RU2108165C1 - Electrostatic precipitator - Google Patents

Abstract

FIELD: cleaning of excess air from finely-divided powder with any specific resistance in loading hopper with loose materials by pneumatic transport. SUBSTANCE: electrostatic precipitator has body accommodating precipitating unit made of coaxially arranged pipes interconnected in their middle part with braces to form cylindrical precipitating channels in which cantilevered from atop and from bottom are corona-forming electrodes in two independent corona-forming units to form two-lope precipitating channels. Each precipitating channel of the first and second fields has cantilevered volume cleaning brushes. In so doing, brushes of the first field are located under brushes of the second field for removal of trapped material of the second field through dust discharging channels of brushes of the first field to hopper in continuous rotation of precipitating unit. EFFECT: prevention of secondary carrying-away of trapped material. 6 dwg

Description

 The invention is intended for the purification of excess air about dust when loading bins by pneumatic conveying of bulk material, in particular when loading bins with alumina in aluminum smelters.

 A vertical electrostatic precipitator is known, where a stack of pipes is used as precipitation electrodes, and special type corona electrodes are installed along the pipe axes without the influence of edges. The cantilever corona electrodes do not protrude beyond the lower edge of the precipitation tubes [1].

 The disadvantages of this design include the difficulty of removing deposited dust, the difficulty of shaking tubular electrodes, and, in addition, the unipolar vertical electrostatic precipitators dramatically reduces their practical application.

 The closest technical solution is an electrostatic precipitator with rotating tubular deposition electrodes, comprising a housing connected to a gas inlet and outlet assembly. A gas distribution device is installed in the gas supply unit. Inside the case, precipitation electrodes made in the form of pipes are installed. Inside each precipitation electrode connected to the positive pole of the constant voltage source, a corona electrode is connected concentrically, connected to the negative pole of the constant voltage source. Precipitation electrodes are equipped with brushes for cleaning them [2].

 The disadvantages of this device are the secondary entrainment of trapped dust during rotation of the precipitation electrodes, the complicated kinematic scheme of rotation of a large number of precipitation electrodes, the need to install cleaning brushes in each precipitation electrode, and, in addition, the design does not allow creating a two-field vertical electrostatic precipitator.

 The task of the technical solution is to develop a two-field tubular electrostatic precipitator with a simplified kinematic scheme of rotation of the precipitation unit and prevent secondary entrainment of the captured material.

 This solution to the problem is achieved by the fact that in the known electrostatic precipitator, comprising a housing, a block of rotating tubular precipitation electrodes, corona electrodes, cleaning brushes, a rotation drive of the precipitation unit, high-voltage power units; the block of precipitation electrodes is made of at least two coaxial, vertically arranged pipes, where the central pipe is equipped with end caps, in which a shaft is mounted, mounted on the vertical axis of the pipe, in each subsequent pipe with a diameter larger than the previous one by two widths of the precipitation channel is rigidly attached to in the middle part of the pipe by extensions located along the perimeter in one horizontal plane, while in each cylindrical sedimentation channel, cantilevers are installed on top and bottom corona electrodes combined in two independent corona blocks connected to separate high-voltage power supply units with the formation of a two-field precipitation channel, where in each precipitation channel of the second field a cleaning brush is placed cantilever to its entire height, made in the form of two arcuate plates of elastic material, for example, conveyor belts, mounted on the frame and convex sides attached towards each other to the rod with the formation of dust extraction channels, where the width of the first plate along the rotation of the precipitation unit is less than the width of the precipitation channel, and the width of the second plate is greater than the width of the precipitation channel and is a scraper to remove the settled dust layer, while a brush of the first field is placed under each cleaning brush of the second field, and the precipitation unit is rotatable to remove settled dust, while the dust layer from the second field is transported to the hopper through the dust removal channels of the cleaning brushes of the first field.

 A comparative analysis of the prototypes shows that the inventive design of the electrostatic precipitator is characterized in that the tubular precipitation electrodes are assembled into a single precipitation unit by coaxial placement with each other and fastened to each other in the middle part of the pipes, and the central pipe is equipped with end caps in which the shaft is fixed, providing a simplified scheme of rotation of the precipitation unit, and the removal of settled dust is carried out by cleaning brushes, the three-dimensional design of which prevents secondary entrainment when removed and transporting the dust layer and into the hopper. Thus, the claimed electrostatic precipitator meets the criteria of the invention of "Novelty."

 A comparison of the proposed solution with the prototype shows that the proposed design of the precipitation unit in combination with the use of volumetric cleaning brushes and the installation of separate blocks of cantilever corona electrodes above and below in the precipitation unit allows you to create a two-floor vertical tubular electrostatic precipitator, which allows us to conclude that the criterion of "Significant differences" .

 In FIG. 1 shows a General view of the electrostatic precipitator, top view; in FIG. 2 is a section AA in FIG. one; in FIG. 3 - section BB in FIG. 2; in FIG. 4 - section bb in figure 2; in FIG. 5 - sedimentation block, top view; in FIG. 6 is a section GG in FIG. 5.

 The proposed electrostatic precipitator consists of a housing 1, in the center of which a precipitating block 3 is mounted with beams 2. The precipitating block 3 is made of a central vertical pipe 4, equipped with end caps 5, in which the shaft 6 is fixed. Coaxially to the central pipe 4 in its middle part with braces 7, a cylindrical precipitation electrode 8 is attached, and a precipitation electrode 9 is attached to the precipitation electrode 8 on the braces 7 with the formation of precipitation channels 10. A cantilever is installed in the precipitation channels 10 from above and below corona electrodes 11, mounted in the upper 12 and lower 13 mounting frames with the formation of separate corona blocks that are placed on insulators 14. Each precipitation unit is connected to a separate high-voltage power supply unit (not shown) with the formation of a two-field precipitation channel, where in each precipitation channel of the second field, a cleaning brush 15 is cantilevered to its full height 15. The cleaning brush 15 is made in the form of two arcuate plates of elastic material, for example, of a conveyor belt, located on the frames 16, which are convex towards each other, rigidly attached to the rod 17 with the formation of dust extraction channels 18, where the width of the first plate 19 in the direction of rotation of the precipitation block is less than the width of the precipitation channel 10, and the width of the second plate 20 is greater than the width of the precipitation channel 10. Plate 20 is a scraper to remove the settled dust layer, while under each cleaning with a brush 15 of the second field there is a brush 21 of the first field, the design of which is identical to the design of the brush 15. For rotation of the precipitation unit and a rotation mechanism 22 is installed on the beams 2. To seal the precipitation unit 3 during rotation up and down, sealing shutters 23 are installed.

 The operation of the electrostatic precipitator is as follows.

 After installing it on the roof of the hopper, turning on the rotation mechanism, applying high voltage to the corona blocks from the high-voltage power units and turning on the pneumatic transport system for loading the hoppers, dusty excess air is sent to the precipitation channels of a two-field vertical electrostatic precipitator. With the passage of dust particles in the active zones of the first and second fields, they are charged, transported, and deposited on the surface of cylindrical precipitation electrodes. Due to the slow rotation of the precipitation unit 3 at a speed of 5-10 rpm, depending on the initial concentration of dust in the excess air being cleaned, the dust layer is cleaned from the surface of the precipitation electrodes by means of scrapers 20 and, under the influence of gravitational forces, is transported directly through the dust extraction channels 18 to the hopper in the first field and through the branch channels of the brushes 21 from the second field.

 Technical and economic effectiveness of the proposed technical solution is as follows.

 The proposed design of the electrostatic precipitator allows you to create a two-floor tubular vertical electrostatic precipitator, which expands the possibility of using tubular electrostatic precipitators in production. The use of volumetric cleaning brushes prevents secondary dust removal of the captured dust and allows for the discharge of captured material in the second cleaning stage through the outlet channels of the cleaning brushes of the first cleaning stage. The proposed installation scheme of a direct-flow electrostatic precipitator directly on the roof of the bunkers when loading them with pneumatic transport automatically solves the problem of recycling the captured material.

Claims (1)

 An electrostatic precipitator including a housing, a block of rotating tubular precipitation electrodes, corona electrodes, cleaning brushes, a rotation drive of the precipitation block, high-voltage power supply units, characterized in that the precipitation electrode block is made of at least two coaxial vertically arranged pipes, the central pipe having end caps in which a shaft mounted on the vertical axis of the pipe is fixed, and each subsequent pipe with a diameter greater than the previous one by two widths of the precipitation channel, it is firmly attached to it in the middle part of the pipes by braces, while in each cylindrical precipitation channel, cantilever corona electrodes are installed at the top and bottom, combined into two independent corona blocks connected to separate high-voltage power units with the formation of a two-field precipitation channel, and in each field cantilever to its entire height placed cleaning brush, made in the form of two arcuate plates of elastic material, for example, of conveyor belt you, mounted on the frame and convex sides attached towards each other to the rod with the formation of dust extraction channels, the width of the first plate in the direction of rotation of the precipitation unit is less than the width of the precipitation channel, and the width of the second plate is greater than the width of the precipitation channel, and the second plate serves as a scraper to remove settled a dust layer, while under each cleaning brush of the second field is placed a brush of the first field, and the precipitation unit is rotatable to remove settled dust, while ylevoy layer from the second field is transported to a hopper through channels pyleotvodnye treatment brushes of the first field.

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