Analysis of fully developed mixed convection in open-ended annuli with viscous dissipation

The vertical, open-ended double-passage annular space between three vertical concentric co-axial cylinders is an important geometry representing significant number of industrial applications. For a design engineer, the knowledge of fully developed mixed convection in this geometry is very essential. Hence, in this paper, it is proposed to numerically as well as analytically investigate the fully developed mixed convective flow in the vertical annuli having two annular passages with open upper and lower boundaries by taking viscous dissipation into consideration. The prime objective of the analysis is to bring out the influences of the location of middle cylinder, known as baffle, and viscous dissipation on the fluid flow and temperature profiles as well as the associated thermal transport rates. By neglecting the viscous dissipation influences, exact solutions are determined, while the finite difference-based numerical solutions are achieved in the presence of viscous dissipation. Further, excellent agreement is obtained between the analytical and numerical solutions under limiting conditions. The roles of viscous dissipation and baffle location are meticulously brought out through the flow pattern, temperature profiles and heat transport rates.

Automated summary

This study investigated the fully developed mixed convective flow in the vertical annuli with two annular passages, considering the influence of viscous dissipation through numerical and analytical methods. The analysis revealed the effects of baffle location and viscous dissipation on fluid flow, temperature profiles, and thermal transport rates. Excellent agreement was observed between analytical and numerical solutions, highlighting the roles of viscous dissipation and baffle location in the flow patterns, temperature distributions, and heat transport rates.