Effects of waste polyester fibers on the mechanical and thermal properties of WPC products

Hosseini, Seyedeh Zahra; Enayati, Ali Akbar

doi:10.22092/ijwpr.2015.102669

Document Type : Research Paper

Authors

¹ M.Sc., Department of wood and paper sciences and technology, Faculty of Natural Resources of Tehran University,Tehran, Iran

² Professor of of Tehran University

https://doi.org/10.22092/ijwpr.2015.102669

Abstract

This study has been undertaken to investigate effects of synthetic waste fibers of polyester in improving mechanical properties of wood plastic composites. Two types of polyester fibers (carpet fibers and polish fibers), high density polyethylene along with 40 wt% wood flour of populus, 2 wt% of maleic anhydride grafted polyethylene (MAPE) and ethylene- glycidyl methacrylate copolymer (E-GMA) as coupling agent were used. After two-stage mixing, resulted granules were hot pressed (at160℃, under 10 Mpa pressures) to produce test boards measuring 20×20×0.7 cm in dimensions. Results from measurement of mechanical properties of the samples have shown that with increasing the amount of polyester fibers (carpet fibers and polish fibers), tensile modulus of elasticity of wood plastic composites decreases and increases his flexural modulus of elasticity. Also by increasing amount carpet fibers, the tensile, flexural strengths of wood plastic composites-carpet fibers increases and the maximum of flexural strength is in a sample that contained 20 wt% carpet fibers. But about the plush fiber, 10 wt% of it is efficient for increasing the flexural and tensile strengths of wood plastic composites-plush fibers. Then on the composites contained the optimal polyester (polish fiber 10% and carpet fibers 20%) for increasing the mechanical strength, TGA and DSC testes for experience the thermal behavior of the composites were analyzed. Thermal analyses results have shown that with addition of polyester in the wood composite plastic, are reduced the percentage of crystallization, temperature of crystallization and the temperature of stability and degradation thermal of the composite.
Morphologic study by Scanning Electron Microscopy indicates that with the increasing percentage of polyester fibers, is more denser and smoother the integration between the fracture surface of the composite material.

Keywords

Main Subjects

Composite wood products

References

-Almaadeeh, M., Kahraman, R., Khanam, N. and Madi, N., 2012. Date palm wood flour/glass fiber reinforced hybrid composites of recycled polypropylene: Mechanical and thermal properties. Journal of Materials and Design, 42: 289-294.

-Anurag, K., Xiao, F. and Amirkhanian, S., 2009. Laboratory investigation of indirect tensile strength using roofing polyester waste fiber in hot mix asphalt. Journal of Construction and Building Materials, 23: 2035-2040.

-Chang, W.P., Kim, K.J. and Gupta, R.K., 2009. Ultrasound assisted surface modification of wood particulates for improved wood plastic composites. Journal of Composite Interfaces, 16: 687-709.

-Cui, Y.H. and Tao, j., 2009. Fabrication and mechanical properties of glass fiber- reinforced wood plastic hybrid composites. Journal of Applied Polymer Science, 112: 1250-1257.

-Fiori, M.A., Paula, M.M.S., Angioletto, E., Santos, M.F., Riella, H.G. and Quadiri, M.G.N., 2008. Effect of the temperature in the antimicrobial action of the bactericide wood polymer composite-BWPC. Journal of Materials Science Forum, 19: 591-593.

-Jiang, H., Kamdem, D.D., Bezubic, B. and Ruede, P., 2003. Mechanical properties of poly (vinyl chloride) wood flour glass fiber hybrid composites. Journal of Vinyl and Additive Technology, 9: 138-145.

-Lei, Y. and Wu, Q., 2010. Wood plastic composites based on microfibrillar blends of high density polyethylene/poly (ethylene terephthalate). Journal of Bioresource Technology, 101: 3665-3671.

-Lei, Y., Wu, Q. and Zhang, Q., 2009. Morphology and properties of microfibrillar composites based on recycled poly (ethylene terephthalate) and high density polyethylene. Journal of Composites: Part A, 40: 904-912.

-Liu, H., Wu, Q. and Zhangm Q., 2009. Preparation and properties of banana fiber-reinforced composites based on high density polyethylene (HDPE) / Nylon-6 blends. Journal of Bioresource Technology, 100: 6088-6097.

-Miraftab, M. and Lickfold, A., 2008. Utilization of carpet waste in reinforcement of substandard soils. Journal of Industrial textiles, 38: 167-174.

-Oromiehee, A. and Jafarzadeh, F., 2008. Plastic-Wood Composite. The Publication of Iranian Polymer Forum, Tehran, 97p.

-Razavi Nouri, M., Jafar Zadeh Dogouri, F., Oromiehie, A. and Ershad Langroudi, A., 2006. Mechanical properties and water absorption behavior of chopped rice husk filled polypropylene composites. Iranian Polymer Journal, 15: 757-766.

-Semeralul, H.O. and Rizvi, G.M., 2009. Characterization of properties of wood plastic compocites (WPC) with glass fiber reinforcements. Journal of Reinforced Plastics and Composites, 2: 22-25.

-Tajvidi, M. and Takemura, A., 2009. Effect of fiber content and type, compatibilizer, and heating rate on thermogravimetric properties of natural fiber high density polyethylene composites. Journal of Polymer Composites, 30: 1226-1233.

-Valente, M., Sarasini, F., Marra, F., Tirillo, J. and Pulci, G., 2011. Hybrid recycled glass fiber/wood flour thermoplastic composites: Manufacturing and mechanical characterization. Journal of Composites: Part A, 42: 649-657.

-Videen, G., Zubko, E., Sun, W., Shkuratov, Y. and Yuffa, A., 2015. Mixing rules and morphology dependence of the scatterer. Journal of Quantitative Spectroscopy and Radiative Transfer, 1: 68–75.

-Voit, B., 2000. New development in hyperbranched polymers. Journal of Polymer Chemistry Science Part A, 38: 2505-2525.

-Zhao, Y., Wang, K., Zhu, F., Xue, P. and Jia, M., 2006. Property of poly (vinyl chloride)/wood flour /montmorillonite composite: effect of coupling agent and layered silicate. Journal of Polymer Degradation and Stability, 91: 2874-2883.

Iranian Journal of Wood and Paper Science Research

Effects of waste polyester fibers on the mechanical and thermal properties of WPC products

References

References

Volume 30, WINTER 4 - Serial Number 53
December 2015
Pages 552-566

Effects of waste polyester fibers on the mechanical and thermal properties of WPC products

References

References

Volume 30, WINTER 4 - Serial Number 53December 2015Pages 552-566

Volume 30, WINTER 4 - Serial Number 53
December 2015
Pages 552-566