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Research of Dynamic Characteristics in Electromagnetic Attraction Forming of AZ31 Magnesium Alloy Tube |
Xiong Qi1,2, Zhu Xinhui1,3, Zhao Xiang1,3, Fan Liping4 |
1. Hubei Provincial Engineering Technology Research Center for Power Transmission Line China Three Gorges University Yichang 443002 China; 2. Wuhan National High Magnetic Field Center Huazhong University of Science and Technology Wuhan 430074 China; 3. College of Electrical Engineering & New Energy China Three Gorges University Yichang 443002 China; 4. Yichang Power Supply Company State Grid Hubei Electric Power Corporation Yichang 443002 China |
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Abstract Electromagnetic forming (EMF) technology can effectively improve the forming limit of light alloys at room temperature, suppress the spring-back of the workpiece, and reduce wrinkling. It has been widely used in the plastic processing of aluminum alloy workpieces. However, compared with aluminum alloys, magnesium alloys have lower electrical conductivity and higher yield strength, so conventional EMF technology can not satisfy the plastic processing of magnesium alloy workpieces at room temperature. Recently, some scholars used high-conductivity alloys as driving plates or heating devices to assist in forming. However, the tooling was complex, and the forming quality needed to be guaranteed. It is not even suitable for small tube forming. Therefore, this paper proposes an electromagnetic attraction forming method for magnesium alloy tubes at room temperature. By establishing a finite element simulation model, the feasibility of the forming scheme, the discharge and electromagnetic parameters, and the workpiece deformation were studied. Firstly, AZ31B magnesium alloy tubes with an inner diameter of 10 mm, a length of 100 mm, and a thickness of 2 mm are selected. The dual-frequency discharge current method is used to generate attractive forces to drive the forming of the tube. Secondly, due to the extremely fast and complex electromagnetic forming, it is necessary to use simulation to explore the relationship between the parameters in the attractive electromagnetic forming process in detail. Finally, a finite element model has been developed considering the influence of tube displacement and deformation. The method realizes the full coupling between the electromagnetic fields and workpiece deformation. Simulation results show that the electromagnetic forming process can be divided into three stages: the stage before the short pulse current is turned on, the deformation stage, and the vibration stage. Changing the long-pulse voltage Us or the short-pulse voltage Uf can change the time-space distribution of electromagnetic parameters at point O and ultimately regulate the motion state of the tube. During the short-pulse current conduction stage, the electromagnetic parameters at point O have opposite signs, and the tube is subjected to a repulsive force. When Us is 9.4 kV and Uf is 13 kV, the tube is radially contracted by 0.27 mm, the final deformation area dent marks appear, and the deformation flatness is poor. In the deformation stage, the electromagnetic parameters at point O have the same sign, and the attractive force deforms the tube. When Uf is 13 kV, Us increases from 4.4 kV to 8.4 kV, and the action time of the attractive force in the deformation stage will become longer. The final radial expansion displacement of the tube will become larger. When Us is 8.4 kV and Uf is raised from 13 kV to 23 kV, the electromagnetic force and radial expansion velocity of point O in the deformation stage increase. However, the final displacement at 23 kV is only 5.84 mm, much lower than 7.13 mm at 21 kV. Uf was raised from 21 kV to 23 kV (0.5 kV intervals) to study this phenomenon. In the vibration stage, the peak shrinkage radial velocity at 21 kV and 21.5 kV were 12.8 m/s and 13.4 m/s, respectively, and the peak shrinkage velocity increased to 32.9 m/s at 22.5 kV. At this time, the repulsive force will dominate the motion state of the tube in the vibration stage, so the final deformation effect is not good. The following conclusions can be drawn: (1) In practical engineering, whether Us will cause necking in the workpiece before the short pulse is turned on should be considered. (2) Since Us has a lower upper limit, increasing Us is more effective than increasing Uf. It can improve the deformation effect of the tube fitting. (3) The upper limit of Uf will be determined by the motion state of the tube fitting in the vibration stage. That is, the velocity movement trend of the tube fitting in this stage should be roughly the same. If the shrinkage speed is significantly increased, Uf cannot be further increased.
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Received: 01 April 2022
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