Generation of matrix-reactance frequency converters based on unipolar PWM AC matrix-reactance choppers

This paper deals with three-phase direct matrix- reactance frequency converters (MRFC) based on unipolar PWM AC matrix-reactance choppers (MRC). The topologies of the proposed MRFC are based on a three- phase unipolar MRC structure. Each MRC with conventional topology has two synchronous-connected switches [SCS] sets. In the MRFC, unlike the MRC topology, one of SCS sets is replaced by a matrix-connected switches (MCS) set in order to make possible of the load voltage frequency change. Six new topologies of the MRFC based on MRC boost, buck-boost, Cuk, Zeta or SEPIC structures are presented. Through the generation concept of the proposed converters both the description of above- mentioned converter topologies and general description of the control strategies are presented. The structure of the proposed MRFC contains a three-phase matrix converter (MC), which is introduced instead of the source or load SCS used in unipolar MRC. The step-down or step-up of the MC set is dependent on the input and output voltage or current source configurations. Analysis determining the location where the MC should be introduced is realized by means of the one-cycle switched models with suitable voltage and current sources introduced instead of the capacitors and inductors respectively. Furthermore, exemplary results of the simplified theoretical analysis, based on the averaged state space method, as well as simulation test results obtained for a classical Venturini control strategy of MC, are also presented as an initial verification of the properties of the proposed converters.

[1]  Luca Zarri,et al.  Matrix converter modulation strategies: a new general approach based on space-vector representation of the switch state , 2002, IEEE Trans. Ind. Electron..

[2]  D. Borojevic,et al.  Space vector modulated three-phase to three-phase matrix converter with input power factor correction , 1995 .

[3]  J.W. Kolar,et al.  Novel Three-Phase AC–AC Sparse Matrix Converters , 2007, IEEE Transactions on Power Electronics.

[4]  Slobodan Cuk,et al.  A general unified approach to modelling switching-converter power stages , 1976, 1970 IEEE Power Electronics Specialists Conference.

[5]  Z. Fedyczak,et al.  Steady and transient state analysis of a matrix-reactance frequency converter based on a boost PWM AC matrix-reactance chopper , 2008, 2008 International School on Nonsinusoidal Currents and Compensation.

[6]  G. Cho,et al.  Analyses of static and dynamic characteristics of practical step-up nine-switch matrix convertor , 1993 .

[7]  Frede Blaabjerg,et al.  Evaluation of modulation schemes for three-phase to three-phase matrix converters , 2004, IEEE Transactions on Industrial Electronics.

[8]  Marco Venturini,et al.  The generalised transformer: A new bidirectional, sinusoidal waveform frequency converter with continuously adjustable input power factor , 1980, 1980 IEEE Power Electronics Specialists Conference.

[9]  Zbigniew Fedyczak,et al.  Matrix-Reactance Frequency Converter Based on Buck-Boost Topology , 2006, 2006 12th International Power Electronics and Motion Control Conference.

[10]  Seung-Ki Sul,et al.  Carrier-Based Modulation Technique for Matrix Converter , 2006, IEEE Transactions on Power Electronics.

[11]  Z. Fedyczak,et al.  Modelling and analysis of a matrix-reactance frequency converter based on buck-boost topology by DQ0 transformation , 2008, 2008 13th International Power Electronics and Motion Control Conference.

[12]  Zbigniew Fedyczak,et al.  Steady‐state modelling of basic unipolar PWM AC line matrix‐reactance choppers , 2005 .

[13]  José R. Rodríguez,et al.  Matrix converters: a technology review , 2002, IEEE Trans. Ind. Electron..

[14]  Patrick Wheeler,et al.  Analysis and comparison of AC-AC matrix converter control strategies , 2003, IEEE 34th Annual Conference on Power Electronics Specialist, 2003. PESC '03..