Single-phase power shunt active filter design using photovoltaic as reactive power compensator

Single-phase power shunt active filter design using photovoltaic as reactive power compensator

Introduction. The rapid production of electronic equipment circulating and used by the public has resulted in a decline in the power quality in the power system. The goal of the article is to build a parallel active filter for reactive power compensation in a single-phase power system using photovol...

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Bibliographic Details
Main Authors: B. Dwinanto, Setiyono, F. Thalib, H. Siswono
Format: Article
Language:English
Published: National Technical University "Kharkiv Polytechnic Institute" 2025-05-01
Series:Electrical engineering & Electromechanics
Subjects:
active shunt filter
compensator
photovoltaic
reactive power
voltage source inverter
Online Access:http://eie.khpi.edu.ua/article/view/311344/317138
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Summary:Introduction. The rapid production of electronic equipment circulating and used by the public has resulted in a decline in the power quality in the power system. The goal of the article is to build a parallel active filter for reactive power compensation in a single-phase power system using photovoltaic (PV) as the input DC link voltage for the inverter through simulation modeling using MATLAB/Simulink. Methods. The method used is to design a parallel active filter modeling for a single-phase electrical network that serves loads in the form of AC DC converters with inductive recessive and capacitive recessive loads using MATLAB/Simulink. Results. The simulation results show that the total harmonic distortion (THD) value of the system before being screened is 37.93 % for inductive resistive loads and 18.77 % for capacitive resistive loads, and after going through screening the THD value can drop significantly by 0.35 % for inductive resistive loads and 1.45 % for resistive capacitive loads. Practical value. PV systems can be used as power generators to provide a voltage of 800 V on a single-phase parallel active power filter using a voltage source inverter. References 30, table 2, figures 11.
ISSN:2074-272X
2309-3404

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