Ukrainian Journal of Forest and Wood Science

Properties of heat-treated ash wood

Olena Pinchevska, Oleksandra Horbachova, Nikolai Bаrdarov, Denys Zavialov, Vladyslav Davydov, Rostislav Oliynyk
Download article
Abstract

Ash wood is characterised by high mechanical and technological properties and has a beautiful texture, which leads to a high demand for furniture and joinery products made from it. However, the widespread and rapid spread of the fungal disease Hymenoscyphus fraxineus (chalar necrosis) and the invasive beetle Agrilus planipennis caused massive dieback of ash trees. All of this led to the transformation of healthy wood during one year into low-quality “deadwood” and limited its use in industry. The objective of the research was to investigate specific properties of ash deadwood subjected to sterilisation through high-temperature treatment using various thermal regimes. To renew its use, it is proposed to use sterilisation without the addition of chemicals by thermal modification at temperatures of 185 °C (schedule 1) and 195 °C (schedule 2), which does not impair the environmental properties of wood.  The physical, mechanical, and technological properties of heat-treated ‘deadwood’ ash and healthy wood dried at a temperature of t ≤ 70 °C were studied. It has been determined that the equilibrium moisture content of heat-treated ‘deadwood’ ash wood decreased by 3.5-4.0% compared to healthy wood; the density at actual moisture and in a completely dry state decreased by 8-12% and by 4-9%, shrinkage in the transverse direction by 53-67%; the bending strength decreased by only 6 % in the case of schedule 1 and by 20% in the case of schedule 2. The static hardness in both the tangential and radial directions had an unexpected trend – an increase of 9-12% when using schedule 1 and a decrease of 1.7-13% when treated by schedule 2. The weight loss of samples of heat-treated ‘deadwood’ ash wood was 60-90% less than the weight loss of healthy wood. The accuracy factor of all experimental studies did not exceed 5%. The results obtained make it possible to effectively choose the use of heat-treated ‘deadwood’ ash wood under schedule 1 in joinery and furniture products, and treated under schedule 2 in furniture products such as tabletops, as there is a decrease in the relevant mechanical properties. The use of both treatment modes allows the use of low-cost ash wood in products that are used outdoors

Keywords

‘deadwood’, heat treatment, physical properties, strength, hardness, biostability

Suggested citation
Pinchevska, О., Horbachova, O., Bаrdarov, N., Zavialov, D., Davydov, V., & Oliynyk, R. (2025). Properties of heat-treated ash wood. Ukrainian Journal of Forest and Wood Science, 16(2), 25-41. https://doi.org/10.31548/forest/2.2025.25
References
  1. Amirou, S., Pizzi, A., & Delmotte, L. (2019). Investigations of mechanical properties and chemical changes occurring during welding of thermally modified ash wood. Journal of Adhesion and Technology, 34(1), 13-24. doi: 10.1080/01694243.2019.1659569.
  2. Appiah-Kubi, O.P., Liu, X., & Wu, Z. (2021). Conservation of wood and restoration of artifacts against wood destroying organisms. International Journal of Natural Resource Ecology and Management, 6(4), 171-175. doi: 10.11648/j.ijnrem.20210604.12.
  3. Brischke, Ch., von Boch-Galhau, N., & Bollmus, S. (2022). Impact of different sterilization techniques and mass loss measurements on the durability of wood against wood-destroying fungi. European Journal of Wood and Wood Products, 80(1), 35-44. doi: 10.1007/s00107-021-01745-8.
  4. Candelier, K., & Dibdiakova, J. (2020). A review on life cycle assessments of thermally modified wood. Holzforschung, 75(3), 199-224. doi: 10.1515/hf-2020-0102.
  5. Coker, T., Rozsypálek, J., Edwards, A., Harwood, T., Butfoy, L., & Buggs, R. (2018). Estimating mortality rates of European ash (Fraxinus excelsior) under the ash dieback (Hymenoscyphus fraxineus) epidemic. Plants, People, Plane, 1(1), 48-58. doi: 10.1002/ppp3.11.
  6. Davies, B. (2017). Ash Dieback: Where are we now? Retrieved from https://www.magogtrust.org.uk/about/updates/ash-dieback-where-are-we-now/
  7. Davydenko, K., Skrylnyk, Y., Borysenko, O., Menkis, A., Vysotska, N., Meshkova, V., Olson, Å., Elfstrand, M., & Vasaitis, R. (2022). Invasion of emerald ash borer Agrilus planipennis and ash dieback pathogen Hymenoscyphus fraxineus in Ukraine – a concerted action. Forests, 13(5), article number 789. doi: 10.3390/f13050789.
  8. DSTU 4922:2008. (2009). Lumber and sawn timber. Methods for determining moisture content. Retrieved from https://online.budstandart.com/ua/catalog/doc-page.html?id_doc=52795.
  9. DSTU EN 408:2007. (2009). Structural timber. Structural and glued laminated timber. Determination of some physical and mechanical properties. Retrieved from https://online.budstandart.com/ua/catalog/doc-page?id_doc=66659.
  10. Herrera-Builes, J.F., Sepúlveda-Villarroel, V., Osorio, J.A., Salvo-Sepúlveda, L., & Ananías, R.A. (2021). Effect of thermal modification treatment on some physical and mechanical properties of Pinus oocarpa wood. Forests, 12(1), article number 249. doi: 10.3390/f12020249.
  11. Hill, C., Altgen, M., & Rautkari, L. (2021). Thermal modification of wood – a review: Chemical changes and hygroscopicity. Journal of Materials Science, 56(11), 6581-6614. doi: 10.1007/s10853-020-05722-z.
  12. ISO 13061-12:2017. (2017). Physical and mechanical properties of wood – test methods for small clear wood specimens – part 12: Determination of static hardness. Retrieved from https://www.iso.org/obp/ui/en/#iso:std:iso:13061:-12:ed-1:v1:en.
  13. ISO 13061-3:2014. (2014). Physical and mechanical properties of wood – test methods for small clear wood specimens – part 3: Determination of ultimate strength in static bending. Retrieved from https://www.iso.org/standard/60065.html.
  14. ISO 4469:1981. (1982). Wood – determination of radial and tangential shrinkage. Retrieved from https://www.iso.org/standard/10364.html.
  15. Jones, D., Sandberg, D., Goli, G., & Todaro, L. (2019). Wood modification in Europe: A state-of-the-art about processes, products and applications. Florence: Florence University Press
  16. Marcon, B., Viguier, J., Candelier, K., Thevenon, M.-F., Butaud, J.-C., Pignolet, L., Gartili, A., Denaud, L., & Collet, R. (2023). Heat treatment of poplar plywood: modifications in physical, mechanical and durability properties. iForest, 16, 1-9. doi: 10.3832/ifor4159-015.
  17. Milić, G., Todorović, N., Veizović, M., & Popadić, R. (2023). Heating rate during thermal modification in steam atmosphere: Influence on the properties of maple and ash wood. Forests, 14(2), article number 189. doi: 10.3390/f14020189.
  18. Mitchell, P. (2018). Calculating the equilibrium moisture content for wood based on humidity measurements. BioResources, 13(1), 171-175. doi: 10.15376/biores.13.1.171-175.
  19. Moliński, W., Roszyk, E., Jabloński, A., Puszyński, J., & Cegiela, J. (2016). Mechanical parameters of thermally modified ash wood determined by compression in radial direction. Maderas. Ciencia y Tecnología, 18(4), 577-586. doi: 10.4067/S0718-221X2016005000050.
  20. Nhacila, F., Sitoe, E., Uetimane Jr., E., Manhica, A., Egas, A., & Möttönen, V. (2020). Effects of thermal modification on physical and mechanical properties of Mozambican Brachystegia spiciformis and Julbernardia globiflora wood. European Journal of Wood and Wood Products, 78(2), 871-878. doi: 10.1007/s00107-020-01576-z.
  21. Paes, J.B., Brocco, V.F., Loiola, P.L., Silva, M.R., & Juizo, C.G.F. (2021). Effect of thermal modification on decay resistance of Corymbia citriodora and Pinus taeda wood. Journal of Tropical Forest Science, 33(2), 185-190. doi: 10.26525/jtfs2021.33.2.185.
  22. Pinchevska, O., Sedliačik, J., Horbachova, O., Spirochkin, A., & Rohovskyi, I. (2019). Properties of hornbeam (Carpinus betulus) wood thermally treated under different conditions. Acta Facultatis Xylologiae Zvolen, 61(2), 25-39. doi: 10.17423/afx.2019.61.2.03.
  23. Pinchevska, O., Horbachova, A., Zavyalov, D., Baranova, O., Holovach, I., & Romasevych, Y. (2022). Use of dead oak wood in furniture products. Ukrainian Journal of Forest and Wood Science,20, 13(1), 25-32. doi: 10.31548/forest.13(1).2022.25-32.36.
  24. Pleschberger, H., Teischinger, A., Müller, U., & Hansmann, C. (2014). Change in fracturing and colouring of solid spruce and ash wood after thermal modification. Wood Material Science & Engineering, 9(2), 92-101. doi: 10.1080/17480272.2014.895418.
  25. Pugovytsia, M. (2020). Ash trees: To be or not to be? Retrieved from https://lisozahyst.at.ua/news/jaseni_buti_chi_ne_buti/2020-12-29-135.
  26. Pyvovarov, A. (2024). Phytosanitary measures for wood packaging material. Retrieved from https://zakon.rada.gov.ua/laws/show/z0969-24#Text.
  27. Scheiding, W., Ala-Viikari, J., & Tetri, T. (2022). Thermal wood modification after 20 years of commercialization: An overview and the ThermoWood® story. In Proceedings of the Tenth European Conference on Wood Modification (pp. 11-22). Nancy: European Conference on Wood Modification.
  28. Sirko, Z.S., Vashchenko, V.V., Protasov, O.S., Bondarenko, O.P., Tsapko, Yu.V., & Tsapko, O.Yu. (2024). Bio-protective treatment of wood. Scientific Bulletin of Construction, 110, 77-82. doi: 10.33042/2311-7257.2024.110.1.11.
  29. UNE EN 113-1:2021. (2021). Durability of wood and wood-based products – Test method against wood destroying basidiomycetes – part 1: Assessment of biocidal efficacy of wood preservatives. Retrieved from https://www.en-standard.eu/une-en-113-1-2021-durability-of-wood-and-wood-based-products-test-method-against-wood-destroying-basidiomycetes-part-1-assessment-of-biocidal-efficacy-of-wood-preservatives/.
  30. UNE EN 113-2:2021. (2021). Durability of wood and wood-based products – test method against wood destroying basidiomycetes – part 2: Assessment of inherent or enhanced durability. Retrieved from https://www.en-standard.eu/une-en-113-2-2021-durability-of-wood-and-wood-based-products-test-method-against-wood-destroying-basidiomycetes-part-2-assessment-of-inherent-or-enhanced-durability/.
  31. Xu, J., Zhang, Y., Shen, Y., Li, C., Wang, Y., Ma, Z., & Wei, S. (2019). New perspective on wood thermal modification: Relevance between the evolution of chemical structure and physical-mechanical properties, and online analysis of release of VOCs. Polymers, 11(7), article number 1145. doi: 10.3390/polym11071145.
  32. Zhang, S.Y., Ren, H., & Jiang, Z. (2021). Wood density and wood shrinkage in relation to initial spacing and tree growth in black spruce (Picea mariana). Journal of Wood Science, 67(1), article number 30. doi: 10.1186/s10086-021-01965-9.