Inverted Trapezoidal Cross-Section H-Shaped Coil for Electromagnetic Pulse Welding
Xiong Qi1,2, Ma Chaojie1,2, Yan Nuo1,2, Chen Kaichuang1,2, Wang Yizhe1,2
1. Hubei Provincial Engineering Research Center of Intelligent Energy Technology China Three Gorges University Yichang 443002 China; 2. College of Electrical Engineering & New Energy China Three Gorges University Yichang 443002 China
Abstract:Electromagnetic pulse welding technology combines the advantages of high-speed forming and solid joining and is ideally suited for joining dissimilar metals. Welding coils are the key components of an EMPW system. H-shaped coils are widely used in plate welding due to their small size and easy assembly. However, most of the H-shaped coils used in existing studies have rectangular cross-sections, and the effect of different cross-section shapes on the weld quality of plate parts is rarely studied. This paper compares and analyses the Lorentz force generated by three types of coils with various cross-sections and explores the relationship between the geometrical parameters of the coil cross-section and the weld quality of plate parts. Taking copper and aluminum plate parts as the research object, the two-dimensional electromagnetic pulse welding simulation model of circuit-magnetic field-structure field coupling is established using finite element software. The plate's dynamic deformation process is the same under the action of three kinds of cross-section coils. Before the plate collision, the movement velocity at the center of the plate is maximum. After the plate collision, the motion velocity at the edge of the collision area is maximum and decreases gradually to both sides. The Lorentz force exerted by the rectangular cross-section coil on the plate is the largest, the trapezoidal cross-section coil is the smallest, and the Lorentz force generated by the inverted trapezoidal cross-section coil is smaller than that of the rectangular cross-section coil. Based on the welding window theory, the maximum effective welding width of the inverted trapezoidal coil is 0.877 9 mm, the rectangular coil is 0.847 8 mm, and the trapezoidal coil is 0.333 6 mm. The effective welding width of the plate increases and then decreases with the rise of the upper bottom edge width of the inverted trapezoidal coil. The maximum effective weld width of the plate is 0.933 2 mm for the upper bottom edge width of 7 mm, which is 10.07% higher than that of the rectangular cross-section coil. The study results show that (1) the inverted trapezoidal cross-section coil has the best welding performance. (2) As the width of the upper bottom edge of the inverted trapezoidal cross-section increases, the effective weld width of the plate increases and then decreases. An optimum parameter exists for the width of the upper bottom edge. (3) The magnitude of the collision velocity of the plate is not the only factor that determines the welding quality of the plate. Welding quality is also related to the contact area of the plate after collision.
[1] 熊奇, 邱爽, 李彦昕, 等. 组合式电磁成形技术研究进展[J]. 电工技术学报, 2024, 39(9): 2710-2729. Xiong Qi, Qiu Shuang, Li Yanxin, et al.Research progress of combined electromagnetic forming tech- nology[J]. Transactions of China Electrotechnical Society, 2024, 39(9): 2710-2729. [2] 李成祥, 沈婷, 吴浩, 等. 平板集磁器结构对涡流分布与集磁效果的影响规律[J]. 电工技术学报, 2023, 38(15): 4087-4096. Li Chengxiang, Shen Ting, Wu Hao, et al.Influence of the structure parameters of the flat field shaper on the eddy current distribution and magnetic con- centration effect[J]. Transactions of China Electro- technical Society, 2023, 38(15): 4087-4096. [3] Sarvari M, Abdollah-zadeh A, Naffakh-Moosavy H, et al. Investigation of collision surfaces and weld interface in magnetic pulse welding of dissimilar Al/Cu sheets[J]. Journal of Manufacturing Processes, 2019, 45: 356-367. [4] Chen Yingzi, Zhang Huaiqing, Wu Hao, et al.Process simulation and experimental investigation on joining of Al/Ti sheets by magnetic pulse welding[J]. The International Journal of Advanced Manufacturing Technology, 2022, 121(7): 5463-5472. [5] Yao Yuanheng, Chen Dingding, Tang Bowei, et al.Miniaturized S-shaped flexible magnetic pulse welding coil design for engineering applications[J]. Journal of Manufacturing Processes, 2023, 104: 372-383. [6] Shotri R, Faes K, Racineux G, et al.Improved coil design for magnetic pulse welding of metallic sheets[J]. Journal of Manufacturing and Materials Processing, 2022, 6(6): 144. [7] 李光耀, 陈侣侣, 耿辉辉, 等. 5182Al/HC340LA异种金属件磁脉冲焊接数值模拟与试验验证[J]. 塑性工程学报, 2018, 25(3): 155-162. Li Guangyao, Chen Lülü, Geng Huihui, et al.Numerical simulation and experimental verification of magnetic pulse welding for dissimilar metal parts 5182Al/HC340LA[J]. Journal of Plasticity Engin- eering, 2018, 25(3): 155-162. [8] 崔俊佳, 袁伟, 李光耀. 汽车车身异种金属板件磁脉冲焊接工艺研究[J]. 汽车工程, 2017, 39(1): 113-120. Cui Junjia, Yuan Wei, Li Guangyao.A study on magnetic pulse welding process for dissimilar sheet metals of autobody[J]. Automotive Engineering, 2017, 39(1): 113-120. [9] 李成祥, 陈丹, 周言, 等. 电磁脉冲焊接锂离子电池叠层极耳电磁力分布及运动特性[J]. 高电压技术, 2025, 51(1): 412-422. Li Chengiang, Chen Dan, Zhou Yan, et al.Elec- tromagnetic parameters distribution and tabs motion characteristic of electromagnetic pulse welding for lithium-ion battery laminated tabs[J]. High Voltage Engineering, 2025, 51(1): 412-422. [10] Li Xiaoxiang, Li Mengxian, Tang Xinyu, et al.Mag- netic pulse welding of large-diameter aluminum-steel dissimilar metal tubes: actuator design, welding process, and mechanism[J]. The International Journal of Advanced Manufacturing Technology, 2025: 1-19. [11] Zhou Yan, Shen Ting, Li Chengxiang, et al.Effect of welding gap on electromagnetic pulse welding of a copper-aluminum alloy joint[J]. Materials and Manufacturing Processes, 2024, 39(16): 2345-2353. [12] Li Zhi, Peng Wenxiong, Chen Yingzi, et al.Simu- lation and experimental analysis of Al/Ti plate magnetic pulse welding based on multi-seams coil[J]. Journal of Manufacturing Processes, 2022, 83: 290-299. [13] 熊奇, 陈开创, 马朝杰, 等. 多边形金属板件洛伦兹力驱动冲压成形动态过程分析及成形效果优化[J]. 电工技术学报, 2025, 40(7): 2007-2019. Xiong Qi, Chen Kaichuang, Ma Chaojie, et al.Dynamic process analysis and optimization of forming effects in lorentz force stamping for polygonal sheet metal[J]. Transactions of China Electrotechnical Society, 2025, 40(7): 2007-2019. [14] 李梦瑶, 邱立, 易宁轩, 等. 基于驱动导体环的板件电磁成形电磁力分布与成形效果研究[J]. 电工技术学报, 2025, 40(1): 13-24. Li Mengyao, Qiu Li, Ying Ningxuan, et al.Study on electromagnetic force distribution and forming effect of plate electromagnetic forming based on driving conductor ring[J]. Transactions of China Electro- technical Society, 2025, 40(1): 13-24. [15] 王宇新, 李晓杰, 王小红, 等. 爆炸焊接技术及工程应用[J]. 航空制造技术, 2019, 62(12): 42-47. Wang Yuxin, Li Xiaojie, Wang Xiaohong, et al.Explosive welding technology and engineering appli- cation[J]. Aeronautical Manufacturing Technology, 2019, 62(12): 42-47. [16] Hoseini Athar M M, Tolaminejad B. Weldability window and the effect of interface morphology on the properties of Al/Cu/Al laminated composites fabri- cated by explosive welding[J]. Materials & Design, 2015, 86: 516-525. [17] Zhou Yan, Li Chengxiang, Wang Xianmin, et al.Investigation of flyer plate dynamic behavior in electromagnetic pulse welding[J]. Journal of Manufa- cturing Processes, 2021, 68: 189-197. [18] 石鑫. 电磁脉冲焊接双H型线圈的优化设计与实验研究[D]. 重庆: 重庆大学, 2021. Shi Xin.Optimal design and experimental study of electromagnetic pulse welding double H-shaped coils[D]. Chongqing: Chongqing University, 2021. [19] Psyk V, Risch D, Kinsey B L, et al.Electromagnetic forming—a review[J]. Journal of Materials Pro- cessing Technology, 2011, 211(5): 787-829. [20] Li Zhi, Peng Wenxiong, Chen Yingzi, et al.Analysis of energy transfer process in magnetic pulse welding and optimization of system efficiency[J]. The Inter- national Journal of Advanced Manufacturing Tech- nology, 2023, 125(5): 2425-2434. [21] Schumacher E, Küimper S, Kryukov l, et al. Analysis of the weld seam area of magnetic pulse welded aluminium-steel-sheet-connections on its suitability as a sign of quality[C]//8thInternational Conference on High Speed Forming, 2018. [22] Zhou Yan, Li Chengxiang, Shi Xin, et al.Evaluation model of electromagnetic pulse welding effect based on Vc-β trajectory curve[J]. Journal of Materials Research and Technology, 2022, 20: 616-626.
2025, Vol. 40 
