Hostname: page-component-cd9895bd7-dk4vv Total loading time: 0 Render date: 2024-12-29T13:24:57.477Z Has data issue: false hasContentIssue false

Magnetothermodynamic Peristaltic Flow of Bingham Non-Newtonian Fluid in Eccentric Annuli with Slip Velocity and Temperature Jump Conditions

Published online by Cambridge University Press:  01 May 2013

M. F. El-Sayed*
Affiliation:
Department of Mathematics, Faculty of Education, Ain Shams University, Heliopolis, Roxy, Cairo, Egypt
N. T. M. Eldabe
Affiliation:
Department of Mathematics, Faculty of Education, Ain Shams University, Heliopolis, Roxy, Cairo, Egypt
A. Y. Ghaly
Affiliation:
Department of Mathematics, Faculty of Education, Ain Shams University, Heliopolis, Roxy, Cairo, Egypt
H. M. Sayed
Affiliation:
Department of Mathematics, Faculty of Education, Ain Shams University, Heliopolis, Roxy, Cairo, Egypt
*
*Corresponding author (mfahmye@yahoo.com)
Get access

Abstract

In this paper, we studied the peristaltic flow and heat transfer of an incompressible, electrically conducting Bingham Non-Newtonian fluid in an eccentric uniform annulus in the presence of external uniform magnetic field with slip velocity and temperature jump at the wall conditions. The viscous and Joule dissipations are taken into account. The inner tube is rigid and moving with a constant axial velocity, while the outer tube has a sinusoidal wave traveling down its wall. Under zero Reynolds number condition with the long wavelength approximation, the axial velocity and the stream function are obtained analytically. A numerical solution for the governing partial differential equation of energy is performed in order to analyze the temperature distribution. The effects of all parameters of the problem are numerically discussed and graphically explained.

Type
Articles
Copyright
Copyright © The Society of Theoretical and Applied Mechanics, R.O.C. 2013 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

1.Beskok, A. and Karniadakis, G. E., “Simulation of Heat and Momentum Transfer in Complex Micro Geometries,” Journal of Thermophysics and Heat Transfer, 8, pp. 647653 (1994).CrossRefGoogle Scholar
2.Paranjape, B. V. and Robson, R. E., “Comment on Slip Velocity at a Fluid-Solid Boundary,” Physics and Chemistry of Liquids, 21, pp. 147156 (1990).CrossRefGoogle Scholar
3.Eirich, F. R., Rheology: Theory and Applications, 3rd Edition, Academic Press Inc. Ltd., New York (1978).Google Scholar
4.Hill, D. A., “Wall Slip in Polymer Melts: A Pseudo-Chemical Model,” Journal of Rheology, 42, pp. 581601 (1998).Google Scholar
5.Malkus, D. S., Nohel, J. A. and Plohr, B. J., “Dynamics of Shear Flow of a Non-Newtonian Fluid,” Journal of Computational Physics, 87, pp. 464487 (1990).CrossRefGoogle Scholar
6.Ameel, T. A., Barron, R. F. and Wang, X., Warrington, R. O., “Laminar Forced Convection in a Circular Tube with Constant Heat Flux and Slip Flow,” Microscale Thermophysical Engineering, 1, pp. 303320 (1977).Google Scholar
7.Kavehpour, H. P., Faghri, M. and Asako, Y., “Effects of Compressibility and Rarefaction on Gaseous Flows in Microchannels,” Numerical Heat Transfer Part A- Applications, 32, pp. 677696 (1997).Google Scholar
8.Tunc, G. and Bayazitoglu, Y., “Heat Transfer in Microtubes with Viscous Dissipation,” International Journal of Heat and Mass Transfer, 44, pp. 23952403 (2001).CrossRefGoogle Scholar
9.Hadjiconstantinou, N. G. and Simek, O., “Constant-Wall-Temperature Nusselt Number in Micro and Nano-Channels,” Transactions of the ASME: Journal of Heat Transfer, 124, pp. 356364 (2002).CrossRefGoogle Scholar
10.Larrodé, F. E., Housiadas, C. and Drossinos, Y., “Slip-Flow Heat Transfer in Circular Tubes,” International Journal of Heat and Mass Transfer, 43, pp. 26692680 (2000).Google Scholar
11.Aydin, O. and Avci, M., “Analysis of Laminar Heat Transfer in Micro-Poiseuille Flow,” International Journal of Thermal Sciences, 46, pp. 3037 (2007).Google Scholar
12.Avci, M. and Aydin, O., “Laminar Forced Convection Slip-Flow in a Micro-Annulus Between Two Concentric Cylinders,” International Journal of Heat and Mass Transfer, 51, pp. 34603467 (2008).CrossRefGoogle Scholar
13.Avci, M. and Aydin, O., “Mixed Convection in a Vertical Micro-Annulus Between Two Concentric Microtubes,” Transactions of the ASME: Journal of Heat Transfer, 131, 014502 (2009).Google Scholar
14.Hong, C., Asako, Y. and Suzuki, K., “Convection Heat Transfer in Concentric Micro Annular Tubes with Constant Wall Temperature,” International Journal of Heat and Mass Transfer, 54, pp. 52425252 (2011).CrossRefGoogle Scholar
15.Nelson, E. B. and Guillot, D., Wall Cementing, 2nd Edition, Schlumberger Dowell, Sugar Land, Texas (2006).Google Scholar
16.Himasekhar, K. and Bau, H. H., “Large Rayleigh Number Convection in a Horizontal Eccentric Annulus Containing Saturated Porous Media,” International Journal of Heat and Mass Transfer, 29, pp. 703712 (1986).Google Scholar
17.Walton, I. C. and Bittleston, S. H., “The Flow of a Bingham Plastic Fluid in a Narrow Eccentric Annulus,” Journal of Fluid Mechanics, 222, pp. 3960 (1991).Google Scholar
18.Siginer, D. A. and Bakhtiyarov, S. I., “Flow of Drilling Fluids in Eccentric Annuli,” Journal of Non-Newtonian Fluid Mechanics, 78, pp. 119132 (1998).CrossRefGoogle Scholar
19.Ahmed, M. E. S. and Attia, H. A., “Magnetohydrodynamic Flow and Heat Transfer of a Non-Newtonian Fluid in an Eccentric Annulus,” Canadian Journal of Physics, 76, pp. 391401 (1998).Google Scholar
20.Meena, S., Kandaswamy, P. and Debnath, L., “Hydrodynamic Flow Between Rotating Eccentric Cylinders with Suction at the Porous Walls,” International Journal of Mathematics and Mathematical Sciences, 25, pp. 93113 (2001).Google Scholar
21.Průša, V. and Rajagopal, K. P., “Flow of an Electrorheological Fluid Between Eccentric Rotating Cylinders,” Theoretical and Computational Fluid Dynamics, 26, pp. 121 (2012).CrossRefGoogle Scholar
22.Mekheimer, Kh. S. and El-Kot, M. A., “Mathematical Modeling of Axial Flow Between Two Eccentric Cylinders: Application on the Injection of Eccentric Catheter Through Stenotic Arteries,” International Journal of Non-Linear Mechanics, 47, pp. 927937 (2012).Google Scholar
23.Mekheimer, Kh. S., Abdelmaboud, Y. and Abdellateef, A. I., “Hydromagnetic Flow Induced by Sinusoidal Peristaltic Waves Through Eccentric Cylinders in a Porous Medium,” Proceedings of the 8th International Scientific Conference on Environmrnt, Development and Bioinformatics, March 26-28, Al-Azhar University, Cairo, Egypt (2012).Google Scholar
24.Kwang, W., Chu, H. and Fang, J., “Peristaltic Transport in a Slip Flow,” The European Physical Journal B, 16, pp. 543547 (2000).Google Scholar
25.Elshehawey, E. F., El-Dabe, N. T. and El-Desoky, I. M., “Slip Effects on the Peristaltic Flow of a Non-Newtonian Maxwellian Fluid,” Acta Mechanica, 186, pp. 141159 (2006).Google Scholar
26.Ramachandra, R. A. and Usha, S., “Peristaltic Pumping in a Circular Tube in Presence of an Eccentric Catheter,” Transactions of the ASME: Journal of Biomechanical Engineering, 117, pp.448454 (1995).Google Scholar
27.Abd El-Naby, A. H. and El-Misery, A. M., “Effects of an Endoscope and Generalized Newtonian Fluid on Peristaltic Motion,” Applied Mathematics and Computation, 128, pp. 1935 (2002).CrossRefGoogle Scholar
28.El-Misery, A. M., Abd El-Naby, A. H. and Nagar, A. H., “Effects of a Fluid with Variable Viscosity and an Endoscope on Peristaltic Motion,” Journal of the Physical Society of Japan, 72, pp. 8994 (2003).Google Scholar
29.Mekheimer, Kh. S., “Peristaltic Transport of a Newtonian Fluid Through a Uniform and Non-Uniform Annulus,” Arabian Journal for Science and Engineering, 30, pp. 6983 (2005).Google Scholar
30.Hayat, T., Momoniat, E. and Mahomed, F. M., “Endoscope Effects on MHD Peristaltic Flow of a Power-Law Fluid,” Mathematical Problems in Engineering, 6, pp. 119 (2006).CrossRefGoogle Scholar
31.Hayat, T., Ali, N., Asghar, S. and Siddiqui, A. M., “Exact Peristaltic Flow in Tubes with an Endoscope,” Applied Mathematics and Computation, 182, pp. 359368 (2006).Google Scholar
32.Eldabe, N. T. M., El-Sayed, M. F., Ghaly, A. Y. and Sayed, H. M., “Peristaltically Induced Transport of a MHD Biviscosity Fluid in a Non-Uniform Tube,” Physica A, 383, pp. 253266 (2007).CrossRefGoogle Scholar
33.Eldabe, N. T. M., El-Sayed, M. F., Ghaly, A. Y. and Sayed, H. M., “Mixed Convection Heat and Mass Transfer in a Non-Newtonian Fluid at a Peristaltic Surface with Temperature-Dependent Viscosity,” Archive of Applied Mechanics, 78, pp. 599624 (2008).CrossRefGoogle Scholar
34.Eldabe, N. T. M., El-Sayed, M. F., Ghaly, A. Y. and Sayed, H. M., “Magnetohydrodynamic Peristaltic Pumping Through Uniform Channel with Porous Peripheral Layer and Hall Currents,” Journal of Porous Media, 12, pp. 869886 (2009).Google Scholar
35.El-Sayed, M. F., Eldabe, N. T. M., Ghaly, A. Y. and Sayed, H. M., “Effects of Chemical Reaction, Heat and Mass Transfer on Non-Newtonian Fluid Flow Through Porous Medium in a Vertical Peristaltic Tube,” Transport in Porous Media, 89, pp. 185212 (2011).Google Scholar
36.Fang, P., Manglik, R. M. and Jog, M. A., “Characteristics of Laminar Viscous Shear-Thinning Fluid Flows in Eccentric Annular Channels,” Journal of Non-Newtonian Fluid Mechanics, 84, pp. 117 (1999).Google Scholar
37.Tsangaris, S., Nikas, C., Tsangaris, G. and Neofytou, P., “Couette Flow of a Bingham Plastic in a Channel with Equally Porous Parallel Walls,” Journal of Non-Newtonian Fluid Mechanics, 144, pp. 4248 (2007).CrossRefGoogle Scholar
38.Engin, T., Dogruer, U., Evrensal, C., Heavin, S. and Gordaninejad, F., “Effect of Wall Roughness on Laminar Flow of Bingham Plastic Fluids Through Microtubes,” Transactions of the ASME: Journal of Fluids Engineering, 126, pp. 880883 (2004).Google Scholar
39.Mernone, A. V., Mazumdar, J. N. and Lucas, S. K., “A Mathematical Study of Peristaltic Transport of a Casson Fluid,” Mathematical and Computer Modelling, 35, pp. 895912 (2002).Google Scholar
40.Chen, Y.-L. and Zhu, K.-Q., “Couette-Poiseuille Flow of Bingham Fluids Between Two Porous Plates with Slip Conditions,” Journal of Non-Newtonian Fluid Mechanics, 153, pp. 111 (2008).Google Scholar
41.Srivastava, V. P. and Saxena, M., “A Two-Fluid Model of Non-Newtonian Blood Flow Induced by Peristaltic Waves,” Rheologica Acta, 34, pp. 406414 (1995).Google Scholar
42.Eckert, E. R. G. and Drake, R. M., Analysis of the Heat and Mass Transfer, McGraw-Hill, New York (1972).Google Scholar
43.Rohsenow, W. M., Hartnett, J. P. and Ganić, E. N., Handbook of Heat Transfer Fundamentals, 2nd Edition, McGraw-Hill, New York (1985).Google Scholar
44.Song, S. and Yovanovich, M. M., “Correlation of Thermal Accommodation Coefficient for Engineering Surfaces,” American Society of Mechanical Engineering-Heat Transfer Division, 69, pp. 107115 (1987).Google Scholar
45.Rao, A. R. and Usha, S., “Peristaltic Transport of Two Immiscibe Viscous Fluids in a Circular Tube,” Journal of Fluid Mechanics, 298, pp. 271285 (1995).Google Scholar
46.Shapiro, A. H., Jaffrin, M. Y. and Weinberg, S. L., “Peristaltic Pumping with Long Wavelength at Low Reynolds Numbers,” Journal of Fluid Mechanics, 37, pp. 799825 (1969).Google Scholar
47.Pontrelli, G., “Blood Flow Through a Circular Pipe with Impulsive Pressure Gradient,” Mathematical Models and Methods in Applied Sciences, 10, pp. 187202 (2000).CrossRefGoogle Scholar
48.El-Misery, A. M., Elshehawey, E. F. and Abd El-Naby, A. H., “Peristaltic Motion of an Incompressible Generalized Newtonian Fluid in a Planar Channel,” Journal of the Physical Society of Japan, 65, pp. 35243529 (1996).Google Scholar
49.Elshehawey, E. F., El-Misery, A. M. and Abd El-Naby, A. H., “Peristaltic Motion of Generalized Newtonian Fluid in a Non-Uniform Channel,” Journal of the Physical Society of Japan, 67, pp. 434440 (1998).Google Scholar
50.Gupta, B. B. and Sheshadi, V., “Peristaltic Pumping in Non-Uniform Tubes,” Journal of Biomechanics, 9, pp. 105109 (1976).Google Scholar