Rectifying jet breakup by electric forcing

Droplet Pub Date : 2023-03-14 DOI:10.1002/dro2.45
David Van Assche, Thomas Beneyton, Jean-Christophe Baret
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Abstract

The high-throughput production of monodisperse droplets is paramount in most of the applications in droplet microfluidics. In a flow-focusing junction, a straightforward way to increase droplet production rate is to increase the flow rates. However, at a critical flow velocity, the droplet monodispersity breaks down due to a transition from the dripping to the jetting regime. As a result, a much more polydisperse droplet population is generated. The change from monodisperse to polydisperse droplet production emerges from the intrinsic properties of the instabilities of jets. In the jetting regime, droplet pinch-off is governed by a convective instability which amplifies random noise when traveling down the jet leading to an irregular breakup. We show that with the use of an amplitude-modulated electric signal, we select the breakup frequency of the jet. Matching the perturbation frequency close to the natural breakup frequency of the jet, we increase the monodispersity of the droplet population. This method is applicable to droplet production at a high throughput, that is, beyond the dripping to jetting threshold, including an active control since the frequency, and hence droplet sizes, are determined by the forcing frequency.

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电强制矫正射流破碎
单分散液滴的高通量生产在液滴微流体的大多数应用中是至关重要的。在流聚焦结中,增加液滴产生速率的一种简单方法是增加流速。然而,在临界流速下,液滴的单分散性由于从滴落状态过渡到喷射状态而破裂。结果,产生了更加多分散的液滴群体。从单分散到多分散液滴产生的变化源于射流不稳定性的内在特性。在喷射状态下,液滴夹断是由对流不稳定性控制的,当液滴沿射流向下传播时,对流不稳定性会放大随机噪声,导致不规则的破裂。我们表明,通过使用调幅电信号,我们选择了射流的破碎频率。使微扰频率接近射流的自然破裂频率,我们增加了液滴群体的单分散性。该方法适用于高产量的液滴生产,也就是说,超过滴到喷射阈值,包括主动控制,因为频率以及液滴尺寸由强制频率决定。
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Issue Information Front Cover, Volume 3, Number 4, October 2024 Inside Back Cover, Volume 3, Number 4, October 2024 Back Cover, Volume 3, Number 4, October 2024 Inside Front Cover, Volume 3, Number 4, October 2024
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