苯并噁嗪改性液体成型环氧树脂的研究

采用具有低固化收缩特性的苯并噁嗪树脂(benzoxazine,BOZ)对液体成型环氧树脂进行改性,以期在不改变液体成型树脂耐热性、工艺性及力学性能的前提下,大幅度降低树脂的固化收缩率.对比研究了不同BOZ含量改性树脂的固化收缩特性、固化反应特性、液体成型工艺性及力学性能.并采用真空辅助树脂浸渗(vacuum assisted resin infusion,VARI)工艺制备了单向碳纤维织物增强复合材料,研究了复合材料的力学性能.结果表明,加入BOZ对液体成型树脂的反应性、工艺性及耐热性影响不大,改性树脂的固化收缩随BOZ含量的提高逐渐减小,其中BOZ质量分数为15 wt%的改性树脂,较未改性树脂的固化收缩减小约80%,拉伸强度提高约19%,冲击强度提高约148%.以此改性树脂作为基体的复合材料相对于未改性树脂复合材料的拉伸强度提高约23%,层间剪切强度提高约9%,具有良好的力学性能和界面结合性能.     

交联聚乙烯/蒙脱土纳米复合物空间电荷特性研究

以十八烷基氯化铵处理的有机化蒙脱土(O-MMT)为无机纳米相,以低密度聚乙烯(LDPE)作为基体聚合物,以马来酸酐接枝聚乙烯(PEMA)为相容剂,以双叔丁基过氧化二异丙基苯BIPB为交联剂,通过熔融插层复合后再进行化学交联的"两步法",制备了交联聚乙烯/有机化蒙脱土(XLPE/O-MMT)纳米复合物.利用电声脉冲法(PEA)试验研究了不同蒙脱土含量的XLPE/O-MMT纳米复合物的空间电荷特性.实验结果表明,与纯XLPE相比,含一定比例O-MMT的XLPE/O-MMT纳米复合物具有不同程度抑制空间电荷的能力.当O-MMT含量为0.5%～1%时,其纳米复合物的空间电荷量最小;在O-MMT含量为3%～7%的范围内,随O-MMT含量的增加,XLPE/O-MMT纳米复合物中空间电荷量逐渐增大,但仍低于纯XLPE中的空间电荷量.通过热激电流(TSC)实验证实,与XLPE相比,XLPE/O-MMT纳米复合物的TSC峰均不同程度地向高温方向偏移,说明纳米复合材料的陷阱深度增加.当O-MMT含量为1 wt%时,TSC曲线所包围的面积最小,相应地,其陷阱密度最小;而随着O-MMT含量的增加,XLPE/O-MMT纳米复合物的TSC曲线所包围面积逐渐增大,说明其陷阱密度有所增加.绝缘电导率的试验结果进一步支持了上述观点.     

悬浮缩聚法制备酚醛树脂/蒙脱土纳米复合材料

采用悬浮缩聚方法在酸性催化剂作用下制备了酚醛树脂/蒙脱土纳米复合材料。以三种不同的蒙脱土：天然土、带有脂肪链季铵盐修饰蒙脱土和带有苯环基团的插层剂修饰的蒙脱土为原料制备了纳米复合材料,并考察了不同插层剂对纳米复合材料形貌的影响,发现带有苯环的插层剂修饰的蒙脱土与酚醛树脂的相容性能更好;研究了固化过程对纳米复合材料形貌的影响,XRD和TEM的结构表明固化过程可以促进带有脂肪链季铵盐修饰的蒙脱土进一步剥离,对其他两类的影响不大;此外还用TGA研究了纳米复合材料的热性能。     

对炔丙氧基苯基噁唑啉的合成及改性苯并噁嗪树脂的研究

通过四步法合成了对炔丙氧基苯基噁唑啉(p-propynyloxyphenyl-2-oxazoline简称POPO),采用核磁共振氢谱(1H-NMR)、傅立叶红外光谱(FTIR)、气相色谱质谱联用仪(GC-MS)和元素分析证实了其分子结构,以示差扫描量热仪(DSC)和热重分析(TGA)揭示了其固化行为和热分解性质,该化合物熔点为120℃,起始固化温度为200℃,固化峰值温度为280℃,自固化产物5 wt%热失重温度为321℃.在此基础上,通过溶液共混法制备了双酚A型苯并噁嗪(BZ)/对炔丙氧基苯基噁唑啉(POPO)共聚树脂,且对其固化机理、固化产物的热分解性质和动态力学性能进行考察.结果表明,该噁唑啉作为交联剂,与苯并噁嗪发生开环聚合和自身炔基发生三聚成环反应,使固化产物的交联密度增加,DSC、TG和动态热机械分析(DMA)表明噁唑啉的引入提高了固化树脂的热性能和动态力学性能.且在噁唑啉含量为10 wt%时,固化树脂的综合性能较优,较之纯的双酚A型苯并噁嗪树脂,起始固化温度从215℃降低至180℃,残碳率从28%提高至44%,玻璃化转变温度从166℃提高至186℃.     

高岭石-硬脂酸插层复合物的制备及结构模型的提出

以张家口高岭土为原料,通过直接插层与取代相结合的方法制备高岭石-硬脂酸插层复合物。利用X射线粉末衍射、红外光谱、热重及透射电子显微镜对制备产物进行表征。结果表明:硬脂酸插入到高岭石层间,高岭石层间距d001值由0.72 nm增加到4.05~4.37 nm,插层率达到86.9%;反应时间和溶液p H值会对高岭石-硬脂酸插层复合物的层间距及插层率产生影响;甲氧基嫁接在高岭石表面,与硬脂酸分子同时存在于高岭石层间。高岭石经甲醇改性后脱羟基温度明显降低,高岭石羟基活性提高;高岭石-硬脂酸插层复合物的稳定温度在160℃以下。经过硬脂酸插层改性后的高岭石片层,从边缘开始出现卷曲现象,并且部分长条状片层形成类似埃洛石相的纳米卷;对硬脂酸插层高岭石的作用机理进行分析,结合结构计算,提出高岭石-硬脂酸插层复合物的结构模型,该模型可以解释高岭石-硬脂酸插层复合物在不同条件制备产物层间距变化的原因。     

混合条件对环氧有机土纳米复合材料插层剥离行为及性能的影响

采用X 射线衍射仪、透射电镜 (TEM )研究了混合条件 ,即混合温度和时间 ,对环氧 /16 烷基胺有机蒙脱土体系在固化前的混合物以及加入固化剂、促进剂固化后有机土的插层与剥离行为的影响 .同时采用拉伸试验机、冲击试验机和热机械分析仪测定了插层与剥离型纳米复合材料的物理力学性能 .从X 射线衍射看出 ,有机土很容易在混合过程被环氧所插层 .混合物经固化后可以形成插层型或剥离型纳米复合材料 .存在一个混合温度 时间 插层剥离转变的 3 T图 .只有在一定的混合条件的区域内才能形成剥离型纳米复合材料 .剥离型比插层型纳米复合材料具有较高的力学性能     

丙烯酸树脂／蒙脱土纳米复合材料的制备研究

采用离子交换法,用十六烷基三甲基溴化铵对钠基蒙脱土(Na-MMT)进行改性制备了有机蒙脱土(OMMT).用丙烯酸(AA)、硫酸化蓖麻油、乳化剂OP-10、过硫酸钾为原料进行水溶液聚合制得丙烯酸树脂.将丙烯酸树脂与改性蒙脱土通过聚合插层制备了丙烯酸树脂/ 蒙脱土纳米复合材料.通过傅立叶变换红外(FTIR)和X-射线衍射 (XRD)等手段对复合材料的结构进行了表征,结果表明:丙烯酸树脂插层进入有机蒙脱土内可形成插层型或剥离型的纳米复合材料.蒙脱土含量及蒙脱土与丙烯酸树脂的反应温度、反应时间均对复合材料的剥离行为产生影响,在蒙脱土含量为树脂固含量的7%、温度为70℃、反应4h的条件下可得到完全剥离的纳米复合材料.     

热致可逆变色的聚二炔／稀土离子纳米复合物

将Dy^＋或Sm^＋掺杂到具有层状结构的10,12-二十五碳二炔酸（PCDA）纳米粒子中,得到二炔酸／稀土离子（PCDA-RE）纳米复合物．随后在稍微高于二炔酸熔点的温度下对PCDA—RE纳米复合物进行退火处理,退火后的PCDA—RE纳米复合物发生拓扑聚合反应得到聚二炔酸／稀土离子（PDA-RE）纳米复合物．虽然纯聚二炔酸的热致变色过程是不可逆的,但是PDA—Sm纳米复合物和PDA-Dy纳米复合物分别具有不完全和完全热致可逆变色的性能．研究表明,PDA-RE纳米复合物的层间距为5,4nm,比纯聚二炔酸的层间距（4．7nm）要大．对于PDA—RE纳米复合物,稀土离子和聚二炔酸之间的强相互作用是纳米复合物实现大部分或完全可逆变色的原因．同时退火处理对实现聚二炔酸可逆变色非常重要,因为退火处理消除了材料结构中的所有缺陷,最终促使材料具有热致可逆变色性能．     

高岭石-硬脂酸插层复合物的制备及结构模型的提出

以张家口高岭土为原料,通过直接插层与取代相结合的方法制备高岭石-硬脂酸插层复合物.利用 X射线粉末衍射、红外光谱、热重及透射电子显微镜对制备产物进行表征.结果表明:硬脂酸插入到高岭石层间,高岭石层间距d₀₀₁值由0.72 nm增加到4.05~4.37 nm,插层率达到86.9%;反应时间和溶液pH值会对高岭石-硬脂酸插层复合物的层间距及插层率产生影响;甲氧基嫁接在高岭石表面,与硬脂酸分子同时存在于高岭石层间.高岭石经甲醇改性后脱羟基温度明显降低,高岭石羟基活性提高;高岭石-硬脂酸插层复合物的稳定温度在160 ℃以下.经过硬脂酸插层改性后的高岭石片层,从边缘开始出现卷曲现象,并且部分长条状片层形成类似埃洛石相的纳米卷;对硬脂酸插层高岭石的作用机理进行分析,结合结构计算,提出高岭石-硬脂酸插层复合物的结构模型,该模型可以解释高岭石-硬脂酸插层复合物在不同条件制备产物层间距变化的原因.     

新疆水黑云母及其HDTMA 插层复合物的红外光谱研究

采用傅立叶转换红外光谱(FTIR)研究了新疆尉犁蛭石矿出产的水黑云母(HB)以及经十六烷基三甲基铵阳离子(HDTMA )插层后形成的HDTMA-HB复合物的红外吸收特征.结果表明,新疆水黑云母红外吸收主要可分为3个区域,同时具有蛭石和金云母的特征吸收峰;十六烷基三甲基铵离子能够插层进入水黑云母的蛭石晶层形成HDTMA-HB复合物,该复合物的红外吸收特征为HDTMA 和水黑云母吸收的结合体,只是某些特征吸收峰的峰位发生了不同程度的漂移;有机分子以类液态的形式存在于水黑云母层间;复合物中水的吸收峰仍然很强.     

液晶环氧树脂/蒙脱土纳米复合材料的制备和固化反应动力学研究

用带有介晶基元的联苯二酚二缩水甘油醚 (BP)、4 氨基苯基磺酰胺 (SAA)和有机化蒙脱土 (93A)采用浇铸成模固化成型的方法制备出液晶环氧树脂 蒙脱土纳米复合材料 .WRXD结果表明 93A含量是 2 %时可形成剥离型纳米材料 ,而当 10 %时形成插层型纳米材料 ,5 %时则形成剥离和插层混合型的纳米材料 ;POM结果表明蒙脱土的存在能够破坏原有的扇形近晶相液晶织构 .DSC研究表明体系的固化反应动力学 ,可用变形的Kissinger Akahira Sunose法 (VKAS)表征 ,从求出的反应活化能和转化率关系 ,发现反应初期 ,蒙脱土使反应活化能降低 ,能够促进液晶环氧树脂的固化 .     

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.     

一种用于快速成型工艺的红光光敏树脂的性能研究

合成了一种吸收波长为 6 80nm的菁染料 有机硼盐复合物光引发剂CDBC ,以 6 80nm激光二极管发射的激光作为光源 ,研究了由CDBC、EA6 12、POTMPTA组成的红光光敏树脂在快速成型工艺中的应用 ,考察了影响树脂几个主要性能即粘度、光固化速度、体积收缩率的因素 .结果表明 ,EA6 12含量高 ,POTMPTA含量低 ,树脂粘度大 ,体积收缩率小 ;相反 ,EA6 12含量低 ,POTMPTA含量高 ,则树脂粘度低 ,体积收缩率大 ;光引发剂CDBC含量 5 %以内时对树脂粘度和体积收缩率没有影响 ,CDBC含量增加 ,树脂的表固速度加快 ,但当CDBC含量大于 3%时 ,表固速度基本不变 .预聚物EA6 12质量分数 70 % ,单体POTMPTA质量分数 2 7% ,光引发剂CDBC质量分数 3%时 ,树脂粘度为 4 2 0mPa·s ,表固时间为 1 0s ,固化体积收缩率为 4 0 % ,具有较好的综合性能 .     

POP-290阻燃剂对丙烯酸酯光固化涂料的影响

制备了双酚A环氧丙烯酸酯(EA)/阻燃剂(POP-290,聚合物聚醚多元醇)/活性单体阻燃UV涂料,主要考察了不同用量的阻燃剂对丙烯酸酯UV涂料的阻燃性能和光固化的影响.研究结果表明,阻燃剂的使用提高了UV涂料体系的固化速度、凝胶含量及玻璃化转变温度(T_g).当m(EA):m(活性单体)=4:1,POP-290含量为7%(质量分数)时,水平燃烧等级达到FH-1,LOI从原来的21提高到26.     

4,4'-二氨基二苯醚二苯酮固化环氧树脂/粘土纳米复合材料的研究

采用离子交换法, 用十六烷基三甲基溴化铵处理钙基蒙脱土(MMT), 使蒙脱土的层间距由1.49 nm扩大到2.21 nm, 制备了环氧树脂/ BADK/MMT纳米复合材料, 并用XRD等手段研究了有机蒙脱土在环氧树脂中的插层及剥离行为. 研究结果表明, 蒙脱土含量及环氧树脂与有机土的混合温度和时间均对固化后复合材料的剥离产生影响, 只有在特定条件下才能得到剥离型纳米复合材料.     

SYNTHESIS, CHARACTERIZATION AND PROPERTIES OF ORGANOCLAY-MODIFIED POLYSULFONE/EPOXY INTERPENETRATING POLYMER NETWORK NANOCOMPOSITES

Organoclay-modified hydroxylterminated polysulfone (PSF)/epoxy interpenetrating network nanocomposites (oM-PSF/EP nanocomposites) were prepared by adding organophilic montmorillonite (oMMT) to interpenetrating polymer networks (IPNs) of polysulfone and epoxy resin (PSF/EP) using diaminodiphenylmethane (DDM) as curing agent.The mechanical properties like tensile strength,tensile modulus,flexural strength,flexural modulus and impact properties of the nanocomposites were studied as per ASTM standards.Differ...     

Preparation and properties characterization of gallic acid epoxy resin/succinic anhydride bionanocomposites modified by green reduced graphene oxide

Graphene oxide was reduced into reducing-graphene oxide (r-GO) successfully using gallic acid (GA) as a green reducing agent. Biobased gallic acid epoxy resin (GAER) was synthesized from renewable GA, and the biobased GAER/r-GO nanocomposites and glass fiber-reinforced composites were prepared with succinic anhydride as a curing agent. The dynamic mechanical, thermal, and mechanical properties of the composites with varying r-GO contents were characterized. When the content of r-GO was 0.5 wt%, the glass transition temperature was 10.4°C higher than the pure resin system. The thermal and mechanical properties were increased with increasing r-GO content; when the r-GO content was 1.0 wt%, the initial degradation temperature was enhanced by approximately 6.8°C, the tensile and impact strengths were 34.5% and 49.1% higher, respectively, than the pure cured GAER. The impact strength of GAER was higher than that of the bisphenol A epoxy resin/SUA curing system, but the tensile strength was lower than it.     

PMMA/黑云母纳米复合材料的制备及表征

采用乳液聚合法制备了聚甲基丙烯酸甲酯 黑云母 (PMMA VMT)纳米复合材料 ,其中的黑云母经甲基丙烯酰氧乙基三甲基氯化铵有机改性 ,所得复合材料经XRD、FT IR、DSC、TG等测试结果证明云母已经被有效的剥离 ,复合材料的耐热性能、玻璃化转变温度 (Tg)比PMMA都有所提高 ,但聚合反应速率有所下降 ,复合材料中可萃取的聚合物粘均分子量升高 .     

Synthesis of a novel benzoxazine monomer‐intercalated montmorillonite and the curing kinetics of polybenzoxazine/clay hybrid nanocomposites

Polybenzoxazine (PBZ), which has a structure similar to that of phenolic resin, is formed through the thermal self‐curing of benzoxazine, that is through a heterocyclic ring opening reaction that requires no catalyst and releases no condensation byproducts. We have used the solvent blending method to prepare PBZ/clay nanocomposites possessing various clay contents. We synthesized a monofunctional benzoxazine monomer (MBM) and then treated the clay with this intercalation agent. The results of X‐ray diffraction (XRD) analysis indicated that MBM intercalated into the galleries of the clay; the nanocomposite possessed an exfoliated structure at 3% clay content. To better understand the curing kinetics of the PBZ/clay nanocomposites, we performed dynamic and isothermal differential scanning calorimetry (DSC) measurements. We describe the thermodynamics of the curing process, using all three of the Kissinger, Ozawa, and Kamal models. The Kissinger and Ozawa methods gave fairly close results for the calculated activation energies, which decreased upon increasing the clay content. The Kamal method, based on an autocatalytic model, suggested a total reaction order of between 2.4 and 2.8. The glass transition temperature (T_g) decreased upon increasing the clay content. Thermogravimetric analysis (TGA) indicated that the nanocomposites have higher decomposition temperatures than does the pristine PBZ; this finding suggests an enhancement in their thermal stability. © 2005 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 44: 347–358, 2006     

Processable and Robust MoS2 Paper Chemically Cross‐Linked with Polymeric Ligands by the Coordination of Divalent Metal Ions

Inorganic graphene analogues (IGAs) are a huge and fascinating family of compounds that have extraordinary electronic, mechanical, and thermal properties. However, one of the largest problems that face the industrial application of IGAs is their poor processability, which has led to a “bottlenecking” in the development of freestanding, large‐area, IGA‐based thin‐film devices. Herein, we report a facile and cost‐efficient method to chemically modify IGAs by using their abundant coordination atoms (S, O, and N). Taking MoS₂ as an example, we have prepared homogeneous “solution” systems, in which MoS₂ nanosheets are chemically cross‐linked through a carboxylate‐containing polymeric ligand, poly(methyl methacrylate) (PMMA), by copper‐ion coordination. Bonding interactions between C?O bonds and sulfur atoms through copper ions were confirmed by various characterization techniques, such as UV/Vis, FTIR, and Raman spectroscopy and XPS. By using our method, freestanding MoS₂ paper with significantly improved mechanical properties was obtained, thus laying the basis for the mass production of large‐area MoS₂‐based thin‐film devices. Furthermore, copper‐ion coordination was also applied to MoS₂/PMMA nanocomposites. Direct and strong nanofiller/matrix bonding interactions facilitate efficient load transfer and endow the polymeric nanocomposites with an excellent reinforcement effect. This method may pave a new way to high‐strength polymeric nanocomposites with superior frictional properties, flame retardance, and oxidation resistance.