RU2312710C2 - Electrical filter - Google Patents

Abstract

FIELD: natural gas industry; petrochemical industry; other industries; production of the electrical filters used for the gases purification.

SUBSTANCE: the invention is pertaining to the electrical filters and may be used for purification of the gasses. The electrical filter contains the body, the depositing and the corona-forming electrodes combined in the groups. In the first gas streamwise groups the purified dust-and-gas stream moves horizontally, and in the last gas streamwise groups - the purified dust-and-gas stream moves vertically. The ratio of the area of the sedimentation to the amount of the purified gas in the area, where the gas is moving horizontally, makes 115 - 76, and in the area, where the gas is moving vertically, this ratio makes 76 - 38. The technical result of the invention is the increased efficiency of usage of the active area of the electric filter.

EFFECT: the invention ensures the increased efficiency of usage of the active area of the electric filter.

7 cl, 2 dwg

Description

The invention relates to the field of electrical methods for collecting aerosols.

A vertical electrostatic precipitator is known, for example, a UV-type electrostatic precipitator (L.1, p.217), in which the purified gas is supplied from the bottom of a group of corona and precipitation electrodes (core), and comes out from above already purified.

The disadvantage of such an electrostatic precipitator is the limited residence time of the gas to be cleaned between the corona and precipitation electrodes in the core and, therefore, the insufficient degree of purification.

To eliminate this drawback, horizontal plate electrostatic precipitators are used, for example, horizontal apparatuses such as UG, EGA, UGT (L.1, p.213), where the residence time of the gas to be cleaned is limited only by the length of the electrostatic precipitator and can be significantly longer than that of a vertical filter, and, accordingly, the degree of purification is higher.

In order to reduce the influence of a decrease in operating voltages, for example, due to dust overgrowth, which is more intense at the beginning of the electrostatic precipitator, the corona and precipitation electrodes are grouped along the length of the electrostatic precipitator and a hopper is formed under each electrode group in the electrostatic precipitator housing. At the top, the corona and precipitation electrodes in a horizontal electrostatic precipitator are suspended from the housing, while a gap occurs between them and the housing without a corona discharge field. Inactive zones form - an organic defect in the group of electrodes when the gas passes horizontally. Through the top of the groups of electrodes and below them, through the hopper, through inactive zones, there is always a slip of particles. Various measures are taken to reduce the breakthrough of particles through inactive zones, but this leads to an increase in the metal consumption of the horizontal electrostatic precipitator, and it is not possible to completely eliminate the phenomenon of the breakthrough of particles through inactive zones, since for any design of partitions with a horizontal gas flow there must always be a gap that excludes electrical breakdown of parts under high (up to 80 kV and higher) voltage to the grounded parts of the device. Therefore, in a horizontal electrostatic precipitator, obtaining an output dust content below 100-50 mg / m ³ is problematic.

1. To eliminate the existing drawbacks of the analogue and prototype — limitations on the length of the active zone and elimination of the phenomena of particle leakage through inactive zones of the electrostatic precipitator — precipitation and corona electrodes are combined into groups having horizontal gas movement in the first electrode groups along the gas, and vertical gas in the last group while the gas outlet is transferred to the top of the last group of electrodes. In addition, the ratio of the deposition surface S ₁ (m ² ) of the active zone of the electrostatic precipitator, where the gas flows horizontally, to the amount of gas Q ₁ (m ³ / s) entering this zone is 115> S ₁ / Q ₁ > 76, and the surface ratio deposition of S ₂ (m ² ) of the active zone of the electrostatic precipitator, where the gas flows vertically, to the amount of gas Q ₂ (m ³ / s) entering this zone is 76> S ₂ / Q ₂ > 38.

2. According to claim 1 of the invention, the electrostatic precipitator is characterized in that there are several latter groups where the gas flows vertically. This allows you to optimize the modes of shaking of the electrodes and their power.

3. According to claim 1, the electrostatic precipitator is characterized in that in each group where the gas flows vertically, the corona and precipitation electrodes are shaken from the outlet side of the purified gas. This allows you to reduce the wear of the shaking mechanisms, contributes to a better distribution of shaking accelerations.

4. The electrostatic precipitator according to claim 1 is characterized in that the dust collected on the electrodes from all the latter groups, where the gas flows vertically, is shaken off into one hopper. This arrangement of the latter groups can reduce metal consumption.

5. The electrostatic precipitator according to claim 1 is characterized in that the corona elements in all groups of electrodes are located across the gas path. With this arrangement, the gas always passes through the corona field, while passing gas in the most active zone, the presence of inactive zones is excluded.

6. The electrostatic precipitator according to claim 1, characterized in that in the last groups, where the gas to be cleaned flows vertically, the precipitation electrodes and the housing form channels having a common surface for deposition of trapped particles, and the corona electrodes are located at an equal distance from the precipitation electrode and the inner surface the housing of the electrostatic precipitator so that they create a corona discharge towards the side of the part of the channel surface formed by the housing.

7. The electrostatic precipitator according to claim 6, characterized in that the part of the channel surface formed by the precipitating electrodes and the housing has the shape of a half cylinder with an axis along which the corona sections of the surface of the corona electrode are located. This arrangement of the corona electrodes relative to the housing completely eliminates the possibility of the existence of inactive zones and, thus, eliminates the breakthrough of dust particles.

The invention is illustrated by drawings (figure 1, figure 2).

Figure 1. General view of the electrostatic precipitator

1 - electrostatic filter housing

2 - input device of the purified gas

3 - corona electrodes with vertically arranged elements, forming groups where the gas flows horizontally

4 - precipitation electrodes, where the gas flows horizontally

5 - groups where the gas to be cleaned goes horizontally

6 - precipitation electrodes, groups where the gas flows vertically

7 - corona electrodes with horizontally arranged elements, forming groups where the gas flows vertically

8 - purified gas outlet device

9 - groups where the gas to be cleaned goes vertically

10 - insulator box

11 - shaking mechanisms of the corona and precipitation electrodes

12 - electrostatic filter housing, where the gas flows vertically

13 - bins

Figure 2. Sectional view of the housing where the gas flows vertically

14 - inner flat part of the housing, on which dust is deposited in the field of corona discharge

15 is a half-cylinder body part.

The housing of the electrostatic precipitator (1), (9) is a supporting structure of a rectangular shape, closed with metal sheets. Bottom of the case of electrostatic precipitators is equipped with bins (13) for collecting trapped dust. The electrostatic precipitator is equipped with gas inlet and outlet devices (2), (8). Precipitation electrodes (4) and corona electrodes (3) are located in each group (5) and form active zones where the gas flows horizontally and the elements of corona electrodes are located vertically. Precipitation electrodes (6) and corona (7) form an active zone in each group (9), where the gas flows vertically, and the elements of the corona electrodes are located horizontally. The walls of the housing (12) of the electrostatic precipitator, where the gas flows vertically (FIG. 2), are made flat (14) and in the form of a half cylinder (15). The dust trapped in the electrostatic precipitator after shaking it enters the hoppers (13).

The housing of the electrostatic precipitator, where the gas flows vertically, can be located above the last group, where the gas flows horizontally. When reconstructing electrostatic precipitators, it can also partially be located above the confuser (output device), where the gas flows horizontally.

The operation of the electrostatic precipitator is carried out as follows: the gas to be cleaned enters the electrostatic precipitator body (1), where the gas flows horizontally through the gas inlet device (2). Next, the gas enters the core, consisting of corona (3) and precipitation (4) electrodes, and passes horizontally through the groups of electrodes (5).

From the last part of group (5), gas enters one or several groups (9), where it passes vertically. The active zone of the groups of electrodes (9) is formed by precipitation (6) and corona (7) electrodes. The dust-free gas exits through the outlet of the purified gas (8). The electrodes of the group (9) are located in the housing (12), the walls of which (Figure 2, view AA) have a flat shape (14) and a half-cylinder shape (15). Dust trapped in all groups is periodically removed using shaking mechanisms from the electrodes and, under the influence of its weight, falls into bins (13), from where it is removed by dust conveying devices. When the gas moves horizontally through groups of electrodes, it is cleaned to a level where the influence of particle slip through inactive zones becomes significant. For example, the number of particles passing through the active zones at the exit from the next group of electrodes becomes equal to the number of particles passing through the inactive zones. The last group of electrodes, where gas flows horizontally, is installed at the rear wall of the housing, and the top of the housing above it is open, and the gas to be cleaned turns up. The length of the electrodes of this group along the gases is necessary to ensure the residence time of particles in the active zone of this group, such that the total number of particles (through active and inactive zones) entering this last group is reduced to the required value.

In the zone of the last group of electrodes, which is located higher than the previous ones, there are no longer inactive zones, since the precipitation electrodes and the casing form rectangular channels, where the entire surface is used to precipitate particles, and the corona electrodes create a corona discharge both towards the precipitation electrodes and side of the surface of the housing adjacent to the collecting electrodes in order to increase the efficiency of particle deposition in areas where the collecting electrodes are suitable for the housing. Due to the fact that with a rectangular configuration of the interelectrode gap in the corners, the electric field is weakened, and the particle deposition efficiency is reduced, part of the surface of the channel formed by the housing between the precipitation electrodes is made in the form of a half cylinder along the axis of which a corona element is installed. In this case, semi-active zones are excluded, and all particles pass only through the active zone of the electrostatic precipitator.

If it is required to achieve an output dust content of less than 50 mg / m ³ , and particles in the electrostatic precipitator are difficult to catch, and the length of the active zone (height) of that part of the electrostatic precipitator where the gas flows vertically requires 12-15 meters, the last group is divided into electrically isolated parts according to length.

This achieves better dust shaking and reducing dust breakthroughs through the active zones when shaking. When particles are shaken, the electrostatic precipitator electrodes, where the gas flows vertically, pass through the active zones into one common hopper, the other part is deposited, but lower, and the next time the electrodes are shaken, it enters this hopper.

The corona electrodes in the channels of group (9), formed by precipitation electrodes and the electrostatic filter housing (12), are located across the gas path, i.e. horizontally to reduce the influence of the semi-active zones that occur between the corona electrodes. If the corona electrodes are arranged vertically, then the semi-active zones will also be located vertically, and particles will slip through them, like through channels. When the corona electrodes are located across the gas path, the active and semi-active zones alternate, and there are always zones with the maximum precipitating effect in the corona discharge field on the particle path.

For ease of maintenance and to reduce the dusting of the insulators of the mechanisms of shaking the electrodes in the group where the gas to be cleaned flows vertically, they are made from the outlet side of the purified gas. This increases the reliability of the electrostatic precipitator.

To implement the present invention does not require new technologies. The manufacture of nodes and installation of an electrostatic precipitator can be carried out using known means.

LITERATURE.

1. A guide to dust and ash collection. Edited by A.A. Rusanov, 2nd ed. M., Energoatomizdat, 1983.

Claims (7)

1. An electrostatic precipitator having a housing, cleaned gas inlet and purified gas inlet devices, hoppers, precipitation and corona electrodes combined into groups, characterized in that in the first groups along the gas the gas to be cleaned flows horizontally, and in the last groups the gas outlet is directed vertically upward, and the ratio of the deposition surface S ₁ (m ² ) of the active zone of the electrostatic precipitator, where the gas flows horizontally, to the amount of gas Q ₁ (m ³ / s) entering this zone is 115> S ₁ / Q ₁ > 76, and the surface ratio deposition S ₂ (m ²⁾ of active area elec rofiltra where gas flows vertically to the quantity Q ₂ (m ³ / s) of gas entering this zone is 76> S ₂ / Q ₂ 38>. 2. The electrostatic precipitator according to claim 1, characterized in that the last groups, where the gas flows vertically, are several. 3. The electrostatic precipitator according to claim 1, characterized in that in the last group, where the gas flows vertically, the corona and precipitation electrodes are shaken from the outlet side of the purified gas. 4. The electrostatic precipitator according to claim 1, characterized in that the trapped dust from all the last groups, where the gas to be cleaned flows vertically, is brushed off into one hopper. 5. The electrostatic precipitator according to claim 1, characterized in that the corona elements in all groups of electrodes are located across the gas path. 6. The electrostatic precipitator according to claim 1, characterized in that in the last groups, where the gas to be cleaned flows vertically, the precipitation electrodes and the housing form channels having a common surface for the deposition of trapped particles, and the corona electrodes are located at an equal distance from the precipitation electrode and the inner surface the housing of the electrostatic precipitator so that they have the ability to create a corona discharge towards the part of the channel surface formed by the housing. 7. The electrostatic precipitator according to claim 6, characterized in that the part of the channel surface formed by the precipitating electrodes and the housing has the shape of a half cylinder with an axis along which the corona sections of the surface of the corona electrode are located.

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