Characterization of randomly oriented strand boards manufactured from juvenile wood of underutilized wood species

The wood-based panel industry in Europe, which is dominated by the use of Norway spruce, will face new challenges due to environmental changes and the bark-beetle calamity, which started a new era of forestry. To explore the possibility of replacing spruce with other wood species, juvenile wood of n...

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Bibliographic Details
Published in:European journal of wood and wood products 2024-08, Vol.82 (4), p.927-941
Main Authors: Pipíška, Tomáš, Nociar, Marek, Král, Pavel, Ráheľ, Jozef, Bekhta, Pavlo, Réh, Roman, Krišťák, Ľuboš, Jopek, Miroslav, Pijáková, Barbora, Wimmer, Rupert, Šernek, Milan
Format: Article
Language:English
Subjects:
Bark
Bend strength
Biomedical and Life Sciences
Birch trees
Boards
Bonding strength
Ceramics
Composites
Coniferous trees
Density
Environmental changes
Glass
Hardwoods
Larix decidua
Life Sciences
Machines
Manufacturing
Mechanical properties
Modulus of elasticity
Natural Materials
Original Article
Physical properties
Pine
Pine trees
Poplar
Processes
Slenderness ratio
Species
Statistical analysis
Willow
Wood
Wood Science & Technology
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Summary:The wood-based panel industry in Europe, which is dominated by the use of Norway spruce, will face new challenges due to environmental changes and the bark-beetle calamity, which started a new era of forestry. To explore the possibility of replacing spruce with other wood species, juvenile wood of nine underutilized wood species (Scots pine, European larch, poplar, willow, alder, birch, European beech, English oak and hornbeam) were used to make randomly oriented strand boards (OSBs). Single-layer OSBs were produced with 3% pMDI resin and 0.5% wax. Standard physical and mechanical properties were measured. The bending strength (MOR) values showed that there was no statistically significant difference between the values for, on the one hand, spruce (34.6 MPa) and, on the other, larch (25.9 MPa), poplar (25.2 MPa), willow (27.8 MPa), alder (34.3 MPa) or birch (27.1 MPa). A similar trend was found for the boards modulus of elasticity (MOE). The highest MOE values of 5,185 MPa and 4,472 MPa were found for spruce and alder, respectively. There was no significant difference between spruce and other wood species in internal bond strength. Boards made from high-density wood species showed better physical performance, whereas those made from low-density wood species (except pine) gave better mechanical properties. Strand-generalized characteristics, such as the slenderness ratio and specific surface, were analyzed for all investigated physical and mechanical properties. European larch, poplar, willow, and alder are potential wood species for manufacturing OSBs in future without mixing species, as they can replace spruce in the wood-based panel industry.
ISSN:0018-3768
1436-736X
DOI:10.1007/s00107-024-02080-4