Laminar bubbly flow in an open capillary channel in microgravity

The study of a bubbly laminar two-phase flow in an open capillary channel under microgravity conditions was conducted aboard the sounding rocket, Texus-45. The channel consists of two parallel plates of width b = 25 mm and distance a = 10 mm. The flow along the length l = 80 mm is confined by a free...

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Bibliographic Details
Published in:International journal of multiphase flow 2010-09, Vol.36 (9), p.707-719
Main Authors: Salim, Abdelkader, Colin, Catherine, Grah, Aleksander, Dreyer, Michael E.
Format: Article
Language:English
Subjects:
Bubbles
Bubbly two-phase flow
Capillarity
Capillary channel flow
Channels
Coalescence
Curvature
Exact sciences and technology
Fluid dynamics
Fundamental areas of phenomenology (including applications)
Image processing
Instrumentation for fluid dynamics
Liquids
Mathematical models
Microgravity
Multiphase and particle-laden flows
Nonhomogeneous flows
Physics
Void fraction
Wall shear stress
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Summary:The study of a bubbly laminar two-phase flow in an open capillary channel under microgravity conditions was conducted aboard the sounding rocket, Texus-45. The channel consists of two parallel plates of width b = 25 mm and distance a = 10 mm. The flow along the length l = 80 mm is confined by a free surface on one side and a plate on the opposite side. The bubbles are injected at the nozzle of the capillary channel via six capillary tubes of 100 μm in inner diameter. Different liquid and gas flow rates were tested leading to different liquid free surface shape and bubble size. The effect of the gas flow rate on the shape of the free surface is analysed from image processing. The local curvature of the free surface can be related to the local wall friction taking into account the entrance effects in the channel. The wall shear stress is found to be increased in two-phase flow by comparison to single-phase flow. The mean bubble velocities averaged over the channel cross section are also measured by image processing. They are directly proportional to the mixture velocity. The bubble size increases along the channel due to coalescence. The bubble size evolution is well predicted by the coalescence model previously developed by the authors.
ISSN:0301-9322
1879-3533
DOI:10.1016/j.ijmultiphaseflow.2010.05.003