Significance of near-wall dynamics in enhancement of heat flux for roughness aided turbulent Rayleigh-Benard convection

We report a numerical investigation of the effect of multiscale roughness on heat flux ( N u ) and near-wall dynamics in turbulent Rayleigh-Benard convection of air in a cell of aspect ratio 2 in the Rayleigh number ( R a ) range 10 6 <= R a <= 4.64 x 10 9. We observe that despite the same wetted area, taller roughness yields higher heat flux owing to a multiple roll state. Based on the number of roughness peaks penetrating the thermal boundary layer, three regimes are identified. In regime I, heat flux drops marginally as only 50% of the peaks emerge uncovered, followed by a nearly unaltered Nu in regime II. A sudden increase in Nu in regime III is noted with more than 65% penetrating peaks. In contrast to the previous observation, heat flux continues to increase even when all the peaks exceed the boundary layer. Transformation of two large-scale rolls into smaller multiple rolls favors better access to the trapped fluid in the roughness throat leading to greater mixing. A significant improvement in the mixing of fluid inside the cavities is found due to the cascade of secondary vortices, which is connected to the improved heat flux in the tallest roughness setup. A thin thermal boundary layer that envelopes the rough surface at higher Ra supports the enhanced inter-mixing of fluid inside the cavities. Greater perturbation of the thermal boundary layer for the smaller roughness setup shows consistent connection with the enhanced N u ( R a ) scaling.

Automated summary

This numerical investigation delves into the impact of multiscale roughness on heat flux and near-wall dynamics in turbulent Rayleigh-Benard convection. Results show that the penetration of roughness peaks through the thermal boundary layer can be categorized into three regimes, with heat flux continuing to increase even when all peaks exceed the boundary layer. The formation of smaller multiple rolls due to the tall roughness favors better fluid mixing and enhances heat flux, demonstrating the significance of the study in understanding convective heat transfer processes.