RU2346886C2 - Ozone generator - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention can be applied in engineering of high-performance ozonation aggregates. Oxygen-containing gas is fed through gaps in mesh 5 cells. External 1 and internal 2 electrodes of ozone generator are made in tube form and connected to alternate current source. Electrodes are separated by discharge gap 3 of given size, through which the oxygen-containing gas flow passes. Under effect of alternate current source voltage between electrodes 1, 2 of ozone generator, volume-surface barrier discharge evolves in discharge gap 3 with structure of separate microdischarges spread regularly over the surface of dielectric layer 4. Mesh 5 is made of electroconductive material resistant to electric discharge, active chemicals and radical effect. Electric power supply is performed by alternate current source based on current inverter with fully controlled valves with quasi-resonant commutation and relay impulse controls.

EFFECT: reduced power cost of electric ozone synthesis.

1 dwg

Description

The invention relates to electrical technology and can be used in the design of new types of ozonation plants of increased productivity, which reduce energy consumption for the electrosynthesis of ozone.

A known ozone generator containing external and internal electrodes made in the form of tubes, one of the tubes has a smaller diameter and is placed coaxially inside the other tube, separated by a discharge gap of a given size, through which a stream of oxygen-containing gas passes, one of the electrodes on the discharge gap side is coated with a dielectric layer (Filippov Yu.V., Voblikova V.A., Panteleev V.I. Electrosynthesis of ozone. - M.: Publishing House of Moscow State University named after M.V. Lomonosov, 1987. - P. 44).

The disadvantage of the ozone generator is the high energy consumption for the electrochemical synthesis of ozone due to design flaws, poor cooling conditions of the electrodes and the insufficiently effective form of the electric barrier discharge in the volume of the discharge gap.

A known ozone generator containing external and internal electrodes made in the form of tubes, one of the tubes has a smaller diameter and is placed coaxially inside the other tube, separated by a discharge gap of a given size, through which a stream of oxygen-containing gas passes, one of the electrodes on the discharge gap side is coated with a dielectric layer (Ozonation equipment. Catalog of products. Kurgan: OJSC Kurganhimmash, 2005. P.58).

The disadvantage of the ozone generator is the high energy consumption for the electrochemical synthesis of ozone due to design flaws, poor cooling conditions of the electrodes and the insufficiently effective form of the electric barrier discharge in the volume of the discharge gap.

A known ozone generator containing external and internal electrodes made in the form of tubes, one of the tubes has a smaller diameter and is placed coaxially inside the other tube, separated by a discharge gap of a given size, through which a stream of oxygen-containing gas passes, one of the electrodes on the discharge gap side is coated with a dielectric layer (Samoilovich V.G., Panin V.V., Krylova L.N. Modern trends in the design of industrial ozonizers. Abstract of the report of the scientific technical conference dedicated to ozone and other environmentally friendly oxidizing agents. June 7-9, 2005, Moscow. 2005. P.138).

This ozone generator is the closest in technical essence to the invention and is considered as a prototype.

The disadvantage of the ozone generator is the high energy consumption for the electrochemical synthesis of ozone due to design flaws, poor cooling conditions of the electrodes and the insufficiently effective form of the electric barrier discharge in the volume of the discharge gap.

The invention is aimed at solving the problem of reducing energy consumption for the electrosynthesis of ozone, which is the purpose of the invention.

Reducing energy costs is achieved by the fact that in the ozone generator containing the external and internal electrodes made in the form of tubes, one of the tubes has a smaller diameter and is placed coaxially inside the other tube, separated by a discharge gap of a given size, through which the flow of oxygen-containing gas passes, one of the electrodes from the side of the discharge gap is covered with a dielectric layer, in the discharge gap there is a grid of conductive material that is resistant to the effects of electric discharge and chemical of active substances and radicals generated during an electric discharge in an oxygen-containing gas, the thickness and design of which determine the size of the discharge gap and the turbulent nature of the flow of oxygen-containing gas, the electric power is supplied from an alternating current source based on a current inverter on fully controllable valves with quasi-resonant switching and pulse-relay control having a falling characteristic of a current source.

A significant difference characterizing the invention is the reduction of energy consumption for the electrosynthesis of ozone. This is achieved by increasing the useful part of the energy input into the discharge and the energy output of ozone due to the significantly higher stability of the gas discharge, reducing losses in the dielectric layer, improving the cooling conditions of the electrodes, increasing the power factor, and reducing losses in the power source.

The reduction in energy consumption for ozone synthesis is the technical result due to the claimed device of the ozone generator, the proposed principle of passing oxygen-containing gas through the discharge gap and power supply, the effective form of the volume-surface barrier discharge and effective cooling of the electrodes, i.e. distinguishing features. Therefore, the distinguishing features of the inventive ozone generator are significant.

The drawing shows a design diagram of an ozone generator, explaining the device and the principle of placement and connection of elements.

The ozone generator contains an outer 1 and an inner 2 electrodes made in the form of tubes. One of the tubes has a smaller diameter and is placed coaxially inside the other tube. The electrodes are separated by a discharge gap 3 of a given size, through which a stream of oxygen-containing gas passes. One of the electrodes on the side of the discharge gap is covered with a dielectric layer 4. In the discharge gap there is a grid 5 made of an electric current-conducting material that is resistant to electric discharges and chemically active substances and radicals formed during an electric discharge in an oxygen-containing gas. The thickness and design of the grid determine the size of the discharge gap and the turbulent nature of the flow of oxygen-containing gas. Electrical power is supplied from an alternating current source based on a current inverter on fully controllable valves with quasi-resonant switching and relay-pulse control, having a falling characteristic of the current source.

The mesh can be made, for example, of titanium wire or stainless steel wire of circular cross section by weaving the threads at right angles. Electrical contact with an electrode that does not have a dielectric coating is ensured by mechanical contact (contact) of the grid surface with the electrode surface. The dielectric layer may be applied to the inner surface of the outer electrode or to the outer surface of the inner electrode. To increase productivity, the ozone generator can be made containing several sets of tubes connected in a stream of oxygen-containing gas in series or in parallel and placed in separate housings or in a single housing. The principle of operation of the ozone generator and the shape of the electric discharge in the discharge gap are not changed. In the discharge gap of the inventive ozone generator, a volume-surface (sliding) barrier discharge is excited.

The ozone generator operates as follows. Oxygen-containing gas passes through the gaps in the cells of the grid 5. The direction of the flow of oxygen-containing gas through the discharge gap 3 in the drawing is indicated by an arrow. The external and internal electrodes of the ozone generator 1, 2 are connected electrically to an AC source. The AC source can be made in the form of a generator of bipolar current pulses of rectangular shape, based on a current inverter on fully controlled valves with quasi-resonant switching and relay-pulse control, having a falling characteristic of the current source, or in the form of an alternating voltage generator of a sinusoidal or other shape, and also as a network source. Under the action of the voltage of the alternating current source between the electrodes 1, 2 of the ozone generator in the discharge gap 3, a volume-surface (sliding) barrier electric discharge arises. The electric discharge has the structure of individual microdischarges uniformly distributed over the surface of the dielectric layer 4. The gas flow due to the presence of the grid 5 in the discharge gap 3 has a turbulent character, which provides good heat transfer, mixing of oxygen-containing gas and helps to increase the uniformity and stability of the electric discharge. In microdischarges, oxygen molecules O ₂ dissociate. O oxygen atoms formed as a result of dissociation in collisions with O ₂ oxygen molecules form O ₃ ozone molecules. At the same time, the reverse reaction of O ₃ decomposition of ozone in an electric discharge by electron impact occurs, as well as under the influence of ultraviolet radiation, discharge and temperature. The technological conditions for electrosynthesis are provided such that the process of formation of ozone O ₃ in the discharge gap 3 prevails over the process of its decomposition. As a result, at the exit from the discharge gap 3, the oxygen-containing gas has a predetermined amount of ozone O ₃ in the mixture. The predetermined concentration of ozone O ₃ is determined by the electric mode of the ozone generator, the quality of preparation and purification of the oxygen-containing gas, as well as the cooling conditions of the elements of the discharge gap 3 and the electrodes 1, 2 of the ozone generator and oxygen-containing gas. The use of a volume-surface barrier discharge, relatively small width and high uniformity gaps, the presence of a grid 5 in the discharge gap 3, as well as the provision of a virtually turbulent flow of oxygen-containing gas through the discharge gap 3, intensify the process of electrosynthesis of ozone O ₃ , provide a small temperature difference of the oxygen-containing gas at the inlet and outlet of the discharge gap 3, intense heat removal from the dielectric layer 4, which increases the concentration and total output of ozone O ₃ . The heat removal from the dielectric layer 4 is partially carried out by the elements of the grid 5. The cooling conditions are significantly improved. The synthesis of ozone O ₃ high concentration is provided by the design of the electrode system. For the concentration of ozone [O ₃ ] at the output of the generator in the case of perfect mixing of the oxygen-containing gas in the discharge gap 3, we have

[O ₃ ] = K ₀ [O ₂ ] ₀ Pρ ^-1 ω ^-1 (1 + K ₁ ρ ^-1 ω ^-1 ) ^-1 ,

where [О ₂ ] ₀ is the initial concentration of oxygen, P ρ ^-1 ω ^-1 is the specific energy (factor of the second kind, kW · h / kg), P is the active power in the discharge, ρ is the density of the oxygen-containing gas, ω is the space velocity oxygen-containing gas, K ₀ - ozone formation constant, K ₁ - decomposition constant, ozone. In the case of ideal displacement (in the absence of diffusion of ozone O ₃ ), we have

[O ₃ ] = K ₀ [O ₂ ] ₀ K ₁ ^-1 (1-exp (-K ₁ Pρ ^-1 ω ^-1 )).

For the reaction of ozone synthesis in an electric discharge, a factor of the second kind (specific energy P ρ ^-1 ω ^-1 ) replaces the time in the kinetic equations. The achievable concentration of ozone [O ₃ ] for the inventive generator is higher.

An additional reduction in energy costs for ozone electrosynthesis can be achieved by using an ozone generator power supply having a falling current source characteristic, which can be performed on the basis of a current inverter on fully controllable valves with quasi-resonant switching and pulse-relay control.

Compared with the prototype, when using the inventive ozone generator, energy consumption for ozone synthesis is significantly reduced. Using the design of the inventive ozone generator allows you to change the shape of the electric discharge in the discharge gap of the ozone generator. In the discharge gap of the inventive ozone generator, a volume-surface barrier discharge is excited, which has the property of symmetry, which fundamentally provides a higher energy output of ozone in comparison with the classical barrier discharge. The greater energy yield of ozone in the volume-surface barrier discharge is due, in particular, to a more uniform distribution of microdischarges over the surface of the dielectric layer and to an improvement in the conditions of "quenching" of nonequilibrium concentrations of atomic oxygen in the volume of the discharge gap. The implementation of the grid of metal wire or metal strips provides greater mechanical rigidity of the design of the ozone generator and allows you to get a more uniform across the width of the discharge gap. The uniformity of the discharge gap contributes to a more uniform electric discharge and also increases the output of ozone. In General, the energy consumption for the electrosynthesis of ozone when using the inventive ozone generator can be reduced by 30-35%.

Claims (1)

An ozone generator containing external and internal electrodes made in the form of tubes, one of the tubes has a smaller diameter and is placed coaxially inside the other tubes, separated by a discharge gap of a given size, through which a stream of oxygen-containing gas passes, one of the electrodes is coated with a dielectric layer on the side of the discharge gap characterized in that in the discharge gap there is a grid of conductive material current resistant to electric discharge and chemically active substances and p adikals formed during an electric discharge in an oxygen-containing gas, the thickness and design of which determine the size of the discharge gap and the turbulent nature of the flow of oxygen-containing gas, the electric power is supplied from an alternating current source based on a current inverter on fully controllable valves with quasi-resonant switching and pulse-relay control having a falling characteristic of a current source.