Multiscale calculation results of the flow behavior in micro/nano porous filtration membrane with the adsorbed layer-fluid interfacial slippage

IF 0.8 4区 工程技术 Q4 ENGINEERING, CHEMICAL Membrane Water Treatment Pub Date : 2021-05-01 DOI:10.12989/MWT.2021.12.3.107
Jian Li, Yongbin Zhang
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Abstract

The paper presents the multiscale calculation results for the multiscale flow in micro/nano porous filtration membranes where the adsorbed layer effect is involved, by considering the adsorbed layer-fluid interfacial slippage. The analysis consists of the molecular scale analysis for the adsorbed layer flow and the continuum analysis for the intermediate fluid flow. The calculation results are respectively compared with the classical flow theory calculations and those based on the solid layer assumption. The adsorbed layer flow rate is also compared with the flow rate of the intermediate continuum fluid. It is shown that for a strong fluid-pore wall interaction or for a large adsorbed layer-fluid interfacial slippage the adsorbed layer can be treated as a solid layer; otherwise it should be treated as a flowing layer. The large interfacial slippage results in the flow rate through the pore far greater than the classical Hagen-Poiseuille equation calculation; it largely propels the flow of the intermediate continuum fluid and makes the adsorbed layer flow negligible particularly for the medium and strong fluid-pore wall interactions. The increasing fluid-pore wall interaction strength significantly reduces the flow rate through the pore.
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吸附层-液界面滑移时微纳多孔过滤膜内流动特性的多尺度计算结果
本文通过考虑吸附层-流体界面滑移,给出了涉及吸附层效应的微/纳米多孔滤膜中多尺度流动的多尺度计算结果。分析包括吸附层流动的分子尺度分析和中间流体流动的连续体分析。计算结果分别与经典流动理论计算和基于固体层假设的计算结果进行了比较。还将吸附层的流速与中间连续体流体的流速进行比较。研究表明,对于较强的流体-孔壁相互作用或较大的吸附层-流体界面滑移,吸附层可以被视为固体层;否则应将其视为流动层。大的界面滑移导致通过孔隙的流速远大于经典的Hagen-Poiseuille方程计算;它在很大程度上推动了中间连续流体的流动,并使吸附层的流动可以忽略不计,特别是对于中等和强流体-孔壁相互作用。流体-孔隙-壁相互作用强度的增加显著降低了通过孔隙的流速。
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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来源期刊
Membrane Water Treatment
Membrane Water Treatment ENGINEERING, CHEMICAL-WATER RESOURCES
CiteScore
1.90
自引率
30.00%
发文量
0
审稿时长
>12 weeks
期刊介绍: The Membrane and Water Treatment(MWT), An International Journal, aims at opening an access to the valuable source of technical information and providing an excellent publication channel for the global community of researchers in Membrane and Water Treatment related area. Specific emphasis of the journal may include but not limited to; the engineering and scientific aspects of understanding the basic mechanisms and applying membranes for water and waste water treatment, such as transport phenomena, surface characteristics, fouling, scaling, desalination, membrane bioreactors, water reuse, and system optimization.
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