Numerical Simulation of the Scalar Mixing Characteristics in Three-dimensional Microchannels

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Numerical Simulation of the Scalar Mixing Characteristics in Three-dimensional Microchannels

LIU Yanhua^a; LIN Jianzhong^a; BAO Fubing^a; SHI Xing^b

^aDepartment of Mechanics, State Key Laboratory of Fluid Power Transmission and Control, Zhejiang University, Hangzhou 310027, China

^b Department of MechanicalEngineering, National University of Singapore, Singapore, 119260

Received:1900-01-01 Revised:1900-01-01 Online:2005-06-28 Published:2005-06-28
Contact: LIU Yanhua

不同三维微通道中被动混合特性的研究

刘演华^a; 林建忠^a; 包福兵^a; 石兴^b

^aDepartment of Mechanics, State Key Laboratory of Fluid Power Transmission and Control, Zhejiang University, Hangzhou 310027, China

^b Department of MechanicalEngineering, National University of Singapore, Singapore, 119260

通讯作者: 刘演华

Abstract

Abstract: Based on the transport phenomena theory, the passive mixing of water and ethanol in different threedimensional microchannels is simulated numerically. The average variance of water volume fraction is used to index the mixing efficiency in the cases with different Reynolds number and different fabricated mixers. The results show that the efficiency of liquid mixing is progressively dependent on the convective transport as the Reynolds number increases. The efficiency of serpentine microchannel decreases with the increasing Reynolds number in the laminar regime. Altering the aspect ratio of channel inlet section has no significant effect on the mixing efficiency. Increasing the area of channel inlet section will cause the decrease of the mixing efficiency. The mixing in serpentine channels is the most efficient among three different mixers because of the existence of second flow introduced by its special structure.

Key words: microchannel, mixer, mixing efficiency, numerical simulation

摘要： Based on the transport phenomena theory, the passive mixing of water and ethanol in different threedimensional microchannels is simulated numerically. The average variance of water volume fraction is used to index the mixing efficiency in the cases with different Reynolds number and different fabricated mixers. The results show that the efficiency of liquid mixing is progressively dependent on the convective transport as the Reynolds number increases. The efficiency of serpentine microchannel decreases with the increasing Reynolds number in the laminar regime. Altering the aspect ratio of channel inlet section has no significant effect on the mixing efficiency. Increasing the area of channel inlet section will cause the decrease of the mixing efficiency. The mixing in serpentine channels is the most efficient among three different mixers because of the existence of second flow introduced by its special structure.

关键词: 微通道;混合处理;混合效率;数值模拟;乙醇;水

LIU Yanhua, LIN Jianzhong, BAO Fubing, SHI Xing. Numerical Simulation of the Scalar Mixing Characteristics in Three-dimensional Microchannels
[J]. .

刘演华,林建忠,包福兵,石兴. 不同三维微通道中被动混合特性的研究[J]. CIESC Journal.

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