甲基取代的聚芳醚酮酮酰亚胺树脂的合成与性能

N,N′-(4,4′-二苯甲烷)-二偏苯三甲酰亚胺酰氯(DIDC-M)与4,4′-二(2-甲基-苯氧基)三苯二酮(o-Me-DPOTPDK) 进行低温溶液共缩聚,制备了甲基侧基取代的聚芳醚酮酮酰亚胺(o-Me-PEKKI)聚合物.用FT-IR,1H-NMR,DSC,TG 和WAXD对聚合物的结构和性能进行了表征.研究表明:聚合物为非晶态结构;具有较高的玻璃化转变温度(Tg:241 ℃)和较好的耐热性能(Td:487 ℃);能溶解于间甲酚、NMP、氯仿、四氯乙烷等有机溶剂中.     

共聚型全芳香聚酰胺的合成及其与聚酰亚胺的复合改性

以对苯二甲酰氯、间苯二甲酰氯和间苯二胺为单体,采用低温溶液缩聚的方法,合成了一系列共聚型全芳香聚酰胺。利用凝胶渗透色谱(GPC)、~1H NMR和傅立叶红外光谱(FT-IR)对所得聚合物的相对分子质量和结构进行了表征确认,并通过热重分析(TGA)、差示扫描量热(DSC)对所得聚合物的热稳定性和玻璃化转变温度进行了分析。结果显示,所得产物的相对分子质量超过10×10~4 g/mol,其共聚单体比例符合预期,玻璃化转变温度处于277～313℃范围内。此外,全芳香聚酰胺与聚酰亚胺共混改性的初步研究结果证实,共混可以显著提高聚酰亚胺材料的弯曲性能。     

侧链含邻苯二甲酰亚胺的聚酰亚胺液晶垂直取向剂的制备与表征

以邻苯二甲酰亚胺和溴代正辛烷为原料,合成了功能性二胺单体N-辛基-4(3,5-二氨基苯甲酰基)-氨基邻苯二甲酰亚胺(D8).用此单体与3,3’-二甲基-4,4’-二氨基二苯甲烷(DMMDA)、3,3’,4,4’-二苯醚四甲酸二酐(ODPA)共缩聚,采用低温缩聚-化学亚胺化方法,通过调节共聚物组成制备了5种聚酰亚胺(PI).利用FTIR、NMR、UV-Vis与DSC等手段对合成的二胺单体及聚酰亚胺进行了结构表征和性能测试;研究了其摩擦取向性能、透光性能、溶解性能和耐热性能.结果表明,5种聚酰亚胺均可溶于常见极性溶剂,如NMP、THF等;随着D8含量的增加,PI膜对液晶分子取向时的预倾角逐渐增大至垂直,当D8含量大于20%,且经过5次摩擦后,预倾角仍能保持在89°以上.此外实验所得PI透过率大于80%,玻璃化转变温度在260℃以上.     

一种新型聚酰亚胺离子型共聚物的合成与表征

以过氧化氢为氧化剂,在三氟乙酸中对2,6-二氯吡啶进行氧化,制备了2,6-二氯吡啶氮氧化物,该单体与4,4′-二巯基二苯砜、3,3′-二甲基-双(4-氯代酰亚胺)-4,4′-二苯甲烷(4-BCPI)通过亲核取代反应生成了含有离子基团的聚酰亚胺。采用红外分析(FT-IR)、黏度测试、溶解度实验、热失重分析(TGA)和示差扫描量热分析(DSC)等测试方法,对所合成的聚酰亚胺的结构与性能进行了表征。测试结果表明:该类聚酰亚胺在室温下不仅可溶于常用的极性非质子有机溶剂,也能溶于氯仿、吡啶等溶剂。此外,10%热失重温度高于430℃,玻璃化转变温度高于210℃。     

一类含萘环结构的聚酯酰亚胺液晶聚合物的结构与性能研究

利用Higashi芳香聚酯直接缩聚法的原理,采用分步投料的方法,以N,N′-1,6-亚己基-双苯偏三酸酰亚胺二酸(IA6)、6-羟基-乙-萘甲酸(HNA)和4,4′-二羟基二苯酮(DHBP)为单体原料,合成了一系列聚酯酰亚胺共聚物.用核磁共振(NMR)、差热分析(DSC)、偏光显微镜(PLM)、广角X射线衍射(WAXD)、热重分析(TGA)等手段对所合成的聚酯酰亚胺的液晶行为、结构以及热性能进行了表征.研究结果表明,当HNA投料量占单体总投料量高于33mol%时,所得聚合物均呈明显的向列型热致液晶特性.但是,此类液晶聚合物仅在升温过程中出现液晶的相转变,而在降温过程中并未观察到液晶的相转变行为.由DSC结果分析可知,此类聚合物具有较高的玻璃化转变温度(Tg)和较低的熔融温度(Tm),有望成为一类既具有较低加工温度又有较高使用温度的液晶聚合物材料.     

以2-苯基-4,4'-二氨基二苯醚为基础的热固性聚酰亚胺树脂及其复合材料

以2-苯基-4,4'-二氨基二苯醚(p-ODA)、异构二苯醚二酐(ODPA)和苯乙炔基苯酐(PEPA)为原料,通过两步法合成了聚合度分别为1,2和3的酰亚胺树脂低聚物,并通过模压成型法制备了单向碳纤维增强的聚酰亚胺复合材料.表征了酰亚胺树脂低聚物的溶解性、熔体黏度及其固化物聚酰亚胺树脂的热性能,结果表明,聚酰亚胺树脂具有良好的溶解性,在N,N-二甲基乙酰胺(DMAc)、四氢呋喃(THF)及1,4-二氧六环等溶剂中的溶解度大于30%;所有酰亚胺树脂低聚物的最低熔体黏度均在10 Pa·s以下,具有良好的成型工艺性;聚酰亚胺树脂具有良好的热性能,玻璃化转变温度(Tg)最高可达300℃,5%热失重温度(T5%)最高可达545℃,碳纤维增强聚酰亚胺复合材料PIC-4,4'-ODPA-2具有最佳的高低温力学性能.     

A_2和B_3单体重氮偶合反应制备超支化偶氮聚合物

利用A2/B3单体通过重氮偶合反应制备了超支化偶氮聚合物.利用核磁共振、红外光谱、紫外光谱和DSC热分析手段表征了聚合物的结构、光谱性能和玻璃化转变温度.合成的超支化偶氮聚合物具有很好的光响应性能,用488nm Ar+激光对超支化偶氮聚合物薄膜进行光加工,得到了规则的表面起伏光栅.     

有机可溶性高折射率聚酰胺酰亚胺的合成与性能

采用含硫二胺1,4-双(4-氨基苯硫基)苯(2SPDA)与偏苯三酸酐反应制备了一种含硫二酸化合物1,4-双(4-三甲酰亚胺基苯硫基)苯(BTPB).以此二酸为原料与两种高硫含量二胺单体,4,4′-双(4-氨基苯硫基)二苯硫醚(3SDA)以及2,7-双(4-氨基苯硫基)噻蒽(APTT)通过高温缩聚法制备了两种聚酰胺酰亚胺(PAI).制备的PAI在室温下可溶解于N-甲基-2-吡咯烷酮(NMP)中.PAI薄膜的起始热分解温度(T5%)超过440℃,玻璃化转变温度(Tg)大于190℃.PAI薄膜在波长大于500nm的可见光区具有良好的透明性.此外,PAI薄膜的折射率大于1.73,双折射小于0.04.     

空心玻璃微珠复合聚酰亚胺泡沫的泡孔结构与性能

通过填充空心玻璃微珠,采用预聚法制备了空心玻璃微珠复合聚酰亚胺泡沫,研究了空心玻璃微珠填充量对复合聚酰亚胺泡沫的泡孔结构、热性能和压缩性能的影响规律。结果表明,随着空心玻璃微珠填充量的增加,聚酰亚胺泡沫泡孔结构变得精细,并且热稳定性、玻璃化转变温度和压缩性能都随之提高。当填充量(空心玻璃微珠与均苯四甲酸酐的质量比)达到20%时,泡沫5%热失重温度提高了13.9℃,玻璃化转变温度提高了8.1℃,压缩强度提高了约21%,压缩模量提高了约12%。     

一种可溶性聚酰亚胺的合成及其渗透汽化脱有机硫化物性能测试

由3,3′,4,4′-二苯醚四甲酸二酐(ODPA)和3,3′-二甲基4,4′二氨基二苯甲烷(DMMDA)二胺为单体,利用低温溶液缩聚化学亚胺化法合成了ODPA DMMDA聚酰亚胺.利用FT IR、NMR与DSC等手段对聚酰亚胺的结构进行了表征;研究了其溶解性能、耐热性能和力学性能.结果表明,此聚酰亚胺可溶于DMF、DMAc等极性溶剂;玻璃化转变温度为264℃,其10%的热分解温度为521℃;断裂强度为137MPa;断裂伸长率为18%.采用相转化法将其制成非对称膜,采用扫描电子显微镜(SEM)观察内部结构,在渗透汽化脱硫实验中,对噻吩有良好的选择透过性能.350K时,硫富集率为3.68,渗透通量为0.92kg m2h.     

Structural characterization of silica modified polyimide membranes

Polyimide and hybrid polyimide‐siloxane were synthesized by polycondensation, imidization, and sol‐gel reaction. The polyimides were prepared from pyromellitic dianhydride (PMDA) and 4,4‐oxydianiline (ODA) in N‐methyl‐2‐pyrollidone (NMP). Trimethoxyvinyl silane (TMVS) was used as a source of silica. Their surface morphologies, structures and thermal performances were determined using scanning electron microscopy (SEM), infrared spectroscopy (IR), thermogravimetric analysis (TGA) and differential scanning calorimetry (DSC). The results showed that the silica particles were finely and rather homogeneously dispersed in polymers. The glass transition temperature (T_g) of hybrid membrane materials increased with the increasing silica content. TGA analysis showed that polyimides were thermally stable with silica. Modified polyimide‐siloxane films, thermal characteristics were found to be better than the polyimide films without silica. Copyright © 2006 John Wiley & Sons, Ltd.     

耐超高温双酮酐型聚酰亚胺的合成及性能

以4,4'-对苯二甲酰二邻苯二甲酸酐(TDPA)为芳二酐单体,对苯二胺(PPD)为芳二胺单体,经低温溶液缩聚制得成膜性能优良的高相对分子质量聚酰胺酸(PAA),再经过热亚胺化制备双酮酐型聚酰亚胺(PI)薄膜。 采用傅里叶变换红外光谱仪(FT-IR)、广角X射线衍射(WAXD)、差示扫描量热仪(DSC)、动态热机械分析仪(DMA)、热重分析仪(TGA)、紫外-可见分光光度计(UV-Vis)及力学性能等技术手段表征了聚酰亚胺膜的结构和性能,考察了不同亚胺化温度对合成的双酮酐型聚酰亚胺膜性能的影响。 结果表明,经程序升温至320 ℃能使PAA热亚胺化基本趋于完成。 PI薄膜为部分有序聚集态结构,玻璃化转变温度(T_g)为298 ℃,具有优异的热性能,热失重温度(T_5%)为523 ℃。 拉伸强度达到130 MPa,弹性模量为5.77 GPa。 PI薄膜紫外光透过截止波长为375 nm,在可见光区具有良好的透光性能及耐溶剂性能。     

Polyimide containing internal acetylene units linked para to the aromatic ring

4,4′-Diaminodiphenylacetylene (p-intA) was reacted with 3,3′,4,4′-biphenyltetracarboxylic dianhydride (BPDA), 3,3′,4,4′-benzophenonetetracarboxylic dianhydride (BTDA) and pyromellitic dianhydride (PMDA) in N-methyl-2-pyrrolidone (NMP) to give poly(amic acid) solution of moderate to high viscosity. Thermal imidization gave polyimide having acetylene units that are linked para to the aromatic connecting unit. Polyimide having acetylene units that are linked meta to the aromatic connecting unit also was prepared utilizing 3,3′-diaminodiphenylacetylene (m-intA) for comparison. The crosslinking behavior of the acetylene units was observed with DSC. Exotherm due to the crosslinking of the para-linked acetylene units appeared at ca. 340 to 380°C depending on the structure of polyimide, whereas meta-linked acetylene units appeared at lower temperature as 340–350°C. After thermal treatment at high temperature such as 350 or 400°C, the amount of the exotherm became smaller and finally disappeared on DSC, confirming the progress of crosslinking. Dynamic mechanical properties of the polyimide films show that glass transition temperature increased with higher heat treatment, also confirming the progress of crosslinking. Tensile properties of the polyimide films showed that rigid polyimide films consisting of p-intA with BPDA or PMDA have considerably higher modulus than those consisting of m-intA. Cold-drawing of the poly(amic acid) followed by imidization gave much higher modulus in the case of rigid polyimide. © 1997 John Wiley & Sons, Inc. J Polym Sci A: Polym Chem 35 : 2395–2402, 1997     

The synthesis and characterization of polyimide homopolymers based on 5(6)‐amino‐1‐(4‐aminophenyl)‐1,3,3‐trimethylindane

The isomeric diamine monomer 5(6)‐amino‐1‐(4‐aminophenyl)‐1,3,3‐trimethylindane (DAPI) was successfully synthesized via the dimerization of α‐methylstyrene followed by nitration and reduction. High molecular weight, soluble polyimides were synthesized via ester–acid solution imidization techniques and had glass‐transition temperature values ranging from 247 to 369 °C. The polymers were soluble in common organic solvents because of the asymmetric and nonplanar nature of DAPI and displayed good short‐term thermal stability by thermogravimetric analysis, as shown by their 5% weight‐loss values above 500 °C in air. The DAPI/(3,4‐dicarboxyphenyl) hexafluoropropane dianhydride (6FDA) polyimide also showed 2‐h thermal stability at 400 °C under nitrogen, despite the partial aliphatic character. Refractive index values as low as 1.571 were observed for DAPI/6FDA, which allows an estimated dielectric constant of 2.47 to be derived. The permeation of O₂ and N₂ was conducted on thin dense films. The bulky, bent, and isomeric nature of DAPI imparted film‐forming membranes that permitted high O₂ permeability. In combination with 3,3′,4,4′‐benzophenone tetracarboxylic dianhydride (BTDA), DAPI had a good combination of O₂ permeability and O₂/N₂ selectivity values of 2.8 Ba and 7.3, respectively. The polymerization method utilized to facilitate the cyclization of DAPI/BTDA to the polyimide affected the final thermal properties of the resulting polymer. The chemical imidization of DAPI/BTDA generated a polyimide with a glass‐transition temperature value of 311 °C and a 5% weight‐loss value in air of 457 °C. However, thermal and ester–acid imidization routes yielded an increase in the thermal properties. The ester–acid solution imidization of DAPI/BTDA produced a polymer glass‐transition temperature value of 333 °C and a 5% weight‐loss value of 525 °C in air. © 2000 John Wiley & Sons, Inc. J Polym Sci A: Polym Chem 38: 2840–2854, 2000     

含异山梨醇结构单元聚酰亚胺的合成与表征

以异山梨醇为原料,合成了含异山梨醇的二胺单体.将该单体与4,4′-(六氟异丙基)双邻苯二甲酸二酐(6FDA)反应,制备了含异山梨醇结构单元的聚酰亚胺.采用红外光谱、氢核磁共振、紫外光谱和热分析等手段,对产物的结构、热性能及光学性能等进行了表征.结果表明,所得到的聚酰亚胺具有较好的热稳定性和光学性能、并在极性溶剂中具有较好的溶解性.     

一种主链含光敏基团聚酰亚胺的合成与表征

通过4,4′-二羟乙基查尔酮与1,2,4-苯三酸酐酰氯反应,得到了一种新型的主链含查尔酮的二酐单体,通过二酐和2,2-双(3(-氨基-4(-羟基苯基)六氟丙烷缩聚并高温亚胺化,得到了一种新型的主链含查尔酮,侧链含羟基的光敏聚酰亚胺,并通过1H-NMR、FTIR、GPC及热分析表征了得到的聚酰亚胺的结构和热性能.这种聚酰亚胺在极性溶剂中具有较好的溶解性,并具有较高的热稳定性,在紫外光照射下,能进行[2+2]的环加成反应.     

The preparation of novel silica modified polyimide membranes: synthesis,characterization, and gas separation properties

In this study, new monomers having siloxane groups were synthesized as an intermediate for preparation of siloxane modified polyimide polymers. Then with these monomers, the synthesis of uncrosslinked and crosslinked polyimide–siloxane hybrid polymer membranes were achieved. The purposes of the preparation of modified polyimides were to modify the thermal and chemical stability, and mechanical strength of polyimides, and to improve the gas separation properties of polymers. The new diamine monomer having siloxane groups was prepared from 3,5‐diaminobenzoic acid (3,5‐DABA) and 3‐aminopropyltrimethoxysilane (3‐APTMS) in N‐methyl‐2‐pyrollidone (NMP) at 180°C. The modified polyimide membranes having different amount of siloxane groups were synthesized from pyromellitic dianhydride (PMDA), 4,4‐oxydianiline (ODA), and 3,5‐diaminobenzamido‐N‐propyltrimethoxy silane (DABA/PTMS) in NMP using a two‐step thermal imidization process. The synthesis of modified polyimide membranes were characterized by Fourier transform infrared spectroscopy (FTIR). The thermal analysis of the polyimides were carried out by differential scanning calorimetry (DSC) and thermogravimetric analysis (TGA). Water absorption and swelling experiments were also carried out for the investigation of structural properties of polymers. FTIR observations confirmed that the polyimide membranes with new diamine intermediate were successfully obtained. Thermal analysis showed that the uncrosslinked copolyimides exhibited two glass transition temperatures, indicating that they were separated microphases and it was found that all the modified copolyimides had showed higher glass transition temperature (T_g) than unmodified polyimides. The separation properties of the prepared polyimide membranes were also characterized by permeability for O₂ and N₂ gases and ideal selectivity values were calculated. Copyright © 2009 John Wiley & Sons, Ltd.     

Structure and infrared emissivity of silicon-containing polyimide/BaTiO3 nanocomposite films

Silicon-containing polyimide/BaTiO₃ nanocomposite films were prepared by the direct mixing of silicon-containing polyamic acid and BaTiO₃ nanoparticles under ultrasonic wave irradiation, followed with thermal imidization. Structure and thermal properties were measured with FTIR, XPS, SEM, DSC and TGA. The results showed that the compatibility of BaTiO₃ and a polyimide might be improved by the introduction of dimethylsilylene groups into the backbone of a polyimide; and BaTiO₃ nanoparticles in the nanocomposites tended to form clusters. The clusters coalesced into a more uniform structure at a higher BaTiO₃ filling than at a lower one.The interfacial interaction between BaTiO₃ and the silicon-containing polyimide resulted in the increase of the glass transition and the thermal decomposition temperature. It was found that the nanocomposites exhibited lower infrared emissivity value than the pure polyimide and the magnitude of infrared emissivity value was related to the content of BaTiO₃ in the nanocomposites.     

Poly(ether‐imide) and related sepiolite nanocomposites: investigation of physical,thermal, and mechanical properties

Novel poly(ether‐imide) and sepiolite nanocomposites were synthesized based on a unique diamine monomer with the aim of improving physical and mechanical properties of final polyimide films. The diamine was polycondensed with 4,4′‐(hexafluoroisopropylidene) diphthalic anhydride to produce related poly(ether amic acid) prepolymer. Pure poly(ether‐imide) and nanocomposite films were prepared via thermal imidization process of poly(ether amic acid). Coexistence of ether, pyridine, and phenylene functional groups in the diamine chemical structure resulted in flexible polyimide films with significant thermal, physical, and mechanical properties. Thermal stability, glass‐transition temperature, dimensional stability, and tensile properties of polymer and nanocomposites were studied and compared. Morphology of nanocomposites was also investigated using scanning and transmission electron microscopic methods to study the distribution and dispersion behavior of sepiolite nanofibers in the polyimide matrix. By introduction of sepiolite nanoparticles, overall improvement of properties was observed in respect to pure polyimides. Copyright © 2015 John Wiley & Sons, Ltd.