Radiation Effects on Flow past a Stretching Plate with Temperature Dependent Viscosity ()

Michalis Xenos

Section of Applied Mathematics and Engineering Research, Department of Mathematics, University of Ioannina, Ioannina, Greece.

**DOI: **10.4236/am.2013.49A001
PDF
HTML XML
3,305
Downloads
6,433
Views
Citations

Section of Applied Mathematics and Engineering Research, Department of Mathematics, University of Ioannina, Ioannina, Greece.

The effect of radiation on the flow over a stretching plate of an optically thin gray, viscous and incompressible fluid is studied. The fluid viscosity is assumed to vary as an inverse linear function of the temperature. The partial differential equations (PDEs) and their boundary conditions, describing the problem under consideration, are dimensionalized and the numerical solution is obtained by using the finite volume discretization methodology which is suitable for fluid mechanics applications. The numerical results for the velocity and temperature profiles are shown for different dimensionless parameters entering the problem under consideration, such as the temperature parameter, *θr*, the radiation parameter,* S*, and the Prandtl number, *Pr*. The numerical results indicate a strong influence of these parameters on the non-dimensional velocity and temperature profiles in the boundary layer.

Keywords

Radiation; Stretching Plate; Optically Thin Gray Fluid; Viscosity as a Function of the Temperature

Share and Cite:

M. Xenos, "Radiation Effects on Flow past a Stretching Plate with Temperature Dependent Viscosity," *Applied Mathematics*, Vol. 4 No. 9A, 2013, pp. 1-5. doi: 10.4236/am.2013.49A001.

1. Introduction

At high temperature, radiation has significant effects on the flow field. These effects have substantial applications in many industrial areas, such as electrical power generation, solar power technology, and aerospace engineering.

There has been extensive research on the effects of radiation on fluid flow. The free convection flow in the presence of radiation has been previously studied by Ali et al. [1], Seddeek and Abdelmeguid [2], Raptis and Toki [3], and Malekzadeh et al. [4]. The magnetohydrodynamic (MHD) flow in the presence of radiation has been investigated by Chamkha et al. [5], Raptis et al. [6], Duwairi [7], Ouaf [8], Abd-El Aziz [9], Pal and Mondal [10] and Shit and Haldar [11]. The flow through a porous medium in the presence of radiation has been studied by Murthy et al. [12], Al-Harbi [13], Al-Odat et al. [14], Raptis and Perdikis [15], Duwairi [16] and Badruddin et al. [17], and Awad et al. [18]. Raptis [19], Datti et al. [20], Abel et al. [21], Siddheshwar and Mahabaleswar [22] and Khan [23] have investigated the effects of radiation on the viscoelastic flow. The above studies, however, are under the assumption that the fluid is considered to be a thick gray fluid.

Bestman and Adiepong [24] studied the unsteady hydromagnetic free-convection flow with radiative heat transfer in a rotating thin gray fluid. The unsteady flow under the radiation effect of a thin gray fluid over a moving vertical plate was studied by Raptis and Perdikis [25]. Rajesh [26] studied the radiation effects of a thin gray fluid on MHD free convective flow near a vertical plate with ramped wall temperature under small magnetic Reynolds number. Rajput and Kumar [27] investigated the rotation and radiation effects on MHD flow of a thin gray fluid past an impulsively started vertical plate with variable temperature. Raptis [28] studied the free convective oscillatory flow and mass transfer past a porous plate in the presence of radiation of an optically thin fluid.

In the present study, we determine the effect of radiation on the flow field over a stretching plate of an optically thin gray fluid. We consider the fluid as viscous and incompressible, with temperature dependent viscosity.

The presented results are obtained after dimensionalization of the PDEs using a numerical approach. This approach is based on the finite volume (FV) discretization scheme. The discretization was performed with the use of a specialized symbolic package created in Mathematics.

2. Governing Equations

We consider the flow of a viscous and incompressible fluid due to an isothermal stretching flat surface. The fluid properties are assumed to be isotropic and constant, except for the fluid dynamic viscosity. The x-axis is taken along the plate and the y-axis normal to it, as depicted in Figure 1. The radiation heat flux in the x-direction is considered negligible in comparison to that in the y-direction.

The equations governing the problem are given by:

Continuity equation

(1)

Momentum equation

(2)

Energy equation

. (3)

where are the components of the velocity in the x and y directions respectively, is the fluid density, is the dynamic viscosity, T is the fluid temperature, k is the thermal conductivity, is the specific heat of the fluid under constant pressure and is the radiative heat flux.

The dynamic viscosity is assumed to be an inverse linear function of temperature [29].

(4)

or

(5)

where

(6)

is a constant, is the dynamic viscosity at infinity, is the kinematic viscosity at infinity, is a reference temperature, is the temperature at infinity, is a constant which in general is positive for liquids and

Figure 1. Physical model and co-ordinate system of the problem.

negative for gases.

The boundary conditions are defined as follows:

(7)

where is a constant and is the temperature of the stretching flat surface. In the case of an optically thin gray fluid the local radiant absorption is expressed as [8, 25,28],

(8)

where is the absorption coefficient and is the Stefan-Boltzman constant. We assume that the temperature differences within the flow are sufficiently small such that may be expressed as a linear function of the temperature. This is accomplished by expanding in a Taylor series about and neglecting higher-order terms, thus

(9)

Equation (8) through (9) takes the form:

(10)

Introducing the following transformations

(11)

where a prime denotes differentiation with respect to. In view of (10) and (11), Equation (1) is satisfied identically and Equations (2) and (3) reduce to

(12)

(13)

The boundary conditions (7) are transformed to

(14)

3. Numerical Solution

The non-linear system of coupled differential Equations (12) and (13) subject to the boundary conditions (14) has been solved following a symbolic approach. For this purpose we have used the Computer Algebra System (CAS) Mathematica [30].

The analysis begins by obtaining the discretized form of the system of equations by using a symbolic package developed for that purpose [31]. To discretize the coupled set of ordinary differential equations the finite volume method on a collocated grid is used [32]. Having obtained the discretized system, we construct the system of algebraic equations. Then the system is solved algebraically by Mathematica’s function Solve in respect to the grid values of the functions,. More details about the numerical approach can be found elsewhere [31]. Grid independence studies were performed to establish that the results are not grid dependent.

4. Results and Discussion

In the present study we numerically investigate the effect of radiation on the flow field over a stretching plate of an optically thin gray fluid, Figure 1. The fluid was considered viscous and incompressible. The viscosity was temperature dependent as shown in Equation (4). The results are presented in figures for the non-dimensional velocity, , and non-dimensional temperature, in respect to the temperature parameter, , radiation parameter, , and the Prantdl number,.

In Figure 2, the effect of the temperature parameter on the non-dimensional velocity, , when and is presented. Velocity decreases with the increase of the temperature parameter. Especially for, the velocity is substantially reduced leading to a thinner boundary layer (Figure 2, line 3).

Figure 2. Velocity profiles for different values of the temperature parameter θ_{r} and for Pr = 0.5, S = 5.

The effect of the radiation parameter S (S: 0.1, 1, 7) on the non-dimensional velocity is shown in Figure 3, when Pr = 0.5 and. The velocity increases with the increase of the radiation parameter. This effect is more pronounced when the radiation parameter has larger values, as depicted in Figure 3.

The effect of the radiation parameter S (S: 0.1, 1, 7) on the non-dimensional temperature is shown in Figure 4, when Pr = 0.5 and. When the radiation parameter increases the temperature decreases, and this effect is more pronounced as the radiation parameter increases.

The effect of the Prandtl number, Pr, on the non-dimensional temperature is presented in Figure 5 for three different values of Prandtl (Pr: 0.5, 0.7, 1), when and S = 1. The increase of Prandtl number leads to a decrease of the temperature in the boundary layer.

Finally, Figures 6 and 7 show the effect of the temperature parameter on the non-dimensional velocity and temperature when Pr = 0.7, S = 1 and for

Figure 3. Velocity profiles for different values of the radiation parameter S and for Pr = 0.5, θ_{r} = −1.

Figure 4. Temperature profiles for different values of the radiation parameter S and for Pr = 0.5, θ_{r} = −1.

Figure 5. Temperature profiles for different values of the Prandtl number Pr and for θ_{r} = −1 and S = 1.

Figure 6. Velocity profiles for different values of the temperature parameter θ_{r} and for Pr = 0.7, S = 1.

Figure 7. Temperature profiles for different values of the temperature parameter θ_{r} and for Pr = 0.7, S = 1.

three different values of the temperature parameter. Temperature increases with the increase of the temperature parameter, (: –2, –0.05, –0.01). However, the effect of the temperature parameter is more pronounced on the non-dimensional velocity and it decreases as the parameter increases, Figure 6.

The numerical results of this study could bring new insight on the effect of thermal radiation on the flow past a stretching plate with temperature dependent viscosity. These results could be utilized in many industrial and practical areas, including glass and semiconductor processing, atmospheric flows with application to global climate change, electrical power generation, solar power technology, and aerospace engineering.

5. Conclusion

The effects of thermal radiation on the flow and temperature fields over a stretching plate of an optically thin gray fluid were numerical investigated. The fluid was considered incompressible with temperature dependent viscosity. The main findings of this study could be summarized in the following: (1) Increase of the radiation parameter increases the velocity profile but decreases the temperature profiles. (2) On the other hand, increase of the temperature parameter decreases the velocity profile and increases the temperature profile in the boundary layer. (3) Increase of Prandtl number decreases the temperature profile in the boundary layer.

Conflicts of Interest

The authors declare no conflicts of interest.

[1] |
M. M. Ali, T. S. Chen and B. F. Armaly, “Natural Con vection-Radiation Interaction in Boundary-Layer Flow over Horizontal Surfaces,” AIAA Journal, Vol. 22, No. 12, 1984, pp. 1797-1803. doi:10.2514/3.8854 |

[2] | M. A. Seddeek and M. S. Abdelmeguid, “Effects of Radi ation and Thermal Diffusivity on Heat Transfer over a Stretching Surface with Variable Heat Flux,” Physics Let ters A, Vol. 348, No. 3-6, 2006, pp. 172-179. doi:10.1016/j.physleta.2005.01.101 |

[3] | A. Raptis and C. J. Toki, “Thermal Radiation in the Pres ence of Free Convective Flow past a Moving Vertical Po rous Plate—An Analytical Solution,” International Jour nal of Applied Mechanics and Engineering, Vol. 14, No. 4, 2009, pp. 1115-1126. |

[4] |
P. Malekzadeh, M. A. Moghimi and M. Nickaeen, “The Radiation and Variable Viscosity Effects on Electrically Conducting Fluid over a Vertically Moving Plate Sub jected to Suction and Heat Flux,” Energy Conversion and Management, Vol. 52, No. 5, 2011, pp. 2040-2047.
doi:10.1016/j.enconman.2010.12.006 |

[5] | A. J. Chamkha, M. Mujtaba, A. Quadri and C. Issa, “Ther mal Radiation Effects on MHD Forced Convection Flow Adjacent to a Non-Isothermal Wedge in the Presence of a Heat Source or Sink,” Heat and Mass Transfer, Vol. 39, No. 4, 2003, pp. 305-312. |

[6] | A. Raptis, C. Perdikis and H. S. Takhar, “Effect of Ther mal Radiation on MHD Flow,” Applied Mathematics and Computation, Vol. 153, No. 3, 2004, pp. 645-649. doi:10.1016/S0096-3003(03)00657-X |

[7] | H. M. Duwairi, “Viscous and Joule Heating Effects on Forced Convection Flow from Radiate Isothermal Porous Surfaces,” International Journal of Numerical Methods for Heat & Fluid Flow, Vol. 15, No. 5-6, 2005, pp. 429 440. doi:10.1108/09615530510593620 |

[8] |
M. E. M. Ouaf, “Exact Solution of Thermal Radiation on MHD Flow over a Stretching Porous Sheet,” Applied Mathematics and Computation, Vol. 170, No. 2, 2005, pp. 1117-1125. doi:10.1016/j.amc.2005.01.010 |

[9] | M. Abd-El Aziz, “Thermal Radiation Effects on Magne Tohydrodynamic Mixed Convection Flow of a Micropo lar Fluid past a Continuously Moving Semi-Infinite Plate for High Temperature Differences,” Acta Mechanica, Vol. 187, No. 1-4, 2006, pp. 113-127. doi:10.1007/s00707-006-0377-9 |

[10] |
D. Pal and H. Mondal, “Effects of Soret Dufour, Chem ical Reaction and Thermal Radiation on MHD Non-Darcy Unsteady Mixed Convective Heat and Mass Transfer over a Stretching Sheet,” Communications in Nonlinear Sci ence and Numerical Simulation, Vol. 16, No. 4, 2011, pp. 1942-1958. doi:10.1016/j.cnsns.2010.08.033 |

[11] | G. C. Shit and R. Haldar, “Effects of Thermal Radiation on MHD Viscous Fluid Flow and Heat Transfer over Non-Linear Shrinking Porous Sheet,” Applied Mathemat ics and Mechanics-English Edition, Vol. 32, No. 6, 2011, pp. 677-688. doi:10.1007/s10483-011-1448-6 |

[12] | P. V. S. N. Murthy, S. Mukherjee, D. Srinivasacharya, and P. V. S. S. S. R. Krishna, “Combined Radiation and Mixed Convection from a Vertical Wall with Suction/In jection in a Non-Darcy Porous Medium,” Acta Mechanica, Vol. 168, No. 3-4, 2004, pp. 145-156. doi:10.1007/s00707-004-0084-3 |

[13] | S. M. Al-Harbi, “Numerical Study of Natural Convection Heat Transfer with Variable Viscosity and Thermal Radi ation from a Cone and Wedge in Porous Media,” Applied Mathematics and Computation, Vol. 170, No. 1, 2005, pp. 64-75. doi:10.1016/j.amc.2004.10.093 |

[14] | M. Q. Al-Odat, F. M. S. Al-Hussien and R. A. Damseh, “Influence of Radiation on Mixed Convection over a We dge in Non-Darcy Porous Medium,” Forschung Im Inge nieurwesen-Engineering Research, Vol. 69, No. 4, 2005, pp. 209-215. doi:10.1007/s10010-005-0004-2 |

[15] | A. Raptis and C. Perdikis, “Flow through a High Poros ity Medium in the Presence of Radiation,” Journal of Porous Media, Vol. 9, No. 2, 2006, pp. 169-175. doi:10.1615/JPorMedia.v9.i2.60 |

[16] |
H. M. Duwairi. “Radiation Effects on Mixed Convection over a Nonisothermal Cylinder and Sphere in a Porous Media,” Journal of Porous Media, Vol. 9, No. 3, 2006, pp. 251-259. doi:10.1615/JPorMedia.v9.i3.60 |

[17] |
I. A. Badruddin, Z. A. Zainal, P. A. A. Narayana and K. N. Seetharamu, “Numerical Analysis of Convection Con duction and Radiation Using a Non-Equilibrium Model in a Square Porous Cavity,” International Journal of Ther mal Sciences, Vol. 46, No. 1, 2007, pp. 20-29.
doi:10.1016/j.ijthermalsci.2006.03.006 |

[18] | F. G. Awad, P. Sibanda, S. S. Motsa and O. D. Makinde, “Convection from an Inverted Cone in a Porous Medium with Cross-Diffusion Effects,” Computers & Mathemat ics with Applications, Vol. 61, No. 5, 2011, pp. 1431-1441. doi:10.1016/j.camwa.2011.01.015 |

[19] | A. Raptis, “Radiation and Viscoelastic Flow,” Internatio nal Communications in Heat and Mass Transfer, Vol. 26, No. 6, 1999, pp. 889-895. |

[20] | P. S. Datti, K. V. Prasad, M. S. Abel and A. Joshi, “MHD Visco-Elastic Fluid Flow over a Non-Isothermal Stretching Sheet,” International Journal of Engineering Science, Vol. 42, No. 8-9, 2004, pp. 935-946. doi:10.1016/j.ijengsci.2003.09.008 |

[21] | S. Abel, K. V. Prasad and A. Mahaboob, “Buoyancy Force and Thermal Radiation Effects in MHD Boundary Layer Visco-Elastic Fluid Flow over Continuously Moving Stre tching Surface,” International Journal of Thermal Scienc es, Vol. 44, No. 5, 2005, pp. 465-476. doi:10.1016/j.ijthermalsci.2004.08.005 |

[22] | P. G. Siddheshwar and U. S. Mahabaleswar, “Effects of Radiation and Heat Source on MHD Flow of a Viscoelas tic Liquid and Heat Transfer over a Stretching Sheet,” In ternational Journal of Non-Linear Mechanics, Vol. 40, No. 6, 2005, pp. 807-820. |

[23] | S. K. Khan, “Heat Transfer in a Viscoelastic Fluid Flow over a Stretching Surface with Heat Source/Sink, Suc tion/Blowing and Radiation,” International Journal of Heat and Mass Transfer, Vol. 49, No. 3-4, 2006, pp. 628-639. doi:10.1016/j.ijheatmasstransfer.2005.07.049 |

[24] | A. R. Bestman and S. K. Adjepong, “Unsteady Hydro Magnetic Free-Convection Flow with Radiative Heat Transfer in a Rotating Fluid. Compressible Optically Thin Fluid,” Astrophysics and Space Science, Vol. 143, No. 2, 1988, pp. 217-224. doi:10.1007/BF00637135 |

[25] | A. Raptis and C. Perdikis, “Thermal Radiation of an Opti cally Thin Gray Gas,” International Journal of Applied Mechanics and Engineering, Vol. 8, No. 1, 2003, pp. 131-134. |

[26] | V. Rajesh, “Radiation Effects on MHD Free Convective Flow near a Vertical Plate with Ramped Wall Tempera ture,” International Journal of Applied Mathematics and Mechanics, Vol. 6, No. 21, 2010, pp. 60-77. |

[27] | U. S. Rajput and S. Kumar, “Rotation and Radiation Ef fects on MHD Flow past an Impulsively Started Vertical Plate with Variable Temperature,” International Journal of Mathematical Analysis, Vol. 5, No 24, 2011, pp. 1155-1163. |

[28] |
A. Raptis, “Free Convective Oscillatory Flow and Mass Transfer past a Porous Plate in the Presence of Radiation for an Optically Thin Fluid,” Thermal Science, Vol. 15, No. 3, 2011, pp. 849-857. doi:10.2298/TSCI101208032R |

[29] | F. C. Lai and F. A. Kulacki, “The Effect of Variable Visco sity on Convective Heat-Transfer Along a Vertical Sur face in a Saturated Porous-Medium,” International Jour nal of Heat and Mass Transfer, Vol. 33, No. 5, 1990, pp. 1028-1031. doi:10.1016/0017-9310(90)90084-8 |

[30] | Wolfram-Research, “Mathematica Edition: Version 8.0,” Wolfram-Research, Inc., Champaign, 2010. |

[31] | M. Xenos, S. Dimas and A. Raptis, “MHD Free Convec tive Flow of Water near 4°C past a Vertical Moving Plate with Constant Suction,” Applied Mathematics, Vol. 4, No. 1, 2013, pp. 52-57. |

[32] | S. V. Patankar, “Numerical Heat Transfer and Fluid Flow,” McGraw-Hill, New York, 1980. |

Journals Menu

Contact us

+1 323-425-8868 | |

customer@scirp.org | |

+86 18163351462(WhatsApp) | |

1655362766 | |

Paper Publishing WeChat |

Copyright © 2024 by authors and Scientific Research Publishing Inc.

This work and the related PDF file are licensed under a Creative Commons Attribution 4.0 International License.