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反渗透系统中的二氧化硅污垢——小角中子散射研究

Silica Fouling in Reverse Osmosis Systems- Small-Angle Neutron Scattering Studies.

作者信息

Pipich Vitaliy, Starc Thomas, Buitenhuis Johan, Kasher Roni, Petry Winfried, Oren Yoram, Schwahn Dietmar

机构信息

Jülich Centre for Neutron Science JCNS-FRM II, Outstation at FRM II, Lichtenbergstr. 1, D-85747 Garching, Germany.

JCNS-1/IBI-8: Neutron Scattering and Soft Matter, Forschungszentrum Jülich GmbH, D-52425 Jülich, Germany.

出版信息

Membranes (Basel). 2021 May 30;11(6):413. doi: 10.3390/membranes11060413.

DOI:10.3390/membranes11060413
PMID:34070912
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8230220/
Abstract

We present operando small-angle neutron scattering (SANS) experiments on silica fouling at two reverse osmose (RO) membranes under almost realistic conditions of practiced RO desalination technique. To its realization, two cells were designed for pressure fields and tangential feed cross-flows up to 50 bar and 36 L/h, one cell equipped with the membrane and the other one as an empty cell to measure the feed solution in parallel far from the membrane. We studied several aqueous silica dispersions combining the parameters of colloidal radius, volume fraction, and ionic strength. A relevant result is the observation of Bragg diffraction as part of the SANS scattering pattern, representing a crystalline cake layer of simple cubic lattice structure. Other relevant parameters are silica colloidal size and volume fraction far from and above the membrane, as well as the lattice parameter of the silica cake layer, its volume fraction, thickness, and porosity in comparison with the corresponding permeate flux. The experiments show that the formation of cake layer depends to a large extent on colloidal size, ionic strength and cross-flow. Cake layer formation proved to be a reversible process, which could be dissolved at larger cross-flow. Only in one case we observed an irreversible cake layer formation showing the characteristics of an unstable phase transition. We likewise observed enhanced silica concentration and/or cake formation above the membrane, giving indication of a first order liquid-solid phase transformation.

摘要

我们展示了在接近实际反渗透(RO)脱盐技术条件下,对两种RO膜上二氧化硅污垢进行的原位小角中子散射(SANS)实验。为实现这一目标,设计了两个用于压力场和切向进料错流的实验池,压力可达50巴,切向进料错流速率可达36升/小时,一个实验池装有膜,另一个为空池,用于在远离膜的位置并行测量进料溶液。我们研究了几种结合了胶体半径、体积分数和离子强度参数的二氧化硅水分散体。一个相关结果是在SANS散射图案中观察到布拉格衍射,这代表了具有简单立方晶格结构的结晶滤饼层。其他相关参数包括膜附近及膜上方的二氧化硅胶体尺寸和体积分数,以及二氧化硅滤饼层的晶格参数、其体积分数、厚度和孔隙率,并与相应的渗透通量进行比较。实验表明,滤饼层的形成在很大程度上取决于胶体尺寸、离子强度和错流。滤饼层的形成被证明是一个可逆过程,在较大错流时可以溶解。仅在一种情况下,我们观察到不可逆的滤饼层形成,表现出不稳定相变的特征。我们同样观察到膜上方二氧化硅浓度增加和/或滤饼形成,这表明发生了一级液 - 固相变。

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