Potential of Cupressus lusitanica sawdust for pellet production using natural binding agents

Authors

  • Tegene Tantu Forest Products Innovation Center of Excellence, Ethiopian Forestry Development Country, Ethiopia
  • Gemechu Yadeta Forest Products Innovation Center of Excellence, Ethiopian Forestry Development Country, Ethiopia
  • Fikremariam Haile Forest Products Innovation Center of Excellence, Ethiopian Forestry Development Country, Ethiopia
  • Mahelete Tsegaye Forest Products Innovation Center of Excellence, Ethiopian Forestry Development Country, Ethiopia

DOI:

https://doi.org/10.47540/ijias.v6i1.2414

Keywords:

Binding Agents, C. lusitanica, Pellets, Sawdust

Abstract

This study explored the potential of Cupressus lusitanica Sawdust for the production of pellets from carbonized sawdust using different natural binding agents (molasses, starch flour, fruit waste, and waste paper). The impacts of particle size and the type of binding agent used on the fuel qualities of pellets were investigated. The experimental results highlight that pellets produced from waste paper and starch flour binders exhibit high calorific values, high fixed carbon, and low moisture content. In contrast, molasses and fruit waste binders lower the fixed carbon and calorific value of pellets. As a result, the maximum calorific values were obtained using starch flour and waste paper, with respective values of 7052 and 7046 (cal/g). Maximum fixed carbon contents were 79.5% and 76.67% for waste paper and starch flour bonded pellets. Fruit waste and molasses binders result in lower calorific values, with respective values of 4831 cal/g and 5034 cal/g respectively. Pellets produced from fruit waste and waste paper showed lower ash contents of 1.53% and 1.67% respectively, indicating their environmental advantages. Therefore, starch flour, waste paper, molasses, and fruit waste are effective binders for biomass pellet production with improved quality.

References

Abolee, J., & S. R. K. (2022). Physio-chemical properties of pellets using different feedstock. International Journal of Agricultural Sciences, 18(1), 18–23.

Adams, P., Bridgwater, T., Lea-Langton, A., Ross, A., & Watson, I. (2018). Biomass Conversion Technologies. Greenhouse Gases Balances of Bioenergy Systems (107–139).

Ahmad, T., & Zhang, D. (2020). A critical review of comparative global historical energy consumption and future demand: The story told so far. Energy Reports, 6, 1973–1991.

Akbar, A., Aslam, U., Asghar, A., & Aslam, Z. (2021). Effect of binding materials on physical and fuel characteristics of bagasse-based pellets. Biomass and Bioenergy, 150, 106118.

Álvarez-Álvarez, P., Pizarro, C., Barrio-Anta, M., Cámara-Obregón, A., Bueno, J., Álvarez, A., Gutiérrez, I., & Burslem, D. (2018a). Evaluation of Tree Species for Biomass Energy Production in Northwest Spain. Forests, 9(4), 160.

Álvarez-Álvarez, P., Pizarro, C., Barrio-Anta, M., Cámara-Obregón, A., Bueno, J., Álvarez, A., Gutiérrez, I., & Burslem, D. (2018b). Evaluation of Tree Species for Biomass Energy Production in Northwest Spain. Forests, 9(4), 160.

Amaya, A. (2015). Preparation of Charcoal Pellets from Eucalyptus Wood with Different Binders. Journal of Energy and Natural Resources, 4(2), 34.

ASTM D3172. (2015). Standard method for fixed carbon determination of solid biofuel.

ASTM D3173-11. (2017). Standard Test Method for Moisture Analysis of Particulate Wood Fuels.

ASTM D3174-12. (2018). D1102-84 Standard Test Method for Ash in Wood.

ASTM D3175-18. (2018). Standard Test Method for Volatile Matter in the Analysis of Particulate Wood Fuels (Vol. 18).

ASTM D5865-13. (2019). ASTM E711—87 Gross Calorific Calorimeter.

Benti, N. E., Gurmesa, G. S., Argaw, T., Aneseyee, A. B., Gunta, S., Kassahun, G. B., Aga, G. S., & Asfaw, A. A. (2021). The current status, challenges and prospects of using biomass energy in Ethiopia. Biotechnology for Biofuels, 14(1), 209.

Berhanu, M., Jabasingh, S. A., & Kifle, Z. (2017). Expanding sustenance in Ethiopia based on renewable energy resources – A comprehensive review. Renewable and Sustainable Energy Reviews.

Cesprini, E., Greco, R., Causin, V., Urso, T., Cavalli, R., & Zanetti, M. (2021). Quality assessment of pellets and briquettes made from glued wood waste. European Journal of Wood and Wood Products, 79(5), 1153–1162.

Faedo de Almeida, C. C., D’Angelo Rios, P., Bayestorff da Cunha, A., Melo Ampessan, C. G., & Spanhol, A. (2016). Applicability evaluation of Cupressus lusitanica for pulp production. Maderas. Ciencia y Tecnología, ahead, 0–0.

FAO. (2018). Forest Products 2016 Year book, FAO Statistics, Rome.

Flach, & Bolla. (2022). EU Wood Pellet Annual.

Gilvari, H., De Jong, W., & Schott, D. L. (2020). The Effect of Biomass Pellet Length, Test Conditions and Torrefaction on Mechanical Durability Characteristics According to ISO Standard 17831-1.

Greinert, A., Mrówczyńska, M., Grech, R., & Szefner, W. (2020). The Use of Plant Biomass Pellets for Energy Production by Combustion in Dedicated Furnaces. Energies, 13(2), 463.

Harun, N. Y., & Afzal, M. T. (2016). Effect of Particle Size on Mechanical Properties of Pellets Made from Biomass Blends. Procedia Engineering, 148, 93–99.

Hu, Q., Shao, J., Yang, H., Yao, D., Wang, X., & Chen, H. (2015). Effects of binders on the properties of bio-char pellets. Applied Energy, 157, 508–516.

Huang, Y., Finell, M., Larsson, S., Wang, X., Zhang, J., Wei, R., & Liu, L. (2017). Biofuel pellets made at low moisture content – Influence of water in the binding mechanism of densified biomass. Biomass and Bioenergy, 98, 8–14.

IEA. (2020). Key World Energy Statistics 2020. Int. Energy Agency, 33(August), 4649.

IEA. (2022). World Energy Outlook.

ISO 17828. (2015). ’Determination of bulk density of solid biofuels.

ISO 17831-2. (2021). Determination of mechanical durability of soild biofuels.

Jaya, S. T. (2018). Effect of pellet die diameter on density and durability of pellets made from high moisture woody and herbaceous biomass. Carbon Resources Conversion.

Kabeyi, M. J. B., & Olanrewaju, O. A. (2022). Sustainable Energy Transition for Renewable and Low Carbon Grid Electricity Generation and Supply. Frontiers in Energy Research, 9.

Kažimírová, V., & Opáth, R. (2016). Biomass combustion emissions. Research in Agricultural Engineering, 62(Special Issue), S61–S65.

Kotta, A. B., Patra, A., & Kumar, M. (2019). Effect of molasses binder on the physical and mechanical properties of iron ore pellets”, Effect of molasses binder on the physical and mechanical properties of iron ore pellets, 26(1).

Kpalo, S. Y., Zainuddin, M. F., Manaf, L. A., & Roslan, A. M. (2020). Production and Characterization of Hybrid Briquettes from Corncobs and Oil Palm Trunk Bark under a Low-Pressure Densification Technique. Sustainability, 12(6), 2468.

Kumar, Chandrashekar, Prasad, & Tailor. (2020). Effect of extractive content on fuelwood characteristics of certain woody and non-woody biomass.

Lee, J. S., Sokhansanj, S., & Lau, A. K. et., et al. (2020). Physical properties of wood pellets exposed to liquid water. Biomass and Bioenergy.

Lisowski, A., Matkowski, P., Dąbrowska, M., Piątek, M., Swietochowski, A., Klonowski, J., Mieszkalski, L., & Reshetiuk, V. (2020). Particle Size Distribution and Physicochemical Properties of Pellets Made of Straw, Hay, and Their Blends. Waste and Biomass Valorization, 11(1), 63–75.

Lulu, Y., Eddy, I., Marsi, Novitri, H., & Hermansyah. (2023). The Chemical-Physical and Quality Parameters of Woods Pellets Generated from Revegetation Reclamation of Post-Coal Mining Land. Journal of Ecological Engineering.

Maillot, M., & Morau, D. (2023). Physico‐chemical characterization of Residual Household Waste for energy recovery in insular territories: Case study of Reunion Island. Environmental Quality Management, 33(1), 107–119.

MEFCC. (2017). Ethiopia’s Institutional Framework for the MRV under the REDD+ Program.

MEFCC. (2018). Review of policies and strategies related to the clean cooking sector in Ethiopia final report, strengthening the enabling environment for clean cooking project.

Nabavi, V., Azizi, M., Tarmian, A., & Ray, C. D. (2020). Feasibility study on the production and consumption of wood pellets in Iran to meet return-on-investment and greenhouse gas emissions targets. Renewable Energy, 151, 1–20.

Niedziółka, A., Szpryngiel, M., Kachel, M., & Kraszkiewicz, A. et al. (2015). Assessment of the energetic and mechanical properties of pellets produced from agricultural biomass. Renewable Energy.

Nisula. (2018). Wood Extractives in Conifers—A Study of Stemwood and Knots of Industrially Important Species.

Ozbayoglu, G. (2018). Energy Production From Coal”, in Comprehensive Energy Systems. Elsevier, 788–821.

Pandey, S. (2022). Wood waste utilization and associated product development from under-utilized low-quality wood and its prospects in Nepal. SN Applied Sciences, 4(6), 168.

Parajuli, R. (2021). Wood pellets versus pulp and paper: Quantifying the impacts of wood pellets on the pulpwood markets in the southeastern United States. Journal of Cleaner Production, 317, 128384.

Pradhan, P., Mahajani, S. M., & Arora, A. (2018). Production and utilization of fuel pellets from biomass: A review. Fuel Processing Technology, 181, 215–232.

Regmi, S., Dahal, K. P., Sharma, G., Regmi, S., & Miya, M. S. (2021). Biomass and Carbon Stock in the Sal (Shorea robusta) Forest of Dang District Nepal. Indonesian Journal of Social and Environmental Issues (IJSEI), 2(3), 204–212.

Saleem, M. (2022). Possibility of utilizing agriculture biomass as a renewable and sustainable future energy source. Heliyon, 8(2), e08905.

Sermyagina, E., Mendoza Martinez, C., Lahti, J., Nikku, M., Mänttäri, M., Kallioinen-Mänttäri, M., & Vakkilainen, E. (2022). Characterization of pellets produced from extracted sawdust: Effect of cooling conditions and binder addition on composition, mechanical and thermochemical properties. Biomass and Bioenergy, 164, 106562.

Sette Jr, C. R., Castro e Freitas, P. de, Freitas, V. P., Yamaji, F. M., & Almeida, R. de A. (2016). Production and characterization of bamboo pellets. Bioscience Journal, 922–930.

Shadangi, K. P., Sarangi, P. K., & Behera, A. K. (2023). Characterization techniques of biomass. Bioenergy Engineering (pp. 51–66).

Shahrukh, H., Oyedun, A. O., Kumar, A., Ghiasi, B., Kumar, L., & Sokhansanj, S. (2016). Techno-economic assessment of pellets produced from steam pretreated biomass feedstock. Biomass and Bioenergy, 87, 131–143.

Sher, F., Iqbal, S. Z., Liu, H., Imran, M., & Snape, C. E. (2020). Thermal and kinetic analysis of diverse biomass fuels under different reaction environment: A way forward to renewable energy sources. Energy Conversion and Management, 203, 112266.

Tolessa, A. (2023). Bioenergy Production Potential of Available Biomass Residue Resources in Ethiopia. Journal of Renewable Energy, 2023, 1–12.

Ullah, S., Noor, R. S., Sanaullah, & Gang, T. (2023). Analysis of biofuel (briquette) production from forest biomass: A socioeconomic incentive towards deforestation. Biomass Conversion and Biorefinery, 13(3), 1–15.

Ungureanu, N., Vladut, V., Voicu, G., Dinca, M.-N., & Zabava, B.-S. (2018, May 23). Influence of biomass moisture content on pellet properties—Review.

World Bioenergy Statistics. (2019). A Technical Report on Global Bioenergy Statistics.

Yang, I., Jeong, H., Lee, J. J., & Lee, S. M. (2019). Relationship between Lignin Content and the Durability of Wood Pellets Fabricated Using Larix kaempferi C. Sawdust. Journal of the Korean Wood Science and Technology, 47(1), 110–123.

Yılmaz, H., Çanakcı, M., Topakcı, M., & Karayel, D. (2021). The effect of raw material moisture and particle size on agri-pellet production parameters and physical properties: A case study for greenhouse melon residues. Biomass and Bioenergy, 150, 106125.

Published

2026-02-27

How to Cite

Tantu, T. ., Yadeta, G. ., Haile, F. ., & Tsegaye, M. . (2026). Potential of Cupressus lusitanica sawdust for pellet production using natural binding agents. Indonesian Journal of Innovation and Applied Sciences (IJIAS), 6(1), 86-93. https://doi.org/10.47540/ijias.v6i1.2414

Issue

Vol. 6 No. 1 (2026): February-May 2025

Section

Articles

Copyright (c) 2026 Tegene Tantu, Gemechu Yadeta, Fikremariam Haile, Mahelete Tsegaye

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