(1856-1858)

сборник решений по уголовным делам

Law: Bell's Crown Cases (составитель Белл, 1858-1860), Dearsley and Bell's Crown Cases (составители Дирсли и Белл, 1856-1858), Dearsley's Crown Cases (составитель Дирсли), Denison and Pearce's Crown Cases (составители Денисон и Пирс, 1844-1852), Denison's Crown Cases (составитель Денисон, 1844-1852), Foster's Crown Cases (составитель Фостер, 1743-1761), John Kelyng's Crown Cases (составитель Дж. Келинг, 1662-1669), Leach's Crown Cases (составитель Лич, 1730-1815), Leigh and Cave's Crown Cases (составители Лей и Кейв, 1861-1865), Lewin's Crown Cases (составитель Льюин, 1822-1838), Moody's Crown Cases (составитель Муди, 1824-1844), Queensland Criminal Reports (Австралия, 1860-1907), Russei and Ryan's Crown Cases (составители Рассел и Райан, 1799-1823), Russel and Ryan's Crown Cases (составители Рассел и Райан, 1799-1823), Temple and Mew's Crown Cases (составители Темпл и Мью, 1848-1851)

сборник решений по уголовным делам, составители Дирсли и Белл

Law: Dearsley and Bell's Crown Cases (1856-1858)

Holden, Sir Isaac

SUBJECT AREA: Textiles

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b. 7 May 1807 Hurlet, between Paisley and Glasgow, Scotland

d. 13 August 1897

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British developer of the wool-combing machine.

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Isaac Holden's father, who had the same name, had been a farmer and lead miner at Alston in Cumbria before moving to work in a coal-mine near Glasgow. After a short period at Kilbarchan grammar school, the younger Isaac was engaged first as a drawboy to two weavers and then, after the family had moved to Johnstone, Scotland, worked in a cotton-spinning mill while attending night school to improve his education. He was able to learn Latin and bookkeeping, but when he was about 15 he was apprenticed to an uncle as a shawl-weaver. This proved to be too much for his strength so he returned to scholastic studies and became Assistant to an able teacher, John Kennedy, who lectured on physics, chemistry and history, which he also taught to his colleague. The elder Isaac died in 1826 and the younger had to provide for his mother and younger brother, but in 1828, at the age of 21, he moved to a teaching post in Leeds. He filled similar positions in Huddersfield and Reading, where in October 1829 he invented and demonstrated the lucifer match but did not seek to exploit it. In 1830 he returned because of ill health to his mother in Scotland, where he began to teach again. However, he was recommended as a bookkeeper to William Townend, member of the firm of Townend Brothers, Cullingworth, near Bingley, Yorkshire. Holden moved there in November 1830 and was soon involved in running the mill, eventually becoming a partner.

In 1833 Holden urged Messrs Townend to introduce seven wool-combing machines of Collier's designs, but they were found to be very imperfect and brought only trouble and loss. In 1836 Holden began experimenting on the machines until they showed reasonable success. He decided to concentrate entirely on developing the combing machine and in 1846 moved to Bradford to form an alliance with Samuel Lister. A joint patent in 1847 covered improvements to the Collier combing machine. The "square motion" imitated the action of the hand-comber more closely and was patented in 1856. Five more patents followed in 1857 and others from 1858 to 1862. Holden recommended that the machines should be introduced into France, where they would be more valuable for the merino trade. This venture was begun in 1848 in the joint partnership of Lister \& Holden, with equal shares of profits. Holden established a mill at Saint-Denis, first with Donisthorpe machines and then with his own "square motion" type. Other mills were founded at Rheims and at Croix, near Roubaix. In 1858 Lister decided to retire from the French concerns and sold his share to Holden. Soon after this, Holden decided to remodel all their machinery for washing and carding the gill machines as well as perfecting the square comb. Four years of excessive application followed, during which time £20,000 was spent in experiments in a small mill at Bradford. The result fully justified the expenditure and the Alston Works was built in Bradford.

Holden was a Liberal and from 1865 to 1868 he represented Knaresborough in Parliament. Later he became the Member of Parliament for the Northern Division of the Riding, Yorkshire, and then for the town of Keighley after the constituencies had been altered. He was liberal in his support of religious, charitable and political objectives. His house at Oakworth, near Keighley, must have been one of the earliest to have been lit by electricity.

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Principal Honours and Distinctions

Baronet 1893.

Bibliography

1847, with Samuel Lister, British patent no. 11,896 (improved Collier combing machine). 1856. British patent no. 1,058 ("square motion" combing machine).

1857. British patent no. 278 1857, British patent no. 279 1857, British patent no. 280 1857, British patent no. 281 1857, British patent no. 3,177 1858, British patent no. 597 1859, British patent no. 52 1860, British patent no. 810 1862, British patent no. 1,890 1862, British patent no. 3,394

Further Reading

J.Hogg (ed.), c.1888, Fortunes Made in Business, London (provides an account of Holden's life).

Obituary, 1897, Engineer 84.

Obituary, 1897, Engineering 64.

E.M.Sigsworth, 1973, "Sir Isaac Holden, Bt: the first comber in Europe", in N.B.Harte and K.G.Ponting (eds), Textile History and Economic History, Essays in Honour of

Miss Julia de Lacy Mann, Manchester.

W.English, 1969, The Textile Industry, London (provides a good explanation of the square motion combing machine).

RLH

facsímil fotolitografiado

(n.) = photolitho facsimile

Ex. The early photolitho books of 1856-7 were again collections of reproductions of art photographs, but in 1858 there was an event of greater bibliographical significance: the production of a photolitho facsimile of a printed book.

* * *

(n.) = photolitho facsimile

Ex: The early photolitho books of 1856-7 were again collections of reproductions of art photographs, but in 1858 there was an event of greater bibliographical significance: the production of a photolitho facsimile of a printed book.

fotografía de obra de arte

(n.) = art photograph

Ex. The early photolitho books of 1856-7 were again collections of reproductions of art photographs, but in 1858 there was an event of greater bibliographical significance: the production of a photolitho facsimile of a printed book.

* * *

(n.) = art photograph

Ex: The early photolitho books of 1856-7 were again collections of reproductions of art photographs, but in 1858 there was an event of greater bibliographical significance: the production of a photolitho facsimile of a printed book.

libro fotolitografiado

(n.) = photolitho book

Ex. The early photolitho books of 1856-7 were again collections of reproductions of art photographs, but in 1858 there was an event of greater bibliographical significance: the production of a photolitho facsimile of a printed book.

* * *

(n.) = photolitho book

Ex: The early photolitho books of 1856-7 were again collections of reproductions of art photographs, but in 1858 there was an event of greater bibliographical significance: the production of a photolitho facsimile of a printed book.

Clark, Edward

SUBJECT AREA: Domestic appliances and interiors

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fl. 1850s New York State, USA

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American co-developer of mass-production techniques at the Singer sewing machine factory.

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Born in upstate New York, where his father was a small manufacturer, Edward Clark attended college at Williams and graduated in 1831. He became a lawyer in New York City and from then on lived either in the city or on his rural estate near Cooperstown in upstate New York. After a series of share manipulations, Clark acquired a one-third interest in Isaac M. Singer's company. They soon bought out one of Singer's earlier partners, G.B.Zeiber, and in 1851, under the name of I.M.Singer \& Co., they set up a permanent sewing machine business with headquarters in New York.

The success of their firm initially rested on marketing. Clark introduced door-to-door sales-people and hire-purchase for their sewing machines in 1856 ($50 cash down, or $100 with a cash payment of $5 and $3 a month thereafter). He also trained women to demonstrate to potential customers the capabilities of the Singer sewing machine. At first their sewing machines continued to be made in the traditional way, with the parts fitted together by skilled workers through hand filing and shaping so that the parts would fit only onto one machine. This resembled European practice rather than the American system of manufacture that had been pioneered in the armouries in that country. In 1856 Singer brought out their first machine intended exclusively for home use, and at the same time manufacturing capacity was improved. Through increased sales, a new factory was built in 1858–9 on Mott Street, New York, but it soon became inadequate to meet demand.

In 1863 the Singer company was incorporated as the Singer Manufacturing Co. and began to modernize its production methods with special jigs and fixtures to help ensure uniformity. More and more specialized machinery was built for making the parts. By 1880 the factory, then at Elizabethport, New Jersey, was jammed with automatic and semi-automatic machine tools. In 1882 the factory was producing sewing machines with fully interchangeable parts that did not require hand fitting in assembly. Production rose from 810 machines in 1853 to half a million in 1880. A new family model was introduced in 1881. Clark had succeeded Singer, who died in 1875, as President of the company, but he retired in 1882 after he had seen through the change to mass production.

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Further Reading

National Cyclopaedia of American Biography.

D.A.Hounshell, 1984, From the American System to Mass Production, 1800–1932. The Development of Manufacturing Technology in the United States, Baltimore (a thorough account of Clark's role in the development of Singer's factories).

F.B.Jewell, 1975, Veteran Sewing Machines. A Collector's Guide, Newton Abbot.

RLH

Gamond, Aimé Thomé de

SUBJECT AREA: Civil engineering

[br]

b. 1807

d. 1876

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French civil engineer and early advocate of the Channel Tunnel.

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He became interested in the possibility of a tunnel or a bridge link between England and France in 1833 when he did his own geological survey of a route between Calais and Dover, and in 1834 he proposed an immersed tube tunnel. However, at the Great Exhibition of 1855 he promoted a scheme incorporating an artificial stone isthmus with movable bridges, which was estimated to cost £33,600,000, but this idea was eventuallv abandoned. He reverted to the idea of a tunnel and did further survey in 1855, with 180 lb (80 kg) of flint for ballast, ten inflated pig bladders to bring him to the surface and pieces of buttered lint plastered over his ears to protect them against the water pressure. He touched bottom between 99 and 108 ft (30 and 33 m). In 1856 Napoleon III granted him an audience and promised a scientific commission to evaluate his scheme, which it eventually approved. In 1858 he went to London and got the backing of Robert Stephenson, Isambard K. Brunel and Joseph Locke. He also obtained an interview with Prince Albert. In 1858, after an assassination attempt on Napoleon III, relations between France and England cooled off and Thomé de Gamond's plans were halted. He revived them in 1867, but others were by now also putting forward schemes. He had worked on the scheme for thirty-five years and expended a small fortune. In 1875 The Times reported that he was "living in humble circumstances, his daughter supporting him by giving lessons on the piano". He died the following year.

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Further Reading

T.Whiteside, 1962, The Tunnel under the Channel.

IMcN

Perkin, Sir William Henry

SUBJECT AREA: Chemical technology, Synthetic materials, Textiles

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b. 12 March 1838 London, England

d. 14 July 1907 Sudbury, England

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English chemist, discoverer of aniline dyes, the first synthetic dyestuffs.

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He early showed an aptitude for chemistry and in 1853 entered the Royal College of Chemistry as a student under A.W.von Hofmann, the first Professor at the College. By the end of his first year, he had carried out his first piece of chemical research, on the action of cyanogen chloride on phenylamine, which he published in the Journal of the Chemical Society (1857). He became honorary assistant to von Hofmann in 1857; three years previously he had set up his own chemical laboratory at home, where he had discovered the first of the azo dyes, aminoazonapththalene. In 1856 Perkin began work on the synthesis of quinine by oxidizing a salt of allyl toluidine with potassium dichromate. Substituting aniline, he obtained a dark-coloured precipitate which proved to possess dyeing properties: Perkin had discovered the first aniline dye. Upon receiving favourable reports on the new material from manufacturers of dyestuffs, especially Pullars of Perth, Perkin resigned from the College and turned to the commercial exploitation of his discovery. This proved highly successful. From 1858, the dye was manufactured at his Greenford Green works as "Aniline Purple" or "Tyrian Purple". It was later to be referred to by the French as mauve. Perkin's discovery led to the development of the modern dyestuffs industry, supplanting dyes from the traditional vegetable sources. In 1869, he introduced two new methods for making the red dye alizarin, in place of the process that involved the use of the madder plant (Rubia tinctorum). In spite of German competition, he dominated the British market until the end of 1873. After eighteen years in chemical industry, Perkin retired and devoted himself entirely to the pure chemical research which he had been pursuing since the 1850s. He eventually contributed ninety papers to the Chemical Society and further papers to other bodies, including the Royal Society. For example, in 1867 he published his synthesis of unsaturated organic acids, known as "Perkin's synthesis". Other papers followed, on the structure of "Aniline Purple". In 1881 Perkin drew attention to the magnetic-rotatory power of some of the substances he had been dealing with. From then on, he devoted particular attention to the application of this phenomenon to the determination of chemical structure.

Perkin won wide recognition for his discoveries and other contributions to chemistry.

The half-centenary of his great discovery was celebrated in July 1906 and later that year he received a knighthood.

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Principal Honours and Distinctions

Knighted 1906. FRS 1866. President, Chemical Society 1883–5. President, Society of Chemical Industry 1884–5. Royal Society Royal Medal 1879; Davy Medal 1889.

Bibliography

26 August 1856, British patent no. 1984 (Aniline Purple).

1867, "The action of acetic anhydride upon the hydrides of salicyl, etc.", Journal of the Chemical Society 20:586 (the first description of Perkin's synthesis).

Further Reading

S.M.Edelstein, 1961, biography in Great Chemists, ed. E.Farber, New York: Interscience, pp. 757–72 (a reliable, short account).

R.Meldola, 1908, Journal of the Chemical Society 93:2,214–57 (the most detailed account).

LRD

Brunel, Isambard Kingdom

SUBJECT AREA: Civil engineering, Land transport, Mechanical, pneumatic and hydraulic engineering, Ports and shipping, Public utilities, Railways and locomotives

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b. 9 April 1806 Portsea, Hampshire, England

d. 15 September 1859 18 Duke Street, St James's, London, England

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English civil and mechanical engineer.

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The son of Marc Isambard Brunel and Sophia Kingdom, he was educated at a private boarding-school in Hove. At the age of 14 he went to the College of Caen and then to the Lycée Henri-Quatre in Paris, after which he was apprenticed to Louis Breguet. In 1822 he returned from France and started working in his father's office, while spending much of his time at the works of Maudslay, Sons \& Field.

From 1825 to 1828 he worked under his father on the construction of the latter's Thames Tunnel, occupying the position of Engineer-in-Charge, exhibiting great courage and presence of mind in the emergencies which occurred not infrequently. These culminated in January 1828 in the flooding of the tunnel and work was suspended for seven years. For the next five years the young engineer made abortive attempts to find a suitable outlet for his talents, but to little avail. Eventually, in 1831, his design for a suspension bridge over the River Avon at Clifton Gorge was accepted and he was appointed Engineer. (The bridge was eventually finished five years after Brunel's death, as a memorial to him, the delay being due to inadequate financing.) He next planned and supervised improvements to the Bristol docks. In March 1833 he was appointed Engineer of the Bristol Railway, later called the Great Western Railway. He immediately started to survey the route between London and Bristol that was completed by late August that year. On 5 July 1836 he married Mary Horsley and settled into 18 Duke Street, Westminster, London, where he also had his office. Work on the Bristol Railway started in 1836. The foundation stone of the Clifton Suspension Bridge was laid the same year. Whereas George Stephenson had based his standard railway gauge as 4 ft 8½ in (1.44 m), that or a similar gauge being usual for colliery wagonways in the Newcastle area, Brunel adopted the broader gauge of 7 ft (2.13 m). The first stretch of the line, from Paddington to Maidenhead, was opened to traffic on 4 June 1838, and the whole line from London to Bristol was opened in June 1841. The continuation of the line through to Exeter was completed and opened on 1 May 1844. The normal time for the 194-mile (312 km) run from Paddington to Exeter was 5 hours, at an average speed of 38.8 mph (62.4 km/h) including stops. The Great Western line included the Box Tunnel, the longest tunnel to that date at nearly two miles (3.2 km).

Brunel was the engineer of most of the railways in the West Country, in South Wales and much of Southern Ireland. As railway networks developed, the frequent break of gauge became more of a problem and on 9 July 1845 a Royal Commission was appointed to look into it. In spite of comparative tests, run between Paddington-Didcot and Darlington-York, which showed in favour of Brunel's arrangement, the enquiry ruled in favour of the narrow gauge, 274 miles (441 km) of the former having been built against 1,901 miles (3,059 km) of the latter to that date. The Gauge Act of 1846 forbade the building of any further railways in Britain to any gauge other than 4 ft 8 1/2 in (1.44 m).

The existence of long and severe gradients on the South Devon Railway led to Brunel's adoption of the atmospheric railway developed by Samuel Clegg and later by the Samuda brothers. In this a pipe of 9 in. (23 cm) or more in diameter was laid between the rails, along the top of which ran a continuous hinged flap of leather backed with iron. At intervals of about 3 miles (4.8 km) were pumping stations to exhaust the pipe. Much trouble was experienced with the flap valve and its lubrication—freezing of the leather in winter, the lubricant being sucked into the pipe or eaten by rats at other times—and the experiment was abandoned at considerable cost.

Brunel is to be remembered for his two great West Country tubular bridges, the Chepstow and the Tamar Bridge at Saltash, with the latter opened in May 1859, having two main spans of 465 ft (142 m) and a central pier extending 80 ft (24 m) below high water mark and allowing 100 ft (30 m) of headroom above the same. His timber viaducts throughout Devon and Cornwall became a feature of the landscape. The line was extended ultimately to Penzance.

As early as 1835 Brunel had the idea of extending the line westwards across the Atlantic from Bristol to New York by means of a steamship. In 1836 building commenced and the hull left Bristol in July 1837 for fitting out at Wapping. On 31 March 1838 the ship left again for Bristol but the boiler lagging caught fire and Brunel was injured in the subsequent confusion. On 8 April the ship set sail for New York (under steam), its rival, the 703-ton Sirius, having left four days earlier. The 1,340-ton Great Western arrived only a few hours after the Sirius. The hull was of wood, and was copper-sheathed. In 1838 Brunel planned a larger ship, some 3,000 tons, the Great Britain, which was to have an iron hull.

The Great Britain was screwdriven and was launched on 19 July 1843,289 ft (88 m) long by 51 ft (15.5 m) at its widest. The ship's first voyage, from Liverpool to New York, began on 26 August 1845. In 1846 it ran aground in Dundrum Bay, County Down, and was later sold for use on the Australian run, on which it sailed no fewer than thirty-two times in twenty-three years, also serving as a troop-ship in the Crimean War. During this war, Brunel designed a 1,000-bed hospital which was shipped out to Renkioi ready for assembly and complete with shower-baths and vapour-baths with printed instructions on how to use them, beds and bedding and water closets with a supply of toilet paper! Brunel's last, largest and most extravagantly conceived ship was the Great Leviathan, eventually named The Great Eastern, which had a double-skinned iron hull, together with both paddles and screw propeller. Brunel designed the ship to carry sufficient coal for the round trip to Australia without refuelling, thus saving the need for and the cost of bunkering, as there were then few bunkering ports throughout the world. The ship's construction was started by John Scott Russell in his yard at Millwall on the Thames, but the building was completed by Brunel due to Russell's bankruptcy in 1856. The hull of the huge vessel was laid down so as to be launched sideways into the river and then to be floated on the tide. Brunel's plan for hydraulic launching gear had been turned down by the directors on the grounds of cost, an economy that proved false in the event. The sideways launch with over 4,000 tons of hydraulic power together with steam winches and floating tugs on the river took over two months, from 3 November 1857 until 13 January 1858. The ship was 680 ft (207 m) long, 83 ft (25 m) beam and 58 ft (18 m) deep; the screw was 24 ft (7.3 m) in diameter and paddles 60 ft (18.3 m) in diameter. Its displacement was 32,000 tons (32,500 tonnes).

The strain of overwork and the huge responsibilities that lay on Brunel began to tell. He was diagnosed as suffering from Bright's disease, or nephritis, and spent the winter travelling in the Mediterranean and Egypt, returning to England in May 1859. On 5 September he suffered a stroke which left him partially paralysed, and he died ten days later at his Duke Street home.

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Further Reading

L.T.C.Rolt, 1957, Isambard Kingdom Brunel, London: Longmans Green. J.Dugan, 1953, The Great Iron Ship, Hamish Hamilton.

IMcN

Fowler, John

SUBJECT AREA: Civil engineering

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b. 11 July 1826 Melksham, Wiltshire, England

d. 4 December 1864 Ackworth, Yorkshire, England

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English engineer and inventor who developed a steam-powered system of mole land drainage, and a two-engined system of land cultivation, founding the Steam Plough Works in Leeds.

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The son of a Quaker merchant, John Fowler entered the business of a county corn merchant on leaving school, but he found this dull and left as soon as he came of age, joining the Middlesbrough company of Gilkes, Wilson \& Hopkins, railway locomotive manufacturers. In 1849, at the age of 23, Fowler visited Ireland and was so distressed by the state of Irish agriculture that he determined to develop a system to deal with the drainage of land. He designed an implement which he patented in 1850 after a period of experimentation. It was able to lay wooden pipes to a depth of two feet, and was awarded the Silver Medal at the 1850 Royal Agriculture Show. By 1854, using a steam engine made by Clayton \& Shuttleworth, he had applied steam power to his invention and gained another award that year at the Royal Show. The following year he turned his attention to steam ploughing. He first developed a single-engined system that used a double windlass with which to haul a plough backwards and forwards across fields. In 1856 he patented his balance plough, and the following year he read a paper to the Institution of Mechanical Engineers at their Birmingham premises, describing the system. In 1858 he won the Royal Agricultural Society award with a plough built for him by Ransomes. Fowler founded the Steam Plough Works in Leeds and in 1862 production began in partnership with William Watson Hewitson. Within two years they were producing the first of a series of engines which were to make the name Fowler known worldwide. John Fowler saw little of his success because he died in 1864 at his Yorkshire home as a result of tetanus contracted after a riding accident.

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Further Reading

M.Lane, 1980, The Story of the Steam Plough Works, Northgate Publishing (provides biographical details of John Fowler, but is mostly concerned with the company that he founded).

AP

Helmholtz, Hermann Ludwig Ferdinand von

SUBJECT AREA: Medical technology

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b. 31 August 1821 Potsdam, Germany

d. 8 September 1894 Berlin, Germany

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German physicist and man of science, inventor of the ophthalmoscope.

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Constrained by poverty despite displaying considerable gifts, particularly in the realm of mathematics, he became a surgeon in the Prussian Army but was able to undertake research; in 1842 he wrote a thesis on the discovery of nerve cells in ganglia. He became Professor of Physiology in Königsberg (now Kaliningrad, Russia) in 1849. moving to a similar post in Bonn in 1855, to Heidelberg in 1858, and the Chair of Physic in Berlin in 1871. This latter included the directorship of the physicotechnical institute at Charlottenburg.

His investigations over the years encompassed almost the whole field of science, including physiology, physiological optics, physiological acoustics, chemistry, mathematics, electricity and magnetism, meteorology and theoretical mechanics. He also made important additions to the understanding of putrefaction and fermentation.

Helmholtz's contributions to the understanding of vision and optics ranged widely, but one of the most significant was the definitive development of the ophthalmoscope in 1851. Incorporating some of the aspects of Babbage's original suggestions (which were not brought to practical fruition), his instrument inaugurated a new diagnostic era in ophthalmology, particularly when his method of direct ophthalmoscopy was supplemented by the indirect method of Ruete. His personal life was uneventful, in contrast to his inventive achievements, which were perhaps unequalled in scope in his century. Michael Faraday's tribute, "the absolute simplicity, modesty and untroubled purity of his disposition had a charm such as I have never encountered in another man", is therefore all the more to be valued.

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Bibliography

1850. "The ophthalmoscope", Physikalische Gesellschaft, Berlin.

1851. Beschreibung eines Augen-Spiegels zur Untersuchung der Netzhaut im lebenden Auge, Berlin. 1856–66, Physiological Optics (2 vols).

Further Reading

L.Konigsberger, 1906, trans. F.A.Welby, Hermann von Helmholtz, Oxford.

MG

Nightingale, Florence

SUBJECT AREA: Medical technology

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b. 15 May 1820 Florence, Italy

d. 13 August 1910 London, England

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English nurse, pioneer of the reform of nursing, hospital organization and technology.

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Dedicated to the relief of suffering, Florence Nightingale spent her early years visiting civil and military hospitals all over Europe. She then attended a course of formal training at Kaiserwerth in Germany and with the Sisters of St Vincent de Paul in Paris.

She had returned to London and was managing, after having reformed, a hostel for invalid gentlewomen when in 1854 the appalling conditions of the wounded in Turkey during the Crimean War led to her taking a party of thirty-eight nurses out to Scutari. The application of principles of hygiene and sanitation resulted in dramatic improvements in conditions and on her return to England in 1856 she applied the large sums which had been raised in her honour to the founding in 1861 of the St Thomas's School of Nursing.

From this base she acted as adviser, goad and promoter of sound nursing common sense for the remainder of a long life marred by a chronic invalidism quite out of keeping with the rigorousness of her role in the nursing field. It was not only in the training and conduct of nursing that her influence was primal. Many concepts of hospital technology relating to hygiene, ventilation and ward design are to be attributed to her forthright common sense. The "Nightingale ward", for a time the target of progressive reformers, has been shown still to have abiding virtues.

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Principal Honours and Distinctions

Order of Merit 1907.

Bibliography

1858, Notes on Nursing.

1899, Notes on Hospitals.

Further Reading

C.Woodham-Smith, 1949, Florence Nightingale, London.

MG

Pole, William

SUBJECT AREA: Civil engineering

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b. 22 April 1814 Birmingham, England

d. 1900

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English engineer and educator.

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Although primarily an engineer, William Pole was a man of many and varied talents, being amongst other things an accomplished musician (his doctorate was in music) and an authority on whist. He served an apprenticeship at the Horsley Company in Birmingham, and moved to London in 1836, when he was employed first as Manager to a gasworks. In 1844 he published a study of the Cornish pumping engine, and he also accepted an appointment as the first Professor of Engineering in the Elphinstone College at Bombay. He spent three pioneering years in this post, and undertook the survey work for the Great Indian Peninsular Railway. Before returning to London in 1848 he married Matilda Gauntlett, the daughter of a clergyman.

Back in Britain, Pole was employed by James Simpson, J.M.Rendel and Robert Stephenson, the latter engaging him to assist with calculations on the Britannia Bridge. In 1858 he set up his own practice. He kept a very small office, choosing not to delegate work to subordinates but taking on a bewildering variety of commissions for government and private companies. In the first category, he made calculations for government officials of the main drainage of the metropolis and for its water supply. He lectured on engineering to the Royal Engineers' institution at Chatham, and served on a Select Committee to enquire into the armour of warships and fortifications. He became a member of the Royal Commission on the Railways of Great Britain and Ireland (the Devonshire Commission, 1867) and reported to the War Office on the MartiniHenry rifle. He also advised the India Office about examinations for engineering students. The drafting and writing up of reports was frequently left to Pole, who also made distinguished contributions to the official Lives of Robert Stephenson (1864), I.K. Brunel (1870) and William Fairbairn (1877). For other bodies, he acted as Consulting Engineer in England to the Japanese government, and he assisted W.H.Barlow in calculations for a bridge at Queensferry on the Firth of Forth (1873). He was consulted about many urban water supplies.

Pole joined the Institution of Civil Engineers as an Associate in 1840 and became a Member in 1856. He became a Member of Council, Honorary Secretary (succeeding Manby in 1885–96) and Honorary Member of the Institution. He was interested in astronomy and photography, he was fluent in several languages, was an expert on music, and became the world authority on whist. In 1859 he was appointed Professor of Civil Engineering at University College London, serving in this office until 1867. Pole, whose dates coincided closely with those of Queen Victoria, was one of the great Victorian engineers: he was a polymath, able to apply his great abilities to an amazing range of different tasks. In engineering history, he deserves to be remembered as an outstanding communicator and popularizer.

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Bibliography

1843, "Comparative loss by friction in beam and direct-action engines", Proceedings of the Institution of Civil Engineers 2:69.

Further Reading

Dictionary of National Biography, London.

Proceedings of the Institution of Civil Engineers 143:301–9.

AB

Preece, Sir William Henry

SUBJECT AREA: Electronics and information technology, Public utilities, Telecommunications

[br]

b. 15 February 1834 Bryn Helen, Gwynedd, Wales

d. 6 November 1913 Penrhos, Gwynedd, Wales

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Welsh electrical engineer who greatly furthered the development and use of wireless telegraphy and the telephone in Britain, dominating British Post Office engineering during the last two decades of the nineteenth century.

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After education at King's College, London, in 1852 Preece entered the office of Edwin Clark with the intention of becoming a civil engineer, but graduate studies at the Royal Institution under Faraday fired his enthusiasm for things electrical. His earliest work, as connected with telegraphy and in particular its application for securing the safe working of railways; in 1853 he obtained an appointment with the Electric and National Telegraph Company. In 1856 he became Superintendent of that company's southern district, but four years later he moved to telegraph work with the London and South West Railway. From 1858 to 1862 he was also Engineer to the Channel Islands Telegraph Company. When the various telegraph companies in Britain were transferred to the State in 1870, Preece became a Divisional Engineer in the General Post Office (GPO). Promotion followed in 1877, when he was appointed Chief Electrician to the Post Office. One of the first specimens of Bell's telephone was brought to England by Preece and exhibited at the British Association meeting in 1877. From 1892 to 1899 he served as Engineer-in-Chief to the Post Office. During this time he made a number of important contributions to telegraphy, including the use of water as part of telegraph circuits across the Solent (1882) and the Bristol Channel (1888). He also discovered the existence of inductive effects between parallel wires, and with Fleming showed that a current (thermionic) flowed between the hot filament and a cold conductor in an incandescent lamp.

Preece was distinguished by his administrative ability, some scientific insight, considerable engineering intuition and immense energy. He held erroneous views about telephone transmission and, not accepting the work of Oliver Heaviside, made many errors when planning trunk circuits. Prior to the successful use of Hertzian waves for wireless communication Preece carried out experiments, often on a large scale, in attempts at wireless communication by inductive methods. These became of historic interest only when the work of Maxwell and Hertz was developed by Guglielmo Marconi. It is to Preece that credit should be given for encouraging Marconi in 1896 and collaborating with him in his early experimental work on radio telegraphy.

While still employed by the Post Office, Preece contributed to the development of numerous early public electricity schemes, acting as Consultant and often supervising their construction. At Worcester he was responsible for Britain's largest nineteenth-century public hydro-electric station. He received a knighthood on his retirement in 1899, after which he continued his consulting practice in association with his two sons and Major Philip Cardew. Preece contributed some 136 papers and printed lectures to scientific journals, ninety-nine during the period 1877 to 1894.

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Principal Honours and Distinctions

CB 1894. Knighted (KCB) 1899. FRS 1881. President, Society of Telegraph Engineers, 1880. President, Institution of Electrical Engineers 1880, 1893. President, Institution of Civil Engineers 1898–9. Chairman, Royal Society of Arts 1901–2.

Bibliography

Preece produced numerous papers on telegraphy and telephony that were presented as Royal Institution Lectures (see Royal Institution Library of Science, 1974) or as British Association reports.

1862–3, "Railway telegraphs and the application of electricity to the signaling and working of trains", Proceedings of the ICE 22:167–93.

Eleven editions of Telegraphy (with J.Sivewright), London, 1870, were published by 1895.

1883, "Molecular radiation in incandescent lamps", Proceedings of the Physical Society 5: 283.

1885. "Molecular shadows in incandescent lamps". Proceedings of the Physical Society 7: 178.

1886. "Electric induction between wires and wires", British Association Report. 1889, with J.Maier, The Telephone.

1894, "Electric signalling without wires", RSA Journal.

1898, "Aetheric telegraphy", Proceedings of the Institution of Electrical Engineers.

Further Reading

J.J.Fahie, 1899, History of Wireless Telegraphy 1838–1899, Edinburgh: Blackwood. E.Hawkes, 1927, Pioneers of Wireless, London: Methuen.

E.C.Baker, 1976, Sir William Preece, F.R.S. Victorian Engineer Extraordinary, London (a detailed biography with an appended list of his patents, principal lectures and publications).

D.G.Tucker, 1981–2, "Sir William Preece (1834–1913)", Transactions of the Newcomen Society 53:119–36 (a critical review with a summary of his consultancies).

GW / KF

Stephenson, Robert

SUBJECT AREA: Land transport, Railways and locomotives

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b. 16 October 1803 Willington Quay, Northumberland, England

d. 12 October 1859 London, England

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English engineer who built the locomotive Rocket and constructed many important early trunk railways.

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Robert Stephenson's father was George Stephenson, who ensured that his son was educated to obtain the theoretical knowledge he lacked himself. In 1821 Robert Stephenson assisted his father in his survey of the Stockton \& Darlington Railway and in 1822 he assisted William James in the first survey of the Liverpool \& Manchester Railway. He then went to Edinburgh University for six months, and the following year Robert Stephenson \& Co. was named after him as Managing Partner when it was formed by himself, his father and others. The firm was to build stationary engines, locomotives and railway rolling stock; in its early years it also built paper-making machinery and did general engineering.

In 1824, however, Robert Stephenson accepted, perhaps in reaction to an excess of parental control, an invitation by a group of London speculators called the Colombian Mining Association to lead an expedition to South America to use steam power to reopen gold and silver mines. He subsequently visited North America before returning to England in 1827 to rejoin his father as an equal and again take charge of Robert Stephenson \& Co. There he set about altering the design of steam locomotives to improve both their riding and their steam-generating capacity. Lancashire Witch, completed in July 1828, was the first locomotive mounted on steel springs and had twin furnace tubes through the boiler to produce a large heating surface. Later that year Robert Stephenson \& Co. supplied the Stockton \& Darlington Railway with a wagon, mounted for the first time on springs and with outside bearings. It was to be the prototype of the standard British railway wagon. Between April and September 1829 Robert Stephenson built, not without difficulty, a multi-tubular boiler, as suggested by Henry Booth to George Stephenson, and incorporated it into the locomotive Rocket which the three men entered in the Liverpool \& Manchester Railway's Rainhill Trials in October. Rocket, was outstandingly successful and demonstrated that the long-distance steam railway was practicable.

Robert Stephenson continued to develop the locomotive. Northumbrian, built in 1830, had for the first time, a smokebox at the front of the boiler and also the firebox built integrally with the rear of the boiler. Then in Planet, built later the same year, he adopted a layout for the working parts used earlier by steam road-coach pioneer Goldsworthy Gurney, placing the cylinders, for the first time, in a nearly horizontal position beneath the smokebox, with the connecting rods driving a cranked axle. He had evolved the definitive form for the steam locomotive.

Also in 1830, Robert Stephenson surveyed the London \& Birmingham Railway, which was authorized by Act of Parliament in 1833. Stephenson became Engineer for construction of the 112-mile (180 km) railway, probably at that date the greatest task ever undertaken in of civil engineering. In this he was greatly assisted by G.P.Bidder, who as a child prodigy had been known as "The Calculating Boy", and the two men were to be associated in many subsequent projects. On the London \& Birmingham Railway there were long and deep cuttings to be excavated and difficult tunnels to be bored, notoriously at Kilsby. The line was opened in 1838.

In 1837 Stephenson provided facilities for W.F. Cooke to make an experimental electrictelegraph installation at London Euston. The directors of the London \& Birmingham Railway company, however, did not accept his recommendation that they should adopt the electric telegraph and it was left to I.K. Brunel to instigate the first permanent installation, alongside the Great Western Railway. After Cooke formed the Electric Telegraph Company, Stephenson became a shareholder and was Chairman during 1857–8.

Earlier, in the 1830s, Robert Stephenson assisted his father in advising on railways in Belgium and came to be increasingly in demand as a consultant. In 1840, however, he was almost ruined financially as a result of the collapse of the Stanhope \& Tyne Rail Road; in return for acting as Engineer-in-Chief he had unwisely accepted shares, with unlimited liability, instead of a fee.

During the late 1840s Stephenson's greatest achievements were the design and construction of four great bridges, as part of railways for which he was responsible. The High Level Bridge over the Tyne at Newcastle and the Royal Border Bridge over the Tweed at Berwick were the links needed to complete the East Coast Route from London to Scotland. For the Chester \& Holyhead Railway to cross the Menai Strait, a bridge with spans as long-as 460 ft (140 m) was needed: Stephenson designed them as wrought-iron tubes of rectangular cross-section, through which the trains would pass, and eventually joined the spans together into a tube 1,511 ft (460 m) long from shore to shore. Extensive testing was done beforehand by shipbuilder William Fairbairn to prove the method, and as a preliminary it was first used for a 400 ft (122 m) span bridge at Conway.

In 1847 Robert Stephenson was elected MP for Whitby, a position he held until his death, and he was one of the exhibition commissioners for the Great Exhibition of 1851. In the early 1850s he was Engineer-in-Chief for the Norwegian Trunk Railway, the first railway in Norway, and he also built the Alexandria \& Cairo Railway, the first railway in Africa. This included two tubular bridges with the railway running on top of the tubes. The railway was extended to Suez in 1858 and for several years provided a link in the route from Britain to India, until superseded by the Suez Canal, which Stephenson had opposed in Parliament. The greatest of all his tubular bridges was the Victoria Bridge across the River St Lawrence at Montreal: after inspecting the site in 1852 he was appointed Engineer-in-Chief for the bridge, which was 1 1/2 miles (2 km) long and was designed in his London offices. Sadly he, like Brunel, died young from self-imposed overwork, before the bridge was completed in 1859.

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Principal Honours and Distinctions

FRS 1849. President, Institution of Mechanical Engineers 1849. President, Institution of Civil Engineers 1856. Order of St Olaf (Norway). Order of Leopold (Belgium). Like his father, Robert Stephenson refused a knighthood.

Further Reading

L.T.C.Rolt, 1960, George and Robert Stephenson, London: Longman (a good modern biography).

J.C.Jeaffreson, 1864, The Life of Robert Stephenson, London: Longman (the standard nine-teenth-century biography).

M.R.Bailey, 1979, "Robert Stephenson \& Co. 1823–1829", Transactions of the Newcomen Society 50 (provides details of the early products of that company).

J.Kieve, 1973, The Electric Telegraph, Newton Abbot: David \& Charles.

See also: Pihl, Carl Abraham; Seguin, Marc

PJGR

Sutton, Thomas

SUBJECT AREA: Photography, film and optics

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b. 1819 England

d. 1875 Jersey, Channel Islands

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English photographer and writer on photography.

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In 1841, while studying at Cambridge, Sutton became interested in photography and tried out the current processes, daguerreotype, calotype and cyanotype among them. He subsequently settled in Jersey, where he continued his photographic studies. In 1855 he opened a photographic printing works in Jersey, in partnership with L.-D. Blanquart- Evrard, exploiting the latter's process for producing developed positive prints. He started and edited one of the first photographic periodicals, Photographic Notes, in 1856; until its cessation in 1867, his journal presented a fresher view of the world of photography than that given by its London-based rivals. He also drew up the first dictionary of photography in 1858.

In 1859 Sutton designed and patented a wideangle lens in which the space between two meniscus lenses, forming parts of a sphere and sealed in a metal rim, was filled with water; the lens so formed could cover an angle of up to 120 degrees at an aperture of f12. Sutton's design was inspired by observing the images produced by the water-filled sphere of a "snowstorm" souvenir brought home from Paris! Sutton commissioned the London camera-maker Frederick Cox to make the Panoramic camera, demonstrating the first model in January 1860; it took panoramic pictures on curved glass plates 152×381 mm in size. Cox later advertised other models in a total of four sizes. In January 1861 Sutton handed over manufacture to Andrew Ross's son Thomas Ross, who produced much-improved lenses and also cameras in three sizes. Sutton then developed the first single-lens reflex camera design, patenting it on 20 August 1961: a pivoted mirror, placed at 45 degrees inside the camera, reflected the image from the lens onto a ground glass-screen set in the top of the camera for framing and focusing. When ready, the mirror was swung up out of the way to allow light to reach the plate at the back of the camera. The design was manufactured for a few years by Thomas Ross and J.H. Dallmeyer.

In 1861 James Clerk Maxwell asked Sutton to prepare a series of photographs for use in his lecture "On the theory of three primary colours", to be presented at the Royal Institution in London on 17 May 1861. Maxwell required three photographs to be taken through red, green and blue filters, which were to be printed as lantern slides and projected in superimposition through three projectors. If his theory was correct, a colour reproduction of the original subject would be produced. Sutton used liquid filters: ammoniacal copper sulphate for blue, copper chloride for the green and iron sulphocyanide for the red. A fourth exposure was made through lemon-yellow glass, but was not used in the final demonstration. A tartan ribbon in a bow was used as the subject; the wet-collodion process in current use required six seconds for the blue exposure, about twice what would have been needed without the filter. After twelve minutes no trace of image was produced through the green filter, which had to be diluted to a pale green: a twelve-minute exposure then produced a serviceable negative. Eight minutes was enough to record an image through the red filter, although since the process was sensitive only to blue light, nothing at all should have been recorded. In 1961, R.M.Evans of the Kodak Research Laboratory showed that the red liquid transmitted ultraviolet radiation, and by an extraordinary coincidence many natural red dye-stuffs reflect ultraviolet. Thus the red separation was made on the basis of non-visible radiation rather than red, but the net result was correct and the projected images did give an identifiable reproduction of the original. Sutton's photographs enabled Maxwell to establish the validity of his theory and to provide the basis upon which all subsequent methods of colour photography have been founded.

JW / BC

Türck, Ludwig

SUBJECT AREA: Medical technology

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b. 22 July 1810 Vienna, Austria

d. 25 February 1868 Vienna, Austria

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Austrian neurologist, developer of the techniques of laryngoscopy.

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The son of a wealthy jeweller, he attended medical school in Vienna and qualified in 1836. Until 1844 he was engaged in research into the anatomy and physiology of the nervous system. In 1844, while on a visit to Paris, he came to the attention of Baron Türckheim, Director of the General Hospital in Vienna. The consequence was the establishment of a special division of the hospital for nervous diseases, with Türck in charge.

In 1857 he was appointed Chief Physician to the largest hospital in Vienna and at the same time he became aware of the invention in 1855 by Manuel García, a music teacher of Paris, of a practical laryngoscope. Türck adapted the apparatus to clinical purposes and proceeded to establish the diagnostic and therapeutic techniques required for its efficient use. Some conflict over priority ensued following a publication by Johann Nepomuk Czermak in 1858, but eventually a professional declaration asserted Türck's priority.

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Bibliography

1862, Recherches cliniques sur diverses maladies du larynx, de la trachée et du pharynx étudiées à l'aide du laryngoscope, Paris.

Papers in Allgemein. Wien. med. Zeit. 1856–68.

MG

Unwin, William Cawthorne

SUBJECT AREA: Civil engineering, Electricity, Mechanical, pneumatic and hydraulic engineering

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b. 12 December 1838 Coggeshall, near Colchester, Essex, England d. 1933

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English engineer and educator.

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Unwin made an important contribution to the establishment of engineering at the University of London. His family were of Huguenot stock, and his father was a Congregational minister. Unwin was educated at the City of London Corporation School and at New College, St John's Wood. At a time when the older universities were still effectively closed to Dissenters, he matriculated with Honours in Chemistry in the London University Matriculation Examination in 1858, and he subsequently graduated BSc from London in 1861. He served as Scientific Assistant to William Fairbairn in Manchester from 1856 to 1862, going on to manage engineering work of various sorts. He was appointed Instructor at the Royal School of Naval Architecture and Marine Engineering (1869–72), and then he became Professor of Hydraulics and Mechanical Engineering at the Royal Indian Engineering College (1872–84). From 1884 to 1904 he was Professor of Civil and Mechanical Engineering at the Central Institution of the City \& Guilds of London, which was incorporated into the University of London in 1900. Unwin's research interests included hydraulics and water power, which led to him taking a leading part in the Niagara Falls hydroelectric scheme; the strength of materials, involving the stability of masonry dams; and the development of the internal combustion engine.

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Principal Honours and Distinctions

FRS 1886.

Further Reading

DNB Supplement.

E.G.Walker, 1938, Lift and Work of William Cawthorne Unwin.

AB

Whitworth, Sir Joseph

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering, Metallurgy, Weapons and armour

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b. 21 December 1803 Stockport, Cheshire, England

d. 22 January 1887 Monte Carlo, Monaco

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English mechanical engineer and pioneer of precision measurement.

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Joseph Whitworth received his early education in a school kept by his father, but from the age of 12 he attended a school near Leeds. At 14 he joined his uncle's mill near Ambergate, Derbyshire, to learn the business of cotton spinning. In the four years he spent there he realized that he was more interested in the machinery than in managing a cotton mill. In 1821 he obtained employment as a mechanic with Crighton \& Co., Manchester. In 1825 he moved to London and worked for Henry Maudslay and later for the Holtzapffels and Joseph Clement. After these years spent gaining experience, he returned to Manchester in 1833 and set up in a small workshop under a sign "Joseph Whitworth, Tool Maker, from London".

The business expanded steadily and the firm made machine tools of all types and other engineering products including steam engines. From 1834 Whitworth obtained many patents in the fields of machine tools, textile and knitting machinery and road-sweeping machines. By 1851 the company was generally regarded as the leading manufacturer of machine tools in the country. Whitworth was a pioneer of precise measurement and demonstrated the fundamental mode of producing a true plane by making surface plates in sets of three. He advocated the use of the decimal system and made use of limit gauges, and he established a standard screw thread which was adopted as the national standard. In 1853 Whitworth visited America as a member of a Royal Commission and reported on American industry. At the time of the Crimean War in 1854 he was asked to provide machinery for manufacturing rifles and this led him to design an improved rifle of his own. Although tests in 1857 showed this to be much superior to all others, it was not adopted by the War Office. Whitworth's experiments with small arms led on to the construction of big guns and projectiles. To improve the quality of the steel used for these guns, he subjected the molten metal to pressure during its solidification, this fluid-compressed steel being then known as "Whitworth steel".

In 1868 Whitworth established thirty annual scholarships for engineering students. After his death his executors permanently endowed the Whitworth Scholarships and distributed his estate of nearly half a million pounds to various educational and charitable institutions. Whitworth was elected an Associate of the Institution of Civil Engineers in 1841 and a Member in 1848 and served on its Council for many years. He was elected a Member of the Institution of Mechanical Engineers in 1847, the year of its foundation.

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Principal Honours and Distinctions

Baronet 1869. FRS 1857. President, Institution of Mechanical Engineers 1856, 1857 and 1866. Hon. LLD Trinity College, Dublin, 1863. Hon. DCL Oxford University 1868. Member of the Smeatonian Society of Civil Engineers 1864. Légion d'honneur 1868. Society of Arts Albert Medal 1868.

Bibliography

1858, Miscellaneous Papers on Mechanical Subjects, London; 1873, Miscellaneous Papers on Practical Subjects: Guns and Steel, London (both are collections of his papers to technical societies).

1854, with G.Wallis, The Industry of the United States in Machinery, Manufactures, and

Useful and Ornamental Arts, London.

Further Reading

F.C.Lea, 1946, A Pioneer of Mechanical Engineering: Sir Joseph Whitworth, London (a short biographical account).

A.E.Musson, 1963, "Joseph Whitworth: toolmaker and manufacturer", Engineering Heritage, Vol. 1, London, 124–9 (a short biography).

D.J.Jeremy (ed.), 1984–6, Dictionary of Business Biography, Vol. 5, London, 797–802 (a short biography).

W.Steeds, 1969, A History of Machine Tools 1700–1910, Oxford (describes Whitworth's machine tools).

RTS