桉树树皮渣在聚氯乙烯复合材料生产中的应用:纤维大小和含量的影响

Luiz G. B. Scapolio, I. Moroz, Antonio Rodolfo Jr, I. Cesarino, A. L. Leão, C. H. Scuracchio
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引用次数: 0

摘要

巴西是世界上最大的短纤维纤维素生产国,产生大量的桉树树皮残渣(EBR)。为了获得木塑复合材料(WPC),研究了磨碎的EBR添加到聚氯乙烯(PVC)基体中的效果,考虑了不同的粒度和基质/负载比例。分析了纤维含量、添加量和粒径范围对PVC-EBR纤维复合材料力学性能和热性能的影响。最后,通过将这些性能与文献报道的性能进行比较,验证了EBR作为填料/增强剂应用于PVC基WPC的可行性。本研究的主要目的是评估EBR纤维的尺寸和含量对PVC基WPC的影响,旨在降低成本,提高其机械和物理性能。所制备的复合材料的加工方法是两辊铣后热压。通过化学和热重分析、扫描电子显微镜(SEM)和长径比测定对残留物进行了表征。复合材料的评估包括密度、拉伸和弯曲测试、抗冲击性、热变形温度(HDT)、吸湿性和拉伸断裂样品的扫描电镜。纤维的加入提高了拉伸模量和弯曲模量,分别提高了46%和58%,粒径较小的纤维效果更好;然而,抗冲击性和断裂伸长率降低,分别达到对照样品性能的48%和5%。扫描电镜图像显示纤维脱离和拔出,由于其低基质粘附。EBR纤维由于界面附着力低,导致更多的空隙形成,从而导致从基体到纤维的应力传递较差,此外,EBR在PVC基体中起到应力集中剂的作用;因此,冲击断裂发生在较低的能量水平。可见纤维脱离和脱离基体的区域,清楚地表明相的低粘附性能,也与观察到的两种纤维的机械性能下降相一致。扫描电镜图像表明,纤维可以被认为是PVC基体内的外来颗粒,起到应力集中剂的作用。此外,由于纤维的直径大于由裂纹引起的空隙,平面密度在垂直于链拉伸的方向上减小,导致断裂值处的应变较低。颗粒更细的纤维复合材料显示出更少的空隙,这可能表明纤维的粘附效率更高。这可能是由于在细纤维的粗糙度中聚合物链的渗透性更高,从而导致更高的抗拉强度值。EBR含量的增加,特别是弯曲模量和拉伸模量的增加,而断裂伸长率和抗冲击性降低。由于纤维-基体界面粘附性差,抗拉强度降低,尽管显著,但允许使用高纤维添加量的复合材料。EBR的使用与循环经济的概念是一致的。因此,较高的纤维添加量与节省资金直接相关,因为这种残留物的成本低于PVC,而且由于WPC可以长期使用,允许回收,这也是这种残留物的环保正确目的地。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Eucalyptus bark residue application for Poly(Vinyl Chloride) composite production: Influence of fiber size and content
Brazil is the world’s largest producer of short fiber cellulose, generating large amounts of eucalyptus bark residue (EBR). Aiming to obtain composites known as wood plastic composites (WPC), the effect of ground EBR addition to a poly(vinyl chloride) (PVC) matrix was studied, considering different granulometries and matrix/load proportions. The influence of fiber content addition and particle size range was analyzed in terms of mechanical and thermal properties of the PVC-EBR fiber composites obtained. Finally, by comparing these properties with those reported in the literature, the viability of EBR application as filler/reinforcement in a WPC with PVC matrix was verified. The main objective of the present study was to evaluated the influence of EBR fiber size and content in the WPC with PVC matrix, aiming to reduce the costs and improve its mechanical and physical properties. The processing method for prepared the composites were two-roll milling and subsequent hot pressing. The residue was characterized via chemical and thermogravimetric analyses, scanning electron microscopy (SEM), and aspect ratio determination. Composite evaluation involved density, tensile and flexural tests, impact resistance, heat deflection temperature (HDT), moisture absorption, and SEM of tensile fractured specimens. Tensile and flexural moduli were improved with fiber addition attaining 46% and 58% increases, respectively, with better results for smaller particle size fibers; impact resistance and elongation at break, however, were reduced, attaining 48% and 5% of the control sample’s properties. SEM images reveal fiber detachment and pull-out due to their low matrix adhesion. EBR fibers cause more void formation due to low interface adhesion, which results in poor stress transference from the matrix to the fiber, in addition to EBR acting as stress concentrators in the PVC matrix; therefore, impact fracture occurs with lower energy levels. Regions with fiber detachment and pullout from the matrix are visible, clearly demonstrating the low adhesion properties of the phases and also in accordance with the observed decrease in mechanical properties for both fibers. SEM images indicate that fibers can be considered foreign particles inside the PVC matrix, acting as stress concentrators. Also, since fibers have diameters larger than the voids caused by crazing, planar density is reduced in the direction perpendicular to chain stretching leading to low strain at break values. Composites of fiber with finer particle showed fewer voids, possibly indicating a more efficient adhesion for fibers. This could be due to a higher penetration of polymeric chains in the rugosity of finer fibers, leading to higher values of tensile strength. The addition of EBR content increased especially flexural and tensile moduli whilst elongation at break and impact resistance are reduced. The reduction in tensile strength due to poor fiber-matrix interfacial adhesion, though significant, allowed the use of composites with higher fiber additions. The use of EBR is coherent with the concept of circular economy. Thus, higher fiber additions relate directly to money savings since this residue costs less than PVC, and also this is an environmentally correct destination for this residue since WPC is long-term usable allowing for recycling.
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