Deep-Learning and Dynamic Time Warping-Based Approaches for the Diagnosis of Reactor Systems

The degradation of clamping force in the core support barrel, which forms the internal structure of a nuclear power plant, has the potential to significantly impact the plant's safety and reliability. Previous studies have concentrated on the detection of clamping force degradation but have bee...

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Bibliographic Details
Published in:Sensors (Basel, Switzerland) Switzerland), 2024-12, Vol.24 (23), p.7865
Main Authors: Jeong, Hoejun, Kim, Jihyun, Jung, Doyun, Kwon, Jangwoo
Format: Article
Language:English
Subjects:
Algorithms
Artificial intelligence
Computational linguistics
Deep learning
Design
dynamic time warping
Fault diagnosis
fault monitoring
Fourier transforms
Language processing
Methods
Natural language interfaces
Neural networks
Nuclear energy
Nuclear fuels
Nuclear power plants
Nuclear reactors
Pressure vessels
reactor internals
Sensors
Vibration analysis
Wavelet transforms
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Summary:The degradation of clamping force in the core support barrel, which forms the internal structure of a nuclear power plant, has the potential to significantly impact the plant's safety and reliability. Previous studies have concentrated on the detection of clamping force degradation but have been constrained in their ability to identify the precise size and position. This study proposes a novel methodology for diagnosing the size and position of clamping force degradation in core support barrels, combining deep-learning techniques and dynamic time warping (DTW) algorithms. DTW is applied to the magnitude data of the ex-core neutron noise signal obtained in the frequency domain, thereby enabling the effective learning of changes in sensor data values. Moreover, autoencoder-based (AE-based) representation learning is utilized to extract features of the data, preventing overfitting and thus enhancing the robustness of the model. The experiment results demonstrate that the size and position of clamping force degradation can be accurately predicted. It is expected that this research will contribute to enhancing the precision and efficiency of internal structure monitoring in nuclear power plants.
ISSN:1424-8220
1424-8220
DOI:10.3390/s24237865