Effects of short-term thermomechanical densification on the structure and properties of wood veneers

The effects of short-term thermomechanical (STTM) densification temperature and pressure on the changes in surface roughness, wettability, mass loss (ML), thickness and density of alder, beech, birch, and pine wood veneer with low moisture content (~5%) were investigated. The anatomical structure of veneers was also observed. Veneer sheets were densified using pressure levels of 4, 8 and 12 MPa at three temperatures: 100°C, 150°C and 200°C for 4 min. The results were compared with those of the non-densified veneers. The obtained results show that STTM densification of veneers similarly to long-term densification of solid wood causes irreversible changes in their properties. The STTM-densified veneer surfaces became smoother and more hydrophobic, ML increased slightly while roughness and thickness values decreased significantly, the cell lumens collapsed and a certain amount of fractures in cell walls developed with increasing densification temperature and pressure. All of the investigated wood species showed higher density values after densification. It was found that an even STTM densification of veneers provides stable properties under normal atmosphere conditions; in particular, the thickness and contact angle values were stable for 24 hours after densification, which is an important consideration for industrial applications.     

Effect of thermomechanical densification on surface roughness of wood veneers

The effect of short-term thermomechanical densification of veneer on the surface roughness and surface anatomical changes in four wood species – alder (Alnus glutinosa Gaertn.), beech (Fagus sylvatica L.), birch (Betula verrucosa Ehrh.), and pine (Pinus sylvestris L.) – was studied. Veneer sheets were densified at a temperature of 100, 150, or 200°C and at a pressure of 4, 8, or 12 MPa for 4 minutes. Seven roughness parameters such as R_a, R_z, R_q, R_p, R_v, R_sk, and R_ku were determined. Profile surface was recorded using a modified Carl Zeiss ME-10 profile gauging profilometer. Surface anatomical changes of veneer were examined using scanning electron microscopy. The results showed that densification temperature and pressure affect surface roughness of veneer. The surface became smoother, and roughness values decreased significantly (except for R_ku which increased slightly) with increasing temperature and pressure of densification. The effect of temperature on surface roughness changes is more pronounced compared with that of densification pressure. The lowest values of surface roughness were recorded for pine veneer samples followed by alder, birch, and beech samples. These results can be used to provide initial data for adhesive application processes in woodworking industry.     

Standardized processes of biomass briquetting densification fuel

Forest biomass resources are available in enormous quantities in China.The development of forest biomass briquetting densification fuel,which has a high calorific value,can ease the energy shortage in China.But the molding technology is still at the primary stage with many questions unresolved,such as unequal distribution of resources,imperfect technology and an inadequate mechanism of market supply and demand.There are no consistent production and quality standards to refer to,which seriously hinder the industrialization of biomass molding technology.Hence,it is imperative to speed up the formulation of production standards of biomass briquetting densification fuel which not only conform to international standards,but are in accordance with national conditions in China.Drawing on the standards of biomass briquetting densification fuel in Europe,a standard system should be concerned with raw material collection,transport and storage of the end products,terminology,denomination and classification of molding equipment,as well as with technical conditions,testing methods,safety and environmental protection.The establishment of a standard system is useful for the development of a healthy,orderly and sustainable biomass fuel industry.