聚碳酸酯／聚丙烯共混物的结构与性能

在过氧化二异丙苯的引发下，用反应挤出的方法制备了聚丙烯接枝甲基丙烯酸环氧丙酯。用双螺杆挤出机制务了不同组成的聚碳酸酯／聚丙烯及ＰＣ／ＰＰ－ｇ－ＧＭＡ／ＰＰ的共混物。用电子显微镜观察了不同经组成的形态，与ＰＰ／ＰＣ共混体系相比，ＰＣ／ＰＰ／ＰＰ－ｇ－ＧＭＡ体系中的ＰＣ一ＰＰ中分散相尺寸明显降低，ＰＰ－ｇ－ＧＭＡ加入改变聚丙烯在共混物中的晶体结构及提高了聚丙烯的结晶温度，同时ＰＰ－ｇ－ＧＭＡ的加入对共     

PA1010／PP—g—ATBS／PP共混体系的形态与性能

采有向向双螺杆杆挤出机制备了不同组成的ＰＡ１０１０／ＰＰ及ＰＡ１０１０／ＰＰ－ｇ－ＡＴＢＳ／ＰＰ的共混物。采用聚丙烯接枝丙烯酰胺基甲基丙烷磺酸共聚物（ＰＰ－ｇ－ＡＴＢＳ）作为增容剂来研究对ＰＡ１０１０／ＰＰ共混体系形态与力学性能的影响，研究不同增容剂含量对ＰＡ１０１０／ＰＰ共混物的力学性能，形态结构的影响。     

PP—g—AA增容尼龙1010／聚丙烯三元共混体系性能研究

用反应挤出方法制备了聚丙烯接枝丙烯酸。用电子显微镜观测了不同ＰＰ－ｇ－ＡＡ含量的ＰＡ１０１０／ＰＰ／ＰＰ－ｇ－ＡＡ三元共混物的形态。与没有加ＰＰ－ｇ－ＡＡ的共混体系相比，增容共混中分散相尺寸明显减小，两相间镶嵌更深。ＰＰ－ｇ－ＡＡ作为第三组分加对其物理力学性能有一定程度的改善。     

反应型增容剂PS-co-GMA在PA1010/ABS共混体系中的增容作用

以ＰＳ－ｃｏ－ＧＡＭ作为ＰＡ１０１０／ＡＢＳ共混体系的增容剂,探讨了增容剂的含量对共混体系力学性能的影响,同时,利用熔融共混法制备了ＰＡ１０１０／ＡＢＳ－ｇ－ＧＭＡ共混体系,比较了两种增容方式对共混体系力学性能的影响。     

MAH—g—PP对PP／EVAL共混体系的增容作用

系统研究了不同组成及配比的马来酸酐接枝聚丙烯（ＭＡＨ－ｇ－ＰＰ）及其用量对聚丙烯（ＰＰ）与乙烯－乙烯醇共聚物（ＥＶＡＬ）的共混体系（ＰＰ／ＥＶＡＬ）力学性能借用Ｂｒａｂｅｎｄｅｒ塑化仪测试了ＰＰ／ＥＶＡＬ／ＭＡＨ－ｇ－ＰＰ共混体系的加工性能。结果表明,ＭＡＨ－ｇ－Ｐ接枝物对ＰＰ／ＥＶＡＬ共混体系有较好的增容作用,适量加入,可使ＰＰ／ＥＶＡＬ共混体系的力学性能明显提高,而加工性能基本不变。     

阻隔性HDPE／MPE／PA1010共混体系的研究

用挤出法以马来酸酐（ＭＡＨ）接枝高密度聚乙烯（ＨＤＰＥ）为增容剂（ＭＰＥ），ＰＡ１０１０为阻隔组分，ＨＤＰＥ为基料，制取了ＨＤＰＥ／ＭＰＥ／ＰＡ１０１０共混材料。研究了挤出温度、ＭＰＥ用量、ＰＡ１０１０含量对其阻隔性能的影响，比较了几种不同渗透体系的吸油率和渗透损失量。     

PA1010／CaSiO3共混物熔体流变性能的研究

本文采用Ｉｎｓｔｒｏｎ毛细管流变仪，研究尼龙１０１０（ＰＡ１０１０）与硅灰石（ＣａＳｉＯ３）共混体系的流动曲线，表观粘度以及共混体系的组成特性本质。ＣａＳｉＯ３是否被偶联化认为是产生ＰＡ１０１０／ＣａＳｉＯ３共混体系流变特性的原因。     

PA－66／（PE／EPDM）－g－MAH共混增韧的研究

本文研究了尼龙－６６（ＰＡ－６６）与聚乙烯（ＬＤＰＥ）共混物的力学性能。结果表明，用马来酸酐接枝聚乙烯和三元乙丙橡胶（ＥＰＤＭ）改善了与基体ＰＡ－６６的相容性。添加弹性体ＥＰＤＭ，使之生成（ＰＥ／ＥＰＤＭ）－ｇ－ＭＡＨ共聚物，可以大幅度度地提高ＰＡ－６６／（ＰＥ／ＥＰＤＭ）－ｇ－ＭＡＨ冲击强度，同时熔体粘度随温度的变化趋于平缓，吸水率有所下降。     

PC／PET／PE—g—MAM三元共混体系流动性的研究

以ＰＥ－ｇ－ＭＡＨ和ＰＥ－ｇ－ＭＡＮａ、ＰＥ－ｇ－ＭＡＺｎ马来酸盐离聚物为相容剂性组成ＰＣ－ＰＥＴ／ＰＥ－ｇ－ＭＡＭ三元共混体系。用毛细管流变仪研究了不同ＰＥ－ｇ－ＭＡＭ的接枝率及用量对共混物流动性的影响。     

PA—66／（PE／EPDM）—g—MAH共混增韧的研究

本文研究了尼龙－６６（ＰＡ－６６）与聚乙烯（ＬＤＰＥ）共混物的力学性能。结果表明，用马来酸酐接枝聚乙烯和三元乙丙橡胶（ＥＰＤＭ）改善了与基体ＰＡ－６６的相容性。添加弹性体ＥＰＤＭ，使之生成（ＰＥ／ＥＰＤＭ）－ｇ－ＭＡＨ共聚物，可以大幅度地提高ＰＡ－６６／（ＰＥ／ＥＰＤＭ）－ｇ－ＭＡＨ冲击强度，同时熔体粘度随温度的变化趋于平缓，吸水率有所下降。     

MORPHOLOGY,CRYSTALLIZATION BEHAVIORS,AND MECHANICAL PROPERTIES OF PA1010/HIPS AND PA1010/HIPS-g-MA BLENDS

The binary blends of polyamide 1010 (PA1010) with the high-impact polystyrene (HIPS)/maleic anhydride (MA) graft copolymer (HIPS-g-MA) and with HIPS were prepared using a wide composition range. Different blend morphologies were observed by scanning electron microscopy according to the nature and content of PA1010 used. Compared with the PA1010/HIPS binary blends, the domain sizes of dispersed-phase particles in PA1010/HIPS-g-MA blends were much smaller than that in PA1010/HIPS blends at the same compositions. It was found that the tensile properties of PA1010/HIPS-g-MA blends were obviously better than that of PA1010/HIPS blends. Wide-angle x-ray diffraction analyses were performed to confirm that the number of hydrogen bonds in the PA1010 phase decreased in the blends of PA1010/HIPS-g-MA. These behaviors could be attributed to the chemical interactions between the two components and good dispersion in PA1010/HIPS-g-MA blends.     

Morphology,thermal behavior,and mechanical properties of PA1010/PP and PA 1010/PP-g-GMA blends

The modification of polypropylene (PP) was accomplished by melt grafting glycidyl methacrylate (GMA) on its molecular chains. The resulting PP-g-GMA was used to prepare binary blends of polyamide 1010 (PA1010) and PP-g-GMA. Different blend morphologies were observed by scanning electron microscopy (SEM) according to the nature and content of PA1010 used. Comparing the PA1010/PP-g-GMA and PA1010/PP binary blends, the size of the domains of PP-g-GMA were much smaller than that of PP at the same compositions. It was found that mechanical properties of PA1010/PP-g-GMA blends were obviously better than that of PA1010/PP blends, and the mechanical properties were significantly influenced by wetting conditions for uncompatibilized and compatibilized blends. A different dependence of the flexural modulus on water was found for PA1010/PP and PA1010/PP-g-GMA. These behaviors could be attributed to the chemical interactions between the two components and good dispersion in PA1010/PP-g-GMA blends. Thermal and rheological analyses were performed to confirm the possible chemical reactions taking place during the blending process. © 1997 John Wiley & Sons, Inc. J Appl Polym Sci 64: 1489–1498, 1997     

Morphology—properties relationships in binary polyamide 6/rubber blends: Influence of the addition of a functionalized rubber

The modification of an amorphous random ethylene-propylene rubbery copolymer (EPM) has been accomplished by solution grafting of maleic anhydride molecules promoted by radical initiators, The resulting EPM-g-succinic anhydride (EPM-g-SA) and EPM have been used to obtain binary polyamide 6/EPM or polyamide 6/EPM-g-SA and ternary polyamide 6/EPM/EPM-g-SA blends by melt mixing. The formation of an EPM-g-PA6 graft copolymer during the blend preparation has been assumed. Different blend morphologies were observed by scanning electron microscopy (SEM) according to the nature and content of the rubber used. The tensile mechanical properties and the impact behavior of the prepared blends were investigated and correlated with the SEM analysis of the fracture surfaces. Binary and ternary blends containing 20 percent by weight of total rubber show a significant improvement of the impact properties at low temperature (?20°C) when the rubber is partly or entirely EPM-g-SA. In the case of PA6/EPM-g-SA (80/20) blend these results are related to the presence of rubbery domains of very small size strongly adherent to the PA6 matrix. In the case of 80/10/10 ternary blends, a much more complicated overall morphology is observed. Such morphology is characterized by the presence of large EPM domains, likely containing some EPM-g-PA6 graft molecules acting as an interfacial agent, and domains of EPM-g-PA6 of smaller size strongly adherent to the matrix as in the previous case.     

The effect of reactive compatibilization of carboxylated polystyrene on morphology and toughness of polyamide-1010/polystyrene blends

The morphology and notched impact behaviour of polyamide-1010/polystyrene (PA1010/PS) (90/10) blends compatibilized by carboxylated polystyrene (CPS) have been studied. It is found that the addition of CPS has a beneficial effect upon the morphology of the resulting blends which leads to a finer dispersion of the PA1010 spherulites and of the PS particles in the PA1010 matrix. However, with increasing CPS content, the shape of the PS domains appears less regular, which may be due to the cracking of the PS spherical domains. Infrared analysis was performed to confirm the formation of PS–PA1010 graft copolymer during the blending process. The notched impact toughness of the compatibilized blends shows a maximum which is almost triple that of the binary blend at approximately 5 wt% of the CPS addition based on the amount of PS. © 1999 Society of Chemical Industry     

PET/聚酰胺类共混体系相容性的研究

将聚对苯二甲酸乙二醇酯(PET)分别与聚酰胺类(PA1010、PA6和PA66)熔融共混,通过热力学分析、示差扫描量热法、扫描电镜和红外光谱等手段,对PET/PA类共混体系进行了研究.热力学分析结果与实验结果不同,表明热力学分析不适用于PET/PA共混体系;DSC分析结果表明:不同的PET/PA共混体系对PET相玻璃化温度向低温区移动程度有影响;SEM分析表明:PET/PA共混体系断面形态不同,相容性关系为PET/PA66>PET/PA6>PET/PA1010;红外光谱分析表明:共混体系中PET的羟基和PA分子的-NH-之间产生了氢键,导致PET的C=0拉伸震动吸收峰移向低波数.     

相容剂和加工工艺对PA1010/PP共混体系形态和力学性能的影响

以马来酸酐（MAH）和苯乙烯（St）多单体熔融接枝聚丙烯[PP-g-(MAH-co-St）]为相容剂,制备了聚酰胺10101/聚丙烯（PA1010/PP）共混体系。用毛细管流变仪、扫描电子显微镜、力学性能测试等方法研究了和加工工艺相容剂对PA1010/PP共混体系的形态和力学性能的影响。结果表明,相容剂PP-g-(MAH-co-St)有效降低了PA1010/PP共混体系的熔体流动速率;该共混体系熔体属于假塑性流体,熔体黏度随PP-g-(MAH-co-St)含量的增加逐渐增大;随着相容剂含量的增加,PA1010/PP共混体系中分散相PP的粒径逐步减小,力学性能得到改善,PA1010/PP/PP-g-(MAH-co-St)为70/25/5和70/20/10的共混体系的拉伸强度分别比PA1010/PP (70/30)共混体系提高了55.0 %和61.9 %,冲击强度分别提高了61.0 %和129.7 %;剪切速率为706.5 s-1时出现熔体破裂现象,剪切速率为5002.65 s-1时出现严重熔体破裂。     

Preparation of the HIPS/MA graft copolymer and its compatibilization in HIPS/PA1010 blends

The graft copolymer of high‐impact polystyrene (HIPS) grafted with maleic anhydride (MA) (HIPS‐g‐MA) was prepared with melt mixing in the presence of a free‐radical initiator. The grafting reaction was confirmed by infrared analyses, and the amount of MA grafted on HIPS was evaluated by a titration method. 1–5% of MA can be grafted on HIPS. HIPS‐g‐MA is miscible with HIPS. Its anhydride group can react with polyamide 1010 (PA1010) during melt mixing of the two components. The compatibility of HIPS‐g‐MA in the HIPS/PA1010 blends was evident. Evidence of reactions in the blends was confirmed in the morphology and mechanical behavior of the blends. A significant reduction in domain size was observed because of the compatibilization of HIPS‐g‐MA in the blends of HIPS and PA1010. The tensile mechanical properties of the prepared blends were investigated, and the fracture surfaces of the blends were examined by means of the scanning electron microscope. The improved adhesion in a 15% HIPS/75% PA1010 blend with 10% HIPS‐g‐MA copolymer was detected. The morphology of fibrillar ligaments formed by PA1010 connecting HIPS particles was observed. © 1999 John Wiley & Sons, Inc. J Appl Polym Sci 71: 2017–2025, 1999     

PA11/PA1010共混物的性能研究

采用熔体共混的方法制备了聚酰胺11/聚酰胺1010(PA11/PA1010)共混物,通过力学性能和差示扫描量热(DSC)测试,研究了PA11/PA1010共混物的力学与结晶性能。测试结果表明:PA1010对PA11同时具有增韧、增强作用;当PA11/PA1010为70/30时,共混物开始出现两个结晶峰和低温熔融峰;共混物的结晶和熔融以PA11为主,兼具有PA11和PA1010的优良性能;断裂伸长率、拉伸强度与缺口冲击强度均达到极大值。     

Compatibilization of side‐chain,thermotropic, liquid‐crystalline ionomers to blends of polyamide‐1010 and polypropylene

A novel side‐chain, liquid‐crystalline ionomer (SLCI) with a poly(methyl hydrosiloxane) main chain and side chains containing sulfonic acid groups was used in blends of polyamide‐1010 (PA1010) and polypropylene (PP) as a compatibilizer. The morphological structure, thermal behavior, and liquid‐crystalline properties of the blends were investigated by Fourier transform infrared, differential scanning calorimetry, thermogravimetric analysis, and scanning electron microscopy. The morphological structure of the interface of the blends containing SLCI was improved with respect to the blend without SLCI. The compatibilization effect of greater than 8 wt % SLCI for the two phases, PA1010 and PP, was better than the effects of other SLCI contents in the blends. © 2002 Wiley Periodicals, Inc. J Appl Polym Sci 83: 2749–2754, 2002; DOI 10.1002/app.10179     

Effect of compatibilization on the properties of HIPS/PA1010 blends

Blends consisting of high‐impact polystyrene (HIPS) as the matrix and polyamide 1010 (PA1010) as the dispersed phase were prepared by mixing. The grafting copolymers of HIPS and maleic anhydride (MA), the compatibilizer precursors of the blends, were synthesized. The contents of the MA in the grafting copolymers are 4.7 wt % and 1.6 wt %, and were assigned as HAM and LMA, respectively. Different blend morphologies were observed by scanning electron microscopy (SEM); the domain size of the PA1010 dispersed phase in the HIPS matrix of compatibilized blends decreased comparing with that of uncompatibilized blends. For the blend with 25 wt % HIPS‐g‐MA component, the T_c of PA1010 shifts towards lower temperature, from 178 to 83°C. It is found that HIPS‐g‐MA used as the third component has profound effect on the mechanical properties of the resulting blends. This behavior has been attributed to the chemical reaction taking place in situ during the mixing between the two components of PA1010 and HIPS‐g‐MA. © 2000 John Wiley & Sons, Inc. J Appl Polym Sci 76: 799–806, 2000