Direct numerical study of speed of sound in dispersed air-water two-phase flow

TL;DR

This paper introduces a novel direct numerical simulation method for analyzing the speed of sound in compressible air-water two-phase flow, incorporating effects like viscosity and heat transfer, validated against experimental data.

Contribution

It presents the first direct numerical simulation approach for the speed of sound in multiphase flow, integrating stratified flow modeling with Riemann solvers and physical effects.

Findings

Speed of sound increases with frequency in bubbly flow.

Simulation results align well with experimental data at 1 kHz.

Homogeneous flow condition is valid at lower frequencies.

Abstract

Speed of sound is a key parameter for the compressibility effects in multiphase flow. We present a new approach to do direct numerical simulations on the speed of sound in compressible two-phase flow, based on the stratified multiphase flow model (Chang & Liou, JCP 2007). In this method, each face is divided into gas-gas, gas-liquid, and liquid-liquid parts via reconstruction of volume fraction, and the corresponding fluxes are calculated by Riemann solvers. Viscosity and heat transfer models are included. The effects of frequency (below the natural frequency of bubbles), volume fraction, viscosity and heat transfer are investigated. With frequency 1 kHz, under viscous and isothermal conditions, the simulation results satisfy the experimental ones very well. The simulation results show that the speed of sound in air-water bubbly two-phase flow is larger when the frequency is higher. At lower frequency, for the phasic velocities, the homogeneous condition is better satisfied. Considering the phasic temperatures, during the wave propagation an isothermal bubble behavior is observed. Finally, the dispersion relation of acoustics in two-phase flow is compared with analytical results below the natural frequency. This work for the first time presents an approach to the direct numerical simulations of speed of sound and other compressibility effects in multiphase flow, which can be applied to study more complex situations, especially when it is hard to do experimental study.