RU2661232C1 - Ozone generation method and ozone generation portable device - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: group of inventions relates to the ozone from oxygen-containing gas physical generation methods and devices and can be used for bactericidal treatment of wounds, gynecological pathologies, surgical instruments sterilization. Method comprises the oxygen-containing gas supply at a pressure of 120 to 140 mm Hg to the interelectrode space. Acting upon the gas with the rectangular shaped electric pulse discharge with steep fronts and cuts with amplitude of 300 kV and frequency of 300 Hz, additionally modulated by amplitude with the frequency of 50 Hz. Portable device contains located in the ozone-resistant housing power supply unit and high-frequency generator, connected to the power supply unit output fan, high-voltage pulse transformer, which input is connected to the high-frequency pulse generator output, and its high-voltage output is connected to the reactor chamber electrodes. Device also contains a pump, which input is connected to the mains switch and the output is to the reactor chamber input. Reactor chamber is the pair of parallel located polished glasses with dimensions of 120×60×5 mm, on the outer side coated with the metallization layer with dimensions of 90×40 mm. Distance between the glasses is 2 mm, and from the ends the chamber is sealed. Into the glasses 2 glass unions are brazed-in with external diameter of 4 mm and internal diameter of 3 mm, at that, the unions are located on the chamber opposite sides at distances of 8 mm from the chamber outer edge.

EFFECT: multiple increase in ozone concentration at the reactor chamber outlet, under otherwise equal conditions and power consumption, absence of the exhaust gas contamination with oxides, increase in the reactor chamber reliability, without the use of expensive metals or their alloys for electrodes, relaxation in the requirements for the oxygen-containing gas preliminary purification and drying.

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Description

FIELD OF THE INVENTION

The group of inventions relates to methods and devices for the physical generation of ozone from an oxygen-containing gas, in particular to a method for generating ozone and a portable device for its implementation, namely, electric discharge ozone generators, and can be used for bactericidal treatment of wounds, gynecological pathologies, sterilization of a surgical instrument.

State of the art

A known method of ozonation of air, which relates to the field of ozone in the air or gas environment, is used as a method for ozone treatment in various fields, in particular, in agricultural production technologies, food and chemical industries. The method includes supplying air to the interelectrode space, exposure to it by an electric pulse discharge with a voltage amplitude of 10-300 kV, a duration of (1.2-10.0) * 10 ^-6 s, a voltage rise rate of 3 * 10 ⁷ sq / s. The surface of one of the electrodes in the interelectrode space is covered with a layer of solid dielectric. An initiating pulse is applied to the electrodes sequentially, the positive potential of which is applied to the electrode covered with a dielectric layer, and an alternating harmonic voltage with an amplitude equal to 0.9 of the amplitude of the initiating pulse, with a frequency of 5-100 kHz. The impact is carried out cyclically with a period of 2 * 10 ^-3 -6 * 10 ^-5 s. A voltage of positive polarity up to 1 kV is applied to an electrode covered with a dielectric layer simultaneously with an alternating voltage supply (see Pat. SU 941276 IPC C01B 13/11, published 07.07.1982).

The disadvantages of this invention is the presence of a dielectric barrier, which is most often damaged in the operation of an element of ozonation installations during the transition of a barrier discharge to a spark discharge, and this transition is detrimental to the ozone generator, because a spark irreversibly violates the integrity of the barrier.

A known method of producing ozone, which consists in passing an oxygen-containing gas through a discharge zone formed concentrically. installed low-voltage and high-voltage tubular electrodes, while cooling the high-voltage electrode with liquid refrigerant, and gaseous bubbles are periodically fed into the internal cavity of the high-voltage electrode, the volume and frequency of their supply being determined by the following formulas:

where d is the thickness of the annular gap, m; R _Tr - the inner radius of the electrode, m; V is the bubble ascent rate, m / s (see Pat SU 1774585 IPC C01B 13/11, publ. 05/15/1994).

The disadvantages of this invention is the dependence of the electrical characteristics of the dielectric barriers on moisture and pollution, their change during operation, a strong effect on gas discharge processes and performance on ozone; and, therefore, the need for mandatory purification of the working gas in the discharge gap from dust and moisture.

A device for generating ozone is known, comprising two electrodes connected to a high voltage source of alternating voltage and forming a gas discharge gap, and dielectric barriers located therein made of organic material, characterized in that a mixture of organosilicon varnish and oxide is deposited on the surface of the dielectric barriers from the gas discharge gap aluminum in a ratio of 1: 1 (see US Pat. RU 2355627 IPC C01B 13/11, published on 05/20/2009).

The disadvantages of this device is the low efficiency and complexity of the mechanical design of the ozonizer.

A known ozone generator containing water-cooled high-voltage and grounded tubular electrodes, tubes of dielectric material, an insulating high-voltage electrode, insulators, a fitting for supplying and exiting working gas and cooling water, characterized in that it contains a device spacing the electrodes, is applied to each electrode by electrostatic sputtering glass enamel with a thickness of 0.3-0.5 mm, and the gas gap between the electrodes is equal to the thickness of the glass enamel (see Pat. RU 2184697 IPC C01B 13/11, publ. 10.07.2002).

The disadvantages of this device is the high cost, the limited size and shape, and the most significant drawback.

Known ozonizer using thermally sprayed ceramic dielectrics. It consists of two electrodes, between which a discharge is formed. The dielectric is located between the first and second electrode, it consists of a support element made of glass or glass ceramics, on which a thin film up to 100 microns is applied. The use of glass or glass ceramics as a dielectric, in combination with an additional thin ceramic dielectric film, can significantly increase the concentration of ozone in the carrier gas, simultaneously with a good yield of ozone (see US Pat. US 6322759 DE 19822841 A1, DE 19822841 B4, publ. 27.11 .2001).

The disadvantages of this device are the high cost of production of ceramic barriers, the limited size and shape, and the most significant drawback is the ceramic, which is a poor structural material, which hinders their widespread adoption for industrial purposes.

The closest in technical essence and the achieved positive effect and adopted by the authors for the prototype is a method of air ozonation, including cleaning, moisture separation, cooling and exposure to an electric discharge, characterized in that, in order to reduce energy intensity and increase the output of ozone, the effect is produced by high-voltage pulse discharge with voltage amplitude - 10-600 kV, pulse duration (1.2-200) * 10 ^-6 s, voltage rise rate 10-10 ⁵ kV / μs and duty cycle between pulses 0.9 * 10 ^-6 3-1.12 s (see Pat. SU 17753 53 IPC C01B 13/11, publ. 15.11.1992).

The disadvantages of this invention is the pollution of the exhaust gas by oxides; obtaining a low concentration of ozone at the outlet of the reactor chamber, ceteris paribus and energy consumption.

The closest in technical essence and the achieved positive effect and accepted by the authors for the prototype is a portable air ozonizer containing a power supply placed in an ozone-resistant housing and a high-frequency generator, the input of which is connected to the output of the power supply, a spark gap with electrodes, while it is equipped with a piezoceramic high-voltage transformer, the input of which is connected to the output of the high-frequency generator, and its high-voltage output is connected to the input electrode of the arrester, the output electrode is The latter is connected to the input of a high-frequency generator, while the spark gap is made in the form of a plate of dielectric material, with electrodes deposited on its both surfaces. It contains a timer whose input is connected to the output of the power supply, and the output is connected to the input of the high-frequency generator, a fan connected to the output of the power supply (see Pat. RU 2139239 IPC C01B 13/00, C01B 13/11, A61L 9/015, A61L 9/12, publ. 10.10.1999).

The main disadvantage of this design is the uneven distribution of the current density of the electric discharge over the entire area of the discharge gap, as well as low efficiency.

Disclosure of invention

The objective of the invention is to develop a method for generating ozone and a portable device for generating ozone, which provides for the absence of pollution of the exhaust gas by oxides; obtaining a multiple increase in ozone concentration at the outlet of the reactor chamber, ceteris paribus and energy consumption, which in turn helps to improve the quality of veterinary care, the development of both animal husbandry and research and development.

The technical result that can be obtained using the present invention is reduced to a multiple increase in the concentration of ozone at the outlet of the reactor chamber, ceteris paribus and energy consumption, provides for the absence of pollution of the exhaust gas by oxides, and the design of the portable device can improve the reliability of the reactor chamber, without using electrodes of expensive metals or their alloys, reduce the requirements for pre-treatment and drainage of oxygen-containing gas.

The technical result of the invention is achieved using a method of generating ozone, including the supply of oxygen-containing gas to the interelectrode space, exposure to it by an electric pulse discharge, an amplitude of 300 kV, while the pressure of the oxygen-containing gas is supplied at 120-140 mmHg, and the electric pulse discharge is used in a rectangular shape with steep fronts and slices, a frequency of 300 Hz, additionally modulated in amplitude with a frequency of 50 Hz.

The technical result is achieved using a portable device for generating ozone, containing a power supply unit and a high-frequency generator, a fan connected to the output of the power supply unit, a high-voltage pulse transformer, the input of which is connected to the output of the high-frequency pulse generator, and its high-voltage output is connected to the electrodes the reactor chamber, while it contains a pump, the input of which is connected to the mains switch, and the output to the input of the reactor chamber, while the reactor chamber is used with two barriers, which consists of two parallel-mounted polished glasses of 120 × 60 × 5 mm in size, coated on the outside with a metallization layer of 90 × 40 mm, the distance between the glasses being 2 mm, and the chamber is sealed from the ends, in glass 2 glass fittings are soldered in with an outer diameter of 4 mm and an inner 3 mm, while the fittings are on opposite sides of the chamber at a distance of 8 mm from the outer edge of the chamber.

Thus, the technical result of the invention is achieved using a device in which it contains a pump, the input of which is connected to a network switch, and the output to the input of the reactor chamber.

The essence of the method for generating ozone and a portable device for generating ozone is to include the supply of oxygen-containing gas to the interelectrode space, an electric pulse discharge of 300 kV amplitude is applied to it, and in order to reduce energy intensity and increase the output of ozone, an oxygen-containing gas pressure is applied at 120-140 mmHg, and an electric pulse discharge is used in a rectangular shape with steep edges and sections, a frequency of 300 Hz, additionally modulated with amplitude 50 Hz.

In the device, which contains a power supply and a high pulse voltage generator located in an ozone-resistant casing, a fan connected to the output of the power supply, a high-voltage pulse transformer, the input of which is connected to the output of the high-voltage pulse generator, and its high-voltage output is connected to the electrodes of the reactor chamber, moreover, it contains a pump, the input of which is connected to the mains switch, and the output - with the entrance of the reactor chamber, the reactor chamber is used with two barriers, the reactor is used a pressure chamber with two barriers, consisting of two parallel polished glasses 120 × 60 × 5 mm in size, coated on the outside with a metallization layer of 90 × 40 mm in size, the distance between the glasses is 2 mm, the chamber is sealed from the ends, 2 glass fittings are soldered into the glass an external diameter of 4 mm and an internal 3 mm, while the fittings are on opposite sides of the camera at a distance of 8 mm from the outer edge of the camera.

A brief description of the drawings and their materials

The drawing shows a method of generating ozone and a portable device for generating ozone, General view.

The implementation of the invention

The method of generating ozone and a portable device for generating ozone is as follows. A portable device for generating ozone contains: a pump 1, a high-voltage pulse generator 2, a high-voltage pulse transformer 3, thermal protection 4, a reactor chamber 5, which consists of two polished glasses 120 × 60 × 5 mm in size arranged in parallel, coated on the outside with a metallization layer size 90 × 40 mm, the distance between the glasses 2 mm, from the ends of the reactor chamber 5 is sealed, 2 glass fittings are soldered into the glass with an external diameter of 4 mm and an internal 3 mm, the fittings are opposite the reactor chamber 5 at a distance of 8 mm from the outer edge of the chamber, a network switch 6, a cooling fan 8 power supply unit 7, an ozone-resistant housing 9, the latter having: a power supply unit 7 and a high-frequency pulse generator 2 high pulse voltage, cooling fan 8 connected to the output of the power supply unit 7, a high-voltage pulse transformer 3, the input of which is connected to the output of the high-voltage pulse generator 2, and its high-voltage output is connected to the electrodes of the reactor chamber 5, wherein use the reactor chamber 5 with two barriers, which are two parallel polished glasses 120 × 60 × 5 mm in size, coated on the outside with a metallization layer of 90 × 40 mm in size, the distance between the glasses is 2 mm, the chamber 5 is sealed from the ends, and soldered to the glass 2 glass fittings (not shown) with an outer diameter of 4 mm and an inner 3 mm, while the fittings are on opposite sides of the chamber 5 at a distance of 8 mm from the outer edge of the chamber 5, and the device further comprises a pump 1, the input of which is connected to the network m switch 6, and the output with the entrance of the reactor chamber 5.

The operation of the portable device for generating ozone is as follows: when the power switch 6 is turned on, the 220 V power supply is supplied to the power supply unit 7 of the cooling fan 8, while the cooling fan 8 and the high voltage pulse generator 2, where electric oscillations are generated by a rectangular rectangular pulse discharge forms with steep fronts and sections, 300 kV amplitude, 300 Hz frequency, additionally modulated in amplitude with a frequency of 50 Hz, transmitted to a high-voltage pulse a transformer 3 connected to the reactor chamber 5, which consists of two barriers, parallel arranged polished glasses of 120 × 60 × 5 mm in size, coated on the outside with a metallization layer of 90 × 40 mm in size. The distance between the glasses is 2 mm. From the ends of the reactor chamber 5 is sealed. 2 glass fittings with an external diameter of 4 mm are soldered into the glass. and internal 3 mm. The fittings are located on opposite sides of the chamber 5 at a distance of 8 mm from the outer edge of the chamber 5. The fittings are designed for supplying and discharging gas. The metallization layers are supplied with a supply voltage from a high pulse voltage generator 2.

This design of the reactor chamber 5 allows you to:

- to achieve a combination of a very uniform pulsed "volumetric, quiet, corona, barrier" discharge, which, combined with a small pressure in the reaction zone, can significantly increase the concentration of ozone at the outlet of the reactor chamber 5;

- there is no contact of the reaction products directly with the metal of the electrodes, which in turn allows not to contaminate the outlet gas with products of oxidation and corrosion of the electrodes, which again in turn allows you to reduce the requirements for preliminary cleaning and drainage of the initial oxygen-containing gas and not to use expensive metals for electrodes or their alloys.

Examples of specific performance of the method of generating ozone.

Example 1. Through pump 1, an oxygen-containing gas is supplied at a pressure of 100 mmHg. column into the reactor chamber 5, an electric pulse discharge using a rectangular shape, a frequency of 200 Hz.

This method of generating ozone with the above parameters does not allow to obtain a sufficient concentration of ozone in the gas mixture.

Example 2. Carried out analogously to example No. 1, but through pump 1, an oxygen-containing gas is supplied at a pressure of 120 mm Hg. column into the reactor chamber 5, an electric pulse discharge using a rectangular shape with steep edges and sections, a frequency of 300 Hz, additionally modulated in amplitude with a frequency of 50 Hz.

This method of generating ozone allows you to get a multiple increase in the concentration of ozone at the outlet of the reactor chamber, ceteris paribus and energy consumption.

Example 3

Carried out analogously to example No. 1, but through pump 1, an oxygen-containing gas is supplied under a pressure of 140 mm. Hg. column into the reactor chamber 5, an electric pulse discharge using a rectangular shape, frequency 400 Hz, additionally modulated in amplitude with a frequency of 1000 Hz.

This method of generating ozone allows you to get a multiple increase in the concentration of ozone at the outlet of the reactor chamber, ceteris paribus and energy consumption.

Example 4

Carried out analogously to example No. 1, but through pump 1, an oxygen-containing gas is supplied under a pressure of 160 mm. Hg. column into the reactor chamber 5, an electric pulse discharge using a rectangular shape, frequency 400 Hz, additionally modulated in amplitude with a frequency of 1000 Hz.

This method of generating ozone allows you to get high concentrations of ozone at the outlet of the reactor chamber, but the energy consumption will be many times increased.

Thus, examples 2 and 3 are optimal, which boil down to a multiple increase in ozone concentration at the outlet of the reactor chamber 5, ceteris paribus and energy consumption, which also revealed the absence of pollution of the exhaust gas by oxides, and the simplified design of the portable device allows to increase the reliability of the reactor chamber 5 , without the use of expensive metals or their alloys for electrodes, reduce the requirements for pre-treatment and drainage of oxygen-containing gas.

The invention in comparison with the prototype and other known technical solutions has the following advantages:

- eliminates pollution of the exhaust gas with oxides;

- allows you to get a multiple increase in the concentration of ozone at the outlet of the reactor chamber, ceteris paribus and energy consumption.

Claims (2)

1. The method of generating ozone, including the supply of oxygen-containing gas to the interelectrode space, exposure to it by an electric pulse discharge, an amplitude of 300 kV, characterized in that the pressure of the oxygen-containing gas is supplied at 120-140 mmHg, and the electric pulse discharge is used in a rectangular shape with steep fronts and slices with a frequency of 300 Hz, additionally modulated in amplitude with a frequency of 50 Hz. 2. A portable device for generating ozone, containing a power supply unit and a high-frequency generator, a fan connected to the output of the power supply unit, a high-voltage pulse transformer, the input of which is connected to the output of the high-frequency pulse generator, and its high-voltage output is connected to the electrodes of the reactor chamber, characterized in that it contains a pump, the input of which is connected to the mains switch, and the output - with the input of the reactor chamber, while the reactor chamber is used with two I have barriers, which consists of two parallel-mounted polished glasses of 120 × 60 × 5 mm in size, covered on the outside with a metallization layer of 90 × 40 mm in size, the distance between the glasses being 2 mm, and the chamber sealed at the ends, 2 glass fittings soldered into the glass an external diameter of 4 mm and an internal 3 mm, while the fittings are on opposite sides of the camera at a distance of 8 mm from the outer edge of the camera.

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