Buoyancy driven bubbly flows: scaling of velocities in bubble columns operated in the heterogeneous regime

TL;DR

This paper investigates the hydrodynamics of bubble columns in the heterogeneous regime, revealing that velocities scale with buoyancy and inertia balance, and confirming the self-organization and velocity behaviors through experiments and data analysis.

Contribution

It introduces a new velocity scaling law for bubble columns in the heterogeneous regime based on dimensional analysis and experimental validation.

Findings

Velocities scale as (gDε)^{1/2} in the heterogeneous regime.

The liquid flow rate is primarily determined by the column diameter D.

Relative velocities can exceed terminal velocity, reaching about 2.4 U_T at high gas velocities.

Abstract

The hydrodynamics of bubble columns in the heterogeneous regime is revisited. Focusing on air-water systems at large aspect ratio, we show from dimensional analysis that buoyancy equilibrates inertia, and that velocities scale as $(gD\varepsilon)^{1/2}$, where $D$ is the bubble column diameter, $\varepsilon$ the void fraction and $g$ the gravitational acceleration. From new experiments in a $0.4$m diameter column with ${\cal{O}}(10^3)$ particle Reynolds number bubbles and from a detailed analysis of published data, we confirm the self-organization prevailing in the heterogeneous regime, and that the liquid flow rate is only set by the column diameter $D$. Besides, direct liquid and gas velocity measurements demonstrate that the relative velocity increases above the terminal velocity $U_T$ in the heterogeneous regime, and that it tends to $\sim 2.4 U_T$ at very large gas superficial velocities $V_{sg}$. The proposed velocity scaling is shown to hold for liquid and gas mean velocities and for their standard deviations. Furthermore, it is found to be valid over a wide range of conditions, corresponding to Froude numbers $Fr=V_{sg}/(gD)^{1/2}$ from 0.02 to 0.5. Then, the relevance of this scaling for coalescing media is discussed. Moreover, following the successful prediction of the void fraction with a Zuber \& Findlay approach at the beginning of the heterogeneous regime, we show how the void fraction is correlated with $Fr$. Further investigations are finally suggested to connect the increase in relative velocity with meso-scale structures known to exist in the heterogeneous regime.