physical+metallurgy

physical metallurgy

• металловедение n

metallurgy

1. металлургия

2. металловедение

adaptive metallurgy — металловедение

aerospace powder metallurgy — порошковая металлургия для авиационно-космической техники, авиационно-космическая порошковая металлургия

composite-powder metallurgy — композиционная порошковая металлургия

dry metallurgy — пирометаллургия

ferrous metallurgy — чёрная металлургия, металлургия чёрных металлов

fiber metallurgy — волоконная [волокнистая] металлургия

fibrous metallurgy — волокнистая [волоконная] металлургия

filamentary metallurgy — волокнистая [волоконная] металлургия

non-ferrous metallurgy — цветная металлургия, металлургия цветных металлов

physical metallurgy — физическое металловедение, физика металлургии

powder metallurgy — порошковая металлургия

process metallurgy — технология металлов

production metallurgy — технология металлов

vacuum metallurgy — вакуумная металлургия

metallurgy

1) металлургия

2) металловедение

•

-
adaptive metallurgy
-
extractive metallurgy
-
ferrous metallurgy
-
fiber metallurgy
-
nonferrous metallurgy
-
physical metallurgy
-
powder metallurgy
-
process metallurgy
-
vacuum metallurgy
-
welding metallurgy

metallurgy

металлургия

– ferrous metallurgy
– metallurgy industry
– non-ferrous metallurgy
– physical metallurgy
– powder metallurgy
– vacuum metallurgy
– welding metallurgy

physical

1) физический

2) телесный
3) материальный
– physical & engineering
– physical atmosphere
– physical circuit
– physical design
– physical libration
– physical magnitudes
– physical metallurgy
– physical model
– physical modelling
– physical optics
– physical pendulum
– physical property
– physical quantity
– physical state
– physical testing
– physical unit

physical beryllium reactor — <engin.> реактор бериллиевый физический

metallurgy

1) металлургия

2) металловедение

•

- adaptive metallurgy

- physical metallurgy
- powder metallurgy
- vacuum metallurgy

metallurgy

1) металлургия

2) металловедение

•

- adaptive metallurgy

- physical metallurgy
- powder metallurgy
- vacuum metallurgy

metallurgy

[ʹmetəlɜ:dʒı] n

металлургия

metallurgy of ferrous [non-ferrous] metals - чёрная [цветная] металлургия

physical metallurgy - физическое металловедение

powder metallurgy - порошковая металлургия

physical vapor deposition-конденсация из паровой фазы

Metallurgy: PVD

metallurgy

meˈtælədʒɪ сущ. металлургия металлургия - * of ferrous metals черная металлургия - physical * физическое металловедение - powder * порошковая металлургия metallurgy металлургия

adaptive metallurgy

металловедение

physical metallurgy — металловедение

fizička metalurgija

• physical metallurgy

fizička metalurgija

• physical metallurgy

физическая металлургия

physical metallurgy

металловедение

physical metallurgy

металловедение

physical metallurgy

* * *

metallurgical science

* * *

physical metallurgy

металловедение

1. physical metallurgy

 

металловедение
Наука о строении и св-вах металлов и сплавов. Осн. задачи м.: создание сплавов с зад. комплексом св-в; установл. закономерностей формиров. структуры и св-в изделий при их отливке, обработке давлением, термообработке и др. способах обработки; установл. закономерностей изменений структуры и св-в металлич. материалов при эксплуатации изделий. Главное в м. — учение о связи практич. важных св-в металлич. материалов с их химич. составом и строением (структурой). Становление м. как науки произошло во 2-й половине XIX в. Начальник златоуст. оруж. з-дов П. П. Аносов, работая над раскрытием тайны булатных клинков, в 1831 г. впервые в истории металлургии применил микроскоп для изучения строения стали. Англ. петрограф Г. Сорби использовал в 1864 г. микроскоп для изуч. строения железных метеоритов. Эти работы положили начало микроструктур. анализу металлов. Великий рус. металлург Д. К. Чернов (1839—1921 гг.) открыл в 1868 г. критич. точки (темп-ры превр.) в стали и связал с ними выбор режима термообработки для получения необх. структуры и св-в. Это открытие оказало определяющее влияние на последующее становление и развитие науки о металлах. Франц. инженер Ф. Осмонд применил изобрет. Ле-Шателье Pt|Rh-Pt термопару для установления критич. точек Чернова в сталях методом термич. анализа (по появл. тепл. эффектов превр.) и использовал изобрет. Ле-Шателье специализир. метал. микроскоп для выявл. в отраж. свете структурных составляющих в сталях. К 90-м гг. XIX в. закончился подготовит. период в развитии металловедения. В 1892 г. Ф. Осмонд предложил называть новую науку, описывающую строение металлов и сплавов, металлографией. Последние годы XIX в. и первые два 10-летия XX в. явл. периодом классич. металлографии, гл. методами к-рой были микроструктурный и термич. анализы. С 1920-х гг., все шире использ. рентгеноструктурный анализ для изучения ат.-кристаллич. строения металлов и разнообр. фаз в металлич. сплавах, а тж. механизма структур. измен. в металлич. материалах при разного вида обработках. К началу 30-х г.г. содержание науки о металлах вышло за рамки классич. металлографии и получило распростр. более емкое ее название — металловедение. В послед, годы в м. все шире используются представления физики тв. тела и физич. методы исследования. С 1950-х гг. широко применяется эл-ная микроскопия, к-рая позволяет более глубоко изучить структуру металлич. материалов. Для соврем. м. хар-но шир. использ. учения о дефектах кристаллич. решетки. М-ду теоретич. м. и физикой металлов нет четкой границы. В теоретич. м. рассматр. диаграммы сост., структура фаз в металлич. сплавах (тв. р-рах, интерметаллидах и др.), механизм и кинетика кристаллизации расплава и фаз. превращ. в тв. состоянии, изменение структуры и св-в металлов при пластич. деформации, общие закономерности влияния химич. состава и структуры на механич. и др. св-ва.
Приклад. (технич.) м. изуч. состав, структуры, процессы обработки и св-ва металлич. материалов конкретных классов (напр., Fe-С-сплавов, конструкц., нерж. сталей, жаропрочных, Аl-, Сu- сплавов, металлокерамики и др.). В связи с развитием новых областей техники возникли задачи изучения поведения металлов и сплавов при радиац. воздействиях, весьма низких темп-pax, высоких давлениях и т.д.
[ http://metaltrade.ru/abc/a.htm]

Тематики

• металлургия в целом

EN

• physical metallurgy

Rosenhain, Walter

SUBJECT AREA: Metallurgy

[br]

b. 24 August 1875 Berlin, Germany

d. 17 March 1934 Kingston Hill, Surrey, England

[br]

German metallurgist, first Superintendent of the Department of Metallurgy and Metallurgical Chemistry at the National Physical Laboratory, Teddington, Middlesex.

[br]

His family emigrated to Australia when he was 5 years old. He was educated at Wesley College, Melbourne, and attended Queen's College, University of Melbourne, graduating in physics and engineering in 1897. As an 1851 Exhibitioner he then spent three years at St John's College, Cambridge, under Sir Alfred Ewing, where he studied the microstructure of deformed metal crystals and abandoned his original intention of becoming a civil engineer. Rosenhain was the first to observe the slip-bands in metal crystals, and in the Bakerian Lecture delivered jointly by Ewing and Rosenhain to the Royal Society in 1899 it was shown that metals deformed plastically by a mechanism involving shear slip along individual crystal planes. From this conception modern ideas on the plasticity and recrystallization of metals rapidly developed. On leaving Cambridge, Rosenhain joined the Birmingham firm of Chance Brothers, where he worked for six years on optical glass and lighthouse-lens systems. A book, Glass Manufacture, written in 1908, derives from this period, during which he continued his metallurgical researches in the evenings in his home laboratory and published several papers on his work.

In 1906 Rosenhain was appointed Head of the Metallurgical Department of the National Physical Laboratory (NPL), and in 1908 he became the first Superintendent of the new Department of Metallurgy and Metallurgical Chemistry. Many of the techniques he introduced at Teddington were described in his Introduction to Physical Metallurgy, published in 1914. At the outbreak of the First World War, Rosenhain was asked to undertake work in his department on the manufacture of optical glass. This soon made it possible to manufacture optical glass of high quality on an industrial scale in Britain. Much valuable work on refractory materials stemmed from this venture. Rosenhain's early years at the NPL were, however, inseparably linked with his work on light alloys, which between 1912 and the end of the war involved virtually all of the metallurgical staff of the laboratory. The most important end product was the well-known "Y" Alloy (4% copper, 2% nickel and 1.5% magnesium) extensively used for the pistons and cylinder heads of aircraft engines. It was the prototype of the RR series of alloys jointly developed by Rolls Royce and High Duty Alloys. An improved zinc-based die-casting alloy devised by Rosenhain was also used during the war on a large scale for the production of shell fuses.

After the First World War, much attention was devoted to beryllium, which because of its strength, lightness, and stiffness would, it was hoped, become the airframe material of the future. It remained, however, too brittle for practical use. Other investigations dealt with impurities in copper, gases in aluminium alloys, dental alloys, and the constitution of alloys. During this period, Rosenhain's laboratory became internationally known as a centre of excellence for the determination of accurate equilibrium diagrams.

[br]

Principal Honours and Distinctions

FRS 1913. President, Institute of Metals 1828–30. Iron and Steel Institute Bessemer Medal, Carnegie Medal.

Bibliography

1908, Glass Manufacture.

1914, An Introduction to the Study of Physical Metallurgy, London: Constable. Rosenhain published over 100 research papers.

Further Reading

J.L.Haughton, 1934, "The work of Walter Rosenhain", Journal of the Institute of Metals 55(2):17–32.

ASD

металловедение

adaptive metallurgy, physical metallurgy, metallurgy

* * *

металлове́дение с.
physical metallurgy, metal science

* * *

metal science

Charpy, Augustin Georges Albert

SUBJECT AREA: Metallurgy

[br]

b. 1 September 1865 Ouillins, Rhône, France

d. 25 November 1945 Paris, France

[br]

French metallurgist, originator of the Charpy pendulum impact method of testing metals.

[br]

After graduating in chemistry from the Ecole Polytechnique in 1887, Charpy continued to work there on the physical chemistry of solutions for his doctorate. He joined the Laboratoire d'Artillerie de la Marine in 1892 and began to study the structure and mechanical properties of various steels in relation to their previous heat treatment. His first memoir, on the mechanical properties of steels quenched from various temperatures, was published in 1892 on the advice of Henri Le Chatelier. He joined the Compagnie de Chatillon Commentry Fourchamboult et Decazeville at their steelworks in Imphy in 1898, shortly after the discovery of Invar by G.E. Guillaume. Most of the alloys required for this investigation had been prepared at Imphy, and their laboratories were therefore well equipped with sensitive and refined dilatometric facilities. Charpy and his colleague L.Grenet utilized this technique in many of their earlier investigations, which were largely concerned with the transformation points of steel. He began to study the magnetic characteristics of silicon steels in 1902, shortly after their use as transformer laminations had first been proposed by Hadfield and his colleagues in 1900. Charpy was the first to show that the magnetic hysteresis of these alloys decreased rapidly as their grain size increased.

The first details of Charpy's pendulum impact testing machine were published in 1901, about two years before Izod read his paper to the British Association. As with Izod's machine, the energy of fracture was measured by the retardation of the pendulum. Charpy's test pieces, however, unlike those of Izod, were in the form of centrally notched beams, freely supported at each end against rigid anvils. This arrangement, it was believed, transmitted less energy to the frame of the machine and allowed the energy of fracture to be more accurately measured. In practice, however, the blow of the pendulum in the Charpy test caused visible distortion in the specimen as a whole. Both tests were still widely used in the 1990s.

In 1920 Charpy left Imphy to become Director-General of the Compagnie des Aciéries de la Marine et Homecourt. After his election to the Académie des Sciences in 1918, he came to be associated with Floris Osmond and Henri Le Chatelier as one of the founders of the "French School of Physical Metallurgy". Around the turn of the century he had contributed much to the development of the metallurgical microscope and had helped to introduce the Chatelier thermocouple into the laboratory and to industry. He also popularized the use of platinum-wound resistance furnaces for laboratory purposes. After 1920 his industrial responsibilities increased greatly, although he continued to devote much of his time to teaching at the Ecole Supérieure des Mines in Paris, and at the Ecole Polytechnique. His first book, Leçons de Chimie (1892, Paris), was written at the beginning of his career, in association with H.Gautier. His last, Notions élémentaires de sidérurgie (1946, Paris), with P.Pingault as co-author, was published posthumously.

[br]

Bibliography

Charpy published important metallurgical papers in Comptes rendus… Académie des Sciences, Paris.

Further Reading

R.Barthélémy, 1947, "Notice sur la vie et l'oeuvre de Georges Charpy", Notices et discours, Académie des Sciences, Paris (June).

M.Caullery, 1945, "Annonce du décès de M.G. Charpy" Comptes rendus Académie des Sciences, Paris 221:677.

P.G.Bastien, 1963, "Microscopic metallurgy in France prior to 1920", Sorby Centennial Symposium on the History of Metallurgy, AIME Metallurgical Society Conference Vol.27, pp. 171–88.

ASD