On study of horizontal thin film flow of Sisko fluid due to surface tension gradient

doi:10.1007/s10483-015-1952-9

Applied Mathematics and Mechanics (English Edition) ›› 2015, Vol. 36 ›› Issue (7): 847-862.doi: https://doi.org/10.1007/s10483-015-1952-9

On study of horizontal thin film flow of Sisko fluid due to surface tension gradient

A. M. SIDDIQUI¹, H. ASHRAF², A. WALAIT², T. HAROON²

1. Department of Mathematics, York Campus, Pennsylvania State University, Pennsylvania 17403, U. S. A.;
2. Department of Mathematics, COMSATS Institute of Information Technology, Islamabad 56180, Pakistan

收稿日期:2014-10-25 修回日期:2014-12-13 出版日期:2015-07-01 发布日期:2015-07-01
通讯作者: H. ASHRAF E-mail:hameedashraf09@yahoo.com

On study of horizontal thin film flow of Sisko fluid due to surface tension gradient

A. M. SIDDIQUI¹, H. ASHRAF², A. WALAIT², T. HAROON²

1. Department of Mathematics, York Campus, Pennsylvania State University, Pennsylvania 17403, U. S. A.;
2. Department of Mathematics, COMSATS Institute of Information Technology, Islamabad 56180, Pakistan

Received:2014-10-25 Revised:2014-12-13 Online:2015-07-01 Published:2015-07-01
Contact: H. ASHRAF E-mail:hameedashraf09@yahoo.com

摘要/Abstract

摘要： The present paper is concerned with the steady thin film flow of the Sisko fluid on a horizontal moving plate, where the surface tension gradient is a driving mechanism. The analytic solution for the resulting nonlinear ordinary differential equation is obtained by the Adomian decomposition method (ADM). The physical quantities are derived including the pressure profile, the velocity profile, the maximum residue time, the stationary points, the volume flow rate, the average film velocity, the uniform film thickness, the shear stress, the surface tension profile, and the vorticity vector. It is found that the velocity of the Sisko fluid film decreases when the fluid behavior index and the Sisko fluid parameter increase, whereas it increases with an increase in the inverse capillary number. An increase in the inverse capillary number results in an increase in the surface tension which in turn results in an increase in the surface tension gradient on the Sisko fluid film. The locations of the stationary points are shifted towards the moving plate with the increase in the inverse capillary number, and vice versa locations for the stationary points are found with the increasing Sisko fluid parameter. Furthermore, shear thinning and shear thickening characteristics of the Sisko fluid are discussed. A comparison is made between the Sisko fluid film and the Newtonian fluid film.

关键词: horizontal moving plate, surface tension gradient, Adomian decomposition method (ADM), thin film flow, Sisko fluid model, analytic solution

Abstract: The present paper is concerned with the steady thin film flow of the Sisko fluid on a horizontal moving plate, where the surface tension gradient is a driving mechanism. The analytic solution for the resulting nonlinear ordinary differential equation is obtained by the Adomian decomposition method (ADM). The physical quantities are derived including the pressure profile, the velocity profile, the maximum residue time, the stationary points, the volume flow rate, the average film velocity, the uniform film thickness, the shear stress, the surface tension profile, and the vorticity vector. It is found that the velocity of the Sisko fluid film decreases when the fluid behavior index and the Sisko fluid parameter increase, whereas it increases with an increase in the inverse capillary number. An increase in the inverse capillary number results in an increase in the surface tension which in turn results in an increase in the surface tension gradient on the Sisko fluid film. The locations of the stationary points are shifted towards the moving plate with the increase in the inverse capillary number, and vice versa locations for the stationary points are found with the increasing Sisko fluid parameter. Furthermore, shear thinning and shear thickening characteristics of the Sisko fluid are discussed. A comparison is made between the Sisko fluid film and the Newtonian fluid film.

Key words: surface tension gradient, Sisko fluid model, horizontal moving plate, analytic solution, Adomian decomposition method (ADM), thin film flow

中图分类号:

A. M. SIDDIQUI, H. ASHRAF, A. WALAIT, T. HAROON. On study of horizontal thin film flow of Sisko fluid due to surface tension gradient[J]. Applied Mathematics and Mechanics (English Edition), 2015, 36(7): 847-862.

参考文献

[1] Papanastasiou, T. C. Applied Fluid Mechanics, PTR Prentice Hall, Inc., Englewood Cliffs, 309-310 (1994)
[2] Howell, P. D. Surface tension driven flow on a moving curved surface. Journal of Engineering Mathematics, 45, 283-308 (2003)
[3] Zhang, N. Surface tension-driven convection flow in evaporating liquid layers. Research Signpost, Trivandrum, Kerala, 147-170 (2006)
[4] Levich, V. G. and Krylov, V. S. Surface tension driven phenomena. Annu. Rev. Fluid Mech., 1, 293-316 (1969)
[5] O' Brien, S. B. G. and Schwartz, L. W. Theory and modeling of thin film flows. Encyclopedia of Surface and Colloid Science, Marcel Dekker, New York (2002)
[6] Myers, T. G. Application of non-Newtonian models to thin film flow. Physical Review E, 72, 066302 (2005)
[7] Sisko, A. W. The flow of lubricating greases. Industrial and Engineering Chemistry Research, 50(12), 1789-1792 (1958)
[8] Siddiqui, A. M., Ansari, A. R., Ahmad, A., and Ahmad, N. On Taylor's scraping problem and flow of a Sisko fluid. Mathematical Modeling and Analysis, 14(4), 515-529 (2009)
[9] Mekheimer, K. S. and El-Kot, M. A. Mathematical modelling of unsteady flow of a Sisko fluid through an anisotropically tapered elastic arteries with time-variant overlapping stenosis. Applied Mathematical Modelling, 36, 5393-5407 (2012)
[10] Siddiqui, A. M., Hameed, A., Haroon, T., and Walait, A. Analytic solution for the drainage of Sisko fluid film down a vertical belt. Applications and Applied Mathematics, 8(2), 465-480 (2013)
[11] Adomian, G. Analytical Solutions for Ordinary and Partial Differential Equations, Center for Applied Mathematics, University of Georgia, Georgia (1987)
[12] Hosseini, M. M. and Nasabzadeh, H. On the convergence of Adomian decomposition method. Applied Mathematics and Computation, 182(1), 536-543 (2006)
[13] Kamran, A. M., Rahim, M. T., Haroon, T., Islam, S., and Siddiqui, A. M. Solution of steady thin film flow of Johnson egalman fluid on a vertical moving belt for lifting and drainage problems using Adomian decomposition method. Applied Mathematics and Computation, 218(21), 10413-10428 (2012)
[14] Wazwaz, A. M. Partial Differential Equations and Solitary Wave Theory, Nonlinear Physical Science, e-ISSN, Springer-Verlag, Berlin, 1867-8459 (2009)
[15] Helal, M. A. and Mehanna, M. S. The tanh method and Adomian decomposition method for solving the foam drainage equation. Applied Mathematics and Computation, 190(1), 599-609 (2007)
[16] Siddiqui, A. M., Hameed, M., Siddiqui, B. M., and Babcock, B. S. Adomian decomposition method applied to study nonlinear equations arising in non-Newtonian flows. Applied Mathematical Sci- ences, 6(98), 4889-4909 (2012)

On study of horizontal thin film flow of Sisko fluid due to surface tension gradient

On study of horizontal thin film flow of Sisko fluid due to surface tension gradient

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