JP2013240741A - Electrode cover device of wet electric dust collector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent the occurrence of abnormal discharge caused by the wraparound of water to cut-in an electrode in spite of a simple structure.SOLUTION: A disc cylinder 33 made of PTFE is fixedly provided to the undersurface of an insulating member 21. Here, the disc cylinder 33 is constituted of an inner cylinder 34 through which an electrode fixture 5 is pierced in a closely fitted state and an outer cylinder 35 having the upper surface part integrally formed to the outer surface of the inner cylinder 34. The upper part of the inner cylinder 34 is closely fitted and mounted in the hole part 26 of an insulating member 21 so as not to form a water passing gap between the insulating member 21 and the electrode fixture 5. Further, a single or a plurality of discharge electrodes 4 may be provided. Fins 36 are provided to the outer peripheral surface of the disc cylinder 33 and the occurrence of the abnormal discharge due to the waterdrops fallen from the disc cylinder 33 is prevented.

Description

  The present invention relates to an electrode cover device for a wet electrostatic precipitator, and more particularly to an electrode cover device for a wet electrostatic precipitator that eliminates a gap in an electrode cover structure and prevents abnormal discharge due to wraparound of water.

  The wet electrostatic precipitator is used to remove pollutant particles (dust mist) in the exhaust gas. This wet type electrostatic precipitator includes a discharge unit that charges the pollutant particles in the exhaust gas, and a dust collection electrode that removes the pollutant particles charged in the discharge unit. Is to be captured.

  FIG. 5 shows a conventional example of a wet electrostatic precipitator. In FIG. 5, reference numeral 1 denotes a cylindrical casing, and a dust collecting electrode 30 is disposed on the inner surface of the side wall of the casing 1.

  The center line C of the casing 1 is provided with a discharge electrode 4 as a discharge portion, and the upper portion of the discharge electrode 4 is suspended by a stainless steel electrode fixture (hereinafter referred to as “electrode fixture”) 5. . The electrode fixture 5 penetrates through an electrode cover 56 made of a synthetic resin (polypropylene or the like) and an insulating glass plate (insulation member) 21, and a fluororesin (polytetrafluoroethylene) is formed in a predetermined region on the upper outer periphery of the electrode fixture 5. , Hereinafter referred to as “PTFE”).

  Next, the structure of the electrode cover 56 will be described. The electrode cover 56 includes the exhaust chamber 10 and includes a circular lower bottom portion 31 and a short cylindrical upper lid portion 13.

  A water inlet 14 is provided in the upper part of the side wall of the casing 1. Water (scrubber water) W can be sprayed from the water inlet 14 to the vicinity of the surface of the dust collecting electrode 30 in the form of a mist or a curtain.

  The upper lid portion 13 is connected to the upper side of the lower bottom portion 31, and the exhaust chamber 10 is formed by the upper lid portion 13 and the lower bottom portion 31. The exhaust chamber 10 and the gas processing chamber 16 in the casing 1 are communicated with each other via a communication port 17 opened in the lower bottom portion 31.

  An exhaust port 18 is formed on the side surface of the upper lid portion 13. Accordingly, the exhaust gas G purified in the gas processing chamber 16 in the casing 1 is introduced into the exhaust chamber 10 via the communication port 17 and then released from the exhaust port 18 to the atmosphere via a pipe (not shown). It has become so.

  Further, a circular insulating glass plate 21 is fixed at a position corresponding to the electrode fixture 5 on the lower surface of the lower bottom portion 31.

  As shown in FIG. 6, a glass cylinder 24 is fixed on the lower surface side of the insulating glass plate 21, and a PTFE disk 25 is fixed inside the glass cylinder 24. The disk 25 is disposed under the hole 26 for penetrating the electrode fixture formed in the insulating glass plate 21. The lower end side of the sleeve 7 attached to the electrode fixture 5 is formed by a plate portion 27, and the lower surface of the plate portion 27 is in surface contact with the insulating glass plate 21.

  In the above structure, the contaminated particles in the exhaust gas G rising in the gas processing chamber 16 in the casing 1 are charged by corona discharge from the discharge electrode 4 and move to the dust collection electrode 30 side. The contaminated particles that have moved come into contact with mist-like or curtain-like water W sprayed from the water inlet 14 and are captured.

Thereby, the contaminating particles in the exhaust gas G are removed. The treated exhaust gas G passes through the communication port 17 from the gas processing chamber 16 and is introduced into the exhaust chamber 10, and then released from the exhaust port 18 into the atmosphere via a pipe (for example, see Patent Document 1). ).

Utility model registration No. 3001822 Japanese Patent No. 3617305

  In the above conventional example, as a means for preventing the occurrence of abnormal discharge from the discharge electrode, it is common to install an insulating member (insulating glass plate) at a certain distance around the upper structure portion of the discharge electrode. However, since there is a slight gap between the insulating member and the structure portion of the electrode cover, water enters the casing through the gap.

  In particular, water penetrates into the glass cylinder from the gap between the electrode fixture and the insulating glass plate, and abnormal discharge occurs through this water, that is, a short or spark occurs in the discharge electrode, and the function of the discharge electrode is deteriorated. There has been a problem of inducing damage to peripheral parts (insulating members, sealing members, etc.).

  Further, part of the water that has flowed into the casing descends along the outer peripheral surface of the glass cylinder and falls as water droplets on the discharge electrode side. And there also existed a problem that this water circulated to the discharge electrode vicinity and induced abnormal discharge.

  In order to solve the above-mentioned problem, an electrode provided with an inclined plate above the electrode is known (see Patent Document 2). According to this, in the type that takes in water from above the electrode, an effect of preventing the water from flowing into the vicinity of the electrode by the inclined plate can be expected. However, a type that takes in water from the side of the electrode is difficult to apply because water wraps around the electrode from the side or from below. In particular, the water taken in from the side adheres to the outer peripheral surface of the glass cylinder, falls on the outer peripheral surface to form water droplets, and abnormal discharge is generated through the water droplets.

  Further, in the inclined plate installation method, when the number of the electrodes increases, the number of inclined plates increases accordingly. This complicates the shape and structure of the entire electrode cover device including the electrodes, and increases the manufacturing cost of the device.

  Therefore, there is a technical problem to be solved in order to prevent abnormal discharge due to water wrapping around the electrode with a simple structure without providing an inclined plate. The purpose is to solve.

  The present invention has been proposed to achieve the above object, and the invention according to claim 1 is an electrode cover device attached to an upper part of a casing containing a discharge electrode and a dust collecting electrode, An insulating member having a hole through which the electrode fixture passes is fixed to the lower surface side of the electrode cover device, and a disk cylinder made of synthetic resin is fixed to the lower surface of the insulating member. And an outer cylinder having an upper surface formed integrally with the outer surface of the inner cylinder, and the upper portion of the inner cylinder is fitted into the hole of the insulating member. Thus, there is provided an electrode cover device for a wet type electrostatic precipitator, characterized in that no gap is formed between the insulating member and the electrode fixture.

  In the conventional structure, there is a drawback that water passes through the gap between the electrode fixture of the discharge electrode and the hole of the insulating member and enters the glass cylinder. The upper part of the inner cylinder that is tightly fitted is tightly fitted into the hole of the insulating member. Therefore, there is no gap in which water descends toward the casing, and in particular, there is no possibility of water entering the disk cylinder located above the discharge electrode.

  According to a second aspect of the present invention, there is provided the electrode cover device for a wet electrostatic precipitator according to the first aspect, wherein an appropriate number of fins are provided on the outer peripheral surface of the disk cylinder.

  According to this configuration, by providing the fin on the outer peripheral surface of the disc cylinder, even when water adheres to the outer peripheral surface of the disc cylinder and falls, the risk of occurrence of abnormal discharge is reduced for the following reasons.

  In other words, the water adhering to the outer peripheral surface of the disc cylinder falls discontinuously as water droplets from the fins, but the distance that the water moves along the outer peripheral surface of the disc cylinder becomes longer and the protrusion length of the fins. Since the space discharge distance is increased by dropping the point separated from the discharge electrode, the risk of occurrence of abnormal discharge is effectively reduced.

  The invention according to claim 3 is characterized in that the outer diameter of the disc cylinder is set to a size equal to or larger than a predetermined value so as not to cause abnormal discharge through water falling from the outer peripheral surface of the disc cylinder. An electrode cover device for a wet electrostatic precipitator according to claim 1 or 2 is provided.

  According to this configuration, by setting the outer diameter of the disc cylinder to a predetermined value or more, water drops falling from the outer peripheral surface of the disc cylinder descend at a side point separated by a predetermined distance from the discharge electrode. Therefore, the risk of occurrence of abnormal discharge through water droplets is reduced.

  According to a fourth aspect of the present invention, there is provided a wet electrostatic precipitator comprising the electrode cover device of the wet electrostatic precipitator according to any one of the first to third aspects.

  According to the first aspect of the present invention, although the structure is simple, the inner and outer concentric cylinder double structure type disc cylinder eliminates the gap where the water descends to the casing side, so that the water flows around the discharge electrode. Can be prevented.

  In particular, since there is no risk of water entering the disk cylinder, it is possible to effectively suppress abnormal discharge caused by intruded water, thereby preventing functional deterioration or breakage of electrodes and peripheral parts due to abnormal discharge. The life of the parts can be extended.

  Further, the present invention has a structure in which a disk cylinder is fixed on the lower surface side of the insulating member. Therefore, in any case of taking in water from above or from the side of the electrode, or the number of discharge electrodes is singular or Any of a plurality of cases can be easily put into practical use and an excellent abnormal discharge prevention effect can be obtained.

  In addition, the present invention does not require an increase in the number of disk cylinders even when the number of discharge electrodes increases, so that the structure is not complicated compared to the conventional example of the inclined plate installation type. It has the advantage of being simple and inexpensive to manufacture.

  In the invention described in claim 2, the water adhering to the outer peripheral surface of the disk cylinder falls through the fins as discontinuous water droplets, and at that time, the space discharge distance is extended. In addition to the effects of the invention, the risk of occurrence of abnormal discharge can be effectively reduced. Therefore, even in a type that takes in water from the side of the electrode, it is possible to more reliably prevent short-circuiting or sparking of the electrode through water.

  In the invention according to claim 3, since the risk of occurrence of abnormal discharge can be reduced by setting the outer diameter of the disk cylinder to a predetermined value or more, the structure of the disk cylinder has the effect of the invention according to claim 1. Although simple, it is possible to more reliably prevent the occurrence of electrode short-circuiting and sparking.

  The invention according to claim 4 can provide a wet electrostatic precipitator comprising the electrode cover device of the wet electrostatic precipitator according to any one of claims 1 to 3.

BRIEF DESCRIPTION OF THE DRAWINGS Explanatory drawing which shows the whole internal structure of the wet electric dust collector which concerns on one Example of this invention. Explanatory drawing which shows the cross-section of the wet-type electrostatic precipitator which concerns on one Example of this invention. FIG. 3 is a detailed view showing a specific example of part A in FIG. 2. FIG. 3 is a detailed view showing another specific example (a disk cylinder with fins) of part A in FIG. 2. Explanatory drawing which shows the cross-section of the wet-type electrostatic precipitator which concerns on a prior art example. FIG. 6 is a detailed view showing a specific example of part A in FIG. 5.

  The present invention provides an electrode cover that is attached to the upper part of a casing that encloses a discharge electrode and a dust collecting electrode in order to achieve the object of preventing abnormal discharge due to water wrapping around the electrode while having a simple structure. An insulating member having a hole through which the electrode fixture passes is fixed to the lower surface side of the electrode cover device, and a synthetic resin disk cylinder is fixed to the lower surface of the insulating member. Is composed of an inner cylinder through which the electrode fixture is tightly fitted and an outer cylinder having an upper surface formed integrally with the outer surface of the inner cylinder, and the upper portion of the inner cylinder is the hole portion of the insulating member. It is characterized by being configured so that a gap is not formed between the insulating member and the electrode fixture.

  According to the present invention, the glass cylinder, the PTFE disk, and the PTFE sleeve according to the conventional example are integrally formed in one PTFE disk cylinder, thereby eliminating a gap for water to enter the disk cylinder. It is possible to prevent the occurrence of abnormal discharge through the.

  Unlike the conventional structure, the present invention eliminates the gap for water to enter, thereby eliminating the variation in the quality of the seal application of the electrode cover by the operator, and the disk cylinder can be periodically replaced as a consumable item.

  Furthermore, even if water adhering to the outer peripheral surface of the disk cylinder falls to the discharge electrode side by extending the space discharge distance by integrally projecting PTFE fins on the outer peripheral surface of the PTFE disk cylinder, The risk of abnormal discharge is effectively reduced.

  Hereinafter, a preferred embodiment of the present invention will be described with reference to FIGS. In this embodiment, the present invention is applied to a detoxification device that collects contaminated particles in gas discharged in a semiconductor manufacturing process or the like with treated water.

For example, in a CVD apparatus in a semiconductor manufacturing process, a process gas such as SiH ₄ is used in a vacuum chamber for generating a Si film, and a cleaning gas such as ClF ₃ is also used. Since these gases are exhausted to the outside by a vacuum pump connected to the vacuum chamber, a detoxifying device is connected to the exhaust side of the vacuum pump.

In the abatement apparatus provided with the combustion device on the upstream side, the gas is exhausted to the outside by the vacuum pump, and therefore, the gas is combusted and decomposed in the combustion furnace of the combustion device on the exhaust side of the vacuum pump.

  As shown in FIG. 1, the exhaust gas G generated by combustion decomposition passes through a transfer tube 44 as shown in FIG. 2. As shown in FIG. 2, the exhaust gas G of the wet electrostatic precipitator in which the dust collection electrode 30 and the discharge electrode 4 are disposed is provided. It is introduced into a gas processing chamber (see reference numeral 16 in FIG. 2) in the casing 1.

  In the gas processing chamber 16, water W is sprayed from the water inlet 14 illustrated in FIG. 2 to the vicinity of the surface of the dust collection electrode 30, and the polluted particles in the exhaust gas G are collected by the sprayed water W. . In the gas processing chamber 16, the water W that has collected the contaminant particles flows into the drain tank 43 from the bottom of the gas processing chamber 16. In FIG. 1, 54 is a water circulation pump.

  In this way, the contaminated particles in the exhaust gas are removed by the wet electrostatic precipitator. This wet electrostatic precipitator includes one or a plurality of discharge parts (discharge electrodes) that charge pollutant particles in the exhaust gas, and a dust collection electrode that electrically sucks and collects the pollutant particles charged in the discharge part. Prepare.

  2 to 4 show specific configuration examples of the wet electrostatic precipitator according to the present invention. The same components as those of the conventional example shown in FIGS. 5 and 6 are denoted by the same reference numerals, and the description thereof is omitted.

  In this embodiment, an insulating glass plate 21 is provided on the lower surface side of the electrode cover 6 attached to the upper portion of the casing 1 in which the discharge electrode 4 and the dust collecting electrode 30 are provided, and the lower surface of the insulating glass plate 21 is provided. The inner and outer concentric cylinder double structure type PTFE disk cylinder 33 is fixed, and the upper part of the inner cylinder 34 through which the electrode fixture 5 is tightly fitted penetrates into the hole 26 of the insulating glass plate 21. The gist is that the gap between the insulating glass plate 21 and the electrode fixture 5 is eliminated, and in particular, water is prevented from entering the disk cylinder 33.

  FIG. 3 is a detailed view showing part A of FIG. As shown in FIG. 3, an upper bottom cylindrical disc cylinder 33 made of PTFE having high water repellency is fixed to the lower surface of the insulating glass plate 21. This disk cylinder 33 prevents water from entering the casing 1 from between the electrode fixture 5 and the insulating glass plate 21.

  The disk cylinder 33 is formed in a double structure of inner and outer concentric cylinders, and has an inner cylinder 34 having an upper and lower end opening shape at the inner center of the disk cylinder 33. In addition, the electrode fixture 5 is airtightly fitted and penetrated inside the inner cylinder 34, and therefore, water is not allowed to pass between the inner cylinder 34 and the electrode fixture.

  The upper part of the inner cylinder 34 protrudes upward from the upper surface of the disk cylinder 33, and the protruding length is set to be equal to the thickness of the insulating glass plate 21. Further, the protruding portion of the inner cylinder 34 is fitted in a hole 26 formed in the insulating glass plate 21 in an airtight manner, and therefore, from between the inner cylinder 34 and the hole 26 of the insulating glass plate 21. Is configured so that water cannot pass through.

  Further, the upper end portion of the outer cylinder 35 is integrated and connected to the outer surface intermediate portion of the inner cylinder 34, and the outer cylinder 35 is formed in an upper bottom shape. The outer cylinder 35 and the inner cylinder 34 are arranged concentrically with each other, the axial length of the outer cylinder 35 is longer than that of the inner cylinder 34, and the lower end of the outer cylinder 35 is predetermined more than the lower end of the inner cylinder 34. It is located below the dimensions.

  In the above configuration, the inner cylinder 34 through which the electrode fixture 5 passes and the periphery of the hole portion 26 of the insulating glass plate 21 are configured so that no gap for water to enter between them is formed. As a result, even when water has entered the vicinity of the bottom plate portion 11 of the electrode cover 6 and the hole portion 26 of the insulating glass plate 21, this water is prevented from entering the inside of the disk cylinder 33. Therefore, since there is no possibility that water will circulate in the vicinity of the discharge electrode 4, it is possible to prevent the occurrence of abnormal discharge through the water and to suppress the occurrence of short circuit or spark in the discharge electrode 4.

  In the present embodiment, the outer diameter of the outer cylinder 35 of the disc cylinder 33 can be set to a size equal to or greater than a predetermined value. Specifically, it can be set to a magnitude equal to or larger than a predetermined value so that water falling from the outer peripheral surface of the outer cylinder 35 descends a side point of a long distance that does not cause abnormal discharge with respect to the discharge electrode 4. .

By setting the outer diameter of the outer cylinder 35 in this way, mist-like or curtain-like water taken into the casing 1 adheres to the outer peripheral surface of the outer cylinder 35 and becomes water droplets on the discharge electrode 4 side. Even if it falls, the space discharge distance becomes long, so abnormal discharge through water droplets is suppressed. Therefore, while having a simple structure, the risk of occurrence of abnormal discharge is avoided in advance, and damage (parts including electrodes, seal members, insulating members, etc.) and functional deterioration due to abnormal discharge are prevented.

  FIG. 4 shows a configuration example different from FIG. As shown in FIG. 4, a plurality of PTFE fins (ribs) 36 are integrally formed on the outer peripheral surface of the outer cylinder 35 of the PTFE disk cylinder 33 so that the fins 36 have a predetermined interval in the vertical direction. It can also be provided.

  In this case, the projection length of the fin 36 from the outer peripheral surface of the outer cylinder 35 is such that the water falling from the projection end of the fin 36 descends at a side distance where no abnormal discharge occurs with respect to the discharge electrode 4. In addition, the size can be set to a predetermined value or more.

  As described above, when the fins 36 are formed on the outer peripheral surface of the outer cylinder 35, even if water adheres to the outer peripheral surface of the outer cylinder 35, the water is moved along the outer peripheral surface of the disk cylinder 33 by the protrusion length of the fins 36. In addition, when the water drops discontinuously as water droplets from the projecting end of the fin 36, the distance moved far from the discharge electrode 4 by the length of the projecting fin. Water descends on the side point. As a result, the risk of occurrence of abnormal discharge through water droplets is reduced.

  In the said Example, although the case where there was one discharge electrode 4 demonstrated, the discharge electrode 4 may be installed in multiple numbers.

  As described above, according to the present invention, the upper part of the inner cylinder through which the electrode fixture is tightly fitted penetrates and is fitted in the hole of the insulating member so that water is poured into the disk cylinder, unlike the conventional structure. There is no gap to enter. As a result, the occurrence of abnormal discharge through water can be prevented. Thus, it is possible to prevent the peripheral parts including the electrode, the insulating member and the seal member from being damaged due to abnormal discharge, and the functional deterioration, thereby improving the life of the parts.

  In addition, while having a simple structure in which a disk cylinder is simply fixed to the lower surface side of the insulating member, it can be easily applied to either a single or multiple discharge electrodes, thereby preventing abnormal discharge. It is possible to prevent the occurrence of electrode short-circuit and spark due to water.

  Furthermore, even if the number of discharge electrodes increases, one electrode fixture may be connected to a plurality of discharge electrodes, so the disk cylinder fixed to the lower surface of the insulating member through which the electrode fixture passes increases the number of discharge electrodes. There is no need. Therefore, it can be manufactured at a low cost without complicating the shape and structure as compared with the conventional example of the inclined plate installation type.

  In the case where a plurality of fins are provided on the outer peripheral surface of the disk cylinder so as to be separated from each other vertically, the present invention can be effectively applied to any type in which water is taken in a mist or curtain form from above or from the side of the electrode.

  For example, water adhering to the outer peripheral surface of the disk cylinder falls as discontinuous water droplets on the discharge electrode side along the outer peripheral surface, and in this case, the disk cylinder is equivalent to the protrusion length of the fin. Drops of water droplets can be achieved by increasing the distance traveled along the outer peripheral surface, and shifting and dropping to a point separated from the discharge electrode by the length of the protrusion of the fin, thereby increasing the spatial discharge distance. It is possible to more effectively reduce the risk of occurrence of abnormal discharge through the air.

  Further, when the outer diameter of the disk cylinder is set to a predetermined value or more, water drops falling from the outer peripheral surface of the disk cylinder descend at a distant point that is separated from the discharge electrode by a predetermined dimension. For this reason, it is possible to effectively prevent the occurrence of a short circuit or spark of the electrode while keeping the structure of the disk cylinder simple.

  It should be noted that the present invention can be variously modified without departing from the spirit of the present invention, and the present invention naturally extends to the modified ones.

  The present invention can also be applied to cover structures other than the electrode cover device of a wet electrostatic precipitator.

DESCRIPTION OF SYMBOLS 1 Casing 4 Discharge electrode 5 Electrode fixture 6 Electrode cover 10 Exhaust chamber 13 Upper cover part 14 Water inlet 16 Gas treatment chamber 17 Communication port 18 Exhaust port 21 Insulating glass plate (insulating member)
26 Hole portion 27 Plate portion 30 Dust collecting electrode 31 Lower bottom portion 33 Disc cylinder 34 Inner tube 35 Outer tube 36 Fin (rib)
56 Electrode cover W Water G Exhaust gas

Claims (4)

An electrode cover device attached to the upper part of the casing containing the discharge electrode and the dust collecting electrode,
An insulating member having a hole through which the electrode fixture passes is fixed to the lower surface side of the electrode cover device,
A disc cylinder made of synthetic resin is fixed to the lower surface of the insulating member, and the disc cylinder has an inner cylinder through which the electrode fixture is tightly fitted and an upper surface portion formed integrally with the outer surface of the inner cylinder. Comprising an outer cylinder having
An electrode of a wet electrostatic precipitator, wherein an upper portion of the inner cylinder is fitted in a hole of the insulating member so as not to form a gap between the insulating member and the electrode fixture. Cover device.   2. The electrode cover device for a wet electrostatic precipitator according to claim 1, wherein an appropriate number of fins are provided on the outer peripheral surface of the disk cylinder.   2. The outer diameter of the disc cylinder is set to a size equal to or greater than a predetermined value so as not to cause abnormal discharge through water falling from the outer peripheral surface of the disc cylinder. The electrode cover apparatus of the wet electric dust collector of 2.   A wet electrostatic precipitator comprising the electrode cover device for a wet electrostatic precipitator according to any one of claims 1 to 3.

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