Heat transfer enhancement using surfactant based alumina nanofluid jet from a hot steel plate

Enhancement of thermal conductivity by the addition of nanofluid is found to improve the rate of cooling of a steel plate. In the present research work, alumina nanofluid at the previously optimized concentration of 10 ppm along with a non ionic surfactant is employed for jet impingement cooling. The steel plate (100 x 100 x 6 mm) is cooled from an initial surface temperature of 900 degrees C. The concentration of non-ionic surfactant polyoxyethylene (20) sorbitan monolaurate (Tween 20) is optimized, and the surfactant is characterized based on its thermal properties. A maximum thermal conductivity enhancement of 21% and a minimum contact angle of 40.48 degrees were exhibited by surfactant added nanofluid at 55 ppm. Inverse heat conduction method was employed to estimate the heat flux and temperature at the plate surface based on the internal thermocouple data. A maximum heat transfer rate of 139 degrees C/s with a critical heat flux (CHF) of 2.931 MW/m(2) was attained at a surfactant concentration of 55 ppm. SEM and EDAX analysis of the plate surface after jet impingement confirmed the presence of the nanoparticles.