High-performance electric arc source of ultraviolet radiation to ozone generate

Andrey Veremeychik; Evgeny Dmukhaylo; Sergey Onysko; Mikhail Sazonov; Vitaly Khvisevich

doi:10.1051/e3sconf/202021201018

All issues

Volume 212 (2020)

E3S Web Conf., 212 (2020) 01018

References

Open Access

Issue		E3S Web Conf. Volume 212, 2020 2020 International Conference on Building Energy Conservation, Thermal Safety and Environmental Pollution Control (ICBTE 2020)


Article Number		01018
Number of page(s)		10
Section		Ecology and Energy Saving
DOI		https://doi.org/10.1051/e3sconf/202021201018
Published online		26 November 2020

V.A. Orlov. Ozonation of water. M.: Stroyizdat, 1984. 88 p. [Google Scholar]
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https://www.secret-dolgolet.ru/ozonoterapiya-ot-koronavirusa [Google Scholar]
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E.M. Silkin Synthesis of ozone in electrical discharges and increasing its efficiency // Components and technologies. No. 6. 2008. P. 136–143. [Google Scholar]
A.V. Tokarev, A.Yu. Makhkambaev. Synthesis of ozone in a combined discharge with a plasma induction electrode. Bulletin of KRSU. 2006. Volume 6. No. 5. P. 16–19. [Google Scholar]
V.G. Samoilovich, L.Yu. Abramovich Arguments “for” and “against” the use of air or oxygen for the industrial production of ozone // First All-Russian Conference “Ozone and other environmentally friendly oxidants” Materials conference, M. 2005. S. 144. [Google Scholar]
R.H. Amirov, E.I. Asinovsky, I.S. Samoilov, A.V. Shepelin. The characteristics of ozone generation from air by nanosecond corona discharge // 20 Int. Conf. Phenom. Ionized Gases, II Ciocco, 8th–12th July, 1991: Contrib. Pap. 1. Pisa, 1991. P. 279–280. [Google Scholar]
A.V. Tokarev Determination of the characteristics of a corona flare discharge as a source of ozone production, abstract of Ph.D. dis. ... Cand. physical-mat. Sciences: 01.04.14. Bishkek, 2000. 146 p. [Google Scholar]
W.J.M. Samaranayake, Y. Miyahara, T. Namihira, S. Katsuki, T. Sakugawal, R. Hackad, H. Akiyama. Pulsed Streamer Discharge Characteristics of Ozone Production in Dry Air // ZEEE Traitsactions on Dielectrics and Electrical lnsulafion. Vol. 7. No. 2, April 2000. P. 254–260. [CrossRef] [Google Scholar]
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V.V. Lunin, N.V. Karyagin, S.N. Tkachenko Methods for producing ozone and modern design of ozonizers: Textbook. M.: Max Press, 2008. [Google Scholar]
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V.V. Lunin, V.I. Gibalov, I.S. Tkachenko Ozone synthesis in a surface barrier discharge in oxygen // Abstracts of reports. Russian seminar dedicated to ozone and other environmentally friendly oxidants. Moscow. June 18-19, 2008. [Google Scholar]
Dingkun Yuan, Can Ding, Yong He, Zhihua Wang, Sunel Kumar, Yanqun Zhu & Kefa Cen. Characteristics of Dielectric Barrier Discharge Ozone Synthesis for Different Pulse Modes // Plasma Chemistry and Plasma Processing Vol. 37, P. 1165–1173 (2017). [CrossRef] [Google Scholar]
I.S. Tkachenko. Modeling the synthesis of ozone in a surface barrier discharge in oxygen / Author’s abstract of the dissertation for the degree of candidate of physical and mathematical sciences 02.00.04. Physical chemistry. Moscow, 2010. 23 p. [Google Scholar]
V.V. Andreev, Yu.P. Pichugin Effect of voltage polarity on ozone synthesis in a dielectric barrier discharge. Applied Physics. 2017 (3). S. 47–51. [Google Scholar]
V.V. Andreev, A.N. Matyunin, Yu.P. Pichugin, V.G. Telegin, G.G. Telegin. Investigation of the efficiency of plasma-chemical ozone generators based on a barrier discharge in air at atmospheric pressure. VANT. Ser. Thermonuclear fusion. 2011, No. 4. P. 112–117. [CrossRef] [Google Scholar]
M.F. Zhukov, A.S. Koroteev, B.A. Uryukov. Applied dynamics of thermal plasm / Novosibirsk: “Science” SB AN. 1975. 299 p. [Google Scholar]
G.Yu. Dautov, M.I. Sazonov. Electric field strength in a vortex-stabilized arc. PMTF, No. 4, 1967. S. 127–131. [Google Scholar]
A.F. Bublievsky. Criteria dependencies for non-consumable electric arcs in the channel // IFZh. 1997. T. 70, No. 1. P. 99–104. [Google Scholar]
A.I. Veremeychik, M.I. Sazonov, D.L. Tsyganov. Study of an electric arc in a helium flow in a high-current plasmatron // Instruments and experimental techniques. 2006. No. 5. P. 99–102. [Google Scholar]
V. V. Batrak, A. I. Veremeychik, M. I. Sazonov, V. M. Khvisevich. Investigation of an electric arc in an argon flow // Bulletin of Brest. state tech. university. 2008. No. 4: Mechanical engineering. S. 26–28. [Google Scholar]

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[1] V.A. Orlov. Ozonation of water. M.: Stroyizdat, 1984. 88 p. [Google Scholar]

[2] S.V. Svitskov, D.A. Danilovich, V.N. Azarov. Wastewater treatment plants as a source of unpleasant odor: causes, characteristics and methods of control // Water supply and sanitary engineering. No. 7. 2016. P. 24–43. [Google Scholar]

[3] http://www.kaufmanntec.ru [Google Scholar]

[4] G.L. Zakladnoy, M.A. Osman. Biological assessment of ozone as a means of combating pests of grain and grain products // Storage and processing of agricultural raw materials. No. 5, 2011. P. 8–9. [Google Scholar]

[5] https://www.secret-dolgolet.ru/ozonoterapiya-ot-koronavirusa [Google Scholar]

[6] Adriana Schwartz, Gregorio Martínez-Sánchez. Potential use of ozone in SARS-CoV-2 / COVID-19. Official Expert Opinion of the International Scientific Committee of Ozone Therapy (ISCO3). ISCO3/EPI/00/04 (March 14, 2020). Approved by ISCO3 on 13.03.2020. Р. 15. [Google Scholar]

[7] Yu.V. Filippov and others. Electrosynthesis of ozone // Publishing house of Moscow State University, 1987. P. 21. [Google Scholar]

[8] E.M. Silkin Synthesis of ozone in electrical discharges and increasing its efficiency // Components and technologies. No. 6. 2008. P. 136–143. [Google Scholar]

[9] A.V. Tokarev, A.Yu. Makhkambaev. Synthesis of ozone in a combined discharge with a plasma induction electrode. Bulletin of KRSU. 2006. Volume 6. No. 5. P. 16–19. [Google Scholar]

[10] V.G. Samoilovich, L.Yu. Abramovich Arguments “for” and “against” the use of air or oxygen for the industrial production of ozone // First All-Russian Conference “Ozone and other environmentally friendly oxidants” Materials conference, M. 2005. S. 144. [Google Scholar]

[11] R.H. Amirov, E.I. Asinovsky, I.S. Samoilov, A.V. Shepelin. The characteristics of ozone generation from air by nanosecond corona discharge // 20 Int. Conf. Phenom. Ionized Gases, II Ciocco, 8th–12th July, 1991: Contrib. Pap. 1. Pisa, 1991. P. 279–280. [Google Scholar]

[12] A.V. Tokarev Determination of the characteristics of a corona flare discharge as a source of ozone production, abstract of Ph.D. dis. ... Cand. physical-mat. Sciences: 01.04.14. Bishkek, 2000. 146 p. [Google Scholar]

[13] W.J.M. Samaranayake, Y. Miyahara, T. Namihira, S. Katsuki, T. Sakugawal, R. Hackad, H. Akiyama. Pulsed Streamer Discharge Characteristics of Ozone Production in Dry Air // ZEEE Traitsactions on Dielectrics and Electrical lnsulafion. Vol. 7. No. 2, April 2000. P. 254–260. [CrossRef] [Google Scholar]

[14] A.A. Mynka, N.P. Polyakov. Method for the synthesis of ozone and a device for its implementation / Patent No. RU2220093C2. [Google Scholar]

[15] Yu.V. Filippov, V.A. Voblikova, V.I. Panteleev Electrosynthesis of ozone. M.: Publishing house of Moscow State University, 1987. [Google Scholar]

[16] V.V. Lunin, N.V. Karyagin, S.N. Tkachenko Methods for producing ozone and modern design of ozonizers: Textbook. M.: Max Press, 2008. [Google Scholar]

[17] P.2346886RF, MKI S01V13 / 11. Ozone generator / E.M. Silkin. Publ. B.I. 2009. No. 5. [Google Scholar]

[18] V.A. Voblikova, E.A. Shabrova, E.V. Shabrova. Optimization of ozone synthesis using special dielectric materials and increased current frequency // Abstracts of reports. Russian conference dedicated to ozone and other environmentally friendly oxidants, science and technology. Moscow. June 7–9, 2005. [Google Scholar]

[19] V.V. Lunin, V.I. Gibalov, I.S. Tkachenko Ozone synthesis in a surface barrier discharge in oxygen // Abstracts of reports. Russian seminar dedicated to ozone and other environmentally friendly oxidants. Moscow. June 18-19, 2008. [Google Scholar]

[20] Dingkun Yuan, Can Ding, Yong He, Zhihua Wang, Sunel Kumar, Yanqun Zhu & Kefa Cen. Characteristics of Dielectric Barrier Discharge Ozone Synthesis for Different Pulse Modes // Plasma Chemistry and Plasma Processing Vol. 37, P. 1165–1173 (2017). [CrossRef] [Google Scholar]

[21] I.S. Tkachenko. Modeling the synthesis of ozone in a surface barrier discharge in oxygen / Author’s abstract of the dissertation for the degree of candidate of physical and mathematical sciences 02.00.04. Physical chemistry. Moscow, 2010. 23 p. [Google Scholar]

[22] V.V. Andreev, Yu.P. Pichugin Effect of voltage polarity on ozone synthesis in a dielectric barrier discharge. Applied Physics. 2017 (3). S. 47–51. [Google Scholar]

[23] V.V. Andreev, A.N. Matyunin, Yu.P. Pichugin, V.G. Telegin, G.G. Telegin. Investigation of the efficiency of plasma-chemical ozone generators based on a barrier discharge in air at atmospheric pressure. VANT. Ser. Thermonuclear fusion. 2011, No. 4. P. 112–117. [CrossRef] [Google Scholar]

[24] M.F. Zhukov, A.S. Koroteev, B.A. Uryukov. Applied dynamics of thermal plasm / Novosibirsk: “Science” SB AN. 1975. 299 p. [Google Scholar]

[25] G.Yu. Dautov, M.I. Sazonov. Electric field strength in a vortex-stabilized arc. PMTF, No. 4, 1967. S. 127–131. [Google Scholar]

[26] A.F. Bublievsky. Criteria dependencies for non-consumable electric arcs in the channel // IFZh. 1997. T. 70, No. 1. P. 99–104. [Google Scholar]

[27] A.I. Veremeychik, M.I. Sazonov, D.L. Tsyganov. Study of an electric arc in a helium flow in a high-current plasmatron // Instruments and experimental techniques. 2006. No. 5. P. 99–102. [Google Scholar]

[28] V. V. Batrak, A. I. Veremeychik, M. I. Sazonov, V. M. Khvisevich. Investigation of an electric arc in an argon flow // Bulletin of Brest. state tech. university. 2008. No. 4: Mechanical engineering. S. 26–28. [Google Scholar]