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The Effect of External Transport on Energetic Efficiency of Biodiesel Production

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Języki publikacji
EN
Abstrakty
EN
In several our publications energetic efficiency of biofuel production was defined as a ratio of the amount of energy obtained in a form of biofuel to the sum of energy contributions necessary to conduct production processes on all the production stages. It was also shown that such a definition enables subsequent inclusion of production steps due to additivity of reciprocals of energetic efficiency determined separately for each step. In the present work, several scenarios of the transport of biomass between plantation and industrial facility converting biomass into biofuel are considered, appropriate values of energetic efficiency are computed and compared. The analysis is confined to biodiesel production based on rapeseed. The results show substantial differences caused by various approaches to that stage of transport.
Rocznik
Strony
57--62
Opis fizyczny
Bibliogr. 19 poz., tab., rys.
Twórcy
autor
  • Bialystok University of Technology, Production Management Dept., Wiejska 45A Str., 15-351 Bialystok, Poland
autor
  • Bialystok University of Technology, Production Management Dept., Wiejska 45A Str., 15-351 Bialystok, Poland
Bibliografia
  • 1. Abnisa F., Wan Daud W.M.A., Husin W.N.W., Sahu J.N. 2011. Utilization possibilities of palm shell as a source of biomass energy in Malaysia by producing bio-oil in pyrolysis process. Biomass and Bioenergy 35, 1863–1872.
  • 2. Arodudu O., Ibrahim E., Voinov A., Duren I. 2014. Exploring bioenergy potentials of built-up areas based on NEG-EROEI indicators, Ecological Indicators 47, 67–79.
  • 3. Bharathiraja B., Chakravarthy M., RanjithKumar R. Yuvaraj D., Jayamuthunagai J., Praveen Kumar R., Palani S. 2014. Biodiesel production using chemical and biological methods – A review of process, catalyst, acylacceptor, source and process variables, Renewable and Sustainable Energy Reviews 38, 368–382.
  • 4. Field C., Campbell J., Lobell D. 2007. Biomass energy: the scale of the potential resource, Trends in Ecology and Evolution 23, 65–72.
  • 5. Liao W., Heijungs R., Huppes G. 2011. Is bioethanol a sustainable energy source? An energy-, exergy-, and emergy-based thermodynamic system analysis, Renewable Energy 36, 3479–3487.
  • 6. Malakul P., Papong S., Chom-in T., Noksa-n S. 2010. Life cycle energy efficiency and potentials of biodiesel production from palm oil in Thailand. Energy Policy 38, 226–233.
  • 7. Marklein D. M., Thoth M.A., Karpoff M.N., Paul G.S,, McCormack R., Kyriazis J., Krueger T. 2010, Food versus biofuels: environmental and economic costs, Human Ecology 37, 1–12.
  • 8. Mediavilla M., deCastro C., Capella´n I., Miguel L.J., Arto I., Frechoso F. 2013. The transition towards renewable energies: Physical limits and temporal conditions, Energy Policy 52, 297–311.
  • 9. Murphy D.J., Hall C.A.S., Dale M., Cleveland C. 2011. Order from Chaos: A Preliminary Protocol for Determining the EROI of Fuels, Sustainability 3, 1888–1907.
  • 10. Nigam P.S., Singh A. 2011. Production of liquid biofuels from renewable resources, Progress in Energy and Combustion Science 37, 52–68.
  • 11. Orynycz O., Wasiak A. 2015. Effects of field’s topology on energetic efficiency of rapeseed plantation for biofuel production. Applied Computer Science 11, 83–98.
  • 12. Russo D., Dassisti M., Lawlorb V., Olabib A.G. 2012. State of the art of biofuels from pure plant oil, Renewable and Sustainable Energy Reviews 16, 4056–4070.
  • 13. Schneider U., Smith A. 2009, Energy intensities and greenhouse gas emission mitigation in global agriculture, Energy Efficiency 2, 195–206.
  • 14. Singh K.P., Prakash V., Srinivas K.P.K., Srivastva A.K. 2008. Effect of tillage management on energy-use efficiency and economics of soybean (Glycine max) based cropping systems under the rainfed conditions in North-West Himalayan Region, Soil & Tillage Research 100, 78–82.
  • 15. Smith S.L., Thelen K.D., MacDonald S.J. 2013. Yield and quality analyses of bioenergy crops grown on a regulatory brownfield, Biomass and Bioenergy 49, 123–130.
  • 16. Talens L., Villalba G., Gabarrell X. 2007, Exergy analysis applied to biodiesel production, Resources, Conservation and Recycling 51, 397–407.
  • 17. Wasiak A., Orynycz O. 2014. Formulation of a model for energetic efficiency of agricultural subsystem of biofuel production, IEEE International Energy Conference: ENERGYCON’2014, Dubrovnik, Croatia, 1333–1337.
  • 18. Wasiak A., Orynycz O. 2015. The effects of energy contributions into subsidiary processes on energetic efficiency of biomass plantation supplying biofuel production system. Agriculture and Agricultural Science Procedia 7, 292–300.
  • 19. Zhang Y., Colosi L.M. 2013. Practical ambiguities during calculation of energy ratios and their impacts on lifecycle assessment calculations, Energy Policy 57, 630–633.
Uwagi
PL
Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-02ebaaa7-e2c4-4fb3-bef5-81cfbc14bafc
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