A New Flexible Power Quality Conditioner With Model Predictive Control

This paper presents the topology, analysis, and control implementation of a new single-phase flexible power quality conditioner (FPQC), which can be used for handling voltage- and current-related power quality (PQ) problems. Different from other PQ-compensating devices, the FPQC can work under two c...

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Veröffentlicht in:	IEEE transactions on industrial informatics 2019-05, Vol.15 (5), p.2569-2579
Hauptverfasser:	Ye, Jian, Gooi, Hoay Beng, Wang, Benfei, Zhang, Xinan
Format:	Artikel
Sprache:	eng
Schlagworte:	Active filter Computer simulation Electric potential Energy management Harmonic analysis Mathematical models Microgrids model predictive control (MPC) Phase change materials Power quality power quality (PQ) PQ conditioner Predictive control Reactive power Relays Switches Topology Transient operation
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creator	Ye, Jian Gooi, Hoay Beng Wang, Benfei Zhang, Xinan
description	This paper presents the topology, analysis, and control implementation of a new single-phase flexible power quality conditioner (FPQC), which can be used for handling voltage- and current-related power quality (PQ) problems. Different from other PQ-compensating devices, the FPQC can work under two compensating modes, i.e., parallel-connection mode (PCM) and series-connection mode (SCM). When the source voltage is unpolluted, the FPQC is working under the PCM so that the load harmonic current and reactive power can be compensated. When the source voltage is polluted, the FPQC is switched to the SCM to mitigate the impact caused by the polluted voltage. In this way, a desired voltage can be maintained at the load side to protect the critical load. The mode switching between PCM and SCM is realized by two relays. To ensure fast dynamics response and smooth transient operation, the model predictive control method is applied to regulate the developed FPQC. Both the simulation platform and laboratorial prototype are built to validate the effectiveness of the system. The simulation and experimental results are presented and discussed.
doi_str_mv	10.1109/TII.2018.2874159
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Different from other PQ-compensating devices, the FPQC can work under two compensating modes, i.e., parallel-connection mode (PCM) and series-connection mode (SCM). When the source voltage is unpolluted, the FPQC is working under the PCM so that the load harmonic current and reactive power can be compensated. When the source voltage is polluted, the FPQC is switched to the SCM to mitigate the impact caused by the polluted voltage. In this way, a desired voltage can be maintained at the load side to protect the critical load. The mode switching between PCM and SCM is realized by two relays. To ensure fast dynamics response and smooth transient operation, the model predictive control method is applied to regulate the developed FPQC. Both the simulation platform and laboratorial prototype are built to validate the effectiveness of the system. 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subjects	Active filter Computer simulation Electric potential Energy management Harmonic analysis Mathematical models Microgrids model predictive control (MPC) Phase change materials Power quality power quality (PQ) PQ conditioner Predictive control Reactive power Relays Switches Topology Transient operation
title	A New Flexible Power Quality Conditioner With Model Predictive Control
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