Post-impact damage tolerance of natural fibre-reinforced sheet moulding compound

IF 1.7 4区材料科学 Q3 MATERIALS SCIENCE, COMPOSITES

Advanced Composites Letters Pub Date : 2020-10-29 DOI:10.1177/2633366X20967935

H. Patel, T. Peijs

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Abstract

Natural fibre composites are of interest for a wide range of semi-structural applications in the building, construction and automotive sector. For a number of these applications, the evaluation of performance degradation after impact is of some relevance. The present work focused on the influence of fibre volume fraction and fibre surface treatment on the residual load-bearing capability of hemp fibre-reinforced sheet moulding compound (H-SMC) after non-penetrating impacts. Post-impact flexural strength and stiffness of H-SMC decreased linearly with increasing impact energy. At higher impact energy levels, the residual flexural strength of H-SMC improved with increasing fibre volume fraction. However, for the same amount of absorbed energy, the residual strength or damage tolerance capability of glass fibre-reinforced sheet moulding compound was about twice that of H-SMC. Composites based on surface treated hemp fibres showed a slight improvement in residual flexural strength, particularly for systems based on hemp fibres treated with a combined alkaline and silane surface treatment. Surface treated systems showed improved levels of adhesion and increased levels of energy absorption through potential mechanisms such as debonding, pull-out or fibre fibrillation.

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天然纤维增强薄板成型复合材料的冲击后损伤容限

天然纤维复合材料在建筑、建筑和汽车行业具有广泛的半结构应用。对于这些应用中的许多应用，对撞击后性能退化的评估具有一定的相关性。研究了纤维体积分数和纤维表面处理对大麻纤维增强片状模塑料（H-SMC）非穿透冲击后残余承载能力的影响。H-SMC的冲击后弯曲强度和刚度随冲击能量的增加呈线性下降。在较高的冲击能级下，H-SMC的残余弯曲强度随着纤维体积分数的增加而提高。然而，对于相同量的吸收能量，玻璃纤维增强片材模塑化合物的残余强度或损伤容限能力大约是H-SMC的两倍。基于表面处理过的大麻纤维的复合材料显示出残余弯曲强度的轻微改善，特别是对于基于经过碱性和硅烷表面处理的大麻纤维处理的系统。表面处理的系统通过潜在的机制，如脱粘、拔出或纤维原纤化，显示出粘合水平的提高和能量吸收水平的提高。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Advanced Composites Letters 工程技术-材料科学：复合

自引率

0.00%

发文量

审稿时长

4.2 months

期刊介绍： Advanced Composites Letters is a peer reviewed, open access journal publishing research which focuses on the field of science and engineering of advanced composite materials or structures.