Title :
Effects of generator and static-load nonlinearities on electromechanical oscillations
Author :
Trudnowski, D.J. ; Dagle, J.E.
Author_Institution :
Montana Univ., Butte, MT, USA
fDate :
8/1/1997 12:00:00 AM
Abstract :
Linear analysis methods, such as eigenanalysis and Prony analysis, are becoming standard tools in studying power system electromechanical oscillations. Because the actual system is nonlinear, large-amplitude oscillatory swings will not necessarily have frequency and damping characteristics indicated by the eigensolution. Understanding the differences can be critical in comparing eigenanalysis and simulated results, and in applying Prony analysis to the nonlinear swings. This paper investigates the effects of excitation limiting, magnetic saturation, the swing equation, and static-load model properties on the linearity of a power swing. Simulation, eigenanalysis, and Prony analysis results are compared on a four-machine system operating under several conditions. It is found that significant differences occur between the eigenanalysis and simulation results when heavy excitation limiting occurs during the swing. Generator magnetic saturation tends to cause the simulated results to have more effective damping than the eigensolution. Other nonlinearities cause little or no differences. Prony analysis tends to match the simulated swing, except if excitation limiting occurs
Keywords :
damping; eigenvalues and eigenfunctions; electric generators; load (electric); power system stability; Prony analysis; damping characteristics; eigenanalysis; electromechanical oscillations; electromechanical stability; excitation limiting; four-machine system; frequency characteristics; generator magnetic saturation; generator nonlinearities; heavy excitation limiting; large-amplitude oscillatory swings; magnetic saturation; static-load model properties; static-load nonlinearities; Analytical models; Damping; Frequency; Magnetic analysis; Magnetic properties; Nonlinear equations; Power system analysis computing; Power system modeling; Power system simulation; Saturation magnetization;
Journal_Title :
Power Systems, IEEE Transactions on
