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http://dx.doi.org/10.1016/j.net.2020.07.020

Automated detection of corrosion in used nuclear fuel dry storage canisters using residual neural networks  

Papamarkou, Theodore (Computational Sciences and Engineering Division, Oak Ridge National Laboratory)
Guy, Hayley (Department of Mathematics, North Carolina State University)
Kroencke, Bryce (Department of Computer Science, University of California)
Miller, Jordan (Center for Cognitive Ubiquitous Computing, Arizona State University)
Robinette, Preston (Presbyterian College)
Schultz, Daniel (Innovative Computing Laboratory, University of Tennessee)
Hinkle, Jacob (Computational Sciences and Engineering Division, Oak Ridge National Laboratory)
Pullum, Laura (Computer Science and Mathematics Division, Oak Ridge National Laboratory)
Schuman, Catherine (Computer Science and Mathematics Division, Oak Ridge National Laboratory)
Renshaw, Jeremy (Electric Power Research Institute)
Chatzidakis, Stylianos (Reactor and Nuclear Systems Division, Oak Ridge National Laboratory)
Publication Information
Nuclear Engineering and Technology / v.53, no.2, 2021 , pp. 657-665 More about this Journal
Abstract
Nondestructive evaluation methods play an important role in ensuring component integrity and safety in many industries. Operator fatigue can play a critical role in the reliability of such methods. This is important for inspecting high value assets or assets with a high consequence of failure, such as aerospace and nuclear components. Recent advances in convolution neural networks can support and automate these inspection efforts. This paper proposes using residual neural networks (ResNets) for real-time detection of corrosion, including iron oxide discoloration, pitting and stress corrosion cracking, in dry storage stainless steel canisters housing used nuclear fuel. The proposed approach crops nuclear canister images into smaller tiles, trains a ResNet on these tiles, and classifies images as corroded or intact using the per-image count of tiles predicted as corroded by the ResNet. The results demonstrate that such a deep learning approach allows to detect the locus of corrosion via smaller tiles, and at the same time to infer with high accuracy whether an image comes from a corroded canister. Thereby, the proposed approach holds promise to automate and speed up nuclear fuel canister inspections, to minimize inspection costs, and to partially replace human-conducted onsite inspections, thus reducing radiation doses to personnel.
Keywords
Convolutional neural networks; Corrosion; Deep learning; Dry storage canisters; Feature detection; Residual neural networks;
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