Innovative Biomass Blending: Improving Oil Palm Trunk (OPT) Pellet Characteristics with Acacia mangium Wood for Bioenergy Production
DOI:
https://doi.org/10.15282/jceib.v11i1.10958Keywords:
Oil palm biomass, Acacia mangium wood, Pellet, Blending ratio, Pellet propertiesAbstract
The increasing consumption of renewable resources is mostly associated to the demand of global energy and the increase of fossil fuel prices but also to the depletion and limited availability of petroleum. The usage of these biomass has lower the environmental impact as compared with other non‐renewable fuels. Currently, pellet production from non‐woody biomass has increasing and one of the important aspects is for the sustainable use as bioenergy sources because of its quality. Due to the abundant sources of non-woody biomass materials like oil palm trunk (OPT) especially in Sarawak, its potential for pellet utilization was investigated. The pellet properties from OPT was improved by blending with fast growing species wood like Acacia mangium at different blending ratio in terms of its physical, chemical and energy properties. Both biomass in fibre forms were used for pellet production by using pelletizing machine. The properties of pellet produced were analysed to evaluate the quality of pellet in terms of its moisture content, bulk density, ash content and calorific value. Blending biomass pellet has decreased slightly the ash content from 2.1 to 2.0% and the calorific values of blending biomass pellet has increased significantly from 17.4 to 18.4 MJ/kg when 30% OPT blended with 70% A. mangium. The result obtained comparable to the standard requirements for commercial pellet that is available in the market. The characteristics of blending biomass pellet is differed from pure biomass pellets which contribute to the further improve its quality, make it has highly potential as bioenergy product.
References
[1] V. Civitarese, A. Acampora, G. Sperandio, A. Assirelli, and R. Picchio, “Production of wood pellets from poplar trees managed as coppices with different harvesting cycles,” Energies, vol. 12, no. 15, p. 2973, 2019.
[2] R. Picchio, F. Latterini, R. Venanzi, W. Stefanoni, A. Suardi, D. Tocci, et al., “Pellet production from woody and non-woody feedstocks: A review on biomass quality evaluation,” Energies, vol. 13, no. 11, p. 2937, 2020.
[3] J. S. López, M. C. Fernández de la Mora, M. S. Gallego, and J. F. Gonzalez, “A proposal for pellet production from residual woody biomass in the island of Majorca (Spain),” AIMS Energy, vol. 3, no. 3, pp. 480-504, 2015.
[4] A. Akbi, M. Saber, M. Aziza, and N. Yassaa, “An overview of sustainable bioenergy potential in Algeria,” Renewable and Sustainable Energy Reviews, vol. 72, pp. 240-245, 2017.
[5] W. Wattana, S. Phetklung, W. Jakaew, S. Chumuthai, P. Sriam, and N. Chanurai, “Characterization of mixed biomass pellet made from oil palm and para-rubber tree residues,” Energy Procedia, vol. 138, pp. 1128-1133, 2017.
[6] V. Strezov, “Properties of biomass fuels,” In Strezov V, Evans TJ, editors. Biomass Processing Technologies, USA: CRC Press, 2014.
[7] A. Yusmur, R. Ardiansyah, and S. Marlinda, “Biomass sources for sustainable bioenergy production in Indonesia,” Biodivers-Biotrop Science Magazine, vol. 1, no. 2, pp. 21-26, 2022.
[8] Polaris Market Research & Consulting LLP, Global Wood Pellet Market from 2024 to 2032- Report by Polaris Market Research (PMR). https://finance.yahoo.com/news/global-wood-pellet-market-worth-125000282.html? accessed on 2 July 2024.
[9] P. Križan, M. Matúš, L. Šooš, and J. Beniak, “Behavior of beech sawdust during densification into a solid biofuel,” Energies, vol. 8, no. 7, pp. 6382-6398, 2015.
[10] Malaysian Timber Industry Board, “Development of Forest Plantation Programme,” https://www.mtib.gov.my/-en/services/forest-plantation/development-of-forest-plantation, accessed on 28 November 2023
[11] R. Amirta, T. Anwar, Sudrajat, Yuliansyah, and W. Suwinarti, “Trial production of fuel pellet from Acacia mangium bark waste biomass,” In IOP Conference Series: Earth and Environmental Science, vol. 144, no. 1, p. 012040, 2018.
[12] R. Picchio, R. Spina, A. Sirna, A. L. Monaco, V. Civitarese, A. D. Giudice AD, et al., “Characterization of woodchips for energy from forestry and agroforestry production,” Energies, vol. 5, no. 10, pp. 3803-3816, 2012.
[13] C. Whittaker and I. Shield, “Factors affecting wood, energy grass and straw pellet durability–A review,” Renewable and Sustainable Energy Reviews, vol. 71, pp. 1-11, 2017.
[14] M. E. Mostafa, S. Hu, Y. Wang, S. Su, X. Hu, S. A. Elsayed, et al., “The significance of pelletization operating conditions: An analysis of physical and mechanical characteristics as well as energy consumption of biomass pellets,” Renewable and Sustainable Energy Reviews, vol. 105, pp. 332-348, 2019.
[15] C. Tenorio, R. Moya, and J. Valaert, “Characterisation of pellets made from oil palm residues in Costa Rica,” Journal of Oil Palm Research, vol. 28, pp. 198-210, 2016.
[16] M. Stasiak, M. Molenda, M. Bańda, J. Wiącek, P. Parafiniuk, and E. Gondek, “Mechanical and combustion properties of sawdust—Straw pellets blended in different proportions,” Fuel Processing Technology, vol. 156, pp. 366-75, 2017.
[17] Z. Liu, X. Liu, B. Fei, Z. Jiang, Z. Cai, and Y. Yu, “The properties of pellets from mixing bamboo and rice straw,” Renewable Energy, vol. 55, pp. 1-5, 2013.
[18] T. Winowiski, “Wheat and pellet quality,” Feed Management, vol. 39, pp. 58-64, 1988.
[19] Z. Liu, B. Mi, Z. Jiang, B. Fei, Z. Cai, and X. Liu, “Improved bulk density of bamboo pellets as biomass for energy production,” Renewable Energy, vol. 86, pp. 1-7, 2016.
[20] EN U. Solid Biofuels. Determination of Mechanical Durability of Pellets and Briquettes-Part 1: Pellets. 2009.
[21] British Standard EN 15148. Solid biofuels-Determination of volatile matter. British Standards Institution, London, 2009b.
[22] British Standard EN 14775, Solid biofuels-Determination of ash content. British Standards Institution, London, 2009c.
[23] British Standard EN 14774-2, Solid biofuels Determination of moisture content–Oven dry method. British Standards Institution, London, 2009a.
[24] F. N. Maluin, M. Z. Hussein, and A. S. Idris, “An overview of the oil palm industry: Challenges and some emerging opportunities for nanotechnology development,” Agronomy, vol. 10, no. 3, p. 356, 2020.
[25] M. H. M. Amini, M. S. M. Rasat, M. Mohamed, R. Wahab, N. H. Ramle, I Khalid, et al., “Chemical composition of small diameter wild Acacia mangium species,” APRN Journal of Engineering and Applied Sciences, vol. 12, no. 8, pp. 2698-2702, 2017.
[26] J. S. Tumuluru, “Effect of pellet die diameter on density and durability of pellets made from high moisture woody and herbaceous biomass,” Carbon Resources Conversion, vol. 1, no. 1, pp. 44-54, 2018.
[27] R. Azargohar, S. Nanda, and A. K. Dalai, “Densification of agricultural wastes and forest residues: A review on influential parameters and treatments,” Recent advancements in biofuels and bioenergy utilization, pp. 27-51, 2018.
[28] L. Sikanen and T. Vilppo, “Small scale pilot combustion experiments with wood pellets–the effect of pellet length,” The Open Renewable Energy Journal, vol. 5, no. 1, pp. 1-6, 2012.
[29] W. Stelte, J. K. Holm, A. R. Sanadi, S. Barsberg, J. Ahrenfeldt, and U. B. Henriksen, “Fuel pellets from biomass: The importance of the pelletizing pressure and its dependency on the processing conditions,” Fuel, vol. 90, no. 11, pp. 3285-3290, 2011.
[30] Y. Chen, S. S. A. Syed-Hassan, Q. Li, Z. Deng, X. Hu, J. Xu, et al., “Effects of temperature and aspect ratio on heterogeneity of the biochar from pyrolysis of biomass pellet,” Fuel Processing Technology, vol. 235, p. 107366, 2022.
[31] A. Zafari and M. H. Kianmehr, “Effect of raw material properties and die geometry on the density of biomass pellets from composted municipal solid waste,” BioResources, vol. 7, no. 4, pp. 4704-4714, 2012.
[32] J. S. Tumuluru, “Specific energy consumption and quality of wood pellets produced using high-moisture lodgepole pine grind in a flat die pellet mill,” Chemical Engineering Research and Design, vol. 110, pp. 82-97, 2016.
[33] D. R. Nhuchhen and P. A. Salam, “Estimation of higher heating value of biomass from proximate analysis: A new approach,” Fuel, vol. 99, pp. 55-63, 2012.
[34] J. Huang, “Low ash content bio-materials for pellet plant,” https://www.biofuelmachines.com/Low-ash-content- bio-materials-for-pellet-plant.html. Accessed on 24 November 2023.
[35] Senila L, Tenu I, Carlescu P, Corduneanu OR, Dumitrachi EP, Kovacs E, Scurtu DA, Cadar O, Becze A, Senila M, Roman M. “Sustainable biomass pellets production using vineyard wastes,” Agriculture, vol. 10, 11, p. 501, 2020.
[36] GEMCO Energy, “What is the ash content of wood pellets?” http://www.gemcopelletmills.com/wood-pellets-ash- content.html. Accessed on 24 November 2023.
[37] I. Obernberger, T. Brunner, and G. Bärnthaler, “Chemical properties of solid biofuels—significance and impact,” Biomass and Bioenergy, vol. 30, no. 11, pp. 973-982, 2006.
[38] M. N. Acda and E. E. Devera, “Physico-chemical properties of wood pellets from forest residues,” Journal of Tropical Forest Science, vol. 2014, pp. 589-595, 2014.
[39] J. P. Carroll and J. Finnan, “Physical and chemical properties of pellets from energy crops and cereal straws,” Biosystems Engineering, vol. 112, no. 2, pp. 151-159, 2012.
[40] N. L. Mustelier, M. F. Almeida, J. Cavalheiro, and F. Castro, “Evaluation of pellets produced with undergrowth to be used as biofuel,” Waste and Biomass Valorization, vol. 3, no. 3, pp. 285-294, 2012.
[41] B. R. Souza, M. D. de Moraes, F. S. Braboza, A. Coneglian, and C. R. Sette Jr, “The presence of bark in Acacia mangium wood improves its energetic potential,” Floresta, vol. 51, no. 1, pp. 54-60, 2021.
[42] N. A. Muda, H. Yoshida, H. Ishak, M. H. Ismail, and S. Izhar, “Production and properties of solid biochar from oil palm trunk waste using sub-critical water technology,” Journal of Oil Palm Research, vol. 32, no. 3, pp. 526-536, 2020.
[43] A. B. Nasrin, S. Vijaya, S. K. Loh, A. A. Astimar, and W. S. Lim, “Quality compliance and environmental impact assessment of commercial empty fruit bunch (EFB) pellet fuel in Malaysia,” Journal of Oil Palm Research, vol. 29, no. 4, pp. 570-578, 2017.
[44] A. Žandeckis, V. Kirsanovs, M. Dzikevičs, and D. Blumberga, “Experimental study on the optimisation of staged air supply in the retort pellet burner,” Agronomy Research, vol. 11, no. 2, pp. 381-390, 2013.
[45] H. M. Faizal, M. A. Jusoh, M. R. Rahman, S. Syahrullail, and Z. A. Latiff, “Torrefaction of palm biomass briquettes at different temperature,” Jurnal Teknologi (Sciences & Engineering), vol. 78, no. 9-2, pp. 61-67, 2016.
[46] S. Krishnan, M. Nasrullah, and S. Mohamad, “Effect of pellet size and adhesive ratio on the production of kenaf pellet as a fossil fuel,” Journal of Chemical Engineering and Industrial Biotechnology, vol. 8, no. 1, pp. 14-17, 2022.
[47] F. Z. Mansur, C. K. Faizal, N. A. Fazli, S. M. Atnaw, and S. A. Sulaiman, “Experimental studies on gasification performance of sawdust and sawdust pellet in a downdraft biomass gasifier,” Journal of Chemical Engineering and Industrial Biotechnology, vol. 5, no. 2, pp. 22-28, 2019.
[48] Y. Kazancoglu, Y. Berberoglu, C. Lafci, O. Generalov, D. Solohub, and V. Koval, “Environmental sustainability implications and economic prosperity of integrated renewable solutions in urban development,” Energies, vol. 16, no. 24, p. 8120, 2023.
[49] L. Goldšteins, M. G. Dzenis, V. Šints, R. Valdmanis, M. Zaķe, and A. Arshanitsa, “Microwave pre-treatment and blending of biomass pellets for sustainable use of local energy resources in energy production,” Energies, vol. 15, no. 9, p. 3347, 2022.
[50] G. Zając, J. Szyszlak-Bargłowicz, and M. Szczepanik, “Influence of biomass incineration temperature on the content of selected heavy metals in the ash used for fertilizing purposes,” Applied Sciences, vol. 9, no. 9, p. 1790, 2019.
[51] G. Zając, J. Szyszlak-Bargłowicz, W. Gołębiowski, and M. Szczepanik, “Chemical characteristics of biomass ashes,” Energies, vol. 11, no. 11, p. 2885, 2018.
[52] D. Trejo‐Zamudio, C. Gutiérrez‐Antonio, J. F. García‐Trejo, A. A. Feregrino‐Pérez, and M. Toledano‐Ayala, “Production of fuel pellets from bean crop residues (Phaseolus vulgaris),” IET Renewable Power Generation, vol. 16, no. 14, pp. 2978-2987, 2022.
[53] M. Pazalja, M. Salihović, J. Sulejmanović, A. Smajović, S. Begić, S. Špirtović-Halilović, an F. Sher, “Heavy metals content in ashes of wood pellets and the health risk assessment related to their presence in the environment,” Scientific Reports, vol. 11, no. 1, p. 17952, 2021.
[54] M. Kuokkanen, T. Kuokkanen, T. Stoor, J. Niinimäki, and V. Pohjonen, “Chemical methods in the development of eco-efficient wood-based pellet production and technology,” Waste Management & Research, vol. 27, no. 6, pp. 561-571, 2009.
[55] DIN 51731. Testing of solid fuels—compressed untreated wood, requirements and testing.
[56] A. Balžekienė and A. Budžytė, “The role of environmental attitudes in explaining public perceptions of climate change and renewable energy technologies in Lithuania,” Sustainability, vol. 13, no. 8, p. 4376, 2021.
[57] A. Nuriana, M. I. Setiawan, S. Fitri, and G. S. Laksito, “A review of renewable energy infrastructure trends literature: A case study of Shopping Mall, Pasar Gedhe Klaten, Indonesia,” International Journal of Industrial Engineering, Technology & Operations Management, vol. 1, no. 2, pp. 65-72, 2023.
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