Yield and mechanical properties of veneer from Brachystegia nigerica

Babatola Olufemi

doi:10.1007/s11676-012-0255-3

Journal of Forestry Research ›› 2012, Vol. 23 ›› Issue (2) :295 -298. DOI: 10.1007/s11676-012-0255-3

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Yield and mechanical properties of veneer from Brachystegia nigerica

Babatola Olufemi ¹^,^a

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Abstract

In an effort to find suitable wood from natural forest to meet the demand for veneer products, the yield and tensile strength of veneers produced from Brachystegia nigerica were investigated. Two trees of B. nigerica were separately selected from 10 different natural forest zones while two logs were obtained from each tree. The logs were debarked and steamed in a vat prior to rotary peeling and slicing for veneer production. The optimum steam temperature was determined by considering different temperatures: 50°C, 60°C, 70°C, 80°C and 90°C for 24 h. Thereafter, optimum steam time was determined at the optimum temperature by considering durations of 24, 48, 72 and 96 h. The average taper of 0.75 mm per 1.0 m length was recorded for B. nigerica, indicating that the logs were reasonably cylindrical; thereby its logs are good for the production of veneer. The yield ranged from 44% to 61% with an average of 52% of the log input. The tensile strength of the veneer was tested perpendicular to grain and both peeled and sliced veneers had the highest tensile strength between 70C and 90C, suggesting that softening of wood polymers, especially lignin, is between 70°C and 90°C. The optimum temperature and time for veneer production are 70°C and 48 h, respectively. Commercial production of veneer from B. nigerica is feasible based on the yield and mechanical properties of the obtained veneer, thereby encouraging the expansion of the scope of its utilization.

Keywords

veneer / Brachystegia nigerica / yield / tensile strength / optimum steam temperature / optimum steam time

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Babatola Olufemi. Yield and mechanical properties of veneer from Brachystegia nigerica. Journal of Forestry Research, 2012, 23(2): 295-298 DOI:10.1007/s11676-012-0255-3

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References

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[1]	American Society for Testing Materials. 2007. Standard test methods for direct moisture content measurement of wood and wood-base materials. ASTM D4442 — 07, Vol. 04.10. ASTM West Conshohocken P.A.

[2]	Ando M., Takahashi N., Yoshizawa N.. Rupture of pit membranes and quality improvement of Sugi logs by a smoke-heating system with increased radiation of far infrared rays. Mokuzai Gakkaishi, 1996, 42: 845-853.

[3]	Brashaw B.K., Vatalar R.J., Lackore M., Ross R.J., Wang X., Forsman J.. Advancing technology to manufacturing of trusses from hardwood lumber. NRRI/T4. 2001, Duluth. MN: Natural Resources Research Institute, University of Minnesota

[4]	Chowdhury S., Fabiyi J.S., Frazier C.E.. Advancing the dynamic mechanical analysis of biomass: comparison of tensile-torsion and compressive-torsion wood DMA. Holzforschung, 2010, 64: 747-756.

[5]	Furuta F., Norimoto M., Yano H.. Thermal softening properties of waterswollen wood V. The effects of drying and heating histories. Mokuzai Gakkaishi, 1998, 44: 82-88.

[6]	Kärki T., Vainikainen V.. Determining the quality of aspen (Populus tremula) logs for mechanical wood processing in Finland. Forest Products Journal, 2004, 54(7&8): 64-71.

[7]	Kio P.R.O., Gbile Z.O., Ola-Adams B.A., Ladipo D.O.. Strategies for the conservation of natural forests and grazing kinds in Nigeria. 1985, Ibadan: Savanna series, Forestry Research Institute of Nigeria

[8]	Lucas EB. 1979. Future trends in Forestry research in tropical areas-Nigerian Experience. Proceedings of Forestry Association of Nigeria.

[9]	Lucas E.B., Olufemi B.. Study of some properties of Brachystegia nigerica relevant to veneer production. Applied Tropical Agriculture, 2001, 6(1): 16-22.

[10]	Nogi M., Yoshida M., Yamamoto H., Okuyama T.. Reduction of residual stress in logs by directing heating treatment: temperature distribution within the furnace. Forest Products Journal, 2001, 5(3): 69-74.

[11]	Olsson A.M., Salmen L.. The effect of lignin composition on the viscoelastic properties of wood. Nordic Pulp and Paper Resources Journal, 1997, 12: 140-144.

[12]	Ross R.J., Erickson J.R., Brashaw B.K., Wang X., Verhey S.A., Forsman J.W., Pilon C.L.. Yield and ultrasonic modulus of elasticity of red mapple veneer. Forest Products Journal, 2004, 54(12): 220-225.

[13]	Steinhagen H.P., Sim H.C., Govett R.L.. Penalty of insufficient conditioning of Grand fir and Douglas-fir veneer blocks. Forest Products Journal, 1989, 39(3): 51-52.

[14]	Uusitalo J.. Predicting the value of sawn timber in pine stands. Res. Notes no. 3. 1994, Helsinki, Finland: Univ. Of Helsinki, Inst. Of For. Tech.