Litcius/Paper detail

Enhancing Transformer Protection: A Machine Learning Framework for Early Fault Detection

Mohammed Alenezi, Fatih Anayi, Michael Packianather, Mokhtar Shouran

2024Sustainability19 citationsDOIOpen Access PDF

Abstract

The reliable operation of power transformers is essential for grid stability, yet existing fault detection methods often suffer from inaccuracies and high false alarm rates. This study introduces a machine learning framework leveraging voltage signals for early fault detection. Simulating diverse fault conditions—including single line-to-ground, line-to-line, turn-to-ground, and turn-to-turn faults—on a laboratory-scale three-phase transformer, we evaluated decision trees, support vector machines, and logistic regression models on a dataset of 6000 samples. Decision trees emerged as the most effective, achieving 99.90% accuracy during 5-fold cross-validation and 95% accuracy on a separate test set of 400 unseen samples. Notably, the framework achieved a low false alarm rate of 0.47% on a separate 6000-sample healthy condition dataset. These results highlight the proposed method’s potential to provide a cost-effective, robust, and scalable solution for enhancing transformer fault detection and advancing grid reliability. This demonstrates the efficacy of voltage-based machine learning for transformer diagnostics, offering a practical and resource-efficient alternative to traditional methods.

Topics & Concepts

Fault detection and isolationTransformerComputer scienceReliability engineeringEngineeringArtificial intelligenceElectrical engineeringVoltageActuatorPower Transformer Diagnostics and InsulationMachine Fault Diagnosis TechniquesFault Detection and Control Systems