(1804-1807)

Bosanquet and Puller's New Reports

Юридический термин: новая серия сборника судебных решений составителей Босанкета и Пуллера (1804-1807), новый сборник судебных решений, составители Босанкет и Пуллер (18041807), новая серия сборника судебных решений (составителей Восанкета и Пуллера, 1804-1807)

B.&P.N.R.

сокр. от Bosanquet and Puller's New Reports

новая серия сборника судебных решений составителей Босанкета и Пуллера (1804-1807)

N.R.

сокр.

1) англ. [Bosanquet and Puller's New Reports] новый сборник судебных решений, составители Босанкет и Пуллер (1804-1807)

2) англ. [The New Reports] "Новый судебный сборник" (1862-1865)

3) [non-resident] не проживающий в государстве суда

4) [not reported] не помещено в сборник судебных решений

5) [no risk] без риска

6) [no responsibility] без ответственности

Code of Napoleon

док.

юр. Кодекс Наполеона

а) = Civil Code of Napoleon

б) мн. (собирательное название кодексов французского гражданского, торгового, гражданско-процессуального, уголовного и уголовно-процессуального права: Французского гражданского кодекса 1804 г., Французского торгового кодекса 1807 г., Гражданского процессуального кодекса 1807 г., Уголовного Кодекса 1810 г., Уголовно-процессуального кодекса 1811 г.)

See:

civil law, continental law, common law, Commercial Code of Napoleon

Johnson, Thomas

SUBJECT AREA: Textiles

[br]

fl. 1800s England

d. after 1846

[br]

English developer of the sizing and beaming machine, and improver of the hand loom.

[br]

Thomas Johnson was an assistant to William Radcliffe c.1802 in his developments of the sizing machine and hand looms. Johnson is described by Edward Baines (1835) as "an ingenious but dissipated young man to whom he [Radcliffe] explained what he wanted, and whose fertile invention suggested a great variety of expedients, so that he obtained the name of the “conjuror” among his fellow-workmen". Johnson's genius, and Radcliffe's judgement and perseverance, at length produced the dressing-machine that was soon applied to power looms and made their use economic. Cotton warps had to be dressed with a starch paste to prevent them from fraying as they were being woven. Up to this time, the paste had had to be applied as the warp was unwound from the back of the loom, which meant that only short lengths could be treated and then left to dry, holding up the weaver. Radcliffe carried out the dressing and beaming in a separate machine so that weaving could proceed without interruption. Work on the dressing-machine was carried out in 1802 and patents were taken out in 1803 and 1804. These were made out in Johnson's name because Radcliffe was afraid that if his own name were used other people, particularly foreigners, would discover his secrets. Two more patents were taken out for improvements to hand looms. The first of these was a take-up motion for the woven cloth that automatically wound the cloth onto a roller as the weaver operated the loom. This was later incorporated by H.Horrocks into his own power loom design.

Radcliffe and Johnson also developed the "dandy-loom", which was a more compact form of hand loom and later became adapted for weaving by power. Johnson was the inventor of the first circular or revolving temples, which kept the woven cloth at the right width. In the patent specifications there is a patent in 1805 by Thomas Johnson and James Kay for an improved power loom and another in 1807 for a vertical type of power loom. Johnson could have been involved with further patents in the 1830s and 1840s for vertical power looms and dressing-machines, which would put his death after 1846.

[br]

Bibliography

1802, British patent no. 2,684 (dressing-machine).

1803, British patent no. 2,771 (dressing-machine).

1805, with James Kay, British patent no. 2,876 (power-loom). 1807, British patent no. 6,570 (vertical powerloom).

Further Reading

There is no general account of Johnson's life, but references to his work with Radcliffe may be found in A.Barlow, 1878, The History and Principles of Weaving by Hand and by Power, London; and in E.Baines, 1835, History of the Cotton Manufacture in Great Britain, London.

D.J.Jeremy, 1981, Transatlantic Industrial Revolution. The Diffusion of Textile Technologies Between Britain and America, 1790–1830s, Oxford (for the impact of the dressing-machine in America).

RLH

Burr, Aaron

(1756-1836) Бэрр, Аарон

Государственный и политический деятель, юрист. Во время Войны за независимость [ Revolutionary War] воевал в рядах Континентальной армии [ Continental Army]. С 1782 практиковал как адвокат. В 1791-97 - сенатор США от штата Нью-Йорк. В 1784-85 и 1798-99 - член законодательного собрания штата Нью-Йорк, в 1789-90 - генеральный прокурор [attorney general] штата. В 1801-05 - вице-президент США [ Vice-President, U.S.] в администрации президента Т. Джефферсона [ Jefferson, Thomas]. 11 июля 1804 смертельно ранил на дуэли А. Гамильтона [ Hamilton, Alexander] (против Бэрра были выдвинуты обвинения в двух штатах, но суд так и не состоялся). Возглавил т.н. "заговор Бэрра" [ Burr Conspiracy], целью которого было создание независимого государственного объединения из западных территорий США и части испанских колоний. Был судим по обвинению в государственной измене в августе 1807, но оправдан. В 1812 вернулся к адвокатской практике.

Hot Springs

Хот-Спрингс

Город в центральной части штата Арканзас, в предгорьях гор Уошито [ Ouachita Mountains] и Озарков [ Ozark Mountains]. 35,7 тыс. жителей (2000). Основан в 1807, статус города с 1886. Считается, что в 1541 эти места посетила экспедиция Э. де Сото [ De Soto, Hernando]. В 1804 группа картографов и других специалистов по заданию Т. Джефферсона [ Jefferson, Thomas] изучала источники и составила карты. Популярный курорт. 47 термальных источников, дающих в сутки примерно 1 млн. галлонов горячей (до 62 гр. C) хлоридно-натриевой минеральной воды. Производство воды в бутылках. Местный колледж [ junior college]. В 1921 создан Национальный парк Хот-Спрингс [Hot Springs National Park].

Jefferson, Thomas

(1743-1826) Джефферсон, Томас

3-й президент США [ President, U.S.] (в 1801-09), государственный и политический деятель, один из "отцов-основателей" [ Founding Fathers] страны. В 1762 окончил Колледж Вильгельма и Марии [ William and Mary College], с 1767 занимался адвокатской практикой. В 1769 начал политическую деятельность в качестве члена законодательного собрания Вирджинии. В ответ на Репрессивные законы [ Intolerable Acts] (1774) написал "Общий обзор прав Британской Америки" ["Summary View of the Rights of British America"], в котором полностью отвергал притязания Англии на управление колониями. В 1775 избран делегатом на Второй Континентальный конгресс [ Continental Congresses]. Возглавил комитет из пяти человек по составлению Декларации независимости [ Declaration of Independence] и стал ее основным автором. Ему, в частности, принадлежат слова из Декларации: "Мы исходим из той самоочевидной истины, что все люди созданы равными и наделены Создателем определенными неотъемлемыми правами, среди которых право на жизнь, свободу и стремление к счастью" ["We hold these truths to be self-evident, that all men are created equal, that they are endowed by their Creator with certain unalienable rights, that among these are Life, Liberty and the pursuit of Happiness"]. В 1779-81 был губернатором Вирджинии, затем избран в Конгресс. В 1785-89 посол США во Франции; сменил на этом посту Б. Франклина [ Franklin, Benjamin]. В администрации Вашингтона [ Washington, George] был госсекретарем [ Secretary of State]. Автор идеи создания светского государства, выступал за демократический характер развития общества [ Jeffersonian Democracy], главный оппонент А. Гамильтона [ Hamilton, Alexander] по этому вопросу; создал Демократическую-Республиканскую партию [ Democratic-Republican Party]. Исповедовал идеалы Просвещения. В результате выборов 1796 стал вице-президентом. Занимая этот пост, написал "Учебник парламентской практики" ["Manual of Parliamentary Practice"] и вместе с Дж. Мэдисоном [ Madison, James] составил Резолюции Кентукки и Вирджинии [ Kentucky and Virginia Resolutions]. На выборах 1800 набрал равное число голосов с А. Бэрром [ Burr, Aaron], поэтому на пост президента был избран Конгрессом. Его президентство отмечено достижениями во внешней политике, в освоении Фронтира [ Frontier], более сбалансированным бюджетом и сокращением национального долга. Джефферсон добился подписания с Францией договора о покупке Луизианы [ Louisiana Purchase] (1803), отправил на Запад экспедицию Льюиса и Кларка [ Lewis and Clark Expedition]. В 1804 был переизбран на второй срок. Второй срок его президентства был отмечен усилиями по сохранению нейтралитета США в наполеоновских войнах, принятием, а затем отменой противоречивого Закона об эмбарго 1807 [ Embargo Act]. В 1809 ушел в отставку и поселился в своем имении Монтиселло [ Monticello]. Был разносторонним человеком: его интересы включали архитектуру, философию, игру на скрипке, воздухоплавание, ботанику, геологию и другие науки. В 1819 он основал Вирджинский университет [ Virginia, University of]. Умер 4 июля 1826, в годовщину Декларации независимости. Завещал выбить на своем могильном камне слова о трех его заслугах перед страной, которые он больше всего ценил: "... автор Декларации независимости США, Вирджинского статута о свободе религии и создатель Вирджинского университета". Наравне с Б. Франклином считается великим представителем эпохи Просвещения. В 1900 среди первой группы американцев избран в национальную Галерею славы [ Hall of Fame]

Thompson, David

(1770-1857) Томпсон, Дэвид

Географ, первопроходец. Один из крупнейших геодезистов Северной Америки в XIX в. Изучил обширные регионы на западе современной Канады и северо-западе современных США. Англичанин по происхождению, с 14 лет работал в Компании Гудзонова залива [ Hudson's Bay Company], где приобрел навыки геодезиста и топографа. В 1797 поступил на работу в Северо-Западную компанию [ North West Company], став в 1804 ее совладельцем. В 1797-98 составил подробные карты верховий р. Миссисипи [ Mississippi River], в 1807 пересек Скалистые горы [ Rocky Mountains] с канадской стороны и открыл истоки р. Колумбия [ Columbia River]. В 1808-10 исследовал территории современных штатов Вашингтон, Айдахо и Монтана. В 1811 стал первым европейцем, прошедшим вдоль всего течения р. Колумбия. В 1816-26 по поручению Комиссии по демаркации границы изучил границу между США и Канадой от реки Св. Лаврентия [ St. Lawrence River] до Лесного озера [ Lake of the Woods]

Cayley, Sir George

SUBJECT AREA: Aerospace

[br]

b. 27 December 1773 Scarborough, England

d. 15 December 1857 Brompton Hall, Yorkshire, England

[br]

English pioneer who laid down the basic principles of the aeroplane in 1799 and built a manned glider in 1853.

[br]

Cayley was born into a well-to-do Yorkshire family living at Brompton Hall. He was encouraged to study mathematics, navigation and mechanics, particularly by his mother. In 1792 he succeeded to the baronetcy and took over the daunting task of revitalizing the run-down family estate.

The first aeronautical device made by Cayley was a copy of the toy helicopter invented by the Frenchmen Launoy and Bienvenu in 1784. Cayley's version, made in 1796, convinced him that a machine could "rise in the air by mechanical means", as he later wrote. He studied the aerodynamics of flight and broke away from the unsuccessful ornithopters of his predecessors. In 1799 he scratched two sketches on a silver disc: one side of the disc showed the aerodynamic force on a wing resolved into lift and drag, and on the other side he illustrated his idea for a fixed-wing aeroplane; this disc is preserved in the Science Museum in London. In 1804 he tested a small wing on the end of a whirling arm to measure its lifting power. This led to the world's first model glider, which consisted of a simple kite (the wing) mounted on a pole with an adjustable cruciform tail. A full-size glider followed in 1809 and this flew successfully unmanned. By 1809 Cayley had also investigated the lifting properties of cambered wings and produced a low-drag aerofoil section. His aim was to produce a powered aeroplane, but no suitable engines were available. Steam-engines were too heavy, but he experimented with a gunpowder motor and invented the hot-air engine in 1807. He published details of some of his aeronautical researches in 1809–10 and in 1816 he wrote a paper on airships. Then for a period of some twenty-five years he was so busy with other activities that he largely neglected his aeronautical researches. It was not until 1843, at the age of 70, that he really had time to pursue his quest for flight. The Mechanics' Magazine of 8 April 1843 published drawings of "Sir George Cayley's Aerial Carriage", which consisted of a helicopter design with four circular lifting rotors—which could be adjusted to become wings—and two pusher propellers. In 1849 he built a full-size triplane glider which lifted a boy off the ground for a brief hop. Then in 1852 he proposed a monoplane glider which could be launched from a balloon. Late in 1853 Cayley built his "new flyer", another monoplane glider, which carried his coachman as a reluctant passenger across a dale at Brompton, Cayley became involved in public affairs and was MP for Scarborough in 1832. He also took a leading part in local scientific activities and was co-founder of the British Association for the Advancement of Science in 1831 and of the Regent Street Polytechnic Institution in 1838.

[br]

Bibliography

Cayley wrote a number of articles and papers, the most significant being "On aerial navigation", Nicholson's Journal of Natural Philosophy (November 1809—March 1810) (published in three numbers); and two further papers with the same title in Philosophical Magazine (1816 and 1817) (both describe semi-rigid airships).

Further Reading

L.Pritchard, 1961, Sir George Cayley, London (the standard work on the life of Cayley).

C.H.Gibbs-Smith, 1962, Sir George Cayley's Aeronautics 1796–1855, London (covers his aeronautical achievements in more detail).

—1974, "Sir George Cayley, father of aerial navigation (1773–1857)", Aeronautical Journal (Royal Aeronautical Society) (April) (an updating paper).

JDS

Jessop, William

SUBJECT AREA: Canals, Civil engineering, Ports and shipping, Railways and locomotives

[br]

b. 23 January 1745 Plymouth, England

d. 18 November 1814

[br]

English engineer engaged in river, canal and dock construction.

[br]

William Jessop inherited from his father a natural ability in engineering, and because of his father's association with John Smeaton in the construction of Eddystone Lighthouse he was accepted by Smeaton as a pupil in 1759 at the age of 14. Smeaton was so impressed with his ability that Jessop was retained as an assistant after completion of his pupilage in 1767. As such he carried out field-work, making surveys on his own, but in 1772 he was recommended to the Aire and Calder Committee as an independent engineer and his first personally prepared report was made on the Haddlesey Cut, Selby Canal. It was in this report that he gave his first evidence before a Parliamentary Committee. He later became Resident Engineer on the Selby Canal, and soon after he was elected to the Smeatonian Society of Engineers, of which he later became Secretary for twenty years. Meanwhile he accompanied Smeaton to Ireland to advise on the Grand Canal, ultimately becoming Consulting Engineer until 1802, and was responsible for Ringsend Docks, which connected the canal to the Liffey and were opened in 1796. From 1783 to 1787 he advised on improvements to the River Trent, and his ability was so recognized that it made his reputation. From then on he was consulted on the Cromford Canal (1789–93), the Leicester Navigation (1791–4) and the Grantham Canal (1793–7); at the same time he was Chief Engineer of the Grand Junction Canal from 1793 to 1797 and then Consulting Engineer until 1805. He also engineered the Barnsley and Rochdale Canals. In fact, there were few canals during this period on which he was not consulted. It has now been established that Jessop carried the responsibility for the Pont-Cysyllte Aqueduct in Wales and also prepared the estimates for the Caledonian Canal in 1804. In 1792 he became a partner in the Butterley ironworks and thus became interested in railways. He proposed the Surrey Iron Railway in 1799 and prepared for the estimates; the line was built and opened in 1805. He was also the Engineer for the 10 mile (16 km) long Kilmarnock \& Troon Railway, the Act for which was obtained in 1808 and was the first Act for a public railway in Scotland. Jessop's advice was sought on drainage works between 1785 and 1802 in the lowlands of the Isle of Axholme, Holderness, the Norfolk Marshlands, and the Axe and Brue area of the Somerset Levels. He was also consulted on harbour and dock improvements. These included Hull (1793), Portsmouth (1796), Folkestone (1806) and Sunderland (1807), but his greatest dock works were the West India Docks in London and the Floating Harbour at Bristol. He was Consulting Engineer to the City of London Corporation from 1796to 1799, drawing up plans for docks on the Isle of Dogs in 1796; in February 1800 he was appointed Engineer, and three years later, in September 1803, he was appointed Engineer to the Bristol Floating Harbour. Jessop was regarded as the leading civil engineer in the country from 1785 until 1806. He died following a stroke in 1814.

[br]

Further Reading

C.Hadfield and A.W.Skempton, 1979, William Jessop. Engineer, Newton Abbot: David \& Charles.

JHB

Reichenbach, Georg Friedrich von

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering, Photography, film and optics, Public utilities

[br]

b. 24 August 1772 Durlach, Baden, Germany

d. 21 May 1826 Munich, Germany

[br]

German engineer.

[br]

While he was attending the Military School at Mannheim, Reichenbach drew attention to himself due to the mathematical instruments that he had designed. On the recommendation of Count Rumford in Munich, the Bavarian government financed a two-year stay in Britain so that Reichenbach could become acquainted with modern mechanical engineering. He returned to Mannheim in 1793, and during the Napoleonic Wars he was involved in the manufacture of arms. In Munich, where he was in the service of the Bavarian state from 1796, he started producing precision instruments in his own time. His basic invention was the design of a dividing machine for circles, produced at the end of the eighteenth century. The astronomic and geodetic instruments he produced excelled all the others for their precision. His telescopes in particular, being perfect in use and of solid construction, soon brought him an international reputation. They were manufactured at the MathematicMechanical Institute, which he had jointly founded with Joseph Utzschneider and Joseph Liebherr in 1804 and which became a renowned training establishment. The glasses and lenses were produced by Joseph Fraunhofer who joined the company in 1807.

In the same year he was put in charge of the technical reorganization of the salt-works at Reichenhall. After he had finished the brine-transport line from Reichenhall to Traunstein in 1810, he started on the one from Berchtesgaden to Reichenhall which was an extremely difficult task because of the mountainous area that had to be crossed. As water was the only source of energy available he decided to use water-column engines for pumping the brine in the pipes of both lines. Such devices had been in use for pumping purposes in different mining areas since the middle of the eighteenth century. Reichenbach knew about the one constructed by Joseph Karl Hell in Slovakia, which in principle had just been a simple piston-pump driven by water which did not work satisfactorily. Instead he constructed a really effective double-action water-column engine; this was a short time after Richard Trevithick had constructed a similar machine in England. For the second line he improved the system and built a single-action pump. All the parts of it were made of metal, which made them easy to produce, and the pumps proved to be extremely reliable, working for over 100 years.

At the official opening of the line in 1817 the Bavarian king rewarded him generously. He remained in the state's service, becoming head of the department for roads and waterways in 1820, and he contributed to the development of Bavarian industry as well as the public infrastructure in many ways as a result of his mechanical skill and his innovative engineering mind.

[br]

Further Reading

Bauernfeind, "Georg von Reichenbach" Allgemeine deutsche Biographie 27:656–67 (a reliable nineteenth-century account).

W.Dyck, 1912, Georg v. Reichenbach, Munich.

K.Matschoss, 1941, Grosse Ingenieure, Munich and Berlin, 3rd edn. 121–32 (a concise description of his achievements in the development of optical instruments and engineering).

WK

Stevens, John

SUBJECT AREA: Land transport, Ports and shipping, Railways and locomotives

[br]

b. 1749 New York, New York, USA

d. 6 March 1838 Hoboken, New Jersey, USA

[br]

American pioneer of steamboats and railways.

[br]

Stevens, a wealthy landowner with an estate at Hoboken on the Hudson River, had his attention drawn to the steamboat of John Fitch in 1786, and thenceforth devoted much of his time and fortune to developing steamboats and mechanical transport. He also had political influence and it was at his instance that Congress in 1790 passed an Act establishing the first patent laws in the USA. The following year Stevens was one of the first recipients of a US patent. This referred to multi-tubular boilers, of both watertube and firetube types, and antedated by many years the work of both Henry Booth and Marc Seguin on the latter.

A steamboat built in 1798 by John Stevens, Nicholas J.Roosevelt and Stevens's brother-in-law, Robert R.Livingston, in association was unsuccessful, nor was Stevens satisfied with a boat built in 1802 in which a simple rotary steam-en-gine was mounted on the same shaft as a screw propeller. However, although others had experimented earlier with screw propellers, when John Stevens had the Little Juliana built in 1804 he produced the first practical screw steamboat. Steam at 50 psi (3.5 kg/cm²) pressure was supplied by a watertube boiler to a single-cylinder engine which drove two contra-rotating shafts, upon each of which was mounted a screw propeller. This little boat, less than 25 ft (7.6 m) long, was taken backwards and forwards across the Hudson River by two of Stevens's sons, one of whom, R.L. Stevens, was to help his father with many subsequent experiments. The boat, however, was ahead of its time, and steamships were to be driven by paddle wheels until the late 1830s.

In 1807 John Stevens declined an invitation to join with Robert Fulton and Robert R.Living-ston in their development work, which culminated in successful operation of the PS Clermont that summer; in 1808, however, he launched his own paddle steamer, the Phoenix. But Fulton and Livingston had obtained an effective monopoly of steamer operation on the Hudson and, unable to reach agreement with them, Stevens sent Phoenix to Philadelphia to operate on the Delaware River. The intervening voyage over 150 miles (240 km) of open sea made Phoenix the first ocean-going steamer.

From about 1810 John Stevens turned his attention to the possibilities of railways. He was at first considered a visionary, but in 1815, at his instance, the New Jersey Assembly created a company to build a railway between the Delaware and Raritan Rivers. It was the first railway charter granted in the USA, although the line it authorized remained unbuilt. To demonstrate the feasibility of the steam locomotive, Stevens built an experimental locomotive in 1825, at the age of 76. With flangeless wheels, guide rollers and rack-and-pinion drive, it ran on a circular track at his Hoboken home; it was the first steam locomotive to be built in America.

[br]

Bibliography

1812, Documents Tending to Prove the Superior Advantages of Rail-ways and Steam-carriages over Canal Navigation.

He took out patents relating to steam-engines in the USA in 1791, 1803, and 1810, and in England, through his son John Cox Stevens, in 1805.

Further Reading

H.P.Spratt, 1958, The Birth of the Steamboat, Charles Griffin (provides technical details of Stevens's boats).

J.T.Flexner, 1978, Steamboats Come True, Boston: Little, Brown (describes his work in relation to that of other steamboat pioneers).

J.R.Stover, 1961, American Railroads, Chicago: University of Chicago Press.

Transactions of the Newcomen Society (1927) 7: 114 (discusses tubular boilers).

J.R.Day and B.G.Wilson, 1957, Unusual Railways, F.Muller (discusses Stevens's locomotive).

See also: Allen, Horatio; Cooper, Peter

PJGR