Title :
Computationally efficient winding loss calculation with multiple windings, arbitrary waveforms, and two-dimensional or three-dimensional field geometry
Author :
Sullivan, Charles R.
Author_Institution :
Thayer Sch. of Eng., Dartmouth Coll., Hanover, NH, USA
fDate :
1/1/2001 12:00:00 AM
Abstract :
The squared-field-derivative method for calculating eddy-current (proximity-effect) losses in round-wire or litz-wire transformer and inductor windings is derived. The method is capable of analyzing losses due to two-dimensional and three-dimensional field effects in multiple windings with arbitrary waveforms in each winding. It uses a simple set of numerical magnetostatic field calculations, which require orders of magnitude less computation time than numerical eddy-current solutions, to derive a frequency-independent matrix describing the transformer or inductor. This is combined with a second, independently calculated matrix, based on derivatives of winding currents, to compute total AC loss. Experiments confirm the accuracy of the method
Keywords :
eddy current losses; electromagnetic fields; finite element analysis; matrix algebra; skin effect; transformers; windings; 2-D field geometry; 3-D field geometry; arbitrary waveforms; eddy-current losses; frequency-independent matrix; inductor windings; litz-wire transformer windings; multiple windings; numerical magnetostatic field calculations; proximity-effect losses; round-wire transformer windings; squared-field-derivative method; total AC loss; transformer winding loss calculation; Computational geometry; Conductors; Finite element methods; Frequency; Inductors; Magnetic analysis; Magnetic devices; Magnetostatic waves; Power conversion; Power transformers;
Journal_Title :
Power Electronics, IEEE Transactions on
