Investigation on the Mechanical Properties of Paper Water Hyacinth (Eichhornia Crassipes)



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Submitted Dec 23, 2022
Published Jan 29, 2023
10.24018/ejeng.2023.8.1.2965

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The widely use of papers and for the promotion of conservation of the forest ecosystem in making papers from the falling of trees. This work is focused on the realization of paper and its mechanical properties. Water hyacinth (Eichornia crassipes) is aquatic plant with a high growth rate that usually cover the river surface and has an impact to the environment and other living things. The work done was to produce a paper from water hyacinth through cutting, grinding, refining, molding, the bleaching process and drying process we obtained different papers. In the realization process of the papers, we have used Hydrogen peroxides for the bleaching process to obtain white paper (Bleached paper). In our case we have both the bleached and the unbleached paper. Papers were successfully produced under experimental condition. Mechanical properties of each paper were investigated. The various density of paper water hyacinth plant of the bleached and unbleached was 21.68 g/m3 and 26.37 g/m3 respectively, average tensile rupture stress 1.337MPa & 0.405MPa and young modulus was found to be 36.278MPa and 17.604MPa, the elongation at break 4.744% and 2.879%, average moisture content of 4.82% to 9.59% and 3.57% to 6.62% respectively for the Unbleached and Bleached paper water hyacinth plant. For this reason, Unbleached Paper with certain different strength ranges could be considered to be applied as packaging, seedling pot, mulching or insulating material in advance application. The use of water hyacinth as biomass with the used of the roots and leaf shows a bulky structure. The study concludes that water hyacinth is a potential fiber for paper production especially in areas where it is abundant, but the tensile strength of unbleached paper is more than the bleached paper. So that the paper can be used for other purpose than writing.

Keywords: Bleached and Unbleached Mechanical Properties Paper Utilization Physical Test Tensile Stress Water Hyacinth

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References

  1. Anonymous. Introduction to paper properties Tappi home study course. Tappi Atlanta; 1978.
     Google Scholar
  2. Baley C, Le Duigou A, Bourmaud A, Davies P. Influence of Drying on the Mechanical Behaviour of Flax Fibers and Their Unidirectional composites.Composites Part A. Applied Science and Manufacturing, 2012;43:1226-1233.
    DOI  |   Google Scholar
  3. Berthelot JM. Mécanique des matériaux et structures composites. France; 2010.
     Google Scholar
  4. Bhuvaneshwari M, Sangeetha K. Effect of blending ratio of water hyacinth fibers on the properties of needle punched nonwoven fabrics. International Journal of Technical Research and Applications, 2017;5(2):2320-8163.
     Google Scholar
  5. Ververis C, Georghiou K, Christodoulakis N, Santas P, Santas R. Fiber dimensions, lignin and cellulose content of various plant materials and their suitability for paper production. Industrial Crops and Products, 2004;19(3):245–254. https://doi.org/10.1016/j.indcrop.2003.10.006.
    DOI  |   Google Scholar
  6. Hunter D. Papermaking: The History and Technique of an Ancient Craft. Dover; 2011.
     Google Scholar
  7. Smook AG. Handbook For Pulp and Paper Technologists (The SMOOK Book). 4th ed. Kocurek M. Ed. Vancouver: TAPPI Press; 2016.
     Google Scholar
  8. Hall G. Historical Perspectives in the Conservation of Works of Art on Paper. Paper Trade Journal, 1926; 84(14): 185.
     Google Scholar
  9. Fyichina. [Internet] 2010. Retrieved from: http://www.fyichina.com.cn/.
     Google Scholar
  10. International Energy Agency (IEA). Biogas Production and Utilization; EA Bio-Energy. [Internet] 2005. Retrieved from: www.iea-biogas.net.
     Google Scholar
  11. Langeland KA, Cherry HM. Identification and Biology of Nonnative Plants in Florida’s Natural Areas. University of Florida-IFAS Publication# SP 257; 2008.
     Google Scholar
  12. Ludwig S. A Publication of the Deutsches Zentrum für Entwicklungstechnologien-gATE. Deutsche Gesellschaft für Technische Zusammenarbeit (GTZ). Biogas Plants; 1988.
     Google Scholar
  13. Nadlene R, Nadlene R, Sapuan SM, Sapuan SM, Jawaid M, Ishak MR, Ishak MR, et al. Material Characterization of Roselle Fibre ([i]Hibiscus sabdariffa [/i]L.) as Potential Reinforcement Material for Polymer Composites. Fibres and Textiles in Eastern Europe, 2015; 23(6(114)): 23–30. https://doi.org/10.5604/12303666.1167413.
    DOI  |   Google Scholar
  14. Sathishkumar T, Navaneethakrishnan P, Shankar S, Rajasekar R, Rajini N. Characterization of natural fiber and composites – A review. Journal of Reinforced Plastics and Composites, 2013;32(19):1457–1476. https://doi.org/10.1177/0731684413495322.
    DOI  |   Google Scholar
  15. Schmitz DC, Schardt JD, Leslie AJ, Dray FA, Osborne JA, Nelson BV. The ecological impact and management history of three invasive alien aquatic plant species in Florida. Proceedings of a symposium held at Indianapolis, ed. McKnight, BN, pp. 173-194, Indianapolis, USA, 1993.
     Google Scholar
  16. Seyni A, Le Bolay N, Molina-Boisseau S. Intérêt d’utiliser des charges vegetals dans des materiaux composites co-broyes. Laboratoire de Genie Chimique UMR CNRS; 2011. French.
     Google Scholar
  17. U. Hirn and R. Schennach. (2015,). , Scientific Reports, 5, 10503.
    DOI  |   Google Scholar
  18. Van TK, Steward KK. Evaluation of Chemicals for Aquatic Plant Control. Annual Report 1981, Ft. Lauderdale, FL; 1982, p. 66.
     Google Scholar