Side-heated Rayleigh-B\'enard Convection

TL;DR

This paper experimentally investigates how sidewall heating influences Rayleigh-Bénard Convection, revealing that side heating can enhance flow circulation and heat transfer, offering a new control mechanism for thermal convection systems.

Contribution

It demonstrates experimentally that sidewall heating modifies flow and heat transfer in RBC, providing a novel method to control thermal convection.

Findings

Sidewall heating enhances flow circulation.

Heat transfer is increased with side heating.

Sidewall conditions allow control of RBC behavior.

Abstract

Unlike solids, the heat transfer in fluids can be greatly enhanced due to the presence of convection. Under gravity, an unevenly distributed temperature field results in differences in buoyancy, driving fluid motion that is seen in Rayleigh-B\'enard Convection (RBC). In RBC, the overall heat flux is found to have a power-law dependence on the imposed temperature difference, with enhanced heat transfer much beyond thermal conduction. In a bounded domain of fluid such as a cube, how RBC responds to thermal perturbations from the vertical sidewall is not clear. Will sidewall heating or cooling modify flow circulation and heat transfer? We address these questions experimentally by adding heat to one side of the RBC. Through careful flow, temperature, and heat flux measurements, the effects of adding side heating to RBC are examined and analyzed, where a further enhancement of flow circulation and heat transfer is observed. Our results also point to a direct and simple control of the classical RBC system, allowing further manipulation and control of thermal convection through sidewall conditions.