Thermosolutal Effects in Cylindrical Flow with Suction Velocity

Chinedu  Nwaigwe; Amos  Emeka; Roseline Ize  Ndu

doi:10.17605/OSF.IO/HV5NP

Chinedu Nwaigwe Department of Mathematics, Rivers State University Port Harcourt, Nigeria
Amos Emeka Department of Mathematics, Rivers State University Port Harcourt, Nigeria
Roseline Ize Ndu Department of Mathematics, Rivers State University Port Harcourt, Nigeria

DOI: https://doi.org/10.17605/OSF.IO/HV5NP

Keywords: Thermosolutal, heat, solute, suction, velocity, specie

Abstract

This paper examined the problem of thermosolutal effects in a horizontal cylindrical channel with suction velocity. The fluid flow is assumed to be of constant viscosity, thermal conductivity, diffusivity and it is axi-symmetrical. The problem modelled followed the work of Ize et al.[24] by incorporating suction velocity to their work. Following their method of solution, the governing equations were solved. The analytical results were graphically computed using python programming codes and the graphs showed that fluid velocity increases with increase heat sink, thermal Grashof and solutal Grashof numbers. Also, velocity, energy and species profiles increase with increase in suction velocity while thermal conductivity and diffusivity decrease energy and specie profiles respectively.

Downloads

Download data is not yet available.

References

Makinde, O. D., & Chinyoka, T. (2012). Analysis of unsteady flow of a variable viscosity reactive fluid in a slit with wall suction or injection. Journal of Petroleum Science and Engineering, 94, 1-11. https://doi.org/10.1016/j.petrol.2012.06.023

Nwaigwe, C. (2010). Mathematical modelling of ground temperature with suction velocity and radiation. American Journal of Scientific and Industrial Research, 1(2), 238-241. doi:10.5251/ajsir.2010.1.2.238.241

Israel-Cookey, C., Ogulu, A., & Omubo-Pepple, V. B. (2003). Influence of viscous dissipation and radiation on unsteady MHD free-convection flow past an infinite heated vertical plate in a porous medium with time-dependent suction. International journal of heat and mass transfer, 46(13), 2305-2311. DOI: 10.1016/S0017-9310(02)00544-6

Deng, C., & Martinez, D. M. (2005). Viscous flow in a channel partially filled with a porous medium and with wall suction. Chemical Engineering Science, 60(2), 329-336. doi:10.1016/j.ces.2004.08.010

Rundora, L., & Makinde, O. D. (2013). Effects of suction/injection on unsteady reactive variable viscosity non-Newtonian fluid flow in a channel filled with porous medium and convective boundary conditions. Journal of Petroleum Science and Engineering, 108, 328-335. https://doi.org/10.1016/j.petrol.2013.05.010

Chinyoka, T., & Makinde, D. O. (2015). Unsteady and porous media flow of reactive non-Newtonian fluids subjected to buoyancy and suction/injection. International Journal of Numerical Methods for Heat & Fluid Flow. 25(7):1682-1704. DOI:10.1108/HFF-10-2014-0329

Nwaigwe, C., & Makinde, O. D. (2020). Finite Difference Investigation of a Polluted Non-Isothermal Variable-Viscosity Porous Media Flow. In Diffusion Foundations (Vol. 26, pp. 145-156). Trans Tech Publications Ltd. 26,145-156. https://doi.org/10.4028/www.scientific.net/DF.26.145

Weli, A., & Nwaigwe, C. (2020). Numerical analysis of channel flow with velocity-dependent suction and nonlinear heat source. Journal of Interdisciplinary Mathematics, 23(5), 987-1008.

Bunonyo, K. W., & Amos, E. (2022). Steady blood flow through a porous microchannel with the influence of an inclined magnetic field. 07(01), 096 – 112. DOI:10.30574/wjaets.2022.7.1.0104

Emeka, A., James, U., & Chinedu, N. (2019) Magnetohydrodynamic Convective Flow of a Walters’ B Fluid through a Non–Homogeneous Porous Medium with Soret Effect. International Journal of Applied Science and Mathematical Theory, 05(02). DOI:10.30574/wjaets.2022.7.1.0104

Emeka, A., Ndu Roseline, I., & Bunuoyo Wilcox, K.(2019) MHD Free Convective Dissipative Flow with Heat Source and Chemical Reaction. International Journal of Applied Science and Mathematical Theory, 05(01).

Hadidi, N., Rebhi, R., Bennacer, R., Menni, Y., Ameur, H., Lorenzini, G., & Ahmad, H. (2021). Thermosolutal natural convection across an inclined square enclosure partially filled with a porous medium. Results in Physics, 21, 103821. https://doi.org/10.1016/j.rinp.2021.103821

Shah, I. A., Bilal, S., Noeiaghdam, S., Fernandez-Gamiz, U., & Shahzad, H. (2022). Thermosolutal natural convection energy transfer in magnetically influenced casson fluid flow in hexagonal enclosure with fillets. Results in Engineering, 15, 100584. DOI:10.1016/j.rineng.2022.100584

Corson, L. T., & Pritchard, D. (2017). Thermosolutal convection in an evolving soluble porous medium. Journal of Fluid Mechanics, 832, 666-696. DOI: https://doi.org/10.1017/jfm.2017.663

Kishan, N., & Amrutha, P. (2015). Variable viscosity effects on mixed convection heat and mass transfer along a semi-infinite vertical plate in the presence of chemical reaction and viscous dissipation. International Journal of Engineering, Science and Technology, 7(2), 27-42. DOI: 10.4314/ijest.v7i2.3

Mahdy, A., & Ahmed, S. E. (2015). Thermosolutal Marangoni boundary layer magnetohydrodynamic flow with the Soret and Dufour effects past a vertical flat plate. Engineering Science and Technology, an International Journal, 18(1), 24-31. doi.org/10.1016/j.jestch.2014.08.003

Khan, A., Shah, R. A., Shuaib, M., & Ali, A. (2018). Fluid dynamics of the magnetic field dependent thermosolutal convection and viscosity between coaxial contracting discs. Results in Physics, 9, 923-938.

Kefayati, G. R., & Tang, H. (2018). MHD thermosolutal natural convection and entropy generation of Carreau fluid in a heated enclosure with two inner circular cold cylinders, using LBM. International Journal of Heat and Mass Transfer, 126, 508-530.

Nwaigwe, C. (2022). An Unconditionally Stable Scheme for Two-Dimensional Convection-Diffusion-Reaction Equations. no. January.

Mebine, P., & Adigio, E. M. (2009). Unsteady free convection flow with thermal radiation past a vertical porous plate with Newtonian heating. Turkish Journal of Physics, 33(2), 109-119.

Nwaigwe, C. (2020). Sequential implicit numerical scheme for pollutant and heat transport in a plane-poiseuille flow. Journal of applied and Computational Mechanics, 6(1), 13-25.

Asogwa, K. K., Uwanta, I. J., Momoh, A. A., & Omokhuale, E. (2013). Heat and mass transfer over a vertical plate with periodic suction and heat sink. Research Journal of Applied Sciences, Engineering and Technology, 5(1), 7-15.

Ize, N. R., Nwaigwe, C., & Emeka, A. (2023). Effects of Viscosity and Magnetic Field on a Non-Isothermal Cylindrical Channel Flow. Journal of Advances in Mathematics and Computer Science, 38(2), 32-47.

Nwaigwe, C. (2020). Analysis and application of a convergent difference scheme to nonlinear transport in a Brinkman flow. International Journal of Numerical Methods for Heat & Fluid Flow, 30(10), 4453-4473.

Nwaigwe, C., Ndu, R. I., & Weli, A. (2019). Wall Motion Effects on Channel Flow with Temperature-Dependent Transport Properties. Applied Mathematics, 9(3), 162-168. doi:10.5923/j.am.20190903.04

Nwaigwe, C., & Amadi, I. U. (2021). Analytical Solution of a Non-isothermal Flow in Cylindrical Geometry. Asian Research Journal of Mathematics, 17(3), 55-76.DOI: 10.9734/arjom/2021/v17i330283