Dimensional stability and tensile strength of biopolymer composite reinforced with hardwood fiber at varying proportions
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Abstract
Abstract. Bola TS, Oluyege AO, Aina KS. 2020. Dimensional stability and tensile strength of biopolymer composite reinforced with hardwood fiber at varying proportions. Asian J For 4: 1-5. Wood-plastic composites (WPCs) are emerging materials that have high potentials to be used in many building applications. This study was designed to produce bio-composites made from three different wood species and at three different mixing ratios of plastic to wood on weight to weight basis. The main variables employed in this study were wood species of Triplochiton scleroxylon, Terminalia superba and Gmelina arborea; at three plastic: wood ratios of 40:60, 50:50, and 60:40. The composite samples were made through compounding and extrusion processes. The properties evaluated were carried out in accordance with the American Standard Testing Methods of 570 and 790 to determine the dimensional stability and strength properties of the composites. The values obtained for the wood species ranged from 0.59 g/cm3 to 0.72 g/cm3, 0.59% to 0.71%, 0.63% to 0.7%and 1.84 MPa to 2.07 MPa for density, water absorption, thickness swelling and tensile strength, respectively. Meanwhile, the values obtained from the mixing ratio ranged from 0.54 g/cm3 to 0.79 g/cm3, 0.53% to 0.79%, 0.42% to 1.00%, and 1.58 MPa to 2.37 MPa for density, water absorption, thickness swelling and tensile strength, respectively. It was observed that mixing ratio and wood species used in this study influenced the dimensional stability and strength properties of the WPCs. This study revealed that as the wood-flour content increased to plastic, the dimensional properties and tensile strength values increases.
2017-01-01
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Ajayi, B. (2004). Reaction of cement-bonded composites from Gmelina arborea and Leuceana leucocephala to water treatment. Nigerian Journal of Forestry, 34(1-2), PP 279-285.
Ajigbon A.A. and Fuwape J.A. (2005): Strength and dimensional properties of plastic composite boards produced from Terminalia superba. Proceeding on conventional development in Agriculture, School of Agriculture and Agricultural Technology, Federal University of Technology, Akure 242 - 244pp
Bentsson, M., Gatenholm, P. and Oksman, K. (2005). The effect of cross linking on the properties of polyethylene/ wood flour composites. Composites Science and Technology, 65: 1468 - 1479.
Berger, M.J., and Stark, N.M. 1997. Investigations of species effects in an injection molding grade wood filled polypropylene, In: Wood fiber-Plastic Composites Conference. Forest Product Society
Carus M., Eder A., Dammer L, Korte H., Scholz L., Essel R., Breitmayer E., and Barth M., (2015) Wood-plastic composites (WPC) and natural ?bre composites (NFC): European and global markets 2012 and future trends in automotive and construction
Caul?eld D.F., Clemons C., Jacobson R.E., and Rowell R.M., (2005) Wood thermoplastic composites. In: Rowell RM (ed) Handbook of wood chemistry and wood composites. CRC Press, Boca Raton, 365–378
Chaharmahali, M., Kazemi-Najafi, S.; and Tajvidi, M. 2005. Mechanical properties of wood plastic composites made from particleboard and MDF wastes and polyethylene (HDPE) waste. Iranian Journal of Wood and Paper Science Research 20(2): 271-284.
Chaharmahali, M., Kazemi-Najafi, S.; and Tajvidi, M. 2007. Effect of Blending Method on the Mechanical Properties of Wood-Plastic Composites. Iranian Journal of Polymer Science and Technology 20(4): 361-367.
Chaharmahali, M., Tajvidi, M.; and Kazemi-Najafi, S. 2008. Mechanical Properties of Wood Plastic Composite Panels Made From Waste Fiberboard and Particleboard. Polymer Composites 29(6): 606-610.
Fuwape, J. A. and Aina, K. S. (2008): Effect of weathering on strength and physical properties of wood plastic composites produced from Gmelina arborea. Nigerian Journal of Forestry 38: 62- 73
Mcdonald, A.G., 2010. Effect of wood species on property and weathering performance of wood plastic composites. Composites Science and Technology, 41: 1434 – 1440
Myers, G.E.; Chahyadi, I.S.; Coberly, C.A. and Ermer, D.S. 1991. Wood flour/polypropylene composites: influence of maleated polypropylene and process and composition variables on mechanical properties. International Journal Polymeric Matter 15:21- 44
Olufemi, A., Sotande, Abiodun O. Oluwadare, Omaojor, O, Paul, F. (2012). Evaluation of Cement-Bonded Board Produced from Afzelia africana Wood Residues. Journal of Engineering Science and Technology, 7: (6), 732-743.
Panthapulakkal, S., Zereshkian, a., and Sain, M. (2006). Preparation and characterization of wheat straw fibers for reinforcing application in injection molded thermoplastic composites. Bioresource Technology, 97(2), 265– 272.
Pilarski, J. M., and Matuana, L. M. (2005). Durability of wood flour?plastic composites exposed to accelerated freeze thaw cycling. Journal of Vinyl and Additive Technology, 11(1), 1-8.
Schoch W; Heller I, Schweinruber F.H and Kienast F (2004): Wood anatomy of central European Species: 2004 online version www.woodanatomy.ch
Yang, H., Wolcott, M. P., Kim, H. S., Kim, S. and Kim, H. J. (2007). Effect of different compatibilizing agents on the mechanical properties of lignocellulosic material filled polyethylene bio-composites. Composites Structure 79: 369 - 375.
Zhang, Z. X., Gao, C., Xin, Z. X., and Kim, J. K. (2012). Effects of extruder parameters and silica on physico-mechanical and foaming properties of PP/wood-fiber composites