Tailoring Basalt Fibers and E-Glass Fibers as Reinforcements for Increased Impact Resistance

Elango Natarajan, Santhosh Mozhuguan Sekar, K. Markandan, C. Ang, Gérald Franz
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Abstract

The usage of basalt fiber in the engineering industries has gained significant interest due to its characteristics such as alkali resistance and enhanced mechanical properties. Similarly, E-glass-fiber-reinforced composites have been widely used in the fabrication of electrically resistive industrial components such as switches, circuit panels, and covering cases. In the present study, the tensile, flexural, thermogravimetric, and low-velocity impact characteristics of various percentages of basalt/E-glass-fiber-reinforced polymer composites fabricated via vacuum-assisted resin transfer molding were investigated. The results show that a higher volume percentage of basalt (39%) significantly enhances the impact resistance up to 45% with a moderate improvement in flexural properties. The higher the vol % of E-glass (40%), the more the tensile and flexural properties are increased, i.e., 185 N/mm2 and 227.87 N/mm2, respectively. It is concluded that by choosing the optimum hybridization method, impact resistance and other mechanical properties can be improved significantly. The thermogravimetric analysis results show that PC313534 (35 vol % basalt and 34 vol % E-glass) possesses the lowest decomposition temperature of 381.10 °C. The results from the present study indicate that the polymer composite fabricated in the present study is suitable for applications where higher structural-load-resistive properties are required.
定制玄武岩纤维和电子玻璃纤维作为增强材料以提高抗冲击性
由于玄武岩纤维具有耐碱性和更强的机械性能等特点,它在工程行业的应用已获得了极大的关注。同样,玻璃纤维增强复合材料也被广泛用于制造开关、电路板和外壳等电阻性工业部件。本研究调查了通过真空辅助树脂传递模塑法制造的不同比例的玄武岩/E 玻璃纤维增强聚合物复合材料的拉伸、弯曲、热重和低速冲击特性。结果表明,玄武岩的体积百分比越高(39%),抗冲击性就会显著提高 45%,弯曲性能也会有适度改善。E 玻璃的体积百分比越高(40%),拉伸和弯曲性能就越高,分别达到 185 牛顿/平方毫米和 227.87 牛顿/平方毫米。结论是,通过选择最佳的杂化方法,可以显著提高抗冲击性和其他机械性能。热重分析结果表明,PC313534(35 体积%玄武岩和 34 体积%E-玻璃)的分解温度最低,为 381.10 ℃。本研究的结果表明,本研究中制造的聚合物复合材料适用于需要较高抗结构荷载性能的应用领域。
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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