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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 1188Mathematical Modeling of Combustion...

Mathematical Modeling of Combustion Characteristics of Agricultural Waste Briquettes

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Abstract:

Rapid population increase coupled with industrialization has led to rise in global energy demand leading to skyrocketing of energy prices. Diversification in energy resources is essential to reduce overdependence on certain resources. Agricultural wastes remain a promising energy resource to be exploited. Laboratory experimental analysis is time consuming and costly. This fueled the adoption of modelling as an alternative to laboratory analysis. Different models such as computational fluid dynamics (CFD), artificial neural network (ANN), and ANFIS fuzzy logic have been used by various researchers. Buckingham pie theorem together with MATLAB was used in this research to evaluate the properties and combustion characteristics of assorted agricultural wastes. The properties modelled were; porosity, density, shatter resistance, higher heating values, burnout time, burning rate, ignition time and efficiency. The factors that affect each of the properties negatively and positively were determined from the models. The significance of each property and characteristics were articulated. The limitations and assumptions of the models were also highlighted. It is recommended that further research incorporating artificial intelligence in the models needs to be exploited aid in reduction of experimental analysis costs and time. Other agricultural wastes which have not been characterized for need to exploited. This will further reduce overdependence on conventional resources such as fossil fuels which are not only getting depleted at an alarming rate but also led to environmental degradation.

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Periodical:

Advanced Materials Research (Volume 1188)

Pages:

87-108

DOI:

https://doi.org/10.4028/p-zt4Imp

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Online since:

February 2026

Authors:

Ondari Brian Overmars*, Stephen Kimutai, Emmanuel Mukubwa

Keywords:

Agricultural Waste, Briquette, Buckingham Pie Theorem, Modelling, Renewable Energy

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© 2026 Trans Tech Publications Ltd. All Rights Reserved

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[1] Yuzhuo Wang, Jun Jie Wu, "Thermochemical conversion of biomass: Potential future prospects", (2023)

DOI: 10.1016/j.rser.2023.113754

[2] Ondari Brian, "Biomass Energy from Agricultural Waste: Evaluating Groundnut Vines and Pumpkin Straws for Combustion Performance". Journal of Energy Research and Reviews 16(10):26-36, (2024)

DOI: 10.9734/jenrr/2024/v16i10375

[3] Zezhi Peng and Jian Sun, "Biomass burning enhanced human exposure risks in the context of global warming", (2025)

DOI: 10.20517/jeea.2024.43

[4] Park H., Jeong S., Peñuelas J., "Accelerated rate of vegetation green-up related to warming at northern high latitudes. Glob. Chang. Bio.", (2020), 6190-202

DOI: 10.1111/gcb.15322

[5] Esra Yilmaz Mertsoy, "Comparison of 2D and 3D numerical simulation of woody biomass combustion in fuidized bed reactor", (2025)

DOI: 10.1007/s13399-025-06689-0

[6] Joao Silva, Senhorinha Teixeira and Jose Teixeira, "A Review of Biomass Thermal Analysis, Kinetics and Product Distribution for Combustion Modeling: From the Micro to Macro Perspective", (2023)

DOI: 10.3390/en16186705

[7] Diakaridia Sangare, Veronica Belandria, Stephane Bostyn and Mario Moscosa-Santillan, "Comparative Analysis of CFD Modeling and Process Simulation for Pyro-Gasification of Biomass", (2025)

DOI: 10.15376/biores.20.2.2844-2870

[8] Mohammad Hosseini Rahdar, Fuzhan Nasiri and Bruno Lee, "A Review of Numerical Modeling and Experimental Analysis of Combustion in Moving Grate Biomass Combustors", (2019)

DOI: 10.1021/acs.energyfuels.9b02073

[9] Pradeep Khatri, Tadahiro Hayasaka, Prabir K. Patra, Husi Letu, Hiren Jethva and Sachiko Hayashida , "Unveiling the effects of post-monsoon agricultural biomass burning on aerosols, clouds, and radiation in Northwest India" (2025)

DOI: 10.1186/s40645-025-00685-8

[10] Dinesh Kumar, Hemant Kumar and Amandeep S. Oberoi, "Recent advances in co-firing of biomass and other fuels in fluidised systems: a review", (2025), https: //doi.org/

DOI: 10.1080/13647830.2025.2475169

[11] Ozge Cepeliogullar Mutlu and Zeng Thomas , "Challenges and Opportunities of Modeling Biomass Gasification in Aspen Plus: A Review", (2020)

DOI: 10.1002/ceat.202000068

[12] German Navarrete Cereijo, Pedro Galione Klot and Pedro Curto-Risso, "Two-Stage Global Biomass Pyrolysis Model for Combustion Applications: Predicting Product Composition with a Focus on Kinetics, Energy, and Mass Balances Consistency", (2024)

DOI: 10.2139/ssrn.4656701

[13] Kraszkiewicz, A. "Influence of Geometrical Features of Solid Biofuels on the Implementation of the Combustion Process. Combustion Science and Technology", 195(10), 2456–2473. (2023)

DOI: 10.1080/00102202.2021.2020263

[14] Ikubanni, P. P., Agboola, O. O., Olabamiji, T. S., Adediran, A. A., Anisere, T., & Oladimeji, S. "Development and performance assessment of piston-type briquetting machine. IOP Conference Series: Earth and Environmental Science", 445(1), 012005. (2020). https://iopscience.iop.org/article/

DOI: 10.1088/1755-1315/445/1/012005/

[15] Oyelaran, O. A., Bolaji, B. O., Waheed, M. A., & Adekunle, M. F. "Characterization of briquettes produced from groundnut shell and waste paper admixture. Iranica Journal of Energy & Environment", (2015). 6(1).

DOI: 10.5829/idosi.ijee.2015.06.01.07

[16] Galadima, Z. A., Shaibu, M., Mohammed, Z. S., Onoja, E., & Samaila, A. A. "Utilization of Groundnut Shells for the Production and Characterization of Bio-Briquettes for Household Cooking. Asian Journal of Science and Applied Technology", (2024). 13(2), 1–5.

DOI: 10.70112/ajsat-2024.13.2.4232

[17] Garikai T. Marangwanda, Daniel M. Madyira and Taiwo O. Babarinde, "Combustion models for biomass: A review". Energy Reports 6 (2020) 664–672

DOI: 10.1016/j.egyr.2019.11.135

[18] Filipe Neves, Armando A. Soares and Abel Rouboa, "Numerical Study of Biomass Combustion Using a Transient State Approach", (2024).

DOI: 10.3390/pr12122800

[19] Gabriel Fernando Garcia Sanchez, Jorge Luis Chacon Velasco, David Alfredo Fuentes Diaz, Yesid Javier Rueda-Ordonez, David Patino, Juan Jesus Rico and Jairo Rene Martínez Morales, "Biomass Combustion Modeling Using Open FOAM: Development of a Simple Computational Model and Study of the Combustion Performance of Lippia origanoides Bagasse", (2023).

DOI: 10.3390/en16062932

[20] Abiodun Ismail Lawal, Adeyemi Emman Aladejare, Moshood Onifade, Samson Bada5, Musa Adebayo Idris, "Predictions of elemental composition of coal and biomass from their proximate analyses using ANFIS, ANN and MLR", (2020)

DOI: 10.1007/s40789-020-00346-9

[21] Rownak Raihan and Muhibur Rahman Saad. "Numerical Modelling of Biomass Combustion in a Large-scale Industrial Furnace", (2023).

[22] Brown, R.C., Thermochemical Processing of Biomass: "Conversion into Fuels, Chemicals", and Power, 2nd ed.; Jonh Wiley & Sons: Hoboken, NJ, USA, (2019).

[23] Miao Yang, Shenghui Zhong, Shijie Xu, Peter Ottosson, Hesameddin Fatehi and Xue-Song Bai, "CFD Simulation of Biomass Combustion in an Industrial Circulation Fluidized Bed Furnace". Vol. 195, No. 14, (2023), 3310-3340

DOI: 10.1080/00102202.2023.2260553

[24] Florin Popescu, Razvan Mahu, Ion V. Ion and Eugen Rusu, "A Mathematical Model of Biomass Combustion Physical and Chemical Processes", (2020).

DOI: 10.3390/en13236232

[25] Onifade M., "Spontaneous combustion liability of coals and coal-shales in the South African coalfields". A PhD Thesis, University of the Witwatersrand, Johannesburg, South Africa, (2018).

[26] Shen J., Zhu S., Liu X., Zhang H. and Tan J., "The prediction of elemental composition of biomass based on proximate analysis". Energy Convers Manage, (2010), 51:983–987

DOI: 10.1016/j.enconman.2009.11.039

[27] ANSYS. ANSYS CFX-Solver theory guide. Ansys Cfx. 2009.

[28] Nhuchhen D. R., "Prediction of carbon, hydrogen, and oxygen compositions of raw and torrefied biomass using proximate analysis". Fuel, (2016), 180:348–356

DOI: 10.1016/j.fuel.2016.04.058

[29] Jong Y. H, Lee C. I., "Influence of geological conditions on the powder factor for tunnel blasting". Int J Rock Mech Min 41:533–538, (2004).

DOI: 10.1016/j.ijrmms.2004.03.095

[30] Veijonen K., Vainikka P., Jarvinen T., Alakangas E., "VTT Processes, Biomass co-firing an efficient way to reduce greenhouse gas emissions. Finland", (2003).

[31] Bhuiyan AA, Naser J., "CFD modelling of co-firing of biomass with coal under oxy-fuel combustion in a large-scale power plant". Fuel159:150–68, (2015).

DOI: 10.1016/j.fuel.2015.06.058

[32] Ma L, Jones J. M., Pourkashanian M, Williams A., "Modelling the combustion of pulverized biomass in an industrial combustion test furnace". Fuel; 86:1959–65, (2007).

DOI: 10.1016/j.fuel.2006.12.019

[33] Yin C., Rosendahl L., Kaer S. K., Condra T. J., "Use of numerical modelling in design for co-firing biomass in wall-fired burners". Chem Eng. Sci; 59:3281–92.

DOI: 10.1016/j.ces.2004.04.036

[34] Tabet F., (2004). Gokalp I., (2015), Review on CFD based models for co-firing coal and biomass. Renew Sustain Energy Rev; 51:1101–14

DOI: 10.1016/j.rser.2015.07.045

[35] Model AF., "Advanced fuel-devolatilization model": FG-DVC, (1990), p.1–8.

[36] Ma L., Gharebaghi M., Porter R., Pourkashanian M., Jones J. M., Williams A., "Modelling methods for co-fired pulverised fuel furnaces. Fuel"; 88:2448–54, (2009).

DOI: 10.1016/j.fuel.2009.02.030

[37] Perez-Jeldres RR, Cornejo P, Flores M, Gordon A, Garcia X, "A modelling approach to co-firing biomass/coal blends in pulverized coal utility boilers: Synergistic effects and emissions profiles. Energy"; 120:663–74, (2017).

DOI: 10.1016/j.energy.2016.11.116

[38] Tillman D. A., Biomass cofiring: "The technology, the experience, the combustion consequences. Biomass Bioenergy"; 19:365–84, (2000).

DOI: 10.1016/s0961-9534(00)00049-0

[39] Zha Q., Li D., Wang C., Che D., "Numerical evaluation of heat transfer and NOx emissions under deep-air-staging conditions within a 600 MWe tangentially fired pulverized-coal boiler. Apple Therm. Eng".; 116:170–81, (2017).

DOI: 10.1016/j.applthermaleng.2016.12.088

[40] Hurt R. H, Calo J. M., "Semi-global intrinsic kinetics for char combustion modelling. Combust Flame"; 125:1138–49, (2001).

[41] Bhuiyan A. A., Blicblau AS, Islam AKMS, Naser J., "A review on thermo-chemical characteristics of coal/biomass co-firing in industrial furnace. J Energy Inst"; 91:1–18, (2018).

DOI: 10.1016/j.joei.2016.10.006

[42] Pallares J., Gil A., Cortes C., Herce C., Numerical study of co-firing coal and cynara cardunculus in a 350 MWe utility boiler. Fuel Process Technol; 90:1207–13, (2009).

DOI: 10.1016/j.fuproc.2009.05.025

[43] Yu J., Zhang M. C., "Experimental and modelling study on char combustion. Energy Fuels"; 23:2874–85, (2009).

[44] Alvarez L, Yin C, Riaza J, Pevida C, Pis JJ, Rubiera F., "Biomass co-firing under oxy-fuel conditions: A computational fluid dynamics modelling study and experimental validation. Fuel Process Technol"; 120:22–33, (2014).

DOI: 10.1016/j.fuproc.2013.12.005

[45] Farokhi M, Birouk M., "Application of eddy dissipation concept for modelling biomass combustion, part 2: Gas-phase combustion modelling of a small-scale fixed bed furnace. Energy Fuels"; 30:10800–8, (2016).

DOI: 10.1021/acs.energyfuels.6b01948

[46] Mardani A., "Optimization of the eddy dissipation concept (EDC) model for turbulence-chemistry interactions under hot diluted combustion of CH4/H2. Fuel"; 191:114–29, (2017).

DOI: 10.1016/j.fuel.2016.11.056

[47] Dumka, P., Chauhan, R., Singh, A., Singh, G., & Mishra, D. "Implementation of Buckingham's Pi theorem using Python. Advances in Engineering Software", 173, 103232

DOI: 10.1016/j.advengsoft.2022.103232

[48] Ciulla, G., D'Amico, A., & Lo Brano, V. "Evaluation of building heating loads with dimensional analysis: Application of the Buckingham π theorem. Energy and Buildings", 154, 479–490

DOI: 10.1016/j.enbuild.2017.08.043

[49] Parsons, N., & Huebsch, W. "Automated Dimensional Analysis Through MATLAB®". 2024 Regional Student Conferences

DOI: 10.2514/6.2024-85776

[50] L. Abdullahi, M. Abubakar and B. Ndagi, "Effect of Compaction Pressure and Biomass Type (Rice Husks and Sawdust) on some Physical and Combustion Properties of Briquettes", (2021).

[51] Peter Aguko Kabok, Daudi M Nyaanga, Jesca Makena Mbugua and Reinilde Eppinga, "Effect of Shapes, Binders and Densities of Faecal Matter– Sawdust Briquettes on Ignition and Burning Times", (2018)

DOI: 10.4172/2157-7463.1000370

[52] Haifan Liao, Kuang Yang, Zhicheng Liang, Hongfei Hu, Xinying Wang, "A new paradigm in critical flow analysis: Combining Buckingham Pi theorem with neural network for improved predictions in microchannels.", (2024)

DOI: 10.1016/j.ces.2024.120483

[53] Sevda Tasan and Yusuf Demir, "Comparative Analysis of MLR, ANN, and ANFIS Models for Prediction of Field Capacity and Permanent Wilting Point for Bafra Plain Soils", 2020;

DOI: 10.1080/00103624.2020.1729374

[54] Mingliang Ma, Abolfazl Safikhani, "Theoretical analysis of deep neural networks for temporally dependent observations", (2022)

[55] Lijun Wang, Samuel A. Agyemang, Hossein Amini and Abolghasem Shahbazi "Mathematical modeling of production and biorefinery of energy crops", (2015)

DOI: 10.1016/j.rser.2014.11.008

[56] Biljana Miljkovic, Ivan Pesenjanski, Marija Vicevic, "Mathematical modelling of straw combustion in a moving bed combustor: A two-dimensional approach", (2013)

DOI: 10.1016/j.fuel.2012.08.017

[57] Sri Suryaningsih, Otong Nurhilal, R A Widyarini and Nendi Suhendi, "The analysis of ignition and combustion properties of the burning briquettes made from mixed biomass of rice husk and corn cob", (2019),;

DOI: 10.1088/1757-899X/550/1/012006

[58] Mingjun Wu, Kexin Wei, Jinxuan Jiang, Ben Bin Xu & Shengbo Ge "Advancing green sustainability: A comprehensive review of biomass briquette integration for coal-based energy frameworks", Volume 12, article number 44, (2025)

DOI: 10.1007/s40789-025-00779-0

[59] Jack Huang, "Factors That Influence Your Briquettes Burning", August 11, (2014)

[60] Jiangkuan Xing, Kun Luo, Haiou Wang, Zhengwei Gao and Jianren Fan "A comprehensive study on estimating higher heating value of biomass from proximate and ultimate analysis with machine learning approaches", (2019)

DOI: 10.1016/j.energy.2019.116077

[61] Abineno, J. C., Dethan, J. J., Haba Bunga, F. J., & Bunga, E. Z. H., "Characterization and performance analysis of Kesambi branch biomass briquettes": A study on particle size effects. Journal of Ecological Engineering, 26(1), (2025). https://www.jeeng.net/pdf-195643-116904

DOI: 10.12911/22998993/195643

[62] Aransiola, E. F., Oyewusi, T. F., Osunbitan, J. A., & Ogunjimi, L. A. O. "Effect of binder type, binder concentration and compacting pressure on some physical properties of carbonized corncob briquette" (2019). Energy Reports, 5, 909–918.

DOI: 10.1016/j.egyr.2019.07.011

[63] Fredrik, H., Bunga. "Sustainable Briquette Production from Hazelnut Shell Waste: The Significance of Particle Size in Quality Enhancement" (2025). Volume 08(Issue 03)

DOI: 10.47191/ijcsrr/V8-i3-19

[64] Kaur, A., Kumar, A., Singh, P., & Kundu, K. "Production, analysis and optimization of low-cost briquettes from biomass residues". Advances in Research, (2017)

DOI: 10.9734/air/2017/37630

[65] Oladeji, J. T., & Enweremadu, C. C. "A predictive model for the determination of some densification characteristics of corncob briquettes", (2013).

[66] Raju, C., Rao, D. P., Madhuri, N., Prem, K., & Rao, P. J. "Studies on Manufacture of Fuel Briquettes and Their Assessment for Higher Calorific Values Estimation", (2017).

[67] Rashif, M. N., Hartini, S., Sari, D. P., Ramadan, B. S., Matsumoto, T., & Balasbaneh, A. T. "Life cycle assessment of biomass waste briquettes as renewable energy. Global Journal of Environmental Science and Management", 11(1), (2025)

[68] Roy, M. M., & Corscadden, K. W. "An experimental study of combustion and emissions of biomass briquettes in a domestic wood stove". Applied Energy, 99, 206–212, (2012)

DOI: 10.1016/j.apenergy.2012.05.003