The influence of different fiber sizes on the flexural strength of natural fiber-reinforced polymer composites

Akhyar,; Gani, Asri; Ibrahim, Masri; Ulmi, Fatlul; Farhan, Ahmad

doi:10.1016/j.rinma.2024.100534

Results in Materials

2024

DOI: 10.1016/j.rinma.2024.100534

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The influence of different fiber sizes on the flexural strength of natural fiber-reinforced polymer composites

Akhyar,

Asri Gani,

Masri Ibrahim

et al.

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2024

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Cited by 19 publications

References 33 publications

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Advances in Composite Materials for Surfboard Manufacturing—A Review

Zimmermann,

de Almeida,

Ponsoni

et al. 2024

J of Applied Polymer Sci

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The evolution of technologies applied to surfboards has accelerated rapidly in recent years. Not only have the designs of surfboards evolved, but also the materials used in their production have advanced substantially. This progress highlights the need to expand research and deepen knowledge of manufacturing processes, materials, and additives, while quantifying the mechanical performance of materials used in sandwich composites for surfboards. Providing designers and surfers with quantitative performance metrics is essential for meaningful comparisons and for optimizing board designs. This review offers an overview of the primary materials and designs currently shaping the surfboard industry, emphasizing the relationship between material properties and surfboard performance. However, challenges remain in furthering these advancements, and continuous dissemination of knowledge will be crucial for driving significant progress in the sport.

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Advances in Composite Materials for Surfboard Manufacturing—A Review

Zimmermann,

de Almeida,

Ponsoni

et al. 2024

J of Applied Polymer Sci

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Mechanical, free vibration, electrical, and water absorption properties of vinyl ester composites reinforced with Phoenix sp. fibers: Influence of eco‐friendly sodium bicarbonate treatment

Rajeshkumar

2024

Polymer Composites

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Environmentally sustainable and eco‐friendly natural fiber‐reinforced polymer composites have become the materials of interest in replacing synthetic fibers. However, weak interfacial interaction between hydrophilic natural fibers and hydrophobic polymer matrix limits their commercial applicability. Improving the interfacial interaction using environmentally friendly chemical treatments would be beneficial for both industries and the environment. In this study, vinyl ester‐based composites were made by incorporating Phoenix sp. fibers in different content (5, 10, 15, 20, and 25 wt%) and lengths (5, 10, 15, and 20 mm). To improve the interfacial interactions, the fibers were treated with eco‐friendly sodium bicarbonate solution at different durations (24, 120, and 240 h) prior to reinforcing. The fabricated composites were characterized by mechanical, free vibration, electrical resistance, and water uptake properties. The results reveal that both fiber content and fiber length have a significant effect on the above properties. Specifically, the composites incorporated with 20 wt% of 15 mm length fibers offered better properties. Further, the composites added with 120 h treated fibers have the maximum tensile strength (61.35 MPa) and modulus (4.13 GPa), flexural strength (152.63 MPa) and modulus (10.24 GPa), impact strength (24.67 kJ/m2), and natural frequency (56.72 Hz). This improvement is mainly due to the improved interfacial bonding, which was evidenced in morphological analysis. Based on the findings, the eco‐friendly treated sustainable Phoenix sp. fibers could be used as a promising reinforcement material for fabricating light weight polymer composites for various industrial applications.Highlights Various properties of Phoenix sp. fiber/epoxy composites were investigated. Interfacial bonding is enhanced through eco‐friendly chemical treatments. Vibration behavior of composites improved due to high stiffness of treated fibers. Composites with treated fibers have excellent electrical and water resistance.

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Recent developments in the mechanical properties and recycling of fiber‐reinforced polymer composites

Kumar,

Dixit,

Singh

et al. 2024

Polymer Composites

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Fiber‐reinforced polymer composites (FRPCs) have become integral to various industries due to their exceptional strength‐to‐weight ratio, corrosion resistance, and versatility. Recent advancements in the properties and recycling of FRPCs reflect significant progress in performance and sustainability. This paper reviews the latest developments in FRPC technology, highlighting innovations in material formulation, including advancements in fiber types, matrix materials, and hybrid composites that enhance mechanical properties. Furthermore, this review emphasizes the modification of matrices by incorporating graphene, which aims to improve the chemical bonding and mechanical interlocking between fiber and matrix. Additionally, it addresses recent breakthroughs in recycling technologies, focusing on methods such as chemical recycling, mechanical recycling, and developing eco‐friendly matrices. Integrating these advancements aims to improve the lifecycle management of FRPCs, reduce environmental impact, and support the transition towards a circular economy. This review underscores the balance between enhancing composite performance and promoting sustainable practices, paving the way for more environmentally responsible applications of FRPCs.Highlights The different types of fiber‐reinforced polymer composites have been thoroughly reviewed. How does graphene affect the mechanical behavior of fiber composite laminates? Provide a systematic correlation and comparison between fabrication methods, materials, and properties. The recycling methods for fiber‐reinforced polymer composites have been deliberated.

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The influence of different fiber sizes on the flexural strength of natural fiber-reinforced polymer composites

Cited by 19 publications

References 33 publications

Advances in Composite Materials for Surfboard Manufacturing—A Review

Advances in Composite Materials for Surfboard Manufacturing—A Review

Mechanical, free vibration, electrical, and water absorption properties of vinyl ester composites reinforced with Phoenix sp. fibers: Influence of eco‐friendly sodium bicarbonate treatment

Recent developments in the mechanical properties and recycling of fiber‐reinforced polymer composites

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