longitude expansion

longitude expansion

пол. экспансия по долготе

Syn:

meridian expansion

meridian expansion

пол. меридианная экспансия (в терминах геополитики: экспансия по оси Север-Юг; расширение сферы военного, стратегического, культурного или экономического влияния вдоль меридиана; основное условие территориальной и стратегической стабильности государства)

Syn:

longitude expansion

See:

meridian integration, geopolitics

Harrison, John

SUBJECT AREA: Horology, Ports and shipping

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b. 24 March 1693 Foulby, Yorkshire, England

d. 24 March 1776 London, England

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English horologist who constructed the first timekeeper of sufficient accuracy to determine longitude at sea and invented the gridiron pendulum for temperature compensation.

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John Harrison was the son of a carpenter and was brought up to that trade. He was largely self-taught and learned mechanics from a copy of Nicholas Saunderson's lectures that had been lent to him. With the assistance of his younger brother, James, he built a series of unconventional clocks, mainly of wood. He was always concerned to reduce friction, without using oil, and this influenced the design of his "grasshopper" escapement. He also invented the "gridiron" compensation pendulum, which depended on the differential expansion of brass and steel. The excellent performance of his regulator clocks, which incorporated these devices, convinced him that they could also be used in a sea dock to compete for the longitude prize. In 1714 the Government had offered a prize of £20,000 for a method of determining longitude at sea to within half a degree after a voyage to the West Indies. In theory the longitude could be found by carrying an accurate timepiece that would indicate the time at a known longitude, but the requirements of the Act were very exacting. The timepiece would have to have a cumulative error of no more than two minutes after a voyage lasting six weeks.

In 1730 Harrison went to London with his proposal for a sea clock, supported by examples of his grasshopper escapement and his gridiron pendulum. His proposal received sufficient encouragement and financial support, from George Graham and others, to enable him to return to Barrow and construct his first sea clock, which he completed five years later. This was a large and complicated machine that was made out of brass but retained the wooden wheelwork and the grasshopper escapement of the regulator clocks. The two balances were interlinked to counteract the rolling of the vessel and were controlled by helical springs operating in tension. It was the first timepiece with a balance to have temperature compensation. The effect of temperature change on the timekeeping of a balance is more pronounced than it is for a pendulum, as two effects are involved: the change in the size of the balance; and the change in the elasticity of the balance spring. Harrison compensated for both effects by using a gridiron arrangement to alter the tension in the springs. This timekeeper performed creditably when it was tested on a voyage to Lisbon, and the Board of Longitude agreed to finance improved models. Harrison's second timekeeper dispensed with the use of wood and had the added refinement of a remontoire, but even before it was tested he had embarked on a third machine. The balance of this machine was controlled by a spiral spring whose effective length was altered by a bimetallic strip to compensate for changes in temperature. In 1753 Harrison commissioned a London watchmaker, John Jefferys, to make a watch for his own personal use, with a similar form of temperature compensation and a modified verge escapement that was intended to compensate for the lack of isochronism of the balance spring. The time-keeping of this watch was surprisingly good and Harrison proceeded to build a larger and more sophisticated version, with a remontoire. This timekeeper was completed in 1759 and its performance was so remarkable that Harrison decided to enter it for the longitude prize in place of his third machine. It was tested on two voyages to the West Indies and on both occasions it met the requirements of the Act, but the Board of Longitude withheld half the prize money until they had proof that the timekeeper could be duplicated. Copies were made by Harrison and by Larcum Kendall, but the Board still continued to prevaricate and Harrison received the full amount of the prize in 1773 only after George III had intervened on his behalf.

Although Harrison had shown that it was possible to construct a timepiece of sufficient accuracy to determine longitude at sea, his solution was too complex and costly to be produced in quantity. It had, for example, taken Larcum Kendall two years to produce his copy of Harrison's fourth timekeeper, but Harrison had overcome the psychological barrier and opened the door for others to produce chronometers in quantity at an affordable price. This was achieved before the end of the century by Arnold and Earnshaw, but they used an entirely different design that owed more to Le Roy than it did to Harrison and which only retained Harrison's maintaining power.

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Principal Honours and Distinctions

Royal Society Copley Medal 1749.

Bibliography

1767, The Principles of Mr Harrison's Time-keeper, with Plates of the Same, London. 1767, Remarks on a Pamphlet Lately Published by the Rev. Mr Maskelyne Under the

Authority of the Board of Longitude, London.

1775, A Description Concerning Such Mechanisms as Will Afford a Nice or True Mensuration of Time, London.

Further Reading

R.T.Gould, 1923, The Marine Chronometer: Its History and Development, London; reprinted 1960, Holland Press.

—1978, John Harrison and His Timekeepers, 4th edn, London: National Maritime Museum.

H.Quill, 1966, John Harrison, the Man who Found Longitude, London. A.G.Randall, 1989, "The technology of John Harrison's portable timekeepers", Antiquarian Horology 18:145–60, 261–77.

J.Betts, 1993, John Harrison London (a good short account of Harrison's work). S.Smiles, 1905, Men of Invention and Industry; London: John Murray, Chapter III. Dictionary of National Biography, Vol. IX, pp. 35–6.

See also: Burgi, Jost; Huygens, Christiaan

DV

degree

1. степень; ступень 2. градус
degree of abrasion степень абразии
degree of air saturation степень насыщения воздуха
degree of arc угол дуги
degree of compacting степень уплотнения
degree of crystallization степень кристаллизации
degree of curvature угол [степень] кривизны
degree of dip угол падения, угол наклона (пласта)
degree of elevation угол [степень] возвышения
degree of expansion степень расширения, расширяемость
degree of freedom степень свободы системы
degree of hardness степень твёрдости
degree of heat степень нагретости, степень нагрева
degree of humidity степень влажности
degree of latitude градус широты, широта
degree of longitude градус долготы, долгота
degree of metamorphism степень метаморфизма
degree of rounding of grains степень окатанности зёрен
degree of slope угол [степень] наклона
degree of sorting степень сортированности
degree of water hardness степень жёсткости воды
compactness degree степень уплотнённости
geothermic degree геотермический градиент
ordering degree степень упорядоченности
relative degree of humidity относительная степень влажности
zero degree абсолютный нуль (температурной шкалы)

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градиент

meridian integration

пол. меридианная [меридиональная\] интеграция (в терминах геополитики: интеграция по оси Север-Юг; связывание отдельных пространственных секторов в единое целое по меридиану; позитивна в случае уверенного контроля над северными и центральными областями; негативна в случае нахождения на севере или в центре геополитических образований, чья лояльность стратегической столице сомнительна или слаба)

Syn:

longitude integration

See:

meridian expansion, geopolitics