Effect of hold time on resistance spot weldability of aluminium to steel

被引:8
作者
Meng, Xianming [1 ]
Li, Siwei [2 ]
Shi, Liting [1 ,3 ]
Zhang, Yongqiang [4 ]
Chen, Yajun [5 ]
Zhang, Sai [1 ]
Wu, Hao [1 ]
机构
[1] CATARC Tianjin Automot Engn Res Inst Co Ltd, Tianjin, Peoples R China
[2] Civil Aviat Univ China, Coll Aeronaut Engn, Tianjin, Peoples R China
[3] Tianjin Univ, Sch Mat Sci & Engn, Tianjin, Peoples R China
[4] Shougang Grp Co Ltd, Res Inst Technol, Beijing, Peoples R China
[5] Civil Aviat Univ China, Sino European Inst Aviat Engn, Tianjin, Peoples R China
来源
SCIENCE AND TECHNOLOGY OF WELDING AND JOINING | 2022年 / 27卷 / 07期
基金
中国博士后科学基金;
关键词
Aluminium; dual-phase steel resistance spot welding; hold time; weld nugget diameter; thickness of intermetallic compound; mechanical properties; fracture mechanism; HIGH-STRENGTH STEEL; FATIGUE BEHAVIOR; INTERMETALLIC COMPOUNDS; MECHANICAL-PROPERTIES; JOINTS; WELDS; MICROSTRUCTURES;
D O I
10.1080/13621718.2022.2080448
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
The effects of welding hold time on weld quality of aluminium alloy to dual-phase steel resistance spot welds were studied. Results demonstrated that there existed an optimum range of hold time (350 similar to 500 ms), within which the largest weld nugget diameter (7.6 mm), thinnest intermetallic compound (IMC) layer (1 similar to 5 mu m) and maximum tensile shear peak load (4.7 kN) were obtained. Too short hold time led to shrinkage, small weld nugget and thick IMC layer due to reduced heat dissipation after removing electrodes, thus resulting in low tensile peak load and brittle fracture along the IMC layer. While too long hold time, i.e. 750 ms, produced a smaller weld nugget diameter due to more rapid heat dissipation.
引用
收藏
页码:522 / 532
页数:11
相关论文
共 19 条
[1]   Role of zinc layer in resistance spot welding of aluminium to steel [J].
Arghavani, M. R. ;
Movahedi, M. ;
Kokabi, A. H. .
MATERIALS & DESIGN, 2016, 102 :106-114
[2]   Fracture mechanisms of Al/steel resistance spot welds in lap shear test [J].
Chen, Nannan ;
Wang, Hui-Ping ;
Carlson, Blair E. ;
Sigler, David R. ;
Wang, Min .
JOURNAL OF MATERIALS PROCESSING TECHNOLOGY, 2017, 243 :347-354
[3]   Resistance spot welding of dissimilar AISI-1008 steel/Al-1100 alloy lap joints with a graphene interlayer [J].
Das, Tanmoy ;
Das, Rajib ;
Paul, Jinu .
JOURNAL OF MANUFACTURING PROCESSES, 2020, 53 :260-274
[4]   Fatigue behaviour of Al/steel dissimilar resistance spot welds fabricated using Al-Mg interlayer [J].
Ibrahim, I. ;
Ito, R. ;
Kakiuchi, T. ;
Uematsu, Y. ;
Yun, K. ;
Matsuda, C. .
SCIENCE AND TECHNOLOGY OF WELDING AND JOINING, 2016, 21 (03) :223-233
[5]   Tensile and Fatigue Behaviour of AA6022-T4 to IF Steel Resistance Spot Welds [J].
Kang, Jidong ;
Rao, Harish M. ;
Sigler, David R. ;
Carlson, Blair E. .
2ND INTERNATIONAL CONFERENCE ON STRUCTURAL INTEGRITY, ICSI 2017, 2017, 5 :1425-1432
[6]   A review on resistance spot welding of aluminum alloys [J].
Manladan, S. M. ;
Yusof, F. ;
Ramesh, S. ;
Fadzil, M. ;
Luo, Z. ;
Ao, S. .
INTERNATIONAL JOURNAL OF ADVANCED MANUFACTURING TECHNOLOGY, 2017, 90 (1-4) :605-634
[7]   Experimental investigation on resistance spot welding of galvannealed HSLA steel [J].
Nieto, J. ;
Guerrero-Mata, M. P. ;
Colas, R. ;
Mani, A. .
SCIENCE AND TECHNOLOGY OF WELDING AND JOINING, 2006, 11 (06) :717-722
[8]   Effect of weld nugget size on overload failure mode of resistance spot welds [J].
Pouranvari, M. ;
Asgari, H. R. ;
Mosavizadch, S. M. ;
Marashi, P. H. ;
Goodarzi, M. .
SCIENCE AND TECHNOLOGY OF WELDING AND JOINING, 2007, 12 (03) :217-225
[9]   Interfacial microstructure and strength of steel/aluminum alloy joints welded by resistance spot welding with cover plate [J].
Qiu, Ranfeng ;
Iwamoto, Chihiro ;
Satonaka, Shinobu .
JOURNAL OF MATERIALS PROCESSING TECHNOLOGY, 2009, 209 (08) :4186-4193
[10]   Growth kinetics and thickness prediction of interfacial intermetallic compounds between solid steel and molten aluminum based on thermophysical simulation in a few seconds [J].
Rong, Jiping ;
Kang, Zhifei ;
Chen, Shuhai ;
Yang, Dawei ;
Huang, Jihua ;
Yang, Jian .
MATERIALS CHARACTERIZATION, 2017, 132 :413-421
12