Critical review on advancements on the fiber-reinforced composites: Role of fiber/matrix modification on the performance of the fibrous composites

Sharma, Harsh; Kumar, Ajay; Rana, Sravendra; Sahoo, Nanda Gopal; Jamil, Muhammad; Kumar, Rajeev; Sharma, Shubham; Li, Changhe; Kumar, Abhinav; Eldin, Sayed M.; Abbas, Mohamed

doi:10.1016/j.jmrt.2023.08.036

Cited by 54 publications

(5 citation statements)

References 175 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In figure 12 (d) the fiberglass as core laminate exhibits better adhesion as intermediate layer which also increase the composite resistance to failure and cracks due the fiberglass properties as mentioned before, while the addition of rubber showed better influence reduced the stress transferred [33].…”

Section: Sem and Fracture Analysismentioning

confidence: 72%

Development of Eco-Friendly Composites: Lamination Configuration and Addition of Waste Tire Rubber Particles on the Mechanical Performance of Polyester-Fiberglass Composite Plates

Abohassan,

Mahmoud,

ibrahim

et al. 2024

Benha Journal of Applied Sciences

View full text Add to dashboard Cite

Section: Sem and Fracture Analysismentioning

confidence: 72%

Development of Eco-Friendly Composites: Lamination Configuration and Addition of Waste Tire Rubber Particles on the Mechanical Performance of Polyester-Fiberglass Composite Plates

Abohassan,

Mahmoud,

ibrahim

et al. 2024

Benha Journal of Applied Sciences

View full text Add to dashboard Cite

“…The fiber/matrix employed and the composite's intended use will determine the best technique for fiber modification. To use NFRCs and hybrid composites, it is crucial to understand the interfacial properties and bonding mechanisms of the fiber-matrix interaction, which necessitates extensive research [116]. Inadequate adhesion between the fibers and the matrix will lead to inefficient load distribution, reducing the composite materials' mechanical properties (such as tensile, flexural, and impact strength).…”

Section: Applications Of Natural Fiber-reinforced Polymer Composites ...mentioning

confidence: 99%

Natural Fiber Composite Filaments for Additive Manufacturing: A Comprehensive Review

Khilji,

Chilakamarry,

Surendran

et al. 2023

Sustainability

View full text Add to dashboard Cite

This research explores the potential and significance of 3D printing natural fiber composite (NFC) materials. The primary objective is to investigate the mechanical, thermal, and environmental properties of NFC filaments, mainly focusing on biodegradable, renewable fibers such as jute, hemp, flax, and kenaf. In addition to studying the properties of NFCs, our research delves into the challenges associated with processing, including moisture absorption and fiber-matrix interfacial bonding. The novelty of this work lies in the convergence of traditional composite materials with the versatility of 3D printing technology. NFC filaments offer unique advantages in terms of sustainability, and we examine their potential contributions to the circular economy. By using eco-friendly NFC materials in 3D printing, we aim to present a viable, environmentally responsible alternative to conventional synthetic composites. The importance of 3D printing NFCs stems from the ways their use can align with sustainability goals. These materials provide the advantages of renewability, reduced carbon impact, and in some cases, biodegradability. Their applications extend to various industries, such as automotive, construction, and packaging, where eco-friendly materials are increasingly sought. Such applications showcase the ways in which NFC-based 3D printing can contribute to a more environmentally responsible and sustainable future. This research explores the mechanical, thermal, and environmental properties of NFC materials, highlighting their unique advantages for 3D printing and the potential to have eco-friendly applications in diverse industries.

show abstract

“…Owning to the excellent mechanical properties and high resistance to chemical corrosion, fiber-reinforced polymer composites have been widely used in many industrial areas like civil constructions, marine, aerospace, machine, automobile, and electronic and electrical engineering . In the past decades, typical synthetic fibers, mainly including glass fibers, carbon fibers, and aramid fibers, are the predominant reinforcements in the market, due to their advantages including high specific strength, strong weatherability, and high-temperature resistance. − However, manufacture of the synthetic fibers heavily relies on the fossil resource, and the production of fibers causes high energy-consumption and environmental pollution. , Seeking sustainable fibers as partial substitutes is promising to reduce the negative effects caused by the production of synthetic fibers. The potential applications of some natural fibers like spider silk, hemp fiber, and bamboo fiber have been intensively studied. , But some disadvantages of these fibers like difficulty in obtaining and processing, as well as poor heat resistance, largely limit their application as engineering materials. , …”

Section: Introductionmentioning

confidence: 99%

High-Performance Basalt-Fiber-Reinforced Laminated Composites: Free of Fiber Surface Modification and Sizing Agent

Shen,

Duan,

Liu

et al. 2024

ACS Sustainable Chem. Eng.

View full text Add to dashboard Cite

Thanks to the advantages of synthesis-free, excellent mechanical properties and heat resistance, basalt fibers (BFs) have been viewed as a new generation of reinforcement, which is a promising substitute for synthetic glass fibers. However, achieving satisfied comprehensive performances for BF-reinforced composites is still a great challenge because of the poor interfacial compatibility of BF toward conventional matrix resins. In this study, a melamine−hexamethylenediamine (MH) thermoset was used for the first time as the matrix of BF-reinforced laminated composites. With no surface modifications performed and no sizing agent used, the BF-reinforced MH composites (BFRMH) exhibited excellent comprehensive performances. Specifically, the BFRMH composites have heat deflection temperature above 300 °C, flexural strength up to 750 MPa, and interlaminar shear strength above 68 MPa. Particularly, the BFRMH composites are highly resistant to extreme temperature as enhanced mechanical strength and toughness were observed at 77 K, and 78% flexural strength retained even after treated at 798 K. These performances are far superior to that of reported BF-reinforced composites and of the glass-fiber-reinforced composites. In addition, the excellent chemical resistance, insulating property, conductivity, as well as flame retardancy (UL94-5VA) suggest that the BFRMH composites are potential materials for electrical and electronic applications. The results of this work revealed the great potential and suitability of the MH resin matrix for fabricating BF-reinforced composites, due to its excellent interfacial compatibility.

show abstract

Critical review on advancements on the fiber-reinforced composites: Role of fiber/matrix modification on the performance of the fibrous composites

Cited by 54 publications

References 175 publications

Development of Eco-Friendly Composites: Lamination Configuration and Addition of Waste Tire Rubber Particles on the Mechanical Performance of Polyester-Fiberglass Composite Plates

Development of Eco-Friendly Composites: Lamination Configuration and Addition of Waste Tire Rubber Particles on the Mechanical Performance of Polyester-Fiberglass Composite Plates

Natural Fiber Composite Filaments for Additive Manufacturing: A Comprehensive Review

High-Performance Basalt-Fiber-Reinforced Laminated Composites: Free of Fiber Surface Modification and Sizing Agent

Contact Info

Product

Resources

About