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Abstract

The long-life driving coil is the prerequisite for electromagnetic forming industrial application. Up to date, the temperature rise is one of the major factors that restrain its working life. For the purpose of reducing the temperature rise of the driving coil, this paper proposes a new coupled cooling method, in which an extra cooling coil is placed on one side of the driving coil, then the Joule heating is coupledly transferred by delaying the breakover control of the driving coil. To achieve this purpose, a finite element simulation model of Electrical Circuit- Electromagnetic Field-Thermal Coupling in the plates setting of the electromagnetic forming is established, after which the influence rules of coil turns, cross-sectional area and materials of cooling coil on temperature rise are analyzed. Then, this paper also establishes a coupled cooling circuit model, in which the influence of cooling coil structure parameters on the Joule heating of driving coil is analyzed. Furthermore, Simulation results show that effective Joule heating transfer can be reached by the best optimization scheme of the cooling driving coil. Specifically, the average temperature rise reduces by 13 degrees, namely 22.8% by using this new method.

Keywords

Electromagnetic forming driving coil temperature rise Joule heating

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References

Xiong

Tang

H.T.

Deng

C.Z.

and Qiu

, Electromagnetic attraction-based bulge forming in small tubes: Fundamentals and simulations, IEEE Transactions on Applied Superconductivity 28(3) (2018), 0600505.

Qiu

Y.J

Nie

X.P.

Yang

Y.Q.

and Su

, Study on material deformation performance and electromagnetic force loading in electromagnetic tube expansion process, Transactions on China Electrotechnical Society 34(2) (2019), 212–218.

Qiu

Y.J.

Yang

Y.Q.

Nie

X.P.

Xiao

Ning

Wang

F.Z.

and Cao

, Analysis of electromagnetic force and experiments in electromagnetic forming with local loading, International Journal of Applied Electromagnetics and Mechanics 57(1) (2018), 29–37.

Lai

Z.P.

Cao

Q.L.

Han

X.T.

Huang

Y.J.

Deng

F.X.

Chen

and Li

, Investigation on plastic deformation behavior of sheet workpiece during radial Lorentz force augmented deep drawing process, Journal of Materials Processing Technology 245 (2017), 193–206.

Xiong

Huang

Xia

L.Y.

, A research based on advance dual-coil electromagnetic forming method on flanging of small-size tubes, The International Journal of Advanced ManuFacturing Technology (2019), 1–8.

Qiu

Xiao

Deng

C.Z.

, Electromagnetic-structural analysis and improved loose coupling method in electromagnetic forming process, International Journal of Advanced Manufacturing Technology 89 (2017), 701–710.

Qiu

Y.T.

Xiong

and Li

, Study on electromagnetic problems in electromagnetic forming process, Transactions on China Electrotechnical Society 34(11) (2019), 2247–2259.

Qiu

Y.J.

Xiong

Deng

C.Z.

Cao

Q.L.

Han

X.T.

and Li

, Analysis of electromagnetic force and deformation behavior in electromagnetic tube expansion with concave coil based on finite element method, IEEE Transactions on Applied Superconductivity 28(3) (2018), 0600705.

Qiu

Y.J.

Xiong

Deng

C.Z.

and Li

, Analysis of electromagnetic force and deformation behavior in electromagnetic forming with different coil systems, International Journal of Applied Electromagnetics and Mechanics 57(3) (2018), 337–345.

10.

Qiu

, Electromagnetic force distribution and deformation homogeneity of electromagnetic tube expansion with a new concave coil structure, IEEE Access 7 (2019), 117107–117114.

11.

Qiu

, Numerical and experimental investigation in electromagnetic tube expansion with axial compression, The International Journal of Advanced Manufacturing Technology 104(5–8) (2019), 3045–3051.

12.

, A new vibration testing platform for electronic current transformers, IEEE Transactions on Instrumentation and Measurement 68(3) (2019), 704–712.

13.

Cao

Q.L.

Han

X.T.

Lai

Z.P.

, Analysis and reduction of coil temperature rise in electromagnetic forming, Journal of Materials Processing Technology 225 (2015), 185–194.

14.

Gies

Löbbe

Weddeling

and Tekkaya

A.E.

, Thermal loads of working coils in electromagnetic sheet metal forming, Journal of Materials Processing Technology 214(11) (2014), 2553–2565.

15.

Abu-Siada

and Zhang

, A new online temperature compensation technique for electronic instrument transformers, IEEE Access 2019:97614–97623.

16.

Golovashchenko

, Material formability and coil design in electromagnetic forming, J. Mater. Eng. Perform. 16(3) (2007), 314–320.

17.

Ouyang

, Investigation of the electromagnetic attractive forming utilizing a dual-coil system for tube bulging, Journal of Manufacturing Processes 49 (2020), 102–115.

18.

Cao

Q.L.

L.M.

Z.Z.

, Investigation of the Lorentz-force-driven sheet metal stamping process for cylindrical cup forming, Journal of Materials Processing Technology 271 (2019), 532–541.

19.

Cao

Q.L.

Z.H.

Lai

Z.P.

, Analysis of the effect of an electrically conductive die on electromagnetic sheet metal forming process using the finite element-circuit coupled method, The International Journal of Advanced Manufacturing Technology 101 (2019), 549–563.

20.

Cao

Q.L.

Lai

Z.P.

Xiong

, Electromagnetic attractive forming of sheet metals by means of a dual-frequency discharge current: Design and implementation, International Journal of Advanced Manufacturing Technology 90(1–4) (2017), 309–316.

21.

Huang

, Effect of equivalent radius of drive coil on forming depth in electromagnetic sheet free bulging, International Journal of Applied Electromagnetics and Mechanics 61 (2019), 377–389.

Analysis of coil temperature rise in electromagnetic forming with coupled cooling method

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