RU51011U1 - WATER OZONIZATION PLANT - Google Patents

Abstract

The utility model relates to electrical technology and can be used in the design of new plants for cleaning and disinfecting high-performance water. The utility model reduces energy consumption when treating water with ozone. Installation for ozonation of water contains a contact tank with nozzles for supplying source and removal of treated water, an ozone generator made in the form of a tube of dielectric material with a nozzle for introducing oxygen-containing gas at one end, coaxially located inside the high-voltage electrode, the outer surface of which forms a discharge gap with the inner surface of the tube through which the oxygen-containing gas to be discharged passes, and the low-voltage electrode, the power source of the generator ora ozone terminals of which are connected to the electrodes, a dispersant for inputting oxygen-containing gas into the water. The ozone generator is placed directly in the water, which acts as a low-voltage electrode. The dispersant is mounted on the other end of the tube. The tube is made of a material that is optically transparent for ultraviolet radiation.

Description

The utility model relates to electrical technology and can be used in the design of new plants for cleaning and disinfecting high-performance water with reduced energy consumption when treating water with ozone.

A known installation for ozonation of water, containing a contact tank with nozzles for supplying the source and removal of treated water, an ozone generator, through the discharge gap of which oxygen-containing gas is subjected to discharge, with high-voltage and low-voltage electrodes, a power source for the ozone generator, the conclusions of which are connected to the electrodes, dispersant for introducing oxygen-containing gas into water (Application for. 2003110894 of the Russian Federation, MKI C 02 F 9 \ 12. Device for disinfecting running water \ V. Lukyanov, V. N. Tyukin, etc. - Application 1 April 6, 2003, Published on November 19, 2004. BIMP No. 32).

The disadvantage of the installation for ozonation of water is the high energy consumption when treating water with ozone, due to design flaws, poor cooling conditions of the discharge gap of the ozone generator, decomposition of ozone during the transportation of oxygen-containing gas from the ozone generator to the dispersant, and also on the walls of the connecting pipelines, which leads to a decrease ozone release, by not using other active factors of the electric discharge (ultraviolet radiation, chemically active short-lived radicals).

A known installation for ozonation of water, containing a contact tank with nozzles for supplying source and removal of treated water, an ozone generator, with a nozzle for introducing oxygen-containing gas, through the discharge gap of which oxygen-containing gas is subjected to discharge, with high-voltage and low-voltage electrodes, a power source for the ozone generator whose findings are connected to

electrodes, a dispersant for introducing oxygen-containing gas into water (Purification of industrial wastewater / S.V. Yakovlev, Y.A. Karelin and others; Edited by S.V. Yakovlev. - M.: Stroyizdat, 1985. - P. 119).

The disadvantage of the installation for ozonation of water is the high energy consumption when treating water with ozone, due to design flaws, poor cooling conditions of the discharge gap of the ozone generator, decomposition of ozone during the transportation of oxygen-containing gas from the ozone generator to the dispersant, and also on the walls of the connecting pipelines, which leads to a decrease ozone release, by not using other active factors of the electric discharge (ultraviolet radiation, chemically active short-lived radicals).

A known installation for ozonation of water, containing a contact tank with nozzles for supplying the source and removal of treated water, an ozone generator made in the form of a tube of dielectric material with a nozzle for introducing oxygen-containing gas at one end, coaxially located inside the high-voltage electrode, the outer surface of which forms a discharge a gap with the inner surface of the tube through which the oxygen-containing gas to be discharged passes and a low-voltage electrode, a power source a generator of ozone, the leads of which are connected to the electrodes, a dispersant for introducing oxygen-containing gas into the water (Vigdorovich V.N., Pravnikov Yu.A., Nizhade-Gavgani E.A. Problems of ozone production and ozone treatment and the creation of second-generation ozone generators. - M. S.Pb .: From the date. "Ecoinformsystem", 1994. - P.27).

This installation for ozonation of water is the closest in technical essence to a utility model and is considered as a prototype.

The disadvantage of the installation for ozonation of water is the high energy consumption when treating water with ozone, due to design flaws, poor cooling conditions of the discharge gap of the ozone generator, and decomposition of ozone over time

transporting oxygen-containing gas from the ozone generator to the dispersant, as well as on the walls of the connecting pipelines, which leads to a decrease in the ozone output by not using other active factors of the electric discharge (ultraviolet radiation, chemically active short-lived radicals).

The utility model is aimed at solving the problem of reducing energy consumption when treating water with ozone, which is the purpose of the utility model.

This goal is achieved by the fact that in the installation for ozonation of water containing a contact tank with nozzles for supplying source and removal of treated water, an ozone generator made in the form of a tube of dielectric material with a nozzle for introducing oxygen-containing gas at one end, coaxially located inside the high-voltage electrode the outer surface of which forms a discharge gap with the inner surface of the tube through which the oxygen-containing gas to be discharged and low voltage passes electrode, the power source of the ozone generator, the leads of which are connected to the electrodes, a dispersant for introducing oxygen-containing gas into the water, the ozone generator is placed directly in the water, which acts as a low-voltage electrode, the dispersant is installed on the other end of the tube, the tube is made of optically transparent for ultraviolet radiation discharge of material.

A significant difference that characterizes the utility model is the reduction in energy consumption when treating water with ozone. This is achieved by improving the design of the installation, increasing the useful part of the energy input into the electric discharge due to a significant improvement in the cooling conditions of the ozone generator, reducing the amount of decaying ozone during transportation from the ozone generator to the dispersant and on the walls of the connecting pipelines, and increasing, for this reason, the ozone output by more full use of all active factors of the electric discharge, in particular ultraviolet radiation and chemically active substances, and briefly ivuschih

radicals, for example, atomic oxygen generated in an electric discharge, as well as a hydroxyl radical.

The reduction of energy consumption in the treatment of water with ozone is the technical result due to the claimed design of the water ozonation unit, the principles of the ozone generator, cooling, the method of water treatment, the connection of the elements of the installation for ozonation of water, that is, the distinguishing features. Therefore, the distinguishing features of the inventive installation for ozonation of water are essential.

The figure shows the functional diagram of the installation for ozonation of water with structural elements, explaining the device, the principle of connecting parts and the operation of the inventive installation for ozonation of water.

The installation for ozonation of water in this embodiment has a design with one ozone generator. Fundamentally, the installation may contain a large number of ozone generators connected in parallel. The principle of operation of the installation for ozonation of water does not change. A barrier discharge is excited in the ozone generator of the water ozonation unit.

Installation for ozonation of water contains a contact tank with nozzles for supplying the source and removal of treated water, an ozone generator made in the form of a tube of dielectric material with a nozzle for introducing oxygen-containing gas at one end, coaxially located inside the high-voltage electrode, the outer surface of which forms a discharge gap with the inner surface of the tube through which the oxygen-containing gas to be discharged passes, and the low-voltage electrode, the power source of the generator ora ozone terminals of which are connected to the electrodes, a dispersant for inputting oxygen-containing gas into the water. The ozone generator is placed directly in the water, which acts as a low-voltage electrode. The dispersant is mounted on the other end of the tube. The tube is made of optical

transparent to ultraviolet radiation discharge material.

Installation for ozonation of water works as follows. Oxygen-containing gas enters the ozone generator through the pipe and passes through the discharge gap of the ozone generator in the direction of the arrow. The ozone generator electrodes, one of which is the treated water, are connected to the terminals of the alternating current ozone generator power source. When applying the voltage of the AC power source between the electrodes of the ozone generator (high voltage electrode and water) under the influence of the specified voltage in the discharge gap between the outer surface of the high voltage electrode and the inner surface of the tube of dielectric material in the flow of oxygen-containing gas, an electric barrier discharge occurs. An electric discharge has the structure of individual microdischarges uniformly distributed over the surface of a tube of dielectric material. In microdischarges, oxygen molecules dissociate. Oxygen atoms formed as a result of dissociation during collisions with oxygen molecules form ozone molecules. At the same time, the reverse reaction of the decomposition of ozone in an electric discharge occurs, under the influence of ultraviolet radiation and temperature. The technological conditions for the synthesis are provided such that the process of ozone formation in the discharge gap prevails over the process of its decomposition. As a result, at the outlet of the discharge gap, the oxygen-containing gas has a predetermined amount of ozone in the mixture. The set ozone concentration 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 discharge gap elements of the ozone generator and the oxygen-containing gas. Oxygen-enriched gas enriched with ozone is introduced into the treated water through a dispersant mounted on the other end of the tube. Since the inventive installation for ozonation of water provides operational contact of an oxygen-containing gas subjected to an electric barrier discharge with the processed

In addition to ozone, other chemically active substances and radicals formed in an electric discharge, for example, atomic oxygen and a hydroxyl radical, can also participate in oxidative reactions. Hydroxyl radical is the most chemically active of the known oxidizing agents. The formation in an electric discharge and the possibility of the simultaneous use of ozone and other chemically active substances and radicals can reduce the required amount of ozone for water treatment and increase the useful part of the energy input into the discharge, that is, reduce the unproductive energy consumption for water treatment. An electric barrier discharge is a source of intense ultraviolet radiation. The implementation of the tube of the ozone generator from a discharge of a dielectric material that is optically transparent for ultraviolet radiation makes it possible to use ultraviolet radiation of the discharge in oxidative processes and to intensify the chemical processes of oxidation by ozone and other chemically active substances and radicals. As a result, all active factors of the electric discharge are used more fully and unproductive energy costs are reduced. The dielectric tube of the ozone generator is cooled by water, which increases the cooling efficiency and ozone output. The treated water enters and leaves the contact reservoir through the nozzles for supplying the source and removal of the treated water.

The ozone generator in the claimed design of the installation for ozonation of water can be made on the basis of a tube of metal. In this case, the internal coaxial high-voltage electrode is made with an external dielectric coating. This design of the ozone generator provides greater mechanical strength. However, in this case, it is impossible to use such an active electric discharge factor as ultraviolet radiation when treating water. The principle of operation of the installation for ozonation of water in the manufacture of a tube of metal, in general, does not change, but the energy consumption during the treatment of water with ozone increases slightly.

Compared with the prototype when using the inventive installation for ozonation of water significantly reduced energy consumption when treating water with ozone. Using the design of the claimed utility model makes it possible to more fully use all the active factors of the electric discharge in the treatment of water with ozone, to intensify the process of water ozonation and the effect of other oxidative reactions on the treated water, the implementation of which becomes possible in the installation for ozonation of water. By improving the cooling conditions of the ozone generator in the inventive utility model, energy costs are reduced and ozone output is significantly increased. Operational input of oxygen-containing gas subjected to electric discharge into the treated water allows reducing the amount of decomposable ozone during transportation of oxygen-containing gas from the ozone generator to the dispersant and on the walls of the connecting pipelines, and makes it possible to use atomic oxygen and other chemically active substances and short-lived substances in oxidative reactions radicals formed in an electric discharge, which increases the energy yield of ozone. Additionally, in gas bubbles in water, including near the outer surface of the tube of an ozone generator, it is also possible to synthesize ozone and other chemically active substances and radicals and the appearance of partial electric discharges (due to local increases in the electric field strength in gas bubbles), intensified by ultraviolet radiation of the barrier discharge in the discharge gap. In general, the energy consumption during water treatment with ozone when using the inventive utility model of the installation for ozonation of water can be reduced by 25 ÷ 30%.

Claims (1)

Installation for ozonation of water, containing a contact tank with nozzles for supplying source and removal of treated water, an ozone generator made in the form of a tube of dielectric material with a nozzle for introducing oxygen-containing gas at one end, coaxially located inside the high-voltage electrode, the outer surface of which forms a discharge gap with the inner surface of the tube through which the oxygen-containing gas to be discharged passes and a low-voltage electrode, a gene power source an ozone generator, the terminals of which are connected to the electrodes, a dispersant for introducing oxygen-containing gas into the water, characterized in that the ozone generator is placed directly in the water, which acts as a low-voltage electrode, the dispersant is installed on the other end of the tube, the tube is made of a discharge optically transparent for ultraviolet radiation material.