Virtual Impedance Control for Load Sharing and Bus Voltage Quality Improvement in Low Voltage AC Microgrid

J. Xiao; L. Wang; P. Bauer; Z. Qin

doi:10.1109/TSG.2023.3325620

Virtual Impedance Control for Load Sharing and Bus Voltage Quality Improvement in Low Voltage AC Microgrid

J. Xiao, L. Wang, P. Bauer, Z. Qin^*

^*Corresponding author for this work

DC systems, Energy conversion & Storage

Research output: Contribution to journal › Article › Scientific › peer-review

2 Citations (Scopus)

32 Downloads (Pure)

Abstract

Due to the mismatched feeder impedances in a resistive feeder AC microgrid, it’s challenging to accurately share harmonic and active power while promising a low bus voltage distortion rate. To address this issue, this paper proposes a distributed philosophy-based virtual impedance modulation strategy. The proposed method regulates the fundamental and harmonic impedance at the desired value by exchanging information with its adjacent inverters. Notably, the proposed method benefits from resilience against communication delay, failure, and cyber-attacks. Moreover, it significantly reduces the communication burden. The proposed method’s effectiveness is validated through experiments conducted in various cases, including different communication scenarios and plug-and-play operations.

Original language	English
Number of pages	13
Journal	IEEE Transactions on Smart Grid
DOIs	https://doi.org/10.1109/TSG.2023.3325620
Publication status	E-pub ahead of print - 2023

Keywords

microgrid
adaptive virtual impedance
power sharing
distributed control

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10.1109/TSG.2023.3325620

Virtual_Impedance_Control_for_Load_Sharing_and_Bus_Voltage_Quality_Improvement_in_Low_voltage_AC_MicrogridAccepted author manuscript, 9.01 MB

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title = "Virtual Impedance Control for Load Sharing and Bus Voltage Quality Improvement in Low Voltage AC Microgrid",

abstract = "Due to the mismatched feeder impedances in a resistive feeder AC microgrid, it{\textquoteright}s challenging to accurately share harmonic and active power while promising a low bus voltage distortion rate. To address this issue, this paper proposes a distributed philosophy-based virtual impedance modulation strategy. The proposed method regulates the fundamental and harmonic impedance at the desired value by exchanging information with its adjacent inverters. Notably, the proposed method benefits from resilience against communication delay, failure, and cyber-attacks. Moreover, it significantly reduces the communication burden. The proposed method{\textquoteright}s effectiveness is validated through experiments conducted in various cases, including different communication scenarios and plug-and-play operations.",

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language = "English",

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T1 - Virtual Impedance Control for Load Sharing and Bus Voltage Quality Improvement in Low Voltage AC Microgrid

AU - Xiao, J.

AU - Wang, L.

AU - Bauer, P.

AU - Qin, Z.

PY - 2023

Y1 - 2023

N2 - Due to the mismatched feeder impedances in a resistive feeder AC microgrid, it’s challenging to accurately share harmonic and active power while promising a low bus voltage distortion rate. To address this issue, this paper proposes a distributed philosophy-based virtual impedance modulation strategy. The proposed method regulates the fundamental and harmonic impedance at the desired value by exchanging information with its adjacent inverters. Notably, the proposed method benefits from resilience against communication delay, failure, and cyber-attacks. Moreover, it significantly reduces the communication burden. The proposed method’s effectiveness is validated through experiments conducted in various cases, including different communication scenarios and plug-and-play operations.

AB - Due to the mismatched feeder impedances in a resistive feeder AC microgrid, it’s challenging to accurately share harmonic and active power while promising a low bus voltage distortion rate. To address this issue, this paper proposes a distributed philosophy-based virtual impedance modulation strategy. The proposed method regulates the fundamental and harmonic impedance at the desired value by exchanging information with its adjacent inverters. Notably, the proposed method benefits from resilience against communication delay, failure, and cyber-attacks. Moreover, it significantly reduces the communication burden. The proposed method’s effectiveness is validated through experiments conducted in various cases, including different communication scenarios and plug-and-play operations.

KW - microgrid

KW - adaptive virtual impedance

KW - power sharing

KW - distributed control

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JO - IEEE Transactions on Smart Grid

JF - IEEE Transactions on Smart Grid

ER -

Virtual Impedance Control for Load Sharing and Bus Voltage Quality Improvement in Low Voltage AC Microgrid

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