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Maximal spreading of droplet during collision on particle: Effects of liquid viscosity and surface curvature

Ikroh Yoon, Seungwon Shin

2021Physics of Fluids37 citationsDOI

Abstract

This study uses the level contour reconstruction method to numerically investigate the maximum spreading due to droplet collision with a dry, stationary, spherical particle. We consider a broad range of impact conditions: Weber number 30–90, Ohnesorge number 0.0013–0.7869, and droplet-to-particle size ratio 1/10–1/2, and quantitatively and systematically analyze 120 collision cases to understand how liquid viscosity and surface curvature affect the maximum spreading. The maximum spreading increases on the smaller particles for both the capillary and viscous regimes, but the underlying physics clearly differ. The increase in maximum spreading is governed mainly by the surface deformation of the rim for the capillary regime and viscous dissipation for the viscous regime. An empirical correlation that can be applied to the droplet impact on both a particle and a flat surface is also presented. The model shows good agreement with existing experimental data as well as our simulation results within a deviation range of ±15%.

Topics & Concepts

PhysicsMechanicsCurvatureViscosityRange (aeronautics)CollisionCapillary numberParticle (ecology)Weber numberCapillary actionDissipationSurface (topology)Viscous liquidDeformation (meteorology)Classical mechanicsGeometryThermodynamicsMaterials scienceMeteorologyReynolds numberOceanographyComputer securityComposite materialComputer scienceMathematicsGeologyTurbulenceFluid Dynamics and Heat TransferSurface Modification and SuperhydrophobicityFluid Dynamics Simulations and Interactions
Maximal spreading of droplet during collision on particle: Effects of liquid viscosity and surface curvature | Litcius