Authors: M. H. Mohammadi Sanjani, A. Oraee, M. Fotuhi-Firuzabad, A. Amirnia, A. Taheri, M. Arabi

Abstract:

Ferroresonance effects cause overvoltage in medium voltage transformers and isolators used in electrical networks. Ferroresonance effects are nonlinear and occur between the network capacitor and the nonlinear inductance of the voltage transformer during saturation. This phenomenon is unwanted for transformers since it causes overheating, introduction of high dynamic forces in primary coils, and rise of voltage in primary coils for the voltage transformer. Furthermore, it results in electrical and thermal failure of the transformer. Expansion of distribution lines, design of the transformer in smaller sizes, and the increase of harmonics in distribution networks result in an increase of ferroresonance. There is limited literature available to improve the effects of ferroresonance; therefore, optimizing its effects for voltage transformers is of great importance. In this study, comprehensive modeling of a medium voltage transformer is performed. In addition, a model is proposed to improve the performance of voltage transformers during the occurrence of ferroresonance using damping oscillations. Also, transformer design optimization is presented in this study to show further improvements in the performance of the voltage transformer. The proposed model is experimentally tested and verified on a medium voltage transformer in the laboratory, and simulation results show a large reduction of the effects of ferroresonance.

Keywords: Optimization, voltage transformer, ferroresonance, damper.

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References:

[1] Heidary, A. and H. Radmanesh, Smart solid‐state ferroresonance limiter for voltage transformers application: principle and test results. IET Power Electronics, 2018. 11(15): p. 2545-2552.
[2] Piasecki, W., et al., Mitigating ferroresonance in voltage transformers in ungrounded MV networks. IEEE Transactions on Power Delivery, 2007. 22(4): p. 2362-2369.
[3] Radmanesh, H., et al., Dual function ferroresonance and fault current limiter based on DC reactor. IET Generation, Transmission & Distribution, 2016. 10(9): p. 2058-2065.
[4] Khan, S.A., et al. Analysis of ferroresonance suppression and transient response performances for various ferroresonance suppression circuits in capacitive voltage transformers. in 3rd IET International Conference on Clean Energy and Technology (CEAT) 2014. 2014. IET.
[5] Heidary, A., et al., Voltage transformer ferroresonance: an inhibitor device. IEEE Transactions on Power Delivery, 2020. 35(6): p. 2731-2733.
[6] E. Bayona, F. Azcondo, C. Branas, J. Diaz, R. Martinez, M.Manana, R. Minguez, J. I. Rodriguez, and A. Pigazo,"Electronic resistor emulators for ferroresonance damping in MV transformers," IET Renewable Power Generation, vol. 13,no. 1, pp. 201-208, Jan. 2019
[7] Rezaei-Zare, A., Iravani, R., Sanaye-Pasand, M.: ‘Impacts of transformer core hysteresis formation on stability domain of ferroresonance modes’, IEEE Trans. Power Deliv., 2009, 24, (1), pp. 177–186
[8] Xukai, Z., Yihan, Y., Hongbo, L., et al.: ‘Study on ferroresonance due to electromagnetic PT in ungrounded neutral system’. Int. Conf. on Power System Technology, 2004, vol. 1, pp. 924–929
[9] Kang, Y.C., Lee, B.E., Zheng, T.Y., et al.: ‘Analytical analysis of PT ferroresonance in the transient-state’. Tenth IET Int. Conf. on Developments in Power System Protection (DPSP 2010): Managing the Change, 29 March– 1 April 2010, pp. 1–5.