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Abstract
This study shows how the air permeability of thermally modified wood contributes to its water-repellent efficiency. For this purpose, freshly cut boards of hornbeam (Carpinus betulus), poplar (Populus nigra), and heartwood of oak (Quercus castanifolia) were modified at a steam temperature of 180 °C for 3 h inside a ThermoWood kiln. The porous structure, permeability, and water uptake of wood were affected differently by thermal modification, depending on the wood species. The creation of micro-cracks in the cell walls, due to collapsing of fiber cells, resulted in a noticeable increase in the permeability of hornbeam. Despite checking in the poplar wood structure, its permeability was negatively affected by thermal modification. In contrast to oak and poplar, a negative water-repellent efficiency was observed for the modified hornbeam, caused by an increase in the permeability.
Keywords
Air permeability
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Thermally modified wood
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Water-repellent efficiency
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Asghar Tarmian, Akbar Mastouri.
Water-repellent efficiency of thermally modified wood as affected by its permeability.
Journal of Forestry Research, 2017, 29(3): 859-867 DOI:10.1007/s11676-017-0495-3
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