离子液体在支撑液膜中的应用

简要叙述了利用离子液体作为膜液相来制备支撑液膜的方法,分析了影响支撑离子液体膜稳定性的主要因素.对支撑离子液体膜的应用情况做了详细综述,内容包括气体分离、有机混合物的分离以及化学反应等3个方面,并对其工业化前景进行展望.     

离子液体支撑液膜分离CO2的研究进展

总结了离子液体支撑液膜分离CO2的研究进展,简要分析了气体在离子液体支撑液膜中的传质机理;介绍了离子液体支撑液膜的制备方法及影响离子液体支撑液膜稳定性的因素;指出了今后用于分离CO2的离子液体支撑液膜的发展方向。     

离子液体支撑液膜技术及其在气体分离中的研究进展

分析离子液体支撑液膜的气体分离机理,总结目前离子液体支撑液膜的制备方法以及不同膜材料、不同离子液体及其亲疏水性对离子液体支撑液膜稳定性的影响。介绍离子液体支撑液膜在气体分离中的应用,对离子液体支撑液膜的工业化前景进行了展望。     

离子液体支撑液膜的研究及应用进展

回顾了目前为止离子液体支撑液膜的制备方法、离子液体结构、支撑膜结构对离子液体支撑液膜稳定性的影响因素,介绍了其在有机物分离、气体分离、分离反应耦合方面的应用。由于传统的单元操作很难满足污染和对过程集成的要求,对离子液体支撑液膜在未来实现清洁生产的发展方向进行了展望。     

离子液体支撑液膜的CO2/CH4分离性能

由于离子液体对CO₂具有较好的溶解选择性,离子液体支撑液膜分离CO₂越来越受到关注。比较了含3种不同阴离子的常规离子液体([bmim][BF₄]、[bmim][PF₆]、[bmim][Tf₂N])作为支撑液膜的液膜相分离CO₂/CH₄的性能,考察了咪唑环上烷基链长对离子液体支撑液膜性能的影响。考虑向离子液体中引入胺基和羧基等亲CO₂基团,制备了1-丁基-3-甲基咪唑丙氨酸离子液体([bmim][β-Ala]),考察了 [bmim][β-Ala]支撑液膜分离CO₂/CH₄的性能,并对在CO₂渗透测试前后的支撑液膜进行了FT-IR分析,发现氨基酸离子液体中的-NH₂和CO₂的较强作用以及该离子液体的高黏性影响了CO₂的透过性,使[Bmim][β-Ala]支撑液膜的CO₂透过率低。     

离子液体在膜分离过程中的应用研究进展

介绍了离子液体(ionic liquids)是由有机阳离子和有机或无机阴离子构成的、在室温或室温附近温度下呈液体状态的盐类,是新兴的可替代挥发性有机化合物的绿色溶剂。阐述了离子液体具有熔点低、不易燃、低挥发性(蒸气压接近于零)、高导电能力、电化学窗口宽、可调节性强等独特性质;在二氧化碳、二氧化硫等酸性气体以及苯、环己烷等有机溶剂分离过程中有广泛应用前景。同时,介绍了含有双键等可聚合基团的一类离子液体-聚离子液体[poly(ionic liquid)s,PILs]在二氧化碳吸收方面有特殊表现,指出聚离子液体与聚偏氟乙烯(PVDF)共混得到的薄膜材料具有高稳定性、高机械强度以及高电导率,对于缓解能源匮乏以及环境污染等具有重大意义。     

离子液体支撑液膜用于分离混合芳烃的研究

利用不同离子液体制备离子液体充填型支撑液膜,将其用于混合芳烃中对二甲苯的蒸汽渗透膜分离实验,比较了不同离子液体、不同支撑底膜、原料中对二甲苯的含量、操作温度等因素对分离性能的影响。结果表明,在40℃温度下,[Bmim][BF4]填充PVDF膜形成的支撑液膜对对二甲苯体积分数为60%的混合芳烃渗透通量为59.5 g/(m2·h),分离因子达16.5;经过90 h的实验测定,支撑液膜分离性能稳定。离子液体支撑液膜的蒸汽渗透过程能够实现从混合芳烃中将对二甲苯分离。     

离子液体支撑液膜用于分离混合芳烃的研究

利用不同离子液体制备离子液体"充填型"支撑液膜,将其用于混合芳烃中对二甲苯的蒸汽渗透膜分离实验,比较了不同离子液体、不同支撑底膜、原料中对二甲苯的含量、操作温度等因素对分离性能的影响。结果表明,在40℃温度下,[Bmim][BF4]填充PVDF膜形成的支撑液膜对对二甲苯体积分数为60%的混合芳烃渗透通量为59.5 g/(m2·h),分离因子达16.5;经过90 h的实验测定,支撑液膜分离性能稳定。离子液体支撑液膜的蒸汽渗透过程能够实现从混合芳烃中将对二甲苯分离。     

离子液体二氧化碳分离膜研究进展

离子液体支撑液膜在较大跨膜压差（0.25～0.3MPa）下的稳定性较差,具有较好稳定性的聚离子液体膜和离子液体-聚合物共混膜等逐渐被关注。本文综述了离子液体支撑液膜、聚离子液体膜、离子液体?聚合物共混膜等离子液体膜CO2分离性能、分离机理及稳定性的最新研究进展,介绍了无机颗粒-离子液体-聚合物共混膜的研究现状。指出离子液体膜的高CO2渗透通量与高稳定性之间的矛盾、共混膜结构调控难等问题是其工业化应用的主要障碍,提出开发新的膜材料、改进制膜工艺以减小膜厚、优化膜结构是提高膜的CO2渗透和分离性能,并保持膜稳定性的有效途径。无机颗粒-离子液体-聚合物共混膜兼有较高的CO2分离性能和较好稳定性,具有良好的应用前景,对其制备方法、结构、性能及CO2分离机理的研究将成为这一领域的热点。     

离子液体-中空纤维支撑液膜技术分离Cs／Mo研究

支撑液膜（SLM）发展迅速、应用前景广阔,在众多支撑液膜性能改进的研究中,采用离子液体（IL）代替传统有机溶剂,已在气体、有机物分离以及生物反应器方面有一定的进展。本实验采用疏水性聚丙烯中空纤维（HF）作支撑体,针对目标金属Cs离子选择杯冠化合物DB18C6作萃取剂,预选[Bmim][PR]、[Bmim][NTf2]和[Bmim][BF4]三种ILs作稀释剂制备膜体系,探索其在Cs／Mo分离中的应用潜力。结果表明,在本实验工艺条件下,使用[Bmim][PF6]成功制备了离子液体中空纤维支撑液膜体系（IL—HFSLM）,该液膜体系在料液流速低于5mL／min的条件下稳定存在,并可实现从含Mo溶液中回收超过80％的Cs。     

负载型离子液体催化剂在催化反应中的应用

负载型离子液体催化剂具有高催化活性、易于分离和环境友好型等特点。综述不同种类负载型离子液体催化剂在不同催化反应中的应用,并展望负载型离子液体催化剂在催化领域的发展方向。     

离子液体支撑膜分离GVOCs的研究进展

本文介绍了用于治理严重影响人类健康和生活环境的气态挥发性有机化合物(GVOCs)的传统分离方法,以及新兴的空气污染防治技术。重点阐述了离子液体膜分离GVOCs的研究现状及存在的不足,并对研究前景进行了展望。     

支撑液膜稳定性研究进展

分析了导致支撑液膜不稳定的因素及其机理。主要提出了近年来各国学者在改进支撑液膜稳定性方面所作的努力,包括对支撑液膜的结构、液膜相组成和制备工艺、膜支撑体以及膜组件改进等方面的工作。最后对支撑液膜的工业化前景进行了展望。     

Kinetic resolution of 1‐phenylethanol integrated with separation of substrates and products by a supported ionic liquid membrane

BACKGROUND: In the present study, the kinetic resolution of rac‐1‐phenylethanol by transesterification with several vinyl esters catalysed by a commercial immobilized Candida antarctica lipase B (Novozym 435) was carried out in n‐hexane at different water contents. The subtrates and products involved in the kinetic resolution were separated using a membrane bioreactor containing a supported liquid membrane based on the ionic liquid 1‐butyl‐3‐methylimidazolium tetrafluoroborate [bmim⁺][BF₄^?]. RESULTS: Variables affecting the kinetic resolution performance of the enzyme were studied. First, the influence of water content of the medium on the synthetic activity, selectivity and enantioselectivity of the enzyme was analysed in order to establish the optimal amount of water. The use of vinyl esters of different alkyl chain length (vinyl propionate, vinyl butyrate and vinyl laurate) as acyl donors to kinetic resolution was studied. Finally, the integrated reaction/separation process for the resolution of rac‐1‐phenylethanol was carried out in the optimal conditions found. CONCLUSION: These investigations demonstrate that the coupling of lipase enantioselectivity with the selective separation of supported liquid membranes based on ionic liquids provides a promising basis for practical production of enantiomerically pure or enriched compounds. Copyright © 2008 Society of Chemical Industry     

Understanding the influence of the ionic liquid composition and the surrounding phase nature on the stability of supported ionic liquid membranes

The industrial application of supported liquid membranes (SLMs) is still limited due to concerns about their stability. In a previous work, the selective separation of the substrates and products of a transesterification reaction was successfully carried out using Nylon membranes impregnated with ionic liquids (ILs). This article analyses the effect of both the IL composition and the nature of the surrounding phase on the stability of these SLMs to design highly stable supported ionic liquid systems. For this purpose, the stability of SLMs based on several ILs after immersion for a week in different feed/receiving phases was characterized using scanning electron microscopy combined with energy dispersive X‐ray (SEM‐EDX). The differential migration of the ILs observed from the membrane toward the surrounding phases was found to be correlated with the solubility of the ILs in the contacting phases. It was observed that SLM stability increased as the polarity of the solvent used as receiving phase decreased and as the hydrophilic character of the ILs used as liquid phase increased. Furthermore, the polymeric support was found to have a strongly stabilizing effect because losses of IL after immersion in a given surrounding phase were much lower than that derived from the solubility of the IL in this phase. © 2011 American Institute of Chemical Engineers AIChE J, 2012