RU2622953C2 - Precipitation electrode of electrofilter (versions) - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: device according to the first version contains separate elements made in the form of hollow drums fixed on the insulators and an axis having threads on both ends for joining the elements of the precipitation electrode and connecting the contact rings when installing the precipitation electrode in the electrofilter. The axis is hollow with high-voltage wires located inside it, one end of which is fixed on the inside of the precipitation electrode, and the other ends are led out through the hollow axes to further feed the supply signal through the contact rings, when the precipitation electrode is installed in the electrofilter. According to the second version, the device comprises a separate element made in the form of a hollow truncated cone fixed on the insulators and the axis having threads at both ends. In the third version, the device comprises separate elements made in the form of smooth, even hollow drums.

EFFECT: mechanical strength, rigidity while maintaining the precipitation surface without sharp edges, which contributes to the efficiency of the electrofilter by maximizing the use of the electrode surface.

3 cl, 3 dwg

Description

The invention relates to the electrical cleaning of gases from suspended particles in various industries, in particular in the chemical and oil refining industries, metallurgy, etc.

Known precipitation electrode [patent RU 82598 U1, IPC B03C 3/00, published May 10, 2009], containing precipitation elements that are in the form of zigzag shaped cross sections of profiled metal plates, the edges of the inclined sections ending with grooved elements or U-shaped connecting elements, grooved elements are formed by sections and zones of transition to inclined sections of the profile parallel to the gas flow, due to the implementation of transition zones in the form of arcs with a large radius of curvature, as well as optimal boron ratios between the sizes of the precipitation electrode elements achieved sufficient mechanical strength, rigidity and surface deposition without sharp edges, this geometric shape which provides the maximum filling body precipitator grating surface with sufficient uniformity of electric field distribution on the deposition surface.

The disadvantage of this design is its complexity.

Known precipitation electrode [patent RU 79806 U1, IPC B03C 3/76, published January 20, 2009], containing precipitation elements, each of which is made in cross section in the form of a complex broken surface, in the middle part of which there is a corrugated part with different heights asymmetrically located corrugations and semi-closed end surfaces in extreme areas, one end surface of each precipitating element is made on one side of it with a protrusion, and on the other side of it with a recess, the size of which coincides with the protrusion, wherein the junction of the precipitating elements of the electrode forms a lock in which one side of the precipitating element enters the other side of the next precipitating element.

The disadvantage of an analogue is the complexity of the design.

Closest to the proposed is a precipitation electrode [patent RU 77181 U1, IPC B03C 3/76, published October 20, 2008], containing individual elements, each of which is made in cross section in the form of a complex broken surface, in the middle part of which there is a corrugated part with with different heights of asymmetrically arranged corrugations and semi-closed end surfaces at the extreme sections, the end plane of the semi-closed end surfaces of the elements is perpendicular to the horizontal plane and is made at the place of formation end edge, rounded with a radius of not more than 3 mm, parallel to the horizontal plane with a curved edge inward at an angle of not more than 30 °.

The disadvantage of the prototype is the large size of the filter.

The objective of the invention is to develop a new design of the precipitation electrode, providing the largest and most easily cleaned area of the precipitation surface while maintaining uniform distribution of the electric field over the deposition surface.

The technical result is the provision of mechanical strength, rigidity while maintaining the deposition surface without sharp edges, which improves the efficiency of the electrostatic precipitator due to the maximum use of the electrode surface.

Used in the claimed invention, the configuration of the electrode deposition surface allows to provide mechanical strength, increase the deposition area due to the cross section of a separate element of the electrode in the form of a broken surface, which increases the efficiency of the electrostatic precipitator.

The problem is solved and the technical result is achieved by carrying out the invention in 3 versions.

According to the first embodiment, the precipitation electrode contains individual elements, each of which is made in cross section in the form of a broken surface. In contrast to the prototype, the device contains elements made in the form of hollow drums mounted on insulators and an axis having a thread at both ends for joining the elements of the precipitation electrode and connecting contact rings when installing the precipitation electrode in the electrostatic precipitator, the axis is hollow with high-voltage wires located inside it , some ends of which are fixed on the inner side of the precipitating electrode, the drum, and the other ends are brought out through the hollow axes for the further supply of the supply signal through the Stroke rings when installing a precipitation electrode in an electrostatic precipitator.

According to the second variant, the precipitation electrode contains individual elements made in cross section in the form of a broken surface. In contrast to the prototype, the device contains an element made in the form of a hollow truncated cone, mounted on insulators and an axis having a thread at both ends, for joining the elements of the precipitation electrode and connecting the contact rings when the precipitation electrode is installed in the electrostatic precipitator, the axis is hollow with inside high-voltage wires, some ends of which are fixed on the inside of the precipitation electrode, the drum, and the other ends are brought out through the hollow axis for further supplying a power signal and through the contact rings when installing the precipitation electrode in the electrostatic precipitator.

In the third embodiment, the precipitation electrode contains individual elements. In contrast to the prototype, the device contains individual elements made in the form of smooth even hollow drums mounted on insulators and an axis having a thread at both ends, for joining the elements of the precipitation electrode and connecting the contact rings when installing the precipitation electrode in the electrostatic precipitator, the axis is hollow with inside it with high-voltage wires, some ends of which are fixed on the inner side of the precipitation electrode, the drum, and the other ends are brought out through the hollow axis for further supply itayuschego signal through slip rings when installing the precipitation electrode in the precipitator.

The technical result, ensuring the presence of a constantly clean surface of the precipitation electrode in the active zone of the electrostatic precipitator, is achieved by installing precipitation electrodes with the possibility of rotation on the axis in the horizontal or vertical position in the bearings, which allows you to continuously remove the settled dust layer in scrapers with scraper, so there is no need shaking the precipitating electrodes and disconnecting the supply voltage from them, in addition, this solution allows you to bypass the cleaned gas stream. This ensures the presence of a constantly clean surface of the precipitation electrode in the zone of deposition of dust particles.

The invention is illustrated by drawings. The drawings depict the claimed device.

In FIG. 1 - General view of the precipitation electrode (1 option).

In FIG. 2 - General view of the precipitation electrode (option 2).

In FIG. 3 - General view of the precipitation electrode (3 option).

The precipitation electrode according to the first embodiment contains (Fig. 1) a separate element 1 made in the form of hollow drums, and in cross section in the form of a broken surface, mounted on insulators 2 and axis 3, inside of which there are high-voltage wires 4.

The precipitation electrode according to the second embodiment contains (Fig. 2) a separate element 1 made in the form of a hollow truncated cone, and in cross section in the form of a broken surface, mounted on insulators 2 and axis 3, inside of which there are high-voltage wires 4.

The deposition electrode according to the third embodiment contains (Fig. 3) a separate element 1 made in the form of hollow drums, and in cross section as a flat surface, mounted on insulators 2 and axis 3, inside of which high-voltage wires 4 are located.

The device according to the first embodiment works as follows.

A precipitation electrode is installed in an electrostatic precipitator, dust particles suspended in a gas stream, ionized by an electric field, are moved and deposited on the surface of a separate element 1, made in cross-section in the form of a broken surface, mounted on insulators 2 and rotating under the action of external forces on the hollow axis 3, in which the high-voltage wires 4 pass, the power of which is supplied from the external power supply of the electrostatic precipitator. The broken surface of the individual element 1, due to its shape, gives the precipitating electrode increased mechanical strength, and also forms peculiar pockets that increase the dust particle deposition area and allow dust to be retained during electrode regeneration, which significantly reduces secondary dust entrainment. At the same time, the geometric shape of the element 1 of the precipitation electrode brings all areas of the precipitation surface of the element 1 closer to the core of the corona discharge, which contributes to the uniform distribution of the electric field on the surface of the precipitation electrode.

The device according to the second embodiment works as follows.

A precipitation electrode is installed in an electrostatic precipitator, dust particles suspended in a gas stream, ionized by an electric field, are moved and deposited on the surface of an individual element 1 made in cross section in the form of a broken surface and in the form of a truncated cone mounted on insulators 2 under the influence of electrostatic field forces and rotating under the action of external forces on the hollow axis 3, in which the high-voltage wires 4 pass through which power is supplied from the external power supply of the electrostatic precipitator. The broken surface of the individual element 1, due to its shape, gives the precipitating electrode increased mechanical strength, and also forms peculiar pockets that increase the dust particle deposition area and allow dust to be retained during electrode regeneration, which significantly reduces secondary dust entrainment. At the same time, the geometric shape of the individual element 1 of the precipitation electrode brings all areas of the precipitation surface of the individual element 1 closer to the active zone of the corona discharge, which contributes to the uniform distribution of the electric field on the surface of the precipitation electrode, moreover, the shape of the precipitation electrode in the form of a truncated cone allows to increase the number of electrodes , and thereby the area of the precipitation electrodes in the active zone of the electrostatic precipitator, which significantly improves the cleaning efficiency.

The device according to the third embodiment works as follows.

A precipitation electrode is installed in an electrostatic precipitator, dust particles suspended in a gas stream, ionized by an electric field, are moved and deposited on the surface of an individual element 1, made in cross section in the form of a smooth, even surface, mounted on insulators 2 and rotating under the action of electrostatic forces external forces on the hollow axis 3, in which the high-voltage wires 4 pass, the power of which is supplied from the external power supply of the electrostatic precipitator. The smooth surface of the individual element 1 gives the precipitation electrode mechanical strength, providing a sufficient area for the deposition of dust particles during electrode regeneration, which significantly reduces the secondary ablation of dust. At the same time, the geometric shape of the element 1 of the precipitation electrode provides the maximum approximation of all sections of the precipitation surface of the individual element 1 to the core of the corona discharge, which ensures uniform distribution of the electric field on the surface of the precipitation electrode.

So, the claimed invention provides the largest and most easily cleaned area of the precipitation surface while maintaining uniform distribution of the electric field over the deposition surface due to the use of the cylindrical shape of a separate element of the electrode of the precipitation electrodes rotating by means of a motor and mechanical transmission, additional ensuring mechanical strength and rigidity is provided by in cross section of an individual element in the form of a broken surface, which ensures ivaet electrostatic efficiency by maximizing the surface of the electrode while maintaining approximates maximum approximation all portions of the grating surface of the element 1 to the active area of the precipitator.

Claims (3)

1. Precipitation electrode containing individual elements, each of which is made in cross section in the form of a broken surface, characterized in that the individual elements are made in the form of hollow drums mounted on insulators and an axis having a thread at both ends, with the possibility of connecting individual elements of the precipitation electrode and the connection of contact rings when installing the precipitation electrode in the electrostatic precipitator, the axis being hollow with high-voltage wires located inside it, one end of which is closed they are insulated from the inside of the precipitation electrode, and the other ends are led out through the hollow axes with the possibility of further supplying a power signal through the contact rings when the precipitation electrode is installed in the electrostatic precipitator. 2. A precipitation electrode containing individual elements, each of which is made in cross section in the form of a broken surface, characterized in that the individual elements are made in the form of a hollow truncated cone, mounted on insulators and an axis having a thread at both ends, with the possibility of mating elements of the precipitation electrode and the connection of contact rings when installing the precipitation electrode in the electrostatic precipitator, the axis is hollow with high-voltage wires located inside it, one ends of which are fixed with the morning side of the precipitation electrode, and the other ends are led out through the hollow axis with the possibility of further supplying a power signal through the contact rings when installing the precipitation electrode in the electrostatic precipitator. 3. A precipitation electrode containing individual elements, characterized in that the individual elements are made in the form of smooth even hollow drums, mounted on insulators and an axis having a thread at both ends, with the possibility of joining the elements of the precipitation electrode and attaching contact rings when installing the precipitation electrode in an electrostatic precipitator, the axis being hollow, with high-voltage wires located inside it, some ends of which are fixed on the inside of the precipitation electrode, and the other ends through hollow axes with the possibility of further supplying a feed signal through slip rings when a precipitation electrode is installed in an electrostatic precipitator.

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