Flammability and morphology of Agel leaf fibre- epoxy composite modified with carbon powder for fishing boat applications

Kurniasih, P.; Wirawan, W. A.; Narto, A.; Pribadi, O. S.; Imron, N. A.; Rachman, N. F.; Pradipta, A.

doi:10.5604/01.3001.0053.8842

Artykuł - szczegóły

Tytuł artykułu

Flammability and morphology of Agel leaf fibre- epoxy composite modified with carbon powder for fishing boat applications

Autorzy

Kurniasih P. , Wirawan W. A. , Narto A. , Pribadi O. S. , Imron N. A. , Rachman N. F. , Pradipta A.

Treść / Zawartość

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Identyfikatory

DOI

10.5604/01.3001.0053.8842

Warianty tytułu

Języki publikacji

Abstrakty

Purpose: Fibre Reinforced Polymer Composites have been extensively developed to construct fishing vessels. This study reports on the successful development of the Agel Leaf Fibre (ALF)- Epoxy composite reinforced with carbon powder and fabricated using the Vacuum Infusion method. Design/methodology/approach: The composites were prepared by varying the carbon powder filler content at volumes of 0%, 10%, and 30%. The fire resistance of the composites was investigated using a burning test according to ASTM D-3014 standards. The morphology of the composites was observed through SEM analysis and analysed using ImageJ software. Findings: The research findings reveal that adding 30% carbon powder in the HCP composite reduced the burning rate by 42.624 mm/sec and the time to ignition by 17.33 seconds, indicating improved fire resistance properties. The carbon powder inhibited flame propagation and reduced the combustion rate by 0.49%. The SEM examination confirmed that the fibre porosity decreased, resulting in a denser composite with enhanced fibre-matrix adhesion. Therefore, the implementation of fire-resistant composite materials in fishing vessel construction can be realised. Research limitations/implications: The present study primarily examined the immediate effects of carbon powder additions on the morphology of the composites. However, it is crucial to consider these composites’ long-term stability and durability. Future research should investigate the ageing behaviour, considering environmental factors such as humidity, temperature, and UV radiation, to assess their impact on the morphology and flammability resistance of the composites. Additionally, it is essential to acknowledge that other factors, including fibre orientation, fibre length, and matrix properties, can significantly influence the overall performance of the composites. Practical implications: The enhanced flammability resistance of Agel Leaf Fibre-Epoxy composites with carbon powder additions holds significant benefits for fishing boat applications. In marine environments, the risk of fire incidents on fishing boats is high, making materials with good fire resistance highly desirable. Therefore, implementing fire-resistant composite materials in fishing boat construction can be realised to reduce the risk of fire incidents in high-seas fishing vessels. Originality/value: Composites with added carbon powder exhibited smaller flames, slower burning rates, and a lack of significant flame propagation. This suggests that adding carbon powder acts as an oxygen barrier and reduces the availability of fuel within the composite.

Słowa kluczowe

natural fibre agel leaf fibre carbon powder composite fire resistance morphology fishing boat application

włókno naturalne włókno z liści agawy proszek węglowy kompozyt odporność ogniowa morfologia zastosowanie w łodziach rybackich

Wydawca

International OCSCO World Press

Czasopismo

Archives of Materials Science and Engineering

Rocznik

2023

Tom

Vol. 122, nr 1

Strony

13--21

Opis fizyczny

Bibliogr. 30 poz.

Twórcy

autor

Kurniasih P.

pritha@pip-semarang.ac.id

Semarang Maritime Polytechnic, Jl. Singosari Raya No.2A, Wonodri, Semarang, Jawa Tengah, 50242, Indonesia

autor

Wirawan W. A.

willy@pengajar.ppi.ac.id

Indonesian Railway Polytechnic, Tirta Raya street, Nambangan Lor, Manguharjo, Madiun, Jawa Timur, 63161, Indonesia

https://orcid.org/0000-0002-0709-5626

autor

Narto A.

Semarang Maritime Polytechnic, Jl. Singosari Raya No.2A, Wonodri, Semarang, Jawa Tengah, 50242, Indonesia

autor

Pribadi O. S.

Indonesian Railway Polytechnic, Tirta Raya street, Nambangan Lor, Manguharjo, Madiun, Jawa Timur, 63161, Indonesia

autor

Imron N. A.

Indonesian Railway Polytechnic, Tirta Raya street, Nambangan Lor, Manguharjo, Madiun, Jawa Timur, 63161, Indonesia

autor

Rachman N. F.

Indonesian Railway Polytechnic, Tirta Raya street, Nambangan Lor, Manguharjo, Madiun, Jawa Timur, 63161, Indonesia

autor

Pradipta A.

Indonesian Railway Polytechnic, Tirta Raya street, Nambangan Lor, Manguharjo, Madiun, Jawa Timur, 63161, Indonesia

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Bibliografia

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bwmeta1.element.baztech-4d3655c3-fed4-4d33-ae36-f64f96def816