Transmission of a Pressure Signal through a Confined Bubble Array

TL;DR

This study investigates how pressure signals propagate through confined bubble arrays using numerical simulations and models, revealing regimes of attenuation and unattenuated transmission, and deriving expressions for sound speed and eigenfrequencies in various bubble systems.

Contribution

The paper introduces the MBP model for predicting pressure transmission in bubble arrays and derives analytical expressions for sound speed and eigenfrequencies in monodisperse and bidisperse systems.

Findings

Good agreement between the MBP model and simulations for initial excitation.

Identified regimes of unattenuated and attenuated pressure transmission.

Derived analytical expressions for eigenfrequencies in bubble systems.

Abstract

Pressure changes travel at an infinite sound speed in an incompressible ideal fluid, opposite to what happens in a bubbly liquid, where the presence of bubbles adds compressibility such that the sound speed becomes finite. Here, the transmission of a pressure signal through a confined bubble array is studied numerically. An axisymmetric Boundary Integral (BI) code was used to simulate a horizontal array of spherical bubbles inside a cylindrical container. On one end of the container, a piston is able to move in either a sinusoidal or impulsive way to excite the bubbles, whereas the other end of the cylinder is fixed. A one-dimensional model, hereafter called the Multiple Bagnold Problem (MBP) model, was developed to predict the behavior of the 3D system. A good agreement between the model and the simulations was found for initial excitation times and qualitatively good agreement for later times. The MBP model was subsequently used to obtain an expression for the sound speed in monodisperse systems, which depends on the ratio between the driving and the natural bubble frequency. Two regimes were found, one where the pressure signal travels unattenuated and the other where attenuation is present. Subsequently we turn to more complex, bidisperse systems, where the influence of the presence of bubbles of two different sizes is explored. Analytical expressions to predict the eigenfrequencies were obtained for monodisperse and bidisperse alternating systems. For bidisperse stacked systems the eigenfrequencies were computed numerically giving a good agreement with the MBP simulations. Finally, we discuss the propagation of a pressure signal through a polydisperse system.