Experimental and simulation analysis of ferroresonance in single-phase transformers considering magnetic hysteresis effects

Ferroresonance is one of the most destructive and longest known power quality disturbances in the history of ac power systems. The undamped ferroresonant oscillations that occur between system capacitances and magnetizing inductances of transformer cores can cause severe damage and disruption to pow...

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Hauptverfasser:	Moses, Paul S, Masoum, Mohammad A S
Format:	Tagungsbericht
Sprache:	eng
Schlagworte:	Bifurcation Capacitance Ferroresonance Hysteresis Integrated circuit modeling Magnetic hysteresis Mathematical model nonlinear transformer power quality Transformer cores
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creator	Moses, Paul S Masoum, Mohammad A S
description	Ferroresonance is one of the most destructive and longest known power quality disturbances in the history of ac power systems. The undamped ferroresonant oscillations that occur between system capacitances and magnetizing inductances of transformer cores can cause severe damage and disruption to power networks. In this paper, ferroresonance in transformers is investigated with the aid of a nonlinear core model which includes magnetic hysteresis effects. Bifurcation and phase-plane analyses are applied to investigate the stability domain of ferroresonance. The impact of resulting ferroresonance modes on transformer voltages, core fluxes and magnetizing currents are shown in time-domain. Supporting measurements of ferroresonance are also provided for verifying model predictions of ferroresonance.
doi_str_mv	10.1109/PES.2010.5589666
format	Conference Proceeding
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subjects	Bifurcation Capacitance Ferroresonance Hysteresis Integrated circuit modeling Magnetic hysteresis Mathematical model nonlinear transformer power quality Transformer cores
title	Experimental and simulation analysis of ferroresonance in single-phase transformers considering magnetic hysteresis effects
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