KR101058257B1 - Automizing device and dust removing and cooling apparatus use of the same - Google Patents

Abstract

PURPOSE: An atomizing tool and a cooling dust removing device using the same are provided to improve the harmful gas collecting capacity of inflow gas by atomizing inflow gas. CONSTITUTION: An atomizing tool comprises a storage part(100), a venturi member(200), and a collision member(300). An inner receptor(110) of the storage stores liquid. The venturi member has a funnel part(210) and a discharge hole(220). The funnel part is located on the lower part of the storage part to be apart. The liquid overflow from both sides of storage part is guided to the funnel part along with the inflow gas. The liquid and inlet gas, flowing in the funnel part, is exhausted through an outlet. A water sheet is located on the lower part of the venturi member by the spreading fluid which is discharged from the outlet.

Description

Atomizing apparatus and cooling dedusting apparatus using same {Automizing device and dust removing and cooling apparatus use of the same}

The present invention relates to an atomizing mechanism and a cooling dedusting apparatus using the same, and more particularly, to maximize the contact area of liquid and inlet gas, thereby improving the trapping power of harmful gases, and thereby improving the cooling dedusting efficiency. It relates to an atomizing mechanism and a cooling dedusting device using the same.

In general, the atomizing mechanism, industrial boilers and incinerators that use or incinerate various fuels, waste oils and various wastes as environmental pollutants as heat sources, inevitably emit a large amount of harmful gases, soot and various foreign substances during combustion or incineration. These exhaust gases and soot accelerate the air pollution so much that it not only destroys the ecosystem but also invades many areas of human life.

Accordingly, in order to prevent air pollution, various filtration devices or cyclones are installed in various boilers or incinerators to collect and collect various smokes and dusts generated during combustion or incineration. While it can filter out relatively large foreign matters, it is impossible to effectively collect various harmful gases including gas with a small amount of particulates, and thus cannot be effectively used. Therefore, in the related art, a method of using an atomizing mechanism capable of contacting a harmful gas and a liquid and collecting contaminants contained in the harmful gas is developed.

However, since the conventional atomizing mechanism has a poor contact area between the liquid and the harmful gas, the problem of poor filtration and collection efficiency of contaminants contained in the noxious gas and consequent poor filtration performance. there was.

An object of the present invention is to provide an atomizing mechanism and a cooling dedusting apparatus using the same, which can improve the harmful gas filtration power by minimizing a liquid and an inlet gas to maximize the contact area, and thus the cooling dedusting efficiency.

According to an aspect of the present invention, the present invention, the upper portion is open and the storage unit provided with a storage portion for storing the liquid therein, the liquid is located at a lower portion of the storage portion and flows from both sides of the storage portion and An inflow gas is introduced together, and a funnel part defining a first venturi part whose distance between the side of the storage part is narrowed toward the lower center in order to increase the flow rate of the liquid and the inflow gas that flows inward, The venturi member formed from the funnel portion and the inlet gas are collected to be discharged downwardly and are located below the venturi member and the venturi member, and the liquid discharged from the outlet is spread out to the side while colliding with the upper surface. When the liquid blocking film is formed on the lower portion of the venturi member by the spread liquid Provides an atomizing apparatus comprising a collision member.

According to another aspect of the present invention, the present invention is provided with a first storage space in which water is stored, and a second storage space communicating with the first storage space, each of which is contaminated in communication with the first storage space. A suction port into which noxious gas flows in, a body having an exhaust port communicating with the second storage space, respectively, are connected to the exhaust port to generate a suction force, and through the suction force, the suction of the first storage space and the second storage space. Suction means for generating an internal pressure difference so that the water in the first storage space is introduced into the second storage space and ascended, and is provided inside the first storage space, the upper portion of which is opened, and the liquid supplied from the water supply unit Is provided with a storage unit for storing, the storage unit is inclined shape so that the side becomes narrower toward the lower side, the upper portion is opened and spaced apart from the lower portion of the storage portion In order to increase the flow rate of the water and the harmful gas flows into the water and the harmful gas flowing from the suction port so as to have a first venturi with respect to the inclined side of the storage unit A funnel part inclined to become narrower with the side toward the lower side, an outlet for collecting and discharging the water and the harmful gas introduced from the funnel part, and an outlet part extending downward from the outlet and having a second venturi part The venturi member and the triangular shape narrowing toward the upper side is spaced apart from the lower portion of the venturi member and the harmful gas flowing out of the discharge portion and the water to spread to the side by colliding with the upper surface to atomize the water and the harmful gas A first atomizing mechanism comprising a collision member for It provides a cooling dedusting device comprising.

Therefore, the atomizing mechanism and the cooling dedusting apparatus using the same according to the present invention can refine the liquid and the inlet gas to maximize the contact area of the liquid and the inlet gas to improve the trapping power of harmful gases contained in the inlet gas. As a result, the cooling and dedusting efficiency can be improved.

1 is a perspective view showing an atomizing mechanism according to an embodiment of the present invention.
FIG. 2 is a plan sectional view of the atomizing mechanism of FIG. 2.
3 is a plan sectional view showing an operating state of the atomizing mechanism of FIG.
4 is a view schematically showing a cooling dedusting apparatus using an atomizing mechanism according to another embodiment of the present invention.
5 is a cross-sectional view illustrating a second atomizing mechanism of FIG. 4.
FIG. 6 is a view illustrating an operating state of the cooling dedusting apparatus of FIG. 4.

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

First, referring to FIG. 1, the atomizing mechanism 400 according to an embodiment of the present invention includes a storage unit 100, a venturi member 200, and a collision member 300. The storage unit 100 is provided with an accommodating unit 110, which is open at an upper side thereof and may store a liquid 1 (see FIG. 3) therein. Here, the storage unit 100 is filled with the liquid (1) through the liquid (1) supply line connected to the receiving unit 110 in order to fill the liquid (1) in the receiving unit 110 The liquid 1 may be filled in the container 110 while the liquid 1 is freely dropped from the upper portion of the reservoir 100. On the other hand, the storage unit 100 is inclined so that the side becomes narrower toward the lower side, thereby further improving the venturi effect of the first venturi unit 150 to be described later.

The venturi member 200 has a funnel portion 210 and an outlet 220. The funnel part 210 is located at a lower portion of the storage part 100 in a funnel shape as a whole and overflows from the sides of the storage part 100 with the inflow gas from the liquid 1. Together through 111). The funnel part 210 defines a first venturi part 150 (refer to FIG. 2) to increase the flow rates of the liquid 1 and the inflow gas. The discharge port 220 is formed in the lower center of the funnel portion 210 and the liquid 1 and the inflow gas introduced from the funnel portion 210 are collected and discharged downward. Furthermore, the venturi member 200 further includes a discharge part 230 having a substantially duct shape extending downward from the discharge port 220, and the discharge part 230 flows out from the discharge port 220. The second venturi part 250 is provided to increase the flow velocity of the liquid 1 and the inflow gas.

Referring to FIG. 2, the first venturi part 150 and the second venturi part 250 of the venturi member 200 will be described.

The first venturi part 150 is a part in which the liquid 1 and the inflow gas are primarily in contact with each other, and is defined by the side surface of the storage part 100 and the funnel part 210. The distance between the inner surface of the portion 210 and the outer surface of the storage portion 100 is narrowed toward the discharge port 220, that is, the lower center (L1, L2). For this reason, the flow rate of the liquid 1 and the inflow gas flowing from the storage part 100 flows faster while passing through the first venturi part 150, and accordingly, the first venturi part 150 is provided. ) Refines the liquid 1 and the inlet gas and improves the contact area. In this embodiment, the side surface of the storage unit 100 is formed to be inclined toward the lower side corresponding to the inclined shape of the funnel portion 210, thereby reducing the Venturi effect of the first venturi unit 150. Improved.

The second venturi part 250 is formed in the outlet 230 to increase the flow rates of the liquid 1 and the inflow gas flowing out of the outlet 220 to obtain a venturi effect. In some cases, if the structure of the above-mentioned venturi effect can be obtained such that the passage cross-sectional area of the second venturi part 250 can be made smaller toward the lower side.

As described above, the present embodiment is provided with the first venturi part 150 and the second venturi part 250 in the venturi member 200, respectively, to provide a flow rate of the liquid 1 and the inflow gas. Further increase and refinement, thereby improving the contact area in which the liquid 1 and the inlet gas are in contact with each other can improve the filtering performance of the harmful substances contained in the inlet gas.

The impingement member 300 is located below the venturi member 200, and the liquid (1) and the inlet gas flowing out of the outlet 220 to the upper surface while spreading to the side, the A liquid barrier layer 10 is formed on the lower part of the venturi member 200 by the spreading liquid 1, and the liquid 1 collides with the outflowing gas and the inflow gas is refined. Here, the liquid barrier layer 10 is further atomized as the inlet gas passes, and the liquid barrier layer 10 thus atomized can further improve the contact area with the inlet gas.

The impingement member 300 has an upper longitudinal cross-sectional shape formed in a triangular shape so as to narrow toward the upper side, reducing the resistance of the liquid (1) and the inflow gas outgoing, and at the same time inclined along a predetermined angle the liquid blocking film (10) ) Can be formed to guide. Here, the collision member 300 in the present embodiment, but the shape of the longitudinal cross-section in order to obtain a fluid resistance reduction and a guide effect as described above as an example, but the liquid (1) and the inflow gas flowing out If the liquid barrier layer 10 can be formed by collision, it can be applied to various shapes such as streamlined convex shape.

The collision member 300 may be slidably moved upward and downward with respect to the discharge part 230 to adjust the separation distances B1 and B2 from the discharge part 230. Accordingly, the collision member 300, by adjusting the side cross-sectional area of the liquid (1) and the inflow gas flowing out from the discharge portion 230 to the side, and the flow rate of the liquid blocking film 10 By controlling the degree of collision between the liquid 1 and the inlet gas, the degree of passage of the inlet gas through the liquid barrier membrane 10 and the degree of miniaturization of the inlet gas and the liquid 1 may be controlled. On the other hand, although not shown, the present embodiment is provided with a fastening bolt on the collision member 300, so that the collision member 300 is a sliding movement, the fastening bolt is passed through the discharge portion 230 After forming the slide hole of the long hole so that the collision member 300 is sliding, it may be a structure for fixing the collision member 300 through a fastening nut, which in one embodiment the fastening bolt and the slide hole Each of the discharge unit 230 and the collision member 300 may be formed, and in addition, if the collision member 300 has a structure that can slide in the vertical direction, various embodiments are possible.

On the other hand, in the present embodiment, the front and rear of the venturi member 200 is formed in a structure coupled to the corresponding side of the storage unit 100, the collision member 300 is in the discharge portion 230 In the combined structure, the entire atomizing mechanism 400 is shown as a single body coupled structure, but may be separated in some cases, it is possible in a variety of structures. Here, the solid arrow of Figure 3 shows the flow of the liquid, the dotted arrow shows the flow of the inlet gas.

As described above, the atomizing mechanism 400 according to the present embodiment has the first venturi part 150 and the second venturi part 250, and thus the flow velocity of the liquid 1 and the inflow gas. To increase the contact area by miniaturizing the liquid 1 and the inflow gas to improve the collection efficiency, and to form the liquid barrier layer 10 by the collision member 300, thereby allowing the inflow gas to By miniaturizing while passing through the liquid barrier membrane 10, the liquid 1 can be further refined to improve the contact area with the inflow gas, thereby improving the filtration efficiency and performance. That is, the atomizing mechanism 400 according to the present embodiment is in contact with the liquid 1 while the inlet gas is miniaturized in the first venturi part 150, and passes through the second venturi part 250. As the finer is further refined by the collision member 300, the contact area with the liquid 1 may be further improved, and the inflow gas may be reduced from the first venturi part 150 to the second venturi part. Since the contact time for contacting the liquid 1 to the liquid blocking film 10 through the 250 and the collision member 300 is long, the harmful gas trapping force contained in the inflow gas can be further improved. have.

On the other hand, the atomizing mechanism 400 according to the present embodiment of the above structure, can be applied to various devices, such as a cooling dust collector, a wet dust collector, aeration device and dust removal device, one or more of the atomizing mechanism 400 It can be provided in multiple numbers, and can be arrange | positioned at the said various apparatus in single stage or multiple stages.

4 to 6, the cooling dedusting apparatus to which the atomizing mechanism 400 is applied will be described.

First, referring to FIG. 4, a cooling dedusting apparatus according to another embodiment of the present invention includes a body, a suction unit, a first atomizing mechanism 400, and a second atomizing mechanism 500.

The body 600 has a first storage space 610 in which water is stored, and a second storage space communicating with the first storage space 610, respectively, and an upper portion of the first storage space 610. Intake port 611 and the exhaust port 622 is in communication with the second storage space 620 is introduced to communicate the polluting harmful gas is formed. Meanwhile, although not shown, the body 600 may be provided with a water supply unit communicating with the first storage space 610 to supply water to the first storage space 610.

The suction means 700 is connected to the exhaust port 622 to generate a suction force, and generates an internal pressure difference between the first storage space 610 and the second storage space 620 through the suction force. The water in the first storage space 610 is introduced into the second storage space 620 to rise.

The first atomizing mechanism 400 includes a storage unit 100, a venturi member 200, and a collision member 300. The storage unit 100 is provided in the first storage space 610, the upper portion is provided with an accommodation unit 110 for storing the water supplied from the water supply unit therein, the side is lower side It is inclined to become narrower. The venturi member 200 has an open top and is spaced apart from the bottom of the storage part 100 so that the water flowing from the sides of the storage part 100 and the inflow gas flowing from the suction port flow in together. And a funnel defining a first venturi part 150 in which the distance between the liquid 1 and the side of the storage part 100 is narrowed toward the lower center in order to increase the flow velocity of the inflowing gas 1. The outlet 210 and the outlet 1 220 which collects the liquid 1 and the inflow gas introduced from the funnel part 210 and discharges downward are formed. The collision member 300 is positioned below the venturi member 200, the liquid 1 flowing out of the discharge port 220 to spread to the side while colliding with the upper surface, the spread liquid (1) The liquid barrier film 10 is formed below the venturi member 200. Here, since the detailed description of the first atomizing mechanism 400 is substantially the same as the atomizing mechanism 400 of FIG. 1, the detailed description thereof will be omitted.

Referring to FIG. 5, the second atomizing mechanism 500 includes a nozzle part 510, an adjusting member 530, and a collision part 520. The nozzle unit 510 is provided in the second storage space 620 in which the water is accommodated so as to communicate the first storage space 610 with the second storage space 620, and the first side is connected to the first storage space 620. 1, an inlet 515 in which the water and the inlet gas of the storage space 610 are introduced by the suction means 700 is formed, and the water and the inlet gas introduced through the inlet 515 An outlet 516 is formed to flow out to the second storage space 620 in the upper direction. The nozzle part 510 is gradually narrowed from the inlet part 515 toward the outlet part 516, and has a passage cross-sectional area smaller than that of the inlet part 515. As a result, the speed of the water and the inflow gas flowing out to the outlet 516 is faster than the speed of the water and the inflow gas flowing into the inlet 515.

The adjusting member 530 is coupled to the sliding side along the upper side of the nozzle unit 510 and adjusts the cross-sectional area of the outlet part 516 in the nozzle unit 510 according to the sliding movement. Do it.

The impingement part 520 is coupled to the upper part of the outlet part 516 so that the inlet gas flowing out in the upper direction collides with a lower surface to form a fine gas bubble and spreads out to the side, and the outlet part Sliding movement in the vertical direction with respect to 516 serves to adjust the separation distance with the outlet portion 516, and includes a collision plate 521, the separation plate 523. Here, the collision plate 521 may be provided in plural in some cases to have a multi-stage structure.

Here, looking at the structure for the sliding movement of the control member 530, the impact portion 520, the embodiment for the sliding movement of the control member 530, horizontal to the control member 530 The first sliding holes 536 of the long hole are formed in the sliding movement direction of the sliding direction, and the first fastening bolts 534 which pass through the first sliding holes 536 are respectively coupled to the nozzle part 510. And a plurality of first fastening nuts 535 fastened to the first fastening bolts 534 to fix the position of the adjustment member 530. In addition, the present embodiment for the sliding movement of the collision portion 520, the second hole of the long hole in the sliding movement direction of the vertical direction on the separation plate 523 of the collision portion 520, similar to the adjustment member 530 Sliding holes 526 are formed, and the second fastening bolts 524 and the second fastening bolts 524 that pass through the second sliding holes 526 in the nozzle unit 510 are fastened to the second fastening bolts 524, respectively. Second fastening nuts 525 to be included. In the present embodiment, the first and second sliding holes (536, 526), the first and second fastening bolts (534, 524) for sliding the control member 530 and the impact portion 520, Although the structure including the first and second fastening nuts 535 and 525 is taken as an example, the present invention is not limited thereto.

Meanwhile, the cooling and dedusting apparatus includes one or more first atomizing mechanisms 400 and is disposed in the first storage space 610 in one or multiple stages, thereby automating inflow gas and contacting with water. The efficiency can be further improved.

Thus, with reference to Figure 6, it will be described with respect to the operation of the cooling dedusting device. In the cooling dedusting apparatus, water is stored in the first storage space 610 and the second storage space 620 of the body by a water supply, and in this state, the first storage by the suction means 700. When a pressure difference between the space 610 and the second storage space 620 occurs, water in the first storage space 610 flows into the second storage space 620 through the second atomizing mechanism 500. As the water level of the first storage space 610 is lowered, the water level of the second storage space 620 is increased. Here, although the second atomizing mechanism 500 is shown as a part submerged in the water in Figure 5, the initial state may be a state in which all of the second atomizing mechanism 500 are all submerged in water. .

At this time, while the air pressure in the first storage space 610 is lower than the outside, the inlet gas is introduced into the first storage space 610 at a high speed through the suction port 611, and is introduced through the suction port 611. The inflow gas flows into the second atomizing mechanism 500, and is injected into the water in the second storage space 620 while the flow rate rapidly increases while passing through the second atomizing mechanism 500. At this time, the inflow gas is dispersed in the water of the second storage space 620 while colliding with the collision plate in the form of air bubbles while being formed as fine air bubbles, foreign matter and fine dust contained in the inflow gas Is filtered in water.

On the other hand, the first atomizing mechanism 400, the water supplied from the water supply unit (not shown) through the supply unit 611 falls to fill the storage unit 100, the storage unit 100 is full Cold water overflows to the outside of the storage unit 100, and the overflowing water and the inflow gas are introduced into the venturi member 200, and the flow rate is discharged quickly, and the discharged water and the inflow gas collide with each other. While forming and miniaturizing the liquid barrier layer 10 by the member 300, the water and the inlet gas are forced to contact each other to cool and filter harmful substances contained in the inlet gas. Here, a mixing cylinder 880 is provided below the collision member 300, and the mixing cylinder 880 has a vortex inside the water and the inflow gas discharged from the first atomizing mechanism 400. Forced mixing is performed while causing forced contact between the water and the incoming gas once again.

The first storage space 610 is provided with a sludge discharge valve 840 at a lower portion of the first storage space 620, the first and second droplet removing layers 810 and 820 are spaced apart from each other. And, the plurality is provided with a plurality of blocking plates 830 alternately spaced apart from each other, the upper portion is formed with discharge parts (621, 622) for discharging the inlet gas. On the other hand, the cooling and dedusting apparatus according to the present embodiment shows the configuration of the cooling and dust collecting portion of the domestic registered patent No. 0860493, other configurations of the domestic registered patent No. 0860493 can be applied to this embodiment, of course, the other For a detailed description of the configuration, refer to Korean Patent Registration No. 0860493.

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.

10 ... Liquid barrier 100 ... Storage
200 ... Venturi member 210 ... Funnel section
220 ... outlet 230 ... outlet
300 ... Collision member 400 ... Atomizing mechanism
900. Cooling and dedusting device

Claims (9)

An upper portion is opened and a receiving portion for storing liquid therein is provided, the storage portion being inclined so that the side thereof becomes narrower toward the lower side;
Located at the bottom of the storage unit and the liquid flowing in from the sides of the storage and the flowing inflow gas flows in together, the inner surface and the outer portion of the storage in order to increase the flow rate of the incoming liquid and the incoming gas A funnel part defining a first venturi part, the distance between which is narrowed toward the lower center, and a second venturi extending downward from the outlet from which the liquid and the inflow gas introduced from the funnel part are collected and discharged downward; A venturi member including an outlet having a portion; And
Located in the lower portion of the venturi member and the sliding movement in the vertical direction with respect to the venturi member to adjust the separation distance with the venturi member, the upper longitudinal cross-sectional shape is formed in a triangular shape so as to narrow toward the venturi And a collision member for forming a liquid barrier film under the venturi member by the spreading liquid by causing the liquid flowing out of the member to spread out to the side while colliding with the upper surface. delete delete delete delete The method according to claim 1,
The atomizing mechanism, the atomizing mechanism is applied to one or a plurality of single or multiple stages are applied to any one selected from the cooling dust collector, the wet dust collector, the aeration device and the dust removal device. A first storage space for storing water and a second storage space communicating with the first storage space are provided, respectively, and an intake port through which the contaminated inflow gas flows in communication with the first storage space is provided thereon. A body having an exhaust port communicating with the storage space, respectively; The suction port is connected to the exhaust port to generate a suction force, and through the suction force, an internal pressure difference between the first storage space and the second storage space is generated so that the water in the first storage space flows into the second storage space. Suction means for raising; And a storage part provided inside the first storage space, the upper part of which is open, and configured to store the liquid supplied from the water supply part therein, the storage part having an inclined shape so that the side thereof becomes narrower toward the lower side, and the upper part of which is opened. The water flowing in from the side of the storage unit and spaced from the lower side of the storage unit and the inlet gas flowing from the inlet flows in together, the side of the storage unit to increase the flow rate of the incoming liquid and the inlet gas And a funnel part defining a first venturi part, the distance between which is narrowed toward the lower center, and extending downward from a discharge port where the liquid and the inflow gas introduced from the funnel part are collected and discharged downward. A venturi member and a venturi member including a discharge portion having a position spaced below the venturi member And a first atomizing mechanism and the fluid from the outlet is out while impinging on the top surface spreads laterally, by the spread liquid comprises a collision member that forms a liquid barrier film in a lower portion of the venturi member,
The first storage space is provided in the second storage space in which the water is accommodated so as to communicate the first storage space and the second storage space, and connected to the exhaust port at one side to generate suction force. An inflow portion is formed through which the water and the inflow gas flow in, and an outflow portion is formed such that the water and the inflow gas introduced through the inflow portion flow out to the second storage space in an upward direction, and the cross-sectional area of the outflow portion is passed. A nozzle unit which is formed to have a smaller cross-sectional area than the inlet so that the outflow speed is faster than the inflow speed; An adjusting member coupled to the upper side of the nozzle to be slidably movable and adjusting a passage cross-sectional area of the nozzle part according to the sliding movement; And coupled to the upper portion of the outlet spaced apart from the inlet gas flowing out in the upper direction to form a fine gas droplets to collide with the lower surface to spread to the side, and the sliding movement in the vertical direction with respect to the outlet portion the outflow And a second atomizing mechanism including a collision unit configured to adjust a separation distance from the unit. delete The method according to claim 7,
The cooling dedusting device,
Cooling dedusting device wherein the first atomizing mechanism is arranged in one or a plurality of stages or stages in the first storage space.

Images