304&Q235异种钢TIG焊接接头组织及力学性能研究
Study on Microstructure and Mechanical Properties of TIG Welded Joint of Dissimilar Steel 304&Q235
- 2022年52卷第1期 页码:54-62
DOI: 10.7512/j.issn.1001-2303.2022.01.07
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徐育烺,钱鹏,李敬勇,等.304&Q235异种钢TIG焊接接头组织及力学性能研究[J].电焊机,2022,52(01):54-62.
XU Y L, QIAN P, LI J Y, et al.Study on microstructure and mechanical properties of TIG welded joint of dissimilar steel 304&Q235[J].Electric Welding Machine, 2022, 52(01): 54-62.
为了充分发挥材料各自的优势,异种钢材料的组合应用应运而生。本文采用TIG焊对Q235普通碳钢和304奥氏体不锈钢进行异种钢焊接试验,并采用控制变量的方法优化焊接工艺,获取符合工程实践要求的焊接接头。结合金相显微镜以及扫描电镜对焊接接头各区域微观组织演变过程进行观察,采用X射线衍射仪对焊缝进行物相分析,利用万能拉伸试验机和显微硬度计分别对焊接试样进行了拉伸性能测试及显微硬度测试。结果表明,焊缝区域微观组织由板条马氏体组成;在Q235碳钢界面明显发生了碳迁移现象;在焊接接头完全熔透的条件下,拉伸断裂位置发生在母材Q235碳钢一侧,说明焊接接头强度高于母材,断口呈现韧性断裂特征;焊接接头各区域显微硬度分布规律为:焊缝>304侧热影响区>304母材>Q235侧热影响区>Q235母材。
In order to give full play to their respective advantages, the combined application of dissimilar steel materials came into being, in this study, the dissimilar steel welding experiments of Q235 carbon steel and 304 austenitic stainless steel were carried out by TIG welding, and the welding process was optimized by controlling variables to obtain the qualified welding joints. The microstructure evolution of the welded joint was observed by metallographic microscope and scanning electron microscope and the analysis of phases in the weld seam were tested by X-ray diffractometer. The tensile properties and microhardness of the welded specimens were tested by universal tensile testing machine and microhardness tester respectively. The results show that the weld zone is composed of lath martensite; Carbon migration occurs obviously at Q235 interface, decarburization layer appears on one side of Q235 and carburization layer appears on one side of weld; The microstructure of 304 side fusion zone is fine and discontinuous vermicular ferrite distributed in austenite matrix. When the welded joint is fully penetrated, the tensile fracture occurs on the side of Q235 steel, which indicates that the strength of the welded joint is higher than that of the base metal, and presenting ductile fracture; The distribution rule of microhardness in each area of welded joint is as follows: weld zone > 304 heat affected zone > 304 base metal > Q235 heat affected zone > Q235 base metal.
异种钢TIG焊接微观组织力学性能
dissimilar steelTIG weldingmicrostructuremechanical properties
黄本生,卢东华,杨逸莎,等. Q345/316L钢焊接接头的腐蚀性能[J]. 材料保护,2014,47(9):22-25+7.
Huang B S, Lu D H, Yang Y S, et al Corrosion behavior of Q345/316L steel welded joints[J]. Material protection, 2014, 47(9):22-25 + 7.
李克俭,李晓刚,张宇,等. 异种金属焊接接头微观组织演化及高温失效机理综述[J]. 电焊机,2020,50(9):17-43.
Li K J, Li X G, Zhang Y, et al. Review on microstructure evolution and high temperature failure mechanism of dissimilar metal welded joints[J]. Electric welding machine, 2020, 50(9):17-43.
王晓军,杨健,周栋,等. Q345/316L异种钢K-TIG焊接接头的组织及性能[J]. 电焊机,2021,51(1):66-72,121.
Wang X J, Yang J, Zhou D, et al. Microstructure and properties of k-tig welded joint of Q345/316L dissimilar steel[J]. Electric Welding Machine, 2021, 51(1):66-72, 121.
赵勇桃,李波波,鲁海涛,等. Q235钢与316不锈钢异种钢焊接接头组织及力学性能的研究[J]. 热加工工艺,2019,48(11):35-38.
Zhao Y T, Li B B, Lu H T, et al. Study on Microstructure and mechanical properties of welded joints between Q235 steel and 316 stainless steel[J]. Hot Working Process, 2019, 48(11):35-38.
高杰,王娟,李亚江. 异种钢的焊接研究现状[J]. 精密成形工程,2017,9(5):83-89.
Gao J, Wang J, Li Y J. Research status of dissimilar steel welding[J]. Precision Forming Engineering, 2017, 9(5):83-89.
黄本生,杨江,卢东华,等. Q345/316L异种钢焊接接头显微组织结构与力学性能[J]. 材料热处理学报,2016,37(5):45-51.
Huang B S, Yang J, Lu D H, et al Microstructure and mechanical properties of Q345/316L dissimilar steel welded joints[J]. Journal of material heat treatment, 2016, 37(5):45-51.
刘东宇,李东,李凯斌,等. E36与304异种金属光纤激光焊接接头的组织分析[J]. 激光与光电子学进展,2015(4):101-107.
Liu D Y, Li D, Li K B, et al. Microstructure analysis of E36 and 304 dissimilar metal fiber laser welded joints[J]. Progress in laser and optoelectronics,2015(4):101-107.
黄健康,潘伟,孙天亮,等. 不锈钢/碳钢TIG焊熔池表面流动行为[J]. 焊接学报,2019,40(8):18-25,161-162.
Huang J k, Pan Wei, Sun T L, et al. Surface flow behavior of stainless steel/Carbon Steel TIG welding pool[J]. Journal of welding, 2019, 40(8):18-25,161-162.
陈今良,王尧. 电流与保护气体对Q235A与304不锈钢异种TIG焊接接头的影响[J]. 中国重型装备,2018(3):51-54.
Chen J L, Wang Y. Effects of current and shielding gas on dissimilar TIG welded joints of Q235A and 304 stainless steel[J]. China heavy equipment, 2018(3):51-
Dinesh W. Experimental analysis of dissimilar metal weld joint: Ferritic to austenitic stainless steel[J]. Materials Science & Engineering A, 2015, 639.
卢东华. 316L不锈钢/Q345钢焊接接头组织与性能研究[D]. 四川:西南石油大学,2015.
Lu D H. Study on Microstructure and properties of 316L stainless steel/Q345 steel welded joint[D]. Southwest Petroleum University, 2015.
卢金斌,王志新,陈建泰. 1Cr17Mn6Ni5N与Q235异种钢焊接接头组织分析[J]. 焊接技术,2008(2):15-17.
Lu J B, Wang Z X, Chen J T. Microstructure analysis of welded joint between 1Cr17Mn6Ni5N and Q235 dissimilar steel[J]. Welding technology, 2008(2):15-17.
马丽,闫亚杰. 1Cr17Mn6Ni5N与Q235异种钢焊接接头组织分析[J]. 热加工工艺,2011,40(3):168-169,172.
Ma L, Yan Y J. Microstructure analysis of welded joint between 1Cr17Mn6Ni5N and Q235 dissimilar steel [J] Hot working process, 2011, 40 (3):168-169,172.
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