Title :
Comments, with reply, on "Parallel resonant converter with LLC-type commutation
Author :
Hamill, D.C. ; Lee, C.Q. ; Liu, Richard
Author_Institution :
Dept. of Electron. & Electr. Eng., Surrey Univ., Guildford, UK
fDate :
5/1/1991 12:00:00 AM
Abstract :
In a recent paper by C.Q. Lee et al. (ibid., vol.25, no.6, p. 844-7, Nov. 1989), the authors analyzed a DC-DC converter that they termed the LLC-type PRC (parallel resonant converter). Its resonant network contains three active components-two inductances and a parallel capacitance-and as a consequence the converter might be expected to have third-order dynamics. But Lee et al. employed a matrix transformation to show that the behavior of the circuit may be represented as a state-plane trajectory, as for a second-order circuit. The purpose of this contribution is to show that the converter has a zero-frequency eigenvalue, associated with undesirable circulating DC. The second-order dynamics exhibited by the third-order converter are explained by an application of Thevenin´s theorem. Some aerospace applications of the LLC-type parallel resonant converter (PRC) are discussed. In their reply, the authors show that the circulating direct current does not exist in the practical converter circuit.<>
Keywords :
circuit resonance; commutation; network analysis; power convertors; DC-DC converter; LLC-type commutation; Thevenin´s theorem; active components; aerospace applications; circulating direct current; matrix transformation; parallel capacitance; parallel resonant converter; second-order circuit; state-plane trajectory; third-order dynamics; zero-frequency eigenvalue; Aerodynamics; Eigenvalues and eigenfunctions; Equations; Equivalent circuits; Inductance; Inductors; Matrix converters; Partial response channels; Power transformer insulation; Resonance;
Journal_Title :
Aerospace and Electronic Systems, IEEE Transactions on
