The role of skin layer defects in organic solvent reverse osmosis membranes

IF 4.9 Q1 ENGINEERING, CHEMICAL Journal of Membrane Science Letters Pub Date : 2021-12-05 DOI:10.1016/j.memlet.2021.100004
Hye Youn Jang, Ryan P. Lively
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Abstract

The fractionation of complex liquid hydrocarbon mixtures is an important and emerging area of membrane science. Polymeric asymmetric hollow fiber membranes have the potential to be used for this purpose, especially if the size and number of defects in the membrane skin layer can be precisely engineered. Here, we fabricated various “defect-engineered” Torlon hollow fiber membranes by modifying hollow fiber spinning conditions and spin dopes to study the role of skin layer defects in the organic solvent reverse osmosis (OSRO) membranes. The quality of the membranes was investigated using several sets of pure gas permeation experiments, which provided input data for a permeation resistance model that estimates the pore size and surface porosity of the asymmetric hollow fiber membrane. We develop and experimentally validate a resistance permeation model for solvent permeation and utilize the surface properties derived from the gas permeation experiments to estimate the relative permeation rates of solvents in a mixture. The approach outlined here highlights the interconnection between gas permeation analysis and OSRO separation performance using Torlon hollow fiber membranes as an exemplar test case. The solvent permeation model is then utilized to provide quantitative insight on the differences between OSRO and organic solvent nanofiltration (OSN), and highlight the important transition region between these two modalities.

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皮肤层缺陷在有机溶剂反渗透膜中的作用
复杂液态烃混合物的分馏是膜科学的一个重要的新兴领域。聚合物不对称中空纤维膜具有用于这一目的的潜力,特别是如果可以精确地设计膜表皮层中缺陷的大小和数量。本文通过改变中空纤维纺丝条件和纺丝掺杂,制备了各种“缺陷工程”的Torlon中空纤维膜,研究了皮层缺陷在有机溶剂反渗透(OSRO)膜中的作用。通过几组纯气体渗透实验对膜的质量进行了研究,为估计不对称中空纤维膜的孔径和表面孔隙率的渗透阻力模型提供了输入数据。我们开发并实验验证了溶剂渗透的阻力模型,并利用气体渗透实验得出的表面性质来估计混合物中溶剂的相对渗透速率。本文概述的方法强调了气体渗透分析与OSRO分离性能之间的联系,并以Torlon中空纤维膜为例进行了测试。然后利用溶剂渗透模型对OSRO和有机溶剂纳滤(OSN)之间的差异进行定量分析,并突出这两种模式之间的重要过渡区域。
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