Heat Transfer in an Inclined Rectangular Cavity Filled with Hybrid Nanofluid Attached to a Vertical Heated Wall Integrated with PCM: An Experimental Study

In this paper, natural convective heat transfer in a rectangular cavity filled with (50% CuO-50% Al2O3)/water hybrid nanofluids connected to a wall containing a phase change material (PCM) has been experimentally investigated. The vertical walls were heated at varying temperatures while the horizontal walls were kept adiabatic. The considered parameters were the concentration of hybrid nanomaterial (phi = 0.03, 0.05), the cavity inclination angle (theta = 0 degrees, 30 degrees, 45 degrees), and the temperature difference between the hot and cold sides ( increment T = 10, 15, 20 degrees C). The results have been validated and agree well with previously published papers. Furthermore, the main results stated that when the nanomaterial concentration increased, the heat transfer rate by free convection also increased. By increasing the natural convection flows via high temperature, symmetrical vortexes may appear near the heated wall. It also found that the PCM can potentially reduce the temperature of the hot side by up to 22% due to its high absorbability and heat storage. Furthermore, the inclusion of hybrid nanofluids in addition to the PCM enhanced its efficiency in heat storage and, therefore, its capacity to cool the hot side. Moreover, the influence of the inclination cavity enhanced the heat transfer, where theta = 30 degrees was the optimal angle in terms of thermal conductivity.

Automated summary

This paper experimentally investigates the natural convective heat transfer in a rectangular cavity filled with (50% CuO-50% Al2O3)/water hybrid nanofluids connected to a phase change material (PCM). The results show that increasing the concentration of hybrid nanomaterial improves the heat transfer rate by free convection, and the PCM can reduce the temperature of the hot side. Furthermore, the inclusion of hybrid nanofluids enhances the efficiency of heat storage of the PCM.