Litcius/Paper detail

A Virtual Complex Impedance based P — V Droop Method for Parallel-connected Inverters in Low-voltage AC Microgrids

Jianbo Chen, Dong Yue, Chunxia Dou, Lei Chen, Shengxuan Weng, Yanman Li

2020IEEE Transactions on Industrial Informatics57 citationsDOI

Abstract

Due to the high R/X ratio and mismatched feeder impedance of low-voltage microgrids, conventional droop method is no longer able to decouple the active and reactive power of distributed generators and the powersharing accuracy is degraded. In this article, a virtual complex impedance based P - V̇ droop method is proposed to decouple the powers and improve the power-sharing accuracy among DGs. With the virtual impedance method, the equivalent impedance between virtual power source and point of common coupling is shaped to be purely resistive. Then, a P - V̇ strategy is adopted to alleviate the effect of mismatched line impedance, where the virtual powers rather than the ordinary P/Q are used in the droop equation. In case the output voltage violates the operation code, a restoration mechanism is proposed to reset V̇ to zero. Compared with existing virtual impedance and Q - V̇ droop methods, the proposed method combines the advantages of both. Besides, a modified P - V̇ strategy is also presented to accelerate the restoration process and improve the active power-sharing accuracy at the same time. Simulation results validate the effectiveness of the proposed method.

Topics & Concepts

Voltage droopOutput impedanceElectrical impedanceControl theory (sociology)Impedance bridgingPower (physics)VoltageAC powerElectronic engineeringCoupling (piping)EngineeringComputer scienceDamping factorVoltage sourceInput impedanceElectrical engineeringPhysicsQuantum mechanicsArtificial intelligenceMechanical engineeringControl (management)Microgrid Control and OptimizationIslanding Detection in Power SystemsOptimal Power Flow Distribution