High-impedance fault location method using guessed fault resistance

IF 3.3 3区工程技术 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

Electric Power Systems Research Pub Date : 2024-11-11 DOI:10.1016/j.epsr.2024.111221

Haonan Cui, Qing Yang

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引用次数: 0

Abstract

Electromagnetic time reversal fault location method requires the placement of observation points at a single location and is effective for searching fault location. Among the various existing metrics, the transfer function correlation metric emerged as the most robust. However, its application to high-impedance faults also presents challenges. This difficulty can be attributed to the unknown real fault resistance in the direct-time process, where the guessed fault resistance is typically set to 0 during the reversed-time process of the electromagnetic time reversal fault location method. Consequently, this practice yields comparable direct-time and reversed-time transfer functions for low-impedance faults. Conversely, high-impedance faults exhibit significant discrepancies between direct-time and reversed-time transfer functions, leading to errors in fault location. To overcome this challenge, this paper proposes a location method based on specific guessed fault resistance preset during the reversed-time process. First, the direct-time voltage and reversed-time current transfer functions under high-impedance faults were derived in the frequency domain. Subsequently, by comparing transfer function differences when fault resistances in the direct-time and reversed-time processes did not align, a principle for selecting the guessed fault resistance was established. Additionally, the similarity of the two transfer functions under specific guessed fault resistances was investigated. Furthermore, the symmetry of the fault current was leveraged to reflect the correlation between the two transfer functions, and the differential fault current symmetry coefficient metric was introduced. A fault location time-domain algorithm based on guessed fault resistance was proposed, and its effectiveness was demonstrated through both reduced-scale and simulation experiments. The results indicate that the proposed method is not only applicable to complex lines but also offers a straightforward calculation approach, facilitating fault location under high-impedance faults.

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利用猜测故障电阻的高阻抗故障定位方法

电磁时间反转故障定位方法需要在单一位置布置观测点，可有效搜索故障位置。在现有的各种指标中，传递函数相关指标最为稳健。然而，它在高阻抗故障中的应用也面临挑战。这种困难可归因于直达时间过程中未知的实际故障电阻，而在电磁时间反转故障定位方法的反转时间过程中，通常会将猜测的故障电阻设为 0。因此，对低阻抗故障而言，这种做法可获得相似的直接时间和反向时间传递函数。相反，高阻抗故障在直接时间和反向时间传递函数之间表现出显著差异，导致故障定位错误。为克服这一难题，本文提出了一种基于反向时间过程中预设的特定猜测故障电阻的定位方法。首先，在频域中推导出高阻抗故障下的正向时电压和反向时电流传递函数。随后，通过比较直接时间和反向时间过程中故障电阻不一致时的传递函数差异，确立了选择猜测故障电阻的原则。此外，还研究了在特定猜测故障电阻下两种传递函数的相似性。此外，还利用故障电流的对称性来反映两个传递函数之间的相关性，并引入了差分故障电流对称系数指标。提出了一种基于猜测故障电阻的故障定位时域算法，并通过缩小尺度和仿真实验证明了该算法的有效性。结果表明，所提出的方法不仅适用于复杂线路，而且提供了一种简单明了的计算方法，有助于在高阻抗故障下进行故障定位。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Electric Power Systems Research 工程技术-工程：电子与电气

CiteScore

7.50

自引率

17.90%

发文量

963

审稿时长

3.8 months

期刊介绍： Electric Power Systems Research is an international medium for the publication of original papers concerned with the generation, transmission, distribution and utilization of electrical energy. The journal aims at presenting important results of work in this field, whether in the form of applied research, development of new procedures or components, orginal application of existing knowledge or new designapproaches. The scope of Electric Power Systems Research is broad, encompassing all aspects of electric power systems. The following list of topics is not intended to be exhaustive, but rather to indicate topics that fall within the journal purview. • Generation techniques ranging from advances in conventional electromechanical methods, through nuclear power generation, to renewable energy generation. • Transmission, spanning the broad area from UHV (ac and dc) to network operation and protection, line routing and design. • Substation work: equipment design, protection and control systems. • Distribution techniques, equipment development, and smart grids. • The utilization area from energy efficiency to distributed load levelling techniques. • Systems studies including control techniques, planning, optimization methods, stability, security assessment and insulation coordination.