Transition to turbulence in randomly packed porous media; scale estimation of vortical structures

TL;DR

This study investigates the dynamics and scale of vortical flow structures during the transition from laminar to turbulent flow in porous media, revealing scale coupling and effects of Reynolds number on vortex characteristics.

Contribution

It introduces a pore-scale measurement approach using PIV to quantify vortical structures and compares macro and micro-scale scalings during flow transition in porous media.

Findings

Vortical structures decrease in size with increasing Reynolds number.

Vortical strength increases as flow transitions to turbulence.

Pore-scale and macro-scale vortex behaviors are coupled during transition.

Abstract

Pore-scale observation of vortical flow structures in porous media is a significant challenge in many natural and industrial systems. Vortical structure dynamics is believed to be the driving mechanism in the transition regime in porous media based on the pore Reynolds number, $Re_p$. To examine this assertion, a refractive-index matched randomly packed porous medium is designed to measure the scale of vortical flow structures in transition from unsteady laminar to turbulent using two-dimensional time-resolved Particle Image Velocimetry (PIV). Planar PIV data for $Re_p$ from 100 to 948 is used to quantify the scale in terms of the size, strength, and number density using two different scalings (i) $Re_p$ macroscopic (global), and (ii) $Re_{\langle p\rangle}$ microscopic (local). Direct measurement of vortex scale is quantified by employing swirl strength, vortex core, and enhanced swirl strength vortex identification methods. These scales are compared with turbulent integral scales. Shear-dominant vortical structures in moderate unsteady laminar Reynolds numbers ($Re_p <300$) were observed, while the swirl-dominant flow structures appeared in weak turbulent Reynolds numbers ($Re_p>500$). From the macroscopic point of view, increasing Rep resulted in, (i) reduction in the sizes of vortical structures to asymptotically to reach 20$\%$ of the global hydraulic diameter, (ii) growth in strength of vortices, and (iii) increase in the average number densities of vortices. From the pore-scale (local) point of view, increasing $Re_{\langle p\rangle}$ led to decrease in the size of vortical structures monotonically, (ii) rise of the strength of vortices, and (iii) invariance in the number density of vortical structures. These findings suggest pore versus macro-scale coupling exists for the scale of vortical flow structures in the transition regime.