Inertio-capillary rebound of a droplet impacting a fluid bath

TL;DR

This study investigates droplet rebound dynamics on a fluid bath through experiments, models, and simulations, revealing how impact parameters influence rebound efficiency and contact time, with implications for understanding fluid-structure interactions.

Contribution

The paper introduces a coupled quasi-potential model validated against DNS and experiments, providing a simplified yet accurate approach to inertio-capillary droplet rebound analysis.

Findings

Rebound coefficient decreases with increased gravity or viscosity.

Inertio-capillary limit sets an upper bound on rebound efficiency.

Model accurately predicts experimental measurements of droplet rebound.

Abstract

The rebound of droplets impacting a deep fluid bath is studied both experimentally and theoretically. Millimetric drops are generated using a piezoelectric droplet-on-demand generator and normally impact a bath of the same fluid. Measurements of the droplet trajectory and other rebound metrics are compared directly to the predictions of a linear quasi-potential model, as well as fully resolved direct numerical simulations (DNS) of the unsteady Navier-Stokes equations. Both models resolve the time-dependent bath and droplet shapes in addition to the droplet trajectory. In the quasi-potential model, the droplet and bath shape are decomposed using orthogonal function decompositions leading to two sets of coupled damped linear harmonic oscillator equations solved using an implicit numerical method. The underdamped dynamics of the drop are directly coupled to the response of the bath through a single-point kinematic match condition which we demonstrate to be an effective and efficient model in our parameter regime of interest. Starting from the inertio-capillary limit in which both gravitational and viscous effects are negligible, increases in gravity or viscosity lead to a decrease in the coefficient of restitution and an increase in the contact time. The inertio-capillary limit defines an upper bound on the possible coefficient of restitution for droplet-bath impact, depending only on the Weber number. The quasi-potential model is able to rationalize historical experimental measurements for the coefficient of restitution, first presented by Jayaratne and Mason (1964).