Analisis Perbandingan Daya Tahan Komposit Serat Alam dan Serat Sintetis pada Lingkungan Produksi Bersuhu Tinggi

Authors

  • Sabikah Nur Nayla Sabikah Universitas Al-Azhar, Medan
  • M.Irfan Syahputra Universitas Al-Azhar
  • Lindi Cistia Praba Universitas Al-Azhar

DOI:

https://doi.org/10.55606/jurritek.v5i1.7559

Keywords:

Composite, High Temperature, Natural Fiber, Synthetic Fiber, Thermal Resistance

Abstract

This study aims to analyze the comparison of the durability of natural fiber and synthetic fiber composites in a high-temperature production environment. Testing was conducted on carbon fiber, aramid (synthetic), ramie, and jute (natural) fiber-based composites with exposure to temperatures of 80-150°C for 500 hours. The parameters measured include tensile strength, elastic modulus, dimensional stability, morphological changes, and moisture absorption. The research results show that synthetic fiber composites have superior durability compared to natural fibers. Carbon fiber composites retain 87% of their initial tensile strength with only a 4.2% reduction in modulus, while flax fibers only retain 62% strength with a 26% reduction in modulus. Microscopic analysis revealed significant delamination in natural fiber composites with interface gaps of 15-25 μm, compared to 3-5 μm in synthetic fibers. Natural fibers undergo thermal degradation due to the decomposition of lignin and hemicellulose, resulting in significant color changes and a dimensional shrinkage of 3.2%. The moisture absorption of natural fibers increases to 8.5% after exposure, indicating damage to the cellular structure. This research concludes that synthetic fiber composites are more suitable for long-term high-temperature production applications, but natural fibers can still be considered for low-temperature applications with appropriate chemical modification.

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References

Addis, L. B., Sendekie, Z. B., & Satheesh, N. (2022). Degradation kinetics and durability enhancement strategies of cellulosic fiber-reinforced geopolymers and cement composites. Vol. 2022.

Alajmi, A., Abousnina, R., Shalwan, A., Alajmi, S., & Alipour, G. (2024). An experimental and numerical investigation into the durability of fibre/polymer composites with synthetic and.

Asyiqin, N., & Nasharudin, M. (2023). The effect of heat treatment and chemical treatment on natural fibre to the durability of wood plastic composites – A review. Journal of Materials Exploration and Findings (JMEF), 2(2). https://doi.org/10.7454/jmef.v2i2.1023

Bichang, D. O., Aramide, F. O., Oladele, I. O., & Alabi, O. O. (2022). A review on the parameters affecting the mechanical, physical, and thermal properties of natural/synthetic fibre hybrid. Vol. 2022.

Billah, M., Rabbi, M. S., & Hasan, A. (2021). A review on developments in manufacturing process and mechanical properties of natural fiber composites. Vol. 02(01), 13–23.

Boimau, K., Bale, J., Putra, R., & Pah, J. (2022). Efek temperatur terhadap sifat tarik komposit poliester berpenguat serat daun gewang. Vol. 6(1), 11–18.

Daud, M. Y., & Aziz, A. (2022). Bamboo-fiber-reinforced thermoset and thermoplastic potential applications.

Fiore, V., Calabrese, L., Miranda, R., Badagliacco, D., Sanfilippo, C., & Palamara, D. (2024). On the response of flax fiber reinforced composites under salt-fog/dry conditions: Reversible and irreversible performance degradation.

Iliyas, R. A., et al. (2022). Bio and synthetic based polymer composite materials. Vol. 14(18). HAL Id: hal-03773674.

Musthaq, M. A., Dhakal, H. N., Zhang, Z., & Barouni, A. (2023). The effect of various environmental conditions on the impact damage behaviour of natural-fibre-reinforced composites (NFRCs): A critical review.

Nugraha, A. D., Nuryanta, M. I., Sean, L., Budiman, K., Kusni, M., & Muflikhun, M. A. (2022). Recent progress on natural fibers mixed with CFRP and GFRP: Properties, characteristics, and failure behaviour.

Patel, R. V., & Yadav, A. (2023). Physical, mechanical, and thermal properties of natural fiber-reinforced epoxy composites for construction and automotive applications.

Simamora, P., Simanjuntak, J., Sinulingga, K., & Laksono, A. D. (2023). Mechanical properties of polypropylene composites with different reinforced natural fibers – A comparative study. Vol. 24(7), 311–317.

Sipil, E. D. A. N. (2023). Desain dan pembuatan alat uji pompa sentrifugal skala laboratorium. Vorteks, 04(01). https://doi.org/10.54123/vorteks.v4i1.267

Sipil, E. D. A. N., Siregar, Z. H., Nasution, A. F., Fazri, M., & Puspita, R. (2024). The effect of fuel mixture composition on gasoline. Vorteks, 05(02), 394–402. https://doi.org/10.54123/vorteks.v5i2.389

Wardani, L., & Sugiyana, D. (2020). Characterization of composite containing LDPE (low-density polyethylene) and modified pineapple leaf fiber. Vol. 21(4).

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Published

2026-01-03

How to Cite

Sabikah, S. N. N., M.Irfan Syahputra, & Lindi Cistia Praba. (2026). Analisis Perbandingan Daya Tahan Komposit Serat Alam dan Serat Sintetis pada Lingkungan Produksi Bersuhu Tinggi. JURAL RISET RUMPUN ILMU TEKNIK, 5(1), 455–463. https://doi.org/10.55606/jurritek.v5i1.7559

Issue

Vol. 5 No. 1 (2026): April: Jurnal Riset Rumpun Ilmu Teknik

Section

Articles

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Copyright (c) 2026 JURAL RISET RUMPUN ILMU TEKNIK

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