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http://dx.doi.org/10.6113/JPE.2015.15.1.190

Modeling and Direct Power Control Method of Vienna Rectifiers Using the Sliding Mode Control Approach  

Ma, Hui (School of Electrical Power, South China University of Technology)
Xie, Yunxiang (School of Electrical Power, South China University of Technology)
Sun, Biaoguang (School of Electrical Power, South China University of Technology)
Mo, Lingjun (School of Electrical Power, South China University of Technology)
Publication Information
Journal of Power Electronics / v.15, no.1, 2015 , pp. 190-201 More about this Journal
Abstract
This paper uses the switching function approach to present a simple state model of the Vienna-type rectifier. The approach introduces the relationship between the DC-link neutral point voltage and the AC side phase currents. A novel direct power control (DPC) strategy, which is based on the sliding mode control (SMC) for Vienna I rectifiers, is developed using the proposed power model in the stationary ${\alpha}-{\beta}$ reference frames. The SMC-based DPC methodology directly regulates instantaneous active and reactive powers without transforming to a synchronous rotating coordinate reference frame or a tracking phase angle of grid voltage. Moreover, the required rectifier control voltages are directly calculated by utilizing the non-linear SMC scheme. Theoretically, active and reactive power flows are controlled without ripple or cross coupling. Furthermore, the fixed-switching frequency is obtained by employing the simplified space vector modulation (SVM). SVM solves the complicated designing problem of the AC harmonic filter. The simplified SVM is based on the simplification of the space vector diagram of a three-level converter into that of a two-level converter. The dwelling time calculation and switching sequence selection are easily implemented like those in the conventional two-level rectifier. Replacing the current control loops with power control loops simplifies the system design and enhances the transient performance. The simulation models in MATLAB/Simulink and the digital signal processor-controlled 1.5 kW Vienna-type rectifier are used to verify the fast responses and robustness of the proposed control scheme.
Keywords
Direct power control (DPC); Power model; Sliding mode control (SMC); Vienna-type rectifier;
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