基于自适应VSG控制的光伏并网系统

doi:10.16180/j.cnki.issn1007-7820.2022.09.004

Abstract

Abstract:

In traditional VSG control, the introduction of the inertia moment and damping coefficient of the synchronous generator into the photovoltaic inverter will result in poor dynamic adjustment capabilities of the photovoltaic grid-connected system. In view of this problem, this study proposes an improved VSG control strategy. The relationship between power angle and active power and the transient process of the rotor angular frequency oscillation period are discussed through the mathematical model of the converter. The principles for selecting moment of inertia and damping coefficient are given, and the rate of change of moment of inertia and angular frequency as well as damping coefficient and angular frequency are analyzed. The relationship between the changes leads to the improvement strategy of photovoltaic grid-connected under the control of adaptive VSG. The simulation results show that the photovoltaic grid-connected system based on the adaptive VSG control strategy has a good dynamic response, which proves the effectiveness and superiority of the improved strategy.

Key words: photovoltaic microgrid, virtual sync machine, moment of inertia, damping coefficient, adaptive control, MATLAB simulation, SVPWM, inverter

CLC Number:

TP273

SUN Sinan,HAO Zhenghang. Photovoltaic Grid-Connected System Based on Adaptive VSG Control[J].Electronic Science and Technology, 2022, 35(9): 22-29.

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区间	Δω	dω/dt	Δω(dω/dt)	J的变化情况	D的变化情况
①	>0	>0	>0	增加	增加
②	>0	<0	<0	减小	增加
③	<0	<0	>0	增加	增加
④	<0	>0	<0	减小	增加

Photovoltaic Grid-Connected System Based on Adaptive VSG Control

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