This study investigates the dimensional stability and mechanical properties of plywood boards made of thermally modified and unmodified beech veneers that have undergone plasma pre-treatment before melamine resin impregnation. The water and melamine resin uptake and resulting weight percent gain of the veneers were investigated, whereby the air plasma pre-treated veneers showed improved liquid uptake. Five-layer plywood boards were then manufactured and tested for their dimensional stability, compressive strength, bending strength, and tensile strength. Plywood boards made of thermally modified and plasma pre-treated veneers showed a significantly improved dimensional stability, along with small influences on their mechanical properties.
Treating wood with water-soluble resins is a well-known and effective method to improve the durability of wood. However, there has been no systematic work to date related to the influence of average molecular size of phenol-formaldehyde (PF) resin on the decay resistance of wood, especially of hardwoods. Therefore, the goal of this study was to investigate the effect of average molecular size of PF resin treatment on the resistance of beech wood against brown- and white-rot fungi. Four different average molecular weights (Mw) of resol type resin oligomers (297, 421, 655 and 854 g/mol) were examined. Different weight percent gains (WPGs) in European beech (Fagus sylvatica) wood blocks (15 × 20 × 50 mm3) were attained through vacuum impregnation using various concentrations of aqueous-PF solutions. Afterwards treated wood blocks passed the leaching and were exposed to brown-rot fungi (Gloeophyllum trabeum; Coniophora puteana) and white-rot fungi (Trametes versicolor) for 16 weeks. No effect of oligomer size on the resistance against G. trabeum decay of wood blocks was observed, resulting in resin loadings of 7–8%. The required WPG for resistance to brown-rot decay by C. puteana increased slightly with increasing oligomer molecular size: 6, 7, 10 and 11% for wood treated with 297, 421, 655 and 854 g/mol, respectively. The extent of white-rot fungal decay resistance of treated wood was affected by the molecular size of oligomers. Resin loadings of 8% and of 17% against T. versicolor were required to attain similar durability levels for beech wood treated with Mw = 297 and 854 g/mol, respectively.
The sorption and desorption of water within the cell wall of wood lead to swelling and shrinkage. Severe stresses occur under varying climatic conditions and damage of the wood structure can result, which eventually causes face checking and pronounced deterioration. Generally, high moisture contents lead to degradation of the wood by basidiomycetes. To protect wood and wood products against these corrupting influences, the modification of the wooden cell wall to inhibit the water uptake, is the best way to provide dimensional stability and durability. In this work rotary cut beech (Fagus sylvatica L.) veneers, 3.7 mm and 2.1 mm thick, were treated in with low molecular weight phenol formaldehyde in aqueous solution. The process contained a two-step impregnation, within a vacuum was followed by atmospheric or over-pressure and a pre-drying. The final curing took place while gluing the veneers in a heated press to form a laminated veneer lumber (LVL) of eight layers resp. 15 layers. It was the aim of the treatment to decrease the water uptake and the extent of dimensional changes by incorporating the phenol formaldehyde resin inside the cell wall and to achieve a permanent bulking. The used resins were water-soluble alkaline types. Related to the used PFconcentration in solution, medium, middle and high dry weight gains were achieved. The fixation was proven in a leaching test according to EN84 with an initial water impregnation under vacuum and with that a dimensional stability that was reached by the modification was found. The swelling in radial direction was reduced by 57% at moderate WPG and was fully eliminated at highest WPG. The durability of the LVL against white rot fungi has been tested for 16 weeks according to the standard ENV 12038. This test revealed that the mass loss had been decreased to almost 1% by the PF-treatment. Because the moisture content of the samples was above the fibre saturation point, fungal growth had been possible, by the way no constrains of fungal growth could be observed. As it is known that cell wall modification has an influence on the mechanical properties of wood, the modulus of rupture (MOR), modulus of elasticity (MOE) and impact bending strength have been assessed. It came out that the MOR and MOE can be increased by the modification and the pressing regime. Concerning the impact bending strength the energy that was absorbed by sample during the test was considerably lower. The weathering performance was tested both in a self-created lab test for LVL and in a field test. Both tests showed that weathering stability can be achieved, but under consideration of economical aspects, a coating is seen to be beneficial. Furthermore, an in-ground test over two years appears the modified LVL to be resistant against soft rot. It can be concluded that an appropriate process exists to produce LVL from the PF modified beech veneers, which is highly durable against white rot fungus Trametes versicolor, dimensional stable, weatherproof, usable in ground contact and with adequate mechanic...
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