Optimal homotopy asymptotic method for investigation of effects of thermal radiation, internal heat generation, and buoyancy on velocity and heat transfer in the Blasius flow. (English) Zbl 1476.80008
Summary: In this study, analytical examination of effects of internal heat generation, thermal radiation, and buoyancy force on flow and heat transfer in the Blasius flow over flat plate has been presented. The governing nonlinear partial differential equations of the problem are transformed into a set of coupled nonlinear third-order ordinary differential equations by the similarity variable method and have been systematically solved using the optimal homotopy asymptotic method. The main aim of the present study is to inspect the effects of various physical parameters in the flow model on velocity and heat transfer in steady two-dimensional laminar boundary layer flow with convective boundary conditions. The influences of the Grashof number, internal heat generation, the Biot number, radiation parameter, and the Prandtl number on the skin-friction coefficient, the fluid velocity profile, and temperature distribution have been determined and discussed in detail through several plots. The finding revealed that the fluid velocity and temperature delivery upsurge with snowballing in the values of the Biot number and internal heat generation parameters. The temperature profile of the fluid declines contrary to the value of the Grashof number and the Prandtl number but increases with thermal radiation. Moreover, it is found that the skin-friction coefficient and the rate of heat intensify with the Grashof number, internal heat generation, the Biot number, and thermal radiation parameter. The obtained result is likened with the previously published numerical results in a limited case of the problem and shows an excellent agreement.
MSC:
| 80A21 | Radiative heat transfer |
| 80A19 | Diffusive and convective heat and mass transfer, heat flow |
| 76R10 | Free convection |
| 35B40 | Asymptotic behavior of solutions to PDEs |
| 35A24 | Methods of ordinary differential equations applied to PDEs |
| 80M35 | Asymptotic analysis for problems in thermodynamics and heat transfer |
Keywords:
thermal radiation; homotopy asymptotic method, buoyancy on velocity; Blasius flow; skin-friction coefficient; Grashof number; internal heat generation; Biot number; Prandtl numberReferences:
| [1] | Blasius, H., Boundary layers in fluids of small viscosity, Zeitschrift für Angewandte Mathematik und Physik, 56, 1, 1-37 (1908) · JFM 39.0803.02 |
| [2] | Fang, T., Similarity solutions for a moving-flat plate thermal boundary layer, Acta Mechanica, 163, 3-4, 161-172 (2003) · Zbl 1064.76031 · doi:10.1007/s00707-003-0004-y |
| [3] | Makinde, O. D., Free convection flow with thermal radiation and mass transfer past a moving vertical porous plate, International Communications in Heat and Mass Transfer, 32, 10, 1411-1419 (2005) · doi:10.1016/j.icheatmasstransfer.2005.07.005 |
| [4] | Cortell, R., Flow and heat transfer of a fluid through a porous medium over a stretching surface with internal heat generation/absorption and suction/blowing, Fluid Dynamics Research, 37, 4, 231 (2005) · Zbl 1153.76423 |
| [5] | Shu, J.-J.; Ioan, P., On thermal boundary layers on a flat plate subjected to a variable heat flux, International Journal of Heat and Fluid Flow, 19, 1, 79-84 (1998) · doi:10.1016/S0142-727X(97)10026-1 |
| [6] | Abusitta, A. M. M., A note on a certain boundary-layer equation, Applied Mathematics and Computation, 64, 1, 73-77 (1994) · Zbl 0811.34013 |
| [7] | Falkneb, V. M.; Sylvia, W. S., LXXXV, The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science, 12, 80, 865-896 (1931) |
| [8] | Wang, L., A new algorithm for solving classical Blasius equation, Applied Mathematics and Computation, 157, 1, 1-9 (2004) · Zbl 1108.65085 |
| [9] | Reddy, M. G.; Rani, M. V. V. N. L. S.; Kumar, K. G.; Prasannakumar, B. C.; Chamkha, A. J., Cattaneo-Christov heat flux model on Blasius-Rayleigh-Stokes flow through a transitive magnetic field and Joule heating, Physica A: Statistical Mechanics and its Applications, 548, article 123991 (2020) · Zbl 07530537 |
| [10] | Abdelsalam, S. I.; Vafai, K., Combined effects of magnetic field and rheological properties on the peristaltic flow of a compressible fluid in a microfluidic channel, European Journal of Mechanics-B/Fluids, 65, 398-411 (2017) · Zbl 1408.76007 · doi:10.1016/j.euromechflu.2017.02.002 |
| [11] | Krishnamurthy, M. R.; Prasannakumara, B. C.; Gorla, R. S. R.; Gireesha, B. J., Non-linear thermal radiation and slip effect on boundary layer flow and heat transfer of suspended nanoparticles over a stretching sheet embedded in porous medium with convective boundary conditions, Journal of Nanofluids, 5, 4, 522-530 (2016) |
| [12] | Xiong, P.-Y.; Hamid, A.; Chu, Y.-M.; Khan, M. I.; Gowda, R. J. P.; Kumar, R. N.; Prasannakumara, B. C.; Qayyum, S., Dynamics of multiple solutions of Darcy-Forchheimer saturated flow of Cross nanofluid by a vertical thin needle point, The European Physical Journal Plus, 136, 3, 1-22 (2021) |
| [13] | Kejela, S. B.; Firdi, M. D., Analytical analysis of effects of buoyancy, internal heat generation, magnetic field, and thermal radiation on a boundary layer over a vertical plate with a convective surface boundary condition, International Journal of Differential Equations, 2020 (2020) · Zbl 1465.76033 |
| [14] | Mabood, F.; Waqar, A. K.; Ahmad, I. M. I., Analytical solution for radiation effects on heat transfer in Blasius flow, International Journal of Modern Engineering Sciences, 2, 2, 63-72 (2013) |
| [15] | Gnaneswara Reddy, M.; Gowda, R. J. P.; Kumar, R. N.; Prasannakumara, B. C.; Kumar, K. G., Analysis of modified Fourier law and melting heat transfer in a flow involving carbon nanotubes, Proceedings of the Institution of Mechanical Engineers, Part E: Journal of Process Mechanical Engineering, 2021, article 09544089211001353 (2021) |
| [16] | Kuo, B., Thermal boundary-layer problems in a semi-infinite flat plate by the differential transformation method, Applied Mathematics and Computation, 150, 2, 303-320 (2004) · Zbl 1059.76061 · doi:10.1016/S0096-3003(03)00233-9 |
| [17] | Sakiadis, B. C., Boundary-layer behavior on continuous solid surfaces: I. Boundary-layer equations for two-dimensional and axisymmetric flow, AICHE Journal, 7, 1, 26-28 (1961) · doi:10.1002/aic.690070108 |
| [18] | Crane, L. J., Flow past a stretching plate, Zeitschrift für angewandte Mathematik und Physik ZAMP, 21, 4, 645-647 (1970) · doi:10.1007/BF01587695 |
| [19] | Hossain, M. A.; Takhar, H. S., Radiation effect on mixed convection along a vertical plate with uniform surface temperature, Heat and Mass Transfer, 31, 4, 243-248 (1996) · doi:10.1007/BF02328616 |
| [20] | Bataller, R., Radiation effects for the Blasius and Sakiadis flows with a convective surface boundary condition, Applied Mathematics and Computation, 206, 2, 832-840 (2008) · Zbl 1153.76025 · doi:10.1016/j.amc.2008.10.001 |
| [21] | Olanrewaju, P. O.; Gbadeyan, J. A.; Hayat, T.; Awatif, A. H., Effects of internal heat generation, thermal radiation and buoyancy force on a boundary layer over a vertical plate with a convective surface boundary condition, South African Journal of Science, 107, 9-10, 80-85 (2011) |
| [22] | Aziz, A., A similarity solution for laminar thermal boundary layer over a flat plate with a convective surface boundary condition, Communications in Nonlinear Science and Numerical Simulation, 14, 4, 1064-1068 (2009) · doi:10.1016/j.cnsns.2008.05.003 |
| [23] | Aziz, A., Hydrodynamic and thermal slip flow boundary layers over a flat plate with constant heat flux boundary condition, Communications in Nonlinear Science and Numerical Simulation, 15, 3, 573-580 (2010) · doi:10.1016/j.cnsns.2009.04.026 |
| [24] | Garg, P.; Purohit, G. N.; Chaudhary, R. C., A similarity solution for laminar thermal boundary layer over a flat plate with internal heat generation and a convective surface boundary condition, Journal of Rajasthan Academy of Physical Sciences, 14, 2, 221-226 (2015) · Zbl 1400.76028 |
| [25] | Esmaeilpour, M.; Davood, D. G., Solution of the Jeffery-Hamel flow problem by optimal homotopy asymptotic method, Computers & Mathematics with Applications, 59, 11, 3405-3411 (2010) · Zbl 1197.76043 · doi:10.1016/j.camwa.2010.03.024 |
| [26] | Golbabai, A.; Mojtaba, F.; Khosro, S., Application of the optimal homotopy asymptotic method for solving a strongly nonlinear oscillatory system, Mathematical and Computer Modelling, 58, 11-12, 1837-1843 (2013) · Zbl 1327.70005 · doi:10.1016/j.mcm.2011.12.027 |
| [27] | Mabood, F.; Waqar, A. K., Homotopy analysis method for boundary layer flow and heat transfer over a permeable flat plate in a Darcian porous medium with radiation effects, Journal of the Taiwan Institute of Chemical Engineers, 45, 4, 1217-1224 (2014) · doi:10.1016/j.jtice.2014.03.019 |
| [28] | Saleem, S.; Nadeem, S.; Rashidi, M. M.; Raju, C. S., An optimal analysis of radiated nanomaterial flow with viscous dissipation and heat source, Microsystem Technologies, 25, 2, 683-689 (2019) · doi:10.1007/s00542-018-3996-x |
| [29] | Khan, I.; Shafquat, U.; Malik, M. Y.; Arif, H., Numerical analysis of MHD Carreau fluid flow over a stretching cylinder with homogenous-heterogeneous reactions, Results in Physics, 9, 1141-1147 (2018) · doi:10.1016/j.rinp.2018.04.022 |
| [30] | Marinca, V.; Nicolae, H.; Iacob, N., Optimal homotopy asymptotic method with application to thin film flow, Open Physics, 6, 3, 648-653 (2008) |
| [31] | Makinde, O. D.; Oladapo Olanrewaju, P., Buoyancy effects on thermal boundary layer over a vertical plate with a convective surface boundary condition, Journal of Fluids Engineering, 132, 4 (2010) |
| [32] | Ibrahim, S. M.; Reddy, N. B., Similarity solution of heat and mass transfer for natural convection over a moving vertical plate with internal heat generation and a convective boundary condition in the presence of thermal radiation, viscous dissipation, and chemical reaction, International Scholarly Research Notices, 2013 (2013) |
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