Zeppelins

zeppelins

n

ცეპელინები

zeppelins in a fog

Национальное блюдо в США

"цеппелины в тумане"

на жаргоне дайнеров - сосиски с картофельным пюре

Zeppelin, Count Ferdinand von

SUBJECT AREA: Aerospace

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b. 8 July 1838 Konstanz, Germany

d. 8 March 1917 Berlin, Germany

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German designer of rigid airships, which became known as Zeppelins.

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Zeppelin served in the German Army and retired with the rank of General in 1890. While in the army, he was impressed by the use of balloons in the American Civil War and during the Siege of Paris. By the time he retired, non-rigid airships were just beginning to make their mark. Zeppelin decided to build an airship with a rigid framework to support the gas bags. Plans were drawn up in 1893 with the assistance of Theodore Kober, an engineer, but the idea was rejected by the authorities. A company was founded in 1898 and construction began. The Luftschiff Zeppelin No. 1 (LZ1) made its first flight on 2 July 1900. Modifications were needed and the second flight took place in October. A reporter called Hugo Eckener covered this and later flights: his comments and suggestions so impressed Zeppelin that Eckener eventually became his partner, publicist, fund-raiser and pilot.

The performance of the subsequent Zeppelins gradually improved, but there was limited military interest. In November 1909 a company with the abbreviated name DELAG was founded to operate passenger-carrying Zeppelins. The service was opened by LZ 7 Deutschland in mid-June 1910, and the initial network of Frankfurt, Baden- Baden and Düsseldorf was expanded. Eckener became a very efficient Director of Flight Operations, and by the outbreak of war in 1914 some 35,000 passengers had been carried without any fatalities. During the First World War many Zeppelins were built and they carried out air-raids on Britain. Despite their menacing reputation, they were very vulnerable to attack by fighters. Zeppelin, now in his seventies, turned his attention to large bombers, following the success of Sikorsky's Grand, but he died in 1917. Eckener continued to instruct crews and improve the Zeppelin designs. When the war ended Eckener arranged to supply the Americans with an airship as part of German reparations: this became the Los Angeles. In 1928 a huge new airship, the Graf Zeppelin, was completed and Eckener took command. He took the Graf Zeppelin on many successful flights, including a voyage around the world in 1929.

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Bibliography

1908, Erfahrungen beim Bau von Luftschiffen, Berlin. 1908, Die Eroberung der Luft, Stuttgart.

Further Reading

There are many books on the history of airships, and on Graf von Zeppelin in particular. Of note are: H.Eckener, 1938, Count Zeppelin: The Man and His Work, London.

——1958, My Zeppelins, London.

P.W.Brooks, 1992, Zeppelin: Rigid Airships 1893–1940, London.

T.Nielson, 1955, The Zeppelin Story: The Life of Hugo Eckener, English edn, London (written as a novel in direct speech).

M.Goldsmith, 1931, Zeppelin: A Biography, New York.

W.R.Nitshe, 1977, The Zeppelin Story, New York.

F.Gütschow, 1985, Das Luftschiff, Stuttgart (a record of all the airships).

JDS

Zeppelin

N

1. बड़ा वायुयान\{जर्मनी में बना\}

Zeppelins have never been used by the Indian Air Force.

Flügge-Lotz, Irmgard

SUBJECT AREA: Aerospace

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b. 1903 Germany

d. 1974 USA

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German/American aeronautical engineer, specializing inflight control.

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Both her father, a mathematician, and her mother encouraged Flügge-Lotz in her desire, unusual for a woman at that time, for a technical education. Her interest in aeronautics was awakened when she was a child, by seeing zeppelins (see Zeppelin, Ferdinand, Count von) being tested. In 1923 she entered the Technische Hochschule in Hannover to study engineering, specializing in aeronautics; she was often the only woman in the class. She obtained her doctorate in 1929 and began working in aeronautics. Two years later she derived the Lotz Method for calculating the distribution in aircraft wings of different shapes, which became widely used. Later, Flügge-Lotz took up an interest in automatic flight control of aircraft, notably of the discontinuous or "on-off" type. These were simple in design, inexpensive to manufacture and reliable in operation. By 1928 she had risen to the position of head of the Department of Theoretical Aerodynamics at Göttingen University, but she and her husband, Wilhelm Flügge, an engineering academic known for his anti-Nazi views, felt themselves increasingly discriminated against by the Hitler regime. In 1948 they emigrated to the USA, where Flügge was soon offered a professorship in engineering, while his wife had at first to make do with a lectureship. But her distinguished work eventually earned her appointment as the first woman full professor in the Engineering Department at Stanford University.

She later extended her work on automatic flight control to the guidance of rockets and missiles, earning herself the description "a female Werner von Braun ".

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Principal Honours and Distinctions

Society of Women Engineers Achievement Award 1970. Fellow, Institution of Aeronautics and Astronautics.

Bibliography

Flügge-Lotz was the author of two books on automatic control and over fifty scientific papers.

Further Reading

A.Stanley, 1993, Mothers and Daughters of Invention, Meruchen, NJ: Scarecrow Press, pp. 899–901.

LRD

Merica, Paul Dyer

SUBJECT AREA: Metallurgy

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b. 17 March 1889 Warsaw, Indiana, USA

d. 20 October 1957 Tarrytown, New York, USA

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American physical metallurgist who elucidated the mechanism of the age-hardening of alloys.

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Merica graduated from the University of Wisconsin in 1908. Before proceeding to the University of Berlin, he spent some time teaching in Wisconsin and in China. He obtained his doctorate in Berlin in 1914, and in that year he joined the US National Bureau of Standards (NBS) in Washington. During his five years there, he investigated the causes of the phenomenon of age-hardening of the important new alloy of aluminium, Duralumin.

This phenomenon had been discovered not long before by Dr Alfred Wilm, a German research metallurgist. During the early years of the twentieth century, Wilm had been seeking a suitable light alloy for making cartridge cases for the Prussian government. In the autumn of 1909 he heated and quenched an aluminium alloy containing 3.5 per cent copper and 0.5 per cent magnesium and found its properties unremarkable. He happened to test it again some days later and was impressed to find its hardness and strength were much improved: Wilm had accidentally discovered age-hardening. He patented the alloy, but he made his rights over to Durener Metallwerke, who marketed it as Duralumin. This light and strong alloy was taken up by aircraft makers during the First World War, first for Zeppelins and then for other aircraft.

Although age-hardened alloys found important uses, the explanation of the phenomenon eluded metallurgists until in 1919 Merica and his colleagues at the NBS gave the first rational explanation of age-hardening in light alloys. When these alloys were heated to temperatures near their melting points, the alloying constituents were taken into solution by the matrix. Quenching retained the alloying metals in supersaturated solid solution. At room temperature very small crystals of various intermetallic compounds were precipitated and, by inserting themselves in the aluminium lattice, had the effect of increasing the hardness and strength of the alloy. Merica's theory stimulated an intensive study of hardening and the mechanism that brought it about, with important consequences for the development of new alloys with special properties.

In 1919 Merica joined the International Nickel Company as Director of Research, a post he held for thirty years and followed by a three-year period as President. He remained in association with the company until his death.

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Bibliography

1919, "Heat treatment and constitution of Duralumin", Sci. Papers, US Bureau of Standards, no. 37; 1932, "The age-hardening of metals", Transactions of the American Institution of Min. Metal 99:13–54 (his two most important papers).

Further Reading

Z.Jeffries, 1959, "Paul Dyer Merica", Biographical Memoirs of the National Academy of Science 33:226–39 (contains a list of Merica's publications and biographical details).

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Wallis, Sir Barnes Neville

SUBJECT AREA: Aerospace, Weapons and armour

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b. 26 September 1887 Ripley, Derbyshire, England

d. 30 October 1979 Leatherhead, Surrey, England

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English aeronautical designer and inventor.

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Wallis was apprenticed first at Thames Engineering Works, and then, in 1908, at John Samuel White's shipyard at Cowes. In 1913, the Government, spurred on by the accelerating development of the German Zeppelins (see Zeppelin, Ferdinand von), ordered an airship from Vickers; Wallis was invited to join the design team. Thus began his long association with aeronautical design and with Vickers. This airship, and the R80 that followed it, were successfully completed, but the military lost interest in them.

In 1924 the Government initiated a programme for the construction of two airships to settle once and for all their viability for long-dis-tance air travel. The R101 was designed by a Government-sponsored team, but the R100 was designed by Wallis working for a subsidiary of Vickers. The R100 took off on 29 July 1930 for a successful round trip to Canada, but the R101 crashed on its first flight on 4 October, killing many of its distinguished passengers. The shock of this disaster brought airship development in Britain to an abrupt end and forced Wallis to direct his attention to aircraft.

In aircraft design, Wallis is known for his use of geodesic construction, which combined lightness with strength. It was applied first to the single-engined "Wellesley" and then the twin-en-gined "Wellington" bomber, which first flew in 1936. With successive modifications, it became the workhorse of RAF Bomber Command during the Second World War until the autumn of 1943, when it was replaced by four-engined machines. In other areas, it remained in service until the end of the war and, in all, no fewer than 11,461 were built.

Wallis is best known for his work on bomb design, first the bouncing bomb that was used to breach the Möhne and Eder dams in the Ruhr district of Germany in 1943, an exploit immortalized in the film Dambusters. Encouraged by this success, the authorities then allowed Wallis to realize an idea he had long urged, that of heavy, penetration bombs. In the closing stages of the war, Tallboy, of 12,000 lb (5,400 kg), and the 10-ton Grand Slam were used to devastating effect.

After the Second World War, Wallis returned to aeronautical design and was given his own department at Vickers to promote his ideas, principally on variable-geometry or swing-wing aircraft. Over the next thirteen years he battled towards the prototype stage of this revolutionary concept. That never came, however; changing conditions and requirements and increasing costs led to the abandonment of the project. Bit-terly disappointed, Wallis continued his researches into high-speed aircraft until his retirement from Vickers (by then the British Aircraft Corporation), in 1971.

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Principal Honours and Distinctions

Knighted 1968. FRS 1945.

Further Reading

J.Morpurgo, 1972, Barnes Wallis: A Biography, London: Longman (a readable account, rather biased in Wallis's favour).

C.J.Heap, 1987, The Papers of Sir Barnes Wallis (1887–1979) in the Science Museum Library, London: Science Museum; with a biographical introd. by L.R.Day.

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