Upward gas–liquid two-phase flow after a U-bend in a large-diameter serpentine pipe

•Gas–liquid flow experiments performed in a large diameter serpentine flow loop.•Flow visualisation done using a wire mesh sensor to identify upward flow regimes.•Conductance probes were used to measure film thickness in the annular regime.•Asymmetrical films after a U-bend became symmetrical at mid...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2017-05, Vol.108, p.784-800
Main Authors: Aliyu, Aliyu M., Almabrok, Almabrok A., Baba, Yahaya D., Lao, Liyun, Yeung, Hoi, Kim, Kyung Chun
Format: Article
Language:English
Subjects:
Conductance film probes
Large diameter pipes
Multiphase flow
Return bends
Wire mesh sensor
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Summary:•Gas–liquid flow experiments performed in a large diameter serpentine flow loop.•Flow visualisation done using a wire mesh sensor to identify upward flow regimes.•Conductance probes were used to measure film thickness in the annular regime.•Asymmetrical films after a U-bend became symmetrical at middle and top positions.•Improved film thickness correlation was developed and compared with existing ones. We present an experimental study on the flow behaviour of gas and liquid in the upward section of a vertical pipe system with an internal diameter of 101.6mm and a serpentine geometry. The experimental matrix consists of superficial gas and liquid velocities in ranges of 0.15–30m/s and from 0.07 to 1.5m/s, respectively, which cover bubbly to annular flow. The effects on the flow behaviours downstream of the 180° return bend are significantly reduced when the flow reaches an axial distance of 47 pipe diameters from the U-bend. Therefore, reasonably developed flow is attained at this development length downstream of the bend. Other published measurements for large-diameter film thickness show similar trends with respect to the superficial gas velocity. However, the trends differ from those of small-diameter pipes, with which the film thickness decreases much faster with increasing gas flow. As a result, only a few of the published correlations for small pipe data agreed with the experimental data for large pipe film thickness. We therefore modified one of the best-performing correlations, which produced a better fit. Qualitative and statistical analyses show that the new correlation provides improved predictions for two-phase flow film thickness in large-diameter pipes.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2016.12.069