KR102552890B1 - A Gas Purification Apparatus with Improved Gas-Liquid Contact Performance - Google Patents

Abstract

The present invention relates to a gas purification device (300) with improved gas-liquid contact performance, comprising: a cleaning chamber (310) providing a space in which gas enters, stays and leaves; a spraying means (350) spraying a cleaning liquid inside the cleaning chamber (310); a blower (320) blowing a contaminated gas into the cleaning chamber (310); a pump (330) pressing and transferring the cleaning liquid to the spraying means; and a cleaning liquid transfer pipe (340) providing a flow path for transferring the cleaning liquid from an outlet of the pump to the spraying means, wherein the gas purification device is provided with a filling material (100) which is filled in the cleaning chamber (310), increases an area of a water film in contact with the contaminated gas and forms turbulent and rotational currents to promote gas-liquid contact, and the gas purification device (300) is provided with a line mixer (200) which is installed in the cleaning liquid transfer pipe (340), generates stirring force by flow energy of fluid and dissolves chemicals, thereby improving gas purification performance.

Description

Gas Purification Apparatus with Improved Gas-Liquid Contact Performance}

The present invention relates to a gas purification device, and more particularly, to a gas purification device in which purification performance is improved through improvement of gas-liquid contact.

As industrialization progresses, due to air pollution and environmental destruction, environmental regulations are strengthened worldwide and efforts are being made to reduce air pollutants. A wet gas purifier used for the purpose of reducing air pollution is a device that purifies by contacting a cleaning liquid with polluted gas, and removes particulates, water-soluble substances, neutralizing or oxidizable substances in the polluted gas.

In the gas purifier in which gas and liquid come into contact as described above, fillers having a large specific surface area are filled to form a filler layer, and a cleaning liquid is sprayed on the filler layer to form a thin water film layer on the surface of the fillers. The pollutant gas to be purified is sent to the filler layer by the blower, and when the water film formed by spraying the cleaning liquid on the surface of the filler and the polluted gas come into contact with each other, mass transfer and reaction occur through gas-liquid contact. In this process, the purification of pollutants It will be done.

Among the pollutants, particulate matter such as dust is collected in the water film, acid gas is neutralized by a cleaning solution in which caustic soda (NaOH) is dissolved, and mercaptan, a source of odor, is oxidized and decomposed by an oxidizing agent such as sodium hypochlorite. do. In this way, since the water film on the surface of the filler is purified by gas-liquid contact, it is desirable to enlarge the surface area of the filler to widen the contact area and increase the contact speed and contact frequency by forming turbulent flow.

The cleaning liquid is continuously sprayed on the filler layer by a spraying means such as a nozzle, so that the water film on the surface of the filler is continuously replaced and regenerated by the newly sprayed cleaning liquid, so that the purification performance can be maintained. In this way, the cleaning fluid must be replaced and regenerated at the gas-liquid contact surface where the water film on the surface of the filler and the polluted gas contact each other, and the purified gas is exhausted by the gas-liquid contact and the polluted gas is contacted with the newly introduced pollutant gas to continue the purification of the polluted gas. It should be done. Therefore, the gas flow is preferably a fast and strong turbulent flow so that the contact interface can be continuously regenerated. As such, in the purification process by gas-liquid contact, supply of cleaning liquid and regeneration of interface through formation of turbulence of gas are very important.

In addition, in the purification of polluted gas, not only the contact between the cleaning liquid water film formed on the surface of the filler and the polluted gas, but also the gas-liquid contact in which the cleaning liquid droplets sprayed downward and the polluted gas blown upward mainly collide with each other is important. Since the collision speed and collision frequency are important in the purification action by direct collision between the cleaning liquid and the pollutant gas, it is desirable to spray the cleaning liquid as finely as possible to increase the total surface area of the droplet and to have a uniform and strong turbulent flow of the pollutant gas. However, conventional fillers focus on the size of pores and porosity in a hurry to reduce blowing resistance, and the specific surface area is provided at a level that is not sufficiently considered. While turbulent flow that increases gas-liquid contact is important, the filler itself is used. Since the formation of turbulence is not properly considered, improvement is required.

In addition, in order to increase the cleaning performance by gas-liquid contact, as described above, the collision speed and frequency of collision between the contaminants in the gas and the cleaning liquid should be increased. Therefore, it is necessary to increase the spraying speed of the cleaning liquid, and it is preferable that the polluted gas has a strong turbulent flow. Among the components of the gas purifier, the places where turbulence is most strongly formed are the inside of the blower casing where the rotor rotates at high speed, and the space around the rotor and the rotor. However, in the conventional gas purifier, elements such as the internal space of the blower casing and the rotor are not properly used for gas-liquid contact, and the blower is used only for generating flow energy for transporting gas, so improvement is required.

In addition, in order to increase the gas purification performance, it is important to increase the above-mentioned gas-liquid contact area as well as increase the contact time and contact frequency to ensure sufficient collection time and sufficient reaction time required for neutralization and oxidation. In the prior art, in order to achieve this purpose, it is uneconomical in terms of land requirements and facility costs by mainly expanding the cleaning room or increasing the filling amount of the filler. However, the duct providing a flow path for transporting the polluted gas is not utilized for purifying the polluted gas even though a considerable residence time is secured while the gas is transported, and thus improvement is required.

In addition, in many cases, a chemical liquid is injected in a conventional washing-type gas purifier, but it is inefficient because a separate line mixer is not provided and the chemical is mainly injected and dissolved in the washing liquid storage tank. It is difficult to install a mechanical line mixer in the washing liquid storage tank disposed at the lower end of the washing tower. An apparatus for mixing and dissolving the cleaning liquid and the chemical liquid being transported by installing a line mixer in the cleaning liquid transfer line extending from the discharge port of the cleaning liquid transfer pump to the spray unit may be considered. However, in the conventional line mixer, a plurality of irregularly bent metal pieces are arranged in a row and installed inside the pipe, so that even and fine turbulence is not formed. There are too many problems and improvement is required.

Patent No. 10-2252558 Patent No. 10-0986245 Patent No. 10-1620266 Patent No. 10-1396227 Patent No. 10-1694095 Patent No. 10-2224430 Patent No. 10-1798427 Patent No. 10-2304952

The present invention has been made to solve the above-mentioned problems, and a filler for improving gas-liquid contact by applying and adding to a gas purification device that cleans pollutants in a gas with a water body or dissolves, neutralizes, and oxidizes pollutants An object of the present invention is to provide a line mixer and a gas purification device having improved purification performance using the same.

One embodiment of a gas purifying device having improved gas-liquid contact performance according to the present invention includes a cleaning chamber 310 in which gas flows in, out, and stays; and a blower 320 through which gas flows; a spraying means 350 for spraying a cleaning solution into the cleaning chamber 310; a pump 330 for pumping the cleaning liquid to the spraying means 350; a cleaning liquid transfer pipe 340 providing a flow path through which the cleaning liquid is transported from the pump 330 to the spray means 350; and a filling material filled in the cleaning chamber 310 to promote gas-liquid contact, wherein the filling material includes: a single pipe member 221 open on both sides and through which fluid can flow; a plurality of blades 225 protruding from the inner surface of the single pipe member 221 toward the center and inclined at a predetermined angle with respect to the longitudinal direction of the single pipe member 221; A plurality of through-holes 105 formed in the blade 225 and through which fluid can flow; and a cutout 106 formed in the single pipe member 221 and opening both sides, wherein the plurality of blades 225 are combined to form one propeller, but the central portion is not connected and each is an independent member. and in the fluid flowing through the single pipe member 221, rotational flow and fine turbulence are formed by the blade 225, through-hole 105, and cutout 106, and gas-liquid contact increases. to be characterized

In the gas purifying device having improved gas-liquid contact performance according to the present invention, the filling material further includes a plurality of inverted streamlined members 107 having a relatively long length compared to the width and a reversed streamlined cross section, and the inverted streamlined member. It is characterized in that fine turbulence is formed by the rear end of the inverted streamlined member (107) in the fluid flowing through the tip end side of the (107).

Another embodiment of the gas purifying device having improved gas-liquid contact performance according to the present invention includes a cleaning chamber 310 in which gas flows in, out, and stays; a blower 320 for flowing gas; a spraying means 350 for spraying a cleaning solution into the cleaning chamber 310; a pump 330 for pumping the cleaning liquid to the spraying means 350; and a cleaning liquid transfer pipe 340 providing a flow path through which the cleaning liquid is transported from the pump 330 to the spray unit 350; and a line mixer 200 installed in the cleaning liquid transfer pipe 340 to agitate the cleaning liquid, wherein the line mixer 200 includes a tubular fluid transfer pipe 210 through which fluid can be transferred. and one or more agitation modules 220 disposed inside the fluid transfer pipe 210, wherein the agitation module 220 includes a tubular member 224 open at both sides and circulating; a plurality of round rods 222 protruding from the inner surface of the tubular member 224 toward the center; and a plurality of plate members 223 relatively thin in thickness compared to their width, wherein the plate member 223 is inclined at a predetermined angle with the longitudinal direction of the tubular member 224. ), fine turbulence is formed in the fluid transported through the tubular member 224, and stirring is performed.

Another embodiment of the gas purifying device having improved gas-liquid contact performance according to the present invention includes a cleaning chamber 310 in which gas flows in, out, and stays; a blower 320 for flowing gas; a spraying means 350 for spraying a cleaning solution into the cleaning chamber 310; a pump 330 for pumping the cleaning liquid to the spraying means 350; a cleaning liquid transfer pipe 340 providing a flow path through which the cleaning liquid is transported from the pump 330 to the spray means 350; and a line mixer 200 installed in the cleaning liquid transfer pipe 340 and configured to agitate the cleaning liquid, wherein the line mixer 200 includes a tubular fluid transfer pipe 210 through which fluid can be transferred. and one or more agitation modules 220 disposed inside the fluid transfer pipe 210, and the agitation module 220 has a single pipe member 221 open on both sides and through which fluid can flow. ); a plurality of blades 225 protruding from the inner surface of the single pipe member 221 toward the center and inclined at a predetermined angle with respect to the longitudinal direction of the single pipe member 221; A plurality of through-holes 105 formed in the blade 225 and through which fluid can flow; and a cutout 106 formed in the single tube member 221 and opening both sides, wherein the plurality of blades 225 are combined to form one propeller, but the central portion is not connected and each is an independent member. And in the fluid transported through the single pipe member 221, rotational flow and fine turbulence are formed by the blade 225, the through hole 105, and the cutout 106, and stirring is performed. to be

In another embodiment of the gas purifying device having improved gas-liquid contact performance according to the present invention, a chemical solution injection facility including a chemical storage tank 370 and a chemical injection pump 380 is further included, and the chemical injection pump ( The discharge port of 380) is configured to inject the chemical solution into a location selected from among the suction part of the cleaning liquid transfer pump 330 and the cleaning liquid transport pipe 340 connecting the inlet of the stirring device 200 and the discharge port of the pump 330. It is characterized in that it communicates so that it can be.

Another embodiment of the gas purifying device having improved gas-liquid contact performance according to the present invention includes a casing 510 having an inlet and an air outlet; a rotor 520 installed inside the casing 510 and provided with a plurality of rotor blades; a driving unit 530 that drives the rotary car 520; a spraying unit 350a for spraying a washing liquid onto the rotary car 520; a pump for pressure-feeding the washing liquid to the spray unit 350a for the rotating vehicle; and a washing liquid transfer pipe 340a providing a passage through which the washing liquid is transported from the pump to the spray means 350a for the rotary car, wherein a strong turbulent flow of gas is formed by the rotation of the rotary car 520. The washing liquid is sprayed by the rotary car spraying means 350a on the rotor 520 inside the casing 510, and the sprayed washing liquid comes into contact with the rotating rotor blades and the gas flow of strong turbulent flow. to be

Another embodiment of a gas purifying device having improved gas-liquid contact performance according to the present invention includes a blower for flowing gas; a duct 600 providing a passage through which gas flowing by the blower is sent; a duct spraying means (350b) for spraying a cleaning liquid into the duct (600); a pump for pressure-feeding the washing liquid to the spraying means for the rotating vehicle (350b); and a washing liquid transfer pipe 340b providing a flow path through which the washing liquid is transported from the pump to the spraying means 350b for the rotary vehicle, and inside the duct 600 through which gas flows by the blower, a duct for The washing liquid is sprayed by the spraying means 350b, and the sprayed washing liquid comes into contact with the flowing gas flow.

In the above embodiment of the gas purifying device having improved gas-liquid contact performance according to the present invention, a fibrous filler 110 composed of laminated fibers of a synthetic resin material having a diameter of 0.3 to 1.5 mm and a specific gravity of 0.9 to 1.6; Including, the filler 100 and the fibrous filler 110 are characterized in that each layer is cross-filled inside the cleaning chamber 310.

In another embodiment of a gas purifying device having improved gas-liquid contact performance according to the present invention, a flat plate member having a relatively long length compared to a width; and a plurality of through-holes formed in the flat material, wherein the flat material is disposed inclined at a predetermined angle with respect to a gas flow direction inside the duct.

The gas purifier according to the present invention has a large specific surface area, generates turbulent flow, and is provided with a filler that improves gas-liquid contact, thereby improving gas-liquid contact performance. , it is possible to provide a gas purifying device in which gas-liquid contact performance is improved by dissolving chemicals.

1 is a conceptual diagram of a first embodiment of a gas purifying device having improved gas-liquid contact performance according to the present invention.
2 is a perspective view showing the concept of a first embodiment of a filler provided in a gas purifying device according to the present invention.
3 is a plan view illustrating the concept of a first embodiment of a filler provided in a gas purifying device according to the present invention.
4 is a perspective view illustrating the concept of a filler provided in a gas purifying device according to a second embodiment of the present invention.
5 is a conceptual diagram of a second embodiment of a gas purifying device having improved gas-liquid contact performance according to the present invention.
6 is a longitudinal cross-sectional view of a first embodiment of a line mixer provided in a gas purifying device according to the present invention.
7 is a cross-sectional view of a first embodiment of a line mixer provided in a gas purifying device according to the present invention.
8 is a longitudinal cross-sectional view of a second embodiment of a line mixer provided in a gas purifying device according to the present invention.
9 is a partially cut-away perspective view of a second embodiment of a line mixer provided in a gas purifier according to the present invention.
10 is a conceptual diagram of a third embodiment of a gas purifying device having improved gas-liquid contact performance according to the present invention.
11 and 12 are conceptual diagrams of a fourth embodiment of a gas purifying device in which gas-liquid contact performance is improved according to the present invention.

Hereinafter, a filler 100 with improved specific surface area and contact performance according to a preferred embodiment of the present invention and a gas purification device using the same will be described in detail with reference to the accompanying drawings.

1 is a conceptual diagram of a first embodiment of a gas purifying device having improved gas-liquid contact performance according to the present invention.

The first embodiment of the gas purifying device 300 according to the present invention for cleaning and purifying gas includes a cleaning chamber 310 providing a space in which gas flows in, staying, and flowing out, and a cleaning liquid inside the cleaning chamber 310. A spray means 350 such as a perforated pipe or a spray nozzle for spraying, a blower 320 for generating flow energy so that polluted gas is transported to the cleaning room 310, a nozzle installed inside the cleaning room 310, etc. A pump 330 for pressure-feeding the cleaning liquid to the spraying means 350 of the pump 330 and a cleaning liquid transfer pipe 340 providing a passage through which the cleaning liquid is transported from the discharge port of the pump 330 to the spraying means 350 do.

The cleaning chamber 310 is filled with a filler that increases gas-liquid contact. The filler provides a surface area on which a water film is formed by the cleaning liquid sprayed from the spraying means 350, forms an appropriate turbulent flow and rotational flow, and Gas purification performance can be improved by increasing gas-liquid contact with the polluted gas sent by the blower 320 inside the seal 310 and increasing mass transfer and solids collection.

Hereinafter, in the description of FIGS. 2 and 3, the configuration and operation of the first to second embodiments of the filler provided in the gas purifier of the first embodiment according to the present invention will be described in detail.

2 is a perspective view showing the concept of a first embodiment of a filler provided in a gas purifying device according to the present invention.

3 is a plan view showing the concept of a first embodiment of a filler provided in a gas purifying device according to the present invention.

The filler 100 according to the first embodiment of the present invention shown in FIGS. 2 and 3 is mainly molded of a hard synthetic resin material, has both sides open to form openings penetrating each other, and has a relatively long length compared to its diameter. It is a configuration in which a blade 225 for generating rotational flow is installed inside a short tubular single pipe member 221 having a mainly circular opening cross section.

A plurality of blades 225 generating rotational flow are provided protruding from the inner surface of the single pipe member 221 toward the center side and disposed inclined at a predetermined angle with respect to the longitudinal direction of the single pipe member 221.

The plurality of blades 225 according to the present invention are combined to form a single propeller, that is, an impeller that induces an axial fluid flow, but converts the flow energy of the fluid into rotational power or an aberration that converts rotational power into flow energy. Its use and configuration are different from the rotating difference of the pump that switches. The blades 225 in the present invention do not require a rotation shaft because they are used to induce a change in the flow form by converting the straight flow of fluid into rotational flow. Therefore, the central axis and the hub are omitted so as to minimize flow path reduction and fluid resistance, and the ends of the blades 225 are gathered and concentrated. are composed of separate independent members.

The fluid flowing toward the opening of the single pipe member 221 composed of the filler 100 of the present invention is converted into a rotational flow by the blade 225 inclined at a predetermined angle while passing through the single pipe member 221. do.

The filling material 100 of the first embodiment is in gas-liquid contact and is filled in the cleaning chamber shown in FIG. When air is supplied, the pollutant gas flow passing through the single pipe opening of the single pipe member 221 is converted into a rotational flow by the blades 225, so that turbulence can be increased and gas-liquid contact can be increased.

As described above, in the filler 100 according to the present invention, gas-liquid contact can be improved because the straight gas flow is converted into rotational flow and turbulent flow is generated.

In addition, if a cutout 106 is further included in the single pipe member 221 and the cutout 106 is further included in the single pipe member 221 and is cut in the longitudinal direction so that the lateral directions communicate with each other and the specific surface area is increased, a water film of the washing liquid can be formed. The surface area of the filling material 100 is increased and more turbulent flow is formed, so that gas-liquid contact can be further improved.

In addition, if a plurality of through-holes 105 passing through the front and rear surfaces of the blade 225 are formed, the specific surface area of the blade 225 is further increased and fluid flows through the through-holes 105. While fine turbulence is additionally generated by the through-holes 105, fluid resistance may be reduced.

The filler 100 according to the present invention having such a configuration has a relatively large porosity and specific surface area compared to its volume, and since rotational flow and turbulence are generated, it can be installed in a reactor or a washing tower to increase the contact area and contact frequency between gas and liquid. there is. Therefore, in the gas purifying device filled with the filler 100 according to the present invention, the dissolution rate at which gaseous, liquid, and solid dissolved substances, etc. are dissolved in the cleaning liquid is increased, so that cleaning performance can be improved and solid materials such as dust It can also be well collected by the washing liquid.

In addition, the filler 100 with a large porosity and specific surface area is composed of a non-toxic material that is not biotoxic and filled in a cleaning room to attach and propagate a biofilm on the surface in a wet state. Biodegradation contained in the gas when contacted with contaminated gas Sexual contaminants can be biodegraded to purify the gas and remove odors.

In addition, since the filler 100 according to the first embodiment of the present invention having the above configuration has a large specific surface area and porosity and improves gas-liquid contact performance, it can be applied to a physicochemical washing tower to which chemicals are injected to increase purification performance. .

The filler 100 according to the present invention having such a configuration has a relatively large porosity and specific surface area compared to its volume, and since rotational flow and turbulence are generated, it can be installed in a reactor or a washing tower to increase the contact area and contact frequency between gas and liquid. there is. Therefore, in the gas purifier in which the filler 100 according to the present invention is filled, the dissolution rate of gaseous, liquid, and solid dissolved substances is increased, so that the cleaning performance can be improved, and solid substances such as dust can be easily cleaned by the cleaning solution. can be captured.

4 is a perspective view illustrating the concept of a second embodiment of a filler provided in a gas purifying device according to the present invention.

As shown in FIG. 4, the filler 100 according to the second embodiment of the present invention is configured to further include, in addition to the filler of the first embodiment, a member whose length is longer than the width and whose cross section is inversely streamlined. The reverse streamlined member 107 may be provided on an outer surface of the single pipe member 221 provided in the filler of the first embodiment. In addition, as shown in FIG. 4, the inverted streamlined member 107 provided in the second embodiment may be configured in a circular shape by extending a plurality from the inlet side outer edge of the single pipe member 221 or configured in a hemispherical shape. there is.

As shown in the enlarged cross-sectional view shown on one side of FIG. 4, the fluid flowing through the tip of the inverted streamlined member 107 is directed toward the rear surface of the inverted streamlined member 107 having an acute angle on both sides and a flat rear surface. It is converted to turbulent flow and gas-liquid contact can be increased. While a general streamlined structure minimizes turbulence and reduces fluid resistance, the filler according to the second embodiment of the present invention additionally configures an inverted streamlined member 107 to increase turbulent flow and further improve gas-liquid contact. it did

5 is a conceptual diagram of a second embodiment of a gas purifying device having improved gas-liquid contact performance according to the present invention.

The gas purifying device 300 according to the second embodiment of the present invention shown in FIG. 5 includes a chemical solution storage tank 370 and a chemical solution injection pump 380 in addition to the gas purifying device 300 of the first embodiment described above. A line mixer 200 is installed in the washing liquid transport pipe 340 between the discharge port of the pump 330 and the spraying means 350 and further includes a chemical liquid input facility including a), in which agitation is performed by the flow energy of the washing liquid. It's about examples.

In order to inject the chemical into the inlet of the cleaning liquid transfer pump 330, the discharge port of the chemical liquid injection pump 380 is communicated, or the cleaning liquid transfer connecting the inlet of the line mixer 200 and the discharge port of the pump 330 The pipe 340 may be communicated to inject a chemical solution. If an oxidizing agent or the like is introduced into the cleaning liquid storage tank 360 and dissolved therein, the oxidizing agent may be consumed and wasted by reducing substances in the storage tank while remaining in the storage tank. Therefore, in the gas purifying device of the second embodiment, the oxidizing agent is directly transported to the atomizing unit 350 to be used for the gas purification reaction, thereby preventing waste of the oxidizing agent due to reducing substances in the storage tank. As such, in this embodiment, chemicals such as an oxidizing agent are directly injected into the cleaning liquid transfer pipe 340, and the cleaning liquid is stirred and dissolved while being transferred using the line mixer 200, and then used immediately for gas purification, thereby reducing unnecessary chemical waste. there will be

Hereinafter, the line mixer provided in the gas purifier according to the second embodiment of the present invention will be described in detail in the following description of FIGS. 6 to 9.

6 is a longitudinal cross-sectional view of a first embodiment of a line mixer provided in a gas purifying device according to the present invention.

7 is a cross-sectional view of a first embodiment of a line mixer provided in a gas purifier according to the present invention.

The line mixer 200 of the first embodiment according to the present invention provided in the gas purifier of the second embodiment described above includes a tubular fluid transport pipe 210 through which fluid can be transported and the inside of the fluid transport pipe 210 It includes one or more agitation modules 220 disposed in, and the agitation module 220 includes a tubular member 224 open on both sides and circulating, and from the inner surface of the tubular member 224 toward the center side. It is configured to include a plurality of protruding round rods 222 and a plurality of flat plates 223 relatively thin in thickness compared to their width.

The fluid transfer pipe 210 provided in the line mixer 200 is installed to constitute a part of the cleaning liquid transfer pipe 340 through which the cleaning liquid is transported by a connecting portion 226 such as a flange, and provides a passage through which the cleaning liquid can flow. will do A plurality of flat plates 223 are installed on each round bar 222 so as to be inclined at a predetermined angle with the longitudinal direction of the fluid transport pipe 210, and transported through the tubular member 224 inside the fluid transport pipe 210. As the fluid passes through the round bar 222 and the plate member 223, fine turbulence is formed and agitation is performed by the flow energy of the fluid flowing. In addition, one side of the flat members 223 installed on the round bar 222 may be connected to another adjacent flat member so that the round bar and the flat member may be formed in a screw shape.

In the cleaning type gas purifier, a chemical input facility is installed to inject neutralizers, oxidizing agents, surfactants, etc. into the cleaning liquid. .

The line mixer 200 according to the present invention includes a cleaning chamber in which gas-liquid contact and cleaning are performed while gas flows in, out, and stays, a blower for flowing gas, a spraying means for spraying a cleaning liquid into the cleaning chamber, and a spraying unit for spraying the cleaning liquid. It is installed in the washer fluid transfer pipe 340 of the gas purifying device, which includes a pump for pressure-feeding the means and a washer fluid transfer pipe providing a flow path through which the washer fluid is transported from the pump to the atomizing means. , cleaning solution containing an oxidizing agent and the like can be stirred.

8 is a longitudinal cross-sectional view of a second embodiment of a line mixer provided in the gas purifier according to the present invention.

9 is a partially cut-away perspective view of a second embodiment of a line mixer provided in a gas purifier according to the present invention.

* The line mixer 200 of the second embodiment provided in the gas purifier according to the present invention includes a tubular fluid transport pipe 210 through which fluid can be transported and one or more tubular fluid transport pipes 210 disposed inside the fluid transport pipe 210. It is configured to include a module 220 for stirring.

The agitation module 220 is mainly formed of a hard synthetic resin material and is composed of a single pipe member 221. Both sides of the single pipe member 221 are open and in communication to form a passage having a circular cross section. Both sides are penetrated to form a passage, and blades 225 for generating rotational flow are installed inside the tubular single pipe member 221, which is relatively short in length compared to its diameter and whose cross section is mainly circular.

The blades 225 that generate rotational flow are configured to protrude from the inner surface of the single pipe member 221 toward the center side, and are arranged obliquely at a predetermined angle with the longitudinal direction of the single pipe member 221. It consists of a plurality of blades.

The plurality of blades 225 are combined to form a single propeller, that is, a propeller that induces an axial fluid flow, but includes an aberration that converts fluid flow energy into rotational power or a pump that converts rotational power into flow energy. It is different from the rotary car in terms of use and configuration. Since the blades 225 in the present invention are used to change the flow form of a fluid that converts a linear flow of fluid into a rotational flow, the central axis and the hub are omitted to minimize flow path narrowing and fluid resistance, and the ends of the blades 225 The parts are gathered and concentrated, and in a general propeller, the central part where the rotation shaft and hub are installed is empty as space. Therefore, the blades 225 are not connected to each other and are composed of separate independent members.

The line mixer 200 of the second embodiment described above is installed in the fluid cleaning fluid transport pipe 340 by the connection part 226, and when the cleaning fluid is transferred through the cleaning fluid transport pipe 340 and the fluid transport pipe 210, the single pipe As the cleaning liquid flows through the member 221, the fluid flow is converted into a rotational flow by the blades 225, and turbulence is increased, resulting in agitation.

In this way, the agitation module 220 has a tubular member 224 open on both sides and through which fluid can flow, and protrudes from the inner surface side of the tubular member 224 toward the center side, and the tubular member 224 and the tubular member 224 It is a configuration including a plurality of blades 225 disposed inclined at a predetermined angle with the longitudinal direction of the fluid transfer pipe 210 . The plurality of blades 225 are combined to form one impeller, but the central portion is not connected and is composed of independent members.

In addition, the blade 225 is configured to include a plurality of through-holes 105 through which fluid can flow, and the fluid passes through and flows through the plurality of through-holes 105 configured in the blade 225. In addition to the rotational flow by 225, fine turbulence is formed, and resistance to fluid flow can be reduced.

Rotational flow and fine turbulence are formed in the fluid transported through the fluid transfer pipe 210 in which the agitation module 220 is disposed, so that the fluid is agitated and chemicals and the like can be dissolved.

The line mixer 200 according to the second embodiment of the present invention includes a cleaning chamber in which gas flows in, out of, and stays, a blower for flowing gas, a spraying means for spraying a washing liquid into the inside of the washing chamber, and the washing liquid to the spraying means. It is installed in the washer fluid transfer pipe 340 of the gas purifier, which includes a pump for pumping pressure and a washer fluid transfer pipe 340 providing a flow path through which the washer fluid is transported from the pump to the spraying means, and uses the flow energy of the fluid. Thus, the stirring function can be performed.

In addition, the fibrous filler 110 having a large specific surface area and porosity may be filled in the cleaning chamber 310 provided in the gas purifying devices according to the present invention in addition to the filler 100 according to the present invention. The fibrous filler 110 has a diameter in the range of 0.3 to 1.5 mm, a specific gravity in the range of 0.9 to 1.6, polyethylene (PE), polypropylene (PP), polyvinyl chloride (PVC), polyvinyl dichloride (PVDC), etc. It is preferable that filamentous bodies of the same synthetic resin material are woven, knitted, or bonded with an adhesive to have a large porosity and to be sparsely stacked in a mat shape.

In addition, the fibrous filler 110 and the filler 100 according to the present invention are laminated together inside the cleaning chamber 310, and the gas-liquid contact can be further increased by crossing and stacking alternately to form layers at a predetermined height. there is.

10 is a conceptual diagram of a third embodiment of a gas purifying device having improved gas-liquid contact performance according to the present invention.

A gas purifying device according to a third embodiment of the present invention includes a casing 510 provided with an inlet and an air outlet, a rotor 520 disposed inside the casing 510 and provided with a plurality of rotary blades, and the A blower 320 including a driving unit 530 that drives the rotary wheel 520, and a spraying means 350a for the blower that sprays a cleaning solution on the rotary wheel 520 rotating inside the casing 510 And, a pump (not shown) for pressure-feeding the washing liquid to the blower spraying means 350a, and a washing liquid transfer pipe 340a providing a flow path through which the washing liquid is transferred from the pump to the blower spraying means 350a. It is composed by

The washing liquid is sprayed by the blower spraying means 350a on the inside of the rotor 520 of the casing 510 where a strong turbulent gas flow is formed by rotation, and the sprayed washing liquid is applied to the rotating blades and strong The gas is cleaned by being dispersed and contacted while colliding with the gas flow of the turbulent flow. In addition, since a water film of cleaning liquid is formed on the surface of the rotor 520 and the interface in contact with the polluted gas is replaced and regenerated by the rapidly rotating rotational force, the purification performance can be further improved.

As described above, in the gas purifier according to the third embodiment of the present invention, focus on the fact that the strongest turbulence is formed in the inside of the blower casing 510 and the rotor 520 rather than in the cleaning chamber where the gas sent from the blower flows. By spraying the washing liquid on the rotor 520, gas-liquid contact can be further increased and purification performance can be improved.

11 and 12 are conceptual diagrams of a fourth embodiment of a gas purifying device in which gas-liquid contact performance is improved according to the present invention.

A gas purifying device according to a fourth embodiment of the present invention includes a blower (not shown) for flowing gas, a duct 600 for providing a flow path through which gas flowing by the blower is transported, and the duct 600. A duct spraying means (350b) for spraying a cleaning liquid into the inside, a pump (not shown) for pressurizing the washing liquid to the duct spraying means (350b), and a cleaning liquid providing a pressure flow path for the washing liquid to the spraying means (350b). A cleaning solution is sprayed by a duct spraying means 350b into the duct 600 including a transfer pipe 340b and gas flows by a blower, and cleaning is performed by colliding with and contacting the flowing gas flow. am.

In addition, the inner space of the duct 600 may further include a flat plate member 610 having a relatively long length compared to its width, and a plurality of through holes 611 formed in the flat plate member. The flat plate member 610 is disposed inclined at a predetermined angle (θ) with the direction of gas flow flowing inside the duct 600 to increase turbulence formation and gas-liquid contact and to increase the flow of gas by the flat plate member 610. Resistance can be minimized.

The gas purifying device 300 of the third and fourth embodiments described above may be configured as an independent and separate gas purifying device. In addition, the gas purification performance can be further improved by being added to the blower or duct provided in the gas purification devices of the first to second embodiments equipped with a cleaning chamber, a spraying means, a filler, a line mixer, and the like.

100: filling material 105: through hole
106: incision 107: reverse streamlined member
110: fibrous filler 200: line mixer
210: fluid transfer pipe 220: module for agitation
221: single pipe member 222: round bar
223: flat material 224: tubular member
225: blade 226: connection
300: gas purifier 310: washing room
320: blower 330: pump
340, 340a, 340b: cleaning solution transfer pipe 350, 350a, 350b: spraying means
360: cleaning liquid storage tank 370: chemical liquid storage tank
380: chemical injection pump 510: casing
520: rotational vehicle 530: driving unit
600: duct

Claims (2)

A blower for flowing gas; and
In the gas purifying device comprising a; duct 600 providing a passage through which gas flowing by the blower is sent,
a duct spraying means (350b) for spraying a cleaning liquid into the duct (600);
a pump that pressurizes the cleaning liquid to the spraying means (350b); and
A cleaning liquid transfer pipe 340b providing a flow path through which the cleaning liquid is transferred from the pump to the spraying means 350b;
Inside the duct 600 where the cleaning liquid is sprayed by the duct spraying means 350b, a flat plate member 610 having a relatively long length compared to the width is provided,
A plurality of through holes 611 are formed in the flat material 610,
The plate material 610 is disposed inclined at a predetermined angle θ with the gas flow direction inside the duct 600,
The washing liquid is sprayed by the spraying means (350b) inside the duct 600 through which the gas flows by the blower, and the sprayed washing liquid comes into contact with the flowing gas flow to utilize the duct for gas purification. A gas purifying device with improved gas-liquid contact performance. delete

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