Machine Learning Modelling of Decay Heat Removal in High Temperature Gas-Cooled Reactor

Volume 7B: Thermal-Hydraulics and Safety Analysis Pub Date : 2022-08-08 DOI:10.1115/icone29-92695

Hao Wu, Liangzhi Yu, F. Niu, J. Tu, Shengyao Jiang

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Abstract

In decay heat removal processes of the pebble-bed high temperature gas-cooled reactors, particle-scale radiative heat transfer between spheres is complicated for modeling and numerical simulations with traditional approaches. Artificial intelligence (AI) provides a new aspect to solve the dense granular dynamics. A machine learning model was developed for predicting the obstructed view factor between all possible pebble pairs in the large-scale nuclear pebble bed. The view factor dataset is obtained by random generation for sphere positions and thermal ray tracing method by CUDA paralleling for the view factor. The regression models are trained by gradient boosting decision tree (GBDT) method of XGBoost software for 2 ∼ 10 spheres cases. It is shown that the model performance will be greatly improved without overfitting by adding more trees rather than going deeper for every tree to reach R2 scores greater than 0.999. For engineering application, the trained XGboost models are applied to predict view factors in large-scale nuclear pebble bed during decay heat removal processes. From the transient numerical results, it takes about 10 h to get its maximum 1520°C only with thermal radiation and it is still less than the design upper limit.

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高温气冷堆衰变排热的机器学习建模

在球床高温气冷堆的衰变除热过程中，球间粒子尺度的辐射传热复杂，难以用传统方法进行模拟和数值模拟。人工智能(AI)为解决密集颗粒动力学问题提供了一个新的视角。建立了一种机器学习模型，用于预测大型核球床中所有可能的卵石对之间的遮挡系数。通过随机生成球体位置和CUDA并行热射线追踪方法获得视角因子数据集。回归模型通过XGBoost软件的梯度增强决策树(GBDT)方法训练，适用于2 ~ 10个球体的情况。结果表明，在不过度拟合的情况下，通过增加更多的树，而不是每棵树都深入到R2分数大于0.999的程度，可以大大提高模型的性能。在工程应用方面，将训练后的XGboost模型应用于大规模核球床衰变除热过程中的视因子预测。从瞬态数值结果来看，仅在热辐射条件下得到其最大温度1520℃大约需要10 h，仍低于设计上限。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Volume 7B: Thermal-Hydraulics and Safety Analysis

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