Experimental Study on Carbon Dioxide Bubble Dynamics at the Interface of Layered Liquids with Different Viscosities

The dynamic characteristics of carbon dioxide bubbles passing through the interface of layered liquid have a far-reaching impact on capture, storage and utilization, metallurgical chemical industry and nuclear reactor operation. In order to study the dynamics of carbon dioxide bubbles on the layered...

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Bibliographic Details
Published in:Fluid dynamics 2022-12, Vol.57 (9), p.1080-1095
Main Authors: Yang, J. X., Gao, D., Xu, W. H., Zhang, H.
Format: Article
Language:English
Subjects:
Bubbles
Carbon dioxide
Carboxymethyl cellulose
Cellulose
Chemical industry
Classical and Continuum Physics
Classical Mechanics
Deionization
Dynamic characteristics
Engineering Fluid Dynamics
Fluid- and Aerodynamics
Herbicides
High speed cameras
Liquid levels
Metallurgical analysis
Nuclear facilities
Nuclear reactors
Pesticides industry
Physics
Physics and Astronomy
Residence time distribution
Sodium carboxymethyl cellulose
Transit time
Viscosity
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Summary:The dynamic characteristics of carbon dioxide bubbles passing through the interface of layered liquid have a far-reaching impact on capture, storage and utilization, metallurgical chemical industry and nuclear reactor operation. In order to study the dynamics of carbon dioxide bubbles on the layered liquid interface of deionized water and oil with different viscosities based on the visual-experimental platform, the carbon dioxide bubbles produced by the nozzle were experimentally studied under the layered liquid level of deionized water and oil with different viscosities, the movement results of carbon dioxide bubbles were photographed and analyzed using a high-speed camera. The initial maximum diameter of a carbon dioxide bubble, the passing diameter of a carbon dioxide bubble, the residence time of a carbon dioxide bubble on the interface, the wake length, and the shedding time were studied experimentally, and the critical diameter number, Eotvos–Galileo image and the length diameter ratio were analyzed. The results show that the critical diameter number of the initial maximum diameter and the passing diameter is greater than 10, and is located in the I and III regions of the Eotvos–Galileo image. The initial maximum diameter when the viscosity of sodium carboxymethyl cellulose solution is equal to 100 mPa s, the passing diameter, the wake length, and the length diameter ratio have a M-shaped distribution as a whole, and the initial maximum diameter when the viscosity of sodium carboxymethyl cellulose solution is small has a W-shaped distribution. The residence time and the transit time increase with increase in the viscosity.
ISSN:0015-4628
1573-8507
DOI:10.1134/S0015462822600663