Minimum Flow Rate in Electro-Coflow

Bulletin of the American Physical Society Pub Date : 2020-03-03 DOI:10.21633/ISSN.2380.5064/S.2020.03.02.31

Benjamin Overlie, Josefa Guerrero Millan

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Abstract

Controlled generation of micron and sub-micron sized drops continues to be of strong interest for the scientific community due to the variety of applications in many different fields. Emulsion drops can be generated by flowing two immiscible liquids inside a glassbased microfluidic device. Their minimum size will be of the order of the tip size. To create smaller drops, an external electric field can be used, similarly to what it is done in the classical electrospray. In electrospray, a liquid is issued into the air from an electrified needle. When the flow rate of the liquid is controlled, there is a minimum flow rate below which a cone-jet cannot be formed regardless of the applied voltage. This minimum flow rate provides the minimum drop size that can be generated, usually one or two orders of magnitude smaller than the tip size. In this presentation, we explore this lower limit in electro-coflow using pressure control instead, which generates different results from using electrospray, and with a more complex behavior. The use of pressure control, and the presence of an outer moving fluid, enrich the dynamics in the minimum flow rate limit. Received: 01/31/2020 Accepted: 02/17/2020 Correspondence: Benjamin Overlie, Augusta University, 1120 15 St. Augusta, GA 30912, boverlie@augusta.edu

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电共流中的最小流量

由于在许多不同领域的各种应用，控制微米和亚微米尺寸滴的产生仍然是科学界的强烈兴趣。通过在玻璃基微流体装置内流动两种不混溶的液体，可以产生乳化液滴。它们的最小尺寸将是尖端尺寸的顺序。为了产生更小的液滴，可以使用外部电场，类似于在经典的电喷雾中所做的。在电喷雾中，液体从带电的针中喷射到空气中。当液体的流量受到控制时，存在一个最小流量，低于该流量，无论施加的电压如何，锥状射流都不能形成。这个最小流量提供了可以产生的最小液滴尺寸，通常比尖端尺寸小一到两个数量级。在本报告中，我们使用压力控制来探索电共流的下限，这与使用电喷雾产生不同的结果，并且具有更复杂的行为。利用压力控制和外部运动流体的存在，丰富了最小流量限制下的动力学。收稿日期:2020年1月31日收稿日期:2020年2月17日通讯:Benjamin Overlie, Augusta University, 1120 15 St. Augusta, GA 30912, boverlie@augusta.edu

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Bulletin of the American Physical Society

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