Waste Processing by Plasma Arc Electrolytic Centrifugal Conversion
( Pp. 102-114)
More about authors
Volkov Anatolii E.
Cand. Sci. (Eng.); Director
AdiRUT LLC
Moscow, Russian Federation Volkov Alexander A. postgraduate student
Ural Federal University named after the first President of Russia B.N. Yeltsin
Yekaterinburg, Russian Federation.
AdiRUT LLC
Moscow, Russian Federation Volkov Alexander A. postgraduate student
Ural Federal University named after the first President of Russia B.N. Yeltsin
Yekaterinburg, Russian Federation.
Abstract:
The plasma-arc electrolytic centrifugal conversion process was developed for processing of crude ore materials and hydrocarbons to end products with simultaneous generation of energy carriers and energy [1]. The developed process may be used with a similar purpose for processing of various wastes. Industrial and household wastes have identical chemistry with common ore and hydrocarbons. Waste ore called “tailings” is comparable to payable ore and, just as in base ore, oxygen comprises about half of its composition. Household wastes for the most part contain organic compounds, including plastic, wood, paper, and form hydrocarbon mixtures containing various metals and nonmetals. Melted waste mixture contains almost every elements of the periodic table with various chemical elements acting as reaction catalysts. The wastes are processed under electric energy generated by hydrogen burning in oxygen. Hydrogen is recovered from hydrocarbon materials contained in household wastes and water contained in the feed. Oxygen is recovered from waste ore. Hydrogen and oxygen are stored in a methanol compound obtained from synthesis gas generated in the course of waste plasma melting.
How to Cite:
Volkov A.E., Volkov A.A. Waste Processing by Plasma Arc Electrolytic Centrifugal Conversion. Computational Nanotechnology. 2024. Vol. 11. No. 2. Pp. 102–114. (In Rus.). DOI: 10.33693/2313-223X-2024-11-2-102-114. EDN: MVHEOZ
Reference list:
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.)
Shilkina S.V. Global trends in waste management and analysis of the situation in Russia. Russian Journal of Resources, Conservation and Recycling. 2020. No. 1 (7). (In Rus.). DOI: 10.15862/05ECOR120. URL: https://resources.today/PDF/05ECOR120.pdf
Vorobyev K.A. Possibilities of the carbon dioxide capture by incinerator slags in gas environment. Bulletin of Perm University. Geology. 2023. Vol. 22. No. 3. Pp. 275–281. (In Rus.)
Vorobyev K.A. Possibilities of using incinerator slags to reduce carbon-containing emissions. In: Man and environment. Collection of reports of the XI All-Russian youth scientific conference. Yu.A. Bobrov, O.M. Startseva, Yu.N. Shabalina (eds.-in-Chief). Syktyvkar, 2023. Pp. 43–47.
Vakarev A.A., Vinogradov V.V. Ensuring environmental safety through the development of waste recycling in modern Russia: Development, difficulties, solutions at the regional level. National Security. 2022. No. 2. Pp. 10–37. (In Rus.) DOI: 10.7256/2454-0668.2022.2.37725
Abubakar I.R., Maniruzzaman Kh.M., Dano U.L. et al. Environmental sustainability impacts of solid waste management practices in the global south. International Journal of Environmental Research and Public Health. 2022. No. 19 (19). P. 12717.
Ding H., Tang J., Qiao J. Control methods of municipal solid wastes incineration process: A survey. In: Materials of 40th Chinese Control Conference (CCC). Shanghai, China, 2021. Pp. 662–667.
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.)
Maidanika M.N., Verbovetskiia E.Kh., Tugov A.N. Preliminary assessment of the possibility to shift thermal power plant boilers for burning alternative coal. Thermal Engineering. 2021. No. 9. Pp. 33–42. (In Rus.)
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.)
Gamrekeli M.N., Purgina P.S. Energy potential of wood thermal utilization processes. In: Forest science in the implementation of the concept of the Ural engineering school: Socio-economic and environmental problems of the forest sector of the economy: Materials of conference. Yekaterinburg, May 21 – September 22, 2019. Pp. 367–370.
Catizzone E., Giuliano A., Barletta D. Waste-to-methanol: Direct CO2 emissions assessment for the methanol production from municipal waste-derived syngas. Chemical Engineering Transactions. 2021. Vol. 86. Pp. 511–516.
Haafa M., Hilz J., Unger A. et al. Methanol production via the utilization of electricity and CO2 provided by a waste incineration plant. In: Materials of 14th International Conference on Greenhouse Gas Control Technologies, GHGT-14, October 21–25, 2018. Melbourne, Australia.
Sedov I.V., Makaryan I.A., Fokin I.G. et al. Currentdevelopments in the field of direct production of methanolfrom natural gas. Scientific Journal of Russian Gas Society. 2021. No. 2 (30). Pp. 44–53. (In Rus.)
Afanasev S.V., Gartman V.L. Catalytic conversion of carbonmonoxide of the first and second stages. Business Magazine “Neftegaz.RU”. 2021. No. 7 (115). Pp. 28–34. (In Rus.)
Shilkina S.V. Global trends in waste management and analysis of the situation in Russia. Russian Journal of Resources, Conservation and Recycling. 2020. No. 1 (7). (In Rus.). DOI: 10.15862/05ECOR120. URL: https://resources.today/PDF/05ECOR120.pdf
Vorobyev K.A. Possibilities of the carbon dioxide capture by incinerator slags in gas environment. Bulletin of Perm University. Geology. 2023. Vol. 22. No. 3. Pp. 275–281. (In Rus.)
Vorobyev K.A. Possibilities of using incinerator slags to reduce carbon-containing emissions. In: Man and environment. Collection of reports of the XI All-Russian youth scientific conference. Yu.A. Bobrov, O.M. Startseva, Yu.N. Shabalina (eds.-in-Chief). Syktyvkar, 2023. Pp. 43–47.
Vakarev A.A., Vinogradov V.V. Ensuring environmental safety through the development of waste recycling in modern Russia: Development, difficulties, solutions at the regional level. National Security. 2022. No. 2. Pp. 10–37. (In Rus.) DOI: 10.7256/2454-0668.2022.2.37725
Abubakar I.R., Maniruzzaman Kh.M., Dano U.L. et al. Environmental sustainability impacts of solid waste management practices in the global south. International Journal of Environmental Research and Public Health. 2022. No. 19 (19). P. 12717.
Ding H., Tang J., Qiao J. Control methods of municipal solid wastes incineration process: A survey. In: Materials of 40th Chinese Control Conference (CCC). Shanghai, China, 2021. Pp. 662–667.
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.)
Maidanika M.N., Verbovetskiia E.Kh., Tugov A.N. Preliminary assessment of the possibility to shift thermal power plant boilers for burning alternative coal. Thermal Engineering. 2021. No. 9. Pp. 33–42. (In Rus.)
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.)
Gamrekeli M.N., Purgina P.S. Energy potential of wood thermal utilization processes. In: Forest science in the implementation of the concept of the Ural engineering school: Socio-economic and environmental problems of the forest sector of the economy: Materials of conference. Yekaterinburg, May 21 – September 22, 2019. Pp. 367–370.
Catizzone E., Giuliano A., Barletta D. Waste-to-methanol: Direct CO2 emissions assessment for the methanol production from municipal waste-derived syngas. Chemical Engineering Transactions. 2021. Vol. 86. Pp. 511–516.
Haafa M., Hilz J., Unger A. et al. Methanol production via the utilization of electricity and CO2 provided by a waste incineration plant. In: Materials of 14th International Conference on Greenhouse Gas Control Technologies, GHGT-14, October 21–25, 2018. Melbourne, Australia.
Sedov I.V., Makaryan I.A., Fokin I.G. et al. Currentdevelopments in the field of direct production of methanolfrom natural gas. Scientific Journal of Russian Gas Society. 2021. No. 2 (30). Pp. 44–53. (In Rus.)
Afanasev S.V., Gartman V.L. Catalytic conversion of carbonmonoxide of the first and second stages. Business Magazine “Neftegaz.RU”. 2021. No. 7 (115). Pp. 28–34. (In Rus.)
Keywords:
plasma, ore reduction and separation, waste, centrifugal conversion, methanol, crude ore, hydrocarbons, hydrogen.
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