Development of RAFM steel for nuclear applications with reduced manganese, silicon and carbon content

Development of RAFM steel for nuclear applications with reduced manganese, silicon and carbon content

•Alternative route for fabrication of RAFM steels with reduced C and Mn content is explored.•Tailored heat treatment reduces DBTT to −133 °C while preserving mechanical strength.•Quench & rolling procedure did not lead to any noticeable reduction of the DBTT. In this work, we investigate an alte...

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Bibliographic Details
Published in:Nuclear materials and energy Vol. 29; p. 101070
Main Authors: Terentyev, D., Puype, A., Kachko, O., Van Renterghem, W., Henry, J.
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-12-2021
Elsevier
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Summary:•Alternative route for fabrication of RAFM steels with reduced C and Mn content is explored.•Tailored heat treatment reduces DBTT to −133 °C while preserving mechanical strength.•Quench & rolling procedure did not lead to any noticeable reduction of the DBTT. In this work, we investigate an alternative route for the production of reduced activation ferritic-martensitic (RAFM) steels with reduced contents of manganese and carbon. Alternation of the chemical composition coupled with various heat treatments as well as quench & rolling procedures are applied in an attempt to reduce the DBTT without altering the nominal strength and ductility. The obtained experimental results on the mechanical properties and microstructural analysis are compared to the reference European RAFM steel i.e. Eurofer97. It is demonstrated that an alternation of the conventional heat treatment of the newly developed low Mn/C steel allows the production of a material with a ductile to brittle transition temperature as low as −133 °C and strength comparable to that of Eurofer97. On the other hand, the performed quench & rolling procedure does not lead to any noticeable reduction of the DBTT, albeit it significantly increases the tensile strength without compromising the ductility in the relevant operational temperature range.
ISSN:2352-1791
2352-1791
DOI:10.1016/j.nme.2021.101070