Mechanical Properties of Activated Carbon (AC) Coir Fibers Reinforced with Epoxy Resin

Authors

  • Z. Salleh Universiti Kuala Lumpur, Applied Science & Advanced Technology Section, Malaysian Institute of Marine Engineering Technology, Dataran Industri Teknologi Kejuruteraan Marin, Bandar Teknologi Maritim, Jalan Pantai Remis 32200 Lumut Perak, Malaysia
  • M.Y.M. Yusop Universiti Kuala Lumpur, Applied Science & Advanced Technology Section, Malaysian Institute of Marine Engineering Technology, Dataran Industri Teknologi Kejuruteraan Marin, Bandar Teknologi Maritim, Jalan Pantai Remis 32200 Lumut Perak, Malaysia
  • M.S. Rosdi Universiti Kuala Lumpur, Applied Science & Advanced Technology Section, Malaysian Institute of Marine Engineering Technology, Dataran Industri Teknologi Kejuruteraan Marin, Bandar Teknologi Maritim, Jalan Pantai Remis 32200 Lumut Perak, Malaysia

DOI:

https://doi.org/10.15282/jmes.5.2013.9.0060

Keywords:

coconut; epoxy resin; reinforced; tensile.

Abstract

This research is to develop a carbon composite prepared from carbon coir fibers that is reinforced with epoxy resin. Carbon coir fibers were taken from three types of coir fiber specifically designated as CKCF, CYCF and CRCF. The samples were prepared using epoxy resin reinforced with carbon at different weight percentages for three types of coir fiber starting with 0wt.%, 2wt.%, 4wt.%, 6wt.%, 8wt.% and 10wt.%. The mechanical properties such as tensile stress and impact strength were used to characterize all the samples. The morphological study of reinforced samples was also conducted in this research using a SEM machine. The characteristics of all the composite materials were also investigated and discussed. It was determined that the CKCF sample exhibited better mechanical properties than the other coir fiber composites, having a higher average tensile stress value at 11.80MPa and higher impact strength values ranging from 268J to 276J at different carbon content. CKCF with 10wt% AC content had a tremendous impact strength compared with CYCF and CRCF.

References

Abdullah, S., Al-Asady, N. A., Ariffin, A. K., & Rahman, M. M. (2008). A review on finite element analysis approaches in durability assessment of automotive components. Journal of Applied Sciences, 8(12), 2192-2201.

Bachtiar, D., Sapuan, S. M., & Hamdan, M. M. (2010). Flexural properties of alkaline treated sugar palm fibre reinforced epoxy composites. International Journal of Automotive and Mechanical Engineering, 1, 79-90.

Bledzki, A. K., Mamun, A. A., & Volk, J. (2010). Barley husk and coconut shell reinforced polypropylene composites: The effect of fibre physical, chemical and surface properties. Composites Science and Technology, 70(5), 840-846.

Eichhorn, S., Baillie, C., Zafeiropoulos, N., Mwaikambo, L., Ansell, M., Dufresne, A.et al.Groom, L. (2001). Review: Current international research into cellulosic fibres and composites. Journal of materials Science, 36(9), 2107-2131.

Ishak, M., Sapuan, S., Leman, Z., Rahman, M., & Anwar, U. (2012). Characterization of sugar palm (arenga pinnata) fibres. Journal of thermal analysis and calorimetry, 109(2), 981-989.

Jeffrey, K. J. T., arlochan, F., & Rahman, M. M. (2011). Residual strength of chop strand mats glass fiber/epoxy composite structures: Effect of temperature and water absorption. International Journal of Automotive and Mechanical Engineering, 4, 504-519.

Mohanty, A., Misra, M., & Hinrichsen, G. (2000). Biofibres, biodegradable polymers and biocomposites: An overview. Macromolecular Materials and Engineering, 276(1), 1-24.

Monteiro, S. N., Lopes, F. P. D., Ferreira, A. S., & Nascimento, D. C. O. (2009). Natural-fiber polymer-matrix composites: Cheaper, tougher, and environmentally friendly. Jom, 61(1), 17-22.

Ravi Sankar, H., Srikant, R. R., Vamsi Krishna, P., Bhujanga Rao, V., & Bangaru Babu, P. (2013). Estimation of the dynamic properties of epoxy glass fabric composites with natural rubber particle inclusions. International Journal of Automotive and Mechanical Engineering, 7, 968-980.

Reddy, N., & Yang, Y. (2005). Biofibers from agricultural byproducts for industrial applications. TRENDS in Biotechnology, 23(1), 22-27.

Sapuan, S., Harimiand, M., & Maleque, M. (2003). Mechanical properties of epoxy/coconut shell filler particle composites. Arabian Journal for Science and Engineering, 28(2), 171-182.

Satyanarayana, K., Pillai, C., Sukumaran, K., Pillai, S., Rohatgi, P., & Vijayan, K. (1982). Structure property studies of fibres from various parts of the coconut tree. Journal of materials Science, 17(8), 2453-2462.

Schuh, T. G., & Gayer, U. (1997). Automotive applications of natural fiber composites. Botucato, Brazil: Unesp Publishers.

Venkataswamy, M., Pillai, C., Prasad, V., & Satyanarayana, K. (1987). Effect of weathering on the mechanical properties of midribs of coconut leaves. Journal of materials Science, 22(9), 3167-3172.

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Published

2013-12-31

How to Cite

[1]
Z. Salleh, M.Y.M. Yusop, and M.S. Rosdi, “Mechanical Properties of Activated Carbon (AC) Coir Fibers Reinforced with Epoxy Resin”, J. Mech. Eng. Sci., vol. 5, no. 1, pp. 631–638, Dec. 2013.

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