环氧氯丙烷橡胶的热可逆共价交联

以环戊二烯二羧酸钾 [DCPD(COOK) 2 ]为交联剂 ,采用溶液反应法使环氧氯丙烷橡胶 (环氧氯丙烷均聚物 ,CER)交联 ,制得了凝胶含量达 88 75 %的交联CER ,研究了溶剂种类、反应温度、催化剂及交联剂用量对凝胶形成量的影响 .IR谱证明 ,DCPD(COOK) 2 与CER发生双端酯化而交联 ;反应溶解性试验表明 ,该共价交联聚合物具有热可逆转化特性 ,热可逆转化百分率随反应温度的提高、交联剂用量的增多而下降     

热可逆共价交联氯化聚乙烯的制备和性能

以双环戊二烯二羧酸钾 [DCPD(COOK) 2 ]为交联剂 ,通过共混反应法制得了共价交联的氯化聚乙烯(CPE)热塑性弹性体 (TPE) ,研究了共混反应条件 (温度、时间及交联剂用量等 )对TPE物性的影响 .反应溶解性和IR测定数据证明 ,DCPD(COOK) 2 与CPE分子链上的活性氯反应形成共价酯键而交联 ;物性测定数据表明 ,交联CPE的主要力学性能接近CPE常规硫化胶 ,不同的是该交联聚合物具备可塑性 ,经反复加工三次后 ,其力学性能还略有提高     

氯化聚乙烯的热可逆共价交联

采用新型热可逆共价交联剂 ,以溶液反应法使氯化聚乙烯 (CPE)交联制得了凝胶量在 80 %左右的共价交联CPE ,研究了不同牌号CPE、催化剂及其用量、反应温度、反应时间及交联剂用量对CPE交联程度的影响 ,并测定了共价交联CPE的热可逆转化特性     

活性氯型丙烯酸酯橡胶的热可逆共价交联

利用热可逆季铵化反应特性,将含叔胺功能基团的聚合物用于活性氯型丙烯酸酯橡胶(ACM)的热可逆共价交联。通过乳液聚合方法合成了丙烯酸丁酯(BA)/4-乙烯基吡啶(4-VP)共聚物交联剂,考察了交联剂用量、模压温度和模压时间对ACM交联程度、力学性能的影响,并通过DSC、变温扭矩测定、热塑再加工成型等方法研究了交联ACM胶样的热可逆性。研究表明,BA-4-VP共聚物交联的炭黑填充ACM胶样拉伸强度可达8.5MPa,并可进行热塑模压成型,再次加工成型后胶样断裂强度增大、伸长率下降。     

热可逆交联环氧树脂的动态结构与性能研究

通过双马来酰亚胺与侧链带有呋喃官能团线性环氧树脂间的Diels-Alder反应,制备了热可逆交联的环氧树脂(DAERs),通过热分析、固体核磁共振技术和力学性能测试详细研究了该热可逆交联聚合物中的热可逆转变过程、动态化学键演化以及交联度对力学性能的影响.示差扫描量热法(DSC)和动态热机械分析(DMA)等热分析结果表明,可逆共价键的化学交联作用提高了材料的玻璃化转变温度,随着交联度的增大,热可逆共价键断裂及玻璃化转变协同作用导致材料软化温度显著提高,进而提高了材料的耐热性.通过变温13C固体NMR实验原位监测DA/retro-DA反应过程,发现DAERs中通过DA反应形成的交联网络结构可以在高温解交联而生成呋喃与马来酰亚胺小分子化合物,而低温时呋喃与马来酰亚胺化合物又再次反应得到DA加成结构,进而从分子水平上为材料的热可逆交联特性提供了关键的实验证据.而原样品和溶液法再加工样品的拉伸实验结果表明,可逆交联DA反应不但使样品具有较高的力学强度,而且使交联聚合物具有了再加工的能力.     

开环共聚法合成热可逆共价交联聚醚橡胶

以烷基铝为催化剂,双环戊二烯二甲酸双缩水甘油酯为交联单体,与环氧氯丙烷、环氧乙烷、环氧丙烷进行离子型开环共聚,制得了热可逆共价交联的聚醚橡胶．研究了聚合方法、聚合配方和工艺条件对单体转化率、共聚物组成的影响．通过 Ｉ Ｒ 和 Ｄ Ｓ Ｃ 测定及反应溶解性和高温成型实验,证明了共聚物的结构及共价交联的热可逆转化特性．     

丙烯酸乙酯/烯丙基缩水甘油醚共聚物的热可逆共价交联

研究了双环戊二烯基二羧酸及其铵盐对丙烯酸乙酯 /烯丙基缩水甘油醚共聚物的交联反应 ,对比了二者的交联速度 .用DSC评价了它们的热可逆转化行为 .制得了热可逆部分达 79 7%的共价交联环氧型丙烯酸酯橡胶     

基于可逆共价化学的交联聚合物加工成型研究——聚合物工程发展的新挑战

可逆共价聚合物能够通过外界刺激(包括加热、光和pH)触发可逆反应,从而实现聚合物拓扑结构的重组,同时在撤销刺激后又可以像不可逆共价聚合物一样保持结构稳定性.近年来,越来越多的研究者致力于利用该特性来解决交联聚合物加工成型的难题,这不仅打破了传统热塑性聚合物和热固性聚合物的严格界限,而且带来了新的材料研发方法和功能,使得聚合物制品种类更加多样化,其生命周期也相应得以延长.孕育着传统聚合物工程领域的新突破,具有重要价值.为及时反映这一态势,本文总结了可逆共价化学的基本原理,阐述了可逆共价聚合物的流变特性,并且综述了由此衍生的含可逆共价键交联聚合物各类成型加工技术原型和应用,如力学性能调控、塑性变形、焊接、纳米填料的分散与增强效应、模压成型与固相回收、注射成型、挤出成型、3D打印、碳纤维复合材料的可控降解与再生等,在此基础上,进一步分析了该新兴领域的挑战和发展趋势.     

环氧树脂类玻璃高分子研究进展

类玻璃高分子(Vitrimer)是一类具有可逆共价交联网络的高分子,其能够在维持交联结构的同时实现交联网络的重构,兼具热固性高分子和热塑性高分子的双重优势.基于通用热固性树脂形成的Vitrimer材料不仅能具有良好的力学性能和耐溶剂性等,还能表现出类似热塑性树脂的流动性和重复加工性能,为从源头上实现交联树脂的回收和再利...     

热可逆共价交联反应及其研究进展

梗概评述了环戊二烯（ＣＰＤ）与双环戊二烯（ＤＣＰＤ）之间Ｄｉｅｌｓ－Ａｌｄｅｒ反应的特点,以及将其引作大分子间交联键的思路;以此为基础详细讨论了热可逆共价交联聚合物的分析方法。制备路线,以及利用这一反应目前所达到的研究水平和成就 。     

Crosslinking of chlorine‐containing polymers by dicyclopentadiene dicarboxylic salts

Alkali‐ and alkali‐earth‐metal salts of dicyclopentadiene dicarboxylic acid (DCPDCA) were prepared and employed as crosslinkers for chlorine‐containing polymers such as polychloromethylstyrene (PCMS), chlorinated polypropylene (CPP), polyepichlorohydrin (PECH), and poly(vinyl chloride) (PVC). Thermally reversible covalent crosslinks (i.e.,  DCPD bridges) between polymer chains were generated through esterification between the chlorine–carbon bonds of the polymer and the carboxylic salt groups of the crosslinker. The crosslinking reactivity decreased in the following sequence: K > Na > LiDCPDCA > alkali‐earth‐metal salts of DCPDCA. In addition, PCMS and CPP had higher gelation rates than PECH and PVC. Good flowability at about 195 °C and solubility in maleimide‐containing dichlorobenzene on heating indicated that the crosslinked PCMS and CPP exhibited thermally reversible crosslinking because of dimer/monomer (cyclopentadiene) conversion of  DCPD moieties via reversible Diels–Alder cycloaddition. Samples of PECH and PVC crosslinked by the alkali salts of DCPDCA were insoluble even when heated in maleimide‐containing dichlorobenzene. However, these crosslinked polymers could be dissolved partially after the same treatment when the crosslinker was an alkali‐earth‐metal salt of DCPDCA. Thermal degradation such as dehydrochlorination of the PECH and PVC might have been responsible for uncontrolled crosslinking because these two polymers are known to be thermally unstable. The unreacted COOK, COONa, or COOLi of the crosslinkers might have initiated base‐induced dehydrochlorination when PECH and PVC were heated at high temperatures. © 2000 John Wiley & Sons, Inc. J Polym Sci A: Polym Chem 38: 818–825, 2000     

Application of Dithlol-s-triazine Derivatives to PVC CrossUnking

The effects of crosslinking on PVC are well known in regard to the improvement of mechanical properties, creep behavior, and softening temperature. Little is known, however, on the application of the PVC-crosslinking reaction, because most of crosslinked PVC tends to color easily at elevated temperatures. In this paper, a novel PVC-crosslinking reaction with 2-R-4,6-dithiol-s-triazine (I) has been presented to obtain insoluble products which hardly color on ageing. The reaction rate and induction period of the crosslinking reaction with I are made controllable by selecting the basicity of the substituent R of I as well as that of an acid acceptor in the blends. The utility of I as stabilizer as well as a crosslinking agent is also emphasized.     

Properties of poly(vinyl chloride) crosslinked by new difunctional reagents

Alkaline and alkaline earth salts of either dimercaptans obtained by duplication of o-mercaptobenzoic acid with α, ω-diols or of o-mercaptobenzoic acid have been synthesized. Their efficiency has been studied with respect to induction time before change in melt viscosity and crosslinking rate assessed with Haake plasticorder equipped with a Rheomix 600 internal mixer. Then efficiency with respect to crosslinking was also characterized by the assessment of the insoluble fraction in tetrahydrofuran. Mechanical properties of uncrosslinked and crosslinked PVC were compared at different temperature through either static tests with high strain as creep and tensile tests or dynamic test in the elastic domain. Except for creep resistance, crosslinking does not improve mechanical properties of plasticized PVC at temperature lower than 80°C if insoluble fraction in tetrahydrofuran is lower than 100 % by weight. Because chemical crosslinking leads to the existence of two interpenetrated networks, a physical one and a covalent one, the temporary physical network governs the properties until the melting of ordered domains, whereas the covalent network governs the properties if temperature rises above the melting temperature of the crystalline populations. To improve mechanical properties of crosslinked PVC at room temperature, the crosslinking density of the covalent crosslinks must be higher than the density of physical crosslinks. Such a situation is reached if insoluble fraction in tetrahydrofuran becomes 100 % by weight.     

Thermally reversible linking of halide-containing polymers by potassium dicyclopentadienedicarboxylate

A novel crosslinker for thermally reversible covalent (TRC) linking of halide-containing polymers is suggested. Chlorine-containing polymers such as chloromethylstyrene copolymers, chlorinated polypropylene, polyvinylchloride, chlorinated polyisoprene, and polyepichlorohydrin were crosslinked with potassium dicyclopentadienedicarboxylate (KDCPDCA). The crosslinker was prepared by reacting potassium ethoxide with dicyclopentadienedicarboxylic acid. Because of the low solubility of KDCPDCA in organic solvents, a phase transfer catalyst, benzyltrimethyl-ammonium bromide, was employed for the crosslinking reaction. The crosslinking reaction occurred at a higher rate in a polar solvent, such as dimethylformamide, than in a nonpolar one, such as toluene, and was affected by the nature of the chlorine-containing polymer. Some of the polymers crosslinked even at room temperature. The chain-extending reaction between KDCPDCA and a α,ω-dihalide compound such as α,α′-dichloro-p-xylene, 1,4-dichlorobutane, or 1,4-dibromobutane also was carried out to obtain linear oligomers. The IR spectra indicated that the crosslinking and chain-extending reactions were based on the esterification between the halide carbon bonds of the polymer and the COOK groups of KDCPDCA. The flowability at 195 °C and solubility on heating in a dichlorobenzen-maleic compound mixture of the crosslinked polymers indicated that the TRC crosslinking occurred via the reversible Diels–Alder cyclopentadiene/dicyclopentadiene conversion as long as the polymer was thermally stable and did not contain olefinic CC bonds. The TRC linking also was confirmed by the rapid decrease of the specific viscosity of the obtained linear oligomers on heating. © 1999 John Wiley & Sons, Inc. J Polym Sci A: Polym Chem 37: 4390–4401, 1999     

交联壳聚糖膜的制备及其性能的研究

用环氧氯丙烷成功地制备出交联壳聚糖膜。用FTIR,XRD和SEM方法表征其结构,并测试了其力学性能。结果表明,壳聚糖在低温下只有氨基参与交联反应,反应温度高于40℃时,羟基才发生反应;环氧氯丙烷的交联作用显着提高了壳聚糖膜的抗张强度,并有效地降低了溶菌酶对其降解速率;该交联膜有望用作可控降解的生物医用材料。