Applied Sciences (Aug 2024)

Study on Thermal Radiation Characteristics and the Multi-Point Source Model of Hydrogen Jet Fire

  • Haiyang Zhang,
  • Xun Cao,
  • Xuhao Yuan,
  • Fengrong Wu,
  • Jing Wang,
  • Yankang Zhang,
  • Qianqian Li,
  • Hu Liu,
  • Zuohua Huang

DOI
https://doi.org/10.3390/app14167098
Journal volume & issue
Vol. 14, no. 16
p. 7098

Abstract

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Hydrogen safety remains a paramount concern in pipeline transportation. Once hydrogen leaks and ignites, it quickly escalates into a jet fire incident. The substantial thermal radiation released poses significant risks of fire and explosion. Therefore, studying the thermal radiation characteristics of hydrogen jet fires and developing accurate prediction models are crucial for establishing relevant safety standards. To address the oversimplified consideration of weighted coefficients in thermal radiation prediction models, this study investigated the thermal radiation characteristics of hydrogen jet fire by carrying out experiments and numerical simulations. The results reveal the significant impacts of the leakage diameter and pressure on thermal radiation. Increases in both the leakage diameter and pressure lead to a rapid escalation in the thermal radiation release, highlighting their critical importance in establishing safety standards for hydrogen pipeline transportation. Additionally, this study optimized the weight coefficients in the multi-point source prediction model based on temperature distribution along the flame axis. The optimized model was validated through comparison with experimental data. After optimization, the prediction error of the multi-point source radiation model was reduced from 19.5% to 13.9%. This model provides significant support for accurately evaluating the risk of hydrogen jet fire.

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