Wood biomass supply costs and potential for biomass energy plants in Japan

Abstract Wood biomass supply costs were estimated and the supply potential was analyzed to determine the optimum amount for suppliers and wood biomass energy plants. First, supply costs, consisting of harvesting and transportation costs, were estimated for the components of wood biomass based on transportation distances. Two types of costs were determined: one based on the current harvesting and transportation system in Japan (CC), the other based on an improved system for harvesting and transporting commonly used in several European countries, with more efficient forestry machines and larger truck container capacity (IC). Second, supply models were created for all target municipalities to estimate marginal costs (MC) and average costs (AC). Third, the amount of wood biomass was estimated when MC and AC were set at 14,000 yen t −1 (100 yen ≈ 1 USD), an expense appropriate under current Japanese forestry conditions. Due to improving forestry machines and truck container capacity, approximately 25% of the cost was reduced for pre-commercial thinning, 32% for final cutting and commercial thinning (including bark, leaves and branches, and low-quality timber), 25% for bark (in mills), 16% for sawdust, and 10% for chip. When MC and AC were set at 14,000 yen t −1 , only Regions 7 and 9 could supply by 0.1 Mt using CC. IC clearly increased the wood biomass supply, particularly for Regions 2, 7, and 9.

[1]  Frederick L. Joutz,et al.  Biomass fuel supply : a methodology for determining marginal costs , 1992 .

[2]  Juha Laitila,et al.  The effect of CO2 emission trade on the wood fuel market in Finland , 2007 .

[3]  Toshihiko Nakata,et al.  Design of Biomass Co‑firing System Considering Resource Distribution and Transportation Optimization , 2010 .

[4]  Kalle Kärhä,et al.  Integrated harvesting of energy wood and pulpwood in first thinnings using the two-pile cutting method , 2011 .

[5]  W. Dale Greene,et al.  Evaluation of integrated harvesting systems in pine stands of the southern United States , 2010 .

[6]  Erik Trømborg,et al.  Forest sector impacts of the increased use of wood in energy production in Norway. , 2010 .

[7]  J. Ilavsky,et al.  Potential for biofuel development in Tihvin and Boksitogorsk districts of the Leningrad region -- The analysis of energy wood supply systems and costs , 2010 .

[8]  Kalle Kärhä,et al.  Integrated procurement of pulpwood and energy wood from early thinnings using whole-tree bundling. , 2011 .

[9]  T. Ranta Logging residues from regeneration fellings for biofuel production - a GIS-based availability analysis in Finland. , 2005 .

[10]  Koichi Yamamoto,et al.  Estimation of Spatial Distribution on Wood Biomass Supply Potential for Three Prefectures in the Northern Tohoku Region , 2009 .

[11]  E. Bjørnstad An engineering economics approach to the estimation of forest fuel supply in North-Trøndelag county, Norway , 2005 .

[12]  Toshihiko Nakata,et al.  Economic Analysis on Small-Scale Forest Biomass Gasification Considering Regional Resource Distribution and Technical Characteristics , 2007 .

[13]  R. Lundmark Cost structure of and competition for forest-based biomass , 2006 .