Title :
CCTT-Core Split-Winding Integrated Magnetic for High-Power DC–DC Converters
Author :
Hartnett, Kevin ; Hayes, John G. ; Egan, Michael G. ; Rylko, Marek S.
Author_Institution :
Power Electron. Res. Lab., Univ. Coll. Cork, Cork, Ireland
Abstract :
A novel CCTT-core split-winding integrated magnetic (IM) structure is presented in this paper. The IM device is optimized for use in high-power dc-dc converters. The IM structure uses a split-winding configuration which allows for the reduction of external leakage inductance, which is a problem for many IM designs. Magnetic poles are incorporated to help shape and contain the leakage flux within the core window. Low-cost and low-power loss ferrite is used which results in a very efficient design. An IM reluctance model is developed which uses fringing equations to develop a more accurate design. An IM design algorithm is developed and implemented in Mathematica for design and optimization. FEA and experimental results from a 72 kW, (155-V dc, 465-A dc input, and 420-V dc output) prototype validate the new IM concept. The 72 kW CCTT- core IM was shown to be 99.7% efficient at full load.
Keywords :
DC-DC power convertors; finite element analysis; magnetic structure; mathematics computing; power engineering computing; symbol manipulation; CCTT-core split-winding integrated magnetic structure; FEA; IM design algorithm; Mathematica; current 465 A; efficiency 99.7 percent; external leakage inductance reduction; fringing equations; high-power dc-dc converters; low-power loss ferrite; magnetic poles; power 72 kW; reluctance model; voltage 155 V; voltage 420 V; Inductance; Magnetic cores; Magnetic flux; Magnetic noise; Magnetic shielding; Magnetic switching; Windings; Coupled inductor; dc–dc Converter; integrated magnetic; magnetic design;
Journal_Title :
Power Electronics, IEEE Transactions on
DOI :
10.1109/TPEL.2013.2240394
