地面轮胎橡胶填充低密度聚乙烯:粒径的影响

IF 9.9 Q1 MATERIALS SCIENCE, COMPOSITES Advanced Industrial and Engineering Polymer Research Pub Date : 2022-01-01 DOI:10.1016/j.aiepr.2021.07.001
Lóránt Kiss , Dániel Ábel Simon , Roland Petrény , Dávid Kocsis , Tamás Bárány , László Mészáros
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引用次数: 9

摘要

在本研究中,我们研究了水射流碾磨生产的超细磨胎橡胶(uGTR)增值回收的可能性,平均粒径为几十微米。我们的目标是比较不同uGTR含量的共混物和与低密度聚乙烯(LDPE)共混制备的常规细磨轮胎橡胶(fGTR)的性能。我们还旨在探索由于尺寸效应而导致的更大的比表面积所引起的性能变化。样品经内部混合后用液压机制备。以地面轮胎橡胶(GTR)填充混合料时,其拉伸性能表现为类橡胶特性:模量显著降低,断裂伸长率保持较高,抗拉强度略有下降。通过扫描电镜(SEM)对试样的断口形貌进行了分析,发现用uGTR制备的材料具有较好的相间附着力。为了研究GTR和LDPE之间的界面粘附性,我们进行了动态机械热分析(DMTA)。与含有fGTR的样品相比,uGTR的玻璃化转变峰向更高的温度移动,存储模量更高。最后,我们测定了材料的邵氏D硬度,该硬度随GTR含量的增加而降低,但uGTR样品的硬度更高。与fGTR相比,含有uGTR的共混物具有更高的比表面积,因此两相之间具有更好的界面粘附性,从而具有更好的机械性能。
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Ground tire rubber filled low-density polyethylene: The effect of particle size

In the present study, we investigated the possibility of value-added recycling of ultrafine ground tire rubber (uGTR) produced from water jet milling, with an average particle size of a few tens of microns. Our goal was to compare the properties of blends with different uGTR and conventional fine ground tire rubber (fGTR) contents prepared by blending with low-density polyethylene (LDPE). We also aimed to explore the property changes caused by the larger specific surface area due to the size effect. Samples were prepared with a hydraulic press after internal mixing. In the case of ground tire rubber (GTR) filled mixtures, the tensile properties showed rubber-like characteristics: with a significant decrease in modulus, elongation at break remained high, and tensile strength slightly decreased. The fracture surfaces of the samples were analyzed by scanning electron microscopy (SEM), wherein the case of materials made with uGTR showed better adhesion between the phases. In order to investigate the interfacial adhesion between the GTR and LDPE, we performed dynamic mechanical thermal analysis (DMTA). The glass transition peak of the uGTR shifted to a higher temperature and the storage modulus was higher than in the case of samples containing fGTR. Finally, we determined the Shore D hardness of the materials, which decreased with increasing GTR content, but hardness was greater in the case of uGTR samples. The better mechanical properties of blends containing uGTR were explained by better interfacial adhesion between the two phases due to the significantly higher specific surface area compared to fGTR.

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来源期刊
Advanced Industrial and Engineering Polymer Research
Advanced Industrial and Engineering Polymer Research Materials Science-Polymers and Plastics
CiteScore
26.30
自引率
0.00%
发文量
38
审稿时长
29 days
期刊最新文献
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