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Prediction of critical heat flux for narrow rectangular channels in a steady state condition using machine learning

Huiyung Kim, Jeong‐Min Moon, Dong-Jin Hong, Eui-Young Cha, Byongjo Yun

2020Nuclear Engineering and Technology54 citationsDOIOpen Access PDF

Abstract

The subchannel of a research reactor used to generate high power density is designed to be narrow and rectangular and comprises plate-type fuels operating under downward flow conditions. Critical heat flux (CHF) is a crucial parameter for estimating the safety of a nuclear fuel; hence, this parameter should be accurately predicted. Here, machine learning is applied for the prediction of CHF in a narrow rectangular channel. Although machine learning can effectively analyze large amounts of complex data, its application to CHF, particularly for narrow rectangular channels, remains challenging because of the limited flow conditions available in existing experimental databases. To resolve this problem, we used four CHF correlations to generate pseudo-data for training an artificial neural network. We also propose a network architecture that includes pre-training and prediction stages to predict and analyze the CHF. The trained neural network predicted the CHF with an average error of 3.65% and a root-mean-square error of 17.17% for the test pseudo-data; the respective errors of 0.9% and 26.4% for the experimental data were not considered during training. Finally, machine learning was applied to quantitatively investigate the parametric effect on the CHF in narrow rectangular channels under downward flow conditions.

Topics & Concepts

Critical heat fluxArtificial neural networkParametric statisticsFlow (mathematics)Power (physics)Mean squared errorTest dataComputer scienceHeat fluxMachine learningArtificial intelligenceEngineeringMathematicsMechanicsHeat transferPhysicsStatisticsQuantum mechanicsProgramming languageNuclear Engineering Thermal-HydraulicsHeat transfer and supercritical fluidsHeat Transfer and Boiling Studies