Comparison of Different Configurations of Saturated Core Fault Current Limiters in a Power Grid by Numerical Method

TL;DR

This paper compares various configurations of saturated core fault current limiters (SCFCLs) using numerical simulations to evaluate their effectiveness in limiting fault currents in power grids.

Contribution

It introduces different structural arrangements of SCFCLs and assesses their performance through detailed finite element simulations.

Findings

Different SCFCL configurations show varied flux density distributions.

Simulation results identify optimal arrangements for fault current limiting.

SCFCLs effectively reduce fault currents with minimal impact during normal operation.

Abstract

Short circuit fault currents are increasing due to growing demand for electricity and high complexity in power systems. Because the fault currents reach the highest value which the breakers are unable to restrict, the electrical grid security is under jeopardy. By entering a limiting impedance into a transmission line in series, these impedances restrict the rising amounts of fault currents to levels that are acceptable. Saturated core fault current limiters (SCFCLs) are a pivotal tool for limiting fault currents rise in power networks that have good performance characteristics. In a normal condition, these limiters have slight effects on the system and can effectively limit short circuit currents when occur. In this chapter, various structures of SCFCLs with different arrangements of ac windings & dc windings are presented and the currents passing through the FCLs under the normal and faulty system conditions are assessed and compared. The flux density in various regions of the core in different arrangements has been investigated as well and the desired analyzes have been performed. Simulation will be presented based on COMSOL Multiphysics 5.4, a finite element software package which can provide a precious assessment to compare these protective devices with different configurations.