HomeAnnals of Tropical Researchvol. 48 no. 1 (2026)

Optimization of Cocoyam (Xanthosoma sagittifolium) Corm Flour as Binder for Charcoal Briquettes Produced from Coconut Shell Charcoal

Julious B. Cerna | Nilo Leorna | Vladimer Mangaya-ay

 

Abstract:

Background: Coconut shell charcoal briquettes serve as a primary energy source for domestic and commercial cooking. While these products traditionally utilize cassava or corn starch as binders, such materials are essential food staples. Objectives: To reduce the non-food utilization of these crops, this study evaluates cocoyam corm flour – a resource of lower economic and food value – as a sustainable binding agent. Methods: Through a 3x3 factorial experiment, the research analyzed the influence of the binder-to-charcoal ratio and flour fineness on the chemical, physical, and combustion properties of the resulting fuel. Results: A higher binder-to-charcoal ratio produces denser briquettes with reduced ash content, slower burning rates, and enhanced structural durability. Optimization via Response Surface Methodology identified a formulation with a 0.379 binder-to-charcoal ratio and a 149-micron flour fineness. The optimum briquette achieved a fixed carbon content of 20.63% -3 and a density of 0.39g cm , demonstrating properties superior to those of the commercial counterpart, including higher compressive strength and more stable combustion. Furthermore, the optimum briquette demonstrated a break-even price three times lower than a commercial alternative, highlighting the significant economic viability and investment efficiency of utilizing cocoyam corm flour as a low-cost binder for sustainable biomass energy. Conclusion: Cocoyam corm flour can be a cost-effective and sustainable alternative binder that enhances the structural, combustion, and economic performance of coconut shell charcoal briquettes while reducing reliance on food-grade materials.



References:

  1. Abdulkareem, S., Hakeem, B. A., Ahmed, I. I., Ajiboye, T. K., Adebisi, J. A., & Yahaya, T. (2018). Combustion characteristics of bio-degradable biomass briquettes. DOAJ: Directory of Open Access Journals, 13(9), 2779–2791. https://doaj.org/article/636b576daac44b0abdcaad281bf93870
  2. Adam, S. N. F. S., Aiman, J. H. M., Zainuddin, F., & Hamdan, Y. (2021). Processing and characterisation of charcoal briquettes made from waste rice straw as a renewable energy alternative. Journal of Physics: Conference Series, 2080(1), 012014. https://doi.org/10.1088/1742-6596/2080/1/012014
  3. Ajimotokan, H. A., Ehindero, A. O., Ajao, K. S., Adeleke, A. A., Ikubanni, P. P., & Shuaib-Babata, Y. L. (2019). Combustion characteristics of fuel briquettes made from charcoal particles and sawdust agglomerates. Scientific African, 6, e00202. https://doi.org/10.1016/j.sciaf.2019.e00202
  4. Akowuah, J. O., Kemausuor, F., & Mitchual, S. J. (2012). Physico-chemical characteristics and market potential of sawdust charcoal briquette. International Journal of Energy and Environmental Engineering, 3(1), 20. https://doi.org/10.1186/2251-6832-3-20
  5. Anggraeni, S., Putri, S. R., Nandiyanto, A. B. D., & Bilad, M. R. (2021). Effect of particle size and tapioca starch content on performance of the rice husk and red bean skin briquettes. Journal of Engineering Science and Technology, 16(2), 1733–1745. https://jestec.taylors.edu.my/Vol%2016%20issue%202%20April%202021/16_2_59.pdf
  6. Aransiola, E. F., Oyewusi, T. F., Osunbitan, J. A., & Ogunjimi, L. A. O. (2019). Effect of binder type, binder concentration and compacting pressure on some physical properties of carbonized corncob briquette. Energy Reports, 5, 909–918. https://doi.org/10.1016/j.egyr.2019.07.011
  7. Borowski, G., Stępniewski, W., & Wójcik-Oliveira, K. (2017). Effect of starch binder on charcoal briquette properties. International Agrophysics, 31(4), 571–574. https://doi.org/10.1515/intag-2016-0077
  8. Brožek, M. (2016). The effect of moisture of the raw material on the properties briquettes for energy use. Acta Universitatis Agriculturae et Silviculturae Mendelianae Brunensis, 64(5), 1453–1458. https://doi.org/10.11118/actaun201664051453
  9. Calle, J., Gasparre, N., Benavent-Gil, Y., & Rosell, C. M. (2021). Aroids as underexplored tubers with potential health benefits. Advances in food and nutrition research, 97, 319–359. https://doi.org/10.1016/bs.afnr.2021.02.018
  10. Chipangura, W., Masauli, B., Mungwari, C. P., Nyamunda, B. C., Madziwa, T. N., Nyathi, L., Tom, H. T., & Chigondo, M. (2024). Fabrication of briquettes from charcoal fines using tannin formaldehyde resin as a binder. European Journal of Sustainable Development Research, 8(1), em0249. https://doi.org/10.29333/ejosdr/14125
  11. Dewi, R. N., Perceka, M. L., Utari, S. P. S. D., Andrayuga, I. W., Azimatun, M. M. N., Qurrahman, T., Arifin, S., Ardiyanti, P. A., Pajriyanti, N., & Irwandi, N. A. (2025). Comparative study on bio-briquette production using coconut shell and seashell: Effects of size, ratio, pyrolysis, and binder. Indonesian Fisheries Research Journal 31(1), 9–22. https://ejournal-balitbang.kkp.go.id/index.php/ifrj/article/viewFile/15405/9685
  12. El-Haggar, S. (2007). Sustainability of agricultural and rural waste management. In Sustainability of agricultural and rural waste management (pp. 223–260). Elsevier. https://doi.org/10.1016/b978-012373623-9/50009-5
  13. Ige, A. R., Ogala, H.,  Elinge, C. M., & Habeeb, A. (2020). The effect of binder ratio on the physical and combustion characteristics of carbonized rice stalk briquettes. International Journal of Advanced Academic Research, 221–229. https://doi.org/10.46654/ij.24889849.e6101
  14. Ikelle, I. I., Chukwuma, A., & Ivoms, O. S. P. (2014). The characterization of the heating properties of briquettes of coal and rice husk. IOSR Journal of Applied Chemistry, 7(5), 100–105. https://doi.org/10.9790/5736-0752100105
  15. Ismail, B. P. (2017). Ash content determination. In Food science text series (pp. 117–119). https://doi.org/10.1007/978-3-319-44127-6_11
  16. Jahirul, M. I., Rasul, M. G., Chowdhury, A. A., & Ashwath, N. (2012). Biofuels production through biomass pyrolysis—A technological review. Energies, 5(12), 4952–5001. https://doi.org/10.3390/en5124952
  17. Jamali, F., Mousavi, S. R., Peyma, A. B., & Moodi, Y. (2022). Prediction of compressive strength of fiber-reinforced polymers-confined cylindrical concrete using artificial intelligence methods. Journal of Reinforced Plastics and Composites, 41(17–18), 679–704. https://doi.org/10.1177/07316844211068116
  18. Khuenkaeo, N., & Tippayawong, N. (2019). Production and characterization of bio-oil and biochar from ablative pyrolysis of lignocellulosic biomass residues. Chemical Engineering Communications, 207(2), 153–160. https://doi.org/10.1080/00986445.2019.1574769
  19. Kpalo, S. Y., Zainuddin, M. F., Manaf, L. A., & Roslan, A. M. (2020). A review of technical and economic aspects of biomass briquetting. Sustainability, 12(11), 4609. https://doi.org/10.3390/su12114609
  20. Lestari, L., Variani, V. I., Sudiana, I. N., Sari, D. P., Ilmawati, W. O. S., & Hasan, E. S. (2017). Characterization of briquette from the corncob charcoal and sago stem alloys. Journal of Physics: Conference Series, 846, 012012. https://doi.org/10.1088/1742-6596/846/1/012012
  21. Li, J., Li, C., Wang, W., Zhang, W., & Li, J. (2016). Reactivity of larch and valonia tannins in synthesis of tannin formaldehyde resins. BioResources, 11(1), 2256–2268. https://doi.org/10.15376/biores.11.1.2256-2268
  22. Meincken, M., & Funk, S. (2014). Burning characteristics of low-cost safety charcoal briquettes made from wood residues and soil for domestic use. Agroforestry Systems, 89(2), 357–363. https://doi.org/10.1007/s10457-014-9772-8
  23. O’Hair, S. K., & Maynard, D. N. (2003). Edible aroids. In Vegetables of tropical climates (pp. 5970–5973). Elsevier. https://doi.org/10.1016/b0-12-227055-x/01245-1
  24. Obi, O. F., Pecenka, R., & Clifford, M. J. (2022). A review of biomass briquette binders and quality parameters. Energies, 15(7), 2426. https://doi.org/10.3390/en15072426
  25. Oladeji, J. T. (2010). Fuel characterization of briquettes produced from corncob and rice husk residues. The Pacific Journal of Science and Technology, 11(1), 101–106. https://www.akamai.university/files/theme/AkamaiJournal/PJST11_1_101.pdf
  26. Patil, D. P., Taulbee, D., Parekh, B. K., & Honaker, R. (2009). Briquetting of coal fines and sawdust—Effect of particle-size distribution. International Journal of Coal Preparation and Utilization, 29(5), 251–264. https://doi.org/10.1080/19392690903294423
  27. Richards, S. R. (1990). Physical testing of fuel briquettes. Fuel Processing Technology, 25(2), 89–100. https://doi.org/10.1016/0378-3820(90)90098-D
  28. Sawadogo, M., Tanoh, S. T., Sidibé, S., Kpai, N., & Tankoano, I. (2018). Cleaner production in Burkina Faso: Case study of fuel briquettes made from cashew industry waste. Journal of Cleaner Production, 195, 1047–1056. https://doi.org/10.1016/j.jclepro.2018.05.261
  29. Seboka, A. D., Morken, J., Adaramola, M. S., Ewunie, G. A., & Feng, L. (2025). Optimization of briquetting parameters and their effects on thermochemical fuel properties of biowaste briquettes. Bioresource Technology, 429, 133277. https://doi.org/10.1016/j.biortech.2025.133277
  30. Sen, R., Wiwatpanyaporn, S., & Annachhatre, A. P. (2016). Influence of binders on physical properties of fuel briquettes produced from cassava rhizome waste. International Journal of Environment and Waste Management, 17(2), 158–175. https://doi.org/10.1504/IJEWM.2016.076750
  31. Shiferaw, Y., Tedla, A., Melese, C., Mengistu, A., Debay, B., Selamawi, Y., Merene, E., & Awoi, N. (2017). Preparation and evaluation of clean briquettes from disposed wood wastes. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, 39(20), 2015–2024. https://doi.org/10.1080/15567036.2017.1399175
  32. Srivastava, N., Mishra, P. C., & Upadhyay, S. N. (2020). 1 - Significance of lignocellulosic biomass waste in the biofuel production process. Indistrial Enzymes for Biofuels Production: recent updates and future trends (pp. 1–18). Elsevier. https://doi.org/10.1016/b978-0-12-821010-9.00001-2
  33. Song, Y., Tumuluru, J. S., Iroba, K. L., Tabil, L. G., Xin, M., & Meda, V. (2010, June). Material and operating variables affecting the physical quality of biomass briquettes. In Proceedings of the 16th World Congress of the International Commission of Agricultural and Biosystems Engineering (CIGR) (pp. 13–17). Canadian Society for Bioengineering. https://www.academia.edu/download/77815521/Material_and_Operating_Variables_Affecti20211231-18509-1ovtufz.pdf
  34. Sun, B., Yu, J., Tahmasebi, A., & Han, Y. (2014). An experimental study on binderless briquetting of Chinese lignite: Effects of briquetting conditions. Fuel Processing Technology, 124, 243–248. https://doi.org/10.1016/j.fuproc.2014.03.013
  35. Tanko, S., Okafor, J. O., & Dim, P. E. (2023). Development and characterization of charcoal briquettes from shea butter seed shell. Journal of Chemical Technology and Metallurgy, 58(5), 865–873. https://doi.org/10.59957/jctm.v58i5.122
  36. Voicea, I., Danciu, A., Matache, M., Voicu, G., & Vladut, V. (2013). Biomass and the thermophysical-chemical properties related to the compaction process. Annals of Faculty Engineering Hunedoara – International Journal of Engineering, 11(1), 59–64. https://annals.fih.upt.ro/pdf-full/2013/ANNALS-2013-1-06.pdf
  37. Wahyuni, H., Aladin, A., Kalla, R., Nouman, M., Ardimas, A., & Chowdhury, M. S. (2022). Utilization of industrial flour waste as biobriquette adhesive: Application on pyrolysis biobriquette sawdust red teak wood. International Journal of Hydrology and Environmental Sustainability, 1(2), 54–69. https://doi.org/10.58524/ijhes.v1i2.74
  38. Yanti, R. N., Suarno, E., & Ratnaningsih, A. T. (2022). Karakteristik limbah biomassa kulit batang sagu sebagai bahan baku energi alternatif di Provinsi Riau. Jurnal Hutan Lestari, 10(3), 564–572. https://doi.org/10.26418/jhl.v10i3.58018
  39. Yiwang, B., Zhongzhe, J., & Li, S. (1994). Quantization of brittleness and impact modulus. Chinese Journal of Materials Research, 8(5), 419-423. https://www.cjmr.org/EN/Y1994/V8/I5/419
  40. Zepeda-Cepeda, C. O., Goche-Télles, J. R., Palacios-Mendoza, C., Moreno-Anguiano, O., Núñez-Retana, V. D., Heya, M. N., & Carrillo-Parra, A. (2021). Effect of sawdust particle size on physical, mechanical, and energetic properties of Pinus durangensis briquettes. Applied Sciences, 11(9), 3805. https://doi.org/10.3390/app11093805

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