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Characterization and feasibility of biomass fuel pellets made of Colombian timber, coconut and oil palm residues regarding European standards

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Strong correlation between economic development, energy demand and fossil fuels utilization during last decades has caused some negative impacts worldwide, based on it, the renewable resources for energy production should be employed to mitigate these effects. Nowadays, biomass is one of the most prominent renewable sources, but factors such as low density and high moisture content are some drawbacks. In order to overcome these problems, some companies use different types of biomass to provide solid biofuels with higher energy density, mechanical resistance and standardized dimensions. Wood pellet industry has increased exponentially during last years, faster than timber industries; therefore, new raw materials should be evaluated to guarantee pellets demand in the near future. Some of them are agricultural residues. Colombia is a country with an interesting potential for biomass production because there is a rising generation of agricultural products. This work aims to assess main properties of Colombian timber industry residues, coconut shells and oil palm shells and compare the characteristics of pellets made from these raw materials with European standards. Pellets made from these feedstocks have an average density between 850 and 1025kg·m-3, low ash contents and heating values around 18000kJ·kg-1. Coconut shell pellets have low compression ratios and problems during pretreatment; whereas, sawdust, wood shavings and oil palm shell pellets proved to be an attractive opportunity for pellet industry development in Colombia.
Rocznik
Strony
67--76
Opis fizyczny
Bibliogr. 17 poz., fot., tab.
Twórcy
  • Clean Development Mechanisms and Energy Management Research Group, Mechanical and Mechatronics Engineering Department, Universidad Nacional de Colombia, Cr 30 45-04, Bogotá, Colombia, Tel. (+57) 3213430593
autor
  • Mechanical and Process Engineering Department, University of Applied Sciences Offenburg, Badstrasse 24, D77652, Offenburg, Germany
  • Clean Development Mechanisms and Energy Management Research Group, Mechanical and Mechatronics Engineering Department, Universidad Nacional de Colombia, Cr 30 45-04, Bogotá, Colombia
Bibliografia
  • Al-mulali, U., C.N.Binti Che Sab. 2012. The impact of energy consumption and CO2 emission on the economic and financial development in 19 selected countries. Renewable and Sustainable Energy Reviews 16: 4365-4369.
  • Di Giacomo, G., L. Taglieri. 2009. Renewable energy benefits with conersion of woody residues to pellets. Energy 34: 724-731.
  • Erlich, C., E. Björrnbom, D. Bolado, M. Giner, T.H. Fransson. 2006. Pyrolysis and gasification of pellets from sugar cane bagasse and wood. Fuel 85: 1535-1540.
  • Forero Núñez, C.A., C.A. Guerrero Fajardo, F.E. Sierra Vargas. 2012a. Producción y uso de pellets de biomasa para la generación de energía térmica: una revisión a los modelos del proceso de gasificación. Revista Iteckne 9: 21-30.
  • Forero Núñez, C.A., A. Cediel Ulloa, J.L. Rivera Gil, A. Suaza Montalvo, F.E. Sierra Vargas. 2012b. Estudio preliminar del potencial energético de cuesco de palma y cáscara de coco en Colombia. Revista Ingeniería Solidaria 8: 19-25.
  • IEA. 2011a. Key World Energy Statistics. Ed. International Energy Agency, Paris. 82 p.
  • IEA. 2011b. CO2 emissions from fuel combustion. Ed. International Energy Agency, Paris. 134 p.
  • IEA Bioenergy. 2011. Global Wood Pellet Industry Market and Trade Study. Ed. IEA Bioenergy, Paris. 190 p.
  • Kaliyan, N., R. Vance Morey. 2009a. Factor affecting strength and durability of densified biomass products. Biomass and Bioenergy 33: 337-359.
  • Kaliyan, N., R. Vance Morey. 2009b. Constitutive model for densification of corn stover and switchgrass. Biosystems Engineering 104: 47-63.
  • Lopez, F., A. Perez, M.A. Zamudio, H.E. De Avila, J.C. Garcia. 2012. Paulownia as raw material for solid biofuel and cellulose pulp. Biomass and Bioenergy 45: 77-86.
  • Mediavilla, I., L. Esteban, M. Fernandez. 2012. Optimisation of pelletisation conditions for poplar energy crop. Fuel Processing Technology 104: 7-15.
  • Obernbrger, I., G. Thek. 2004. Physical characterisation and chemical composition of densified biomass fuel with regard to their combustion behaviour. Biomass and Bioenergy 27: 653-669.
  • Renewable Energy Policy Network for the 21st century. REN21. 2011. Renewables 2011 Global Status Report. Paris. 116 p.
  • Stahl, R., E. Henrich. 2004. Renewable fuels for advanced power trains. Definition of a standard biomass. Forshungszentrum Karlsruhe GmbH. Karlsruhe. 120 p.
  • Teixeira, G., L. Van de Steene, E. Martin, F. Gelix, S. Salvador. 2012. Gasification of char from wood pellets and from wood chips: Textural properties and thermochemical conversion along a continuos fixed bed. Fuel 102: 514-524.
  • Vassilev, S.V., D. Baxter, L.K. Andersen, C.G. Vassileva. 2010. An overview of the chemical composition of biomass. Fuel 89: 913-933.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-65936271-8bea-45b3-834f-c8df0d23377e
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