Abstract:
A series of experimental investigations is performed for determining the thermal and environmental characteristics of burning heavy fuel oil of the M-100 type sprayed by a jet of superheated steam in a laboratory prototype of a new burner. A scheme of liquid fuel burning preventing choking of narrow fuel channels of injectors is proposed; this scheme ensures effective burning of high-viscosity fuels and wastes. The process of stable burning of heavy fuel oil in a low-power (7 kW) burner with low concentrations of toxic emissions and high combustion efficiency is realized.
Keywords:
burner, heavy fuel oil, superheated steam, composition of combustion products, calorimetric measurements.
Citation:
S. V. Alekseenko, I. S. Anufriev, M. S. Vigriyanov, E. P. Kopyev, I. S. Sadkin, O. V. Sharypov, “Burning of heavy fuel oil in a steam jet in a new burner”, Prikl. Mekh. Tekh. Fiz., 61:3 (2020), 11–18; J. Appl. Mech. Tech. Phys., 61:3 (2020), 324–330
\Bibitem{AleAnuVig20}
\by S.~V.~Alekseenko, I.~S.~Anufriev, M.~S.~Vigriyanov, E.~P.~Kopyev, I.~S.~Sadkin, O.~V.~Sharypov
\paper Burning of heavy fuel oil in a steam jet in a new burner
\jour Prikl. Mekh. Tekh. Fiz.
\yr 2020
\vol 61
\issue 3
\pages 11--18
\mathnet{http://mi.mathnet.ru/pmtf313}
\crossref{https://doi.org/10.15372/PMTF20200302}
\elib{https://elibrary.ru/item.asp?id=42982059}
\transl
\jour J. Appl. Mech. Tech. Phys.
\yr 2020
\vol 61
\issue 3
\pages 324--330
\crossref{https://doi.org/10.1134/S0021894420030025}
Linking options:
https://www.mathnet.ru/eng/pmtf313
https://www.mathnet.ru/eng/pmtf/v61/i3/p11
This publication is cited in the following 10 articles:
I. S. Sadkin, M. A. Mukhina, E. Yu. Shadrin, E. P. Kopyev, “Development and research of a low-emission burner device for fuel combustion in a jet of superheated water steam”, J. Appl. Mech. Tech. Phys., 65:1 (2024), 1–6
Tianxingyu Jiang, Zhiqi Wang, Liuming Chen, Xiaoxia Xia, “Sensitivity analysis and optimization of heavy oil burner for drum dryer in asphalt mixing plant based on numerical simulation and orthogonal experimental method”, Thermal Science and Engineering Progress, 52 (2024), 102663
E. P. Kopyev, “Analysis of superheated steam influence on the content of solid carbon particles during diffusion combustion of liquid hydrocarbon fuel”, Thermophys. Aeromech., 31:2 (2024), 345
I. S. Anufriev, E. P. Kopyev, I. S. Sadkin, M. A. Mukhina, A. V. Minakov, V. A. Kuznetsov, “Combustion of n-heptane with steam injection in a laboratory spray burner”, Thermophys. Aeromech., 30:2 (2023), 249
Ivan Sadkin, Mariia Mukhina, Evgeny Kopyev, Oleg Sharypov, Sergey Alekseenko, “Low-Emission Waste-to-Energy Method of Liquid Fuel Combustion with a Mixture of Superheated Steam and Carbon Dioxide”, Energies, 16:15 (2023), 5745
I S Sadkin, E P Kopyev, M A Mukhina, I S Anufriev, “Experimental study of the characteristics of heptane combustion in a high-speed steam jet”, J. Phys.: Conf. Ser., 2233:1 (2022), 012001
A.V. Minakov, I.S. Anufriev, V.A. Kuznetsov, A.A. Dekterev, E.P. Kopyev, O.V. Sharypov, “Combustion of liquid hydrocarbon fuel in an evaporative burner with forced supply of superheated steam and air to the reaction zone”, Fuel, 309 (2022), 122181
E. Yu. Shadrin, I. S. Sadkin, E. P. Kopyev, I. S. Anufriev, V. V. Leshchevich, S. Yu. Shimchenko, “Characteristics of a fuel spray atomized with a steam jet”, Thermophys. Aeromech., 29:4 (2022), 579
I. S. Anufriev, E. P. Kopyev, M. A. Mukhina, I. S. Sadkin, “Investigation into Characteristics of Combustion of n-Heptane Sprayed by Jet of Steam or Air”, J. Engin. Thermophys., 31:3 (2022), 420
Andrey V. Minakov, Viktor A. Kuznetsov, Artem A. Dekterev, Igor S. Anufriev, Evgeny P. Kopyev, Sergey V. Alekseenko, “Comparative Analysis of Numerical Methods for Simulating N-Heptane Combustion with Steam Additive”, Energies, 16:1 (2022), 25
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