Microstructure and mechanical properties of similar and dissimilar joints of RAFM and 316L by electron beam welding

•The electron beam deflects towards RAFM steel in the dissimilar welding joint of RAFM/316L.•The WM of RAFM/316L electron beam weld consists of lath martensite and a small amount of ferrite.•The WM of RAFM/RAFM electron beam weld consists of coarse lath martensite and coarse ferrite.•The HAZ of RAFM...

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Bibliographic Details
Published in:Fusion engineering and design 2021-01, Vol.162, p.112130, Article 112130
Main Authors: Fan, Xiaosong, Shen, Xu, Zhang, Yong, Liu, Zhihong, Wu, Jiefeng, Liu, Zhenfei, Ma, Jianguo
Format: Article
Language:English
Subjects:
Deflection
Dissimilar materials
Electron beam welding
Ferrites
Ferritic stainless steels
Heat affected zone
Heat treating
High energy electrons
Impact strength
Martensite
Martensitic stainless steels
Mechanical properties
Microstructure
Quenching
RAFM
Tensile strength
Vessels
Weld metal
Welded joints
Welding parameters
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Summary:•The electron beam deflects towards RAFM steel in the dissimilar welding joint of RAFM/316L.•The WM of RAFM/316L electron beam weld consists of lath martensite and a small amount of ferrite.•The WM of RAFM/RAFM electron beam weld consists of coarse lath martensite and coarse ferrite.•The HAZ of RAFM can be divided into fusion zone, completely quenched zone, and incompletely quenched zone. 316L is a structural material used in fusion reactor vacuum vessels (VVs), in-vessel component supports, and cooling pipes, while reduced-activation ferritic/martensitic (RAFM) steel is the structural material used in test blanket modules (TBMs). High-energy electron beam welding is a suitable method for welding RAFM/316L joints. To explore the electron beam welding process of RAFM/316L, 150 kV/39 mA are chosen as the welding parameters to connect the dissimilar materials, and the microstructure and mechanical properties of the joint are tested and analyzed after welding. The results demonstrate a magnetic deflection of the 316L/RAFM welding joint due to phase change. Thus, an electron beam shift is made to compensate for this deflection. Microstructural observations indicate that the weld metal (WM) of RAFM/316L comprises lath martensite and a small amount of ferrite. The RAFM heat-affected zone (HAZ) of RAFM/316L can be divided into three regions: a fusion zone comprising coarse ferrite and martensite, a completely quenched zone comprising quenched martensite, and an incompletely quenched zone comprising eutectic ferrite and quenched martensite. Mechanical property test results indicate that the WM of RAFM/316L is better than the 316L base material and WM of 316L/316L in terms of tensile strength, and the top of the RAFM/316L joint is comparable to, but with a weaker bottom, than that of the 316L and RAFM base materials in terms of impact toughness.
ISSN:0920-3796
1873-7196
DOI:10.1016/j.fusengdes.2020.112130