Experimental investigation of heat transfer in a cavity filled with (50% CuO-50% Al2O3)/Water with hybrid nanofluid attached to a vertically heated wall partially integrated with PCM

Al-Maliki, Muqdad; Al-Farhany, Khaled

doi:10.30772/qjes.v16i1.912

	Experimental investigation of heat transfer in a cavity filled with (50% CuO-50% Al2O3)/Water with hybrid nanofluid attached to a vertically heated wall partially integrated with PCM
Al-Qadisiyah Journal for Engineering Sciences
Volume 16, Issue 1, March 2023, Pages 21-29 PDF (1.15 M)
Document Type: Research Paper
DOI: 10.30772/qjes.v16i1.912
Authors
Muqdad Al-Maliki¹; Khaled Al-Farhany^* ²
¹Department of Mechanical Engineering, Collage of Engineering, University of Al-Qadisiyah, Al-Diwaniyah, Iraq
²Department of Mechanical Engineering, University of Al-Qadisiyah, Ad-Diwaniyah, 58001, Iraq
Abstract
An empirical evaluation of free convective heat transmission was conducted in a rectangular enclosure containing a hybrid nanofluid of (50% CuO-50% Al₂O₃)/water linked to a PCM-containing wall. The enclosure's left and right surfaces were kept at constant warm and cold temperatures, whereas the remaining surfaces were assumed to be isolated. The left side was filled partially with PCM. Several variables were examined, such as the hot-side temperature differential (∆T =10, 15,20 ◦C) and the hybrid nanofluid concentration (Φ=0.03,0.05,0.07)%. The findings show that the rate of heat transmission through natural convection rises as the concentration of nanomaterials rises. Due to its great absorbability and heat storage capacity, PCM was also shown to have the potential to lower the hot side temperature by up to 15.5%. The Nusselt number rises over time as the left cavity is filled partially with PCM. When added hybrid nanofluid is, PCM’s heat-storage efficiency and, by extension, its ability to cool the hot side is greatly improved.
Keywords
(50% CuO; 50% Al2O3)/Water Hybrid nanofluid Natural convection PCM Rectangular Cavity

References
M.S. Sadeghi, N. Anadalibkhah, R. Ghasemiasl, T. Armaghani, A.S. Dogonchi, A.J. Chamkha, H. Ali, A. Asadi, On the natural convection of nanofluids in diverse shapes of enclosures: an exhaustive review, Journal of Thermal Analysis and Calorimetry, (2020) 1-22. I. Garbadeen, M. Sharifpur, J. Slabber, J. Meyer, Experimental study on natural convection of MWCNT-water nanofluids in a square enclosure, International Communications in Heat and Mass Transfer, 88 (2017) 1-8. R. Mohebbi, S.H. Khalilabad, Y. Ma, Effect of γ-Al2O3/Water Nanofluid on Natural Convection Heat Transfer of Corrugated┐ Shaped Cavity: Study the Different Aspect Ratio of Grooves, Journal of Applied Fluid Mechanics, 12(4) (2019) 1151-1160. A.D. Abdulsahib, K. Al-Farhany, Review of the Effects of Stationary/Rotating Cylinder in a Cavity on the Convection Heat Transfer in Porous Media with/without Nanofluid, Mathematical Modelling of Engineering Problems, 8(3) (2021) 356-364. K.K. Al-Chlaihawi, H.H. Alaydamee, A.E. Faisal, K. Al-Farhany, M.A. Alomari, Newtonian and non-Newtonian nanofluids with entropy generation in conjugate natural convection of hybrid nanofluid-porous enclosures: A review, Heat Transfer, 51(2) (2022) 1725-1745. T. Tayebi, H.F. Öztop, A.J. Chamkha, Natural convection and entropy production in hybrid nanofluid filled-annular elliptical cavity with internal heat generation or absorption, Thermal Science and Engineering Progress, 19 (2020) 100605. B.M. Amine, F. Redouane, L. Mourad, W. Jamshed, M.R. Eid, W. Al-Kouz, Magnetohydrodynamics Natural Convection of a Triangular Cavity Involving Ag-MgO/Water Hybrid Nanofluid and Provided with Rotating Circular Barrier and a Quarter Circular Porous Medium at its Right-Angled Corner, Arabian Journal for Science and Engineering, 46(12) (2021) 12573-12597. C. Revnic, T. Groşan, M. Sheremet, I. Pop, Numerical simulation of MHD natural convection flow in a wavy cavity filled by a hybrid Cu-Al 2 O 3-water nanofluid with discrete heating, Applied Mathematics and Mechanics, 41(9) (2020) 1345-1358. A.J. Chamkha, I.V. Miroshnichenko, M.A. Sheremet, Numerical analysis of unsteady conjugate natural convection of hybrid water-based nanofluid in a semicircular cavity, Journal of Thermal Science and Engineering Applications, 9(4) (2017) 041004. M.A. Alomari, K. Al-Farhany, A.L. Hashem, M.F. Al-Dawody, F. Redouane, O.A. Olayemi, Numerical study of mhd natural convection in trapezoidal enclosure filled with (50%mgo-50%ag/water) hybrid nanofluid: Heated sinusoidal from below, International Journal of Heat and Technology, 39(4) (2021) 1271-1279. F. Redouane, W. Jamshed, S.S.U. Devi, B.M. Amine, R. Safdar, K. Al-Farhany, M.R. Eid, K.S. Nisar, A.H. Abdel-Aty, I.S. Yahia, Influence of entropy on Brinkman–Forchheimer model of MHD hybrid nanofluid flowing in enclosure containing rotating cylinder and undulating porous stratum, Scientific Reports, 11(1) (2021). M. Kheradmand, M. Abdollahzadeh, M. Azenha, J. de Aguiar, Phase change materials as smart nanomaterials for thermal energy storage in buildings, Intelligent Nanomaterials, 2 (2016) 247-293. Y. Hong, W.-B. Ye, J. Du, S.-M. Huang, Solid-liquid phase-change thermal storage and release behaviors in a rectangular cavity under the impacts of mushy region and low gravity, International Journal of Heat and Mass Transfer, 130 (2019) 1120-1132. M. Parsazadeh, M. Malik, X. Duan, A. McDonald, Numerical study on melting of phase change material in an enclosure subject to Neumann boundary condition in the presence of Rayleigh-Bénard convection, International Journal of Heat and Mass Transfer, 171 (2021) 121103. A. Labihi, F. Aitlahbib, H. Chehouani, B. Benhamou, M. Ouikhalfan, C. Croitoru, I. Nastase, Effect of phase change material wall on natural convection heat transfer inside an air filled enclosure, Applied Thermal Engineering, 126 (2017) 305-314. T. Bouhal, O. Limouri, Y. Agrouaz, T. Kousksou, Y. Zeraouli, A. Jamil, Numerical analysis of PCM melting filling a rectangular cavity with horizontal partial fins, in: MATEC Web of Conferences, EDP Sciences, 2020, pp. 01011. A. Chamkha, A. Doostanidezfuli, E. Izadpanahi, M. Ghalambaz, Phase-change heat transfer of single/hybrid nanoparticles-enhanced phase-change materials over a heated horizontal cylinder confined in a square cavity, Advanced Powder Technology, 28(2) (2017) 385-397. A. Laouer, K. Al-Farhany, M.F. Al-Dawody, A.L. Hashem, A numerical study of phase change material melting enhancement in a horizontal rectangular enclosure with vertical triple fins, International Communications in Heat and Mass Transfer, 137 (2022). A. Laouer, K. Al-Farhany, Melting of nano-enhanced phase change material in a cavity heated sinusoidal from below: Numerical study using lattice Boltzmann method, Heat Transfer, 51(6) (2022) 5952-5970. H. Shili, K. Fahem, S. Harmand, S. Ben Jabrallah, Thermal control of electronic components using a liquid around the phase change material, Journal of Thermal Analysis and Calorimetry, 140(3) (2020) 1177-1189. T.H. Kean, N.A.C. Sidik, J. Kaur, Numerical investigation on melting of Phase Change Material (PCM) dispersed with various nanoparticles inside a square enclosure, in: IOP Conference Series: Materials Science and Engineering, IOP Publishing, 2019, pp. 012034. M. Sivashankar, C. Selvam, S. Manikandan, S. Harish, Performance improvement in concentrated photovoltaics using nano-enhanced phase change material with graphene nanoplatelets, Energy, 208 (2020) 118408. S. Ebadi, S.H. Tasnim, A.A. Aliabadi, S. Mahmud, Melting of nano-PCM inside a cylindrical thermal energy storage system: Numerical study with experimental verification, Energy Conversion and Management, 166 (2018) 241-259. A. Abdelrazik, F. Al-Sulaiman, R. Saidur, Numerical investigation of the effects of the nano-enhanced phase change materials on the thermal and electrical performance of hybrid PV/thermal systems, Energy Conversion and Management, 205 (2020) 112449. S. Nada, D. El-Nagar, H. Hussein, Improving the thermal regulation and efficiency enhancement of PCM-Integrated PV modules using nano particles, Energy conversion and management, 166 (2018) 735-743. S. Chavan, D.A. Perumal, V. Gumtapure, Numerical Studies For Charging And Discharging Characteristics Of Composite Phase Change Material In A Deep And Shallow Rectangular Enclosure, in: IOP Conference Series: Materials Science and Engineering, IOP Publishing, 2018, pp. 012059. F. Asdrubali, F. D'Alessandro, S. Schiavoni, A review of unconventional sustainable building insulation materials, Sustainable Materials and Technologies, 4 (2015) 1-17. K.H. Hilal Fluid Flow and Heat Transfer Characteristics in a Vertical Tube Packed Bed Media, University of Technology, (2004). A. Moradi, M. Zareh, M. Afrand, M. Khayat, Effects of temperature and volume concentration on thermal conductivity of TiO2-MWCNTs (70-30)/EG-water hybrid nano-fluid, Powder Technology, 362 (2020) 578-585. B. Rahmatinejad, M. Abbasgholipour, B. Mohammadi Alasti, Investigating thermo-physical properties and thermal performance of Al2O3 and CuO nanoparticles in Water and Ethylene Glycol based fluids, International Journal of Nano Dimension, 12(3) (2021) 252-271. B.C. Pak, Y.I. Cho, Hydrodynamic and heat transfer study of dispersed fluids with submicron metallic oxide particles, Experimental Heat Transfer an International Journal, 11(2) (1998) 151-170. M. Mansour, S. Siddiqa, R.S.R. Gorla, A. Rashad, Effects of heat source and sink on entropy generation and MHD natural convection of Al2O3-Cu/water hybrid nanofluid filled with square porous cavity, Thermal Science and Engineering Progress, 6 (2018) 57-71.
Statistics Article View: 294 PDF Download: 59