he+ran+second

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

Kay (of Bury), John

SUBJECT AREA: Textiles

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b. 16 July 1704 Walmersley, near Bury, Lancashire, England

d. 1779 France

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English inventor of the flying shuttle.

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John Kay was the youngest of five sons of a yeoman farmer of Walmersley, near Bury, Lancashire, who died before his birth. John was apprenticed to a reedmaker, and just before he was 21 he married a daughter of John Hall of Bury and carried on his trade in that town until 1733. It is possible that his first patent, taken out in 1730, was connected with this business because it was for an engine that made mohair thread for tailors and twisted and dressed thread; such thread could have been used to bind up the reeds used in looms. He also improved the reeds by making them from metal instead of cane strips so they lasted much longer and could be made to be much finer. His next patent in 1733, was a double one. One part of it was for a batting machine to remove dust from wool by beating it with sticks, but the patent is better known for its description of the flying shuttle. Kay placed boxes to receive the shuttle at either end of the reed or sley. Across the open top of these boxes was a metal rod along which a picking peg could slide and drive the shuttle out across the loom. The pegs at each end were connected by strings to a stick that was held in the right hand of the weaver and which jerked the shuttle out of the box. The shuttle had wheels to make it "fly" across the warp more easily, and ran on a shuttle race to support and guide it. Not only was weaving speeded up, but the weaver could produce broader cloth without any aid from a second person. This invention was later adapted for the power loom. Kay moved to Colchester and entered into partnership with a baymaker named Solomon Smith and a year later was joined by William Carter of Ballingdon, Essex. His shuttle was received with considerable hostility in both Lancashire and Essex, but it was probably more his charge of 15 shillings a year for its use that roused the antagonism. From 1737 he was much involved with lawsuits to try and protect his patent, particularly the part that specified the method of winding the thread onto a fixed bobbin in the shuttle. In 1738 Kay patented a windmill for working pumps and an improved chain pump, but neither of these seems to have been successful. In 1745, with Joseph Stell of Keighley, he patented a narrow fabric loom that could be worked by power; this type may have been employed by Gartside in Manchester soon afterwards. It was probably through failure to protect his patent rights that Kay moved to France, where he arrived penniless in 1747. He went to the Dutch firm of Daniel Scalongne, woollen manufacturers, in Abbeville. The company helped him to apply for a French patent for his shuttle, but Kay wanted the exorbitant sum of £10,000. There was much discussion and eventually Kay set up a workshop in Paris, where he received a pension of 2,500 livres. However, he was to face the same problems as in England with weavers copying his shuttle without permission. In 1754 he produced two machines for making card clothing: one pierced holes in the leather, while the other cut and sharpened the wires. These were later improved by his son, Robert Kay. Kay returned to England briefly, but was back in France in 1758. He was involved with machines to card both cotton and wool and tried again to obtain support from the French Government. He was still involved with developing textile machines in 1779, when he was 75, but he must have died soon afterwards. As an inventor Kay was a genius of the first rank, but he was vain, obstinate and suspicious and was destitute of business qualities.

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Bibliography

1730, British patent no. 515 (machine for making mohair thread). 1733, British patent no. 542 (batting machine and flying shuttle). 1738, British patent no. 561 (pump windmill and chain pump). 1745, with Joseph Stell, British patent no. 612 (power loom).

Further Reading

B.Woodcroft, 1863, Brief Biographies of Inventors or Machines for the Manufacture of Textile Fabrics, London.

J.Lord, 1903, Memoir of John Kay, (a more accurate account).

Descriptions of his inventions may be found in A.Barlow, 1878, The History and Principles of Weaving by Hand and by Power, London; R.L. Hills, 1970, Power in the

Industrial Revolution, Manchester; and C.Singer (ed.), 1957, A History of

Technology, Vol. III, Oxford: Clarendon Press. The most important record, however, is in A.P.Wadsworth and J. de L. Mann, 1931, The Cotton Trade and Industrial

Lancashire, Manchester.

RLH

Maxim, Sir Hiram Stevens

SUBJECT AREA: Aerospace, Weapons and armour

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b. 5 February 1840 Brockway's Mills, Maine, USA

d. 24 November 1916 Streatham, London, England

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American (naturalized British) inventor; designer of the first fully automatic machine gun and of an experimental steam-powered aircraft.

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Maxim was born the son of a pioneer farmer who later became a wood turner. Young Maxim was first apprenticed to a carriage maker and then embarked on a succession of jobs before joining his uncle in his engineering firm in Massachusetts in 1864. As a young man he gained a reputation as a boxer, but it was his uncle who first identified and encouraged Hiram's latent talent for invention.

It was not, however, until 1878, when Maxim joined the first electric-light company to be established in the USA, as its Chief Engineer, that he began to make a name for himself. He developed an improved light filament and his electric pressure regulator not only won a prize at the first International Electrical Exhibition, held in Paris in 1881, but also resulted in his being made a Chevalier de la Légion d'honneur. While in Europe he was advised that weapons development was a more lucrative field than electricity; consequently, he moved to England and established a small laboratory at Hatton Garden, London. He began by investigating improvements to the Gatling gun in order to produce a weapon with a faster rate of fire and which was more accurate. In 1883, by adapting a Winchester carbine, he successfully produced a semi-automatic weapon, which used the recoil to cock the gun automatically after firing. The following year he took this concept a stage further and produced a fully automatic belt-fed weapon. The recoil drove barrel and breechblock to the vent. The barrel then halted, while the breechblock, now unlocked from the former, continued rearwards, extracting the spent case and recocking the firing mechanism. The return spring, which it had been compressing, then drove the breechblock forward again, chambering the next round, which had been fed from the belt, as it did so. Keeping the trigger pressed enabled the gun to continue firing until the belt was expended. The Maxim gun, as it became known, was adopted by almost every army within the decade, and was to remain in service for nearly fifty years. Maxim himself joined forces with the large British armaments firm of Vickers, and the Vickers machine gun, which served the British Army during two world wars, was merely a refined version of the Maxim gun.

Maxim's interests continued to occupy several fields of technology, including flight. In 1891 he took out a patent for a steam-powered aeroplane fitted with a pendulous gyroscopic stabilizer which would maintain the pitch of the aeroplane at any desired inclination (basically, a simple autopilot). Maxim decided to test the relationship between power, thrust and lift before moving on to stability and control. He designed a lightweight steam-engine which developed 180 hp (135 kW) and drove a propeller measuring 17 ft 10 in. (5.44 m) in diameter. He fitted two of these engines into his huge flying machine testrig, which needed a wing span of 104 ft (31.7 m) to generate enough lift to overcome a total weight of 4 tons. The machine was not designed for free flight, but ran on one set of rails with a second set to prevent it rising more than about 2 ft (61 cm). At Baldwyn's Park in Kent on 31 July 1894 the huge machine, carrying Maxim and his crew, reached a speed of 42 mph (67.6 km/h) and lifted off its rails. Unfortunately, one of the restraining axles broke and the machine was extensively damaged. Although it was subsequently repaired and further trials carried out, these experiments were very expensive. Maxim eventually abandoned the flying machine and did not develop his idea for a stabilizer, turning instead to other projects. At the age of almost 70 he returned to the problems of flight and designed a biplane with a petrol engine: it was built in 1910 but never left the ground.

In all, Maxim registered 122 US and 149 British patents on objects ranging from mousetraps to automatic spindles. Included among them was a 1901 patent for a foot-operated suction cleaner. In 1900 he became a British subject and he was knighted the following year. He remained a larger-than-life figure, both physically and in character, until the end of his life.

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Principal Honours and Distinctions

Chevalier de la Légion d'Honneur 1881. Knighted 1901.

Bibliography

1908, Natural and Artificial Flight, London. 1915, My Life, London: Methuen (autobiography).

Further Reading

Obituary, 1916, Engineer (1 December).

Obituary, 1916, Engineering (1 December).

P.F.Mottelay, 1920, The Life and Work of Sir Hiram Maxim, London and New York: John Lane.

Dictionary of National Biography, 1912–1921, 1927, Oxford: Oxford University Press.

See also: Pilcher, Percy Sinclair

CM / JDS

Pasley, General Sir Charles William

SUBJECT AREA: Civil engineering

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b. 8 September 1780 Eskdalemuir, Dumfriesshire, Scotland

d. 19 April 1861 London, England

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Scottish Colonel-Commandant, Royal Engineers.

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At first he was educated by Andrew Little of Lan-gholm. At the age of 14 he was sent to school at Selkirk, where he stayed for two years until joining the Royal Military Academy at Woolwich in August 1796. He was commissioned as Second Lieutenant in the Royal Artillery and transferred to the Royal Engineers on 1 April 1798. He served at Minorca, Malta, Naples, Sicily, Calabria and in the siege of Copenhagen and in other campaigns. He was promoted First Captain in 1807, and was on the staff of Sir John Moore at the battle of Coruna. He was wounded at the siege of Flushing in 1809 and was invalided for a year, employing his time in learning German.

In November 1810 he published his Essay on Military Policy and Institutions of the British Empire, which ran through four editions. In 1811 he was in command of a company of Royal Military Artificers at Plymouth and there he devised a method of education by which the NCOs and troops could teach themselves without "mathematical masters". His system was a great success and was adopted at Chatham and throughout the corps. In 1812 he was appointed Director of the School of Military Engineering at Chatham. He remained at Chatham until 1841, when he was appointed Inspector-General of Railways. During this period he organized improved systems of sapping, mining, telegraphing, pontooning and exploding gunpowder on land or under water, and prepared pamphlets and courses of instruction in these and other subjects. In May 1836 he started what is probably the most important work for which he is remembered. This, was a book on Limes, Calcareous Cements, Mortar, Stuccos and Concretes. The general adoption of Joseph Aspdin's Portland Cement was largely due to Pasley's recommendation of the material.

He was married twice: first in 1814 at Chatham to Harriet Cooper; and then on 30 March 1819 at Rochester to Martha Matilda Roberts, with whom he had six children— she died in 1881.

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Principal Honours and Distinctions

KGB 1846. FRS 1816. Honorary DCL, Oxford University 1844.

Bibliography

1810, Essay on Military Policy and Institutions of the British Empire. Limes, Calcareous Cements, Mortar, Stuccos and Concretes.

Further Reading

Porter, History of the Corps of Royal Engineers. DNB. Proceedings of the Royal Society.

IMcN

Perkins, Jacob

SUBJECT AREA: Architecture and building, Paper and printing

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b. 9 July 1766 Newburyport, Massachusetts, USA

d. 30 July 1849 London, England

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American inventor of a nail-making machine and a method of printing banknotes, investigator of the use of steam at very high pressures.

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Perkins's occupation was that of a gold-and silversmith; while he does not seem to have followed this after 1800, however, it gave him the skills in working metals which he would continue to employ in his inventions. He had been working in America for four years before he patented his nail-making machine in 1796. At the time there was a great shortage of nails because only hand-forged ones were available. By 1800, other people had followed his example and produced automatic nail-making machines, but in 1811 Perkins' improved machines were introduced to England by J.C. Dyer. Eventually Perkins had twenty-one American patents for a range of inventions in his name.

In 1799 Perkins invented a system of engraving steel plates for printing banknotes, which became the foundation of modern siderographic work. It discouraged forging and was adopted by many banking houses, including the Federal Government when the Second United States Bank was inaugurated in 1816. This led Perkins to move to Philadelphia. In the intervening years, Perkins had improved his nail-making machine, invented a machine for graining morocco leather in 1809, a fire-engine in 1812, a letter-lock for bank vaults and improved methods of rolling out spoons in 1813, and improved armament and equipment for naval ships from 1812 to 1815.

It was in Philadelphia that Perkins became interested in the steam engine, when he met Oliver Evans, who had pioneered the use of high-pressure steam. He became a member of the American Philosophical Society and conducted experiments on the compressibility of water before a committee of that society. Perkins claimed to have liquified air during his experiments in 1822 and, if so, was the real discoverer of the liquification of gases. In 1819 he came to England to demonstrate his forgery-proof system of printing banknotes, but the Bank of England was the only one which did not adopt his system.

While in London, Perkins began to experiment with the highest steam pressures used up to that time and in 1822 took out his first of nineteen British patents. This was followed by another in 1823 for a 10 hp (7.5 kW) engine with only 2 in. (51 mm) bore, 12 in. (305 mm) stroke but a pressure of 500 psi (35 kg/cm²), for which he claimed exceptional economy. After 1826, Perkins abandoned his drum boiler for iron tubes and steam pressures of 1,500 psi (105 kg/cm²), but the materials would not withstand such pressures or temperatures for long. It was in that same year that he patented a form of uniflow cylinder that was later taken up by L.J. Todd. One of his engines ran for five days, continuously pumping water at St Katherine's docks, but Perkins could not raise more finance to continue his experiments.

In 1823 one his high-pressure hot-water systems was installed to heat the Duke of Wellington's house at Stratfield Saye and it acquired a considerable vogue, being used by Sir John Soane, among others. In 1834 Perkins patented a compression ice-making apparatus, but it did not succeed commercially because ice was imported more cheaply from Norway as ballast for sailing ships. Perkins was often dubbed "the American inventor" because his inquisitive personality allied to his inventive ingenuity enabled him to solve so many mechanical challenges.

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Further Reading

Historical Society of Pennsylvania, 1943, biography which appeared previously as a shortened version in the Transactions of the Newcomen Society 24.

D.Bathe and G.Bathe, 1943–5, "The contribution of Jacob Perkins to science and engineering", Transactions of the Newcomen Society 24.

D.S.L.Cardwell, 1971, From Watt to Clausius. The Rise of Thermodynamics in the Early Industrial Age, London: Heinemann (includes comments on the importance of Perkins's steam engine).

A.F.Dufton, 1940–1, "Early application of engineering to warming of buildings", Transactions of the Newcomen Society 21 (includes a note on Perkins's application of a high-pressure hot-water heating system).

RLH

Warren, Henry Ellis

SUBJECT AREA: Horology

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b. 21 May 1872 Boston, Massachusetts, USA

d. 21 September 1957 Ashland, Massachusetts, USA

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American electrical engineer who invented the mains electric synchronous clock.

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Warren studied electrical engineering at the Boston Institute of Technology (later to become the Massachusetts Institute of Technology) and graduated in 1894. In 1912 he formed the Warren Electric Clock Company to make a battery-powered clock that he had patented a few years earlier. The name was changed to the Warren Telechron (time at a distance) Company after he had started to produce synchronous clocks.

In 1840 Charles Wheatstone had produced an electric master clock that produced an alternating current with a frequency of one cycle per second and which was used to drive slave dials. This system was not successful, but when Ferranti introduced the first alternating current power generator at Deptford in 1895 Hope-Jones saw in it a means of distributing time. This did not materialize immediately because the power generators did not control the frequency of the current with sufficient accuracy, and a reliable motor whose speed was related to this frequency was not available. In 1916 Warren solved both problems: he produced a reliable self-starting synchronous electric motor and he also made a master clock which could be used at the power station to control accurately the frequency of the supply. Initially the power-generating companies were reluctant to support the synchronous clock because it imposed a liability to control the frequency of the supply and the gain was likely to be small because it was very frugal in its use of power. However, with the advent of the grid system, when several generators were connected together, it became imperative to control the frequency; it was realized that although the power consumption of individual clocks was small, collectively it could be significant as they ran continuously. By the end of the 1930s more than half the clocks sold in the USA were of the synchronous type. The Warren synchronous clock was introduced into Great Britain in 1927, following the setting up of a grid system by the Electricity Commission.

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Principal Honours and Distinctions

Franklin Institute John Price Wetherill Medal. American Institute of Electrical Engineers Lamme Medal.

Bibliography

The patents for the synchronous motor are US patent nos. 1,283,432, 1,283,433 and 1,283,435, and those for the master clock are 1,283,431, 1,409,502 and 1,502,493 of 29 October 1918 onwards.

1919, "Utilising the time characteristics of alternating current", Transactions of the American Institute of Electrical Engineers 38:767–81 (Warren's first description of his system).

Further Reading

J.M.Anderson, 1991, "Henry Ellis Warren and his master clocks", National Association of Watch and Clock Collectors Bulletin 33:375–95 (provides biographical and technical details).

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