Title :
Inductor Geometry With Improved Energy Density
Author :
Han Cui ; Ngo, Khai D. T. ; Moss, Jim ; Lim, Michele Hui Fern ; Rey, Ernesto
Author_Institution :
Bradley Dept. of Electr. & Comput. Eng., Virginia Tech, Blacksburg, VA, USA
Abstract :
The “constant-flux” concept is leveraged to achieve high magnetic-energy density, leading to inductor geometries with height significantly lower than that of conventional products. Techniques to shape the core and to distribute the winding turns to shape a desirable field profile are described for the two basic classes of magnetic geometries: those with the winding enclosed by the core and those with the core enclosed by the winding. A relatively constant flux distribution is advantageous not only from the density standpoint, but also from the thermal standpoint via the reduction of hot spots, and from the reliability standpoint via the suppression of flux crowding. In this journal paper on a constant-flux inductor (CFI) with enclosed winding, the foci are operating principle, dc analysis, and basic design procedure. Prototype cores and windings were routed from powder-iron disks and copper sheets, respectively. The design of CFI was validated by the assembled inductor prototype.
Keywords :
inductors; magnetic cores; reliability; windings; CFI design; assembled inductor prototype; constant-flux concept; constant-flux inductor; copper sheets; dc analysis; design procedure; enclosed winding; field profile; flux crowding suppression; high magnetic-energy density; hot spot reduction; improved energy density; inductor geometry; magnetic geometries; powder-iron disks; prototype cores; relative constant flux distribution; reliability standpoint; thermal standpoint; winding turn distribution; Inductance; Inductors; Magnetic cores; Magnetic flux; Permeability; Resistance; Windings; Constant-flux; high energy density; inductor; low profile; uniform flux distribution;
Journal_Title :
Power Electronics, IEEE Transactions on
DOI :
10.1109/TPEL.2013.2289926
