Improving toughness of medium-Mn steels after friction stir welding through grain morphology tuning  被引量：1

作　　者：Mun Sik Jeong Tak Min Park Dong-Il Kim Hidetoshi Fujii Hye Ji Im Pyuck-Pa Choi Seung-Joon Lee Jeongho Han 

机构地区：[1]Division of Materials Science and Engineering,Hanyang University,Seoul 04763,Republic of Korea [2]Department of Advanced Materials Engineering,Korea Polytechnic University,Siheung 15073,Republic of Korea [3]Joining and Welding Research Institute,Osaka University,Osaka 567-0047,Japan [4]Department of Materials Science and Engineering,Korea Advanced Institute of Science and Technology,Daejeon 34141,Republic of Korea [5]Department of Materials Science and Engineering,Northwestern University,Evanston,IL 60208,USA

出　　处：《Journal of Materials Science & Technology》2022年第23期243-254,共12页材料科学技术（英文版）

基　　金：supported by the National Research Foundation of Korea(NRF)(No.2020R1F1A1070808);supported by the Korea Institute for Advancement of Technology(KIAT)grant funded by the Korea Government(MOTIE)(P0008425,The Competency Development Program for Industry Specialist)。

摘　　要：This work demonstrated the viability of friction stir welding for the welding of medium-Mn steels when used as cryogenic vessel materials for liquefied gas storage.We used an intercritically annealed Fe-7 Mn-0.2 C-3 Al(wt.%)steel with a dual-phase(α'martensite andγ_(R) retained austenite)nanolaminate structure as a base material and systematically compared its microstructure and impact toughness after friction stir and tungsten inert gas welding.The friction stir welded specimen exhibited a large amount ofγ_(R) phase owing to a relatively low temperature during welding,whereas the tungsten inert gas welded specimen comprised only theα'phase.Furthermore,the friction stir welded steel exhibited a tuned morphology of nanoscale globular microstructure at the weld zone and did not exhibit any prior austenite grain boundary due to active recrystallization caused by deformation during welding.The preserved fraction ofγ_(R) and morphological tuning in the weldment improved the impact toughness of the friction stir welded steel at low temperatures.In the steel processed by tungsten inert gas welding,the notch crack propagated rapidly along the prior austenite grain boundaries-weakened by Mn and P segregations-resulting in poor impact toughness.However,the friction stir welded steel exhibited a higher resistance against notch crack propagation due to the slow crack propagation along the ultrafine ferrite/ferrite(α/α)interfaces,damage tolerance by the active transformation-induced plasticity from the large amount ofγR,and enhanced boundary cohesion by suppressed Mn and P segregations.

关 键 词：Charpy impact test Transformation-induced plasticity Friction stir welding Phase stability Medium-Mn steel 

分 类 号：TG453.9[金属学及工艺—焊接]