Litcius/Paper detail

Experimental Investigation into Natural Convection of Zinc Oxide/Water Nanofluids in a Square Cavity

Mohsen Sharifpur, Solomon O. Giwa, Kyoung-Yeoll Lee, Hadi Ghodsinezhad, Josua P. Meyer

2020Heat Transfer Engineering42 citationsDOI

Abstract

The public domain is inundated with discrepancies in numerical and experimental findings on the natural convection heat transfer performance of nanofluids in a cavity. This paper presents the experimental investigation of the natural convection of deionized water (DIW)-based zinc oxide (ZnO) nanofluid in a rectangular cavity. The ZnO nanoparticles (20 nm) were dispersed in DIW to formulate nanofluids at various volume concentrations (0.10, 0.18, 0.36, 0.50 and 1.0 vol.%). The spectrophotometer and zeta potential were used to verify the stability of ZnO/DIW nanofluid at various temperatures and concentrations. ZnO/DIW nanofluids and DIW were charged into a rectangular cavity with the opposite vertical walls under varying temperature differences. The natural convection of ZnO/DIW nanofluid was performed at Rayleigh number range of 7.45 × 107 and 9.20 × 108. Zeta potential values revealed stable nanofluids with no sedimentation of nanoparticles observed within 24 h. At 0.10 vol.% and temperature difference of 32 °C, the ZnO/DIW nanofluid was observed to enhance the heat transfer coefficient by 9.14% relative to DIW. Further increase in volume concentration resulted in the attenuation of heat transfer. Additionally, the Nusselt number and heat transfer rate were augmented by 8.42% and 6.75% at 0.10 vol.%, respectively.

Topics & Concepts

NanofluidMaterials scienceNatural convectionNusselt numberRayleigh numberZeta potentialHeat transferZincThermodynamicsChemical engineeringNanoparticleReynolds numberNanotechnologyMetallurgyTurbulencePhysicsEngineeringNanofluid Flow and Heat TransferSolar Thermal and Photovoltaic SystemsHeat Transfer Mechanisms