铝合金空心板件复合式电磁成形研究

doi:10.19595/j.cnki.1000-6753.tces.250596

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摘要当前空心板件制造工艺多采用机械力与热作用相结合的方式实现,在钛合金等硬脆且电导率较低的材料加工中展现出较好的工艺适配性,但对于具有高延展性和高电导率的铝合金材料而言,现有工艺难以实现良好的适配性。因此,该文首先提出一种铝合金空心板件复合式电磁成形方案,详细介绍了该技术的成形原理,将整个过程分为两个关键阶段：空心腔体胀形和板件两端电磁脉冲焊接。然后,通过建立有限元模型,对其动态过程和成形效果进行了分析,并深入探讨了系统参数对成形效果的影响。结果表明：本方案成功实现了空心腔体高度为20.1 mm的铝合金空心板件成形,胀形最大速度达20.71 m/s;板件表面最大成形差值为0.15 mm,均匀性良好;板件两端可形成有效焊接接头,总时长小于3 ms。改变放电电压、放电电容、板件厚度及绝缘板厚度,可以有效控制空心腔体成形高度,而成形空心板件的均匀性仅受板件厚度影响。

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关键词 ：铝合金空心板件, 电磁成形, 系统参数, 板件均匀度, 有限元分析

Abstract：As a high-speed forming technology that uses the Lorentz force to induce plastic deformation of metal materials, electromagnetic forming can effectively address the problems of uneven wall thickness, long manufacturing cycles, and complex processes caused by the superplastic forming/diffusion bonding process for manufacturing hollow plates. Therefore, this paper proposes a composite electromagnetic forming scheme for an aluminum alloy hollow plate. The principles of this technology are introduced. The process is divided into two key stages: hollow-cavity bulging and electromagnetic-pulse welding at both ends of the plate.
First, the basic model of the electromagnetic forming system for hollow plate parts is established, and power supply systems for the through-flow forming and electromagnetic pulse welding processes are designed. Secondly, since the forming process is very rapid and it is difficult to observe changes in electromagnetic parameters, it is necessary to develop a simulation model to study the dynamic forming process. Finally, a fully coupled electromagnetic field and mechanics model is established, and the feasibility of the scheme is verified.
The simulation results show that the cross-flow forming process can be divided into three stages: stress, inertia, and rebound. The inertia stage accounts for 70% of the total time of the cross-flow forming, and the cavity height is 20.1 mm. The electromagnetic pulse welding process connects the upper and lower plates at both ends, with a collision speed of 255.35 m/s and a collision angle of 11.31°.
The conclusions are as follows. (1) Electromagnetic forming technology is used to form an aluminum alloy hollow plate with a 20.1 mm hollow cavity height, and the two ends of the plate are welded to form effective joints. The total processing time of the aluminum alloy hollow plate is less than 3 ms. Compared with the 2.5 h processing time required by the SPF/DB process, this scheme effectively leverages the material properties of aluminum alloy, such as high strain rate and high conductivity. It improves the manufacturing efficiency of aluminum alloy hollow plates. (2) Hollow cavity wall thickness’s size maximum tolerance is only 0.15 mm, and no appearance defects, meeting the 6063 aluminum alloy profile executive standard GB/T 5237—2008. Changing the plate thickness significantly affects forming uniformity. (3) By adjusting the system parameters, the forming height of the hollow cavity can be improved. Increasing the discharge voltage and discharge capacitance can significantly improve the forming height of the hollow cavity. On the contrary, increasing the thickness of the insulation plate and the plate significantly reduces the forming height of the hollow cavity.

Key words： Aluminum alloy hollow plate electromagnetic forming system parameter plate uniformity finite element analysis

收稿日期: 2025-04-10

PACS:

TM154

基金资助:广东省极端条件重点实验室资助项目（2023B1212010002）

通讯作者: 阎诺男,1997年生,硕士研究生,研究方向为电磁成形、电磁场分析及应用。E-mail: mamba1021@126.com

作者简介: 熊奇男,1990年生,博士,副教授,博士生导师,中国电工技术学会高级会员,IEEE Senior Member,研究方向为电磁成形、多场耦合分析及储能技术。E-mail: pandaqi0218@gmail.com

引用本文:

熊奇, 路凯, 程辉, 魏钰颖, 阎诺. 铝合金空心板件复合式电磁成形研究[J]. 电工技术学报, 2026, 41(6): 1828-1843. Xiong Qi, Lu Kai, Cheng Hui, Wei Yuying, YanNuo. Research on Composite Electromagnetic Forming of Aluminum Alloy Hollow Plate. Transactions of China Electrotechnical Society, 2026, 41(6): 1828-1843.

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[1] 熊奇, 杨猛, 周丽君, 等. 双线圈吸引式板件电磁成形过程中的涡流竞争问题[J]. 电工技术学报, 2021, 36(10): 2007-2017.
Xiong Qi, Yang Meng, Zhou Lijun, et al.Eddy currents competition in electromagnetic forming process of plates by double-coil attraction[J]. Transactions of China Electrotechnical Society, 2021, 36(10): 2007-2017.
[2] 杨合, 李落星, 王渠东, 等. 轻合金成形领域科学技术发展研究[J]. 机械工程学报, 2010, 46(12): 31-42.
Yang He, Li Luoxing, Wang Qudong, et al.Research on the development of advanced forming for lightweight alloy materials area[J]. Journal of Mechanical Engineering, 2010, 46(12): 31-42.
[3] 龚航, 黄亮, 李建军, 等. 大型铝合金曲面件在电磁渐进成形首次放电条件下的起皱行为研究[J]. 中国材料进展, 2016, 35(4): 284-291, 261.
Gong Hang, Huang Liang, Li Jianjun, et al.Research on wrinkling behavior after the first discharge in electromagnetic incremental forming process of large aluminum alloy curved surface parts[J]. Materials China, 2016, 35(4): 284-291, 261.
[4] 梁春华, 杨锐. 航空发动机宽弦空心风扇叶片的发展及应用[J]. 航空发动机, 1999, 25(2): 54-58.
[5] 王国峰, 张建威, 张晓巍, 等. 2B06铝合金双层结构件DB&SPF组合工艺研究[J]. 锻压技术, 2020, 45(7): 187-192.
Wang Guofeng, Zhang Jianwei, Zhang Xiaowei, et al.Research on DB&SPF combination process of double-layer structural parts for 2B06 aluminum alloy[J]. Forging & Stamping Technology, 2020, 45(7): 187-192.
[6] 许慧元, 李志强, 付明杰, 等. Ti3Al合金加中间层扩散连接界面性能及在SPF/DB工艺中的应用[J]. 新技术新工艺, 2021(9): 65-69.
Xu Huiyuan, Li Zhiqiang, Fu Mingjie, et al.The properties of Ti3Al alloy with interlayer diffusion connection interface and the application in SPF/DB process[J]. New Technology & New Process, 2021(9): 65-69.
[7] 王会东, 付和国, 韩颖杰, 等. 大型双曲率非等厚TC4钛合金壁板整体SPF/DB成形工艺及优化[J]. 锻压技术, 2022, 47(1): 75-80.
Wang Huidong, Fu Heguo, Han Yingjie, et al.Integral SPF/DB forming process and its optimization for TC4 titanium alloypanel with large size,dual curvature and non-uniform thickness[J]. The International Journal of Advanced Manufacturing Technology, 2022, 47(1): 75-80.
[8] Huang Yongxian, Wan Long, Lü Shixiong, et al.Novel design of tool for joining hollow extrusion by friction stir welding[J]. Science and Technology of Welding and Joining, 2013, 18(3): 239-246.
[9] Duan Mianjun, Wei Ling, Hong Jin, et al.Experimental study on hollow structural component by explosive welding[J]. Fusion Engineering and Design, 2014, 89(12): 3009-3015.
[10] Xiong Qi, Tang Hongtao, Wang Muxue, et al.Design and implementation of tube bulging by an attractive electromagnetic force[J]. Journal of Materials Processing Technology, 2019, 273: 116240.
[11] 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.
[12] 邱立, 陈玉红, 张锦荣, 等. 基于离散屏蔽的管件电磁胀形电磁力分布与轴向均匀度研究[J/OL]. 电工技术学报, 1-13[2025-06-18]. https://doi.org/10. 19595/j.cnki.1000-6753.tces.241918.
Qiu Li, Chen Yuhong, Zhang Jinrong, et al. research on electromagnetic force distribution and axial uniformity of tube electromagnetic bulging based on discrete shielding[J/OL]. Transactions of China Electrotechnical Society, 1-13[2025-06-18]. https://doi. org/10.19595/j.cnki.1000-6753.tces.241918.
[13] 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 technology[J]. Transactions of China Electrotechnical Society, 2024, 39(9): 2710-2729.
[14] Fei F, Jianjun L, Liang H, et al.Direct pulse current electromagnetic forming (DPCEMF): a novel electromagnetic forming technology for aluminum alloy sheet[J]. The International Journal of Advanced
[15] Noh H G, Song W J, Kang B S, et al.Two-step electromagnetic forming process using spiral forming coils to deform sheet metal in a middle-block die[J]. The International Journal of Advanced Manufacturing Technology, 2015, 76(9): 1691-1703.
[16] Su Hongliang, Huang Liang, Li Jianjun, et al.On the forming uniformity during a single layer forming of electromagnetic incremental forming[J]. The International Journal of Advanced Manufacturing Technology, 2020, 107(11): 4561-4572.
[17] Dong Pengxin, Li Zhangzhe, Cao Quanliang, et al.Pulsed magnet design and fabrication for generating background magnetic field in discharge current-based forming[J]. IEEE Transactions on Applied Superconductivity, 2020, 30(4): 3700405.
[18] Cao Quanliang, Li Xian, Li Zhenhao, et al.Coil-less electromagnetic forming process with uniformpressure characteristics for shaping sheet metals[J]. Journal of Manufacturing Processes, 2021, 70: 140-151.
[19] Gerlach R, Kettenbeil C, Petrinic N.A new split Hopkinson tensile bar design[J]. International Journal of Impact Engineering, 2012, 50: 63-67.
[20] 熊奇, 马朝杰, 阎诺, 等. 应用于电磁脉冲焊接的倒梯形截面H型线圈[J]. 电工技术学报, 2025, 40(20): 6422-6432.
Xiong Qi, Ma Chaojie, Yan Nuo, et al.Inverted trapezoidal cross-section H-shaped coil for electromagnetic pulse welding[J]. Transactions of China Electrotechnical Society, 2025, 40(20): 6422-6432.
[21] 曹亚明, 杨尚磊, 夏明许, 等. 铝-铝电磁脉冲焊接技术及其机理研究[J]. 热加工工艺, 2020, 49(9): 50-53, 58.
Cao Yaming, Yang Shanglei, Xia Mingxu, et al.Research on Al-Al electromagnetic pulse welding technology and mechanism[J]. Hot Working Technology, 2020, 49(9): 50-53, 58.
[22] Watanabe M, Kumai S.Interfacial morphology of magnetic pulse welded aluminum/aluminum and copper/copper lap joints[J]. Materials Transactions, 2009, 50(2): 286-292.
[23] 李显. 板件通流式电磁成形数值模拟及实验研究[D]. 武汉: 华中科技大学, 2022.
Li Xian. numerical simulation and experimental study of coil-less electromagnetic metal sheet forming[D]. Wuhan: Huazhong University of Science and Technology, 2022.
[24] 安立辉, 苑世剑. 2219铝合金薄壁曲面件拉形过程变形均匀性[J]. 材料工程, 2020, 48(4): 123-130.
An Lihui, Yuan Shijian.Deformation uniformity of 2219 aluminum alloy thin-walled curved parts in stretch forming process[J]. Journal of Materials Engineering, 2020, 48(4): 123-130.
[25] 李剑飞, 贾国朋, 李细锋, 等. 蒙皮拉形中橘皮缺陷的研究进展[J]. 模具技术, 2018(2): 55-63.
Li Jianfei, Jia Guopeng, Li Xifeng, et al.Research progress of orange peel defect during stretch forming of aircraft skin[J]. Die and Mould Technology, 2018(2): 55-63.
[26] Li Yan, Yang Dezhi, Yang Wenyu, et al.Multiphysics numerical simulation of the transient forming mechanism of magnetic pulse welding[J]. Metals, 2022, 12(7): 1149.
[27] Chen Meng, Lai Zhipeng, Cao Quanliang, et al.Investigation on deformation control of sheet metal inradial Lorentz force augmented deep drawing[J]. The International Journal of Advanced Manufacturing Technology, 2019, 105(5/6): 2369-2381.
[28] 熊奇, 周丽君, 杨猛, 等. 单脉冲电磁成形中洛伦兹力在时间上的双向竞争关系及其对成形效果的影响[J]. 电工技术学报, 2022, 37(14): 3453-3463.
Xiong Qi, Zhou Lijun, Yang Meng, et al.The two-way competitive relationship of Lorentz force in time in single pulse electromagnetic forming and its influence on forming effect[J]. Transactions of China Electrotechnical Society, 2022, 37(14): 3453-3463.
[29] Xiong Qi, Han Xiaotao, Cao Quanliang, et al.Bulging of 1420 Al-Li alloy based on pulse current[J]. Procedia Engineering, 2014, 81: 808-812.
[30] 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, Yi Ningxuan, et al.Study on electromagnetic force distribution and forming effect of plate electromagnetic forming based on driving conductor ring[J]. Transactions of China Electrotechnical Society, 2025, 40(1): 13-24.
[31] 邹智涛, 李劲风, 马鹏程, 等. 热处理及晶粒组织对2A55超高强铝锂合金板材各向异性的影响[J]. 宇航材料工艺, 2024, 54(3): 45-54.
Zou Zhitao, Li Jinfeng, Ma Pengcheng, et al.Effect of heat treatments and grain structures on the anisotropy of super high-strength 2A55 Al-Li alloy sheets[J]. Aerospace Materials & Technology, 2024, 54(3): 45-54.