Numerical Simulation of Mixing Characteristics in a Split-and-Recombine Microchannel

Qiushi Chen; Mindi Zhang; Chen Zheng; Hansheng Li

doi:10.1080/01457632.2022.2140637

Numerical Simulation of Mixing Characteristics in a Split-and-Recombine Microchannel

Qiushi Chen, Mindi Zhang^*, Chen Zheng, Hansheng Li

^*此作品的通讯作者

Beijing Institute of Technology

科研成果: 期刊稿件 › 文章 › 同行评审

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摘要

The mixing efficiency in microdevices is limited by laminar flow. For passive mixing, the structure of micromixer determines its mixing performance. A novel micromixer with a self-designed repetitive SAR (split-and-recombine) mixing element was carried out and investigated in the present work. The number of mixing elements for simulation was confirmed primarily. Based on the established model, the flow and geometric parameters in this micromixer were discussed systematically by numerical simulation and evaluated by mixing index. Furthermore, the mixing performance of SAR micromixer was compared with conventional T-shaped micromixer for Reynolds numbers ranging from 0.05 to 960. Finally, we concluded that the novel SAR micromixer revealed high performance of mixing due to the enhanced convection. In addition, its input power was similar to that of T-shaped micromixer, which provided the possibility for future industrial applications.

源语言	英语
页（从-至）	1563-1577
页数	15
期刊	Heat Transfer Engineering
卷	44
期	16-18
DOI	https://doi.org/10.1080/01457632.2022.2140637
出版状态	已出版 - 2023

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Chen, Q., Zhang, M., Zheng, C., & Li, H. (2023). Numerical Simulation of Mixing Characteristics in a Split-and-Recombine Microchannel. Heat Transfer Engineering, 44(16-18), 1563-1577. https://doi.org/10.1080/01457632.2022.2140637

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title = "Numerical Simulation of Mixing Characteristics in a Split-and-Recombine Microchannel",

abstract = "The mixing efficiency in microdevices is limited by laminar flow. For passive mixing, the structure of micromixer determines its mixing performance. A novel micromixer with a self-designed repetitive SAR (split-and-recombine) mixing element was carried out and investigated in the present work. The number of mixing elements for simulation was confirmed primarily. Based on the established model, the flow and geometric parameters in this micromixer were discussed systematically by numerical simulation and evaluated by mixing index. Furthermore, the mixing performance of SAR micromixer was compared with conventional T-shaped micromixer for Reynolds numbers ranging from 0.05 to 960. Finally, we concluded that the novel SAR micromixer revealed high performance of mixing due to the enhanced convection. In addition, its input power was similar to that of T-shaped micromixer, which provided the possibility for future industrial applications.",

author = "Qiushi Chen and Mindi Zhang and Chen Zheng and Hansheng Li",

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year = "2023",

doi = "10.1080/01457632.2022.2140637",

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T1 - Numerical Simulation of Mixing Characteristics in a Split-and-Recombine Microchannel

AU - Chen, Qiushi

AU - Zhang, Mindi

AU - Zheng, Chen

AU - Li, Hansheng

PY - 2023

Y1 - 2023

N2 - The mixing efficiency in microdevices is limited by laminar flow. For passive mixing, the structure of micromixer determines its mixing performance. A novel micromixer with a self-designed repetitive SAR (split-and-recombine) mixing element was carried out and investigated in the present work. The number of mixing elements for simulation was confirmed primarily. Based on the established model, the flow and geometric parameters in this micromixer were discussed systematically by numerical simulation and evaluated by mixing index. Furthermore, the mixing performance of SAR micromixer was compared with conventional T-shaped micromixer for Reynolds numbers ranging from 0.05 to 960. Finally, we concluded that the novel SAR micromixer revealed high performance of mixing due to the enhanced convection. In addition, its input power was similar to that of T-shaped micromixer, which provided the possibility for future industrial applications.

AB - The mixing efficiency in microdevices is limited by laminar flow. For passive mixing, the structure of micromixer determines its mixing performance. A novel micromixer with a self-designed repetitive SAR (split-and-recombine) mixing element was carried out and investigated in the present work. The number of mixing elements for simulation was confirmed primarily. Based on the established model, the flow and geometric parameters in this micromixer were discussed systematically by numerical simulation and evaluated by mixing index. Furthermore, the mixing performance of SAR micromixer was compared with conventional T-shaped micromixer for Reynolds numbers ranging from 0.05 to 960. Finally, we concluded that the novel SAR micromixer revealed high performance of mixing due to the enhanced convection. In addition, its input power was similar to that of T-shaped micromixer, which provided the possibility for future industrial applications.

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Numerical Simulation of Mixing Characteristics in a Split-and-Recombine Microchannel

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