Metal, Nonmetal, Energy and Energy Carrier Production by Plasma Arc Electrolytic Centrifugal Conversion
( Pp. 122-139)
More about authors
Volkov Anatolii E.
AdiRUT LLC
Moscow, Russian Federation Volkov Alexander A.
Ural Federal University named after the first President of Russia B.N. Yeltsin
Yekaterinburg, Russian Federation.
AdiRUT LLC
Moscow, Russian Federation Volkov Alexander A.
Ural Federal University named after the first President of Russia B.N. Yeltsin
Yekaterinburg, Russian Federation.
Abstract:
The new plasma arc electrolytic centrifugal conversion process is intended to reduce material consumption, time and energy costs when producing various products represented by metals, nonmetals and energy carriers. The task is accomplished through combining the metallurgical, chemical and energy production into an integral production facility. All polluting emissions associated today with the metallurgical, chemical and energy sectors serve as reagents for the new process and are used for manufacture of useful products sent to the market. Energy saving substance separation requires concentration of the maximum possible amount of various chemical elements in the melting area; they serve as catalysts reducing the reaction energy consumption. The energy production and consumption processes are closed loop with the generated reagents redistributed among the production areas and reversed for recycling what allows low potential heat retaining from losses to the environment. As of today, thermal and nuclear power stations as well as metallurgical and petrochemical plants discharge about two thirds of the produced heat energy to the environment. In the plasma arc electrolytic centrifugal conversion process the energy is diverted from one production process to another allowing several times higher hydrocarbon processing. Elimination of harmful emissions into the atmosphere requires energy released due to the system combining the energy production with the mining, metallurgical and chemical industries. The substance processing is induced by the energy produced when burning hydrogen derived from hydrocarbon materials in oxygen recovered from ore. All energy produced but not consumed for external energy demand, is transferred into methanol serving as hydrogen, and therefore energy, accumulator. Energy is transferred over large distances by methanol transportation over pipelines with the return to the processing area of carbon dioxide gas, required for plasma initiation.
How to Cite:
Volkov A.E., Volkov A.A. Metal, Nonmetal, Energy and Energy Carrier Production by Plasma Arc Electrolytic Centrifugal Conversion. Computational Nanotechnology. 2023. Vol. 10. No. 4. Pp. 122–139. (In Rus.) DOI: 10.33693/2313-223X-2023-10-4-122-139. EDN: CHBQDD
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Andreev D.V. Oxidative methanol steam reforming in microchannel reactor. Polzunovskiy vestnik. 2021. No. 4. Pp. 123–128. (In Rus.)
Sadykov V.A., Krasnov A.V., Fedorova Yu.E. et al. Novel nanocomposite materials for oxygen and hydrogen separation membranes. International Journal of Hydrogen Energy. 2020. Vol. 45. Issue 25. Pp. 13575–13585. (In Rus.)
Startsev A.N. Low-temperature catalytic decomposition of hydrogen sulfide into hydrogen and diatomic gaseous sulfur. Kinetics and Catalysis. 2016. Vol. 57. No. 4. Pp. 516–528. (In Rus.)
Aminov R.Z., Bairomov A.N. Combining hydrogen energy cycles with nuclear power plants. Moscow: Nauka, 2016. 254 p.
Shchukarev S.A. Lectures on the general course of chemistry. Leningrad: Leningrad University Publishing House, 1962. Vol. 1.
Khazeev A.A., Cherepanova M.V. Modernization of the synthesis stage in the production of methanol. PNRPU Bulletin. Chemical Technology and Biotechnology. 2020. No. 3. Pp. 123–142. (In Rus.)
Krilov O.V. Carbon dioxide conversion of methane into synthesis gas. Russian Chemistry Journal. 2000. Vol. 44. No. 1. Pp. 19–33. (In Rus.)
Afanasev S.V., Gartman V.L. Catalytic conversion of carbon monoxide of the first and second stages. Business magazine “Neftegaz.RU”. 2021. No. 7 (115). Pp. 28–34. (In Rus.)
Grim R.G., Zhe Huang, Guarnieri M. et al. Transforming the carbon economy: Challenges and opportunities in the convergence of low-cost electricity and reductive CO2 utilization. Energy & Environmental Science. 2020. No. 13 (2). Pp. 472–494.
Sedov I.V., Makaryan I.A., Fokin I.G. et al. Current developments in the field of direct production of methanol from natural gas. Scientific Journal of Russian Gas Society. 2021. No. 2 (30). Pp. 44–53. (In Rus.)
Khalifa A.A., Bazhin V.YU., Shalabi M.E.M.K. et al. Improving the efficiency of the carbothermal reduction of red mud by microwave treatment. Proceedings of Irkutsk State Technical University. 2021. No. 2 (157). Pp. 264–279.
Makushev Yu.P., Polyakova T.A., Bykov P.S. Calculation and experimental definition combustion heats of hydrocarbon fuels. In: Architectural, Construction and Road Transportation Complexes: Problems, Prospects, Innovations. Omsk: Siberian State Automobile and Highway University, 2019. Pp. 163–168.
Rudoi V.I. Review of little-known methods for distributing fuel between thermal power plant products. Yung Scientist. 2021. No. 6 (348). Pp. 33–35. (In Rus.)
Gamburg D.U. et al. Hydrogen. Properties, production, storage, transportation, application: Reference book. D.U. Gamburga, N.F. Dubovkina (eds.). Moscow: Himiia, 1989. 671 p.
Ola J., Gubert А., Pracash G. Methanol and the energy of the future. When oil and gas run out. I.V. Mishin (transl. from English). 3rd ed., electronic. Moscow: Laboratoriya Znaniy, 2020.
Volkov A.E. Patent RF 2524036. Method and device for centrifugal metal casting. Application 28.10.2010. Published 27.07.2014.
Volkov A.A. Patent RF 2758609. Method and device for plasma-thermal centrifugal reduction and separation of chemicals from ore in a gravitational field. Application 20.07.2020. Published 01.11.2021.
Kesel L.G., Milochkin V.A., Kesel B.A. Process for producing methanol from natural gas under the influence of laser radiation. Electronics, Photonics and Cyberphysical Systems. 2022. Vol. 2. No. 1. Pp. 85–92. (In Rus.)
Shein A.P., Gudima N.V. A metallurgist’s brief guide to non-ferrous metals. Moscow: Metallurgiya, 1964. 412 p.
Karpova K.S., Karpov A.V. Solid-phase recovery of iron oxides under laboratory conditions. Modern Materials, Equipment and Technonlogies. 2018. No. 1 (16). Pp. 27–32. (In Rus.)
Filippov S., Golodnitsky A., Kashin A. Fuel cells and hydrogen energy. Public Business Science Magazine “Energy Policy”. 2020. No. 11 (153). Pp. 28–39. (In Rus.)
Agapitov E.B. Perspectives of the development of plasma steel-fuel ovens. The Theory and Process Engineering of Metallurgical Production. 2018. No. 1 (24). Pp. 38–41. (In Rus.)
Andreev D.V. Oxidative methanol steam reforming in microchannel reactor. Polzunovskiy vestnik. 2021. No. 4. Pp. 123–128. (In Rus.)
Sadykov V.A., Krasnov A.V., Fedorova Yu.E. et al. Novel nanocomposite materials for oxygen and hydrogen separation membranes. International Journal of Hydrogen Energy. 2020. Vol. 45. Issue 25. Pp. 13575–13585. (In Rus.)
Startsev A.N. Low-temperature catalytic decomposition of hydrogen sulfide into hydrogen and diatomic gaseous sulfur. Kinetics and Catalysis. 2016. Vol. 57. No. 4. Pp. 516–528. (In Rus.)
Aminov R.Z., Bairomov A.N. Combining hydrogen energy cycles with nuclear power plants. Moscow: Nauka, 2016. 254 p.
Shchukarev S.A. Lectures on the general course of chemistry. Leningrad: Leningrad University Publishing House, 1962. Vol. 1.
Khazeev A.A., Cherepanova M.V. Modernization of the synthesis stage in the production of methanol. PNRPU Bulletin. Chemical Technology and Biotechnology. 2020. No. 3. Pp. 123–142. (In Rus.)
Krilov O.V. Carbon dioxide conversion of methane into synthesis gas. Russian Chemistry Journal. 2000. Vol. 44. No. 1. Pp. 19–33. (In Rus.)
Afanasev S.V., Gartman V.L. Catalytic conversion of carbon monoxide of the first and second stages. Business magazine “Neftegaz.RU”. 2021. No. 7 (115). Pp. 28–34. (In Rus.)
Grim R.G., Zhe Huang, Guarnieri M. et al. Transforming the carbon economy: Challenges and opportunities in the convergence of low-cost electricity and reductive CO2 utilization. Energy & Environmental Science. 2020. No. 13 (2). Pp. 472–494.
Sedov I.V., Makaryan I.A., Fokin I.G. et al. Current developments in the field of direct production of methanol from natural gas. Scientific Journal of Russian Gas Society. 2021. No. 2 (30). Pp. 44–53. (In Rus.)
Khalifa A.A., Bazhin V.YU., Shalabi M.E.M.K. et al. Improving the efficiency of the carbothermal reduction of red mud by microwave treatment. Proceedings of Irkutsk State Technical University. 2021. No. 2 (157). Pp. 264–279.
Keywords:
centrifugal conversion, plasma, electrolysis, energy performance, separation, photocatalysis, melting, evaporation, dissociating, energy saving.
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