Abstract
The condition monitoring and fault diagnosis of power transformers plays a significant role in the safe, stable and reliable operation of the whole power system. Dissolved gas analysis (DGA) methods are widely used for fault diagnosis, however, their accuracy is limited by the selection of DGA features and the performance of fault diagnosis models, for example, the classical support vector machine (SVM), is easily affected by unbalanced training samples. This paper presents a transformer fault diagnosis model based on chemical reaction optimization and a twin support vector machine. Twin support vector machines (TWSVMs) are used as classifiers for solving problems involving unbalanced and insufficient samples. Restricted Boltzmann machines (RBMs) are used for data preprocessing to ensure the effective identification of feature parameters and improve the efficiency and accuracy of fault diagnosis. The chemical reaction optimization (CRO) algorithm is used to optimize TWSVM parameters to select the optimal training parameters. The cross-validation (CV) method is used to ensure the reliability and generalization ability of the diagnostic model. Finally, the validity of the model is verified using real fault samples and random testing.
Highlights
With the development of smart grids in power system construction, improving the real-time diagnosis and analysis of the equipment involved represents an urgent technical challenge.The reliability of power transformers, which are critical core equipment in power transmission and distribution systems, dictates the safe and reliable performance of the whole electrical system
We propose a transformer fault diagnosis model based on chemical reaction optimization and a Twin support vector machines (TWSVMs) based on the status of the power industry and the characteristics of transformer fault diagnosis
The fault diagnosis model parameters are derived from the input characteristic values of the fault diagnosis methods recommended by International Electrotechnical Commission (IEC) and Institute of Electrical and Electronics Engineers (IEEE), which are mainly divided into two categories: the input parameters of the IEC method, Roger method (RRM), and Doernenburg method (DRM) are gas ratios; and the input parameters of the key gas method (KGM), David triangle method (DTM) are gas contents
Summary
With the development of smart grids in power system construction, improving the real-time diagnosis and analysis of the equipment involved represents an urgent technical challenge. The improved/new three-ratio (IEC three-ratio) and Dornerburg method are effective methods for oil-immersed transformer fault diagnosis, being implemented and widely used. The collected fault samples are often unbalanced, the application in practical work of AI diagnostic methods has been limited by these conditions. SVM is affected by unbalanced samples [10,11,12] To overcome this disadvantage, researchers have introduced many modification methods, and twin support vector machine (TWSVM) is the most commonly applied among them. Conclusions are drawn and potential future work is discussed is Section 6
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