Theoretical and numerical simulation study on jet formation and penetration of different liner structures driven by electromagnetic pressure

The use of a shaped liner driven by electromagnetic force is a new means of forming jets. To study the mechanism of jet formation driven by electromagnetic force, we considered the current skin effect and the characteristics of electromagnetic loading and established a coupling model of “Electric–Ma...

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Bibliographic Details
Published in:Defence technology 2021-06, Vol.17 (3), p.846-858
Main Authors: Dou, Jian-hao, Jia, Xin, Huang, Zheng-xiang, Gu, Xiao-hui, Zheng, Ying-min, Ma, Bin, Xiao, Qiang-qiang
Format: Article
Language:English
Subjects:
Electromagnetic field
Numerical simulation
Shaped charge jet formation
Theoretical calculation
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Summary:The use of a shaped liner driven by electromagnetic force is a new means of forming jets. To study the mechanism of jet formation driven by electromagnetic force, we considered the current skin effect and the characteristics of electromagnetic loading and established a coupling model of “Electric–Magnetic–Force” and the theoretical model of jet formation under electromagnetic force. The jet formation and penetration of conical and trumpet liners have been calculated. Then, a numerical simulation of liner collapse under electromagnetic force, jet generation, and the stretching motion were performed using an ANSYS multiphysics processor. The calculated jet velocity, jet shape, and depth of penetration were consistent with the experimental results, with a relative error of less than 10%. In addition, we calculated the jet formation of different curvature trumpet liners driven by the same loading condition and obtained the influence rule of the curvature of the liner on jet formation. Results show that the theoretical model and the ANSYS multiphysics numerical method can effectively calculate the jet formation of liners driven by electromagnetic force, and in a certain range, the greater the curvature of the liner is, the greater the jet velocity is.
ISSN:2214-9147
2214-9147
DOI:10.1016/j.dt.2020.05.016