Abstract
Since it is difficult for the traditional fault diagnosis method based on dissolved gas analysis (DGA) to meet today’s engineering needs in terms of diagnostic accuracy and stability, this paper proposes an artificial intelligence fault diagnosis method based on a probabilistic neural network (PNN) and bio-inspired optimizer. The PNN is used as the basic classifier of the fault diagnosis model, and the bio-inspired optimizer, improved salp swarm algorithm (ISSA), is used to optimize the hidden layer smoothing factor of PNN, which stably improves the classification performance of PNN. Compared with the traditional SSA, the sine cosine algorithm (SCA) and disruption operator are introduced in ISSA, which effectively improves the exploration capability and convergence speed. To verify the engineering applicability of the proposed method, the ISSA-PNN model was developed and tested using sensor data provided by Jiangxi Province Power Supply Company. In addition, the method is compared with machine learning methods such as support vector machine (SVM), back propagation neural network (BPNN), multi-layer perceptron (MLP), and traditional fault diagnosis methods such as the international electrotechnical commission (IEC) ratio method. The results show that the proposed method has a strong learning ability for complex fault data and has advantages in accuracy and robustness compared to other methods.
Highlights
Oil-immersed power transformers are among the most expensive and essential pieces of equipment in power systems [1,2,3]
It can be seen that the average accuracy of improved salp swarm algorithm (ISSA)-probabilistic neural network (PNN) is 99.65%, which is higher than the other methods: salp swarm algorithm (SSA)-PNN 97.37%; multi-verse optimizer (MVO)-PNN 97.02%; bat algorithm (BA)-PNN 96.52%; seagull optimization algorithm (SOA)-PNN 95.80%; particle swarm optimization (PSO)-PNN 94.49%; and PNN 86.70%
It can be seen that the average accuracy of ISSA-PNN is superior to other methods, ISSA-PNN (98.59%) is inferior to BA-back propagation neural network (BP) (99.06%) and genetic algorithm (GA)-BP (99.06%) methods in low temperature and overheating (LT) (
Summary
Oil-immersed power transformers are among the most expensive and essential pieces of equipment in power systems [1,2,3]. Oil-immersed transformers are subjected to various stresses, such as electrical, thermal, chemical, and mechanical stresses, which can lead to the aging and deterioration of their insulation. Insulation defects are the most common cause of failure in excitation transformers and directly affect the reliability of the equipment [4,5]. In today’s increasingly large power demand, if a power transformer fails, it will likely cause an interruption of power supply to the energy system and bring significant economic losses. Being able to quickly and accurately diagnose the type of faults during transformer operation has become an important issue in promoting the smart grid process
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