聚氨酯／顺丁橡胶共混物结构与性能的研究

采用物理共混的方法,制备了廉价的ＢＲ和贵的热塑性聚氨酯（ＴＰＵ）共混物。利用电子拉力机,液变仪,动态粘弹仪,偏光显微镜和电子显微镜对力学性能、流变性能,动态粘弹性和形态结构进行了研究和分析。结果表明,ＢＲ和ＴＰＵ有较好的相容性,ＴＰＵ／ＢＲ共混物能达到使用要求,一些性能好于纯ＴＰＵ《     

聚氯乙烯与热塑性聚氨酯的共混改性

将聚氯乙烯（ＰＶＣ）与自制的热塑性聚氨酯（ＴＰＵ）进行共混改性，试验研究了ＰＶＣ分子量、ＰＶＣ／ＴＰＵ共混比及共混方法对共混物性能的影响。结果表明，ＸＳ－３型ＰＶＣ与ＴＰＵ的相容性最好，性能也较为满意。     

热塑性聚氨酯对ABS的共混改性研究

研究了热塑性聚氨酯（ＴＰＵ）与丙烯腈－丁二烯－苯乙烯共聚物（ＡＢＳ）共混对ＡＢＳ结构和性能的影响,结果表明,ＴＰＵ与ＡＢＳ有良好的相容性,ＴＰＵ的加入可以同时改善ＡＢＳ的韧性和流动性,共混物的熔体流动速率随着ＴＰＵ含量的增加而提高,缺口冲击强度则在ＡＢＳ／ＴＰＵ（质量比）为８０：２０时最佳,ＴＰＵ对丁二烯含量较高的ＡＢＳ的改性效果比对丁二烯含量较低的ＡＢＳ更好。     

TPU/PVC弹性材料性能的研究

研究了热塑性聚氨酯（ＴＰＵ）对软质聚氯乙烯材料共混改性的情况,探讨了不同类型,不同含量的ＴＰＵ对共混物的力学性能、弹性性能、老化性能及流变性能的影响,从而获得了性能较好的共混弹性材料。     

TPU／PVC弹性体性能的研究

文章研究了热塑性聚氨酯（ＴＰＵ）对软质聚氯乙烯材料共混改性的情况,探讨了不同类型,不同含量的ＴＰＵ对共混物的力学性能,弹性性能,老化性能及流变性能的影响,从而获得性能较好的共混弹性材料。     

PC／TPU共混物的流变性能

用毛细管流变仪研究了聚碳酸酯（ＰＣ）及聚碳酸酯／热塑性聚氨酯弹性体（ＰＣ／ＴＰＵ）共混物的流变性能。实验结果表明：ＰＣ熔体粘度对剪切速率（γ）不敏感，而对温度（Ｔ）敏感。温度升高，ＰＣ粘度降低。加入ＴＰＵ大大改善了共混物的流动性能，使共混物的成型加工变得容易进行。当ＴＰＵ含量为４０份时，共混物的熔体粘度出现一极小值。加入不同第三组分对于降低共混物的熔体粘度效果不同，第三组分Ｅ对共混物有增粘作用     

PVC／TPU／SBS—g—MMA共混体系研究

制备了ＳＢＳ－ｇ－ＭＭＡ系列接枝共聚物,并对其进行了表征。以ＳＢＳ－ｇ－ＭＭＡ作为ＰＶＣ／ＴＰＵ共混体系的增容剂,对不同配比的ＰＶＣ／ＴＰＵ／ＳＢＳ－ｇ－ＭＭＡ共混体系的物理力学性能、流变性等进行了研究。结果表明,ＳＢＳ－ｇ－ＭＭＡ接枝共聚物对ＰＶＣ／ＴＰＵ共混体系起到了明显的增容作用。     

聚甲醛／热塑性聚氨酯弹性共混增韧的研究

本文选用热塑性聚氨酯弹性体（ＴＰＵ）、用Ｂｒａｂｅｎｄｅｒ熔融挤出共混的方法对聚甲醛（ＰＯＭ）的改性增韧性进行了研究。对ＰＯＭ／ＴＰＵ共混体系的力学性能、流变性能、动态力学性能和形态结构进行了测试及分析。结果表明：随着ＴＰＵ用量的增加，共混体系的冲击强度出现峰值，而同时又保持了其它性能的适当水平。     

POM／PU共混物增容剂的合成与应用

本文以酸为催化剂，将甲醛与一缩乙二醇缩合聚合，缩合物经ＴＤＩ封端，１，４－丁二醇扩链合成了ＰＯＭ／ＰＵ共混物的增容剂ＰＯＵ。利用化学分析法、红外光谱法对合成的ＰＯＵ增容剂进行了表征；借助扫描电子显微镜，差分析仪分析了共混物的微观结构形热行为，并对共混物的力学性能进行了系统研究。研究发现ＰＯＵ的加入使分散相颗粒尺寸明显减小，使三元共混物中ＰＯＭ的烷点降低，并使三元共混物的拉伸强度、缺口冲击强度、断裂     

新型聚丙烯汽车保险杠专用料的研制

作者研究了以聚丙烯（ＰＰ）为基础树脂,以聚烯烃热塑性弹性体ＴＰＥ－１为主增韧剂,同时加入辅助增韧剂和无机填料制备汽车保险杠用改性ＰＰ共混物的方法,并讨论了其共混物组成,用量,ＰＰ熔融指数以及共混物形态结构等对共混物性能的影响。     

聚氨酯增韧聚甲醛的研究

采用机械共混的方法，制备了聚甲醛(POM)／热塑性聚氨酯弹性体(TPU)复合材料；研究了缺口曲率半径对纯POM以及TPU增韧体系冲击韧性的影响；并对其形态结构进行了测试分析。结果表明，纯POM的冲击韧性受缺口尖锐程度影响大，TPU能减小POM结晶度，缩小球晶尺寸，显著降低POM的缺口敏感性；POM／TPU形成双连续结构时成为超韧体系。     

Morphologies and mechanical properties of polylactide/thermoplastic polyurethane elastomer blends

To explore a potential method for improving the toughness of a polylactide (PLA), we used a thermoplastic polyurethane (TPU) elastomer with a high strength and toughness and biocompatibility to prepare PLA/TPU blends suitable for a wide range of applications of PLA as general‐purpose plastics. The structure and properties of the PLA/TPU blends were studied in terms of the mechanical and morphological properties. The results indicate that an obvious yield and neck formation was observed for the PLA/TPU blends; this indicated the transition of PLA from brittle fracture to ductile fracture. The elongation at break and notched impact strength for the PLA/20 wt %TPU blend reached 350% and 25 KJ/m², respectively, without an obvious drop in the tensile strength. The blends were partially miscible systems because of the hydrogen bonding between the molecules of PLA and TPU. Spherical particles of TPU dispersed homogeneously in the PLA matrix, and the fracture surface presented much roughness. With increasing TPU content, the blends exhibited increasing tough failure. The J‐integral value of the PLA/TPU blend was much higher than that of the neat PLA; this indicated that the toughened blends had increasing crack initiation resistance and crack propagation resistance. © 2010 Wiley Periodicals, Inc. J Appl Polym Sci, 2011     

Super‐Tough and Highly‐Ductile Poly(l‐lactic acid)/Thermoplastic Polyurethane/Epoxide‐Containing Ethylene Copolymer Blends Prepared by Reactive Blending

Ethylene‐methyl acrylate‐glycidyl methacrylate copolymer (E‐MA‐GMA) is employed to improve the impact toughness of poly(l ‐lactic acid) (PLLA)/thermoplastic polyurethane (TPU) blends by reactive melt‐blending. The reaction and miscibility between the components are confirmed by Fourier transform infrared spectroscopy, dynamic mechanical analysis, and differential scanning calorimetry. A super‐tough PLLA/TPU/E‐MA‐GMA multiphase blend (75/10/15) exhibits a significantly improved impact strength of 77.77 kJ m^?2, which is more than 17 times higher than that of PLLA/TPU (90/10) blend. A co‐continuous‐like TPU phase structure involving E‐MA‐GMA phase at the etched cryo‐fractured surface and the high‐orientated matrix deformation at the impact‐fractured surface are observed by scanning electron microscopy. The high‐orientated matrix deformation induced by the co‐continuous TPU phase structure is responsible for the super toughness of PLLA/TPU/E‐MA‐GMA blends.     

Investigation of structure and mechanical properties of toughened poly(l‐lactide)/thermoplastic poly(ester urethane) blends

In this study, poly(l ‐lactide) (PLA) is melt‐blended with thermoplastic polyurethane (TPU) to modify the brittleness of PLA. An aliphatic ester‐based TPU was selected in order to have an ester sensitivity for degradation and an inherent biocompatibility. Using this compatible TPU, there was no need to apply problematic compatibilizers, so the main positive properties of PLA such as biocompatibility and degradability were not challenged. The detected microstructure of PLA/TPU blends showed that when the TPU content was lower than 25 wt %, the structure appeared as sea‐islands, but when the TPU content was increased, the morphology was converted to a cocontinuous microstructure. A higher interfacial surface area in the blend with 25 wt % TPU (PLA25) resulted in a higher toughness and abrasion resistance. The various analyses confirmed interactions and successful coupling of two phases and confirmed that melt‐blending of PLA with the aliphatic ester‐based TPU is a convenient, cost‐effective, and efficient method to conquer the brittleness of PLA. The prepared blends are general‐purpose plastics, but PLA25 showed an optimum mechanical strength, toughness, and biocompatibility suitable for a wide range of applications. © 2015 Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2016 , 133, 43104.     

Interfacial reaction and its influence on phase morphology and impact properties of modified‐polyacetal/thermoplastic polyurethane blends

The cationic polymerization of 1,3,5‐trioxane, 1,3‐dioxolane and a small amount of 2‐hydroxyacetic acid (HAA) was carried out, and the resulting modified‐polyacetal (POM) was blended with thermoplastic polyurethane (TPU) in melt. The results of ¹H NMR analysis indicated that HAA was almost incorporated in the modified‐POM, and that the resulting carboxyl end‐group and hydroxyl end‐group in the modified‐POM reacted with TPU during the melt blending. There were many boundary layers between the cavities and matrix in the modified‐POM/TPU (82/18 by weight) blend that was etched with tetrahydrofuran (THF), and the diameter of the cavities became ～0.3–1 μm long when the blending time reached 10 min. The results of scanning electron microscopic (SEM) observation and dynamic mechanical analysis (DMA) indicated that the modified‐POM/TPU blend had a good compatibility because of the interfacial reaction between the modified‐POM and TPU phase in the blend. The modified‐POM/TPU blend exhibited higher Charpy impact strength when compared with a normal‐POM/TPU blend; the toughness of the modified‐POM/TPU blend attributed to the good compatibility between the two phases. © 2006 Wiley Periodicals, Inc. J Appl Polym Sci 100: 4375–4382, 2006     

抗静电TPU／LDPE／SBS共混材料的性能研究

报道了ＴＰＵ／ＬＤＰＥ／ＳＢＳ共混材料的电性能和力学性能,探讨了共混比、乙炔炭黑用量对材料性能的影响;用透射电镜分析了该共混体系的结构。结果表明,该共混体系可以形成互穿网络结构,从而强迫相容,在共混比为１０／３／１００时,乙炔炭黑用量为２２质量份可以制得综合性能优良的抗静电塑性橡胶材料。     

The mechanical and rheological behavior of the PA/TPU blend with POE‐g‐MA modifier

In this research, we attempt to improve the impact strength and the viscosity of PA (polyamide) by blending two elastomers, TPU (thermoplastic polyurethane) and POE‐g‐MA (maleic anhydride‐grafted polyethylene‐octene elastomer), in PA matrix with twin screw extruder. The ratio of blending is 80PA/20TPU and 80PA/20TPU/20POE‐g‐MA (66.66PA/16.67TPU/16.67POE‐g‐MA). Results indicate that POE‐g‐MA improves the low viscosity of PA and TPU during the blending process, and also their compatibility. Thus, the 80PA/20TPU/20POE‐g‐MA blend has better tensile stress and elongation than 80PA/20TPU blend, and furthermore POE‐g‐MA significantly improves the impact strength of PA, even to super‐toughness grade. © 2009 Wiley Periodicals, Inc. J Appl Polym Sci, 2010     

Tailoring morphology to improve the gas‐barrier properties of thermoplastic polyurethane/ethylene‐vinyl alcohol blends

The morphology and helium‐barrier properties of thermoplastic polyurethane (TPU)/ethylene‐vinyl alcohol (EVOH) blends with and without dicumyl peroxide (DCP) were investigated by melting blending. A lamellar dispersion of EVOH with good helium‐barrier properties was observed in the TPU matrix with DCP. The evolution of the morphology of the blends is mainly related to the variation of the viscosity ratio between the dispersed phase and the matrix phase. Compared with pure TPU, lamellar morphology increased the helium‐barrier properties of the TPU/EVOH (60/40) blend by as much as 10‐fold. We also explored the effects of composition, DCP content, and blending sequence on the morphology and helium‐barrier properties of the TPU/EVOH blends. The morphology of the blends ranged from a droplet‐matrix to a lamellar structure. We determined the optimum amount of DCP to improve the helium barrier of the blends. The helium‐barrier properties of the blends prepared by direct blending were superior to those of the blends prepared by two‐segment blending, and the blends prepared by direct blending exhibited a well‐developed lamellar morphology. We compared the permeability of the samples with the theoretical results to explain the relationship between morphology and helium‐barrier properties. POLYM. ENG. SCI., 56:922–931, 2016. © 2016 Society of Plastics Engineers     

Mechanical fracture behavior of polyacetal and thermoplastic polyurethane elastomer toughened polyacetal

Polyacetal (POM) toughening with thermoplastic polyurethane (TPU) elastomer was investigated in terms of Theological, mechanical, and morphological properties. Polyacetal can be effectively toughened by the blending with TPU elastomer and the improvement on toughness is found most significant with TPU content from 20 to 30 percent. POM does fracture in ductile mode under extremely low deformation rate and the ductile-brittle transition rate is at 0.5 mm/min. The transition rate is increased with the increase of elastomer content. The precrack hysteresis energy is important in dictating the failure mode. The experimental results show the hysteresis energy (under constant load) increases with the increase of elastomer content and the decrease of deformation rate. Greater hysteresis energy results in larger precrack plastic zone size and thus tends to shift the fracture mode from brittle to ductile as the critical size of the plastic zone is reached. The adoption of the slow rate fracture method has the advantages of ranking toughness of very brittle polymeric materials vs. the conventional Izod or Charpy impact method by varying temperatures. FTIR shows significant interaction between POM and TPU which is probably responsible for the TPU elastomer being such an efficient toughening agent for POM. Delamination in the buffer zone between the plane-strain and the plane-stress is discovered and the possible mechanism is discussed.