Performance evaluation of a 3D split-and-recombination micromixer with asymmetric structures

Dezhao Jiao; Ruirong Zhang; Hantian Zhang; Shuang Ren; Huicheng Feng; Honglong Chang

doi:10.1088/1361-6439/ac7771

Performance evaluation of a 3D split-and-recombination micromixer with asymmetric structures

Dezhao Jiao, Ruirong Zhang, Hantian Zhang, Shuang Ren, Huicheng Feng, Honglong Chang

School of Mechanical Engineering

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

2 Scopus citations

Abstract

Micromixers are widely used in lab-on-a-chip devices for analytical chemistry, bioengineering, and biomedicine to achieve rapid mixing and analysis of samples. However, the existing micromixers are mostly two-dimensional structures with low mixing efficiency. Even three-dimensional (3D) micromixers with complex structures have low mixing efficiency in the low Reynolds number range. In this paper, a 3D split-and-recombination (SAR) micromixer inspired by the horseshoe transform principle is proposed to further improve the mixing efficiency. There 3D SAR micromixers with different subchannel sizes were designed and tested in the Reynolds numbers range of 0.1-100. The optimal size of the micromixer was revealed through computational fluid dynamics simulations and experimental test results. A minimum mixing index of 91% is achieved in the range of Reynolds numbers from 0.1 to 100.

Original language	English
Article number	075007
Journal	Journal of Micromechanics and Microengineering
Volume	32
Issue number	7
DOIs	https://doi.org/10.1088/1361-6439/ac7771
State	Published - Jul 2022

Keywords

computational fluid dynamics
lab on a chip
micromixer
mixing index
split-and-recombination

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10.1088/1361-6439/ac7771

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title = "Performance evaluation of a 3D split-and-recombination micromixer with asymmetric structures",

abstract = "Micromixers are widely used in lab-on-a-chip devices for analytical chemistry, bioengineering, and biomedicine to achieve rapid mixing and analysis of samples. However, the existing micromixers are mostly two-dimensional structures with low mixing efficiency. Even three-dimensional (3D) micromixers with complex structures have low mixing efficiency in the low Reynolds number range. In this paper, a 3D split-and-recombination (SAR) micromixer inspired by the horseshoe transform principle is proposed to further improve the mixing efficiency. There 3D SAR micromixers with different subchannel sizes were designed and tested in the Reynolds numbers range of 0.1-100. The optimal size of the micromixer was revealed through computational fluid dynamics simulations and experimental test results. A minimum mixing index of 91% is achieved in the range of Reynolds numbers from 0.1 to 100.",

keywords = "computational fluid dynamics, lab on a chip, micromixer, mixing index, split-and-recombination",

author = "Dezhao Jiao and Ruirong Zhang and Hantian Zhang and Shuang Ren and Huicheng Feng and Honglong Chang",

note = "Publisher Copyright: {\textcopyright}3/4 20, the mixing index is higher than 99%. The results obtained indicate that this 3D SAR micromixer with an asymmetric structure shows a satisfactory choice in the fluid mixing process of microfluidic systems, and has a potential application in the field of microchip-based biochemical analysis. ",

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AU - Ren, Shuang

AU - Feng, Huicheng

AU - Chang, Honglong

N1 - Publisher Copyright: ©3/4 20, the mixing index is higher than 99%. The results obtained indicate that this 3D SAR micromixer with an asymmetric structure shows a satisfactory choice in the fluid mixing process of microfluidic systems, and has a potential application in the field of microchip-based biochemical analysis.

PY - 2022/7

Y1 - 2022/7

N2 - Micromixers are widely used in lab-on-a-chip devices for analytical chemistry, bioengineering, and biomedicine to achieve rapid mixing and analysis of samples. However, the existing micromixers are mostly two-dimensional structures with low mixing efficiency. Even three-dimensional (3D) micromixers with complex structures have low mixing efficiency in the low Reynolds number range. In this paper, a 3D split-and-recombination (SAR) micromixer inspired by the horseshoe transform principle is proposed to further improve the mixing efficiency. There 3D SAR micromixers with different subchannel sizes were designed and tested in the Reynolds numbers range of 0.1-100. The optimal size of the micromixer was revealed through computational fluid dynamics simulations and experimental test results. A minimum mixing index of 91% is achieved in the range of Reynolds numbers from 0.1 to 100.

AB - Micromixers are widely used in lab-on-a-chip devices for analytical chemistry, bioengineering, and biomedicine to achieve rapid mixing and analysis of samples. However, the existing micromixers are mostly two-dimensional structures with low mixing efficiency. Even three-dimensional (3D) micromixers with complex structures have low mixing efficiency in the low Reynolds number range. In this paper, a 3D split-and-recombination (SAR) micromixer inspired by the horseshoe transform principle is proposed to further improve the mixing efficiency. There 3D SAR micromixers with different subchannel sizes were designed and tested in the Reynolds numbers range of 0.1-100. The optimal size of the micromixer was revealed through computational fluid dynamics simulations and experimental test results. A minimum mixing index of 91% is achieved in the range of Reynolds numbers from 0.1 to 100.

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Performance evaluation of a 3D split-and-recombination micromixer with asymmetric structures

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