EA046103B1 - PLASMA OZONATOR MODULE AND INSTALLATION FOR OZONE PRODUCTION - Google Patents

Description

The invention relates to a device for producing ozone using a plasma electric discharge and can be used in various industries for treatment with an ozone-air mixture in order to reduce the concentration of harmful substances in the air.

An ozone generator is known (Ozone generator: patent RU 2200701, Russian Federation, application RU 2002102584, application 01/28/2002, published 03/20/2003), consisting of a dielectric cylindrical pipe, on the outer surface of which an external metal electrode is placed. The internal electrode is made of metal mesh and placed coaxially, without a gap, along the inner surface of the pipe. The inner and outer electrodes are connected to an alternating current source. The air flow inside the dielectric pipe is supplied using an electric fan.

The disadvantages of this generator are determined by its design. The tight fit of the electrodes to the glass (dielectric barrier) causes a small area of the electrical barrier discharge, which, in turn, means low ozone productivity (g/h), because not all air flow passing through the dielectric pipe passes through the barrier discharge zone and, accordingly, is not affected by it. A tight fit of the electrodes also increases the likelihood of the ozone generator failing due to local overheating of the glass (there is no possibility of blowing) and, as a result, glass breakdown.

An ozonator is also known (Ozonator: patent RU 2261837, Russian Federation, application RU 2003124328, application 04.08.2003, publ. 10.10.2005), containing metal electrodes connected to an alternating current power source. The electrodes are separated by a discharge gap and a dielectric layer. The metal electrodes are made with a chamfer on the edges from the internal opposing surfaces, and the dielectric layer has a negative temperature coefficient of relative dielectric constant.

The absence in the description of this patent for an invention of numerical values of energy consumption for ozone production makes it impossible to assess the claimed advantages over similar devices. Also, the description does not contain the dimensions of the prototype generator, as well as the operating frequencies of its power source, which makes it difficult to assess the possibility of introducing ozonizers of this type into production.

Long-term operation of the ozonizer with a power source without automatic adjustment can lead to an increase in the temperature of the air cooling the ozonizer, which, in turn, will lead to a decrease in the dielectric constant of the dielectric layer. As a result, the performance characteristics of the ozonizer will deteriorate.

The closest to the claimed invention is an ozone generator (Ozone generator: patent EP 3478633, European patent organization, application EP 17823714, application/07/04/2017, publ. 03/24/2021), which is an ozonizer in which plates installed as electrodes are used parallel to each other. Due to the large area of the electrodes and the possibility of installing them in parallel from 2 to 30 pairs, the efficiency of ozone production increases while maintaining the small size of the ozonizer.

Additional advantages of using flat electrodes are an increase in the number of discharges on their surface and the efficiency of cooling the flat surface by passing air flows. Recommended electrode thickness is 0.3-1.5 mm.

By using flexible insulating gaskets between the electrodes, the required amount of ozone produced can be achieved.

The ozonizer described in the patent is equipped with microcontrollers that control the voltage of the power source based on the values of environmental parameters. The power supply allows you to output voltage in the range of 6 kV-12 kV with a frequency from 1 to 35 kHz.

It is recommended to cut rectangular electrodes from metal sheets, preferably stainless steel. This form allows you to effectively use the space allocated for the placement of the ozonizer.

The product described in the patent can be placed in the path of air or oxygen for ozone synthesis. It is recommended to place the developed ozonizer in insulated air ducts with a rectangular cross-section. The placement should be parallel to or coaxial with the air flow. The ozonator has a modular structure, with each module consisting of a pair of electrodes and a dielectric plate between them. The number of modules may vary depending on the required volume of ozone. The outer casing of the ozonizer allows the modules to be placed and fixed.

The disadvantages of this generator are due to the complexity of its design. Thus, without completely disassembling the ozonizer, it is impossible to replace a broken dielectric plate, as well as to flush out decay products of pollutants that adhere to the electrodes and dielectric plate during operation. The aerodynamic resistance of an industrial design of this design is quite high; in addition, the parallel arrangement of electrodes of a large area reduces the likelihood of an equal distance between the electrodes over the entire area and, as a result, does not provide a uniform distribution of the barrier discharge.

Thus, the technical problem is the need to develop devoid of the above

- 1 046103 identified disadvantages of efficient and compact plasma modules for ozonizers and ozone production plants.

The technical result consists in increasing the yield of generated plasma, active oxygen and ozone due to the production of nonequilibrium low-temperature plasma in the surface layer of the dielectric in a sliding barrier discharge.

An additional technical result is an increase in reliability due to improved protection against breakdown, as well as simplification of the manufacture and maintenance of ozonizers and ozone production units.

The technical result is achieved by the special design of the ozonizer. According to the invention, the electrodes and a dielectric plate made of glass are mounted on holders. The electrodes are made of metal pins located on the same line parallel to the plate at a distance of 5-15 mm from each other; Insulated electrodes are also placed inside the glass plate. The air flow passes along the ozonizer, bending around the electrodes.

The proposed design of the ozonizer and installation ensures the effective production of plasma, active oxygen and ozone due to the production of nonequilibrium low-temperature plasma in the surface layer of the dielectric in a sliding barrier discharge that occurs when a high alternating current voltage is applied to the electrodes. In this case, an electric field of a nonlinear shape is formed between the electrodes and a sliding electric barrier discharge appears on the surface of the dielectric, which spreads between the turns of the electrodes and, due to their ordered arrangement, is evenly distributed over the surface of the dielectric plate and has a very narrow attenuation region. Free electrons arising in the discharge plasma cause intense ionization of the gas or air flow passing through the cross section of the gas-discharge element. If gaseous substances are present in a given gas-air flow, then their molecules are subjected to intense bombardment by electrons, ionization and destruction of molecules occurs, OH-, O- radicals and other excited molecules appear, which enter into chemical oxidation reactions, which leads to the destruction of gaseous harmful substances, ensuring maximum cleaning efficiency. Such non-thermal plasma is generated by applying an electromagnetic field strong enough to discharge a neutral gas, thereby creating a quasi-neutral environment containing neutrals, ions, radicals, electrons and ultraviolet photons. Due to their light mass, electrons are selectively accelerated by the field and acquire high temperatures, while heavier ions remain relatively cold due to the exchange of energy during collisions with the background gas.

Providing better protection against breakdown in the claimed invention is due to the use of tempered glass 1-3 mm thick as a dielectric barrier and by regulating power, voltage and frequency by software settings of the power converter. Moreover, the power is regulated in the range of 1-5% of the nominal power values, which provides sufficient protection against breakdown and does not have a negative impact on the cleaning efficiency.

The device is easy to manufacture and maintain, since it does not contain such structural elements as wires (used as fuses), sharp teeth, needles, soldered elements (also used as fuses), etc. All this allows you to quickly and easily assemble the device, as well as quickly remove and replace the element with a high-voltage electrode and glass with a new one if the element is broken or fails. The assembly of the proposed device (both the ozonizer and the installation) is carried out from standard components without the use of high-precision machines.

The claimed invention is illustrated by drawings, where in Fig. 1 shows the ozonizer in general form, Fig. 2 is a side view of the ozonizer (from the end), and in FIG. 3 is a top view of the ozonizer, and in FIG. 4 - diagram of the installation for ozone production.

The ozonizer plasma module includes electrodes (1) and a dielectric plate (2) located between them with gaps, made of silicate glass. Electrodes (1) and plate (2) are mounted on holders (3) on both sides. The electrodes (1) are made of metal pins located on the same line parallel to the plate (2) at a distance of 5-15 mm from each other and 1-5 mm from the edge of the pin to the plate (2). Inside the plate (2) there are insulated electrodes (not shown in the drawings). In a preferred embodiment of the invention, the pins are located at a distance of 10-15 mm from each other, the glass of the plate (2) is chemically strengthened glass with a thickness of 1-3 mm, the electrodes (1) are made of stainless steel.

The installation for producing ozone includes a control panel (4), a power supply converter (5) connected in series with each other, which contains a sine filter, a step-up transformer and the necessary protection of the electrical circuit, the above-described plasma module zonator (6), a catalytic/sorption unit (7) , and fan/blower (8). The power supply converter (5) is designed to regulate power, voltage, frequency and, accordingly, the production of ozone and active oxygen. In some embodiments of the invention, the installation may include several plasma modules (3).

The claimed invention works as follows.

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On the control panel (4), the ozone production unit is turned on and the fan/blower is started. Air contaminated with various organic, inorganic, odorous, and harmful substances, previously cleaned of suspended particles, is sent to a purification unit using an exhaust fan/blower. Passes to the discharge zone for cleaning. After receiving the corresponding signal, electricity is supplied from the supply power converter (5) to the plasma ozonizer module (6). A high 9-11 kV AC voltage is supplied to the electrodes (1) of the module (6). In this case, an electric field of a nonlinear shape is formed between the electrodes (1) and a sliding electric barrier discharge appears on the surface of the dielectric (plate 2), which spreads between the turns of the electrodes (1), and due to their ordered arrangement, is evenly distributed over the surface of the dielectric plate (2) and has a very narrow attenuation region. Non-thermal plasma is generated and a neutral gas discharge is ensured. This creates an environment containing ozone, neutrals, ions, radicals, and electrons. The electrons acquire high temperature and energy, are accelerated by the field and bombard the gas molecules. Other processes of ionization and the addition of electrons to form OH ^- O ^- also occur. This reactive mixture is well suited for converting pollutants into CO ₂ and H2O and other decomposition products that are less harmful to the environment. Next, the gas mixture is supplied to the catalyst, which has a branched surface with a large working area. On the surface of the catalyst in macro-, meso- and micropores, the final oxidative purification processes occur. The destruction of unreacted ozone also occurs. As a result, the purified air is released into the atmosphere.

The claimed invention is illustrated by examples.

Example 1. Selection of optimal characteristics of the plasma module.

For experimental studies, an installation for producing ozone and a series of samples of an ozonizer module with different characteristics of the distance between metal pins and the distance from the edge of the pin to the plate were assembled. More detailed characteristics of the images are given in the table.

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Characteristics of test images

No. Distance between metal and studs Distance from the edge of the stud to the insulating plate Thickness of insulating plate (glass) Number of studs Material from which the electrodes are made mm mm mm PC 1 5 1 1 29 stainless steel 2 5 1 2 29 stainless steel 3 5 1 3 29 stainless steel 4 5 3 1 29 stainless steel 5 5 3 2 29 stainless steel 6 5 3 3 29 stainless steel 7 5 5 1 29 stainless steel 8 5 5 2 29 stainless steel 9 5 5 3 29 stainless steel 10 10 1 1 29 stainless steel AND 10 1 2 29 stainless steel 12 10 1 3 29 stainless steel 13 10 3 1 29 stainless steel 14 10 3 2 29 stainless steel 15 10 3 3 29 stainless steel 16 10 5 1 29 stainless steel 17 10 5 2 29 stainless steel 18 10 5 3 29 stainless steel 19 15 1 1 29 stainless steel 20 15 1 2 29 stainless steel 21 15 1 3 29 stainless steel 22 15 3 1 29 stainless steel

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sharp steel 23 15 3 2 29 stainless steel 24 15 3 3 29 stainless steel 25 15 5 1 29 stainless steel 26 15 5 2 29 stainless steel 27 15 5 3 29 stainless steel 28 20 1 1 29 stainless steel 29 20 1 2 29 stainless steel thirty 20 1 3 29 stainless steel 31 20 3 1 29 stainless steel 32 20 3 2 29 stainless steel 33 20 3 3 29 stainless steel 34 20 5 1 29 stainless steel 35 20 5 2 29 stainless steel 36 20 5 3 29 stainless steel 37 10 3 2 58 stainless steel 38 15 3 2 58 stainless steel

During the tests, each of the samples worked in the installation for one hour. During this time, the following parameters were measured: voltage, frequency, current, flow temperature, air flow, and the amount of ozone generated. Also, after one hour of operation, a visual inspection of the module’s condition was carried out. As a result of the tests, samples 14 and 23 performed best. These samples showed the best balance of energy contribution and generated ozone. Samples 5, 32, 37, 38 also showed good results. But this design is due to either large dimensions, or the complexity of assembly, or the application of a large amount of energy. The remaining samples showed unsatisfactory results.

Claims (5)

CLAIM 1. A plasma ozonator module, including electrodes and a dielectric plate made of glass located between them with gaps, wherein the electrodes and the plate are fixed on holders on both sides, characterized in that the electrodes are made of metal pins located on the same line parallel to the plate on at a distance of 5-15 mm from each other and at a distance of 1-5 mm from the edge of the pin to the plate; in addition, insulated electrodes are located inside the glass plate. 2. Plasma ozonizer module according to claim 1, characterized in that the pins are located at a distance of 10-15 mm from each other. 3. Plasma ozonator module according to claim 1, characterized in that tempered silicate glass with a thickness of 1-3 mm is used. 4. Plasma ozonizer module according to claim 1, characterized in that the electrodes are made of stainless steel. 5. An installation for producing ozone, including a plasma ozonizer module according to claim 1, as well as a control panel, a power supply converter, a catalytic unit and a fan connected to it, wherein the converter is configured to regulate power.