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http://dx.doi.org/10.14248/JKOSSE.2020.16.2.038

A System Engineering Approach to Predict the Critical Heat Flux Using Artificial Neural Network (ANN)  

Wazif, Muhammad (Nuclear Engineering Department, KEPCO International Nuclear Graduate School)
Diab, Aya (Nuclear Engineering Department, KEPCO International Nuclear Graduate School)
Publication Information
Journal of the Korean Society of Systems Engineering / v.16, no.2, 2020 , pp. 38-46 More about this Journal
Abstract
The accurate measurement of critical heat flux (CHF) in flow boiling is important for the safety requirement of the nuclear power plant to prevent sharp degradation of the convective heat transfer between the surface of the fuel rod cladding and the reactor coolant. In this paper, a System Engineering approach is used to develop a model that predicts the CHF using machine learning. The model is built using artificial neural network (ANN). The model is then trained, tested and validated using pre-existing database for different flow conditions. The Talos library is used to tune the model by optimizing the hyper parameters and selecting the best network architecture. Once developed, the ANN model can predict the CHF based solely on a set of input parameters (pressure, mass flux, quality and hydraulic diameter) without resorting to any physics-based model. It is intended to use the developed model to predict the DNBR under a large break loss of coolant accident (LBLOCA) in APR1400. The System Engineering approach proved very helpful in facilitating the planning and management of the current work both efficiently and effectively.
Keywords
Critical Heat Flux; Artificial Intelligence Algorithm; Artificial Neural Network; DNBR; LBLOCA;
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