Activation of the Process of Layer Combustion of Coal with Iron Nitrate and Waste of Metal Rolling Production; Solid Fuel Chemistry; Vol. 58, iss. 3
| Parent link: | Solid Fuel Chemistry.— .— New York: Allerton Press, Inc. Vol. 58, iss. 3.— 2024.— P. 219-225 |
|---|---|
| Main Author: | |
| Corporate Author: | |
| Other Authors: | , |
| Summary: | Title screen The influence of metal-rolling production waste and iron nitrate on the characteristics of the process of layer combustion of coal was investigated. Coal of T grade was used as a solid fuel. Metal scale and iron nitrate were introduced into the fuel by mechanical mixing. According to XRD analysis data, the phases of iron oxide Fe3O4 and manganese oxide Mn3O4 were identified in the metal scale. The process characteristics of the combustion of test samples were studied using high-speed video recording in a combustion chamber at a heating medium temperature of 700°C. The process of activated layer combustion of coal was also scaled up using a solid fuel boiler unit. It has been experimentally established that the use of metal scale and iron nitrate led to an increase in the reactivity of the fuel, as evidenced by a decrease in the ignition delay time. The carbon loss and the concentration of CO formed in the gas-phase combustion products were reduced due to the intensification of the combustion process. Текстовый файл AM_Agreement |
| Language: | English |
| Published: |
2024
|
| Subjects: | |
| Online Access: | https://doi.org/10.3103/S0361521924700034 |
| Format: | Electronic Book Chapter |
| KOHA link: | https://koha.lib.tpu.ru/cgi-bin/koha/opac-detail.pl?biblionumber=674236 |
Similar Items
Activation of the Process of Layer Combustion of Coal with Iron Nitrate and Waste of Metal Rolling Production; Solid Fuel Chemistry; Vol. 58, iss. 3
by: Shuataev M. K. Merlan Kalkamanovich
Published: (2024)
by: Shuataev M. K. Merlan Kalkamanovich
Published: (2024)
Activation of Combustion Process of Anthracite by Metal Nitrates; Combustion Science and Technology; Vol. XX, iss. X
Published: (2022)
Published: (2022)
Non-isothermal oxidation of coal with Ce(NO3)3 and Cu(NO3)2 additives; International Journal of Coal Science and Technology; Vol. 6, iss. 1
by: Larionov K. B. Kirill Borisovich
Published: (2019)
by: Larionov K. B. Kirill Borisovich
Published: (2019)
Combustion of Wet Coal Processing Waste and Coal Slime as Components of Fuel Slurries; Combustion Science and Technology; Vol. 193, iss. 7
by: Vershinina K. Yu. Kseniya Yurievna
Published: (2020)
by: Vershinina K. Yu. Kseniya Yurievna
Published: (2020)
Influence of Forest Combustible Material on the Characteristics and Conditions of Ignition of Bio-coal Water Fuels; Combustion Science and Technology; Vol. 195, iss. 3
Published: (2023)
Published: (2023)
Lab Scale Combustion of High Moisture Fuels From Peat, Coal Waste and Milled Lignite; Waste and Biomass Valorization; Vol. 12
by: Vershinina K. Yu. Kseniya Yurievna
Published: (2021)
by: Vershinina K. Yu. Kseniya Yurievna
Published: (2021)
Co-combustion of coal processing waste, oil refining waste and municipal solid waste: Mechanism, characteristics, emissions; Chemosphere; Vol. 240
by: Glushkov D. O. Dmitry Olegovich
Published: (2020)
by: Glushkov D. O. Dmitry Olegovich
Published: (2020)
Stabilized fuel slurries based on fine coal slime: Rheology, combustion and feasibility study; Fuel; Vol. 356
Published: (2024)
Published: (2024)
Combustion of Coal Flotation Wastes and Woodworking Wastes in Blends and Suspensions; Coke and Chemistry; Vol. 62, iss. 5
Published: (2019)
Published: (2019)
Effect of Cu(NO3)2 and Cu(CH3COO)2 Activating Additives on Combustion Characteristics of Anthracite and Its Semi-Coke; Energies; Vol. 13, iss. 22
Published: (2020)
Published: (2020)
Benefits of Slurry Fuels Based on Industrial Wastes; Coke and Chemistry; Vol. 62, iss. 9
Published: (2019)
Published: (2019)
Co-Combustion of Coal and Biomass: Heating Surface Slagging and Flue Gases; Fire; Vol. 8, iss. 3
Published: (2025)
Published: (2025)
Combustion of bituminous coal loaded with copper salts; Fuel; Vol. 286
Published: (2021)
Published: (2021)
Energy recycling of pyrolysis water as a part of coal-water fuel; International Journal of Energy Research; Vol. 45, iss. 10
Published: (2021)
Published: (2021)
Combustion of bituminous coal and semicoke with copper salts; Fuel Processing Technology; Vol. 213
Published: (2021)
Published: (2021)
Intensification of the Oxidation of Lignite and Coal by an Activating Additive of Fe(NO3)2; Solid Fuel Chemistry; Vol. 53, iss. 5
Published: (2019)
Published: (2019)
Effect of iron and boron ultrafine powders on combustion of aluminized solid propellants; Combustion and Flame; Vol. 178
Published: (2017)
Published: (2017)
Ignition of two-component and three-component fuel mixtures based on brown coal and char under slow heating conditions; Journal of Thermal Analysis and Calorimetry; Vol. 147
Published: (2022)
Published: (2022)
Effect of the shape of an organic water–coal fuel particle on the condition and characteristics of its ignition in a hot air flow; Russian Journal of Physical Chemistry B; Vol. 10, iss. 6
Published: (2016)
Published: (2016)
Correction of iron deficiency anemia by Fe(III) hydroxocomplexes stabilized with humic ligands in rat; Humic substances and ecoadaptive technologies (HIT-2021)
Published: (2021)
Published: (2021)
Mathematical modeling of the thermochemical processes of sequestration of SOx when burning the particles of the coal and wood mixture; Renewable Energy; Vol. 185
Published: (2022)
Published: (2022)
Composition, Combustion and Emission Characteristics of Distillation Fractions of Pyrolysis Oil of Waste Heavy-Duty Tires; Waste and Biomass Valorization; Vol. 15, iss. 6.
Published: (2024)
Published: (2024)
High-speed contactless measurements of temperature evolution during ignition and combustion of coal-based fuel pellets; International Journal of Heat and Mass Transfer; Vol. 175
by: Glushkov D. O. Dmitry Olegovich
Published: (2021)
by: Glushkov D. O. Dmitry Olegovich
Published: (2021)
Using ignition of coal dust produced by different types of mechanical treatment under conditions of rapid heating; Combustion, Explosion, and Shock Waves; Vol. 52, iss. 3
Published: (2016)
Published: (2016)
Extraction processing of concentrated solutions of uranyl nitrate with high impurities content; Bulletin of the Tomsk Polytechnic University; Vol. 311, № 3
Published: (2007)
Published: (2007)
Experimental Research of the Initial Temperature and Additives Effect on the Ignition and Combustion Mechanisms of Composite Liquid Fuel in a High-Temperature Oxidizer; Applied Sciences; Vol. 13, iss. 6
Published: (2023)
Published: (2023)
Influence of the Heating Rate on the Activation of Coal and Lignite Oxidation by Copper Nitrate; Coke and Chemistry; Vol. 63, iss. 8
Published: (2020)
Published: (2020)
Municipal solid waste recycling by burning it as part of composite fuel with energy generation; Journal of Environmental Management; Vol. 231
Published: (2019)
Published: (2019)
Change of coal-water fuel rheological properties by rotary flows modulation; 11th International Forum on Strategic Technology (IFOST 2016); Pt. 2
Published: (2016)
Published: (2016)
Ignition and Combustion of Composite Solid Propellants Based on a Double Oxidizer and Boron-Based Additives; Russian Journal of Physical Chemistry B; Vol. 14, iss. 4
Published: (2020)
Published: (2020)
Flame Propagation Characteristics in the Boundary Layer of the Bio-Water-Coal Fuel Particle During its Ignition; Combustion Science and Technology; Vol. XX, iss. X
Published: (2022)
Published: (2022)
Combustion features of dispersed aluminum and boron in high-energy composition; FirePhysChem; Vol. 4, iss. 4
by: Korotkikh A. G. Aleksandr Gennadievich
Published: (2024)
by: Korotkikh A. G. Aleksandr Gennadievich
Published: (2024)
Fuel mixtures of oil sludge and waste oils: comprehensive ignition and combustion analysis; Energy Conversion and Management; Vol. 348, Pt. B
Published: (2026)
Published: (2026)
Ignition of particles of finely dispersed fuel mixtures based on coal and fine wood; Energy; Vol. 220
Published: (2021)
Published: (2021)
Ignition, Combustion, and Mechanical Properties of Briquettes from Coal Slime and Oil Waste, Biomass, Peat and Starch; Waste and Biomass Valorization; Vol. 14, iss. 2
Published: (2023)
Published: (2023)
Intensification of microwave pyrolysis of hard coal by adding microwave absorbers based on iron and copper; Journal of Analytical and Applied Pyrolysis; Vol. 191
Published: (2025)
Published: (2025)
Limiting Ignition Conditions and Time Characteritics of Combustion of Liquid Biofuel Drops; Chemical and Petroleum Engineering; Vol. 58, iss. 3-4
Published: (2022)
Published: (2022)
Ignition of Coal-Water Fuel Droplets with Addition of Small Amount of Various Alcohols; Combustion Science and Technology; Vol. XXX, iss. XX
by: Gvozdyakov D. V. Dmitry Vasilievich
Published: (2021)
by: Gvozdyakov D. V. Dmitry Vasilievich
Published: (2021)
A comparison of ignition characteristics of slurry fuels prepared using coal processing waste and finely divided coal; Journal of the Energy Institute; Vol. 92, iss. 4
by: Vershinina K. Yu. Kseniya Yurievna
Published: (2019)
by: Vershinina K. Yu. Kseniya Yurievna
Published: (2019)
An experimental investigation into the fuel oil-free start-up of a coal-fired boiler by the main solid fossil fuel with additives of brown coal, biomass and charcoal for ignition enhancement; Fuel Processing Technology; Vol. 223
Published: (2021)
Published: (2021)