Experiments are performed in a recirculating two-phase flow loop using an airlift pump with an axial air injector and at different non-Newtonian rheological behaviours. This was achieved using three mixtures of Xanthan Gum (XG) and water of 0.05 %, 0.15 %, and 0.25 % by weight concentrations. Both air and liquid flow rates are recorded for the desire pump operating conditions. The pump performance found to be directly correlated with the concentrations of XG. The pump flow rates decreased as the XG concentration increased due to the decrease of slug velocity which is responsible for high lifting effect. The recorded slug velocity was found to change between 1.81 cm/s, 1.75 cm/s, and 1.7 cm/s for XG concentrations of 0.05 %, 0.15 %, and 0.25 % respectively. Also, with the increase of XG concentration, the slug length found to increase due to the formation of large slugs without many trailing small bubbles as seen in the lower concentrations' cases. As the viscosity increased for different XG concentrations, the calculated efficiency of the airlift pump found to decrease as well. This is attributed to the fact that as the liquid became more viscous, higher energy of the air is required to overcome the shear stresses acting on the liquid phase to provide lifting.
Two-phase flow can be seen in petroleum, air conditioning systems, refrigeration systems, pumping technologies and power generation [1]. Two-phase flow is characterized by different flow pattern such as bubble flow, churn flow, slug flow, and annular flow behaviour[2]. Void fraction can be defined as the volumetric ratio between the gas phase to the total mixture. One of the most widely used techniques to determine void fraction is the electrical impedance by placing two electrodes on either side of the pipe and measuring the impedance between these two probes [3]. In this technique the capacitance change is related to the variation of the dielectric constants of the two phases within the sensor [4]. Minimizing the error in the capacitance readings will prove helpful in accurately identifying the flow pattern passing through the sensor. The void fraction time signal for air-water two-phase mixture will be evaluated for different two-phase flow patterns by the use of a capacitance sensor. The experimental setup consists of a Flonergia airlift pump, and controlled through mass flow meters to be able to create the different flow patterns within the vertical pipe. A concave designed sensor was mounted on the vertical pipe and connected to a DAQ system where the data is collected using LabVIEW. To ensure accurate readings from the capacitance sensor, a calibration of the sensor was performed by taking time signals of two cases: 1. Vertical column full of liquid, 2. Vertical column full of air. This provides the two points on a linear calibration curve between void fraction and the capacitance signals. For each air-water capacitance signal, 50000 samples are collected at a sample rate of 1000 Hz to obtain the time signal for each case. It was determined that the average air signal was 401.5 and the average water signal was 412.93. By taking the maximum root mean square from each signal and dividing the value by the range, the error in each reading was less than 1 %. The three flow regimes that were evaluated were bubbly flow, slug flow, and churn flow. The void fraction that were determined for each flow rate were 1.6% for an air flow rate of 0.5LPM, 14% for 3.5 LPM and 21% for 15 SLPM. It was observed that as the airflow rates increased, the void fraction also increased and the flow patterns change for bubble to slug and to churn flow. The next steps will be to evaluate the time signal for each flow pattern to understand the structure of the bubble that will be passing through the capacitance sensor. Evaluating the time signal will give a better understanding of the flow pattern that is in operation. In addition, the void fraction for a range of flow conditions can be compared with flow visualization to accurately determine the flow pattern.
The continuous demand for energy has open many pathways to develop new sustainable power generation processes. Magnetohydrodynamics (MHD) power generation is an alternative process being investigated to recover energy from low temperature sources but is not limited to low temperatures. Liquid Metal MHD (LMMHD) power generation is the process of circulating liquid metal through an MHD generator using gas injection. The need to design a low energy two-phase gas-lift pump and evaluate its performance as well as the two-phase dynamics in this energy recovering process are crucial components to develop the system. In this study, a preliminary analysis utilizing ANSYS Fluent ® for pumping two-phase flow mixture of nitrogen and galinstan is performed. These numerical results along with the analytical model based on drift flux assumptions are used to understand the performance of the gas-lift two-phase flow pump in this system. Reasonable agreement between the numerical and analytical results were obtained. The CFD results were used to describe the void fraction of the two phases in the pipe riser and considered to be the first step to understand the performance of LMMHD power generation loop.
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