International Journal of Energy and Power Engineering
Volume 5, Issue 1-1, February 2016, Pages: 21-30
Received: Aug. 24, 2015;
Accepted: Aug. 25, 2015;
Published: Sep. 29, 2015
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Zhiguang Cheng, Institute of Power Transmission and Transformation Technology, Baobian Electric Co., Ltd, Baoding, China
Behzad Forghani, Infolytica Corporation, Place du Parc, Montreal, Canada
Yang Liu, Institute of Power Transmission and Transformation Technology, Baobian Electric Co., Ltd, Baoding, China; State Grid Smart Grid Research Institute, Beijing, China
Yana Fan, Institute of Power Transmission and Transformation Technology, Baobian Electric Co., Ltd, Baoding, China
Tao Liu, Institute of Power Transmission and Transformation Technology, Baobian Electric Co., Ltd, Baoding, China
Zhigang Zhao, School of Electrical Engineering, Hebei University of Technology, Tianjin, China
The modeling and numerical analysis of the magnetic loss inside components under multi-harmonic and/or DC-biasing excitations are increasingly of concern in large and special electromagnetic devices. This paper aims to investigate efficient and reliable approaches to determine the magnetic losses inside both the solid and laminated components under such extreme excitations. All the proposed approaches presented in the paper are experimentally validated.
Magnetic Loss Inside Solid and Laminated Components under Extreme Excitations, International Journal of Energy and Power Engineering. Special Issue: Numerical Analysis, Material Modeling and Validation for Magnetic Losses in Electromagnetic Devices.
Vol. 5, No. 1-1,
2016, pp. 21-30.
F. Fiorillo and A. Novikov, “An improved approach to power losses in magnetic laminations under nonsinusoidal induction waveform,” IEEE Trans. Magn., vol. 26, no.5, pp. 2904-2910, 1990.
T. Sasaki, S. Saiki, and S. Takada, "Magnetic losses of electrical iron sheets under ac magnetization superimposed with higher harmonics", IEEE Trans. J. Magn. Japan, vol. 7, no. 1, pp. 64-74, 1992.
E. Barbisio, F. Fiorillo, and C. Ragusa: “Predicting loss in magnetic steels under arbitrary induction waveform and with minor hysteresis loops”, IEEE Trans. Magn., vol. 40, no.4, pp.1810-1819, 2004.
X. Zhao, J. Lu, L. Li, Z. Cheng, et al, “Analysis of the DC bias phenomenon by the harmonic balance finite element method,” IEEE Trans. Power Delivery, vol.26. no.1, pp.475-485, 2011.
Y.Yao, C.Koh, G.Ni, and D.Xie, “3-D nonlinear transient eddy current, calculation of online power transformer under DC bias,” IEEE Trans. Magn., vol.41, no.5, pp.1840-1843, 2005.
T. Moses and J. Leicht, “Prediction and Measurement of losses under PWM Magnetisation conditions in electrical steels with different silicon content,” Journal of Applied Physics 97, 10R507 (2005).
IEC TR 62383, First edition 2006-01, Determination of magnetic loss under magnetic polarization waveforms including higher harmonic components. Measurement, modelling and calculation methods.
Z. Cheng, N. Takahashi, B. Forghani, G. Gilbert, J. Zhang, L. Liu, Y. Fan, X. Zhang, Y. Du, J. Wang, and C. Jiao, “Analysis and measurements of iron loss and flux inside silicon steel laminations,” IEEE Trans. Magn.,vo.45, no.3, pp.1222-1225, 2009.
Z. Cheng, N. Takahashi, B. Forghani, et al, “Effect of excitation patterns on both iron loss and flux in solid and laminated steel configurations,” IEEE Trans. Magn., vol.46, no.8, pp.3185-3188, 2010.
Y. Zhang, Z. Peng, D. Xie, and B. Bai, “Effect of different magnetization curves on simulation for transformer core loss under DC bias,” Trans., China Electrotechnical Society, vo.29, no.5, pp.43-48, 2014.
Z. Cheng, N. Takahashi, B. Forghani, Y. Du, Y. Fan, L. Liu, and H. Wang, “Effect of variation of B-H properties on both iron loss and flux in silicon steel lamination,” IEEE Trans. Magn., vol.47, no.5, pp.1346-1349, 2011.
Z. Cheng, N. Takahashi, B. Forghani, et al, “3-D finite element modeling and validation of power frequency multi-shielding effect,” IEEE Trans. Magn., vol.48, no.2, pp.243-246, 2012.
Z. Cheng, N. Takahashi, B. Forghani, et al, “Electromagnetic and Thermal Field Modeling and Application in Electrical Engineering,” (in Chinese), ISBN 978-7-03-023561-9, Science Press, Beijing, 2009.
IEC 60404-6, Magnetic materials- Part 6: Methods of measurement of the magnetic properties of magnetically soft metallic and powder materials at frequencies in the range 20 Hz to 200 kHz by the use of ring specimens.
TEAM Benchmark Problems (no.1-n0.34) [on line] available: www.compumag.org/team.
Z. Cheng, N. Takahashi, B. Forghani, L. Liu, Y. Fan, T. Liu, Q.Hu, S. Gao, J. Zhang, and X. Wang, “Extended progress in TEAM Problem 21 family,” COMPEL, 33, 1/2, pp.234-244, 2014.
Z. Cheng, B. Forghani, D. Lowther, Y. Liu, Z. Zhao, T. Liu, Y. Fan, and G. Han, "Stray-field loss modeling under hybrid excitation in smoothing reactors", presented at 20th international Conference on the Computation of Electromagnetic Fields(Compumag), June 28-July 2, 2015, Montreal, Canada.
Z. Cheng, N. Takahashi, B. Forghani, A. Moses, P. Anderson, Y. Fan, T. Liu, X. Wang, Z. Zhao, and L. Liu, “Modeling of magnetic properties of GO electrical steel based on Epstein combination and loss data weighted processing,” IEEE Trans. Magn., vol.50, no.1, 6300209, 2014.