Title :
AC resistance of planar power inductors and the quasidistributed gap technique
Author :
Hu, Jiankun ; Sullivan, Charles R.
Author_Institution :
Agere Syst., Allentown, PA, USA
fDate :
7/1/2001 12:00:00 AM
Abstract :
Low-AC-resistance planar or foil-wound inductors constructed using a quasidistributed gap comprising multiple small gaps that approximate a distributed gap are analyzed. Finite-element simulations are used systematically to develop a model broadly applicable to the design of such quasidistributed gap inductors. It is shown that a good approximation of a distributed gap is realized if the ratio of gap pitch to spacing between gap and conductor is less than four, or if the gap pitch is comparable to a skin depth or smaller. Large gaps can reduce AC resistance, but for most practical designs gap length has little effect. A closed-form expression, which closely approximates the AC resistance factor for a wide range of designs, is developed. The methods are illustrated with an inductor for a high-ripple-current fast-response voltage regulator module (VRM) for microprocessor power delivery
Keywords :
air gaps; coils; computer power supplies; electric resistance; finite element analysis; inductors; voltage control; voltage regulators; AC resistance; closed-form expression; eddy currents; finite-element simulations; foil-wound inductors; fringing effects; gap length; gap pitch; high-ripple-current fast-response voltage regulator module; low-AC-resistance planar inductors; magnetic devices; microprocessor power delivery; multiple small gaps; planar power inductors; power conversion; proximity effect; quasidistributed gap technique; skin depth; voltage regulator modules; Conducting materials; Conductors; Eddy currents; Finite element methods; Inductors; Load flow; Load flow analysis; Permeability; Power system modeling; Regulators;
Journal_Title :
Power Electronics, IEEE Transactions on
