交叉结构序列对三维微混合器内混合性能的影响。

Effect of the crossing-structure sequence on mixing performance within three-dimensional micromixers.

作者信息

Feng Xiangsong, Ren Yukun, Jiang Hongyuan

机构信息

School of Mechatronics Engineering, Harbin Institute of Technology, Harbin 150001, China.

出版信息

Biomicrofluidics. 2014 Jun 2;8(3):034106. doi: 10.1063/1.4881275. eCollection 2014 May.

DOI:10.1063/1.4881275

PMID:24959307

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4048443/

Abstract

The geometry of crossing structure formed by two-layer microchannels determines the axial and transverse movements of contact interface between two liquid streams, which gives us a new method for promoting the micromixers. Hence, we designed four different three-dimensional micromixers by selecting two different crossing structures as basic units (one unit is a crossing structure called "X" and the other is a reversed crossing structure called "rX"). In order to find out how the crossing-structure sequence affects the mixing performance within three-dimensional micromixers, we organized these four mixers in different ways, i.e., the first combination is X-rX-X-rX-…, the second is X-rX-rX-X-…, the third is X-X-rX-X-…, and the last one is X-X-X-X…. Consequently, quite distinct mixing phenomena are engendered. Furthermore, experiments were also conducted using the first and the last models to verify the simulation results. We infer that the last mixer is more likely to trigger chaos and convection by rotating the contact surface than the first one that merely swings the surface even when the flow rates and viscosities of the two liquid streams are increased.

摘要

由两层微通道形成的交叉结构的几何形状决定了两股液流之间接触界面的轴向和横向运动，这为促进微混合器提供了一种新方法。因此，我们通过选择两种不同的交叉结构作为基本单元（一种单元是称为“X”的交叉结构，另一种是称为“rX”的反向交叉结构）设计了四种不同的三维微混合器。为了弄清楚交叉结构序列如何影响三维微混合器内的混合性能，我们以不同方式组合这四种混合器，即第一种组合是X-rX-X-rX-…，第二种是X-rX-rX-X-…，第三种是X-X-rX-X-…，最后一种是X-X-X-X…。结果，产生了截然不同的混合现象。此外，还使用第一种和最后一种模型进行了实验以验证模拟结果。我们推断，即使增加两股液流的流速和粘度，最后一种混合器比仅使表面摆动的第一种混合器更有可能通过旋转接触面引发混沌和对流。

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