不同溶剂对聚醚砜酮基炭膜结构及气体分离性能的影响

为考察不同溶剂对聚醚砜酮(PPESK)炭膜结构和性能的影响,以PPESK为前驱体,分别以NMP,CHCl3,C2H2Cl4,DMAc为溶剂制备气体分离炭膜。并采用红外光谱、热重分析、X射线衍射和气体渗透等测试手段对所制膜的化学结构、炭膜的微结构和气体的分离性能进行了表征。结果表明,溶剂的溶度参数、沸点、挥发性以及原膜中溶剂的含量等导致所制备聚合物膜形成不同的化学结构,改变它在预氧化和炭化过程的结构变化规律,使形成炭膜表现出不同的炭结构、孔隙结构和表观柔韧性,最终影响炭膜的气体渗透性和分离选择性。     

聚酰亚胺碳分子筛气体分离膜的研究进展

聚酰亚胺碳分子筛膜由于具有较高的热稳定性、耐化学性、气体渗透性和选择性,而受到广泛关注。根据近年来聚酰亚胺碳分子筛膜在气体分离方面的研究现状,详细介绍了填充改性、对前驱体进行预处理和聚酰亚胺单体改性的研究成果,并展望了聚酰亚胺碳分子筛分离膜的发展趋势,以期为未来高效分离膜的研发提供参考。     

密胺苯二醛多孔聚合物/聚二甲基硅氧烷混合基质膜的制备及气体分离性能

以溶液复合成膜法制备了密胺苯二醛多孔聚合物(MA)/聚二甲基硅氧烷(PDMS)混合基质膜,利用扫描电镜(SEM)表征了混合基质膜的形貌。考察了不同MA用量下MA/PDMS混合基质膜的气体分离性能,结果表明,MA的加入可以在提高PDMS膜渗透系数的同时提高CO_2气体分离选择性;随着混合基质膜中MA含量的增加,混合基质膜的渗透系数均明显提高,气体分离选择性则先增大后减小。双组分混合气体分离测试结果表明,MA/PDMS(1.2%(w,质量分数))混合基质膜对CO_2/N_2和CO_2/CH_4的分离选择性分别是19.2和6.0,CO_2的渗透系数达到8100Barrer,均高于纯PDMS膜。MA/PDMS(1.2%(w))混合基质膜对CO_2/N_2混合气的分离性能突破了Robeson上限。     

抗溶胀型聚酰亚胺气体分离膜的制备及其研究进展

膜分离技术具有绿色、高效、低能耗等特点.聚酰亚胺膜具有优异的气体分离性能及机械性能,但在分离高压天然气及生物气时,聚酰亚胺膜易被CO2溶胀塑化,导致膜的选择性下降.近年来,已经报道了多种可用于提高聚酰亚胺膜抗溶胀的技术.本文介绍了由于CO2渗透引起的聚合物膜塑化机理,并详述了热退火、热交联、化学交联、热重排、与纳米材料共混及与聚合物共混等用于抑制聚酰亚胺膜塑化的方法,提出了用于天然气及生物气分离的膜材料,未来的主要研究方向是开发同时具备高气体渗透性及高抗CO2塑化的聚酰亚胺膜材料.     

二氧化钛纳米粒子-氧化石墨烯/聚酰亚胺混合基质膜的原位聚合及气体渗透性能

以钛酸四丁酯为前驱体,采用浸渍-沉淀法制备二氧化钛纳米粒子-氧化石墨烯(TiO_2-GO)复合物,再将TiO_2-GO复合物与4,4'-(六氟异亚丙基)邻苯二甲酸酐和4,4'-二氨基二苯醚通过原位聚合构建TiO_2-GO/TiO_2-GO/PI(聚酰亚胺)混合基质膜,用于CO_2的渗透脱除.采用傅里叶变换红外光谱(FTIR)、拉曼光谱(Raman)、透射电子显微镜(TEM)、扫描电子显微镜(SEM)、热失重(TG)和Zeta电位等表征了TiO_2-GO复合物和TiO_2-GO/PI混合基质膜的形貌与结构;探讨了TiO_2掺杂量对TiO_2-GO复合物及TiO_2-GO/PI混合基质膜的结构和气体渗透性能的影响.结果表明,TiO_2-GO复合物中TiO_2纳米粒子较均匀地沉积在GO片层上,TiO_2纳米粒子在形成的同时破坏了GO的结构,使其无序度增加.TiO_2的掺杂对TiO_2-GO/PI混合基质膜的形貌与结构影响较小,但提升了TiO_2-GO/PI混合基质膜的CO_2和N2渗透性能.但过量的掺杂使TiO_2粒子在GO片层上团聚,从而导致TiO_2-GO复合物在混合基质膜中的分散性变差,CO_2渗透性及CO_2/N2渗透选择性降低.当TiO_2掺杂质量分数为30%时,TiO_2-GO/PI混合基质膜的CO_2渗透性为360 Barrer[1 Barrer=10~(-10)cm~3(STP)·cm/(cm~2·s·cm Hg)=7.5×10~(-14)cm~3(STP)·cm/(cm~2·s·Pa)],CO_2/N_2的渗透选择性可达31.     

分子结构对聚酰亚胺膜分离CO_2/CH_4性能的影响

气体在致密高分子膜中的渗透过程与高分子的链段活动性和自由体积有关,高分子的链段活动性越大,气体的扩散越容易,气体的透过速度越快,高分子自由体积增大,气体的溶解系数增大,扩散速率加快,透气速率上升．因此,为了得到高选择性和高透气性的分离膜,可对其化学结...     

含聚醚链段聚酰亚胺膜的制备及气体分离性能

利用均苯四甲酸二酐（PMDA）与4,4’-二氨基二苯醚（ODA）和聚醚胺（PPO, Mn～2000）共聚合,合成聚酰胺酸前驱体,经热处理得到一系列含PPO链段的聚酰亚胺薄膜.研究了PPO链段的引入对薄膜结构及气体分离性能的影响.结果表明,在芳香族聚酰亚胺中引入柔性链段PPO有利于气体分子的传输.得益于PPO链段在分离膜内部形成的微相分离结构,气体分子在分离膜内的扩散系数随PPO含量的增加显著提升.当PPO含量为65 wt%时,PPO链段在分离膜内仍呈现非晶相,CO₂渗透系数高达131.61 Barrer,比PMDA/ODA均聚聚酰亚胺薄膜提高22倍.同时,得益于聚醚链段对CO₂独特的亲和作用,随着PPO含量的提高,分离膜对CO₂/N₂的分离系数由18.77提高至30.12.结果表明PPO链段的引入对于调控聚酰亚胺膜的结构和气体分离性能具有重要作用.     

由聚合物结构预测气体的透过性能

本文利用基团加和法,对20多种常见聚合物的自由体积和内聚能进行了计算。发现氧气和氮气在聚合物膜中的透过率与自由体积和内聚能的比值有直接关系。此比值越大,气体的透过率越大,透过率的对数与自由体积和内聚能的比值基本呈线性关系。据此,对未知聚合物可根据其化学结构,从已有的基团数据计算该比值,从而预测它对氧气和氮气的透过性能。     

含四芳基咪唑结构的热重排气体分离膜的制备与性能研究

合成了一种新型含四芳基咪唑结构的二胺单体4,4’-(4,5-二苯基-(3-羟基-4-氨基苯氧基)苯基)咪唑(PMAPPP),然后分别与5种二酐单体聚合,经热酰亚胺化处理得到含羟基聚酰亚胺(HPI)薄膜.接着,对这些薄膜进行450℃热处理,得到相应的热重排(TR)膜材料,并对薄膜进行了结构与性能表征.结果表明,刚性大体积四芳基咪唑结构的引入使HPI膜表现出优异的热性能和力学性能,玻璃化转变温度在263～361℃,拉伸强度在98.4～118.3 MPa.热重排后,TR膜的气体分离性能得到了显著提高.其中,TR(PMAPPP-6FDA)的气体渗透性能最佳,即H₂ (269.31 Barrer)、CO₂ (284.25 Barrer)、O₂ (62.75 Barrer)和N₂(10.67 Barrer),CO₂/N₂和O₂/N₂的理想选择性分别为25.24和5.88,且O₂/N₂     

聚酰亚胺气体分离膜的进展

本文叙述了近年来聚酰亚胺气体分离膜的发展概况。讨论了聚合物结构、共聚改性、交联改性和成膜历史对聚酰亚胺透气性能的影响。脂环族聚酰亚胺和六氟二酐(6FDA)型聚酰亚胺兼具有高透气性和高透气选择性,是一类具有发展前途的气体分离膜材料。     

Structure and properties relationships for aromatic polyimides and their derived carbon membranes: experimental and simulation approaches

The main objective of this study is to investigate the factors of the chemical structure and physical properties of rigid polyimides in determining the performance of derived carbon membranes through both the experimental and simulation methods. Four polyimides made of different dianhydrides were pyrolyzed at 550 and 800 degrees C under vacuum conditions. The resultant carbon membranes exhibit excellent gas separation performances beyond the traditional upper limit line for polymer membranes. The thermal stability and the fractional free volume (FFV) of polyimides were examined by a thermogravimetric analyzer and a density meter. The chain properties of polyimide, such as flatness, chain linearity, and mobility, were simulated using the Cerius(2) software. All above characterizations of polyimides were related to the microstructure and gas transport properties of the resultant carbon membranes. It was observed that the high FFV values and low thermal stability of polyimide produce carbon membranes with bigger pore and higher gas permeability at low pyrolysis temperatures. Therefore, polyimides with big thermally labile side groups should be preferred to prepare carbon membranes at low pyrolysis temperatures for high permeability applications. On the other side, since the flatness and in-plane orientation of precursors may lead carbon membranes to ordered structure, thus obtaining high gas selectivity, linear polyimides with more coplanar aromatic rings should be first choice to prepare carbon membranes at high pyrolysis temperatures for high selectivity applications. The location of the indan group also affects chain flatness and in-plane orientation. As a result, carbon membranes derived from the BTDA-DAI precursor have superior separation performance to those derived from Matrimid.     

Transport properties of polyimides derived from benzophenonetetracarboxylic dianhydride and other diamines

Gas-separating membrane characteristics of polyimide films composed of the common fragment of benzophenone-3,3′,4,4′-tetracarboxylic dianhydride and diamines of varying structure were studied. Permeability coefficient P, diffusion coefficient D, and solubility coefficient S for H₂, CO, CO₂, and CH₄ were determined. The polyimide derived from m-phenylenediamine exhibited the best gas-separating properties. A relationship between the chain rigidity, free volume, and transport parameters (P, D, S, and selectivity) of polyimide was established on the basis of the data. It was shown that there is an optimal chain rigidity for the studied polyimides that results in polymer structurization during film preparation and corresponds to high separation selectivity.     

共聚聚酰亚胺膜材料的合成及其气体渗透性能研究

以2,2′-双(3,4-二羧基苯基)六氟丙烷二酐(6FDA)作为二酐单体,1,3-苯二胺(mPDA)和2,6-二氨基甲苯(2,6-DAT)为二胺单体,采用溶液共缩聚方法合成了一系列新型共聚聚酰亚胺(6FDA-2,6-DAT/mPDA),该类聚合物均能溶于DMF、DMAc、NMP等极性非质子溶剂中,具有较好的成膜性.测试了H2、N2、O2、CH4、CO25种气体在6FDA-2,6-DAT/mPDA共聚聚酰亚胺致密膜中的渗透性能.结果显示,该系列共聚物具有优异的分离性能.在35℃,0.2 MPa下,H2/N2、O2/N2、CO2/CH4的分离性能均接近或突破Robeson上限.     

Synthesis,characterization, and evaluation of novel polyhydantoins as gas separation membranes

Novel polyhydantoins ( PHYs ) were synthesized from original aromatic diisocyanates and bisiminoacetates by a two‐step polycondensation procedure, which involved the cyclization of polyurea intermediates promoted by acid catalysis. The physical properties of the novel PHYs were evaluated by comparing them with a classical PHY derived from 4,4′‐methylenediphenyl diisocyanate. All PHYs were soluble and could be processed into dense films, which showed good mechanical properties (tensile strength up to 110 MPa) and thermal stability of >400 °C. High glass transition temperatures (T_gs), ranging from 260 to 410 °C, were observed. Fractional free volume (FFV) was strongly dependent on the chemical structure, and a linear correlation between gas permeability and FFV of PHYs could be found. The gas separation properties were comparable to those of the commercial polyimide Matrimid^®, with the exception of one of the PHYs which exhibited very promising properties as its gas productivity was comparable to the gas separation performance of well‐established experimental polyimides. © 2013 Wiley Periodicals, Inc. J. Polym. Sci., Part A: Polym. Chem. 2013 , 51, 4052–4060     

Gas transport properties of hyperbranched polyimide/hydroxy polyimide blend membranes

Gas transport properties of novel hyperbranched polyimide/hydroxy polyimide blends and their silica hybrid membranes were investigated. Gas permeability coefficients of the blend membranes showed positive deviation from a semilogarithmic additive rule. The enhanced gas permeability were resulted from the increase in free volume elements caused by the intermolecular interaction between terminal amine groups of the hyperbranched polyimide and hydroxyl groups of the hydroxy polyimide backbone. Additionally, CO₂/CH₄ separation ability of the blend membranes was markedly promoted by hybridization with silica. The remarkable CO₂/CH₄ separation behavior was considered to be due to characteristic distribution and interconnectivity of free volume elements created by the incorporation of silica. For the hyperbranched polyimide/hydroxy polyimide blend system, polymer blending and hybridization techniques synergistically provided the excellent CO₂/CH₄ separation ability.     

6FDA-containing polyimide-ionene + ionic liquid gas separation membranes

Polyimides (PI) synthesized from 4,4′-(hexafluoroisopropylidene)diphthalic anhydride (6FDA) with various diamines have been frequently studied as gas separation membranes. The use of 6FDA in polyimides creates a bent structure than can increase fractional free volume (FFV) and gas permeability. Here, we demonstrate that 6FDA is also a useful building block for PI-ionene materials, which contain cations directly within the polymer backbone. These new 6FDA-containing PI-ionenes were combined with several different imidazolium ionic liquids (ILs) to form thin membranes. The thermal properties of all the derivatives were investigated to determine the relationship between regiochemistry and degradation as well as the intermolecular forces that are present within these structures. The gas separation properties of these 6FDA-containing PI-ionene + IL materials were investigated, showing modest CO₂ permeabilities similar to other polyimide-ionenes and CO₂/CH₄ and CO₂/N₂ permselectivities that were relatively higher than other polyimide-ionenes.     

含叔丁基聚酰亚胺均质膜的气体分离性能

采用高温“一步法”缩聚合成了一系列含叔丁基的可溶性芳香聚酰亚胺树脂, 然后通过溶液浇注法制得相应均质薄膜, 并对其气体分离性能进行了测试, 同时研究了二酐结构和温度对聚酰亚胺均质膜气体分离性能的影响. 结果表明, 对于H₂, N₂, O₂, CO₂和CH₄ 等5种气体, 含叔丁基聚酰亚胺均质膜不仅表现出良好的透气性, 而且具有较高的气体透过选择性, 4,4'-(六氟异丙烯)二酞酸酐(6FDA)和均苯四甲酸二酐(PMDA)两类聚酰亚胺均质膜的气体分离性能最佳. 除CO₂外, 这两类聚酰亚胺均质膜的气体渗透系数随温度升高而升高, 而所有测试气体在这两种均质膜中的扩散系数和溶解度系数均随温度升高而增大.     

Tuning microcavities in thermally rearranged polymer membranes for CO2 capture

Microporous materials have a great importance in catalysis, delivery, storage and separation in terms of their performance and efficiency. Most microporous materials are comprised of inorganic frameworks, while thermally rearranged (TR) polymers are a microporous organic polymer which is tuned to optimize the cavity sizes and distribution for difficult separation applications. The sub-nano sized microcavities are controlled by in situ thermal treatment conditions which have been investigated by positron annihilation lifetime spectroscopy (PALS). The size and relative number of cavities increased from room temperature to 230 °C resulting in improvements in both permeabilities and selectivities for H(2)/CO(2) separation due to the significant increase of gas diffusion and decrease of CO(2) solubility. The highest performance of the well-tuned TR-polymer membrane was 206 Barrer for H(2) permeability and 6.2 of H(2)/CO(2) selectivity, exceeding the polymeric upper bound for gas separation membranes.     

Influence of conformational rigidity on membrane properties of polyimides

Several polyimides were studied with regard to the influence of their conformational rigidity on the packing in glassy state, and consequently on their physical properties such as glass transition temperature and selectivity of gas separation membranes made from these polymers. The values of their physical properties were taken from literature, while the conformational rigidity parameters such as Kuhn segment, characteristic ratio, and occupied, free, and accessible volumes were calculated here and were correlated with physical properties. It was shown that there are correlations between selectivity of gas separation membranes made from these polyimides on one hand, and characteristic ratio, on another hand.