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Danielsson, Henrik
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Publications (9/9 displayed)
- 2024Impact of Acetylation on the Behaviour of Single-Dowel Timber Connections
- 2023Experimental Testing and Numerical Evaluation of the Strain-softening Behavior of Birch Using a Cross-validation Calibration Approach
- 2021Moisture-dependency of the fracture energy of woodcitations
- 2021Moisture-dependency of the fracture energy of wood : A comparison of unmodified and acetylated Scots pine and birchcitations
- 2020Fracture characteristics of acetylated young Scots pinecitations
- 2017Strength and stiffness of cross laminated timber at in-plane beam loading
- 2016Fracture analysis of perpendicular to grain loaded dowel-type connections using a 3D cohesive zone modelcitations
- 2014Fracture analysis of glued laminated timber beams with a hole using a 3D cohesive zone modelcitations
- 2013A three dimensional plasticity model for perpendicular to grain cohesive fracture in woodcitations
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article
Moisture-dependency of the fracture energy of wood
Abstract
<p>The moisture-dependency of the fracture energy for unmodified and acetylated Scots pine (Pinus sylvestris L.) and birch (Betula pendula Roth) has been investigated. Specimens were conditioned at relative humidity levels of 20, 75, and 97%, as well as dry and water-saturated. At moisture contents below 15%, the fracture energy increased with increasing moisture content for both unmodified and acetylated wood, while it decreased for untreated wood at higher moisture contents. A significant difference in moisture-dependency was found, indicating higher fracture energy for unmodified wood compared to acetylated wood at similar moisture contents. Additionally, to assess the impact of the increased brittleness for structural applications, the fracture energy was compared at equal relative humidity levels. The largest difference was seen at 75% relative humidity with approximately 50% lower fracture energy for acetylated wood. No significant differences were found for water-saturated samples. The moisture-dependency of the fracture energy, combined with the reduced hygroscopicity of acetylated wood, is suggested to be one, but not the only, contributing factor to the lower fracture energy of acetylated wood compared to unmodified wood at equal humidity levels. These observations have importance for structural design since design codes often assess material parameters based on ambient humidity. </p>