Document Type : Research Paper

Authors

1 Wood and forest products division, Research Institute of Forests and Rangelands, Agricultural Resear

2 PhD, Wood and forest products division, Research Institute of Forests and Rangelands, Agricultural Research Education and Extension Organization (AREEO), Tehran, Iran

3 Wood and Forest Products Science Research Division, Research Institute of Forests and Rangelands, Agricultural Research Education and Extension Organization (AREEO) P.O. Box 13185-116, Tehran, Iran

4 Scientific member of Islamic Azad University (pishva -Varamin) branch

Abstract

Wood fibers are increasingly being used as reinforcement in commercial thermoplastic composites due to their low cost, high specific strength properties and renewable nature. The ultimate goal of our research was to find the fundamental understanding of the mechanical behavior of poplar wood fiber/polypropylene (PP) composites. The effect of wood fiber concentrations and compounding temperature on the mechanical properties of composites, prepared using MAPP as the coupling agent, was investigated. In the sample preparation, four levels of fiber loading (10, 20, 30, and 40 w/w%) and three compounding temperatures (180, 190, and 200oC) were used. The results revealed that the major changes in composite properties occurred at fiber contents above 30%. The results clearly showed that the fiber loading of 30 and 40 w/w% at 190oC provided adequate reinforcement to increase the tensile and flexural strength of the composite. The modulus also increased with increasing fiber content, because poplar wood fibers are believed to be more rigid than polymer. However, the addition of wood fibers resulted in the reduction of both elongation and impact strength properties of the composites. The FTIR spectroscopy showed that the polymer was bonded to the fibers by ester linkages and hydrogen bonds at 1705–1735 cm-1.

Keywords

Main Subjects

- ASTM Standards, (1997). Plastics (I): D-256-D747-D638. Volume 08.01.
- Banks, W.B., Din, R.H., and Owen, N. L., (1995). Fiber Activation and subsequent CO-polymerisation. Holzforchung. j. vol. 79. 1995. No. 2 page 104-107.
- Felix, J.M., Gatenholm, P., and Schreiber, H. P., (1993). Controlled Interaction in cellulose-polymer composites. I effect on Mechanical properties. Polym compos. J., 1993. 14. 49.
- Hill, C. A. S., (2000). Wood-plastic composites: strategies for compatibilising the phases. Journal of the Istitute of wood science volume 15 No. 3 (2000) page 140-149.
- Maldas, D., and kokta, B. r. (1989). Improving Adhesion of wood fiber with polystyrene by the chemical Treatment of fiber with a coupling Agent and the Influence on the Mechanical properties of composites. J. Adhes. Sci. Technol. 3(7): 529-539.
- Matuana, L. M., Balatinecz, J. g., park, C.B., woodhams, R. T. (1999). Surface characteristics of chemically modified Newsprint fibers Deterimined by Invers Gas chromadtography. Wood and fiber science, 31 (2). 1999 pp. 116-127.
- Matuana, L. M., Balaticcz, J. J., sodhi, R. N. S., park, C. B., (2001). Surface characterization of esterified Cellulosic Fibers b) XPS and FTIR spectroscopy. Wood science and Technology 35 (2001) 191-201 springer-verlag 2001.
- Rowell, R. M., caulfield, D. F., chen, G. W., Ellis, W. D., Jacobson, R. E., lange, S., and Schumann, R. (1998). Recent Advances in Agro-fiber/thermoplastic composites. Natural polymers and composites. May 10-13 1998. A tibaia, SP. Brazil page 11-20.