Sage Journals: Discover world-class research

Abstract

Two kinds of wood particles with different sizes and properties were compounded with polypropylene (PP) in highly concentrated levels (by 50% and 60% weight concentration). Their flow abilities were estimated by viscosity-shear rheological test and spiral flow mold respectively; the results show that higher concentrations result in poor flow ability. However, to estimate the relation between particle size and flow ability, spiral flow-mold testing results are not consistent with those of the rheological test. The thermal melting, crystallization, and stability of the highly filled wood/PP composites were measured by differential scanning calorimetry (DSC). The results clearly showed that the melting temperature, thermal stability, and crystalline degree of composites decrease when filler contents and size increase. The mechanical properties of these materials were assessed by tensile test machine and testing results also show that the filler concentration and size dramatically affect the mechanical properties, such as E module, tensile strength, and breaking strength of wood-particle-filled PP composites. The weld-line strength of all wood composites with the contents was also tested in the same way. By testing, one found that the usual defect of weld line in injection-molding process had a very significant negative impact on the mechanical properties of wood composites and the relation of wood-particle-filling fraction and size to weld-line strength was also analyzed and clarified.

Keywords

wood particles polypropylene flow ability mechanical property thermal property weld line.

Get full access to this article

View all access options for this article.

References

Park, B.D. and Balatinecz, J.J. ( 1997). A Comparison of Compounding Processes for Woodfiber/ Thermoplastic Composites, Polymer Composites, 18(3): 425-431.

Park, B.D. and Balatinecz, J.J. ( 1997). Mechanical Properties of Wood-fiber/Toughened lsotactic Polypropylene Composites, Polymer Composites, 18(1): 80-89.

Beshay, A.D. , Kokta, B.V. and Daneault, C. ( 1985). Use of Wood Fibers in Thermoplastic Composites II Polyethylene , Polymer Composites, 6(4): 261-271.

Kokta, B.V. , Chen, R. , Daneault, C. and Valade, J.L. ( 1983). Use of Wood Fibers in Thermoplastic Composites, Polymer Composites, 4(4): 229-232.

Selke, S.E. and Wichman, I. ( 2004). Wood Fiber Polyolefin Composites, Composites: Part A, 35: 321-326.

Bledzki, A.K. and Gassan, J. (1999). Composites Reinforced with Cellulose Based Fibers, Progress in Polymer Science, 24: 221-274.

Zaini, M.J. , Fuad, M. , Ismail, Z. , Mansor, M.S. and Mustafah, J. ( 1996). The Effect of Filler Content and Size on the Mechanical Properties of Polypropylene/Oil Palm Wood Flour Composites, Polymer International, 40: 51-55.

Ismail, H. , Rozman, H.D. , Jaffri, R.M. and Ishak, Z.A. ( 1997). Oil Palm-wood Flour Reinforced Epoxidized Natural Rubber Composites: The Effect of Filler Content and Size, European Polymer Journal, 33: 1627-1632.

Gupta, B.S. , Reiniati, I. and Laborie, M.-P. -G. (2007). Surface Properties and Adhesion of Wood Fiber Reinforced Thermoplastic Composites, Colloids Surfaces A: Physicochemical Engineering Aspects, 302(1): 388-395.

10.

Lundquist, L. , Marque, B. , Hagstrand, P.O. , Leterrier, Y. and Manson, J.A.E. (2003). The Curves of Wood Powder/Polypropylene Composites with ..., Composites Science Technology, 63: 137-152.

11.

Eckert, C. ( 2000). Opportunities for Natural Fibers in Plastic Composites , In: Proceedings of Progress in Wood Fibre-Plastic Composites, 25-26 May, Toronto, ON, Canada.

12.

Pritchard, G. (2004). Two Technologies Merge: Wood Plastic Composites, Plastics, Additive Compound, 6(4): 18-21.

13.

Chen, Y. , Sun, L. , Chiparus, O. , Negulescu, I. , Yachmenev, V. and Warnock, M. ( 2005). Kenaf/Ramie Composite for Automotive Headliner, Journal of Enviromental Polymer, 13(3): 107-114.

14.

Rouilly, A. , Orliac, O. , Silvestre, F. and Rigal, L. (2006). New natural Injection-Moldable Composite Material from Sunflower Oil Cake, Bioresource Technology , 97(4): 553-561.

15.

Zampaloni, M. , Pourboghrat, F. , Yankovich, S.A. , Rodgers, B.N. , Moore, J. , Drzal, L.T. , Mohanty, A.K. and Misra, M. (2007). Kenaf Natural Fiber... Problems and Solutions , Composites: Part A, 38: 1569-1580.

16.

Lyons, J.S. and Ahmed, M.R. (2005). Factors Affecting the Bond between Polymer Composites and Wood, Journal of Reinforced Plastics and Composites, 24(4): 413-421.

17.

Cantero, G. , Arbelaiz, A. , Mugika, F. , Valea, A. and Mondragon, I. (2003). Mechanical Behavior of Wood Polypropylene Composites Effects of Fiber Treatments and Ageing Processes , Journal of Reinforced Plastics and Composites, 22(1): 37-50.

18.

Kaboorani, A. and Faezipour, M. (2009). Effects of Wood Preheat Treatment on Thermal Stability of HDPE Composites, Journal of Reinforced Plastics and Composites, doi: 10.1177/0731684408094064.

19.

Cui, Y.H. , Tao, J. , Noruziaan, B. , Cheung, M. and Lee, S. (2008). DSC Analysis and Mechanical Properties of Wood Plastic Composites, Journal of Reinforced Plastics and Composites, doi: 10.1177/0731684408097766.

20.

Chahamarali, M. , Mirbagheri, J. , Tajvidi, M. , Kazemi Najafi, S. and Mirbagheri, Y. (2008). Mechanical and Physical Properties of Wood Plastic Composite Panels, Journal of Reinforced Plastics and Composites, doi: 10.1177/0731684408093877.

21.

Azizi, H. and Ghasemi, I. ( 2009). Investigation on the Dynamic Melt Rheological Properties of Polypropylene Wood Flour Composites, Polymer Composites , 30: 429-435.

22.

Hristov, V. and Vlachopoulos, J. (2008). Effects of Polymer Molecular Weight and Filler Particle Size on Flow Behavior of Wood Polymer Composites , Polymer Composites, 29: 831-839.

23.

Nourbakhsh, A. and Ashoriz, A. (2008). Fundamental Studies on Wood Plastic Composites Effects of Fiber Concentration and Mixing Temperature on Mechanical Property of Poplar PP Composites, Polymer Composites , 29: 569-573.

24.

Migneault, S. , Koubaa, A. , Erchiqui, F. , Chaala, A. , Englund, K. and Wolcott, M.P. (2009). Effects of Processing Method and Fiber Size on the Structure and Properties of Wood Plastic Composites , Composites: Part A, 40: 80-85.

25.

Beg, M.D.H. and Pickering, K.L. (2008). Reprocessing of Wood Fibre Reinforced Polypropylene Composites. Part I. Effects on Physical and Mechanical Properties, Composites: Part A, 39: 1091-1100.

26.

Dominkovics, Z. and Béla Pukánszk, L. (2007 ). Surface Modification of Wood Flour and Its Effect on the Properties of PP Wood Composites, Composites: Part A, 38: 1893-1901.

Influence of Particle Concentration and Type on Flow,Thermal,and Mechanical Properties of Wood-Polypropylene Composites

Abstract

Keywords

Get full access to this article

References