The microstructure, tensile and impact properties of low-activation ferritic-martensitic steel EK-181 after high-temperature thermomechanical treatment

The microstructure, tensile and impact properties of low-activation ferritic-martensitic steel EK-181 after high-temperature thermomechanical treatment

In this work, we study the effect of high-temperature thermomechanical treatment (HTMT) with deformation in the austenite region on the microstructure, tensile properties, impact toughness, and fracture features of advanced low-activation 12% chromium ferritic-martensitic reactor steel EK-181. HTMT...

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Bibliographic Details
Published in:Metals Vol. 12, № 11. P. 1928 (1-20)
Other Authors: Polekhina, Nadezhda A., Linnik, Valeria V., Litovchenko, Igor Yu, Almaeva, Kseniya V., Akkuzin, Sergey A., Moskvichev, Evgeny N., Chernov, Vyacheslav M., Leontyeva-Smirnova, Mariya V., Degtyarev, Nikolay A., Moroz, Kirill A.
Format: Article
Language:English
Subjects:
микроструктура
механические свойства
вязко-хрупкий переход
температура
ударная вязкость
высокотемпературная термомеханическая обработка
расслаивание
мартенситно-ферритные стали
статьи в журналах
Online Access:http://vital.lib.tsu.ru/vital/access/manager/Repository/koha:001016202
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Summary:In this work, we study the effect of high-temperature thermomechanical treatment (HTMT) with deformation in the austenite region on the microstructure, tensile properties, impact toughness, and fracture features of advanced low-activation 12% chromium ferritic-martensitic reactor steel EK-181. HTMT more significantly modifies the steel structural-phase state than the traditional heat treatment (THT). As a result of HTMT, the hierarchically organized structure of steel is refined. The forming grains and subgrains are elongated in the rolling direction and flattened in the rolling plane (so-called pancake structure) and have a high density of dislocations pinned by stable nanosized particles of the MX type. This microstructure provides a simultaneous increase, relative to THT, in the yield strength and impact toughness of steel EK-181 and does not practically change its ductile-brittle transition temperature. The most important reasons for the increase in impact toughness are a decrease in the effective grain size of steel (martensite blocks and ferrite grains) and the appearance of a crack-arrester type delamination perpendicular to the main crack propagation direction. This causes branching of the main crack and an increase in the absorbed impact energy.
Bibliography:Библиогр.: 40 назв.
ISSN:2075-4701

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