Symmetry-breaking of turbulent flow due to asymmetric vortex shedding in periodic porous media

TL;DR

This study investigates how turbulent flow in periodic porous media with cylindrical obstacles undergoes symmetry-breaking due to vortex shedding, influenced by porosity and Reynolds number, with implications for flow control and heat transfer.

Contribution

The paper provides new insights into symmetry-breaking mechanisms in turbulent flow through porous media, highlighting the role of vortex shedding and secondary flow instabilities.

Findings

Symmetry-breaking occurs in intermediate porosity regimes between 0.8 and 0.9.

Transition from symmetric to asymmetric flow happens between Reynolds numbers 37 and 100.

Symmetry-breaking affects flow forces and may enhance heat transfer at obstacle surfaces.

Abstract

In this paper, we report new insight into a symmetry-breaking phenomenon that occurs for turbulent flow in periodic porous media composed of cylindrical solid obstacles with circular cross-section. We have used Large Eddy Simulation to investigate the symmetry-breaking phenomenon by varying the porosity (0.57-0.99) and the pore scale Reynolds number (37-1,000). Asymmetrical flow distribution is observed in the intermediate porosity flow regime for values of porosities between 0.8 and 0.9, which is characterized by the formation of alternating low and high velocity flow channels above and below the solid obstacles. These channels are parallel to the direction of the flow. Correspondingly, the microscale vortices formed behind the solid obstacles exhibit a bias in the shedding direction. The transition from symmetric to asymmetric flow occurs in between the Reynolds numbers of 37 (laminar) and 100 (turbulent). A Hopf bifurcation resulting in unsteady oscillatory laminar flow marks the origin of a secondary flow instability arising from the interaction of the shear layers around the solid obstacle. When turbulence emerges, stochastic phase difference in the vortex wake oscillations caused by the secondary flow instability results in flow symmetry breaking. We note that symmetry breaking does not occur for cylindrical solid obstacles with square cross-section due to the presence of sharp vertices in the solid obstacle surface. At the macroscale level, symmetry-breaking results in residual transverse drag force components acting on the solid obstacle surfaces. Symmetry-breaking promotes attached flow on the solid obstacle surface, which is potentially beneficial for improving transport properties at the solid obstacle surface such as convection heat flux.