KR20200017014A - Dust collecting electrode of wet electrostatic precipitator for removal of high viscosity material - Google Patents

Abstract

The present invention relates to a dust collecting electrode of a wet type electric dust collector, configured to, by increasing a surface temperature of a dust collecting electrode through circulation of a high-temperature fluid, reduce viscosity of non-aqueous and high viscosity materials and collect the materials thereof, wherein a wet type electric dust collector includes: a plurality of dust collecting electrodes installed at regular intervals in forward and backward directions; and discharge electrodes installed between the dust collecting electrodes. A barrier having an opened lower side is installed on an inner side of the dust collecting electrode and a water feeding space and a water discharging space are formed to be connected to each other around the barrier. A high-temperature fluid is supplied to the water feeding space and discharged through the water discharging space, wherein the fluid is configured to heat a surface of the dust collecting electrode so that viscosity of non-aqueous and high viscosity materials is reduced, and the materials thereof fall and are collected. Therefore, the present invention is configured to heat a surface of a dust collecting electrode by continuously supplying heated fluid, thereby further conveniently removing non-aqueous or high viscosity materials, and to transfer the fluid to the inside, not the outside of the dust collecting electrode, thereby minimizing contamination of the fluid, and thus, the fluid can be more conveniently recycled. In addition, the electric dust collector can be operated with minimum calories by slowing down a cooling speed of the fluid, thereby being more economical.

Description

Dust collecting electrode of wet electrostatic precipitator for removal of high viscosity material

The present invention relates to a wet electrostatic precipitator, and more particularly, a wet electric for removing high viscosity substances collected by reducing the viscosity of a non-aqueous and highly viscous material by circulating a high temperature fluid to increase the surface temperature of the dust collector. It relates to the dust collector of the dust collector.

In general, electrostatic precipitators are installed in incinerators, boiler desulfurization facilities and other fine dust and harmful gas removal facilities and are widely used to prevent air pollution. Such an electrostatic precipitator usually applies a high voltage of direct current to the discharge electrode in the high voltage generator, and the negative electrode is connected to the discharge electrode to apply a negative charge to the dust particles contained in the air passing between the discharge electrode and the collecting electrode. The dust is removed by induction adhesion toward the dust collecting pole having a relatively positive electrode property, which is largely classified into dry and wet according to a method of cleaning dust attached to the dust collecting pole.

At this time, the dry electrostatic precipitator is a method of cleaning by dropping the dust attached by applying the impact of the wrapping (rapping the dust collector with a hammer) to the dust collector. However, since the adherent or sticky dust is not easily removed from the dust collector, it causes a problem of lowering the efficiency of dust collection by lowering the electrical conductivity of the dust collector.

On the other hand, the wet electrostatic precipitator was developed to compensate for the shortcomings of the dry electrostatic precipitator. The wet electrostatic precipitator adopts a method of cleaning the surface of the dust collector by intermittent or continuous water supply. The method of forming a water film to clean the source of contamination of the dust collector (dust collecting plate) at the source is particularly useful for treating dust of resistivity or dust with strong adhesion and age hardenability.

However, the conventional wet electrostatic precipitator has a problem of gradually falling as the dust collection efficiency is not used because the dust collecting plate is not smoothly cleaned, and a plurality of spray pipes are installed on the upper portion of the dust collecting plate to increase the size of the dust collecting device. The unnecessary spark or arc discharge caused by the generated water particles make it difficult to operate continuously and the installation cost of installing the dust collecting plate is very high due to the limitation of the material of the dust collecting plate.

In order to overcome this problem, the present applicant prevents water particles from scattering during water film formation by spraying the cleaning liquid sprayed from the spray nozzle in a direction inclined at an angle with respect to the plane of the dust collecting plate in Korean Patent Publication No. 10-2014-0089722. In order to prevent unnecessary spark or arc discharge and to spread the cleaning liquid throughout the dust collecting plate, a water film forming apparatus for a wet electrostatic precipitator is formed to form a uniform water film on the surface of the dust collecting plate.

However, the above-described electrostatic precipitator has a limitation in removing high viscosity and high tacky substances such as water-insoluble oil mist and tar.

An object of the present invention is to provide a dust collecting electrode of a wet electrostatic precipitator for the removal of a high viscosity material for collecting by reducing the viscosity of a water-insoluble and high viscosity material.

In addition, another object of the present invention is to provide a dust collecting pole of a wet electrostatic precipitator for removing high viscosity materials having high recycled and economical efficiency by circulating high temperature fluid inside the dust collecting pole.

In the wet electrostatic precipitator of the wet electrostatic precipitator for the removal of high-viscosity material according to the present invention, a plurality of precipitating poles are installed at intervals before and after the discharge electrode, and a discharge electrode is installed between the precipitating poles. The open partition wall is formed, and the water supply space portion and the water extraction space portion are formed to communicate with each other around the partition wall. The technical feature is that the surface is heated to reduce the viscosity of the water-insoluble and high-viscosity material to be collected by the drop.

According to the dust collecting electrode of the wet electrostatic precipitator for removing the high viscosity material according to the present invention, the surface of the collecting electrode can be heated by the continuous supply of the heated fluid to more easily remove the non-aqueous or high viscosity material. Since the contamination of the fluid is minimized by transporting the inside of the dust collecting pole to the inside of the dust collecting pole, it is easier to recycle, and the electrostatic precipitator can be operated with a minimum amount of heat by slowing down the cooling rate of the fluid, thereby providing a more economical effect.

1 is a front view of the electrostatic precipitator installed with the dust collecting pole of the present invention,
Figure 2 is a side view of the electric dust collector is installed dust collector of the present invention,
3 is a perspective view of a dust collecting pole according to the present invention;
4 is a perspective view showing the inside of the dust collecting pole according to the present invention;
Figure 5 is a perspective view showing the flow of fluid in the collector electrode of the present invention.

Preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The dust collecting pole of the wet electrostatic precipitator for the removal of high-viscosity material according to the present invention has a plurality of dust collecting poles 100 having a square shape installed at intervals before and after, and left and right, as shown in FIGS. 1 and 2. The discharge electrode 10 supported by the upper support 11 and the lower support 12 is coupled between the dust collecting electrodes 100.

As shown in FIG. 3, the dust collecting electrode 100 is formed of a metal plate to have a predetermined thickness, and a space is formed inside the dust collecting electrode 100.

The dust collecting poles 100 connected to the front and rear are connected by a pair of transfer pipes 20 coupled to the upper side so that the inner side communicates with each other, and the lower side of the dust collecting poles 100 corresponds to the length of the transfer pipes 20. Spacing the maintenance site 30 is coupled to maintain a constant interval to install the discharge electrode (10).

A feed pipe 40 is connected to the tip of the transfer pipe 20 on one side to supply fluid to the inside of the dust collecting pole 100, and the water is discharged to recover the supplied fluid to the tip of the transfer pipe 20 on the other side. The pipe 50 is connected.

A pair of transfer holders 60 are coupled to each of the dust collecting poles 100, and the transfer holders 60 are installed inside the transfer pipe 20 so as to communicate with the inside of the dust collecting poles 100. .

Meanwhile, as shown in FIG. 4, a partition wall 70 is formed vertically inside the dust collecting pole 100, and a water supply space 71 is formed on the left side of the partition wall 70. On the right side, a water discharge space 72 is formed, and the water supply space 71 and the water discharge space 72 are configured to communicate with each other by opening the lower side of the partition wall 70.

The transfer holder 60 is installed to be connected or communicated with the inside of the transfer pipe 20, the rear end is inserted into the water supply space 71 and the water discharge space 72, respectively, the transfer holder (inserted) On the outer circumferential surface of 60, a plurality of transfer holes 61 are formed radially.

Then, the connecting pipes 21 and 31 are coupled to each other by passing through the conveying pipe 20 and the conveying holder 60 and the spacing retaining hole 30, and the front ends of the connecting pins 21 and 31, respectively. A nut is coupled and fixed to the rear end, and a plurality of dust collecting poles 100, a conveying pipe 20, and a spacing hole 30 are connected to the connecting pins 21 and 31 fixed to the dust collecting pole 100 by nuts. Supported by engagement.

The collecting electrode 100 of the wet electrostatic precipitator for the removal of the high viscosity material according to the present invention configured as described above is to remove the non-aqueous or highly viscous material collected on the surface.

That is, the heated water or oil is mainly used, and depending on the situation, it is also possible to use high temperature steam, and it is preferable to supply the fluid by recovering waste heat or by heating the hot water tank using an electric heater.

When the high-temperature fluid is supplied to each of the transfer pipes 20 through the water supply pipe 40 as shown in FIG. 5, the transfer hole 61 of the transfer holder 60 installed inside the transfer pipe 20 is opened. The fluid is transferred to the water supply space 71.

Then, the fluid in the water supply space 71 is transferred to the water outlet space 72 by the hydraulic pressure, and thus, the high temperature fluid filled in the water supply space 71 and the water outlet space 72 is applied to the dust collecting electrode 100. Substances such as non-aqueous oil mist and tar with high viscosity collected on the surface gradually decrease in viscosity and are collected by falling due to their own weight.

The fluid is transferred to the conveying pipe 20 and the outlet pipe 50 through the transfer holder 60 of the outlet space 72 by the water pressure by the continuous supply of the water supply pipe 40, and the discharged fluid is reheated. Is supplied to the water supply pipe 40, or is recycled by spraying through a nozzle installed on the upper side of the electrostatic precipitator to clean the surface of the dust collector (100).

Therefore, the present invention can more easily remove the non-aqueous or high viscosity material by heating the surface of the dust collecting electrode 100 by the continuous supply of the heated fluid, and the fluid to the inside rather than the outside of the dust collecting electrode 100 By transporting, the contamination of the fluid is minimized, so it is easier to recycle, and the electrostatic precipitator can be operated with a minimum amount of heat by slowing down the cooling rate of the fluid, which is more economical.

10: discharge electrode 11: upper support
12: lower support 20: feed pipe
21, 31: connecting pin 30: spacing
40: water supply pipe 50: water discharge pipe
60: transfer holder 61: transfer hole
70: bulkhead 71: water supply space
72: water outlet space 100: dust collecting play

Claims (5)

In the wet electrostatic precipitator having a plurality of dust collecting poles are installed at intervals before and after the discharge electrode, and a discharge electrode is installed between the dust collecting poles
A partition wall 70 having an open lower side is formed inside the dust collecting pole 100, and a water supply space 71 and a water discharge space 72 are formed to communicate with the partition 70.
The high temperature fluid is supplied to the water supply space 71 to be discharged through the water discharge space 72, and the fluid heats the surface of the dust collecting electrode 100 to reduce the viscosity of the non-aqueous and high viscosity material. A dust collecting pole of a wet electrostatic precipitator for the removal of high-viscosity material, characterized in that configured to be collected by dropping.
The method of claim 1,
The dust collecting electrode 100 is connected back and forth by a feed pipe 20 communicated with the water supply pipe 40 and the water discharge pipe 50, respectively, and the water supply space 71 and the water discharge inside the transport pipe 20. A dust collecting pole of the wet electrostatic precipitator for removing high-viscosity material, characterized in that the transfer holder 60 is connected to each of the space portion 72 to supply and discharge the fluid.
The method of claim 2,
A dust collecting pole of a wet electrostatic precipitator for removing high viscosity material, characterized in that a plurality of transfer holes 61 are radially formed on the outer circumferential surface of the transfer holder 60 to supply or discharge fluid.
The method of claim 2,
Dust collecting of the wet electrostatic precipitator for the removal of high viscosity material, characterized in that coupled to the inner side of the conveying pipe 20, the connecting pin 21 for supporting the plurality of dust collecting poles 100 through the conveying holder (60). drama.
The method of claim 1,
A lower end of the dust collecting pole 100 is coupled to the gap retaining hole 30 corresponding to the length of the conveying pipe 20, the connection pin for supporting the dust collecting pole 100 inside the gap holding (30) ( 31) is a dust collecting pole of the wet electrostatic precipitator for the removal of high-viscosity material, characterized in that combined.

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