Earth fault location determination independent of fault impedance for distribution networks

Elsadd, Mahmoud A.; Elkalashy, Nagy I.; Kawady, Tamer A.; Taalab, Abdel-Maksoud I.

doi:10.1002/etep.2307

Cited by 18 publications

(4 citation statements)

References 26 publications

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“…These equations were described as the steady-state fault condition. In [11,65], the earth fault locations were depended on the equality between the computed sequence components of the current at the fault point at different load conditions. Traveling wave methods were discussed in [66,67].…”

Section: Fdir Algorithms Based On Masmentioning

confidence: 99%

A review: Smart Distribution Grid Management using Agents

Esmail¹,

Elsadd

Elkalashy

et al. 2020

Wseas Transactions on Systems

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This paper focuses on the main features of the smart distribution grid (grid management using agents). The fault management is consisting of three stages including faulted section identification, faulted section isolation, and restoration. The probable control strategies utilized in the smart grid are either centralized, decentralized, or autonomous control. Multi-Agent System (MAS) based model uses both centralized and decentralized strategies. The fault management process is usually carried out based on MAS. A literature survey on fault management control schemes is investigated. Furthermore, the reliability is estimated for both centralized, decentralized, autonomous, and modified centralized control strategies. This paper presents reliability modeling and analysis of all considered control strategies. In this paper, comprehensive detailed reliability models of considered control strategies are developed. Using this equivalent reliability model, various reliability indices are calculated.

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Section: Fdir Algorithms Based On Masmentioning

confidence: 99%

A review: Smart Distribution Grid Management using Agents

Esmail¹,

Elsadd

Elkalashy

et al. 2020

Wseas Transactions on Systems

Self Cite

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“…However, the fault resistance, laterals, and loads might remarkably reduce its accuracy in distribution networks. It also depended on the feeder parameters and configuration [5,6].…”

Section: Introductionmentioning

confidence: 99%

Earth fault distance estimation using travelling waves provided with triacs‐based reclosing in distribution networks

Elkalashy

Eldeeb

Kawady

et al. 2021

IET Renewable Power Gen

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This study presents an earth fault distance determination algorithm for distribution networks using active travelling waves. Three triacs are used in parallel with a three-phase breaker poles to overcome the mechanical inequality of the poles' reclosing times, so that the three phases are simultaneously reclosed. As the proposed fault location technique is an active type with controllable reclosing instant, the arrival time of the reflected surge from the fault point should be stamped precisely. For this purpose, three different travellingwave detection algorithms are evaluated including the discrete wavelet transform, Hilbert transform, and signal derivative. The fault location performance is evaluated under different fault conditions such as fault distances, fault resistances, and busbar faults. Due to utilising the reclosing transients, the proposed fault location function successfully estimates the fault distance for different earthing concepts such as unearthed, compensated, and earthed networks. This study is accomplished via simulating a typical 20 kV distribution network by the ATP/EMTP program. The results ensure the superior performance of the proposed fault distance estimation algorithm for earth faults in distribution networks. This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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“…In the last decade, a vast number of research work have been reported on different aspects related to various faults in the area of underground power distribution system likely analysis of faults [25][26][27][28][29][30], adaptive fault [31][32][33], SC, OC and ground faults [34][35][36][37], detection [38,39], classification [40] and fault location [41][42][43][44][45][46], sustainable protection [47,48], noise monitoring [49], and for thermal test [50].…”

Section: Introductionmentioning

confidence: 99%

A Dynamic-SUGPDS Model for Faults Detection and Isolation of Underground Power Cable Based on Detection and Isolation Algorithm and Smart Sensors

Rajpoot

Pandey²,

Rajpoot³

et al. 2021

J. Electr. Eng. Technol.

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This paper proposes a SUGPDS model based on Detection and Isolation algorithm and smart sensors, namely micro phasor measurement unit, smart sensing and switching device, phasor data concentrator, and ZigBee technology, etc. for the identification, classification, and isolation of the various fault occurs in the underground power cable in the distribution system. The proposed SUGPDS is a quick and smart tool in supervising, managing, and controlling various faults and issues and maintaining the reliability, stability, and uninterrupted flow of electricity. First, the SUGPDS model is analyzed using a distributed parameter approach. Then, the proper arrangement of the system required for the implantation of SUGPDS is demonstrated using figures. The Phasor data concentrator plays an essential role in developing the detection and classification report for identification and classification. Finally, smart sensing and switching device installed at a different location isolated the faulty phase from a healthy network. This approach helps to decrease power consumption. Hence, SUGPDS has super abilities compared to the underground power distribution system. The effectiveness of the proposed method and model is demonstrated via figures and tables. Keywords Fault detection and isolation • Micro phasor measurement unit (µPMU) • Underground power cable • Phasor data concentrator (PDC) • Smart sensing and switching device (SSSD) • Smart underground power distribution system (SUGPDS) • Short-circuit fault • Open-circuit fault • Ground fault

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Earth fault location determination independent of fault impedance for distribution networks

Cited by 18 publications

References 26 publications

A review: Smart Distribution Grid Management using Agents

A review: Smart Distribution Grid Management using Agents

Earth fault distance estimation using travelling waves provided with triacs‐based reclosing in distribution networks

A Dynamic-SUGPDS Model for Faults Detection and Isolation of Underground Power Cable Based on Detection and Isolation Algorithm and Smart Sensors

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