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Feedstock cost analysis of corn stover residues for further processing

Author

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  • Perlack, R.D.
  • Turhollow, A.F.

Abstract

In this paper, we evaluate the costs for collecting, handling, and hauling corn stover to an ethanol conversion facility. We estimate costs for a conventional baling system at varying levels of feedstock demand or conversion facility size. Our results generally indicate that stover can be collected, stored, and hauled for about $43.10–51.60/dry ton using conventional baling equipment for conversion facilities ranging from 500 to 4000 dry tons/day. The cost difference between facility sizes is due to transportation. Transportation, collection and baling, and farmer payments account for over 90% of total delivered costs. These estimates are based on average corn stover resource availability assumptions and are inclusive of all costs including farmer payments. Under conditions of high resource availability costs can be lowered by $6–10/dry ton. Delivered costs increase considerably under low resource availability conditions.

Suggested Citation

  • Perlack, R.D. & Turhollow, A.F., 2003. "Feedstock cost analysis of corn stover residues for further processing," Energy, Elsevier, vol. 28(14), pages 1395-1403.
    • Handle: RePEc:eee:energy:v:28:y:2003:i:14:p:1395-1403
    DOI: 10.1016/S0360-5442(03)00123-3
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    Citations

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    Cited by:

    1. Miranowski, John & Rosburg, Alicia, 2010. "An economic breakeven model of cellulosic feedstock production and ethanol conversion with implied carbon pricing," ISU General Staff Papers 201002040800001108, Iowa State University, Department of Economics.
    2. Parker, Nathan C, 2007. "Optimizing the Design of Biomass Hydrogen Supply Chains Using Real-World Spatial Distributions: A Case Study Using California Rice Straw," Institute of Transportation Studies, Working Paper Series qt8sp9n37c, Institute of Transportation Studies, UC Davis.
    3. Nurun Nahar & Ramsharan Pandey & Ghasideh Pourhashem & David Ripplinger & Scott W. Pryor, 2021. "Life Cycle Perspectives of Using Non-Pelleted vs. Pelleted Corn Stover in a Cellulosic Biorefinery," Energies, MDPI, vol. 14(9), pages 1-14, April.
    4. Bundhoo, Zumar M.A. & Surroop, Dinesh, 2019. "Evaluation of the potential of bio-methane production from field-based crop residues in Africa," Renewable and Sustainable Energy Reviews, Elsevier, vol. 115(C).
    5. Golecha, Rajdeep & Gan, Jianbang, 2016. "Effects of corn stover year-to-year supply variability and market structure on biomass utilization and cost," Renewable and Sustainable Energy Reviews, Elsevier, vol. 57(C), pages 34-44.
    6. Lavigne, Amanda & Powers, Susan E., 2007. "Evaluating fuel ethanol feedstocks from energy policy perspectives: A comparative energy assessment of corn and corn stover," Energy Policy, Elsevier, vol. 35(11), pages 5918-5930, November.
    7. Akhtari, Shaghaygh & Sowlati, Taraneh & Day, Ken, 2014. "The effects of variations in supply accessibility and amount on the economics of using regional forest biomass for generating district heat," Energy, Elsevier, vol. 67(C), pages 631-640.
    8. Scott M. Swinton & Felix Dulys & Sarah S.H. Klammer, 2021. "Why Biomass Residue Is Not as Plentiful as It Looks: Case Study on Economic Supply of Logging Residues," Applied Economic Perspectives and Policy, John Wiley & Sons, vol. 43(3), pages 1003-1025, September.
    9. Khachatryan, Hayk & Jessup, Eric L. & Casavant, Ken, 2009. "Derivation of Crop Residue Feedstock Supply Curves Using Geographic Information Systems," Journal of the Transportation Research Forum, Transportation Research Forum, vol. 48(1).
    10. Kesharwani, Rajkamal & Sun, Zeyi & Dagli, Cihan & Xiong, Haoyi, 2019. "Moving second generation biofuel manufacturing forward: Investigating economic viability and environmental sustainability considering two strategies for supply chain restructuring," Applied Energy, Elsevier, vol. 242(C), pages 1467-1496.
    11. Wang, Xiaoquan & Morrison, William & Du, Zhenyi & Wan, Yiqin & Lin, Xiangyang & Chen, Paul & Ruan, Roger, 2012. "Biomass temperature profile development and its implications under the microwave-assisted pyrolysis condition," Applied Energy, Elsevier, vol. 99(C), pages 386-392.
    12. Fan, Kang-Qi & Zhang, Peng-Fei & Pei, Z.J., 2013. "An assessment model for collecting and transporting cellulosic biomass," Renewable Energy, Elsevier, vol. 50(C), pages 786-794.
    13. Tittmann, P.W. & Parker, N.C. & Hart, Q.J. & Jenkins, B.M., 2010. "A spatially explicit techno-economic model of bioenergy and biofuels production in California," Journal of Transport Geography, Elsevier, vol. 18(6), pages 715-728.
    14. William Stafford & Adrian Lotter & Alan Brent & Graham von Maltitz, 2017. "Biofuels technology: A look forward," WIDER Working Paper Series wp-2017-87, World Institute for Development Economic Research (UNU-WIDER).
    15. Parker, Nathan, 2007. "Optimizing the Design of Biomass Hydrogen Supply ChainsUsing Real-World Spatial Distributions: A Case Study Using California Rice Straw," Institute of Transportation Studies, Working Paper Series qt5kr728sp, Institute of Transportation Studies, UC Davis.
    16. Carriquiry, Miguel A. & Du, Xiaodong & Timilsina, Govinda R., 2011. "Second generation biofuels: Economics and policies," Energy Policy, Elsevier, vol. 39(7), pages 4222-4234, July.
    17. William Stafford & Adrian Lotter & Alan Brent & Graham von Maltitz, 2017. "Biofuels technology: A look forward," WIDER Working Paper Series 087, World Institute for Development Economic Research (UNU-WIDER).
    18. Diep, Nhu Quynh & Fujimoto, Shinji & Minowa, Tomoaki & Sakanishi, Kinya & Nakagoshi, Nobukazu, 2012. "Estimation of the potential of rice straw for ethanol production and the optimum facility size for different regions in Vietnam," Applied Energy, Elsevier, vol. 93(C), pages 205-211.
    19. Baral, Nawa Raj & Quiroz-Arita, Carlos & Bradley, Thomas H., 2017. "Uncertainties in corn stover feedstock supply logistics cost and life-cycle greenhouse gas emissions for butanol production," Applied Energy, Elsevier, vol. 208(C), pages 1343-1356.
    20. Petrolia, Daniel R., 2006. "Ethanol from Biomass: Economic and Environmental Potential of Converting Corn Stover and Hardwood Forest Residue in Minnesota," 2006 Annual meeting, July 23-26, Long Beach, CA 21422, American Agricultural Economics Association (New Name 2008: Agricultural and Applied Economics Association).
    21. Sun, Shanxia & Johnson, David R. & Hertel, Thomas W., 2018. "Quantifying the Impacts of Biomass Co-Firing on GHG Emissions from Coal-Powered Electricity Generation," 2018 Annual Meeting, August 5-7, Washington, D.C. 274452, Agricultural and Applied Economics Association.
    22. Kambo, Harpreet Singh & Dutta, Animesh, 2015. "A comparative review of biochar and hydrochar in terms of production, physico-chemical properties and applications," Renewable and Sustainable Energy Reviews, Elsevier, vol. 45(C), pages 359-378.
    23. Qian Chen & Yanling Jin & Guohua Zhang & Yang Fang & Yao Xiao & Hai Zhao, 2012. "Improving Production of Bioethanol from Duckweed ( Landoltia punctata ) by Pectinase Pretreatment," Energies, MDPI, vol. 5(8), pages 1-14, August.
    24. Diep, Nhu Quynh & Sakanishi, Kinya & Nakagoshi, Nobukazu & Fujimoto, Shinji & Minowa, Tomoaki, 2015. "Potential for rice straw ethanol production in the Mekong Delta, Vietnam," Renewable Energy, Elsevier, vol. 74(C), pages 456-463.
    25. Gallagher, Paul W. & Baumes, Harry, 2012. "Biomass Supply From Corn Residues: Estimates and Critical Review of Procedures," Agricultural Economic Reports 308488, United States Department of Agriculture, Economic Research Service.

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