Comparative Study of Epoxy Composites Reinforced with Kenaf Fiber and Different Types of Microparticles
Reinforcement of both fibrous and particulate materials can improve composite properties for various applications, such as biomedical applications. The alkali-treated kenaf fibers and (SiO2, bentonite, and CaCO3) microparticles 400 mesh in size reinforce the epoxy matrix for hybrid composites. The b...
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my.unimas.ir.388612022-07-13T01:32:27Z http://ir.unimas.my/id/eprint/38861/ Comparative Study of Epoxy Composites Reinforced with Kenaf Fiber and Different Types of Microparticles Harini, Sosiati Muhammad Fahmi, Rozi Cahyo, Budiyantoro Sinin, Hamdan TJ Mechanical engineering and machinery Reinforcement of both fibrous and particulate materials can improve composite properties for various applications, such as biomedical applications. The alkali-treated kenaf fibers and (SiO2, bentonite, and CaCO3) microparticles 400 mesh in size reinforce the epoxy matrix for hybrid composites. The bending and impact properties of hybrid composites, as well as their water absorption, are compared. The hybrid composites were prepared in a compression mold using a hand lay-up technique at 100°C for 20 – 50 minutes consisting of 28 vol.% of short kenaf fibers ~5 mm in length, 2 vol.% of each type of microparticle, and 70 vol.% the epoxy resin. The flexural and impact properties of kenaf/silica/epoxy composite indicated the highest flexural strength (58.37±3.9 MPa), flexural modulus (4.68 ± 0.17 MPa), and impact strength (7.49 kJ/m2). The addition of the microparticles reduced water absorption in the composites. The water absorption of kenaf/silica/epoxy composite appeared to be stable for immersion time near 216 hours. Other microparticle-filled composites did not show this pattern. The incorporation of silica microparticles to the kenaf/epoxy composite potentially enhanced the mechanical properties of the composite, with the expectation of using it to be developed for biomedical composite material. 2022 Proceeding PeerReviewed text en http://ir.unimas.my/id/eprint/38861/1/Comparative%20Study%20of%20Epoxy.pdf Harini, Sosiati and Muhammad Fahmi, Rozi and Cahyo, Budiyantoro and Sinin, Hamdan (2022) Comparative Study of Epoxy Composites Reinforced with Kenaf Fiber and Different Types of Microparticles. In: 3rd International Conference on Advances in Materials, Mechanical and Manufacturing, AMMM 2021 and 10th International Conference on Engineering and Innovative Materials virtual conference, ICEIM 2021, 24-26 September 2021, Virtual, Online. https://www.scientific.net/KEM.918.73 |
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TJ Mechanical engineering and machinery Harini, Sosiati Muhammad Fahmi, Rozi Cahyo, Budiyantoro Sinin, Hamdan Comparative Study of Epoxy Composites Reinforced with Kenaf Fiber and Different Types of Microparticles |
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Reinforcement of both fibrous and particulate materials can improve composite properties for various applications, such as biomedical applications. The alkali-treated kenaf fibers and (SiO2, bentonite, and CaCO3) microparticles 400 mesh in size reinforce the epoxy matrix for hybrid composites. The bending and impact properties of hybrid composites, as well as their water absorption, are compared. The hybrid composites were prepared in a compression mold using a hand lay-up technique at 100°C for 20 – 50 minutes consisting of 28 vol.% of short kenaf fibers ~5 mm in length, 2 vol.% of each type of microparticle, and 70 vol.% the epoxy resin. The flexural and impact properties of kenaf/silica/epoxy composite indicated the highest flexural strength (58.37±3.9 MPa), flexural modulus (4.68 ± 0.17 MPa), and impact strength (7.49 kJ/m2). The addition of the microparticles reduced water absorption in the composites. The water absorption of kenaf/silica/epoxy composite appeared to be stable for immersion time near 216 hours. Other microparticle-filled composites did not show this pattern. The incorporation of silica microparticles to the kenaf/epoxy composite potentially enhanced the mechanical properties of the composite, with the expectation of using it to be developed for biomedical composite material. |
format |
Proceeding |
author |
Harini, Sosiati Muhammad Fahmi, Rozi Cahyo, Budiyantoro Sinin, Hamdan |
author_facet |
Harini, Sosiati Muhammad Fahmi, Rozi Cahyo, Budiyantoro Sinin, Hamdan |
author_sort |
Harini, Sosiati |
title |
Comparative Study of Epoxy Composites Reinforced with Kenaf Fiber and Different Types of Microparticles |
title_short |
Comparative Study of Epoxy Composites Reinforced with Kenaf Fiber and Different Types of Microparticles |
title_full |
Comparative Study of Epoxy Composites Reinforced with Kenaf Fiber and Different Types of Microparticles |
title_fullStr |
Comparative Study of Epoxy Composites Reinforced with Kenaf Fiber and Different Types of Microparticles |
title_full_unstemmed |
Comparative Study of Epoxy Composites Reinforced with Kenaf Fiber and Different Types of Microparticles |
title_sort |
comparative study of epoxy composites reinforced with kenaf fiber and different types of microparticles |
publishDate |
2022 |
url |
http://ir.unimas.my/id/eprint/38861/1/Comparative%20Study%20of%20Epoxy.pdf http://ir.unimas.my/id/eprint/38861/ https://www.scientific.net/KEM.918.73 |
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