later+investigator

следователь, ведущий повторное расследование

Law: later investigator

следователь, принявший дело к производству на последующем этапе

Law: later investigator

увидеть

(= видеть) see, observe, lay eyes on

• В главе 3 мы увидим другое обобщение той же самой основной идеи. - In Chapter 3 we shall meet another generalization of the same basic idea.

• В самом деле, позднее мы увидим, что... - As a matter of fact, we will see later that...

• В следующей главе мы увидим, что... - We shall see in the next chapter that...

• В частности, позднее мы увидим, что... - In particular, we shall see later that...

• Вскоре мы увидим, что... - We shall see shortly that...

• Далее, трудно увидеть, как... - It is difficult to see, then, how...

• Действительно, мы увидим, что... - Actually we shall see that...

• Довольно просто увидеть, что... - It is fairly easy to see that...

• Из геометрических соображений можно легко увидеть, что... - It is easily seen geometrically that...

• К сожалению, как мы увидим, данная теория не предсказывает... - Unfortunately, as we shall see, the theory does not predict...

• Как мы увидим в следующем параграфе, это не простое совпадение. - This is not a coincidence, as we will see in the next section.

• Как мы увидим дальше... - As we shall see later,...

• Как мы увидим из дальнейшего, данная теорема является основой для... - This theorem, as we shall see, is the basis of...

• Как мы увидим позднее,... - As will be seen later,...

• Можно легко увидеть причину такой зависимости. - One can easily see the reason for this dependence.

• Мы немедленно увидим, что... - It will be seen at once that...

• Мы увидим позже, что... - It will be seen later that...

• Мы увидим, что возможно (преобразовать и т. п.)... - We shall find it possible to...

• Мы увидим, что данное исследование применимо также в случае... - It will be observed that this investigation applies also to the case of...

• Мы увидим, что данные вопросы тесно взаимосвязаны. - We shall see that these questions are closely related.

• Мы увидим, что эти методы могут использоваться лишь тогда, когда... - It will be observed that these methods are only applicable when...

• Мы увидим, что эти условия могут быть выполнены при использовании... - We shall see that these conditions can be met using...

• Мы увидим, что это пример (чего-л). - We shall see that this is an example of...

• Не требуется много усилий для того, чтобы увидеть, что... - It does not require much reflection to see that...

• Однако мы увидим, что... - However, we shall discover that...

• Однако, как мы сейчас увидим, это другая ситуация. - But here the situation is different, as we shall now see.

• Оказывается, Смит [1] был первым, кто увидел, что... - It appears that Smith [1] was the first to recognize that...; Smith [1] appears to be the first to have recognized that...

• Справедливость того же результата можно увидеть геометрически. - The same result can be seen geometrically.

• Теперь мы могли бы легко увидеть, что... - Now we may easily see that...

• Трудно увидеть, как эти различия могли бы возникнуть из (чего-л). - It is difficult to see how these differences could arise from...

• Умелый исследователь быстро увидит, что... - The skilled investigator will quickly see that...

• Читатель с хорошей подготовкой немедленно увидит, что... - The knowledgeable reader will see at once that...

• Читатель увидит, как можно использовать высшую математику в... - The reader will see how ordinary calculus can be applied to...

• Чтобы доказать эту теорему, недостаточно увидеть, что... - То prove this theorem it is not enough to observe that...

• Чтобы понять это, достаточно рассмотреть... - То see this, it suffices to consider...

• Чтобы увидеть это более детально, отметим, что... - То see this in greater detail, let us note that...

Abel, John Jacob

SUBJECT AREA: Medical technology

[br]

b. 19 May 1857 near Cleveland, Ohio, USA

d. 26 May 1938 Baltimore, Maryland, USA

[br]

American pharmacologist and physiologist, proponent of the "artificial kidney" and the isolator of pure insulin.

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Born of German immigrant farming stock, his early scientific education at the University of Michigan, where he graduated PhB in 1883, suffered from a financially dictated interregnum of three years. In 1884 he moved to Leipzig and worked under Ludwig, moving to Strasbourg where he obtained his MD in 1888. In 1891 he was able to return to the University of Michigan as Lecturer in Materia Medica and Therapeutics, and in 1893 he was offered the first Chair of Pharmacology at Johns Hopkins University, a position he occupied until 1932. He was a pioneer in emphasizing the importance of chemistry, in its widest sense, in medicine and physiology. In his view, "the investigator must associate himself with those who have laboured in fields where molecules and atoms rather than multi-cellular tissues or even unicellular organisms are the units of study".

Soon after coming to Baltimore he commenced work on extracts from the adrenal medulla and in 1899 published his work on epinephrine. In later years he developed an "artificial kidney" which could be used to remove diffusible substances from the blood. In 1913 he was able to demonstrate the existence of free amino-acids in the blood and his investigations in this field foreshadowed not only the developments of blood and plasma transfusion but also the possibility of the management of renal failure.

From 1917 to 1924 he moved to a study of the hormone content of pituitary extracts, but in 1924 he suddenly transferred his attention to the study of insulin. In 1925 he announced the discovery of pure crystalline hormone. This work at first failed to gain full acceptance, but as late as 1955 the full elucidation of the protein structure of insulin proved the final culmination of his studies.

Abel's dedication to laboratory research and his disdain for matters of administration may explain the relative paucity of worldy honours awarded to such an outstanding figure.

[br]

Principal Honours and Distinctions

FRS.

Bibliography

1913, "On the removal of diffusible substances from the circulating blood by means of dialysis", Transactions of the Association of American Physiologists.

Further Reading

1939, Obituary Notices, Fellows of the Royal Society, London: Royal Society.

1946, Biographical Memoir: John Jacob Abel. 1857–1938, Washington, DC: National Academy of Sciences.

MG

Perkins, Jacob

SUBJECT AREA: Architecture and building, Paper and printing

[br]

b. 9 July 1766 Newburyport, Massachusetts, USA

d. 30 July 1849 London, England

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American inventor of a nail-making machine and a method of printing banknotes, investigator of the use of steam at very high pressures.

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Perkins's occupation was that of a gold-and silversmith; while he does not seem to have followed this after 1800, however, it gave him the skills in working metals which he would continue to employ in his inventions. He had been working in America for four years before he patented his nail-making machine in 1796. At the time there was a great shortage of nails because only hand-forged ones were available. By 1800, other people had followed his example and produced automatic nail-making machines, but in 1811 Perkins' improved machines were introduced to England by J.C. Dyer. Eventually Perkins had twenty-one American patents for a range of inventions in his name.

In 1799 Perkins invented a system of engraving steel plates for printing banknotes, which became the foundation of modern siderographic work. It discouraged forging and was adopted by many banking houses, including the Federal Government when the Second United States Bank was inaugurated in 1816. This led Perkins to move to Philadelphia. In the intervening years, Perkins had improved his nail-making machine, invented a machine for graining morocco leather in 1809, a fire-engine in 1812, a letter-lock for bank vaults and improved methods of rolling out spoons in 1813, and improved armament and equipment for naval ships from 1812 to 1815.

It was in Philadelphia that Perkins became interested in the steam engine, when he met Oliver Evans, who had pioneered the use of high-pressure steam. He became a member of the American Philosophical Society and conducted experiments on the compressibility of water before a committee of that society. Perkins claimed to have liquified air during his experiments in 1822 and, if so, was the real discoverer of the liquification of gases. In 1819 he came to England to demonstrate his forgery-proof system of printing banknotes, but the Bank of England was the only one which did not adopt his system.

While in London, Perkins began to experiment with the highest steam pressures used up to that time and in 1822 took out his first of nineteen British patents. This was followed by another in 1823 for a 10 hp (7.5 kW) engine with only 2 in. (51 mm) bore, 12 in. (305 mm) stroke but a pressure of 500 psi (35 kg/cm²), for which he claimed exceptional economy. After 1826, Perkins abandoned his drum boiler for iron tubes and steam pressures of 1,500 psi (105 kg/cm²), but the materials would not withstand such pressures or temperatures for long. It was in that same year that he patented a form of uniflow cylinder that was later taken up by L.J. Todd. One of his engines ran for five days, continuously pumping water at St Katherine's docks, but Perkins could not raise more finance to continue his experiments.

In 1823 one his high-pressure hot-water systems was installed to heat the Duke of Wellington's house at Stratfield Saye and it acquired a considerable vogue, being used by Sir John Soane, among others. In 1834 Perkins patented a compression ice-making apparatus, but it did not succeed commercially because ice was imported more cheaply from Norway as ballast for sailing ships. Perkins was often dubbed "the American inventor" because his inquisitive personality allied to his inventive ingenuity enabled him to solve so many mechanical challenges.

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Further Reading

Historical Society of Pennsylvania, 1943, biography which appeared previously as a shortened version in the Transactions of the Newcomen Society 24.

D.Bathe and G.Bathe, 1943–5, "The contribution of Jacob Perkins to science and engineering", Transactions of the Newcomen Society 24.

D.S.L.Cardwell, 1971, From Watt to Clausius. The Rise of Thermodynamics in the Early Industrial Age, London: Heinemann (includes comments on the importance of Perkins's steam engine).

A.F.Dufton, 1940–1, "Early application of engineering to warming of buildings", Transactions of the Newcomen Society 21 (includes a note on Perkins's application of a high-pressure hot-water heating system).

RLH

Wöhler, August

SUBJECT AREA: Metallurgy

[br]

b. 22 June 1819 Soltau, Germany

d. 21 June 1914 Hannover, Germany

[br]

German railway engineer who first established the fatigue fracture of metals.

[br]

Wöhler, the son of a schoolteacher, was born at Soltau on the Luneburg Heath and received his early education at his father's school, where his mathematical abilities soon became apparent. He completed his studies at the Technical High School, Hannover.

In 1840 he obtained a position at the Borsig Engineering Works in Berlin and acquired there much valuable experience in railway technology. He trained as an engine driver in Belgium and in 1843 was appointed as an engineer to the first Hannoverian Railway, then being constructed between Hannover and Lehrte. In 1847 he became Chief Superintendent of rolling stock on the Lower Silesian-Brandenhurg Railway, where his technical abilities influenced the Prussian Minister of Commerce to appoint him to a commission set up to investigate the reasons for the unusually high incidence of axle failures then being encountered on the railways. This was in 1852, and by 1854, when the Brandenburg line had been nationalized, Wöhler had already embarked on the long, systematic programme of mechanical testing which eventually provided him with a clear insight into the process of what is now referred to as "fatigue failure". He concentrated initially on the behaviour of machined iron and steel specimens subjected to fluctuating direct, bending and torsional stresses that were imposed by testing machines of his own design.

Although Wöhler was not the first investigator in this area, he was the first to recognize the state of "fatigue" induced in metals by the repeated application of cycles of stress at levels well below those that would cause immediate failure. His method of plotting the fatigue stress amplitude "S" against the number of stress cycles necessary to cause failure "N" yielded the well-known S-N curve which described very precisely the susceptibility to fatigue failure of the material concerned. Engineers were thus provided with an invaluable testing technique that is still widely used in the 1990s.

Between 1851 and 1898 Wöhler published forty-two papers in German technical journals, although the importance of his work was not initially fully appreciated in other countries. A display of some of his fracture fatigue specimens at the Paris Exposition in 1867, however, stimulated a short review of his work in Engineering in London. Four years later, in 1871, Engineering published a series of nine articles which described Wöhler's findings in considerable detail and brought them to the attention of engineers. Wöhler became a member of the newly created management board of the Imperial German Railways in 1874, an appointment that he retained until 1889. He is also remembered for his derivation in 1855 of a formula for calculating the deflections under load of lattice girders, plate girders, and other continuous beams resting on more than two supports. This "Three Moments" theorem appeared two years before Clapeyron independently advanced the same expression. Wöhler's other major contribution to bridge design was to use rollers at one end to allow for thermal expansion and contraction.

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Bibliography

1855, "Theorie rechteckiger eiserner Brückenbalken", Zeitschrift für Bauwesen 5:122–66. 1870, "Über die Festigkeitversuche mit Eisen und Stahl", Zeitschrift für Bauwesen 20:73– 106.

Wöhler's experiments on the fatigue of metals were reported in Engineering (1867) 2:160; (1871) 11:199–200, 222, 243–4, 261, 299–300, 326–7, 349–50, 397, 439–41.

Further Reading

R.Blaum, 1918, "August Wöhler", Beiträge zur Geschichte der Technik und Industrie 8:35–55.

——1925, "August Wöhler", Deutsches biographisches Jahrbuch, Vol. I, Stuttgart, pp. 103–7.

K.Pearson, 1890, "On Wöhler's experiments on alternating stress", Messeng. Math.

20:21–37.

J.Gilchrist, 1900, "On Wöhler's Laws", Engineer 90:203–4.

ASD