Department of Wood and Paper Sciences and Technology, Faculty of Natural Resources, University of Tehran, Karaj, Iran.
10.22059/jfwp.2024.371195.1279
Abstract
Different methods have been developed for the heat treatment of wood. Oil heat treatment (OHT), as a unique method, can provide a dry and oxygen-free heating medium. This study used a pilot-scale oil heat treatment to treat poplar wood at different temperatures to enhance its weathering resistance. Poplar timber was subjected to oil heat treatment using a specific heating program at three target temperatures (180, 190, and 200 °C), each held for two hours. The specimens were prepared and subjected to 1000 hours of accelerated weathering with a Gardner wheel. Water absorption and volumetric swelling were also determined during seven days of soaking in water. Contact angle measurements of water droplets, colorimetry, and ATR-FTIR analysis were also conducted before and after weathering. The dimensional stability of treated wood increased with higher processing temperature. Although the water absorption values of treated wood were lower than those of the control specimens, the difference was not significant. The samples exhibited an obvious color difference before weathering due to oil heat treatment, but their color changed to silver-gray tans after weathering. The maximum ∆E value after weathering was observed in the samples treated at 200 °C. Weathering increased the wettability of wood surfaces, but the treated samples still had a higher water droplet contact angle than those of the control sample. ATR-FTIR results determined that oil heat treatment is not an effective method for preventing the degradation of lignin in wood surface exposed to weathering factors.
Ke, Q., Zhang, F., & Zhang, Y. (2016). Optimization of L-shaped Corner Dowel Joint in Modified Poplar using Finite Element Analysis with Taguchi Method. Journal of the Korean Wood Science and Technology, 44(2), 204-217.
Chu, D., Xue, L., Zhang, Y., Kang, L., & Mu, J. (2016). Surface characteristics of poplar wood with high-temperature heat treatment: Wettability and surface brittleness. BioResources, 11(3), 6948-6967.
Hill, C.A.S. (2006). Wood Modification: Chemical, Thermal, and Other Processes, Wiley, Chichester, England. 264
Awoyemi, L., Cooper, P.A., & Ung, T.Y. (2009). In-treatment cooling during thermal modification of wood in soy oil medium: soy oil uptake, wettability, water uptake and swelling properties. European Journal of Wood and Wood Products, 67(4), 465-470.
Suri, I. F., Purusatama, B. D., Lee, S., Kim, N., Hidayat, W., Ma'ruf, S.D., & Febrianto, F. (2021). Characteristic features of the oil-heat treated woods from tropical fast growing wood species. Wood Research, 66(3), 365-378.
Wang, J.Y., & Cooper, P.A. (2005). Effect of oil type, temperature and time on moisture properties of hot oil-treated wood. European Journal of Wood and Wood Products, 63(6), 417-422.
Esteves, B. (2009). Wood modification by heat treatment: A review. BioResources, 4(1), 470-404.
Acosta, R.A., Arango, J.A.M., & Da Silva, E.J. (2021). Technologies Applied to Wood Heat Treatments, a Review. Scientia et Technica, 26(2), 129-136.
Lee, S.H., Ashaari, Z., Lum, W.C., Halip, J.A., Ang, A.F., Tan, L.P., Chin, K.L., & Tahir, P.M. (2018). Thermal treatment of wood using vegetable oils: A review. Construction and Building Materials, 181, 408-419.
Rapp, A.O., & Sailer, M. (2001). Oil heat treatment of wood in Germany-State of the art. Review on heat treatments of wood. In Proceedings of the Special Seminar, 9th Feb., Antibes, France, Forestry and Forestry Products, France. COST Action E, 22, 43-60.
Dubey, M.K., Pang, S., & Walker, J. (2012). Oil uptake by wood during heat-treatment and post-treatment cooling, and effects on wood dimensional stability. European Journal of Wood and Wood Products, 70(1), 183-190.
Bal, B. C. (2015). Physical properties of beech wood thermally modified in hot oil and in hot air at various temperatures. Maderas. Ciencia y tecnología, 17(4), 789-798.
Godinho, D., Araújo, S.D.O., Quilhó, T., Diamantino, T., & Gominho, J. (2021). Thermally modified wood exposed to different weathering conditions: A review. Forests, 12(10), 1400.
Var, A.A., Yalçin, M., Yalçin, Ö.Ü., & Demir, M. (2021). Effects of hot-cold oil treatment on biological resistance and physical properties of Brutia pine sapwood. Maderas. Ciencia y tecnología, 23, 42, 1-12.
Bak, M. and Nemeth, M., 2012. (2012). Modification of wood by oil heat treatment. In International Scientific Conference March, 52(2), 63-70.
BS EN 927-6. (2006). Paints and varnishes. Coating materials and coating systems for exterior wood Exposure of wood coatings to artificial weathering using fluorescent UV lamps and water.
Roux, M.L., & Podgorski, L. (2000). The advantages of having in the future a European accelerated weathering test for wood finishes. Surface Coatings International, 83(8): 399-403.
Mastouri, A., Efhamisisi, D., Shirmohammadli, Y., & Oladi, R. (2021). Physicochemical properties of thermally treated poplar wood in silicone and rapeseed oils: A comparative study. Journal of Building Engineering, 43, 102511.
ISO 13061-13. (2016). Physical and mechanical properties of wood — Test methods for small clear wood specimens — Part 13: Determination of radial and tangential shrinkage
ISO 13061-2. (2013). Physical and mechanical properties of wood — Test methods for small clear wood specimens — Part 2: Determination of density for physical and mechanical tests
Pockrandt, M., Jebrane, M., Cuccui, I., Allegretti, O., Uetimane Jr, E., & Terziev, N. (2018). Industrial Thermowood® and Termovuoto thermal modification of two hardwoods from Mozambique. Holzforschung, 72(8), 701-709.
Sidorova, K. (2008). Oil Heat Treatment of Wood. In Proceedings of the 7th Meeting of the Nordic-Baltic Network in Wood Material Science and Engineering (WSE), 27–28 October 2011, Oslo, Norway.
Mohebby, B., Kevily, H., & Kazemi-Najafi, S. (2014). Oleothermal modification of fir wood with a combination of soybean oil and maleic anhydride and its effects on physico-mechanical properties of treated wood. Wood Science and Technology, 48(4), 797-809.
Abde, M. R., Mootab Saei, A., Mohebby, B., & Kazemi-Najafi, S. (2015). Influence of Temperature and Holding Time in Oil Heat Treatment on Physical and Mechanical Properties of Fir Wood (Abies Sp.). Forest and Wood Products, 68(2), 303-315.
Esteves, B., Graca, J., & Pereira, H. (2008). Extractive composition and summative chemical analysis of thermally treated eucalypt wood. Holzforschung, 62(3), 344-351.
Abedini, R., Gorji. M., (2020). Effect of different oil heat treatment conditions on chemical structure and physical properties of wingnut (Pterocarya fraxinifolia) wood. Iranian Journal of Wood and Paper Industries, 11(2), 199-209.
Suri, I.F., Purusatama, B.D., Kim, J.H., Yang, G.U., Prasetia, D., Kwon, G.J., Hidayat, W., Lee, S. H., Febrianto, F., Kim, N. H. (2022). Comparison of physical and mechanical properties of Paulownia tomentosa and Pinus koraiensis wood heat-treated in oil and air. European Journal of Wood and Wood Products, 80(6), 1389-1399.
Asadi Khoramabadi, L., Khazaeian, A., Masteri Farahani, M.R., & Shakeri, A. (2014). Effect of HeatTreatment with Modified Soybean Oil on Mechanical Properties of Beech. Iranian Journal of Wood and Paper Science Research, 29(2), 208-219.
Scheiding, W., Direske, M., & Zauer, M. (2016). Water absorption of untreated and thermally modified sapwood and heartwood of Pinus sylvestrisEuropean Journal of Wood and Wood Products, 72(4), 585-589.
Jämsä, S., & Viitaniemi, P. (2001). Heat treatment of wood–Better durability without chemicals. In Proceedings of special seminar held in Antibes, France, pp 1-66.
Bazyar, B. (2012). Decay resistance and physical properties of oil heat treated aspen wood. BioResources, 7(1): 696-705. http://dx.doi.org/10.15376/biores.7.1.696-705
Kamdem D., & Pizzi, A. (2002). Jermannaud, Durability of heat-treated wood. Holz als Roh-und Werkstoff, 60(1), 1-6.
Suri, I. F., Purusatama, B.D., Kim, J. H., Hidayat, W., Iswanto, A. H., Park, S. Y., Lee, S., Kim, N.H. (2023). Artificial Weathering Effects on the Physical and Chemical Properties of Paulownia tomentosa and Pinus koraiensis Woods Heat-Treated in Oil and Air. Forests, 14(8), 1546.
Yildiz, S., Tomak, E. D., Yildiz, U. C., & Ustaomer, D. (2013). Effect of artificial weathering on the properties of heat treated wood. Polymer Degradation and Stability, 98(8), 1419-1427.
Yildiz, S., Yildiz, U.C., & Tomak, E.D. (2011). The effects of natural weathering on the properties of heat-treated alder wood. BioResources, 6(3).
Nemeth, R., Tolvaj, L., Bak, M., & Alpar, T. (2016). Colour stability of oil-heat treated black locust and poplar wood during short-term UV radiation. Journal of Photochemistry and Photobiology A: Chemistry, 329, 287-292.
Tolvaj, L., Nemeth, R., Pasztory, Z., Bejo, L., & Takats, P. (2014). Colour stability of thermally modified wood during short-term photodegradation. BioResources, 9(4), 6644-6651.
Cui, X., & Matsumura, J. (2019). Wood surface changes of heat-treated Cunninghamia lanceolate following natural weathering. Forests, 10(9): 791.
Pelosi, C., Agresti, G., Lanteri, L., Picchio, R., Gennari, E., & Lo Monaco, A. (2020). Artificial weathering effect on surface of heat-treated wood of Ayous (Triplochiton scleroxylon Shum). Environmental Sciences Proceedings, 3(1), 15.
Kocaefe, Kocaefe, D., Poncsak, S., Dor, G. V., & Younsi, R. (2008). Effect of heat treatment on the wettability of white ash and soft maple by water. Holz als roh-und werkstoff, 66(5), 355-361
Huang, X., Kocaefe, D., Kocaefe, Y., Boluk, Y., & Pichette, A. (2012). Changes in wettability of heat-treated wood due to artificial weathering. Wood Science and Technology, 46(6), 1215-1223.
Jirouš-Rajković, V., & Miklečić, J. (2017). Weathering resistance of modified wood-a review. Godišnjak Akademije tehničkih znanosti Hrvatske, 1, 223-246.
Mastouri, A., Efhamisisi, D., Tarmian, A., Boukherroub, R., Lexa, M., Karami, E., Panek, M., and Frigione, M. (2024). Sustainable superhydrophobic and self-cleaning wood via wax within Epoxy/PDMS nano-composite coatings: Durability related to surface morphology. Progress in Organic Coatings, 186” 107951.
Okon, K. E., Lin, F., Chen, Y., & Huang, B. (2017). Effect of silicone oil heat treatment on the chemical composition, cellulose crystalline structure and contact angle of Chinese parasol wood. Carbohydrate Polymers, 164” 179-185
Poletto, M., Zattera, A. J., & Santana, R.M. (2012). Structural differences between wood species: Evidence from chemical composition, FTIR spectroscopy, and thermogravimetric analysis. Journal of Applied Polymer Science, 126(S1)” E337-E344.
Yue, K., Qian, J., Wu, P., Jiao, X., Lu, D., & Song, X. (2023). Experimental analysis of thermally-treated Chinese poplar wood with focus on structural application. Industrial Crops and Products, 197, 116612.
He, L., Zhang, T., Zhao, X., Zhao, Y., Xu, K., He, Z., & Yi, S. (2023). Synergistic effect of tung oil and heat treatment on surface characteristics and dimensional stability of wood. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 665, 131233.
Esteves, B., Marques, A.V., Domingos, I., Pereira, H. (2013). Chemical changes of heat treated pine and eucalypt wood monitored by FTIR. Maderas. Cienc y tecnología 15(2), 245-258.
Hao, X., Wang, Q., Wang, Y., Han, X.,Yuan, C. L.,Cao, Y.,Lou, Z., & Li, Y. (2021). The effect of oil heat treatment on biological, mechanical and physical properties of bamboo. Journal of Wood Science, 67(1), 1-14.
Pandey, K. K. (1999). A study of chemical structure of soft and hardwood and wood polymers by FTIR spectroscopy. Journal of Applied Polymer Science, 71(12), 1969-1975.
Tarmian, A., & Mastouri, A. (2018). Changes in moisture exclusion efficiency and crystallinity of thermally modified wood with aging. iForest-Biogeosciences and Forestry, 12(1), 92-97.
Colom, X., Carrillo, F., Nogués, F., & Garriga, P. (2003). Structural analysis of photodegraded wood by means of FTIR spectroscopy. Polymer Degradation and Stability, 80(3), 543-549.
Lim, S. Y., Abdul Mutalib, M. S., Khaza’ai, H., & Chang, S.K. (2018). Detection of fresh palm oil adulteration with recycled cooking oil using fatty acid composition and FTIR spectral analysis. International Journal of Food Properties, 21(1), 2428-2451.
Temiz, A., Terziev, N., Eikenes, M., & Hafren, J. (2007). Effect of accelerated weathering on surface chemistry of modified wood. Applied Surface Science, 253(12), 5355-5362.
Xing, D., Wang, S., & Li, J. (2015). Effect of artificial weathering on the properties of industrial-scale thermally modified wood. BioResources, 10(4), 8238-8252.
Bessala, L. F. B., Gao, J., He, Z., Wang, Z., & Yi, S. (2023). Effects of heat treatment on color, dimensional stability, hygroscopicity and chemical structure of Afrormosia and Newtonia wood: A comparative study of air and palm oil medium. Polymers, 15(3), 774.
Mburu, F., Dumarcay, S., Huber, F., Petrissans, M., & Gerardin, P. )2007(. Evaluation of thermally modified Grevillarobusta heartwood as an alternative to shortage of wood resource in Kenya: Characterisation of physicochemical properties and improvement of bio-resistance. Bioresource Technology, 98(18), 3478-3486.
Anderson, E. L., Pawlak, Z., Owen, N. L., & Feist, W. C. (1991). Infrared studies of wood weathering. Part I: Softwoods. Applied Spectroscopy, 45(4), 641-647.
Mastouri, A., Azadfallah, M., Rezaei, F., Tarmian, A., Efhamisisi, D., Mahmoudkia, M., & Corcione, C. E. (2023). Kinetic studies on photo-degradation of thermally-treated spruce wood during natural weathering: Surface performance, lignin and cellulose crystallinity. Construction and Building Materials, 392, 131923.
Tomak, E.D., Ustaomer, D., Ermeydan, M.A., & Yildiz, S. (2018). An investigation of surface properties of thermally modified wood during natural weathering for 48 months. Measurement, 127, 187-197.
Haseli, M., Efhamisisi, D., Abdolkhani, ., & Oladi, R. (2024). Effect of oil heat treatment on weathering resistance of poplar wood. Forest and Wood Products, 77(1), 55-71. doi: 10.22059/jfwp.2024.371195.1279
MLA
Maryam Haseli; Davood Efhamisisi; ِِAli Abdolkhani; Reza Oladi. "Effect of oil heat treatment on weathering resistance of poplar wood". Forest and Wood Products, 77, 1, 2024, 55-71. doi: 10.22059/jfwp.2024.371195.1279
HARVARD
Haseli, M., Efhamisisi, D., Abdolkhani, ., Oladi, R. (2024). 'Effect of oil heat treatment on weathering resistance of poplar wood', Forest and Wood Products, 77(1), pp. 55-71. doi: 10.22059/jfwp.2024.371195.1279
VANCOUVER
Haseli, M., Efhamisisi, D., Abdolkhani, ., Oladi, R. Effect of oil heat treatment on weathering resistance of poplar wood. Forest and Wood Products, 2024; 77(1): 55-71. doi: 10.22059/jfwp.2024.371195.1279
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