cbe

Cockerell, Christopher Sydney

SUBJECT AREA: Aerospace, Ports and shipping

[br]

b. 4 June 1910 Cambridge, England

[br]

British designer and engineer who invented the hovercraft.

[br]

He was educated at Gresham's School in Holt and at Peterhouse College, Cambridge, where he graduated in engineering in 1931; he was made an Honorary Fellow in 1974. Cockerell entered the engineering firm of W.H.Allen \& Sons of Bedford as a pupil in 1931, and two years later he returned to Cambridge to engage in radio research for a further two years. In 1935 he joined Marconi Wireless Telegraph Company, working on very high frequency (VHF) transmitters and direction finders. During the Second World War he worked on airborne navigation and communication equipment, and later he worked on radar. During this period he filed thirty six patents in the fields of radio and navigational systems.

In 1950 Cockerell left Marconi to set up his own boat-hire business on the Norfolk Broads. He began to consider how to increase the speed of boats by means of air lubrication. Since the 1870s engineers had at times sought to reduce the drag on a boat by means of a thin layer of air between hull and water. After his first experiments, Cockerell concluded that a significant reduction in drag could only be achieved with a thick cushion of air. After experimenting with several ways of applying the air-cushion principle, the first true hovercraft "took off" in 1955. It was a model in balsa wood, 2 ft 6 in. (762 mm) long and weighing 4½ oz. (27.6 g); it was powered by a model-aircraft petrol engine and could travel over land or water at 13 mph (20.8 km/h). Cockerell filed his first hovercraft patent on 12 December 1955. The following year he founded Hovercraft Ltd and began the search for a manufacturer. The government was impressed with the invention's military possibilities and placed it on the secret list. The secret leaked out, however, and the project was declassified. In 1958 the National Research and Development Corporation decided to give its backing, and the following year Saunders Roe Ltd with experience of making flying boats, produced the epoch-making SR N1, a hovercraft with an air cushion produced by air jets directed downwards and inwards arranged round the periphery of the craft. It made a successful crossing of the English Channel, with the inventor on board.

Meanwhile Cockerell had modified the hovercraft so that the air cushion was enclosed within flexible skirts. In this form it was taken up by manufacturers throughout the world and found wide application as a passenger-carrying vehicle, for military transport and in scientific exploration and survey work. The hover principle found other uses, such as for air-beds to relieve severely burned patients and for hover mowers.

The development of the hovercraft has occupied Cockerell since then and he has been actively involved in the several companies set up to exploit the invention, including Hovercraft Development Ltd and British Hovercraft Corporation. In the 1970s and 1980s he took up the idea of the generation of electricity by wavepower; he was Founder of Wavepower Ltd, of which he was Chairman from 1974 to 1982.

[br]

Principal Honours find Distinctions

Knighted 1969. CBE 1955. FRS 1967.

LRD

de Havilland, Sir Geoffrey

SUBJECT AREA: Aerospace

[br]

b. 27 July 1882 High Wycombe, Buckinghamshire, England

d. 21 May 1965 Stanmore, Middlesex, England

[br]

English designer of some eighty aircraft from 1909 onwards.

[br]

Geoffrey de Havilland started experimenting with aircraft and engines of his own design in 1908. In the following year, with the help of his friend Frank Hearle, he built and flew his first aircraft; it crashed on its first flight. The second aircraft used the same engine and made its first flight on 10 September 1910, and enabled de Havilland to teach himself to fly. From 1910 to 1914 he was employed at Farnborough, where in 1912 the Royal Aircraft Factory was established. As Chief Designer and Chief Test Pilot he was responsible for the BE 2, which was the first British military aircraft to land in France in 1914.

In May 1914 de Havilland went to work for George Holt Thomas, whose Aircraft Manufacturing Company Ltd (Airco) of Hendon was expanding to design and build aircraft of its own design. However, because de Havilland was a member of the Royal Flying Corps Reserve, he had to report for duty when war broke out in August. His value as a designer was recognized and he was transferred back to Airco, where he designed eight aircraft in four years. Of these, the DH 2, DH 4, DH 5, DH 6 and DH 9 were produced in large numbers, and a modified DH 4A operated the first British cross- Channel air service in 1919.

On 25 September 1920 de Havilland founded his own company, the De Havilland Aircraft Company Ltd, at Stag Lane near Edgware, London. During the 1920s and 1930s de Havilland concentrated on civil aircraft and produced the very successful Moth series of small biplanes and monoplanes, as well as the Dragon, Dragon Rapide, Albatross and Flamingo airliners. In 1930 a new site was acquired at Hatfield, Hertfordshire, and by 1934 a modern factory with a large airfield had been established. His Comet racer won the England-Australia air race in 1934 using de Havilland engines. By this time the company had established very successful engine and propeller divisions. The Comet used a wooden stressed-skin construction which de Havilland developed and used for one of the outstanding aircraft of the Second World War: the Mosquito. The de Havilland Engine Company started work on jet engines in 1941 and their Goblin engine powered the Vampire jet fighter first flown by Geoffrey de Havilland Jr in 1943. Unfortunately, Geoffrey Jr and his brother John were both killed in flying accidents. The Comet jet airliner first flew in 1949 and the Trident in 1962, although by 1959 the De Havilland Company had been absorbed into Hawker Siddeley Aviation.

[br]

Principal Honours and Distinctions

Knight Bachelor 1944. Order of Merit 1962. CBE 1934. Air Force Cross 1919. (A full list is contained in R.M.Clarkson's paper (see below)).

Bibliography

1961, Sky Fever, London; repub. 1979, Shrewsbury (autobiography).

Further Reading

R.M.Clarkson, 1967, "Geoffrey de Havilland 1882–1965", Journal of the Royal Aeronautical Society (February) (a concise account of de Havilland, his achievements and honours).

C.M.Sharp, 1960, D.H.—An Outline of de Havilland History, London (mostly a history of the company).

A.J.Jackson, 1962, De Havilland Aircraft since 1915, London.

JDS

Donald, Ian

SUBJECT AREA: Medical technology

[br]

b. 27 December 1910 Paisley, Scotland

d. 19 June 1987 Paglesham, Essex, England

[br]

Scottish obstetrician and gynaecologist, pioneer of the diagnostic use of ultrasound in medicine.

[br]

After he received his initial education in Scotland, Donald's family moved to South Africa, where he obtained a BA degree in Cape Town in 1930. After the death of his parents he returned to England, graduating in medicine in 1937. He served in the RAF from 1942 to 1946 and was awarded the MBE for bravery in rescuing air-crews. In 1954, following a fruitful period as Reader and Lecturer at St Thomas's Hospital and the Hammersmith Hospital, he was appointed Regius Professor of Midwifery in Glasgow. It was while at St Thomas's and Hammersmith that he evolved a demand-response respirator for infants. With the assistance of Tom Brown, an engineer, and the company Kelvin Hughes—which had earlier produced ultrasound equipment for detecting flaws in metal castings—he was able to originate, develop and improve the diagnostic use of ultra-sound in obstetrics and gynaecology. The use of this technique rapidly spread into other disciplines. Donald was fortunate in that the procedure proved to have no untoward influence on pregnancy; at the time, little was known of possible side effects.

He was the proponent of other advances in the speciality, including laparoscopy, breast-feeding and the preservation of the membranes during labour. An ardent anti-abortionist, his authoritarian Scottish approach made Glasgow a world centre, with himself as a renowned and loved teacher. Despite undergoing three major cardiac interventions, his longevity did not surprise those who knew of his immense vitality.

[br]

Principal Honours and Distinctions

CBE 1973. Honorary DSc, London and Glasgow Universities. Royal College of Obstetricians and Gynaecologists Eardley Holland Gold Medal. Royal College of Surgeons Victor Bonney Prize. Royal Society of Medicine Blair Bell Gold Medal.

Bibliography

1958, "Investigation of abdominal masses by pulsed ultrasound", Lancet (with Brown and MacVicar).

Numerous other papers in learned journals.

Further Reading

Obituary, 1987, Lancet (18 July).

MG

Du Cane, Peter

SUBJECT AREA: Ports and shipping

[br]

b. England

d. 31 October 1984

[br]

English engineer, one of the foremost designers of small high-speed ships.

[br]

Peter Du Cane was appointed a midshipman in the Royal Navy in 1913, having commenced as a cadet at the tender age of 13. At the end of the First World War he transferred to the engineering branch and was posted ultimately to the Yangtze River gunboat fleet. In 1928 he resigned, trained as a pilot and then joined the shipbuilders Vosper Ltd of Portsmouth. For thirty-five years he held the posts of Managing Director and Chief Designer, developing the company's expertise in high-speed, small warships, pleasure craft and record breakers. During the Second World War the company designed and built many motor torpedo-boats, air-sea rescue craft and similar ships. Du Cane served for some months in the Navy, but at the request of the Government he returned to his post in the shipyard. The most glamorous products of the yard were the record breakers Bluebird II, with which Malcolm Campbell took the world water speed record in 1939, and the later Crusader, in which John Cobb lost his life. Despite this blow the company went from strength to strength, producing the epic Brave class fast patrol craft for the Royal Navy, which led to export orders. In 1966 the yard merged with John I.Thornycroft Ltd. Commander Du Cane retired seven years later.

[br]

Principal Honours and Distinctions

Commander of the Royal Navy. CBE 1965.

Bibliography

1951, High Speed Small Craft, London: Temple Press.

Further Reading

C.Dawson, 1972, A Quest for Speed at Sea, London: Hutchinson.

FMW

Duddell, William du Bois

SUBJECT AREA: Electricity

[br]

b. 1872 Kensington, London, England

d. 4 November 1917 London, England

[br]

English engineer, inventor of the first practical oscillograph.

[br]

After an education at the College of Stanislas, Cannes, Duddell served an apprenticeship with Davy Paxman of Colchester. Studying under Ayrton and Mather at the Central Technical College in South Kensington, he found the facilities for experimental work of exceptional value to him and remained there for some years. In 1897 Duddell produced a galvanometer which was sufficiently responsive to display an alternating-current wave-form. This instrument, with a coil carrying a mirror in the air gap of a powerful electromagnet, had a small periodic time. An oscillating mirror driven by a synchronous motor spread out the deflection on a time-scale. This development became the first commercial oscillograph and brought Duddell into prominence as a first-rate designer of special instruments. The Duddell oscillograph remained in use until after the Second World War, examples being used for recording short-circuit tests on high-power switchgear and other rapidly varying or transient phenomena. His next important work was to collaborate with Professor Marchant at Liverpool University to investigate the characteristics of the electric arc. This led to the suggestion that, coupled to a resonant circuit, the electric arc could form a generator of high-frequency currents. This arrangement was later developed by Poulson for wireless telegraphy. Duddell spent the last years of his life on government research as a member of the Admiralty Board of Inventions and Research and also of the Inventions Board of the Ministry of Munitions.

[br]

Principal Honours and Distinctions

CBE 1916. FRS 1907. Royal Society Hughes Medal 1912. President, Institution of Electrical Engineers 1912 and 1913.

Bibliography

1897, Electrician, 39:636–8 (describes his oscillograph). 5 March 1898, British patent no. 5,449 (the oscillograph).

1899, with E.W.Marchant, "Experiments on alternate current arcs by aid of oscillograph", Journal of the Institution of Electrical Engineers 28: 1–107.

Further Reading

V.J.Phillips, 1987, Waveforms, Bristol (a comprehensive account).

1945, "50 years of scientific instrument manufacture", Engineering, 159:461.

GW

Fox, Uffa

SUBJECT AREA: Ports and shipping

[br]

b. 15 January 1898 Cowes, Isle of Wight, England

d. 27 October 1972 Isle of Wight (?), England

[br]

English yacht designer.

[br]

Coming from a family that had originated in East Anglia, his first name was that of an early British king and was to typify his unusual and refreshing zest for life. Fox commenced his professional career as an apprentice with the flying boat and high-speed craft builders Messrs S.E.Saunders, and shortly after the outbreak of the First World War he was conscripted into the Royal Naval Air Service. In 1920 he made his first transatlantic crossing under sail, a much greater adventure then than now, and returned to the United Kingdom as deck-hand on a ship bound for Liverpool. He was to make the crossing under sail twice more. Shortly after his marriage in 1925, he purchased the old Floating Bridge at Cowes and converted it to living accommodation, workshops and drawing offices. By the 1930s his life's work was in full swing, with designs coming off his drawing board for some of the most outstanding mass-produced craft ever built, as well as for some remarkable one-off yachts. His experimentation with every kind of sailing craft, and even with the Eskimo kayak, gave him the knowledge and experience that made his name known worldwide. During the Second World War he designed and produced the world's first airborne parachuted lifeboat. Despite what could be described as a robust lifestyle, coupled with interests in music, art and horseriding, Fox continued to produce great designs and in the late 1940s he introduced the Firefly, followed by the beautiful Flying Fifteen class of racing keel boats. One of his most unusual vessels was Britannia, the 24 ft (7.3 m) waterline craft that John Fairfax was to row across the Atlantic. Later came Britannia II, which Fairfax took across the Pacific!

[br]

Principal Honours and Distinctions

CBE 1959. Royal Designer to Industry (RDI).

Bibliography

Fox produced a series of yachting books, most first published in the late 1930s, and some more lighthearted volumes of reminiscences in the 1960s. Some of the best-known titles are: Sail and Power, Racing and Cruising Design, Uffa Fox's Second Book and The Crest of the Wave.

Further Reading

J.Dixon, 1978, Uffa Fox. A Personal Biography, Brighton: Angus \& Robertson.

FMW

Gabor, Dennis (Dénes)

SUBJECT AREA: Photography, film and optics

[br]

b. 5 June 1900 Budapest, Hungary

d. 9 February 1979 London, England

[br]

Hungarian (naturalized British) physicist, inventor of holography.

[br]

Gabor became interested in physics at an early age. Called up for military service in 1918, he was soon released when the First World War came to an end. He then began a mechanical engineering course at the Budapest Technical University, but a further order to register for military service prompted him to flee in 1920 to Germany, where he completed his studies at Berlin Technical University. He was awarded a Diploma in Engineering in 1924 and a Doctorate in Electrical Engineering in 1927. He then went on to work in the physics laboratory of Siemens \& Halske. He returned to Hungary in 1933 and developed a new kind of fluorescent lamp called the plasma lamp. Failing to find a market for this device, Gabor made the decision to abandon his homeland and emigrate to England. There he joined British Thompson-Houston (BTH) in 1934 and married a colleague from the company in 1936. Gabor was also unsuccessful in his attempts to develop the plasma lamp in England, and by 1937 he had begun to work in the field of electron optics. His work was interrupted by the outbreak of war in 1939, although as he was not yet a British subject he was barred from making any significant contribution to the British war effort. It was only when the war was near its end that he was able to return to electron optics and begin the work that led to the invention of holography. The theory was developed during 1947 and 1948; Gabor went on to demonstrate that the theories worked, although it was not until the invention of the laser in 1960 that the full potential of his invention could be appreciated. He coined the term "hologram" from the Greek holos, meaning complete, and gram, meaning written. The three-dimensional images have since found many applications in various fields, including map making, medical imaging, computing, information technology, art and advertising. Gabor left BTH to become an associate professor at the Imperial College of Science and Technology in 1949, a position he held until his retirement in 1967. In 1971 he was awarded the Nobel Prize for Physics for his work on holography.

[br]

Principal Honours and Distinctions

Royal Society Rumford Medal 1968. Franklin Institute Michelson Medal 1968. CBE 1970. Nobel Prize for Physics 1971.

Bibliography

1948. "A new microscopic principle", Nature 161:777 (Gabor's earliest publication on holography).

1949. "Microscopy by reconstructed wavefronts", Proceedings of the Royal Society A197: 454–87.

1951, "Microscopy by reconstructed wavefronts II", Proc. Phys. Soc. B, 64:449–69. 1966, "Holography or the “Whole Picture”", New Scientist 29:74–8 (an interesting account written after laser beams were used to produce optical holograms).

Further Reading

T.E.Allibone, 1980, contribution to Biographical Memoirs of Fellows of the Royal Society 26: 107–47 (a full account of Gabor's life and work).

JW

Handley Page, Sir Frederick

SUBJECT AREA: Aerospace

[br]

b. 15 November 1885 Cheltenham, England

d. 21 April 1962 London, England

[br]

English aviation pioneer, specialist in large aircraft and developer of the slotted wing for safer slow flying.

[br]

Frederick Handley Page trained as an electrical engineer but soon turned his attention to the more exciting world of aeronautics. He started by manufacturing propellers for aeroplanes and airships, and then in 1909 he founded a public company. His first aeroplane, the Bluebird, was not a success, but an improved version flew well. It was known as the "Yellow Peril" because of its yellow doped finish and made a notable flight across London from Barking to Brooklands. In 1910 Handley Page became one of the first college lecturers in aeronautical engineering. During the First World War Handley Page concentrated on the production of large bombers. The 0/100 was a biplane with a wing span of 100 ft (30 m) and powered by two engines: it entered service in 1916. In 1918 an improved version, the 0/400, entered service and a larger four-engined bomber made its first flight. This was the V/1500, which was designed to bomb Berlin, but the war ended before this raid took place. After the war, Handley Page turned his attention to airline operations with the great advantage of having at his disposal large bombers which could be adapted to carry passengers. Handley Page Air Transport Ltd was formed in 1919 and provided services to several European cities. Eventually this company became part of Imperial Airways, but Handley Page continued to supply them with large airliners. Probably the most famous was the majestic HP 42 four-engined biplane, which set very high standards of comfort and safety. Safety was always important to Handley Page and in 1920 he developed a wing with a slot along the leading edge: this made slow flying safer by delaying the stall. Later versions used separate aerofoil-shaped slats on the leading edge that were sometimes fixed, sometimes retractable. The HP 42 was fitted with these slats. From the 1930s Handley Page produced a series of bombers, such as the Heyford, Hampden, Harrow and, most famous of all, the Halifax, which played a major role in the Second World War. Then followed the Victor V-bomber of 1952 with its distinctive "crescent" wing and high tailplane. Sir Frederick's last venture was the Herald short-haul airliner of 1955; designed to replace the ubiquitous Douglas DC-3, it was only a limited success.

[br]

Principal Honours and Distinctions

Knighted 1942. CBE 1918. Lord Lieutenant of the County of Middlesex 1956–60. Honorary Fellow of the Royal Aeronautical Society.

Bibliography

1950, "Towards slower and safer flying, improved take-off and landing and cheaper airports", Journal of the Royal Aeronautical Society.

Further Reading

Two accounts of Handley Page's life and work were published in the Journal of the Royal Aeronautical Society December 1962 and July 1964.

D.C.Clayton, 1970, Handley Page: An Aircraft Album, London (for details of his aircraft).

C.H.Barnes, 1976, Handley Page Aircraft since 1907, London.

JDS

Hounsfield, Sir Godfrey Newbold

SUBJECT AREA: Medical technology

[br]

b. 28 August 1919 Newark, Nottinghamshire, England

[br]

English scientist, inventor and developer of computer-assisted tomography (CAT) scanning technique of radiographic examination.

[br]

After an education in Newark and London in radiocommunications and radar, Hounsfield volunteered and served in the RAF during 1939–45. He was a lecturer at Cranwell Radar School from c.1942 to 1945. From 1947 to 1951 he undertook further study in electrical and mechanical engineering, and in 1951 he joined Electrical and Musical Instruments (EMI) Ltd, where he led the design team for the first British all-transistor computer (EMIDEC, 1959). In 1969–72 he invented and developed the EMI computerized transverse axial tomography scanner system of X-ray examination; this, while applicable to other areas of the body, particularly permitted the elimination of difficulties presented since the earliest days of X-ray examination in the examination of the cranial contents.

[br]

Principal Honours and Distinctions

Knighted 1981. CBE 1976. FRS 1975. Nobel Prize for Medicine or Physiology (jointly with A.M.Cormack) 1979.

Bibliography

1973, "Computerized transverse axial scanning (Tomography)", British Journal of Radiology, American Journal of Roentgenology.

MG

King, James Foster

SUBJECT AREA: Ports and shipping

[br]

b. 9 May 1862 Erskine, Scotland

d. 11 August 1947 Glasgow, Scotland

[br]

Scottish naval architect and classification society manager who made a significant contribution to the safety of shipping.

[br]

King was educated at the High School of Glasgow, and then served an apprenticeship with the Port Glasgow shipyard of Russell \& Co. This was followed by experience in drawing offices in Port Glasgow, Hull and finally in Belfast, where he was responsible for the separate White Star Line drawing office of Harland \& Wolff Ltd, which was then producing the plans for the Atlantic passenger liners Majestic and Teutonic. Following certain unpopular government shipping enactments in 1890, a protest from shipbuilders and shipowners in Ireland, Liverpool and the West of Scotland led to the founding of a new classification society to compete against Lloyd's Register of Shipping. It became known as the British Corporation Register and had headquarters in Glasgow. King was recruited to the staff and by 1903 had become Chief Surveyor, a position he held until his retirement thirty-seven years later. By then the Register was a world leader, with hundreds of thousands of tons of shipping on its books; it acted as consultant to many governments and international agencies. Throughout his working life, King did everything in his power to quantify the risks and problems of ship operation: his contribution to the Load Lines Convention of 1929 was typical, and few major enactments in shipping were designed without his approval. During the inter-war period the performance of the British Corporation outshone that of all rivals, for which King deserved full credit. His especial understanding was for steel structures, and in this respect he ensured that the British Corporation enabled owners to build ships of strengths equal to any others despite using up to 10 per cent less steel within the structure. In 1949 Lloyd's Register of Shipping and the British Corporation merged to form the largest and most influential ship classification society in the world.

[br]

Principal Honours and Distinctions

CBE 1920. Honorary Member, Institution of Engineers and Shipbuilders in Scotland 1941; North East Coast Institution of Engineers and Shipbuilders (Newcastle) 1943; British Corporation 1940. Honorary Vice-President, Institution of Naval Architects.

Further Reading

G.Blake, 1960, Lloyd's Register of Shipping 1760–1960, London: Lloyd's Register. F.M.Walker, 1984, Song of the Clyde. A History of Clyde Shipbuiding, Cambridge: PSL. 1947, The British Corporation Register of Shipping and Aircraft 1890–1947, An

Illustrated Record, 1947, Glasgow.

1946, The British Corporation Register. The War Years in Retrospect, 1956, Glasgow.

FMW

Lovelock, James Ephraim

SUBJECT AREA: Domestic appliances and interiors, Electricity, Electronics and information technology

[br]

b. 26 July 1919 Brixton, London, England

[br]

English biologist and philosopher, inventor of the microwave oven and electron capture detector.

[br]

Lovelock was brought up in Brixton in modest circumstances. At the age of 4 he was given a toy electrical set, which first turned his attention towards the study of science. From the Strand School, Brixton, he went on to the universities of Manchester and London, and after graduating in science, in 1941 he joined the National Institute for Medical Research, Mill Hill, as a staff scientist, remaining there for twenty years. During the early 1950s, he and his colleagues were engaged in research into freezing live animals and bringing them back to life by heating: Lovelock was struck by the intense pain this process caused the animals, and he sought a more humane method. He tried diathermy or internal heating through the effect of a continuous wave magnetron borrowed from the Navy. He found that the animals were brought back to life painlessly, and impressed with his success he tried baking a potato for his lunch in the apparatus and found that it cooked amazingly quickly compared with the one hour normally needed in an ordinary oven. Lovelock had invented the microwave oven, but its commercial possibilities were not at first realized.

In the late 1950s he invented the electron capture detector, which proved to be more sensitive than any other analytical equipment in detecting and measuring toxic substances. The apparatus therefore had obvious uses in testing the quality of the environment and so offered a tremendous boost to the "green" movement. In 1961 he was invited to joint the US National Aeronautics and Space Administration (NASA) to employ the apparatus in an attempt to detect life in space.

In the early 1970s Lovelock relinquished his biological work in order to devote his attention to philosophical matters, specifically to develop his theory of the Universe, now widely celebrated as the "Gaia theory". In this controversial theory, Lovelock regards our planet and all its living beings, including humans, as a single living organism.

[br]

Principal Honours and Distinctions

CBE 1990. FRS 1974. Many academic awards and honorary degrees. Visiting Professor, University of Reading 1967–90.

Bibliography

1979, Gaia.

1983, The Great Extinction.

1988, The Ages of Gaia.

1991, Gaia: The Practical Science of Planetary Medicine.

LRD

McKay, Hugh Victor

SUBJECT AREA: Agricultural and food technology

[br]

b. c. 1866 Drummartin, Victoria, Australia

d. 21 May 1926 Australia

[br]

Australian inventor and manufacturer of harvesting and other agricultural equipment.

[br]

A farmer's son, at the age of 17 McKay developed modifications to the existing stripper harvester and created a machine that would not only strip the seed from standing corn, but was able to produce a threshed, winnowed and clean sample in one operation. The prototype was produced in 1884 and worked well on the two acres of wheat that had been set aside on the family farm. By arrangement with a Melbourne plough maker, five machines were made and sold for the 1885 season. In 1886 the McKay Harvester Company was formed, with offices at Ballarat, from which the machines, built by various companies, were sold. The business expanded quickly, selling sixty machines in 1888, and eventually rising to the production of nearly 2,000 harvesters in 1905. The name "Sunshine" was given to the harvester, and the "Sun" prefix was to appear on all other implements produced by the company as it diversified its production interests. In 1902 severe drought reduced machinery sales and left 2,000 harvesters unsold. McKay was forced to look to export markets to dispose of his surplus machines. By 1914 a total of 10,000 machines were being exported annually. During the First World War McKay was appointed to the Business Board of the Defence Department. Increases in the scale of production resulted in the company moving to Melbourne, where it was close to the port of entry of raw materials and was able to export the finished article more readily. In 1909 McKay produced one of the first gas-engined harvesters, but its cost prevented it from being more than an experimental prototype. By this time McKay was the largest agricultural machinery manufacturer in the Southern hemisphere, producing a wide range of implements, including binders. In 1916 McKay hired Headlie Taylor, who had developed a machine capable of harvesting fallen crops. The jointly developed machine was a major success, coming as it did in what would otherwise have been a disastrous Australian harvest. Further developments included the "Sun Auto-header" in 1923, the first of the harvesting machines to adopt the "T" configuration to be seen on modern harvesters. The Australian market was expanding fast and a keen rivalry developed between McKay and Massey Harris. Confronted by the tariff regulations with which the Australian Government had protected its indigenous machinery industry since 1906, Massey Harris sold all its Australian assets to the H.V. McKay company in 1930. Twenty-three years later Massey Ferguson acquired the old Sunshine works and was still operating from there in the 1990s.

Despite a long-running history of wage disputes with his workforce, McKay established a retiring fund as well as a self-help fund for distressed cases. Before his death he created a charitable trust and requested that some funds should be made available for the "aerial experiments" which were to lead to the establishment of the Flying Doctor Service.

[br]

Principal Honours and Distinctions

CBE.

Further Reading

Graeme Quick and Wesley Buchele, 1978, The Grain Harvesters, American Society of Agricultural Engineers (devotes a chapter to the unique development of harvesting machinery which took place in Australia).

AP

McNeill, Sir James McFadyen

SUBJECT AREA: Ports and shipping

[br]

b. 19 August 1892 Clydebank, Scotland

d. 24 July 1964 near Glasgow, Scotland

[br]

Scottish naval architect, designer of the Cunard North Atlantic Liners Queen Mary and Queen Elizabeth.

[br]

McNeill was born in Clydebank just outside Glasgow, and was to serve that town for most of his life. After education at Clydebank High School and then at Allan Glen's in Glasgow, in 1908 he entered the shipyard of John Brown \& Co. Ltd as an apprentice. He was encouraged to matriculate at the University of Glasgow, where he studied naval architecture under the (then) unique Glasgow system of "sandwich" training, alternately spending six months in the shipyard, followed by winter at the Faculty of Engineering. On graduating in 1915, he joined the Army and by 1918 had risen to the rank of Major in the Royal Field Artillery.

After the First World War, McNeill returned to the shipyard and in 1928 was appointed Chief Naval Architect. In 1934 he was made a local director of the company. During the difficult period of the 1930s he was in charge of the technical work which led to the design, launching and successful completion of the great liners Queen Mary and Queen Elizabeth. Some of the most remarkable ships of the mid-twentieth century were to come from this shipyard, including the last British battleship, HMS Vanguard, and the Royal Yacht Britannia, completed in 1954. From 1948 until 1959, Sir James was Managing Director of the Clydebank part of the company and was Deputy Chairman by the time he retired in 1962. His public service was remarkable and included chairmanship of the Shipbuilding Conference and of the British Ship Research Association, and membership of the Committee of Lloyd's Register of Shipping.

[br]

Principal Honours and Distinctions

Knight Commander of the Royal Victorian Order 1954. CBE 1950. FRS 1948. President, Institution of Engineers and Shipbuilders in Scotland 1947–9. Honorary Vice-President, Royal Institution of Naval Architects. Military Cross (First World War).

Bibliography

1935, "Launch of the quadruple-screw turbine steamer Queen Mary", Transactions of the Institution of Naval Architects 77:1–27 (in this classic paper McNeill displays complete mastery of a difficult subject; it is recorded that prior to launch the estimate for travel of the ship in the River Clyde was 1,194 ft (363.9 m), and the actual amount recorded was 1,196 ft (364.5m)!).

FMW

Meek, Marshall

SUBJECT AREA: Ports and shipping

[br]

b. 22 April 1925 Auchtermuchty, Fife, Scotland

[br]

Scottish naval architect and leading twentieth-century exponent of advanced maritime technology.

[br]

After early education at Cupar in Fife, Meek commenced training as a naval architect, taking the then popular sandwich apprenticeship of alternate half years at the University of Glasgow (with a Caird Scholarship) and at a shipyard, in his case the Caledon of Dundee. On leaving Dundee he worked for five years with the British Ship Research Association before joining Alfred Holt \& Co., owners of the Blue Funnel Line. During his twenty-five years at Liverpool, he rose to Chief Naval Architect and Director and was responsible for bringing the cargo-liner concept to its ultimate in design. When the company had become Ocean Fleets, it joined with other British shipowners and looked to Meek for the first purpose-built containership fleet in the world. This required new ship designs, massive worldwide investment in port facilities and marketing to win public acceptance of freight containers, thereby revolutionizing dry-cargo shipping. Under the houseflag of OCL (now POCL), this pioneer service set the highest standards of service and safety and continues to operate on almost every ocean.

In 1979 Meek returned to the shipbuilding industry when he became Head of Technology at British Shipbuilders. Closely involved in contemporary problems of fuel economy and reduced staffing, he held the post for five years before his appointment as Managing Director of the National Maritime Institute. He was deeply involved in the merger with the British Ship Research Association to form British Maritime Technology (BMT), an organization of which he became Deputy Chairman.

Marshall Meek has held many public offices, and is one of the few to have been President of two of the United Kingdom's maritime institutions. He has contributed over forty papers to learned societies, has acted as Visiting Professor to Strathclyde University and University College London, and serves on advisory committees to the Ministry of Defence, the Department of Transport and Lloyd's Register of Shipping. While in Liverpool he served as a Justice of the Peace.

[br]

Principal Honours and Distinctions

CBE 1989. Fellow of the Royal Academy of Engineering 1990. President, Royal Institution of Naval Architects 1990–3; North East Coast Institution of Engineers and Shipbuilders 1984–6. Royal Designer for Industry (RDI) 1986. Royal Institution of Naval Architects Silver Medal (on two occasions).

Bibliography

1970, "The first OCL containerships", Transactions of the Royal Institution of Naval Architects.

FMW

Mitchell, Reginald Joseph

SUBJECT AREA: Aerospace

[br]

b. 20 May 1895 Talke, near Stoke-on-Trent, Staffordshire, England

d. 11 June 1937 Southampton, England

[br]

English aircraft designer.

[br]

He was the son of a headmaster who, when Mitchell was aged 6 years, set up his own printing business. Mitchell was apprenticed at the age of 16 to a locomotive builder in Stoke and also studied engineering, mechanics, mathematics and drawing at night-school. With the outbreak of war in 1914 he became increasingly interested in aircraft and in 1916 joined the Supermarine Aviation Works at Southampton. Such was his talent for aviation design that within three years he had risen to be Chief Engineer Designer. Initially Mitchell's work was concentrated on flying boats, but with the resurrection after the First World War of the biennial Schneider Trophy races for seaplanes he turned his attention increasingly to high-speed floatplanes. He first achieved success with his S-5 in the 1927 race at Venice and followed it up with further victories in 1929 and 1931 with the S-6 and S-6B, enabling Britain to win the trophy outright (See also Royce, Sir Frederick Henry). Using the experience gained from the Schneider Trophy races, Mitchell now began to design fighter aircraft. He was dissatisfied with his first attempt, which was to produce a fighter to an Air Ministry specification, and started afresh on his own. The result was the Supermarine Spitfire, which was to become one of the outstanding aircraft of the Second World War. Sadly, he died of cancer before his project came to full fruition, with the Spitfire not entering Royal Air Force service until June 1938. The success of Mitchell's designs was due to his ability to combine good engineering with aerodynamic grace.

[br]

Principal Honours and Distinctions

Royal Aeronautical Society Silver Medal 1927. CBE 1931.

Further Reading

Ralph Barker, 1971, The Schneider Trophy Races, London: Chatto \& Windus.

CM

Mole, Lancelot de

SUBJECT AREA: Weapons and armour

[br]

b. 13 March 1880 Adelaide, Australia

d. 6 May 1950 Sydney, Australia

[br]

Australian engineer and early tank designer.

[br]

De Mole's father was an architect and surveyor and he himself followed a similar avenue as a draughtsman working on mining, surveying and engineering projects in Australia. It was in 1911, while surveying in particularly rough terrain in Western Australia, that he first conceived the idea of the tank as a tracked, armoured vehicle capable of traversing the most difficult ground. He drew up detailed plans and submitted them to the War Office in London the following year, but although they were rejected, not all the plans were returned to him. When war broke out in 1914 he tried without success to interest the Australian authorities, even after he had constructed a model at their request. A further blow came in 1916, when the first tanks, built by the British, appeared on the battlefields of France and looked remarkably similar in design to his own. Believing that he could play a significant role in further tank development, but lacking the funds to travel to Britain, de Mole eventually succeeded, after an initial rejection by a medical board, in enlisting in the Australian Army, which got him to England at the beginning of 1918. He immediately took his model to the British Inventions Committee, who were sufficiently impressed to pass it to the Tank Board, who promptly mislaid it for six weeks. Meanwhile, in March 1918, Private de Mole was ordered to France and was unable to take matters further. On his return to England in early 1919 he made a formal claim for a reward for his invention, but this was turned down on the grounds that no direct link could be established between his design and the first tanks that were built. Even so, the Inventions Committee did authorize a sum of money to cover his expenses, and in 1920 de Mole was a made a Commander of the Order of the British Empire.

Returning to Australia, de Mole worked as an engineer in the design branch of the Sydney Water Board. He continued to invent, but none of his designs, which covered a wide range of items, were ever taken up.

[br]

Principal Honours and Distinctions

CBE 1920.

Further Reading

Australian Dictionary of Biography, 1918, Vol. 8.

A.J.Smithers, 1986, A New Excalibur: The Development of the Tank 1909–1939, London: Leo Cooper (for illustrations of the model of his tank).

Mention of his invention is made in a number of books on the history of the tank.

CM

Moulton, Alexander

SUBJECT AREA: Automotive engineering, Land transport

[br]

b. 9 April 1920 Stratford-on-Avon

[br]

English inventor of vehicle suspension systems and the Moulton bicycle.

[br]

He spent his childhood at The Hall in Bradfordon-Avon. He was educated at Marlborough College, and in 1937 was apprenticed to the Sentinel Steam Wagon Company of Shrewsbury. About that same time he went to King's College, Cambridge, where he took the Mechanical Sciences Tripos. It was then wartime, and he did research on aero-engines at the Bristol Aeroplane Company, where he became Personal Assistant to Sir Roy Fedden. He left Bristol's in 1945 to join his family firm, Spencer \& Moulton, of which he eventually became Technical Director and built up the Research Department. In 1948 he invented his first suspension unit, the "Flexitor", in which an inner shaft and an outer shell were separated by an annular rubber body which was bonded to both.

In 1848 his great-grandfather had founded the family firm in an old woollen mill, to manufacture vulcanized rubber products under Charles Goodyear's patent. The firm remained a family business with Spencer's, consultants in railway engineering, until 1956 when it was sold to the Avon Rubber Company. He then formed Moulton Developments to continue his work on vehicle suspensions in the stables attached to The Hall. Sponsored by the British Motor Corporation (BMC) and the Dunlop Rubber Company, he invented a rubber cone spring in 1951 which was later used in the BMC Mini (see Issigonis, Sir Alexander Arnold Constantine): by 1994 over 4 million Minis had been fitted with these springs, made by Dunlop. In 1954 he patented the Hydrolastic suspension system, in which all four wheels were independently sprung with combined rubber springs and damper assembly, the weight being supported by fluid under pressure, and the wheels on each side being interconnected, front to rear. In 1962 he formed Moulton Bicycles Ltd, having designed an improved bicycle system for adult use. The conventional bicycle frame was replaced by a flat-sided oval steel tube F-frame on a novel rubber front and rear suspension, with the wheel size reduced to 41 cm (16 in.) with high-pressure tyres. Raleigh Industries Ltd having refused his offer to produce the Moulton Bicycle under licence, he set up his own factory on his estate, producing 25,000 bicycles between 1963 and 1966. In 1967 he sold out to Raleigh and set up as Bicycle Consultants Ltd while continuing the suspension development of Moulton Developments Ltd. In the 1970s the combined firms employed some forty staff, nearly 50 per cent of whom were graduates.

He won the Queen's Award for Industry in 1967 for technical innovation in Hydrolastic car suspension and the Moulton Bicycle. Since that time he has continued his innovative work on suspensions and the bicycle. In 1983 he introduced the AM bicycle series of very sophisticated space-frame design with suspension and 43 cm (17 in.) wheels; this machine holds the world speed record fully formed at 82 km/h (51 mph). The current Rover 100 and MGF use his Hydragas interconnected suspension. By 1994 over 7 million cars had been fitted with Moulton suspensions. He has won many design awards and prizes, and has been awarded three honorary doctorates of engineering. He is active in engineering and design education.

[br]

Principal Honours and Distinctions

Queen's Award for Industry 1967; CBE; RDI. Fellow of the Royal Academy of Engineering.

Further Reading

P.R.Whitfield, 1975, Creativity in Industry, London: Penguin Books.

IMcN

Rickover, Admiral Hyman George

SUBJECT AREA: Ports and shipping, Weapons and armour

[br]

b. 27 January 1900 Russian Poland

d. 8 July 1986 Arlington, Virginia, USA

[br]

Polish/American naval officer, one of the principal architects of the United States nuclear submarine programme.

[br]

Born in Poland, Rickover was brought to the United States early in his life by his father, who settled in Chicago as a tailor. Commissioned into the US Navy in 1922, he specialized in electrical engineering (graduating from the US Naval Postgraduate School, Columbia, in 1929), quali-fied as a Submariner in 1931 and then held various posts until appointed Head of the Electrical Section of the Bureau of Ships in 1939. He held this post until the end of the Second World War.

Rickover was involved briefly in the "Manhattan" atomic bomb project before being assigned to an atomic energy submarine project in 1946. Ultimately he was made responsible for the development and building of the world's first nuclear submarine, the USS Nautilus. He was convinced of the need to make the nuclear submarine an instrument of strategic importance, and this led to the development of the ballistic missile submarine and the Polaris programme.

Throughout his career he was no stranger to controversy; indeed, his remaining on the active service list as a full admiral until the age of 82 (when forced to retire on the direct intervention of the Navy Secretary) indicates a man beyond the ordinary. He imposed his will on all around him and backed it with a brilliant and clear-thinking brain; his influence was even felt by the Royal Navy during the building of the first British nuclear submarine, HMS Dreadnought. He made many friends, but he also had many detractors.

[br]

Principal Honours and Distinctions

US Distinguished Service Medal with Gold Star. Honorary CBE. US Congress Special Gold Medal 1959. Numerous awards and honorary degrees.

Bibliography

Rickover wrote several treatises on education and on the education of engineers. He also wrote on several aspects of the technical history of the US Navy.

Further Reading

W.R.Anderson and C.Blair, 1959, Nautilus 90 North, London: Hodder \& Stoughton. E.L.Beach, 1986, The United States Navy, New York: Henry Holt.

FMW

Sopwith, Sir Thomas (Tommy) Octave Murdoch

SUBJECT AREA: Aerospace

[br]

b. 18 January 1888 London, England

d. 27 January 1989 Stockbridge, Hampshire, England

[br]

English aeronautical engineer and industrialist.

[br]

Son of a successful mining engineer, Sopwith did not shine at school and, having been turned down by the Royal Navy as a result, attended an engineering college. His first interest was motor cars and, while still in his teens, he set up a business in London with a friend in order to sell them; he also took part in races and rallies.

Sopwith's interest in aviation came initially through ballooning, and in 1906 he purchased his own balloon. Four years later, inspired by the recent flights across the Channel to France and after a joy-ride at Brooklands, he bought an Avis monoplane, followed by a larger biplane, and taught himself to fly. He was awarded the Royal Aero Society's Aviator Certificate No. 31 on 21 November 1910, and he quickly distinguished himself in flying competitions on both sides of the Atlantic and started his own flying school. In his races he was ably supported by his friend Fred Sigrist, a former motor engineer. Among the people Sopwith taught to fly were an Australian, Harry Hawker, and Major Hugh Trenchard, who later became the "father" of the RAF.

In 1912, depressed by the poor quality of the aircraft on trial for the British Army, Sopwith, in conjunction with Hawker and Sigrist, bought a skating rink in Kingston-upon-Thames and, assisted by Fred Sigrist, started to design and build his first aircraft, the Sopwith Hybrid. He sold this to the Royal Navy in 1913, and the following year his aviation manufacturing company became the Sopwith Aviation Company Ltd. That year a seaplane version of his Sopwith Tabloid won the Schneider Trophy in the second running of this speed competition. During 1914–18, Sopwith concentrated on producing fighters (or "scouts" as they were then called), with the Pup, the Camel, the 1½ Strutter, the Snipe and the Sopwith Triplane proving among the best in the war. He also pioneered several ideas to make flying easier for the pilot, and in 1915 he patented his adjustable tailplane and his 1 ½ Strutter was the first aircraft to be fitted with air brakes. During the four years of the First World War, Sopwith Aviation designed thirty-two different aircraft types and produced over 16,000 aircraft.

The end of the First World War brought recession to the aircraft industry and in 1920 Sopwith, like many others, put his company into receivership; none the less, he immediately launched a new, smaller company with Hawker, Sigrist and V.W.Eyre, which they called the H.G. Hawker Engineering Company Ltd to avoid any confusion with the former company. He began by producing cars and motor cycles under licence, but was determined to resume aircraft production. He suffered an early blow with the death of Hawker in an air crash in 1921, but soon began supplying aircraft to the Royal Air Force again. In this he was much helped by taking on a new designer, Sydney Camm, in 1923, and during the next decade they produced a number of military aircraft types, of which the Hart light bomber and the Fury fighter, the first to exceed 200 mph (322 km/h), were the best known. In the mid-1930s Sopwith began to build a large aviation empire, acquiring first the Gloster Aircraft Company and then, in quick succession, Armstrong-Whitworth, Armstrong-Siddeley Motors Ltd and its aero-engine counterpart, and A.V.Roe, which produced Avro aircraft. Under the umbrella of the Hawker Siddeley Aircraft Company (set up in 1935) these companies produced a series of outstanding aircraft, ranging from the Hawker Hurricane, through the Avro Lancaster to the Gloster Meteor, Britain's first in-service jet aircraft, and the Hawker Typhoon, Tempest and Hunter. When Sopwith retired as Chairman of the Hawker Siddeley Group in 1963 at the age of 75, a prototype jump-jet (the P-1127) was being tested, later to become the Harrier, a for cry from the fragile biplanes of 1910.

Sopwith also had a passion for yachting and came close to wresting the America's Cup from the USA in 1934 when sailing his yacht Endeavour, which incorporated a number of features years ahead of their time; his greatest regret was that he failed in his attempts to win this famous yachting trophy for Britain. After his retirement as Chairman of the Hawker Siddeley Group, he remained on the Board until 1978. The British aviation industry had been nationalized in April 1977, and Hawker Siddeley's aircraft interests merged with the British Aircraft Corporation to become British Aerospace (BAe). Nevertheless, by then the Group had built up a wide range of companies in the field of mechanical and electrical engineering, and its board conferred on Sopwith the title Founder and Life President.

[br]

Principal Honours and Distinctions

Knighted 1953. CBE 1918.

Bibliography

1961, "My first ten years in aviation", Journal of the Royal Aeronautical Society (April) (a very informative and amusing paper).

Further Reading

A.Bramson, 1990, Pure Luck: The Authorized Biography of Sir Thomas Sopwith, 1888– 1989, Wellingborough: Patrick Stephens.

B.Robertson, 1970, Sopwith. The Man and His Aircraft, London (a detailed publication giving plans of all the Sopwith aircraft).

CM / JDS

Wallace, Sir William

SUBJECT AREA: Ports and shipping

[br]

b. 25 August 1881 Leicester, England

d. 27 May 1963 Edinburgh, Scotland

[br]

English engineer; developer of the Denny-Brown fin stabilizer for ships.

[br]

Wallace was brought up just outside Glasgow, and educated at Paisley Grammar School and later at the Anderson College in Glasgow. The next few years were typical of the early years in the life of many young engineers: he served an apprenticeship at the Paisley shipyard of Bow, MacLachlan, before joining the British and Burmese Steam Navigation Company (Paddy Henderson's Line) as a junior engineer. After some years on the Glasgow to Rangoon service, he rose to the rank of Chief Engineer early in life and then came ashore in 1911.

He joined the old established Edinburgh engineering company of Brown Brothers as a draughtsman, but by 1917 had been promoted Managing Director. He was appointed Chairman in 1946. During his near thirty years at the helm, he experimented widely and was the engineering force behind the development of the Denny-Brown ship stabilizer which was jointly pursued by Brown Brothers and the Dumbarton shipyard of William Denny \& Brothers. The first important installation was on the cross-channel steamer Isle of Sark, built at Dumbarton for the Southern Railway in 1932. Over the years countless thousands of these installations have been fitted on liners, warships and luxury yachts. Brown Brothers produced many other important engineering innovations at this time, including the steam catapult for aircraft carriers.

In later years Sir William (now knighted) took an active part in the cultural life of Edinburgh and of Scotland. From 1952 to 1954 he served as President of the Institution of Engineers and Shipbuilders in Scotland.

[br]

Principal Honours and Distinctions

Knighted 1951. CBE 1944. Fellow of the Royal Society of Edinburgh. President, Institution of Engineers and Shipbuilders in Scotland 1952–4; Gold Medal.

Bibliography

1954–5 "Experiences in the stabilization of ships", Transactions of the Institution of Engineers and Shipbuilders in Scotland 98:197–266.

FMW