@ARTICLE{Fadodun_Olatomide_G._Numerical_2020, author={Fadodun, Olatomide G. and Amosun, Adebimpe A. and Salau, Ayodeji O. and Olaloye, David O. and Ogundeji, Johnson A. and Ibitoye, Francis I. and Balogun, Fatai A.}, volume={vol. 41}, number={No 1}, journal={Archives of Thermodynamics}, pages={3-30}, howpublished={online}, year={2020}, publisher={The Committee of Thermodynamics and Combustion of the Polish Academy of Sciences and The Institute of Fluid-Flow Machinery Polish Academy of Sciences}, abstract={In this paper, investigation of the effect of Reynolds number, nanoparticle volume ratio, nanoparticle diameter and entrance temperature on the convective heat transfer and pressure drop of Al2O3/H2O nanofluid in turbulent flow through a straight pipe was carried out. The study employed a computational fluid dynamic approach using single-phase model and response surface methodology for the design of experiment. The Reynolds average Navier-Stokes equations and energy equation were solved using k-" turbulent model. The central composite design method was used for the response-surface-methodology. Based on the number of variables and levels, the condition of 30 runs was defined and 30 simulations were performed. New models to evaluate the mean Nusselt number and pressure drop were obtained. Also, the result showed that all the four input variables are statistically significant to the pressure drop while three out of them are significant to the Nusslet number. Furthermore, sensitivity analysis carried out showed that the Reynolds number and volume fraction have a positive sensitivity to both the mean Nusselt number, and pressure drop, while the entrance temperature has negative sensitivities to both.}, type={Article}, title={Numerical investigation and sensitivity analysis of turbulent heat transfer and pressure drop of Al2O3/H2O nanofluid in straight pipe using response surface methodology}, URL={http://czasopisma.pan.pl/Content/116170/PDF/01_paper.pdf}, doi={10.24425/ather.2020.132948}, keywords={Nusselt number, Reynolds number, pressure drop, Response-surface-methodology, Nanofluid, Single-phase flow}, }