Efficient Control of Microbubble Properties by Alcohol Shear Flows in Ceramic Membrane Channels

Yefei Liu; Yang Han; Xiaoli Li; Hong Jiang; Rizhi Chen

doi:10.1002/ceat.201700226

Efficient Control of Microbubble Properties by Alcohol Shear Flows in Ceramic Membrane Channels

Yefei Liu, Yang Han, Xiaoli Li, Hong Jiang, Rizhi Chen

College of Chemical Engineering

Nanjing Tech University

Research output: Contribution to journal › Article › peer-review

25 Scopus citations

Abstract

Efficient control of microbubbles is achieved by alcohol shear flows in ceramic membrane channels. The dependence of hydrodynamic and mass transfer properties of microbubbles on liquid viscosity was investigated in a bubble column. The multichannel ceramic membrane worked as the gas sparger, and the shear flow on the membrane surface controlled the microbubble generation. Oxygen gas and glycerin solutions with different viscosities served as gas phase and liquid phase, respectively. The microbubbles were massively generated at different liquid viscosities. With increasing viscosity, the bubble size first decreased and then increased. The dual effect of viscosity on bubble size was related to bubble coalescence. However, an impact of viscosity on gas holdup was not observed for microbubbles.

Original language	English
Pages (from-to)	168-174
Number of pages	7
Journal	Chemical Engineering and Technology
Volume	41
Issue number	1
DOIs	https://doi.org/10.1002/ceat.201700226
State	Published - Jan 2018

Keywords

Bubble controlling
Ceramic membrane
Hydrodynamics
Mass transfer
Microbubbles

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10.1002/ceat.201700226

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title = "Efficient Control of Microbubble Properties by Alcohol Shear Flows in Ceramic Membrane Channels",

abstract = "Efficient control of microbubbles is achieved by alcohol shear flows in ceramic membrane channels. The dependence of hydrodynamic and mass transfer properties of microbubbles on liquid viscosity was investigated in a bubble column. The multichannel ceramic membrane worked as the gas sparger, and the shear flow on the membrane surface controlled the microbubble generation. Oxygen gas and glycerin solutions with different viscosities served as gas phase and liquid phase, respectively. The microbubbles were massively generated at different liquid viscosities. With increasing viscosity, the bubble size first decreased and then increased. The dual effect of viscosity on bubble size was related to bubble coalescence. However, an impact of viscosity on gas holdup was not observed for microbubbles.",

keywords = "Bubble controlling, Ceramic membrane, Hydrodynamics, Mass transfer, Microbubbles",

author = "Yefei Liu and Yang Han and Xiaoli Li and Hong Jiang and Rizhi Chen",

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year = "2018",

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doi = "10.1002/ceat.201700226",

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AU - Liu, Yefei

AU - Han, Yang

AU - Li, Xiaoli

AU - Jiang, Hong

AU - Chen, Rizhi

PY - 2018/1

Y1 - 2018/1

N2 - Efficient control of microbubbles is achieved by alcohol shear flows in ceramic membrane channels. The dependence of hydrodynamic and mass transfer properties of microbubbles on liquid viscosity was investigated in a bubble column. The multichannel ceramic membrane worked as the gas sparger, and the shear flow on the membrane surface controlled the microbubble generation. Oxygen gas and glycerin solutions with different viscosities served as gas phase and liquid phase, respectively. The microbubbles were massively generated at different liquid viscosities. With increasing viscosity, the bubble size first decreased and then increased. The dual effect of viscosity on bubble size was related to bubble coalescence. However, an impact of viscosity on gas holdup was not observed for microbubbles.

AB - Efficient control of microbubbles is achieved by alcohol shear flows in ceramic membrane channels. The dependence of hydrodynamic and mass transfer properties of microbubbles on liquid viscosity was investigated in a bubble column. The multichannel ceramic membrane worked as the gas sparger, and the shear flow on the membrane surface controlled the microbubble generation. Oxygen gas and glycerin solutions with different viscosities served as gas phase and liquid phase, respectively. The microbubbles were massively generated at different liquid viscosities. With increasing viscosity, the bubble size first decreased and then increased. The dual effect of viscosity on bubble size was related to bubble coalescence. However, an impact of viscosity on gas holdup was not observed for microbubbles.

KW - Bubble controlling

KW - Ceramic membrane

KW - Hydrodynamics

KW - Mass transfer

KW - Microbubbles

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DO - 10.1002/ceat.201700226

M3 - 文章

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JO - Chemical Engineering and Technology

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Efficient Control of Microbubble Properties by Alcohol Shear Flows in Ceramic Membrane Channels

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