Initial Desorption of Reaction Beech Wood

The research aimed to obtain empirical data for modeling the initial desorption in reaction wood from the cross-section of the green beech (Fagus sylvatica L.) log. Firstly, we analyzed the chemical composition, macro and microscopic structure of tension wood tension and opposite wood tissue. Then, the Equilibrium Moisture Content (EMC) was measured by the Dynamic Vapor Sorption method during the initial desorption. The used air parameters were specific for the mild drying schedule of green beech timber (t = 20, 35, and 50 degrees C, Relative Humidity (RH) ranging from 95 to 0 %). Relationships between the EMC of reaction wood and drying parameters were modeled using the Response Surface Method (RSM). The tests revealed: different hygroscopic properties of tension and opposite wood, the dependence of EMC value on temperature, and differences between EMC values for initial (first) and second desorption. Moreover, it was confirmed that, during initial desorption, the EMCs of reaction wood are significantly higher than reference EMC data. The differences in the EMC value are up to 0.14 kg/kg (for air with RH above 90 %). The presented polynomial model of the initial desorption of reaction beech wood can improve drying schedules for beech sawn timber with a high amount of reaction tissue.

Automated summary

This research aimed to obtain empirical data on the initial desorption in reaction wood from the cross-section of green beech logs. The study analyzed the chemical composition and structure of tension wood and opposite wood tissue, and measured the Equilibrium Moisture Content (EMC) during the initial desorption. The results showed differences in hygroscopic properties between tension wood and opposite wood, and the dependence of EMC value on temperature. Additionally, a polynomial model for the initial desorption of reaction beech wood was proposed.