Abstract
The fault diagnosis of power transformers is of great significance to improve the reliability of power systems. This paper proposes a novel fault diagnosis method called the expertise-guided machine learning (EGML) model where a genetic algorithm (GA) and a mind evolutionary algorithm (MEA) are used as optimization algorithms. Thereby, two types of EGML models are generated, that is, the GA-EGML model and the MEA-EGML model. In the EGML model, knowledge function replaces the cost function of traditional artificial intelligence algorithms, which can provide additional information for each individual and bring some corrections to the prediction results. To investigate the application potentials of the proposed models in power transformer fault diagnosis, real dissolved gases data are utilized to evaluate the diagnosis performance of the proposed models. Results indicate that the performance of the EGML model outperforms the traditional back propagation neural network (BPNN) model and all other models participating in the comparison. Both the GA-EGML model and MEA-EGML model can be used to diagnose the faults of a power transformer, and the latter is better. In addition, to further investigate the robustness of the proposed models for different data, four scenarios are simulated. Empirical results show that the accuracies of all models decrease in the other three scenarios compared to the baseline scenario, especially in scenario 2. However, the proposed models decline less than the traditional models in scenario 2 and scenario 4, and obtain satisfactory accuracy in all scenarios.
Highlights
With the drastic increase in the power system capacity, the requirements for the reliability of power transmission and supply are higher [1]
This section aims to introduce the structure of the expertise-guided machine learning (EGML) model, in which the back propagation neural network (BPNN) model is the benchmark learning model and genetic algorithm (GA) and mind evolutionary algorithm (MEA) are selected as the optimization algorithm
The performance of the MEA-EGML model was superior to the BPNN model and the MEA-BPNN model
Summary
With the drastic increase in the power system capacity, the requirements for the reliability of power transmission and supply are higher [1]. As important equipment for power transmission in power systems, the power transformer is significant for safe and stable operation of the entire power network. In the event of a fault in a transformer, generating capacity will be harmed. It is important to study fault diagnosis technology pertaining to power transformers [2]. Power transformer faults generally arise from electrical and thermal stresses, and these faults differ only in their energy, location, and time of occurrence. The oil temperature will rise and some gases will be produced when the fault appears. There are five common dissolved gases in transformer oil, namely, hydrogen (H2), methane (CH4), ethane (C2H6), ethylene (C2H4), and acetylene (C2H2) [3,4]
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