Post-Buckling Analysis of E-Glass Fiber Reinforced Thin-Walled Cylindrical Composite

Materials Science Forum Pub Date : 2024-02-29 DOI:10.4028/p-jltwg1

B. Ugwu, John N. Ani, Timine Suoware, Sylvester Onyemaechi Edelugo

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Abstract

Post buckling analysis of E-glass fiber reinforced cylindrical composite under axial compression using both experimental and numerical method is presented. Using the Eigen value buckling analysis, the studies employ a mixture ratio of E-glass fiber composite of chopped strand mat. Five molds of each E-glass fiber mixture were reinforced with polyester resin to produce cylindrical shells of equal dimensions. Various cylindrical specimens’ predicted critical buckling load were tested and recorded using a compressive loading machine. Comparisons were made to ascertain the cylindrical shells buckling and post buckling behavior at certain load levels between the experimental and analytical results. A one-way Anova was used to compare the outcome of the theoretical, experimental and numerical methods of analysis and the result showed that there is no evidence to suggest difference between the three methods applied in the buckling load analysis. The post buckled shapes of the samples were obtained and recorded as bulge diamond shape of a buckled cylindrical structure. The effective mechanical properties of the chopped strand mat (CSM) reinforced composite cylinder were recorded from the experiment which has modulus of Elasticity 197.707 N/mm2, Poisson’s ratio of 0.22 and density of 1250 Kg/m3.

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电子玻璃纤维增强薄壁圆柱复合材料的屈曲后分析

本文采用实验和数值方法对 E 玻璃纤维增强圆柱形复合材料在轴向压缩下的后屈曲分析进行了介绍。利用特征值屈曲分析，研究采用了一种混合比例的短切毡 E 玻璃纤维复合材料。用聚酯树脂对每种 E 玻璃纤维混合物的五个模具进行加固，生产出等尺寸的圆柱形壳体。使用压缩加载机对各种圆柱形试样的预测临界屈曲载荷进行了测试和记录。对实验结果和分析结果进行比较，以确定圆柱形壳体在特定载荷水平下的屈曲和后屈曲行为。结果表明，没有证据表明这三种方法在屈曲载荷分析中存在差异。样品屈曲后的形状被记录为屈曲圆柱结构的隆起菱形。实验记录了短切毡增强复合材料圆柱体的有效机械性能，其弹性模量为 197.707 N/mm2，泊松比为 0.22，密度为 1250 Kg/m3。

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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Materials Science Forum

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