共查询到18条相似文献,搜索用时 156 毫秒
1.
液晶聚合物对尼龙1010/聚丙烯共混合金的结晶行为和力学性能的影响 总被引:3,自引:0,他引:3
用DSC研究了液晶聚合物(LCP)的含量对PA1010/聚丙烯(PP)共混合金结晶和熔融行为的影响:用TGA研究了共混合金的热稳定性:用拉伸试验检测共混材料的力学性能。结果表明:PA1010/PP共混合金中加入0.6%-0.8%(质量)LCP时能起微纤增强和异相成核剂作用,提高合金结晶温度和结晶度,使结晶完善程度略有增加,结晶速率略受影响,并且共混材料的拉伸强度明显增强,但对其热稳定性影响不大。当LCP含量增加到5%时,将作为独立组分在共混合金中起作用,使PA1010和PP的结晶峰均出现明显分峰现象,共混材料的力学性能和热稳定性显著下降。 相似文献
2.
聚丙烯/尼龙6共混物的X射线衍射研究EI 总被引:10,自引:0,他引:10
用广角 X射线衍射 (WAXD)方法研究了不同接枝聚丙烯对聚丙烯 /尼龙 6 (PP/PA6 )共混物结晶行为的影响。结果表明 ,与简单机械共混物相比 ,由于增容剂的加入 ,PP的结晶行为发生变化——不同晶面的生长速率不同 ,且在所研究的范围内有随增容剂含量的增加 。 相似文献
3.
马来酸酐接枝聚丙烯对聚氨酯/聚丙烯共混物的形态和力学性能的影响 总被引:1,自引:0,他引:1
用熔融法制备了聚氨酯(TPU)与聚丙烯(PP)的(80/20)共混物,用扫描电镜和力学性能测试研究了以马来酸酐接枝的聚丙烯(PP-g-M A)为增容剂对TPU/PP体系的增容作用。形态和力学性能均表明,PP-g-M A是TPU/PP共混物有效的增容剂,当其用量为5%(质量分数)时,共混体系的形态和力学性能最佳。用FT-IR表征了PP-g-M A对TPU和PP的增容机理。 相似文献
4.
研究了PP/PC不同共混比对PP结晶行为、共混物物理性能的影响.探讨了以PP-g-MAH为增容剂、PF为增容助剂对共混物的增容效果。对比了单双螺杆挤出两种共混方式对共混物物理性能和相结构的影响。结果表明,PC的加入使PP球晶细化、结晶度降低、结晶不完善.共混物强度提高.韧性下降。加入PP—g—MAH可同时提高强度和韧性,再加入PF可使强度进一步提高.但韧性变差。PP/PP—g—MAH/PC的Tg与Tm差值比PP/PC的差值缩小了2.9℃,说明PP—g—MAH的确起到增容作用。运用双螺杆挤出机共混效果较好。 相似文献
5.
力化学方法制备PP-g-HMA增容PA6/PP/硅灰石复合材料的形态和力学性能 总被引:1,自引:0,他引:1
以力化学方法制备的N-羟甲基丙烯酰胺接枝聚丙烯(PP-g-HMA)作尼龙6(PA6)/聚丙烯(PP)共混体系的增容剂,将增容尼龙6/聚丙烯共混体系与硅灰石复合.研究了复合材料的形态结构、硅灰石用量、偶联剂种类和用量以及增容剂等对复合材料的力学性能的影响.结果表明,PP-g-HMA能提高PA6/PP/硅灰石复合材料的力学性能,而KH-550和ON-330两种偶联剂复配使用则可以显著提高PP-g-HMA增容PA6/硅灰石复合材料的力学性能. 相似文献
6.
PP固相接枝物增容PP/PA6共混物的界面相互作用和力学性能 总被引:5,自引:0,他引:5
研究了PP固相接枝混合三单体(gPP)增容PP/PA6共混物的界面相互作用和力学性能,结果表明,该gPP是PP/PA6共混物的有效增容剂,在PP/PA6共混物的所有组成范围内,加入少量的gPP均可达到良好的增容效果,能显著提高共混物的力学性能,固相接枝物对PP/PA6共混体系的增容效果与固相接枝物用量及制备固相接枝物时第三单体的用量相关,通过Molau实验,傅里叶红外谱换光谱测试,抽提实验等证实;gPP的加入使得PP/PA6共混物在共混过程中就地形成了两相之间的增容剂PP-gPA6,增强了两相界面间的相互作用,gPP用量越大,PP-g-PA6的生成量越大,两相间的界面相互作用越强 相似文献
7.
通过Molau实验、扫描电子显微镜(SEM)观察和力学、热学性能测试,研究了三元乙丙橡胶接枝马来酸酐共聚物(EPDM-g-MAH)增容剂在PA6/PP共混物中的作用.重点讨论了PA6/PP配比、EPDM-g-MAH用量对共混物结构、冲击强度、热变形温度和吸水率的影响.实验结果表明:EPDM-g-MAH是一种反应型增容剂.适量的EPDM-~MAH加入可很好地改善PA6和PP两相的相容性,减小PP分散相的粒径,提高PA6、PP两相界面的相互作用.当PA6/PP/EPDM-g-MAH质量比为80/20/(10~15)时,共混物综合性能最好.和纯PA6相比,共混物冲击强度提高3倍以上,热变形温度提高7℃以上,吸水率减少2/3. 相似文献
8.
9.
纳米CaCO3/PP/PS复合材料的结晶与熔融行为 总被引:2,自引:0,他引:2
熔融方法制备了纳米CaCO3/PP/PS复合材料,DSC研究了PP/PS、增容PP/PS共混物及其纳米CaCO3填充共混物的结晶与熔融行为。研究结果表明加入PS对PP结晶行为影响不大,但导致PP熔点下降,熔融峰从单峰变为双峰。纳米CaCO3和增容剂对PP/PS共混物中PP结晶存在异相成核作用,提高PP结晶温度和熔点,PP—g—MA和PP—g—AA的异相成核作用比CaCO3的大。PP—g—MA增容的PP/PS共混物和CaCO3填充共混物有利于PP形成β晶,但CaCO3填充共混物、PP—g—AA的增容PP/PS共混物和CaCO3填充共混物无β晶形成。 相似文献
10.
以马来酸酐接枝乙烯-辛烯共聚物(POE-g-MAH)作为增容剂, 采用熔体共混的方法制备了PA1010-PP共混物, 通过扫描电镜(SEM)、 力学性能和差示扫描量热(DSC)测试, 研究了动态保压注射成型中POE-g-MAH对PA1010-PP共混物的增容作用。力学性能测试结果表明, 在注射成型过程中施加剪切应力, 明显提高了共混物的拉伸和冲击性能。SEM结果表明, 剪切诱导制品产生多层次结构, 而且分散相相区尺寸显著减小, 分散更趋均匀, 相界面更加模糊。DSC结果表明, 剪切应力作用下, 当POE-g-MAH的质量分数达到15%时, PP出现2个结晶峰, 即出现异相成核结晶和均相成核结晶, PP均相成核结晶的出现从另一个方面表明动态试样中分散相PP尺寸小于静态试样。剪切应力作用下增容作用的提高归因于剪切应力作用下独特相形态的形成。 相似文献
11.
先使聚丙烯接枝马来酸酐(PP-g-MAH)与炭黑(CB)反应,再与聚丙烯/尼龙6(PP/PA6)共混制备出CB位于两相界面处的PP/PA6/PP-g-MAH/CB导电高分子复合材料,研究了材料的特殊结构和电学性能。结果表明,在PP/PA6/CB体系中CB粒子分布在PA6相,体系的逾渗阈值为2%;而在PP/PA6/PP-g-MAH/CB体系中,CB被PP-g-MAH诱导分布在两相界面处。PP/PA6两相为海岛结构时,PP/PA6/PP-g-MAH/CB体系仍可导电。PP/PA6/PP-g-MAH/CB体系的逾渗阈值降至1.6%,低于PP/PA6/CB体系。体系的正温度效应(PTC)强度远高于PP/PA6/CB体系,在90-135℃范围内不出现负温度效应(NTC)。PP/PA6/PP-g-MAH/CB体系的电学性能归结于其特殊的界面形态结构:导电通道由位于共混物界面处的PP-g-MAH和CB构建而成。 相似文献
12.
PP/PA1010共混物的形态结构及力学性能的研究 总被引:8,自引:0,他引:8
利用红外光谱、扫描电子显微镜和力学测试等方法, 甲基丙烯酸环氧丙酯熔融接枝聚丙烯PP-g-GMA对不同组成的PP/PA1010共混物形态结构和力学性能的影响。 相似文献
13.
TiO2 nanoparticles were pretreated with excessive toluene-2,4-diisocyanate to synthesize TDI-functionalized TiO2 (TiO2-NCO), and then the polypropylene/polyamide 6/(PP/PA6, 70/30 wt%) blends containing 3 phr of the TDI-functionalized TiO2 were prepared using twin-screw extruder followed by injection molding. Maleated polypropylene (PP-g-MAH) was used to compatibilize the blends. The mechanical properties of PP/PA6 blends based nanocomposites were studied through tensile and flexural tests. Scanning electron microscopy (SEM) and transmission electron microscopy (TEM) were used to assess the fracture surface morphology and the dispersion of the TDI-functionalized TiO2, respectively. The dynamic mechanical properties of PP/PA6 based nanocomposites were analyzed by using dynamic mechanical thermal analyzer (DMTA). The strength and stiffness of the PP/PA6 compounds were improved significantly in the presence of PP-g-MAH. This has been attributed to the synergistic effect of TDI-functionalized TiO2 and PP-g-MAH. The PP-g-MAH compatibilized PP/PA6 compounds showed a homogeneous morphology supporting the compatibility improvement between PP, PA6 and TDI-functionalized TiO2. TEM results revealed that the TDI-functionalized TiO2 nanoparticles were exfoliated and uniformly dispersed in blends matrix. Possible chemical interactions between PP, PA6, TDI-functionalized TiO2 and PP-g-MAH were proposed based on the experimental work. 相似文献
14.
RSMA增容PA6/PP共混物的形态结构与增容机理 总被引:15,自引:0,他引:15
采用RSMA为增容剂制备了PA6/PP共混物,研究了RSMA增容PA6/PP共混物的形态结构和热行为以及晶态结构,并探讨RSMA增容PA6/PP共混物的增容机理结果表明,PA6/PP共混物为热力不相容的海岛型两相结构,RSMA的加入改善BPA6与PP相间的相容性,使两相分均匀,分散度提高。RSMA对PA/PP共混物的增容机理可用界面-分散相复合模型描述。 相似文献
15.
In this paper unreinforced and long-glass-fibre-reinforced PA66/PP blends with different glass-fibre sizing were studied with respect to their fracture toughness determined by the typical Kc method. The fracture surfaces of these blends were studied by scanning electron microscopy in order to characterize the failure mechanisms. For the unreinforced blends a decrease in fracture toughness was observed when 25 wt% of polyamide (PA) was added to the polypropylene (PP) matrix, compared with the plain PP and PA matrices. On the other hand an increase in fracture toughness was observed when 25 wt% of PP was added to the PA matrix. This was explained by the differences in thermal expansion of PP and PA. The fracture toughness of the long-glass-fibre (LGF) composites were not affected by the glass-fibre sizing up to a PA/PP ratio of 50/50. After the phase inversion from a continuous PP to a continuous PA phase in the matrix (between PA/PP ratios of 50/50 and 75/25) the PA glass-fibre sized composite showed higher fracture toughness than the PP sized. This was explained by the change of the fibre-related failure mechanism from frequent fibre pull-out to fibre fracture. In addition the matrix affected the fracture toughness of the PA/PP75/25 blend with PA glass-fibre sizing in a positive way, resulting in the highest fracture toughness observed in this study. 相似文献
16.
Pankaj Agrawal Silvia I. Oliveira E. M. Araújo Tomas J. A. Melo 《Journal of Materials Science》2007,42(13):5007-5012
In this work, the rheological, mechanical and morphological properties of nylon 6/polypropylene compatibilized blends were
investigated. Two types of polypropylene were used. One with MFI of 40 g/10 min (PP H103) and the other with MFI of 3.5 g/10 min
(PP H503). The compatibilizers used were polypropylene grafted with 6% of acrylic acid (PPgAA) and polypropylene grafted with
1% of maleic anhydride (PPgMA). The blends composition was 80/20 (wt%) for the PA6/PP binary blends and 80/10/10(wt%) for
the nylon 6/PPgAA/polypropylene and nylon 6/PPgMA/polypropylene ternary blends. Torque rheometry analysis showed that when
PPgAA and PPgMA were added to nylon 6/polypropylene blends, there was an increase in the torque, indicating that reactive
compatibilization has occurred. There is no influence of the polypropylene MFI on the mechanical properties of the uncompatibilized
and compatibilized blends. The impact strength of the blends containing PPgMA were greater than those of the blends containing
PPgAA. The blends containing PPgAA are unstable. SEM analysis showed that PPgMA improves considerably the adhesion between
PA6/PP phases, leading to good mechanical properties. 相似文献
17.
增容作用和动态固化对聚丙烯/环氧树脂共混物形态结构的影响 总被引:2,自引:0,他引:2
研究了增容作用和动态固化对聚丙烯(PP)/环氧树脂(EP)共混物形态结构的影响。实验结果表明,PP/EP共混物是不相容共混体系,当环氧树脂含量小于50%时,共混物中环氧树脂以分散相存在,PP为连续相。反之,则共混物的相态发生相反转,即环氧树脂为连续相,PP为分散相。加入马来酸酐接枝聚丙烯(M AH-g-PP)促进环氧树脂与PP的相容性,使得分散相的颗粒明显变小。与PP/EP和PP/M AH-g-PP/EP共混物不同,当环氧树脂含量大于50%时,动态固化PP/EP和PP/M AH-g-PP/EP共混物仍是环氧树脂分散相和PP连续相结构,未出现相反转。对于相同含量环氧树脂的共混物,动态固化PP/M AH-g-PP/EP共混物中环氧树脂分散相尺寸明显小于动态固化PP/EP共混物中环氧树脂分散相尺寸。 相似文献
18.
利用自主设计的多级拉伸挤出设备,制备了聚丙烯/(聚酰胺+炭黑)(PP/(PA1010+CB))复合材料,该聚合物熔体在挤出过程中受纵向拉伸力(F∥)和横向拉伸力(F⊥)的双向拉伸作用。通过扫描电子显微镜观察,随着分散相(PA1010+CB)含量的增加,CB在PA1010中含量的增加,相容剂含量的降低,分散相(PA1010+CB)的尺寸变大且变形能力增强,此时F⊥发挥作用,使分散相发生横向变形。体系中尺寸较大的分散相形成二维片状,尺寸较小的分散相形成纤维状。 相似文献