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PIER PIER B PIER C PIER M PIER Letters
2016-05-03
Topology Measurement of Substation's Grounding Grid by Using Electromagnetic and Derivative Method
By
Aamir Qamar,

    Dr. Aamir Qamar

    School of Electrical Engineering

    Chongqing University

    China

    Homepage

Fan Yang,

    Prof. Fan Yang

    School of Electrical Engineering

    Chongqing University

    China

    Homepage

Wei He,

    Dr. Wei He

    Electrical Engineering College

    Chongqing University

    China

    Homepage

Ammad Jadoon,

    Dr. Ammad Jadoon

    School of Electrical Engineering

    Chongqing University

    China

    Homepage

Muhammad Zeeshan Khan,

    Dr. Muhammad Zeeshan Khan

    School of Electrical Engineering

    Chongqing University

    China

    Homepage

Naidong Xu

    Dr. Naidong Xu

    School of Electrical Engineering

    Chongqing University

    China

    Homepage

Progress In Electromagnetics Research B, Vol. 67, 71-90, 2016
doi:10.2528/PIERB16030701 | Google Scholar

Abstract
The topology of grounding grid is important for diagnosing its status, which plays a critical role in the safety of personnel and stable operation of power system. The electromagnetic field method and derivative of surface magnetic flux density on the line has been used to measure the branch position in case the grid is parallel to the plane of earth surface that in practice is unknown while the node points and connections were not discussed. This paper introduces a method that uses derivative of surface flux density on circles and lines in a systematic order to find the position of the grid in the plane of the earth surface and connecting the nodes to measure the full topology. This method even identifies any angled branch present in the mesh of a grid. Software simulations and experimental tests verify that the method is feasible and can be applied to identify the topology of a grounding grid.
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Citation
Aamir Qamar, Fan Yang, Wei He, Ammad Jadoon, Muhammad Zeeshan Khan, and Naidong Xu, "Topology Measurement of Substation's Grounding Grid by Using Electromagnetic and Derivative Method," Progress In Electromagnetics Research B, Vol. 67, 71-90, 2016.
doi:10.2528/PIERB16030701
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