Microstructure features and formation mechanism in a newly developed electroslag welding

被引：1

作者：

Kakizaki, Tomonori ^{[1
]}

Koga, Shodai ^{[2
]}

Yamamoto, Hajime ^{[2
]}

Mikami, Yoshiki ^{[2
]}

Ito, Kazuhiro ^{[2
]}

Yamazaki, Kei ^{[1
]}

Sasakura, Shuji ^{[1
]}

Watanabe, Hirohisa ^{[1
]}

机构：

[1] Kobe Steel Ltd, Tech Ctr, Welding Proc Dept, Welding Business, 100-1 Miyamae, Fujisawa, Kanagawa 2518551, Japan

[2] Osaka Univ, Joining & Welding Res Inst, 11-1 Mihogaoka, Ibaraki, Osaka 5670047, Japan

来源：

WELDING IN THE WORLD | 2022年 / 66卷 / 02期

关键词：

Electroslag welding; Weld metal toughness; Acicular ferrite; Cooling speed; Effective heat input; Finite element method; ACICULAR FERRITE; HETEROGENEOUS NUCLEATION; STEEL; INCLUSION;

D O I：

10.1007/s40194-021-01215-y

中图分类号：

TF [冶金工业];

学科分类号：

0806 ;

摘要：

Electroslag welding (ESW) is known to show higher heat input than electrogas welding (EGW), resulting in poor low-temperature toughness. However, a newly developed ESW (dev. ESW) method using low-resistivity slag bath exhibited excellent low-temperature toughness as a result of lower effective heat input than conventional EGW, as demonstrated by the faster cooling rates measured in weld metals and estimated using finite element method analyses. This led to much shallower molten pool in the dev. ESW, resulting in much finer columnar grains and thinner centerline axial grains. High cooling speed in the dev. ESW method appeared to contribute to increased acicular ferrite proportion. The uniform microstructure with large acicular ferrite proportion and small number of inclusions in the weld metal permitted the dev. ESW weld metal to possess little variation in Charpy impact energy across the center of weld metal.

引用

页码：313 / 324

页数：12

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