KR20180047303A - Dust collecting equipment - Google Patents

Abstract

The present invention relates to dust collecting equipment, which includes: a housing having an inlet on one side and an exhaust port on the other side; and a control member located inside the housing and extending the movement distance of gas. The dust collecting equipment of the present invention can effectively separate and remove dust from dust-containing gas.

Description

Dust collecting equipment

The present invention relates to a dust collecting apparatus, and more particularly, to a dust collecting apparatus capable of efficiently separating and removing dust contained in a gas.

Generally, dust collecting facilities are pollution prevention facilities that can collect dusts generated during operation and improve air pollution prevention and work environment. For example, coal used as a fuel in the blast furnace operation of a steel mill is produced as coke by combustion in a coke oven. A large amount of coke dust is generated in the process of producing, discharging and transporting the coke produced in the coke producing process. In addition, a large amount of dust is also generated in a temper rolling process in which a cold rolled plate is passed through a plurality of rolls in order to impart appropriate mechanical properties to cold rolled products. Therefore, a dust collecting facility for treating dust can be provided at the operating place where dust is generated to collect the dust.

The dust collecting facility sucks the dust-containing gas from the dust generating place to the dust collecting hood by the attracting pressure of the suction fan, and the dust-containing gas sucked into the dust collecting hood is separated into gas and dust while passing through the filter chamber. The filtered gas is discharged to the atmosphere through the stack through a clean room and an exhaust pipe communicating with the filter chamber, and the separated dust is stored in a reservoir storing the dust and is periodically discharged.

The dust collecting facility can be operated by various methods such as electrolysis, dry and wet method. Among the dust collecting facilities operated by the wet method, the dust containing gas is passed through the collection water in the dust collecting facility to separate the dust from the dust containing gas, Can be removed.

In the case of a dust collecting apparatus operated in a wet manner, the collected water is contained in the filter chamber and the clean room provided therein, and the dust contained in the gas is separated while the dust-containing gas passes through the collected water contained in the filter chamber and the clean room. The separated gas is discharged to the outside through the clean room, and the separated dust is stored in the sludge state in the reservoir communicating with the filter room and the clean room. At this time, as the dust-containing gas moves from the filter chamber to the clean room, large air bubbles are generated in the clean room. However, as the air bubbles burst, the dust collected in the air bubbles is scattered and flows out into the atmosphere through the clean room, which can pollute the environment.

KR1282328B KR1998-0006800U

The present invention provides a dust collecting apparatus capable of effectively collecting dust.

The present invention provides a dust collecting facility capable of preventing or preventing environmental pollution by blocking the outflow of pollutants.

A dust collecting apparatus according to an embodiment of the present invention includes: a housing having an inlet formed on one side and an outlet formed on the other side; And control means provided inside the housing, for extending the moving distance of the gas.

A filter chamber provided inside the housing to communicate with the inlet; A clean room provided on at least one side of the filter chamber to communicate with the exhaust port; A reservoir provided at a lower portion of the housing to communicate with the housing, the filter chamber, and the clean room; And a collection water supply means capable of supplying collected water to the housing, wherein the control member can be provided between the filtration chamber and the clean room.

The control member may have a flow path formed therein so that the gas and the trapped water can move, and the length of the flow path may be longer than the linear length of the control member.

The control member may include a hollow formed in a hollow shape in which both sides thereof are open, and a thread and a groove alternately formed on the inner wall.

The control member is formed in a hollow shape in which both sides are opened, and may be formed in a coil shape.

The control member comprises: Through holes may be formed in a direction crossing the direction in which the gas and the trapped water move.

And a spraying means for spraying the collected water to form a collecting water screen in a direction crossing the moving direction of the gas to the clean room.

The dust collecting apparatus according to the embodiment of the present invention can efficiently separate and remove dust from the dust containing gas. That is, a bubble generating member may be provided between the filtration chamber and the clean chamber of the dust collecting facility to generate a large amount of minute bubbles when the dust-containing gas moves from the filter chamber to the clean room. As a result, the contact area between the dust-containing gas and the trapped water is increased, and dust is trapped by the minute bubbles, thereby effectively separating and removing dust.

Further, the gas moving speed from the filter chamber to the clean room is delayed by the bubble generating means to increase the contact time between the trapped water and the dust-containing gas, thereby increasing the dust separation efficiency from the dust-containing gas.

In addition, it is possible to form dust collecting screens on the path through which the dust-removed gas moves, and dusts that have not been removed can be removed, thereby preventing or preventing the outflow of dust to the outside.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view of a dust collecting apparatus according to an embodiment of the present invention; FIG.
2 is a view showing an internal structure of a dust collecting apparatus according to an embodiment of the present invention;
3 is a view showing various examples of control members provided between a filter chamber and a clean room;
4 is a view showing a modification of the dust collecting apparatus according to a modification of the present invention.
5 is a view showing a state in which dust containing gas is treated using a dust collecting apparatus according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be embodied in various different forms, and it is to be understood that these embodiments are merely illustrative of the principles of the invention and are not intended to limit the scope of the invention to those skilled in the art. It is provided to let you know completely.

FIG. 1 is a view showing a schematic configuration of a dust collecting apparatus according to an embodiment of the present invention, FIG. 2 is an internal structure of a dust collecting apparatus according to an embodiment of the present invention, FIG. FIG. 4 is a view showing a modification of the dust collecting apparatus according to a modification of the present invention. FIG.

Before describing the present invention, the overall structure of the dust collecting apparatus will be described.

1, the dust collecting apparatus includes a collecting unit 100 for sucking the dust-containing gas from the dust generating site to the dust collecting hood 110 and the inlet duct 120 by the suction pressure of the suction fan 320, A filtering unit 200 for filtering the dust-containing gas into gas and dust, and an exhaust unit 300 for discharging the filtered gas to the atmosphere. The dust collected in the filtration unit 200 can be collected in the storage unit 400 provided below the filtration unit 200.

The dust collecting hood 110 may be installed in a dust generating place, for example, a facility for transporting a raw material used in a blast furnace or a facility for producing coke. The dust collecting hood 110 is connected to the filtration unit 200 through the inlet duct 120 and sucks the dust containing gas by the suction pressure of the suction fan 320 provided in the exhaust unit 300, . The dust-removed gas in the filtration unit 200 is discharged to the atmosphere through the stack 330 via the discharge pipe 310 connecting the filtration unit 200 and the discharge unit 300.

The filtration unit 200 has an inlet 212 through which the dust-containing gas transferred through the inlet duct 120 is formed and a drain 214 through which the dust-removed gas is discharged. . A reservoir 250 may be provided in the lower portion of the housing 210 to communicate with the interior of the housing 210 and store dust separated from the dust-containing gas therein.

The housing 210 is provided therein with a filter chamber 220 for removing dust from the dust-containing gas introduced from the inlet port 212 and at least one side of the filter chamber 220 in communication with the filter chamber 220, And a clean room 230 through which the removed gas is discharged. The inner space of the filter chamber 220 and the clean room 230 is communicated with the reservoir 250 so that the dust removed from the inside can be deposited into the reservoir 250.

The clean room 230 is provided to communicate with the exhaust port 214 to discharge the dust-removed gas to the outside through the exhaust unit 300.

The filtration unit 200 can use a wet system in which dust is passed through the collected water to separate the dust. The filtration unit 200 may include trapped water supply means 260 for supplying trapped water to the inside of the housing 210.

The collection water supply means 260 may include a collection water tank (not shown) for storing collected water and an injection nozzle 262 for supplying the collected water stored in the collection water tank into the housing 210. At this time, the collection water supply means 260 may include a drain 264 for discharging the collected water so that the collected water maintains a certain height inside the housing 210.

The drain 264 may be provided in the housing 210 to discharge the collected water inside the housing 210 to the outside and may include at least dust containing gas formed between the filter chamber 220 and the clean chamber 230, Is preferably formed at a position higher than the movement path of the water.

As described above, the filter chamber 220, the clean room 230, and the reservoir 250 may be configured to communicate with the inner space of the housing 210. Therefore, when the collected water is supplied to the inside of the housing 210, the collected water is filled in the reservoir 250 provided in the lower part of the housing 210, and the filtered water in the filter chamber 220 and the clean room 230 and the housing 210 can be filled up to a height of a predetermined height, that is, to a height at which the drain 264 is formed.

The filtration unit 200 may allow the dust-containing gas flowing into the filter chamber 220 to pass through the trapped water and be discharged into the clean room 230. The dust-containing gas is separated into gas and dust while passing through the trapped water. The separated dust is introduced into the reservoir 250 in the lower portion of the filter chamber 220 and precipitated. The gas is discharged to the discharge port 214 through the clean room 230, Lt; / RTI > At this time, the dust separated from the entire region where the collection water formed to extend to the housing 210 outside the clean room 230 and the clean room 230 can be introduced into the reservoir 250.

Meanwhile, while the dust-containing gas passes through the filter chamber 220, some of the dust-containing gas may be introduced into the clean room 230 without dust separated. Accordingly, in order to effectively separate the dust while the dust-containing gas is moving from the filter chamber 220 to the clean room 230, that is, while passing the collection water, the dust- And a control member 240 for controlling the movement distance of the water.

The control member 240 can be disposed over the filter chamber 220 and the clean room 230 and can extend the travel distance of the dust-containing gas and the collected water. That is, the linear distance of the control member 240 may be shorter than the distance that the dust-containing gas and the trapped water move. In other words, the length of the flow path formed inside the control member 240 may be longer than the straight length of the control member 240. The control member 240 may be formed in various forms to extend the travel distance of the dust-containing gas and the collected water.

3 (a), the control member 240 may be formed in a hollow cylindrical shape with both open sides, and on the inner wall thereof, a thread having alternately formed valleys and grooves in the longitudinal direction of the control member 240 . Thus, the dust-containing gas and the collected water may move along the threads in the control member 240 and move from the filter chamber 220 to the clean room 230. When the dust-containing gas and the collected water pass through the control member 240 while rotating, the time for which the dust-containing gas comes into contact with the collected water increases, and the dust contained in the gas can be easily trapped by the trapped water.

Referring to FIG. 3 (b), the control member 240 may be formed in a coil shape. This shape is a structure that can increase the length of the control member 240 itself in a relatively narrow space and can increase the contact distance between the dust containing gas and the collected water by increasing the travel distance of the dust containing gas and the collected water.

Referring to FIG. 3 (c), the control member 240 may be provided with a through-hole in a direction crossing the movement direction of the dust-containing gas and the collected water. In this case, the moving distance of the dust-containing gas and the trapped water is increased, and the dust-containing gas and the trapped water move along the control member 240 while a part of the dust-containing gas and the trapped water are discharged into the through- . As a result, the contact area between the dust-containing gas and the collected water is increased, so that dust in the dust-containing gas can be easily trapped by the bubbles.

Through the above-described structure, the contact time and the contact area between the dust-containing gas and the collected water increase in the dust-containing gas through the filter chamber 220 and the clean chamber 230, thereby effectively removing dust from the dust-containing gas.

The separated gas may be introduced into the clean room 230 and discharged to the stack 330 through the exhaust port 214. At this time, the clean room 230 is provided with a control member 240 at a position opposite to the control member 240, that is, in a direction in which the dust-containing gas and the collected water are discharged from the control member 240 so as to prevent dust from scattering A blocking plate 232 may be provided. The blocking plate 232 may be provided to face the control member 240 and may be inclined upward toward the control member 240 so that the collected water or dust may flow into the trapping water again when the blocking plate 232 collides. .

In addition, the dust-containing gas that has not been removed from dust among the gases introduced into the clean room 230 may be included.

As shown in FIG. 4, an additional spraying unit 270 for spraying the collected water into the clean room 230 may be provided to spray the collected water in a direction crossing the direction in which the gas moves in the clean room 230 have.

The spraying means 270 may include a nozzle or the like capable of spraying collected water. With this configuration, the collected water can be sprayed on the clean room 230 across the clean room 230 to form a captured water screen.

Thus, the gas passing through the filter chamber 220 moves along the clean room 230 and passes through the collection water screen. The gas is brought into contact with the captured water while passing through the trapped water screen, and the dust contained in the gas can be trapped by the trapped water and can be introduced into the trapped water accommodated in the lower portion of the clean room 230. The gas may thus be vented to the stack 330 via the exhaust port 214 with the dust minimized or completely removed.

Meanwhile, the dust separated by the trapped water in the filter chamber 220 and the clean chamber 230 is trapped in the trapped water and settled in the reservoir 250. The separated dust is stored in the reservoir 250 for a predetermined period of time, and then the valve 252, for example, the rotary valve provided in the reservoir 250 can be opened and discharged to the outside. At this time, a reservoir or the like for storing dust in a sludge state may be connected to the reservoir 250.

Hereinafter, a method of treating the dust-containing gas using the above-described dust collection equipment will be described.

FIG. 5 is a view showing a state in which dust containing gas is treated using a dust collecting apparatus according to an embodiment of the present invention, and a method of treating dust containing gas in connection with FIG. 1 will be described.

First, the dust-containing gas generated at the dust generating location is sucked into the dust collecting hood 110 by the attracting pressure of the suction fan 320 and is introduced into the filtering unit 200 through the inlet duct 120.

The dust-containing gas flowing into the filter chamber 220 of the filtration unit 200 passes through the trapped water accommodated in the filter chamber 220 and moves to the clean chamber 230. At this time, the dust-containing gas moves to the clean room 230 while passing through the control member 240 provided between the filter chamber 220 and the clean chamber 230.

At this time, the dust-containing gas and the collected water travel along the inside of the control member 240, and the traveling speed is delayed, so that the contact time is increased. The dust contained in the gas is mostly trapped in the trapped water, and when it reaches the clean room 230, it is settled by the self weight and deposited in the reservoir 250.

On the other hand, when the dust-containing gas and the trapped water pass through the control member 240 shown in FIG. 3 (c), some of the dust-containing gas and the trapped water escape into the through- . Dust that has not yet been removed while passing through the filter chamber 220 and the control member 240 can be collected by the bubbles. Since the bubbles generated are very small in size, they are blown up mainly in the vicinity of the capture water bath, so that dust can not be scattered but can be introduced into the capture water by its own weight.

In addition, the dust-removed gas can pass through the collecting water screen formed in the clean room 230 while moving to the exhaust port 214 along the clean room 230. Accordingly, dust can be further removed from the gas moving along the clean room 230, so that clean gas from which most of the dust is removed can be discharged through the exhaust port 214.

Although the present invention has been described in connection with certain exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Therefore, the scope of the present invention should not be limited by the described embodiments, but should be defined by the appended claims and equivalents thereof.

100: collecting part 200: filtration part
210: housing 220:
230: clean room 240: control member
250: reservoir 260: collection water supply means
270: injection means

Claims (7)

A housing having an inlet formed at one side thereof and an exhaust port formed at the other side thereof; And
And control means provided in the housing for extending the travel distance of the gas. The method according to claim 1,
A filter chamber provided inside the housing to communicate with the inlet;
A clean room provided on at least one side of the filter chamber to communicate with the exhaust port;
A reservoir provided at a lower portion of the housing to communicate with the housing, the filter chamber, and the clean room; And
And collecting water supply means capable of supplying collected water to the housing
Wherein the control member is provided between the filtration chamber and the clean chamber. The method of claim 2,
Wherein the control member comprises:
Wherein a flow path is formed therein so that the gas and the trapped water can move,
Wherein the length of the flow path is longer than the linear length of the control member. The method of claim 3,
Wherein the control member comprises:
And a thread formed on the inner wall alternately with a valley and a groove. The method of claim 4,
Wherein the control member comprises:
And is formed in a coil shape. The method according to claim 4 or 5,
The control member comprises:
And a through-hole is formed in a direction crossing the direction in which the gas and the trapped water move. The method of claim 6,
And a jetting means for jetting the collected water to form a collecting water screen in a direction crossing the moving direction of the gas to the clean room.

Images