Power Quality Improvement using a New DPC Switching Table for a Three-Phase SAPF

Bouchaib Essoussi; Ahmed Moutabir; Bahloul Bensassi; Abderrahmane Ouchatti; Yassine Zahraoui; Bouchaib Benazza

doi:10.31763/ijrcs.v3i3.1042


Power Quality Improvement using a New DPC Switching Table for a Three-Phase SAPF

⁽¹⁾ Bouchaib Essoussi

(Hassan II University, Morocco)
⁽²⁾ Ahmed Moutabir

(Hassan II University, Morocco)
⁽³⁾ Bahloul Bensassi

(Hassan II University, Morocco)
⁽⁴⁾ Abderrahmane Ouchatti

(Hassan II University, Morocco)
^{(5) *} Yassine Zahraoui

(Hassan II University, Morocco)
⁽⁶⁾ Bouchaib Benazza

(Mohammed V University, Morocco)
^*corresponding author

Abstract

This research focuses on the analysis and design of robust direct power control (DPC) for a shunt active power filter (SAPF). The study proposes a novel switching table design based on an analysis of the impact of inverter switching vectors on the derivatives of instantaneous reactive and active powers. The goal is to reduce the number of commutations by eliminating null vectors while maintaining the desired DC-bus voltage using a PI regulator-based anti windup technique. Additionally, a robust PLL structure-based band pass multivariate filter (BPMVF) is utilized to enhance the network voltage. The research demonstrates the effectiveness of the suggested power control through extensive simulation results, showing high performance in both transient and steady-state conditions. The proposed approach offers the advantages of sinusoidal network current, and unitary power factor, and eliminates the need for current regulators and coordinate transformations or PWM generators. Further research directions could explore the practical implementation and real-world performance of this technique in power systems.

Keywords

shunt active power filter; power quality improvement; new DPC switching table; harmonics reduction; IEEE 519-1992

DOI

https://doi.org/10.31763/ijrcs.v3i3.1042

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