The intention of this research is to recapitulate the two different fillers like E glass fiber and nanocarbon fiber, which were utilized to fabricate the polymer matrix composites by the assistance of epoxy resin. The mechanical compression molding was influenced to produce the polymer-based nanocomposites under consideration of optimal process parameters. There are three different weight fractions E glass fiber (40%, 45%, and 50%), nanocarbon fiber (10%, 15%, and 20%), and epoxy concentrations (30%, 40%, and 50%), respectively, that were used to produce the polymer matrix composites. Those processing parameters were designed by the L9 Taguchi with DOE technique to conduct the mechanical tests like tensile strength and hardness properties. The signal-to-noise ratios were successfully accomplished to identify optimal process parameters for improving the individual responses. The ANOVA and interaction was additional supports to enhance the mechanical properties. The scanning electron microscope was used to examine the fracture surfaces at the tensile fracture specimens with optimal conditions. Moreover, the maximum mechanical characteristics were attained by the increasing of nanocarbon fiber in the processed polymer matrix composites.

中文翻译：

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分析制造的 MMCs 对纳米碳影响聚合物复合材料的机械特性

本研究的目的是概括两种不同的填料，如 E 玻璃纤维和纳米碳纤维，它们在环氧树脂的辅助下用于制造聚合物基复合材料。在考虑最佳工艺参数的情况下，影响机械压缩成型以生产聚合物基纳米复合材料。有三种不同重量分数的E玻璃纤维（40%、45%和50%）、纳米碳纤维（10%、15%和20%）和环氧浓度（30%、40%和50%），分别用于生产聚合物基复合材料。这些加工参数由 L9 Taguchi 采用 DOE 技术设计，用于进行拉伸强度和硬度性能等机械测试。成功实现了信噪比以确定最佳工艺参数以改善个体响应。方差分析和相互作用是增强机械性能的额外支持。扫描电子显微镜用于在最佳条件下检查拉伸断裂试样的断裂表面。此外，通过在加工的聚合物基复合材料中增加纳米碳纤维，可以获得最大的机械性能。