4.6 Article

Dynamic changes in gas-liquid mass transfer during Taylor flow in long serpentine square microchannels

期刊

CHEMICAL ENGINEERING SCIENCE
卷 182, 期 -, 页码 17-27

出版社

PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.ces.2018.02.018

关键词

Microchannel; Gas-liquid; Mass transfer; Carbon dioxide; Taylor flow

资金

  1. National Natural Science Foundation of China [21376234, 21676263, 21676230, U1662124]
  2. State Key Laboratory of Chemical Engineering [SKL-ChE-08A01]

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The present work focuses on the hydrodynamics variation and mass transfer characteristics of Taylor flow along long serpentine microchannels with a square cross-section. The volumetric mass transfer coefficient (k(L)a) is regarded as the transient change value to characterize the gas-liquid mass transfer process of CO2 in water. All experimental data of Taylor bubble are obtained from 1000 continuously captured images. An online high-speed imaging method and the unit cell model are adopted in this study. The effects of gas and liquid flow rates, together with microchannel geometry are investigated on Taylor bubble characteristics in terms of length, velocity and the mass transfer performance. Taylor bubble length shrinks and subsequently plateaus out along the flow direction from the T-junction, resulting in the decrease in Taylor bubble velocity. k(L)a in a unit cell gradually decreases along the serpentine microchannel, and increases as the channel cross-sectional area decreases. As the gas flow rate increases under a given liquid flow rate, a critical point is found for the evolution of k(L)a and k(L) (that is the liquid phase mass transfer coefficient). The results indicate that the contribution of the circulation in the liquid slug to kL is dominant before the critical point compared to the leakage flow in the liquid film. All these findings in this work give important information to understand the dynamic change in gas-liquid Taylor flow mass transfer within microchannels. They will serve as basis for designing and optimizing gas-liquid multiphase microreactors in the future. (C) 2018 Elsevier Ltd. All rights reserved.

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