Thermally modified wood

Thermally modified wood is engineered wood that has been modified by a controlled pyrolysis process of wood being heated to (> 180 °C) in an oxygen free atmosphere. This process changes to the chemical structures of wood's cell wall components lignin, cellulose and hemicellulose which decreases its hygroscopy and thus increases dimensional stability.[1] Low oxygen content prevents the wood from burning at these high temperatures. Several different technologies use different media including nitrogen gas, steam and hot oil. All processes degrade strength and toughness of the treated lumber to some degree.

Beechwood processed at different temperatures. From left to right: 200 °C, 190 °C, untreated
comparison European Ash, left= untreated, right= thermally modified
wood surface, thermally modified European Ash wood

Modification processes

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In 1946 the US Forest Service conducted partially successful experiments by submersing wood in a liquid metal alloy (zinc, lead and cadmium) to produce a heat stabilized product (proposed to be named staybwood) and concluded:

"An appreciable degree of dimensional stabilization and decay resistance can be imparted to wood by dry heat, This can be accomplished over a broad range of temperatures and times, the time of heating decreasing rapidly with an increase in temperature,
This heat treatment causes a serious loss in strength properties, especially toughness and abrasion resistance. When the wood is heated beneath the surface of a molten metal the strength loss for any antishrink efficiency is less than when heated in air. The strength loss is still too great to make this a commercially applicable method for obtaining dimensional stabilization of wood, except perhaps for some abnormal use where strength is of relatively little importance."[2]

A process of thermal modification of pressurized wood with a medium moisture content was described in a paper by Burmester in 1973.[3]

Todey there are five different thermal modification processes. Finland produced Thermowood also known as Premium wood. France uses the Les Bois Perdure Retification process, the Netherlands uses the Plato process while Germany uses Oil-heat treatment. Westwood Process and the AlphaInterloc processes are proprietary process technologies in USA.[1]

Description of the process

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Three of the processes are performed in one step, using oil (oil-heat treatment), nitrogen (Reti wood) and steam (Le-Bois Perdure).[1] The Thermo wood process consists of drying, heat treatment and finally cooling/conditioning, and takes up to 72 hours.[4] The Plato process consists of hydrothermolysis, dry curing and conditioning, and can take up to 7 days. The required time depends on wood species, width and initial moisture content.[5]

Westwood Process

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Westwood is the most advanced modern thermo-modification process, patented in 2004. The process has initially developed for treatment hardwoods, which are more complicated compared to softwoods due to thermo-chemical reactions appeared in hardwoods during thermo-treatment. The fully automated Westwood control system allows to manage thermo-treatment of any hardwoods and softwood species.[6]

AlphaInterloc Process

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AlphaInterloc process is an advanced thermo-chemical, Exothermic reaction proprietary process pending and Copyright 2022. This process uses specialized thermo-mechanical process. The AlphaInterloc process is entirely green technology.[7]

 
AlphaInterloc OAK DARK
 
AlphaInterloc Ash Wood processes

Retification

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Retification refers to the French word rétification, which is the portmanteau of réticulation (creation of chemical bonds between polymeric chains) and torréfaction (roasting). Wood in this process must have a moisture content at 12% or lower which can be attained through simple drying processes. The wood is then placed in a high nitrogen atmosphere with no more than 2% oxygen content.[8] The Perdure Process is relatively similar to retification but holds the wood at a lower temperature.[9]

ThermoWood

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This process is similar to the Les Bois Perdure treatment in that it uses a steam environment at atmospheric pressure to treat the wood. However, this process can also be used on "green" wood and was the most widely used commercial process as of 2004.[5][10]

Genuine industrial scale ThermoWood process was developed in Finland in 1990's. The process was patented. ThermoWood is a registered trademark owned by the International ThermoWood Association. The legal right to use the ThermoWood trademark is held by the permanent members] of the association.[11] A new ThermoWood Handbook was published in May 2023.[12]

Characteristics of thermally modified wood

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The main advantage is that softwood can be used for applications that require high durability. Durability class 1–3, according to European Standard EN 350-2, can be obtained out of non durable (class 5) softwood species.[13]

The main disadvantage is that the strength is decreased as a result of the high temperatures. In general the bending strength is reduced up to 30% with more reduction at higher temperatures.[14]

The biological resistance against some (not all) micro-organisms and insects is improved. However, due to breakdown of volatile organic compounds (VOC) the antimicrobial properties of wood may also decrease.[15] Shrinking and swelling is reduced up to 50–90%.[16] The treated wood is somewhat darkened in colour.

As a principle the heat treatment process can be done on all wood species.

Maturity of the technology

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Thermally modified wood is not just an academic topic these days. Thermal wood treatment has already been penetrating the market for a number of years. There is also some industrial input in the research and development. The Natural Resources Research Institute at the University of Minnesota Duluth has a pilot-scale kiln to research the effectiveness of thermal modification on the Minnesota tree species to expand the wood markets.[17]

In the guitar-making industry, this process is called "Thermo Curing", "Baked" and "Roasted", among other names.[18] Some guitar manufacturers have begun using acoustic sound boards and electric guitar fretboards that are thermally cured in order to help prevent the typical warping and cracking that often occurs from seasonal humidity swings.[19] As a secondary benefit, acoustic guitars tend to sound like well-broken-in aged instruments much sooner than do non-thermally modified guitars. See more under Tonewood: Preparation.

 
Alphainterloc exotic wood process

Main companies in the industry

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In Europe thermally modified wood production on a commercial scale has been concentrated largely in Estonia. Estonia is geographically close to the major Finnish producers of thermo-kilns, while labor and overhead costs are lower than in Finland or the Scandinavian countries. Three major Estonian producers of thermally modified wood emerged in the late 1990s: Brenstol OU, Tre-Timber OU and Ha-Serv. All 3 companies focused on providing sauna materials for the Finnish market and interior flooring—Brenstol specializing in hardwoods and Tre-Timber specializing in softwoods. In the early 2000s, Brenstol purchased Tre-Timber, becoming the largest producer of thermally modified wood.[20]

At about that time, the market for thermally modified wood expanded dramatically from its traditional application in sauna materials, to include exterior products, such as decking (terrace)[21] and cladding (siding).[22] While Ha-Serv continued to focus primarily on the Finnish sauna market, Brenstol established the Thermory brand and begin to export across Europe and to Japan and Thermory has become the most widely-recognized brand of thermally modified wood in these regions.[23] The market for thermally modified exterior products increased very rapidly as European consumers increasingly looked for alternatives to tropical woods from Asia, Africa and South America. A Turkish producer, Nova Wood, also started producing of thermally modified wood and became a minor player in European markets.

In 2012, Brenstol established an affiliate in the U.S., Thermory USA and began to expand aggressively in markets around the world. The Thermory brand has become well-established in the U.S. and Canada, and has been shipped to over 55 countries around the world.[24] In 2016, Thermory’s revenue was 29 mln euros, with 1.8 mln euros in profit.[25]

Small, local producers continue to emerge in each region, but there are high barriers to entry into the thermally modified wood market—particularly for thermally modified hardwoods. The proper thermal modification equipment is extremely expensive. In addition, because the technology is not well known, there is little public information available about drying schedules, and many new producers of thermally modified woods experience a large % of drying defects, discoloration, brittleness, equipment malfunctions (including fires) and an inability to obtain the high durability ratings that more established producers, like Brenstol (Thermory), have achieved. In 2018, Thermory purchased Ha-Serv, becoming the market leader in the thermally modified wood segment.[26]

ThermoWood®, a registered trademark of the International ThermoWood® Association |url= https://thermowood.fi/ , is a leading name in thermally modified wood, renowned for its eco-friendly and chemical-free enhancement of durability and dimensional stability. This process is carried out under strict environmental and quality guidelines, providing a premium product for demanding applications like decking, cladding, and furniture. Non-trademarked thermally modified wood employs similar heat treatments to achieve comparable improvements but may vary in process specifics, branding, and market positioning. Pioneer companies like HJT-Holz Oy |url= https://thermoholz.fi/ stands out as a prominent player in this space, offering ThermoWood® products that embody precision and sustainability, reinforcing its reputation as a key industry innovator​​​. HJT-Holz exports mostly it's products to Europe and expanding in the year 2024 toward North American Markets.

The latest research of thermo modification process showed that the coloration of wood during thermo-treatment is not necessary leading to its durability and stability: the reactions which are responsible for changing color during modification are different than reactions which are responsible for durability. Not all brown wood should be considered really thermo-modified.[27]

Ongoing research

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There is ongoing research[28] to optimize the industrial processes and the various parameters to produce it and to develop the applications for this wood. There is also research in order to find new wood heat treatment processes, even trying to combine different wood modification processes.

AlphaInterloc is a company that is doing current process engineering and equipment design in USA North America.[7]

 
AlphaInterloc Pine Processes

See also

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References

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  1. ^ a b c "What is Thermally Modified Wood?". Hardwood Distributors Association. 2015-07-28. Archived from the original on 2019-09-18. Retrieved 2019-09-13.
  2. ^ Alfred Stamm, Horace Burr, Albert Kline: Heat stabilized Wood (Staybwood) (pdf file), No. 1621, revised April 1955, originally published June 1946, Forest Products Laboratory, Forest Service, U.S. Department of Agriculture. In: govinfo.gov
  3. ^ Burmester, A. (1973): Einfluß einer Wärme-Druck Behandlung halbtrockenen Holzes auf seine Formbeständigkeit. Holz als Roh- und Werkstoff 31, pp. 237–243
  4. ^ ThermoWood Handbook. International ThermoWood Association. 2003.
  5. ^ a b "Strength and Colour Response of Solid Wood to Heat Treatment" (PDF). Luleå University of Technology. Archived (PDF) from the original on April 8, 2016. Retrieved April 4, 2016.
  6. ^ "World experience: Thermo-treated Wood". www.westwoodcorporation.com. Archived from the original on 2019-09-19. Retrieved 2019-09-13.
  7. ^ a b "Alpha Interloc". www.alphainterloc.com. Archived from the original on September 24, 2022. Retrieved 14 May 2023.
  8. ^ "Principles & applications of wood retification" (PDF). Thermotreatedwood.com (Georgia, United States). Archived from the original (PDF) on October 19, 2016. Retrieved April 4, 2016.
  9. ^ Gérardin, Philippe (2016-09-01). "New alternatives for wood preservation based on thermal and chemical modification of wood— a review". Annals of Forest Science. 73 (3): 559–570. Bibcode:2016AnFSc..73..559G. doi:10.1007/s13595-015-0531-4. ISSN 1297-966X.
  10. ^ International ThermoWood Association (2003). "ThermoWood Handbook" (PDF). Archived (PDF) from the original on 2023-02-02. Retrieved 2023-06-02.
  11. ^ "Members". International ThermoWood Association. Archived from the original on May 30, 2023. Retrieved June 1, 2023. Members of the International ThermoWood Association are allowed to use the word ThermoWood® and official ITWA logotype. Members co-operate in standardisation, quality control, and research, in order to enhance the use of ThermoWood products.
  12. ^ "ThermoWood Handbook" (PDF). International Thermowood Association. Archived (PDF) from the original on 2023-05-30. Retrieved 2023-06-02.
  13. ^ European Standard EN 350-2 (1994); Durability of Wood and Wood-based Products – Natural Durability of Solid Wood: Guide to natural durability and treatability of selected wood species of importance in Europe
  14. ^ "Recent Development of Thermal Wood Treatments" (PDF). International Association of Wood Products Societies (IAWPS). Archived (PDF) from the original on March 25, 2015. Retrieved January 24, 2016.
  15. ^ Munir, Muhammad Tanveer; Pailhories, Hélène; Eveillard, Matthieu; Irle, Mark; Aviat, Florence; Federighi, Michel; Belloncle, Christophe (24 August 2020). "Experimental Parameters Influence the Observed Antimicrobial Response of Oak Wood (Quercus petraea)". Antibiotics. 9 (9): 535. doi:10.3390/antibiotics9090535. PMC 7558063. PMID 32847132.
  16. ^ "Wood modification developments" (PDF). HERON. Archived (PDF) from the original on March 3, 2016. Retrieved January 24, 2016.
  17. ^ jbrenema (2017-01-26). "NRRI expands markets for modified wood". Natural Resources Research Institute. Archived from the original on 2019-08-29. Retrieved 2019-09-13.
  18. ^ "What is a "Torrefied" Guitar Top? | Gryphon Strings". Gryphon Stringed Instruments. 2017-05-15. Archived from the original on 2021-05-15. Retrieved 2019-09-13.
  19. ^ "Comparison of different techniques of thermal modification, regarding the improvement of acoustical properties of resonant soundboard material Scientific Report by order of Pacific Rim Tonewoods Inc". ResearchGate. Retrieved 2021-08-16.
  20. ^ "Brenstol - Sisustusweb.ee". www.sisustusweb.ee. Archived from the original on 2021-05-15. Retrieved 2019-09-13.
  21. ^ "Thermory in Exterior Design: Decking". Thermory Decking & Cladding. 2019-01-03. Archived from the original on 2021-05-15. Retrieved 2019-09-13.
  22. ^ "Thermory in Exterior Design: Cladding". Thermory Decking & Cladding. 2019-04-23. Archived from the original on 2020-08-11. Retrieved 2019-09-13.
  23. ^ "Thermory takes the traditional timber industry to a new level". Invest in Estonia. 2019-02-15. Archived from the original on 2020-09-30. Retrieved 2019-09-13.
  24. ^ Lupeikiene, Audrone; Vasilecas, Olegas; Dzemyda, Gintautas (2018-08-14). Databases and Information Systems: 13th International Baltic Conference, DB&IS 2018, Trakai, Lithuania, July 1-4, 2018, Proceedings. Springer. ISBN 9783319975719. Archived from the original on 2022-01-31. Retrieved 2023-06-02.
  25. ^ "Thermory 20th anniversary". Thermory Decking & Cladding. 2017-09-27. Archived from the original on 2020-11-01. Retrieved 2019-09-13.
  26. ^ Veske, Kaido (29 October 2018). "Thermory and Ha-Serv merge to become the world's largest producer of thermally modified wood and sauna materials". Livonia Partners. Archived from the original on 27 January 2019. Retrieved 13 September 2019.
  27. ^ Zhang, Nannan; Xu, Min; Cai, Liping (2019-01-30). "Improvement of mechanical, humidity resistance and thermal properties of heat-treated rubber wood by impregnation of SiO2 precursor". Scientific Reports. 9 (1): 982. doi:10.1038/s41598-018-37363-3. ISSN 2045-2322. PMC 6353935. PMID 30700757.
  28. ^ "8th European Conference on Wood Modification October 2015 Helsinki". ECWM 2015. Archived from the original on January 30, 2016. Retrieved January 24, 2016.