Title :
Dynamic electrical-magnetic-thermal simulation of magnetic components
Author :
Wilson, Peter R. ; Ross, J. Neil ; Brown, Andrew D.
Author_Institution :
Dept. of Electron. & Comput. Sci., Southampton Univ., UK
Abstract :
This paper describes how the modeling and simulation of electromagnetic devices can be extended to include dynamic thermal effects. The power generated by hysteresis inside ferrite cores is connected to a thermal model of the core material. The thermal conduction of the core material is modeled as is the convection of thermal energy from the core to the surrounding environment. The effective temperature change inside the core is used to modify the parameters of the core material model to accurately reflect the dynamic performance of the device at all temperatures. The electrical circuit, magnetic material and thermal networks are all modeled concurrently in the time domain to allow dynamic interactions across all three domains
Keywords :
circuit simulation; convection; ferrite devices; heat conduction; magnetic cores; magnetic hysteresis; magnetic materials; thermal analysis; time-domain analysis; Jiles-Atherton model; circuit simulators; core material; core material model; dynamic electrical-magnetic-thermal simulation; dynamic interactions; dynamic performance; dynamic thermal effects; electrical circuit; electromagnetic devices; ferrite cores; hysteresis; magnetic components; magnetic material; modeling; power generation; temperature change; thermal conduction; thermal energy convection; thermal model; thermal networks; time domain modelling; Conducting materials; Electromagnetic devices; Electromagnetic modeling; Ferrites; Magnetic cores; Magnetic hysteresis; Magnetic materials; Power generation; Temperature; Thermal conductivity;
Conference_Titel :
Computers in Power Electronics, 2000. COMPEL 2000. The 7th Workshop on
Conference_Location :
Blacksburg, VA
Print_ISBN :
0-7803-6561-5
DOI :
10.1109/CIPE.2000.904732
