Analysis of Synchronverter Self-Synchronization Dynamics to Facilitate Parameter Tuning

This paper proposes a self-synchronizing synchronverter controller design that leverages the addition of a virtual resistance (along with a suitable coordinate transformation) to compute feedback signals during self synchronization prior to grid connection. With respect to analysis, we exploit separ...

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Veröffentlicht in:	IEEE transactions on energy conversion 2020-03, Vol.35 (1), p.11-23
Hauptverfasser:	Dong, Shuan, Jiang, Jingya, Chen, Yu Christine
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Sprache:	eng
Schlagworte:	Computer simulation Control systems design Controllers Coordinate transformations Damping correction loop dynamics Impedance Initial conditions Mathematical models model-order reduction Parameters Phase locked loops Reduced order models Resistance self synchronization Switches Synchronism Synchronization synchronverter Time synchronization Tuning virtual resistance virtual synchronous generator Voltage measurement
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creator	Dong, Shuan Jiang, Jingya Chen, Yu Christine
description	This paper proposes a self-synchronizing synchronverter controller design that leverages the addition of a virtual resistance (along with a suitable coordinate transformation) to compute feedback signals during self synchronization prior to grid connection. With respect to analysis, we exploit separation-of-time-scales arguments and develop appropriate reduced-order models, which are well-suited for studying phase-angle and voltage-magnitude self-synchronization dynamics independently. Our work provides analytical justification for the effects of pertinent controller parameters and system initial conditions on self-synchronization dynamics observed empirically in time-domain simulations. As such, it offers practical guidance on favourable parameter-value settings to achieve fast self synchronization, and it yields accurate estimates for self-synchronization times with well-tuned parameters. Through numerical simulations and experiments, we illustrate the efficacy of the proposed controller design and verify the validity of subsequent analyses.
doi_str_mv	10.1109/TEC.2019.2945958
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subjects	Computer simulation Control systems design Controllers Coordinate transformations Damping correction loop dynamics Impedance Initial conditions Mathematical models model-order reduction Parameters Phase locked loops Reduced order models Resistance self synchronization Switches Synchronism Synchronization synchronverter Time synchronization Tuning virtual resistance virtual synchronous generator Voltage measurement
title	Analysis of Synchronverter Self-Synchronization Dynamics to Facilitate Parameter Tuning
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