KR101037350B1 - Dust collector scrubbing apparatus of wet electrostatic precipitator - Google Patents

Abstract

Disclosed are a dust collector continuous cleaning apparatus applied to a wet electrostatic precipitator utilizing a corona discharge and an electrostatic force, a wet ionizer device, and a hybrid wet scrubbing device using the same.

The dust collector continuous cleaning device of the present invention is fixedly installed on the discharge electrode space keeping bar, a plurality of discharge electrodes to which a high voltage is applied, and a predetermined distance is installed between the discharge electrodes, a special surface that can reduce the critical surface tension on the surface The cleaning pipe header unit is provided with a dust collecting electrode, a reinforcing rod installed between the dust collecting electrodes to maintain the gap between the dust collecting electrodes, and a unit injection device for radially spraying the washing water onto the surface of the dust collecting electrode. And a water trough installed under the dust collecting pole to prevent washing water from flowing to the discharge electrode gap maintaining rod to which a high voltage is applied, and by forming a stable water film on the surface of the dust collecting pole with a minimum amount of washing water, thereby adhering adhesive particles. Deposition can be blocked at source, which is why the By minimizing the intermittent cleaning can be maintained at a high level, ultimately the efficiency of the wet electrostatic precipitator.

Wet, electrostatic precipitating, discharging, critical surface tension, cleaning, continuous

Description

DUST COLLECTOR SCRUBBING APPARATUS OF WET ELECTROSTATIC PRECIPITATOR}

The present invention relates to a wet electrostatic precipitator utilizing a corona discharge and electrostatic force, a wet ionizer device, and a continuous collector cleaning device applied to a hybrid wet scrubbing device using the same, and more specifically, to the dust deposited on the dust collector. The present invention relates to a dust collector continuous cleaning apparatus capable of continuously cleaning.

In general, the electrostatic precipitator is a device for purifying the air by applying an electric field to the floating dust in the air to generate electricity by electrostatic force, it is divided into wet and dry according to the method of removing the dust deposited on the dust collector.

Electrostatic precipitators utilizing electrostatic force are basically composed of a discharge electrode to which a high voltage is applied, and a grounded dust collecting pole, and are charged by a continuous electric field of particles through corona discharge due to an unbalanced electric field formed at a sharp part of the discharge electrode. The dust is collected by moving the particles to the dust collecting pole. When dust collection is performed, dust is deposited on the dust collector, and excessive dust deposition causes excessive spark discharge (spark), which causes problems in the electrostatic precipitator high voltage supply system or the discharge electrode and the dust collector system.

Therefore, for continuous operation, a suitable cleaning device for the collected dust is required, and cleaning by generating mechanical vibration using hammers is called a dry device, and a device for cleaning with water is called a wet device.

In the conventional wet electrostatic precipitator, as a cleaning method for the dust collecting electrode, dust is collected by spraying periodically or continuously by using a spray nozzle, or by forming a water tank on the collecting electrode and pouring it through the outer periphery of the collecting electrode. A method of forming a water film on the pole surface has been used.

However, the above methods, especially in the case of a dust collecting pole made of a material having a high critical surface tension, may not be maintained until the water film formed at the top is not maintained until the bottom, and a valley of the flow may be formed to form a portion where the washing is not performed. As a result, cleaning of the dust collecting electrode by manpower is required every predetermined period.

The related domestic patent is "water spraying device of electrostatic precipitator (application number 20-1999-0024552)", which installs a water pipe across the dust collecting plate on the top of the dust collecting plate and connects the pipes for connecting nozzles to each of the water supply pipes. It is formed by connecting and installing spray nozzles, which branch and spray water directly onto the dust collecting plate on both sides, and another Korean patent "Wet Electrostatic Precipitator (Application No. 10-2006-0044500)" forms a water tank at the upper part of the dust collecting unit The present invention relates to an apparatus capable of continuously cleaning the surface of the dust collecting electrode by supplying water to the collector circumference to evenly flow through the dust collecting cylinder circumference, and characterized in that the material of the dust collecting electrode is made of synthetic resin.

Related US patents include "Self-cleaning electro-inertial precipitator unit (Patent No. 4,388,089)" and "Wet wall electrostatic precipitator with liquid recycle" (Patent No. 5,084,072). Contains the content of rinsing continuously.

The above patents refer to the direct injection method through the spray nozzle to the dust collector or the water film formation using the overflow from the upper tank of the dust collector, but the method of mitigating the critical surface tension of the dust collector surface for efficient water film formation is mentioned. It is not.

Therefore, in the dust collecting electrode made of a material having a large critical surface tension, it is possible to form a portion that cannot be cleaned when a huge washing liquid is not supplied, thereby solving the conventional problem of cleaning the dust collecting electrode by manpower every predetermined period. It is not there.

In particular, when dealing with fine particles of 1㎛ or less, due to the excellent adhesion of the particles and the aging hardening properties, the cleaning of the dust collector through the intermittent cleaning liquid injection is not efficient, even in the case of continuous cleaning material with a large critical surface tension For example, if the dust collector is formed of synthetic resin, it is necessary to clean by frequent personnel.

Accordingly, the present invention is to improve the problems of the conventional wet electrostatic precipitator or the wet ionizer device as described above, by improving the surface significantly reducing the critical surface tension, efficient cleaning with a small amount of cleaning The purpose is to provide possible dust collection.

In addition, by improving the surface of the dust collector to significantly reduce the critical surface tension, it is an object of the present invention to provide a dust collector continuous cleaning device capable of efficient cleaning even with a small amount of cleaning water.

In addition, an injector capable of injecting a 90 ° radiation on each surface of the dust collector is attached to the washing water pipe, thereby ultimately forming a continuous water film with a minimum amount of washing water on the entire surface of the dust collector, and thus having strongly adherent particles. It is an object of the present invention to provide a dust collector continuous cleaning apparatus capable of a continuous operation by blocking the attachment of.

In addition, it is an object of the present invention to provide a dust collector continuous cleaning device that is easy to maintain by providing a cleaning device that can be attached and detached to the dust collector.

In order to achieve the above object, in the present invention, the discharge electrode is fixedly installed on the discharge electrode spacing bar, a plurality of discharge electrodes to which a high voltage is applied, and a predetermined distance is installed between the discharge electrodes, and the critical surface tension is reduced on the surface. A dust collecting electrode having a surface treatment, a reinforcing rod installed between the dust collecting electrodes to maintain the gap between the dust collecting electrodes, and a unit injection device for radially spraying the washing water onto the surface of the dust collecting electrode. A dust collecting electrode continuous cleaning apparatus is provided that includes a pipe header unit and a water trough installed under the dust collecting pole to prevent washing water from flowing to the discharge electrode gap maintaining rod to which a high voltage is applied.

In the present invention, the surface treatment performed on the surface of the dust collecting electrode is any one selected from a mechanical method by shot blast or sand blast, a hydrophilic surface treatment by plasma, and a coating method of nanoparticles. You can do it one way.

In addition, in the present invention, the cleaning pipe header unit is provided with a pipe header to which the washing water is supplied, and a unit injection device having a washing water discharge hole formed integrally with the pipe header to discharge the washing water to the surfaces of the dust collecting electrodes. Is made of.

Herein, the pipe header provided with the unit injection device is formed with a through hole to communicate with the unit injection device, the unit injection device is made of a hollow inside, the lower surface of the washing water discharge hole is predetermined in the vertical direction with the dust collecting electrode It is formed to have an angle of.

In particular, the washing water discharge hole may be formed to have an angle of 5 ~ 20 ° in the vertical direction with the dust collector, when the unit injection device is installed at the corner of the dust collector to uniformly clean the surface of the dust collector The washing water discharge hole may be radially formed within an angle range of 90 °.

In addition, when the unit injection device is installed above the dust collecting electrode so as to uniformly clean the surface of the dust collecting electrode, the washing water discharge hole may be radially formed within an angle range of 180 °.

In the present invention, the washing water discharge hole may be formed in a size having a diameter of 2 ~ 4mm.

In the present invention, the upper end of the dust collecting pole is formed with a 'U' shaped mounting groove, the unit injection device is fitted in the mounting groove, the washing pipe header unit is installed, the washing pipe header unit is the dust collecting pole It can be separated from.

On the other hand, the trough has a U-shaped cross-sectional shape, it may be installed in a V-shaped inverted to send the washing water falling from the dust collecting pole to the outside.

In the present invention, the dust collecting electrode may be made of any one selected from stainless steel, carbon FRP, PVC, PP.

As described above, according to the dust collector continuous cleaning apparatus of the present invention, by continuously forming a stable water film with a minimum amount of cleaning water on the surface of the dust collector, deposition of the sticky particles can be blocked at the source, and thus a high voltage power supply. By minimizing the intermittent cleaning that is performed after the blocking, ultimately, the efficiency of the wet electrostatic precipitator can be maintained.

In addition, it is possible to reduce the maintenance cost by increasing the dust collector cleaning cycle by the manpower and to reduce the production cost by applying engineering plastic as the dust collector material.

Hereinafter, with reference to the accompanying drawings, the dust collector continuous cleaning device of the present invention will be described in detail.

1 is a schematic view showing a hybrid wet scrubber system including a dust collecting device for continuously cleaning a dust collector according to an embodiment of the present invention, and the dust collecting continuous cleaning apparatus of the present invention having a discharge electrode 201 and a dust collecting electrode 202 is shown in FIG. An apparatus is installed, and a washing liquid circulation pump 101, a high voltage power supply 102, and an insulating air supply blower 103 are installed.

Figure 2 is a perspective view showing a dust collecting device continuous cleaning apparatus according to an embodiment of the present invention, the dust collector continuous cleaning device applied to a wet electrostatic precipitator or a wet ionizer device according to the present invention is a plurality of discharge electrodes to which a high voltage is applied 201, a dust collecting electrode 202 installed at a predetermined distance from the discharge electrode 201, a reinforcing rod 203 for maintaining a gap between the dust collecting electrodes 202, and the dust collecting electrode 202. The cleaning pipe header unit 204 is provided with a unit injection device 205 for spraying the washing water radially on the surface, and the water gutter 206 is provided below the dust collecting pole.

The discharge electrode 201 is fixed to the discharge electrode interval maintaining bar 211 is provided with a plurality of predetermined intervals, the dust collecting electrode 202 is provided with a predetermined distance between the discharge electrode.

The dust collecting electrode 202 of the present invention is characterized in that a special treatment is made to reduce the critical surface tension on the surface.

The collecting surface 202 has a critical surface tension that varies depending on the material and the surface state. When the critical surface tension is large, the contact angle θ ₁ formed by the water droplet and the surface of the collecting electrode becomes large (FIG. 6 (a)). Spreading is not smooth.

Therefore, the minimum wetting rate to wet the surface of the dust collector becomes large, and when the flow rate of the cleaning liquid supplied to the dust collector becomes less than the minimum wet liquid, the water film goes to the lower part even if the water film is not well formed or formed in the dust collector. This breakage causes contamination of the dust collecting electrode by the strongly sticky particulate matter.

Therefore, a special surface treatment is required to reduce the critical surface tension of the surface of the dust collecting electrode (Fig. 6 (b)). In the present invention, a special treatment performed on the surface of the dust collecting electrode 202 is a shot blast. A mechanical method such as sand blast may be used, and methods such as hydrophilic surface treatment by plasma or coating of nanoparticles may be used.

The cleaning pipe header unit 204 according to the present invention is provided integrally with the pipe header 214 to which the washing water is supplied and the pipe header 214 to radiate the washing water to the surfaces of the dust collecting electrodes 202. And a unit injection device 205 in which washing water discharge holes are formed.

In the pipe header 214 provided with the unit injection device 205, as shown in FIG. 4A, a through hole 214a is formed to communicate with the unit injection device 205. Is made of a hollow type, and the washing water flows into the unit injection device 205 through the through hole 214a.

The through hole 214a is formed as a hole having a size of 5 to 10 mm, and has a structure capable of supplying a cleaning liquid to the unit injection device 205.

Further, a washing water discharge hole 205a is formed in the lower surface of the unit injection device 205, and the washing water discharge hole 205a is formed to have a predetermined angle in a direction perpendicular to the dust collecting electrode 202.

That is, as shown in FIG. 4A, the washing water discharge hole 205a is formed to have a predetermined angle in a direction perpendicular to the dust collecting electrode 202 and sprayed to the dust collecting electrode 202 through the washing water discharge hole 205a. The washing water is sprayed at an angle so as to have a contact angle θ of the dust collecting electrode 202 with a predetermined angle.

Here, the washing water discharge hole (205a) is preferably formed to have a 5 to 20 ° angle in the vertical direction with the dust collecting electrode (202). That is, the contact angle θ of the cleaning water discharge hole 205a and the dust collecting electrode 202 is formed to have an angle of 5 to 20 degrees.

In addition, the washing water discharge hole 205a is radially formed within an angle range of 90 °. As shown in FIG. 3A, the unit injection device 205 is configured to uniformly clean the surface of the dust collecting electrode 202. When installed at the edge of the dust collecting electrode 202, the washing water discharge hole 205a is formed radially within an angle range of 90 °.

The washing water discharge hole 205a is formed of holes having a diameter of 2 to 4 mm, and when the unit injection device 205 is installed at the edge of the dust collecting electrode 202, as shown in FIG. It is preferable to install 5 to 15 radially within the angle range.

As described above, in the present invention in which the washing water discharge hole 205a is radially formed within an angle range of 90 °, as shown by a dotted line in FIG. It is possible to clean the dust collecting electrode 202 while being in contact with 202 at a predetermined interval, so that the overall uniform cleaning power can be obtained on the surface of the dust collecting electrode 202.

In addition, when the dust collecting electrode 202 is installed in the upper part of the dust collecting electrode 202, not the corner of the dust collecting electrode 202, as shown in Figure 3b to apply to a wide length, the washing water discharge hole 205a may be radially formed and expanded within an angle range of 180 °. In addition, it is possible to apply not only horizontal flow but also vertical flow.

The unit injection device 205 as such is preferably welded to the pipe header 204 is configured integrally.

Meanwhile, a water trough 206 is installed below the dust collecting pole 202 to prevent the washing water from flowing to the discharge electrode gap maintaining rod 211 to which a high voltage is applied, and the water trough 206 is shown in FIG. 5. As described above, it is formed to have a U-shaped cross-sectional shape to receive the washing water coming down the dust collecting electrode 202, and is welded and installed under the dust collecting electrode 202 in an inverted V shape to be installed at the dust collecting electrode 202. By preventing the falling washing water from falling into the discharge electrode gap keeping rod 211 and flowing it to the outside, it is possible to maintain a stable insulation state.

In addition, in the present invention, as shown in Figure 7, 'U' shaped mounting groove 202a is formed at the upper end of the dust collecting pole 202, the unit injection device 205 is fitted in the mounting groove 202a In addition, the cleaning pipe header unit 204 is installed.

In this way, the dust collecting electrode 202 and the cleaning pipe header unit 204 can be separated, and maintenance of the nozzle hole and the like can be facilitated.

In addition, as the material of the dust collecting electrode 202, not only conductive materials such as stainless steel and carbon FRP, but also non-conductive engineering plastics such as PVC, PP, etc., which are excellent in corrosion resistance and inexpensive due to the water film formed continuously, may be applied.

Although the present invention has been described in detail only with respect to the described embodiments, it will be apparent to those skilled in the art that various changes and modifications can be made within the technical scope of the present invention, and such modifications and modifications belong to the appended claims.

1 is a schematic view showing a hybrid wet scrubber system including a dust collecting device for continuous cleaning according to an embodiment of the present invention;

Figure 2 is a perspective view showing a dust collector continuous cleaning apparatus according to an embodiment of the present invention,

3A to 3B are front views illustrating a dust collecting film forming pattern and an expanded dust collecting film forming pattern of the present invention;

Figure 4a is a cross-sectional view showing a radial unit injection value of the present invention,

4B is a front view showing a radial unit injection value of the present invention;

5 is a detailed perspective view of the dust collecting container lower basin of the present invention,

6a to 6b are views showing the contact angle between the water droplet and the solid surface,

7 is a perspective view showing a state in which the cleaning pipe header unit of the present invention is separated from the dust collecting pole.

Explanation of symbols on the main parts of the drawings

101: cleaning liquid circulation pump 102: high voltage power supply

103: blower for supplying insulated air 201: discharge electrode

202: dust collector 203: reinforcing rod

204: washing pipe header unit 205: unit injection device

206: water gutter

Claims (10)

A plurality of discharge electrodes fixedly installed on the discharge electrode space keeping bar and to which a high voltage is applied; A dust collecting electrode having a predetermined distance spaced between the discharge electrodes and having a surface treatment to reduce the critical surface tension on the surface; A reinforcing rod installed between the dust collecting poles to maintain a gap between the dust collecting poles; A cleaning pipe header unit having a unit injection device for radially spraying cleaning water on the surface of the dust collecting electrode; And And a water collecting container disposed under the dust collecting electrode and including a water trough for preventing washing water from flowing to the discharge electrode gap maintaining rod to which a high voltage is applied. The method of claim 1, The surface treatment performed on the surface of the dust collecting electrode may be performed by any one method selected from a mechanical method by shot blast or sand blast, hydrophilic surface treatment by plasma, and coating method of nanoparticles. Dust collector continuous cleaning device characterized in that. The method of claim 1, wherein the cleaning pipe header unit, A dust collecting electrode continuous washing apparatus, comprising: a pipe header supplied with washing water; and a unit injection device provided integrally with the pipe header, and the washing water discharge hole is formed to radiate washing water on each surface of the dust collecting electrode. The method of claim 3, The pipe header provided with the unit injection device is formed with a through hole to communicate with the unit injection device, the unit injection device is made of a hollow inside, the lower surface of the washing water discharge hole is a predetermined angle in the vertical direction with the dust collecting electrode Dust collector continuous cleaning device characterized in that it is formed to have. The method of claim 4, wherein The washing water discharge hole is formed to have an angle of 5 ~ 20 ° in the vertical direction with the dust collecting pole, When the unit injection device is installed at the corner of the dust collecting electrode so as to uniformly clean the surface of the dust collecting electrode, the washing water discharge holes are formed radially within an angle range of 90 °. . The method of claim 4, wherein The washing water discharge hole is formed in a size having a diameter of 2 ~ 4mm Dust collector continuous cleaning device. The method of claim 4, wherein The washing water discharge hole is formed to have an angle of 5 ~ 20 ° in the vertical direction with the dust collecting pole, When the unit injection device is installed above the dust collecting electrode so as to uniformly clean the surface of the dust collecting electrode, the washing water discharge holes are formed radially within an angle range of 180 °. . The method of claim 1, The upper end of the dust collecting pole is formed with a 'U' shaped groove, The unit injection device is inserted into the mounting groove, and the cleaning pipe header unit is installed, and the cleaning pipe header unit can be separated from the dust collecting electrode. The method of claim 1, The water collecting container has a U-shaped cross-sectional shape, and is installed in a V-shaped inverted so as to flow the washing water falling from the dust collecting to the outside. The method of claim 1, The dust collecting electrode is a continuous cleaning device, characterized in that made of any one selected from stainless steel, carbon FRP, PVC, PP.

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