短玻璃纤维增韧硬质聚氯乙烯的机理研究

短玻璃纤维增韧硬质聚氯乙烯的机理研究叶林忠，吴其晔（青岛化工学院高分子材料与工程系，青岛，２６６０４２）关键词短玻璃纤维，硬质聚氯乙烯（Ｒ－ＰＶＣ），增韧机理弹性体增韧塑料机理的研究已经向模型化和定量化方向发展ｌ‘］，刚性粒子增韧塑料的机理正在逐渐完...     

无机刚性粒子增韧聚丙烯的影响因素

简要介绍了无机刚性粒子对聚丙烯(PP)的增韧机理,并着重介绍了利用无机刚性粒子增韧PP时,PP基体、无机刚性粒子的性质及用量、无机刚性粒子在PP基体中的分散情况、无机刚性粒子与PP基体间的界面相互作用等因素对增韧效果的影响。     

橡胶增韧塑料机理

综述了橡胶增韧塑料机理研究的发展与现状,着重探讨了橡增韧机理中有关脆韧转变的定量研究,同时也讨论了分散相的形态参数、界面相容性和韧性测试条件以及分散相与基体的性能等因素对橡胶增韧塑料性能及增韧的影响,最后提出了橡胶增韧塑料研究的发展趋势。     

硬质PVC复合改性界面研究进展

综述了增强增韧硬质PVC方面所做的研究工作及最新的研究进展,探究了增强、增韧PVC的方法以及机理,机理包括:多重银纹,剪切屈服,剪切屈服-银纹化,逾渗,空穴。目前的改性方法包括:改性无机粒子增强增韧PVC,如微米粒子、纳米粒子、"核-壳"结构粒子、其它无机粒子;聚合物和无机粒子/聚合物以及接枝改性增强增韧PVC。     

塑料的刚性填料增韧

刚性粒子增韧作为一种新的增韧方法，已越来越受到人们的关注。本文根据刚性粒子增韧塑料的系列研究，分别讨论了有机刚性粒子和无机刚性粒子增韧塑料的机理，并集中解释了研究中的一些实验现象。     

超高分子量聚乙烯／聚丙烯共混体系流变行为及形态的研究

超高分子量聚乙烯／聚丙烯共混体系流变行为及形态的研究汪晓东,励杭泉,金日光（北京化工大学高分子系,北京,１０００２９）关键词共混合金,线性互穿网络,双连续相,网络增韧机理通常聚合物的增韧机理是在树脂中引人柔性链段［１］形成复合物（如橡塑共混物）,这些...     

刚性有机粒子对聚氯乙烯／氯化聚乙烯共混体系形态和增韧机理的研究

刚性有机粒子对聚氯乙烯／氯化聚乙烯共混体系形态和增韧机理的研究周丽玲，吴其晔，杨文君，刘士龙，张漫（青岛化工学院橡胶系青岛２６６０４２）关键词刚性有机填料，聚氯乙烯ＰＶＣ，氯化聚乙烯（ＣＰＥ）形态，增韧机理在共混改性中，弹性体增韧硬质聚氯乙烯（ｎｙＶ...     

非弹性体增韧—聚合物增韧的新途径

本文是一篇关于非弹性增韧方法的综述。文章首先简要回顾了传统的橡胶增韧韧性聚合物材料的机理,然后着重介绍了最近在国外出现的刚性有机填料(ROF)增韧的基本概念、分析方法和增韧的冷拉机理,列举了脆性塑料粒子和韧性基体组成的合金体系的大量实验结果来说明以上内容,最后通过与传统橡胶增韧机理的对比指出非弹性体增韧是不同于后者的一种新增韧方法,并有可能成为制备高强度、高韧性工程塑料的一种新途径。     

卷积神经网络和支持向量机算法在塑料近红外光谱分类中的模型应用

机器学习算法的应用使得塑料自动分类成为可能,而废旧塑料的分类回收对保护环境、节约资源有重要意义。该文结合近红外光谱分析技术,比较了使用一维卷积神经网络（1D CNN）和多元散射处理后支持向量机算法（MSC－SVM）建模的效果,及对PP新生料、PP再生料、PE新生料、PE再生料4种塑料分类的准确率。基于100个塑料样本近红外光谱数据的分类结果表明,验证集上1D CNN模型准确率为91.5%,MSC－SVM模型准确率为90.8%。1D CNN模型用于识别PP和PE新生料时,准确率可达100%。证明1D CNN建模方法在小数据集上进行准确塑料分类是可行的。     

无机粉体对微发泡聚丙烯复合材料力学行为的影响

通过改性的不同形状（针状MgSO4晶须、片状云母粉、球形状SiO2）无机粉体材料,以5％含量加入到聚丙烯中,在二次开模条件下制备微发泡PP复合材料;测定PP／无机粉体材料复合体系接触角,联合粘接理论计算液-固界面的黏附功;以异相成核理论和填充增强机理为基础,分析了不同形状的无机粉体材料对微发泡PP材料力学行为的影响规律...     

Effect of ionomers on mechanical properties, morphology, and rheology of polyoxymethylene and its blends with methyl methacrylate-styrene-butadiene copolymer

Two ionomers, ethylene-methacrylic acid copolymer ionized with sodium cation (EMA-Na) and zinc cation (EMA-Zn), were employed as impact modifiers to prepare blends with polyoxymethylene (POM) via a melt extrusion. A copolymer of methyl methacrylate-styrene-butadiene (MBS) used as a co-impact modifier was also incorporated into the blends. The mechanical properties, thermal properties, morphology, and rheology were studied. A moderate toughening was observed for POM/ionomer binary blends, which was attributable to the rubbery natural and good adhesion of the ionomers. EMA-Zn exhibited a much better toughening effect than EMA-Na because of its higher elasticity and stronger interaction with POM. The incorporation of the ionomers into POM/MBS blends resulted in an improvement of mechanical properties, which was attributable to the compatibilizing effect of ionomer on POM/MBS blending system. The observation of scanning electron microscopy demonstrated that the finer phase domains were caused by incorporation of ionomers, which, acting as a compatibilizer as well as an impact modifier, reduced the interfacial tension and improved the interfacial adhesion between the phases. Differential scanning calorimetry investigation indicated that the presence of ionomer in the blends disturbed the crystallization of POM and resulted in a decrease in the crystallinity of POM. The evaluation of melt flow index revealed an increase in viscosity of the blends by incorporation of the ionomers, which was caused the ionic interaction between POM and the ionomers.     

稀土对MoSi2力学性能和抗氧化性能的影响

采用自蔓延和真空烧结方法制备了掺杂0．9％La2O3的MoSi2基复合材料，利用热重分析法，SEM和X射线考察了La2O3颗粒对MoSi2力学性能、抗氧化特性以及循环氧化后力学性能的影响。结果表明，与纯MoSi2相比，RE／MoSi2材料的弯曲强度和断裂韧性分别提高了46％和78％；稀土对MoSi2材料的强韧化机制主要是细晶强化、弥散强化和细晶韧化。RE／MoSi2的氧化增重是纯MoSi2的2．5倍，稀土使MoSiz材料的抗氧化性能降低。由于纯MoSi2材料氧化后的晶粒长大，其抗弯强度比氧化前降低了17％。稀土对MoSi2氧化时的晶粒长大倾向有抑制作用，使得RE／MoSi2材料的抗弯强度基本不变。     

聚对苯二甲酸丙二醇酯的无卤阻燃化改性

聚对苯二甲酸丙二醇酯作为新型聚酯材料,具有非常优良的性能,但其易燃性很大的限制了它的应用范围。为了提高对苯二甲酸乙二醇酯的阻燃性能,本文以无卤膨胀型EPFR-300A为阻燃改性剂,马来酸酐接枝聚烯烃(POE-g-MAH)弹性体为增韧剂,对聚对苯二甲酸丙二醇酯树脂(PTT)进行阻燃改性。通过热重分析仪(TGA)、示差扫描量热仪(DSC)、扫描电子显微镜(SEM)、力学性能等技术手段研究了阻燃剂和增韧剂对PTT树脂力学、热学和阻燃性能的影响。结果表明,增韧剂POE和POE-g-MAH的添加提高了PTT树脂的综合力学性能。当质量分数相同时,POE-g-MAH对PTT树脂的增韧效果要优于POE,且当POE-g-MAH质量分数为7%时,综合力学性能最佳。当添加相同质量分数增韧剂,EPFR-300A质量分数达到20%时,阻燃PTT材料阻燃性能最佳,极限氧指数(LOI)达到28.0%,垂直燃烧阻燃等级达到UL94 V-0级。EPFR-300A阻燃剂与PTT树脂间相容性良好,可以有效地促进PTT树脂成炭并提高材料的阻燃性能。     

玻璃微珠填充改性聚合物研究进展

玻璃微珠作为一种新型的刚性粒子 ,除了对于聚合物的增强增韧作用 ,在许多方面都已引起聚合物改性工作者的关注。本文从玻璃微珠对聚合物的增韧效果 ,玻璃微珠填充聚合物的拉伸性能、动态力学性能、流变形能、界面以及其他性能等方面综述了近年来玻璃微珠填充改性聚合物的研究进展     

Highly efficient toughening effect of ultrafine full-vulcanized powdered rubber on poly(lactic acid)(PLA)

A unique ultrafine full-vulcanized powdered ethyl acrylate rubber (EA-UFPR) was used as the toughening modifier for poly (lactic acid) (PLA). Largely improved tensile toughness was successfully achieved with the incorporation of only 1 wt% EA-UFPR, while the tensile strength and modulus of the blends were almost the same as pure PLA. The highly efficient toughening of PLA by UFPR is mainly ascribed to the strong interfacial interaction between PLA and UFPR and good dispersion of UFPR particles in PLA matrix. Our work provides an effective toughening method to largely improve the mechanical properties of PLA without sacrificing its stiffness, which is very important for the wide application of PLA materials.     

插层型NBR/膨润土混杂材料及其对PVC增韧作用的研究

研究了胶乳插层法制备的丁腈橡胶 /有机改性膨润土 (NBR/OMB)混杂材料的力学性能和微观结构及其对聚氯乙烯 (PVC)的增韧作用。结果表明 :胶乳插层法制备的NBR/OMB混杂材料具有优异的力学性能 ;TEM和XRD结果表明 ,有部分NBR大分子嵌入到膨润土层间 ,形成较均匀、细致的分散。NBR/OMB混杂材料增韧PVC的效果明显优于NBR ,增韧后拉伸强度和弯曲强度的保持率明显提高     

橡胶活性官能团对增韧环氧树脂动态力学性能的影响

用动态扭摆法测试聚丙烯酸丁酯橡胶增韧环氧树脂的动态力学行为,研究在环氧树脂低固化度和高固化度时,橡胶活性官能团种类(环氧基官能团与羧基官能团)和数量(官能度)对其影响。研究体系中橡胶玻璃化转变温度(Tg)的移动大小,与橡胶和基体树脂健合程度之间的关系。     

Effect of phase change microcapsules on the thermo-mechanical,fracture and heat storage properties of unidirectional carbon/epoxy laminates

This work aims at producing and characterizing unidirectional carbon/epoxy composites containing different fractions of paraffin microcapsules (MC) for thermal management applications. The viscosity of the epoxy/MC mixtures increases with the MC content, thereby increasing the final matrix weight and volume fraction and reducing that of the fibers. This is at the basis of the decrease in mechanical properties of the laminates with high MC concentration (the elastic modulus decreases up to 53% and the flexural strength up to 67%), but the application of theoretical models shows that this decrease is only due to the lower fiber volume fraction, and not to a change in the properties of the constituents or the fiber/matrix interaction. The MC phase is preferentially distributed in the interlaminar zone, which leads to a thickening of this region and a decrease in matrix-related properties, such as the interlaminar shear strength, which decreases of up to 70%. However, a modest MC fraction causes an increase in the mode I interlaminar fracture toughness of 48%, due to the introduction of new toughening mechanisms. On the other hand, an excessive MC content lets the crack propagating through the matrix and not at the fiber/matrix interface, thereby reducing the toughening mechanism provided by fiber bridging. For the thermal properties, the phase change enthalpy increases with the MC fraction up to 48.7 J/g, and this is reflected in better thermal management performance, as proven by thermal imaging tests. These results are promising for the development of multifunctional polymer composites with thermal energy storage and thermal management properties, and future works will be focused on a deeper study of the micromechanical properties of PCM microcapsules and on the improvement of the capsule/matrix adhesion.