Numerical investigation of the influence produced by electric circuit parameters on the formation of chemically active radicals in water vapours

Numerical investigation of the influence produced by electric circuit parameters on the formation of chemically active radicals in water vapours

The numerical investigation of the formation of chemically active radicals during the discharge in water vapors has been carried out. An increase in the number of radicals in terms of time and a change in thermodynamical discharge parameters were determined for different U, L, C values of the discha...

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Date:2015
Main Author: Vinnikov, D.V.
Format: Article
Language:English
Published: Національний науковий центр «Харківський фізико-технічний інститут» НАН України 2015
Series:Вопросы атомной науки и техники
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Вычислительные и модельные системы
Online Access:https://nasplib.isofts.kiev.ua/handle/123456789/112112
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Cite this:Numerical investigation of the influence produced by electric circuit parameters on the formation of chemically active radicals in water vapours / D.V. Vinnikov // Вопросы атомной науки и техники. — 2015. — № 3. — С. 159-165. — Бібліогр.: 23 назв. — англ.

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spelling nasplib_isofts_kiev_ua-123456789-1121122025-02-10T00:40:20Z Numerical investigation of the influence produced by electric circuit parameters on the formation of chemically active radicals in water vapours Чисельне дослідження впливу параметрів електричного кола на напрацювання хімічно активних радикалів у парах води Численное исследование влияния параметров электрической цепи на наработку химически активных радикалов в парах воды Vinnikov, D.V. Вычислительные и модельные системы The numerical investigation of the formation of chemically active radicals during the discharge in water vapors has been carried out. An increase in the number of radicals in terms of time and a change in thermodynamical discharge parameters were determined for different U, L, C values of the discharge circuit. Consideration was given to the two domains, in particular the discharge channel and the region between the discharge channel and the shock wave front. Special attention was given to such chemical components as: OH, O, H, H₂O₂, HO₂, H₂O. Проведено чисельне дослідження утворення хімічно активних радикалів при розряді в парах води. Для різних значень U, L, C розрядного кола визначене напрацювання радикалів у часі та зміна термодинамічних параметрів розряду. Розглянуті дві області утворення радикалів: канал розряду, область між каналом розряду і фронтом ударної хвилі. Розглядалися хімічні компоненти: OH, O, H, H₂O₂, HO₂, H₂O. Проведено численное исследование образования химически активных радикалов при разряде в парах воды. Для различных значений U, L, C разрядной цепи определены наработка радикалов во времени и изменение термодинамических параметров разряда. Рассмотрены две области образования радикалов: канал разряда, область между каналом разряда и фронтом ударной волны. Рассматривались химические компоненты: OH, O, H, H₂O₂, HO₂, H₂O. 2015 Article Numerical investigation of the influence produced by electric circuit parameters on the formation of chemically active radicals in water vapours / D.V. Vinnikov // Вопросы атомной науки и техники. — 2015. — № 3. — С. 159-165. — Бібліогр.: 23 назв. — англ. 1562-6016 PACS: 52.80.Wg, 52.80.Tn, 51.50.+v https://nasplib.isofts.kiev.ua/handle/123456789/112112 en Вопросы атомной науки и техники application/pdf Національний науковий центр «Харківський фізико-технічний інститут» НАН України
institution Digital Library of Periodicals of National Academy of Sciences of Ukraine
collection DSpace DC
language English
topic Вычислительные и модельные системы
Вычислительные и модельные системы
spellingShingle Вычислительные и модельные системы
Вычислительные и модельные системы
Vinnikov, D.V.
Numerical investigation of the influence produced by electric circuit parameters on the formation of chemically active radicals in water vapours
Вопросы атомной науки и техники
description The numerical investigation of the formation of chemically active radicals during the discharge in water vapors has been carried out. An increase in the number of radicals in terms of time and a change in thermodynamical discharge parameters were determined for different U, L, C values of the discharge circuit. Consideration was given to the two domains, in particular the discharge channel and the region between the discharge channel and the shock wave front. Special attention was given to such chemical components as: OH, O, H, H₂O₂, HO₂, H₂O.
format Article
author Vinnikov, D.V.
author_facet Vinnikov, D.V.
author_sort Vinnikov, D.V.
title Numerical investigation of the influence produced by electric circuit parameters on the formation of chemically active radicals in water vapours
title_short Numerical investigation of the influence produced by electric circuit parameters on the formation of chemically active radicals in water vapours
title_full Numerical investigation of the influence produced by electric circuit parameters on the formation of chemically active radicals in water vapours
title_fullStr Numerical investigation of the influence produced by electric circuit parameters on the formation of chemically active radicals in water vapours
title_full_unstemmed Numerical investigation of the influence produced by electric circuit parameters on the formation of chemically active radicals in water vapours
title_sort numerical investigation of the influence produced by electric circuit parameters on the formation of chemically active radicals in water vapours
publisher Національний науковий центр «Харківський фізико-технічний інститут» НАН України
publishDate 2015
topic_facet Вычислительные и модельные системы
url https://nasplib.isofts.kiev.ua/handle/123456789/112112
citation_txt Numerical investigation of the influence produced by electric circuit parameters on the formation of chemically active radicals in water vapours / D.V. Vinnikov // Вопросы атомной науки и техники. — 2015. — № 3. — С. 159-165. — Бібліогр.: 23 назв. — англ.
series Вопросы атомной науки и техники
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fulltext NUMERICAL INVESTIGATION OF THE INFLUENCE PRODUCED BY ELECTRIC CIRCUIT PARAMETERS ON THE FORMATION OF CHEMICALLY ACTIVE RADICALS IN WATER VAPOURS D.V.Vinnikov ∗ National Science Center ”Kharkov Institute of Physics and Technology”, 61108, Kharkov, Ukraine (Received February 6, 2015) The numerical investigation of the formation of chemically active radicals during the discharge in water vapors has been carried out. An increase in the number of radicals in terms of time and a change in thermodynamical discharge parameters were determined for different U , L, C values of the discharge circuit. Consideration was given to the two domains, in particular the discharge channel and the region between the discharge channel and the shock wave front. Special attention was given to such chemical components as: OH, O, H, H2O2, HO2, H2O. PACS: 52.80.Wg, 52.80.Tn, 51.50.+v 1. INTRODUCTION At the present time the underwater spark discharge finds many practical applications. The electrical hy- draulics repeatedly makes itself known as a new chap- ter of electrochemistry, which is called the pulsed electrochemistry. The electrohydraulic method can be used as an alternative of chemical methods used for the treatment of the medium in such processes as the removal of incrusting matters and diamond cakes or metal catalysts from the flax fiber, and also bleaching of flax cotton wool, drinking water disinfec- tion and waste water treatment. Therefore, a lot of experimental and theoretical work is done at the mo- ment [1-10] to investigate the mechanisms of changes in physical and chemical properties of water and wa- ter solutions of organic and inorganic substances sub- jected to the action of electrical discharge. The elec- trohydraulic discharge has many advantages as for its chemical action on liquid media in comparison with the atmospheric pressure barrier glow discharge with the electrolytic cathode, and the spark electric air discharge in the presence of water vapors [11]. In the case of electrohydraulic discharge active radicals are formed directly in the treated medium, and this pro- vides the volumetric treatment of the medium. Other types of discharges provide only the surface treatment that reduces their efficiency. In contrast to gas and transient discharges electric water discharges practi- cally exclude the formation of the broad spectrum of nitrides of high toxicity and sufficiently long lifetime. A hydroxyl radical OH is rather easily formed in wa- ter discharges and it has better oxidation properties in comparison with ozone. It should be noted that it is difficult to produce ozone in high humidity condi- tions because of the increased velocity of its decom- position. In previous papers consideration was given to the underwater spark discharge and its potential application for different technological processes [12- 14]. These scientific papers describe the vapor-gas- plasma cavity (VGPC) in which plasma, chemically active elements and their components capable of pro- ducing influence on the acidity of treated medium are formed. The VGPC envelope coincides with the shock wave front and it functions as an interface between the untreated liquid and the vapor-gas-plasma mix- ture. We gave no consideration to the availability of radicals outside the VGPC envelope. The pro- cesses that occur within the VGPC envelope require more detailed studies to reveal the areas of accrual of some chemically active radicals, for example, OH, HO2 those that are capable of changing the acid- ity of the treated medium. There are many math- ematical models [15-18] that allow for the adequate description of the processes that occur in the electro- hydraulic discharge. However, the chemical compo- sition of the medium for the known compositions is calculated on the assumption of the establishment of chemical equilibrium. The characteristic times of the behavior of chemical processes at abrupt discharges can exceed the characteristic times of the behavior of electrophysical processes. Therefore we need to use mathematical models that take into considera- tion nonequilibrium chemical kinetics and allow for ∗Corresponding author E-mail address: vinniden@mail.ru ISSN 1562-6016. PROBLEMS OF ATOMIC SCIENCE AND TECHNOLOGY, 2015, N3(97). Series: Nuclear Physics Investigations (64), p.159-165. 159 the estimation of formed active radicals. A scien- tific paper [19] proposes the numerical model that takes into consideration the nonequilibrium chemi- cal kinetics with the formation of active particles in the water exposed to the action of pulsed ultravio- let radiation created over the liquid surface by the independent spark discharge. The model [19] allows for the determination of a change in the concentra- tion of primary products that are formed in water. However, the mechanism of a change in physical and mechanical properties of water and water solutions at the electrohydraulic discharge differs from that of spark discharges over the liquid surface. This pre- vents us from using the known model [19] to study the processes in the electrohydraulic discharge. Due to the fact that it is rather difficult to take into con- sideration the liquid resistance to the dynamics of the VGPC boundary for the numerical simulation, the first stage of the research deals with the studies of the influence the parameters of electrical circuit on the formation of chemically active radicals in water vapors. 2. DESCRIPTION OF THE MODEL AND SIMULATION CONDITIONS For the numerical simulation of the spark discharge in water vapors we used the mathematical model that was described in detail in scientific paper [19] and that takes into consideration the nonequilibrium chemical kinetics with changed initial simulation con- ditions. The spark channel expansion process was described by the following equation system: ∂a⃗ ∂t + 1 r ∂r⃗b ∂r = 1 r f⃗ , (1) Where the column vectors are equal to: a⃗ =  ρ ρu ρε+ ρu2/2 yi  , b⃗ =  ρu p+ ρu2 u(ρε+ ρu2/2 + p) + kT dT/dr uyi  , f⃗ =  0 p r(σE2 −Qem) rω̇i  , (2) where ρ is the gas density, u is the velocity, p is the pressure, ε is the gas internal energy per gas mass unit, kT is the heat conduction coefficient, E is the electric field intensity in the discharge channel col- umn, σ is the channel plasma conductivity, Qem is the discharge energy losses for the radiation including the ionization and dissociation , r is the radius coor- dinate, T is the gas temperature, yi is the molar con- centration of the i-th component (OH, O, H, H2O2, HO2, H2O); is the rate of change in the concentration of the i-th component of the mixture due to chemical reactions. The model assumes that the local ther- modynamic equilibrium is established in the domain of the current-carrying channel. The processes that occur outside the current-carrying channel were cal- culated using the equations of nonequilibrium chem- ical kinetics [20]. Electric processes in the discharge circuit were expressed by the equation L di dt + [Rc +Rs(t)]i+ 1 C ∫ t 0 idt = U0 , (3) where L is the equivalent inductance of the dis- charge circuit, i is a current of the discharge cir- cuit, Rc is the active resistance of the discharge circuit, Rs is the resistance of the spark, C is the electric capacitance of the capacitor, U0 is the initial voltage of the capacitor charge. The formation of chemically active radicals was stud- ied in compliance with chemical reactions (Tab.1). Table 1. A simplified kinetic circuit of the behavior of chemical reactions [21] adopted for the model ( M denotes the third particle ) Number Reactions 1 H2O +M ↔ H +OH +M 2 H2O +H ↔ OH +H2 3 H +O2 +O2 ↔ HO2 +O2 4 H +O2 +H2O ↔ HO2 +H2O 5 H +O2 ↔ O +OH 6 H +HO2 ↔ O2 +H2 7 H +HO2 ↔ OH +OH 8 H +H2O2 ↔ HO2 +H2 9 H +O2 +M ↔ HO2 +M 10 OH +OH +M ↔ H2O2 +M 11 OH +HO2 ↔ O2 +H2O 12 OH +H2O2 ↔ HO2 +H2O 13 HO2 +HO2 ↔ O2 +H2O2 14 O +O +M ↔ O2 +M 15 O +H +M ↔ OH +M 16 H +OH ↔ O +H2 17 H +H +M ↔ H2 +M For the initial conditions in the calculated region we specified the availability of water vapors with the following thermodynamic parameters: p(r)|t=0 = p0 , T (r)|t=0 = T0 , u(r)|t=0 = 0 , (4) where p0 = 105 Pa, T0 = 473K. The given tem- perature and pressure provide the condition for the occupation of the calculated area with water vapors. The resistance of the discharge circuit was assumed to be equal to Rc = 0.1Ohm. The influence pro- duced by the parameters of electric circuit on the formation of radicals was studied by varying the value of one of the parameters (C, U0, L). The val- ues of the parameters are C = {2µF, 4µF, 6µF}, 160 U0 = {15 kV, 20 kV, 25 kV }, L{3µH, 5µH, 7µH}. The length of the discharge gap was assumed to be equal to l = 5mm. For the boundary conditions it was assumed that the gradients of thermodynamic parameters on the discharge channel axis are equal to zero. The processes of the intensive nucleation of chemically active radicals occur in the first quar- ter of the period of oscillatory decaying discharge [21]. Therefore, the calculated data are given for this particular period of time. It is known [22] that the chemical activation region is limited during the dis- charge by the parameter B = 4l, where l is the length of the interelectrode gap. Therefore the size of the calculated region was The equation system of the gas dynamics (1) was calculated using the S.K.Godunov scheme [23]. 3. MATHEMATICAL SIMULATION DATA To study the general mechanisms of the change in the chemical composition of the discharge medium it is necessary to consider the kinetics of the change of the mole concentrations of the components along the radius of the spark channel with the elapse of time (Figs.1,a-c and Fig.2). Water dissociation into hy- drogen and oxygen occurs in the spark channel under the action of high temperature. The concentration of water vapors increases while moving away from the discharge channel axis due to the drop in the medium temperature (see Fig.2). The concentration peak of water vapors is in the middle of the region between the discharge channel and the shock wave front, which is related to the medium compression process after the shock wave front at the gas dynamic expansion of the spark channel. m 3/cmmol m 3/cmmol m 3/cmmol m 3/cmmol m 3/cmmol m 3/cmmol Fig.1. The distribution of the mole concentrations of components as a function of the distance along the radius [ a) — O; b) — H; c) — H2O; d) — OH; e) — HO2; f) — H2O2 ] across the channel section at a time point of 1...0.1µs, 2...0, 5µs, 3...1µs, 4...2µs, 5...3µs ( the discharge at C = 2µF , U = 25 kV , L = 3µH ) Figs.1,a-c show that all chemical components, ex- cept water are characterized by a decrease in their maximum concentration values after 0.5µs from the beginning of the discharge progress. The radicals O and H are formed not only in the current carrying channel but also in the region adjacent to the chan- nel and limited by the shock wave front. An increase in the number of radicals is caused by nonequilib- rium chemical reactions. The radicals OH, HO2, and peroxide H2O2 are formed in the region be- tween the discharge channel and the shock wave front (Figs.1,g,d,e). In the region of the current-carrying channel the concentration of the components OH, HO2, and peroxide H2O2 is negligibly small (see Fig.2). Therefore, an increase in the concentration of the given radicals begins from the moment of the separation of the shock wave front from the current- carrying channel, which in terms of calculations cor- responds to the time range of 0.2...0.5µs. The con- centration maximum occurs at a distance of 2mm from the discharge channel axis. As the spark dis- charge develops the region of OH, HO2, and peroxide H2O2 formation moves away from the channel axis. As a result the radical formation space is increased in proportion to the radius square (of the current po- sition of the formation region). The comparative analysis of the distribution of the mole concentrations of considered active radi- cals along the radius at a time point of t = 3µs is given in Fig.2. It has been established that the O, H and OH components have the highest con- centration and the concentration of HO2 and H2O2 is several orders lower. This gives the grounds to suppose that a change in the chemical composition 161 of the medium at the water discharge can mainly be provided due to the action of the O, H and OH. m 3/cmmol Fig.2. The distribution of the mole concentrations of the components along the radius at a time point of t = 3µs (for the discharge at C = 2µF , U = 25 kV , L = 3µH) Since the conditions for the progress of chemical reactions are created between the current-carrying channel and the shock wave front and the concen- tration of the OH radical in this region exceeds the concentration of other components one can state that the main physical and chemical transformations that occur at the liquid discharge are related to the for- mation of the hydroxyl radical OH. The vertically dotted line shows the regions under consideration. 1 — the discharge channel, 2 – the first half of the region between the discharge channel and the shock wave front, 3 — the second half of the region be- tween the discharge channel and the shock wave front, 4 – the region in front of the shock wave front. The calculated concentrations of active radicals at a time point of t = 3µs are given in Table 3. It should be noted that the jump in HO2 and H2O2 concentrations is the most intensive and it changes by 8 to 11 orders accordingly, while the OH con- centration increases by 4 orders. The concentration of hydrogen and oxygen is somewhat lower in the current-carrying channel due to a decrease in den- sity. However, in the region between the channel and the shock wave front the radicals O, H and OH have the highest concentration. Table 2. The concentration of active components at a time point of 3µs after the initiation of the spark channel in water vapors Active Concentration mol/cm3 Concentration mol/cm3, the first half Concentration mol/cm3, radicals in the discharge channel the region between the discharge the second half of the region Region N1 channel and the shock wave front between the discharge channel Region N2 and the shock wave front Region N3 H 8× 10−6...10−5 10−5...7× 10−7 7× 10−7...0 O 5× 10−6...7× 10−6 7× 10−6...10−7 10−7...0 OH 9× 10−10...4× 10−9 4× 10−9...2× 10−6 2× 10−6...0 HO2 7× 10−15...6× 10−14 6× 10−14...10−8 10−8...0 H2O2 5× 10−19...10−16 10−16...5× 10−9 5× 10−9...0 Figs.3,a,b,c,d gives the results of the studies of the influence produced by electric circuit parameters on the formation of the hydroxyl radical OH, and also on the distribution of thermodynamic parameters in the spark channel. The subsequent comparative analysis of the influence of electric circuit parame- ters was done with regard to the calculation variant: U0 = 25 kV , C = 2µF , L = 3µH (see Fig.3,a). Cal- culated data that are given in Fig.3,b were obtained by changing the voltage U0. To obtain further results we changed the capacitor capacitance (see Fig.3,c) and the discharge circuit induction (see Fig.3,d). Only one circuit parameter was changed: the others remained unchanged. It has been established that as the capacitor charge voltage drops from 25 kV to 15 kV , the mean temperature and the pressure in the region of the progress of nonequilibrium chemical reactions (between the current-carrying channel and the shock wave front) reduce by the time point of 3µs from 3500K to 2500K, and from 1.5MPa to 1MPa, accordingly. (see Fig. 3 a, b). The concentration of the radical OH drops from 8mol/cm3 at 25 kV to 5, 8mol/cm3 at 15 kV . A change in the capacitance from 2µF to 6µF affects the OH formation to a lesser extent, though the mean values of temperature and pressure are somewhat increased (see Fig 3 a, b). The increase in the discharge circuit induction from 3µH to 7µH results in a decrease of the average con- centration of the hydroxyl radical down to 5mol/cm3 (see Fig.3,a,d). It should be noted that the change of either electric parameter results in no characteris- tic region for the formation of active radicals. The maximum values of the concentration of hydroxyl radicals are observed in the section that is closer to the current-carrying channel. It has thus been established that the formation of chemically active radicals, in particular the hydroxyl radical OH occurs in the region between the discharge channel and the shock wave front and directly depends on the current and thus the electric parameters of the discharge loop. 162 Pa m 3/cmmol Pa m 3/cmmol Pa m 3/cmmol Pa m 3/cmmol Fig.3. The distribution of the mole concentrations of the hydroxyl radical OH taking into consideration the changes in temperature and pressure as a func- tion of a distance along the radius at a time point t = 3µs. For a)– U = 25 kV , C = 2µF , L = 3µH; b)– U = 15 kV , C = 2µF , L = 3µH; c)– U = 25 kV , C = 6µF , L = 3µH; d)– U = 25 kV , C = 2µF , L = 7µH Figs.4, 5, 6 show the distribution relationships of the mole concentrations of the atomic oxygen and the OH radical as a function of discharge circuit param- eters. We can see that an increase in the voltage and battery capacitance results in a change of the concentrations of both radicals. An increase in the induction results on the contrary in a decrease in the formation of the radicals proposed for the considera- tion. The experimental papers show that the electric field intensity affects the formation of active radicals and the intensity can be controlled in its turn using electric circuit parameters. The formation of active radicals intensifies as the intensity increases and the capacitance factor and the induction factor are opti- mized. The above Figures show that the realization of these relationships results in higher concentra- tions of the OH radical at initial discharge stages and general increase in the formed substance across the distance along the discharge channel section. m 3/cmmol m 3/cmmol Fig.4. The distribution of the mole concentrations of the components as a function of a distance along the radius at a time point of t = 3µs. a) — O, and b) — OH. For C = 2µF , L = 3µH, 1...15 kV , 2...20 kV , 3...25 kV m 3/cmmol m 3/cmmol Fig.5. The distribution of the mole concentrations of the components as a function of a distance along the radius at a time point of t = 3µs: a) — O, and b) — OH. For U = 25 kV , L = 3µH, 1...2µF , 2...4µF , 3...6µF 163 m 3/cmmol m 3/cmmol Fig.6. The distribution of the mole concentrations of the components as a function of a distance along the radius at a time point of t = 3µs. a)— O, and b)— OH. For C = 2µF , U = 25 kV , 1...3µH, 2...5µH, 3...7µH 4. CONCLUSIONS The numerical investigation of the influence produced by the electric parameters of the discharge circuit on the formation of chemically active radicals OH, O, H2O2, HO2 at the development of the spark dis- charge in water vapors has been carried out. It has been established that by changing the parameter values of the discharge circuit one can regulate the amount of the produced substance and control ther- modynamic parameters. The induction and voltage affect significantly the values under study. A decrease in the discharge circuit induction and an increase in the voltage result in the intensified formation of ac- tive radicals. A change in the capacitance in the con- sidered range produces a lower influence. During the liquid discharge active particles are formed both in plasma, i.e. in the current channel and in the gas- vapor phase, i.e. the region between the outer chan- nel boundary and the shock wave front, which cor- responds to the internal space of vapor-gas-plasma cavity. Hydrogen and oxygen are prevalent in the area adjacent to discharge channel.The most active formation phase is observed in the region adjacent to the current channel. Near the internal boundary of the shock wave front the intensity of the reactions is decreased and as a consequence the formation of ac- tive radicals decays. In the region between the cur- rent channel and the shock wave front we observe an increase in the concentration of OH, H2O2, HO2 radicals with a simultaneous precocious decrease in O and H concentrations. Therefore, during the assem- bly of electrical equipment used for electrochemical purposes, in particular for the generation of chemi- cally active particles, or to change pH of the medium or to intensify the bactericidal effect action on the pathogenic microflora we recommend to decrease in- duction factors with a simultaneous increase in U and C parameters. From the point of view of the practi- cal application the variant of the change of the charge voltage to improve radical formation factors will be the most optimal. It has been established that the hy- droxyl radical OH and the atomic oxygen that define the medium acidity prevail in the given time ranges for studied radicals, which is important for different practical applications. One can assume that for prac- tical purposes the formation of chemically active rad- icals in treated liquid media can be controlled using the electrohydraulic method, which in its turn can provide many advantages in comparison with some chemical methods of treatment,for example, using the chlorination. References 1. B.N.Kondrikov, A. I. Vovchenko, V. E.Annikov, V.V. Ivanov. Explosive Conversions of Electric and Chemical Energies // Explosive Conver- sions of Electric and Chemical Energies . Kyiv: ”Naukova Dumka”, 1987, 128 p. (in Russian). 2. E.V.Krivitskiy. Electric Detonation Dynamics in Liquid. Kyiv: ”Naukova Dumka”,1986, 208 p. (in Russian). 3. V.Y.Ushakov. Pulsed Liquid Breakdown. TSU Publishing House . Tomsk, 1975, 258 p. (in Rus- sian). 4. N. I.Kuskova. Spark Discharges in Condensed Media // Journal of Engineering Physics . 2001, iss.2, 71 p. (in Russian). 5. A.A.Ruhadze. Exploding Wires. M.: ”Publishing House of Foreign Literature”. 1963, 341 p. 6. B.V. Semkin, A. F.Usov, V. I.Kurets. Basics of the Material Destruction by Electric Pulse. M.: ”Nauka”. 1993, 276 p. (in Russian). 7. L.A.Kuzmicheva. Generation of Chemically Ac- tive Oxidizing Particles in Electrolyte Solutions Exposed to the Action of the Glow Discharge and the Diaphragm Discharge //Electronic Treat- ment of Materials . 2007, N2, p.20-30 (in Rus- sian). 8. L.A.Kuzmicheva, Y.V.Titova, A. I.Maksymov. Output of Hydroxyl Radicals and Hydrogen Per- oxide in the Glow Discharge System with the Liq- uid Cathode // Electronic Treatment of Materi- als. 2011, N47(6), p.45-47 (in Russian). 9. N.A.Yavorovskiy, Ya. I. Kornev, S.V. Preis, S. S. Pelzman, M.B.Haskelberg, B.N.Chen. 164 Pulse Barrier Discharge as a Method of Water Treatment: Active Particles Act as Oxidizers in the Air-Water Flow // Izvestiia of Tomsk Polytechnic University. 2006. N2, 309 p. (in Russian). 10. I.M.Piskarev. Selection of Electric Discharge Conditions During the Generation of Chemically Active Particles to Decompose Admixtures in Water // Journal of Engineering Physics . 1999, iss.1, v.69, p.58-63 (in Russian). 11. R.Ono, T.Oda. Dynamics of Ozone and OH Radicals Generated by Pulsed Corona Discharge in Humid-Air Flow Reactor Measured by the Laser Spectroscopy // J.Appl. Phys. 2003, v.93, N10, p.5876–5882. 12. V.B.Yuferov,D.V.Vinnikov,I. V.Buravilov, A.N. Ponomarev, E.V.Mufel, A.Yu. Pahomov, V.V.Garbuz, K. I.Givankov. Electrohydraulic Method of Degassing Evacuated Liquids // Vestnik of NTU “KPI”. 2011, N16, p.211-217 (in Russian). 13. D.V.Vinnikov, A.N.Ozerov, V.B.Yuferov, A.V. Sakun, K.V.Korytchenko, A. P.Mesenko. Experimental Investigation of Electric Liquid Discharge Created Between the Electrodes with the Cone Cavity // Elektrotechnika and Elek- tromechanika. 2013, N1, p.55-60 (in Russian). 14. D.V.Vinnikov, A.N.Ozerov, V.B.Yuferov , A.N. Ponomarev, I. V.Buravilov. Comparative Analysis of Electrohydraulic and Pneumoacous- tic Sources for Some Technological Processes // PAST. 2014, N1(89), p.74–80. 15. K.V.Dubovenko. Taking into Account the Inter- action of the Plasma in the Underwater Elec- tric Discharge Channel with the Shock Wave Re- flected by the Chamber Wall // Electronic Treat- ment of Materials. 2013, N49(1), p.30-38. 16. T.A.Andreeva, S.N.Kolgatin, K.V.Hishenko. To the Issue on the Selection of Adequate Mathe- matical Model for the Solution of Problems with Powerful Pulse Energy Input // Journal of En- gineering Physics. 1998, N5, 68 p. (in Russian). 17. T.A.Andreeva, S.N.Kolgatin, K.V.Hishenko. The Dynamics of Gas Cavity Pulsations in the Compressed Liquid Caused by the Electrodischarge-Based Energy Input. // Elec- tronic Treatment of Materials. 2013, N49(4), p.94-99. 18. I.M.Piskarev, I. P. Ivanova, S.V.Trofimova Chemical Effects of Independent Spark Dis- charge. Simulation of Processes in Liquid // High Energy Chemistry. 2013, v.47, N2, p.152-156 (in Russian). 19. K.V.Korytchenko, E.V. Poklonskiy, D.V.Vinnikov, D.V.Kudin. Numerical sim- ulation of gasdynamic stage of spark discharge in oxygen // Problems of Atomic Science and Technology. 2013, 4(86), p.155-161. 20. E. L. Petersen, R.K.Hanson. J. Prop, and Power. 1999, v.15 (4), p.591. 21. http://expert.urc.ac.ru/egd/65687759.html. 22. E.A.Azizov, A. I. Emelianov, V.A. Iagnov. Elec- tric Discharge Methods Used for the Water Dis- infection // Applied Physics . 2003, N2, p.26-30 (in Russian). 23. S.K.Godunov, et. al. Numerical Solution of the Multidimensional Problems of Gas Dynamics. M.: ”Major Editorial Office of the Scientific Pa- pers for Physics and Mathematics of the Publish- ing House Nauka”, 1976, p.400. ×ÈÑËÅÍÍÎÅ ÈÑÑËÅÄÎÂÀÍÈÅ ÂËÈßÍÈß ÏÀÐÀÌÅÒÐΠÝËÅÊÒÐÈ×ÅÑÊÎÉ ÖÅÏÈ ÍÀ ÍÀÐÀÁÎÒÊÓ ÕÈÌÈ×ÅÑÊÈ ÀÊÒÈÂÍÛÕ ÐÀÄÈÊÀËΠ ÏÀÐÀÕ ÂÎÄÛ Ä.Â.Âèííèêîâ Ïðîâåäåíî ÷èñëåííîå èññëåäîâàíèå îáðàçîâàíèÿ õèìè÷åñêè àêòèâíûõ ðàäèêàëîâ ïðè ðàçðÿäå â ïàðàõ âîäû. Äëÿ ðàçëè÷íûõ çíà÷åíèé U , L, C ðàçðÿäíîé öåïè îïðåäåëåíû íàðàáîòêà ðàäèêàëîâ âî âðåìåíè è èçìåíåíèå òåðìîäèíàìè÷åñêèõ ïàðàìåòðîâ ðàçðÿäà. Ðàññìîòðåíû äâå îáëàñòè îáðàçîâàíèÿ ðàäèêàëîâ: êàíàë ðàçðÿäà, îáëàñòü ìåæäó êàíàëîì ðàçðÿäà è ôðîíòîì óäàðíîé âîëíû. Ðàññìàòðèâàëèñü õèìè÷åñêèå êîìïîíåíòû: OH, O, H, H2O2, HO2, H2O. ×ÈÑÅËÜÍÅ ÄÎÑËIÄÆÅÍÍß ÂÏËÈÂÓ ÏÀÐÀÌÅÒÐI ÅËÅÊÒÐÈ×ÍÎÃÎ ÊÎËÀ ÍÀ ÍÀÏÐÀÖÞÂÀÍÍß ÕIÌI×ÍÎ ÀÊÒÈÂÍÈÕ ÐÀÄÈÊÀËIÂ Ó ÏÀÐÀÕ ÂÎÄÈ Ä.Â.Âiííiêîâ Ïðîâåäåíî ÷èñåëüíå äîñëiäæåííÿ óòâîðåííÿ õiìi÷íî àêòèâíèõ ðàäèêàëiâ ïðè ðîçðÿäi â ïàðàõ âîäè. Äëÿ ðiçíèõ çíà÷åíü U , L, C ðîçðÿäíîãî êîëà âèçíà÷åíî íàïðàöþâàííÿ ðàäèêàëiâ ó ÷àñi òà çìiíà òåðìîäèíàìi÷íèõ ïàðà- ìåòðiâ ðîçðÿäó. Ðîçãëÿíóòi äâi îáëàñòi óòâîðåííÿ ðàäèêàëiâ: êàíàë ðîçðÿäó, îáëàñòü ìiæ êàíàëîì ðîçðÿäó i ôðîíòîì óäàðíî¨ õâèëi. Ðîçãëÿäàëèñÿ õiìi÷íi êîìïîíåíòè: OH, O, H, H2O2, HO2, H2O. 165

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