RU48815U1 - DEVICE FOR CLEANING AND DISINFECTION OF AIR (OPTIONS) - Google Patents

Abstract

A utility model relates to the design of a device used to purify air or oxygen-containing gas mixtures. Such a device, hereinafter referred to as an air purifier, can be used to remove dust particles, solid or liquid smoke particles, bacterial and viral aerosols, vapors of most organic and many inorganic substances. A device for cleaning and disinfecting air consists of an elongated housing containing an inlet and outlet of air or an oxygen-containing gas mixture;

an electrostatic filter located at the inlet of the cleaned air or oxygen-containing gas mixture; an adsorption filter following the electrostatic filter in the direction of the purified air or oxygen-containing gas mixture; a photocatalytic filter following the adsorption filter in the direction of the purified air or oxygen-containing gas mixture. The device may further comprise mechanical and / or end filters. The designs of photocatalytic filters used in this utility model are described. EFFECT: high efficiency of air purification.

Description

A utility model relates to the design of a device used to purify air or oxygen-containing gas mixtures. Such a device, hereinafter referred to as an air purifier, can be used to remove dust particles, solid or liquid smoke particles, bacterial and viral aerosols, vapors of most organic and many inorganic substances. Removing these substances leads to disinfection and deodorization of air.

The problem of clean air is extremely important for the life and health of people. Many dangerous diseases, such as measles, plague, anthrax, tuberculosis, flu, etc. are transmitted by aerosol methods and cause the death of millions of people every year. Plant pollen, dust, chemical air pollutants cause great damage to health and cause a decrease in labor productivity and quality of life.

Electrostatic filters can remove particles with a size of at least 0.01 microns from the passing air stream. Dual-zone electrostatic filters contain an ionization zone and a deposition zone. In the ionization zone containing corona positively charged electrodes, pollutant particles are charged with a positive charge, and in the deposition zone containing alternating grounded and negatively charged precipitation electrodes, the contaminant particles are deposited on the surface of the precipitation electrodes.

Known electrostatic air purifier using bactericidal lamps (US 6149717, 03 C 3/011, 11/21/2000). In this purifier, air passes through a preliminary mechanical filter to remove particles larger than 10 microns, then passes through a two-zone electrostatic filter, and the precipitation plates of the electrostatic filter are irradiated with a bactericidal lamp to destroy the deposited microbes. An optional filter may be installed to remove organic contaminants. The disadvantages of this cleaner is the inefficient use of light

lamps, low cleaning rate from inorganic and volatile organic substances, as well as the release of ozone as a result of the operation of bactericidal lamps.

Photocatalytic oxidation is the most promising method for removing molecular pollutants from air at low concentrations. For its implementation, a heterogeneous photocatalyst is irradiated with light, and organic and inorganic substances are oxidized on its surface. The utility model (RU 8634, B 01 J 19/10, 12.16.98) provides for the deposition of a photocatalyst on a transparent porous carrier through which air is pumped. Part of the light of the lamp irradiating the photocatalyst passes through the carrier with the catalyst, and therefore, the invention functions as an air purifier and a lamp at the same time.

Also known photocatalytic air purifier and lamp (WO 02/102497, D 01 D 53/86, 12/27/02). In this case, the photocatalyst is applied to glass tubes, and the function of the lamp is carried out by means of luminescent conversion of ultraviolet light from a lamp on an additional casing with a phosphor. These types of air purifiers are ineffective at removing mechanical air pollutants and inefficiently use lamp light for the cleaning process due to the fact that part of the light passes through the carrier.

Known air purifiers combining several types of filters. Thus, an electrostatic filter is known (US 5993738, C 22 C 13/02, 30.11.99), on the precipitation electrodes of which a photocatalyst is applied, irradiated with light. The disadvantages of this invention is the rapid loss of photocatalytic activity due to the closure of the photocatalyst surface from light by a layer of deposited dust and the low efficiency of the use of lamp light.

The invention described in US 5779769, B 03 C 3/155, 07/14/98 is intended for both air purification and lighting. In this case, lighting is carried out by a separate lamp, and air purification is carried out using sequentially located electrostatic and adsorption filters. The disadvantage of the invention is the low cleaning efficiency in relation to volatile pollutants.

The closest is a device using a combination of a photocatalytic filter and an adsorption filter for air purification (US 6358374, B 01 D 53 / 00.19.03.02). Air pollutants first accumulate on the adsorption filter. Then the inlet and outlet of the purifier are closed by heating

pollutants are desorbed from the adsorption filter and photocatalytically oxidized. Due to the increased concentration of pollutants, photocatalytic oxidation is rapid. This cleaner is not effective against mechanical air pollutants. A significant drawback is also the periodic effect of this cleaner.

It can be seen from the above examples that, despite the large number of existing cleaners, they have significant drawbacks that need to be addressed.

This utility model can significantly increase the efficiency of air purification.

This device allows you to remove from the air all of these pollutants, such as dust particles, solid or liquid smoke particles, bacterial and viral aerosols, fumes of most organic and many inorganic substances with low energy consumption

The essence of the proposed utility model is the use of the properties of an electrostatic filter, an adsorption filter and a photocatalytic filter in such a way that their simultaneous use leads to a higher efficiency of cleaning air or oxygen-containing gas mixtures than the sum of their effectiveness when used separately.

It is known that electrostatic filters generate toxic ozone gas during operation. In the presence of organic substances, ozone reacts with them to form numerous oxygen-containing oxidation products. Such polar oxidation products are adsorbed much stronger than non-polar substances on the surface of a number of adsorbents. Thus, a higher degree of adsorption purification is achieved. The second reason for more effective air purification is the elimination of deactivation of the photocatalyst in the photocatalytic filter under the action of ozone. In the absence of organic air pollutants, the photocatalyst irradiated with appropriate light effectively decomposes ozone to molecular oxygen, preventing it from appearing at the outlet of the air purifier.

In FIG. 1 shows a diagram of a device for cleaning and disinfecting air. The device is available in four versions.

The first option contains an electrostatic filter 2, an adsorption filter 3, a photocatalytic filter 4 and a housing 7.

The second option contains a mechanical coarse filter 1, an electrostatic filter 2, an adsorption filter 3, a photocatalytic filter 4 and a housing 7.

The third option contains an electrostatic filter 2, an adsorption filter 3, a photocatalytic filter 4, a final filter 5, and a housing 7.

The fourth option comprises a mechanical coarse filter 1, an electrostatic filter 2, an adsorption filter 3, a photocatalytic filter 4, a final filter 5, and a housing 7.

The device operates as follows.

Polluted air 12 first passes through a mechanical pre-filter 1, which removes particles larger than 20 microns. Then the air passes through an electrostatic filter 2, where it is cleaned of dust with a size up to 0.01 microns. The electrostatic filter emits ozone, which oxidizes molecular air pollutants. Oxidation products and initially hardly volatile pollutants are adsorbed on the adsorption filter 3, which is filled with one or more types of adsorbents. Further purification of air from molecular pollutants takes place in a photocatalytic filter 4, which oxidizes all remaining molecular pollutants. The high activity of the photocatalytic filter is supported by the ozone emitted by the electrostatic filter 2. The purified air passes through the filter of final purification 5, which removes the remaining molecular contaminants. An adsorption or absorption filter may act as such a filter. The fan 6 pumps air through the filters fixed in the body of the cleaner 7.

The high efficiency of the photocatalytic filter is associated with the efficient use of light from lamps irradiating the photocatalyst. The use of porous mesh photocatalyst carriers with a pore size of 0.1-10 mm can significantly increase the oxidation rate due to the distribution of light over a large surface area of the photocatalysts. Such media may

be made of ceramics (ceramic foam carriers), metal (foam carriers) or other solid materials.

The problem is also solved by the designs of the photocatalytic filter (2 options).

In FIG. 2 shows a section of a photocatalytic filter with a mesh porous catalyst carrier 8 made in the form of plates arranged parallel to the lamps 9. The light of the lamps not directly incident on the catalyst carriers is reflected by reflectors 10 mounted on the filter housing 7. The cleaned air passes perpendicular to the carrier plates.

FIG. 3 illustrates the construction of a photocatalytic filter with porous mesh supports made in the form of tubes 11. In this case, most of the light emitted by the lamps 9 is incident directly on the support. A reflector may be mounted at the end of the media. The cross section of the pipes 11 may have a round shape, an oval shape, a polygon shape, or any other shape. The cross section of the pipes can be unequal in different parts.

Claims (24)

1. A device for cleaning and disinfecting air, consisting of: an elongated body containing an inlet and outlet of air or an oxygen-containing gas mixture; an electrostatic filter located at the inlet of the cleaned air or oxygen-containing gas mixture; an adsorption filter following the electrostatic filter in the direction of the purified air or oxygen-containing gas mixture; a photocatalytic filter following the adsorption filter in the direction of the purified air or oxygen-containing gas mixture. 2. The device according to claim 1, characterized in that the electrostatic filter contains a spatially separated ionization zone and the deposition zone. 3. The device according to claim 1, characterized in that the photocatalytic filter contains catalyst supports made of a mesh porous carrier in the form of a plate or pipe. 4. The device according to claim 1, characterized in that titanium dioxide or titanium dioxide treated with acid and / or coated with a noble metal is used as the photocatalyst. 5. Device for cleaning and disinfecting air, consisting of: a housing containing the inlet and outlet of air or an oxygen-containing gas mixture; a mechanical filter located at the inlet of the cleaned air or oxygen-containing gas mixture; an electrostatic filter located behind the mechanical filter in the direction of the purified air or oxygen-containing gas mixture; an adsorption filter following the electrostatic filter in the direction of the purified air or oxygen-containing gas mixture; a photocatalytic filter following the adsorption filter in the direction of the purified air or oxygen-containing gas mixture. 6. The device according to claim 5, characterized in that the electrostatic filter contains a spatially separated ionization zone and the deposition zone. 7. The device according to claim 5, characterized in that the photocatalytic filter contains catalyst supports made of a mesh porous carrier in the form of a plate or pipe. 8. The device according to claim 5, characterized in that titanium dioxide or titanium dioxide treated with acid and / or coated with a noble metal is used as the photocatalyst. 9. A device for cleaning and disinfecting air, consisting of a housing containing the inlet and outlet of air or an oxygen-containing gas mixture; an electrostatic filter located at the inlet of the cleaned air or oxygen-containing gas mixture; an adsorption filter following the electrostatic filter in the direction of the purified air or oxygen-containing gas mixture; a photocatalytic filter following the adsorption filter in the direction of the purified air or oxygen-containing gas mixture; final filter following the photocatalytic filter. 10. The device according to claim 9, characterized in that the electrostatic filter contains a spatially separated ionization zone and the deposition zone. 11. The device according to claim 9, characterized in that the photocatalytic filter contains catalyst supports made of a mesh porous carrier in the form of a plate or pipe. 12. The device according to claim 9, characterized in that titanium dioxide or titanium dioxide treated with an acid and / or coated with a noble metal is used as the photocatalyst. 13. The device according to claim 9, characterized in that as the final filter using an adsorption or absorption filter. 14. A device for cleaning and disinfecting air, consisting of a housing containing the inlet and outlet of air or an oxygen-containing gas mixture; a mechanical filter located at the inlet of the cleaned air or oxygen-containing gas mixture; an electrostatic filter located behind the mechanical filter in the direction of the purified air or oxygen-containing gas mixture; an adsorption filter following the electrostatic filter in the direction of the purified air or oxygen-containing gas mixture; a photocatalytic filter following the adsorption filter in the direction of the purified air or oxygen-containing gas mixture; final filter following the photocatalytic filter. 15. The device according to 14, characterized in that the electrostatic filter contains a spatially separated ionization zone and the deposition zone. 16. The device according to 14, characterized in that the photocatalytic filter contains catalyst supports made of a mesh porous carrier in the form of a plate or pipe. 17. The device according to 14, characterized in that as the photocatalyst use titanium dioxide or titanium dioxide treated with acid and / or coated with a noble metal. 18. The device according to 14, characterized in that the adsorption or absorption filter is used as the final filter. 19. Photocatalytic filter, consisting of one or more ultraviolet lamps; mesh porous carriers coated with a photocatalyst, made in the form of plates with a pore size of 0.1-10 mm and located parallel to the axis of the ultraviolet lamps and perpendicular to the flow of the medium to be cleaned. 20. The photocatalytic filter according to claim 18, characterized in that it contains reflective elements parallel to the axis of the ultraviolet lamps. 21. A photocatalytic filter consisting of one or more ultraviolet lamps; mesh porous media with a deposited photocatalyst, made in the form of tubular elements covering ultraviolet lamps, and having a pore size of 0.1-10 mm 22. The photocatalytic filter according to item 21, characterized in that the porous mesh carrier has the form of tubes with different diameters in different parts of the carrier. 23. The photocatalytic filter according to item 21, characterized in that the medium to be cleaned enters the media through the side openings on the axis of the pipe. 24. The photocatalytic filter according to item 21, characterized in that the carrier is made of a light-transmitting porous material.