RU196591U1 - Electrostatic precipitator - Google Patents

Abstract

The present technical solution relates to the field of electric gas purification from dust (dispersed suspensions) and can be used mainly in the power industry, in the chemical, metallurgical and building materials industries. The technical result in an electrostatic precipitator containing a housing with a diffuser at the inlet and a confuser at the outlet, located in housing precipitation and corona electrodes with a suspension system, forming segments of the corona system, shaking mechanisms, high-voltage electrical power units Connectors, connected by means of insulators with corona electrodes, crossbars and bins, are achieved by the fact that each segment of the corona system connected to the power supply unit has six suspension points located two on each of three sequentially installed crossbars. The technical result is an increase in the efficiency of the electrostatic precipitator.

Description

Technical field

This technical solution relates to the field of electric dust cleaning of gases (dispersed suspensions) and can be used mainly in the power industry, in chemical and metallurgical industries, in the building materials industry and in other industries.

State of the art

Currently, there are various designs of electrostatic precipitators used for cleaning gases from dust (dispersed suspensions). In particular, the electrostatic precipitator shown in FIG. 1-3, comprising a housing 1 with a diffuser 2 at the inlet and a confuser 3 at the outlet, precipitating 4 and corona 5 electrodes with a suspension system 6 located in the housing, shaking mechanisms 7, high-voltage power units 8 connected by means of insulators 9 with corona electrodes, crossbars 10 and bunkers 11 (see the Handbook on dust-ash collection under the editorship of AA Rusanov, Moscow, Energia, 1975, pp. 188-190). The electrostatic precipitator contains several active zones formed by precipitation 4 and corona 5 electrodes.

The disadvantage of this design of the electrostatic precipitator is low efficiency, which is due to the significant distance X between the active zones of the fields, similarly for other active zones (not shown). This distance X in existing samples of electrostatic precipitators created on the basis of a known design can be, for example, 1654 mm. (in the EGBM1-20-7.5-4-2 electrostatic precipitator). The consequence of this is increased metal consumption and overall dimensions of the electrostatic precipitator, and most importantly, a decrease in the active zones of the electrostatic precipitator, since corona and precipitation electrodes cannot be placed in the indicated significant intervals, spaces under the crossbar.

This drawback is due to the design of the electrostatic precipitator, in which the corona system consists of segments having four suspension points, supported by two adjacent crossbars 10 (Fig. 3). This is due to the placement of two rows of bushings 9 in the crossbars 10, which does not allow to reduce the distance between the crossbars due to the risk of breakdown. In other words, in the known design, in the intermediate crossbars, between the fields in the crossbar structure, the need to maintain a sufficient distance between the metal structures to ensure the absence of short circuits is taken into account, which does not significantly reduce this distance X in the existing structure. An additional disadvantage is the overall dimensions and metal consumption of the electrostatic precipitator, which is also due to significant voids between the active zones (distance X in Fig. 1.).

The objective of this technical solution is to increase the efficiency of the electrostatic precipitator by reducing the distance X between the active zones.

Disclosure

The object of this technical solution is an electrostatic precipitator containing a housing with a diffuser at the inlet and a confuser at the outlet, precipitation and corona electrodes with a suspension system located in the housing, forming corona system segments, shaking mechanisms, high-voltage power supply units connected by means of insulators with corona electrodes, crossbars and bunkers.

The technical result in the inventive electrostatic precipitator is achieved by the fact that each segment of the corona system connected to the power supply unit has six suspension points located two on each of three sequentially installed crossbars.

This scheme allows you to reduce the distance between the active zones by at least 2 times, which allows to increase the area of the active zones of the electrostatic precipitator without changing the overall dimensions of the housing, and, therefore, increase the efficiency of the electrostatic precipitator.

The technical result is an increase in the efficiency of the electrostatic precipitator.

Brief Description of the Drawings

In FIG. 1 shows a cross section of an electrostatic precipitator according to the prior art (side view).

In FIG. 2 shows a section BB of the electrostatic precipitator according to the prior art (side view).

In FIG. 3 shows a segment of a corona system according to the prior art.

In FIG. 4 shows a cross section of the inventive electrostatic precipitator according to a non-limiting embodiment (side view).

In FIG. 5 shows a section BB of the inventive electrostatic precipitator according to a non-limiting embodiment.

In FIG. 6 shows a cross-section BB of the inventive electrostatic precipitator according to a non-limiting embodiment.

In FIG. 7 shows a segment of the corona system of the inventive electrostatic precipitator according to a non-limiting embodiment.

Description

In FIG. 4-7 depict the inventive electrostatic precipitator, which, as known, contains a housing 1, with a diffuser 2 at the input and a confuser 3 at the output. In the case, there are precipitation 4 and corona 5 electrodes with a suspension system 6, shaking mechanisms 7, high-voltage power supply units 8 connected by means of insulators 9 with corona electrodes 5, crossbars 10 and bins 11.

Each segment of the corona system connected to the power unit has six suspension points located two on each of the three crossbars installed in series. See FIG. 7.

This arrangement allows you to reduce the distance X to two times. As shown in FIG. 4, the distance between the active zones is X / 2, where X is the distance between the active zones of fields I and II in the known design of the electrostatic precipitator shown in FIG. 1.

That is, the width of the segment of the corona system in the intermediate crossbar is reduced by half, and the length is doubled, the segments are arranged in a row. In the design of the proposed electrostatic precipitator, the width of the intermediate crossbar is reduced by 2 times, since in the intermediate crossbars of the inventive electrostatic precipitator (Fig. 4-7), unlike the known design of the electrostatic precipitator (Fig. 1-3), it is not necessary to install 2 rows of support insulators, which allows you to reduce the linear dimensions of the electrostatic precipitator, or increase the size of the active zone (increase the efficiency of the electrostatic precipitator), reduce the metal consumption, reduce the cost of the electrostatic precipitator.

Thus, for example, for the EGBM1-20-7.5-4-2 electrostatic precipitator, it is possible to reduce the distance between each two active zones from 1654 mm to 827 mm. Therefore, if there are several active zones, considerable space is saved.

Therefore, in the claimed design, in comparison with the known analogue, while maintaining overall dimensions, the area of the active zones can be increased and the efficiency of the electrostatic precipitator can be increased. Alternatively or additionally, the overall dimensions of the electrostatic precipitator can be reduced while maintaining or increasing efficiency.

The presented illustrative embodiments, examples and description serve only to provide an understanding of the claimed technical solution and are not limiting. Other possible embodiments will be apparent to those skilled in the art from the description provided. The scope of this utility model is limited only by the attached utility model formula.

Claims (1)

An electrostatic precipitator comprising a housing with a diffuser at the input and a confuser at the output, precipitation and corona electrodes with a suspension system located in the housing, forming corona system segments, shaking mechanisms, high-voltage power supply units connected by means of insulators with corona electrodes, crossbars and bunkers, characterized in that each segment of the corona system connected to the power supply unit has six suspension points located two on each of three sequentially installed Igel.

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