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FDTD Simulation of Induction Heating of Conducting Ceramic Ware

Published online by Cambridge University Press:  10 February 2011

Mikel J White ,
Magdy F. Iskander  and
Shane Bringhurst
Mikel J White
Affiliation:
University of Utah, Electrical Engineering Department, Salt Lake City, UT 84112
Magdy F. Iskander
Affiliation:
University of Utah, Electrical Engineering Department, Salt Lake City, UT 84112
Shane Bringhurst
Affiliation:
University of Utah, Electrical Engineering Department, Salt Lake City, UT 84112
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Abstract

Induction heating for the treatment of metals has been in commercial use since the mid 1960's. Traditional advantages of induction heating over the convection or radiation processes include speed of heating, possible energy savings, and the ability to customize the coil design to optimize the heating process. In this paper we used the Finite-Difference Time-Domain (FDTD) technique to simulate and analyze the induction heating process for highly conducting ceramics. In order to analyze frequency effects, simulations were performed at 300 kHz, 2 MHz, and 25 MHz. It is found that at higher frequencies coils with a pitch of 2″ or greater became capacitive and generate a large, axial, electric-field component. This new axial electric field, in addition to the normally encountered azimuthal field, causes an improvement in the uniformity of the power deposition in the ceramic sample. If the sample occupies a large portion of the coil, uniformity may also be improved by using a variable-pitch coil, or by extending the length of the coil a few turns beyond the length of the sample. In a production-line arrangement, where multiple sample are place inside the coil, it is shown that maximum uniformity is achieved when the samples are placed coaxially.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 430: Symposium O – Microwave Processing of Materials V , 1996 , 377
Copyright
Copyright © Materials Research Society 1996

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References

[1] Kim, W.B. and Na, S.J., Surface and Coatings Technology, Vol.58, pp. 129136, Feb. 1993.Google Scholar
[2] Lundin, R., Proceedings of the IEEE, Vol.73, No. 9, pp. 14281429, Sept. 1985.Google Scholar
[3] Wang, K.F., Chandrasekar, S., and Yang, T.Y., Journal of Mat. Eng. and Perf, Vol.1(1), pp. 97112, Feb 1992.Google Scholar
[4] Donea, J., Giuliani, S., and Philippe, A., Int. Jnl. for Num. Meth. in Eng., Vol.8, pp. 359367, Sept. 1974.Google Scholar
[5] Lavers, J.D., IEEE Trans. on Magnetics, Vol. MAG–19, No. 6, pp. 25662572, Nov. 1983.Google Scholar
[6] Fawzi, T.H., Ali, K.F., and Burke, P.E., IEEE Trans. on Mag., Vol. MAG–19, No.6, pp. 24012404, Nov. 1983.Google Scholar
[7] Tsuboi, H., Tanaka, M., Kobayashi, F., and Misaki, T., IEEE Trans. on Mag., Vol.29, No. 2, pp. 15741577, March 1993.Google Scholar