Abstract
Logistics cost, the cost of moving feedstock or products, is a key component of the overall cost of recovering energy from biomass. In this study, we calculate for small- and large-project sizes, the relative cost of transportation by truck, rail, ship, and pipeline for three biomass feedstocks, by truck and pipeline for ethanol, and by transmission line for electrical power. Distance fixed costs (loading and unloading) and distance variable costs (transport, including power losses during transmission), are calculated for each biomass type and mode of transportation. Costs are normalized to a common basis of a giga Joules of biomass. The relative cost of moving products vs feedstock is an approximate measure of the incentive for location of biomass processing at the source of biomass, rather than at the point of ultimate consumption of produced energy. In general, the cost of transporting biomass is more than the cost of transporting its energy products. The gap in cost for transporting biomass vs power is significantly higher than the incremental cost of building and operating a power plant remote from a transmission grid. The cost of power transmission and ethanol transport by pipeline is highly dependent on scale of project. Transport of ethanol by truck has a lower cost than by pipeline up to capacities of 1800 t/d. The high cost of transshipment to a ship precludes shipping from being an economical mode of transport for distances less than 800 km (woodchips) and 1500 km (baled agricultural residues).
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Kumar, A., Cameron, J., and Flynn, P. (2003), J. Biomass Bioenergy 24, 445–464.
Mahmudi, H. and Flynn, P. (2006), J. Appl. Biochem. Biotechnol. 129–132, 88–103.
Kumar, A., Cameron, J., and Flynn, P. (2004), J. Appl. Biochem. Biotechnol. 113, 27–40.
Flynn, P. and Kumar, A. (2005), Trip Report, Pietarsaari, Finland. University of Alberta, Canada (May 1, 2006). www.biocap.ca/files/reports.
Aden, A., Ruth, M., Ibsen, K. Lignocellulosic biomass to ethanol process design and economics utilizzing co-carrent diulte acid prehydrolsis for corn stoner, TP-5-32438 (2002), National Renewable Energy Laboratory, Golden, Colorado.
Wooley, R., Ruth, M., Sheehan, J., and Ibsen, K. (1999), Lignocellulosic biomass to ethanol process design and economics utilizing co-corrent dilute acid prehydrolysis and enzymatic hydrolysis—current and futuristic scenarios, TP-580-26157. National Renewable Energy Laboratory, Golden, Colorado.
Kumar, A., Cameron, J., and Flynn, P. (2005), J. Bioresour. Technol. 96, 819–829.
Borjesson, P. and Gustavsson, L. (1996), J. Energy 21, 747–764.
Taylor, J. (2002), Regional Manager of Gibson’s Trucking Company, Alberta, Canada, personal communication.
Williams, D. (2002), Chief Estimator for Bantrel Corporation (an affiliate of Bechtel), Edmonton, Calgary, Alberta, Canada, personal communication.
Ghafoori, E. and Feddes, J. (2005), Pipeline vs beef transport of beef cattle manure. ASAE Pacific Northwest Section Meeting Presentation, PNW05-1012, Lethbridge, Alberta, Canada.
Rao, M., Singh, S., Sodha, M., Dubey, A., and Shyam, M. (2004), J. Biomass Bioenergy 27, 155–171.
Cameron, J., Kumar, A., and Flynn, P. (2004), ASAE/CSAE Annual International Meeting, PN 048039, Ottawa, Ontario, Canada.
Van den Broek, R., Faaij, A., and Van Wijk, A. (1995), Department of Science, Technology and Society, Utrecht University, Netherlands.
Mailey, S. (2006), Transmission information engineer, Manitoba Hydro, Winnipeg, Manitoba, Canada, personal communication.
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Searcy, E., Flynn, P., Ghafoori, E. et al. The relative cost of biomass energy transport. Appl Biochem Biotechnol 137, 639–652 (2007). https://doi.org/10.1007/s12010-007-9085-8
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DOI: https://doi.org/10.1007/s12010-007-9085-8