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将多种流体动力学效应与新型三边膜阀相结合,以开发一种用于无过滤连续水净化的微流控装置。

Amalgamation of diverse hydrodynamic effects with novel triple-sided membrane valves for developing a microfluidic device for filterless and continuous water purification.

作者信息

Prabhakar Amit, Jaiswar Ankur, Mishra Neha, Kumar Praveen, Dhwaj Amar, Nayak Prashant, Verma Deepti

机构信息

Department of Applied Sciences, Indian Institute of Information Technology Allahabad 211015 India

Department of Chemistry, University of Allahabad Allahabad 211002 India

出版信息

RSC Adv. 2021 Aug 25;11(46):28723-28734. doi: 10.1039/d1ra04353f. eCollection 2021 Aug 23.

DOI:10.1039/d1ra04353f
PMID:35478548
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9038102/
Abstract

The requirement for clean water has been increasing for several reasons, for instance, the fast industrialization of developing countries, climate change, environmental pollution, growth of biofuel use and the resulting growth in irrigation. To meet the requirements for contamination-free water, a cost-effective water treatment can substantially improve the developing world's health, largely for children, and there is predicted to be a huge market for this. Existing water treatment processes consist of various phases that are time-consuming as well as pricey. There is an essential demand for cost-effective point of use methods to purify drinking water to reduce the impact of diseases induced by numerous waterborne pathogens. The development of micro-devices, with different outcomes, can be a helpful solution to various problems. To make this reality, a novel microfluidic device for the purification of water, with multiple hydrodynamic effects, has been shown in this paper. In the proposed novel device, the network of interconnected microfluidic channels was created in such a way that an amalgamation of multiple effects, such as the Fåhræus effect, centrifugal force, the Zweifach-Fung effect and constriction followed by expansion, act together in the microchannel to separate suspended impurities ( bacteria and similar length scale particles present in water in the suspension form) from water. Furthermore, to improve the bacterial separation efficiency of the device, the pure water channel of the microdevice was designed with an encircled triple-sided film valve arrangement at a few points, which aided the modulation of the cross-sectional area of the pure water channel. Consecutively, the reduction of the cross-sectional area of the pure water channel caused a highly effective Zweifach-Fung effect, which aided the better separation of the suspended particles ( bacteria, dust particles ). The device was observed to have an average of 99.6% efficiency in the separation of suspended microparticles/microbes with dimensions in the range of 1-10 micrometres. The device performance indicated its potential for the separation of other similar suspended impurities, small dust particles, bacteria, fungi, viruses and similar particles present in water in the suspension form.

摘要

对清洁水的需求一直在增加,原因有多种,例如发展中国家的快速工业化、气候变化、环境污染、生物燃料使用的增长以及随之而来的灌溉用水增加。为满足对无污染水的需求,具有成本效益的水处理可大幅改善发展中世界的健康状况,主要惠及儿童,预计这将有巨大的市场。现有的水处理工艺由多个阶段组成,既耗时又昂贵。迫切需要具有成本效益的使用点方法来净化饮用水,以减少由多种水传播病原体引起的疾病的影响。不同结果的微器件的开发可能是解决各种问题的有用方案。为实现这一目标,本文展示了一种具有多种流体动力学效应的新型微流控水净化装置。在所提出的新型装置中,相互连接的微流控通道网络以这样一种方式构建,即多种效应的结合,如法厄效应、离心力、 Zweifach-Fung效应以及收缩后扩张,在微通道中共同作用以从水中分离悬浮杂质(以悬浮形式存在于水中的细菌和类似长度尺度的颗粒)。此外,为提高该装置的细菌分离效率,微器件的纯水通道在几个点处设计有环绕的三边薄膜阀装置,这有助于调节纯水通道的横截面积。连续地,纯水通道横截面积的减小导致了高效的Zweifach-Fung效应,这有助于更好地分离悬浮颗粒(细菌、灰尘颗粒)。观察到该装置在分离尺寸范围为1 - 10微米的悬浮微粒/微生物方面平均效率为99.6%。该装置的性能表明其在分离其他类似的悬浮杂质、小灰尘颗粒、细菌、真菌、病毒以及以悬浮形式存在于水中的类似颗粒方面的潜力。

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