Formulating Polypropylene with Desired Mechanical Properties through Melt Compounding of Homopolymer and Impact Copolymer

IF 1.9 Q2 CRYSTALLOGRAPHY Polymer Crystallization Pub Date : 2022-04-28 DOI:10.1155/2022/3084446
Yucheng Peng, Shaoyang Liu, Pixiang Wang, Yifen Wang, Xueqi Wang
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引用次数: 3

Abstract

Many grades of homopolymer polypropylene (HPP) and impact copolymer PP (ICPP) with a wide range of mechanical properties have been developed for a variety of applications in different industrial sectors. Management of this wide range of materials is a challenge for material suppliers and manufacturers and product developers. This research was to provide insights for managing material supplies through formulating PP with specific mechanical properties using melt compounding of ICPP and HPP. ICPP and HPP were compounded with an internal mixer at different ratios and then the mixtures were injection molded into specimens for characterization. The mechanical behaviors, fracture surfaces, and thermal properties of the mixtures were then characterized. The fracture surface results indicated that the morphologies of the rubber particles in ICPP changed after compounding with HPP, leading to different mechanical and thermal behaviors of the mixtures. Notched and unnotched impact strengths increased linearly with increasing ICPP contents. The crystallization peak temperatures increased linearly with increasing ICPP contents while the degrees of crystallinity of the mixtures decreased linearly. The thermal compounding process and the original material properties mainly determine the final mixture behaviors, and the mixture properties can be predicted based on the weight ratios of the two components.
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均聚物和抗冲共聚物熔融共混制备具有所需力学性能的聚丙烯
许多牌号的均聚聚丙烯(HPP)和冲击共聚物PP (ICPP)具有广泛的机械性能,已被开发用于不同工业部门的各种应用。管理如此广泛的材料对材料供应商、制造商和产品开发人员来说是一个挑战。本研究旨在通过使用ICPP和HPP的熔体复合来制定具有特定机械性能的PP,从而为管理材料供应提供见解。将ICPP和HPP按不同比例用内混频器混合,然后注射到样品中进行表征。然后对混合物的力学行为、断口表面和热性能进行了表征。断口形貌分析结果表明,与HPP复合后,ICPP中橡胶颗粒的形貌发生了变化,导致混合物的力学和热行为发生了变化。缺口和非缺口冲击强度随ICPP含量的增加而线性增加。结晶峰温度随ICPP含量的增加而线性升高,而结晶度则线性降低。热复合过程和原材料性能主要决定了最终的混合性能,混合性能可以根据两组分的重量比进行预测。
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来源期刊
Polymer Crystallization
Polymer Crystallization Materials Science-Materials Science (miscellaneous)
CiteScore
4.70
自引率
0.00%
发文量
7
期刊最新文献
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