Experimental investigation in thermal conductivity of CuO and ethylene glycol nanofluid in serpentine shaped microchannel

The results obtained in this work, using the internal void formulation, were compared with the thermal response from finite element formulation, for heat conduction with

The increase in thermal conductivity of the nanofluid of approximately 36%, combined with its colloidal stability, suggests that the nanofluid produced could be a promising

Summarizing, GO can be reduced using either ethanol or ethylene glycol via a solvothermal route, using additional pretreatment dependent on the alcohol, leading to RGO sheets with

Effects of thermal buoyancy and variable thermal conductivity on the MHDflow and heat transfer in a power-law fluid past a vertical stretching sheet in the presence

Subsequently, the heat transfer coefficient, overall heat transfer coeffi- cient, friction factor, pressure drop and pumping power for CuO/EG nanofluid calculated based on

Experimental and simulation results showed that the thermal performance of nanofluids is higher than that of the base fluid and the heat transfer enhancement increases with

In this work, the micrographs of copolymer beads based on methyl methacrylate (MMA), ethylene glycol dimethacrylate (EGDM) and vinyl triethoxysilane (VTES) were used

different organic solvents of furfural, furfural alcohol and ethylene glycol (the ILs, also organic solvents, used in this work are illustrated in Figure 3), involving a variety