KR20220090606A - Mist collection device for bolier waste gas treating - Google Patents

Abstract

The present invention is a boiler flue gas dust collector, and by using plasma to filter the flue gas of the boiler, an object of the present invention is to make it easy to use even in small and medium-sized enterprises.
To this end, in the present invention, a filtration chamber is configured, an intake port through which the combustion gas generated in the boiler enters one side, and the combustion gas entering the intake port is formed by the filtration action of the filtration chamber as the combustion gas enters the filtration chamber. a body including an exhaust port for exhausting clean air to the outside; a primary filtration unit configured in the filtration chamber of the body to primarily filter foreign substances of a certain size included in the combustion gas entering through the intake port; and configured on one side of the primary filtration unit to perform a filtration action to remove fine dust contained in the combustion gas as the combustion gas first filtered by the primary filtration unit is charged using plasma, It characterized in that it includes; a plasma generator to make clean air to be exhausted to the outside through the exhaust port of the main body.

Description

Boiler flue gas dust collector {Mist collection device for bolier waste gas treating}

The present invention relates to a boiler flue gas dust collector, and more particularly, to a boiler flue gas dust collector, which is configured to filter flue gas of a boiler using plasma so that it can be easily used by small and medium-sized enterprises.

In general, there is a problem of threatening human health or polluting the environment by leaking particulate matter such as corrosive oxides from a boiler or industrial equipment production process, combustion process or equipment to the outside together with exhaust gas.

In order to solve this problem, a dust collector is installed to collect and filter particulate pollutants contained in the exhaust gas discharged through the exhaust passage.

On the other hand, fine dust contained in the air exhaust gas generated during use due to the increase in demand for industrial boilers is a source of constant complaints and diseases harmful to public health due to respiratory diseases and air quality deterioration of residents in the surrounding areas. It is causing difficulties in

Accordingly, although dust collectors used in thermal power plants have been put to practical use, they cannot be used in small businesses due to their large scale and excessive operating costs.

Accordingly, there is an urgent need to develop a dust collector with excellent dust collection efficiency while minimizing the burden of maintenance cost and power consumption in industrial complexes or small and medium-sized factories concentrated in industrial complexes.

Republic of Korea Patent No. 10-2060441 (2019.12.27. Announcement)

As proposed in order to solve the above problems, an object of the present invention is to provide a boiler flue gas dust collector that can be easily used by small and medium-sized enterprises by using plasma to filter the combustion gas of the boiler. is to provide

In the present invention for achieving the above object, a filtration chamber is configured, an intake port through which the combustion gas generated in the boiler enters one side, and the filtration chamber as the combustion gas entering the intake port enters the filtration chamber a body including an exhaust port through which the clean air formed by the filtration action of the air is exhausted to the outside; a primary filtering unit configured in the filtration chamber of the main body to first filter foreign substances of a certain size included in the combustion gas entering through the intake port; and configured on one side of the primary filtration unit to perform a filtration action to remove fine dust contained in the combustion gas as the combustion gas first filtered by the primary filtration unit is charged using plasma, It characterized in that it includes; a plasma generator to be exhausted to the outside through the exhaust port of the main body so as to form clean air.

In the present invention, in the boiler flue gas dust collector, a secondary filtration unit configured in the filtration chamber of the main body to improve the cleanliness of the clean air by secondary filtering the clean air formed through the plasma generator It is preferable to further include;

In the present invention, the main body is configured between the intake port and the filtration chamber to lower the pressure of the combustion gas entering through the intake port so that the filtration efficiency is improved in the primary filtration unit configured in the filtration chamber, and the filtration chamber and It is preferable to include; a water collecting pipe configured between the exhaust ports to increase the flow rate so that the clean air exhausted through the exhaust port is quickly exhausted.

In the present invention, the filtration chamber is separated and formed in the main body by a partition wall, so that the filtration efficiency of the combustion gas of the boiler is improved, it is preferable to consist of a plurality of;

According to the present invention, by using plasma to filter the combustion gas of the boiler, there is an effect of making it easy to use even in small and medium-sized enterprises.

In addition, there is an effect of reducing operating costs by filtering the combustion gas of the boiler with low power.

1 is a configuration diagram of a boiler flue gas dust collection system according to the present invention.
Figure 2 is a front cross-sectional view of the boiler flue gas dust collector according to the present invention.
3 is a side cross-sectional view of the boiler flue gas dust collector according to the present invention.
4 is a perspective view of a plasma generator according to the present invention;
5 is a functional diagram of a plasma generator according to the present invention,
5a is a cross-sectional view, and 5b is a diagram of the electrodeposition of fine dust.
6 is a block diagram of a boiler flue gas dust collector showing another example of the present invention.

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

As shown in FIG. 1, the boiler flue gas dust collector of the present invention is configured on one side of the boiler 1, collects the flue gas generated by the operation of the boiler 1, and then filters and collects it. As a result, it performs a function of exhausting the clean air filtered by fine dust or volatile organic substances to the outside.

As shown in FIGS. 2 and 3 , the boiler flue gas dust collector includes a main body 10 , a primary filtration unit 20 , a plasma generator 30 , and a secondary filtration unit 40 . .

The main body 10 performs a function of supporting each component, that is, the primary filtration unit 20, the plasma generator 30 and the secondary filtration unit 40 to maintain a stable mounted state.

The main body 10 includes an intake port 110 through which combustion gas generated from the boiler 1 enters, and an exhaust port 120 that is configured at a position opposite to the intake port 110 and exhausts clean air.

For example, as shown in FIG. 1 , the intake port 110 is configured at the lower end of the main body 10 and the exhaust port 120 is configured at the upper end of the vertical type dust collector, and as shown in FIG. 6 , the main body It is a horizontal dust collector in which the intake port 110 is configured at the left end of (10) and the exhaust port 120 is configured at the right end, and the body 10 including the intake port 110 and the exhaust port 120 is hung from the ceiling or As a ceiling-type dust collector to be buried, the composition or structure can be freely modified according to the purpose of use or the structure of the boiler 1, the installation environment, and the needs of the user.

In addition, between the main body 10 and the intake port 110 or between the main body 10 and the exhaust port 120, air is stably moved in and out, so that the filtration efficiency of the combustion gas is improved. ) is included.

That is, the water collecting pipe 112 configured between the intake port 110 and the main body 10 lowers the pressure of the combustion gas before the combustion gas entered through the intake port 110 enters the body 10 so that the combustion gas is diffused. Induces to enter the state, and the water collecting pipe 122 configured between the main body 10 and the exhaust port 120 collects the clean air exhausted by the filtration action and induces to maintain a rapid exhaust state. Of course, the present invention is not limited thereto, and the water collecting pipes 112 and 122 may be omitted.

In addition, the main body 10 includes at least one support 130 provided to stably fix the main body 10 depending on the installation location of the main body 10 .

The support 130 is configured to perform a supporting function to stably fix the main body 10 according to the installation location, and has various configurations or structures for the purpose of use or the installation location.

On the other hand, the main body 10 is configured such that a plurality of filtration chambers 12 by the partition wall.

The filtration chamber 12 forms a space separated from the inside of the main body 10 by a partition wall, and the primary filtration unit 20, the plasma generator 30, and the secondary filtration unit 40 in the separated space. As each is installed, the filtration efficiency through the separated space is improved. Of course, the present invention is not limited thereto, and the filtration chamber 12 may be omitted depending on the purpose of use or filtration efficiency.

In addition, as shown in FIG. 3 , the main body 10 includes a blast discharge port 140 to prevent explosion due to a rise in pressure therein.

The explosion discharge port 140 has a through hole 142 configured on one side of the main body 10, a sealing cover 144 configured to open and close the through hole 142, and one end of the sealing cover 144. and a spring 146 configured.

Accordingly, the through hole 142 is normally closed by maintaining the sealing cover 144 in close contact with the body 10 by the elastic force of the spring 146 , and the inside of the body 10 is closed. When the applied pressure deviates from the elastic force of the spring 146, the pressure of the body 10 is increased by the through hole 142 that is opened as the sealing cover 144 is pushed out of the through hole 142 by the pressure. As it is dispersed, tyranny is prevented.

The primary filtration unit 20 is configured in the filtration chamber 12 of the main body 10 , and functions to filter the combustion gas entering through the intake port 110 .

The primary filtering unit 20 is preferably a pre-filter capable of filtering foreign substances of a certain size included in the combustion gas. Of course, the present invention is not limited thereto, and the primary filtering unit 20 may use any configuration or structure capable of easily filtering foreign substances contained in the combustion gas.

The plasma generator 30 is configured on one side of the primary filtration unit 20, receives the combustion gas filtered with foreign substances through the primary filtration unit 20, and fine dust contained in the combustion gas by high voltage discharge It performs the function of collecting bad particles on the back.

As shown in FIGS. 4 and 5 , the plasma generator 30 includes a body 310 , a dust collecting plate 320 , and a discharge electrode 330 .

The body 310 supports the dust collecting plate 320 and the discharge electrode 330 to be stably mounted in the filtration chamber configured in the body 10 .

In addition, the body 310 is configured with an intake hole 312 for inducing entry of the combustion gas that has passed through the primary filtering unit 20 .

In addition, one side of the body 310 is configured with a handle gripped by an operator to facilitate detachment and attachment to the body 10 .

A plurality of dust collecting plates 320 are disposed at one end of the body 310 at regular intervals, and perform a function of electrodepositing pollutants, eg, fine dust particles, charged by high voltage discharge.

The discharge electrode 330 is configured between the plurality of dust collecting plates 320 to generate a high voltage discharge, thereby inducing the fine dust included in the combustion gas to be charged.

In this case, the discharge electrode 330 constitutes an insulator at each of both ends of one side of the body 310 so that the high voltage generated by the discharge electrode 330 does not affect the body 310 .

Accordingly, in the plasma generator 30, as shown in FIG. 5b, when the combustion gas enters through the intake hole 312, it passes between the plurality of dust collecting plates 320, and at this time, the plurality of dust collecting plates 320 ), a plasma is generated by high voltage discharge in the discharge electrode 330 configured between the As they are electrodeposited on the dust collecting plate 320 , only clean air from which fine dust contained in the combustion gas is filtered passes through the plasma generator 30 .

The secondary filtration unit 40 is configured on one side of the plasma generator 30 and filters clean air from which fine dust contained in the combustion gas is filtered by the plasma generated by the plasma generator 30 by secondary filtration. , it performs the function to further improve the cleanliness.

The secondary filtration unit 40 may be any configuration capable of improving the cleanliness of the clean air that has passed through the plasma generator 30 . For example, the secondary filtration unit 40 may be a pre-filter, a HEPA filter, or an ion particle dust collector, and may be omitted in some cases.

The operating state of the boiler flue gas dust collector configured as described above is as follows.

First, the combustion gas generated by the operation of the boiler 1 enters the intake port 110 of the main body 10 configured in the boiler combustion gas dust collector.

And, the combustion gas entering the intake port 110 is induced so that the particles of the combustion gas are dispersed due to the pressure drop by the water collecting pipe 112 configured on one side of the intake port 110 .

In addition, the combustion gas dispersed due to the pressure drop enters the filtration chamber 12 configured in the main body 10 .

At this time, the filtration chamber 12 is configured in plurality in the main body 10 to separate and filter the entered combustion gas.

In addition, foreign substances having a predetermined size are filtered out of the entering combustion gas by the primary filtration unit 20 configured in the filtration chamber 12 .

That is, the pressure of the combustion gas initially entering the intake port 110 is first reduced by the water collecting pipe 112 , and the secondary pressure is lowered according to the dispersed entry by the plurality of filtration chambers 12 . As this is achieved, the filtering performance of foreign substances contained in the combustion gas is improved.

Subsequently, the combustion gas first filtered through the primary filtration unit 20 enters the plasma generator 30 , and the combustion gas that enters the plasma generator 30 is a high voltage of the plasma generated by the discharge electrode 330 . By the discharge, the fine dust contained in the combustion gas is charged, and the charged fine dust is electrodeposited on the dust collecting plate 320 , thereby forming clean air from which the fine dust contained in the combustion gas is removed.

In addition, since the clean air from which fine dust has been removed by the plasma generator 30 passes through the secondary filtration unit 40, the cleanliness of the clean air is further improved by the secondary filtration unit 40. .

Thereafter, the clean air passing through the filtration chamber 12 of the main body 10 is rapidly discharged as the flow rate is increased by the water collecting pipe 122 configured between the main body 10 and the exhaust port 120 .

On the other hand, as described above, a pressure increase may occur due to other reasons during the filtration process of the combustion gas in the filtration chamber 12 of the main body 10, and when the pressure rises in this way, the blast pressure configured on one side of the main body 10 By preventing the pressure rise above a certain level by the dissipation port 140 , damage to the main body 10 due to the pressure rise is prevented.

What has been described above is only one embodiment for implementing the boiler flue gas dust collector, and the present invention is not limited to the above embodiment. Those of ordinary skill in the art to which the present invention pertains will understand that various modifications can be made without departing from the gist of the present invention.

10: body 12: filtration chamber
110: intake port 112, 122: water collection pipe
120: exhaust port 130: support
140: Typhoon Bangsangu 142: Tonggong
144: sealing cover 146: spring
20: primary filtration unit 30: plasma generator
310: body 320: dust collecting plate
330: discharge electrode 40: secondary filtration unit

Claims (4)

A filtration chamber is configured, an intake port through which the combustion gas generated in the boiler enters one side, and as the combustion gas entering the intake port enters the filtration chamber, clean air formed by the filtration action of the filtration chamber is exhausted to the outside a main body including an exhaust port to enable it;
a primary filtration unit configured in the filtration chamber of the body to primarily filter foreign substances of a certain size included in the combustion gas entering through the intake port; and
It is configured on one side of the primary filtration unit and performs a filtration action to remove fine dust contained in the combustion gas by charging the combustion gas first filtered by the primary filtration unit using plasma, a plasma generator for forming air to be exhausted to the outside through an exhaust port of the body;
Boiler flue gas dust collector comprising a. According to claim 1, wherein the boiler flue gas dust collector,
a secondary filtration unit configured in the filtration chamber of the main body to improve the cleanliness of the clean air by secondary filtration of the clean air formed through the plasma generator;
Boiler flue gas dust collector further comprising a. According to claim 1, wherein the main body,
It is configured between the intake port and the filtration chamber, and lowers the pressure of the combustion gas entering through the intake port to improve the filtration efficiency in the primary filtration unit configured in the filtration chamber,
a water collecting pipe configured between the filtration chamber and the exhaust port to increase the flow rate so that the clean air exhausted through the exhaust port is quickly exhausted;
Boiler flue gas dust collector comprising a. According to claim 1, wherein the filtration chamber,
A plurality of separation and formation by the bulkhead on the main body, so as to improve the filtration efficiency of the combustion gas of the boiler;
Boiler flue gas dust collector, characterized in that consisting of.

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