不平衡电网电压下三相中点钳位并网逆变器动态相电流补偿和直流母线电压纹波抑制策略

This paper proposes dynamic phase current compensation and DC-link voltage mitigation strategies for three-phase four-wire neutral-point-clamped (NPC) grid-tied inverters under unbalanced grid voltages. When the grid fault occurs, the fault-phase voltage will diverge from its normal value. To achieve the reactive power compensation capability, the inverter should output reactive current on the fault phase. However, the unbalanced three-phase active/reactive power generates non-ideal harmonics and oscillations on the DC-link voltage, which might damage the DC-link capacitors. It is possible to increase the capacitance to suppress the ripple. However, the circuit size and cost will be increased. Therefore, this paper develops a dynamic phase current compensation (DPCC) strategy. This strategy will dynamically adjust the magnitude and phase angle of normal phase currents. Consequently, the harmonics and oscillations on the DC-link voltage can effectively be suppressed. The developed DPCC does not require additional circuits and components, and this strategy can be realized via the digital signal processor (DSP). Detailed theoretical analysis and mathematical derivations of the proposed strategy will be presented in this paper. Finally, a 5kVA prototype circuit with both computer simulations and hardware experiments demonstrates the performance and feasibility of the proposed DPCC. From the results, it can be confirmed that the maximum suppression rate of DC-link voltage ripple will be 83.17% with the proposed DPCC.