great+britain+time

Farman, Henri

SUBJECT AREA: Aerospace

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b. 26 May 1874 Paris, France

d. 17 July 1958 Paris, France

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French aeroplane designer who modified Voisin biplanes and later, with his brother Maurice (b. 21 March 1877 Paris, France; d. 26 February 1964 Paris, France), created a major aircraft-manufacturing company.

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The parents of Henri and Maurice Farman were British subjects living in Paris, but their sons lived all their lives in France and became French citizens. As young men, both became involved in cycle and automobile racing. Henri (or Henry—he used both versions) turned his attention to aviation in 1907 when he bought a biplane from Gabriel Voisin. Within a short time he had established himself as one of the leading pilots in Europe, with many record-breaking flights to his credit. Farman modified the Voisin with his own improvements, including ailerons, and then in 1909 he designed the first Farman biplane. This became the most popular biplane in Europe from the autumn of 1909 until well into 1911 and is one of the classic aeroplanes of history. Meanwhile, Maurice Farman had also begun to design and build biplanes; his first design of 1909 was not a great success but from it evolved two robust biplanes nicknamed the "Longhorn" and the "Shorthorn", so called because of their undercarriage skids. In 1912 the brothers joined forces and set up a very large factory at Billancourt. The "Longhorn" and "Shorthorn" became the standard training aircraft in France and Britain during the early years of the First World War. The Farman brothers went on to produce a number of other wartime designs, including a large bomber. After the war the Farmans produced a series of large airliners which played a key role in establishing France as a major airline operator. Most famous of these was the Goliath, a twin-engined biplane capable of carrying up to twelve passengers. This was produced from 1918 to 1929 and was used by many airlines, including the Farman Line. The brothers retired when their company was nationalized in 1937.

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Bibliography

1910, The Aviator's Companion, London (with his brother Dick Farman).

Further Reading

M.Farman, 1901, 3,000 kilomètres en ballon, Paris (an account of several balloon flights from 1894 to 1900).

J.Liron, 1984, Les Avions Farman, Paris (provides comprehensive descriptions of all Farman aircraft).

Jane's Fighting Aircraft of World War I, 1990, London (reprint) (gives details of all early Farman aircraft).

J.Stroud, 1966, European Aircraft since 1910, London (provides details about Farman air-liners).

JDS

Heinkel, Ernst

SUBJECT AREA: Aerospace, Weapons and armour

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b. 24 January 1888 Grünbach, Remstal, Germany

d. 30 January 1958 Stuttgart, Germany

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German aeroplane designer who was responsible for the first jet aeroplane to fly.

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The son of a coppersmith, as a young man Ernst Heinkel was much affected by seeing the Zeppelin LZ 4 crash and burn out at Echterdringen, near Stuttgart. After studying engineering, in 1910 he designed his first aeroplane, but it crashed; he was more successful the following year when he made a flight in it, with an engine on hire from the Daimler company. After a period working for a firm near Munich and for LVG at Johannisthal, near Berlin, he moved to the Albatros Company of Berlin with a monthly salary of 425 marks. In May 1913 he moved to Lake Constance to work on the design of sea-planes and in May 1914 he moved again, this time to the Brandenburg Company, where he remained as a designer until 1922, when he founded his own company, Ernst Heinkel Flugzeugwerke. Following the First World War, German companies were not allowed to build military aircraft, which was frustrating for Heinkel whose main interest was high-speed aircraft. His sleek He 70 airliner, built for Lufthansa, was designed to carry four passengers at high speeds: indeed it broke many records in 1933. Lufthansa decided it needed a larger version capable of carrying ten passengers, so Heinkel produced his most famous aeroplane, the He 111. Although it was designed as a twin-engined airliner on the surface, secretly Heinkel was producing a bomber. The airliner version first flew on Lufthansa routes in 1936, and by 1939 almost 1,000 bombers were in service with the Luftwaffe. A larger four-engined bomber, the He 177, ran into development problems and it did not see service until late in the Second World War. Heinkel's quest for speed led to the He 176 rocket-powered research aeroplane which flew on 20 June 1939, but Hitler and Goering were not impressed. The He 178, with Dr Hans von Ohain's jet engine, made its historic first flight a few weeks later on 27 August 1939; this was almost two years before the maiden flight in Britain of the Gloster E 28/39, powered by Whittle's jet engine. This project was a private venture by Heinkel and was carried out in great secrecy, so the world's first jet aircraft went almost unnoticed. Heinkel's jet fighters, the He 280 and the He 162, were never fully operational. After the war, Heinkel in 1950 set up a new company which made bicycles, motor cycles and "bubble" cars.

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Bibliography

1956, He 1000, trans. M.Savill, London: Hutchinson (the English edition of his autobiography).

Further Reading

J.Stroud, 1966, European Transport Aircraft since 1910, London.

Jane's Fighting Aircraft of World War II, London: Jane's; reprinted 1989.

P. St J.Turner, 1970, Heinkel: An Aircraft Album, London.

H.J.Nowarra, 1975, Heinkel und seine Flugzeuge, Munich (a comprehensive record of his aircraft).

JDS / IMcN

Nervi, Pier Luigi

SUBJECT AREA: Architecture and building, Civil engineering

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b. 21 June 1891 Sondrio, Italy

d. 9 January 1979 (?), Italy

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Italian engineer who played a vital role in the use and adaptation of reinforced concrete as a structural material from the 1930s to the 1970s.

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Nervi early established a reputation in the use of reinforced concrete with his stadium in Florence (1930–2). This elegant concrete structure combines graceful curves with functional solidity and is capable of seating some 35,000 spectators. The stadium was followed by the aircraft hangars built for the Italian Air Force at Orvieto and Ortebello, in which he spanned the vast roofs of the hangars with thin-shelled vaults supported by precast concrete beams and steel-reinforced ribs. The structural strength and subtle curves of these ribbed roofs set the pattern for Nervi's techniques, which he subsequently varied and elaborated on to solve problems that arose in further commissions.

Immediately after the Second World War Italy was short of supplies of steel for structural purposes so, in contrast to the USA, Britain and Germany, did not for some years construct any quantity of steel-framed rectangular buildinngs used for offices, housing or industrial use. It was Nervi who led the way to a ferroconcrete approach, using a new type of structure based on these materials in the form of a fine steel mesh sprayed with cement mortar and used to roof all kinds of structures. It was a method that resulted in expressionist curves instead of rectangular blocks, and the first of his great exhibition halls at Turin (1949), with a vault span of 240 ft (73 m), was an early example of this technique. Nervi continued to create original and beautiful ferroconcrete structures of infinite variety: for example, the hall at the Lido di Roma, Ostia; the terme at Chianciano; and the three buildings that he designed for the Rome Olympics in 1960. The Palazzetto dello Sport is probably the most famous of these, for which he co-operated with the architect Annibale Vitellozzi to construct a small sports palace seating 5,000 spectators under a concrete "big top" of 194 ft (59 m) diameter, its enclosing walls supported by thirtysix guy ropes of concrete; inside, the elegant roof displays a floral quality. In 1960 Nervi returned to Turin to build his imaginative Palace of Labour for the centenary celebrations of Garibaldi and Victor Emmanuel in the city. This vast hall, like the Crystal Palace in England a century earlier (see Paxton), had to be built quickly and be suitable for later adaptation. It was therefore constructed partly in steel, and the metal supporting columns rose to palm-leaf capitals reminiscent of those in ancient Nile palaces.

Nervi's aim was always to create functional buildings that simultaneously act by their aesthetic qualities as an effective educational influence. Functionalism for Nervi never became "brutalism". In consequence, his work is admired by the lay public as well as by architects. He collaborated with many of the outstanding architects of the day: with Gio Ponti on the Pirelli Building in Milan (1955–9); with Zehrfuss and Breuer on the Y-plan UNESCO Building in Paris (1953–7); and with Marcello Piacentini on the 16,000-seat Palazzo dello Sport in Rome. Nervi found time to write a number of books on building construction and design, lectured in the Universities of Rio de Janiero and Buenos Aires, and was for many years Professor of Technology and Technique of Construction in the Faculty of Architecture at the University of Rome. He continued to design new structures until well into the 1970s.

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Principal Honours and Distinctions

RIBA Royal Gold Medal 1960. Royal Institute of Structural Engineers Gold Medal 1968. Honorary Degree Edinburgh University, Warsaw University, Munich University, London University, Harvard University. Member International Institute of Arts and Letters, Zurich; American Academy of Arts and Sciences; Royal Academy of Fine Arts, Stockholm.

Bibliography

1956, Structures, New York: Dodge.

1945, Scienza o Arte del Costruire?, Rome: Bussola.

Further Reading

P.Desideri et al., 1979, Pier Luigi Nervi, Bologna: Zanichelli.

A.L.Huxtable, 1960, Masters of World Architecture; Pier Luigi Nervi, New York: Braziller.

DY

Reason, Richard Edmund

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering

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b. 21 December 1903 Exeter, Devon, England

d. 20 March 1987 Great Bowden, Leicestershire, England

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English metrologist who developed instruments for measuring machined-surface roughness.

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Richard Edmund Reason was educated at Tonbridge School and the Royal College of Science (Imperial College), where he studied under Professor A.F.C.Pollard, Professor of Technical Optics. After graduating in 1925 he joined Taylor, Taylor and Hobson Ltd, Leicester, manufacturers of optical, electrical and scientific instruments, and remained with that firm throughout his career. One of his first contributions was in the development, with E.F.Fincham, of the Fincham Coincidence Optometer. At this time the firm, under William Taylor, was mainly concerned with optical instruments and lens manufacture, but in the 1930s Reason was also engaged in developing means for measuring the roughness of machined surfaces. The need for establishing standards and methods of measurement of surface finish was called for when the subcontracting of aero-engine components became necessary during the Second World War. This led to the development by Reason of an instrument in which a stylus was moved across the surface and the profile recorded electronically. This was called the Talysurf and was first produced in 1941. Further development followed, and from 1947 Reason tackled the problem of measuring roundness, producing the first Talyrond machine in 1949. The technology developed for these instruments was used in the production of others such as the Talymin Comparator and the Talyvel electronic level. Reason was also associated with the development of optical projection systems to measure the profile of parts such as gear teeth, screw threads and turbine blades. He retired in 1968 but continued as a consultant to the company. He served for many years on committees of the British Standards Institution on surface metrology and was a representative of Britain at the International Standards Organization.

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Principal Honours and Distinctions

OBE 1967. FRS 1971. Honorary DSc University of Birmingham 1969. Honorary DSc Leicester University 1971.

Further Reading

D.J.Whitehouse, 1990, Biographical Memoirs of Fellows of the Royal Society 36, London, pp. 437–62 (an illustrated obituary notice listing Reason's eighty-nine British patents, published between 1930 and 1972, and his twenty-one publications, dating from 1937 to 1966).

K.J.Hume, 1980, A History of Engineering Metrology, London, 113–21 (contains a shorter account of Reason's work).

RTS

Stalkartt, Marmaduke

SUBJECT AREA: Ports and shipping

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b. 6 April 1750 London (?), England

d. 24 September 1805 Calcutta, India

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English naval architect and author of a noted book on shipbuilding.

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For a man who contributed much to the history of shipbuilding in Britain, surprisingly little is known of his life and times. The family are reputedly descendants of Danish or Norwegian shipbuilders who emigrated to England around the late seventeenth century. It is known, however, that Marmaduke was the fourth child of his father, Hugh Stalkartt, but the second child of Hugh's second wife.

Stalkartt is believed to have served an apprenticeship at the Naval Yard at Deptford on the Thames. He had advanced sufficiently by 1796 for the Admiralty to send him to India to establish shipyards dedicated to the construction of men-of-war in teak. The worsening supply of oak from England, and to a lesser extent Scotland, coupled with the war with France was making ship procurement one of the great concerns of the time. The ready supply of hardwoods from the subcontinent was a serious attempt to overcome this problem. For some years one of the shipyards in Calcutta was known as Stalkartt's Yard and this gives some credence to the belief that Stalkartt left the Navy while overseas and started his own shipbuilding organization.

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Bibliography

1781, Naval Architecture; or, the Rudiments and Rules of Shipbuilding; repub. 1787, 1803 (an illustrated textbook).

FMW

Thomson, Sir William, Lord Kelvin

SUBJECT AREA: Electricity, Telecommunications

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b. 26 June 1824 Belfast, Ireland (now Northern Ireland)

d. 17 December 1907 Largs, Scotland

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Irish physicist and inventor who contributed to submarine telegraphy and instrumentation.

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After education at Glasgow University and Peterhouse, Cambridge, a period of study in France gave Thomson an interest in experimental work and instrumentation. He became Professor of Natural Philosophy at Glasgow in 1846 and retained the position for the rest of his career, establishing the first teaching laboratory in Britain.

Among his many contributions to science and engineering was his concept, introduced in 1848, of an "absolute" zero of temperature. Following on from the work of Joule, his investigations into the nature of heat led to the first successful liquefaction of gases such as hydrogen and helium, and later to the science of low-temperature physics.

Cable telegraphy gave an impetus to the scientific measurement of electrical quantities, and for many years Thomson was a member of the British Association Committee formed in 1861 to consider electrical standards and to develop units; these are still in use. Thomson first became Scientific Adviser to the Atlantic Telegraph Company in 1857, sailing on the Agamemnon and Great Eastern during the cable-laying expeditions. He invented a mirror galvanometer and more importantly the siphon recorder, which, used as a very sensitive telegraph receiver, provided a permanent record of signals. He also laid down the design parameters of long submarine cables and discovered that the conductivity of copper was greatly affected by its purity. A major part of the success of the Atlantic cable in 1866 was due to Thomson, who received a knighthood for his contribution.

Other instruments he designed included a quadrant electrostatic voltmeter to measure high voltages, and his "multi-cellular" instrument for low voltages. They could be used on alternating or direct current and were free from temperature errors. His balances for precision current measurement were widely used in standardizing laboratories.

Thomson was a prolific writer of scientific papers on subjects across the whole spectrum of physics; between 1855 and 1866 he published some 110 papers, with a total during his life of over 600. In 1892 he was raised to the peerage as Baron Kelvin of Largs. By the time of his death he was looked upon as the "father" of British physics, but despite his outstanding achievements his later years were spent resisting change and progress.

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Principal Honours and Distinctions

Knighted 1866. Created Lord Kelvin of Largs 1892. FRS 1851. President, Royal Society 1890–4. An original member of the Order of Merit 1902. President, Society of Telegraph Engineers 1874. President, Institution of Electrical Engineers 1889 and 1907. Royal Society Royal Medal 1856, Copley Medal 1883.

Bibliography

1872, Reprints of Papers on Electrostatics and Magnetism, London; 1911, Mathematical and Physical Papers, 6 vols, Cambridge (collections of Thomson's papers).

Further Reading

Silvanus P.Thompson, 1910, The Life of William Thomson, Baron Kelvin of Largs, 2 vols, London (an uncritical biography).

D.B.Wilson, 1987, Kelvin and Stokes: A Comparative Study in Victorian Physics, Bristol (provides a present-day commentary on all aspects of Thomson's work).

J.G.Crowther, 1962, British Scientists of the 19th Century, London, pp. 199–257 (a short critical biography).

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Tideman, Bruno Joannes

SUBJECT AREA: Ports and shipping

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b. 7 August 1834 Amsterdam, The Netherlands

d. 11 February 1883 Amsterdam, The Netherlands

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Dutch naval architect and constructor, early hydrodyna midst.

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The first thirty years of Tideman's life followed the normal pattern for a naval architect: study at the Breda Military Academy, work in the Royal Dockyards of Vlissingen as a constructor and then experience in the United Kingdom "standing by" an armoured vessel being built for the Dutch at Birkenhead. Tideman took the opportunity to acquaint himself with current developments in British shipyards and to study the work of Macquorn Rankine at Glasgow University.

On his return to the Netherlands he was given the task of adapting the Royal Dockyard of Amsterdam for ironclad construction and from 1870 iron ships were built there. From 1868 until 1873 he taught shipbuilding at what was then the Delft Polytechnic, but resigned on his appointment as Chief Naval Constructor of Holland.

Through representations to appropriate authority he assisted in founding the great shipyard Koninklijke Maatschappij "De Schelde" and in the setting up of Dutch ferry services across the North Sea. His interest in ship design and in the pioneering work of William Froude led to the founding of the world's second ship model test tank in 1876 in a sheltered part of the Royal Amsterdam Dockyard. The design was based on Froude's Torquay Tank.

As Scotland's first tank was not opened until 1883, he attracted work from the Clyde, including the testing of the Russian Imperial Yacht Livadia built by Elder's of Glasgow. This contract was so critical that it was agreed that a quartersize model be tested on Loch Lomond. Throughout his life he was respected as an all-round engineer and consultancy work flowed in, the vast bulk of it from Britain. Continual trying to improve standards, Tideman was working on a development plan for Dutch shipbuilding at the time of his death.

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Further Reading

J.M.Dirkzwager, 1970, Bruno Joannes Tideman 1834–1883. Grondlegger van de Moderne Scheepsbouw in Nederland, Leiden.

FMW

Watson, George Lennox

SUBJECT AREA: Ports and shipping

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b. 1851 Glasgow, Scotland

d. 12 November 1904 Glasgow, Scotland

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Scottish designer of some of the world's largest sailing and powered yachts, principal technical adviser to the Royal National Lifeboat Institution.

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Almost all of Watson's life was spent in or around the City of Glasgow; his formal education was at the city's High School and at the age of 16 he entered the yard and drawing offices of Robert Napier's Govan Shipyard. Three years later he crossed the River Clyde and started work in the design office of the Pointhouse Shipyard of A. \& J.Inglis, and there received the necessary grounding of a naval architect. Dr John Inglis, the Principal of the firm, encouraged Watson, ensured that he was involved in advanced design work and allowed him to build a yacht in a corner of the shipyard in his spare time.

At the early age of 22 Watson set up as a naval architect with his own company, which is still in existence 120 years later. In 1875, assisted by two carpenters, Watson built the 5-ton yacht Vril to his own design. This vessel was the first with an integral heavy lead keel and its success ensured that design contracts flowed to him for new yachts for the Clyde and elsewhere. His enthusiasm and increasing skill were recognized and soon he was working on the ultimate: the America's Cup challengers Thistle, Valkyrie II, Valkyrie III and Shamrock II. The greatest accolade was the contract for the design of the J Class yacht Britannia, built by D. \& W.Henderson of Glasgow in 1893 for the Prince of Wales.

The company of G.L.Watson became the world's leading designer of steam yachts, and it was usual for it to offer a full design service as well as supervise construction in any part of the world. Watson took a deep interest in the work of the Royal National Lifeboat Institution and was its technical consultant for many years. One of his designs, the Watson Lifeboat, was a stalwart in its fleet for many years. In public life he lectured, took an active part in the debates on yacht racing and was recognized as Britain's leading designer.

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Bibliography

1881, Progress in Yachting and Yacht-Building, Glasgow Naval and Marine Engineering Catalogue, London and Glasgow: Collins.

1894, The Evolution of the Modern Racing Yacht, Badminton Library of Sports and Pastimes, Vol. 1, London: Longmans Green, pp. 54–109.

Further Reading

John Irving, 1937, The King's Britannia. The Story of a Great Ship, London: Seeley Service.

FMW