超酸催化的三庚烯基聚合物可提高用于挥发性有机化合物氮分子筛分的膜渗透性

Yuan Gao , Zhihao Huang , Wenyue Lv , Hua Zhang , Yuanqing Ye , Rongfei Zhou , Huiyun Liao , Haoli Zhou , Wanqin Jin
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引用次数: 0

摘要

超酸催化因其简便的聚合程序而成为合成膜材料的一种合适方法,已被广泛研究。然而,超酸催化的二元共面聚合物膜通常表现出较低的渗透性。在本研究中,通过三氟苯乙酮和二苯醚对三庚烯进行超酸催化,合成了一种刚性三维三庚烯基聚合物,以提高挥发性有机化合物(VOC)分子筛氮的膜渗透性。利用不同的特性研究了含有(CF3PhET)或不含三庚烯(CF3PhE)的聚合物的合成。根据对分子量、成膜性能和分离性能的分析,对合成聚合物中的三庚烯含量进行了优化。比较了使用 CF3PhE、CF3PhET 以及 CF3PhE 和三庚烯混合物制造的膜的分离性能。结果表明,在 1 升/(平方米/分钟)的条件下分离 3 摩尔%的氮气/环己烷混合物时,在膜中引入非共面三庚烯可使自由体积增大,从而使渗透性提高近 60 倍,从 CF3PhE 膜的 30 巴勒提高到三庚烯含量为 5 摩尔%的膜的 1755 巴勒。此外,排斥率保持不变,这为利用超酸催化合成高性能膜材料提供了有效的思路。
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Superacid catalyzed triptycene-based polymer to enhance membrane permeability for molecular sieving of nitrogen over VOC

Superacid catalysis, a suitable method for the synthesis of membrane materials owing to its facile polymerization procedure, has been extensively studied. However, superacid-catalyzed binary coplanar polymer membranes generally exhibit low permeabilities. In this study, a rigid 3D triptycene-based polymer was synthesized by the superacid catalysis of triptycene with trifluoroacetophenone and diphenyl ether to enhance membrane permeability for the molecular sieving of nitrogen over volatile organic compound (VOC). The synthesis of polymers with (CF3PhET) or without triptycene (CF3PhE) was investigated using different characterizations. The triptycene content of the synthesized polymers was optimized based on an analysis of the molecular weight, membrane-forming properties, and separation performance. The separation performances of membranes fabricated using CF3PhE, CF3PhET, and a mixture of CF3PhE and triptycene were compared. Results showed that the introduction of non-coplanar triptycene in the membrane can increase permeability by nearly 60 times due to the enhanced free volume, from 30 Barrer for the CF3PhE membrane to 1755 Barrer for the membrane with 5 ​mol% triptycene content for the separation of a 3 ​mol% nitrogen/cyclohexane mixture at 1 ​L/(m2·min). Furthermore, the rejection remains constant, which provides an effective idea for the synthesis of membrane materials with high performance using superacid catalysis.

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