Investigation of active voltage support control approach of DC distribution networks based on virtual inertia coordination

IF 1.6 Q4 ENERGY & FUELS IET Energy Systems Integration Pub Date : 2023-10-20 DOI:10.1049/esi2.12123
Lei Chen, Yuqi Jiang, Zekai Zhao, Shencong Zheng, Yifei Li, Hongkun Chen
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Abstract

DC distribution networks (DCDNs) possess the advantages of high power efficiency, low operation loss, and favourable control flexibility, and are regarded as an essential form of future power distribution systems. In order to increase the voltage transient performance of DCDNs against disturbances, this paper proposes a methodology for realising the active voltage support control of DCDNs based on virtual inertia coordination. Firstly, the impact of the inertia of DCDNs towards the transient voltage change is analysed, and the active voltage support mechanism considering the variable droop inertia control and virtual DC motor inertia (VDCMI) control is explored. Then, a time sequence coordination strategy based on the voltage grading of DCDNs is developed, and an adaptive inertia coefficient is designed to achieve the inertia adjustment in terms of the voltage sag and recovery processes. Using MATLAB/Simulink, a detailed model of the double-terminal DCDNs is created to check the efficacy of the proposed approach. Different voltage disturbance scenarios are imitated, and the comparative simulations demonstrate that the proposed approach can fully utilise the inertia potential of the DCDNs to suppress the voltage sag and smooth the voltage recovery procedure. The proposed method's validity and feasibility can be well validated.

The cover image is based on the Original Article Investigation of active voltage support control approach of DC distribution networks based on virtual inertia coordination by Lei Chen et al., https://doi.org/10.1049/esi2.12123.

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基于虚拟惯性协调的直流配电网主动电压支持控制方法研究
直流配电网(DCDN)具有功率效率高、运行损耗低、控制灵活等优点,被视为未来配电系统的重要形式。为了提高 DCDN 的电压暂态抗干扰性能,本文提出了一种基于虚拟惯性协调的 DCDN 主动电压支持控制方法。首先,分析了 DCDN 的惯性对瞬态电压变化的影响,并探讨了考虑变垂惯性控制和虚拟直流电机惯性(VDCMI)控制的主动电压支持机制。然后,开发了基于 DCDN 电压分级的时序协调策略,并设计了自适应惯性系数,以实现电压下陷和恢复过程中的惯性调整。使用 MATLAB/Simulink 创建了双端 DCDN 的详细模型,以检验所提方法的有效性。模拟了不同的电压扰动情况,比较仿真结果表明,所提出的方法可以充分利用 DCDN 的惯性潜力来抑制电压骤降,并使电压恢复过程更加平滑。封面图片来自陈磊等人的原创文章《基于虚拟惯性协调的直流配电网主动电压支持控制方法研究》,https://doi.org/10.1049/esi2.12123。
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来源期刊
IET Energy Systems Integration
IET Energy Systems Integration Engineering-Engineering (miscellaneous)
CiteScore
5.90
自引率
8.30%
发文量
29
审稿时长
11 weeks
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