风筝形腔被动微混合器的设计与优化

Israt Zahan Nishu, M. F. Samad
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引用次数: 0

摘要

微混合器是一种带有微通道的设备,可以有效地混合流体在很小的区域和有限的流动路线上。微流体系统的关键部件之一是微混合器,它应该以最小的压降产生最大的混合。本文提出了一种带有矩形桥的风筝形腔室和涡诱导入口的无源微混合器。流体在桥上的垂直分离及其在腔室中的重新组合改善了这里的混合性能。目的是通过使用田口方法和灰色关联分析(GRA)优化设计来最大化结果。田口试验设计采用三个因子,每个因子有三个水平值,形成一个L9正交阵列,共9个试验。通过分析,得出了最优微混合器和最具影响的参数。使用COMSOL Multiphysics软件进行数值模拟,其中雷诺数范围为0.1至100。在其5.8毫米的长度,优化的微型混合器产生98%的混合和最大9.8千帕的压降。从模拟分析可以看出,所提出的微混合器可以适用于化学和生物医学领域的实际应用。
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Design and Optimization of a Passive Micromixer with Kite-Shaped Chambers
Micromixers are devices with microchannels that effectively mix fluids across a tiny area and a limited flow route. One of the crucial components of a microfluidic system is a micromixer that should produce the maximum mixing with the smallest pressure drop. In this paper, a passive micromixer with kite-shaped chambers with rectangular bridges, and vortex-inducing inlets is proposed. The vertical separation of the fluid streams across the bridges and their recombination in the chambers has improved the mixing performance in here. The aim is to maximize the result by optimizing the design using the Taguchi approach and Grey Relational Analysis (GRA). Three factors, each with three level values, are employed in the Taguchi Design of Experiment, which produce a L9 orthogonal array with nine (9) trials. The optimal micromixer and the most influential parameter are derived from the analyses. COMSOL Multiphysics software is used to conduct the numerical simulation, which includes a Reynolds number range of 0.1 to 100. In its 5.8 mm length, the optimized micromixer produces 98% mixing and a maximum 9.8 kPa pressure drop. From the simulated analyses, it can be said that the proposed micromixer could be appropriate for the practical uses in the chemical and the biomedical sectors.
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