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Effects of the nanoparticle shape on natural convection heat transfer in a square enclosure filled with Cu-H2O nanofluid

Birol Şahin

Abstract


Heat is transferred by natural or forced convection in devices such as heat exchangers, which are frequently used in heating-cooling processes. One of the ways to passively increase heat transfer is to use nanofluid as the working fluid. In this study, natural convection heat transfer in a square enclosure having a hot vertical wall and a cold vertical wall was investigated numerically. The horizontal walls of the enclosure are perfectly insulated. The effects of the nanoparticle shape on natural convection heat transfer in a square enclosure filled with Newtonian Cu-H2O nanofluid were investigated. In this study, different volume fractions of the spherical, cylindrical, and blade-shaped nanoparticles were examined. The numerical study was carried out in the range of Rayleigh number 104-106 and the nanoparticle volume fractions were taken as 0%, 2%, and 4%, respectively. The non-dimensional equations of the continuum, momentum, and energy are discretized by the SIMPLE (Semi Implicit Pressure Linked Equations) algorithm and solved by the finite volume method (FVM) in a Fortran code.  As a result of the study, it was noted that nanoparticle volume fraction, Rayleigh number, as well as nanoparticle shape, increased heat transfer up to 19% compared to the base fluid.


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References


G. de Vahl Davis, “Natural convection of air in a square cavity: a benchmark numerical solution,” International Journal for Numerical Methods in Fluids, 3(3), pp. 249-264, 1983.

T. Fusegi, J. M. Hyun, K. Kuwahara, B. Farouk, “A numerical study of three-dimensional natural convection in a differentially heated cubical enclosure,” International Journal of Heat and Mass Transfer, 34(6), pp. 1543-1557, 1991.

G. Barakos, E. Mitsoulis, D. Assimacopoulos, “Natural convection flow in a square cavity revisited: laminar and turbulent models with wall functions,” International Journal for Numerical Methods in Fluids, 18(7), pp. 695-719, 1994.

N. C. Markatos, K. A. Pericleous, “Laminar and turbulent natural convection in an enclosed cavity,” International Journal of Heat and Mass Transfer, 27(5), pp. 755-772, 1984.

A. Doostani, M. Ghalambaz, A .J. Chamkha, “MHD natural convection phase-change heat transfer in a cavity: analysis of the magnetic field effect,” Journal of the Brazilian Society of Mechanical Sciences and Engineering, 39(7), pp. 2831-2846, 2017.

A. Raisi, “The effect of conductive baffles on natural convection in a power-law fluid-filled square cavity,” Journal of the Brazilian Society of Mechanical Sciences and Engineering, 40(33), pp. 1-15, 2018.

S.U.S. Choi, J. A. Eastman, “Enhancing thermal conductivity of fluids with nanoparticles,” No. ANL/MSD/CP-84938; CONF-951135-29. Argonne National Lab., IL (United States), pp. 1-8, 1995.

K. Khanafer, K. Vafai, M. Lightstone, “Buoyancy-driven heat transfer enhancement in a two-dimensional enclosure utilizing nanofluids,” International Journal of Heat and Mass Transfer, 46(19), pp. 3639-3653, 2003.

J. Buongiorno, “Convective transport in nanofluids,” Journal of Heat Transfer, 128(3), pp. 240-250, 2006.

M. Mahmoodi, “Numerical simulation of free convection of nanofluid in a square cavity with an inside heater,” International Journal of Thermal Sciences, 50(11), pp. 2161-2175, 2011.

G. R. Kefayati, S. F. Hosseinizadeh, M. Gorji, H. Sajjadi, “Lattice Boltzmann simulation of natural convection in tall enclosures using water/SiO2 nanofluid,” International Communications in Heat and Mass Transfer, 38(6), pp. 798-805, 2011.

B. Ghasemi, S. M. Aminossadati, “Natural convection heat transfer in an inclined enclosure filled with a water-CuO nanofluid,” Numerical Heat Transfer, Part A: Applications, 55(8), pp. 807-823, 2009.

A. Ghafouri, M. Salari, “Numerical investigation of the heat transfer enhancement using various viscosity models in a chamber filled with water–CuO nanofluid,” J Braz. Soc. Mech. Sci. Eng., vol. 36, pp. 825–836, 2014.

N. Nithyadevi, T. Mahalakshmi, “A numerical study on MHD natural convective heat transfer in an Ag-water nanofluid filled enclosure with center heater,” Journal of the Korean Society for Industrial and Applied Mathematics, 21(4), pp. 225-244, 2017.

Z. Haddad, H. F. Oztop, E. Abu-Nada, A. Mataoui, “A review on natural convective heat transfer of nanofluids,” Renewable and Sustainable Energy Reviews, 16(7), pp. 5363-5378, 2012.

D. Das, M. Roy, T. Basak, “Studies on natural convection within enclosures of various (non-square) shapes–A review,” International Journal of Heat and Mass Transfer, 106, pp. 356-406, 2017.

X. Q. Wang, A. S. Mujumdar, “A review on nanofluids-part I: theoretical and numerical investigations,” Brazilian Journal of Chemical Engineering, 25(4), pp. 613-630, 2008.

X. Q. Wang, A. S. Mujumdar, “A review on nanofluids-part II: experiments and applications,” Brazilian Journal of Chemical Engineering, 25(4), pp. 631-648, 2008.

N. Putra, W. Roetzel, S. K. Das, “Natural convection of nano-fluids,” Heat and Mass Transfer, 39(8-9), pp. 775-784, 2003.

D. K. Bairwa, K. K. Upman, G. Kantak, “Nanofluids and its Applications,” International Journal of Engineering, Management & Sciences, vol. 2, pp. 14-17, 2015.

A. E. M. Bouchoucha, R. Bessaih, “Natural convection and entropy generation of nanofluids in a square cavity,” International Journal of Heat and Technology, 33(4), pp. 1-10, 2015.

B. Mliki, M. A. Abbassi, A. Omri, B. Zeghmati, “Augmentation of natural convective heat transfer in linearly heated cavity by utilizing nanofluids in the presence of magnetic field and uniform heat generation/absorption,” Powder Technology, vol. 284, pp. 312-325, 2015.

M. Sheikholeslami, K. Vajravelu, “Nanofluid flow and heat transfer in a cavity with variable magnetic field,” Applied Mathematics and Computation, vol. 298, pp. 272-282, 2017.

S. Belhaj, B. Ben-Beya, “Magnetoconvection and entropy generation of nanofluid in an enclosure with an isothermal block: Performance evaluation criteria analysis,” Journal of Thermal Science and Technology, 13(1), pp. 1-23, 2018.

X. Q. Wang, A. S. Mujumdar, “Heat transfer characteristics of nanofluids: a review,” International Journal of Thermal Sciences, 46(1), pp. 1-19, 2007.

T. Mahalakshmi, N. Nithyadevi, H. F. Oztop, N. Abu-Hamdeh, “Natural convective heat transfer of Ag-water nanofluid flow inside enclosure with center heater and bottom heat source,” Chinese Journal of Physics, 56(4), pp. 1497-1507, 2018.

G. H. R. Kefayati, “Heat transfer and entropy generation of natural convection on non-Newtonian nanofluids in a porous cavity,” Powder Technology, vol. 299, pp. 127-149, 2016.

G. H. R. Kefayati, “Simulation of heat transfer and entropy generation of MHD natural convection of non-Newtonian nanofluid in an enclosure,” International Journal of Heat and Mass Transfer, vol. 92, pp. 1066-1089, 2016.

N. Ben-Cheikh, A. J. Chamkha, B. Ben-Beya, T. Lili, “Natural convection of water-based nanofluids in a square enclosure with non-uniform heating of the bottom wall,” Journal of Modern Physics, 4(02), pp. 147-159, 2013.

K. S. Al Kalbani, M. M. Rahman, S. Alam, N. Al-Salti, I.A. Eltayeb, “Buoyancy induced heat transfer flow inside a tilted square enclosure filled with nanofluids in the presence of oriented magnetic field,” Heat Transfer Engineering, 39(6), pp. 511-525, 2018.

A. Turgut, Ş. Sağlanmak, S. Doğanay, “Experimental investigation on thermal conductivity and viscosity of nanofluids: particle size effect,” Journal of the Faculty of Engineering & Architecture of Gazi University, 31(1), pp. 95-103, 2016.

A. S. Dogonchi, M. Waqas, S. M. Seyyedi, M. Hashemi-Tilehnoee, D. D. Ganji, “Numerical simulation for thermal radiation and porous medium characteristics in flow of CuO-H 2 O nanofluid,” Journal of the Brazilian Society of Mechanical Sciences and Engineering, 41(249), pp. 1-13, 2019.

E.V. Timofeeva, J. L. Routbort, D. Singh, “Particle shape effects on thermophysical properties of alumina nanofluids,” Journal of Applied Physics, 106(1), 014304, 2009.

M. S. Asmadi, Z. Siri, R. M. Kasmani, H. Saleh, “Nanoparticle shape effect on the natural-convection heat transfer of hybrid nanofluid inside a U-shaped enclosure,” Thermal Science, 26(1 Part B), pp. 463-475, 2022.

G. A. Sheikhzadeh, A. Aghaei, S. Soleimani, “Effect of nanoparticle shape on natural convection heat transfer in a square cavity with partitions using water-SiO2 nanofluid,” Challenges in Nano and Micro Scale Science and Technology, 6(1), pp. 27-38, 2018.

R. L. Hamilton, “Thermal conductivity of heterogeneous mixtures,” Doctoral dissertation, The University of Oklahoma, 1960.

J. C. Maxwell, “A treatise on electricity and magnetism,” (Vol. 1), Oxford: Clarendon Press, 1873.

H. C. Brinkman, “The viscosity of concentrated suspensions and solutions,” The Journal of Chemical Physics, 20(4), pp. 571-571, 1952.

S. V. Patankar, “Numerical Heat Transfer and Fluid Flow,” McGraw Hill, New York, 1980.




URN: https://sloi.org/urn:sl:tjoee82291



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