Efficiency of preparation for solid fuel burning
Lviv Polytechnic National University
Autor do korespondencji
Taras Kravets   

Lviv Polytechnic National University
Mining Science 2022;29:205-220
The research presented in this study focuses on solid fuel and the process of preparing it for combustion. This topic is highly relevant as it plays a significant role in providing energy to the population and contributes to Ukraine's independence in the economic and energy sectors. Understanding the processes involved in solid fuel preparation is crucial for ensuring efficient energy production and minimizing negative environmental impacts. Therefore, this study aims to provide valuable insights into this area of research. The purpose of the work is to analyze the efficiency of preparation for burning solid fuel and to introduce effective tools that will allow to increase the efficiency of preparation to a new level. The article employed various methods to analyze the topic at hand, including the analytical method, deduction method, functional method, statistical method, synthesis method, and other relevant approaches. In the course of the research, the peculiarities of solid fuel and its differences with other sources from which energy is obtained were noted, errors in the preparation for the burning process of this object and the reasons for their appearance were analyzed. Ineffective methods of increasing the efficiency of preparation for burning solid fuel and their impact on the quality of this process were identified. It was determined that the process of burning solid fuel plays the most important role in increasing the efficiency of power plants of industrial enterprises and not only that.
Broumand M, Khan MS, Yun S, Hong Z, Thomson MJ (2021) Feasibility of running a micro gas turbine on wood-derived fast pyrolysis bio-oils: Effect of the fuel spray formation and preparation. Renewable Energy 178: 775-784. 10.1016/j.renene.2021.06.105.
Datta A, Das M, Ganguly R (2021) Design, development, and technological advancements in gas burners for domestic cook stoves: a review. Transactions of the Indian National Academy of Engineering 63: 569-593. 10.1007/s41403-021-00223-0.
Deshmukh PR, Lee H, Kim Y, Shin WG (2021) Ignition and oxidation performance of SnO2 coated boron particles: A solid fuel for energetic applications. Journal of Alloys and Compounds 886: 161123. 10.1016/j.jallcom.2021.161123.
Duan H, Jia M, Wang H, Li Y, Xia G (2023) Control of low-temperature polyoxymethylene dimethyl ethers (PODEn)/gasoline combustion considering fuel concentration, fuel reactivity, and intake temperature at low loads. Fuel 334: 126823. 10.1016/j.fuel.2022.126823.
Gao X, Liu C, Weng J, Wang C, Che D (2022) Effects of Combustion Organization on N()v Generation Behaviors During the Grate Co-firing of Bituminous Coal with Semi-coke. Coal Conversion 45(3): 1-10. 10.19726/j.cnki.ebcc.202203001.
Golyshev LV, Mysak IS, Dovgoteles GA, Sidenko AP, Kravets TYu (2001) The effect of coal quality on the limitation of the nominal capacity of a power unit. Thermal Engineering 48(7): 538-541.
Jach-Nocoń M, Pełka G, Luboń W, Mirowski T, Nocoń A, Pachytel P (2021) An assessment of the efficiency and emissions of a pellet boiler combusting multiple pellet types. Energies 1415: 4465. 10.3390/en14154465.
Jetter JJ, Kariher P (2009) Solid-fuel household cook stoves: Characterization of performance and emissions. Biomass and Bioenergy 332: 294-305. 10.1016/j.biombioe.2008.05.014.
Kim S, Moon H, Kim J (2015) Thermal characterizations of the paraffin wax/low density polyethylene blends as a solid fuel. Thermochimica Acta 613: 9-16. 10.1016/j.tca.2015.05.016.
Kolbasenko OV, Dymo BV (2022) Complex solution to the problem of increasing the technical, economic and environmental efficiency of boiler plants by means of plasma activation of the combustion of water-fuel emulsions. In: Materials of the IV International Maritime Scientific Conference of the Ship Power Plants and Technical Operation Department of Odessa National Maritime University (pp. 163-170). Odessa: National Maritime University.
Liang W, Wang G, Xu R, Ning X, Zhang J, Guo X, Wang C (2022) Hydrothermal carbonization of forest waste into solid fuel: Mechanism and combustion behavior. Energy 246: 123343. 10.1016/
Ma X, Jin S, Xie W, Liu Y, Zhang W, Chen Y (2022) A novel green electrically controlled solid propellant with good electrical response and high energy performance. Colloids and Surfaces A: Physicochemical and Engineering Aspects 641: 128550. 10.1016/j.colsurfa.2022.128550.
Mykhaylovska O, Bulgakov V (2022) Study of the effect of fly ash on the strength of soil cement. Grail of Science 17: 210-212.
Norchak VI (2022) Combustion of composite peat-coal mixtures in a vortex furnace. Collection of Scientific Works of the Ukrainian State University of Railway Transport 199: 23-31.
Pang W, Li Y, De Luca LT, Liang D, Qin Z, Liu X, Fan X (2021) Effect of metal nanopowders on the performance of solid rocket propellants: a review. Nanomaterials 1110: 2749. 10.3390/nano11102749.
Perez-Vega R, Abad A, Garcia-Labiano F, Gayin P, Luis F, Izquierdo MT, Adinez J (2018) Chemical Looping Combustion of gaseous and solid fuels with manganese-iron mixed oxide as oxygen carrier. Energy Conversion and Management 159: 221-231. 10.1016/j.enconman.2018.01.007.
Polozhai SG, Mazur SV, Muzychuk SV, Raykovsky IM (2021) Increasing the efficiency of lime firing in a rotary kiln using sawdust-wood fuel. Metal ta lyttya Ukrayiny 29(1): 8-13.
Roskovshenko YuK, Senchuk MP (2010) Effectiveness of using solid bulk in modernized heat supply systems. Ventilation, Lighting and Gas Supply 14: 35-45.
Sankar V, Thampi BG, Panicker MR, Ramachandran M (2022) Multi‐fuel performance and emission characteristics of an optimized thermal barrier coated diesel engine. Environmental Progress Sustainable Energy 11: e13813. 10.1002/ep.13813.
Senchuk MP (2020) The combined scheme of burning solid fuel in low-power heating boilers. Ventilation, Lighting and Gas Supply 35: 6-14.
Stupar GM, Tucaković DR, Stamenković OS, Novaković Ž, Milanović Ž (2023) Possibilities of steam boiler process optimization in the TPP Ugljevik. Thermal Science 27(1): 133-149. 10.2298/TSCI2301133S.
Surina III G, Georgalis G, Aphale SS, Patra A, DesJardin PE (2022) Measurement of hybrid rocket solid fuel regression rate for a slab burner using deep learning. Acta Astronautica 190: 160-175. 10.1016/j.actaastro.2021.09.046.
Tang P, Yang B, Li R, Wang Y, Li X, Yang G (2022) Ti3C2 MXene: A reactive combustion catalyst for efficient burning rate control of ammonium perchlorate based solid propellant. Carbon 186: 678-687. 10.1016/j.carbon.2021.10.069.
Wang Q, Wu S, Cui D, Zhou H, Wu D, Pan S, Wang Z (2022) Co-hydrothermal carbonization of organic solid wastes to hydrochar as potential fuel: A review. Science of the Total Environment 850: 158034. 10.1016/j.scitotenv.2022.158034.
Yuan C, Peng S, Zhou L (2023) Multi-field coupling effect of injection on dynamics and thermodynamics of a linear combustion engine generator with slow compression and fast expansion. Energy 270: 126915. 10.1016/
Zhang W, Pei J, Zhu Z, Ye Z, You C (2022) Optimization of the Combustion Organization in a 1000 MWe Opposed Wall-Fired Utility Boiler by Wall Air Injection. Combustion Science and Technology. 10.1080/00102202.2022.2097007.
Journals System - logo
Scroll to top