Evaluation of Furfural/Urea complexes to improve physico-mechanical properties of birch wood

Document Type : Complete scientific research article

Authors

1 University of Tehran

2 MS graduated in Wood Sciences and Technology, Faculty of Natural Resources, University of Tehran

3 Head of the Wood Preservation Laboratory, CIRAD, UR BIOWooEB, TA B-114/16, 73 rue Jean-François Breton, F-34398 Montpellier Cedex 5, France BIOWooEB, Univ. Montpellier, CIRAD, Montpellier, France

4 Associated Prof. Department of Wood and Paper Sciences and Technology, Faculty of Natural Resources, University of Tehran

Abstract

Background and objectives: Impregnation of wood with different monomers and their conversion to the un-leachable reacted polymers inside the wood causes a new product which is called wood polymer. The furan compounds such as Furfuryl alcohol (FA) is commercially used for wood modification, producing then wood polymer. Wood is impregnated with FA, convert to the polyFA by heating. Furfural which is in fact the primary raw material in the manufacture of FA is extensively manufactured in Iran from residues of sugar cane. Furfural could not be easily polymerized alone like FA; but it is an aldehyde which can react with urea to make polymer network. In this study, the possibility of furfural/urea polymer along with acidic catalyzer (maleic anhydride) was evaluated for the improvement of physico-mechanical properties of birch wood.
Materials and methods: Birch wood (Betula sp.) imported from Russia was used for experiments. With a double treatment procedure Furfural+Urea/Maleic anhydride was impregnated into the wood according to a 2 steps vacuum/pressure technology: (1) diluted furfural in water and methanol, followed by (2) Urea/Maleic anhydride aqueous solution. For making comparison between the results, a commercial formulation based on the FA was also used as a reference. The mixes impregnated into the wood were polymerized by heating. Then, different physico-mechanical properties of wood samples were measured according to the standard guidelines of ISO 13061 series.
Results: The proportion of Furfural+Urea/Maleic anhydride was appropriately selected, and approximately 60 to 80% were converted to the polymer. The leaching rate of the products once polymerized within the treated wood was around 4% which is comparable to the results of commercial formulation based on FA. The weight percentage gain (WPG) of the wood samples varied between 27 to 57% depending on the furfural concentration in the treatment solutions. Despite the bulking effect, the density of samples after treatment increased significantly. The water absorption during samples soaking in the water is clearly linked with the WPG, and decreases with the increase of WPG. The volumetric swelling of the samples treated with the combination of furfural+urea/maleic anhydride also follows the same trend. However, the lowest volumetric swelling was obtained with the treatment with FA. The mechanical resistance evaluation showed that wood treatment by furfural +urea/maleic anhydride reduced the hardness and the impact bending of wood, while static strength such as modulus of rupture, modulus of elasticity, and compression parallel to the grain increased. The treatment with FA also reduced the resistance of wood against impact bending.
Conclusion: Wood treatment with the complex of furfural+urea/maleic anhydride, especially at high WPG levels, has a good potential for improving most wood properties. The high acidity of furfural based solutions is one of the issues requiring additional studies. If the alkaline pH is used, the curing of the resin will be disturbed and the leaching rate will increase. On the other hand, acidic pH also has a negative impact on wood properties.

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References

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