Dynamic behavior of non-evaporative droplet impact on a solid surface: Comparative study of R113, water, ethanol and acetone

•Droplet impact dynamics of R113, water, ethanol and acetone were compared.•Initial droplet diameter minimally affects the morphology and spreading factor.•Low droplet viscosity and surface tension produced large spreading capability.•Large droplet impact velocity and viscosity promoted splashing.•G...

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Bibliographic Details
Published in:Experimental thermal and fluid science 2019-07, Vol.105, p.153-164
Main Authors: Tian, Jia-Meng, Chen, Bin
Format: Article
Language:English
Subjects:
Acetone
Atomizing
Comparative studies
Cooling
Correlation
Deionization
Droplet impact dynamics
Droplets
Ethanol
Impact velocity
Impingement
Maximum spreading factor
Morphology
Solid surfaces
Splashing threshold
Spray cooling
Spreading
Surface tension
Tension
Velocity
Viscosity
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Summary:•Droplet impact dynamics of R113, water, ethanol and acetone were compared.•Initial droplet diameter minimally affects the morphology and spreading factor.•Low droplet viscosity and surface tension produced large spreading capability.•Large droplet impact velocity and viscosity promoted splashing.•General maximum spreading factor correlation was proposed based on experiments. Droplet impact on a solid surface is a common phenomenon observed in industries. Fundamental investigations of droplet impact are helpful in enhancing spray cooling capability and advance spray–wall impingement model. In this work, the effects of droplet diameter, impact velocity, viscosity, and surface tension on droplet impact dynamics were systematically investigated with four liquids, that is, R113, deionized water, ethanol, and acetone. Results illustrated that the initial droplet diameter minimally affects morphology and dynamic spreading factor, whereas large viscosity and surface tension hindered droplet spreading, thereby yielding a small maximum spreading factor and velocity. Low droplet viscosity and surface tension contribute to enhancing spray cooling capability by producing improved atomization, large spreading velocity, and extended contact area. The existing maximum spreading factor correlations failed to predict experimental results accurately. On the basis of experimental data in this work, general maximum spreading factor and splashing threshold correlations are proposed. All the proposed correlations agreed well with the present experimental results and literature data. The maximum spreading factor correlation indicated that large droplet impact velocity, small viscosity, and surface tension will produce a large maximum spreading capability.
ISSN:0894-1777
1879-2286
DOI:10.1016/j.expthermflusci.2019.03.024