JP2009131795A - Wet type electric dust collector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a wet type electric dust collector which reduces a spark between electrodes and also can form a water film on a dust collecting electrode in a smaller amount of water. <P>SOLUTION: The wet type electric dust collector includes a guide plate 42 which has a plurality of slits 42a for passing a gas to be treated under a nozzle 41 for spraying a cleaning liquid and also recovers the cleaning liquid sprayed by the nozzle 41 to guide it onto the surface of the dust collecting electrode 31. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a wet electrostatic precipitator that electrically adsorbs and removes contaminant particles in a gas to be treated.

  The electric dust collector is incorporated in, for example, a kitchen exhaust device and is used to remove contaminant particles (for example, dust and oil mist) in the kitchen exhaust. This electrostatic precipitator is equipped with a discharge part that charges the pollutant particles in the exhaust gas and a dust collection electrode that electrically adsorbs the pollutant particles charged by the discharge part. To collect.

In such an electrostatic precipitator, when the collected contaminated particles are deposited on the precipitator electrode, the dust collecting ability is lowered. Therefore, a so-called wet electrostatic precipitator in which the precipitator electrode is cleaned with a cleaning liquid such as water has been developed. (Some wet electrostatic precipitators collect water-soluble toxic gases). In a wet electrostatic precipitator, it is important to form a uniform water film on the surface of the dust collecting electrode because of its dust collecting principle. As an example of a conventional wet electrostatic precipitator, there is one in which water is sprayed from above a dust collecting electrode using a flat nozzle or a full cone spray nozzle to form a water film on the dust collecting electrode (for example, a patent) Reference 1). For example, in a device that sprays water using a flat nozzle, there is a problem that the amount of water is more than double that of a general conical nozzle. On the other hand, a full cone type spray nozzle has a conical spray region, and water droplets are distributed in the center of the conical region, so that uniform spraying is possible and a smaller amount of water is required than a flat type nozzle. It can be cleaned effectively.
Japanese Patent No. 2688004

  However, although the full cone spray nozzle is effective in reducing the amount of water, some of the sprayed water droplets pass between the electrodes without forming a water film, so that the water droplets can be used effectively enough. I can't say that.

  In addition, when relatively coarse water droplets (for example, water droplets of about 3 mm) condensed and generated by structures above the dust collecting electrode such as nozzles and nozzle piping fall between the dust collecting electrode and the counter electrode, There is a problem that the space insulation distance between the dust collecting electrode and the counter electrode is shortened by the size of the water droplet, and sparks are generated. As described above, the apparatus is stopped during the generation of the spark, which is not efficient. This spark can be reduced by increasing the distance between the dust collecting electrode and the counter electrode, but this causes problems such as an increase in the size of the device and a decrease in dust collecting performance.

  The present invention has been made paying attention to the above-described problem, and an object of the present invention is to make it possible to form a water film on a dust collecting electrode with a smaller amount of water while reducing sparks between the electrodes.

In order to solve the above problems, the first invention is
In the gas passage (11) through which the gas to be treated flows, a discharge part (20) for charging the dust in the gas to be treated, a dust collection electrode (31), and a dust collection electrode (31) facing the dust collection electrode (31). A dust counter electrode (32), and disposed on the downstream side of the discharge part (20) to electrically charge the dust charged by the discharge part (20) to the dust collection electrode (31) A dust collecting part (30) to be adsorbed, and a spray means (41) for spraying and supplying a cleaning liquid for cleaning the dust adsorbed on the dust collecting electrode (31) from above the dust collecting electrode (31); A wet type electric dust collector,
The cleaning liquid sprayed by the spraying means (41) is disposed on the lower side of the spraying means (41), has a plurality of flow holes (42a) through which the gas to be treated passes, and the dust collecting electrode (31 ) Is provided with a guide plate (42) for guiding to the surface.

  Thereby, the cleaning liquid sprayed by the spraying means (41) is collected by the guide plate (42) and guided to the surface of the dust collecting electrode (31). The cleaning liquid guided to the surface of the dust collection electrode (31) forms a water film there. In addition, the gas to be treated passes through the flow hole (42a) of the guide plate (42), and the dust in the gas is charged in the discharge part (20). 31) is electrically adsorbed by.

In addition, the second invention,
A wet electrostatic precipitator according to the first invention,
The guide plate (42) is formed in a mountain shape having a slope inclined toward the upper end of the dust collection electrode (31).

  As a result, the cleaning liquid on the surface (upper surface) of the guide plate (42) is reliably guided to the dust collecting electrode (31) and passes through the flow hole (42a) and travels to the back surface of the guide plate (42). Is guided to the dust collecting electrode (31) along the back surface of the guide plate (42).

In addition, the third invention,
A wet electrostatic precipitator according to the first invention,
The flow hole (42a) has a slit shape.

  Thereby, the gas to be processed passes through the slit (42a) and is introduced into the discharge part (20).

In addition, the fourth invention is
A wet electrostatic precipitator according to the first invention,
A plurality of the guide plates (42) are provided in a multiplexed manner.

  Thereby, for example, even if the cleaning liquid passes through one guide plate (42) and falls as water droplets, the lower guide plate (42) collects the dropped cleaning liquid and guides it to the dust collecting electrode (31). To do.

In addition, the fifth invention,
A wet electrostatic precipitator according to the first invention,
The size of the flow hole (42a) is such that when the cleaning liquid sprayed from the spray means (41) falls as water droplets from the flow hole (42a), the size of the water droplets is the dust collecting electrode (31 ) And the dust-collecting counter electrode (32) so as not to cause a spark.

  Thus, the size of water droplets (cleaning liquid) that passes through the circulation hole (42a) and falls between the dust collection electrode (31) and the dust collection counter electrode (32) is regulated.

  According to the first invention, since the sprayed cleaning liquid is collected, the dust collecting electrode (31) can be cleaned with a smaller amount of water. Moreover, there is no restriction | limiting in the form of the nozzle (41) used for spraying, Various forms, such as a flat type nozzle and a full cone type spray nozzle, are employable. In addition, compared with a wet electrostatic precipitator that does not have a guide plate (42), the amount of cleaning liquid that falls as water droplets between the dust collection electrode (31) and the dust collection counter electrode (32) can be reduced, so that a spark is generated. Can be reduced.

  According to the second invention, the cleaning liquid is more reliably guided to the dust collection electrode (31). In addition, since the cleaning liquid that has passed through the flow hole (42a) is also guided to the dust collection electrode (31), it is less likely to fall between the dust collection electrode (31) and the dust collection counter electrode (32) as water droplets. As a result, the occurrence of sparks can be more reliably reduced.

  According to the third invention, the gas to be treated is efficiently introduced into the dust collection part (30) below the guide plate (42). That is, dust collection efficiency is improved.

  Further, according to the fourth invention, the cleaning liquid sprayed by the spraying means (41) can be more reliably collected and guided to the dust collecting electrode (31), and the dust collecting electrode (31) and the collecting electrode can be guided. Dropping of water droplets between the dust counter electrode (32) can be more reliably reduced.

  According to the fifth invention, even if the cleaning liquid passes through the flow hole (42a) and falls as a water droplet between the dust collecting electrode (31) and the dust collecting counter electrode (32), the water droplet Can be made large enough not to break the insulation between the electrodes (31, 32). Therefore, the occurrence of a spark between both electrodes (31, 32) can be more reliably reduced.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use. In the following description of each embodiment and modification, components having the same functions as those described once will be given the same reference numerals and description thereof will be omitted.

<< Embodiment of the Invention >>
The wet type electrostatic precipitator according to the embodiment of the present invention is incorporated in, for example, a kitchen exhaust device and used to remove contaminant particles (such as dust and oil mist) in the kitchen exhaust.

-Configuration of wet electrostatic precipitator-
FIG. 1 is a diagram showing a wet electrostatic precipitator (1) according to an embodiment of the present invention. This wet electrostatic precipitator (1) is a discharge that charges the particles in the gas to be treated (air in this example) in the casing (10) and the air passage (11) formed in the casing (10). Dust collection part (30), which collects the charged particles from the discharge part (20) and the discharge part (20) by electrically adsorbing them to the electrode (dust collection electrode) and cleaning liquid for cleaning the dust collection electrode (this example In the cleaning liquid supply unit (40) for supplying water, the high-voltage power supply (50) for supplying voltage to the discharge unit (20) and the dust collection unit (30), and the air passage (11) It is comprised by arrange | positioning the air blower (60) which discharges | emits to-be-processed gas from. Here, the air passage (11) is formed vertically so that the gas to be processed flows in the vertical direction of the apparatus, the upper side is an inlet of the gas to be processed, and the lower side is an outlet (exhaust duct). A blower (60) is disposed in the exhaust duct of the air passage (11), and the blower (60) sucks a gas to be treated in the air passage (11) to discharge an air outlet (61) of the blower (60). ) From the upper side to the lower side in the air passage (11).

  The discharge part (20) has a plurality of discharge electrodes (21) and a plurality of electrodes (discharge counter electrodes) facing the respective discharge electrodes (21). These electrodes are supplied with power from a high-voltage power supply (50) and cause corona discharge between the electrodes.

  In the present embodiment, the discharge counter electrode also serves as the dust collection electrode (31) of the dust collection section (30) described later. As shown in FIG. 2, the dust collection electrode (31) is formed in a plate shape, for example.

  On the other hand, in the present embodiment, the discharge electrode (21) is formed by forming the tip of a dust collecting counter electrode (32) (described later) in a sawtooth shape. Specifically, as shown in FIG. 2, a plurality of triangular protrusions are provided as discharge electrodes (21) at the tip of the counter electrode (32) for dust collection formed in a plate shape.

  In this wet electrostatic precipitator (1), as shown in FIG. 1, each discharge counter electrode (dust collection electrode (31)) is arranged in parallel with each other at substantially equal intervals, and each electrode surface is in a direction in which the gas to be treated flows. It arrange | positions in an air channel | path (11) so that it may follow. In FIG. 1, the width direction of the dust collecting electrode (31) is illustrated as a direction perpendicular to the paper surface. In addition, between the discharge counter electrodes (dust collection electrode (31)), the discharge electrode (21) is parallel to the discharge counter electrode and faces the surface near the upper end of the discharge counter electrode. Are arranged.

  In this wet electrostatic precipitator (1), since the air passage (11) is arranged vertically and the upper side of the air passage (11) is upstream of the gas to be treated, the gas to be treated is discharged in this discharge section (20). It passes from the upper side to the lower side between the electrode (21) and the corresponding counter electrode for discharge (dust collecting electrode (31)). At this time, the discharge electrode (21) and the discharge counter electrode (dust collection electrode (31)) are connected to the negative electrode side and the positive electrode side of the high-voltage power source (50), respectively, and corona discharge is caused between the two electrodes. Wake up. Therefore, the gas to be processed flowing in the air passage (11) is charged by corona discharge generated between both electrodes when passing between these electrodes.

  The dust collection part (30) includes a plurality of dust collection electrodes (31) and a plurality of dust collection counter electrodes (32), and is located downstream of the air passage (11) from the discharge part (20) (that is, It is arrange | positioned below a discharge part (20). The dust collecting counter electrode (32) is formed in a plate shape as described above. In each gap between the dust collection electrodes (31), the dust collection counter electrode (32) is disposed in parallel with the dust collection electrode (31). Thereby, also in the dust collection part (30), both electrodes (31, 32) are arranged alternately in the air passage (11) so that the electrode surface is along the direction in which the gas to be treated flows. Become. Therefore, the gas to be treated (specifically, the gas to be treated charged by the discharge part (20)) flowing in the air passage (11) is between the dust collecting electrode (31) and the dust collecting counter electrode (32). Will pass from top to bottom.

  Each dust collecting electrode (31) and each dust collecting counter electrode (32) are connected to the positive electrode side and the negative electrode side of the high voltage power source (50), respectively, and are supplied with power. That is, each dust collection electrode (31) has a polarity different from that of the discharge electrode (21). With this configuration, the gas to be treated charged by the discharge unit (20) is electrically adsorbed to the dust collection electrode (31).

  The cleaning liquid supply unit (40) includes a nozzle (41) for spraying cleaning liquid for cleaning the dust collecting electrode (31), and a cleaning liquid sprayed by the nozzle (41) below the nozzle (41). A guide plate (42) for guiding to (31), a solution tank (43) for storing cleaning liquid, a liquid transport pump (44) for supplying water in the solution tank (43) to the nozzle (41), and cleaning It has a water droplet collection part (45) that collects the used cleaning liquid.

  The nozzle (41) is connected to the liquid transport pump (44) by piping, and sprays the cleaning liquid in the solution tank (43) supplied by the liquid transport pump (44) toward the lower guide plate (42). . The form of the nozzle (41) is not particularly limited. For example, a flat type nozzle or a full cone type spray nozzle can be employed, but a full cone type spray nozzle is advantageous in order to reduce the amount of water used.

  The guide plate (42) is provided below the nozzle (41) and has a plurality of flow holes for allowing the gas to be processed to pass therethrough. More specifically, as shown in FIG. 3, the guide plate (42) of this embodiment is formed by providing a plurality of slits (42a) in parallel as flow holes in the plate material and bending the plate into a mountain shape. is doing. In this example, the slit (42a) is formed such that the inclination direction of the angled slope is the longitudinal direction of the slit (42a). Moreover, the straight part (42b) which is a mutually parallel surface is provided in the part of both skirts of this mountain-shaped guide plate (42). The interval (W in FIG. 3) between these straight portions (42b) is set slightly smaller than the interval between two dust collecting electrodes (31) adjacent to each other. The depth (D in FIG. 3) of the guide plate (42) is set to be substantially the same as the width (horizontal width) of the dust collection electrode (31).

  The guide plate (42) formed in this way is located above the two dust collecting electrodes (31) adjacent to each other, with the chevron tip facing upward, and each straight portion (42b) Near the upper end inside the dust electrode (31), the dust collection electrode (31) and the straight portion (42b) are arranged to face each other with a predetermined gap (see FIG. 4). With this arrangement, the slope of the mountain-shaped guide plate (42) is inclined toward the upper ends of the dust collecting electrodes (31) on both sides. In the wet electrostatic precipitator (1), since the plurality of dust collecting electrodes (31) are arranged in parallel, the guide plate (42) is arranged between the respective dust collecting electrodes (31).

  When the cleaning liquid is sprayed from above the guide plates (42) by the nozzle (41), the cleaning liquid collides with and adheres to the upper surface side of the inclined surface of the guide plate (42). As shown in FIG. 4, the cleaning liquid adhering to the upper surface of the guide plate (42) flows along the slope toward the upper end of the dust collecting electrode (31), and the straight portion (42b) and the dust collecting electrode (31). A uniform water film is formed on the surface of the dust collecting electrode (31). The cleaning liquid that has formed a water film on the surface of the dust collection electrode (31) flows on the surface of the dust collection electrode (31) and falls downward from the lower end of the dust collection electrode (31).

  The water droplet collection unit (45) is arranged below the dust collection unit (30) (specifically, the dust collection electrode (31)) to receive the cleaning liquid that has flowed down the surface of the dust collection electrode (31) and dropped as water droplets. ing. The water droplet collection unit (45) is configured to block the passage of the received water droplets (cleaning liquid used for cleaning), allow the flow of the treated gas, and collect the contaminated particles in the water droplets. The water droplets from which the contaminating particles have been removed are discharged to a solution tank (43) provided below the water droplet collection section (45). With this configuration, the cleaning liquid is circulated and used in the wet electrostatic precipitator (1).

-Operation of wet electrostatic precipitator (1)-
The to-be-treated gas sent into the air passage (11) is sucked by the blower (60) and flows downward from the upper entrance to the inside of the air passage (11). At this time, as will be described later, the cleaning liquid is sprayed from the nozzle (41) of the cleaning liquid supply section (40), and the sprayed cleaning liquid is subjected to a contamination particle (for example, dust or oil mist) in the gas to be treated. The part adheres, but most of the contaminated particles flow in the air passage (11) while being contained in the gas to be treated. When the gas to be processed reaches the guide plate (42), the gas to be processed passes through the slit (42a) of the guide plate (42) and proceeds further downstream to reach the discharge section (20). At this time, in the discharge part (20), corona discharge is generated from the discharge electrode (21) toward the discharge counter electrode (dust collection electrode (31)) facing the discharge electrode (21). By this corona discharge, contaminant particles (for example, dust and oil mist) in the gas to be treated that have reached the discharge section (20) are charged.

  On the other hand, the cleaning liquid in the solution tank (43) is supplied to the nozzle (41) of the cleaning liquid supply unit (40) by the liquid transport pump (44). The cleaning liquid is sprayed from the nozzle (41) toward the guide plate (42). The sprayed cleaning liquid spreads in the air passage (11) above each guide plate (42) and collides with and adheres to the slope of each guide plate (42). The cleaning liquid adhering to each guide plate (42) flows along the slope of the guide plate (42) toward the upper end of the dust collection electrode (31), and the straight portion (42b) and the dust collection electrode (31). A uniform water film is formed on the surface of the dust collecting electrode (31). At this time, there may be a case where relatively coarse water droplets condensed and generated by the structure above the dust collecting electrode such as the nozzle (41) and the piping for the nozzle (41) fall. Such relatively coarse water drops fall on the guide plate (42), are collected by the guide plate (42), and are guided to the dust collecting electrode (31).

  The gas to be treated containing the contaminated particles charged by the discharge part (20) flows further downstream (downward) and enters between the dust collecting electrode (31) and the dust collecting counter electrode (32). Go. At this time, the charged contaminant particles in the gas to be treated are attracted toward the dust collection electrode (31) by an electric force. Since the water film is formed on the surface of the dust collecting electrode (31) as described above, the contaminant particles attracted to the surface of the dust collecting electrode (31) flow downward by the flow of the water film. It will be done. When the cleaning liquid containing the contaminating particles reaches the lower end of the dust collecting electrode (31), it falls as water droplets on the water droplet collecting part (45). As described above, the gas to be treated containing the contaminating particles passes between the dust collecting electrode (31) and the dust collecting counter electrode (32), so that the polluting particles are removed by an electric force. And the to-be-processed gas from which the pollutant particle was removed flows further downstream, and reaches | attains a water droplet collection | recovery part (45).

  In the water droplet collection section (45), the gas to be treated (contaminated particles are removed) passes and is discharged from the air outlet (61) of the blower (60) to the outside of the wet electrostatic precipitator (1). On the other hand, the cleaning liquid (water droplets) containing the contaminated particles is discharged to the solution tank (43) after the contaminated particles are removed in the water droplet recovery section (45). The discharged cleaning liquid is supplied again to the nozzle (41) by the liquid transport pump (44).

-Effect of wet electrostatic precipitator (1)-
As described above, according to the present embodiment, the cleaning liquid sprayed from the nozzle (41) is surely collected by the guide plate (42) and flows onto the surface of the dust collecting electrode (31) to form a water film. Can do. That is, water droplets passing through between the dust collecting electrode (31) and the dust collecting counter electrode (32) are reduced. Therefore, the dust collection electrode (31) can be cleaned with a smaller amount of water. Moreover, there is no restriction | limiting in the form of the nozzle (41) to be used, and various forms, such as a flat type nozzle and a full cone type spray nozzle, can be adopted.

  By the way, for example, if there is no guide plate as shown in FIG. 5, relatively coarse water droplets condensed and generated by the structure above the dust collecting electrode such as the nozzle and nozzle piping are collected by the dust collecting electrode and the dust collecting electrode. It may fall between the counter electrodes for use. At this time, if the water droplets dropped between the two electrodes have a certain size or more, the space insulation distance between the two electrodes is shortened, and spark is generated between the two electrodes. And while the spark is generated, the contaminant particles cannot be adsorbed and the dust collection efficiency is deteriorated. On the other hand, in this embodiment, since the guide plate (42) is provided, these water droplets are collected and guided to the surface of the dust collection electrode (31) to form a water film. That is, in this wet electrostatic precipitator (1), since the drop of water drops between the dust collecting electrode (31) and the dust collecting counter electrode (32) can be reduced, the wet electric dust collector not provided with the guide plate (42) Compared to a dust collector, the occurrence of sparks can be reduced more reliably.

  Moreover, since the guide plate (42) is formed in a mountain shape, the cleaning liquid that has passed through the slit (42a) and has traveled to the back side of the slope travels along the back side of the slope toward the dust collecting electrode (31). Will flow. That is, even when the cleaning liquid passes through the slit (42a), it is possible to reduce the water droplets falling between the dust collection electrode (31) and the dust collection counter electrode (32). Some of the cleaning liquid that has passed through the slit (42a) may fall between the dust collecting electrode (31) and the dust collecting counter electrode (32) as water droplets. If the width of the slit (42a) is set so that the insulation does not break the insulation between both electrodes (31, 32), the occurrence of sparks between both electrodes (31, 32) can be further increased. It can be reliably reduced.

<Modification of guide plate (42)>
For example, as shown in FIG. 6, a plurality of guide plates (42) may be arranged in the vertical direction. By doing so, the cleaning liquid sprayed from the nozzle (41) can be more reliably collected and guided to the dust collecting electrode (31).

  Further, the inclination of the slope of the guide plate (42) may be different as shown in FIG. 7, for example.

  FIG. 8 is an example in which one dust collection cell is constituted by four dust collection electrodes (31), and one dust collection section (30) is constituted by arranging a plurality of dust collection cells in a grid pattern ( FIG. 8 shows only one dust collection cell). In this case, the guide plate (42) is formed in a quadrangular pyramid shape having four inclined surfaces, and is arranged at the upper end of each dust collection cell.

<< Other Embodiments >>
As described above, it is not necessary to use the counter electrode of the discharge electrode (21) in the discharge part (20) and the dust collection electrode (31) of the dust collection part (30). Good. Similarly, the discharge electrode (21) and the dust collecting counter electrode (32) may be configured as separate electrodes.

  Further, the discharge electrode (21) may not have a sawtooth shape. For example, the discharge electrode (21) can be formed in a wire shape. In this case, for example, the wire-shaped discharge electrode (21) is placed near the upper end of the discharge counter electrode and in the gap between the discharge counter electrodes (in the above example, the dust collecting electrode (31)). In parallel with the counter electrode, the discharge counter electrode is disposed so as to extend in the entire width direction (horizontal direction).

  Further, the flow hole of the guide plate (42) is not limited to the slit (42a) described in the above example. In addition to the slits, for example, it can be formed in a mesh shape (or wire mesh shape) or by using a punching metal.

  Further, the shape of the dust collecting electrode (31) is not limited to a plate shape, and it is sufficient that the dust collecting electrode (31) has a surface that adsorbs dust.

  The wet electrostatic precipitator according to the present invention is useful as a wet electrostatic precipitator that electrically adsorbs and removes contaminating particles in the gas to be treated.

It is a figure which shows the wet electric dust collector which concerns on embodiment of this invention. It is a perspective view which shows the shape of a discharge electrode, the counter electrode for discharge, a dust collection electrode, and the counter electrode for dust collection. It is a perspective view of the guide plate which concerns on embodiment of this invention. It is a figure which shows arrangement | positioning etc. of each electrode and a guide plate. It is a figure explaining operation | movement of the wet electric dust collector without a guide plate. It is a figure which shows the other structural example of a guide plate. It is a figure which shows the further another structural example of a guide plate. It is an example of the guide plate in the case where a plurality of dust collection cells are arranged in a grid to constitute one dust collection portion.

Explanation of symbols

1 Wet electrostatic precipitator 11 Air passage (treated gas passage)
20 Discharge unit 30 Dust collection unit 31 Dust collection electrode 32 Counter electrode for dust collection 41 Nozzle (spraying means)
42 Guide plate 42a Slit (flow hole)

Claims (5)

In the gas passage (11) through which the gas to be treated flows, a discharge part (20) for charging the dust in the gas to be treated, a dust collection electrode (31), and a dust collection electrode (31) facing the dust collection electrode (31). A dust counter electrode (32), and disposed on the downstream side of the discharge part (20) to electrically charge the dust charged by the discharge part (20) to the dust collection electrode (31) A dust collecting part (30) to be adsorbed, and a spray means (41) for spraying and supplying a cleaning liquid for cleaning the dust adsorbed on the dust collecting electrode (31) from above the dust collecting electrode (31); A wet type electric dust collector,
The cleaning liquid sprayed by the spraying means (41) is disposed on the lower side of the spraying means (41), has a plurality of flow holes (42a) through which the gas to be treated passes, and the dust collecting electrode (31 A wet type electrostatic precipitator comprising a guide plate (42) for guiding to the surface of The wet electrostatic precipitator according to claim 1,
The wet electrostatic precipitator, wherein the guide plate (42) is formed in a mountain shape having a slope inclined toward the upper end of the dust collection electrode (31). The wet electrostatic precipitator according to claim 1,
The wet electrostatic precipitator, wherein the flow hole (42a) has a slit shape. The wet electrostatic precipitator according to claim 1,
The wet electrostatic precipitator, wherein a plurality of the guide plates (42) are provided in a multiplexed manner. The wet electrostatic precipitator according to claim 1,
The size of the flow hole (42a) is such that when the cleaning liquid sprayed from the spray means (41) falls as water droplets from the flow hole (42a), the size of the water droplets is the dust collecting electrode (31 ) And the counter electrode for dust collection (32). The wet electrostatic precipitator is set to have a size that does not cause a spark.

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