SVM-Based Synchronized Fault Detection for 100% Renewable Microgrids: Preprint

Research output: Contribution to conferencePaper

Abstract

Traditional protection schemes face significant challenges when applied to microgrids with high penetrations of renewables with inverter-based resources (IBRs). The proliferation of advanced sensing and communication technologies has generated copious data, offering an opportunity to overcome these limitations using data-driven machine learning approaches. This work proposes a novel approach based on a support vector machine (SVM) for detecting faults within a 100% renewable microgrid. The approach encompasses a systematic offline training stage for the development of a linear SVM-based fault detection algorithm. This process covers offline data collection from the microgrid under study, the extraction of features such as positive- and negative-sequence components and the total harmonic distortion of the voltage and current measurements of the relays, and the design of the linear SVM-based classifier. During the online implementation, however, different classifiers can exhibit asynchronicity in detecting the fault inception at different subcycle-to-cycle period-level delays. To circumvent this asynchronicity issue, a separate algorithm is developed for each relay to estimate the fault inception time as close to the real fault time. The performance of the proposed SVM-based synchronized fault detection method is evaluated using online time-domain simulation studies on a microgrid test system. The results corroborate the reliability of the fault detection scheme when tested under various fault cases (fault types, locations, and impedances) and non-fault cases during both grid-tied and islanded operation modes.
Original languageAmerican English
Number of pages9
StatePublished - 2024
Event2024 IEEE Industrial Electronics Society (IECON) - Chicago, Illinois
Duration: 3 Nov 20246 Nov 2024

Conference

Conference2024 IEEE Industrial Electronics Society (IECON)
CityChicago, Illinois
Period3/11/246/11/24

NREL Publication Number

  • NREL/CP-5D00-87961

Keywords

  • 100% microgrid
  • fault isolation
  • grid-following inverters
  • grid-forming inverters
  • power system protection

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