RU61595U1 - ELECTROSTATIC FILTER (OPTIONS) - Google Patents

Abstract

The utility model relates to the purification of gas, air from dust and dirt in residential and industrial premises.

The task was to create an electrostatic precipitator design with a high degree of gas purification and improved operational characteristics.

18. In an electrostatic filter containing ionization 2 and precipitation 3 chambers enclosed in housing 1, ionization chamber 2 consists of sections 4, including corona 5 and installed parallel to the air flow, plate non-corona 6 electrodes, and metal or polymer networks 7 installed in ionization 2 chamber at the inlet and outlet perpendicular to the air flow and electrically connected with non-corona 6 electrodes, precipitation 3 chamber, consisting of parallel to each other made of polymer, aluminum of an antistatic polymer or plates 8 with a conductive layer with the same or alternating different potentials, plates 8 can be curly (arched, wavy, angular and corrugated) and made of antistatic polymer, sedimentation chamber 3 can be filled with a mass of porous conductive material replacing the plates 8 (option 2), the corona 5 electrodes are located equidistant from the non-corona 6 electrodes and the grid 7, ionization 2 and precipitation 3 chambers can be placed in separate cases.

The presence of the above characteristics makes it possible to solve the problem of increasing the efficiency of the electrostatic filter by increasing the active deposition area, and improving the operational characteristics by performing curly deposition plates, which gives additional structural rigidity and placement of ionization 2 and precipitation 3 chambers in separate buildings.

2 s.p., 15 s.p. f-ly, 9 ill.

Description

The utility model relates to the purification of gas, air from dust and dirt in residential and industrial premises.

A device for cleaning and disinfecting air, containing a grounded housing with a high-voltage power supply, moreover, in the housing are installed in series from the input and output parts of the charging and precipitation electrode systems, made in the form of plates installed parallel to one another, connected alternately with the negative and grounded terminals of the unit power supply, and the neutralizing electrode system is made in the form of N electrode sections, where N> 1, and the sections are placed one after another in the direction of movement the ionization of ions and all sections of these electrodes, except the first, are connected to the positive terminal of the high-voltage power supply through the appropriate voltage divider, the first section is connected directly to the positive terminal of the power supply (see patent RU No. 2033272, IPC V03C 3/12, A01K 1/01 , 1/00, A61L 9/015, BIPM 04/20/1995).

A two-zone electrostatic precipitator is known for gas purification, comprising a charging chamber sequentially installed along the gas in the form of parallel grounded plates symmetrical with respect to a plane in which a corona electrode is located perpendicular to the longitudinal axis of the electrostatic precipitator, and a precipitation chamber in the form of a system of alternating polar flat deposition electrodes arranged symmetrically with respect to a precipitation electrode lying in the plane of symmetry of the charging chamber and having the same polarity with an irrigation electrode, and the precipitation electrodes closest to the symmetry plane are mounted relative to the precipitation electrode lying in the symmetry plane at a greater distance than the distance

between other pairs of adjacent precipitation electrodes, or in another embodiment, the electrode in the symmetry plane and the precipitation electrodes closest to the symmetry plane are made shorter than adjacent precipitation electrodes (see patent RU No. 2060830, IPC B03C 3/08, 3/12, BIPM 27.05 .1996).

Closest to the claimed device is a dual-zone electrostatic precipitator containing an ionizer enclosed in a housing, consisting of plate-shaped non-corona electrodes corona and mounted parallel to the air flow, a precipitator and metal grids installed in the ionizer at the inlet and side of the precipitate perpendicular to the air flow and electrically connected to the non-corona electrodes (Patent RU No. 2192927, IPC B03C 3/00, 3/08, 3/12, BIPM 11/20/2002).

The known design does not have a sufficient degree of gas purification.

The task was to create an electrostatic precipitator design with a high degree of gas purification and improved operational characteristics.

The problem is solved in that in an electrostatic filter containing an ionization chamber enclosed in a housing, consisting of sections including corona-shaped and non-corona plate electrodes and grids installed in the ionization chamber at the inlet and outlet perpendicular to the air flow and electrically connected to non-corona electrodes, grids can be made of metal or polymer, a precipitation chamber, consisting of plates located parallel to each other , the plates can be made of polymer, an antistatic polymer with a conductive layer or aluminum, while the plates have alternating different or the same potential, the plates can be curly (arched, wavy, angular and corrugated) (option 2), in addition, the precipitation chamber can be filled with a mass of porous conductive material, in the ionization

corona electrodes are located equidistant from non-corona electrodes and grids made of metal or polymer; ionization and precipitation chambers can be placed in separate housings.

The presence of the above characteristics allows us to solve the problem of increasing the efficiency of the electrostatic filter by increasing the active deposition area, and improving the operational characteristics due to the implementation of curly plates, which gives additional structural rigidity.

The search in the patent and scientific and technical literature did not reveal a technical solution similar to that proposed in terms of the essential features, therefore, it corresponds to the “novelty” condition.

The inventive utility model is illustrated by drawings:

in FIG. 1 - electrostatic filter, General view (option 1);

figure 2 - ionization chamber (option 1);

figure 3 - plate sedimentation chamber with a conductive layer (option 1);

figure 4 - precipitation chamber (option 2);

figure 5 - electrostatic filter with ionization and precipitation chambers in separate housings;

figure 6 - electrostatic filter with arched plates of the precipitation chamber, General view (option 1);

figure 7 - wavy plate sedimentation chamber;

on Fig - angular plates of the precipitation chamber;

figure 9 - corrugated (zigzag) plate sedimentation chamber.

In the first embodiment, the electrostatic filter (figure 1) consists of a housing 1, in which are placed ionization 2 and precipitation 3 chambers.

The ionization chamber 2 consists of three or more ionization sections 4. There may be a larger number of sections, depending on the purpose of the electrostatic filter and the degree of contamination of the gas being cleaned. In sections 4, there are 5 corona electrodes connected to a high voltage source (not shown) and 6 non-corona electrodes connected to a grounded terminal of the high voltage source. Grids 7 are located at the inlet and outlet of the ionization chamber 2 perpendicular to the air flow. Mesh 7 can be made of metal or polymer. The corona 5 electrodes are located equidistant from the non-corona 6 electrodes and grids 7, which allows to obtain a centrally symmetric electrostatic field with a center of symmetry on the corona 5 electrode. This arrangement of the corona electrodes ensures uniform formation of gas ions along the entire length of the corona electrode 5.

Precipitation 3 chamber consists of plates 8 located parallel to each other with alternating different or equal potential. Plate 8 (figure 3) is made of polymer with a layer 9 of a conductive material or metal deposited on it. The conductive layer 9 can completely cover the plate. The plates 8 may be made of aluminum or an antistatic polymer.

The plates of the precipitation chamber can have various geometric shapes: arcuate (Fig.6), wave-like (Fig.7), angular (Fig.8), having one rib in the middle of the plate, corrugated (Fig.9), with several stiffeners. This embodiment of the precipitation plates increases the rigidity of the structure and contributes to a more efficient deposition.

The material for the precipitation plates can be an electrically conductive material, for example, an aluminum strip, an antistatic polymer with a specific surface resistance of not more than 10 ¹⁰ Ohms.

The second version of the electrostatic filter is made similar to the first option, the difference is in the design of the precipitation chamber.

In the second embodiment (FIG. 6), the precipitation chamber 3 (FIG. 4) is filled with a mass of porous conductive material that replaces the plates 8: graphite, cotton wool of thin metal threads and other conductive material, activated carbon with a large absorbent surface. This embodiment of the precipitation 3 chambers will increase the area of deposition and increase the efficiency of the filter.

Both in the first and in the second variants, the ionization 2 and precipitation 3 chambers can be placed both in a single housing 1, and in separate buildings 10, 11, respectively.

The electrostatic filter operates as follows.

The cleaned gas enters the ionization chamber 2, where, passing between the corona 5 electrodes, non-corona 6 electrodes and grids 7, it acquires a charge. Then the charged dust particles enter the precipitation chamber 3, where, due to the action of electrostatic forces, dust particles are deposited on the plates 8 or in a porous conductive material having an electric potential.

The proposed design of an electrostatic filter, consisting of an ionization chamber having several sections, of a precipitation chamber, consisting of plates having various geometric shapes and material composition, allows us to solve the problem of increasing the efficiency of the electrostatic filter by increasing the active deposition area.

Placing the ionization chamber 2 and the precipitation chamber 3 in separate housings makes it possible to simplify filter maintenance, thereby improving its operational characteristics.

The proposed electrostatic filter can be manufactured on standard equipment based on existing technologies using modern materials.

Claims (17)

1. An electrostatic filter containing an ionization chamber enclosed in a housing, consisting of sections including corona-shaped plate-shaped non-corona electrodes and parallel to the air flow, metal grids installed in the ionization chamber at the inlet and outlet perpendicular to the air stream and electrically connected to the non-corona electrodes, and a precipitation a chamber consisting of plates arranged parallel to each other, characterized in that the corona electrodes are equidistant from non-corona electrodes and grids, and the precipitation chamber consists of plates with a conductive layer with electric potential. 2. The electrostatic filter according to claim 1, characterized in that the precipitation chamber consists of plates made of aluminum. 3. The electrostatic filter according to claim 1, characterized in that the precipitation chamber consists of plates made of polymer. 4. The electrostatic filter according to claim 1, characterized in that the precipitation chamber consists of plates made of an antistatic polymer. 5. The electrostatic filter according to claim 1, characterized in that the plates of the precipitation chamber are made arcuate. 6. The electrostatic filter according to claim 1, characterized in that the plates of the precipitation chamber are made wavy. 7. The electrostatic filter according to claim 1, characterized in that the plates of the precipitation chamber are angled. 8. The electrostatic filter according to claim 1, characterized in that the plates of the precipitation chamber are corrugated. 9. The electrostatic filter according to claim 1, characterized in that the ionization and precipitation chambers are housed in separate housings. 10. The electrostatic filter according to claim 1, characterized in that the mesh of the ionization chamber is made of polymer. 11. The electrostatic filter according to claim 1, characterized in that the mesh of the ionization chamber is made of metal. 12. The electrostatic filter according to claim 1, characterized in that the precipitation chamber consists of polymer plates with a conductive layer with the same potential. 13. The electrostatic filter according to claim 1, characterized in that the precipitation chamber consists of polymer plates with a conductive layer with alternating potential. 14. An electrostatic filter containing an ionization chamber enclosed in a housing, which consists of sections including corona-shaped plate-shaped non-corona electrodes and parallel to the air flow, grids installed in the ionization chamber at the inlet and outlet perpendicular to the air stream and electrically connected to the non-corona electrodes, and a precipitation chamber characterized in that the corona electrodes are equidistant from the non-corona electrodes and the grid, and the precipitation chamber is filled with istym conductive material with an electric potential. 15. The electrostatic filter according to 14, characterized in that the ionization and precipitation chambers are housed in separate housings. 16. The electrostatic filter according to 14, characterized in that the mesh of the ionization chamber is made of polymer. 17. The electrostatic filter according to 14, characterized in that the mesh of the ionization chamber 'is made of metal.