JP2000107637A - Electric precipitator and flue gas treating device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To use an electric precipitator keeping a dust collecting function against outer swinging to contrive saving a space of a flue gas treating device. SOLUTION: Dust collecting electrodes 32 in a wet electric precipitator 20 are fixed and arranged at the upper and lower parts thereof. Discharge electrodes 34 are hung and supported through insulators on the upper surface of a casing 22 at the lower parts thereof, and also the lower parts of the discharge electrodes 34 are connected in the laminated direction and are connected to connecting rods of lower bushing chambers supported by frames provided on the side faces of the casing 22. By insulating and supporting the discharge electrodes at not only the upper parts but also the upper parts thereof, separations between the discharge electrodes 34 and the duct collecting electrodes 32 are kept. Accordingly, even if swinging occurs in the wet electric precipitator 20, the dust collecting electrodes 32 and the discharge electrodes 34 are not short-circuited to keep dust collecting function and to enable operating the precipitator. Therefore, the wet electric precipitator 20 can be assembled with a steel tower to contrive saving a space of a flue gas treating system.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electrostatic precipitator and a flue gas treatment system using the electric precipitator. The flue gas treatment system.

[0002]

2. Description of the Related Art Conventionally, a wet-type electrostatic precipitator has been used to remove dust containing mist from flue gas. FIG. 6 is an explanatory view of a conventional wet-type electrostatic precipitator. An inlet flue 3 is provided on the side surface of the casing 2 of the wet-type electrostatic precipitator 1, and an outlet flue 4 is provided on the opposite surface, and communicates with a smoke exhaust passage penetrating through the inside of the casing.

[0003] A dust collecting electrode 5 and a discharge electrode 6 are provided in a casing 2.
Are alternately arranged at predetermined intervals in parallel with the flue gas flow path. The dust collecting electrode 5 is connected to a positive electrode side of a power supply device 7 installed on the upper surface of the casing 2. The discharge electrode 6 is connected to the negative electrode side of the power supply device 7 via an insulator tube chamber 8 provided on the upper surface of the casing 2. The dust collecting electrode 5 is fixedly arranged at the upper part and the lower part. On the other hand, both ends of the discharge electrode 6 are connected to the porcelain tube chamber 8 at the upper part, are suspended and supported, and are insulated from other members.
A washing water pipe 9 for removing dust and mist collected by the dust collecting electrode 5 is provided above the dust collecting electrode 5. A hopper 10 integrated with the casing 2 is provided on the bottom surface of the casing 2.

[0004] The operation of the wet type electrostatic precipitator configured as described above is as follows. The exhaust gas flows into the wet-type electrostatic precipitator 1 from the inlet flue 3. Since a high voltage is applied by the power supply device 7 between the dust collecting electrode 5 and the discharge electrode 6 provided on the smoke exhaust channel, corona discharge is generated between the two electrodes. When the smoke passes between the two electrodes, the electrons emitted from the discharge electrode 6 adhere to dust and mist in the smoke. The negatively charged dust and mist are collected by the positively charged dust collection electrode 5. The collected dust and mist are washed off from the dust collecting electrode 6 by washing water from a washing water pipe 9 provided above the dust collecting electrode 5. Then, the dust and mist are discharged from the lower hopper 10 to the outside of the wet electrostatic precipitator 1 together with the cleaning water. Thereafter, the purified flue gas is discharged from the outlet flue 4.

FIG. 7 shows a flue gas treatment system using a conventional wet-type electrostatic precipitator. The flue gas treatment system includes a boiler 11, a desulfurization device 12, a wet electric precipitator 1, and a chimney 13, all of which are fixedly arranged on the ground. The flue gas is discharged from the boiler 11, and sulfur oxides are removed in a desulfurizer 12. Then, as described above, the dust containing mist is removed from the flue gas by the wet electric dust collector 1. Thereafter, the flue gas flows into the chimney 13 and the chimney 1
3. It was discharged outside from the upper part.

[0006]

However, as described above, since the discharge electrode of the electrostatic precipitator is only suspended and supported from the top, if the electric precipitator itself shakes, the discharge electrode is discharged. Shaking also occurs in the electrodes. Therefore, when the discharge electrode comes into contact with the dust collecting electrode, a short circuit occurs and the dust collecting function is lost. Therefore, when the electric dust collector shakes due to an earthquake or the like, the operation of the electric dust collector has to be stopped.

[0007] Conventionally, since the flue gas treatment system is arranged on the ground, a large space is required, and improvement is required from the viewpoint of cost reduction and space efficiency.
Therefore, it is conceivable to integrate the flue gas treatment system with the steel tower in the chimney.However, in the conventional electric dust collector, the dust collecting function is lost if it is disposed at a high place where the shaking is large as described above. It was hindering the realization.

An object of the present invention is to provide an electric precipitator which retains a dust collecting function even when external shaking occurs by always keeping a separation distance between a dust collecting electrode and a discharge electrode in the electric precipitator. Is to do. Further, a second object of the present invention is to make it possible to save space in a smoke exhaust treatment system by using the above-mentioned electric dust collecting device which can be arranged at a high place where shaking occurs.

[0009]

In order to achieve the above object, an electric dust collecting apparatus according to the present invention has a dust collecting electrode and a discharge electrode arranged alternately in a casing, and an upper part of the discharge electrode is insulated. By suspending and supporting the lower part of the discharge electrodes via insulators and connecting the lower parts of the discharge electrodes to a fixed member such as the casing and fixing and supporting the lower parts of the discharge electrodes via insulators, it is possible to prevent short circuit due to the swing of the lower part of the discharge electrodes and to collect It was configured to maintain the distance from the dust electrode. Further, the dust collecting electrode and the discharge electrode are alternately arranged in the casing, and the upper part of the discharge electrode is suspended and supported via an insulator, and the lower parts of the plurality of discharge electrodes are connected through a rod in the stacking direction, Insulation is fixed and supported via an insulator provided at the lower part of the casing to prevent a short circuit due to shaking of the lower part of the discharge electrode and to maintain a distance from the dust collecting electrode.

[0010] In the flue gas treatment system according to the present invention, a desulfurizer for removing sulfide in flue gas is disposed in a lower part of the chimney, and an electric precipitator is disposed above the desulfurizer. It is assumed that dust can be collected in the process of smoke rising flow, and the above-mentioned electric dust collector suspends the upper part of the discharge electrode from the upper part of the casing with an insulator, and fixes the lower part of the discharge electrode to the casing via the insulator in cooperation with each other By supporting it, it was configured to prevent contact between the discharge electrode and the dust collection electrode due to chimney shaking.

The electric precipitator is roughly classified into a wet type and a dry type, and any type may be used depending on the application. Also,
A spacer made of an insulating member may be provided below the discharge electrode to maintain a distance from the dust collection electrode.

[0012]

In the above construction, the discharge electrode is provided with an insulator between the upper and lower parts, so that the insulation state with other members is maintained. When shaking occurs in the electrostatic precipitator itself, the shaking below the discharge electrode is transmitted to a fixed member such as a casing via a connecting member below the discharge electrode. Therefore, the lower part of the discharge electrode is supported by the fixing member such as the casing. The upper part of the discharge electrode is supported by a hanging member. Therefore,
A short circuit with another member due to the swing of the discharge electrode can be prevented, and the interval between the discharge electrode and the dust collection electrode can be always maintained to exhibit the dust collection function. In addition, sulfides in the flue gas are removed by a desulfurizer arranged in the lower part of the chimney. The ascending flue gas flows into the electric precipitator disposed above the desulfurizer. As described above, the electrostatic precipitator is supported by suspending the upper part of the discharge electrode and supporting the lower part by a fixing member such as a casing via a connecting member. Therefore, the distance between the discharge electrode and the dust collecting electrode is maintained irrespective of the swing generated in the chimney, and the dust can be removed from the smoke without losing the dust collecting function.

[0013]

Embodiments of the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 is a perspective view of a wet electric precipitator according to the present embodiment. A wet electric precipitator is used to remove dust containing mist. A smoke exhaust port 24 is provided at the center of the bottom surface of the casing 22 of the wet type electrostatic precipitator 20, and a smoke exhaust port 26 is provided at the center of the upper surface of the casing 22.
Is provided, and a smoke exhaust passage passes through the inside of the casing 22 connecting the inflow port 24 and the discharge port 26. Inside the casing 22, a plurality of dust collecting electrodes 32 and a plurality of discharge electrodes 34 are alternately arranged in parallel with the smoke exhaust passage. Dust collection electrode 32
Is connected to the positive electrode side of the power supply device 30 installed near the outlet 26 on the upper surface of the casing 22. The power supply device 30 applies a high voltage of about 50,000 to 60,000 volts for generating corona discharge between the dust collecting electrode 32 and the discharge electrode 34. The discharge electrode 34 is connected to the negative electrode side of the power supply device 30, but is passed through an insulator 29 in an insulator tube chamber 28 provided on the upper surface of the casing 22 in order to maintain an insulation state with other members. .

The dust collecting electrode 32 for collecting dust and mist is
By positioning beams 44 and 46 extending in the stacking direction,
It is fixedly supported at the top and bottom. In order to maintain the insulation state between the discharge electrode 34 and another member, the upper part of the discharge electrode 34 is suspended from the insulator 29 so as to be connected to the insulator 29. In the present embodiment, the lower insulator chamber 42 including the insulator 60 is provided on the outer wall of the casing 22 facing the discharge electrode 34.
The lower part of the discharge electrode 34 is connected to the lower insulator chamber 42 to support the lower part of the discharge electrode 34 while maintaining an insulation state with other members.

That is, the dust collecting electrode 32 is provided in the casing 22.
And the discharge electrodes 34 are alternately arranged, the upper part of the discharge electrodes 34 is suspended and supported via the insulator 29 of the insulator tube chamber 28, and the lower parts of the plurality of discharge electrodes 34 are connected so that the casing 22 and the like are connected. By being fixedly supported by the fixing member via the insulator 60, a short circuit due to shaking of the lower part of the discharge electrode 34 is prevented, and the gap between the dust collecting electrode 32 is maintained.

This will be described in more detail as follows. FIG. 2 is a cross-sectional view of the wet type electrostatic precipitator in the AB direction in FIG. Inside the casing 22, a plurality of dust collecting electrodes 32 are arranged at predetermined intervals in two rows on the left and right. The upper part of the dust collecting electrode 32 is connected to the positive electrode side of the power supply device 30. Positioning beams 44 and 46 extending in the stacking direction are connected to the upper and lower portions of the dust collecting pole 32.
The beams 44 and 46 are connected to the inner wall of the casing 22 at both ends to support the dust collecting electrode 32 on the wall of the casing 22. Therefore, the swing of the dust collecting electrode 32 is
2 will be synchronized.

A discharge electrode 34 is inserted between the dust collecting electrodes 32. The discharge electrode 34 includes a rectangular frame 34a,
A plurality of discharge wires 3 delivered to the upper and lower portions of the frame 34a
4b and an auxiliary member (stay) 34c for dividing the frame 34a into two in the longitudinal direction. The upper grids 35a projecting from the upper frame of the two rows of discharge frames 34a on the left and right are connected by a connecting grid 35b projecting upward, and the lower grid 37a projecting from the lower frame is similarly connected by the connecting grid 37b projecting downward. To maintain the interval between the left and right discharge electrodes 34 in two rows.

FIG. 3 is a view of the wet type electrostatic precipitator C in FIG.
It is sectional drawing of the D direction. In order to connect the discharge electrodes 34 in each row, an upper rod 48 extending in the stacking direction connects the center of the upper grid 35a. In order to suspend and support the connected discharge electrode 34 from above, a suspension rod 50 connected to the insulator 29 of the insulator tube chamber 28 is connected to the upper rod 48. Therefore, the discharge electrode 34
In the upper part, the state of insulation from other members is maintained.

In this embodiment, in order to fix the discharge electrode 34 at the lower portion while maintaining the insulating state, the lower insulator chamber 42 communicating with the lower portion of the discharge electrode 34 is provided with the discharge electrode 34.
It is installed at the lower part of the casing 22 opposite to. In order to connect the discharge electrode 34 to the lower insulator chamber 42, a lower rod 52 extending in the stacking direction is joined at the center of the lower grid 37 a projecting from the lower part of the discharge electrode 34 and communicates with the lower insulator chamber 42. The connection rod 58 is connected.
Due to the lower rod, the discharge electrodes 34 in each row are kept at a constant interval. Then, the swing generated in the discharge electrode 34 is transmitted to the lower insulator chamber 42 by the connecting rod 58 connected to the lower rod.

The lower porcelain chamber 42 is arranged so as to protrude above the outer wall of the side surface of the casing 22 parallel to the surface of the discharge electrode 34. FIG. 4 is a sectional view of a main part of the lower insulator chamber 42. The inside of the lower insulator chamber 42 mainly includes the insulator 60 and the insulator 6.
0, a connecting rod 58 connected to the lower rod 52, and a shaft 62 connecting the connecting rod 58 and the insulator 60. The connection rod 58 penetrates the wall surface of the casing 22 and connects the lower rod 52 and the shaft 62. The shaft 62 extends upward outside the wall surface of the casing 22 and has an insulator 60 whose upper part is covered with an insulator cap 64.
Contact Accordingly, the lower rod 52 connecting the lower part of the discharge electrode 34 and the insulator 60 communicate with each other through the connection rod 58 and the shaft 62, and
Even in the lower part, the insulation state with other members can be maintained.

The surface of the lower insulator chamber 42 covers the insulator tube receiver 56 covering the connecting rod 58, the stool 65a covering the lower half of the shaft 62, the stool 65b covering the upper half of the shaft, the insulator 60 and the like. The insulator cover 68 is used. Between the stool 65a and the stool 65b, a pedestal 66 that protrudes laterally from the side surface of the casing 22 and is fixed and supported by the casing 22 is provided. The porcelain tube receiver 56 protrudes from the lower portion of the side surface of the casing 22 and has a through hole coaxial with the shaft 62 at the upper portion. The stool 65a extends above the through hole, and connects the stool 65b via the gantry 66. The stool 65b is supported by a gantry 66,
It is connected to the insulator cover 68. The insulator tube receiver 56
Are not fixedly installed on the casing 22 and
Is applied to the gantry 66 via the stools 65a and 65b. That is, the load generated in the lower insulator chamber 42 is applied to the gantry 66 fixed to the casing 22.

A cleaning device 36 is provided in the direction perpendicular to the surface of the dust collecting electrode 32 above the dust collecting electrode 32, and discharges washing water toward the dust collecting electrode 32 from above, and continuously cleans the dust collecting electrode 32 plate. Running water. An inlet distribution plate 38 is provided below each of the dust collecting electrodes 32, and a gutter 40 installed on the inner wall of the casing 22.
Contact

The operation of the wet type electrostatic precipitator constructed as described above is as follows. The discharge electrode 34 communicates with the insulator 29 in the insulator chamber 28 at the upper part, and also communicates with the insulator 60 in the lower insulator chamber 42 installed on the outer wall of the casing 22 at the lower part, to insulate the other parts. Will be retained. When the wet electric precipitator 20 shakes, the shaking of the lower part of the discharge electrode 34 is transmitted to the lower rod 52 connected to the lower grid 37a projecting from the lower part of the discharge electrode 34. The lower insulator chamber 4 is connected via the connecting rod 52 in the lower insulator chamber 42 connected to the lower rod 52.
2 is transmitted to the upper shaft 62.

The lower porcelain chamber 42 is supported by the gantry 66 which is fixed and installed so as to protrude from the wall surface of the casing 22 as described above. Therefore, the shaking generated at the lower part of the discharge electrode 34 is transmitted to the wall surface of the casing 22 via the gantry 66. Further, the swing of the upper part of the discharge electrode 34 is transmitted to the wall surface of the casing 22 by the suspension rod 50. On the other hand, the shaking generated in the dust collection electrode 32 is caused by the dust collection electrode 3
2 is transmitted to the wall surface of the casing 22 by positioning beams 44 and 46 connecting the two in the stacking direction. Therefore, since the swing of the dust collecting electrode 32 and the discharge electrode 34 are both transmitted to the wall surface of the casing 22, the separation distance between the two can be maintained. For this reason, even if the wet electric precipitator 20 itself shakes, it is possible to remove dust and mist from the exhaust gas.

The dust removal of the flue gas is performed as follows. Corona discharge occurs between the dust collecting electrode 32 connected to the positive electrode of the power supply device 30 and the discharge electrode 34 connected to the negative electrode. Dust and mist in the flue gas flowing in from the flue gas inlet 24
It collides with electrons and negative ions from 4 and becomes negatively charged. The charged dust and mist are attracted to the positively charged dust collection electrode 32 and collected by the dust collection electrode 32. The collected dust and mist are washed down by the washing device 36 on the dust collecting electrode 32. Then, the dust and mist flow into the inlet distribution plate 38 provided below the dust collecting electrode 32, and are discharged to the outside of the wet electric dust collector 20 by the gutter 40 connected to the distribution plate 38.

Further, by using the above-mentioned wet type electrostatic precipitator 20, it is possible to save the space of the smoke exhaust treatment system. FIG. 5 is an explanatory diagram of a flue gas treatment system showing an embodiment of the present invention. In the present embodiment, a desulfurization device 72 for removing sulfides is installed in a steel tower 70 for discharging flue gas to the outside.
And a wet electric precipitator 20 that collects dust and mist, and is integrated into the steel tower 70. Desulfurization device 7
Numeral 2 is disposed on the ground side in the steel tower 70 as pretreatment, and communicates with a smoke exhaust passage of a boiler (not shown). The wet electrostatic precipitator 20 having the same structure as that of the above-described apparatus is disposed above the desulfurizer 72 and supported by the steel tower 70. The desulfurizer 72 of the steel tower and the wet-type electrostatic precipitator 2
Between 0 and 0, a demister 74 is provided. A swirler 76 for forcibly exhausting exhaust gas is provided above the wet type electrostatic precipitator 20.

The smoke exhausted from a boiler (not shown)
First, the sulfide is removed by the desulfurization device 72 installed below the steel tower 70. The flue gas flows into the gas inlet 22 of the wet type electrostatic precipitator 20 provided above the desulfurizer 72. As described above, in the wet electrostatic precipitator 20 according to the present embodiment, even if the wet electric precipitator 20 itself oscillates, the separation distance between the dust collecting electrode 32 and the discharge electrode 34 is maintained and short-circuit occurs. Don't worry. Therefore, even in a high place where shaking occurs, the dust and mist in the smoke exhaust can be removed while maintaining a stable dust collecting function. The purified smoke is sucked by the swirlers 76 and discharged to the outside from the top of the steel tower 70.

In this embodiment, the tower 7 serving as a chimney
0, a desulfurization device 72 for removing sulfide in flue gas.
And the wet-type electrostatic precipitator 20 is disposed above the desulfurizer 72. In particular, since the discharge electrodes are connected to each other and supported by the casing, it is possible to collect dust in the process of the upward flow of the flue gas. I have. In addition, the electric precipitator 20
Since the distance between the dust collecting electrode 32 and the discharge electrode 34 is always maintained as described above, the contact between the dust collecting electrode 32 and the discharge electrode 34 due to the chimney swing is prevented. For this reason, it is possible to always operate the wet electric precipitator 20 even in the steel tower 70, and it is possible to save the space of the smoke exhaust treatment system. In addition, in this embodiment, although the wet type electric dust collector was used for the electric dust collector, a dry electric dust collector may be used according to the use.

[0029]

As described above, in the electric precipitator according to the present invention, since the separation distance between the precipitating electrode and the discharge electrode is maintained, even if the external shaking occurs, no short circuit occurs between the two electrodes. In addition, dust collection can be performed without stopping operation. The flue gas treatment system according to the present invention is provided with a desulfurization device for removing sulfide in flue gas at a lower part of the chimney, and an electric dust collector according to the present invention disposed above the flue gas treatment device. Smoke exhaust processing can be performed without using the apparatus, and the smoke exhaust processing system can be made compact.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram of a wet-type electrostatic precipitator according to an embodiment of the present invention.

FIG. 2 is a cross-sectional view of the wet type electrostatic precipitator according to the embodiment of the present invention.

FIG. 3 is a cross-sectional view of the wet type electrostatic precipitator according to the embodiment of the present invention.

FIG. 4 is a sectional view of a lower porcelain chamber according to the embodiment of the present invention.

FIG. 5 is an explanatory diagram of a flue gas treatment system according to the embodiment of the present invention.

FIG. 6 is an explanatory diagram of a conventional wet-type electrostatic precipitator.

FIG. 7 is an explanatory diagram of a conventional smoke exhaust treatment system.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Wet electric dust collector 2 Casing 3 Inlet flue 4 Outlet flue 5 Dust collecting electrode 6 Discharge electrode 7 Power supply device 8 Insulator tube room 9 Cleaning water pipe 10 Hopper 11 Boiler 12 Desulfurizer 13 Chimney 20 Wet electric dust collector 22 Casing 24 Smoke exhaust inlet 26 Smoke exhaust outlet 28 Insulator tube chamber 29 Insulator 30 Power supply 32 Dust collecting electrode 34 Discharge electrode 34a Discharge frame 34b Discharge line 34c Stay 35a Upper grid 35b Connection grid 36 Cleaning device 37a Lower grid 37b Connection grid 38 Inlet distribution plate 40 Gutter 42 Lower insulator chamber 44 Positioning beam 46 Positioning beam 48 Upper rod 50 Suspension rod 52 Lower rod 56 Insulator tube receiver 58 Connecting rod 60 Insulator 62 Shaft 64 Insulator cap 65a Stool 65b Stool 66 Mount 68 Insulator cover 70 Tower 72 desulfurizer 74 demister 76 swirlers

[Procedure amendment]

[Submission date] October 2, 1998 (1998.10.
2)

[Procedure amendment 1]

[Document name to be amended] Drawing

[Correction target item name] Fig. 7

[Correction method] Change

[Correction contents]

FIG. 7

 ────────────────────────────────────────────────── ─── Continuing on the front page (72) Inventor Akira Uchida 1-1-1, Uchikanda, Chiyoda-ku, Tokyo F-term (reference) in Hitachi Plant Construction Co., Ltd. 4D054 AA02 AA09 BA01 BA04 BA11 BB26 EA21

Claims (3)

[Claims] 1. A dust collecting electrode and a discharge electrode are alternately arranged in a casing, an upper part of the discharge electrode is suspended and supported via an insulator, and a lower part of a plurality of discharge electrodes is connected to connect the casing. An electric precipitator, wherein a short-circuit caused by shaking of the lower part of the discharge electrode is prevented and a space between the precipitator and a dust collecting electrode is maintained by being fixedly supported by a fixing member via an insulator. 2. A dust collecting electrode and a discharge electrode are alternately arranged in a casing, an upper part of the discharge electrode is suspended and supported via an insulator, and a lower part of the plurality of discharge electrodes is passed through a rod in a stacking direction. An electric collector which is connected and insulated and fixedly supported through an insulator provided at a lower portion of the casing to prevent a short circuit caused by shaking of the lower portion of the discharge electrode and to maintain a distance from a dust collecting electrode. Dust equipment. 3. A desulfurizer for removing sulfide in flue gas is disposed in a lower portion of the chimney, and an electric dust collector is disposed above the desulfurizer, so that dust is collected in the process of ascending flue gas. The electric precipitator is capable of discharging the dust by the chimney sway by suspending the upper part of the discharge electrode from the upper part of the casing with an insulator and making the lower part of the discharge electrode fixedly supported by the casing via the insulator in cooperation with each other. A flue gas treatment system characterized by preventing contact between an electrode and a dust collection electrode.