Prediction of impact behaviour for natural fiber-reinforced composites using the finite element method

Phani Prasanthi Parvathaneni, V. V. V. Madhav, C. S. Chaitanya, Vallabhaneni Veda Spandana, K. Saxena, Sahil Garg, M. A. Zeleke
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Abstract

In the past ten years, as awareness of biodegradability has increased, so has the utilization of natural fiber-reinforced composites. Along with the material properties, dynamic responsiveness is also necessary for the efficient design of these natural reinforced composites. In the current work, elastic characteristics and interfacial stress are evaluated for natural fiber-reinforced composites utilizing micromechanics and finite element methods. Later, employing explicit dynamic analysis, the natural composite plate was examined under impact loading. The analytical results used to verify the finite element models at each stage show good agreement. To carry out the current study, natural fiber-reinforced composites like hemp, sisal and flax as well as hemp + sisal, sisal + flax and hemp + flax hybrid composites were evaluated for their elastic modulus in longitudinal, transverse, in-plane and out of plane directions as well as their major and minor Poisson’s ratio. By adjusting the impactor’s velocity from 2 m/s to 11 m/s, the deformation, stresses, internal energy and energy summary of the hybrid natural fiber-reinforced composite are calculated from the impact analysis. Based on all the findings, the performance of hemp fiber and hemp fiber-based hybrid composites is better than all other composites taken into consideration for the current work. This research is utilized to build composite materials that function effectively under gradual loading.
用有限元法预测天然纤维增强复合材料的冲击性能
在过去的十年里,随着人们对生物可降解性的认识的提高,天然纤维增强复合材料的利用也越来越多。除了材料性能外,动态响应性对这些天然增强复合材料的有效设计也是必要的。本文采用细观力学和有限元方法对天然纤维增强复合材料的弹性特性和界面应力进行了研究。随后,采用显式动力分析方法,对天然复合材料板进行了冲击载荷下的受力分析。各阶段有限元模型的分析结果吻合较好。为开展本研究,对天然纤维增强复合材料如麻、剑麻和亚麻,以及麻+剑麻、剑麻+亚麻和麻+亚麻混杂复合材料在纵向、横向、面内、面外方向的弹性模量以及主、次泊松比进行了评价。通过将冲击器速度从2 m/s调整到11 m/s,通过冲击分析计算了混杂天然纤维增强复合材料的变形、应力、内能和能量汇总。综上所述,大麻纤维和大麻纤维基混杂复合材料的性能优于目前所考虑的所有其他复合材料。本研究将用于构建在渐变载荷下有效工作的复合材料。
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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