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肋状T型结微通道中微滴形成的混合电-结构控制数值模拟

Numerical Simulation of Hybrid Electric-Structural Control for Microdroplet Formation in Ribbed T-Junction Microchannels.

作者信息

Fu Ruyi

机构信息

School of Science, Shanghai Institute of Technology, Shanghai 201418, China.

出版信息

Micromachines (Basel). 2025 Jun 22;16(7):732. doi: 10.3390/mi16070732.

DOI:10.3390/mi16070732
PMID:40731641
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12298688/
Abstract

Microdroplet formation in microfluidic systems plays a pivotal role in chemical engineering, biomedicine, and energy applications. Precise control over the droplet size and formation dynamics of microdroplets is essential for optimizing performance in these fields. This work explores a hybrid control strategy that combines an active electric field with passive rib structures to regulate the droplet formation in a ribbed T-junction microchannel under an electric field. Numerical simulations based on the phase-field method are employed to analyze the effects of the electric capillary number Cae and rib height a/wc on the droplet formation mechanism. The results reveal that increasing Cae induces three distinct flow regimes of the dispersed phase: unpinning, partially pinning, and fully pinning regimes. This transition from an unpinning to a pinning regime increases the contact area between the wall and dispersed phase, restricts the flow of the continuous phase, and induces the shear stress of the wall, leading to a reduction in droplet size with the enhanced Cae. Furthermore, an increase in rib height a/wc enhances the shear stress of the continuous phase above the rib, causing a progressive shift from a fully pinning to an unpinning regime, which results in a linear decrease in droplet size. A new empirical correlation is proposed to predict droplet size S/wc2 as a function of rib height a/wc and two-phase flow rate ratio Qd/Qc: S/wc2=(-0.62-1.8Qd/Qc)(a/w)+(0.64+0.99Qd/Qc).

摘要

微流控系统中的微滴形成在化学工程、生物医学和能源应用中起着关键作用。精确控制微滴的尺寸和形成动力学对于优化这些领域的性能至关重要。这项工作探索了一种混合控制策略,该策略将有源电场与无源肋结构相结合,以调节电场作用下肋状T型结微通道中的微滴形成。采用基于相场法的数值模拟来分析电毛细数Cae和肋高a/wc对微滴形成机制的影响。结果表明,增加Cae会诱导分散相出现三种不同的流动状态:解钉扎、部分钉扎和完全钉扎状态。从解钉扎状态到钉扎状态的这种转变增加了壁与分散相之间的接触面积,限制了连续相的流动,并诱导了壁的剪切应力,导致随着Cae的增加微滴尺寸减小。此外,肋高a/wc的增加会增强肋上方连续相的剪切应力,导致从完全钉扎状态逐渐转变为解钉扎状态,从而导致微滴尺寸呈线性减小。提出了一种新的经验关联式,以预测微滴尺寸S/wc2作为肋高a/wc和两相流速比Qd/Qc的函数:S/wc2 = (-0.62 - 1.8Qd/Qc)(a/w) + (0.64 + 0.99Qd/Qc) 。

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