咪唑固化不同类型环氧树脂的固化特征、固化动力学及其反应活性

以咪唑为固化剂,对缩水甘油醚型、缩水甘油酯型环氧树脂(简称链型环氧树脂)及脂环环氧树脂的固化特征、固化动力学及反应活性进行了研究.DSC实验结果表明,固化过程均分两阶段进行,链型环氧树脂固化反应表观活化能低于脂环环氧树脂.各树脂第一阶段的表观反应活化能均低于第二阶段活化能.当脂环环氧树脂中混入不同比例的链型环氧树脂后,固化反应速率均较脂环环氧树脂单独固化时快,当链型环氧树脂量大于50％时,更为明显.     

不同温度下环氧树脂代木搪塑模具的固化过程

采用流变学的方法研究了环氧树脂代木搪塑模具在不同温度下的固化过程。 为了找到合适的测试条件,首先研究了应变和振荡频率对环氧树脂代木搪塑模具的测试结果的影响。 环氧树脂代木搪塑模具固化过程中,体系交联程度逐渐变大;在不同的固化阶段,固化程度的变化快慢不同,先缓慢增加,然后迅速增加,最后缓慢增加至平台值;储能模量和损耗模量的变化速度在不同阶段的变化与固化程度的变化相似,根据储能模量和损耗模量的最快增长速率与温度的关系得到体系的活化能约为27.2 kJ/mol;随着固化温度升高,环氧树脂代木搪塑模具固化完全所需的时间减少,同时环氧树脂的施工容留时间也相应地减少。     

丙烯酸环氧酯树脂灌浆材料的研究

丙烯酸环氧酯树脂(Epoxy-acrylate resins)是六十年代出现的一种新型热固性树脂,它结合了环氧树脂和不饱和聚酯树脂的优点,成为一种很有发展前途的新型树脂。环氧树脂具有粘结力强,机械性能好,电绝缘性能和耐腐蚀性能好等一系列优点,但也存在一些缺点,如树脂本身粘度大,不易操作,加入稀释剂则其性能明显下降;树脂的固化过程不易控制,一般固化时间较长等。不饱和聚酯树脂虽然性能不如环氧树脂,但它却有很好的操作性能和固化性能。丙烯酸环氧酯树脂就是一种既保持环氧树脂的优良性能,并使之具有不饱和聚酯的优良操作性能和固化性能的新型树脂。最常用的丙烯酸环氧酯树脂是双酚A型环氧树脂的丙烯酸酯,具有下式结构:     

导电炭黑填充室温硫化硅橡胶的屏蔽性能

研究了导电炭黑及镍粉等导电填料填充室温硫化(RTV)硅橡胶的电阻率及屏蔽值随填料配比、拉力的变化特性。结果表明,在低阻值情况下可用Schelkunoff理论较好地描述其屏蔽效果,且屏蔽值随着电阻值的变化产生了类似于渗滤现象的突变;在102Ω·cm以下随着电阻率的降低,屏蔽效果迅速增加。同时根据隧道导电理论推导了电阻值随拉力的变化关系,该关系式可近似用二次多项式表示,并对实验结果进行很好地拟合。     

环氧树脂固化过程的红外光谱研究

通过对环氧树脂和顺丁烯二酸酐在加热固化过程中红外光谱演变情况的观察,阐明了树脂在不同固化阶段和不同固化温度所进行的各类反应和相应的结构变化。在固化过程中使树脂的分子量增大和形成交联结构的主要反应是酯化反应。Fisch等提出的醚化反应在红外光谱中没有得到证实。树脂在酯化反应中生成的顺丁烯二酸酯的结构受热的影响会产生顺、反异构化反应。反应的进程取决于固化温度。在180℃加热已固化的树脂将导致部分碳-碳双键和剩余环氧基的减少,同时产生新的羟基和羰基。     

动态固化聚丙烯/环氧树脂共混物的研究

将动态硫化技术应用于热塑性树脂 热固性树脂体系 ,制备了动态固化聚丙烯 (PP) 环氧树脂共混物 .研究了动态固化PP 环氧树脂共混物中两组分的相容性、力学性能、热性能和动态力学性能 .实验结果表明 ,马来酸酐接枝的聚丙烯 (PP g MAH)作为PP和环氧树脂体系的增容剂 ,使分散相环氧树脂颗粒变细 ,增加了两组分的界面作用力 ,改善了共混物的力学性能 .与PP相比 ,动态固化PP 环氧树脂共混物具有较高的强度和模量 ,含 5 %环氧树脂的共混物拉伸强度和弯曲模量分别提高了 30 %和 5 0 % ,冲击强度增加了 15 % ,但断裂伸长率却明显降低 .继续增加环氧树脂的含量 ,共混物的拉伸强度和弯曲模量增加缓慢 ,冲击强度无明显变化 ,断裂伸长率进一步降低 .动态力学性能分析 (DMTA)表明动态固化PP 环氧树脂共混物是两相结构 ,具有较高的储能模量 (E′)     

电子束辐射固化环氧树脂的动态力学分析——树脂化学结构、分子量及其分布的影响

应用不同化学结构、分子量及其分布的环氧树脂进行了电子束辐射固化实验 ,对固化物进行了动态力学分析 ,研究了不同样品凝胶含量、内耗tanδ及动态模量的变化规律 .分析结果表明环氧树脂辐射反应活性与其化学结构有很大关系 ,酚醛型环氧树脂的辐射反应活性高 ,固化后高温模量及玻璃化温度较高 ,而脂环族环氧树脂反应活性小 .在低辐射剂量下 ,环氧树脂的固化度随分子量增大略有下降 ,但固化物的玻璃化温度随分子量增加而升高 .增大辐射剂量 ,树脂固化度的提高受分子量大小的影响很小 ,分子量较大样品的网络均匀程度有所提高 ,在较高反应程度下 ,玻璃化温度主要受固化度影响 .树脂固化程度也是决定其模量高低的主要因素 ,而在固化程度相近的情况下 ,分子量的影响作用很大 .在同样辐射剂量下 ,分子量分布宽的树脂固化反应程度高 ,但交联网络均匀性低 .     

含苯并噁唑环氧树脂的合成、固化动力学及热性能

通过两步法制备了两种含苯并噁唑结构的环氧树脂双苯并二噁唑型环氧(DAROH-O)树脂与双酚A型苯并噁唑环氧(HOH-O)树脂,采用红外光谱和氢核磁共振波谱分析对树脂的结构进行了表征。结果表明:当以二氨基二苯基甲烷(DDM)为固化剂时,对于DAROH-O/DDM体系,采用Kissinger法和Ozawa法计算得到的表观反应活化能分别为176.92kJ/mol和175.36kJ/mol;对于HOH-O/DDM体系,采用Kissinger法和Ozawa法计算得到的表观反应活化能分别为198.45kJ/mol和196.15kJ/mol。热重分析结果表明这两种环氧树脂固化物的耐热性能均远高于普通双酚A环氧树脂/DDM固化物的耐热性能。固化物的失重过程包括两个阶段,第一阶段的分解出现在350～370℃,第二阶段的分解发生在600℃左右,属于苯并噁唑环的分解。     

环氧树脂电子束固化过程中的电子能量传播机制

将环氧树脂辐射固化过程中的温度分布和辐射固化后的固化度分布与反应前的电子能量沉积模拟计算结果相结合, 探讨电子束在辐射固化过程中的能量传播机制. 结果表明, 辐射开始初期, 固化反应发生前, 电子能量在聚丙烯模具内环氧树脂体系中的沉积满足离子注入理论, 即电子能量沉积在距辐射表面一定距离处达到最大, 然后随辐射距离的增加沉积能量减小; 而在玻璃模具内的树脂体系中, 电子能量从辐射表面向里逐渐降低. 随体系中固化反应的发生, 最大电子浓度区域转移, 最终出现在临近最大电子沉积浓度区域辐射深度稍远的地方. 能量吸收和反应放热导致的升温不影响树脂固化度大小, 但会影响固化度分布.     

亲水性形状记忆环氧树脂制备及表面浸润性调控

采用聚乙二醇(PEG)对间苯二甲胺(MXDA)固化的TDE-85环氧树脂体系进行改性,制备了亲水性形状记忆环氧树脂,结合微形貌构筑和热响应方式对树脂表面浸润性进行智能调控.结果表明,PEG的引入有效地增加了TDE-85环氧树脂的亲水性.PEG的最佳含量为20%(质量分数)时,树脂表面的接触角为54°,实现了环氧树脂从原始TDE-85/MXDA固化体系表面的疏水性(接触角为108°)到TDE-85/MXDA/PEG固化体系表面亲水性的转变;改性后树脂的玻璃化转变温度Tg为71℃,形状固定率和回复率分别为96.10%和99.97%,表明得到的树脂具有良好的形状记忆性能.进一步采用模板法在树脂表面构筑了微阵列结构,基于形状记忆效应,通过对表面微阵列形态的控制,实现了环氧树脂表面介于亲水性(接触角为51°)与超亲水性(接触角为0°)间的可逆浸润性智能调控.     

2－乙基－4－甲基咪唑固化环氧树脂的固化反应机理、动力学及其反应活性

本文应用ＤＳＣ和ＦＴＩＲ对２－乙基－４－甲基咪唑固化双酚Ａ二缩水甘油醚型环氧树脂体系的固化反应机理和２－乙基－４－甲基咪唑固化双酚Ａ二缩水甘油醚型、缩水甘油酯与脂环型环氧树脂体系的固化反应特征、动力学及其反应活性进行了研究．结果表明，双酚Ａ二缩水甘油醚型环氧树脂／咪唑体系的固化反应是分两步独立进行的，第一步是加成反应，第二步是催化聚合反应．缩水甘油酯与脂环型环氧树脂（ＴＤＥ－８５）／咪唑体系的固化反应过程也分两步进行，第一阶段反应主要是缩水甘油酯型环氧基进行的加成反应和催化聚合反应，第二阶段主要是脂环型环氧基进行的加成反应．各体系第一阶段的表现反应活化能均低于第二阶段活化能．当ＴＤＥ－８５型环氧树脂中引入缩水甘油醚型环氧树脂后，固化反应速率均较ＴＤＥ－８５环氧树脂单独固化时快．     

Towards the development of self-healing carbon/epoxy composites with improved potential provided by efficient encapsulation of healing agents in core-shell nanofibers

A self-healing carbon/epoxy composite was fabricated with the incorporation of healing agent loaded core-shell nanofibers between carbon fiber fabric layers. The healing agents, consisting of two components, a low viscosity epoxy resin and its amine-based curing agent, were encapsulated in Styrene acrylonitrile (SAN) nanofibers via a coaxial electrospinning method. Transmission electron microscope (TEM), Fourier Transform Infrared (FTIR), and thermogravimetric analysis (TGA) results confirmed the successful encapsulation of both epoxy and curing agent in SAN nanofiber shells. TGA and the extraction method confirmed a high encapsulation yield (90% for the epoxy resin and 97% for the curing agent). Mechanical studies of the hybrid composite showed that embedding the fabricated core-shell nanofibers did not lead to a reduction in the mechanical properties of host composite, which was corroborated with statistical analysis. Mechanical evaluations and curing behavior studies both showed that incorporation of the aforementioned nanofibers between carbon layers can imbue the conventional carbon/epoxy composite with a self-healing ability, allowing it to repair itself to restore its mechanical properties for up to three cycles at room temperature in absent of any external driving force.     

含联苯结构的环氧树脂固化性能的研究

以3,3′,5,5′-四甲基联苯二酚为单体,合成了一种含联苯结构的环氧树脂.用DDM和DDS为固化剂对环氧树脂的固化性能进行了研究,发现与双酚A型环氧树脂相比,含有联苯结构的环氧树脂具有更好的耐热性,同时在耐湿性方面也有很大改进.     

Percolation in carbon black filled epoxy resin

The conditions to form a conductive network in carbon black filled epoxy resin were examined. It was found that the formation is controlled by particle-particle interaction which can be influenced by shear forces or by the ionic concentration of the resin. Therefore the network morphology and thus the percolation threshold depends strongly upon the processing route. On best conditions the percolation threshold was reduced to 0.06 vol.-%. That a continuous network can form with such a low volume fraction can be explained by the fractal dimension of agglomerates the network is made of.     

Effect of Non-Woven Carbon Nanofiber Mat Presence on Cure Kinetics of Epoxy Nanocomposites

Summary : An investigation was carried out into the cure kinetics of carbon nanofiber (CNF) mat-epoxy nanocomposites, composed of bisphenol-A based epoxy resin and diethylene triamine as a curing agent. It was observed that the rate of cure reaction for CNF mat-epoxy nanocomposites was higher than that for neat epoxy resin at low curing temperatures and the presence of the CNF mat produced the maximum influence at a certain curing temperature and time. At high curing temperature and long curing times, the effect of CNF mat on the cure rate was insignificant. The CNF mat-epoxy composite exhibited somewhat lower value of activation energy than that of the neat epoxy system at the beginning of the curing stage. The weight fraction of CNF mat also affected the cure reaction of epoxy nanocomposites at the same curing temperature. As the amount of CNF mat increased, the cure rate was higher at the same cure time. However, at high CNF mat loading, the cure reaction was retarded since the amount of epoxy and hardener decreased dramatically at high CNF contents together with the hindering effect of the CNF mat on the diffusion of epoxy resin and the curing agent, leading to lower crosslinking efficiency. Although the curing efficiency of epoxy nanocomposites dropped at high CNF mat content, the glass transition temperature (T_g) was still high due to the ultra-high strength of the CNF mat. The cure kinetics of CNF mat-epoxy nanocomposites was in good agreement with Kamal's model.     

Synthesis of raspberry-like monodisperse magnetic hollow hybrid nanospheres by coating polystyrene template with Fe(3)O(4)@SiO(2) particles

A new inorganic/organic hybrid material containing silsesquioxane was prepared by the reaction of caged octa (aminopropyl silsesquioxane) (POSS-NH(2)) with n-butyl glycidyl ether (nBGE) and 1,4-butanediol diglycidyl ether (BDGE). The copolymers of POSS, nBGE, and BDGE could be obtained with varied feed ratio of POSS-NH(2), nBGE, and BDGE in the preparation. The hybrid material was added into an epoxy resin (E51) for enhancing the toughening and thermal properties of the epoxy resin. The results showed that the toughening and the thermal properties of the cured epoxy resin were greatly improved by the addition of the hybrid. The enhancement was ascribed to nano-scale effect of the POSS structure and the formation of anchor structure in the cured network. The investigation of kinetics for the curing process of the hybrid-modified epoxy resin revealed that two kinds of curing reactions occurred in different temperature ranges. They were attributed to the reactions between amino groups of the curing agent with epoxy groups of E51 and with residue epoxy groups in the hybrid. The reacting activation energies were calculated based on Kissinger's and Flynn-Wall-Ozawa's methods, respectively.     

升温与等温法非模型动力学研究环氧树脂固化反应

基于DSC数据,采用以Vyazovkin积分法为基础的升温法非模型动力学和等温法非模型动力学对双酚A型环氧树脂E51/4,4′-二氨基二苯基砜(DDS)体系及多官能度环氧树脂AG80/DDS体系的固化过程进行了研究,并结合玻璃化转变温度的变化和原位红外测试技术,对比分析了升温与等温条件下的固化反应规律.结果表明,与传统的模型拟合法相比,非模型动力学更适合定量预测树脂固化反应过程,并能为固化过程中反应机理变化的研究提供重要依据;等温法非模型动力学能够更好地预测两种树脂体系在不同恒温条件下的固化反应历程,并且升温法与等温法非模型动力学所得到的反应活化能-固化度之间的变化关系不同,表明不同温度条件下树脂的反应机理不同,这与升温和恒温条件下玻璃化效应及环氧官能团的变化规律相吻合.     

Toughening of a trifunctional epoxy system: IV. Dynamic mechanical relaxational study of the thermoplastic-modified cure process

Dynamic mechanical spectroscopy has been used to investigate the cure of a thermoplastically modified trifunctional epoxy resin. The complex dissolution, curing behavior, and variations in the glass transition of the thermoplastic (PSF) phase were described, as was the T_g behavior of the epoxy phase. Prereaction of the PSF material with the epoxy resin was found to greatly increase the solubility of the PSF in the epoxy phase with little effect on the concentration of the epoxy monomer dissolving in the PSF phase. The curing behavior of the epoxy component in the thermoplastic phase was also investigated, in addition to changes in the mobility of the network at both gelation and vitrification. © 1997 John Wiley & Sons, Inc.