Title :
A two-factor saturation model for synchronous machines with multiple rotor circuits
Author :
Tahan, S.-A. ; Kamwa, I.
Author_Institution :
Dept. de Genie Electr., Laval Univ., Que., Canada
fDate :
12/1/1995 12:00:00 AM
Abstract :
It is generally felt that no major accuracy breakthrough in predicting the steady-state and transient performance of synchronous machines could be achieved without taking proper account of the iron saturation effects as well as eddy-current losses. Although the two issues were often treated separately in the past, this paper attempts to unite them by developing a general model covering both the main-path magnetic saturation and frequency effects in the dynamic equations. Mathematical analysis in the d-q space pinpoints cross-saturation coupling which, a priori, does not seem to be symmetrical for salient-pole machines. Yet the model is theoretically sound, since it fulfils at least the physical constraints using energy balance principles. Some test points from a 555-MVA turbine-generator are used for an initial assessment the model´s capability to predict the field current and internal angle for various loading conditions
Keywords :
eddy current losses; eddy currents; losses; machine theory; rotors; synchronous generators; transient analysis; turbogenerators; 555 MVA; cross-saturation coupling; d-q space; dynamic equations; eddy-current losses; energy balance principles; field current prediction; frequency effects; internal angle prediction; main-path magnetic saturation; mathematical analysis; multiple rotor circuits; steady-state performance; synchronous machines; transient performance; turbine-generator; two-factor saturation model; Accuracy; Equations; Frequency; Iron; Magnetic separation; Mathematical analysis; Performance loss; Saturation magnetization; Steady-state; Synchronous machines;
Journal_Title :
Energy Conversion, IEEE Transactions on
