RU193625U1 - Horizontal multi-field electrostatic precipitator - Google Patents

Abstract

This technical solution relates to the field of electric gas cleaning from dust (dispersed suspensions) and can be used mainly in the power industry, in the chemical, metallurgical and building materials industries. The technical result is in a horizontal multi-field electrostatic precipitator containing precipitation and corona electrodes forming an active zone, and shaking mechanisms located above the core, each corona electrode includes a frame with vertical and horizontal rods between which the corona elements are vertically fixed; this is achieved by the fact that a dividing beam is inserted into the frame, which is installed perpendicular to the corona elements, dividing the frame into two adjacent parts; movable elements are located between the two adjacent adjacent parts of the frame, hinged at one end to the first on one part of the frame, and the second end with a horizontal rod of the other part of the frame of the two adjacent frame parts, and the frame parts are made with possible technical oscillation of the corona electrode system of the electrostatic precipitator, including for designs of electrode systems of high height (for example, 8 meters and more).

Description

Technical field

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

State of the art

Known electrostatic precipitators such as EGA, EHD, EG, EGBM and others (see. Catalog. Gas purification equipment. TSINTIHIMNEFTEMASH, M., 1988). In them, the precipitation electrodes are suspended on the suspension beams, which, in turn, are installed on the shelves of the crossbars of the electrostatic precipitators. The mechanisms of shaking the precipitation system are located in the lower part of the body in the pre-bunker space. Shaking of each of the electrodes is carried out by side impacts of hammers on shaking beams at the lower ends of the elements. The corona electrodes of the frame construction are mounted with brackets to the suspension frames mounted on the supporting and supporting bushing insulators. Shafts with hammers are mounted on the suspension frames. Each electrode is brushed off with a separate hammer. The number of shafts in height depends on the size and modification of the electrostatic precipitator.

The disadvantage is the impossibility of installing large electrode systems in these devices, in particular corona electrodes, due to the need to use several levels of shaking along the height of the electrostatic precipitator. This significantly reduces the reliability and maintainability of the electrostatic precipitator.

A known design of the electrostatic precipitator according to US patent No. US5344481 A, 09/06/1994, B 03 C 3/76, in which, for the effective use of the active zone, the mechanisms of shaking of the electrode systems are located in the upper part of the apparatus bodies. The electrostatic precipitator contains precipitation and corona electrodes forming the active zone and shaking mechanisms located above the active zone. Each corona electrode includes a frame with vertical and horizontal rods, between which corona elements are vertically fixed.

The disadvantage of this electrostatic precipitator is the impossibility of using electrode systems of large height (for example, 8 meters or more) due to the insufficient degree of their cleaning from dust with the upper arrangement of shaking mechanisms. The hammer blow of the shaking mechanism of the corona system is carried out along the side shaft of the frame, as a result of which there is a significant attenuation of the shock pulse throughout the frame.

The transmission of a shock pulse arriving at the electrodes depends on the length of the frame rods, which also reduces the efficiency of shaking the corona electrode system and the rigidity of the frame. When shaking the corona electrodes with one hammer, the entire mass of the corona system is involved in the shock interaction. Due to the larger mass ratio of the corona system and the hammer, the dynamic characteristics are significantly reduced, and, consequently, the effectiveness of shaking off all the corona electrodes, which also does not allow to expand the active zone of the electrostatic precipitator. The installation of several shaking mechanisms significantly complicates the design of the electrostatic precipitator.

The objective of this utility model is to increase the efficiency of shaking the corona electrode system of an electrostatic precipitator, including for constructions of electrode systems of high height (for example, 8 meters and more).

Disclosure

The object of this utility model is a horizontal multi-field electrostatic precipitator containing precipitation and corona electrodes forming an active zone and shaking mechanisms located above the active zone, each corona electrode includes a frame with vertical and horizontal rods, between which corona elements are vertically fixed. The technical result is achieved the fact that a dividing beam is installed in the frame, installed perpendicular to the corona elements, dividing the frame into d e adjacent parts, between the two adjacent adjacent parts of the frame are movable elements pivotally connected at one end to a first dividing beam fixed to one part of the frame and the second end to a horizontal rod of the other part of the frame from said two adjacent parts of the frame, the frame parts being made with the possibility of oscillatory movements relative to each other under the action of the shaking mechanism.

An embodiment of an electrostatic precipitator is possible, according to which N additional dividing beams are introduced into the frame, dividing the mentioned parts of the frame into N + 1 additional parts of the frame, movable elements are located between each adjacent additional parts of the frame, articulated at one end with an additional dividing beam fixed to one additional parts of the frame, and the second end with a horizontal rod of another additional part of the frame adjacent to it, and parts of the frame are made with the possibility of I oscillate with respect to each other under the action of a shaking mechanism.

An embodiment of an electrostatic precipitator is possible, according to which the height of the frame parts coincides.

An embodiment of an electrostatic precipitator is possible, according to which the height of the frame parts of the two frame parts is different from each other.

An embodiment of an electrostatic precipitator is possible, according to which the height of the additional parts of the frame coincides.

An embodiment of an electrostatic precipitator is possible, according to which the height of the additional parts of the frame from said additional two parts of the frame is different from each other.

An embodiment of an electrostatic precipitator is possible, according to which the movable elements are plates.

An embodiment of an electrostatic precipitator is possible, according to which the movable elements are rods.

An embodiment of an electrostatic precipitator is possible, according to which the movable elements are tubes.

EFFECT: increased efficiency of shaking the corona electrode system of an electrostatic precipitator, including for constructions of electrode systems of high height (for example, 8 meters and more). Reducing the attenuation of the shock pulse is achieved while maintaining the location of the shaking mechanism above the active zone. And as a result, increasing the efficiency of shaking and cleaning the core, which increases the efficiency of the electrostatic precipitator as a whole.

As will be clear to the specialist, the execution of the individual parts of the frame movable relative to each other allows to increase the amplitude of vibrations when exposed to the shaking mechanism and to reduce the decay rate of the shock pulse.

Brief Description of the Drawings

Figure 1 shows a non-limiting embodiment of a horizontal cross-section electrostatic precipitator in cross section.

Figure 2 shows the node And the design of the electrostatic precipitator of figure 1.

Description

The design of a horizontal multi-field electrostatic precipitator is well known to those skilled in the art. It should only be noted that the electrostatic precipitator includes a housing, inside which precipitation electrodes are located parallel to each other, between which there are corona electrodes, which form an active zone between each other. All these electrodes are arranged in several rows and are suspended on insulators. Below, under the electrodes, there are silos for deposited dust.

In FIG. 1 shows an embodiment of a horizontal multi-field electrostatic precipitator in cross section (hereinafter the electrostatic precipitator). Each corona electrode includes a frame 1 with vertical and horizontal rods, between which corona elements 2 are vertically fixed. The corona electrode frame 1 is suspended on insulators 3. In the upper part of the frame 1 above the core of the electrostatic precipitator there is a mechanism of shaking 4 of the corona electrode. The shaking mechanism can be performed, for example, in the form of rotating hammer mechanisms by striking the anvil 5 attached to the frame 1.

A dividing beam 6 (Fig. 2) is inserted into the frame 1, mounted perpendicular to the corona elements 2, dividing the frame 1 into two adjacent parts, movable elements 7 (Fig. 2) are located between the two adjacent adjacent parts of the frame, articulated at one end with a dividing beam 6, mounted on one part of the frame, and with the second end with a horizontal rod 8 of the other part of the frame 1 of the two adjacent parts of the frame 1. Moreover, the parts of the frame 1 are made with the possibility of oscillatory movements relative to each other under action m shaking mechanism 4.

N additional dividing beams (not shown) can be introduced into frame 1, dividing said parts of the frame into N + 1 additional parts of the frame, in a similar manner. Between each adjacent additional parts of the frame are movable elements (similar to the movable elements 7), pivotally connected at one end with an additional dividing beam fixed to one additional part of the frame, and the second end with a horizontal rod of another additional part of the frame adjacent to it, and the frame parts are made with the possibility of vibrational movements relative to each other under the action of the shaking mechanism 4.

Thus, a frame of high height (more than 8 meters) can be divided into several parts (for example, 2, 3, 4, 5, etc.), which are made with the possibility of oscillatory movements relative to each other under the action of the shaking mechanism 4. The height of the parts of the frame 1 can be the same or different, which can be chosen based on the dimensions of the frame, the characteristics of the oscillatory motion and vibration damping after exposure to the shaking mechanism 4 and other parameters. As it will be clear to the specialist when dividing the frame into whiter than two parts, some parts may be the same in height, and some may be different, or all may be the same, or all may be different.

The movable elements 7 may be plates or rods or tubes made of metal, articulated by means of, for example, cotter pins, hairpins, or other elements that allow for articulation or with a dividing beam 6, mounted on one part of the frame, and the second end with horizontal rod 8, mounted on another part of the frame.

The claimed design provides improved shaking efficiency of the corona electrode system of the electrostatic precipitator, including for designs of electrode systems of high height (for example, 8 meters or more). Reducing the attenuation of the shock pulse is achieved while maintaining the location of the shaking mechanism above the active zone.

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 (9)

1. A horizontal multi-field electrostatic precipitator containing precipitation and corona electrodes forming an active zone and shaking mechanisms located above the active zone, each corona electrode includes a frame with vertical and horizontal rods, between which corona elements are vertically fixed, characterized in that a dividing beam is introduced to the frame, mounted perpendicular to the corona elements, dividing the frame into two adjacent parts, between the two adjacent adjacent parts of the frame p movable elements are pivotally connected pivotally at one end to a dividing beam fixed on one part of the frame, and at the second end to a horizontal rod of the other part of the frame from the two adjacent frame parts, the frame parts being able to oscillate relative to each other under the action of the shaking mechanism . 2. The electrostatic precipitator according to claim 1, characterized in that N additional dividing beams are introduced into the frame, dividing the said parts of the frame into N + 1 additional parts of the frame, movable elements are located between each adjacent additional parts of the frame, articulated at one end with an additional dividing beam mounted on one additional part of the frame, and the second end with a horizontal rod of another additional part of the frame adjacent to it, and part of the frame is made with the possibility of oscillating motion s relative to each other under the effect of shaking mechanism. 3. The electrostatic precipitator according to claim 1, characterized in that the height of the frame parts coincides. 4. The electrostatic precipitator according to claim 1, characterized in that the height of the frame parts of the two frame parts is different from each other. 5. The electrostatic precipitator according to claim 2, characterized in that the height of the additional parts of the frame coincides. 6. The electrostatic precipitator according to claim 2, characterized in that the height of the additional parts of the frame from said additional two parts of the frame is different from each other. 7. The electrostatic precipitator according to claim 1, characterized in that the movable elements are plates. 8. The electrostatic precipitator according to claim 1, characterized in that the movable elements are rods. 9. The electrostatic precipitator according to claim 1, characterized in that the movable elements are tubes.

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