%0 Journal Article
%@ 09270248
%A Akilu, S.
%A Baheta, A.T.
%A M.Said, M.A.
%A Minea, A.A.
%A Sharma, K.V.
%D 2018
%F scholars:10296
%I Elsevier B.V.
%J Solar Energy Materials and Solar Cells
%K Copper compounds; Copper oxides; Ethylene; Ethylene glycol; Glycerol; Heat transfer; Mixtures; Nanoparticles; Physical properties; Polyols; Silica; Silicon compounds; Solar collectors; Solar energy; Specific heat; Synthesis (chemical); Thermal conductivity; Thermodynamic properties; Ultrasonic applications; Viscosity, Empirical correlations; Heat Transfer enhancement; Hybrid nanofluid; Hybrid nanoparticle; Mixing techniques; Temperature range; Thermo-physical property; Volume concentration, Nanofluidics
%P 118-128
%R 10.1016/j.solmat.2017.10.027
%T Properties of glycerol and ethylene glycol mixture based SiO2-CuO/C hybrid nanofluid for enhanced solar energy transport
%U https://khub.utp.edu.my/scholars/10296/
%V 179
%X Hybrid nanofluids are a novel class of colloidal fluids which have drawn significant attention due to potential tailoring of their thermo-physical properties for heat transfer enhancement by a combination of more than one nano-additive to meet specific requirements of an application. In the present work, ceramic copper oxide/carbon (SiO2-CuO/C) nanoparticles in 80:20 (wt) composition were prepared by ultrasonic-assisted wet mixing technique. The hybrid nanofluid was formulated by dispersing the nanoparticles into a base fluid mixture of 60:40 ( by mass) glycerol and ethylene glycol (G/EG) using the two-steps method. The influence of nanoparticles on the augmentation of specific heat, thermal conductivity and viscosity was examined in the volume concentration range of 0.5â��2.0 in the temperature range of 303.15â��353.15 K. The results demonstrate that the synthesized SiO2-CuO/C hybrid nanoparticles enhanced the thermo-physical properties of the base fluid mixture which is higher than using SiO2 alone. In the case of SiO2â��G/EG nanofluid, the specific heat capacity decremented by a maximum value of 5.7 whereas the thermal conductivity and viscosity incremented by 6.9 and 1.33-times as compared with G/EG at maximum volume concentration of 2.0 at a temperature of 353.15 K. Comparatively, a reinforcement of 80 SiO2 with 20 CuO/C in G/EG mixture led to thermal conductivity and viscosity enhancement by 26.9 and 1.15-times, respectively with a significant reduction of specific heat by 21.1. New empirical correlations were proposed based on the experimental data for evaluation of thermophysical properties. Â© 2017 Elsevier B.V.
%Z cited By 114