Matthew Bernard scite author profile

The objective of this study is to advance the local multi-sensor conductivity probe measurement technique through systematic investigation into several practical aspects of a conductivity probe measurement system. Firstly, signal "ghosting" among probe sensors is found to cause artificially high bubble velocity measurements and low interfacial area concentration (a i) measurements that depend on sampling frequency and sensor impedance. A revised electrical circuit is suggested to eliminate this artificial variability. Secondly, the sensitivity of the probe measurements to sampling frequency is investigated in 13 two-phase flow conditions with superficial liquid and gas velocities ranging from 1.00-5.00m/s and 0.17-2.0m/s, respectively. With increasing gas flow rate, higher sampling frequencies, greater than 100kHz in some cases, are required to adequately capture the bubble number frequency and a i measurements. This trend is due to the increase in gas velocity and the transition to the slug flow regime. Thirdly, the sensitivity of the probe measurements to the measurement duration as well as the sample number is investigated for the same flow conditions. Measurements of both group-I (spherical/distorted) and group-II (cap/slug/churn-turbulent) bubbles are found to be relatively insensitive to both the measurement duration and the number of bubbles, as long as the measurements are made for a duration long enough to capture a collection of samples characteristic to a given two-phase flow system (or a statistical ensemble). Fourthly, investigation into the orientation of a double-sensor probe in the pipe indicates that the sensors should be oriented parallel to the pipe wall to ensure symmetric bubble velocity measurements. Lastly, Monte Carlo simulations are performed to study the effects of the axial (s) and lateral (d) probe sensor separation distances. In addition to

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Experimental study on interfacial structure and interfacial area transport in downward two-phase flow

Wang

Dang

et al. 2017

International Journal of Heat and Mass Transfer

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Evaluation of two-group interfacial area transport equation model for vertical small diameter pipes against high-resolution experimental data

Dave

Manera

Beyer

et al. 2017

Chemical Engineering Science

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Considerations in the Practical Application of the Multisensor Conductivity Probe for Two-Phase Flow

et al. 2015

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Matthew Bernard

Experimental study of interfacial characteristics of vertical upward air-water two-phase flow in 25.4 mm ID round pipe

Sensitivity studies on the multi-sensor conductivity probe measurement technique for two-phase flows

Experimental study on interfacial structure and interfacial area transport in downward two-phase flow

Evaluation of two-group interfacial area transport equation model for vertical small diameter pipes against high-resolution experimental data

Considerations in the Practical Application of the Multisensor Conductivity Probe for Two-Phase Flow

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