Welcome to Open Science
Contact Us
Home Books Journals Submission Open Science Join Us News
Effects of Thermal Radiation and Heat Generation on the Mechanical Properties of Unsteady Continuous Moving Surface in a Nanofluid in the Presence of Suction/Injection
Current Issue
Volume 1, 2014
Issue 3 (May)
Pages: 24-30   |   Vol. 1, No. 3, May 2014   |   Follow on         
Paper in PDF Downloads: 38   Since Aug. 28, 2015 Views: 1628   Since Aug. 28, 2015
Authors
[1]
Abdel-Rahman A. Saad, Engineering Mathematics and Physics Department, Faculty of Engineering, Benha University, Cairo, Egypt.
[2]
E. M. A. Elbashbeshy, Mathematics Department, Faculty of Science, Ain Shams University, Abbassia, Cairo, Egypt.
[3]
T. G. Emam, Mathematics Department, Faculty of Science, Ain Shams University, Abbassia, Cairo, Egypt.
[4]
M. S. Abdel-wahed, Engineering Mathematics and Physics Department, Faculty of Engineering, Modern University -MTI, Cairo, Egypt.
Abstract
The effect of thermal radiation, heat generation, suction/injection, Nanoparticles type, and Nanoparticles volume fraction on heat transfer characteristics and mechanical properties of unsteady moving surface embedded into cooling medium consists of water with Cu, Ag or Al2O3 particles has been investigated. Similarity equations are obtained through the application of similarity transformation techniques. These equations are solved numerically to obtain the velocity, temperature in the respective boundary layer.
Keywords
Nanofluid, Unsteady Motion, Heat Generation, Thermal Radiation, Suction/Injection
Reference
[1]
Schlichting H., Boundary layer theory, 6 edn. McGraw-hill, New Yourk, 1968.
[2]
Sakiadis, B.C. Boundary layer behavior on a continuous solid surface. AIChE 1961, 7:26-28.
[3]
Crane, L.J. Flow past a stretching plate. Zeitschrift fur Angewandte Mathematik und physic 1970,21:645-647.
[4]
Grubka,K. M. Bobba, Heat transfer characteristics of a contuous stretching surface with variable temperature, (ASME) Journal of Heat Transfer, 107 (1985), pp 248-250.
[5]
Gupta P.S. and Gupta A.S. Heat and mass transfer on a stretching sheet with suction or blowing. Can. J. Chem. Eng. 55,744-746,1977.
[6]
Banks, W.H.H. Similarity solution of the boundary layer equation for a stretching wall. J. Mech. Theory Appl., 2,375-392-1983.
[7]
Ali M.E. On thermal boundary layer on a power law stretched surface with suction or injection. Int. J. Heat Mass Flow, 16,280-290,1995.
[8]
Elbashbeshy E.M.A, Heat transfer over a stretching surface with variable heat flux. J. phys. D, phys, 31, 1951-1955, 1998.
[9]
Elbashbeshy E.M.A., and Bazid M.A.A. the effect of temperature dependent viscosity on heat transfer over continuous moving surface. J. phys. D, phys, 33, 2721, 2000.
[10]
Elbashbeshy E.M.A., and Bazid M.A.A. . Heat transfer in a porous medium over a stretching surface with internal heat generation and suction or injection. Appl Math. Coput. 158(3), 799-807,2004.
[11]
Elbashbeshy E.M.A.,and Bazid M.A.A. . Heat transfer over a stretching surface with internal heat generation. Can. J. Phys. 81:699-703.
[12]
Elbashbeshy E.M.A.,and Bazid M.A.A. Heat transfer over a continuously moving plate embedded in non-darcian porous medium. Int. J. Heat Mass Transfer, 43,3087-2092,2000.
[13]
Devi C.D.S., Takhar H.S. and Nath G., Unsteady mixed convection flow in stagnation region adjacent to a vertical surface, Heat Mass Transfer 26,71-79,1991.
[14]
Anderson H.T., Aarsth J.B., and Dandapat B.S., Heat transfer in a liquid film on an unsteady stretching surface. Int. J. Heat Transfer 43, 69-74, 2000.
[15]
Elbashbeshy E.M.A.,and Bazid M.A.A. Heat transfer over an unsteady stretching surface. Heat Mass Transfer, 41,1-4,2004.
[16]
Elbashbeshy E.M.A.,and Bazid M.A.A. Heat transfer over an unsteady stretching surface with internal heat generation. Appl. Math and Computations. 138(3), 239-245,2003.
[17]
Nazar R., Amin N., Pop I. and Flip D. Unsteady boundary layer flow in the region of the stagnation point on a stretching sheet. Int. J. Eng. Sci. 42,1241-1253,2004.
[18]
Ishak A, Nazar R., and Pop I. Heat transfer over an unsteady stretching permeable surface with prescribed wall temperature.Nonlinear Analysis: Real World Application 10: 2909-2913, 2009.
[19]
Choi S.U.S., Enhancing conductivity of fluids with Nanoparticles, ASME Fluid Eng. Division, 231,99-105,1995.
[20]
Das, S.K., Choi, S.U.S., Yu, W. and Pradeep, T. Nanofluids: Science and Technology NJ:Wiley; 2007.
[21]
Azizah M., Syakila A., Pop I., Flow and heat transfer over an unsteady shrinking sheet with suction in nanofluids. Int. J. Heat and Mass Transfer,2011.
[22]
Aminreza N., Rashid P., and Mohamed G. Effect of partial slip boundary condition on the flow and heat transfer of nanofluids past stretching sheet prescribed constant wall temperature. Int. J. of thermal Sci., 1-9,2012.
[23]
Nazar R., Tham L. and Pop I., Mixed convection boundary layer flow from a horizontal circular cylinder embedded in a porous medium filled with a nanofluid, Tranp. Porous med., 86, 517-536, 2011.
[24]
M. Hamad, Analytical solution of natural convection flow of Nanofluid over a linearly stretching sheet in the presence of magnetic field. International communications in heat and mass transfer 38, 487-492, 2011.
[25]
Oztop H. F., Abu Nada E., Numerical study of natural convection in partially heated rectangular enclosures filled with nanofluids, Int. J. Heat Fluid Flow, 29,1326-1336,2008.
[26]
Yacob, N.A, Ishak, A., Nazar, R. and Pop, I. Boundary layer flow past a stretching/ shrinking surface beneath an external uniform shear flow with a convective surface boundary condition in a nanofluid. Nanoscale Research Letters, 6:1-7,2011.
Open Science Scholarly Journals
Open Science is a peer-reviewed platform, the journals of which cover a wide range of academic disciplines and serve the world's research and scholarly communities. Upon acceptance, Open Science Journals will be immediately and permanently free for everyone to read and download.
CONTACT US
Office Address:
228 Park Ave., S#45956, New York, NY 10003
Phone: +(001)(347)535 0661
E-mail:
LET'S GET IN TOUCH
Name
E-mail
Subject
Message
SEND MASSAGE
Copyright © 2013-, Open Science Publishers - All Rights Reserved