{"title":"Applying Wavelet Transform to Ferroresonance Detection and Protection ","authors":"Chun-Wei Huang, Jyh-Cherng Gu, Ming-Ta Yang","volume":91,"journal":"International Journal of Electrical and Computer Engineering","pagesStart":1129,"pagesEnd":1137,"ISSN":"1307-6892","URL":"https:\/\/publications.waset.org\/pdf\/9998899","abstract":"
Non-synchronous breakage or line failure in power
\r\nsystems with light or no loads can lead to core saturation in
\r\ntransformers or potential transformers. This can cause component and
\r\ncapacitance matching resulting in the formation of resonant circuits,
\r\nwhich trigger ferroresonance. This study employed a wavelet
\r\ntransform for the detection of ferroresonance. Simulation results
\r\ndemonstrate the efficacy of the proposed method.<\/p>\r\n","references":"[1] A. I. Ibrahim, \"A Novel Approach for the Analysis of Power Systems\r\nTransients,\u201d Proc. of The 10th IEEE International Conference on\r\nElectronics, Circuits and Systems, Vol. 1. 14-17, pp. 368-371, Dec. 2003.\r\n[2] I. Daubechies, \"The Wavelet Transform, Time-frequency Localization\r\nand Signal Analysis,\u201d IEEE Trans. on Information Theory, Vol. 36, No. 5,\r\npp. 961-1005, Sep. 1990.\r\n[3] J. A. Martinez and B. A. Mork, \"Transformer Modeling for Low- and\r\nMid-frequency Transients - A Review,\u201d IEEE Trans. on Power Delivery,\r\nVol. 20, No. 2, pp. 1625-1632, Apr. 2005.\r\n[4] Boucherot, \"Existence de Deux R\u2019egimes en Ferroresonance,\u201d Rev. Gen.\r\nde L\u2019Elec., Vol. 8, No. 24, pp. 827-828, Dec. 1920.\r\n[5] R. Rudenberg, Transient Performance of Electric Power Systems,\r\nMcGraw-Hill, New York, ch. 48, 1950.\r\n[6] C. Hayashi, Nonlinear Oscillations in Physical Systems, McGraw-Hill,\r\nNew York, 1964.\r\n[7] J. G. Frame, N. Mohan and T. Liu, \"Hysteresis Modeling in an\r\nElectromagnetic Transients Program,\u201d IEEE Trans. on PAS, Vol.\r\nPAS-101, No. 9, pp. 3403-3411, Sep. 1982.\r\n[8] R. A. Walling, K. D. Barker, T. M. Compton and E. Zimmerman,\r\n\"Ferroresonant Overvoltage in Grounded Wye-wye Padmount\r\nTransformers with Low-loss Silicon-steel Cores,\u201d IEEE Trans. on Power\r\nDelivery, Vol. 8, No. 3, pp. 1647-1660, Jul. 1993.\r\n[9] L. A. Neves and W. Dommel, \"On Modeling Iron Core Nonlinearities,\u201d\r\nIEEE Trans. on Power System, Vol. 8, No. 2, pp. 417-425, May 1993.\r\n[10] A. Haar, \"Theorie der Orthogonalen Funkionen-systeme,\u201d\r\nMathematische Annalen, Vol. 69, pp. 331-371, 1910.\r\n[11] http:\/\/www.energy.siemens.com\/entry\/energy\/hq\/en\r\n[12] http:\/\/www.abb.com\/\r\n[13] Zhang Bo and Lu Tiecheng, \"On the Use of Wavelet Decomposition for\r\nFerroresonance Detection in Power System,\u201d Proc. Conference on Power\r\nand Energy Engineering, pp. 1-4, Mar. 2009.\r\n[14] J. Barros, M. De Apraiz, R. I. Diego, \"Measurement of Subharmonics in\r\nPower Voltages,\u201d Proc. of IEEE Conference on Power Tech, pp.\r\n1736-1740, Jul. 2007.\r\n[15] M. di Bernardo, F. Garofalo, L. Glielmo, F. Vasca, \"Quasi-periodic\r\nBehaviors in DC\/DC Converters,\u201d Proc. of The 27th IEEE Specialists\r\nConference on Power Electronics, Vol. 2, pp. 1376-1381, Jan. 1996.\r\n[16] E. H. Cayo and S. C. A. Alfaro, \"Welding Stability Assessment in the\r\nGMAW-S Process Based on Fuzzy Logic by Acoustic Sensing from Arc\r\nEmissions,\u201d Journal of Achievements in Materails and Manufacturing\r\nEngineering, Vol. 55, No. 1, Nov. 2012.\r\n[17] Fenghua Wang, Zhijian Jin and Zishu Zhu, \"Modeling and Prediction of\r\nElectric Arc Furnace Based on Neural Network and Chaos Theory,\u201d\r\nLecture Notes in Computer Science, Vol. 3498, pp. 819-826, 2005.","publisher":"World Academy of Science, Engineering and Technology","index":"Open Science Index 91, 2014"}