Grid Simulator With Phase-Amplitude Compensation

This paper proposes a grid simulator with Phase-Amplitude Compensation (PAC). The system allows independent and flexible adjustment of specific harmonic controller parameters to simulate abnormal grid conditions (e.g., short-circuit faults, high harmonic contamination, and sudden frequency changes)....

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Veröffentlicht in:	IEEE transactions on industry applications 2024-05, Vol.60 (3), p.4201-4212
Hauptverfasser:	Chang, Yun-Hsiang, Wu, Tsai-Fu, Chiu, Jui-Yang, Hung, Chien-Chih
Format:	Artikel
Sprache:	eng
Schlagworte:	3Φ4W voltage converter Amplitudes Compensation Control methods Controllers Frequency control Harmonic analysis Harmonic control Inductance phase-amplitude compensation (PAC) Picture archiving and communication systems Power grids Power harmonic filters Resonant frequencies Short circuits Tracking errors Voltage control wide-inductance drop
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creator	Chang, Yun-Hsiang Wu, Tsai-Fu Chiu, Jui-Yang Hung, Chien-Chih
description	This paper proposes a grid simulator with Phase-Amplitude Compensation (PAC). The system allows independent and flexible adjustment of specific harmonic controller parameters to simulate abnormal grid conditions (e.g., short-circuit faults, high harmonic contamination, and sudden frequency changes). With the proposed phase and amplitude compensation loops, the tracking error can be effectively reduced not only in the control of the fundamental frequency components, but in the high-frequency harmonic components. Compared with the conventional grid simulator, it can more flexibly adjust the fundamental and harmonic components of the output voltages. With the proposed method, users can modularly add fundamental and harmonic controllers to the system according to the required needs, independently control the required voltage harmonics, and still simulate common power grid fault situations. Moreover, when designing a harmonic controller, it is sufficient to design it for low-frequency signals, which greatly reduces the complexity. Finally, the proposed control method is validated by measurements of different abnormal power-grid simulations.
doi_str_mv	10.1109/TIA.2024.3371430
format	Article
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The system allows independent and flexible adjustment of specific harmonic controller parameters to simulate abnormal grid conditions (e.g., short-circuit faults, high harmonic contamination, and sudden frequency changes). With the proposed phase and amplitude compensation loops, the tracking error can be effectively reduced not only in the control of the fundamental frequency components, but in the high-frequency harmonic components. Compared with the conventional grid simulator, it can more flexibly adjust the fundamental and harmonic components of the output voltages. With the proposed method, users can modularly add fundamental and harmonic controllers to the system according to the required needs, independently control the required voltage harmonics, and still simulate common power grid fault situations. Moreover, when designing a harmonic controller, it is sufficient to design it for low-frequency signals, which greatly reduces the complexity. 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The system allows independent and flexible adjustment of specific harmonic controller parameters to simulate abnormal grid conditions (e.g., short-circuit faults, high harmonic contamination, and sudden frequency changes). With the proposed phase and amplitude compensation loops, the tracking error can be effectively reduced not only in the control of the fundamental frequency components, but in the high-frequency harmonic components. Compared with the conventional grid simulator, it can more flexibly adjust the fundamental and harmonic components of the output voltages. With the proposed method, users can modularly add fundamental and harmonic controllers to the system according to the required needs, independently control the required voltage harmonics, and still simulate common power grid fault situations. Moreover, when designing a harmonic controller, it is sufficient to design it for low-frequency signals, which greatly reduces the complexity. 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The system allows independent and flexible adjustment of specific harmonic controller parameters to simulate abnormal grid conditions (e.g., short-circuit faults, high harmonic contamination, and sudden frequency changes). With the proposed phase and amplitude compensation loops, the tracking error can be effectively reduced not only in the control of the fundamental frequency components, but in the high-frequency harmonic components. Compared with the conventional grid simulator, it can more flexibly adjust the fundamental and harmonic components of the output voltages. With the proposed method, users can modularly add fundamental and harmonic controllers to the system according to the required needs, independently control the required voltage harmonics, and still simulate common power grid fault situations. Moreover, when designing a harmonic controller, it is sufficient to design it for low-frequency signals, which greatly reduces the complexity. 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subjects	3Φ4W voltage converter Amplitudes Compensation Control methods Controllers Frequency control Harmonic analysis Harmonic control Inductance phase-amplitude compensation (PAC) Picture archiving and communication systems Power grids Power harmonic filters Resonant frequencies Short circuits Tracking errors Voltage control wide-inductance drop
title	Grid Simulator With Phase-Amplitude Compensation
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