Abstract
Glass Fiber Reinforced Polymeric (GFRP) Composites are most commonly used as bumpers for vehicles, electrical equipment panels, and medical devices enclosures. These materials are also widely used for structural applications in aerospace, automotive, and in providing alternatives to traditional metallic materials. The paper fabricated epoxy and polyester resin composites by using silicon carbide in various proportions along with GFRP. The hand lay-up technique was used to fabricate the laminates. To determine the properties of fabricated composites, the tensile, impact, and flexural tests were conducted. This method of fabrication was very simple and cost-effective. Their mechanical properties like yield strength, yield strain, Young’s modulus, flexural modulus, and impact energy were investigated. The mechanical properties of the GFRP composites were also compared with the fiber volume fraction. The fiber volume fraction plays a major role in the mechanical properties of GFRP composites. Young’s modulus and tensile strength of fabricated composites were modelled and compared with measured values. The results show that composites with epoxy resin demonstrate higher strength and modulus compared to composites with polyester resin.
Highlights
Plastic matrices reinforced with glass fibers are known as Glass Fiber Reinforced Polymeric (GFRP)
The mechanical properties of the GFRP composites were compared with the fiber volume fraction
The fiber volume fraction plays a major role in the mechanical properties of GFRP composites
Summary
Plastic matrices reinforced with glass fibers are known as GFRPs. These materials consist of a plastic matrix reinforced with glass fibers. Increasing the volume fraction of glass fiber to a maximum of 75% resulted in higher flexural and impact properties [3]. The author has fabricated hybrid polymer composites with random oriented e-glass fiber in the unsaturated polyester resin matrix. The results showed that the combined reinforcement effect yields better mechanical properties with increased fiber length and particulate material [4]. Throughout this study, random oriented reinforced polymer composites made of E-glass fiber were developed by hand lay-up with differing fiber percentages (15%, 30%, 45%, and 60%). This paper aims to increase mechanical properties like the tensile, flexural, and impact strength to the extent of 16.8%, 7.8%, and 13%, respectively by the increased incorporation of nanoparticles for that the author has prepared a hybrid epoxy nanocomposite reinforced
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