阻燃共聚酯/粘土复合物热降解动力学研究

用插层共聚方法合成了含磷共聚酯／粘土复合物。用热重(TG)方法考察热降解动力学。通过在空气中以不同的升温速率升温至设定温度,用Kissinger法和Hymn-Wall-Ozawa法对数据进行处理。结果表明,粘土组分含量较高的反应活化能较大,热稳定性较好。     

阻燃共聚酯的热降解动力学研究——Ⅰ.含磷共聚PET和PET的比较

1　前言ＰＥＴ(聚对苯二甲酸乙二醇酯 )由于具有优良的综合性能 ,被广泛地应用于合成纤维、薄膜和工程塑料等领域 ,但由于它的可燃性 ,在火灾事故中 ,由其着火所致占有较大比例 ,因此它的阻燃化更加引起了世界范围内学者的广泛关注[1 ] 。由于磷是对聚酯的最有效阻燃元素 ,采用共聚法制备含磷ＰＥＴ的报道较多 ,也有关于其热降解动力学研究的报道[2～ 1 0 ] 。但本文所采用的单体羟基苯氧膦丙酸 (ＣＥＰＰ)和ＰＥＴ共聚所得产物的热降解动力学研究 ,尚未见报道。研究该种含磷ＰＥＴ的热稳定性和热降解行为对研究该材料的使用范围和成型加工…     

共聚酯PEIT-PEG结构与性能的研究

PET与PEG共聚可改善PET的抗静电性，但PEG含量的增加，会使共聚物的结晶温度大幅度地降低，不利于纤维加工，且伴随着结晶的发生，纤维的抗静电性也受到影响。在共聚体系中添加间苯二甲酸(IPA)，不仅能破坏大分子链结构的规整性、降低共聚酯的结晶性，而且能提高共聚酯纤雏的抗静电性能。用DSC与TG对共聚酯(PEIT-PEG)的聚集态结构、热性能、结晶性能等进行了表征。     

新型侧基含磷共聚酯的合成、表征及性能

以精制对苯二甲酸（TPA）、乙二醇（EG）和含磷反应型阻燃剂9,10-二氢-9-氧杂-10-[2,3-二（2-羟基乙氧基）羰基丙基]-10-磷杂菲-10-氧化物为原料,利用熔融缩聚法合成了含磷量分别为0．35％、0．65％的阻燃聚酯。通过熔融纺丝法将聚酯制成纤维及织物,研究了纤维的染色性能,并通过极限氧指数法和垂直燃烧法研究了织物的阻燃性能。FT-IR和NMR研究结果表明：阻燃共聚酯含磷量为0．35％时,其氧指数（LOI）达31．5％,并无熔滴、烟雾产生,具有优异的阻燃性能和抗熔滴性能。DSC、TG和XPS的研究结果表明：侧基舍磷单元的引入降低了聚酯的Tg和Tm,较低的Tm将有利于材料加工性能的改善;阻燃聚酯侧基上的P-C、P-O键易断裂并挥发至气相中,从而降低了聚酯热稳定性,阻燃聚酯可能以气相阻燃机理为主发挥阻燃作用。此外,含磷共聚酯纤维具有较优异的染色性能。     

共聚酯PEIT-PEG结晶性能的研究

通过偏光显微镜、广角X衍射与FTIR三种测试手段对共聚酯PEIT-PEG的结晶性能进行了系统的研究，重点分析了间苯二甲酸(IPA)、聚乙二醇(PEG)分子量和含量对共聚酯结晶性的影响。研究表明，PEIT与PEG之间发生了共聚反应，IPA的引入使PET结晶性能下降，晶粒尺寸减少，结晶度降低。引入PEG后，当PEG分子量和含量较低时，共聚酯结晶性能提高；当PEG含量较高时，在PEG分子量不变的情况下，随着PEG含量的增加，结晶性能下降；若PEG重量含量相同，PEG分子量越高，结晶性能越好。     

含磷全芳族热致液晶共聚酯的合成及热性能

全芳族热致液晶聚酯因其优良的力学性能、热稳定性及较低的熔融粘度而倍受关注 ,是当今最有前途的特种高分子材料之一 .但是 ,全芳族聚酯的刚性结构使其熔点较高 ,难以加工 ,因而通过分子设计制备熔点较低的热致全芳香族聚酯液晶成为研究的热点 .在主链型热致液晶高分子的分子设计中 ,通常采用共聚或在高分子链中引入取代基、柔性链段、扭结成分等方法来达到降低聚合物相转变温度的目的[1～ 6 ] .本文以对羟基苯甲酸、对苯二甲酸、间苯二甲酸和含磷二元酚化合物为单体 ,合成了一类具有较低熔点或流动温度的新型全芳族热致共聚酯液晶 ,其分子…     

水溶性聚酯的热降解动力学研究

水溶性聚酯的热降解动力学研究应宗荣李瑞霞吴大诚（四川联合大学轻纺学院成都６１００６５）关键词水溶性聚酯，热降解，动力学，活化能高聚物的热稳定性直接影响高聚物的应用和加工成型．高聚物在高温时易发生热降解，导致分子链断裂，分子量降低，性能劣化．研究...     

固态后缩聚方法合成高分子量的含磷热致性液晶共聚酯

为了获得较高分子量的具有高阻燃性的热致性液晶高分子,通过固态聚合方法合成了一种基于对羟基苯甲酸、对苯二甲酸、乙二醇和含磷菲环取代二酚的高热稳定性、较低相转变温度和宽的液晶相转变温度范围的含磷液晶共聚酯(BDQTEP),并对该含磷液晶共聚酯预聚物(pre-BDQTE)在不同固态聚合条件下获得的聚合物热性能和液晶性进行了研究.对其固态反应速率控制进行了初步的探讨,当反应温度为235℃时,固态聚合反应较为理想.在聚合的初始阶段,共聚酯特性黏数[η]、黏流温度Tf和羧基浓度[COOH]均随聚合时间而明显变化,但在6 h后变化较小,几乎不变.通过固态后缩聚,将熔融聚合获得的特性黏数[η]=0.44 dL/g的含磷液晶共聚酯BDQTE的特性黏数提高了近两倍.     

聚对苯二甲酸二甲酯/聚2,5-呋喃二甲酸二甲酯嵌段聚酯的合成与表征

以生物基单体2,5-呋喃二甲酸、乙二醇为原料合成聚2,5-呋喃二甲酸乙二醇酯(PEF)。采用熔融酯交换法以PEF聚酯部分取代聚对苯二甲酸乙二醇酯(PET),制备了系列PET-b-PEF嵌段共聚酯。通过核磁共振仪(NMR)、差示扫描量热仪(DSC)、热失重仪(TGA)、X射线衍射仪(XRD)等技术手段表征了共聚酯的结构和性能。结果表明,该系列共聚酯的玻璃化转变温度(Tg)在75.8~80.3℃之间,且随着PEF链段质量分数的增加,PET-b-PEF嵌段共聚酯的Tg先降低后升高,结晶度和熔融温度逐渐降低。当PEF链段含量高于15%时,共聚酯没有结晶峰。该系列共聚酯具有良好的热稳定性,起始分解温度在392.2~407.9℃之间,与所制备的PET起始分解温度403.3℃接近。且当共聚酯中PEF链段含量低于15%时,起始分解温度均在407℃左右,优于PET的热稳定性。     

Degradation mechanism of diethylene glycol units in a terephthalate polymer

Diethylene glycol (DEG) is incorporated into poly(ethylene terephthalate) (PET) during industrial synthesis in order to control crystallisation kinetics. DEG is known to be a weak point in the thermal degradation of PET, which is problematic during the recycling of the polymer.Studies on the thermal decomposition of the model polymer poly(diethylene glycol terephthalate) (PDEGT) have been performed using TG, DSC, TVA and spectroscopic techniques. They revealed a degradation behaviour with two distinct steps, where the first step initiates some 100 K below the degradation temperature of PET. The second step is similar to the behaviour of PET.Based on our observations, a new degradation mechanism specific to DEG units is proposed, where random ether groups along the backbone can back-bite and form cyclic oligomers. These cyclic species, containing ether moieties, are evolved at 245 °C and constitute the first of the two steps of degradation observed for PDEGT.     

磷系阻燃共聚酯的结构与性能

采用磷系阻燃剂2-羧乙基苯基次磷酸（CEPPA）作为第3单体,通过聚合反应制备了含磷的阻燃共聚酯。采用核磁共振、DSC、元素分析和极限氧指数仪表征阻燃共聚酯的化学组成、序列分布、结晶性能、磷含量和极限氧指数。结果表明：大部分CEPPA单元以无规分布的形式共聚到聚酯分子链中,小部分CEPPA单元以短嵌段的形式共聚在聚酯分子链中,且随着阻燃剂含量增加,无规系数变小。由于分子链的规整性下降,与聚对苯二甲酸乙二酯（PET）相比,阻燃共聚酯的Tg和Tm下降,结晶度减小。随阻燃剂含量的增加,极限氧指数值增加,当阻燃共聚酯中的磷含量达到9．08mg／g时,极限氧指数值达到33％以上。     

Kinetics of thermal degradation in non-isothermal conditions of some phosphorus-containing polyesters and polyesterimides

The thermal decomposition behavior of some phosphorus-containing polyesters and a polyesterimide was studied using thermogravimetric analysis in air at several heating rates between 5 °C/min and 20 °C/min. The results of this study, realized for polymers with phosphorus linkage as pendant group, were compared with the behavior of some polymers having the same backbone structure, with phosphorus in the main chain, respectively, without phosphorus. The kinetic processing of data was carried out using the Coats-Redfern, Reich-Levi, Flynn-Wall-Ozawa and Kissinger methods.     

无卤磷系阻燃聚合物研究进展

无卤磷系阻燃聚合物燃烧时低烟无毒,对环境污染少,阻燃剂含量较少就能达到好的阻燃效果,且对聚合物材料的各种性能影响甚微,因而无卤磷系阻燃聚合物得到广泛的应用。文中在参考了大量文献的基础上,对无卤磷系阻燃聚合物的合成、结构、性能及应用做了详细的介绍和论述,并展望了无卤磷系阻燃聚合物的发展方向和前景。     

Degradation of poly(ethylene terephthalate)/clay nanocomposites during melt extrusion: Effect of clay catalysis and chain extension

Organoclays with various contents of hydroxyl groups and absorbed ammonium were prepared and compounded with poly(ethylene terephthalate) (PET), forming PET/clay nanocomposites via melt extrusion. Dilute solution viscosity techniques were used to evaluate the level of molecular weight of PET/clay nanocomposites. Actually, a significant reduction in PET molecular weight was observed. The level of degradation depended on both the clay structure and surfactant chemistry in organoclays. The composites, based on clay with larger amount of hydroxyl groups on the edge of clay platelets, experienced much more degradation, because the hydroxyl groups acted as Brønsted acidic sites to accelerate polymer degradation. Furthermore, organoclays with different amounts of absorbed ammonium led to different extents of polymer degradation, depending upon the acidic sites produced by the Hofmann elimination reaction of ammonium. In addition, the composite with better clay dispersion state, which was considered as an increasing amount of clay surface and ammonium exposed to the PET matrix, experienced polymer degradation more seriously. To compensate for polymer degradation during melt extrusion, pyromellitic dianhydride (PMDA) was used as chain extender to increase the intrinsic viscosity of polymer matrix; more importantly, the addition of PMDA had little influence on the clay exfoliation state in PET/clay nanocomposites.     

Thermal degradation investigation of poly(ethylene terephthalate)/fibrous silicate nanocomposites

Based on the fibrous silicates (palygorskite, PT) organically modified by water-soluble polyvinylpyrrolidone (PVP), poly(ethylene terephthalate) (PET) nanocomposite with good dispersion of the PT nano-particles was prepared via in situ polycondensation. The thermal degradation behavior of PET and PET/PT nanocomposite was investigated by thermogravimetric analysis (TGA) under non-isothermal conditions at various heating rates in air and nitrogen, respectively. The apparent activation energies of the samples were evaluated by Kissinger and Flynn-Wall-Ozawa method. It is suggested that, during thermal decomposition in nitrogen, the clay as a mass-transport protective barrier can slow down degradation of polymer, but the catalytic effect of metal derivatives in clays may accelerate the decomposition behavior of PET. The combination of these two effects determines the final thermal stability of nanocomposite. However, in air atmosphere, the oxidative thermal stability of PET/PT nanocomposite was obviously superior to that of pure PET.     

含蒽醌结构新型共聚酯染料的合成及性能

以溶液聚合法合成了以１,５－二－β－羟乙醚基蒽醌为染料单体的新型共取酯染料,通过紫外－可见、核磁共振、热重等方法对聚合物性能进行表征,将其作为色母在毛细管流变仪上对聚酯纤维进行共混染色,并测定其光宾度。     

Fire retardant poly(ethylene terephthalate)/polycarbonate/triphenyl phosphite blends

Flame retardant recycled PET blends containing PC and triphenyl phosphite (TPP) have been designed using the following sequential processing strategy: PET and PC are first melt blended with a transesterification catalyst, allowing the compatibilisation of the blend, before adding TPP. The presence of this last component was shown to stop the transesterification reaction between PET and PC, avoiding chain breaking. In addition, TPP acts as a chain extender of PET, allowing the average chain length to be increased. The optimized blends obtained present “V-0” UL94 rating due to a better thermal stability leading to low flammability and to the development of an important, stable and covering char layer, resulting in self-extinguishability and very low Heat Release Rates during combustion.     

苯基次磷酸盐离聚物/聚磷酸铵协效阻燃增韧改性聚乳酸

通过将双端羟基的聚己内酯(PCL)、聚乳酸(PLA)预聚物以及苯基次磷酸离子盐扩链得到一种含苯基次磷酸盐的离子共聚物,将其与聚磷酸铵(APP)复合用于协同改性聚乳酸,离聚物中苯基次磷酸盐结构与APP具有优异的协同阻燃PLA的作用,同时该离聚物中PLA与苯基次磷酸盐结构有效提升了APP在PLA中的分散能力,最后该离聚物中PCL柔性链段有效改善了PLA的韧性,最终得到更高效阻燃性能且韧性也较好改善的PLA/PCLA-PIU/APP复合材料.一方面,离聚物中苯基次磷酸盐结构与APP协同有效促进了PLA的成炭,形成更连续致密的炭层从而阻隔可燃气体的释放,达到更好的阻燃效果.锥形量热、残炭的扫描电子显微镜(SEM)、能谱分析(EDS)、拉曼光谱等测试证实了这一结果,与纯PLA以及仅使用APP的PLA/APP相比,PLA/PCLA-PIU/APP的热释放速率与总热释放均降低,同时残炭的石墨化程度更高,形成了更为致密的炭层.另一方面,力学性能测试结果表明,离聚物中PCL柔性链段的存在使得与APP复合改性后的PLA的韧性相比纯PLA和PLA/APP有较大的提升;SEM测试表明,离聚物中PLA与苯基次磷酸盐结构起到增容作用,提升了APP在PLA中的分散性.