Abstract
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Power grids are highly susceptible to various types of faults and their associated consequences. In recent years,
numerous fault location methods have been proposed for different types of power networks. Generally, these
methods determine the location of a fault by measuring current and voltage data on one or both sides of the line.
However, the use of current data can result in calculation errors due to the saturation state of the current
transformer and the bidirectional fault current. Moreover, the use of measuring devices in different nodes can
lead to increased costs and the need for advanced telecommunication systems and data synchronization. In this
paper, we propose a comprehensive technique for fault location in power networks that incorporates the presence of D-STATCOM and considers the effect of line capacitors. Our method estimates the distance and faulty
branch by measuring the difference in fault voltage magnitude at the substation and comparing it with simulated
faults in other branches. Unlike other methods that rely on current data, our proposed technique is independent
of current data, resulting in higher accuracy and faster fault detection. Furthermore, our method offers significant cost savings compared to other fault location methods. To evaluate the performance of our technique, we
conducted simulations on a 32-node power network in MATLAB/SIMULINK and an 8-node network in a power
system simulator. We tested the sensitivity of our method to various fault locations, resistances, and DG penetration levels. The results of our simulations demonstrate the high accuracy and speed of our proposed technique,
making it a promising alternative to other fault location methods in the field.
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