# On angled bounce-off impact of a drop impinging on a flowing soap film

**Authors:** Saikat Basu, Ali Yawar, Andres Concha, M M Bandi

arXiv: 1705.05948 · 2017-12-06

## TL;DR

This paper investigates the impact dynamics of droplets on flowing soap films, combining experiments and a reduced order analytical model to understand bounce-off behavior and vortex shedding, with implications for bio-locomotion analogies.

## Contribution

It introduces a phase-based analytical framework for droplet impact on soap films and validates it with experiments, linking impact dynamics to bio-locomotion mechanisms.

## Key findings

- Model predictions align with experimental phase domains.
- Impact causes vortex dipole shedding and surface waves.
- Momentum transfer magnitudes are comparable to biological impulsive actions.

## Abstract

Small drops impinging angularly on thin flowing soap films frequently demonstrate the rare emergence of bulk elastic effects working in-tandem with the more common-place hydrodynamic interactions. Three collision regimes are observable: (a) drop piercing through the film, (b) it coalescing with the flow, and (c) it bouncing off the film surface. During impact, the drop deforms along with a bulk elastic deformation of the film. For impacts that are close-to-tangential, the bounce-off regime predominates. We outline a reduced order analytical framework assuming a deformable drop and a deformable three-dimensional film, and the idealization invokes a phase-based parametric study. Angular inclination of the film and the ratio of post and pre impact drop sizes entail the phase parameters. We also perform experiments with vertically descending droplets impacting against an inclined soap film, flowing under constant pressure head. Model predicted phase domain for bounce-off compares well to our experimental findings. Additionally, the experiments exhibit momentum transfer to the film in the form of shed vortex dipole, along with propagation of free surface waves. On consulting prior published work, we note that for locomotion of water-walking insects using an impulsive action, the momentum distribution to the shed vortices and waves are both significant, taking up respectively 2/3-rd and 1/3-rd of the imparted streamwise momentum. In view of the potentially similar impulse actions, this theory is applied to the bounce-off examples in our experiments, and the resultant shed vortex dipole momenta are compared to the momenta computed from particle imaging velocimetry data. The magnitudes reveal identical order ($10^{-7}$ N$\cdot$s), suggesting that the bounce-off regime can be tapped as a simple analogue for interfacial bio-locomotion relying on impulse reactions.

## Full text

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## Figures

7 figures with captions in the complete paper: https://tomesphere.com/paper/1705.05948/full.md

## References

51 references — full list in the complete paper: https://tomesphere.com/paper/1705.05948/full.md

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Source: https://tomesphere.com/paper/1705.05948