Evaluation of the Mechanical Properties of a Novel Hybrid Composite Composed of Rattan and Date Palm Fiber: An Experimental Study

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Md. Kharshiduzzaman, Mohammad Rejaul Haque, Md Shahnewaz Bhuiyan, Sabrul Alam, Md. Mashuk, S.K. Nayeem Ahmed, Shahidul Haque Afgani, M. A. Gafur
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Abstract

Numerous studies have examined rattan and date palm fibers separately, but none have combined both fibers in a single composite. This research focuses on creating novel hybrid composites using untreated and treated rattan and date palm fibers. Fibers were treated with 3%, 4%, and 5% NaOH solutions. Fiber diameters were measured microscopically. The NaOH treatment enhanced the tensile strength of the fibers. Untreated rattan, midrib, and spadix stem fibers exhibited tensile strengths of 18, 57, and 37 MPa, respectively. Polyester was used as the matrix, combined with fibers in weight fractions of 70 : 30, 75 : 25, and 80 : 20. All composites were made for 1 : 1 rattan–midrib and 1 : 1 rattan–spadix stem fibers. Composites containing 20% treated rattan–midrib fibers displayed the highest tensile and flexural strengths, measuring 13 and 39 MPa, respectively. Meanwhile, rattan–spadix stem composites achieved the highest tensile strength of 14 MPa at 30% treated fiber loading, and the highest flexural strength of 28.91 MPa at 20% fiber wt.%. Additionally, SEM images of the tensile fracture surfaces revealed voids, cracks, and impurities. The goal was to develop a new composite that provides a low cost, structurally sound, and environmentally friendly strong material suited for industrial, construction, and aviation applications.

Abstract Image

评估由藤条和枣椰树纤维组成的新型混合复合材料的力学性能:实验研究
许多研究分别对藤条纤维和椰枣纤维进行了研究,但没有一项研究将这两种纤维结合在一种复合材料中。本研究的重点是使用未经处理和处理过的藤条和枣椰纤维制造新型混合复合材料。纤维分别用 3%、4% 和 5% 的 NaOH 溶液进行处理。纤维直径通过显微镜测量。NaOH 处理增强了纤维的拉伸强度。未经处理的藤、中肋和穗茎纤维的抗拉强度分别为 18、57 和 37 兆帕。以聚酯为基体,结合重量分数为 70 :30、75 : 25 和 80 : 20 的纤维。所有复合材料均为 1 :1 的藤中叶纤维和 1 :1 的藤茎纤维。含有 20% 经过处理的藤中肋纤维的复合材料显示出最高的拉伸强度和弯曲强度,分别为 13 兆帕和 39 兆帕。同时,藤条-穗条茎纤维复合材料在含有 30% 的处理纤维时,抗拉强度最高,达到 14 兆帕,在含有 20% 的处理纤维时,抗弯强度最高,达到 28.91 兆帕。此外,拉伸断裂表面的 SEM 图像显示出空隙、裂缝和杂质。我们的目标是开发一种新型复合材料,为工业、建筑和航空应用提供一种成本低、结构合理且环保的高强度材料。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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