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Unsteady Unidirectional Flow of Bingham Fluid Through the Parallel Microgap Plates with Wall Slip and Given Inlet Volume Flow Rate Variations

Published online by Cambridge University Press:  29 January 2013

Y.W. Lin
Affiliation:
Department of Mechanical Engineering, National Cheng Kung University Tainan, Taiwan 70101, R.O.C.
C.-I. Chen
Affiliation:
Department of Industrial Management, I-Shou University, Kaohsiung, Taiwan 84001, R.O.C.
C.-K. Chen*
Affiliation:
Department of Mechanical Engineering, National Cheng Kung University, Tainan, Taiwan 70101, R.O.C.
*
*Corresponding author (, [email protected])
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Abstract

In this paper, Laplace transformation method is used to solve the velocity profile and pressure gradient of the unsteady unidirectional flow of Bingham fluid. Between the parallel microgap plates, the flow motion is induced by a prescribed arbitrary inlet volume flow rate which varies with time. Due to the rarefaction, the wall slip condition is existed; therefore, the complexity of solution is also increased. In order to understand the flow behavior of Bingham fluid, there are two basic flow situations are solved. One is a suddenly started flow and the other is constant acceleration flow. Furthermore, linear acceleration and oscillatory flow are also considered. The result indicates when the yield stress τ0 is zero; the solution of the problem reduces to Newtonian fluid.

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

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References

REFERENCES

1.Das, D. and Arakeri, J. H., “Unsteady Laminar Duct Flow with a Given Volume Flow Rate Variation,” Journal of Applied Mechanics, 67, pp. 274281 (2000).Google Scholar
2.Chen, C. I., Yang, Y. T. and Chen, C. K., “Unsteady Unidirectional Flow of a Voigt Fluid Between the Parallel Plates with Different Given Volume Flow Rate Conditions,” Applied Mathematics and Computation, 144, pp. 249260 (2003).Google Scholar
3.Chen, C. I., Chen, C. K. and Yang, Y. T., “Unsteady Unidirectional Flow of Voigt Fluid in the Circular Duct with Different Given Volume Flow Rate Conditions,” Heat and Mass Transfer, 41, pp. 3743 (2004).CrossRefGoogle Scholar
4.Chen, C. I., Hayat, T. and Chen, J. L., “Exact Solutions for the Unsteady Flow of a Burger's Fluid in a Duct Induced by Time-Dependent Prescribed Volume Flow Rate,” Heat and Mass Transfer, 43, pp. 8590 (2006).Google Scholar
5.Chen, C. I., Chen, C. K. and Yang, Y. T., “Unsteady Unidirectional Flow of Bingham Fluid Between Parallel Plates with Different Given Volume Flow Rate Conditions,” Applied Mathematical Modelling, 28, pp. 697709 (2004).Google Scholar
6.Chen, C. I., Chen, C. K. and Yang, Y. T., “Unsteady Unidirectional Flow of an Oldroyd-B Fluid in a Circular Duct with Different Given Volume Flow Rate Conditions,” Heat and Mass Transfer, 40, pp. 203209 (2004).Google Scholar
7.Chen, C. K., Chen, C. I. and Yang, Y. T., “Proceedings of the Institution of Mechanical Engineers, Part C,” Journal of Mechanical Engineering Science, 216, pp. 583590 (2002).Google Scholar
8.Chen, C. I., Chen, C. K. and Yang, Y. T., “Unsteady Unidirectional Flow of Second Grade Fluid Between the Parallel Plates with Different Given Volume Flow Rate Conditions,” Applied Mathematics and Computation, 137, pp. 437450 (2003).CrossRefGoogle Scholar
9.Ambrish, K. T. and Santos, K. R., “Analytical Studies on Transient Rotating Flow of a Second Grade Fluid in a Porous Medium,” Advances in Theoretical and Applied Mechanics, 2, pp. 3341 (2009).Google Scholar
10.Beskok, A. and Karniadakis, G. E., “Simulation of Slip-Flows in Complex Micro-Geometries,” Proceedings of the Annual Meeting of the American Society of Mechanical Engineers, 40, pp. 355370 (1992).Google Scholar
11.Abdullah, I., Amin, N. and Hayat, N. T., “Magneto-hydrodynamic Effects on Blood Flow Through an Irregular Stenosis,” International Journal for Numerical Methods in Fluids, 67, pp. 16241636 (2011).CrossRefGoogle Scholar
12.Hayat, T., Safdar, A., Awais, M., et al, “Unsteady Three-Dimensional Flow in a Second-Grade Fluid over a Stretching Surface,” Zeitschrift Fur Naturforschung Section A-A Journal of Physical Sciences, 66, pp. 635642 (2011).CrossRefGoogle Scholar
13.Wang, Y., Ali, N. and Hayat, T., “Peristaltic Motion of a Magnetohydrodynamic Micropolar Fluid in a Tube,” Applied Mathematical Modelling, 35, pp. 37373750 (2011).Google Scholar
14.Hayat, T., Saleem, N., Mesloub, S., and Ali, N., “Magnetohydrodynamic Flow of a Carreau Fluid in a Channel with Different Wave Forms,” Zeitschrift Fur Naturforschung Section A-A Journal of Physical Sciences, 66, pp. 215222 (2011).Google Scholar
15.Hayat, T., Saleem, N. and Hendi, A. A., “A Mathematical Model for Studying the Slip Effect on Peristaltic Motion with Heat and Mass Transfer,” Chinese Physics Letters, 28, 034702 (2011).Google Scholar
16.Wang, Y., Ali, N. and Hayat, T., “Peristaltic Motion of a Magnetohydrodynamic Generalized Second-Order Fluid in an Asymmetric Channel,” Numerical Methods for Partial Differential Equations, 27, pp. 415435 (2011).Google Scholar
17.Hayat, T., Javed, M., Asghar, S., and Mesloub, S., “Compliant Wall Analysis of an Electrically Conducting Jeffrey Fluid with Peristalsis,” Zeitschrift Fur Naturforschung Section A-A Journal of Physical Sciences. 66, pp. 106116 (2011).Google Scholar
18.Chen, C. K., Lai, H. Y. and Chen, W. F., “Unsteady Unidirectional Flow of Second-Grade Fluid Through a Microtube with Wall Slip and Different Given Volume Flow Rate,” Mathematical Problems in Engineering Article Number: 416837 (2010).Google Scholar
19.Chen, C. I., Chen, C. K. and Lin, H. K., “Analysis of Unsteady Flow Through a Microtube with Wall Slip and Given Inlet Volume Flow Rate Variations,” Journal of Applied Mechanics-T, ASME, 75, 014506 (2008).Google Scholar
20.Lee, C. M. and Tsai, K. I., Non-Newtonian Fluid Mechanics, Petroleum University Press, China, (1998) (in Chinese).Google Scholar
21.Arpaci, V. S., Conduction Heat Transfer, Addison-Wesley, USA (1966).Google Scholar