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Surface Engineering and Applied Electrochemistry
Published in: Surface Engineering and Applied Electrochemistry 5/2023

01-10-2023

Synthesis of Combined Power Sources Based on High-Voltage Electrochemical Explosion

Authors: A. I. Vovchenko, L. Yu. Demidenko, S. S. Kozyrev, L. E. Ovchinnikova

Published in: Surface Engineering and Applied Electrochemistry | Issue 5/2023

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Abstract

A stepwise algorithm was developed for the synthesis of combined power sources based on high-voltage electrochemical explosion (HVECE). These sources ensure the necessary spatial-temporal force and energy effects on objects of treatment to perform specific technological operations. Initially, a power source is synthesized based on high-voltage electrical discharge in condensed media through solving inverse synthesis problems. This determines the required total energy, which is then optimally divided into electrical and chemical components. The dependences of the force impact on the object of treatment on the energy characteristics of HVECE were experimentally studied. Based on the experimental results, criteria for the optimal division of the required total energy into the electrical and chemical components were established. A specific application example of the developed algorithm for the synthesis of a combined power source based on HVECE is provided, which confirmed that it can be used for engineering calculations.
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Literature
1.
Gulyi, G.A., Nauchnye osnovy razryadno-impul’snykh tekhnologii (Scientific Foundations of Discharge-Pulse Technologies), Kiev: Naukova dumka, 1990.
2.
Rizun, A.R., Golen’, Yu.V., and Yatsyuk, S.A., Electric-discharge destruction of bottom soils, Eletron. Obrab. Mater., 2006, vol. 42, no. 1, p. 70.
3.
Rytov, S.A., Smirnov, P.V., Electrodischarge technological devices for large-diameter drilled shafts, Inf. Vestn., 2006, vol. 1, no. 12, p. 10.
4.
Rizun, A.R., Golen’, Yu.V., Denisyuk, T.D., and Mushtatnyi, G.P., Pulsed electric discharge technologies in construction, Budivnitstvo Ukraini, 2008, no. 10, p. 39.
5.
Vovchenko, A.I. and Posokhov, A.A., Upravlyaemye elektrovzryvnye protsessy preobrazovaniya energii v kondensirovannykh sredakh (Controlled Electroexplosive Processes of Energy Conversion in Condensed Media), Kiev: Naukova dumka, 1992.
6.
Demydenko, L. and Kozyrev, S., Sontrol of high voltage discharge-pulse installation for implementation of technological modes of electrochemical explosion, Eastern-Eur. J. Enterprise Technol., 2020, vol. 104, nos. 2–5, p. 29.
7.
Vovchenko, A.I., Demidenko, L.Yu., and Starkov, I.N., Algorithm for calculating the parameters of a combined electric-discharge energy source in high-voltage electrochemical explosion in a confined volume, Surf. Eng. Appl. Electrochem., 2019, vol. 55, p. 718.CrossRef
8.
Vovchenko, A.I. and Demidenko, L.Yu., Parameters of high-voltage electrochemical explosion under controlled electrical energy supply, Surf. Eng. Appl. Electrochem., 2021, vol. 57, p. 101.CrossRef
9.
Vovchenko, A.I., Demidenko, L.Yu., Kozyrev, S.S., and Ovchinnikova, L.E., High voltage electrochemical explosion in discharge-pulse technologies, Surf. Eng. Appl. Electrochem., 2022, vol. 58, p. 731.CrossRef
10.
Vovchenko, A.I., Shomko, V.V., Shishov, A.M., Mathematical modeling and optimization of electrohydropulse technological processes, Tekh. Elektrodin., 2005, no. 3, p. 68.
11.
Romanov, V.G., Obratnye zadachi matematicheskoi fiziki (Inverse Problems of Mathematical Physics), Moscow: Nauka, 1984.
12.
Tikhonov, A.N., Kal’ner, V.D., and Glasko, V.B., Matematicheskoe modelirovanie tekhnologicheskikh protsessov i metod obratnykh zadach v mashinostroenii (Mathematical Modeling of Technological Processes and the Method of Inverse Problems in Mechanical Engineering), Moscow: Mashinostroenie, 1990.
13.
Glasko, V.B., Obratnye zadachi matfiziki (Inverse Problems of Mathematical Physics), Moscow: Mosk. Gos. Univ., 1984.
14.
Barbashova, G.A., On the reconstruction of the characteristics of an underwater spark discharge channel from the time dependence of pressure in a liquid, Prikl. Gidromekh., 2007, vol. 9, no. 4, p. 69.MATH
15.
Krivitskii, E.V. and Shamko, V.V., Perekhodnye protsessy pri vysokovol’tnom razryade v vode (Transient Processes during High-Voltage Discharge in Water), Kiev: Naukova dumka, 1979.
16.
Barbashova, G.A., Kosenkov, V.M., and Tsurkin, V.N., On the effect of hydrostatic pressure on hydrodynamic processes during electric discharge, Teor., Eksp., Prakt. Elektrorazryadn. Tekhnol., 2000, no. 3, p. 36.
17.
Hairer, E. and Wanner, G., Solving Ordinary Differential Equations II. Stiff and Differential-Algebraic Problems, Berlin: Springer, 1996.MATH
18.
Vovchenko, A.I., Boguslavskii, L.Z., and Miroshnichenko, L.N., Trends in the development of high-power high-voltage pulsed current generators at the Institute of Pulse Processes and Technologies of the National Academy of Sciences of Ukraine, Tekh. Elektrodin., 2010, no. 5, p. 69.
Metadata
Title
Synthesis of Combined Power Sources Based on High-Voltage Electrochemical Explosion
Authors
A. I. Vovchenko
L. Yu. Demidenko
S. S. Kozyrev
L. E. Ovchinnikova
Publication date
01-10-2023
Publisher
Pleiades Publishing
Published in
Surface Engineering and Applied Electrochemistry / Issue 5/2023
Print ISSN: 1068-3755
Electronic ISSN: 1934-8002
DOI
https://doi.org/10.3103/S1068375523050174

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