material being machined

material being machined

Автоматика: материал, обрабатываемый на ( металлорежущем) станке

the material being machined

Математика: обрабатываемый материал

material

материал; вещество || материальный; вещественный

material being cut — материал, обрабатываемый резанием; разрезаемый материал

material being fed — подаваемый материал, продвигаемый материал

material being machined — материал, обрабатываемый на станке, материал, обрабатываемый на металлорежущем станке

material to be routed — материал, обрабатываемый на быстроходном фасонно-фрезерном станке

- abraded workpiece material

- abrasive material
- absorbing material
- absorption material
- acidproof material
- acid-resisting material
- activated material
- active material
- add material
- adding material
- adhering molding material
- alloy materials
- alloying material
- alternate material
- antifriction material
- antislip material
- architectural material
- as-received material
- audiovisual material
- auxiliary material
- backing material
- bad material
- balled material
- base material
- basic material
- bead material
- bearing material
- best quality materials
- binder material
- binding material
- bonding material
- brazing material
- brittle material
- building material
- bulk material
- burden material
- carbide material
- carbon electric material
- carbon electrical material
- carbonaceous reducing material
- carburizing material
- casthouse materials
- categorized material
- ceramic material
- certified reference material
- charge material
- charging material
- clad material
- cleansing material
- coating material
- coiled material
- cold-charged material
- cold-worked material
- combustible material
- commercial material
- composite material
- composite metallic material
- composition material
- compound material
- conducting material
- contact conductor material
- container material
- controlled-porosity material
- core material
- corrosion-resisting material
- creep strained material
- critical material
- crucible material
- cushioning material
- cutting material
- cutting-tool material
- cycled material
- damping material
- deep-coat material
- defective material
- defense material
- depleated material
- diamagnetic material
- difficult-to-cut material
- difficult-to-machine material
- dispersion-hardened material
- dispersion-strengthened material
- dissimilar materials
- dissipative material
- document material
- dolomite-based material
- ductile material
- easy-to-cut material
- elastomeric material
- electric contact material
- electrical engineering material
- electrically active polymeric material
- electrically insulating material
- electrode material
- electrotechnical material
- elongated material
- emitting material
- engineering materials
- enriched material
- environmentally resilient material
- epoxy matrix material
- excessive uncut material
- extraneous material
- extreme pressure material
- facing material
- feed material
- ferrimagnetic material
- ferroelectric material
- ferromagnetic material
- ferrous materials
- fettling material
- fiber material
- fiber-reinforced material
- fiber-strengthened material
- fibrous composite material
- fibrous material
- filling material
- fine material
- flexible-heavy material
- fluid-extruded material
- fluorescent material
- fluxing material
- foreign material
- free-cutting material
- free-machining material
- friction material
- fuel material
- fully dense material
- fully fired material
- fully flattened material
- grain material
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- grinding material
- half-finished material
- hard material
- hard-magnetic material
- hard-to-cut material
- hard-to-machine material
- hard-to-punch material
- heat-absorbing material
- heat-conductive material
- heat-insulating material
- heat-resistant material
- heat-sensitive material
- heat-transfer material
- heavily alloyed material
- heavy material
- heavy-duty material
- heavy-gravity material
- high-coercivity material
- high-conductivity material
- high-force material
- high-friction material
- high-melting-point material
- high-resistivity material
- high-strength material
- high-technology materials
- high-temperature-resistant material
- high-tempering temperature material
- high-tensile strength material
- honest material
- host material
- hot-finished material
- hyperconductor material
- ideally plastic material
- imperfect material
- incombustible material
- incoming materials
- incompressible material
- inert material
- inflammable material
- ingoing material
- in-process material
- instructional material
- insulating material
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- intermediate material
- iron-bearing material
- isotropic material
- jointing material
- lagging material
- laser material
- light material
- light-duty material
- light-stiff material
- limy material
- lining material
- loading material
- loose material
- low-ash reducing material
- low-coercivity material
- low-density material
- low-expansion material
- low-grade material
- low-strength material
- low-temperature material
- low-tensile strength material
- luminescent material
- lump material
- magnetic material
- magnetostrictive material
- material of construction
- material of high-absorbing power
- material of high-electric conductivity
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- material of low-machinability rating
- matrix material
- medium-strength material
- mix material
- moderator material
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- multilayer bearing material
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- multimedia materials
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- nonconducting material
- noncrystalline material
- nonferromagnetic material
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- off-gage material
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- original material
- oversized material
- oxidizing material
- packing material
- paint material
- paramagnetic material
- parent material
- particulate material
- perfect material
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- plastic material
- plus material
- PM material
- polycrystalline material
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- poor heat conducting material
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- pore-forming material
- positive active material
- powder material
- powder metallurgical material
- powdered material
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- prehardened material
- prepared burden materials
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- problem material
- radioactive material
- random material
- raw material
- recycled material
- reducing material
- reference material
- refractory backing material
- refractory conductor material
- refractory material
- refused material
- reinforced material
- rejected material
- remove material
- resistive material
- return material
- rework material
- roll-compacted powder material
- rolled sheet material
- rolling material
- rust-inhibiting material
- saleable material
- sandwiched material
- sandwich-type material
- scattering material
- scrap material
- sealant material
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- secondary raw materials
- section material
- semiconducting material
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- semifinished material
- semimanufactured material
- sheet material
- sheet-like material
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- shipbuilding material
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- siliceous material
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- sintered bearing material
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- slag-forming material
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- sorted secondary raw materials
- sound-absorbing material
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- spent material
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- standard cubic material
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- starting material
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- stopping material
- strain-hardened material
- strain-rate-resistive material
- strong material
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- superconducting material
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- test material
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- tracer material
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- waste material
- wearable material
- web material
- weighing material
- weld material
- welding wire material
- work material
- work-hardening material
- worthless material
- xerographic materials

обрабатываемый материал

1) Engineering: process material, work material

2) Mathematics: the material being machined

3) Mechanics: worked stock

4) Automation: work stock

материал, обрабатываемый на (металлорежущем) станке

Automation: material being machined

материал, обрабатываемый на станке

Automation: (металлорежущем) material being machined

обрабатываемый материал

•

Speeds of working vary according to the material being worked (or machined).

Wöhler, August

SUBJECT AREA: Metallurgy

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b. 22 June 1819 Soltau, Germany

d. 21 June 1914 Hannover, Germany

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

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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