Investigation on spreading behavior and influencing parameters of particle-droplet collision

This paper investigated the dynamic wetting characteristics during droplet impact on spherical particle as the main monitoring object, and analyzed the effects of droplet impact velocity, and surface tension on droplet spreading coefficient (Dc) and particle force. The droplet-particle collision condensation test platform designed and constructed in this paper. In addition, a novel particle-droplet collision numerical model was constructed by combining VOF, dynamic mesh and mesh adaptation techniques to assist the research. The results shown that the rate of increase of Dc increased with the increase of the collision velocity. When the collision velocity was less than 1 m/s, the attraction force generated by droplet on particle was greater than the resistance generated by surface tension, which results in adsorption force. The resistance of droplet to particle increased with the increase of velocity, while the effect of adsorption decreased. When the collision velocity exceeded 1 m/s, the effect of adsorption force was negligible, the particle and droplet could not produce adsorption mode of bonding and need to overcome the surface tension for wrapping. Reducing the surface tension could increase the encapsulation speed of the droplet to the particle, for example, the droplet with a surface tension of 28mN/m took only half as long as the surface tension of 76mN/m. The results of this study provide a basic theoretical basis for further exploration of the particle-droplet collision and coalescence mechanism.