静电纺丝技术制备聚苯乙烯/石墨烯复合纳米纤维

通过静电纺丝技术制备了聚苯乙烯/石墨烯复合纳米纤维膜,利用扫描电子显微镜、傅里叶变换红外光谱、粉末X-射线衍射和激光拉曼光谱等技术对所制备的纤维膜结构和组成进行表征,并通过电化学法考察该复合纳米纤维膜的电活性。结果表明,石墨烯已掺杂到聚苯乙烯纤维中。与聚苯乙烯纤维膜相比,聚苯乙烯/石墨烯复合纳米纤维膜导电性能增强,表明本实验成功实现了对聚苯乙烯纤维的改性。     

聚苯乙烯/层状双金属氢氧化物纳米复合材料的制备与表征

由离子交换法制备4,4′-偶氮二(4-氰基戊酸)根(ACP)单独插层和ACP/对苯乙烯磺酸根(VBS)复合插层的层状双金属氢氧化物(LDH),再通过原位悬浮聚合制得聚苯乙烯(PS)/LDH纳米复合材料,对插层改性LDH和复合材料进行了结构和性能表征.X-射线衍射和元素分析表明ACP可以单独或与VBS一起插入到LDH层间.透射电镜和X-射线衍射分析表明采用ACP/VBS复合插层LDH与苯乙烯原位聚合得到的复合材料中LDH剥离程度高,熔融加工后LDH基本以纳米层板形式分散在PS基体中.LDH的引入可明显提高PS的热稳定性,而熔体流动性下降.     

纳米氧化硅表面阴离子接枝聚合苯乙烯

通过正丁基锂(BL)引发甲基丙烯酰氧丙基纳米氧化硅(MAMSN)与苯乙烯共聚，制备了聚苯乙烯表面接枝纳米氧化硅(PS—g—Silica)，并考察了正丁基锂加入量对苯乙烯转化率(C)、接枝率(PG)以及聚苯乙烯分子量(Mn)的影响。实验结果表明，阴离子聚合可以获得比自由基聚合更大的分子量和更高的转化率以及接枝率。     

sPS/PA6/蒙脱土纳米复合材料的制备与性能

讨论了间规聚苯乙烯 (sPS) 尼龙 6(PA6) 磺化间规聚苯乙烯 (SsPS H) 蒙脱土纳米复合材料的制备技术和新材料的结构与性能特征 .蒙脱土经层间改性处理后 (MTN) ,可分别将SsPS H和aPS(无规聚苯乙烯 )插入其纳米层间 ,制备出插层型纳米复合物MTN SsPS和MTN aPS .在sPS/PA6/SsPS H三组分共混体系中加入MTN SsPS或MTN aPS ,进行四组分熔融共混即可制备出sPS/PA6/SsPS H/蒙脱土纳米复合材料 .TEM测定证实了蒙脱土在基体中的层厚分布约为 5 0nm .此外 ,采用DSC、DMA、XRD及力学性能测试仪等现代分析方法对sPS/PA6/SsPS H/蒙脱土纳米复合材料的结构与性能进行了详细研究 .研究结果表明这种纳米复合材料具有优良的综合性能     

纳米SiO2对火焰喷涂聚酰胺12涂层非等温结晶与熔融行为的影响

采用火焰喷涂法制备了聚酰胺12/纳米SiO2(PA12/nano-SiO2)复合涂层,利用差示扫描量热法(DSC)对复合涂层的非等温结晶过程、熔融行为进行了分析.结果表明:纳米SiO2粒子的加入不仅能提高复合涂层的结晶度和结晶温度,而且使复合涂层的熔融峰温度高于纯PA12涂层,说明纳米SiO2粒子具有明显的成核剂作用,它能诱导聚酰胺大分子结晶,提高其结晶能力、结晶速率、结晶的完善程度及结晶度,并能改善涂层的力学、耐老化及耐摩擦磨损性能.     

MWCNTs/PVA-co-PE纳米纤维膜导电性能的研究

通过原位自组装法制备MWCNTs/PVA-co-PE复合材料,将此复合材料与纤维素酯共混后,利用热塑性聚合物熔融共混相分离法制备了MWCNTs/PVA-co-PE复合纳米纤维。通过SEM和TEM分析表征了MWCNTs/PVA-co-PE复合纳米纤维的形态、结构以及多壁碳纳米管在纳米纤维中的分布状态;研究了多壁碳纳米管添加量对MWCNTs/PVA-co-PE复合纳米纤维导电性能的影响。结果表明,当多壁碳纳米管的添加量大于6%时,MWCNTs/PVA-co-PE复合材料的表面电阻会显著下降;提高MWCNTs的添加量会使MWCNTs/PVA-co-PE复合纳米纤维的表面电阻稍微下降,但是效果不大,这可能是由于MWCNTs在纳米纤维内部不能形成良好的导电通道。     

石墨烯/二氯化镁负载钛系齐格勒-纳塔催化剂制备及其乙烯聚合性能

石墨烯自2004年发现以来,由于其独一无二的优异性迅速成为科学家们的研究热点.由于石墨烯具有极其优异的电学、力学和热学等性能,因此被广泛应用于高性能聚合物基复合材料的制备.众所周知,纳米填料在聚合物中的分散状态以及与基体间的界面作用是构筑高性能聚合物纳米复合材料的关键因素.由于石墨烯极易团聚,难以通过传统的熔融共混法制备均匀分散的石墨烯增强-聚烯烃纳米复合材料.另一方面,聚烯烃通常需要在较高温度下才能溶于部分有毒溶剂(如:三氯苯和二甲苯等),因此溶液共混法也不适用于聚烯烃-石墨烯纳米复合材料的制备.有鉴于此,本文开发了一种共沉积法制备石墨烯/二氯化镁负载钛系齐格勒-纳塔催化剂的路线.通过原位聚合直接制备出石墨烯均匀分散的聚烯烃/石墨烯纳米复合材料.考察了石墨烯的加入量对催化剂形态及其催化乙烯聚合行为的影响.当石墨烯加入量较低时,多个石墨烯片被包裹于较大的催化剂粒子中.随着石墨烯加入量的增加,催化剂趋向于在石墨烯表面聚集.继续增加石墨烯量将导致石墨烯包裹催化剂粒子,降低过渡金属钛的负载效率.通过三乙基铝活化后,所制备的催化剂具有非常高的乙烯催化活性,所生成的聚乙烯/石墨烯纳米复合材料复制了催化剂的片状结构.同时,通过对所制备的聚乙烯/石墨烯纳米复合材料进行电子显微镜和X射线衍射分析可知,石墨烯均匀分散于聚乙烯基体中,并且没有任何团聚现象发生.该复合材料的热重分析表明,仅加入非常少量的石墨烯就可以使其具有比纯聚乙烯更高的热稳定性,当石墨烯加入量为0.66 wt%时,其5 wt%热分解温度较纯聚乙烯升高了54°C.同时,所制备聚乙烯/石墨烯纳米复合材料具有更优异的机械性能.因此,本研究提供了一个简单高效的高性能聚烯烃/石墨烯纳米复合材料的制备方法.     

石墨烯/二氯化镁负载钛系齐格勒-纳塔催化剂制备及其乙烯聚合性能（英文）

石墨烯自2004年发现以来,由于其独一无二的优异性迅速成为科学家们的研究热点.由于石墨烯具有极其优异的电学、力学和热学等性能,因此被广泛应用于高性能聚合物基复合材料的制备.众所周知,纳米填料在聚合物中的分散状态以及与基体间的界面作用是构筑高性能聚合物纳米复合材料的关键因素.由于石墨烯极易团聚,难以通过传统的熔融共混法制备均匀分散的石墨烯增强-聚烯烃纳米复合材料.另一方面,聚烯烃通常需要在较高温度下才能溶于部分有毒溶剂(如:三氯苯和二甲苯等),因此溶液共混法也不适用于聚烯烃-石墨烯纳米复合材料的制备.有鉴于此,本文开发了一种共沉积法制备石墨烯/二氯化镁负载钛系齐格勒-纳塔催化剂的路线.通过原位聚合直接制备出石墨烯均匀分散的聚烯烃/石墨烯纳米复合材料.考察了石墨烯的加入量对催化剂形态及其催化乙烯聚合行为的影响.当石墨烯加入量较低时,多个石墨烯片被包裹于较大的催化剂粒子中.随着石墨烯加入量的增加,催化剂趋向于在石墨烯表面聚集.继续增加石墨烯量将导致石墨烯包裹催化剂粒子,降低过渡金属钛的负载效率.通过三乙基铝活化后,所制备的催化剂具有非常高的乙烯催化活性,所生成的聚乙烯/石墨烯纳米复合材料复制了催化剂的片状结构.同时,通过对所制备的聚乙烯/石墨烯纳米复合材料进行电子显微镜和X射线衍射分析可知,石墨烯均匀分散于聚乙烯基体中,并且没有任何团聚现象发生.该复合材料的热重分析表明,仅加入非常少量的石墨烯就可以使其具有比纯聚乙烯更高的热稳定性,当石墨烯加入量为0.66 wt%时,其5 wt%热分解温度较纯聚乙烯升高了54℃.同时,所制备聚乙烯/石墨烯纳米复合材料具有更优异的机械性能.因此,本研究提供了一个简单高效的高性能聚烯烃/石墨烯纳米复合材料的制备方法.     

一步聚合法制备壳核型、可控阶层结构的羰基铁/聚苯乙烯复合微球

采用改进的悬浮聚合法合成了一系列粒径和结构可调的羰基铁粉/聚苯乙烯磁性高分子微球.利用傅立叶变换红外光谱仪、热重分析仪、X射线衍射仪、扫描电镜等分析了微球的结构、化学成分及形貌.结果表明,通过改变苯乙烯单体和聚乙烯醇(PVA)的加入量,可以制备三类不同形貌和结构的复合微球,即多孔复合微球,无孔复合微球和含"带状"突起的...     

高芯材含量聚苯乙烯石蜡微胶囊的制备及性能研究

为解决石蜡在使用过程中的一系列问题,以聚苯乙烯为壁材,58~#石蜡为芯材,采用悬浮聚合法制备了高芯材含量的微胶囊.考察了二己烯基苯(DVB)用量、芯壁比、复合改性时共聚单体种类和用量对微胶囊的影响.采用FT-IR、SEM、DSC、TG表征了微胶囊的结构、形貌、储热性能及热稳定性能.实验结果表明,DVB用量11%、芯壁比3∶1制备的微胶囊大小均匀,无团聚现象;交联改性的同时,加入20%MA单体共聚改性制备的微胶囊形貌好,热稳定性最佳,微胶囊中石蜡含量为91.7%时储热性能最优.     

The toughness amplification map of poly(vinyl chloride) and its cellulose acetate‐compatibilized starch alloys containing core/shell rubber particles: Possible transition to super‐toughening

Toughening amplification of the neat poly(vinyl chloride) (PVC) and its reinforced version containing 25 phr of the cellulose acetate (CA)‐compatibilized starch using methyl methacrylate‐butadiene‐styrene (MBS) core–shell particles was studied. The room temperature measured impact strength of the PVC showed mild increase up to 10 wt % with the addition of MBS particles. Then, the toughness enhanced discontinuously to super‐tough plateau regime. The room temperature measured impact strength of PVC containing 20 phr of MBS particles, however, was reduced by as much as 95% when it was filled with 25 phr of the CA‐compatibilized starch. In addition, the brittle–ductile transition (BDT) of the toughened PVC increased from 0 to 60 °C because of its reinforcement, even though the matrix number density of the core/shell particles remained almost constant. The decline in the impact strength and the rise in the BDT of the hybrid PVC system were attributed to the decrease in the shear deformable matrix and shear deformation propagation rate despite the increase in the process zone size. Maximum impact strength of the hybrid system at 60 °C (its BDT) increased to about 25% of the toughened PVC at its BDT (0 °C). The toughness amplification correlation of the toughened and hybrid PVC systems with their process zones fractional stress volumes under the impact load showed three regimes: quasi‐tough, transition, and super‐tough, which were superimposable on literature data regarding hybrid nylon 66 systems. © 2010 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys, 2010     

Copolymerization of styrene. III. Physical and mechanical properties of copolymers with styrene derivatives containing nitrile groups in the side chain

Copolymers of styrene with cinnamonitrile (I), ethyl benzylidenecyanoacetate (II), and benzylidenemalononitrile (III) were prepared in bulk, in suspension, and in emulsion up to high conversion. Their softening points, flexural properties, impact resistance, hardness, and volumetric shrinkage due to polymerization were studied. All three copolymers show improved thermal resistance in comparison to polystyrene, but whereas copolymers styrene–I and styrene–III are inferior to polystyrene in flexural strength and the impact resistance, the copolymer styrene–II is about equal to polystyrene in its flexural properties and impact resistance.     

聚氯乙烯/纳米水滑石复合材料的形态与力学性能

对由原位悬浮聚合制备的聚氯乙烯(PVC)纳米水滑石复合树脂加工得到的纳米复合材料的形态和力学性能进行了研究,并与直接熔融加工得到的PVC纳米水滑石复合材料进行比较.发现由前一方法得到的PVC纳米水滑石复合材料中纳米水滑石的分散性明显优于由后一方法得到的PVC纳米水滑石复合材料,水滑石以初级粒子形式存在,分散良好,无明显团聚体;与之对应,由前一方法得到的PVC纳米水滑石复合材料的力学性能也明显优于由后一方法得到的PVC纳米水滑石复合材料,当纳米水滑石含量小于5wt%时,复合材料的杨氏摸量、拉伸强度和缺口冲击强度均随水滑石含量增加而增大;纳米水滑石的引入可显著提高复合树脂的热稳定性;PVC纳米水滑石复合材料的储能和损耗模量略大于纯PVC材料,而损耗因子和玻璃化温度变化不大.     

sPS/PET/SsPS-H共混体系的研究

以自制间规聚苯乙烯(sPS)功能化合成的磺化间规聚苯乙烯（SsPS-H)作相容剂,研究其对sPS/PET共混物微相结构与性能的影响,发现SsPS-H能够有效地改善二者的相容性,当sPS/PET/SsPS-H为85／15／2（重量比）时,冲击强度达到11．4kJ/m^2,为纯sPS的3倍,此时材料的弯曲强度为39．1MPa,下降约8％;DMA结果表明,随SsPS-H用量的增加,共混物的Tg逐渐提高;DSC分析结果表明,共混体系中sPS的熔点不受SsPS-H含量的影响,而PET的熔点在加入6份SpPS-H时明显降低。sPS在达到最大结晶速率的温度均随SsPS-H用量的增加先提而后下降。SEM观察到加入SsPS-H后,PET分散相的尺寸减小,且均匀程度增加,共混物室温下冲击断裂显著地由脆性转变为韧性,当加入6份SsPS-H后,冲击断裂又出现脆性。     

Impact fracture toughness of polyamide‐6/montmorillonite nanocomposites toughened with a maleated styrene/ethylene butylene/styrene elastomer

Polyamide‐6 (PA6)/montmorillonite (MMT) nanocomposites toughened with maleated styrene/ethylene butylene/styrene (SEBS‐g‐MA) were prepared via melt compounding. Before melt intercalation, MMT was treated with an organic surfactant agent. Tensile and impact tests revealed that the PA6/4% MMT nanocomposite fractured in a brittle mode. The effects of SEBS‐g‐MA addition on the static tensile and impact properties of PA6/4% MMT were investigated. The results showed that the SEBS‐g‐MA addition improved the tensile ductility and impact strength of the PA6/4% MMT nanocomposite at the expenses of its tensile strength and stiffness. Accordingly, elastomer toughening represents an attractive route to novel characteristics for brittle clay‐reinforced polymer nanocomposites. The essential work of fracture (EWF) approach under impact drop‐weight conditions was used to evaluate the impact fracture toughness of nanocomposites toughened with an elastomer. Impact EWF measurements indicated that the SEBS‐g‐MA addition increased the fracture toughness of the PA6/4% MMT nanocomposite. © 2005 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 43: 585–595, 2005     

聚硫橡胶对环氧胶粘剂的增韧作用研究

环氧树脂以其优良的粘接性、化学稳定性、工艺性等性能,在粘接、涂料、机械、电子、国防等领域有广泛的应用[1].环氧树脂改性及工艺研究的相关报道较多[2-9].环氧树脂固化后有脆性大的缺点,在一定程度上限制了环氧树脂的应用.采用液体橡胶增韧环氧胶是改善环氧胶脆性的有效途径.本文介绍了采用聚硫橡胶增韧环氧胶的方法,并且研究了增韧后环氧胶的力学性能.     

以四重氢键结合的超支化聚合物及其涂层材料

合成了以Upy(2-ureido-4[1H]-pyrimidone)封端的超支化聚合物并研究其涂层材料性能.首先在哌嗪与三羟甲基丙烷三丙烯酸酯摩尔比2.25∶1条件下,合成了端仲胺基超支化聚(酯-胺)(HPEA),进而在仲胺基/异氰酸酯基官能团比1∶0.3、1∶0.4和1∶0.5下,通过HPEA与单异氰酸酯基甲基异胞嘧啶反应,合成了一系列带有Upy基元的改性超支化聚合物.由于Upy基元间形成了自识别四重氢键,改性聚合物比HPEA具有更高的玻璃化转变温度和热分解温度,并且改性聚合物涂层具有优良的力学性能,这表明分子间强氢键相互作用可有效改善超支化聚合物的性能.     

Influence of SEBS-g-MA on morphology, mechanical, and thermal properties of PA6/PP/organoclay nanocomposites

Polyamide 6/polypropylene (PA6/PP = 70/30 parts) blends containing 4 phr (parts per hundred resin) of organically modified clay (organoclay) toughened with maleated styrene-ethylene-butylene-styrene (SEBS-g-MA) were prepared by melt compounding using co-rotating twin-screw extruder followed by injection molding. X-ray diffraction (XRD) and transmission electron microscope (TEM) were used to characterize the structure of the nanocomposites. The mechanical properties of the nanocomposites were determined by tensile, flexural, and notched Izod impact tests. The single edge notch three point bending test was used to evaluate the fracture toughness of SEBS-g-MA toughened PA6/PP nanocomposites. Thermal properties were studied by using thermogravimetric analysis (TGA) and differential scanning calorimetry (DSC). XRD and TEM results indicated the formation of the exfoliated structure for the PA6/PP/organoclay nanocomposites with and without SEBS-g-MA. With the exception of stiffness and strength, the addition of SEBS-g-MA into the PA6/PP/organoclay nanocomposites increased ductility, impact strength and fracture toughness. The elongation at break and fracture toughness of PA6/PP blends and nanocomposites were increased with increasing the testing speed, whereas tensile strength was decreased. The increase in ductility and fracture toughness at high testing speed could be attributed to the thermal blunting mechanism in front of crack tip. DSC results revealed that the presence of SEBS-g-MA had negligible effect on the melting and crystallization behavior of the PA6/PP/organoclay nanocomposites. TGA results showed that the incorporation of SEBS-g-MA increased the thermal stability of the nanocomposite.     

三异丁氧基混合稀土增韧聚苯乙烯的研究

通过原位本体聚合制备三异丁氧基混合稀土掺杂聚苯乙烯 ,采用FT IR、UV Vis、FS和DMTA等对其表征 ,并测定其冲击强度 .表明改性聚苯乙烯中存在着稀土金属离子和苯环的配位作用 ,改性聚苯乙烯的玻璃化温度随稀土含量增加而下降 ,但其抗冲性能显著提高 .说明三异丁氧基混合稀土对聚苯乙烯有明显的增韧改性作用