The Friction Wear Properties and Application of Thermoplastic Polyester Elastomer and Polyoxymethylene

The experiment of injection molding, Dais-simulating test, morphological structure investigation(Scanning Electron Microscopy, SEM),X-ray photoelectron spectroscopy(XPS)were performed on mini-automobile spherical seat which was made of thermoplastic polyester elastomer(TPEE)and oiled polyoxymethylene(POM),respectively. The friction-wear properties between the frictionl pair of polymer spherical seat and metallic(iron)spherical pin were studied. The test results indicate that the antifriction property of TPEE is superior to that of POM, while its surface chemical effect is inferior to that of POM.

STRUCTURE-PROPERTY RELATIONSHIP OF THERMOPLASTIC ELASTOMERS——BLOCK COPOLYMERS

Block copolymers are marked by alternation of hard blocks and soft blocks, whereby the hard blocks are believed to form crystalline domains in non-crystalline matrix formed by aggregation of the soft blocks and a fraction of the hard blocks escaping crystallization. On the basis of this two-phase model a number of studies has been made varying the nature and length of hard and soft blocks. After reviewing some papers published in this field, it may be concluded that the system in which properties of thermoplastic elastomers are exhibited can be generally divided into three catalogues, they are polyurethane, polyether-ester, polyesteramide elastomers. Structure-property relationship of these thermoplastic elastomers are given in this paper.

HYDROGEN BOND EFFECT IN THERMOPLASTIC POLYURETHANE ELASTOMERS

Hydrogen bond effects in thermoplastic polyurethane elastomers (TPU) with different chain extender structures and hard segment contents have been studied quantitatively by dynamic mechanical analysis. It has been found that the hydrogen bond effects in TPU decrease with the increase of temperature. The temperature dependence of hydrogen bonding in TPU’s can be described by the Arrhenius equation, and the activation energy of hydrogen bonding as well as the physical cross-link density have been calculated.

Hydrogen Bonding in Thermoplastic Polyurethane Elastomers:IR Thermal Analysis

The hydrogen bond percentage and its temperature dependence of the three TPU samples synthesized from polytetrahydrofuran, 4,4'-diphenylmethane diisocyanate, N -methyl diethanol amine or 1,4-butane diol were studied by means of IR thermal analysis. The enthalpy and the entropy of the hydrogen bond dissociation were determined by the Van't Hoff plot.

Piezoresistive behavior of elastomer composites with segregated network of carbon nanostructures and alumina

Electrically conductive elastomer composites(CECs)with segregated networks of conductive nanofillers show high potential in stretchable strain sensors due to balanced mechanical and electrical properties,yet the sensitivity at low strain is generally insufficient for practical application.Herein,we report an easy and effective way to improve the resistive response to low strain for CECs with segregated network structure via adding stiff alumina into carbon nanostructures(CNS).The CEC containing 0.7 wt%CNS and 5 wt%Al_(2)O_(3) almost sustains the same elasticity(elongation at break of~900%)and conductivity(0.8 S/m)as the control,while the piezoresistive sensitivity is significantly improved.Thermoplastic polyurethane(TPU)composites with a segregated network of hybrid nanofillers(CNS and Al_(2)O_(3))show much higher strain sensitivity(Gauge factor,GF-566)at low strain(45%strain)due to a local stress concentration effect,this sensitivity is superior to that of TPU/CNS composites(GF-11).Such a local stress concentration effect depends on alumina content and its distribution at the TPU particle interface.In addition,CECs with hybrid fillers show better reproducibility in cyclic piezoresistive behavior testing than the control.This work offers an easy method for fabricating CECs with a segregated filler network offering stretchable strain sensors with a high strain sensitivity.

Fabrication and Characterization of Poly(Styrene-Butadiene-Styrene)/Thermoplastic Polyurethane Blends

This investigation presents thermoplastic elastomers (TPEs) based on poly (styrene-butadiene-styrene) (SBS) and thermoplastic polyurethane (TPU) materials were prepared with varying compositions. A series of works were conducted on the relationships between rheological, optical properties, morphology, mechanical properties, abrasion resistance and thermostability given. The results showed that the shear viscosity of SBS not obvious effect with TPU content. The optical properties of the SBS/TPU blend that its uniform transparency. The morphology characteristics indicating the phase diversion and the variation in the size of the SBS domains from large to small as the TPU contents increased, with heterogeneous domain dispersions. Additionally, the mechanical properties, abrasion resistance and thermal resistance are improved as the amount of added TPU is increased, suggesting that the blending of SBS with TPU is consistent with the compound rule.

CPE增容TPU/PVC共混弹性体及相形态

为提高热塑性聚氨酯弹性体(TPU)与聚氯乙烯(PVC)的相容性,以氯化聚乙烯(CPE)为增容剂,经双螺杆挤出机熔融共混制备TPU/PVC共混型热塑性弹性体,测试了不同CPE用量的共混弹性体的拉伸强度、断裂伸长率和硬度等力学性能,以及动态流变性能、动态力学性能和热稳定性。通过扫描电子显微镜(SEM)对共混弹性体的相态结构进行研究。结果表明,当TPU/PVC质量比为70/30时,共混弹性体综合力学性能最佳,拉伸强度为19.92 MPa,断裂伸长率为972%。随着CPE用量的增加,TPU/PVC共混弹性体的拉伸强度、断裂伸长率、硬度等均先增大后减小;CPE用量为6份时,TPU/PVC共混弹性体拉伸强度达到最大,为23.73 MPa,相较未加CPE时提高19.1%。加入CPE的共混弹性体复数黏度和储能模量均呈下降趋势。此外,CPE的加入还能有效提升弹性体高温热稳定性,TPU和PVC两种组分的损耗因子峰内移靠近,共混弹性体液氮脆断面的SEM照片显示PVC相筹明显变小且更为均匀,以上说明CPE对共混弹性体的增塑、增容作用明显,且CPE用量为6份时增容效果最佳。

含能热塑性弹性体推进剂研究进展

含能热塑性弹性体推进剂具有高能量、力学性能优异、可循环利用、可回收等优点,近年来成为固体推进剂发展的重要方向。总结了常见的含能热塑性弹性体的综合性能;论述了含能热塑性弹性体推进剂在高能、高燃速、钝感、低特征信号和富燃料推进剂等领域的研究进展;介绍了压延成型、模压成型、螺压成型和熔铸成型四种含能热塑性弹性体推进剂的制备工艺;综述了含能热塑性弹性体推进剂的重复加工性能和回收利用工艺;指出了目前该类推进剂存在的问题和不足,并对其未来发展方向进行了展望。

微相分离型聚丙烯热塑性弹性体的力学性能

为了制备相畴尺寸均匀、细小,形态结构易控,力学性能稳定的聚丙烯热塑性弹性体(PTPE),设计出了从聚丙烯(PP)与弹性体的均相体系出发,利用在硫化过程中的能效应使之发生微相分离,能效应和熵效应控制组分相畴的尺寸和形态以制备PTPE的原理和技术,研究了橡/塑比、橡胶配比、PP相对分子质量、引发剂用量、架桥剂用量、反应温度对样品化学结构和力学性能的影响。结果表明,在125℃反应温度下样品配方为:橡塑质量比为70/30、乙丙橡胶与丁苯质量比为80∶20、引发剂用量为2.14份、架桥剂用量为18.2份时,制得试样的综合力学性能最佳,拉伸强度、100%定伸应力、扯断伸长率、撕裂强度、扯断永久变形分别为11.25 MPa、8.78 MPa、384%、58.5 kN/m、78%。

锂系聚烯烃弹性体(TPOE)与聚烯烃树脂的共混行为及性能研究

本文剖析了锂系热塑性聚乙烯-丙烯-丁烯-异丙烯(TPOE)、三元乙丙橡胶(EPDM4770P)、聚烯烃弹性体(POE8480)和聚烯烃(TPO/CA10A)树脂的分子结构,探究了这类聚合物的热学性能和物理机械性能,研究了不同用量的TPOE对PP/PE树脂共混物的热学性能和物理机械性能的影响。结果表明,TPOE/PE=1.6~2.5、TPOE/PP=1.4~2.5的共混物,其热学性能和物理机械性能均可与CA10A及POE8480相媲美。

热塑性聚酰胺弹性体合成研究进展

热塑性聚酰胺弹性体(TPAE)是一种由聚酰胺为硬段和聚醚或聚酯等为软段构成的多嵌段共聚物,具有密度低、热稳定性好和耐磨性优等优异性能。TPAE的硬段和软段主要通过它们之间不同类型的端基反应连接,包括羧基与羟基、羧基与氨基、异氰酸酯基与羧基、酰氯与氨基、异氰酸酯基与氨基等官能团之间的缩合反应。本文综述了TPAE合成的研究进展,系统介绍了缩聚反应法、聚加成反应法、原位聚合反应法及其它合成TPAE的方法的反应机理与特点,并分析讨论了它们的优缺点。

不同软段的长碳链聚酰胺弹性体的合成与性能

为研究软段种类对聚酰胺(PA)弹性体性能的影响,合成了具有不同性能的热塑性PA弹性体(TPAE)。以十二碳二元酸、十二碳二元胺和三种不同种类的聚醚[聚环氧乙烷(PEO)、聚环氧丙烷(PPO)和聚四氢呋喃(PTHF)]为原料,采用一步法分别合成了三个系列的PA1212基热塑性弹性体。采用傅里叶变换红外光谱、核磁共振氢谱确定了TPAE的成功合成,通过差示扫描量热分析、热失重分析、动态力学分析(DMA)、力学性能测试、吸水性能测试和电阻率测试对TPAE的性能进行了表征。结果表明,合成的TPAE的熔点高于170℃,热分解温度高于410℃,其中PEO系列弹性体的熔点和结晶温度较高。DMA测试结果表明PEO软段与PA硬段相容性最好,而PPO系列弹性体在-50~-40℃之间的tanδ大于0.3,表明此种材料在低温下具有良好的阻尼性能。PEO系列弹性体力学性能最优,拉伸强度在30~38.5 MPa之间,断裂伸长率高于620%,且拥有较高的吸水性能,饱和吸水率可达到30.2%,体积电阻率相对于PA1212降低了6个数量级。而PTHF系列弹性体有着最低的吸水率,饱和吸水率低至1.4%。三种材料可以应用于不同场景。

医疗器械用热塑性弹性体的制备及耐辐照性能

采用具有耐辐照特性的溴化聚(异丁烯-对甲基苯乙烯)(BIMS)为基体橡胶,与苯乙烯-乙烯-丁烯-苯乙烯嵌段共聚物(SEBS)共混,以烷基苯酚二硫化物作为硫化交联剂,并配合一种生物基增塑剂,采用动态硫化工艺,制备了一种医疗器械用耐辐照动态硫化热塑性弹性体(TPV)。通过对不同剂量辐照后TPV的基本理化性质、顶空气相色谱、红外图谱、热稳定性、动态机械性能和力学性能对比分析研究发现,在辐照灭菌(≤40 kGy)后,产品性能未发生变化,可满足常规医疗器械用弹性体制品对耐辐照性能的要求。

超临界CO_(2)辅助热塑性聚氨酯/热塑性聚酯弹性体的发泡及其回弹特性

为克服热塑性聚氨酯(TPU)发泡后,其发泡材料回弹性不足、压缩强度低及收缩率大等问题,采用热塑性聚酯弹性体(TPEE)改性TPU,并以超临界CO_(2)为发泡剂,制备了TPU/TPEE发泡材料。研究了TPU/TPEE共混物的熔融及结晶行为、流变性能以及TPEE含量对TPU/TPEE发泡材料循环压缩性能、回弹性能、压缩永久变形及发泡性能的影响。差示扫描量热仪与落球回弹、压缩永久形变结果表明,TPEE的加入能使TPU分子链排列的有序性降低,回弹性提高;旋转流变仪结果表明,TPEE的引入可以有效改善共混物熔体的黏弹性,使得弹性作为主导,并显著改善发泡性能;循环压缩结果表明,加入TPEE可以进一步改善泡沫的压缩性能。当添加TPEE的质量分数为7%时,TPU/TPEE发泡体相对于纯TPU泡沫,发泡体落球回弹性提高了7.25%、压缩永久变形值降低了2.84%、压缩强度提高了326%。

共混GAP基含能热塑性弹性体的氢键行为与力学性能

为了改善GAP热塑性弹性体的力学性能,采用了DSC、低场核磁测试、静态力学测试和动态力学测试的方法对两种异氰酸酯固化的弹性体共混体系的氢键行为和力学性能进行分析,建立微观结构与宏观性能的关系。结果表明,由于分子结构原因,HMDI固化的GAP热塑性弹性体和IPDI固化的弹性体显示出不同的氢键行为和力学性能,通过物理共混得到了兼具抗拉强度及断裂延伸率的弹性体,50℃下抗拉强度高于1.5MPa,-40℃下延伸率不低于300%,相较于纯HMDI固化的弹性体,低温延伸率提升了约150%,IPDI固化的弹性体高温抗拉强度提升了约1.4MPa,说明通过共混可得到性能更为均衡的含能热塑性弹性体。

无机粒子对热塑性聚酰胺弹性体发泡及抗收缩行为的影响:开孔机制揭示

以超临界CO_(2)为发泡剂,制备了低收缩高倍率的热塑性聚酰胺弹性体(TPAE)/无机粒子微孔泡沫。基于扫描电子显微镜、接触角仪、真密度仪等仪器,并结合间歇发泡实验研究了无机粒子对TPAE发泡及抗收缩行为的影响。结果表明,相比较于滑石粉(Talc),硅酸钙(CaSiO_(3))、碳酸钙(CaCO_(3))以及硅灰石(WI)这3种无机粒子都分别与TPAE间的界面张力更高,表现出明显的热力学不相容行为。通过对泡沫开孔结构形成机制的分析,发现复合物泡沫的开孔率随无机粒子与TPAE基体间界面张力、无机粒子直径以及分布密度的增加而提高。而开孔结构的形成可加快CO_(2)与空气的置换速率,降低TPAE泡沫的收缩。故无机粒子的引入改善了TPAE泡沫的泡孔密度和泡孔结构的均匀性和尺寸稳定性,进而制备出开孔率超过90%、发泡倍率达到20倍、收缩率低于5%的TPAE泡沫,并显著增强了TPAE泡沫的尺寸稳定性。

锂电池热管理用TPE基柔性复合相变材料的研究进展

热塑性弹性体(TPE)因其出色的柔韧性、低成本和强相容性,可作为相变材料(PCM)的载体,将其与相变材料和导热填料复合制备的柔性复合相变材料(FCPCM)在电池热管理(BTM)领域具有广泛的应用前景。本文通过总结国内外关于TPE基柔性复合相变材料在电池热管理领域的研究成果,对常用的TPE材料进行了分类并对其工作原理和制备方法等进行了详细介绍。针对相变材料在电池热管理应用中存在的低导热性、低形状稳定性、不良力学性能等问题,本文重点介绍了TPE基柔性复合相变材料的热物理性能(相变潜热和热导率)、电池热管理效果(最高温度和最大温差)、力学性能和抗振性能等。指出当前电池热管理中柔性复合相变材料存在的局限性并对未来的发展方向进行了展望,寻找潜在的柔性材料、协同的二元柔性载体和二元导热填料,提高柔性复合相变材料的绝缘性、介电性和低温适应性等方面应是未来的主要研究方向,增强柔性复合相变材料在振动条件下对锂电池的温控性也需要进一步探索。该综述对电池热管理中TPE基柔性复合相变材料的进一步研究和开发提供重要参考价值。

环保丁基再生橡胶/聚氯乙烯热塑性弹性体阻尼材料的制备与性能研究

采用共混法制备环保丁基再生橡胶/聚氯乙烯(PVC)热塑性弹性体阻尼材料(以下简称热塑性弹性体),研究环保丁基再生橡胶用量、PVC改性剂种类和用量、填料(磁粉和硅藻土等)用量对热塑性弹性体性能的影响。结果表明:随着环保丁基再生橡胶用量的增大,热塑性弹性体的力学性能和压缩永久变形下降,密度增大,阻燃性能无明显变化;当环保丁基再生橡胶用量为40份时,热塑性弹性体的综合性能良好且性价比高。采用20份氯化聚乙烯与10份苯乙烯-乙烯-丙烯-苯乙烯共聚物并用作为PVC改性剂,热塑性弹性体的综合性能较优。随着填料用量的增大,热塑性弹性体的密度、阻燃性能和磁性提高,但力学性能下降;当填料用量为120份时,热塑性弹性体的综合性能较优,阻尼温域为-55~100℃,损耗因子≥0.3,阻尼性能好。

基于可低温加工SEBS的发泡母粒及微发泡热塑性弹性体的制备

以可低温加工的氢化苯乙烯-丁二烯嵌段共聚物(SEBS)为基体,将偶氮二甲酰胺(AC)发泡剂、助发泡剂和表面活性剂制备成基于SEBS的发泡母粒,并采用双螺杆挤出机将发泡母粒与动态硫化三元乙丙橡胶(EPDM)/聚丙烯(PP)热塑性弹性体材料(TPE)共混熔融挤出,制备了微发泡TPE材料。研究了SEBS引入量与发泡母粒添加量对微发泡TPE样品的密度、拉伸性能以及泡孔形貌的影响。结果表明,当SEBS的质量分数低于6%,发泡母粒的质量分数为3%时,制备的微发泡TPE材料具有较低的密度、较高的拉伸性能,且泡孔规整度达到最优。