Evaluation of mechanical properties of natural fiber based polymer composite

Tarikur Jaman Pramanik , Md. Rafiquzzaman , Anup Karmakar , Marzan Hasan Nayeem , S M Kalbin Salim Turjo , Md. Ragib Abid
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Abstract

Natural fiber based polymer composites are eco-friendly alternatives to synthetic materials, with greater mechanical properties, biodegradability, availability, ease of access, and affordability. Jute fiber is widely recognized as one of the most important and beneficial natural fibers due to its strength, durability, and biodegradability. In this study, the jute composite is designed and fabricated using a 5-layer jute and epoxy resin, utilizing the manual hand lay-up technique. The combination of 52.5 % jute and 47.5 % of epoxy resin and harder is found optimized to achieve the goals of improving the tensile strength and flexural strength, reducing the cost of epoxy resin, and promoting eco-friendliness and sustainability. Tensile testing was performed on a universal testing machine, while flexural testing was done with a three-point bending test. Experimentally, the composites reinforced with jute and epoxy resin were capable of achieving the required levels of tensile strength (42.91 MPa) and bending strength (69.30 MPa). To validate and visualize specimens, numerical analysis was performed on the ABAQUS simulation software. The numerical simulation utilized ASTM D3039 and ASTM D7264 as the specified requirements for tensile and flexural behavior. For validation, these tensile and flexural test results were then numerically analyzed and compared to the experimental data. Finally, composite design, fabrication, and optimization can improve mechanical properties, reduce composite weight, lower resin cost, and increase sustainability. The proposed design and composition can be implemented to achieve lightweight properties in various applications, such as car components, door handle sheets, bicycle seat backs, and luggage covers.
天然纤维基聚合物复合材料机械性能评估
基于天然纤维的聚合物复合材料是合成材料的生态友好型替代品,具有更高的机械性能、生物可降解性、可用性、易获取性和经济性。黄麻纤维因其强度、耐久性和生物可降解性,被公认为最重要、最有益的天然纤维之一。在这项研究中,我们利用手工铺层技术,设计并制造了一种由 5 层黄麻和环氧树脂组成的黄麻复合材料。研究发现,52.5% 的黄麻和 47.5%的环氧树脂以及较硬的黄麻的优化组合可实现提高拉伸强度和抗弯强度、降低环氧树脂成本以及促进生态友好性和可持续性的目标。拉伸测试在万能试验机上进行,而弯曲测试则采用三点弯曲试验。实验结果表明,用黄麻和环氧树脂增强的复合材料能够达到所需的拉伸强度(42.91 兆帕)和弯曲强度(69.30 兆帕)。为了验证和观察试样,使用 ABAQUS 仿真软件进行了数值分析。数值模拟采用 ASTM D3039 和 ASTM D7264 作为拉伸和弯曲行为的指定要求。然后,对这些拉伸和弯曲测试结果进行数值分析,并与实验数据进行比较,以进行验证。最后,复合材料的设计、制造和优化可以改善机械性能、减轻复合材料重量、降低树脂成本并提高可持续性。所建议的设计和组成可在汽车部件、门把手板、自行车椅背和行李箱盖等各种应用中实现轻质特性。
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CiteScore
4.80
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