Safety analysis of hydrogen leakage accident with a mobile hydrogen refueling station

The operation of mobile hydrogen refueling stations will be popular for hydrogen energy supply in the future, and the investigation includes the hydrogen diffusion behavior of hydrogen leakage and the potential risk of explosion is pivotal to commercializing the mobile hydrogen refueling station. The dispersion of hydrogen leakage and the minimum safe distance of explosion of the mobile hydrogen refueling station are studied by simulation. The 3D full-scale geometry is established. Experimental data verifies the numerical models. The effects of the ventilation scenarios of the truck container and the ambient wind (wind speeds and wind di-rections) on hydrogen volume and diffusion distance are analyzed. By calculating the severe working conditions results, the hydrogen volume in the open space and the hydrogen concentration in the four 3-way corners of the ceiling in the truck container are obtained. Finally, the overpressure caused by hydrogen explosion is evaluated, and the minimum safe distance under different damage effects is predicted. The obtained results reveal that the conditions included that the side door and side window are open, low ambient wind speed, and wind direction from front to rear of the mobile hydrogen refueling station increase the risk of hydrogen leakage and diffusion. Based on severe working conditions, the average hydrogen volume is 87.9 m3 in the air in stable status. In the case of a hydrogen explosion, the minimum safe distance is 313.2 m. The investigation provided a valuable reference for evaluating and preventing hydrogen leakage accidents of the mobile hydrogen refueling station.

Automated summary

This study simulates the dispersion of hydrogen leakage and the minimum safe distance of explosion in a mobile hydrogen refueling station. A 3D full-scale geometry is established and experimental data validates the numerical models. The effects of ventilation scenarios and ambient wind on hydrogen volume and diffusion distance are analyzed. The investigation provides valuable insights for evaluating and preventing hydrogen leakage accidents in mobile hydrogen refueling stations.