Title :
Experimental investigation of high-flux density magnetic materials for high-current inductors in hybrid-electric vehicle DC-DC converters
Author :
Rylko, Marek S. ; Hayes, John G. ; Egan, Michael G.
Author_Institution :
Univ. Coll. Cork, Cork, Ireland
Abstract :
High-flux-density materials, such as iron-based amorphous metal and 6.5% silicon steel for gapped inductors, and powdered alloys for gapless inductors, are very competitive for high-power-density inductors. The high-flux-density materials lead to low weight/volume solutions for high-power dc-dc converters used in hybrid-electric and electric vehicles. In this paper, the practical effects of frequency, dc bias, flux-density de-rating, the duty cycle, air-gap fringing on the core and winding, and thermal configuration based on lamination direction are investigated for iron-based amorphous metal, 6.5% silicon steel and iron-based powdered alloy material. A 2.5 kW converter is built to verify the optimum material selection and thermal configuration. Analytical, simulation, and experimental results are presented.
Keywords :
DC-DC power convertors; hybrid electric vehicles; magnetic materials; power inductors; air-gap fringing; dc bias; duty cycle; flux-density derating; gapless inductors; gapped inductors; high-current inductors; high-flux density magnetic materials; high-power dc-dc converters; hybrid-electric vehicles; iron-based amorphous metal; iron-based powdered alloy material; lamination direction; optimum material selection; power 2.5 kW; silicon steel; thermal configuration; Inductors; Magnetic cores; Silicon; Steel; Windings; Materials comparison; distributed gap effect; frequency effect; thermal configuration;
Conference_Titel :
Vehicle Power and Propulsion Conference (VPPC), 2010 IEEE
Conference_Location :
Lille
Print_ISBN :
978-1-4244-8220-7
DOI :
10.1109/VPPC.2010.5729214
