Effects of Surface Tension on Drop Impact on a Horizontal Rotating Disk

Xiao Fang Yuan; Jing Yin Li; Bin Zhang

doi:10.4028/www.scientific.net/AMM.268-270.1084

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 268-270Effects of Surface Tension on Drop Impact on a...

Effects of Surface Tension on Drop Impact on a Horizontal Rotating Disk

Abstract:

The impact processes of water and ethanol drops on a rotating horizontal aluminum disk were recorded and analyzed using a high-speed digital camera together with an image analysis program. The angular velocities of the disk were altered to study the effect of surface tension of drops on drop impact processes. The experimental results show that a lower surface tension will result in a higher tangential spread factor and a lower receding rate during the receding stage, for the drop impinging and depositing on a rotating disk. In addition, a lower surface tension of the drop tends to promote the occurrence of splash. The experimental results further verify a proposed correlation of splash-deposition boundary for drops impinging on a rotating disk. Both drops, though they have a quite different surface tension, experience four stages, with two new stages different from those of drops impinging on stationary surfaces. Their tangential spreading factors both increase obviously with the tangential velocity at the impact point, while their radial spreading factors vary a little.

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Periodical:

Applied Mechanics and Materials (Volumes 268-270)

Pages:

1084-1093

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.268-270.1084

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Online since:

December 2012

Authors:

Xiao Fang Yuan, Jing Yin Li, Bin Zhang

Keywords:

Deposition-Splash Bounday, Drop Impact, Rotating Disk, Surface Tension, Tangential Velocity

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References

[1] A.M. Worthington, On the forms assumed by drops of liquids falling vertically on a horizontal plate. Proc. R. Soc. London, 25, 1876-1877: 261-272.

DOI: 10.1098/rspl.1876.0048

Google Scholar

[2] G E Cossali, M. Marengo, M. Santini: Atomization Sprays Vol. 15, No. 6 (2005) pp.699-736

Google Scholar

[3] S Y Lee, S U. Ryu: Journal of Mechanical Science and Technology Vol. 20, No. 8 (2006) pp.1101-1117

Google Scholar

[4] A.L. Yarin: Annual Reviews Vol. 38 (2006) pp.159-192

Google Scholar

[5] A.S. Moita, A.L. Moreira: Proceedings of the combustion institute Vol. 31 (2007) pp.2175-2183

Google Scholar

[6] K.K. Shalnev, O.A. Povarov, O.I. Nazarov, I.A. Shalobasov, Collision of drop with moving plane surface, in: Conference on Fluid Machinery, 5th, Budapest, Hungary, (1975)

Google Scholar

[7] Povarov, O.I. Nazarov, L.A. Ignatevskaya, A.I. Nikolskii: Journal of Engineering Physics and Thermophysics Vol. 31 No. 6(1976) pp.1453-1456

Google Scholar

[8] Li JY, Yuan XF, Han Q and Xi G: Journal of Mechanical Engineering Science Vol. 226 (2012) pp.956-967

Google Scholar

[9] S.C. Yao, K.Y. Cai: Expermental Thermal and Fluid Science Vol. 1(1988) pp.363-371

Google Scholar

[10] Q.L. Zhou, N. Li, X. Chen, et al: International Journal of Impact Engineering Vol. 36 (2009) pp.1156-1171.

Google Scholar

[11] I. Day, J. Willams, C. Freeman: Journal of turbomachinery Vol. 130 (2008) pp.1-10

Google Scholar