JP2007117983A - Moving electrode of moving electrode type electric dust-collecting device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a moving electrode of moving electrode type electric dust-collecting device capable of enlarging the length of dust-collecting electrodes and contributing simplification of device constitution and the cost reduction. <P>SOLUTION: The moving electrode 18 of the moving electrode type electric dust-collection device comprises: a pair of driving wheels 20; a pair of driven rollers 22; a pair of endless chains 24 stretched between the driving wheels and the driven rollers; and dust-collecting electrodes 26 suspended by the pair of endless chains 24, and is constituted such that the dust-collecting electrodes 26 revolvingly move around a discharging electrode, wherein a first auxiliary roller 32 and a second auxiliary roller 36 are attached respectively to a middle position of a rotation shaft 30 connecting the pair of driving wheels 20 and to a middle position of a rotation shaft 34 connecting the pair of driven rollers 22. A permanent magnet is incorporated on the outer circumference of the second auxiliary roller. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a moving electrode of a moving electrode type electrostatic precipitator, and more particularly, to a moving electrode type electric collector in which a plurality of dust collecting electrode plates suspended around an endless strip are moved around a discharge electrode. The present invention relates to a moving electrode of a dust device.

  Patent Document 1 discloses a moving electrode type electrostatic precipitator for removing dust from boiler exhaust gas from a thermal power plant and exhaust gas from various furnaces. FIG. 4 is a perspective view showing a schematic structure of a moving electrode used in this type of moving electrode type electrostatic precipitator. Between a pair of driving sprocket wheels 1 arranged at the upper part and a pair of driven rollers 2 arranged at the lower part, a pair of endless chains 3 and 3 as endless ropes are rotatably stretched. A rectangular dust collecting electrode plate 4 is attached between the pair of endless chains 3 and 3 by being connected by an intermediate portion 5 at the side edge thereof, and a plurality of dust collecting electrode plates 4, 4,... Are attached to arrange. The shaft 6 of the drive sprocket wheel 1 is rotated by a drive mechanism (not shown), and the rotation of the shaft 6 is transmitted to a pair of endless chains 3 and 3 meshing with the drive sprocket wheel 1, and a plurality of sheets forming a loop as a whole. The dust collecting plates 4, 4,... Move around a discharge electrode (not shown).

  FIG. 5 is a layout view of the lower part of the moving electrode 10, and the dust collecting electrode plate 4 suspended and lowered by the endless chain 3 makes a U-turn at the position of the driven roller 2 and starts to rise. A rotating brush 7 is arranged for each lane of the moving electrode 10 at a position sandwiching the dust collecting electrode plate 4 immediately after the ascent. A discharge electrode 8 is disposed above the rotating brush 7. While the dust collecting electrode plates 4 and 4 move vertically along the discharge electrode 8, dust in the exhaust gas is charged by corona discharge from the discharge electrode 8 and collected on the surface of each dust collection electrode plate 4. The When each dust collecting electrode plate 4 passes through the position where the rotating brush 7 is disposed, the dust adhering to the surface of the dust collecting electrode plate 4 is peeled off and removed by the rotating brush 7.

  That is, in this type of moving electrode type electrostatic precipitator, dust is collected on the surface of each dust collecting electrode plate 4 while each dust collecting plate 4 moves in the upper dust collecting space where the discharge electrode 8 exists. The dust collecting electrode plate 4 is lowered, makes a U-turn at the position of the driven roller 2, and the dust adhering to the surface of the dust collecting electrode plate 4 when it turns upward is peeled off and removed by the rotating brush 7. repeat. According to such a configuration, every time the dust collecting electrode plate 4 passes through the rotating brush 7, dust attached to the surface of the dust collecting electrode plate 4 is surely removed, and the cleanliness of the surface of the dust collecting electrode plate 4 is restored. To do. For this reason, the thickness of the dust layer collected and deposited on the surface of the dust collecting electrode plate 4 can always be kept thin.

The dust collection performance of the electric dust collector is greatly affected by the electrical resistivity of the collected dust. In particular, when the electrical resistivity of the dust is as high as 10 ¹² Ωcm or more, the reverse ionization phenomenon occurs when the thickness of the dust layer deposited on the surface of the dust collection electrode plate exceeds a certain value, and the dust collection performance sharply decreases. Since the moving electrode type electrostatic precipitator can always keep the thickness of the dust layer collected and deposited on the surface of the dust collecting electrode plate 4 as described above, the reverse ionization phenomenon hardly occurs. Therefore, this type of moving electrode type electrostatic precipitator is mainly used for exhaust gas containing high resistance dust.
JP 2001-246284 A

  In the moving electrode 10, as shown in FIG. 4, the gas to be processed including dust flows in from the direction of arrow A and passes through the moving electrode 10 in a flow parallel to the dust collecting electrode plate 4. The processing gas that has been cleaned of dust by moving electrode 10 is discharged in the direction of arrow B. The dust collection rate greatly depends on the residence time when the gas to be processed passes through the region of the moving electrode 10. If the residence time of the gas to be treated is short, the dust collection rate decreases, and if the residence time of the gas to be treated is lengthened, the dust collection rate is improved.

  When the flow rate of the gas to be processed is constant, the residence time of the gas to be processed becomes longer as the width of the moving electrode 10 indicated by the dimension L in the drawing is larger. Therefore, in order to improve the dust collection rate, the width of the moving electrode 10 (in other words, the length of the dust collection electrode plate 4) may be increased.

  However, when the width of the moving electrode 10 is increased excessively, a practical problem occurs. FIG. 6 is a schematic side view of the moving electrode 10 for explaining the problem. That is, it is necessary to reduce the weight of the dust collecting electrode plate 4 in order to reduce the cost, and it is necessary to make it as thin as possible in order to make the brush cleaning effect by the rotating brush 7 effective. Therefore, if the length of such a thin dust collecting electrode plate 4 is increased unnecessarily, the dust collecting electrode plate 4 makes a U-turn at the position of the upper drive sprocket wheel 1 or the lower driven roller 2 as shown in FIG. In this case, there is a problem that the dust collecting electrode plates 4A and 4B which are in a horizontal state are greatly bent. When the deflection becomes large, a large bending stress is generated in the electrode plate itself, and plastic deformation occurs. When this plastic deformation gradually increases, the intermediate portion 5 is also adversely affected, and the dust collecting electrode plate 4 falls off from the endless chain 3 or the meshing between the endless chain 3 and the drive sprocket wheel 1 is not aligned, leading to malfunction. At the same time, the distance from the discharge electrode changes to induce a spark.

  Therefore, in the conventional moving electrode type electrostatic precipitator, as a measure for improving the dust collection rate, the moving electrode 10 unitized as shown in FIG. 7 is moved in the previous stage along the flow direction of the gas to be processed. A configuration in which the electrode 10A and the moving electrode 10B in the subsequent stage are arranged in multiple stages has been adopted. However, such a configuration complicates the device configuration and causes an increase in cost.

  It is an object of the present invention to improve the problems of the prior art, increase the length of the dust collecting electrode plate, and simplify the device configuration and contribute to cost reduction. It is to provide an electrode.

  In order to achieve the above object, a moving electrode provided with a dust collecting electrode plate that circulates around a discharge electrode in an electrostatic precipitator, wherein the dust collecting electrode plate that circulates in a circulation path of the dust collecting electrode plate An auxiliary roller that is in rolling contact with the inner surface is provided. In this case, the auxiliary roller may be disposed at the reversal portion in the circumferential direction.

  In addition, the moving electrode of the moving electrode type electrostatic precipitator according to the present invention includes a pair of driving wheels disposed above, a pair of driven rollers disposed below, and a space between the driving wheel and the driven rollers. A pair of endless cords stretched over and a plurality of dust collecting electrode plates suspended from the pair of endless cords, wherein the plurality of dust collecting electrode plates circulate around the discharge electrode In the moving electrode of the moving electrode type electrostatic precipitator configured to move, a first auxiliary roller that suppresses the deflection of the dust collecting electrode plate being moved to an intermediate position of a rotating shaft connecting the pair of drive wheels. And a second auxiliary roller that suppresses the deflection of the dust collecting electrode plate that is moving is provided at an intermediate position of a rotating shaft that connects the pair of driven rollers. The endless striated body can be interpreted as broadly as possible and includes an endless chain and an endless wire.

  The moving electrode may have a configuration in which a permanent magnet is incorporated on the outer periphery of the second auxiliary roller. The moving electrode has an endless wire stretched between the first auxiliary roller and the second auxiliary roller, and a central portion of the plurality of dust collecting electrode plates is connected to the endless strip. Can be configured. Furthermore, the endless cord-like body may be a chain, and the drive wheel may be configured as a sprocket wheel that meshes with the chain. Alternatively, it is desirable that the endless wire has a twisted rope structure as a wire rope. Further, the first and second auxiliary rollers may be disposed at one central position of the dust collecting electrode plate. Further, at least one of the first and second auxiliary rollers may be arranged at two or more locations along the longitudinal direction of the dust collecting electrode plate.

  The first auxiliary roller and the second auxiliary roller of the present invention support the load of the dust collecting electrode plate when the dust collecting electrode plate is in a horizontal state due to the U-turn at the position of the driving wheel or the driven roller. , To suppress the bending. For this reason, according to the moving electrode of the moving electrode type electrostatic precipitator of the present embodiment, the length of the dust collecting electrode plate can be increased, which can contribute to simplification of the apparatus configuration and cost reduction.

  FIG. 1 is a schematic perspective view showing a first embodiment of a moving electrode of a moving electrode type electrostatic precipitator according to the present invention. A pair of endless chains 24, 24 as endless strips are rotatably stretched between a pair of drive wheels 20 arranged at the upper part and a pair of driven rollers 22 arranged at the lower part. A plurality of dust collecting electrode plates 26, 26,... Are suspended from the pair of endless chains 24, 24 by being locked to the suspension member 28 at intermediate positions in the width direction. In FIG. 1, for the convenience of explanation, the illustration of most of the dust collecting electrode plates 26 is omitted. Further, a chain may be used for the endless cord-like body, and a sprocket wheel that meshes with the chain may be used for the drive wheel 20.

  The pair of drive wheels 20 are connected by a rotating shaft 30. A first auxiliary roller 32 is attached to an intermediate position of the rotary shaft 30. The first auxiliary roller 32 is approximately the same diameter as the drive wheel 20. The pair of driven rollers 22 are connected by a rotating shaft 34, and a second auxiliary roller 36 is attached to an intermediate position of the rotating shaft 34. The second auxiliary roller 36 has substantially the same diameter as the driven roller 22. A permanent magnet 37 is incorporated on the outer periphery of the second auxiliary roller 36.

  A driving mechanism (not shown) is connected to one end of the rotating shaft 30, and the rotating shaft 30 is rotated by this driving mechanism, so that the driving wheels 20, 20 and the first auxiliary roller 32 rotate integrally. The rotation of the drive wheels 20, 20 is transmitted to a pair of endless chains 24, 24, and a plurality of dust collecting electrode plates 26, 26,... Forming a loop as a whole move around a discharge electrode (not shown). To do. The auxiliary roller 36 is disposed on the inner surface of the dust collecting electrode 26 that circulates, and is disposed at the reverse portion of the dust collecting electrode 26 that circulates.

  FIG. 2 is a front view showing a main configuration of a moving electrode type electrostatic precipitator including the moving electrode 18 having the above-described configuration. A plurality of discharge electrodes 38 are arranged in parallel at a predetermined interval in the dust collection space, and a plurality of moving electrodes 18 are arranged so as to surround every other discharge electrode 38. The dust collecting plate 26 suspended and lowered by the endless chain 24 makes a U-turn at the position of the driven roller 22 and starts to rise. A rotating brush 40 is arranged for each lane of the moving electrode 18 at a position sandwiching the dust collecting electrode plate 26 immediately after the ascent.

  A gas to be treated containing high-resistance dust flows in a direction perpendicular to the paper surface. While the dust collecting electrode plates 26 and 26 move in the vertical direction along the discharge electrode 38 in the dust collection space above the rotating brush 40, the dust being processed is charged by corona discharge from the discharge electrode 38, The dust is collected on the surface of each dust collecting electrode plate 26. When each dust collecting electrode plate 26 passes through the position where the rotating brush 40 is disposed, the dust attached to the surface of the dust collecting electrode plate 26 is peeled off and removed by the rotating brush 40.

  That is, in this type of moving electrode type electrostatic precipitator, dust is trapped on the surface of each dust collecting electrode plate 26 while each dust collecting electrode plate 26 moves in the upper dust collecting space where the discharge electrode 38 exists. The dust collecting electrode plate 26 is lowered, makes a U-turn at the position of the driven roller 22, and the dust adhering to the surface of the dust collecting electrode plate 26 immediately after turning upward is peeled off and removed by the rotating brush 40. repeat.

  When the dust collecting electrode plate 26 rises and makes a U-turn at the position of the drive wheel 20 and starts to descend, the dust collecting electrode plate 26A becomes horizontal as shown in FIG. For this reason, the dust collecting electrode plate 26A tends to bend. However, according to the moving electrode of the present embodiment, the first auxiliary roller 32 is present. Since the first auxiliary roller 32 rotates so as to be always in contact with the lower surface of the dust collecting electrode plate 26A and supports the load of the dust collecting electrode plate 26A, the deflection of the dust collecting electrode plate 26A is suppressed.

  Even when the dust collecting electrode plate 26 descends and makes a U-turn at the position of the driven roller 22 and starts to rise, the dust collecting electrode plate 26 becomes horizontal during the movement. For this reason, the dust collecting electrode plate 26B tends to bend. However, according to the moving electrode of the present embodiment, the second auxiliary roller 36 exists at this position, and a permanent magnet 37 is incorporated on the outer periphery of the second auxiliary roller 36. The dust collecting electrode plate 26 is made of a magnetically adherent material such as a carbon steel plate. For this reason, the central portion of the dust collecting electrode plate 26B is attracted to the outer periphery of the second auxiliary roller 36 by an appropriate magnetizing force of the permanent magnet 37, and bending is suppressed.

  However, careful consideration is required for the magnetizing force of the permanent magnet 37. If the magnetizing force is too small, a desired attracting action cannot be obtained. Also, if the magnetizing force is excessive, the moving operation when the dust collecting electrode plate 26B makes a U-turn at the position of the driven roller 22 does not proceed smoothly.

  As described above, in the moving electrode 18 of the present embodiment, the first auxiliary roller 32 has the dust collecting electrode plate 26 </ b> A disposed when the dust collecting electrode plate 26 </ b> A becomes horizontal due to the U-turn at the position of the drive wheel 20. Supports the load and suppresses its deflection. Further, the second auxiliary roller 36 attracts the dust collecting electrode plate 26B when the dust collecting electrode plate 26B is in a horizontal state due to the U-turn at the position of the driven roller 22 by a magnetic adhesion force, and suppresses the bending thereof. For this reason, according to the moving electrode 18 of the moving electrode type electrostatic precipitator of the present embodiment, the length of the dust collecting electrode plate 26 can be increased, which can contribute to simplification of the apparatus configuration and cost reduction.

  FIG. 3 is a schematic perspective view showing a second embodiment of the moving electrode of the moving electrode type electrostatic precipitator according to the present invention. 3, elements having the same reference numerals as those in FIG. 1 have the same functions as those described in the first embodiment, and a description thereof is omitted. In the moving electrode 18 </ b> A according to the second embodiment, a first auxiliary roller 42 is attached to an intermediate position of the rotating shaft 30, and a second auxiliary roller 44 is attached to an intermediate position of the rotating shaft 34. An endless wire 46 is stretched between the first auxiliary roller 42 and the second auxiliary roller 44. A wire rope can be used for the endless wire 46, and it is more preferable that the endless wire 46 has a twisted rope structure. A central portion of each dust collecting electrode plate 26 is connected to the endless wire 46 by a connecting member 48. Therefore, each dust collecting electrode plate 26 moves while being supported by the endless chains 24 and 24 by the suspension member 28 at both ends in the length direction and supported by the endless wire 46 by the connecting member 48 at the center. Therefore, even when the driving wheel 20 and the driven roller 22 are in the horizontal state due to the U-turn, the bending is suppressed and the movement is stable. For this reason, according to the moving electrode 18A of the moving electrode type electrostatic precipitator of this embodiment, the length of the dust collecting electrode plate 26 can be increased, which can contribute to simplification of the apparatus configuration and cost reduction.

  In each of the above-described embodiments, the case where the first auxiliary roller and the second auxiliary roller are arranged at one position at the position corresponding to the center of the dust collecting electrode plate 26 is shown. However, the present invention is not limited to this, and two or more first auxiliary rollers or second auxiliary rollers may be arranged at positions where the dust collecting electrode plate 26 is substantially equally divided.

It is a typical perspective view which shows 1st Embodiment of the moving electrode which concerns on this invention. It is the front view which showed the main structures of the moving electrode type electrostatic precipitator provided with the moving electrode which concerns on this invention. It is a typical perspective view which shows 2nd Embodiment of the movement electrode which concerns on this invention. It is a perspective view which shows schematic structure of the movement electrode which concerns on a prior art. It is an arrangement plan of the lower part of the movement electrode concerning a prior art. It is a model side view for demonstrating the problem of the moving electrode which concerns on a prior art. It is the perspective view which showed the example of arrangement | positioning of the moving electrode which concerns on a prior art.

Explanation of symbols

18, 18A ......... Moving electrode, 20 ......... Driving wheel, 22 ......... Driving roller, 24 ......... Endless chain, 26, 26A, 26B ......... Dust collecting electrode plate, 28 ......... Suspension member, 30 ......... Rotating shaft, 32 ......... First auxiliary roller, 34 ......... Rotating shaft, 36 ......... Second auxiliary roller, 37 ......... Permanent magnet, 38 ......... Discharge electrode, 40 ... ...... Rotating brush 42... First auxiliary roller 44... Second auxiliary roller 46... Endless wire 48.

Claims (9)

  A moving electrode provided with a dust collecting electrode plate that circulates around a discharge electrode in an electric dust collector, and an auxiliary roller that is in rolling contact with the inner surface of the dust collecting electrode plate that circulates in a circulation path of the dust collecting electrode plate A moving electrode of a moving electrode type electrostatic precipitator characterized by being provided.   The moving electrode of the moving electrode type electrostatic precipitator according to claim 1, wherein the auxiliary roller is disposed in a reversing portion in a circumferential direction.   A pair of driving wheels disposed above, a pair of driven rollers disposed below, a pair of endless cords stretched between the driving wheel and the driven rollers, and the pair of endless cords In the moving electrode of the moving electrode type electrostatic precipitator having a plurality of dust collecting electrode plates suspended on the body, wherein the plurality of dust collecting electrode plates are moved around the discharge electrode, A first auxiliary roller that suppresses the deflection of the dust collecting electrode plate that is moving is provided at an intermediate position of the rotating shaft that connects the pair of drive wheels, and is provided at an intermediate position of the rotating shaft that connects the pair of driven rollers. A moving electrode of a moving electrode type electrostatic precipitator, wherein a second auxiliary roller for suppressing the bending of the moving dust collecting electrode plate is attached.   The moving electrode of the moving electrode type electrostatic precipitator according to claim 3, wherein a permanent magnet is incorporated on an outer periphery of the second auxiliary roller.   The endless wire is stretched between the first auxiliary roller and the second auxiliary roller, and the central portions of the plurality of dust collecting electrode plates are respectively connected to the endless strips. 4. A moving electrode of the moving electrode type electrostatic precipitator according to 3.   The moving electrode of the moving electrode type electrostatic precipitator according to claim 3, wherein the endless cord-like body is a chain, and the drive wheel is a sprocket wheel meshing with the chain.   The moving electrode of the moving electrode type electrostatic precipitator according to claim 3, wherein the endless wire is a wire rope.   The moving electrode of the moving electrode type electrostatic precipitator according to claim 3, wherein the first and second auxiliary rollers are disposed at one central position of the dust collecting electrode plate.   The moving electrode type electrostatic precipitator according to claim 3, wherein at least one of the first and second auxiliary rollers is arranged at two or more locations along a longitudinal direction of the dust collecting electrode plate. Moving electrode.

Images