Synergistic Utilization of Flax Fiber Polymer Composites: A Review

Arunprasath, Kanagaraj

doi:10.5185/amlett.2021.011590

Cited by 2 publications

(2 citation statements)

References 53 publications

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“…Efforts have been made towards increasing the raised temperature property of alloy structures by alloying elements with a high melting point, such as manganese, nickel, and silicon, or by utilizing resources of distributed hard next-phase particles [5]. This study investigated the influence of nanoparticles based on aluminium and magnesium on improving mechanical properties [6]. According to the findings of this study, the proof stress of 0.2%, tensile strength, and ductility all decrease with increasing particle size [7].…”

Section: Introductionmentioning

confidence: 99%

Experimental investigation of mechanical and tribological properties of AA7065- B₄C nano-composite

Madan,

Parthiban

2024

E3S Web Conf.

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The present study used the stir casting technique to create hybrid composites employing aluminium AA 7065 alloy for the matrix and boron carbide reinforcements. In order to study the high-temperature tribological behaviour of aluminium boron carbide composites, the pin-on-disc method with pin heating setup was adopted. As a supplemental reinforcing material, fly ash particles were used due to their exceptional mechanical, metallurgical, and tribological properties. Microhardness testing, microstructure analysis, and tensile testing were all carried out. The wear rate of hybrid composites was studied on load, sliding velocity, and temperature. Mechanical properties and particle distribution were vastly improved during the testing phase. Although the ductility of hybrid composites was down, their tensile and compression strengths increased dramatically. The surface morphology of the pin was analyzed using a high-resolution scanning electron microscope. The impact of wear parameters on wear rate was analyzed using analysis of variance.

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Section: Introductionmentioning

confidence: 99%

Experimental investigation of mechanical and tribological properties of AA7065- B₄C nano-composite

Madan,

Parthiban

2024

E3S Web Conf.

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“…Few works have so far been reported in recent past on composites that have utilized some industrial and construction wastes such as blast furnace slag, LD slag, fly ash, red mud, marble dust, copper slag, and so forth. [26][27][28][29][30][31][32][33][34][35] In view of this, the present work explores the reinforcing potential of an industry waste called sponge iron (SI) slag in polymer in order to improve the physical and mechanical properties and simultaneously to bring down the cost. SI slag is generated in huge quantities as a solid waste during the production of sponge iron.…”

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confidence: 99%

Processing and physico‐mechanical characterization of sponge iron slag filled ramie fiber reinforced epoxy‐based composites

Mahapatra

Satapathy

2022

Polymer Composites

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The present research focuses on developing a new class of hybrid composites with woven ramie fiber mats reinforced in epoxy resin filled with different proportions of sponge iron (SI) slag. These multi-layered composites are fabricated using conventional hand layup method. The cured composite samples are subjected to various physical, mechanical and micro-structural characterization tests. Properties such as composite density, void content, tensile strength, flexural strength, impact and inter-laminar shear strength, micro-hardness, and so forth, are evaluated under controlled laboratory conditions. The compositional/micro-structural features are identified with the help of scanning electron microscopy, Fourier transform infrared spectroscopy (FTIR), stereomicroscopy, X-ray diffraction, and so forth. Scanning electron microscopy reveals the shape, size and distribution pattern of the filler particles in the composites. The FTIR study is done to identify the functional groups present in the filler, fiber and in the resulting composite to get an insight to the chemistry of composite formation. Similarly, X-Ray diffraction curve reveals the presence of hard phases such as silica, magnesioferrite, graphite, hematite, and so forth. This work suggests that successful fabrication of natural fiber composites is possible with additional reinforcement of an industrial waste like sponge iron slag and that most of the mechanical properties improve with increase in the content of SI slag in the composite.characterization, hybrid composite, ramie fiber, sponge iron slag | INTRODUCTIONPolymer composites are finding wider applications in various industrial, structural, and bio-medical fields in comparison to monolithic alloys as they are cheaper, have improved strength and wear resistance. In such composites, usually synthetic fibers are used as the reinforcing materials for their high tensile strength, stiffness and lightweight. But in recent years, natural fibers are fast emerging as replacement of synthetics and have drawn the attention of researchers worldwide due to several advantages like low cost, easy availability, biodegradability, fairly good strength, and low impact on the environment. Natural fibers have the ability to replace synthetic

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Synergistic Utilization of Flax Fiber Polymer Composites: A Review

Cited by 2 publications

References 53 publications

Experimental investigation of mechanical and tribological properties of AA7065- B₄C nano-composite

Experimental investigation of mechanical and tribological properties of AA7065- B₄C nano-composite

Processing and physico‐mechanical characterization of sponge iron slag filled ramie fiber reinforced epoxy‐based composites

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Synergistic Utilization of Flax Fiber Polymer Composites: A Review

Cited by 2 publications

References 53 publications

Experimental investigation of mechanical and tribological properties of AA7065- B4C nano-composite

Experimental investigation of mechanical and tribological properties of AA7065- B4C nano-composite

Processing and physico‐mechanical characterization of sponge iron slag filled ramie fiber reinforced epoxy‐based composites

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Experimental investigation of mechanical and tribological properties of AA7065- B₄C nano-composite

Experimental investigation of mechanical and tribological properties of AA7065- B₄C nano-composite