Multi-Physics Field Coupling Simulation of Induction Leveling Process

doi:10.16183/j.cnki.jsjtu.2021.312

Abstract

Abstract:

The electromagnetic induction leveling method has the characteristics of high efficiency and easy operation. It has a good application prospect in the thin plate leveling process. Based on the fixed inline coil induction leveling process used by the shipyard, this research uses COMSOL Multiphysics to establish a three-dimensional electromagnetic-thermal-mechanical coupling induction leveling finite element model. The model inputs the temperature-dependent physical properties as the material properties of the AH36 steel plate, and takes the residual stress and welding deformation of the butt weldment as the initial state. The method of sequential coupling is used to calculate the changes of electromagnetic field, temperature field, and structure field during the leveling process. The two-way coupling relationship between the temperature field and the electromagnetic field is verified and the deformation of the welded part after leveling is obtained. Through the self-built induction leveling experiment platform, the accuracy and effectiveness of the finite element model are verified.

Key words: electromagnetic induction, welding distortion and leveling, multi-physics field coupling, finite element simulation

CLC Number:

TH162

LIU Xuyang, CAI Changru, ZHAO Yixi, JU Liyang. Multi-Physics Field Coupling Simulation of Induction Leveling Process[J]. Journal of Shanghai Jiao Tong University, 2023, 57(3): 253-263.

Figures/Tables 19

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x/mm	瞬态20 s矫平量/mm	稳态矫平量/mm
0	0.898 9	0.989 2
100	1.002 2	1.072 8
200	0.760 9	0.792 4
300	0.439 6	0.460 2
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