Journal
IEEE JOURNAL OF EMERGING AND SELECTED TOPICS IN POWER ELECTRONICS
Volume 11, Issue 3, Pages 3236-3250Publisher
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/JESTPE.2023.3242986
Keywords
High power converters; low carrier ratio (LCR); negative sequence elimination; phase correction; resonant control
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In this article, the amplification effect of negative sequence voltage to negative sequence current under unbalanced grid voltage is revealed and explained. A phase-corrected proportional resonant (PR) controller is introduced to suppress the amplification effect and enhance system stability. A design scheme for phase correction angles is proposed to improve system dynamics. Finally, simulation and experiments validate the effectiveness of the proposed approach.
High-power converters operate at low carrier ratios (LCRs) featuring significant digital delay, making it challenging to suppress negative sequence current stably under unbalanced grid voltage. In this article, the worse amplification effect from negative sequence voltage to negative sequence current due to LCR under conventional proportional-integral (PI) control is first revealed and quantitatively explained with the complex transfer function. Furthermore, a phase-corrected proportional resonant (PR) controller is presented to suppress the amplification effect by the newly added pole and enhance the system stability by local phase correction (LPC). Meanwhile, a design scheme for phase correction angles is proposed to improve dynamics. Finally, simulation and experiments are provided to validate the negative sequence current elimination capability under various grid voltage sag depths as high as 100% at different carrier ratios as low as five, enhanced stability, and improved dynamic performance.
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