Interactions in droplet and particle system of near unity size ratio

Mitra, Subhasish; Evans, Geoffrey M.; Doroodchi, Elham; Pareek, Vishnu; Joshi, Jyeshtharaj B.

Title: Interactions in droplet and particle system of near unity size ratio
Creator: Mitra, Subhasish; Evans, Geoffrey M.; Doroodchi, Elham; Pareek, Vishnu; Joshi, Jyeshtharaj B.
Relation: Chemical Engineering Science Vol. 170, Issue October, p. 154-175
Publisher Link: http://dx.doi.org/10.1016/j.ces.2017.03.059
Publisher: Pergamon Press
Resource Type: journal article
Date: 2017
Description: In this study, we report collision interactions between a single droplet (diameter: 2.48-2.61 mm) and a stationary hydrophobically coated thermally conductive particle (diameter: 3 mm) in the low impact Weber number range of ~0.9-47.1 Experiments were performed under both cold and hot state with the aid of high speed imaging to capture the interaction dynamics. Two outcomes were observed in the cold state: deposition at low Weber numbers and complete wetting of particle surface through formation of a spreading lamella of thick peripheral rim at higher Weber numbers. The complete wetting behaviour of the droplet exhibited three distinct regimes of temporal variation in liquid film thickness at the apex point of particle. In non-dimensional coordinates, these regimes included - a short interval regime of linear reduction in film thickness due to initial droplet deformation, a relatively larger interval of inertia dominated regime of non-linear reduction in the film thickness and a relatively time invariant large interval of gravity draining regime with an oscillatory transition state due to capillary effect. A novel non-invasive laser based particle heating system was deployed for the non-isothermal interaction cases which showed two outcomes - rebound at lower Weber numbers and complete wetting followed by disintegration of the lamella at higher Weber numbers. Variation in particle temperature was insignificant in the rebound regime however significant temperature reduction (~10 to 70 °C) occurred due to increased wetted contact and nucleate boiling of secondary droplets at higher Weber numbers. Regardless of the heat transfer effect at solid-liquid interface, the temporal variation in the film thickness followed the same trend in regime 1 and 2 as noted in the cold interaction cases. The effect of heat transfer was however uniquely characterised by the absence of the regime 3 due to nucleate boiling at solid-liquid contact surface which led to rupture of the interface through eruption of the vapour bubbles at the end of regime 2.
Subject: droplet-particle interaction; spreading; film thickness; rebound; droplet-particle heat transfer; thin-film boiling
Identifier: http://hdl.handle.net/1959.13/1389952
Identifier: uon:32959
Identifier: ISSN:0009-2509
Language: eng
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