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http://dx.doi.org/10.1016/j.net.2017.06.014

Gas detonation cell width prediction model based on support vector regression  

Yu, Jiyang (Department of Engineering Physics, Tsinghua University)
Hou, Bingxu (CNNC China Zhongyuan Engineering Corporation)
Lelyakin, Alexander (Institute for Nuclear and Energy Technologies, Karlsruhe Institute of Technology)
Xu, Zhanjie (Institute for Nuclear and Energy Technologies, Karlsruhe Institute of Technology)
Jordan, Thomas (Institute for Nuclear and Energy Technologies, Karlsruhe Institute of Technology)
Publication Information
Nuclear Engineering and Technology / v.49, no.7, 2017 , pp. 1423-1430 More about this Journal
Abstract
Detonation cell width is an important parameter in hydrogen explosion assessments. The experimental data on gas detonation are statistically analyzed to establish a universal method to numerically predict detonation cell widths. It is commonly understood that detonation cell width, ${\lambda}$, is highly correlated with the characteristic reaction zone width, ${\delta}$. Classical parametric regression methods were widely applied in earlier research to build an explicit semiempirical correlation for the ratio of ${\lambda}/{\delta}$. The obtained correlations formulate the dependency of the ratio ${\lambda}/{\delta}$ on a dimensionless effective chemical activation energy and a dimensionless temperature of the gas mixture. In this paper, support vector regression (SVR), which is based on nonparametric machine learning, is applied to achieve functions with better fitness to experimental data and more accurate predictions. Furthermore, a third parameter, dimensionless pressure, is considered as an additional independent variable. It is found that three-parameter SVR can significantly improve the performance of the fitting function. Meanwhile, SVR also provides better adaptability and the model functions can be easily renewed when experimental database is updated or new regression parameters are considered.
Keywords
Detonation Cell Width; Hydrogen Safety; Machine Learning; Support Vector Regression;
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