Improved Core-Loss Calculation for Magnetic Components Employed in Power Electronic Systems

Abstract

In modern power electronic systems, voltages across inductors or transformers generally show rectangular shapes, including periods of zero voltage. In the stage of zero applied voltage (constant flux), core losses are not necessarily zero. At the beginning of a period of constant flux, losses still occur in the material. This is due to relaxation processes. A physical explanation about magnetic relaxation is given and a new core-loss modeling approach that takes relaxation effects into consideration is introduced. The new loss model is called improved-improved generalized Steinmetz equation and it has been verified experimentally.

References

Page 1

	Year	Citations
Accurate prediction of ferrite core loss with nonsinusoidal waveforms using only Steinmetz parameters K. Venkatachalam, Charles R. Sullivan, T. Ben Abdallah, Steinmetz ParametersElectrical EngineeringFerrite Core LossEngineeringFlux Trajectory	2003	1.1K
Calculation of losses in ferro- and ferrimagnetic materials based on the modified Steinmetz equation J. Reinert, A. Brockmeyer, R.W.A.A. De Doncker IEEE Transactions on Industry Applications Magnetic PropertiesElectric MachineEngineeringPower ElectronicsDynamic Hysteresis Model	2001	646
Soft Ferrites—Properties and Applications F. Brailsford Electronics and Power MagnetismFerromagnetismElectrical EngineeringMagnetic PropertiesEngineering	1970	616
Improved calculation of core loss with nonsinusoidal waveforms Jieli Li, T. Ben Abdallah, Charles R. Sullivan Magnetic PropertiesNew FormulationEngineeringSpectrum EstimationMagnetic Materials	2002	513
Accurate Power Loss Model Derivation of a High-Current Dual Active Bridge Converter for an Automotive Application Florian Krismer, Johann W. Kolar IEEE Transactions on Industrial Electronics Electrical EngineeringEngineeringEnergy ManagementEnergy EfficiencyPower Electronics Converter	2009	450
Calculation of losses in ferro- and ferrimagnetic materials based on the modified Steinmetz equation J. Reinert, A. Brockmeyer, Rik W. De Doncker Magnetic PropertiesElectric MachineEngineeringPower ElectronicsDynamic Hysteresis Model	2003	406
A Practical, Accurate and Very General Core Loss Model for Nonsinusoidal Waveforms W.A. Roshen IEEE Transactions on Power Electronics Electric MachineEngineeringPower Electronics ConverterSpectrum EstimationElectric Power Conversion	2007	227
Summary of losses in magnetic materials John B. Goodenough IEEE Transactions on Magnetics Magnetic PropertiesEngineeringMagnetic ResonanceMagnetic MaterialsMagnetoresistance	2002	190
Impact of Power Density Maximization on Efficiency of DC–DC Converter Systems J. Biela, U. Badstuebner, Johann W. Kolar IEEE Transactions on Power Electronics EngineeringPower EngineeringEnergy EfficiencyEnergy ConversionPower Density Maximization	2009	181
Global Loss Evaluation Methods for Nonsinusoidally Fed Medium-Frequency Power Transformers Irma Villar, U. Viscarret, Ion Etxeberria‐Otadui, IEEE Transactions on Industrial Electronics Electrical EngineeringPower EngineeringEngineeringConversion SystemsEnergy Efficiency	2009	181

Page 1