaching liquor" made with chlorine and milk of lime from their bleach works at Darnley. A year later the use of dry lime to make bleaching powder, a process worked out by Macintosh, was patented. Macintosh remained associated with Tennant's St Rollox chemical works until 1814. During this time, in 1809, he had set up a yeast factory, but it failed because of opposition from the London brewers.

There was a steady demand for the ammonia that gas works produced, but the tar was often looked upon as an inconvenient waste product. Macintosh bought all the ammonia and tar that the Glasgow works produced, using the ammonia in his establishment to produce cudbear, a dyestuff extracted from various lichens. Cudbear could be used with appropriate mordants to make shades from pink to blue. The tar could be distilled to produce naphtha, which was used as a flare. Macintosh also became interested in ironmaking. In 1825 he took out a patent for converting malleable iron into steel by taking it to white heat in a current of gas with a carbon content, such as coal gas. However, the process was not commercially successful because of the difficulty keeping the furnace gas-tight. In 1828 he assisted J.B. Neilson in bringing hot blast into use in blast furnaces; Neilson assigned Macintosh a share in the patent, which was of dubious benefit as it involved him in the tortuous litigation that surrounded the patent until 1843.

In June 1823, as a result of experiments into the possible uses of naphtha obtained as a by-product of the distillation of coal tar, Macintosh patented his process for waterproofing fabric. This comprised dissolving rubber in naphtha and applying the solution to two pieces of cloth which were afterwards pressed together to form an impermeable compound fabric. After an experimental period in Glasgow, Macintosh commenced manufacture in Manchester, where he formed a partnership with H.H.Birley, B.Kirk and R.W.Barton. Birley was a cotton spinner and weaver and was looking for ways to extend the output of his cloth. He was amongst the first to light his mills with gas, so he shared a common interest with Macintosh.

New buildings were erected for the production of waterproof cloth in 1824–5, but there were considerable teething troubles with the process, particularly in the spreading of the rubber solution onto the cloth. Peter Ewart helped to install the machinery, including a steam engine supplied by Boulton \& Watt, and the naphtha was supplied from Macintosh's works in Glasgow. It seems that the process was still giving difficulties when Thomas Hancock, the foremost rubber technologist of that time, became involved in 1830 and was made a partner in 1834. By 1836 the waterproof coat was being called a "mackintosh" [sic] and was gaining such popularity that the Manchester business was expanded with additional premises. Macintosh's business was gradually enlarged to include many other kinds of indiarubber products, such as rubber shoes and cushions.

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Principal Honours and Distinctions

FRS 1823.

Further Reading

G.Macintosh, 1847, Memoir of Charles Macintosh, London (the fullest account of Charles Macintosh's life).

T.Hancock, 1957, Narrative of the Indiarubber Manufacture, London.

H.Schurer, 1953, "The macintosh: the paternity of an invention", Transactions of the Newcomen Society 28:77–87 (an account of the invention of the mackintosh).

RLH / LRD