物理
混合器
雷诺数
层流
混合(物理)
微通道
微流控
涡流
机械
二次流
缩放比例
均质化(气候)
流线、条纹线和路径线
经典力学
压力降
微尺度化学
流体力学
流量(数学)
流动可视化
斯托克斯流
下降(电信)
平流
横截面
惯性参考系
计算流体力学
赫尔肖流
作者
Varun Gupta,Shubhangi Pandit,M. K. S. Verma
出处
期刊:Physics of Fluids
[American Institute of Physics]
日期:2025-09-01
卷期号:37 (9)
被引量:4
摘要
Efficient mixing in microfluidic systems at low Reynolds numbers is fundamentally limited by laminar flow, where molecular diffusion governs inter-stream transport. To address this constraint, we present a comprehensive three-dimensional numerical study of a novel split-and-recombined multihelical (SRMH) micromixer that combines curvature- and torsion-induced secondary flows. The SRMH design leverages the formation of Dean vortices and torsional swirl to intensify transverse advection and stretch fluid interfaces, enabling rapid homogenization even in diffusion-limited regimes. This can further help in shrinking microfluidic devices and creating multi-functional gadgets for numerous applications. Using finite element simulations, we systematically vary the Reynolds number (Re=1–450), helix angle, and shape deformation index (SDI) to evaluate mixing efficiency (η), velocity fields, and pressure drop. Compared to standard triple multihelical designs, the SRMH architecture exhibits markedly higher mixing efficiency (eta), particularly in the intermediate and high-Re regimes. A unified power-law scaling relation, η∼Re(βm−αm)( sin2θ cos θ)βm, captures the interplay between inertial suppression (αm) and curvature- and torsion-driven enhancement (βm).Our results reveal that secondary flow strength, quantified via Dean and Germano-type effects, increases with both Reynolds number and SDI, promoting strong radial and tangential velocity components. However, at very high Re and low SDI, a decline in βm is observed, indicating that excessive overlap and transition toward circular cross-sectional geometry suppress asymmetric vortex generation. These findings underscore the importance of geometric modulation in sustaining secondary flow structures and establish the SRMH micromixer as a robust and scalable platform for enhanced mixing in laminar microfluidic systems.
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