Estimation of Scots pine bark biomass delivered to the wood industry in Northern Germany
Author:
Berendt Ferréol12, Bajalan Iman13, Wenig Charlett4, Hinds Charlotte1, Blaško Ľubomír15, Cremer Tobias1
Affiliation:
1. 1 Eberswalde University for Sustainable Development , Department of Forest Utilization and Timber Market , Eberswalde , Germany 2. 2 State Enterprise for Forestry and Timber, North Rhine-Westphalia, Forest Education Center , Arnsberg , Germany 3. 3 Eberswalde University for Sustainable Development , Department for GIS and Remote Sensing , D-16225 Eberswalde , Germany 4. 4 Max Planck Institute of Colloids and Interfaces , Department of Biomaterials , Potsdam , Germany 5. 5 Technical University in Zvolen , Department of Forest Harvesting, Logistics and Amelioration , Zvolen , Slovak Republic
Abstract
Abstract
Scots pine (Pinus sylvestris L.) is the most widely distributed pine species in the world. In Germany, as in many other European countries, it is a very important species both culturally and economically. Few studies have focused on bark volumes being delivered to the wood industry together with the roundwood, being potentially a valuable resource for material or energetic utilization. Therefore, logs from six different forest sites were collected and bark variables including double bark thickness (DBT) in three different categories, diameter, and bark damage (as a degree of miss-DBT) in three different categories, diameter, and bark damage (as a degree of missing bark) were measured and analyzed in order to model bark volume (Vbark) and bark mass (Mbark). The correlation analysis using Pearson’s method showed that the highest correlation coefficients were observed from the correlation between DBT and Vbark, as well as between DBT and Mbark. Also, results demonstrated that with DBT greater than 20 mm, the percentage of Vbark exceeded 20%. Finally, different linear regression models were recommended to predict Vbark and Mbark based on the other variables. The results of this study can be used in different wood industries in order to predict bark volume and bark mass of e.g. truckloads or roundwood stacks.
Publisher
Walter de Gruyter GmbH
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