Acoustic emission-based flow noise detection and mechanism analysis for gas-liquid two-phase flow

Abstract

Abstract The interphase forces of gas-liquid two-phase flow produce flow noise, which contains abundant two-phase flow information, such as two-phase flow rate, flow pattern, void fraction, etc. In this study, the acoustic emission technique is utilized to measure the flow noise of gas-liquid two-phase flow quantitatively. The signal is separated and identified by the Hilbert Huang transform, the R/S analysis, and the flow noise mathematical model. The Autoregressive Integrated Moving Average (ARIMA) time series model is used to predict the energy change of bubble flow. The results show that the Hilbert Huang transform can separate the noise signal. According to the R/S analysis, IMF1-IMF3 is the interaction noise of the gas and liquid. The results show that the prediction results all fall within the 95% confidence interval. It provides new approaches for the quantitative analysis of gas-liquid two-phase flow and flow pattern transitions.