Impact of hybrid nanofluids (Ag‐TiO₂/H₂O) on improving the performance of a heat exchanger with turbulent induction elements

Abstract: In this article, the optimization of a twisted strip heat exchanger was explored aiming at enhancing heat transfer. To this end, governing equations using ANSYS‐FLUENT software and nanofluid flow using the k‐ε RNG turbulence model were simulated in the heat exchanger, respectively. The investigated parameters included temperature, pressure, velocity, turbulence kinetic energy (TKE), nanofluid concentration, nanofluid shape factor, Reynolds number, and the diameter of the spherical obstacle on the twisted tape.… Show more

“…Bisheh et al, [17] investigated the Impact of hybrid nanofluids (Ag-TiO2/Water) at 1.5-3-6% concentration with10000-18000 Re on improving the performance of a heat exchanger with turbulent induction elements and concluded that the heat transfer coefficient had increased by 52% at 6% of Ag-TiO2/ Water. Elfaghi et al, [18] studied the Forced Convection Heat Transfer Enhancement in Pipes numerically Using Al2O3/Water Nanofluid with (0.5-1-2% of concentration) in the Reynolds number range from 6000 to 12000.…”

Numerical and Experimental Studies of the Nanofluid Characteristics that Effects on Heat Transfer Enhancement: Review and Comparison

“…Bisheh et al, [17] investigated the Impact of hybrid nanofluids (Ag-TiO2/Water) at 1.5-3-6% concentration with10000-18000 Re on improving the performance of a heat exchanger with turbulent induction elements and concluded that the heat transfer coefficient had increased by 52% at 6% of Ag-TiO2/ Water. Elfaghi et al, [18] studied the Forced Convection Heat Transfer Enhancement in Pipes numerically Using Al2O3/Water Nanofluid with (0.5-1-2% of concentration) in the Reynolds number range from 6000 to 12000.…”

Numerical and Experimental Studies of the Nanofluid Characteristics that Effects on Heat Transfer Enhancement: Review and Comparison

Estimation of the thermal properties of MgO-SiO2/water hybrid nanofluid and development of novel thermo-economically viable model for heat transfer applications

Advanced Thermo-Hydraulic Assessment of Helical Pipes with Different Shapes of Jackets Using Single-Phase and Hybrid Nanofluids