The application of timoho fiber coating to improve the composite performance

Sanjay, M. R.; Djakfar, Ludfi; Hadajani, Rinawati P.; Yusran, Yusfan Adeputera; Hidayatullah, Syarif; Suteja, I Wayan; Sanjay, M. R.; Siengchin, Suchart

doi:10.1016/j.rineng.2022.100499

Cited by 13 publications

(12 citation statements)

References 29 publications

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“…High tool wear and poor surface finish are crucial in machining NFRCs. Recent research shows that feed rate and material removal rate may help reduce the impact of machining flaws like peel-up or push-down stratification on the surface [120]. High cutting speeds of the tool induce frictional heat leading to matrix melting, and better surface finish of the composite is always dependent on the fibre orientation [121].…”

Section: Challenges Facing Duringmentioning

confidence: 99%

Preparation, Characteristics, and Application of Biopolymer Materials Reinforced with Lignocellulosic Fibres

Gurupranes¹,

Rajendran²,

Gokulkumar

et al. 2023

International Journal of Polymer Science

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Various environmental concerns motivate scientists and researchers to look out for unique new materials in science and technology. In order to address the demand for polymeric materials with partial biodegradability, the usage of lignocellulosic fibre in the polymer matrix has risen. Lignocellulosic fibres are a cheap, easily renewable resource that is readily available in all regions. Cellulosic plant fibres also have a plethora of possibilities for use in polymer reinforcement because of their properties. Many researchers put their effort into developing a natural polymer with better mechanical properties and thermal stability using nanotechnology and the use of natural polymers to make its composites with lignocellulosic fibres. This study provides a review of the biodegradable composite market, processing methods, matrix-reinforcement phases, morphology, and characteristic improvements. In addition, it provides a concise summary of the findings of significant research on natural fibre polymer composites (NFRCs) that have been published. Indeed, a noticeably brief discussion is provided on the significant issues faced during composite extraction as well as the challenges encountered during the machining. Recent developments in the study of lignocellulosic fibre composites or NFRCs have demonstrated their enormous potential as structural elements in vehicles, aerospace structures, buildings, ballistics, soundproofing, and other structures.

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Section: Challenges Facing Duringmentioning

confidence: 99%

Preparation, Characteristics, and Application of Biopolymer Materials Reinforced with Lignocellulosic Fibres

Gurupranes¹,

Rajendran²,

Gokulkumar

et al. 2023

International Journal of Polymer Science

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“…Increased environmental awareness together with the aim of limited hazardous gaseous emissions across the globe and the urge for the development of a newer class of materials from renewable resources has led to the invention of natural fibers derived from plants and their reinforcement in polymer composites. [1][2][3][4][5] Natural fibers as a reinforcement in polymer or other bio-based composites have led to the development of more commercial products and have found their presence elsewhere with a wide range of applications in diverse fields. [5][6][7][8][9][10][11][12] Since the inception of the 20th century, metallurgists, scientists, and professors across the globe have been inspired highly in employ natural fibers rather than synthetic fibers as an ideal reinforcement in polymer composites due to their numerous unique attributes such as light-weight, lesser cost, abundance in availability, less dense, reduced hazardous gas emissions, eco-friendly, ease in fabrication, biodegradable and sustainable.…”

Section: Introductionmentioning

confidence: 99%

Characterization of novel natural cellulosic fibers from Abutilon Indicum for potential reinforcement in polymer composites

ArunRamnath¹,

Murugan

Rangappa

et al. 2022

Polymer Composites

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The prime objective of this research study was the investigation the new natural cellulosic fiber extracted from the stem of Abutilon Indicum plants as an alternative reinforcement in greener composite materials for structural applications. Abutilon Indicum a flowering plant with unique medicinal values are abundantly found in India and other south Asian countries. The fibers extracted from the stem of the Abutilon Indicum plant are proven to be sustainable, ecofriendly, and novel and hence this fiber is chosen for characterization study. In this experimental investigation the physical, chemical, thermal, morphological, crystallinity, chemical constituents, and surface characteristics of raw Abutilon Indicum fibers (AIF) were analyzed. Chemical analysis results convey the presence of higher cellulose content of (56.12 wt.%) in AIF. The diameter (175 μm) and density (1.170 g/cm3) of AIFs are determined by physical analysis of the raw fibers. Such lower density values observed in AIF make it as a perfect material for lightweight applications. Crystalline properties of AIFs are determined from X‐ray diffraction tests with a crystalline index of 77.35%, and crystalline size of 2.20 nm, which attributes to the presence of cellulose‐1β and the crystallites are ordered in nature. Thermal stability of 175°C, maximum degradation temperature upto 302.6°C and kinetic activation energy of 86.95 kJ/mol of AIF are established based on thermo gravimetric analysis. Morphological and surface characteristics of AIF through a scanning electron microscope (SEM) and atomic force microscope (AFM) analysis revealed that the raw fibers display a relatively finer surface. Research findings of the AIF mentioned above conclude that the AIFs prove to be an ideal, alternative reinforcement in greener composite materials for sustainable and cleaner production of components in structural applications.

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“…[32][33][34][35][36][37][38][39][40] To solve the issue, hybrid composites were produced, which are made up of two or more fibers, such as natural fiber -natural fiber or natural fiber -synthetic fiber. [41][42][43][44][45][46][47][48][49][50][51][52][53] Researchers examined the mechanical characteristics of (jute/hemp/flax) fiber-reinforced epoxy hybrid composites by varying the fiber layering sequences. [54] From the results, jute/hemp/flax/epoxy hybrid composite exhibits the enhanced mechanical properties compared to jute/hemp/epoxy and hemp/flax/epoxy hybrid composites.…”

Section: Introductionmentioning

confidence: 99%

“…To solve the issue, hybrid composites were produced, which are made up of two or more fibers, such as natural fiber ‐ natural fiber or natural fiber ‐ synthetic fiber. [ 41–53 ]…”

Section: Introductionmentioning

confidence: 99%

Mechanical, absorption, and swelling properties of jute/kenaf/banana reinforced epoxy hybrid composites: Influence of various stacking sequences

et al. 2022

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The effect of jute, kenaf, and banana fiber reinforced epoxy hybrid composites with different stacking sequences were fabricated by compression molding techniques. The pure epoxy, pure jute, pure kenaf, pure banana composites are also fabricated for comparison purposes. Tensile, flexural, inter-laminar shear strengths, and hardness properties of the fabricated composites were investigated. Physical parameters like density, water absorption, and thickness swelling were also examined. From mechanical properties, the results are evident that when compared to hybrid composites pure banana composites have the highest tensile, flexural, interlaminar shear strength and shore D hardness value of 41, 67, 18, and 86 MPa respectively. Also, pure banana composites have better water absorption and thickness swelling percentage of 4% and 1.6%. However, KBJJBK hybrid composites exhibit a maximum tensile strength of 34 MPa, flexural strength of 54 MPa. Further BJKKJB hybrid composites possess the highest hardness value of 87, intralaminar shear strength of 17 MPa and lowest water absorption of 8% and thickness swelling percentage of 2%. Certain pure and hybrid configuration have enhanced mechanical strength, stiffness, and lower water absorption and thickness swelling properties, indicating that they are suitable for automotive structural applications.

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The application of timoho fiber coating to improve the composite performance

Cited by 13 publications

References 29 publications

Preparation, Characteristics, and Application of Biopolymer Materials Reinforced with Lignocellulosic Fibres

Preparation, Characteristics, and Application of Biopolymer Materials Reinforced with Lignocellulosic Fibres

Characterization of novel natural cellulosic fibers from Abutilon Indicum for potential reinforcement in polymer composites

Mechanical, absorption, and swelling properties of jute/kenaf/banana reinforced epoxy hybrid composites: Influence of various stacking sequences

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