Phenomenology of droplet collision hydrodynamics on wetting and non-wetting spheres

In this study, the spreading characteristics of water droplets impacted on a solid spherical target have been investigated experimentally and theoretically. Droplet impact and postimpact feature studies have been conducted on hydrophilic and superhydrophobic spherical surfaces. Effects of the impact...

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Published in:Physics of Fluids
Main Authors: Khurana, Gargi, Sahoo, Nilamani, Dhar, Purbarun
Other Authors: IIT Ropar
Format: Article in Journal/Newspaper
Language:English
Published: AIP Publishing 2019
Subjects:
North Pole
Online Access:http://dx.doi.org/10.1063/1.5103223
https://pubs.aip.org/aip/pof/article-pdf/doi/10.1063/1.5103223/14059606/072003_1_online.pdf
id craippubl:10.1063/1.5103223
record_format openpolar
spelling craippubl:10.1063/1.5103223 2024-09-15T18:24:53+00:00 Phenomenology of droplet collision hydrodynamics on wetting and non-wetting spheres Khurana, Gargi Sahoo, Nilamani Dhar, Purbarun IIT Ropar 2019 http://dx.doi.org/10.1063/1.5103223 https://pubs.aip.org/aip/pof/article-pdf/doi/10.1063/1.5103223/14059606/072003_1_online.pdf en eng AIP Publishing Physics of Fluids volume 31, issue 7 ISSN 1070-6631 1089-7666 journal-article 2019 craippubl https://doi.org/10.1063/1.5103223 2024-09-05T04:03:29Z In this study, the spreading characteristics of water droplets impacted on a solid spherical target have been investigated experimentally and theoretically. Droplet impact and postimpact feature studies have been conducted on hydrophilic and superhydrophobic spherical surfaces. Effects of the impact Weber number and target-to-drop diameter ratio on the spreading hydrodynamics have been discussed. Postcollision dynamics are explored with side and top views of impaction phenomenon using a high speed imaging technique. The morphological outcome of this impingement process has been quantitatively discussed with three geometric parameters, namely, liquid film thickness at the north-pole of the target surface, spread factor, and the maximum spread angle. Observations revel that spread factor and the maximum spread angle increases with the decrease in the size of the spherical target, whereas opposite of this is true for liquid film thickness at the north-pole of the target surface. Temporal variations of liquid film thickness at the north pole of the target have been plotted and found in agreement with the theoretical predictions made in the earlier studies. Finally, a mathematical model based on the energy balance principle has been proposed to predict the maximum spread angle on spherical targets. The theoretical values are found in good agreement with the experimental results for a wide range of spherical diameters studied. The findings may have implications toward a better understanding of fluid wetting, spraying, and coating behavior of complex shapes and geometries. Article in Journal/Newspaper North Pole AIP Publishing Physics of Fluids 31 7
institution Open Polar
collection AIP Publishing
op_collection_id craippubl
language English
description In this study, the spreading characteristics of water droplets impacted on a solid spherical target have been investigated experimentally and theoretically. Droplet impact and postimpact feature studies have been conducted on hydrophilic and superhydrophobic spherical surfaces. Effects of the impact Weber number and target-to-drop diameter ratio on the spreading hydrodynamics have been discussed. Postcollision dynamics are explored with side and top views of impaction phenomenon using a high speed imaging technique. The morphological outcome of this impingement process has been quantitatively discussed with three geometric parameters, namely, liquid film thickness at the north-pole of the target surface, spread factor, and the maximum spread angle. Observations revel that spread factor and the maximum spread angle increases with the decrease in the size of the spherical target, whereas opposite of this is true for liquid film thickness at the north-pole of the target surface. Temporal variations of liquid film thickness at the north pole of the target have been plotted and found in agreement with the theoretical predictions made in the earlier studies. Finally, a mathematical model based on the energy balance principle has been proposed to predict the maximum spread angle on spherical targets. The theoretical values are found in good agreement with the experimental results for a wide range of spherical diameters studied. The findings may have implications toward a better understanding of fluid wetting, spraying, and coating behavior of complex shapes and geometries.
author2 IIT Ropar
format Article in Journal/Newspaper
author Khurana, Gargi
Sahoo, Nilamani
Dhar, Purbarun
spellingShingle Khurana, Gargi
Sahoo, Nilamani
Dhar, Purbarun
Phenomenology of droplet collision hydrodynamics on wetting and non-wetting spheres
author_facet Khurana, Gargi
Sahoo, Nilamani
Dhar, Purbarun
author_sort Khurana, Gargi
title Phenomenology of droplet collision hydrodynamics on wetting and non-wetting spheres
title_short Phenomenology of droplet collision hydrodynamics on wetting and non-wetting spheres
title_full Phenomenology of droplet collision hydrodynamics on wetting and non-wetting spheres
title_fullStr Phenomenology of droplet collision hydrodynamics on wetting and non-wetting spheres
title_full_unstemmed Phenomenology of droplet collision hydrodynamics on wetting and non-wetting spheres
title_sort phenomenology of droplet collision hydrodynamics on wetting and non-wetting spheres
publisher AIP Publishing
publishDate 2019
url http://dx.doi.org/10.1063/1.5103223
https://pubs.aip.org/aip/pof/article-pdf/doi/10.1063/1.5103223/14059606/072003_1_online.pdf
genre North Pole
genre_facet North Pole
op_source Physics of Fluids
volume 31, issue 7
ISSN 1070-6631 1089-7666
op_doi https://doi.org/10.1063/1.5103223
container_title Physics of Fluids
container_volume 31
container_issue 7
_version_ 1810465295556411392

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