Turbulent heat transfer enhancement by compliant walls

TL;DR

This paper uses direct numerical simulations to explore how compliant walls influence turbulent heat transfer, revealing that wall elasticity can dynamically control heat flux via turbulent convection.

Contribution

It demonstrates the impact of wall elasticity on heat transfer and turbulence structures in channel flows with fully resolved fluid-structure interactions.

Findings

Compliant walls increase both momentum and heat transfer in turbulent flows.

Heat flux near compliant walls is dominated by turbulent convection rather than diffusion.

Adjusting wall elasticity can control heat flux by modifying turbulence structures.

Abstract

This study investigates the effect of compliant walls on the turbulent heat transfer in channel flows over viscous-hyperelastic walls. We perform Direct Numerical Simulations, fully resolving the mutual fluid-structure interactions between the turbulent flow and the compliant walls, varying the wall elasticity and the thermal diffusivity in a fully turbulent condition. We show that the compliant wall leads to an increase not only of the momentum transfer but also of the heat transfer. Since the compliant wall can dynamically move, in the near-wall region heat flux is mostly transferred via turbulent convection rather than diffusion, as typically found with rigid walls. Thus, the heat flux can be controlled not only by varying the thermal diffusivity, but also by changing the transverse modulus of elasticity which governs the wall-normal velocity fluctuations and consequently the temperature ones. Finally, we show that the physical mechanism controlling these modifications are the sweep and ejection events.