Study on Flow Characteristics of Hydraulic Suction of Seabed Ore Particles

Efficient and environmentally friendly ore collecting operation requires that the ore collecting head can provide just enough suction to start the ore particles in different working conditions. In this work, computational fluid dynamics and discrete element method (CFD-DEM) is used to simulate the hydraulic suction process of ore particles. After analyzing the pressure and velocity characteristics of the flow field, the effects of different suction velocities on the lateral displacement offset, drag coefficient C-d and Reynolds number Re-p of particles are studied. It is determined that the lifting force is caused by the different flow velocities of the upper and lower flow fields; particle start-up time and the lateral offset are inversely proportional to suction speed. When h/d =2.25, the vertical force on particles is no longer affected by h/d. When S/d = 2.5, F-Z decreases to 0 N; when h/d increases from 1.5 to 1.75, F-Z decreases by nearly half. Three empirical equations for F-Z represented by D/d, h/d, and S/d are obtained. After integrating the above three equations, the functional relationship of F-Z with D/d, h/d and S/d is finally obtained within a certain range. The errors of the equations are within 6%. The particle stress characteristics obtained in this paper can be applied to the establishment of ore collecting performance prediction model and provide data support for the research and development of intelligent ore collecting equipment.