A robust diagnosis method specifically for similar faults in nuclear power plant multi-systems based on data segmentation and stacked convolutional autoencoders

•Propose KSCAE combining K-Means and stacked convolutional autoencoder for better similar fault diagnosis.•Apply K-Means for data segmentation, guided by the effective elbow method.•Develop classifiers with stacked convolutional autoencoder, tuned via Bayesian optimization, enhancing fault diagnosis...

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Bibliographic Details
Published in:Annals of nuclear energy Vol. 213; p. 111178
Main Authors: Ai, Xin, Liu, Yongkuo, Shan, Longfei, Gao, Jiarong, Zhang, Wanzhou
Format: Journal Article
Language:English
Published: Elsevier Ltd 01.04.2025
Subjects:
Data segmentation
Nuclear power plant
Robust diagnostics
Similar faults diagnosis
Stacked convolutional autoencoders
Similar faults diagnosis
Stacked convolutional autoencoders
Nuclear power plant
Data segmentation
Robust diagnostics
ISSN:0306-4549
Online Access:Get full text
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Summary:•Propose KSCAE combining K-Means and stacked convolutional autoencoder for better similar fault diagnosis.•Apply K-Means for data segmentation, guided by the effective elbow method.•Develop classifiers with stacked convolutional autoencoder, tuned via Bayesian optimization, enhancing fault diagnosis.•KSCAE achieves top accuracy, boosting diagnostic accuracy by 14.67%-21.54%, excelling in distinguishing similar faults.•K-Means enhances robust classification boundaries, improving accuracy in diagnosing similar faults. Nuclear power plants consist of multiple subsystems characterized by nonlinear correlations, numerous monitoring parameters, and faults with similar characteristics. These similar faults often exhibit closely distributed data points, resulting in unclear classification boundaries and reduced diagnostic accuracy for fault detection algorithms. A single deep learning model cannot establish a diagnostic model that is broad in scope, highly accurate, and robust. This paper proposes a robust, multi-system similar fault diagnosis model for nuclear power plants, combining K-Means and Stacked Convolutional Autoencoders (KSCAE). First, K-Means data segmentation model partitions complex multi-system fault data into several similar data clusters. Then, specialized diagnostic models are developed for each cluster using powerful stacked convolutional autoencoders to focus on learning and classifying similar faults. Testing across three nuclear power plant fault diagnosis scenarios based on data from the Fuqing nuclear power plant simulator demonstrates that KSCAE outperforms single deep learning models in diagnostic accuracy, particularly when fault severity differs between training and testing sets. The results show that the KSCAE algorithm achieves a maximum accuracy of 99.31% and a minimum accuracy of 79.11% under severe noise and data distribution differences. Compared to the baseline algorithms, KSCAE achieves an average accuracy improvement of up to approximately 20% across multiple tests, particularly in Scenario 2. This study demonstrates the effectiveness and robustness of the proposed model for diagnosing similar faults, providing a reliable approach for multi-system fault diagnosis in nuclear power plants.
ISSN:0306-4549
DOI:10.1016/j.anucene.2024.111178