Litcius/Paper detail

Application to Real Power Networks of a Method to Locate Partial Discharges Based On Electromagnetic Time Reversal

Antonella Ragusa, Hugh Sasse, Alistair Duffy, Marcos Rubinstein

2021IEEE Transactions on Power Delivery22 citationsDOIOpen Access PDF

Abstract

The paper presents an experimental validation of a method to locate partial discharges (PDs) on power distribution and transmission networks. The method is based on electromagnetic time reversal (EMTR) theory, and it uses a Transmission Line Matrix (TLM) model to describe the propagation of the PD signals in the reversed time. Since PDs are regarded as a symptom of insulation degradation, on-line PD location is considered an important approach to monitoring the integrity of a power distribution network, with the aim of detecting and preventing faults and improving network reliability. In this paper, the EMTR-based method is described and its effectiveness in PD localization using only one measurement point is demonstrated in three real 33 kV power lines. Its effectiveness is proved with and without an on-line electromagnetically noisy environment, and its accuracy is evaluated with respect to different signal-to-noise ratio (SNR) levels of the networks. The validation shows that the method is able to locate PDs with an error of 0.14% with respect to the total length of the line in the absence of noise, and with an error that is always lower than 0.5% for an SNR down to −7 dB.

Topics & Concepts

Transmission lineReliability (semiconductor)Electric power transmissionPower (physics)Line (geometry)Electronic engineeringPartial dischargeNoise (video)Computer scienceTransmission (telecommunications)Transmission-line matrix methodPoint (geometry)SIGNAL (programming language)Signal-to-noise ratio (imaging)Power transmissionEngineeringElectrical engineeringVoltageTelecommunicationsMathematicsComputational electromagneticsPhysicsElectromagnetic fieldArtificial intelligenceGeometryQuantum mechanicsProgramming languageImage (mathematics)Electrical Fault Detection and ProtectionGeophysical Methods and ApplicationsHigh voltage insulation and dielectric phenomena