Reducing resin content and board density without adversely affecting the mechanical properties of particleboard through controlling particle size

Mohammad Arabi; Mehdi Faezipour; Heydar Gholizadeh

doi:10.1007/s11676-011-0207-3

Journal of Forestry Research ›› 2011, Vol. 22 ›› Issue (4) : 659 -664. DOI: 10.1007/s11676-011-0207-3

Original Paper

Reducing resin content and board density without adversely affecting the mechanical properties of particleboard through controlling particle size

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Abstract

Density and resin content are two factors that have a significant effect on the production cost of wood composite. However, particle size affects resin content and density, which suggests that the interaction of these three factors can be manipulated to reduce the board density and resin content of particleboard without adversely influencing its mechanical properties. Some mathematical functional forms based on resin content, board density and slenderness ratio were regressed and an appropriate form was chosen. According to analysis of the results using SHAZAM 9 software, the exponential function best fit the experimental data. Finally, “indifference curves” of mechanical properties were illustrated and analyzed. The results indicated that negative effects of density or resin content reduction on mechanical properties could be compensated for by controlling particles’ slenderness ratio. Interestingly, increases in slenderness ratio compensated for the negative effects of decreases in resin content or board density on module of rupture (MOR) and module of elasticity (MOE). Moreover, this “compensation ratio” intensified as resin content or density decreased and/or as the MOR or MOE increased. On the other hand, reduction in slenderness ratio indicated a complementary effect on reducing internal bond (IB) strength, a result of decreases in resin content or density. Moreover, this “complementary ratio” was intensified as resin content or density decreased and/or as IB strength increased.

Keywords

Forestry Research / Internal Bond / Slenderness Ratio / Indifference Curve / Resin Content

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Mohammad Arabi, Mehdi Faezipour, Heydar Gholizadeh. Reducing resin content and board density without adversely affecting the mechanical properties of particleboard through controlling particle size. Journal of Forestry Research, 2011, 22(4): 659-664 DOI:10.1007/s11676-011-0207-3

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Azizi M., Ghorbannezhad P., Hatefnia H.. Estimation of demand for wood panels in Iran by the year of 2012. Journal of Forestry Research, 2009, 20(2): 179-182.

[2]	Azizi M.. A model of supplying poplar wood for Iranian paper & wood factories. Journal of Forestry Research, 2008, 19(4): 323-328.

[3]	Amiri S.. Economic investigation of particleboard plants. Journal of Iranian Natural Resource, 1998, 51: 25-35.

[4]	Barnes D.. A model of the effect of strand length and strand thickness on the strength properties of oriented wood composites. Forest Prod J, 2001, 51(2): 36-46.

[5]	EN 310. 1993. Wood-based panels determination of modulus of elasticity in bending and of bending strength. European standard.

[6]	EN 319. 1993. Particleboards and fiberboards: determination of tensile strength perpendicular to the plane of the board. European standard.

[7]	Hill M., Wilson J.. Particlaeboard strength as affected by unequal resin distribution on different particle fractions. Forest Prod J, 1987, 28: 44-48.

[8]	Kazakevics A.R., Spedding D.J.. The Rate of Formaldehyde Emission from particleboard. Holzforschung, 2009, 33(5): 155-158.

[9]	Maloney T.M.. Modern particleboard and dry process fiberboard manufacturing. 1977, San Francisco, CA.: Miller Freeman Publication, 672.

[10]	Marra A.A.. Technology of wood bonding: principles in practice. 1992, New York: Van Nostrand

[11]	Reinhold, Miyamoto K., Nakahara S., Suzuki S.. Effect of particle shape on linear expansion of particleboard. J Wood Sci, 2002, 48: 185-190.

[12]	Mendes L.M., Mendes S.A., Iwakiri S., Chaves M.D., Mori F.A., Mendes R.F.. Effects of board density and layers composition on the physical and mechanical properties of OSB manufactured from clones of Eucalyptus. Cerne, 2008, 14: 379-385.

[13]	Post P.W.. Effect of particle geometry and resin content on bending strength of oak flake board. Forest Prod J, 1968, 8: 317-322.

[14]	Prasittisopin L., Li K.. A new method of making particleboard with a formaldehyde-free soy-based adhesive. Composites: Part A, 2010, 41: 1447-1453.

[15]	Sackey E.K., Semple K.E., Oh S.W., Smith G.D.. Improving core bond strength of particleboard through particle size redistribution. Wood Fiber Sci, 2008, 40: 214-24.

[16]	Sackey E.K., Smith G.D.. Characterizing macro-voids of uncompressed mats and finished particleboard panels using response surface methodology and X-ray CT. Holzforschng, 2010, 64: 343-352.

[17]	Sun Y.G., Arima T.. Structural mechanics of wood composite materials II: Ultrasonic propagation mechanism and internal bonding of particleboard. J Wood Sci., 1999, 45: 221-226.

[18]	Wanga S.Y., Yanga T.H., Lina L.T., Lin C.J., Tsai M.J.. Properties of low-formaldehyde-emission particleboard made from recycled wood-waste chips sprayed with PMDI/PF resin. Build Environ, 2007, 42: 2472-2479.

[19]	Wong E.D., Zhang M., Wang Q., Kawai S.. Formation of the density profile and its effects on the properties of particleboard. Wood Sci Technol, 1999, 33: 327-340.

[20]	Zeli Q., Takeshi F., Sadanobu K., Yoshihiko Ni.. Effects of urea-formaldehyde resin mole ratio on the properties of particleboard. Build Environ, 2007, 42: 1257-1263.

[21]	Zhang X., Muszynski L., Douglas J.G.. Measuring resin-adhesive spray characteristics using a laser diffraction analyzer. Forest Prod J, 2009, 59(1): 83-87.