Performance of different microfluidic devices in continuous liquid-liquid separation

IF 2 4区 化学 Q3 CHEMISTRY, MULTIDISCIPLINARY Journal of Flow Chemistry Pub Date : 2024-06-13 DOI:10.1007/s41981-024-00326-z
Bastian Oldach, Ya-Yu Chiang, Leon Ben-Achour, Tai-Jhen Chen, Norbert Kockmann
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Abstract

Droplet-based microfluidics exhibit numerous benefits leading to relevant innovations and many applications in various fields. The precise handling of droplets in capillaries, including droplet formation, manipulation, and separation, is essential for successful operation. Only a few reports are known concerning the separation of segmented flows, particularly the continuous separation of droplets, which is of high interest regarding the control of biochemical and chemical reactions or other applications where the contact time of the involved phases is crucial. Here, the separation must be flexible and adjusted to different flow parameters, such as the surface tension, the volumetric flow rates, and their ratios. This contribution presents two novel open-source approaches based on additive manufacturing and mechanical deforming for continuous liquid–liquid separation under various flow conditions. The Laplace pressure is the driving force for the separation, which is adjusted to the flow conditions by adapting the distance of pinning points provided by the design of the devices. Details of the device design and experimental setup are shown along with limitations to promote further development and to increase availability for researchers. With the right parameters, sophisticated separations can be realized by inexpensive laboratory equipment and simple control of them. It was found that the distance between the pinning points needs to enlarged for increasing volumetric flow rates and reduced for higher viscosities of the continuous phase respectively higher amounts of the dispersed phase. The open source approach of this article expands the exploration space in addition to commercially available phase separators only available to a selected group of people.

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不同微流控装置在连续液-液分离中的性能
基于液滴的微流控技术具有众多优势,可带来相关创新并在各个领域得到广泛应用。精确处理毛细管中的液滴,包括液滴的形成、操作和分离,是成功运行的关键。关于分段流的分离,特别是液滴的连续分离,目前只有少数报道,而这在生化和化学反应的控制或其他应用中具有很高的关注度,因为在这些应用中,各相的接触时间至关重要。在这种情况下,分离必须灵活,并根据不同的流动参数(如表面张力、体积流量及其比率)进行调整。本文介绍了两种基于快速成型制造和机械变形的新型开源方法,用于在各种流动条件下实现连续的液-液分离。拉普拉斯压力是分离的驱动力,可通过调整装置设计所提供的销钉点距离来适应流动条件。为了促进进一步开发和增加研究人员的可用性,我们展示了装置设计和实验设置的细节以及限制条件。有了正确的参数,通过廉价的实验室设备和简单的控制,就可以实现复杂的分离。研究发现,随着体积流量的增加,针刺点之间的距离需要增大,而当连续相的粘度较高时,分散相的数量较多时,针刺点之间的距离需要减小。除了仅向特定人群提供的商用相分离器外,本文的开源方法还拓展了探索空间。
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来源期刊
Journal of Flow Chemistry
Journal of Flow Chemistry CHEMISTRY, MULTIDISCIPLINARY-
CiteScore
6.40
自引率
3.70%
发文量
29
审稿时长
>12 weeks
期刊介绍: The main focus of the journal is flow chemistry in inorganic, organic, analytical and process chemistry in the academic research as well as in applied research and development in the pharmaceutical, agrochemical, fine-chemical, petro- chemical, fragrance industry.
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