The Use of Forestry and Agricultural Biomass in the Production of Pellets

Aghalari A., Aladwan B. S., Marufuzzaman M., Tanger S., Da Silva B. K., Gnaneswar Gude V. Optimizing a pellet supply system: Market-specific pellet production with biomass quality considerations. Computers & Chemical Engineering. 2021, 153, 107417, Search in Google Scholar

Anukam, A., Berghel, J., Henrikson, G., Frodeson, S., & Ståhl, M. (2021). A review of the mechanism of bonding in densified biomass pellets. Renewable and Sustainable Energy Reviews, 148, 111249. doi:10.1016/j.rser.2021.111249 Search in Google Scholar

Bajwa D.S., Peterson T., Sharma N., Shojaeiarani J., Bajwa S. G. A review of densified solid biomass for energy production. Renewable and Sustainable Energy Reviews. 2018, 96, 296-305, https://doi.org/10.1016/j.rser.2018.07.040. Search in Google Scholar

Bălan, E. M., Cismaș, L. M., & Zeldea, C. G. (2021). Agricultural Biomass Production: Implications for Economic Growth and Environment in Central and Eastern European Countries. In Contemporary Issues in Social Science (Vol. 106, pp. 263-279). Emerald Publishing Limited. Search in Google Scholar

Bioenergy Europe | European Bioenergy Outlook – Pellet Report | 2022 Search in Google Scholar

Cofas, E., & Bălăceanu, C. T. (2023). Evaluation of the biomass energy production potential in agricultural holdings in relation to their size. Case study for crop farms in Romania. Romanian Agricultural Research, (40). Search in Google Scholar

European Union: Biofuels Annual, June 22, 2021 | Attaché Report (GAIN) | E42021-0053 Search in Google Scholar

García, R., Gil, M. V., Rubiera, F., & Pevida, C. (2019). Pelletization of wood and alternative residual biomass blends for producing industrial quality pellets. Fuel, 251, 739-753 Search in Google Scholar

Kimming, M., Sundberg, C., Nordberg, Å., Baky, A., Bernesson, S., Norén, O., & Hansson, P. A. (2011). Biomass from agriculture in small-scale combined heat and power plants–A comparative life cycle assessment. Biomass and bioenergy, 35(4), 1572-1581. Search in Google Scholar

Kpalo S.Y., Zainuddin M.F., Manaf L.A., Roslan A.M. A Review of Technical and Economic Aspects of Biomass Briquetting. Sustainability. 2020, 12(11):4609. https://doi.org/10.3390/su12114609 Search in Google Scholar

Malik B., Pirzadah T., Islam S., Tahir I., Kumar M., Rehman R. Biomass Pellet Technology: A Green Approach for Sustainable Development. In: Hakeem K., Jawaid M., Y. Alothman O. (eds) Agricultural Biomass Based Potential Materials. Springer, 2015 Cham. https://doi.org/10.1007/978-3-319-13847-3_19 Search in Google Scholar

Picchio, R., Latterini, F., Venanzi, R., Stefanoni, W., Suardi, A., Tocci, D., & Pari, L. (2020). Pellet Production from Woody and Non-Woody Feedstocks: A Review on Biomass Quality Evaluation. Energies, 13(11), 2937. doi:10.3390/en13112937 Search in Google Scholar

Popa, L., Trokhaniak, V., Constantin, A. M., Miron, C., Zaica, A., Persu, C., & Pruteanu, A. (2023). Experimental research regarding the achievement of an equipment designed for chopping woody waste. (2023): 757-766. Search in Google Scholar

Pradhan, P., Arora, A., & Mahajani, S. M. (2018). Pilot scale evaluation of fuel pellets production from garden waste biomass. Energy for sustainable development, 43, 1-14. Search in Google Scholar

Rodino, S., Butu, A., Dragomir, V., & Butu, M. (2019). An analysis regarding the biomass production sector in Romania-a bioeconomy point of view. Scientific Papers Series Management, Economic Engineering in Agriculture and Rural Development, 19(1), 497-502. Search in Google Scholar

Roh, H. B. Wood Pellets as a Biofuel : Current Status and their Market Potential, 2016. doi:http://dx.doi.org/10.14288/1.0314326 Search in Google Scholar

Saleem, M. (2022). Possibility of utilizing agriculture biomass as a renewable and sustainable future energy source. Heliyon. Search in Google Scholar

Sarker, T. R., Azargohar, R., Dalai, A. K., & Meda, V. (2021). Characteristics of torrefied fuel pellets obtained from co-pelletization of agriculture residues with pyrolysis oil. Biomass and Bioenergy, 150, 106139. Search in Google Scholar

Schipfer, F., Kranzl, L., Olsson, O., & Lamers, P. (2020). The European wood pellets for heating market-Price developments, trade and market efficiency. Energy, 212, 118636. Search in Google Scholar

Sherwood, J. (2020). The significance of biomass in a circular economy. Bioresource Technology, 300, 122755. Search in Google Scholar

Smaga, M., Wielgosiński, G., Kochański, A., & Korczak, K. (2018). Biomass as a major component of pellets. Acta Innovations. Search in Google Scholar

Stasiak, M., Molenda, M., Bańda, M., Wiącek, J., Parafiniuk, P., & Gondek, E. (2017). Mechanical and combustion properties of sawdust—Straw pellets blended in different proportions. Fuel Processing Technology, 156, 366-375. Search in Google Scholar

Tauro, R., García, C. A., Skutsch, M., & Masera, O. (2018). The potential for sustainable biomass pellets in Mexico: An analysis of energy potential, logistic costs and market demand. Renewable and Sustainable Energy Reviews, 82, 380-389. Search in Google Scholar

Whittaker, C., & Shield, I. (2017). Factors affecting wood, energy grass and straw pellet durability–A review. Renewable and Sustainable Energy Reviews, 71, 1-11. Search in Google Scholar

Wiloso, E. I., Setiawan, A. A. R., Prasetia, H., Wiloso, A. R., Sudiana, I., Lestari, R., ... & Heijungs, R. (2020). Production of sorghum pellets for electricity generation in Indonesia: A life cycle assessment. Biofuel Research Journal, 7(3), 1178-1194. Search in Google Scholar

Zhang, Q., Zou, D., Zeng, X., Li, L., Wang, A., Liu, F., ... & Xiao, Z. (2021). Effect of the direct use of biomass in agricultural soil on heavy metals activation or immobilization?. Environmental Pollution, 272, 115989. Search in Google Scholar