Modeling, Identification and Simulation of DC Resistance Spot Welding Process for Aluminum Alloy 5182

doi:10.1007/s12204-013-1371-8

上海交通大学学报（英文版） ›› 2013, Vol. 18 ›› Issue (1): 101-104.doi: 10.1007/s12204-013-1371-8

Modeling, Identification and Simulation of DC Resistance Spot Welding Process for Aluminum Alloy 5182

GONG Liang1* (贡亮), XI Yan2 (席艳), Ma Zhe-ren1 (马喆人), LIU Cheng-liang1 (刘成良)

(1. Institute of Mechatronics, Shanghai Jiaotong University, Shanghai 200240, China; 2. Department of Electrical Engineering, Yantai Vocational College, Yantai 264000, Shandong, China)

出版日期:2013-02-28 发布日期:2013-03-19
通讯作者: GONG Liang1* (贡亮) E-mail:gongliang mi@sjtu.edu.cn

Modeling, Identification and Simulation of DC Resistance Spot Welding Process for Aluminum Alloy 5182

GONG Liang1* (贡亮), XI Yan2 (席艳), Ma Zhe-ren1 (马喆人), LIU Cheng-liang1 (刘成良)

(1. Institute of Mechatronics, Shanghai Jiaotong University, Shanghai 200240, China; 2. Department of Electrical Engineering, Yantai Vocational College, Yantai 264000, Shandong, China)

Online:2013-02-28 Published:2013-03-19
Contact: GONG Liang1* (贡亮) E-mail:gongliang mi@sjtu.edu.cn

摘要/Abstract

摘要： Currently the aluminum alloy resistance spot welding (AA-RSW) has been extensively used for light weight automotive body-in-white manufacturing. However the aluminum alloys such as AA5182 have inferior weldability for forming the joint due to their high reflectiveness to heat and light. Therefore it is necessary to further develop the high performance control strategy and the set-up of a new welding schedule. The welding process identification is the essential issue where the difficulty arises from the fact that the AA-RSWis a nonlinear time-varying uncertain process which couples the thermal, electrical, mechanical and metallurgical dynamics. To understand this complicated physical phenomenon a novel dual-phase M-series pseudo-random electrical pattern is adopted to excite the AA-RSW electrical-thermal process and the thermal response is recorded according to the welding power outputs. Based on the experimental information, the transfer function of an AA-RSW electricalthermal mechanism is identified, and the optimum model order and parameters are determined. Subsequently a control-oriented DC AA-RSWmodel is established to explore the welding power control algorithm. The simulated results of the control model show agreement with the experimental data, which validates its feasibility for the corresponding welding control.

关键词: resistance spot welding (RSW), aluminum alloy, system identification, modeling and simulation

Abstract: Currently the aluminum alloy resistance spot welding (AA-RSW) has been extensively used for light weight automotive body-in-white manufacturing. However the aluminum alloys such as AA5182 have inferior weldability for forming the joint due to their high reflectiveness to heat and light. Therefore it is necessary to further develop the high performance control strategy and the set-up of a new welding schedule. The welding process identification is the essential issue where the difficulty arises from the fact that the AA-RSWis a nonlinear time-varying uncertain process which couples the thermal, electrical, mechanical and metallurgical dynamics. To understand this complicated physical phenomenon a novel dual-phase M-series pseudo-random electrical pattern is adopted to excite the AA-RSW electrical-thermal process and the thermal response is recorded according to the welding power outputs. Based on the experimental information, the transfer function of an AA-RSW electricalthermal mechanism is identified, and the optimum model order and parameters are determined. Subsequently a control-oriented DC AA-RSWmodel is established to explore the welding power control algorithm. The simulated results of the control model show agreement with the experimental data, which validates its feasibility for the corresponding welding control.

Key words: resistance spot welding (RSW), aluminum alloy, system identification, modeling and simulation

中图分类号:

TG 438.2

GONG Liang1* (贡亮), XI Yan2 (席艳), Ma Zhe-ren1 (马喆人), LIU Cheng-liang1 (刘成良). Modeling, Identification and Simulation of DC Resistance Spot Welding Process for Aluminum Alloy 5182[J]. 上海交通大学学报（英文版）, 2013, 18(1): 101-104.

GONG Liang1* (贡亮), XI Yan2 (席艳), Ma Zhe-ren1 (马喆人), LIU Cheng-liang1 (刘成良). Modeling, Identification and Simulation of DC Resistance Spot Welding Process for Aluminum Alloy 5182[J]. Journal of shanghai Jiaotong University (Science), 2013, 18(1): 101-104.

参考文献

[1] Gould J E. Joining aluminum sheet in the automotive industry: A 30 year history [J]. Welding Journal, 2012, 91(1): 23-34.
[2] Florea R S, Bammann D J, Yeldell A, et al. Welding parameters influence on fatigue life and microstructure in resistance spot welding of 6061-T6 aluminum alloy [J]. Materials and Design, 2013, 45(3): 456-465.
[3] Wang S C, Wei P S. Modeling dynamic electrical resistance during resistance spot welding [J]. Transaction of the ASME, 2001, 123(6): 576-585.
[4] Williams N T, Parker J D. Review of resistance spot welding of steel sheets. Part 1. Modeling and control of weld nugget formation [J]. International Material Review, 2004, 49(2): 45-75.
[5] Gong L, Liu C L, Yuan J, et al. Fuzzy orthogonal optimization for determining the optimal resistance spot welding parameters [J]. Applied Mechanics and Materials, 2012, 152-154: 1046-1051.
[6] Salem M, Brown L J. Improved consistency of resistance spot welding with tip voltage control [C]//Proceedings of 24th Canadian Conference on Electrical and Computer Engineering (CCECE). Niagara Falls, Canada: IEEE, 2011: 548-551.
[7] The Aluminum Association. Aluminum standards and data, 2009 metric SI [M]. New York: The Aluminum Association, 2009.
[8] Gong L, Liu C L, Li Y M. Control criteria determination and quality inference for resistance spot welding through monitoring the electrode displacement using Bayesian belief networks [J]. Journal of Advanced Mechanical Design, Systems, and Manufacturing, 2012, 6(4): 432-444.
[9] Jun S M, Kim G S, Kim J M, et al. Power control of resistance spot welding system with high dynamic performance [C]// Proceedings of 23rd International Conference on Industrial Electronics, Control and Instrumentation. New Orleans, LA: IEEE, 1997: 845-849.
[10] Gupta O P, De A. An improved numerical modeling for resistance spot welding process and its experimental verification [J]. Transaction of the ASME, 1998, 120(5): 246-251.

Modeling, Identification and Simulation of DC Resistance Spot Welding Process for Aluminum Alloy 5182

Modeling, Identification and Simulation of DC Resistance Spot Welding Process for Aluminum Alloy 5182

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 5

编辑推荐

Metrics

本文评价

[1]	WANG Xianjin, GAO Xu, YU Kuigang . Fixture Locating Modelling and Optimization Research of Aluminum Alloy Sidewall in a High-Speed Train Body[J]. J Shanghai Jiaotong Univ Sci, 2020, 25(6): 706-713.
[2]	宋金龙，赵亦希，于忠奇，孔庆帅. 铝合金封头旋压成形变厚度毛坯设计方法[J]. 上海交通大学学报（自然版）, 2017, 51(11): 1304-1311.
[3]	LI Da1,2 (李达), CUI Zhan-quan2 (崔占全), YANG Qing-xiang2* (杨庆祥),SUN Bing1 (孙兵), SUN. Microstructure and Property of Friction Stir Welding Joint of 7075Al and AZ31BMg[J]. 上海交通大学学报（英文版）, 2012, 17(6): 679-683.
[4]	YAN Yu1 (阎昱), WANG Hai-bo1* (王海波), WAN Min2 (万敏). Forming Path Optimization for Press Bending of Aluminum Alloy Aircraft Integral Panel[J]. 上海交通大学学报（英文版）, 2012, 17(5): 635-642.
[5]	LUO Ping1 (罗平), DONG Shi-jie1 (董仕节), XIE Zhi-xiong2 (谢志雄). Novel Material of Hydrogen Generation[J]. 上海交通大学学报（英文版）, 2012, 17(3): 356-359.