Fracture mechanisms of low activation 12% chromium ferritic-martensitic steel EK-181 in the temperature range from -196 to 800 ºC | Izvestiya vuzov. Fizika. 2021. № 8. DOI: 10.17223/00213411/64/8/82

Fracture mechanisms of low activation 12% chromium ferritic-martensitic steel EK-181 in the temperature range from -196 to 800 ºC

A comparative study of the fracture features of promising low-activation 12% chromium ferritic-martensitic steel EK-181 after uniaxial tensile tests in the temperature range from -196 to 800 °C in states after traditional heat treatment (THT) and high-temperature thermomechanical treatment (HTMT) has been carried out. It is shown that the features of steel fracture are weakly dependent on the treatment mode and are determined by the temperature dependence of its yield stress. In the range from -196 to 20 ºС, there are differences in the orientation of secondary microcracks depending on the treatment mode - after HTMT they are mainly parallel to the rolling plane, after THT their direction is more chaotic. At Т ≥ 300 ºС, the differences in the type of steel fracture after the investigated treatments practically disappear. When the temperature decreases from 20 to -80 ºС, the fracture mechanism of steel after both treatments changes from mixed (by the mechanisms of transcrystalline dimple fracture and transcrystallite quasi-cleavage) to brittle fracture with quasi-cleavage. At the same time, some elements of brittle intercrystalline fracture have been found, the fraction of which increases with decreasing temperature from 20 to -196 ºС. In the region of positive temperatures from 350 to 800 ºС, destruction occurs by the mechanism of ductile transcrystalline dimple fracture.

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Keywords

ferritic-martensitic steel, low-activation steel, fracture mechanism, fractography, high-temperature thermomechanical treatment

Authors

Name	Organization	E-mail
Polekhina N.A.	Institute of Strength Physics and Materials Science Siberian Branch Russian Academy of Science	nadejda89tsk@yandex.ru
Litovchenko I.Yu.	Institute of Strength Physics and Materials Science Siberian Branch Russian Academy of Science	litovchenko@spti.tsu.ru
Almaeva K.V.	Institute of Strength Physics and Materials Science Siberian Branch Russian Academy of Science	kseni_ya_almaeva@mail.ru
Tyumentsev A.N.	Institute of Strength Physics and Materials Science Siberian Branch Russian Academy of Science	tyuments@phys.tsu.ru
Pinzhin Yu.P.	Institute of Strength Physics and Materials Science Siberian Branch Russian Academy of Science	pinzhin@phys.tsu.ru
Chernov V.M.	Bochvar High-Technology Research Institute of Inorganic Materials	vmchernov@bochvar.ru
Leotyeva-Smirnova M.V.	Bochvar High-Technology Research Institute of Inorganic Materials	mvleonteva-smirnova@bochvar.ru

Всего: 7

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