Publicado 4 números por año
ISSN Imprimir: 1093-3611
ISSN En Línea: 1940-4360
Indexed in
PLASMA TECHNOLOGIES FOR FUEL CONVERSION
SINOPSIS
The results of long-term research of plasmachemical technologies of pyrolysis, hydrogenation, thermochemical treatment for combustion, gasification, radiation-plasma, and complex conversion of solid fuels, including uranium-containing slate coal, and cracking of hydrocarbon gases, are presented. The use of these technologies for obtaining target products (hydrogen, hydrocarbon black, hydrocarbon gases, synthesis gas, and valuable components of the coal mineral mass) meet the modern experimental and economic requirements to the power sector, metallurgy and chemical industry. Plasma coal conversion technologies are characterized by a small time of reagents retention in the reactor and a high rate of the original substances conversion to the target products without catalysts. Thermochemical treatment of fuel for combustion is performed in a plasma fuel system, representing a reaction chamber with a plasmatron, while other plasma fuel conversion technologies are performed in a combined plasmachemical reactor of 100 kW nominal power, in which the area of heat release from the electric arc is combined with the area of chemical reactions.
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Matveev Igor B., Serbin Serhiy I., Washchilenko Nikolay V., Plasma-Assisted Treatment of Sewage Sludge, IEEE Transactions on Plasma Science, 44, 12, 2016. Crossref
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Matveev Igor B., Washchilenko Nikolay V., Serbin Serhiy I., Plasma-Assisted Reforming of Natural Gas for GTL: Part III—Gas Turbine Integrated GTL, IEEE Transactions on Plasma Science, 43, 12, 2015. Crossref
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Lelievre C., Pickles C. A., Hultgren S., Plasma-Augmented Fluidized Bed Gasification of Sub-bituminous Coal in CO2–O2 Atmospheres, High Temperature Materials and Processes, 35, 1, 2016. Crossref
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Matveev Igor B., Serbin Serhiy I., Washchilenko Nikolay V., New Combined-Cycle Gas Turbine System for Plasma-Assisted Disposal of Sewage Sludge, IEEE Transactions on Plasma Science, 45, 12, 2017. Crossref
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Ustimenko Alexandr B., Messerle Vladimir E., 4.26 Plasma Gasification Energy Conversion Systems, in Comprehensive Energy Systems, 2018. Crossref
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Messerle V. E., Ustimenko A. B., Plasma-Fuel Systems for Environment Enhancement and Processing Efficiency Increasing, in Computational Problems in Engineering, 307, 2014. Crossref
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Butakov E, Burdukov A, Siniakov I, Chernova G, Investigation of steam-air gasification of mechanically activated coal fuel at a setup with thermal capacity of 1 MW, Journal of Physics: Conference Series, 1382, 1, 2019. Crossref
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Messerle V.E., Ustimenko A.B., Lavrichshev O.A., Plasma coal conversion including mineral mass utilization, Fuel, 203, 2017. Crossref
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Messerle V.E., Ustimenko A.B., Plasma processing of uranium-containing solid fuels, Fuel, 242, 2019. Crossref
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Messerle V. E., Ustimenko A. B., Greening Uranium-Containing Solid Fuels, 2018 International Conference and Utility Exhibition on Green Energy for Sustainable Development (ICUE), 2018. Crossref
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Messerle V. E., Ustimenko A. B., Tastanbekov A. K., Plasma ignition of solid fuels at thermal power plants. Part 1. Mathematical modeling of plasma-fuel system, Thermophysics and Aeromechanics, 29, 2, 2022. Crossref