中性点非有效接地系统中单相接地故障的分布式自愈控制

IF 0.8 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC

International Journal of Emerging Electric Power Systems Pub Date : 2024-04-01 DOI:10.1515/ijeeps-2023-0420

Silin He, Jiran Zhu, Di Zhang, Shengpeng Liu, Luxin Zhan, Chun Chen

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引用次数: 0

摘要

在配电网络中，非有效接地系统中的单相接地不会导致短路，因此故障电流较低。特别是在高电阻接地情况下，故障电流会变得极低，从而增加保护误判的风险。为了提高此类故障期间自愈的速度和准确性，提出了一种基于灵活接地和零序电流分析的分布式自愈控制方法，适用于非有效接地系统。该方法采用点对点分布式自愈和灵活接地技术，将隔离或电弧抑制中性点系统转换为低电阻接地系统。此外，还引入了不受中性点接地模式影响的定位标准，利用故障上游和下游零序电流的偏差作为区分特征。所提出的方法原理简单，可利用现有的终端设备进行准确、快速的故障处理。仿真结果验证了该方法对过渡电阻和中性点接地条件的适应性，证明其适用于所有系统类型的单相接地故障定位。研究成果有效确保了非有效接地系统单相接地故障自愈的准确性和快速性。

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Distributed self-healing control of single-phase grounding fault in neutral point non-effective grounding system

In distribution networks, single-phase grounding occurrences in non-effectively grounded systems do not result in short-circuits, thus leading to low fault currents. Particularly in high-resistance grounding scenarios, fault currents become extremely low, increasing the risk of protection misjudgments. To enhance the speed and accuracy of self-healing during such faults, a distributed self-healing control method based on flexible grounding and zero-sequence current analysis for non-effectively grounded systems is proposed. This method employs peer-to-peer distributed self-healing and flexible grounding techniques to convert isolated or arc-suppressed neutral systems to low-resistance grounded systems. Additionally, a localization criterion unaffected by neutral grounding modes is introduced, utilizing deviations in zero-sequence current upstream and downstream of the fault as distinguishing characteristics. The proposed method is straightforward in principle and leverages existing terminal equipment for accurate and swift fault processing. Simulation results validate the method’s resilience to transition resistance and neutral grounding conditions, demonstrating its suitability for single-phase grounding fault localization across all system types. The research findings effectively ensure the accuracy and swiftness of self-healing during single-phase grounding faults in non-effectively grounded systems.

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来源期刊

International Journal of Emerging Electric Power Systems ENGINEERING, ELECTRICAL & ELECTRONIC-

CiteScore

3.00

自引率

10.00%

发文量

期刊介绍： International Journal of Emerging Electric Power Systems (IJEEPS) publishes significant research and scholarship related to latest and up-and-coming developments in power systems. The mandate of the journal is to assemble high quality papers from the recent research and development efforts in new technologies and techniques for generation, transmission, distribution and utilization of electric power. Topics The range of topics includes: electric power generation sources integration of unconventional sources into existing power systems generation planning and control new technologies and techniques for power transmission, distribution, protection, control and measurement power system analysis, economics, operation and stability deregulated power systems power system communication metering technologies demand-side management industrial electric power distribution and utilization systems.