Abstract
Previous studies have shown that thermally modified wood (TMW) performs well in outdoor, above-ground conditions in terms of resistance to wood-decaying fungi. Yet, little is known about the development of defects such as checks and the corresponding mechanical properties of TMW in this condition. This experiment focused on the effect of 30 months outdoor above-ground exposure (weathering) on the degree of checking, dynamic stiffness and static bending properties of thermally modified timber (TMT) of Norway spruce. Two board pairs per log were cut from 190 logs; one board of each pair was thermally modified and the other used as control. Then, 90 board pairs were exposed to the weather in south Sweden. Surface checking and axial stiffness were monitored at six-month intervals by using digital photography and non-destructive tests (time-of-flight and resonance method) to monitor changes in the material upon weathering. Finally, all boards were tested destructively in a 4-point static bending test following EN 408 standard. Results showed that weathering had no significance influence on static bending properties of TMT even though the degree of checking was considerably higher in TMT than unmodified timber after weathering. In particular, checks along growth rings were deeper, longer and more common in TMT after weathering, especially on the pith side of boards. The maximum depth of these checks did not depend on board orientation (i.e., which side was exposed) and exceeded limits given in strength grading standards for 7% of the modified boards included. Axial dynamic stiffness determined at 6-month intervals was less influenced by fluctuations in moisture content for TMT compared to unmodified timber, but did not confirm the increase in the degree of checking of TMT. The presence of checks from weathering did influence failure modes in TMT; horizontal shear failure became more frequent and some boards failed in compression.
Highlights
Thermal modification would prolong the service life of wood in outdoor applications, because its biological durability and dimensional stability are improved by a decrease in hygroscopicity after modification [1,2]
The total production capacity of thermally modified wood (TMW) was estimated at 300,000 m3 in 2015 of which roughly half was modified according to the ThermoWood® process [3,5]
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Summary
Thermal modification would prolong the service life of wood in outdoor applications, because its biological durability and dimensional stability are improved by a decrease in hygroscopicity after modification [1,2]. During the thermal modification process, wood is heated up to a target temperature of 160–240 ◦ C that is maintained for a few hours while oxygen levels are kept low. Compared to other wood modification technologies, thermally modified wood (TMW) is available in largest volumes and at the lowest cost [3,4]. The total production capacity of TMW was estimated at 300,000 m3 in 2015 of which roughly half was modified according to the ThermoWood® process [3,5]. In 2019, the total production of ThermoWood® was slightly over 220,000 m3 [5]. The softwood species spruce (Picea abies [L.] Karst.) and pine (Pinus sylvestris L.) are primarily used for thermal modification, and TMW
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