The multi-peaks structure of the blast wave generated by a liquid hydrogen storage tank BLEVE
Donatella Cirrone, Dmitriy Makarov, Vladimir Molkov
Abstract
Blast wave structure of boiling liquid expanding vapour explosions (BLEVE) for liquid hydrogen (LH 2 ) storage is not fully understood. There is a lack of experimental and numerical studies on underlying physical phenomena. This study develops a CFD model able to simulate multiple pressure peaks of the blast wave accounting for both the effect of combustion on the strength of blast wave generated by the compressed gaseous hydrogen (CGH 2 ) in ullage space, and the slower process of flashing boiling of the liquid phase resulted from pressure drop. The simulations reproduced the measured overpressures and multi-peak structure of blast wave observed in the BLEVE tests performed by BMW. It is confirmed that the larger first pressure peak is produced by the CGH 2 shock fed by combustion. The flash boiling of LH 2 during pressure drop produces a series of follow-up pressure waves. Combustion contribution to the entire blast wave dynamics is demonstrated. • Modelling of multi-peak structure of blast wave pressure generated from LH 2 BLEVE. • Maximum blast wave pressure is generated by the compressed gaseous hydrogen shock. • LH 2 flash boiling produces smaller secondary pressure peaks of comparable impulse. • Combustion energy contributes to blast wave strength during the entire process. • Validation of simulation results against experiments performed by BMW on LH 2 BLEVE.