Thermofluid behaviour of boron nitride nanotube nanofluid in a microchannel under optimized conditions

While numerical modelling of different types of nanofluids in various microchannel heat sink geometry under different flow conditions are many, few involved utilizations of experimental data. Reports so far have indicated the potential cooling capability of nanofluids in general, yet none have investigated the effects of the surfactant alone on the fluid flow, in particular the thermofluid flow pattern. This paper reports the results of a numerical simulation with CFD on the fluid flow of Triton TX-100 surfactant with boron nitride nanotubes (BNN) in distilled water (base fluid) at 30 and 50 degrees C. The nanofluid (BNNT) operated at high temperature provided a lower thermal resistance. A higher pumping power was found for BNNTs and TX-100 at 30 celcius compared to distilled water at both temperatures. The outcomes of the present study provide a better understanding of flow characteristic and flow visualization along a microchannel heat sink so that better design decision can be made for improvement of this application for different needs.

Automated summary

This study used CFD numerical simulation to investigate the fluid flow of nanofluids with Triton TX-100 surfactant and boron nitride nanotubes as the base fluid at different temperatures in microchannels. The results showed that nanofluids operated at high temperature had lower thermal resistance, but higher pumping power compared to distilled water at 30 degrees Celsius.