Direct Active and Reactive Power Control for Grid-Connected PEC9 Inverter Using Finite Control Set Model Predictive Method

2021 22nd IEEE International Conference on Industrial Technology (ICIT) Pub Date : 2021-03-10 DOI:10.1109/ICIT46573.2021.9453660

M. Babaie, M. Mehrasa, K. Al-haddad

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引用次数: 3

Abstract

This paper is dealing with designing an advanced Direct Power Control (DPC) technique for a grid-connected nine-level Packed E-Cell (PEC9) inverter through Finite Control Set Model Predictive Control (FCSMPC) and Single-phase Direct-Quadrature (s-d-q) frame. Generating a nine-level voltage waveform using minimum active and passive components count makes PEC9 a cost-effective compact multilevel converter in single-phase applications. FSMPC symmetrically stabilizes the nine-level voltage waveform and accurately synchronizes the inverter current with the grid voltage by applying direct control to the switching operation of PEC9 inverter. The phase and the amplitude of the reference current in the proposed DPC are adjusted regarding the desired level of active and reactive power through s-d-q frame. In order to address the FCSMPC weighting factors tuning difficulty, some new adaptive functions using the error value of the capacitors voltages and the inverter current are also proposed. The experiments and simulations approve that PEC9 accurately generates the desired amounts of active and reactive power with standard level of THD and dc voltage ripple.

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有限控制集模型预测法的并网PEC9逆变器有功无功直接控制

本文通过有限控制集模型预测控制(FCSMPC)和单相直接正交(s-d-q)框架，设计了一种先进的并网九电平充电电池(PEC9)逆变器直接功率控制(DPC)技术。使用最小的有源和无源元件计数产生9级电压波形，使PEC9成为单相应用中经济高效的紧凑型多电平转换器。FSMPC通过对PEC9逆变器的开关操作进行直接控制，对称稳定9级电压波形，实现逆变器电流与电网电压的精确同步。根据期望的有功和无功功率水平，通过s-d-q框架对所提出的DPC中参考电流的相位和幅度进行调整。为了解决FCSMPC加权因子调谐困难的问题，提出了利用电容器电压误差值和逆变器电流误差值的自适应函数。实验和仿真结果表明，PEC9能在标准THD和直流电压纹波水平下准确地产生所需的有功和无功功率。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2021 22nd IEEE International Conference on Industrial Technology (ICIT)

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