Study of Convective Heat Transfer Enhancement of Nanofluid inside Tube.

Arid, F. F.; Elshafei, E.; Mousa, Mohamed; Elkandary, Omer

doi:10.21608/bfemu.2020.122158

Study of Convective Heat Transfer Enhancement of Nanofluid inside Tube.

Document Type : Research Studies

Authors

¹ Mechanical Power Engineering Department., Faculty of Engineering., El-Mansoura University., Mansoura., Egypt.

² Mechanical Power Engineering Dept., Faculty of Engineering., El-Mansoura University Mansoura., Egypt.

³ Professor of Mechanical Power Engineering Department., Faculty of Engineering., El-Mansoura University., Mansoura., Egypt.

⁴ Associate Professor., Mechanical Power Engineering Department., Faculty of Engineering., El-Mansoura University., Mansoura., Egypt.

10.21608/bfemu.2020.122158

Abstract

Nanofluids are suspensions of metallic or nonmetallic nano-powders in base liquid and can be employed to increase heat transfer rate in various applications. In this work laminar flow forced convection heat transfer of (Al²O³ or CuO)/water nanofluid inside a circular tube with constant wall heat flux is investigated experimentally. The Nusselt numbers of nanofluids are obtained for different nano particle concentrations as well as various Reynolds number. Experimental results emphasize the enhancement of heat transfer due to the nano-particles presence in the fluid. Heat transfer coefficient increases by increasing the concentration of nano-particles in nanofluid. The increase in heat transfer coefficient due to presence of nano-particles is much higher than the prediction of single phase heat transfer correlation used with nanofluid properties. Considering the factors affecting the convective heat transfer coefficient of the nanofluid, a new convective heat transfer correlation for nanofluid under single-phase flows in tube is established. Comparison between the experimental data and the calculated results indicate that the correlation describes correctly the energy transport of the nanofluid. The range of operating parameter is Reynolds number from 500 to 2500 and particle volume concentrations up to 2.0%. Comparison between present and pervious results is carried out.

Keywords