provide+an+education

Buckle, William

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering

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b. 29 July 1794 Alnwick, Northumberland, England

d. 30 September 1863 London, England

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English mechanical engineer who introduced the first large screw-cutting lathe to Boulton, Watt \& Co.

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William Buckle was the son of Thomas Buckle (1759–1849), a millwright who later assisted the 9th Earl of Dundonald (1749–1831) in his various inventions, principally machines for the manufacture of rope. Soon after the birth of William, the family moved from Alnwick to Hull, Yorkshire, where he received his education. The family again moved c.1808 to London, and William was apprenticed to Messrs Woolf \& Edwards, millwrights and engineers of Lambeth. During his apprenticeship he attended evening classes at a mechanical drawing school in Finsbury, which was then the only place of its kind in London.

After completing his apprenticeship, he was sent by Messrs Humphrys to Memel in Prussia to establish steamboats on the rivers and lakes there under the patronage of the Prince of Hardenburg. After about four years he returned to Britain and was employed by Boulton, Watt \& Co. to install the engines in the first steam mail packet for the service between Dublin and Holyhead. He was responsible for the engines of the steamship Lightning when it was used on the visit of George IV to Ireland.

About 1824 Buckle was engaged by Boulton, Watt \& Co. as Manager of the Soho Foundry, where he is credited with introducing the first large screw-cutting lathe. At Soho about 700 or 800 men were employed on a wide variety of engineering manufacture, including coining machinery for mints in many parts of the world, with some in 1826 for the Mint at the Soho Manufactory. In 1851, following the recommendations of a Royal Commission, the Royal Mint in London was reorganized and Buckle was asked to take the post of Assistant Coiner, the senior executive officer under the Deputy Master. This he accepted, retaining the post until the end of his life.

At Soho, Buckle helped to establish a literary and scientific institution to provide evening classes for the apprentices and took part in the teaching. He was an original member of the Institution of Mechanical Engineers, which was founded in Birmingham in January 1847, and a member of their Council from then until 1855. He contributed a number of papers in the early years, including a memoir of William Murdock whom he had known at Soho; he resigned from the Institution in 1856 after his move to London. He was an honorary member of the London Association of Foreman Engineers.

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Bibliography

1850, "Inventions and life of William Murdock", Proceedings of the Institution of Mechanical Engineers 2 (October): 16–26.

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Deere, John

SUBJECT AREA: Agricultural and food technology

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b. 7 February 1804 Rutland, Vermont, USA

d. 17 May 1886 USA

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American inventor and manufacturer of agricultural equipment.

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John Deere was the son of a tailor, and first worked as a tanner before becoming apprenticed to a blacksmith. He married Demarius Lamb in 1827, but it appears that competition for blacksmiths was fierce, and the Deere family moved frequently. Two attempts to establish forges ended in fires, and changing partnerships and arguments over debts were to be a feature of Deere's working life. In 1836 John Deere moved west on his own, in an attempt to establish himself. He settled in Grand Detour, Illinois. In this new frontier a blacksmith's skills were sought after, and the blacksmith, with no ready supply of raw materials, had to be able to operate both a furnace for melting metal and a forge for working it. Deere was sufficiently successful for his family to be able to join him. A chance visit to a sawmill and the acquisition of a broken saw blade led to the making of a plough that was to establish John Deere in manufacturing. There were two distinctive features associated with the plough: the soil in the area failed to stick to the steel blade, with obvious benefits to the draught of the implement; and second, the shape of the working mouldboard was square. The reputation that developed with his first three ploughs established that Deere had made the transition from blacksmith to manufacturer.

Over the next decade he had a number of partnerships and eventually set up a factory in Moline, Illinois, in 1848. The following year he sold 2,136 ploughs, and by early 1850 he was producing 350 ploughs per month. Deere was devastated by the loss of his eldest son in the year that the company moved to Moline. However, his second son, Charles, joined him in 1851 and was to be a major influence on the way in which the company developed over the next half-century. The company branched out into the production of cultivators, harrows, drills and wagons. John Deere himself played an active part in the company, but also played an increasing role in public life, with a particular interest in education. The company was incorporated in 1868.

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Further Reading

The following both provide biographical details of John Deere, but are mainly concerned with the company and the equipment it produced: W.G.Broehl, 1984, John Deere's Company: A History of Deere and Company and its

Times, American Society of Agricultural Engineers.

D.Macmillan, 1988, John Deere Tractors and Equipment, American Society of Agricultural Engineers.

AP

Holden, Sir Isaac

SUBJECT AREA: Textiles

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b. 7 May 1807 Hurlet, between Paisley and Glasgow, Scotland

d. 13 August 1897

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British developer of the wool-combing machine.

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Isaac Holden's father, who had the same name, had been a farmer and lead miner at Alston in Cumbria before moving to work in a coal-mine near Glasgow. After a short period at Kilbarchan grammar school, the younger Isaac was engaged first as a drawboy to two weavers and then, after the family had moved to Johnstone, Scotland, worked in a cotton-spinning mill while attending night school to improve his education. He was able to learn Latin and bookkeeping, but when he was about 15 he was apprenticed to an uncle as a shawl-weaver. This proved to be too much for his strength so he returned to scholastic studies and became Assistant to an able teacher, John Kennedy, who lectured on physics, chemistry and history, which he also taught to his colleague. The elder Isaac died in 1826 and the younger had to provide for his mother and younger brother, but in 1828, at the age of 21, he moved to a teaching post in Leeds. He filled similar positions in Huddersfield and Reading, where in October 1829 he invented and demonstrated the lucifer match but did not seek to exploit it. In 1830 he returned because of ill health to his mother in Scotland, where he began to teach again. However, he was recommended as a bookkeeper to William Townend, member of the firm of Townend Brothers, Cullingworth, near Bingley, Yorkshire. Holden moved there in November 1830 and was soon involved in running the mill, eventually becoming a partner.

In 1833 Holden urged Messrs Townend to introduce seven wool-combing machines of Collier's designs, but they were found to be very imperfect and brought only trouble and loss. In 1836 Holden began experimenting on the machines until they showed reasonable success. He decided to concentrate entirely on developing the combing machine and in 1846 moved to Bradford to form an alliance with Samuel Lister. A joint patent in 1847 covered improvements to the Collier combing machine. The "square motion" imitated the action of the hand-comber more closely and was patented in 1856. Five more patents followed in 1857 and others from 1858 to 1862. Holden recommended that the machines should be introduced into France, where they would be more valuable for the merino trade. This venture was begun in 1848 in the joint partnership of Lister \& Holden, with equal shares of profits. Holden established a mill at Saint-Denis, first with Donisthorpe machines and then with his own "square motion" type. Other mills were founded at Rheims and at Croix, near Roubaix. In 1858 Lister decided to retire from the French concerns and sold his share to Holden. Soon after this, Holden decided to remodel all their machinery for washing and carding the gill machines as well as perfecting the square comb. Four years of excessive application followed, during which time £20,000 was spent in experiments in a small mill at Bradford. The result fully justified the expenditure and the Alston Works was built in Bradford.

Holden was a Liberal and from 1865 to 1868 he represented Knaresborough in Parliament. Later he became the Member of Parliament for the Northern Division of the Riding, Yorkshire, and then for the town of Keighley after the constituencies had been altered. He was liberal in his support of religious, charitable and political objectives. His house at Oakworth, near Keighley, must have been one of the earliest to have been lit by electricity.

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Principal Honours and Distinctions

Baronet 1893.

Bibliography

1847, with Samuel Lister, British patent no. 11,896 (improved Collier combing machine). 1856. British patent no. 1,058 ("square motion" combing machine).

1857. British patent no. 278 1857, British patent no. 279 1857, British patent no. 280 1857, British patent no. 281 1857, British patent no. 3,177 1858, British patent no. 597 1859, British patent no. 52 1860, British patent no. 810 1862, British patent no. 1,890 1862, British patent no. 3,394

Further Reading

J.Hogg (ed.), c.1888, Fortunes Made in Business, London (provides an account of Holden's life).

Obituary, 1897, Engineer 84.

Obituary, 1897, Engineering 64.

E.M.Sigsworth, 1973, "Sir Isaac Holden, Bt: the first comber in Europe", in N.B.Harte and K.G.Ponting (eds), Textile History and Economic History, Essays in Honour of

Miss Julia de Lacy Mann, Manchester.

W.English, 1969, The Textile Industry, London (provides a good explanation of the square motion combing machine).

RLH

Ramsden, Jesse

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering

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b. 6 October 1735 (?) Halifax, Yorkshire, England

d. 5 November 1800 Brighton, Sussex, England

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English instrument-maker who developed machines for accurately measuring angular and linear scales.

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Jesse Ramsden was the son of an innkeeper but received a good general education: after attending the free school at Halifax, he was sent at the age of 12 to his uncle for further study, particularly in mathematics. At the age of 16 he was apprenticed to a cloth-worker in Halifax and on completion of the apprenticeship in 1755 he moved to London to work as a clerk in a cloth warehouse. In 1758 he became an apprentice in the workshop of a London mathematical instrument-maker named Burton. He quickly gained the skill, particularly in engraving, and by 1762 he was able to set up on his own account. He married in 1765 or 1766 the youngest daughter of the optician John Dollond FRS (1706– 61) and received a share of Dollond's patent for making achromatic lenses.

Ramsden's experience and reputation increased rapidly and he was generally regarded as the leading instrument-maker of his time. He opened a shop in the Haymarket and transferred to Piccadilly in 1775. His staff increased to about sixty workers and apprentices, and by 1789 he had constructed nearly 1,000 sextants as well as theodolites, micrometers, balances, barometers, quadrants and other instruments.

One of Ramsden's most important contributions to precision measurement was his development of machines for obtaining accurate division of angular and linear scales. For this work he received a premium from the Commissioners of the Board of Longitude, who published his descriptions of the machines. For the trigonometrical survey of Great Britain, initiated by General William Roy FRS (1726–90) and continued by the Board of Ordnance, Ramsden supplied a 3 ft (91 cm) theodolite and steel measuring chains, and was also engaged to check the glass tubes used to measure the fundamental base line.

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Principal Honours and Distinctions

FRS 1786; Royal Society Copley Medal 1795. Member, Imperial Academy of St Petersburg 1794. Member, Smeatonian Society of Civil Engineers 1793.

Bibliography

1774, Description of a New Universal Equatorial Instrument, London; repub. 1791. 1777, Description of an Engine for Dividing Mathematical Instruments, London. 1779, Description of an Engine for Dividing Straight Lines on Mathematical

Instruments, London.

1779, "Description of two new micrometers", Philosophical Transactions of the Royal Society 69:419–31.

1782, "A new construction of eyeglasses for such telescopes as may be applied to mathematical instruments", Philosophical Transactions of the Royal Society 73:94–99.

Further Reading

R.S.Woodbury, 1961, History of the Lathe to 1850, Cleveland, Ohio; W.Steeds, 1969, A History of Machine Tools 1700–1910, Oxford (both provide a brief description of Ramsden's dividing machines).

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Whitney, Eli

SUBJECT AREA: Textiles, Weapons and armour

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b. 8 December 1765 Westborough, Massachusetts, USA

d. 8 January 1825 New Haven, Connecticut, USA

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American inventor of the cotton gin and manufacturer of firearms.

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The son of a prosperous farmer, Eli Whitney as a teenager showed more interest in mechanics than school work. At the age of 15 he began an enterprise business manufacturing nails in his father's workshop, even having to hire help to fulfil his orders. He later determined to acquire a university education and, his father having declined to provide funds, he taught at local schools to obtain the means to attend Leicester Academy, Massachusetts, in preparation for his entry to Yale in 1789. He graduated in 1792 and then decided to study law. He accepted a position in Georgia as a tutor that would have given him time for study; this post did not materialize, but on his journey south he met General Nathanael Greene's widow and the manager of her plantations, Phineas Miller (1764–1803). A feature of agriculture in the southern states was that the land was unsuitable for long-staple cotton but could yield large crops of green-seed cotton. Green-seed cotton was difficult to separate from its seed, and when Whitney learned of the problem in 1793 he quickly devised a machine known as the cotton gin, which provided an effective solution. He formed a partnership with Miller to manufacture the gin and in 1794 obtained a patent. This invention made possible the extraordinary growth of the cotton industry in the United States, but the patent was widely infringed and it was not until 1807, after amendment of the patent laws, that Whitney was able to obtain a favourable decision in the courts and some financial return.

In 1798 Whitney was in financial difficulties following the failure of the initial legal action against infringement of the cotton gin patent, but in that year he obtained a government contract to supply 10,000 muskets within two years with generous advance payments. He built a factory at New Haven, Connecticut, and proposed to use a new method of manufacture, perhaps the first application of the system of interchangeable parts. He failed to supply the firearms in the specified time, and in fact the first 500 guns were not delivered until 1801 and the full contract was not completed until 1809.

In 1812 Whitney made application for a renewal of his cotton gin patent, but this was refused. In the same year, however, he obtained a second contract from the Government for 15,000 firearms and a similar one from New York State which ensured the success of his business.

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Further Reading

J.Mirsky and A.Nevins, 1952, The World of Eli Whitney, New York (a good biography). P.J.Federico, 1960, "Records of Eli Whitney's cotton gin patent", Technology and Culture 1: 168–76 (for details of the cotton gin patent).

R.S.Woodbury, 1960, The legend of Eli Whitney and interchangeable parts', Technology and Culture 1:235–53 (challenges the traditional view of Eli Whitney as the sole originator of the "American" system of manufacture).

See also Technology and Culture 14(1973):592–8; 18(1977):146–8; 19(1978):609–11.

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Whitworth, Sir Joseph

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering, Metallurgy, Weapons and armour

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b. 21 December 1803 Stockport, Cheshire, England

d. 22 January 1887 Monte Carlo, Monaco

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English mechanical engineer and pioneer of precision measurement.

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Joseph Whitworth received his early education in a school kept by his father, but from the age of 12 he attended a school near Leeds. At 14 he joined his uncle's mill near Ambergate, Derbyshire, to learn the business of cotton spinning. In the four years he spent there he realized that he was more interested in the machinery than in managing a cotton mill. In 1821 he obtained employment as a mechanic with Crighton \& Co., Manchester. In 1825 he moved to London and worked for Henry Maudslay and later for the Holtzapffels and Joseph Clement. After these years spent gaining experience, he returned to Manchester in 1833 and set up in a small workshop under a sign "Joseph Whitworth, Tool Maker, from London".

The business expanded steadily and the firm made machine tools of all types and other engineering products including steam engines. From 1834 Whitworth obtained many patents in the fields of machine tools, textile and knitting machinery and road-sweeping machines. By 1851 the company was generally regarded as the leading manufacturer of machine tools in the country. Whitworth was a pioneer of precise measurement and demonstrated the fundamental mode of producing a true plane by making surface plates in sets of three. He advocated the use of the decimal system and made use of limit gauges, and he established a standard screw thread which was adopted as the national standard. In 1853 Whitworth visited America as a member of a Royal Commission and reported on American industry. At the time of the Crimean War in 1854 he was asked to provide machinery for manufacturing rifles and this led him to design an improved rifle of his own. Although tests in 1857 showed this to be much superior to all others, it was not adopted by the War Office. Whitworth's experiments with small arms led on to the construction of big guns and projectiles. To improve the quality of the steel used for these guns, he subjected the molten metal to pressure during its solidification, this fluid-compressed steel being then known as "Whitworth steel".

In 1868 Whitworth established thirty annual scholarships for engineering students. After his death his executors permanently endowed the Whitworth Scholarships and distributed his estate of nearly half a million pounds to various educational and charitable institutions. Whitworth was elected an Associate of the Institution of Civil Engineers in 1841 and a Member in 1848 and served on its Council for many years. He was elected a Member of the Institution of Mechanical Engineers in 1847, the year of its foundation.

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Principal Honours and Distinctions

Baronet 1869. FRS 1857. President, Institution of Mechanical Engineers 1856, 1857 and 1866. Hon. LLD Trinity College, Dublin, 1863. Hon. DCL Oxford University 1868. Member of the Smeatonian Society of Civil Engineers 1864. Légion d'honneur 1868. Society of Arts Albert Medal 1868.

Bibliography

1858, Miscellaneous Papers on Mechanical Subjects, London; 1873, Miscellaneous Papers on Practical Subjects: Guns and Steel, London (both are collections of his papers to technical societies).

1854, with G.Wallis, The Industry of the United States in Machinery, Manufactures, and

Useful and Ornamental Arts, London.

Further Reading

F.C.Lea, 1946, A Pioneer of Mechanical Engineering: Sir Joseph Whitworth, London (a short biographical account).

A.E.Musson, 1963, "Joseph Whitworth: toolmaker and manufacturer", Engineering Heritage, Vol. 1, London, 124–9 (a short biography).

D.J.Jeremy (ed.), 1984–6, Dictionary of Business Biography, Vol. 5, London, 797–802 (a short biography).

W.Steeds, 1969, A History of Machine Tools 1700–1910, Oxford (describes Whitworth's machine tools).

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IOC as lead partner

1. МОК в роли ведущего партнера

 

МОК в роли ведущего партнера
Выступая в роли ведущего партнера, МОК:
• Предоставляет фонды, системы и решения: через программу спонсорства ТОП, другие маркетинговые программы и продажу телевизионных прав, МОК может собирать и выделять значительные фонды, а также предоставлять организаторам Игр информационные системы и решения для сложных проектов (например, системы информации о результатах). Из-за имеющихся особых обязательств перед спонсорами, маркетинг-партнерами и вещателями-правообладателями, МОК должен обеспечить информирование организаторов обо всех контрактных обязательствах и их строгое выполнение.
• Реализует образовательные программы и программы поддержки: посредством программы УЗОИ и своей сети консультантов, МОК предлагает организаторам образовательные, консультационные и информационные услуги.
[Департамент лингвистических услуг Оргкомитета «Сочи 2014». Глоссарий терминов]

EN

IOC as lead partner
In its role as lead partner, the IOC:
• Provides funds, systems and solutions: through the TOP sponsor program, other marketing programs and the sale of television rights, the IOC is able to collect and allocate substantial funds, and provide information systems and solutions to complex projects (such as the results information systems) for the Games organizers. As there are specific commitments made to sponsors, marketing partners and rights holding broadcasters, the IOC must ensure that all contractual obligations and commitments are communicated to the organizers and strictly fulfilled.
• Delivers education and support programs: through the OGKM program and its network of advisors, the IOC offers training, advisory and information services to organizers.
[Департамент лингвистических услуг Оргкомитета «Сочи 2014». Глоссарий терминов]

Тематики

• спорт (управление Играми)

EN

• IOC as lead partner

memorandum of understanding (MOU)

1. меморандум о взаимопонимании

 

меморандум о взаимопонимании
Соглашение между ОКОИ и МСФ, являющееся инструментом, отражающим ожидания сторон путем определения действий и услуг, которые ОКОИ обязуется оказать МСФ и наоборот, а также содержащее объяснения, каким образом ОКОИ и МСФ будут сотрудничать с целью выполнения особых приготовлений, необходимых для каждого вида спорта на Играх.

Документ, подписанный 8 августа 2008 года между МОК, ОКР и Оргкомитетом «Сочи-2014» о создании Российского международного Олимпийского университета в Сочи с целью организации профессионального Олимпийского образования, сосредоточенного на подготовке специалистов международного уровня в области спортивного менеджмента, знания которых позволят трансформировать опыт Олимпийских и Паралимпийских игр в уникальные решения для индустрии спорта.
[Департамент лингвистических услуг Оргкомитета «Сочи 2014». Глоссарий терминов]

EN

memorandum of understanding (MOU)
An agreement between the OCOG and the IF that serves as a reference tool for managing expectations by clearly defining the deliverables and services that the OCOG will provide to the IF, and vice versa, along with an explanation of how the OCOG and IF will work together to finalize the specific arrangements as required by each sport for the Games.

Document that was signed on August 8, 2008 by the IOC, the ROC and the Sochi 2014 Organizing Committee on the creation of a Russian International Olympic University in Sochi in order to found The Professional education program that will enable world-class specialists to be trained in the field of sports management. The knowledge they pick up will enable the experience gleaned from the Olympic Games to be translated into unique solutions for the sports industry and other humanities.
[Департамент лингвистических услуг Оргкомитета «Сочи 2014». Глоссарий терминов]

Тематики

• спорт (финансы и правовое обеспечение)
• спорт (церемонии и культурные программы)

EN

• memorandum of understanding (MOU)