Low-cost plantain fiber composite as an alternative material for auto body fenders: A performance and manufacturing cost comparison

Authors

  • Obiafudo Obiora Jeremiah Nnamdi Azikiwe University Author
  • Ofochebe Sunday Madubueze Nnamdi Azikiwe University Author
  • Anyaora Sunday Chimezie Nnamdi Azikiwe University Author
  • Godspower Onyekachukwu Ekwueme Nnamdi Azikiwe University Author

DOI:

https://doi.org/10.63373/3047-8014/34

Keywords:

plantain fiber, composite material, manufacturing cost modeling

Abstract

High density polyethylene composite reinforced with natural plantain fiber was produced using injection moulding technique. The production process utilized the popular L18 Taguchi experimental design to investigate the effects of the major process variables such as barrel temperature, mold temperature, injection pressure, holding pressure, back pressure, clamping force and shaft speed in the final mechanical property of the composite material. The mechanical tests conducted on the new material reveal that fiber volume fraction of 0.1 combined with particle size of 75 μm and compactibilizer mass of 0.00024 kg gives a high-quality composite material suitable for auto body fender application, at reduced manufacturing cost of ₦1454/kg of the composite. The composite material produced at optimized process condition was found to have tensile strength of 87.44 MPa, yield strength of 76.6 MPa, flexural strength of 77.03 J, Rockwell hardness strength of 756.99, Impact strength of 16.21 J and density of 993 kg/m3. The result shows that the auto body fender produced based on the compactibilized plantain fiber reinforced high-density polyethylene composite has an advantage of low density and reduced production cost compared to conventional/alternative materials.

References

Bao, H., & Samareh, J. (2000, September). Affordable design-A methodology to implement process-based manufacturing cost models into the traditional performance-focused multidisciplinary design optimization. In 8th Symposium on Multidisciplinary Analysis and Optimization (p. 4839). DOI: https://doi.org/10.2514/6.2000-4839

Carle, D., & Blount, G. (1999). The suitability of aluminium as an alternative material for car bodies. Materials & design, 20(5), 267–272. DOI: https://doi.org/10.1016/S0261-3069(99)00003-5

Cheon, S. S., & Choi, J. H. (1995). Development of the composite bumper beam for passenger cars. Composite structures, 32(1-4), 491–499. DOI: https://doi.org/10.1016/0263-8223(95)00078-X

Davoodi, M. M., Sapuan, S. M., & Yunus, R. (2008). Conceptual design of a polymer composite automotive bumper energy absorber. Materials & Design, 29(7), 1447–1452. DOI: https://doi.org/10.1016/j.matdes.2007.07.011

Food and Agriculture Organization. (1990). Production Yearbook 1990. Rome: FAO, Rome.

Food And Agriculture Organization. (2006). Production Yearbook 2006. Rome: FAO, Rome.

Gutowski, T., Hoult, D., Dillon, G., Neoh, E. T., Muter, S., Kim, E., & Tse, M. (1994). Development of a theoretical cost model for advanced composite fabrication. Composites manufacturing, 5(4), 231-239. DOI: https://doi.org/10.1016/0956-7143(94)90138-4

International news – ULSAB Consortium unveils the new look of ultralight steel auto body. Mater. Des., 1996, 17, 107–110. DOI: https://doi.org/10.1016/S0261-3069(97)87182-8

Jambor, A., & Beyer, M. (1997). New cars—new materials. Materials & design, 18(4-6), 203–209. DOI: https://doi.org/10.1016/S0261-3069(97)00049-6

Joseph, S., Sreekala, M. S., & Thomas, S. (2002). Studies on resol matrix resin. Composites, 62, 1857.

Northrop Corporation, Advanced composites cost estimating manual (ACCEM). (1976). Technical report AFFDL-TR-76-87, Air Force Flight Dynamics Laboratory, Wright–Pattens Air Force Base Dayton, Ohio, August 1976.

Okafor, C. E., Ihueze, C., & Ujam, A. J. (2017). Optimization of tensile strengths response of plantain fibres reinforced polyester composites (PFRP) applying Taguchi robust design. Innovative Systems Design and Engineering ISSN, 2222-1727.

Opbroek, E. (2013). Ultralight steel: a global consortium changes the future of automotive steel. Xlibris Corporation.

Robinson, J. C., & Saúco, V. G. (2010). Bananas and plantains (Vol. 19). Cabi. DOI: https://doi.org/10.1079/9781845936587.0000

Sanadi, A. R., Calufield, D. F., & Rowell, R. M. (1994). Reinforcing polypropylene with natural fibers. Plastics Engineering(USA), 50(4), 27–28.

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Published

2025-06-06

Issue

Vol. 2 No. 2 (2025)

Section

Articles

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Copyright (c) 2025 Obiafudo Obiora Jeremiah, Ofochebe Sunday Madubueze, Anyaora Sunday Chimezie, Godspower Onyekachukwu Ekwueme (Author)

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How to Cite

Low-cost plantain fiber composite as an alternative material for auto body fenders: A performance and manufacturing cost comparison. (2025). Humanities Horizon, 2(2), 77-86. https://doi.org/10.63373/3047-8014/34

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