would+be+subject+to

Brindley, James

SUBJECT AREA: Canals

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b. 1716 Tunstead, Derbyshire, England

d. 27 September 1772 Turnhurst, Staffordshire, England

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English canal engineer.

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Born in a remote area and with no material advantages, Brindley followed casual rural labouring occupations until 1733, when he became apprenticed to Abraham Bennett of Macclesfield, a wheelwright and millwright. Though lacking basic education in reading and writing, he demonstrated his ability, partly through his photographic memory, to solve practical problems. This established his reputation, and after Bennett's death in 1742 he set up his own business at Leek as a millwright. His skill led to an invitation to solve the problem of mine drainage at Wet Earth Colliery, Clifton, near Manchester. He tunnelled 600 ft (183 m) through rock to provide a leat for driving a water-powered pump.

Following work done on a pump on Earl Gower's estate at Trentham, Brindley's name was suggested as the engineer for the proposed canal for which the Duke of Bridge water (Francis Egerton) had obtained an Act in 1759. The Earl and the Duke were brothers-in-law, and the agents for the two estates were, in turn, the Gilbert brothers. The canal, later known as the Bridgewater Canal, was to be constructed to carry coal from the Duke's mines at Worsley into Manchester. Brindley advised on the details of its construction and recommended that it be carried across the river Irwell at Barton by means of an aqueduct. His proposals were accepted, and under his supervision the canal was constructed on a single level and opened in 1761. Brindley had also surveyed for Earl Gower a canal from the Potteries to Liverpool to carry pottery for export, and the signal success of the Bridgewater Canal ensured that the Trent and Mersey Canal would also be built. These undertakings were the start of Brindley's career as a canal engineer, and it was largely from his concepts that the canal system of the Midlands developed, following the natural contours rather than making cuttings and constructing large embankments. His canals are thus winding navigations unlike the later straight waterways, which were much easier to traverse. He also adopted the 7 ft (2.13 m) wide lock as a ruling dimension for all engineering features. For cheapness, he formed his canal tunnels without a towpath, which led to the notorious practice of legging the boats through the tunnels.

Brindley surveyed a large number of projects and such was his reputation that virtually every proposal was submitted to him for his opinion. Included among these projects were the Staffordshire and Worcestershire, the Rochdale, the Birmingham network, the Droitwich, the Coventry and the Oxford canals. Although he was nominally in charge of each contract, much of the work was carried out by his assistants while he rushed from one undertaking to another to ensure that his orders were being carried out. He was nearly 50 when he married Anne Henshall, whose brother was also a canal engineer. His fees and salaries had made him very wealthy. He died in 1772 from a chill sustained when carrying out a survey of the Caldon Canal.

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Further Reading

A.G.Banks and R.B.Schofield, 1968, Brindley at Wet Earth Colliery: An Engineering Study, Newton Abbot: David \& Charles.

S.E.Buckley, 1948, James Brindley, London: Harrap.

JHB

Brush, Charles Francis

SUBJECT AREA: Electricity, Public utilities

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b. 17 March 1849 Euclid, Michigan, USA

d. 15 June 1929 Cleveland, Ohio, USA

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American engineer, inventor of a multiple electric arc lighting system and founder of the Brush Electric Company.

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Brush graduated from the University of Michigan in 1869 and worked for several years as a chemist. Believing that electric arc lighting would be commercially successful if the equipment could be improved, he completed his first dynamo in 1875 and a simplified arc lamp. His original system operated a maximum of four lights, each on a separate circuit, from one dynamo. Brush envisaged a wider market for his product and by 1879 had available on arc lighting system principally intended for street and other outdoor illumination. He designed a dynamo that generated a high voltage and which, with a carbon-pile regulator, provided an almost constant current permitting the use of up to forty lamps on one circuit. He also improved arc lamps by incorporating a slipping-clutch regulating mechanism and automatic means of bringing into use a second set of carbons, thereby doubling the period between replacements.

Brush's multiple electric arc lighting system was first demonstrated in Cleveland and by 1880 had been adopted in a number of American cities, including New York, Boston and Philadelphia. It was also employed in many European towns until incandescent lamps, for which the Brush dynamo was unsuitable, came into use. To market his apparatus, Brush promoted local lighting companies and thereby secured local capital.

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Principal Honours and Distinctions

Chevalier de la Légion d'honneur 1881. American Academy of Arts and Sciences Rumford Medal 1899. American Institute of Electrical Engineers Edison Medal 1913.

Bibliography

18 May 1878, British patent no. 2,003 (Brush dynamo).

11 March 1879, British patent no. 947 (arc lamp).

26 February 1880, British patent no. 849 (current regulator).

Further Reading

J.W.Urquhart, 1891, Electric Light, London (for a detailed description of the Brush system).

H.C.Passer, 1953, The Electrical Manufacturers: 1875–1900, Cambridge, Mass., pp. 14– 21 (for the origins of the Brush Company).

S.Steward, 1980, in Electrical Review, 206:34–5 (a short account).

See also: Hammond, Robert

GW

By, Lieutenant-Colonel John

SUBJECT AREA: Canals

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b. 7 (?) August 1779 Lambeth, London, England

d. 1 February 1836 Frant, Sussex, England

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English Engineer-in-Charge of the construction of the Rideau Canal, linking the St Lawrence and Ottawa Rivers in Canada.

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Admitted in 1797 as a Gentleman Cadet in the Royal Military Academy at Woolwich, By was commissioned on 1 August 1799 as a second lieutenant in the Royal Artillery, but was soon transferred to the Royal Engineers. Posted to Plymouth upon the development of the fortifications, he was further posted to Canada, arriving there in August 1802.

In 1803 By was engaged in canal work, assisting Captain Bruyères in the construction of a short canal (1,500 ft (460 m) long) at the Cascades on the Grand, now the Ottawa, River. In 1805 he was back at the Cascades repairing ice damage caused during the previous winter. He was promoted Captain in 1809. Meanwhile he worked on the fortifications of Quebec and in 1806–7 he built a scale model of the Citadel, which is now in the National War Museum of Canada. He returned to England in 1810 and served in Portugal in 1811. Back in England at the end of the year, he was appointed Royal Engineer Officer in charge at the Waltham Abbey Gunpowder Works on 1 January 1812 and later planned the new Small Arms Factory at Enfield; both works were on the navigable River Lee.

In the post-Napoleonic period Major By, as he then was, retired on half-pay but was promoted to Lieu tenant-Colonel on 2 December 1824. Eighteen months later, in March 1826, he returned to Canada on active duty to build the Rideau Canal. This was John By's greatest work. It was conceived after the American war of 1812–14 as a connection for vessels to reach Kingston and the Great Lakes from Montreal while avoiding possible attack from the United States forces. Ships would pass up the Ottawa River using the already-constructed locks and bypass channels and then travel via a new canal cut through virgin forest southwards to the St Lawrence at Kingston. By based his operational headquarters at the Ottawa River end of the new works and in a forest clearing he established a small settlement. Because of the regard in which By was held, this settlement became known as By town. In 1855, long after By's death, the settlement was designated by Queen Victoria as capital of United Canada (which was to become a self-governing Dominion in 1867) and renamed Ottawa; as a result of the presence of the national government, the growth of the town accelerated greatly.

Between 1826–7 and 1832 the Rideau Canal was constructed. It included the massive engineering works of Jones Falls Dam (62 ft 6 in. (19 m) high) and 47 locks. By exercised an almost paternal care over those employed under his direction. The canal was completed in June 1832 at a cost of £800,000. By was summoned back to London to face virulent and unjust criticism from the Treasury. He was honoured in Canada but vilified by the British Government.

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Further Reading

R.F.Leggett, 1982, John By, Historical Society of Canada.

—1976, Canals of Canada, Newton Abbot: David \& Charles.

—1972, Rideau Waterway, Toronto: University of Toronto Press.

Bernard Pothier, 1978, "The Quebec Model", Canadian War Museum Paper 9, Ottawa: National Museums of Canada.

JHB

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

Clarke, Arthur Charles

SUBJECT AREA: Aerospace, Telecommunications

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b. 16 December 1917 Minehead, Somerset, England

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English writer of science fiction who correctly predicted the use of geo-stationary earth satellites for worldwide communications.

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Whilst still at Huish's Grammar School, Taunton, Clarke became interested in both space science and science fiction. Unable to afford a scientific education at the time (he later obtained a BSc at King's College, London), he pursued both interests in his spare time while working in the Government Exchequer and Audit Department between 1936 and 1941. He was a founder member of the British Interplanetary Society, subsequently serving as its Chairman in 1946–7 and 1950–3. From 1941 to 1945 he served in the Royal Air Force, becoming a technical officer in the first GCA (Ground Controlled Approach) radar unit. There he began to produce the first of many science-fiction stories. In 1949–50 he was an assistant editor of Science Abstracts at the Institution of Electrical Engineers.

As a result of his two interests, he realized during the Second World War that an artificial earth satellite in an equatorial orbital with a radius of 35,000 km (22,000 miles) would appear to be stationary, and that three such geo-stationary, or synchronous, satellites could be used for worldwide broadcast or communications. He described these ideas in a paper published in Wireless World in 1945. Initially there was little response, but within a few years the idea was taken up by the US National Aeronautics and Space Administration and in 1965 the first synchronous satellite, Early Bird, was launched into orbit.

In the 1950s he moved to Ceylon (now Sri Lanka) to pursue an interest in underwater exploration, but he continued to write science fiction, being known in particular for his contribution to the making of the classic Stanley Kubrick science-fiction film 2001: A Space Odyssey, based on his book of the same title.

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Principal Honours and Distinctions

Clarke received many honours for both his scientific and science-fiction writings. For his satellite communication ideas his awards include the Franklin Institute Gold Medal 1963 and Honorary Fellowship of the American Institute of Aeronautics and Astronautics 1976. For his science-fiction writing he received the UNESCO Kalinga Prize (1961) and many others. In 1979 he became Chancellor of Moratuwa University in Sri Lanka and in 1980 Vikran Scrabhai Professor at the Physical Research Laboratory of the University of Ahmedabad.

Bibliography

1945. "Extra-terrestrial relays: can rocket stations give world wide coverage?", Wireless World L1: 305 (puts forward his ideas for geo-stationary communication satellites).

1946. "Astronomical radar: some future possibilities", Wireless World 52:321.

1948, "Electronics and space flight", Journal of the British Interplanetary Society 7:49. Other publications, mainly science-fiction novels, include: 1955, Earthlight, 1956, The

Coast of Coral; 1958, Voice Across the Sea; 1961, Fall of Moondust; 1965, Voices

from the Sky, 1977, The View from Serendip; 1979, Fountain of Paradise; 1984, Ascent to Orbit: A Scientific Autobiography, and 1984, 2010: Odyssey Two (a sequel to 2001: A Space Odyssey that was also made into a film).

Further Reading

1986, Encyclopaedia Britannica.

1991, Who's Who, London: A. \& C.Black.

See also: Pierce, John Robinson

KF

Clinton, De Witt

SUBJECT AREA: Canals

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b. 2 March 1769 Little Britain, Orange County, New York, USA

d. 11 February 1828 Albany, New York, USA

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American statesman and entrepreneur.

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After gaining his degree at Columbia College, Clinton studied law and then entered politics. After a defeat in 1795 he studied natural science, until in 1798 he was elected to the State Senate. In 1802 he was elected to the US Senate, but he resigned in 1803 to become Mayor of New York City; he occupied this post, apart from two short breaks, until 1815, when he was removed from office. He was very concerned for the welfare of ordinary people and introduced many improvements. From 1815 Clinton devoted himself to what was to become the Erie Canal. He had already been appointed one of the canal commissioners in 1810 and had himself surveyed a possible route to Lake Erie that would be a safer passage from New York to the Great Lakes in the event of war with Great Britain. The war of 1812, in fact, interfered with the project, but in 1816 Clinton realized that the time was propitious. He arranged meetings, and on 17 April 1816 the legislature adopted his idea and a new survey for a link between the Hudson and Lake Erie was undertaken. In March 1817 he became Governor of New York State and vigorously pursued the canal scheme both in writing and by personal supervision of the works. Party politics removed him from his post as Canal Commissioner on 12 April 1824, but in November he was re-elected as Governor. He held this position when the Erie Canal (362 miles or 583 km long) and the Champlain Canal (71 miles or 114 km) were opened in 1825. In his character he was overbearing, but he was administratively competent.

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Further Reading

J.Renwick, 1840, Life of De Witt Clinton, New York.

JHB

Coade, Eleanor

SUBJECT AREA: Architecture and building

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b. 24 June 1733 Exeter, Devon, England

d. 18 November 1821 Camberwell, London, England

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English proprietor of the Coade Factory, making artificial stone.

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Born Elinor Coade, she never married but adopted, as was customary in business in the eighteenth century, the courtesy title of Mrs. Following the bankruptcy and death of her father, George Coade, in Exeter, Eleanor and her mother (also called Eleanor) moved to London and founded the works at Lambeth, South London, in 1769 that later became famous as the Coade factory. The factory was located at King's Arms Stairs, Narrow Wall. During the eighteenth century, several attempts had been made in other businesses to manufacture a durable, malleable artificial stone that would be acceptable to architects for decorative use. These substances were not very successful, but Coade stone was different. Although stories are legion about the secret formula supposedly used in this artificial stone, modern methods have established the exact formula.

Coade stone was a stoneware ceramic material fired in a kiln. The body was remarkable in that it shrank only 8 per cent in drying and firing: this was achieved by using a combination of china clay, sand, crushed glass and grog (i.e. crushed and ground, previously fired stoneware). The Coade formula thus included a considerable proportion of material that, having been fired once already, was unshrinkable. Mrs Coade's name for the firm, Coade's Lithodipyra Terra-Cotta or Artificial Stone Manufactory (where "Lithodipyra" is a term derived from three Greek words meaning "stone", "twice" and "fire"), made reference to the custom of including such material (such as in Josiah Wedgwood's basalt and jasper ware). The especially low rate of shrinkage rendered the material ideal for making extra-life-size statuary, and large architectural, decorative features to be incorporated into stone buildings.

Coade stone was widely used for such purposes by leading architects in Britain and Ireland from the 1770s until the 1830s, including Robert Adam, Sir Charles Barry, Sir William Chambers, Sir John Soane, John Nash and James Wyatt. Some architects introduced the material abroad, as far as, for example, Charles Bulfinch's United States Bank in Boston, Massachusetts, and Charles Cameron's redecoration for the Empress Catherine of the great palace Tsarkoe Selo (now Pushkin), near St Petersburg. The material so resembles stone that it is often mistaken for it, but it is so hard and resistant to weather that it retains sharpness of detail much longer than the natural substance. The many famous British buildings where Coade stone was used include the Royal Hospital, Chelsea, Carlton House and the Sir John Soane Museum (all of which are located in London), St George's Chapel at Windsor, Alnwick Castle in Northumberland, and Culzean Castle in Ayrshire, Scotland.

Apart from the qualities of the material, the Coade firm established a high reputation for the equally fine quality of its classical statuary. Mrs Coade employed excellent craftsmen such as the sculptor John Bacon (1740–99), whose work was mass-produced by the use of moulds. One famous example which was widely reproduced was the female caryatid from the south porch of the Erechtheion on the acropolis of Athens. A drawing of this had appeared in the second edition of Stuart and Revett's Antiquities of Athens in 1789, and many copies were made from the original Coade model; Soane used them more than once, for example on the Bank of England and his own houses in London.

Eleanor Coade was a remarkable woman, and was important and influential on the neo-classical scene. She had close and amicable relations with leading architects of the day, notably Robert Adam and James Wyatt. The Coade factory was enlarged and altered over the years, but the site was finally cleared during 1949–50 in preparation for the establishment of the 1951 Festival of Britain.

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Further Reading

A.Kelly, 1990, Mrs Coade's Stone, pub. in conjunction with the Georgian Group (an interesting, carefully written history; includes a detailed appendix on architects who used Coade stone and buildings where surviving work may be seen).

DY

Cobbett, William

SUBJECT AREA: Agricultural and food technology

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b. 9 March 1762 Farnham, Surrey, England

d. 17 June 1835 Guildford, Surrey, England

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English political writer and activist; writer on rural affairs, with a particular concern for the conditions of the agricultural worker; a keen experimental farmer who claimed responsibility for the import of Indian maize to Britain.

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The son of a smallholder farmer and self-taught surveyor, William Cobbett was brought up to farm work from an early age. In 1783 he took employment as an attorney's clerk in London, but not finding this to his liking he travelled to Chatham with the intention of joining the Navy. A mistake in "taking the King's shilling" found him in an infantry regiment. After a year's training he was sent out to Nova Scotia and quickly gained the rank of sergeant major. On leaving the Army he brought corruption charges against three officers in his regiment, but did not press with the prosecution. England was not to his taste, and he returned to North America with his wife.

In America Cobbett taught English to the growing French community displaced by the French Revolution. He found American criticism of Britain ill-balanced and in 1796 began to publish a daily newspaper under the title Porcupine's Gazetteer, in which he wrote editorials in defence of Britain. His writings won him little support from the Americans. However, on returning to London in 1800 he was offered, but turned down, the management of a Government newspaper. Instead he began to produce a daily paper called the Porcupine, which was superseded in 1802 by Cobbett's Political Register, this publication continued on a weekly basis until after his death. In 1803 he also began the Parliamentary Debates, which later merged into Hansard, the official report of parliamentary proceedings.

In 1805 Cobbett took a house and 300-acre (120-hectare) farm in Hampshire, from which he continued to write, but at the same time followed the pursuits he most enjoyed. In 1809 his criticism of the punishment given to mutineers in the militia at Ely resulted in his own imprisonment. On his release in 1812 he decided that the only way to remain an independent publisher was to move back to the USA. He bought a farm at Hampstead, Long Island, New York, and published A Year's Residence in America, which contains, amongst other things, an interesting account of a farmer's year.

Returning to Britain in the easier political climate of the 1820s, Cobbett bought a small seed farm in Kensington, then outside London. From there he made a number of journeys around the country, publishing accounts of them in his famous Rural Rides. His experiments and advice on the sowing and cultivation of crops, particularly turnips and swedes, and on forestry, were an important mechanism for the spread of ideas within the UK. He also claimed that he was the first to introduce the acacia and Indian maize to Britain. Much of his writing expresses a concern for the rural poor and he was firmly convinced that only parliamentary reform would achieve the changes needed. His political work and writing led to his election as Member of Parlaiment for Oldham in the 1835 election, which followed the Reform Act of 1832. However, by this time his energy was failing rapidly and he died peacefully at Normandy Farm, near Guildford, at the age of 73.

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Bibliography

Cobbett's Observations on Priestley's Emigration, published in 1794, was the first of his pro-British tracts written in America. On the basis of his stay in that country he wrote A Year's Residence in America. His books on agricultural practice included Woodlands (1825) and Treatise on Cobbett's Corn (1828). Dealing with more social problems he wrote an English Grammar for the use of Apprentices, Plough Boys, Soldiers and Sailors in 1818, and Cottage Economy in 1821.

Further Reading

Albert Pell, 1902, article in Journal of the Royal Agricultural Society of England 63:1–26 (describes the life and writings of William Cobbett).

James Sambrook, 1973, William Cobbett, London: Routledge (a more detailed study).

AP

Columella, Lucius Iunius Moderatus

SUBJECT AREA: Agricultural and food technology

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b. first century AD Gades (now Cádiz), Spain

d. first century AD Tarentum (now Taranto), Italy

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Spanish writer on agricultural practice during the Roman era.

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Columella was a native of Gades, a Roman municipium in southern Spain. The only knowledge of him is through his writings, in which he makes reference to his uncle, but not to his parents. His uncle was an expert farmer of the region, and it would appear that Columella spent much of his youth with him. As an adult he moved near to Rome, and spent the rest of his life in that region, owning at least three farms in Latium, and a fourth probably near the Etruscan town of Caere. There is evidence that he visited Syria in Cilicia, where it is possible that he was doing military service. His fame lies in the twelve books of the Res Rustica, which provide the most detailed extant discussion of Roman agricultural practice, and a single volume on trees. Each volume of Res Rustica was addressed and sent to Publius Silvinius as it was completed. The single volume De Arboribus, dealing with trees, vines and olives, was addressed to Epruis Marcellus. Columella was quoted by Seneca (4 BC-65 AD) and Pliny the elder (23–79 AD).

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Bibliography

1941, Res Rustica, Vols I–IV, trans. H.Boyd; Vols V–XII, trans. E.S.Forster and E.H.Heffner, Heinemann, Loeb Classical Library series (Vol. I has a biog. introd. with full bibliographical details).

AP

Dalen, Nils Gustav

SUBJECT AREA: Domestic appliances and interiors, Electricity, Ports and shipping

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b. 30 November 1869 Stenstorp, Sweden

d. 9 December 1937 Stockholm, Sweden

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Swedish physicist and engineer who was awarded the Nobel Prize for his "sun valve".

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Nils Gustav Dalen is probably best known as the inventor of the solid-fuel Aga Cooker. He was confined at home for some time in the 1920s, having been blinded as the result of an accident, and found the time to consider the need for an efficient, clean, attractive-looking cooker that would be economical in fuel consumption. The resultant cooking range of 1924 was based on sound scientific principles, was simple to manage and needed a minimum of attention.

The first Aga contained a cast-iron firebox enclosed in an insulated jacket of kieselguhr. The firebox was connected to cast-iron hotplates and ovens, all designed so that the heat was conducted to the various parts at precisely the correct temperatures for all types of cooking: simmering, boiling, roasting, baking and grilling. The hotplate heat was maintained at the desired temperature by way of insulated hinged covers that were lifted only when the hotplate was in use. The Aga was made in Sweden and was introduced into Britain in 1929. It was noted for being costly to purchase but inexpensive to run as no energy was wasted.

Dalen is also known for his invention of the "sun valve", a device which, as required, automatically lighted or extinguished light beacons and buoys; this invention brought him the Nobel Prize for Physics in 1912.

DY

Delvigne, Captain Henri-Gustave

SUBJECT AREA: Weapons and armour

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b. 1799 Hamburg, Germany

d. 18 October 1876 Toulon, France

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French soldier and firearms designer.

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He joined the French army after the restoration of the monarchy in 1815 and rose to the rank of Captain in the Royal Guard. His main interest was in developing a more effective rifle, and in 1826 he produced a model in which the chamber was narrower than the bore. By tapping the musket ball with the ramrod, the ball could be made to fit into the grooves of the rifling, thus ensuring greater accuracy and increased effective range over previous models. The French army adopted Delvigne's rifle and used it with some success in Algeria in the 1830s. In the meantime Delvigne tried to go a stage further by designing a cylindro-conical bullet with a hollow base, which would enable it to expand into the grooves when fired, but his concept did not come to total fruition and was left to Minié to develop some twenty years later. Even so, in 1842 Delvigne completed the design of a chambered breech rifle, which was also adopted by the French army.

CM

Dickson, J.T.

SUBJECT AREA: Chemical technology, Synthetic materials, Textiles

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b. c.1920 Scotland

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Scottish co-inventor of the polyester fibre, Terylene.

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The introduction of one type of artificial fibre encouraged chemists to look for more. J.T.Dickson and J.R. Whinfield discovered one such fibre in 1941 when they derived polyester from terephthalic acid and ethylene glycol. Dickson, a 21-year-old Edinburgh graduate, was working under Whinfield at the Calico Printers' Association research laboratory at Broad Oak Print Works in Accrington. He was put onto fibre research: probably in April, but certainly by 5 July 1941, a murky-looking resin had been synthesized, out of which Dickson successfully drew a filament, which was named "Terylene" by its discoverers. Owing to restrictions imposed in Britain during the Second World War, this fibre was developed initially by the DuPont Company in the USA, where it was marketed under the name "Dacron". When Imperial Chemical Industries (ICI) were able to manufacture it in Britain, it acquired the brand name "Terylene" and became very popular. Under the microscope, Terylene appears identical to nylon: longitudinally, it is completely devoid of any structure and the filaments appear as glass rods with a perfectly circular cross-section. The uses of Terylene are similar to those of nylon, but it has two advantages. First, it can be heat-set by exposing the fabric to a temperature about 30°C higher than is likely to be encountered in everyday use, and therefore can be the basis for "easy-care" clothing such as drip-dry shirts. It can be blended with other fibres such as wool, and when pressed at a high temperature the creases are remarkably durable. It is also remarkably resistant to chemicals, which makes it particularly suitable for industrial purposes under conditions where other textile materials would be degraded rapidly. Dickson later worked for ICI.

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Further Reading

For accounts of the discovery of Terylene, see: J.R.Whinfield, 1953, Textile Research Journal (May). R.Collins, 1991, "Terylene", Historian 30 (Spring).

Accounts of the introduction of svnthetic fibres are covered in: D.S.Lyle, 1982, Modern Textiles, New York.

S.R.Cockett, An Introduction to Man-Made Fibres.

G.R.Wray, Modern Yarn Production.

RLH

Diesel, Rudolph Christian Karl

SUBJECT AREA: Steam and internal combustion engines

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b. 1858 Paris, France

d. 1913 at sea, in the English Channel

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German inventor of the Diesel or Compression Ignition engine.

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A German born in Paris, he was educated in Augsburg and later in Munich, where he graduated first in his class. There he took some courses under Professor Karl von Linde, pioneer of mechanical refrigeration and an authority on thermodynamics, who pointed out the low efficiency of the steam engine. He went to work for the Linde Ice Machine Company as an engineer and later as Manager; there he conceived a new basic cycle and worked out its thermodynamics, which he published in 1893 as "The theory and construction of a rational heat motor". Compressing air adiabatically to one-sixteenth of its volume caused the temperature to rise to 1,000°F (540°C). Injected fuel would then ignite automatically without any electrical system. He obtained permission to use the laboratories of the Augsburg-Nuremburg Engine Works to build a single-cylinder prototype. On test it blew up, nearly killing Diesel. He proved his principle, however, and obtained financial support from the firm of Alfred Krupp. The design was refined until successful and in 1898 an engine was put on display in Munich with the result that many business people invested in Diesel and his engine and its worldwide production. Diesel made over a million dollars out of the invention. The heart of the engine is the fuel-injection pump, which operates at a pressure of c.500 psi (35 kg/cm). The first English patent for the engine was in 1892. The firms in Augsburg sent him abroad to sell his engine; he persuaded the French to adopt it for submarines, Germany having refused this. Diesel died in 1913 in mysterious circumstances, vanishing from the Harwich-Antwerp ferry.

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Further Reading

E.Diesel, 1937, Diesel, derMensch, das Werk, das Schicksal, Hamburg. J.S.Crowther, 1959, Six Great Engineers, London.

John F.Sandfort, 1964, Heat Engines.

IMcN

Diggle, Squire

SUBJECT AREA: Textiles

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fl. c.1845 England

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English inventor of a mechanized drop box for shuttles on power looms.

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Robert Kay improved his father John's flying shuttle by inventing the drop box, in which up to four shuttles could be stored one below the other. The weaver's left hand controlled levers and catches to raise or lower the drop box in order to bring the appropriate shuttle into line with the shuttle race on the slay. The shuttle could then be driven across the loom, leaving its particular type or colour of weft. On the earliest power looms of Edmund Cartwright in 1785, and for many years later, it was possible to use only one shuttle. In 1845 Squire Diggle of Bury, Lancashire, took out a patent for mechanizing the drop box so that different types or colours of weft could be woven without the weaver attending to the shuttles. He used an endless chain on which plates of different heights could be fixed to raise the boxes to the required height; later this would be operated by either the dobby or Jacquard pattern-selecting mechanisms. He took out further patents for improvements to looms. One, in 1854, was for taking up the cloth with a positive motion. Two more, in 1858, improved his drop box mechanism: the first was for actually operating the drop box, while the second was for tappet chains which operated the timing for raising the boxes.

[br]

Bibliography

1845, British patent no. 10,462 (mechanized drop box). 1854, British patent no. 1,100 (positive uptake of cloth) 1858, British patent no. 2,297 (improved drop-box operation). 1858, British patent no. 2,704 (tappet chains).

Further Reading

A.Barlow, 1878, The History and Principles of Weaving by Hand and by Power, London (provides drawings of Diggle's invention).

C.Singer (ed.), 1958, A History of Technology, Vol. IV, Oxford: Clarendon Press.

See also: Kay, John

RLH

Ding Huan (Ting Huan)

SUBJECT AREA: Domestic appliances and interiors, Photography, film and optics

[br]

fl. c.100 AD China

[br]

Chinese inventor of various devices.

[br]

Ding Huan invented a form of suspension rediscovered by the French Renaissance mathematician Jerome Cardan, although a reference in the "Ode to beautiful women" (c.740) indicates that the device was probably in existence earlier (see vol. IV.2, p. 233 in the reference given below). Ding Huan also invented the zoetrope lamp (c.180), which had a thin canopy bearing vanes at the top that were caused to rotate by an ascending current of warm air from the lamp. The canopy bore images which, if the canopy were rotated fast enough, gave the impression of movement, as in early forerunners of the cinematograph. In the Xi Jing Za Ji (Miscellaneous Records of the Western Capital), it is recorded that Ding Huan devised an air-conditioning fan that consisted of a set of seven fans, each 10 ft (3 m) in diameter, connected so that they could be worked together by one person. The device could cool a hall so that "people would even begin to shiver".

[br]

Further Reading

J.Needham, 1972–4, Science and Civilisation in China, Cambridge: Cambridge University Press, vols IV. 1, pp. 123, 125; IV. 2, pp. 150–1, 233, 236; V. 2, p. 133.

LRD

Ehrlich, Paul

SUBJECT AREA: Medical technology

[br]

b. 14 March 1854 Strehlen, Silesia, Germany

d. 20 August 1915 Homburg, Saarland, Germany

[br]

German medical scientist who laid the foundations of intra-vital staining in histology, and of chemotherapy.

[br]

After studying medicine at a number of schools in Germany, Ehrlich graduated from Leipzig in 1878. After some years at the Charite in Berlin, an attack of tuberculosis compelled a three-year sojourn in Egypt for treatment. Upon his return in 1890, he was invited by Koch to work at the new Institute for Infectious Diseases. There he commenced his work on immunity, having already, while a student, discovered the mast cells in the blood (1877) and then developed the techniques of differential staining which identified the other white cells of the blood. In 1882 he established the diazo reaction in the urine of typhoid patients, and in the same year he identified the acid-fast staining reactions of the tubercle bacillus. He then moved to the study of immunity in infectious disease, which led him to the search for synthetic chemical substances which would act on the causative organism without harming the patient's tissue. The outcome of his specific investigation of syphilis was the discovery of the first two specific chemotherapeutic agents: salvarsan (being the 606th compound to be tested); and the later, but less toxic, neosalvarsan (the 909th). In 1896 he became Director of the State Institute for Serum Research, and in 1906 Director of the new Royal Institute for Experimental Therapy at Frankfurt-am-Main. He received numerous awards and honours from governments and learned societies.

[br]

Principal Honours and Distinctions

Nobel Prize for Medicine or Physiology (jointly with E.Metchnikov) 1908.

Bibliography

1879, "Beiträge für Kentnis der granulierten Bindegewabszellen und der Eosinophilen Leucocythen" Arch. Anat. Physiol. Abt.

1914, Paul Ehrlich: eine Darstellung seines wissenschaftlichen Wirkens, Festschrift zum

60. Geburtstage des Forschers.

Further Reading

M.Marquardt, 1924, Paul Ehrlich als Mensch und Arbeiter.

MG

Elder, John

SUBJECT AREA: Ports and shipping, Steam and internal combustion engines

[br]

b. 9 March 1824 Glasgow, Scotland

d. 17 September 1869 London, England

[br]

Scottish engineer who introduced the compound steam engine to ships and established an important shipbuilding company in Glasgow.

[br]

John was the third son of David Elder. The father came from a family of millwrights and moved to Glasgow where he worked for the well-known shipbuilding firm of Napier's and was involved with improving marine engines. John was educated at Glasgow High School and then for a while at the Department of Civil Engineering at Glasgow University, where he showed great aptitude for mathematics and drawing. He spent five years as an apprentice under Robert Napier followed by two short periods of activity as a pattern-maker first and then a draughtsman in England. He returned to Scotland in 1849 to become Chief Draughtsman to Napier, but in 1852 he left to become a partner with the Glasgow general engineering company of Randolph Elliott \& Co. Shortly after his induction (at the age of 28), the engineering firm was renamed Randolph Elder \& Co.; in 1868, when the partnership expired, it became known as John Elder \& Co. From the outset Elder, with his partner, Charles Randolph, approached mechanical (especially heat) engineering in a rigorous manner. Their knowledge and understanding of entropy ensured that engine design was not a hit-and-miss affair, but one governed by recognition of the importance of the new kinetic theory of heat and with it a proper understanding of thermodynamic principles, and by systematic development. In this Elder was joined by W.J.M. Rankine, Professor of Civil Engineering and Mechanics at Glasgow University, who helped him develop the compound marine engine. Elder and Randolph built up a series of patents, which guaranteed their company's commercial success and enabled them for a while to be the sole suppliers of compound steam reciprocating machinery. Their first such engine at sea was fitted in 1854 on the SS Brandon for the Limerick Steamship Company; the ship showed an improved performance by using a third less coal, which he was able to reduce still further on later designs.

Elder developed steam jacketing and recognized that, with higher pressures, triple-expansion types would be even more economical. In 1862 he patented a design of quadruple-expansion engine with reheat between cylinders and advocated the importance of balancing reciprocating parts. The effect of his improvements was to greatly reduce fuel consumption so that long sea voyages became an economic reality.

His yard soon reached dimensions then unequalled on the Clyde where he employed over 4,000 workers; Elder also was always interested in the social welfare of his labour force. In 1860 the engine shops were moved to the Govan Old Shipyard, and again in 1864 to the Fairfield Shipyard, about 1 mile (1.6 km) west on the south bank of the Clyde. At Fairfield, shipbuilding was commenced, and with the patents for compounding secure, much business was placed for many years by shipowners serving long-distance trades such as South America; the Pacific Steam Navigation Company took up his ideas for their ships. In later years the yard became known as the Fairfield Shipbuilding and Engineering Company Ltd, but it remains today as one of Britain's most efficient shipyards and is known now as Kvaerner Govan Ltd.

In 1869, at the age of only 45, John Elder was unanimously elected President of the Institution of Engineers and Shipbuilders in Scotland; however, before taking office and giving his eagerly awaited presidential address, he died in London from liver disease. A large multitude attended his funeral and all the engineering shops were silent as his body, which had been brought back from London to Glasgow, was carried to its resting place. In 1857 Elder had married Isabella Ure, and on his death he left her a considerable fortune, which she used generously for Govan, for Glasgow and especially the University. In 1883 she endowed the world's first Chair of Naval Architecture at the University of Glasgow, an act which was reciprocated in 1901 when the University awarded her an LLD on the occasion of its 450th anniversary.

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Principal Honours and Distinctions

President, Institution of Engineers and Shipbuilders in Scotland 1869.

Further Reading

Obituary, 1869, Engineer 28.

1889, The Dictionary of National Biography, London: Smith Elder \& Co. W.J.Macquorn Rankine, 1871, "Sketch of the life of John Elder" Transactions of the

Institution of Engineers and Shipbuilders in Scotland.

Maclehose, 1886, Memoirs and Portraits of a Hundred Glasgow Men.

The Fairfield Shipbuilding and Engineering Works, 1909, London: Offices of Engineering.

P.M.Walker, 1984, Song of the Clyde, A History of Clyde Shipbuilding, Cambridge: PSL.

R.L.Hills, 1989, Power from Steam. A History of the Stationary Steam Engine, Cambridge: Cambridge University Press (covers Elder's contribution to the development of steam engines).

RLH / FMW

Ericsson, John

SUBJECT AREA: Ports and shipping, Railways and locomotives

[br]

b. 31 July 1803 Farnebo, Sweden

d. 8 March 1899 New York, USA

[br]

Swedish (naturalized American 1848) engineer and inventor.

[br]

The son of a mine owner and inspector, Ericsson's first education was private and haphazard. War with Russia disrupted the mines and the father secured a position on the Gotha Canal, then under construction. He enrolled John, then aged 13, and another son as cadets in a corps of military engineers engaged on the canal. There John was given a sound education and training in the physical sciences and engineering. At the age of 17 he decided to enlist in the Army, and on receiving a commission he was drafted to cartographic survey duties. After some years he decided that a career outside the Army offered him the best opportunities, and in 1826 he moved to London to pursue a career of mechanical invention.

Ericsson first developed a heat (external combustion) engine, which proved unsuccessful. Three years later he designed and constructed the steam locomotive Novelty, which he entered in the Rainhill locomotive trials on the new Liverpool \& Manchester Railway. The engine began by performing promisingly, but it later broke down and failed to complete the test runs. Later he devised a self-regulating lead (1835) and then, more important and successful, he invented the screw propeller, patented in 1835 and installed in his first screw-propelled ship of 1839. This work was carried out independently of Sir Francis Pettit Smith, who contemporaneously developed a four-bladed propeller that was adopted by the British Admiralty. Ericsson saw that with screw propulsion the engine could be below the waterline, a distinct advantage in warships. He crossed the Atlantic to interest the American government in his ideas and became a naturalized citizen in 1848. He pioneered the gun turret for mounting heavy guns on board ship. Ericsson came into his own during the American Civil War, with the construction of the epoch-making warship Monitor, a screw-propelled ironclad with gun turret. This vessel demonstrated its powers in a signal victory at Hampton Roads on 9 March 1862.

Ericsson continued to design warships and torpedoes, pointing out to President Lincoln that success in war would now depend on technological rather than numerical superiority. Meanwhile he continued to pursue his interest in heat engines, and from 1870 to 1888 he spent much of his time and resources in pursuing research into alternative energy sources, such as solar power, gravitation and tidal forces.

[br]

Further Reading

W.C.Church, 1891, Life of John Ericsson, 2 vols, London.

LRD

Ferguson, Harry

SUBJECT AREA: Agricultural and food technology

[br]

b. 4 November 1884 County Down, Ireland

d. 25 October 1960 England

[br]

Irish engineer who developed a tractor hydraulic system for cultivation equipment, and thereby revolutionized tractor design.

[br]

Ferguson's father was a small farmer who expected his son to help on the farm from an early age. As a result he received little formal education, and on leaving school joined his brother in a backstreet workshop in Belfast repairing motor bikes. By the age of 19 he had built his own bike and began hill-climbing competitions and racing. His successes in these ventures gained useful publicity for the workshop. In 1907 he built his own car and entered it into competitions, and in 1909 became the first person in Britain to build and fly a machine that was heavier than air.

On the outbreak of the First World War he was appointed by the Irish Department of Agriculture to supervise the operation and maintenance of all farm tractors. His experiences convinced him that even the Ford tractor and the implements available for it were inadequate for the task, and he began to experiment with his own plough designs. The formation of the Ferguson-Sherman Corporation resulted in the production of thousands of the ploughs he had designed for the Ford tractor, but in 1928 Ford discontinued production of tractors, and Ferguson returned to Ireland. He immediately began to design his own tractor. Six years of development led to the building of a prototype that weighed only 16 cwt (813kg). In 1936 David Brown of Huddersfield, Yorkshire, began production of these tractors for Ferguson, but the partnership was not wholly successful and was dissolved after three years. In 1939 Ferguson and Ford reached their famous "Handshake agreement", in which no formal contract was signed, and the mass production of the Ford Ferguson system tractors began that year. During the next nine years 300,000 tractors and a million implements were produced under this agreement. However, on the death of Henry Ford the company began production, under his son, of their own tractor. Ferguson returned to the UK and negotiated a deal with the Standard Motor Company of Coventry for the production of his tractor. At the same time he took legal action against Ford, which resulted in that company being forced to stop production and to pay damages amounting to US$9.5 million.

Aware that his equipment would only operate when set up properly, Ferguson established a training school at Stoneleigh in Warwickshire which was to be a model for other manufacturers. In 1953, by amicable agreement, Ferguson amalgamated with the Massey Harris Company to form Massey Ferguson, and in so doing added harvesting machinery to the range of equipment produced. A year later he disposed of his shares in the new company and turned his attention again to the motor car. Although a number of experimental cars were produced, there were no long-lasting developments from this venture other than a four-wheel-drive system based on hydraulics; this was used by a number of manufacturers on occasional models. Ferguson's death heralded the end of these developments.

[br]

Principal Honours and Distinctions

Honorary DSc Queen's University, Belfast, 1948.

Further Reading

C.Murray, 1972, Harry Ferguson, Inventor and Pioneer. John Murray.

AP

Fischer, E.

SUBJECT AREA: Broadcasting, Electronics and information technology

[br]

fl. 1930s Switzerland

[br]

Swiss engineer who invented the Eidophor large-screen television projector.

[br]

Fischer was a professor of engineering at the Swiss Federal Institute of Technology in the late 1930s. Interested in the emerging technology for television, he was of the opinion that the growth of television would take place through the development and use of large-screen cinema-type displays serving large audiences. He therefore carried out research into suitable techniques. Realizing the brightness limitations of projection systems based on the optical magnification of the image produced by a conventional cathode ray tube, he used the deflected electron-beam, not to excite a phosphor screen, but to deposit a variable charge on the surface of a film or oil. By means of a Schlieren slit system, the consequent deformations of the surface were used to spatially modulate the light from an electric arc or a discharge tube, giving a large, high-brightness image. Although the idea, first put forward in 1939, was not taken up for cinema television, the subsequent requirement of the US National Aeronautics and Space Administration in the 1960s for large colour displays in its Command and Control Centres led to the successful development of the idea by Gretag AG, a subsidiary of Ciba-Geigy: separate units were used for the red, green and blue images. In the 1990s, colour Eidophor projectors were used for large conference meetings and pop concerts.

[br]

Bibliography

1946, "Views on the suitability of a cathode ray tube with a fluorescent screen for projection in cinemas", Bulletin of the Association of Swiss Electricians 39:468 (describes the concept of the Eidophor).

Further Reading

E.H.Baumann, 1953, "The Fischer large screen projection system", Journal of Society of Motion Picture and Television Engineers 60:344.

A.Robertson, 1976, "Projection television. A review of current practice in large-screen projectors", Wireless World 47.

KF