加工温度、压力和纤维体积分数对完全可回收的单向热塑性聚合物-纤维增强聚合物的机械和形态行为的影响

IF 5.3 Q2 MATERIALS SCIENCE, COMPOSITES
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引用次数: 0

摘要

这项研究探讨了一种称为热塑性聚合物-纤维增强聚合物(PFRP)的复合材料,这种复合材料通常被称为自增强复合材料(SRC)。使用嵌入高密度聚乙烯(HDPE)基体中的单向(UD)超高分子量聚乙烯(UHMWPE)纤维,对具有代表性的 PFRP 进行了示范。实验研究了压缩成型温度和压力对不同纤维体积分数(Vf)的丝状缠绕 PFRP 的机械和形态行为的影响。结果阐明了 PFRP 的形态和拉伸性能因热熔化、压力造成的纤维错位以及 Vf 引起的结构变化而发生的演变,而这一点尚未得到全面报道。PFRP 薄片的最高比拉伸强度和模量分别达到 600 兆帕/(克/立方厘米)和 31 千兆帕/(克/立方厘米)。这些性能与玻璃/芳纶纤维增强聚合物(GFRPs、GFRTPs、AFRPs 和 AFRTPs)相当,与其他常见聚合物复合材料相比,PFRPs 表现出更好的延展性(峰值载荷时的比应变≈ 4%/(g/cm3))。这项工作的动机是 PFRP 具有很高的可回收性,可通过熔化纤维和基体进行回收,然后对其进行重塑以重新制造复合材料,从而最大限度地提高材料的再利用效率。这一工艺简化了闭环回收、再制造和再利用的实施过程,从而支持复合材料的可持续发展。这项工作旨在推动热塑性 PFRP 在各行各业的潜在应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Effects of processing temperature, pressure, and fiber volume fraction on mechanical and morphological behaviors of fully-recyclable uni-directional thermoplastic polymer-fiber-reinforced polymers

This work explores a type of composite called thermoplastic polymer-fiber-reinforced polymers (PFRPs), often referred to as self-reinforced composites (SRCs). A representative PFRP was exemplified using unidirectional (UD) ultra-high-molecular-weight polyethylene (UHMWPE) fibers embedded in a high-density polyethylene (HDPE) matrix. The effects of compression molding temperature and pressure on the mechanical and morphological behaviors of the filament-wound PFRPs with various fiber volume fractions (Vf) were experimentally investigated.

The results elucidate the evolution of morphologies and tensile properties of the PFRPs due to thermal melting, fiber misalignment from pressure, and Vf-induced structural variance, which has not been comprehensively reported yet. The highest specific tensile strength and modulus of the PFRP laminae reach 600 MPa/(g/cm3) and 31 GPa/(g/cm3), respectively. These properties are comparable to glass-/aramid-fiber-reinforced polymers (GFRPs, GFRTPs, AFRPs, and AFRTPs), with PFRPs exhibiting better ductility (specific strain at peak load 4%/(g/cm3)) than other common polymer composites.

The motivation for this work was the high recyclability of PFRPs, which can be recycled by melting both the fibers and the matrix, and then reshaped them for re-manufacturing composites to maximize the efficiency in material reuse. This process simplifies the implementation of closed-loop recycling, re-manufacturing, and reuse to support sustainability in composites. This work aims to contribute to advancing thermoplastic PFRPs for their potential applications in various industries.

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来源期刊
Composites Part C Open Access
Composites Part C Open Access Engineering-Mechanical Engineering
CiteScore
8.60
自引率
2.40%
发文量
96
审稿时长
55 days
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