Title :
Inductor design for high-power applications with broad-spectrum excitation
Author :
Wallace, Ian T. ; Kutkut, Nasser H. ; Bhattacharya, Subhashish ; Divan, Deepak M. ; Novotny, Donald W.
Author_Institution :
Soft Switching Technol., Middleton, WI, USA
fDate :
1/1/1998 12:00:00 AM
Abstract :
The design of high-power inductors for applications with broad current spectrum excitation is a challenging task. The resonant inductor of a resonant DC-link inverter (RDCLI) is one such example. The inductor current consists of a resonant current component, a DC component, which supplies the active power to the load and a modulation component, which depends on the modulation strategy. In addition, the frequency and amplitude of the dominant current components change with operating point. Conventional inductor designs for single-frequency excitation do not perform well in broad-spectrum applications. In order to improve these designs, the impact of broad current spectrums on winding design, core selection, power density, and thermal-handling capability must be investigated. In this paper, alternate inductor topologies, which better address the above issues, are proposed and investigated
Keywords :
finite element analysis; inductors; invertors; resonant power convertors; windings; active power; alternate inductor topologies; broad current spectrums; broad-spectrum excitation; core selection; dominant current components; finite element analysis; high frequency magnetics; inductor design; inductor designs; modulation strategy; power density; resonant DC-link inverter; resonant current component; resonant inductor; single-frequency excitation; thermal-handling capability; winding design; Frequency; Inductors; Magnetic cores; Power harmonic filters; Pulse width modulation; Pulse width modulation inverters; Resonance; Topology; Wire; Wounds;
Journal_Title :
Power Electronics, IEEE Transactions on
