KR101611538B1 - A Scrubber for Collecting Contaminator from Gas with Swirl Generating Structure - Google Patents

Abstract

The present invention relates to a dust collector for treating gas, having a swirl generation spray structure and, more specifically, to a dust collector for treating gas, having a swirl generation spray structure with improved dust collection efficiency by generating swirl while introducing both liquid for forming particle and gas. The dust collector for treating gas, having a swirl generation spray structure (10) comprises: a housing (11) including a collision separation unit (111) disposed on an upper side of a liquid storage space storing dust collection liquid and at least one collision gas treating unit disposed on an upper side of the collision separation unit (111); a swirl generating unit (12) where contaminants are captured by the particle through coming into contact with the dust collection liquid supplied to the collision separation unit (111) and contaminated gas; and a particle generating nozzle (13) which sprays the dust collection liquid to the swirl generating unit (12).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a dust collector having a vortex generating structure for gas treatment,

The present invention relates to a dust collector having a vortex generating jetting structure for gas treatment, and more particularly, to a dust collector having a vortex generating jetting structure for gas treatment, which improves the dust collecting efficiency by introducing a liquid for forming fine particles together with a gas, .

A cleaning dust collector or scrubber is a device for removing contaminants trapped in a liquid by spraying the droplet onto a gas containing gas or particulate contaminants. There is a clean ventilator with a small venturi injection circulation structure, such as a laboratory exhaust hood with a small gas treatment capacity, a school and factory workshop, a pilot or bench scale plant facility. Such a small dust collector has a disadvantage that the gas removal efficiency is low and the use range is limited. Another known type of scrubbing dust collector is a large scrubbing scrubber for treating industrial harmful gases and for treating odors generated by agricultural and livestock products. Such a large cleaning dust collector is disadvantageous in that the nozzle structure is simple, the complete treatment of harmful gas is difficult, the installation cost is high, and maintenance and operation costs are high due to the large pump and circulation structure.

Patent Document No. 10-2007-0061497 corresponding to the prior art related to the cleaning and dust collector has a housing, a gas inlet formed at a lower portion of the housing, a gas outlet formed at an upper portion of the housing, and a gas inlet height between the housing and the gas outlet And a cleaning liquid drain pipe formed at a lower end of the housing, wherein the cleaning liquid is supplied to the contaminated gas flowing through the gas inlet and is purified by spraying the cleaning liquid supplied through the cleaning liquid inlet pipe, The present invention relates to a wet-type gas scrubber that discharges a liquid through a gas scrubber. The rotary supply unit may include a pair of hollow supply rods having one end communicated with the rinse solution inflow pipe and having a discharge port formed in a direction facing each other, Characterized in that it comprises a supply rod and the rotation supply part is rotated by an opposite direction thrust generated by the recoil when the washer fluid is discharged through the outlet of each supply rod.

Patent No. 10-1172708 discloses a chamber having a gas inflow tube at a lower portion through which a contaminated gas flows, and providing a space where mass transfer between gas and cleaning liquid occurs; A cleaning liquid injector installed at one or more stages perpendicularly to the chamber for spraying the cleaning liquid; And a gas-liquid separator provided on the upper portion of the washer fluid ejection apparatus for separating and removing water from the gas, wherein the cone washer fluid ejection apparatus comprises a washer fluid pipe having at least one cleaning hole through which the washer fluid can be injected, Wherein the gas-liquid separator comprises a cylindrical separating part having at least one wetting gas inlet through which a gas containing water is introduced, A wet gas scrubber including a cylindrical enlarged separation portion having a larger diameter than the separation portion is provided on the upper portion of the separation portion.

Patent Publication No. WO < RTI ID = 0.0 > 2012/000790 < / RTI > relates to a cleaning facility for a contaminated scrubber fluid from an exhaust gas scrubber fluid loop, the cleaning facility comprising means for flowing a portion of the contaminated scrubber fluid from the scrubber fluid loop, And a disc stacking type centrifugal separator for separating the cleaned scrubbing fluid, the separator comprising a rotor enclosing a separation space having a stack of separation discs, a separator inlet for the part extending into the separation space, A first separator outlet for the scrubbed scrubber fluid extending from the separation space and a second separator outlet for the contaminant phase extending from the separation space, the scrubbing facility comprising means for directing the portion to the separator inlet, Means for withdrawing the scrubbed fluid from the separator outlet, And a means for collecting the contaminant phase from the outlet of the gas scrubber.

The prior art does not disclose an apparatus or a method by which a contamination gas and a cleaning solution can collide with each other, and a foreign matter can be effectively adsorbed on a fine droplet formed from a cleaning solution. The contaminated gas and cleaning solution must be sufficiently contacted so that the contaminants can be adsorbed, while at the same time the cleaning solution should have a sufficient amount of fine droplets to adsorb contaminants. However, the prior art does not disclose a technique that can enhance such contact efficiency and at the same time suitably adsorb.

The present invention has been made to solve the problems of the prior art and has the following purpose.

Prior Art 1: Patent Publication No. 10-2007-0061497 (published on June 13, 2007, Pico Corporation) A wet gas scrubber Prior Art 2: Patent Registration No. 10-1172708 (published on Aug. 09, 2012, Yumi On) Wet gas scrubber Prior Art 3: WO 2012/000790 (published on Jan. 05, 2012, Alfa Laval Corporation Apis) Cleaning equipment for gas scrubber fluids

SUMMARY OF THE INVENTION It is an object of the present invention to provide a dust collector of a vortex generating jetting structure for gas treatment which improves the dust collecting efficiency by causing the polluted gas to collide with the dust collecting fluid with the vortex forming spray structure.

According to a preferred embodiment of the present invention, the dust collector of the eddy current generating jet structure for gas treatment comprises a collision separation unit disposed above the liquid storage space in which the dust-collecting liquid is stored and at least one collision gas treatment A housing including a unit; A vortex generating unit for bringing the polluted gas into contact with the dust-removing liquid supplied to the collision-separating unit so that the pollutant is captured by the particulates; And a particulate generation nozzle for spraying the dust-collecting liquid with a vortex generating unit.

According to another preferred embodiment of the present invention, the vortex generation unit has a structure in which the cross-sectional area increases from the upper side of the housing to the lower side, and includes a stay space formed below.

According to another preferred embodiment of the present invention, the apparatus further comprises a gas inflow unit for introducing gas into the particulate generation nozzle.

According to another preferred embodiment of the present invention, there is further provided an inflow unit (15) for introducing the contaminated gas into the vortex generation unit, wherein the inflow unit has a curved path for swirl generation.

According to another preferred embodiment of the present invention, the apparatus further includes a mixed fluid discharge unit disposed below the retention space and having a plurality of holes or meshes.

According to another preferred embodiment of the present invention, the at least one impact gas processing unit is disposed in a space separated from the vortex generation unit.

According to another preferred embodiment of the present invention, the particulate generation nozzle 13 for spraying the dust-collecting liquid mixes a high-pressure one fluid or a liquid and a gaseous substance to generate particulates and spin-jet.

The dust collector according to the present invention improves the dust collecting efficiency by mixing contaminated noxious gas or a gas containing odor with the functional liquid for removing water or contaminants through the fine particle spray nozzle. The dust collector according to the present invention can be applied to the cooling and circulation control of the hot combustion gas, the deodorization of the gas including the purification or the smell of the gas containing contaminants such as nitrogen oxides, sulfides or mercury. Further, the dust collector according to the present invention can be applied to the removal of odors in a public place such as a domestic indoor odor elimination, a food treatment, and a restaurant.

1 shows an embodiment of a dust collector according to the present invention.
2 shows an embodiment of a vortex generating structure that can be applied to a dust collector according to the present invention.
FIG. 3 shows an embodiment of a spray nozzle that can be applied to a dust collector according to the present invention.
4 shows another embodiment of the dust collector according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto. In the following description, components having the same reference numerals in different drawings have similar functions, so that they will not be described repeatedly unless necessary for an understanding of the invention, and the known components will be briefly described or omitted. However, It should not be understood as being excluded from the embodiment of Fig.

1 shows an embodiment of a dust collector 10 according to the present invention.

1, a dust collector 10 according to the present invention includes a collision separation unit 111 disposed above a liquid storage space in which dust is stored, and a collision separation unit 111 disposed above the collision separation unit 111. At least one collision A housing (11) including a gas treatment unit; A vortex generation unit (12) for bringing the contaminated liquid supplied to the collision separation unit (111) into contact with the polluted gas so that the contaminants are captured by the particulates; And a particulate generation nozzle (13) for spraying the dust-collecting liquid into the vortex generation unit (12).

A dust collector 10 according to the present invention may be applied to the trapping of cleaning contaminants from a polluted gas in various forms, for treatment and cooling, nitrogen compounds (NO _X) in the high-temperature combustion gas g., Sulfide (SO _2), or It can be applied for the capture of contaminants such as mercury. It can also be applied for the collection of ozone and for removing the odor of food or livestock products. For such an application, the dust collector 10 according to the present invention may be installed at a suitable scale in various places such as industrial facilities, public facilities, restaurants, farms or homes. Therefore, the dust collector 10 according to the present invention is not limited by the kind, scale or installation place of the processing gas.

The housing 10 may have an overall hollow cylindrical structure, but is not limited thereto and may have various shapes. And various processing units including a filter unit for treating the polluted gas inside the housing 10 can be disposed in an appropriate position. A dust collecting liquid PL sprayed for collecting contaminants contained in the contaminated gas can be stored below the housing 10. The dust collecting liquid PL can be sterilized water containing a sterilizing component such as hypochlorous acid water, alkaline electrolytic water, hypochlorous hypochlorous acid water, sodium hypochlorite water, alkaline ion water or acidic ionized water, can do. And may be connected to an apparatus for generating such a material for supplying electrolytic water or deodorizing components as needed. The dust collecting liquid PL can be discharged to the outside by the drain unit DR and supplied to the vortex generating unit 12 through the circulating discharge unit 119. [

A supply tube may be formed from the circulation discharge unit 119 and connected to the fluid supply unit 121 formed above the housing 111. [ And a supply pump (PU) is provided at a proper position of the supply tube to regulate the supply of the dust-collecting liquid (PL).

The fluid supply unit 121 may be connected to the particulate generation nozzle 13 to supply the dust-collecting liquid PL. Thereafter, the dust-collecting liquid PL may be sprayed in the form of fine particles into the nozzle tip 131 of the particulate generation nozzle 13 together with the high-pressure gas introduced through the gas inlet unit 122. The dust-collecting liquid PL can be made into particulates in the form of droplets of a suitable size with spraying and can comprise, for example, fine particles having an average diameter of 2 to 100. [ At the same time, the dust-collecting liquid PL can be lowered downwardly of the vortex generating unit 12 while forming a swirling or vortex SW as indicated by the arrow B in FIG. The swirling flow SW may be formed by the structure of the particulate generation nozzle 13, the structure of the vortex generation unit 12, or the structure of the inflow unit 15.

The vortex generation unit 12 may be conical in shape with a gradually increasing cross sectional area while extending downward and a retention space 14 may be formed in the lower part of the vortex generation unit 12. [ The retention space 14 may be in the form of a cylinder having a constant cross-sectional area. The conical shape having a larger cross-sectional area as described above may have a function of inducing vortex formation at the same time while assisting particulate formation of the dust-collecting liquid sprayed from the particulate generation unit 12.

An inflow unit 15 may be connected to the retention space 14 for introducing the polluted gas as indicated by the arrow A from the outside. A suitable inflow induction device, such as a fan, may be provided in front of the inflow unit 15 if necessary, but this is not required. The inflow unit 15 may have a tubular structure and at least a curved shape in the interior of the housing 11, preferably inside the retention space 14. Due to this curved shape, the polluted gas can flow into the circumferential surface of the vortex generation unit 12 or the interior of the retention space 14 in the form of a vortex. As a result, the polluted gas contained in the polluted gas can be easily trapped in the fine particles due to the increase of the contact area due to the homogeneous mixing of the polluted gas and the particulate type dust collecting liquid. The particulate matter collecting liquid which has captured the contaminant may be discharged to the bottom surface of the retention space 14 and may collide with the collision separating unit 111.

The collision separation unit 111 may have a plate shape in which a plurality of slits or holes are uniformly distributed, and a center portion thereof may have a concave lens shape convex downward. And a certain area from the center of the concave lens shape may be immersed in the dust-collecting liquid PL. The fine particles having a small diameter in the process of collision through the slit or the hole can be raised upward and the fine particles having a large diameter can be introduced into the dust collecting liquid PL. The concave lens structure facilitates the separation of the contaminants and the fine particles by causing the collision of the fine particles to be formed in an inclined shape. The collision separation unit 111 can be made in various structures and the present invention is not limited to the embodiments shown.

The gas containing contaminants separated from the particulate droplets by the collision separation unit 111 can be purified through the collision gas processing unit and discharged to the outside through the gas exhaust unit 16. [ The gas treatment unit may include, for example, a diffuser plate 112, a grid unit 113, a filter layer 114, or a droplet removal pad 115. The diffuser plate 112 may include pores or slits through which a plurality of gases may pass. The diameter of the pores or the spacing of the slits can be appropriately determined depending on the kind of contaminant to be treated. The grid unit 113 may have a function of removing droplets contained in the rising gas and may have a lattice-like grid structure. The droplets removed through the grid unit 113 may fall down into the dust-collecting liquid. The gas containing the contaminant may then be purified while passing through the filter layer 114. The filter layer 114 may comprise various types of filters known in the art and may be appropriately selected depending on the type of contaminant to be treated. For example, the filter layer 114 may comprise a zeolite layer, an activated carbon layer, a carbon layer, or a nonwoven layer. The gas with the contaminant removed by the filter layer 114 may then be in the form of a purified gas which has been completely removed from the droplet removing pad 115. And the purge gas may be discharged through a discharge unit 16 to a predetermined location as indicated by arrow F. [ Various impact gas processing units can be appropriately selected depending on the type of contaminants, and the present invention is not limited to the embodiments shown.

The polluted gas flowing through the inflow unit 15 in the dust collector 10 according to the present invention can form a swirl.

2 shows an embodiment of a vortex generating structure that can be applied to a dust collector according to the present invention.

2 (a) and 2 (b), the inflow unit 15 for guiding the contaminated gas into the retention space 14 can form a curved path. Specifically, the contaminated gas introduced into the inflow unit 15, as indicated by the arrow A, is uniformly mixed with the atomized dust collecting liquid while flowing through a circular path formed around the vortex generating unit, And is discharged to the outside as indicated by the arrow B through the outlet unit 16 of the housing 11 after the dust collecting process. The curved path may have a helical shape.

A mixed fluid discharge unit 141 having a plurality of pores 221 or a mesh structure 222 may be formed below the retention space 14. The pores 221 or the mesh structure 222 may have a sufficiently large cross-sectional area as compared with the diameter of the fine particles of the dust-collecting liquid. Such a structure of the retention space 14 increases the residence time of the collecting liquid and the contaminated gas, while increasing the time for the collecting liquid to collect the contaminants from the contaminated gas. While at the same time preventing the mixed fluid from colliding linearly with the collision separation unit 111 described above. This makes it easy to separate the gas containing the pollutant and the dust collecting liquid.

Various structures for generating vortex or mixed fluid by the inlet unit 15 can be applied to the dust collector according to the present invention and the present invention is not limited to the embodiments shown.

As described above, a suitable nozzle structure for vortex formation can be applied to the dust collector according to the present invention.

3 shows an embodiment of a spray nozzle 13 which can be applied to a dust collector according to the invention.

3, the spray nozzle 13 includes an inlet block 311 connected to the fluid supply unit 121, a gas inlet unit 122 formed on the side of the inlet block 311, And a nozzle tip 131 formed at the end portion. The vortex slit 331 may be formed in the nozzle tip 131.

The dust collecting liquid introduced through the inlet block 311 may be formed into a particulate form while being injected through the nozzle tip 131 together with the high pressure gas introduced through the gas inlet unit 122. The vortex slit 331 may be formed across the spray surface and the side surface of the cylindrical nozzle tip 131 and may be formed linearly at an eccentric position with respect to the spray surface. Such an eccentric position and a staggered shape can form a vortex. The number of the vortex slits 331 is not particularly limited and may preferably be symmetrically paired.

In the embodiment shown in FIG. 3, a nozzle 13 for generating fine droplets by mixing a fluid to be introduced with a gas through a gas inflow unit 122 to spin-jet is proposed, but only liquid may be injected have. Specifically, the nozzle 13 can generate fine particles by mixing one fluid of a high pressure or a liquid of a gas and a gaseous substance, and rotate the gaseous mixture. Therefore, the present invention is not limited by the kind or the number of the fluid sprayed from the nozzle 13.

Various nozzle structures for particulate formation and vortex formation can be applied to the dust collector according to the present invention, and the present invention is not limited to the embodiments shown.

4 shows another embodiment of the dust collector according to the present invention.

Referring to FIG. 4, the dust collector may be constructed as a dual housing structure or a multiple housing structure. The pollutant can be collected in the first housing 41 and the pollutant can be filtered in the second housing 42. Various devices for forming a dust collector may be added separately or installed independently as needed.

A first dust collecting liquid PL1, a collision separating unit 411, a vortex generating unit 12, a diffusing unit 412 and first and second droplet separating units 413 and 414 are disposed inside the first housing 41 . The second dust collecting liquid PL2, the grid unit 421, the filter layer 422, and the droplet removing pad 423 may be disposed inside the second housing 42. The collision separation unit 411, the diffusion unit 412, the grid unit 421, the filter layer 422 and the droplet removal pad 423 are the same as the collision separation unit 411, the diffusion unit 112, The filter layer 422 and the droplet removal pad 423 may have the same or similar function. The first and second droplet separating units 413 and 414 may have a hole or a lattice with a smaller cross-sectional area than the diffusing unit 421 and may have the function of separating droplets from the ascending pollutant collecting gas. Further, the first droplet separating unit 413 may have a hole or a grating having a larger cross-sectional area than the second droplet separating unit 414, a grating having a different shape, or a grating formed in a different position or direction Lt; / RTI > The first and second droplet separation units 413 and 414 may have a structure similar to that of the grid unit 421.

The contaminated gas flowing through the inflow unit 15 can flow into or around the vortex generation unit 14 and is raised while forming a vortex around the vortex generation unit 12 and discharged through the connection unit 415 And can be introduced into the second housing 42 through the introduction unit 431. The contaminants may be removed by the impact gas processing unit inside the second housing 42, and the purified gas may be discharged to the outside through the discharge unit 44.

The connection tube GT may be formed between the connection unit 415 and the introduction unit 431 and the second dust collection fluid PL2 stored in the second housing 42 may be connected to the first housing 41). The water level sensor LS may be disposed in the second housing 42 to detect the level of the second dust-collecting liquid PL2 inside the second housing 42 as needed. When the water level reaches a predetermined level, an injection pump (not shown) is operated to supply the second dust collection liquid PL2 to the first housing 41. [

4 may have the same or similar functions as those of the embodiment of Fig.

The dust collector according to the present invention can be made of various module structures having different components, and the present invention is not limited to the embodiments shown.

The dust collector according to the present invention improves the dust collecting efficiency by mixing contaminated noxious gas or a gas containing odor with the functional liquid for removing water or contaminants from the mist spraying nozzle through the nozzle. The dust collector according to the present invention can be applied to the cooling and circulation control of the hot combustion gas, the deodorization of the gas including the purification or the smell of the gas containing contaminants such as nitrogen oxides, sulfides or mercury. Further, the dust collector according to the present invention can be applied to the removal of odors in a public place such as a domestic indoor odor elimination, a food treatment, and a restaurant.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention . The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

10: dust collector 11: housing
12: vortex generating unit 13: particulate generating nozzle
14: Retention space 15: Inflow unit
16: gas discharge unit 41: first housing
42: second housing
111: collision separation unit 112: diffusion plate
113: grid unit 114: filter layer
115: droplet removal pad 119: circulation discharge unit
121: fluid supply unit 122: gas inflow unit
131: nozzle tip 141: mixed fluid discharge unit
311: Inflow block 331: Whirlpool slit

Claims (7)

A diffuser plate 112 and a diffuser plate 112 disposed above the impingement separating unit 111 with a plurality of pores or slits, the diffuser plate 112 being disposed above the liquid storage space in which the dust- A collision-gas processing unit including a grid unit (113) disposed on the upper side of the vehicle;
A vortex generating unit (12) that extends downward and gradually increases in cross-sectional area, contacts the contaminated gas supplied to the collision separation unit (111) with the polluted gas so as to capture the contaminants into the particles;
A particulate generation nozzle 13 for spraying the dust-collecting liquid into the vortex generation unit 12;
A retention space 14 formed below the vortex generation unit 12 and located between the diffusion plate 112 and the grid unit 113; And
And an inflow unit (15) having a curved path for generating a swirl while introducing the polluted gas into the stay space (14)
Wherein the collision separation unit (111) has a concave lens shape in which a plurality of slits or holes are uniformly distributed and a central portion thereof is convex downward. delete The dust collector according to claim 1, further comprising a gas inflow unit (122) for introducing gas into the particulate generation nozzle (13). delete The dust collector as claimed in claim 1, further comprising a mixed fluid discharge unit (141) disposed below the retention space (14) and having a plurality of holes or meshes. delete 2. The gas-generating vortex generating spraying structure for gas processing according to claim 1, wherein the particulate generation nozzle (13) for spraying the dust-collecting liquid is formed by mixing particulate matter with a high- Dust Collector.

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