LAUSR

Abstract Water spray is the most commonly used method for suppressing mine dust. On the heading face of high gassy mine, forced ventilation is employed to dilute and discharge methane in order to prevent methane accumulation. In this paper, we utilize the program ANSYS FLUENT to investigate the influence of airflow from forced ventilation on the water spray flow field. The three-dimensional (3D) steady wind and spray flow models are successfully established and simulated under different spray pressures, which range from 0.5 MPa to 3.0 MPa. The results show that the wind wall produces a significant number of vortices from the interaction between the wind and heading face, which blocks the advance of the droplets. As spray pressure increases, the trajectory of the spray droplets is more strongly affected; i.e. the spray was so disturbed that it could not reach the dust source. The average droplet diameter gradually decreases, and the average droplet velocity first decreases and then increases as the spray pressure increases. Under the condition of this study, we find 2.4 MPa to be the optimal operating pressure for water spray to suppress dust at dust source on the coal wall, which can prevent dust from entering the mine air and effectively reduce the dust concentration.