Litcius/Paper detail

Novel Fault Distance Estimation Method for Three-Terminal Transmission Line

Vishal Kumar Gaur, Bhavesh R. Bhalja, Mladen Kezunović

2020IEEE Transactions on Power Delivery30 citationsDOI

Abstract

A new faulty section identification and fault distance estimation technique for three-terminal transmission line (TTL) is proposed in this paper. It is based on the derivation of three indices by solving non-linear equations with iterative method utilizing synchronized measurements from three ends of the line. In the absence of synchronization, an angle synchronization operator is derived for building a common reference among the three terminals. The efficacy of the technique is verified by generating several fault cases on an existing Indian 400 kV TTL using PSCAD/EMTDC software. Reported results demonstrate the capability of the presented technique for all types of fault on three-terminal transposed/untransposed as well as the non-homogeneous transmission line. It also provides accurate fault location under comprehensive variation in type of fault, line length, fault inception angle, complex fault impedance, source impedance, and current transformer (CT) saturation condition. Its accuracy remains almost constant despite errors in line parameters, as well as synchronization and noise in the measured signals. The initial guess has a minimal impact on the accuracy and convergence of the presented technique. The attained results reveal higher accuracy and better robustness of the proposed technique in comparison with those of several existing techniques.

Topics & Concepts

Robustness (evolution)Control theory (sociology)Transmission lineElectrical impedanceFault (geology)Synchronization (alternating current)Electric power transmissionElectronic engineeringEngineeringComputer scienceTopology (electrical circuits)Electrical engineeringControl (management)BiochemistryGeologyChemistryGeneSeismologyArtificial intelligencePower Systems Fault DetectionIslanding Detection in Power SystemsHVDC Systems and Fault Protection