KR101122672B1 - Dust removing and cooling apparatus - Google Patents

Abstract

PURPOSE: A cooling and dust removing apparatus is provided to improve the filtering and collecting efficiency of contaminants by increasing contact time of gas and liquid. CONSTITUTION: A cooling and dust removing apparatus comprises a body(200), a suction unit(300), and an atomizing mechanism(400). The body has first and second storage spaces(210,220), a suction port(201), and an exhaust port(202). Water flowing from a water supply unit(100) is stored in the first storage space. The suction port and the exhaust port are connected to the first and second storage spaces, respectively. The suction unit generates suction force to generate the internal pressure difference between the first and second storage spaces. The atomizing mechanism sends water from the first storage space to the second storage space and injects gas from the first storage space to the second storage space.

Description

Dust removing and cooling apparatus

The present invention relates to a cooling dedusting apparatus, and more particularly, to a cooling dedusting apparatus capable of supplying harmful gas discharged from an incinerator, an industrial boiler, a melting furnace, a melting furnace, etc., into a water in a bubble state, and cooling and dedusting.

Incinerators, industrial boilers, various furnaces, melting furnaces, etc., which use or burn various fuels, waste oils and various wastes, which are environmental pollutants, are used as incinerators, incinerators, melting furnaces, etc. Various dusts are to be emitted, and air pollution is also considerable due to this.

Therefore, in order to prevent such air pollution, air pollution prevention environmental facilities are installed to filter and collect various fumes and dust harmful gases generated during combustion, incineration, melting, and melting.

However, these existing air pollution environmental facilities can filter out relatively large dust, but it is virtually impossible to collect various gaseous harmful gases, including rather small particulates, and especially high temperature impregnated harmful gases. Not only dust is generated, but also harmful gases or odors are generated at the same time, so that the configuration of the environmental equipment is complicated and diversified in order to prevent them all, there is a problem in management.

In order to solve this problem, the cooling and dedusting apparatus described in Korean Patent No. 885993 is to supply gas discharged from an incinerator, an industrial boiler, various melting furnaces and a melting furnace in the form of bubbles in the liquid to allow the gas to be cooled and dedusted. It has a structure.

However, the conventional cooling dedusting apparatus has a problem that the flow of the fine gas droplets is not smooth in the collision plate that the gas collides to form the fine gas droplets, thereby lowering the performance and efficiency of the cooling dedusting apparatus.

The present invention is to provide a cooling dedusting device that can improve the cooling dedusting performance and efficiency by inducing the flow of fine gas droplets collided by the impingement plate to flow in a predetermined direction to smooth the flow of the gas droplets. The purpose.

The present invention is provided with a first storage space for storing the water flowing from the water supply unit, and a second storage space communicating with the first storage space, respectively, the upper inlet gas contaminated in communication with the first storage space A body into which a suction port into which the gas is introduced and an exhaust port communicating with the second storage space are formed, respectively, is connected to the exhaust port to generate a suction force, and internal pressures of the first storage space and the second storage space are generated through the suction force. Suction means for generating a difference so that the water in the first storage space is introduced into the second storage space and ascended, provided inside the second storage space to communicate the first storage space and the second storage space. By the suction force, the water in the first storage space is introduced into the second storage space, and the inlet gas in the first storage space into the second storage space. And an atomizing mechanism for injecting fine droplets into the water in the second storage space, wherein the atomizing mechanism comprises: an inlet portion through which the water and the inflow gas of the first storage space flow; An outflow part through which the water introduced through the inflow part and the inflow gas flows out into the second storage space is formed, and a cross-sectional area of the outflow part is smaller than the inflow part of the inflow part so that the outflow speed is faster than the inflow speed; And a colliding portion having a flow guide means which is spaced apart from the upper portion of the nozzle portion so that the inflowing gas collides with a lower surface to form the fine gas droplets, and guides the gas droplets to spread in a predetermined direction. It provides a cooling dedusting device comprising.

Therefore, the cooling dedusting apparatus according to the present invention provides the following effects.

First, by inducing the flow of the fine gas droplets collided in the impact portion to flow in a predetermined direction, it is possible to improve the performance and efficiency of the cooling dedusting apparatus by smoothing the flow flow.

Second, by increasing the contact time between the gas and the liquid to increase the filtration and collection efficiency of the pollutants contained in the gas it can improve the cooling dust removal efficiency accordingly.

1 is a view schematically showing a configuration of a cooling dedusting apparatus according to an embodiment of the present invention.
FIG. 2 is a cross-sectional perspective view showing the atomizing mechanism of FIG. 1.
FIG. 3 is a cross-sectional front view illustrating the flow of fine gas bubbles in the collision part of FIG. 2.
4 is a view illustrating a bottom surface of the collision part of FIG. 2.
5 is a perspective view illustrating a second embodiment of the collision part of FIG. 2.
6 is a front view illustrating a third embodiment of the collision part of FIG. 2.
FIG. 7 is a front view illustrating a case in which the collision part of FIG. 2 is disposed in multiple stages.
8 is a schematic perspective view of the hydraulic damping mechanism of FIG.

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

First, referring to FIG. 1, the cooling dedusting apparatus 800 according to the exemplary embodiment of the present invention includes a body 200, a suction means 300, and an atomizing mechanism 400.

The body 200 is provided with a first storage space 210, in which water flowing from the water supply unit 100 is stored, and a second storage space 220 communicating with the first storage space 210, respectively. In an upper portion, an inlet 201 through which the contaminated inflow gas flows in communication with the first storage space 210 and an exhaust port 202 communicating with the second storage space 220 are formed, respectively. Here, reference numeral 110 denotes a control valve which is connected to the water supply unit 100 to adjust the flow rate of the water supplied. In the drawings, the solid line represents the flow of water and the dotted line represents the flow of gas.

The suction means 300 is connected to the exhaust port 202 to generate a suction force, and generates a pressure difference between the first storage space 210 and the second storage space 220 through the suction force. Water in the first storage space 210 is introduced into the second storage space 220 and serves to rise. A blower fan coupled to the driving motor may be applied to the suction means 300.

The atomizing mechanism 400 is provided in the second storage space 220 to communicate the first storage space 210 and the second storage space 220, the first by the suction force Water in the storage space 210 is introduced into the second storage space 220. In addition, the atomizing mechanism 400, by introducing the inlet gas in the first storage space 210 into the second storage space 220 and sprayed with a fine gas droplet in the water in the second storage space 220. Play a role. Detailed description of the atomizing mechanism 400 will be described later.

Meanwhile, a water tank 510, a first water flow plate 520, a mixing cylinder 530, and second water flow plates 540 and 550 are provided in the first storage space 210.

The water tank 510 may be provided in the first storage space 210, and may open at an upper portion thereof to store water supplied from the water supply unit 100.

The first water flow plate 520 is disposed to be spaced apart from the lower portion of the water tank 510, and the water flowing in from the water tank 510 and the inflow gas flows into the venturi shape gradually narrowing toward the lower portion. A first discharge port 521 is formed to increase the flow rates of the inflowing water and the inflow gas and to discharge the inflow gas contaminated with the water at the bottom thereof.

The mixing cylinder 530 is disposed to be spaced apart from the lower portion of the first discharge port 521, forcing the water discharged through the first discharge port 521 and the contaminated inlet gas to vortex the inside. Mixing is made to force the contact of the water with the inlet gas.

The second water flow plates 540 and 550 are arranged to be spaced apart from the lower portion of the mixing cylinder 530 and gradually become narrower toward the bottom thereof, and second outlets 541 and 551 are formed at the bottom thereof. Here, the second water flow plates 540 and 550 may be arranged in multiple stages according to design.

On the other hand, the cooling dedusting apparatus 800 is provided under each of the first storage space 210 and the second storage space 220, the first storage space 210 and the second storage space 220. And one or more communication tubes 610 communicating with each other so that the water in the first storage space 210 and the water in the second storage space 220 communicate with each other, and are provided on the communication tube 610. It includes a flow rate control valve 620 to regulate the communication of the water or to control the communication degree.

In addition, the cooling dedusting apparatus 800, the sludge discharge pipe 632 for discharging the sludge in the lower portion of the first storage space 210 and the second storage space 220, the sludge discharge pipe 632 ) May be provided with a discharge valve (634).

Referring to FIG. 2, the atomizing mechanism 400 will be described in detail. The atomizing mechanism 400 includes a nozzle part 410 and a collision part 420.

The nozzle unit 410 may include an inlet 411 through which the water and the inlet gas flow into the first storage space 210, and the water and the inflow gas introduced through the inlet 411. Outlets 412 are formed to allow the second storage space 220 to flow upward. Here, the nozzle 410, the passage cross-sectional area of the outlet 412 is formed smaller than the passage cross-sectional area of the inlet 411 so that the passage cross-sectional area is gradually narrowed to make the outflow speed faster than the inlet speed.

The impingement part 420 is located at an upper portion of the outlet part 412 in the nozzle part 410, and the outflowing gas collides with the lower surface 421 to be formed as the fine gas bubbles. .

Here, the collision part 420 is formed long in the front-rear direction, and the outer frame (not shown) coupled to the front and rear, respectively, so that the position is fixed in the second storage space 220, the body 200 C), or the front and rear may be extended so that its position can be fixed by directly coupling to the inner surface of the body 200. In addition, the collision portion 420, as shown in Figure 3, the front and rear of the body 200 is coupled to the frame 440 coupled with the nozzle unit 410, respectively, the position is to be fixed In addition to these embodiments, various embodiments may be possible if the location of the collision unit 420 may be fixed in the second storage space 220.

On the other hand, since the atomizing mechanism 400 has a structure in which the front and the rear of the impact portion 420 are blocked as described above, the gas droplets exit the front and rear of the impact portion 420. If you do not do this, you will get a stagnation. In this case, the gas bubbles are agglomerated with each other to form large gas bubbles, and when such large gas bubbles are formed, the contact area with water is reduced by that amount, and consequently, the cooling dust removal performance is reduced.

Accordingly, the collision part 420 has a flow guide means 430 which guides the gas bubbles to spread in a predetermined direction so as to prevent the gas bubbles from stagnation on the lower surface 421.

Referring to FIG. 4, the flow guide means 430 is formed along the left and right directions of the collision part 420 so that the gas bubbles spread in both directions of the collision part 420. The lower surface 421 of the 420 is composed of a plurality of guide grooves 432 spaced apart from each other.

Here, the guide groove 432 may be formed in the shape of a curved groove to further refine the inlet gas collided to promote the formation of the fine gas droplets, the fine gas bubbles are guide groove 432 Follow the guide to flow in the left and right directions of the impact portion 420.

Referring to FIG. 5, the collision part 420b may include a plurality of guide protrusions 434 formed on the bottom surface of the collision part 420 so that the flow guide means 430 is different from the groove shape. It is. The guide protrusions 434 are formed to protrude along the left and right directions on the lower surface of the collision part 420 to improve the refinement of the inflow gas, and the gas bubbles collide with the grooves formed between adjacent protrusions. Induced to flow in the left and right direction of the portion 420. Here, the guide grooves 432 and the guide protrusions 434 may be variously changed in depth (protrusion degree) and shape of the guide grooves 432 according to the design such as the degree of miniaturization of the inlet gas.

As described above, the impingement portion, by forming the flow guide means to smoothly escape the gas bubbles to the left and right sides, to prevent the gas droplets stagnation and to block the re-agglomeration due to stagnation of water Increasing the contact area with the can improve the collection performance of harmful substances.

On the other hand, the collision part 420 has a shape in which the lower surface 421 is convex in the upward direction in order to induce the gas bubbles to flow in the downwardly inclined direction.

In this case, the gas bubbles spreading along the lower surface 421 of the collision part do not immediately rise by the buoyancy force and the suction force of the suction means while spreading, and move downward in the water of the second storage space and then move upward. The longer the moving distance in the water, the longer the contact time with water. That is, the collision part may improve the filtration and collection efficiency of pollutants contained in the gas by increasing the contact degree with water by artificially increasing the moving distance and residence time of the gas bubbles in the water (see FIG. 3). .

This is to improve the filtration and collection efficiency of the pollutants contained in the gas by increasing the contact time with the water droplets that are spread along the lower surface 421 of the collision portion 420, as shown in FIG. . The impingement part 420 may vary the convexity in response to the velocity of the inlet gas flowing out through the outlet part 412 so that the smooth flow of the gas bubble is maintained. Various embodiments are possible if it can be guided in the lower inclined direction.

In addition to the convex shape described above, referring to FIG. 6, the collision part 420c may have a lower surface 422 formed in a direction in which both ends thereof are inclined downward with respect to the left and right directions. This is unlike the lower surface of the impact portion 420 of Figure 5 is formed in a convex shape as a whole, only a portion of the both ends are formed in the inclined downward direction to obtain the effect of increasing the contact time of the gas droplets with the water. have.

Referring to FIG. 7, the atomizing mechanism 400 includes a plurality of collision parts 420 in the first storage space 210 and is disposed in multiple stages in the vertical direction, and further increases the refinement of the inflow gas. You can. In this case, the colliding portions 420 disposed to be spaced apart from each other in multiple stages may have various combinations such that the flow guide means 430 may be alternately formed, or both may be formed.

Meanwhile, referring to FIG. 8, the cooling dedusting apparatus 800 further includes a hydraulic pressure damping mechanism 700 communicating with the second storage space 220.

The hydraulic pressure damping mechanism 700 is connected in communication with the second storage space 220, while the suction state 300 is changed to an overload operation state higher than the normal load operation state, the second The level of the storage space 220 is higher than the steady state level of the overload operation occurs. Due to such an excessive water level, since the inflow of the gas required by the suction means 300 is reduced, there is a fear that the stable operation of the equipment in which the cooling dedusting device 800 is installed may be inhibited. Therefore, the hydraulic damping mechanism 700 discharges the water in the second storage space 220 to increase the inflow of the gas into the second storage space 220 of the second storage space 220. It serves to reduce water pressure.

The hydraulic damping mechanism 700 includes a main body 710 and a sliding gate 720. First, the body 200 has a communication hole (not shown) is formed to communicate with the second storage space 220 on one side.

Thus, the main body 710 is in communication with the communication hole on one side is formed with an inlet hole 711 in which the water in the second storage space 220 is introduced, the inlet from the inlet hole 711 A storage chamber 712 is formed in which the water is stored.

The sliding gate 720 is slidably coupled to the inflow hole 711 along the up and down direction, and changes the open area of the inflow hole 711 as the second storage space moves along the up and down direction. Adjust the degree of hydraulic pressure attenuation of 220. On the other hand, the water pressure damping mechanism 700 may discharge the water stored in the storage chamber 712 to the outside as it is, or reuse the water discharged in connection with the water supply unit 100. Here, reference numeral 710 denotes a valve capable of adjusting the flow rate of water.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

100 ... water supply 200 ... body
210 ... First storage space 220 ... Second storage space
300 ... suction 400 ... atomizing device
410 ... Nozzle 420,420b, 420c ... Collision
430 ... flow guide means 432 ... guide groove
434 .... guide turning 510 ... countertop
520 ... First Water Flow Plate 530 ... Mixing Can
540, 550 ... 2nd water flow plate 610 ... Communication tube
700 ... Hydraulic Damping Mechanism 800 ...

Claims (11)

A first storage space for storing the water flowing from the water supply unit and a second storage space communicating with the first storage space are provided, respectively, and an upper portion of the suction port through which the contaminated inflow gas flows into the first storage space. And, the body is formed in each of the exhaust port communicating with the second storage space;
The suction port is connected to the exhaust port to generate a suction force, and the suction force generates an internal pressure difference between the first storage space and the second storage space so that water in the first storage space flows into the second storage space and rises. Suction means to enable;
It is provided in the second storage space and the first storage space and the second storage space to communicate, by the suction force to introduce the water in the first storage space into the second storage space, and the second 1. An atomizing mechanism for introducing the inlet gas in the storage space into the second storage space to be sprayed with fine gas bubbles in the water in the second storage space.
The atomizing mechanism,
An inflow portion into which the water and the inflow gas flow into the first storage space, and an outflow portion through which the water and the inflow gas flow out through the inflow portion flow into the second storage space, and pass through the outflow portion A nozzle portion having a cross-sectional area smaller than a passage cross-sectional area of the inflow portion to make the outflow speed faster than the inflow speed;
A cooling part including a collision part having a flow guide means for guiding the gas flowing out in a predetermined direction by colliding with the lower surface of the inlet gas, which is located at an upper portion of the nozzle part and collides with a lower surface of the nozzle; Dust removal device. The method according to claim 1,
The flow guide means,
Cooling exhaustion apparatus is a plurality of guide grooves formed on the lower surface of the impact portion spaced apart from each other. The method according to claim 1,
The flow guide means,
Cooling exhaustion apparatus is a plurality of guide projections formed spaced apart from each other on the lower surface of the impingement. The method according to claim 1,
The collision part,
Cooling exhaustion apparatus is a convex shape in the upper direction when the gas bubbles are guided to flow in the downward inclined direction to increase the contact time of the gas bubbles with the water. The method according to claim 1,
The collision part,
When the gas bubbles are guided to flow in the downward inclined direction, so that the contact time of the gas bubbles with the water is increased, both ends are inclined downwardly. The method according to claim 1,
The collision part,
It is formed long in the front and rear direction,
Cooling and dust removal device coupled to the inner surface of the body, respectively, or coupled to the outer frame is coupled to the front and rear, so that the position is fixed in the second storage space. The method of claim 6,
The guide grooves,
Cooling dedusting apparatus formed along the left and right directions so that the gas bubbles spread in both directions. The method according to claim 1,
The atomizing mechanism,
Cooling dedusting apparatus provided with a plurality of the impact portion arranged in the first storage space in the multi-stage in the vertical direction. The method according to claim 8,
The plurality of collision parts arranged in the multi-stage,
Cooling and dedusting device that the flow guide means are alternately formed or all formed for each. The method according to any one of claims 1 to 9,
A water tank provided inside the first storage space and having an upper portion open to store water supplied from the water supply unit;
A first water flow plate disposed to be spaced apart from the lower portion of the water tank and narrowed toward the lower portion and having a first discharge port formed at a lower end thereof;
A mixing passage spaced apart from the lower portion of the first outlet,
And a second water flow plate disposed to be spaced apart from the lower portion of the mixing cylinder and narrowing toward the lower portion and having a second discharge port formed at a lower end thereof. The method according to claim 10,
One or a plurality of communication tubes provided below each of the first storage space and the second storage space to communicate the first storage space with the second storage space;
Cooling dedusting device further comprises a flow control valve provided on the communication tube.

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