Abstract
This article presents the possibilities of decreasing moisture sorption properties via thermal modification of Norway spruce wood in musical instruments. The 202 resonance wood specimens that were used to produce piano soundboards have been conditioned and divided into three density groups. The first specimen group had natural untreated properties, the second was thermally treated at 180 °C, and the third group was treated at 200 °C. All specimens were isothermally conditioned at 20 °C with relative humidity values of 40, 60, and 80%. The equilibrium moisture content (EMC), swelling, and acoustical properties, such as the longitudinal dynamic modulus (E’L), bending dynamic modulus (Eb), damping coefficient (tan δ), acoustic conversion efficiency (ACEL), and relative acoustic conversion efficiency (RACEL) were evaluated on every moisture content level. Treatment at 180 °C caused the EMC to decrease by 36% and the volume swelling to decrease by 9.9%. Treatment at 200 °C decreased the EMC by 42% and the swelling by 39.6%. The 180 °C treatment decreased the value of the longitudinal sound velocity by 1.6%, whereas the treatment at 200 °C increased the velocity by 2.1%. The acoustical properties EL′, Eb, ACEL, and RACEL were lower due to the higher moisture content of the samples, and only the tanδ increased. Although both treatments significantly affected the swelling and EMC, the treatment at 180 °C did not significantly affect the acoustical properties.
Highlights
Wood is commonly used to make musical instruments across the world, and until today, there has been no available substitute for this superb material
High-quality resonance wood for soundboards is characterized by high sound velocity in a longitudinal direction, low internal friction, relatively low density, high radiation ratio, and a dynamic modulus or specific
All specimens in any direction αi (w)—the same The dimension bewhere, αimax—dimension were climatized at a temperature of 20 ◦ Cafter andswelling; an air humidity of 60%
Summary
Wood is commonly used to make musical instruments across the world, and until today, there has been no available substitute for this superb material. The raised temperature acts as a reaction catalyst This process prevents humidity absorption, it increases density, which decreases the acoustic conversion efficiency (ACEL ) and relative acoustic conversion efficiency (RACEL ) [6,7]. Saligenin treatment or nano-solution SurfaPoreTM improve the water-related properties and have an insignificant effect on the wood density [12,13]. These treatments are potentially suitable for the soundboard properties; they are technically and economically unavailable in piano production. The present study aims to find a way to decrease hygroscopicity and swelling of the piano soundboard wood, focusing on sustainability and maintaining its acoustical properties
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