Title :
Viscosity-based magnetodynamic model of soft magnetic materials
Author :
Zirka, Sergey E. ; Moroz, Yury I. ; Marketos, Philip ; Moses, Anthony J.
Author_Institution :
Dept. of Appl. Phys. & Technol., Dnepropetrovsk Nat. Univ.
Abstract :
A time-stepping method based on the concept of magnetic viscosity developed to reproduce the excess loss in electrical steel is proposed. A numerical scheme for simultaneous solution of Maxwell equations and equations describing the magnetic viscosity has been developed. The method is suitable for describing arbitrary magnetization regimes such as waveforms associated with pulsewidth modulation (PWM) voltage excitation, and the model differential equations can be conveniently combined with equations of an external electric circuit. The accuracy of the proposed dynamic model is shown using three nonoriented electrical steel as examples. Fitting of the magnetic viscosity parameters for one sinusoidal flux regime enables dynamic hysteresis loops and losses to be predicted with high accuracy over a wide range of frequencies and amplitudes of sinusoidal or nonsinusoidal flux densities
Keywords :
Maxwell equations; eddy current losses; finite difference time-domain analysis; magnetic aftereffect; magnetic hysteresis; magnetic leakage; soft magnetic materials; viscosity; Maxwell equations; finite-difference time-domain analysis; magnetic hysteresis; magnetic losses; magnetic viscosity; pulsewidth modulation voltage excitation; soft magnetic materials; time-stepping method; viscosity-based magnetodynamic model; Differential equations; Magnetic flux; Magnetization; Maxwell equations; Pulse circuits; Pulse width modulation; Soft magnetic materials; Space vector pulse width modulation; Steel; Viscosity; Finite-difference time-domain analysis; magnetic hysteresis; magnetic losses; soft magnetic materials;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2006.880685
