to institute a vice-president

vice-president

n

1) вице-президент, заместитель президента

2) заместитель председателя

•

to institute a vice-president — учреждать должность вице-президента

to run for vice-president — баллотироваться на пост вице-президента

to stand as vice-president — баллотироваться на выборах в качестве кандидата на пост вице-президента

- current vice-president

Appleton, Sir Edward Victor

SUBJECT AREA: Broadcasting, Telecommunications

[br]

b. 6 September 1892 Bradford, England

d. 21 April 1965 Edinburgh, Scotland

[br]

English physicist awarded the Nobel Prize for Physics for his discovery of the ionospheric layer, named after him, which is an efficient reflector of short radio waves, thereby making possible long-distance radio communication.

[br]

After early ambitions to become a professional cricketer, Appleton went to St John's College, Cambridge, where he studied under J.J.Thompson and Ernest Rutherford. His academic career interrupted by the First World War, he served as a captain in the Royal Engineers, carrying out investigations into the propagation and fading of radio signals. After the war he joined the Cavendish Laboratory, Cambridge, as a demonstrator in 1920, and in 1924 he moved to King's College, London, as Wheatstone Professor of Physics.

In the following decade he contributed to developments in valve oscillators (in particular, the "squegging" oscillator, which formed the basis of the first hard-valve time-base) and gained international recognition for research into electromagnetic-wave propagation. His most important contribution was to confirm the existence of a conducting ionospheric layer in the upper atmosphere capable of reflecting radio waves, which had been predicted almost simultaneously by Heaviside and Kennelly in 1902. This he did by persuading the BBC in 1924 to vary the frequency of their Bournemouth transmitter, and he then measured the signal received at Cambridge. By comparing the direct and reflected rays and the daily variation he was able to deduce that the Kennelly- Heaviside (the so-called E-layer) was at a height of about 60 miles (97 km) above the earth and that there was a further layer (the Appleton or F-layer) at about 150 miles (240 km), the latter being an efficient reflector of the shorter radio waves that penetrated the lower layers. During the period 1927–32 and aided by Hartree, he established a magneto-ionic theory to explain the existence of the ionosphere. He was instrumental in obtaining agreement for international co-operation for ionospheric and other measurements in the form of the Second Polar Year (1932–3) and, much later, the International Geophysical Year (1957–8). For all this work, which made it possible to forecast the optimum frequencies for long-distance short-wave communication as a function of the location of transmitter and receiver and of the time of day and year, in 1947 he was awarded the Nobel Prize for Physics.

He returned to Cambridge as Jacksonian Professor of Natural Philosophy in 1939, and with M.F. Barnett he investigated the possible use of radio waves for radio-location of aircraft. In 1939 he became Secretary of the Government Department of Scientific and Industrial Research, a post he held for ten years. During the Second World War he contributed to the development of both radar and the atomic bomb, and subsequently served on government committees concerned with the use of atomic energy (which led to the establishment of Harwell) and with scientific staff.

[br]

Principal Honours and Distinctions

Knighted (KCB 1941, GBE 1946). Nobel Prize for Physics 1947. FRS 1927. Vice- President, American Institute of Electrical Engineers 1932. Royal Society Hughes Medal 1933. Institute of Electrical Engineers Faraday Medal 1946. Vice-Chancellor, Edinburgh University 1947. Institution of Civil Engineers Ewing Medal 1949. Royal Medallist 1950. Institute of Electrical and Electronics Engineers Medal of Honour 1962. President, British Association 1953. President, Radio Industry Council 1955–7. Légion d'honneur. LLD University of St Andrews 1947.

Bibliography

1925, joint paper with Barnett, Nature 115:333 (reports Appleton's studies of the ionosphere).

1928, "Some notes of wireless methods of investigating the electrical structure of the upper atmosphere", Proceedings of the Physical Society 41(Part III):43. 1932, Thermionic Vacuum Tubes and Their Applications (his work on valves).

1947, "The investigation and forecasting of ionospheric conditions", Journal of the

Institution of Electrical Engineers 94, Part IIIA: 186 (a review of British work on the exploration of the ionosphere).

with J.F.Herd \& R.A.Watson-Watt, British patent no. 235,254 (squegging oscillator).

Further Reading

Who Was Who, 1961–70 1972, VI, London: A. \& C.Black (for fuller details of honours). R.Clark, 1971, Sir Edward Appleton, Pergamon (biography).

J.Jewkes, D.Sawers \& R.Stillerman, 1958, The Sources of Invention.

KF

Riley, James

SUBJECT AREA: Metallurgy

[br]

b. 1840 Halifax, England

d. 15 July 1910 Harrogate, England

[br]

English steelmaker who promoted the manufacture of low-carbon bulk steel by the open-hearth process for tin plate and shipbuilding; pioneer of nickel steels.

[br]

After working as a millwright in Halifax, Riley found employment at the Ormesby Ironworks in Middlesbrough until, in 1869, he became manager of the Askam Ironworks in Cumberland. Three years later, in 1872, he was appointed Blast-furnace Manager at the pioneering Siemens Steel Company's works at Landore, near Swansea in South Wales. Using Spanish ore, he produced the manganese-rich iron (spiegeleisen) required as an additive to make satisfactory steel. Riley was promoted in 1874 to be General Manager at Landore, and he worked with William Siemens to develop the use of the latter's regenerative furnace for the production of open-hearth steel. He persuaded Welsh makers of tin plate to use sheets rolled from lowcarbon (mild) steel instead of from charcoal iron and, partly by publishing some test results, he was instrumental in influencing the Admiralty to build two naval vessels of mild steel, the Mercury and the Iris.

In 1878 Riley moved north on his appointment as General Manager of the Steel Company of Scotland, a firm closely associated with Charles Tennant that was formed in 1872 to make steel by the Siemens process. Already by 1878, fourteen Siemens melting furnaces had been erected, and in that year 42,000 long tons of ingots were produced at the company's Hallside (Newton) Works, situated 8 km (5 miles) south-east of Glasgow. Under Riley's leadership, steelmaking in open-hearth furnaces was initiated at a second plant situated at Blochairn. Plates and sections for all aspects of shipbuilding, including boilers, formed the main products; the company also supplied the greater part of the steel for the Forth (Railway) Bridge. Riley was associated with technical modifications which improved the performance of steelmaking furnaces using Siemens's principles. He built a gasfired cupola for melting pig-iron, and constructed the first British "universal" plate mill using three-high rolls (Lauth mill).

At the request of French interests, Riley investigated the properties of steels containing various proportions of nickel; the report that he read before the Iron and Steel Institute in 1889 successfully brought to the notice of potential users the greatly enhanced strength that nickel could impart and its ability to yield alloys possessing substantially lower corrodibility.

The Steel Company of Scotland paid dividends in the years to 1890, but then came a lean period. In 1895, at the age of 54, Riley moved once more to another employer, becoming General Manager of the Glasgow Iron and Steel Company, which had just laid out a new steelmaking plant at Wishaw, 25 km (15 miles) south-east of Glasgow, where it already had blast furnaces. Still the technical innovator, in 1900 Riley presented an account of his experiences in introducing molten blast-furnace metal as feed for the open-hearth steel furnaces. In the early 1890s it was largely through Riley's efforts that a West of Scotland Board of Conciliation and Arbitration for the Manufactured Steel Trade came into being; he was its first Chairman and then its President.

In 1899 James Riley resigned from his Scottish employment to move back to his native Yorkshire, where he became his own master by acquiring the small Richmond Ironworks situated at Stockton-on-Tees. Although Riley's 1900 account to the Iron and Steel Institute was the last of the many of which he was author, he continued to contribute to the discussion of papers written by others.

[br]

Principal Honours and Distinctions

President, West of Scotland Iron and Steel Institute 1893–5. Vice-President, Iron and Steel Institute, 1893–1910. Iron and Steel Institute (London) Bessemer Gold Medal 1887.

Bibliography

1876, "On steel for shipbuilding as supplied to the Royal Navy", Transactions of the Institute of Naval Architects 17:135–55.

1884, "On recent improvements in the method of manufacture of open-hearth steel", Journal of the Iron and Steel Institute 2:43–52 plus plates 27–31.

1887, "Some investigations as to the effects of different methods of treatment of mild steel in the manufacture of plates", Journal of the Iron and Steel Institute 1:121–30 (plus sheets II and III and plates XI and XII).

27 February 1888, "Improvements in basichearth steel making furnaces", British patent no. 2,896.

27 February 1888, "Improvements in regenerative furnaces for steel-making and analogous operations", British patent no. 2,899.

1889, "Alloys of nickel and steel", Journal of the Iron and Steel Institute 1:45–55.

Further Reading

A.Slaven, 1986, "James Riley", in Dictionary of Scottish Business Biography 1860–1960, Volume 1: The Staple Industries (ed. A.Slaven and S. Checkland), Aberdeen: Aberdeen University Press, 136–8.

"Men you know", The Bailie (Glasgow) 23 January 1884, series no. 588 (a brief biography, with portrait).

J.C.Carr and W.Taplin, 1962, History of the British Steel Industry, Harvard University Press (contains an excellent summary of salient events).

JKA

Zworykin, Vladimir Kosma

SUBJECT AREA: Broadcasting, Electronics and information technology

[br]

b. 30 July 1889 Mourum (near Moscow), Russia

d. 29 July 1982 New York City, New York, USA

[br]

Russian (naturalized American 1924) television pioneer who invented the iconoscope and kinescope television camera and display tubes.

[br]

Zworykin studied engineering at the Institute of Technology in St Petersburg under Boris Rosing, assisting the latter with his early experiments with television. After graduating in 1912, he spent a time doing X-ray research at the Collège de France in Paris before returning to join the Russian Marconi Company, initially in St Petersburg and then in Moscow. On the outbreak of war in 1917, he joined the Russian Army Signal Corps, but when the war ended in the chaos of the Revolution he set off on his travels, ending up in the USA, where he joined the Westinghouse Corporation. There, in 1923, he filed the first of many patents for a complete system of electronic television, including one for an all-electronic scanning pick-up tube that he called the iconoscope. In 1924 he became a US citizen and invented the kinescope, a hard-vacuum cathode ray tube (CRT) for the display of television pictures, and the following year he patented a camera tube with a mosaic of photoelectric elements and gave a demonstration of still-picture TV. In 1926 he was awarded a PhD by the University of Pittsburgh and in 1928 he was granted a patent for a colour TV system.

In 1929 he embarked on a tour of Europe to study TV developments; on his return he joined the Radio Corporation of America (RCA) as Director of the Electronics Research Group, first at Camden and then Princeton, New Jersey. Securing a budget to develop an improved CRT picture tube, he soon produced a kinescope with a hard vacuum, an indirectly heated cathode, a signal-modulation grid and electrostatic focusing. In 1933 an improved iconoscope camera tube was produced, and under his direction RCA went on to produce other improved types of camera tube, including the image iconoscope, the orthicon and image orthicon and the vidicon. The secondary-emission effect used in many of these tubes was also used in a scintillation radiation counter. In 1941 he was responsible for the development of the first industrial electron microscope, but for most of the Second World War he directed work concerned with radar, aircraft fire-control and TV-guided missiles.

After the war he worked for a time on high-speed memories and medical electronics, becoming Vice-President and Technical Consultant in 1947. He "retired" from RCA and was made an honorary vice-president in 1954, but he retained an office and continued to work there almost up until his death; he also served as Director of the Rockefeller Institute for Medical Research from 1954 until 1962.

[br]

Principal Honours and Distinctions

Zworykin received some twenty-seven awards and honours for his contributions to television engineering and medical electronics, including the Institution of Electrical Engineers Faraday Medal 1965; US Medal of Science 1966; and the US National Hall of Fame 1977.

Bibliography

29 December 1923, US patent no. 2,141, 059 (the original iconoscope patent; finally granted in December 1938!).

13 July 1925, US patent no. 1,691, 324 (colour television system).

1930, with D.E.Wilson, Photocells and Their Applications, New York: Wiley. 1934, "The iconoscope. A modern version of the electric eye". Proceedings of the

Institute of Radio Engineers 22:16.

1946, Electron Optics and the Electron Microscope.

1940, with G.A.Morton, Television; revised 1954.

1949, with E.G.Ramberg, Photoelectricity and Its Applications. 1958, Television in Science and Industry.

Further Reading

J.H.Udelson, 1982, The Great Television Race: History of the Television Industry 1925– 41: University of Alabama Press.

See also: Baird, John Logie; Farnsworth, Philo Taylor; Jenkins, Charles Francis

KF

Townes, Charles Hard

SUBJECT AREA: Electronics and information technology

[br]

b. 28 July 1915 Greenville, South Carolina, USA

[br]

American physicist who developed the maser and contributed to the development of the laser.

[br]

Charles H.Townes entered Furman University, Greenville, at the early age of 16 and in 1935 obtained a BA in modern languages and a BS in physics. After a year of postgraduate study at Duke University, he received a master's degree in physics in 1936. He then went on to the California Institute of Technology, where he obtained a PhD in 1939. From 1939 to 1947 he worked at the Bell Telephone Laboratories, mainly on airborne radar, although he also did some work on radio astronomy. In 1948 he joined Columbia University as Associate Professor of Physics and in 1950 was appointed a full professor. He was Director of the University's Radiation Laboratory from 1950 to 1952, and from 1952 to 1955 he was Chairman of the Physics Department.

To meet the need for an oscillator generating very short wavelength electromagnetic radiation, Townes in 1951 realized that use could be made of the different natural energy levels of atoms and molecules. The practical application of this idea was achieved in his laboratory in 1953 using ammonia gas to make the device known as a maser (an acronym of microwave amplification by stimulated emission of radiation). The maser was developed in the next few years and in 1958, in a joint paper with his brother-in-law Arthur L. Schawlow, Townes suggested the possibility of a further development into optical frequencies or an optical maser, later known as a laser (an acronym of light amplification by stimulated emission of radiation). Two years later the first such device was made by Theodore H. Maiman.

In 1959 Townes was given leave from Columbia University to serve as Vice-President and Director of Research at the Institute for Defense Analyses until 1961. He was then appointed Provost and Professor of Physics at the Massachusetts Institute of Technology. In 1967 he became University Professor of Physics at the University of California, where he has extended his research interests in the field of microwave and infra-red astronomy. He is a member of the National Academy of Sciences, the Institute of Electrical and Electronics Engineers and the American Astronomical Society.

[br]

Principal Honours and Distinctions

Nobel Prize for Physics 1964. Foreign Member, Royal Society of London. President, American Physical Society 1967. Townes has received many awards from American and other scientific societies and institutions and honorary degrees from more than twenty universities.

Bibliography

Townes is the author of many scientific papers and, with Arthur L.Schawlow, of

Microwave Spectroscopy (1955).

1980, entry, McGraw-Hill Modern Scientists and Engineers, Part 3, New York, pp. 227– 8 (autobiography).

1991, entry, The Nobel Century, London, p. 106 (autobiography).

Further Reading

T.Wasson (ed.), 1987, Nobel Prize Winners, New York, pp. 1,071–3 (contains a short biography).

RTS

Watson-Watt, Sir Robert Alexander

SUBJECT AREA: Aerospace, Electronics and information technology, Weapons and armour

[br]

b. 13 April 1892 Brechin, Angus, Scotland

d. 6 December 1973 Inverness, Scotland

[br]

Scottish engineer and scientific adviser known for his work on radar.

[br]

Following education at Brechin High School, Watson-Watt entered University College, Dundee (then a part of the University of St Andrews), obtaining a BSc in engineering in 1912. From 1912 until 1921 he was Assistant to the Professor of Natural Philosophy at St Andrews, but during the First World War he also held various posts in the Meteorological Office. During. this time, in 1916 he proposed the use of cathode ray oscillographs for radio-direction-finding displays. He joined the newly formed Radio Research Station at Slough when it was opened in 1924, and 3 years later, when it amalgamated with the Radio Section of the National Physical Laboratory, he became Superintendent at Slough. At this time he proposed the name "ionosphere" for the ionized layer in the upper atmosphere. With E.V. Appleton and J.F.Herd he developed the "squegger" hard-valve transformer-coupled timebase and with the latter devised a direction-finding radio-goniometer.

In 1933 he was asked to investigate possible aircraft counter-measures. He soon showed that it was impossible to make the wished-for radio "death-ray", but had the idea of using the detection of reflected radio-waves as a means of monitoring the approach of enemy aircraft. With six assistants he developed this idea and constructed an experimental system of radar (RAdio Detection And Ranging) in which arrays of aerials were used to detect the reflected signals and deduce the bearing and height. To realize a practical system, in September 1936 he was appointed Director of the Bawdsey Research Station near Felixstowe and carried out operational studies of radar. The result was that within two years the East Coast of the British Isles was equipped with a network of radar transmitters and receivers working in the 7–14 metre band—the so-called "chain-home" system—which did so much to assist the efficient deployment of RAF Fighter Command against German bombing raids on Britain in the early years of the Second World War.

In 1938 he moved to the Air Ministry as Director of Communications Development, becoming Scientific Adviser to the Air Ministry and Ministry of Aircraft Production in 1940, then Deputy Chairman of the War Cabinet Radio Board in 1943. After the war he set up Sir Robert Watson-Watt \& Partners, an industrial consultant firm. He then spent some years in relative retirement in Canada, but returned to Scotland before his death.

[br]

Principal Honours and Distinctions

Knighted 1942. CBE 1941. FRS 1941. US Medal of Merit 1946. Royal Society Hughes Medal 1948. Franklin Institute Elliot Cresson Medal 1957. LLD St Andrews 1943. At various times: President, Royal Meteorological Society, Institute of Navigation and Institute of Professional Civil Servants; Vice-President, American Institute of Radio Engineers.

Bibliography

1923, with E.V.Appleton \& J.F.Herd, British patent no. 235,254 (for the "squegger"). 1926, with J.F.Herd, "An instantaneous direction reading radio goniometer", Journal of

the Institution of Electrical Engineers 64:611.

1933, The Cathode Ray Oscillograph in Radio Research.

1935, Through the Weather Hours (autobiography).

1936, "Polarisation errors in direction finders", Wireless Engineer 13:3. 1958, Three Steps to Victory.

1959, The Pulse of Radar.

1961, Man's Means to his End.

Further Reading

S.S.Swords, 1986, Technical History of the Beginnings of Radar, Stevenage: Peter Peregrinus.

KF

Sarnoff, David

SUBJECT AREA: Broadcasting, Electronics and information technology, Telecommunications

[br]

b. 27 February 1891 Uzlian, Minsk (now in Belarus)

d. 12 December 1971 New York City, New York, USA

[br]

Russian/American engineer who made a major contribution to the commercial development of radio and television.

[br]

As a Jewish boy in Russia, Sarnoff spent several years preparing to be a Talmudic Scholar, but in 1900 the family emigrated to the USA and settled in Albany, New York. While at public school and at the Pratt Institute in Brooklyn, New York, he helped the family finances by running errands, selling newspapers and singing the liturgy in the synagogue. After a short period as a messenger boy with the Commercial Cable Company, in 1906 he became an office boy with the Marconi Wireless Telegraph Company of America (see G. Marconi). Having bought a telegraph instrument with his first earnings, he taught himself Morse code and was made a junior telegraph operator in 1907. The following year he became a wireless operator at Nantucket Island, then in 1909 he became Manager of the Marconi station at Sea Gate, New York. After two years at sea he returned to a shore job as wireless operator at the world's most powerful station at Wanamaker's store in Manhattan. There, on 14 April 1912, he picked up the distress signals from the sinking iner Titanic, remaining at his post for three days.

Rewarded by rapid promotion (Chief Radio Inspector 1913, Contract Manager 1914, Assistant Traffic Manager 1915, Commercial Manager 1917) he proposed the introduction of commercial radio broadcasting, but this received little response. Consequently, in 1919 he took the job of Commercial Manager of the newly formed Radio Corporation of America (RCA), becoming General Manager in 1921, Vice- President in 1922, Executive Vice-President in 1929 and President in 1930. In 1921 he was responsible for the broadcasting of the Dempsey-Carpentier title-fight, as a result of which RCA sold $80 million worth of radio receivers in the following three years. In 1926 he formed the National Broadcasting Company (NBC). Rightly anticipating the development of television, in 1928 he inaugurated an experimental NBC television station and in 1939 demonstrated television at the New York World Fair. Because of his involvement with the provision of radio equipment for the armed services, he was made a lieutenant-colonel in the US Signal Corps Reserves in 1924, a full colonel in 1931 and, while serving as a communications consultant to General Eisenhower during the Second World War, Brigadier General in 1944.

With the end of the war, RCA became a major manufacturer of television receivers and then invested greatly in the ultimately successful development of shadowmask tubes and receivers for colour television. Chairman and Chief Executive from 1934, Sarnoff held the former post until his retirement in 1970.

[br]

Principal Honours and Distinctions

French Croix de Chevalier d'honneur 1935, Croix d'Officier 1940, Croix de Commandant 1947. Luxembourg Order of the Oaken Crown 1960. Japanese Order of the Rising Sun 1960. US Legion of Merit 1946. UN Citation 1949. French Union of Inventors Gold Medal 1954.

KF

See also: Zworykin, Vladimir Kosma

Goldmark, Peter Carl

SUBJECT AREA: Broadcasting, Electronics and information technology, Recording

[br]

b. 2 December 1906 Budapest, Hungary

d. 7 December 1977 Westchester Co., New York, USA

[br]

Austro-Hungarian engineer who developed the first commercial colour television system and the long-playing record.

[br]

After education in Hungary and a period as an assistant at the Technische Hochschule, Berlin, Goldmark moved to England, where he joined Pye of Cambridge and worked on an experimental thirty-line television system using a cathode ray tube (CRT) for the display. In 1936 he moved to the USA to work at Columbia Broadcasting Laboratories. There, with monochrome television based on the CRT virtually a practical proposition, he devoted his efforts to finding a way of producing colour TV images: in 1940 he gave his first demonstration of a working system. There then followed a series of experimental field-sequential colour TV systems based on segmented red, green and blue colour wheels and drums, where the problem was to find an acceptable compromise between bandwidth, resolution, colour flicker and colour-image breakup. Eventually he arrived at a system using a colour wheel in combination with a CRT containing a panchromatic phosphor screen, with a scanned raster of 405 lines and a primary colour rate of 144 fields per second. Despite the fact that the receivers were bulky, gave relatively poor, dim pictures and used standards totally incompatible with the existing 525-line, sixty fields per second interlaced monochrome (black and white) system, in 1950 the Federal Communications Commission (FCC), anxious to encourage postwar revival of the industry, authorized the system for public broadcasting. Within eighteen months, however, bowing to pressure from the remainder of the industry, which had formed its own National Television Systems Committee (NTSC) to develop a much more satisfactory, fully compatible system based on the RCA three-gun shadowmask CRT, the FCC withdrew its approval.

While all this was going on, Goldmark had also been working on ideas for overcoming the poor reproduction, noise quality, short playing-time (about four minutes) and limited robustness and life of the long-established 78 rpm 12 in. (30 cm) diameter shellac gramophone record. The recent availability of a new, more robust, plastic material, vinyl, which had a lower surface noise, enabled him in 1948 to reduce the groove width some three times to 0.003 in. (0.0762 mm), use a more lightly loaded synthetic sapphire stylus and crystal transducer with improved performance, and reduce the turntable speed to 33 1/3 rpm, to give thirty minutes of high-quality music per side. This successful development soon led to the availability of stereophonic recordings, based on the ideas of Alan Blumlein at EMI in the 1930s.

In 1950 Goldmark became a vice-president of CBS, but he still found time to develop a scan conversion system for relaying television pictures to Earth from the Lunar Orbiter spacecraft. He also almost brought to the market a domestic electronic video recorder (EVR) system based on the thermal distortion of plastic film by separate luminance and coded colour signals, but this was overtaken by the video cassette recorder (VCR) system, which uses magnetic tape.

[br]

Principal Honours and Distinctions

Institute of Electrical and Electronics Engineers Morris N.Liebmann Award 1945. Institute of Electrical and Electronics Engineers Vladimir K. Zworykin Award 1961.

Bibliography

1951, with J.W.Christensen and J.J.Reeves, "Colour television. USA Standard", Proceedings of the Institute of Radio Engineers 39: 1,288 (describes the development and standards for the short-lived field-sequential colour TV standard).

1949, with R.Snepvangers and W.S.Bachman, "The Columbia long-playing microgroove recording system", Proceedings of the Institute of Radio Engineers 37:923 (outlines the invention of the long-playing record).

Further Reading

E.W.Herold, 1976, "A history of colour television displays", Proceedings of the Institute of Electrical and Electronics Engineers 64:1,331.

See also: Baird, John Logie

KF

Saniter, Ernest Henry

SUBJECT AREA: Metallurgy

[br]

b. 1863 Middlesbrough, England

d. 2 November 1934 Rotherham, Yorkshire

[br]

English chemist and metallurgist who introduced a treatment to remove sulphur from molten iron.

[br]

Saniter spent three years as a pupil in J.E.Stead's chemical laboratory in Middlesbrough, and then from 1883 was employed in the same town as Assistant Chemist at the new North-Eastern Steelworks. In 1890 he became Chief Chemist to the Wigan Coal and Iron Company in Lancashire. There he devised a desulphurizing treatment for molten iron and steel, based upon the presence of abundant lime together with calcium chloride. Between 1898 and 1904 he was in the Middlesbrough district once more, employed by Dorman Long \& Co. and Bell Brothers in experiments which led to the establishment of Teesside's first large-scale basic open-hearth steel plant. Calcium fluoride (fluorspar), mentioned in Saniter's 1892 patent, soon came to replace the calcium chloride; with this modification, his method retained wide applicability throughout the era of open-hearth steel. In 1904 Saniter became chief metallurgist to Steel, Peech \& Tozer Limited of Sheffield, and he remained in this post until 1928. Throughout the last forty years of his life he participated in the discussion of steelmaking developments and practices.

[br]

Principal Honours and Distinctions

Vice-President, Iron and Steel Institute 1927–34. Iron and Steel Institute (London) Bessemer Gold Medal 1910.

Bibliography

1892. "A new process for the purification of iron and steel from sulphur", Journal of the Iron and Steel Institute 2:216–22.

1893. "A supplementary paper on a new process for desulphurising iron and steel", Journal of the Iron and Steel Institute 1:73–7. 29 October 1892, British patent no. 8,612.

15 October 1892, British patent no. 8,612A. 29 July 1893, British patent no. 17, 692.

28 October 1893, British patent no. 23,534.

Further Reading

K.C.Barraclough, 1990, Steelmaking: 1850–1900 458, London: Institute of Metals, 271– 8.

JKA

Murray, John Mackay

SUBJECT AREA: Ports and shipping

[br]

b. 25 June 1902 Glasgow, Scotland

d. 5 August 1966 Maplehurst, Sussex, England

[br]

Scottish naval architect who added to the understanding of the structural strength of ships.

[br]

Murray was educated in Glasgow at Allan Glen's School and then at the University, from which he graduated in naval architecture in 1922. He served an apprenticeship simultaneously with Barclay Curle \& Co., rising to the rank of Assistant Shipyard Manager before leaving in 1927 to join Lloyd's Register of Shipping. After an initial year in Newcastle, he joined the head office in London, which was to be base for the remainder of his working life. Starting with plan approval, he worked his way to experimental work on ship structures and was ultimately given the massive task of revising Lloyd's Rules and placing them on a scientific basis. During the Second World War he acted as liaison officer between Lloyd's and the Admiralty. Throughout his career he presented no fewer than twenty-two papers on ship design, and of these nearly half dealt with hull longitudinal strength. This work won him considerable acclaim and several awards and was of fundamental importance to the shipping industry. The Royal Institution of Naval Architects honoured Murray in 1960 by inviting him to present one of the only two papers read at their centenary meeting: "Merchant ships 1860–1960". At Lloyd's Register he rose to Chief Ship Surveyor, and at the time of his death was Honorary Vice-President of the Royal Institution of Naval Architects.

[br]

Principal Honours and Distinctions

MBE 1946. Honorary Vice-President, Royal Institution of Naval Architects. Royal Institution of Naval Architects Froude Gold Medal. Institute of Marine Engineers Silver Medal. Premium of the Institution of Engineers and Shipbuilders in Scotland.

FMW

Voelcker, John Christopher

SUBJECT AREA: Agricultural and food technology

[br]

b. 24 September 1822 Frankfurt am Main, Germany

d. 5 December 1884 England

[br]

German analytical chemist resident in England whose reports on feedstuffs and fertilizers had a considerable influence on the quality of these products.

[br]

The son of a merchant in the city of his birth, John Christopher had delicate health and required private tuition to overcome the loss of his early years of schooling. At the age of 22 he went to study chemistry at Göttingen University and then worked for a short time for Liebig at Giessen. In 1847 he obtained a post as Analyst and Consulting Chemist at the Agricultural Chemistry Association of Scotland's Edinburgh office, and two years later he became Professor of Chemistry at the Royal Agricultural College in Cirencester, retaining this post until 1862. In 1855 he was appointed Chemist to the Bath and West Agricultural Society, and in that capacity organized lectures and field trials, and in 1857 he also became Consulting Chemist to the Royal Agricultural Society of England. Initially he studied the properties of farmyard manure and also the capacity of the soil to absorb ammonia, potash and sodium. As Consulting Chemist to farmers he analysed feedstuffs and manures; his assessments of artificial manures did much to force improvements in standards. During the 1860s he worked on milk and dairy products. He published the results of his work each year in the Journal of the Royal Agricultural Society of England. In 1877 he became involved in the field trials initiated and funded by the Duke of Bedford on his Woburn farm, and he continued his association with this venture until his death.

[br]

Principal Honours and Distinctions

FRS. Founder and Vice-President, Institute of Chemistry of Great Britain and Northern Ireland 1877. Member Chemical Society 1849; he was a member of Council as well as its Vice-President at the time of his death. Member of the Board of Studies, Royal Agricultural College, Cirencester; Honorary Professor from 1882.

Bibliography

His papers are to be found in the Journal of the Royal Agricultural Society of England, for which he began to write reports in 1855, and also in the Journal of the Bath and West Society.

Further Reading

J.H.Gilbert, 1844, obituary, Journal of the Royal Agricultural Society of England, pp. 308–21 (a detailed account).

Sir E.John Russell, A History of Agricultural Science in Great Britain.

See also: Voelcker, John Augustus

AP

Donkin, Bryan IV

SUBJECT AREA: Electricity, Public utilities

[br]

b. 29 April 1903 London, England

d. 17 October 1964 Albury, Surrey, England

[br]

English electrical engineer.

[br]

Bryan Donkin IV was the son of S.B.Donkin (1871–1952) and the great-great-grandson of Bryan Donkin I (1768–1855). He was educated at Gresham's School in Holt, and at Pembroke College, Cambridge. He served a three-year apprenticeship with the English Electric Company Ltd, followed by a special one-year course with the General Electric Company of America. He became a partner in the consulting firm of Kennedy \& Donkin in 1933 (see Donkin, Bryan III) and was associated with the construction of 132 kV and 275 kV overhead-transmission lines in Britain and with many electricity generating schemes. He was responsible for the design of the Pimlico district heating scheme, and was a member of the Institution of Civil Engineers, the Institution of Electrical Engineers and the American Institute of Electrical Engineers.

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Principal Honours and Distinctions

President, Association of Supervising Electrical Engineers 1954–6. President, Engineer's Guild 1954–6. President, Junior Institution of Engineers 1956–7. Vice-President, Institution of Electrical Engineers 1960–4.

RTS

Wood, Henry Alexander Wise

SUBJECT AREA: Paper and printing

[br]

b. 1 March 1866 New York, USA

d. 9 April 1939 USA

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American manufacturer and inventor of printing machinery, including a stereotype casting machine.

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The son of a Congressman and mayor of New York, Wood was educated at Media Academy in Pennsylvania, specializing in scientific subjects. The death of his father in 1881 prevented his going on to college and he went to work at the Campbell Printing and Manufacturing Company, of which he became President in 1896. In the meantime, he had married the daughter of J.L.Brower, the previous head of the company. Later business consolidations brought into being the Wood Newspaper Machine Corporation.

Wood was responsible for a series of inventions that brought great benefit to the newspaperprinting processes. Most notable was the Autoplate, patented first in 1900 and finally in 1903. This enabled a whole page of newspaper type to be cast in metal at once, saving much time and effort in the forming of stereotypes; this invention earned him the Elliott Cresson gold medal of the Franklin Institute in 1909. Other inventions were the Autoreel, a high-speed press-feeder device, and the Autopaster, which automatically replaced a spent paper roll with a new one in a newspaper press, without the need to stop the press. Wood's improved presses and inventions increased the speed of newspaper production from 24,000 to 60,000 copies per hour, printed and folded.

He was also much interested in aviation and was an early member of the Aero Club of America, becoming its Vice-President for six years. He helped to found the magazine Flying and was its Editor from 1911 to 1919. He had predicted the part played by aircraft and submarines during the Second World War and was invited to join a panel of consulting inventors and engineers to assist the development of the US Navy. He was soon at odds with the authorities, however, and he resigned in 1915. After the war, he spent time in vigorous campaigning against immigration, America's entry into the League of Nations and on many other issues, in all of which he was highly controversial. Nevertheless, he retained his interest in the newspaper-machinery business, remaining President of his company until 1935 and Chairman of the Board thereafter. In 1934 he became Chairman of the NRA Code Authority of the newspaper-machine industry.

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Further Reading

Obituary, 1939, New York Times (10 April). Obituary, 1939, New York Herald Tribune (10 April).

LRD

Alden, George I.

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering

[br]

b. 22 April 1843 Templeton, Massachusetts, USA

d. 13 September 1926 Princeton, Massachusetts, USA

[br]

American mechanical engineer and professor of engineering.

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From 1868 to 1896 George Alden was head of the steam and mechanical engineering departments at the Worcester Polytechnic Institute, Worcester, Massachusetts. He made a donation in 1910 to establish a hydraulic laboratory at the Institute, and later a further donation for an extension of the laboratory which was completed in 1925. He was Chairman of the Board of Norton (Abrasives) Company and made a significant contribution to the theory of grinding in his paper in 1914 to the American Society of Mechanical Engineers. He was a member of that society from 1880, the year of its foundation, and took an active part in its proceedings.

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Principal Honours and Distinctions

Vice-President, American Society of Mechanical Engineers 1891–3.

Bibliography

1914, "Operation of grinding wheels in machine grinding", Transactions of the American Society of Mechanical Engineers 36:451–60.

Further Reading

For a description of the Alden Hydraulic Laboratory, see Mechanical Engineering, June 1926: 634–5.

RTS

Bode, Hendrik Wade

SUBJECT AREA: Electronics and information technology, Weapons and armour

[br]

b. 24 December 1905 Madison, Wisconsin, USA

d. 21 June 1982 Cambridge, Massachusetts, USA

[br]

American engineer who developed an extensive theoretical understanding of the behaviour of electronic circuits.

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Bode received his bachelor's and master's degrees from Ohio State University in 1924 and 1926, respectively, and his PhD from Columbia University, New York, in 1935. In 1926 he joined the Bell Telephone Laboratories, where he made many theoretical contributions to the understanding of the behaviour of electronic circuits and, in particular, in conjunction with Harry Nyquist, of the conditions under which amplifier circuits become unstable.

During the Second World War he worked on the design of gun control systems and afterwards was a member of a team that worked with Douglas Aircraft to develop the Nike anti-aircraft missile. A member of the Bell Laboratories Mathematical Research Group from 1929, he became its Director in 1952, and then Director of Physical Sciences. Finally he became Vice-President of the Laboratories, with responsibility for systems engineering, and a director of Bellcomm, a Bell company involved in the Moon-landing programme. When he retired from Bell in 1967, he became Professor of Systems Engineering at Harvard University.

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Principal Honours and Distinctions

Presidential Certificate of Merit 1946. Institute of Electrical and Electronics Engineers Edison Medal 1969.

Bibliography

1940, "Relation between attenuation and phase in feedback amplifier design", Bell System Technical Journal 19:421.

1945, Network Analysis and Feedback Amplifier Design, New York: Van Nostrand.

1950, with C.E.Shannon, "A simplified derivation of linear least squares smoothing and prediction theory", Proceedings of the Institute of Radio Engineers 38:417.

1961, "Feedback. The history of an idea", Proceedings of the Symposium on Active Networks and Feedback Systems, Brooklyn Polytechnic.

1971, Synergy: Technical Integration and Technical Innovation in the Bell System Bell Laboratories, Bell Telephone Laboratories (provides background on his activities at Bell).

Further Reading

P.C.Mahon, 1975, Mission Communications, Bell Telephone Laboratories. See also Black, Harold Stephen; Shannon, Claude Elwood.

KF

Bond, George Meade

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering

[br]

b. 17 July 1852 Newburyport, Massachusetts, USA

d. 6 January 1935 Hartford, Connecticut, USA

[br]

American mechanical engineer and metrologist, co-developer of the Rogers- Bond Comparator.

[br]

After leaving school at the age of 17, George Bond taught in local schools for a few years before starting an apprenticeship in a machine shop in Grand Rapids, Michigan. He then worked as a machinist with Phoenix Furniture Company in that city until his savings permitted him to enter the Stevens Institute of Technology at Hoboken, New Jersey, in 1876. He graduated with the degree of Mechanical Engineer in 1880. In his final year he assisted William A.Rogers, Professor of Astronomy at Harvard College Observatory, Cambridge, Massachusetts, in the design of a comparator for checking standards of length. In 1880 he joined the Pratt \& Whitney Company, Hartford, Connecticut, and was Manager of the Standards and Gauge Department from then until 1902. During this period he developed cylindrical, calliper, snap, limit, thread and other gauges. He also designed the Bond Standard Measuring Machine. Bond was elected a member of the American Society of Mechanical Engineers in 1881 and of the American Society of Civil Engineers in 1887, and served on many of their committees relating to standards and units of measurement.

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Principal Honours and Distinctions

Vice-President, American Society of Mechanical Engineers 1908–10. Honorary degrees of DEng, Stevens Institute of Technology 1921, and MSc, Trinity College, Hartford, 1927.

Bibliography

1881. "Standard measurements", Transactions of the American Society of Mechanical Engineers 2:81.

1882. "A standard gauge system", Transactions of the American Society of Mechanical

Engineers 3:122.

1886, "Standard pipe and pipe threads", Transactions of the American Society of Mechanical Engineers 7:311.

1887. Standards of Length and Their Practical Application, Hartford.

Further Reading

"Report of the Committee on Standards and Gauges", 1883, Transactions of the American Society of Mechanical Engineers 4:21–9 (describes the Rogers-Bond Comparator).

See also: Pratt, Francis Ashbury; Whitney, Amos

RTS

Kettering, Charles Franklin

SUBJECT AREA: Automotive engineering, Electricity, Electronics and information technology, Metallurgy, Steam and internal combustion engines

[br]

b. 29 August 1876 near Londonsville, Ohio, USA

d. 25 November 1958 Dayton, Ohio, USA

[br]

American engineer and inventor.

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Kettering gained degrees in mechanical and electrical engineering from Ohio State University. He was employed by the National Construction Register (NCR) of Dayton, Ohio, where he devised an electric motor for use in cash registers. He became Head of the Inventions Department of that company but left in 1909 to form, with the former Works Manager of NCR, Edward A. Deeds, the Dayton Engineering Laboratories (later called Delco), to develop improved lighting and ignition systems for automobiles. In the first two years of the new company he produced not only these but also the first self-starter, both of which were fitted to the Cadillac, America's leading luxury car. In 1914 he founded Dayton Metal Products and the Dayton Wright Airplane Company. Two years later Delco was bought by General Motors. In 1925 the independent research facilities of Delco were moved to Detroit and merged with General Motors' laboratories to form General Motors Research Corporation, of which Kettering was President and General Manager. (He had been Vice-President of General Motors since 1920.) In that position he headed investigations into methods of achieving maximum engine performance as well as into the nature of friction and combustion. Many other developments in the automobile field were made under his leadership, such as engine coolers, variable-speed transmissions, balancing machines, the two-way shock absorber, high-octane fuel, leaded petrol or gasoline, fast-drying lacquers, crank-case ventilators, chrome plating, and the high-compression automobile engine. Among his other activities were the establishment of the Charles Franklin Kettering Foundation for the Study of Chlorophyll and Photosynthesis at Antioch College, and the founding of the Sloan- Kettering Institute for Cancer Research in New York City. He sponsored the Fever Therapy Research Project at Miami Valley Hospital at Dayton, which developed the hypertherm, or artificial fever machine, for use in the treatment of disease. He resigned from General Motors in 1947.

IMcN

Barnaby, Kenneth C.

SUBJECT AREA: Ports and shipping

[br]

b. c.1887 England

d. 22 March 1968 England

[br]

English naval architect and technical author.

[br]

Kenneth Barnaby was an eminent naval architect, as were his father and grandfather before him: his grandfather was Sir Nathaniel Barnaby KGB, Director of Naval Construction, and his father was Sydney W.Barnaby, naval architect of John I. Thornycroft \& Co., Shipbuilders, Southampton. At one time all three were members of the Institution of Naval Architects, the first time that this had ever occurred with three members from one family.

Kenneth Barnaby served his apprenticeship at the Thornycroft shipyard in Southampton and later graduated in engineering from the Central Technical College, South Kensington, London. He worked for some years at Le Havre and at John Brown's shipyard at Clydebank before rejoining his old firm in 1916 as Assistant to the Shipyard Manager. In 1919 he went to Rio de Janeiro as a chief ship draughtsman, and finally he returned to Thornycroft, in 1924 he succeeded his father as Naval Architect, and remained in that post until his retirement in 1955, having been appointed a director in 1950.

Barnaby had a wide knowledge and understanding of ships and ship design and during the Second World War he was responsible for much of the development work for landing craft, as well as for many other specialist ships built at the Southampton yard. His experience as a deep-sea yachtsman assisted him. He wrote several important books; however, none can compare with the Centenary Volume of the Royal Institution of Naval Architects. In this work, which is used and read widely to this day by naval architects worldwide, he reviewed every paper presented and almost every verbal contribution made to the Transactions during its one hundred years.

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Principal Honours and Distinctions

OBE 1945. Associate of the City and Guilds Institute. Royal Institution of Naval Architects Froude Gold Medal 1962. Honorary Vice-President, Royal Institution of Naval Architects 1960–8.

Bibliography

c.1900, Marine Propellers, London. 1949, Basic Naval Architecture, London.

1960, The Institution of Naval Architects 1860–1960, London.

1964, 100 Years of Specialised Shipbuilding and Engineering, London. 1968, Some Ship Disasters and their Causes, London.

FMW

Colpitts, Edwin Henry

SUBJECT AREA: Electronics and information technology, Telecommunications

[br]

b. 9 January 1872 Pointe de Bute, Canada

d. 6 March 1949 Orange, New Jersey, USA

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Canadian physicist and electrical engineer responsible for important developments in electronic-circuit technology.

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Colpitts obtained Bachelor's degrees at Mount Allison University, Sackville, New Brunswick, and Harvard in 1894 and 1896, respectively, followed by a Master's degree at Harvard in 1897. After two years as assistant to the professor of physics there, he joined the American Bell Telephone Company. When the Bell Company was reorganized in 1907, he moved to the Western Electric branch of the company in New York as Head of the Physical Laboratories. In 1911 he became a director of the Research Laboratories, and in 1917 he became Assistant Chief Engineer of the company. During this time he invented both the push-pull amplifier and the Colpitts oscillator, both major developments in communications. In 1917, during the First World War, he spent some time in France helping to set up the US Signal Corps Research Laboratories. Afterwards he continued to do much, both technically and as a manager, to place telephone communications on a firm scientific basis, retiring as Vice-President of the Bell Telephone Laboratories in 1937. With the outbreak of the Second World War in 1941 he was recalled from retirement and appointed Director of the Engineering Foundation to work on submarine warfare techniques, particularly echo-ranging.

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Principal Honours and Distinctions

Order of the Rising Sun, Japan, 1938. US Medal of Merit 1948.

Bibliography

1919, with E.B.Craft, "Radio telephony", Proceedings of the American Institution of Electrical Engineers 38:337.

1921, with O.B.Blackwell, "Carrier current telephony and telegraphy", American Institute of Electrical Engineers Transactions 40:205.

11 September 1915, US reissue patent no. 15,538 (control device for radio signalling).

28 August 1922, US patent no. 1,479,638 (multiple signal reception).

Further Reading

M.D.Fagen, 1975, A History of Engineering \& Science in the Bell System, Vol. 1, Bell Laboratories.

See also: Hartley, Ralph V.L.

KF

Coolidge, William David

SUBJECT AREA: Electricity, Metallurgy

[br]

b. 23 October 1873 Hudson, Massachusetts, USA

d. 3 February 1975 New York, USA

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American physicist and metallurgist who invented a method of producing ductile tungsten wire for electric lamps.

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Coolidge obtained his BS from the Massachusetts Institute of Technology (MIT) in 1896, and his PhD (physics) from the University of Leipzig in 1899. He was appointed Assistant Professor of Physics at MIT in 1904, and in 1905 he joined the staff of the General Electric Company's research laboratory at Schenectady. In 1905 Schenectady was trying to make tungsten-filament lamps to counter the competition of the tantalum-filament lamps then being produced by their German rival Siemens. The first tungsten lamps made by Just and Hanaman in Vienna in 1904 had been too fragile for general use. Coolidge and his life-long collaborator, Colin G. Fink, succeeded in 1910 by hot-working directly dense sintered tungsten compacts into wire. This success was the result of a flash of insight by Coolidge, who first perceived that fully recrystallized tungsten wire was always brittle and that only partially work-hardened wire retained a measure of ductility. This grasped, a process was developed which induced ductility into the wire by hot-working at temperatures below those required for full recrystallization, so that an elongated fibrous grain structure was progressively developed. Sintered tungsten ingots were swaged to bar at temperatures around 1,500°C and at the end of the process ductile tungsten filament wire was drawn through diamond dies around 550°C. This process allowed General Electric to dominate the world lamp market. Tungsten lamps consumed only one-third the energy of carbon lamps, and for the first time the cost of electric lighting was reduced to that of gas. Between 1911 and 1914, manufacturing licences for the General Electric patents had been granted for most of the developed work. The validity of the General Electric monopoly was bitterly contested, though in all the litigation that followed, Coolidge's fibering principle was upheld. Commercial arrangements between General Electric and European producers such as Siemens led to the name "Osram" being commonly applied to any lamp with a drawn tungsten filament. In 1910 Coolidge patented the use of thoria as a particular additive that greatly improved the high-temperature strength of tungsten filaments. From this development sprang the technique of "dispersion strengthening", still being widely used in the development of high-temperature alloys in the 1990s. In 1913 Coolidge introduced the first controllable hot-cathode X-ray tube, which had a tungsten target and operated in vacuo rather than in a gaseous atmosphere. With this equipment, medical radiography could for the first time be safely practised on a routine basis. During the First World War, Coolidge developed portable X-ray units for use in field hospitals, and between the First and Second World Wars he introduced between 1 and 2 million X-ray machines for cancer treatment and for industrial radiography. He became Director of the Schenectady laboratory in 1932, and from 1940 until 1944 he was Vice-President and Director of Research. After retirement he was retained as an X-ray consultant, and in this capacity he attended the Bikini atom bomb trials in 1946. Throughout the Second World War he was a member of the National Defence Research Committee.

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Bibliography

1965, "The development of ductile tungsten", Sorby Centennial Symposium on the History of Metallurgy, AIME Metallurgy Society Conference, Vol. 27, ed. Cyril Stanley Smith, Gordon and Breach, pp. 443–9.

Further Reading

D.J.Jones and A.Prince, 1985, "Tungsten and high density alloys", Journal of the Historical Metallurgy Society 19(1):72–84.

ASD