KR102272956B1 - Alkaline waste gas treatment equipment using co2 - Google Patents

Abstract

The present invention relates to an alkaline waste gas treatment facility using CO2 which can efficiently and effectively treat alkaline ammonia waste gas discharged from semiconductor factories, chemical plants and chemical plants without harmful substances such as sulfuric acid. According to an embodiment of the present invention, an alkaline waste gas treatment facility using CO2 comprises: a waste gas treatment scrubber body; an exhaust gas supply unit configured to supply exhaust gas to the waste gas treatment scrubber body and discharge a neutralized exhaust gas through treated water comprising carbon dioxide (CO2) from the waste gas treatment scrubber body; a treated water supply unit configured to supply treated water containing carbon dioxide gas to the waste gas treatment scrubber body; a carbon dioxide supply unit for supplying the treated water supplied from the treated water supply unit to contain carbon dioxide; a modular filter-demister means provided in plural in an exhaust gas flow direction in the waste gas treatment scrubber body and configured to increase a contact area between the exhaust gas and the treated water; and a contorl module unit configured to control the exhaust gas supply unit, treated water supply unit and carbon dioxide supply unit.

Description

Alkaline waste gas treatment facility using CO2 gas {ALKALINE WASTE GAS TREATMENT EQUIPMENT USING CO2}

The present invention relates _{to a facility for treating alkaline waste gas using CO 2} gas, and more particularly, efficiently and effectively treating alkaline ammonia waste gas discharged from semiconductor factories, chemical plants, and chemical plants without hazardous substances such as sulfuric acid It relates to an alkaline waste gas treatment facility using _{CO 2} that can.

Most of the alkaline exhaust gas emitted from semiconductor manufacturing plants, chemical plants, and chemical plants is ammonia gas, and when it is released into the atmosphere as it is, it causes environmental pollution and odor.

Therefore, a neutralization process for lowering the content of harmful components to below an allowable concentration is absolutely necessary for such exhaust gas, and for this neutralization process, a huge amount of chemicals such as sulfuric acid and hydrochloric acid are used.

Chemicals such as sulfuric acid and hydrochloric acid are hazardous chemicals and accident-preparing substances, so they have difficulties in handling and a high risk of chemical leakage. Therefore, businesses using them had to install safety-related facilities such as oil repellents for safety management of chemical accidents, and maintenance costs were also a big problem.

As an apparatus of the related art for treating waste gas containing ammonia, it is disclosed in Korean Patent Registration No. 10-0938911.

The above-mentioned patent publication discloses a technique for reducing the generation of wastewater by providing a pyrolysis unit for heating the waste gas containing ammonia to decompose it into nitrogen and hydrogen, and a combustion unit for injecting air into the waste gas passing through the pyrolysis unit to burn it.

However, in the above-mentioned patent publication, when the waste gas containing ammonia is burned in the combustion part, the temperature of the combustion part is continuously maintained at a high temperature at a specific point, and damage to the waste gas processing device may occur, thereby reducing the durability of the waste gas processing device. have.

In addition, the technology disclosed in the above-mentioned patent publication has a structure in which a heating means is disposed on the outer periphery of the reactor, and thermal decomposition and combustion are performed in the middle part of the reactor, so it is suitable for treating a small amount of waste gas containing ammonia, but the scale There is a structural limit to increasing the capacity of the waste gas treatment device in order to treat the waste gas containing ammonia generated in large quantities in large factories, so it is difficult to treat the waste gas containing a large amount of ammonia, and the waste gas containing a large amount of ammonia There is a problem in that the installation cost increases because the number of waste gas treatment devices needs to be increased in order to treat the waste gas.

Republic of Korea Patent Publication No. 10-0938911 (published on Jan. 27, 2010) Republic of Korea Patent Publication No. 10-11542b39 (2012.05.07. Announcement) Republic of Korea Patent Publication No. 10-1239877 (2013.03.06. Announcement)

The present invention is to provide an alkaline waste gas treatment facility using _{CO 2} gas that can efficiently and effectively treat alkaline ammonia waste gas discharged from semiconductor factories, chemical plants, and chemical plants without dangerous substances such as sulfuric acid.

More specifically, the present invention is injected into the scrubber to chemicals such as sulfuric acid in a pressurized state, the neutralization process, and in particular, CO ₂ gas in place, and using an alkaline exhaust gas CO ₂ gas to a CO ₂ gas to bubble form of micros This can shorten the neutralization time and reduce the _{amount of CO 2} used, and the injected CO ₂ An object of the present invention is to provide an alkaline waste gas treatment facility using _{a CO 2} gas capable of maximizing the reaction efficiency of the gas and the alkaline gas.

The problems to be solved of the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

According to one aspect of the present invention for achieving the above objects and other features of the present invention, as an alkaline waste gas treatment facility for neutralizing exhaust gas discharged from a facility generating exhaust gas, which is an alkaline waste gas, a waste gas treatment scrubber body ; an exhaust gas supply unit configured to supply exhaust gas to the waste gas treatment scrubber body and discharge the neutralized exhaust gas through treated water including carbon dioxide (CO _{2 ) from the waste gas treatment scrubber body;} a treated water supply unit configured to supply treated water containing carbon dioxide gas to the waste gas treatment scrubber body; a carbon dioxide supply unit for supplying the treated water supplied from the treated water supply unit to contain carbon dioxide; a modular filter-demister means provided in the waste gas treatment scrubber body in a flow direction of the exhaust gas and configured to increase a contact area between the exhaust gas and the treated water; and a control module unit configured to control the exhaust gas supply unit, the treated water supply unit, and the carbon dioxide supply unit.

In the present invention, the exhaust gas supply unit includes an exhaust gas supply duct connected to a gas inlet of the waste gas treatment scrubber body, a treatment exhaust gas discharge duct connected to the waste gas treatment scrubber body, and the treatment exhaust gas discharge duct and a blower provided in the , wherein the treated water supply unit includes a treated water storage tank configured to be in communication with the waste gas treatment scrubber body at a lower portion of the waste gas treatment scrubber body, and one end of which is treated water from the treated water storage tank. It is provided to flow in, the other end is a treated water supply pipe configured to extend toward the upper side of the waste gas treatment scrubber body, and is branched from the treated water supply pipe, and the modular filter-demister means with respect to the flow direction of the exhaust gas a branch pipe provided on the front side of a branch pipe, a plurality of injection nozzles provided in the branch pipe for spraying treated water to the modular filter-demister means, and a treatment water supply pipe provided in the control module unit to control the It may include a pump driven to pump the treated water by the.

In the present invention, the carbon dioxide supply unit includes: a treated water flow pipe having one end connected to one side of the treated water storage tank and the other end connected to the other side of the treated water storage tank; a circulation pump provided in the treated water flow pipe to pump the treated water stored in the treated water storage tank to circulate through the treated water flow pipe; a circulating water flow meter and a circulating water pressure gauge provided in the treated water flow pipe to detect the flow rate and pressure of the circulated treated water; a carbon dioxide supply pipe having one end connected to the carbon dioxide supply line and the other end connected to the treated water flow pipe; a carbon dioxide supply control means provided in the carbon dioxide supply pipe to detect and control the flow rate and pressure of the supplied carbon dioxide; a carbon dioxide-treated water mixing device provided at the junction of the treated water flow pipe and the carbon dioxide supply pipe, the carbon dioxide being included in the treated water; a dissolution tank provided on a downstream side of the junction of the treated water flow pipe and the carbon dioxide supply pipe and configured to increase the dissolution rate of carbon dioxide in the treated water containing carbon dioxide; and an internal ejection pipe connected to the other end of the treated water flow pipe and extending into the treated water storage tank to eject the treated water containing carbon dioxide.

In the present invention, the carbon dioxide-treated water mixing device includes an inlet connector and an outlet connector connected to the treated water flow pipe at both ends, and at least one carbon dioxide inlet connector connected to the carbon dioxide supply pipe in the central part. and may be composed of a tubular body having a mixing flow path formed therein.

In the present invention, the mixing flow path has a relatively smaller diameter at the central portion than at both end sides, and is tapered to expand toward both ends with respect to the central portion, and the carbon dioxide inlet connector is on the central side. It may be formed in communication.

In the present invention, the dissolution tank, a tank body having a space inside which is closed; a treated water inlet formed at one end of the tank body and into which treated water in which carbon dioxide is dissolved is introduced; a treated water outlet formed at the other end of the tank body through which treated water in which carbon dioxide is dissolved is discharged; and a partition wall member for zigzag flow that is provided with a gap inside the tank body and causes the treated water introduced through the treated water inlet to flow in a zigzag and discharged through the treated water outlet.

In the present invention, the dissolution tank, a tank body having a space inside which is closed; a treated water inlet formed in the upper central portion of the tank body; a treated water outlet formed in the center of the lower end of the tank body; a support pipe provided on the inner lower surface of the tank body, communicating with the treated water outlet, protruding at a predetermined height, and having one or more treated water outlet holes formed at the lower end thereof; The lower back surface is coupled to the upper end of the support tube, a cross-section "U"-shaped treated water internal receptor; and a partition wall member for flow provided on the inner wall of the tank body and the outer surface of the treated water internal receptor so that the treated water flows in a zigzag and discharged to the treated water outlet through the treated water discharge hole.

In the present invention, the internal jet pipe, a tubular body; an ejection hole formed with a gap in the tubular body; and a mixing member provided inside the tubular body, the treated water being provided to be flowable, and stirring the treated water containing carbon dioxide.

In the present invention, the carbon dioxide supply unit may include: a dissolution tank internal pressure control module configured between the dissolution tank and the treated water storage tank to maintain a constant pressure in the dissolution tank; And a pH or electrical conductivity detection module for controlling the supply of carbon dioxide by detecting the pH or electrical conductivity of the treated water to increase the treatment efficiency of the exhaust gas by the treated water containing carbon dioxide flowing into the waste gas treatment scrubber body; may include

In the present invention, the modular filter-demister means includes: an enclosure-type outer frame member formed to allow air flow and having an opening on one side; a plurality of filter modules stacked on the outer frame member to allow air flow; a spacing adjusting member provided to adjust the spacing distance between the filter modules; a closing frame member that covers and finishes the opening of the outer frame member and is formed to allow air flow; and a detachable coupling means configured to detachably couple the outer frame member, the finishing frame member, and the adjacent outer frame member.

In the present invention, in the outer frame member, a circular or polygonal central frame portion is formed in the center of four sides and a surface opposite to the open portion, and a lattice in the longitudinal and transverse directions is symmetrically based on the central frame portion. A frame portion is formed, and the finishing frame member includes an outer frame formed to correspond to the open portion of the outer frame member, and a grid frame formed on the outer frame, wherein the grid frame of the finishing frame member is circular or A polygonal central frame portion may be formed, and a lattice frame portion may be formed symmetrically in the longitudinal and transverse directions based on the central frame portion.

In the present invention, the plurality of filter modules, a contact area increasing portion for expanding the contact area for waste gas and washing water is formed, and a first detachable coupling that is detachably coupled to the second filter member and the interval adjusting member below. a first filter member of a lattice structure formed with a portion; and a contact area increasing part for expanding a contact area for waste gas and washing water is formed on one surface of the first filter member to be detachably stacked with a gap, and detachable from the first filter member and the spacing adjusting member and a second filter member having a lattice structure formed with a second detachable coupling portion coupled to the first.

In the present invention, the contact area increasing part is formed of a plurality of protruding protrusions protruding from one surface of the first filter member and the second filter member, and one of the first detachable coupling part and the second detachable coupling part is , is formed with a coupling protrusion protruding from one surface of the first filter member and the second filter member, and the other one of the first detachable coupling part and the second detachable coupling part is, the first filter member and the second filter member It may be formed as a coupling groove on the other surface of the

In the present invention, it is preferable that the contact area increasing part, the first detachable coupling part, and the second detachable coupling part are formed at intersections of the lattice structure, respectively.

In the present invention, the spacing adjusting member includes a lattice frame portion, and a coupling protrusion protruding from the lattice intersection of the lattice frame portion, and the detachable coupling means is formed extending from the upper end and the lower end of the outer frame member A first coupling flange portion, a second coupling flange portion extending in a direction parallel to the first coupling flange portion from the outer end of the outer frame of the closing frame member, and the first coupling flange portion and the second coupling plan It may include one or more fastening holes formed in the branch, and a fastener detachably fastened to the fastening holes.

In the present invention, the fastening hole is formed as a long hole, the fastener has a fastener body formed in an "L" shape, and one end of the fastener body is formed with a fastening protrusion of a shape corresponding to the long hole, A knob piece may be formed at the other end of the fastener body.

According to the alkaline waste gas treatment facility using _{CO 2} gas according to the present invention, the following effects are provided.

First, the present invention has the effect of reducing the use of hazardous chemicals such as sulfuric acid in the industry and reducing the safety management cost of the workplace by replacing the treatment agent (or treatment chemical) for the alkaline waste gas treatment with CO _{2 gas.}

Second, the present invention maximizes the contact area between the alkaline waste gas to be treated and the washing water, thereby increasing the treatment efficiency even under poor conditions, that is, high superficial velocity and low liquid gas ratio.

Third, the present invention is configured in a modular type and can be easily changed and applied according to the processing capacity or the size of the scrubber, thereby securing versatility.

Fourth, the present invention can facilitate assembly, separation, and cleaning, thereby providing excellent maintainability.

Effects of the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a schematic diagram of an alkaline waste gas treatment facility using _{CO 2} according to the present invention.
2 is a cross-sectional view showing a carbon dioxide-treated water mixing device included in the alkaline waste gas treatment facility using _{CO 2} according to the present invention.
3 is a configuration diagram showing a dissolution tank included in the alkaline waste gas treatment facility using _{CO 2} according to the present invention.
Figure 4 is a configuration diagram showing another embodiment of the dissolution tank included in the alkaline waste gas treatment facility using _{CO 2} according to the present invention.
5 is a partially cut-away perspective view showing a carbon dioxide-treated water ejection pipe included in the alkaline waste gas treatment facility using _{CO 2} according to the present invention.
6 is a perspective view of the modular filter-demister means included in the alkaline waste gas treatment facility using _{CO 2} according to the present invention viewed from the upper side.
7 is a perspective view of the modular filter-demister means included in the alkaline waste gas treatment facility using _{CO 2} according to the present invention viewed from the front side.
8 is a view showing an outer frame member constituting the modular filter-demister means included in the alkaline waste gas treatment facility using _{CO 2} according to the present invention.
9 is a perspective view of the first demister-filter member constituting the modular filter-demister means included in the alkaline waste gas treatment facility using _{CO 2} according to the present invention, viewed from the upper side and the distribution side.
10 is a perspective view of the second demister-filter member constituting the modular filter-demister means included in the alkaline waste gas treatment facility using _{CO 2} according to the present invention viewed from the upper side and the distribution side.
11 is a perspective view of the interval adjusting member constituting the modular filter-demister means included in the alkaline waste gas treatment facility using _{CO 2} according to the present invention viewed from the upper side.
12 is a perspective view showing a case where the modular filter-demister means included in the alkaline waste gas treatment facility using _{CO 2} according to the present invention is configured as 2×2.
13 is a block diagram schematically illustrating the configuration of a control module unit included in an alkaline waste gas treatment facility using _{CO 2} according to the present invention.
_{14 is a graph for explaining a state in which CO 2} is dissolved in the form of CO2 (H2CO3) and HCO3- in treated water.
15 is a graph of _{CO 2} solubility according to pressure and temperature.

Additional objects, features and advantages of the present invention may be more clearly understood from the following detailed description and accompanying drawings.

Prior to the detailed description of the present invention, the present invention can make various changes and can have various embodiments, and the examples described below and shown in the drawings are not intended to limit the present invention to specific embodiments. No, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

When a component is referred to as being “connected” or “connected” to another component, it is understood that the other component may be directly connected or connected to the other component, but other components may exist in between. it should be On the other hand, when it is said that a certain element is "directly connected" or "directly connected" to another element, it should be understood that no other element is present in the middle.

The terms used herein are used only to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In this specification, terms such as "comprises" or "have" are intended to designate that the features, numbers, steps, operations, components, parts, or combinations thereof described in the specification exist, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof.

In addition, terms such as "...unit", "...unit", "...module", etc. described in the specification mean a unit that processes at least one function or operation, which includes hardware or software or hardware and It can be implemented by a combination of software.

In addition, in the description with reference to the accompanying drawings, the same components are given the same reference numerals regardless of the reference numerals, and the overlapping description thereof will be omitted. In describing the present invention, if it is determined that a detailed description of a related known technology may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

_{Hereinafter, an alkaline waste gas treatment facility using a CO 2} gas according to the present invention according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 is the carbon dioxide contained in the alkaline waste gas treatment system using CO ₂ in accordance with an alkaline waste gas treatment plant using a CO ₂ according to the present invention, a flow diagram, the invention Figure 2 is present - is a sectional view showing the process could mixing apparatus, Figure 3 is a block diagram showing the dissolution tank contained in the alkaline waste gas treatment plant using a CO ₂ according to the invention, Figure 4 showing another embodiment of the melting tank included in the treatment facility alkaline waste gas using the CO ₂ in accordance with the present invention It is a configuration diagram. 5 is a partially cut-away perspective view showing a carbon dioxide-treated water ejection pipe included in the alkaline waste gas treatment facility using _{CO 2} according to the present invention. 6 is a perspective view of the modular filter-demister means included in the alkaline waste gas treatment facility using _{CO 2} according to the present invention viewed from the upper side, and FIG. 7 is an alkaline waste gas treatment facility using _{CO 2 according to the present invention Included in the facility} It is a perspective view of the modular filter-demister means viewed from the front side. 8 is a view showing an outer frame member constituting a modular filter-demister means included in an alkaline waste gas treatment facility using _{CO 2} according to the present invention, and FIG. 9 is an alkaline waste gas treatment using _{CO 2 according to the present invention.} The first demister-filter member and the second demister-filter member constituting the modular filter-demister means included in the facility are perspective views viewed from the upper side, and FIG. 10 is an alkaline waste gas using _{CO 2 according to the present invention.} The first demister-filter member and the second demister-filter member constituting the modular filter-demister means included in the treatment facility are perspective views viewed from the distribution side, and FIG. 11 is an alkaline using _{CO 2 according to the present invention.} The modular filter included in the waste gas treatment facility is a perspective view from the upper side of the interval adjusting member constituting the demister means, and FIG. 12 is the modular filter included in the alkaline waste gas treatment facility using _{CO 2 according to the present invention-de} It is a perspective view which shows the case where the Mr. means is comprised by 2x2. 13 is a block diagram schematically illustrating the configuration of a control module unit included in an alkaline waste gas treatment facility using _{CO 2} according to the present invention.

_{The alkaline waste gas treatment facility using CO 2} according to the present invention is an alkaline waste gas treatment facility for neutralizing waste gas (exhaust gas) discharged from a facility generating exhaust gas, which is an alkaline waste gas, such as a semiconductor factory, a chemical plant, a chemical plant, etc. , As shown in Figures 1 to 13, largely waste gas treatment scrubber body 100; exhaust gas supply unit 200; treated water supply unit 300; Carbon dioxide supply unit 400; and modular filter-demister means 500 ; and a control module unit 600 .

_{Specifically, the alkaline waste gas treatment facility using CO 2} according to the present invention is an alkaline waste gas for neutralizing waste gas (exhaust gas) discharged from a facility generating exhaust gas, which is an alkaline waste gas, such as a semiconductor factory, a chemical plant, and a chemical plant. As a treatment facility, as shown in Figs. 1 to 13, a waste gas treatment scrubber body 100; An exhaust gas supply device configured to supply exhaust gas to one side of the waste gas treatment scrubber body 100 and discharge the neutralized exhaust gas through treated water including _{carbon dioxide (CO 2 ) from the waste gas treatment scrubber body 100 .} part 200; The treated water supply unit 300 configured to supply treated water (washing water) containing carbon dioxide gas supplied through the carbon dioxide (CO _{2 ) supply unit 400 to the waste gas treatment scrubber body 100 ;} a carbon dioxide supply unit 400 for supplying the treated water supplied from the treated water supply unit 300 to contain carbon dioxide gas; a modular filter-demister means 500 provided in a plurality of exhaust gas flow directions inside the waste gas treatment scrubber body 100 and configured to increase a contact area between the exhaust gas and the treated water; and a control module unit 600 configured to control the exhaust gas supply unit 200 , the treated water supply unit 300 , and the carbon dioxide supply unit 400 .

The waste gas treatment scrubber body 100 is an enclosure type such that the exhaust gas introduced into the exhaust gas inlet 101 on one side flows from one side to the other side, for example, flows in a horizontal flow as shown in the drawing and is discharged to the other side exhaust port 102 . is formed with The exhaust gas passing through the waste gas treatment scrubber body 100 passes through the modular filter-demister means 500 provided in the waste gas treatment scrubber body 100 .

Here, the waste gas treatment scrubber body 100 is configured to communicate with the treated water storage tank 310 constituting the treated water supply unit 300 to be described below by opening the lower portion thereof.

The exhaust gas supply unit 200 is connected to the exhaust gas duct 10 through which alkaline waste gas is discharged, such as semiconductor factories, chemical factories and chemical plants, and supplies exhaust gas to one side of the waste gas treatment scrubber body 100 . and exhaust gas neutralized through treated water including carbon dioxide (CO ₂ ) from the waste gas treatment scrubber body 100 .

Specifically, the exhaust gas supply unit 200 has one end connected to the exhaust gas duct 20 of the facility for discharging waste gas, and the other end is the front end (exhaust gas flow) of the waste gas treatment scrubber body 100 . The exhaust gas supply duct 210 connected to the exhaust gas inlet 101 of the end of the side that is introduced as a reference, and the rear end of the waste gas treatment scrubber body 100 (on the side that is discharged based on the flow of exhaust gas) end) and a treatment exhaust gas discharge duct (or pipe) 220 connected to the discharge port 102 , and a blower 230 provided on the treatment exhaust gas discharge duct 220 .

A damper 211 capable of adjusting the amount of exhaust gas supplied to the waste gas treatment scrubber body 100 may be configured on the exhaust gas supply duct 210 .

The exhaust gas (waste gas) supplied by the exhaust gas supply unit 200 configured in this way is the exhaust gas duct 20 of the facility → the exhaust gas supply duct 210 → the damper 211 → the waste gas treatment scrubber body ( 100) front end inlet 101 → scrubber body 100 → waste gas treatment scrubber body 100 rear end outlet 102 → treatment exhaust gas discharge duct 220 → blower 230 → treatment exhaust gas discharge Duct 220 has a flow outlet.

The exhaust gas supply unit 200 (specifically, the damper 211 and the blower 230 ) cooperates with other components to be described below and the flow of exhaust gas by the control of the control module unit 600 . This is controlled.

Next, the treated water supply unit 300 converts treated water (washing water) containing carbon dioxide gas supplied through the _{following carbon dioxide (CO 2 ) supply unit 400 to the waste gas treatment scrubber body 100 .} It is configured to neutralize the exhaust gas by supplying it, and circulate and use the treated water used for the neutralization treatment again.

Specifically, the treated water supply unit 300 includes a treated water storage tank 310 configured to communicate with the waste gas treatment scrubber body 100 at the lower portion of the waste gas treatment scrubber body 100 and, at one end, the treatment The treated water supply pipe 320 is provided so that the treated water flows in from the water storage tank 310, and the other end is configured to extend toward the upper side of the waste gas treatment scrubber body 100. In the treated water supply pipe 320 A branch pipe 330 which is branched and provided on the front side of the modular filter-demister means 500 with respect to the flow direction of the exhaust gas, and a plurality of branches are provided in the branch pipe 330 to supply treated water to the modular type A pump that is provided on the spray nozzle 340 for spraying the filter-demister means 500 and the treated water supply pipe 320 and is driven to pump the treated water under the control of the control module unit 600 . (350).

In addition, a valve 331 for controlling the flow rate by being controlled by the control module unit 600 may be provided near the branch portion of the branch pipe 330 .

The treated water supply unit 300 configured in this way pumps the treated water stored in the treated water storage tank 310 through the pump 350 controlled by the control module unit 600, and is a modular filter-demister means. The treated water is injected through the injection nozzle 340 located on the front side of the 500 .

Here, the treated water sprayed by the injection nozzle 340 contains carbon dioxide supplied by the carbon dioxide supply unit 400 to be described below to neutralize the exhaust gas passing through the waste gas treatment scrubber body 100 . do.

The treated water sprayed by the modular filter-demister means 500 and used for neutralization treatment falls to the lower side (by gravity) and the treated water storage tank 310 is located in the lower part of the waste gas treatment scrubber body 100 . is recovered with

Next, the carbon dioxide supply unit 400 is configured to include carbon dioxide gas in the treated water supplied from the treated water supply unit 300 to be supplied in a bubble form.

Specifically, the carbon dioxide supply unit 400 has one end communicated with one side of the treated water storage tank 310 , and the other end is connected with the other side of the treated water storage tank 310 , and the treated water storage tank (310) The treated water flow pipe 410 having a supply control solenoid valve 411 on the inlet side, and the treated water provided on the treated water flow pipe 410 and stored in the treated water storage tank 310 A circulation pump 420 for pumping a portion to circulate through the treated water flow pipe 410, and a circulation water flow meter provided on the treated water flow pipe 410 to detect the flow rate and pressure of the circulated treated water ( 431) and a circulating water pressure gauge 432, a carbon dioxide supply pipe 440 having one end connected to the carbon dioxide supply line 10 of the carbon dioxide supply device and the other end connected to the treated water flow pipe 410, and the carbon dioxide Carbon dioxide supply control means 450 provided on the supply pipe 440 to detect and control the flow rate and pressure of the supplied carbon dioxide, and provided at the junction of the treated water flow pipe 410 and the carbon dioxide supply pipe 440 . carbon dioxide-treatment in which the supplied carbon dioxide is bubbled in nano- and micro-units so that the bubbled (bubbled in nano- and micro-units) carbon dioxide is input to the treated water circulated through the treated water flow pipe 410 It is provided on the downstream side of the water mixing device 460 and the carbon dioxide-treated water mixing device 460 , that is, on the downstream side of the junction of the treated water flow pipe 410 and the carbon dioxide supply pipe 440 , The dissolution tank 470 is configured to increase the dissolution rate of carbon dioxide in the treated water containing the treated water, and is connected to the other end of the treated water flow pipe 410, and the inside of the treated water storage tank 310 and an internal ejection pipe 480 configured to eject the treated water containing bubbled carbon dioxide extending to the .

The carbon dioxide supply control means 450 includes a pressure gauge 451 for detecting a supply pressure of carbon dioxide, a regulator 452 for maintaining a constant supply pressure of carbon dioxide, and a safety valve 453 for controlling a supply pressure of carbon dioxide; , a flow meter 454 for detecting a supply amount of carbon dioxide, a check valve 455 for preventing a reverse flow of carbon dioxide, and an automatic valve 456 for controlling the supply of carbon dioxide.

As shown in FIG. 2 , the carbon dioxide-treated water mixing device 460 has an inlet connector 461 and an outlet connector 462 connected at both ends to the treated water flow pipe 410 , and the central part is carbon dioxide At least one carbon dioxide inlet connector 463 connected to the supply pipe 440 is formed, and is composed of a tubular body in which the mixing flow path 464 is formed.

In the carbon dioxide-treated water mixing device 460 , the mixing flow path 464 has a relatively smaller diameter at the central side than at both ends, is tapered to decrease from one end to the center, and is tapered to expand from the central side to the other end. is formed The carbon dioxide inlet connector 463 is preferably formed in communication with the central portion.

In the carbon dioxide-treated water mixing device 460, the mixing flow path 464 has a higher flow rate than the other parts at the point where the carbon dioxide inlet connector 463 communicates, and thus the carbon dioxide bubbled in the treated water is dissolved. It is provided to the waste gas treatment scrubber body side.

Subsequently, as shown in FIG. 3 , the dissolution tank 470 includes a tank body 471 having a closed space, and treated water formed at one end of the tank body 471 in which carbon dioxide is dissolved is introduced. A treated water inlet 472 to be used, a treated water outlet 473 formed at the other end of the tank body 471 to discharge treated water in which carbon dioxide is dissolved, and a gap inside the tank body 471 are provided and a partition wall member 474 for zigzag flow so that the treated water (treated water in which carbon dioxide is dissolved) flowing in through the treated water inlet 472 flows in a zigzag and discharged through the treated water outlet 473 do. In addition, a vent nozzle port 475 is provided on one side of the upper end of the tank body 471 of the dissolution tank 471, and a dissolution tank pressure gauge 479 is provided on the other side.

The tank body 471 may be formed in a cone shape or a cylindrical shape.

The treated water inlet 472 is preferably formed at the edge of the tank body 471 .

The dissolution tank 470 is made such that the internal pressure is maintained constant, preferably 1.1bar ~ 5.5bar.

In addition, as another embodiment of the dissolution tank 470 , as shown in FIG. 4 , a tank body 471 having a space in which the inside is closed, is formed in the upper center of the tank body 471 to dissolve carbon dioxide The treated water flows in and the treated water inlet 472 whose lower end extends to the inside of the treated water internal receptor 477, and the treated water formed in the lower center of the tank body 471 to discharge the treated water in which carbon dioxide is dissolved The discharge port 473 and the support provided on the inner lower surface of the tank body 471 communicate with the treated water outlet 473, are formed to protrude a predetermined height, and have one or more treated water discharge holes 476a formed at the lower end A tube body 476, the inner wall of the tank body 471 and the treated water inner receptor 477 having a cross-section “U” shape in which the lower rear surface is coupled to and supported by the upper end of the support tube body 476 , and the inner wall of the tank body 471 . A partition wall member for flow that is provided on the outer surface of 477 and causes the introduced treated water (treated water in which carbon dioxide is dissolved) to flow in a zigzag and discharged to the treated water outlet 473 through the treated water discharge hole 476a ( 478). In addition, a vent nozzle hole 475 is provided on one side of the upper end of the tank body 471 of the dissolution tank 471, and a dissolution tank pressure gauge 479 is provided on the other side.

The tank body 471 may be formed in a cone shape or a cylindrical shape.

The upper end of the treated water inner container 477 is formed with an extended taper portion 477a that is inclined to extend upward and outward.

The dissolution tank 470 of another embodiment is also made to maintain a constant internal pressure, preferably 1.1bar ~ 5.5bar.

Subsequently, as shown in FIG. 5 , the internal jet pipe 480 includes a tubular body 481 , a jet hole 482 formed with a gap in the tubular body 481 , and the tubular body 481 . ) The treated water is provided to flow therein, and includes a mixing member 483 for stirring (or mixing) the treated water (treated water in which carbon dioxide is dissolved).

The tubular body 481 is configured in plurality and coupled to each other to extend to a predetermined length.

The mixing member 483 may be formed as a twisted plate, or may have a screw shape.

In addition, the carbon dioxide supply unit 400 is configured between the dissolution tank 470 and the treated water storage tank 310 to maintain a constant pressure in the dissolution tank 470, the dissolution tank internal pressure control module 490 further includes

The dissolution tank internal pressure control module 490 has one end connected to the treated water storage tank 310 and the other end is a pressure control bypass pipe connected to the vent nozzle port 475 of the dissolution tank 470 (or If it is provided on the vent pipe) 491, and the pressure control bypass pipe 491, and the internal pressure (dissolution tank pressure gauge 479) exceeds a certain level (that is, 1.1 bar ~ 5.5 bar) and an automatic valve 492 for venting configured to adjust the pressure by opening the valve (when the set holding pressure is exceeded).

In addition, the carbon dioxide supply unit 400 is treated to increase the processing efficiency of the exhaust gas made in the waste gas treatment scrubber body 100 by the treated water containing carbon dioxide flowing into the waste gas treatment scrubber body 100 . It further includes a pH or electrical conductivity detection module for controlling the supply of carbon dioxide by detecting the pH or electrical conductivity of the water.

The pH or electrical conductivity detection module has one end branched from the treated water supply pipe 320 and the other end is a treated water detection pipe 493 connected to an upper side of the treated water storage tank 310, and the treatment It is provided on the pipe 493 for water detection, and includes a pH or electrical conductivity sensor box 495 including a pH sensor or an electrical conductivity sensor 494 for detecting the pH of the treated water.

The pH or electrical conductivity detection module is a component that manages the pH of the treated water in order to increase the treatment efficiency of the exhaust gas made in the waste gas treatment scrubber body 100, and the treated water detected by the sensor 494 If the pH of is higher than 7, the CO ₂ supply automatic valve 456, the supply control solenoid valve 411 is opened, and the circulation pump 420 is operated, and when it is lower than the reference value, the CO ₂ supply automatic valve 456, the supply control By closing the automatic valve 411 and stopping the circulation pump 420, the concentration of carbon dioxide contained in the treated water is adjusted, thereby increasing the gas treatment efficiency for the exhaust gas.

Next, a plurality of the modular filter-demister means 500 are provided in the exhaust gas flow direction inside the waste gas treatment scrubber body 100, and are configured to increase the contact area between the exhaust gas and the treated water.

The modular filter-demister means 500 is classified for a filter or a demister according to the installation density of the filter module 520 . In the present invention, the modular filter-demister means 500 has one or more filters on the upstream side based on the flow direction of the exhaust gas, and the filter module 520 is denser on the downstream side compared to the configuration on the upstream side. It is preferable to be provided for a demister that is configured to do so.

The modular filter-demister means 500, as shown in FIGS. 6 to 12, largely includes an outer frame member 510; a plurality of filter modules 520; spacing adjusting member 530; finishing frame member 540; and a detachable coupling means 550 .

Specifically, the modular filter-demister means 500 includes: an enclosure-type outer frame member 510 formed to allow air flow in all directions; a plurality of filter modules 520 stacked inside the outer frame member 510 to allow air flow; a spacing adjusting member 530 provided between the filter modules 520 to adjust the spacing distance between the filter modules 520; a closing frame member 540 that covers and finishes one end of the outer frame member 510 and is formed to allow air flow; and a detachable coupling means 550 configured to detachably couple the outer frame member 510 and the closing frame member 540 and the neighboring outer frame member 510 .

The outer frame member 510 is formed to allow air flow over the entire surface, and the plurality of filter modules 520 whose spacing is adjusted by the spacing adjusting member 530 are stacked therein.

Specifically, the outer frame member 510 is formed to be open at any one of the upper and lower sides, and five surfaces other than the open surface are formed in a housing type in which air flows through a lattice structure of a predetermined shape. .

More specifically, on the four side surfaces of the outer frame member 510 and any one of the upper and lower surfaces (the lower surface in the drawing), a circular or polygonal central frame portion 511 is formed in the central portion, and the central frame portion 511 is formed. A lattice frame portion 512 is formed in the longitudinal and transverse directions symmetrically with respect to the reference.

In addition, the outer frame member 510 is integrally formed with a coupling flange portion (first coupling flange portion) 551 that is further extended from the periphery of the upper end and the lower end. The coupling flange portion 551 constitutes one component of the detachable coupling means 550 to be described below, which will be described in the description of the detachable coupling means 550 .

Subsequently, the plurality of filter modules 520 are stacked to allow air flow inside the outer frame member 510, and are assembled and combined with a contact area increasing part and other components to increase the contact area between the waste gas and the washing water. It consists of a pair of filter modules which are integrally formed with an assembly component that allows.

The plurality of filter modules 520 each largely includes a first filter member 521 and a second filter member 522 that is detachably stacked and coupled to the filter member 521 with a gap therebetween.

Specifically, each of the plurality of filter modules 520 is formed with a contact area increasing part 521a for expanding a contact area for waste gas and washing water, and a second filter member 522 or an interval adjusting member 400 below. ) and a first filter member 521 of a lattice structure in which a detachable coupling portion (first detachable coupling portion) 521b that is detachably coupled to the lattice structure is formed, and detachably stacked on one surface of the first filter member 521 A detachable coupling portion ( 522a ) that is coupled to and is detachably coupled to the first filter member ( 521 ) or the interval adjusting member ( 400 ) for expanding the contact area for waste gas and washing water ( It includes a second filter member 522 having a lattice structure in which a second detachable coupling portion) 522b is formed.

The first filter member 521 and the second filter member 522 are formed in a plate shape having a rectangular grid structure.

The contact area increasing parts 521a and 522a of the first filter member 521 and the second filter member 522 include a plurality of protrusion protrusions integrally protruding from one surface.

Here, it is preferable that the contact area increasing parts 521a and 522a are formed at intersections of the lattice structures.

In addition, the detachable coupling part (first detachable coupling part 522b) of the first filter member 521 and the detachable coupling part (second detachable coupling part) 522b of the second filter member 522 are fitted formed into a structure.

Specifically, one of the detachable coupling part (first detachable coupling part 522b) of the first filter member 521 and the detachable coupling part (second detachable coupling part) 522b of the second filter member 522 is , is formed with a plurality of coupling protrusions protruding from one surface, and a detachable coupling part (first detachable coupling part 522b) of the first filter member 521 and a detachable coupling part of the second filter member 522 (the first) The other of the two detachable coupling portions) 522b is formed as a coupling groove formed on the opposite surface (rear surface) of the one surface on which the coupling protrusion is formed.

It is preferable that the coupling protrusion and the coupling groove are formed to be stepped in two-stage.

Accordingly, when the first filter member 521 and the second filter member 522 are stacked and coupled, they are stacked and coupled while being spaced apart by the height of the coupling protrusion.

In addition, in the plurality of the plurality of filter modules 520 , when the first filter member 521 and the second filter member 522 are stacked and coupled, the lattice holes of the first filter member 521 and the It is characterized in that the lattice holes of the second filter member 522 are stacked in a state where they are shifted.

In other words, in the plurality of the plurality of filter modules 520, when the first filter member 521 and the second filter member 522 are laminated and coupled, when the coupled state is viewed in a plan view, It is characterized in that the intersecting point of the lattice structure of the second filter member 522 is positioned and coupled to the center of the lattice hole of the first filter member 521 . Alternatively, in the plurality of the plurality of filter modules 520 , when the first filter member 521 and the second filter member 522 are laminated and coupled, when the coupled state is viewed in a plan view, the It is characterized in that the contact area increasing portion of the first filter member 522 is positioned at the center of the grating hole of the second filter member 522 .

As described above, the first filter member 521 and the second filter member 522 are stacked and combined so that the lattice structure of the first filter member 521 and the lattice structure of the second filter member 522 are on the same line (gas flow direction). ), the gas passing through them collides at the lattice structure part, and the contact area with the washing water is further expanded, so that it is possible to further increase the treatment efficiency of the waste gas.

Next, the interval adjusting member 530 adjusts the interval between the filter module 520 including the first filter member 521 and the second filter member 522 , or a plurality of filter modules 520 different from the plurality of filter modules 520 . It is provided so as to adjust the interval between the filter modules 520 of the.

Specifically, the spacing adjusting member 530 includes a lattice frame part 531 and a coupling protrusion 532 protruding from the lattice intersection of the lattice frame part 531 .

The coupling protrusion 532 includes a detachable coupling part (a first removable coupling part 522b) of the first filter member 521 and a detachable coupling part (second detachable coupling part) 522b of the second filter member 522 . ) is detachably coupled to the other one of the coupling grooves.

Subsequently, the closing frame member 540 covers the upper end and lower end of the outer frame member 510 to finish the finish, and is formed to allow air flow.

Specifically, the finishing frame member 540 includes an outer frame 541 formed to correspond to an open portion of an upper or lower portion of the outer frame member 510 , and a lattice frame formed inside the outer frame 541 . (542).

The lattice frame 542 may have the same lattice structure as the lattice structure of the outer frame member 510 .

In other words, the lattice frame 542 of the finishing frame member 540 has a circular or polygonal central frame portion 542a formed in the central portion, and is symmetrically in longitudinal and lateral directions with respect to the central frame portion 542a. The lattice frame portion 542b is formed.

And in the outer frame 541 of the closing frame member 540, a coupling flange portion (second coupling flange portion) 552 formed upward (in a direction parallel to the first coupling flange portion 551) from the outer end thereof. ) is integrally formed. The coupling flange portion 552 constitutes one component of the detachable coupling means 550 to be described below, which will be described in the description of the detachable coupling means 550 .

Next, the detachable coupling means 550 is configured to detachably couple between the outer frame member 510 and the closing frame member 540 and the neighboring outer frame member 510 .

Specifically, the detachable coupling means 550 includes a coupling flange portion (a first coupling flange portion) 551 extending from the outside of the upper end and lower end of the outer frame member 510 , and the finishing frame member 540 . ) from the outer end of the outer frame 541 to the upper side (in a direction parallel to the first coupling flange part 551) and a coupling flange part (second coupling flange part) 552 formed to extend, and the first It includes one or more fastening holes 553 formed in the coupling flange part 551 and the second coupling flange part 522 , and a fastener 554 detachably fastened to the coupling hole 553 .

The fastening hole 553 is formed as a long hole.

And the fastener 554 has a fastener body formed in an "L" shape, and a fastening protrusion 554a having a shape corresponding to the long hole is formed at one end of the fastener body, and the other end of the fastener body is formed. The knob piece (knob piece) 554b is integrally formed.

The modular filter-demister means 500 configured as described above is provided in the waste gas treatment scrubber body 100 to maximize the contact area between the exhaust gas and the treated water to increase the treatment efficiency, and the case and internal components All of these are modular, so they can be easily changed and applied according to the processing capacity or the size of the scrubber body, and since gas processing and droplet removal can be performed at the same time, versatility as packing and demister can be secured as well as assembly and Separation and cleaning can be facilitated, which can provide excellent maintainability.

Next, as shown in FIG. 13 , the control module unit 600 controls the exhaust gas supply unit 200 , that is, the exhaust gas supply control unit 610 that controls the damper 211 and the blower 230 . ), a treated water supply control unit 620 for controlling the pump 350 of the treated water supply unit 300 , and a carbon dioxide supply control unit for controlling the circulation pump 420 of the carbon dioxide supply unit 400 ( 630).

The exhaust gas supply control unit 610 controls the damper 211 to open when the blower 230 is operated, and the treated water supply control unit 620 controls the pump 350 to operate.

In addition, the control module unit 600 receives the detection signal of the pH or electrical conductivity detection module _{to open and close the automatic CO 2} supply valve 456 and/or the automatic supply control valve 411, and control the circulation pump 420 . It includes a pH or electrical conductivity interlocking control unit 640 for ON / OFF.

The carbon dioxide supply control unit 630 and the pH or electrical conductivity interlock control unit 640 controls the automatic valves 411 and 456 to open when the pump 420 is operated.

In addition, when the value of the pressure gauge 479 provided in the dissolution tank 470 exceeds a certain level or more (that is, when the control module 600 exceeds the holding pressure set in 1.1 bar to 5.5 bar), the control module 600 is for venting. and a dissolution tank pressure control unit 650 for controlling the automatic valve 492 to open.

The treatment operation of the exhaust gas by the alkaline waste gas treatment facility using _{the CO 2} gas according to the present invention configured as described above will be described as follows.

The treated water in the treated water storage tank 310 is pumped by the pump 350 and is sprayed to the modular filter-demister means 500 through the spray nozzle 340 of the branch pipe 330 . In the modular filter-demister means 500 , gas components (exhaust gas and carbon dioxide) are absorbed and processed, and the gas (processed gas) is discharged through the blower 230 to the outside through the treatment exhaust gas exhaust duct 220 . is emitted

The treated water in which the polluting gas has been absorbed is recovered to the treated water storage tank 310 by gravity. Here, the modular filter-demister means 500 not only absorbs and neutralizes the gas, but also the modular filter-demister means 500 provided on the most downstream side in the flow direction of the exhaust gas functions as a demister. Moisture contained by the air current flow is captured.

Here, the treated water sprayed to the modular filter-demister means 500 contains carbon dioxide.

That is, a portion of the treated water of the waste gas treatment storage tank 310 is pumped through the circulation pump 420 and supplied to the dissolution tank 470 together with _{the CO 2 gas through the carbon dioxide-treated water mixing device 460 .} Here, the dissolution tank 470 is maintained at a constant pressure (preferably, 1.1 to 5,5 bar) as a component for increasing the _{CO 2 gas dissolution rate.} The dissolution tank 470 _{absorbs more CO 2 gas in the treated water because the higher the pressure of the CO 2} gas, the higher the solubility of the CO 2 gas, and the amount of _{CO 2} gas that is not absorbed and is lost is reduced.

And the carbon dioxide-treated water mixing device 460 _{bubbles the CO 2} gas in nano and micro units to increase the residence time of the _{CO 2} gas in the treated water storage tank 310, and the neutralization treatment efficiency of the _{CO 2 gas and the exhaust gas} increase the

Nano and microbubbles of carbon dioxide through the carbon dioxide-treated water mixing device 460 produce a slow rise time in the treated water storage tank 310, a large surface area for the same volume, a negatively charged surface, and hydroxyl radicals. It provides the effect of, and can improve the reaction efficiency of the treated water and exhaust gas in the modular filter-demister means 500 through the high pressure in the dissolution tank 470, and the treated water storage tank 310 It is possible to increase the neutralization rate in This _{is the reason why the CO 2} is supplied in the form of bubbles and the dissolution tank is provided as a pressure tank.

_{The CO 2} supplied in the bubble form is absorbed into the treated water in the dissolution tank 470 , and is supplied to the treated water storage tank 310 in the form of CO2 (H2CO3) and HCO3-. At this time, the pressure of the dissolution tank 470 is detected through a pressure gauge 479 or the like and is controlled to maintain a constant pressure (preferably, 1,1 to 5,5 bar). When the pressure of the dissolution tank 470 is low, the circulation pump 420 is operated, and when the pressure is high, the vent valve 482 is opened and controlled.

_{14 is a graph for explaining a state in which CO 2} is dissolved in the form of CO2 (H2CO3) and HCO3- in treated water, _{and FIG. 15 is a graph of CO 2} solubility according to pressure and temperature. Gas component is absorbed in treated water The resulting reaction is as follows.

CO2 + NH3 → NH2COOH

NH2COOH + NH3 → NH4+ + NH2COO-

NH2COO- + H2O ↔ NH4CO3

NH4COONH4 + H2O + CO2 ↔ NH4HCO3

Here, the present invention manages the pH value in order to increase the gas treatment efficiency of the exhaust gas. When the pH detected by the pH sensor of the pH detection module is higher than 7, the _{automatic CO 2} supply valve 456 is opened, and the reference value If it is lower, it _{closes the automatic CO 2} supply valve 456 .

_{According to the alkaline waste gas treatment facility using CO 2} gas according to the present invention as described above, by replacing the treatment agent (or treatment chemical) for the alkaline waste gas treatment with CO ₂ gas, the amount of harmful chemicals such as sulfuric acid is reduced in the industry and It is possible to reduce the cost of safety management in the workplace, and by maximizing the contact area between the alkaline waste gas to be treated and the washing water, the treatment efficiency can be increased even under poor conditions, i.e., high superficial velocity and low liquid gas ratio. there is an advantage

In addition, according to the present invention, it is composed of a modular type and can be easily changed and applied according to the processing capacity or the size of the scrubber, thereby securing versatility, and assembling, disassembling, and cleaning can be facilitated, thereby providing excellent maintainability. There are advantages to providing

The embodiments described in this specification and the accompanying drawings are merely illustrative of some of the technical ideas included in the present invention. Therefore, since the embodiments disclosed in the present specification are for explanation rather than limitation of the technical spirit of the present invention, it is obvious that the scope of the technical spirit of the present invention is not limited by these embodiments. Modifications and specific embodiments that can be easily inferred by those skilled in the art within the scope of the technical idea included in the specification and drawings of the present invention should be interpreted as being included in the scope of the present invention.

10: CO2 piping
20: exhaust gas duct
100: waste gas treatment scrubber body
101: exhaust gas inlet
102: outlet
200: exhaust gas supply unit
210: exhaust gas supply duct
211: damper
220: treatment exhaust gas exhaust duct
230: blower device
300: treated water supply unit
310: treated water storage tank
320: treated water supply pipe
330: branch pipe
331: valve
340: spray nozzle
350: pump
400: carbon dioxide supply unit
410: treated water flow pipe
411: supply control automatic valve
420: circulation pump
431: circulating water flow meter
432: circulating water pressure gauge
440: carbon dioxide supply pipe
450: carbon dioxide supply control means
451: pressure gauge
452: regulator
453: safety valve
454: flow meter
455: check valve
456: automatic valve
460: carbon dioxide-treated water mixing device
461: inlet connector
462: outlet side connector
463: carbon dioxide inlet connector
464: mixed flow path
470: melting tank
471: tank body
472: treated water inlet
473: treated water outlet
474: bulkhead member for flow flow
475: vent nozzle
476: support body
476a: treated water outlet hole
477: treated water internal receptor
477a: tapered part
478: flexible bulkhead member
479: dissolution tank pressure gauge
480: internal blowout pipe
481: tubular body
482: squirt hole
483: mixing element
490: dissolution tank internal pressure control module
491: pressure control bypass piping (or vent piping)
492: automatic valve for vent
493: pipe for detecting treated water
494: pH or conductivity sensor
495: pH or conductivity sensor box
500: modular filter-demister means
510: outer frame member
511: central frame portion
512: lattice frame unit
512a: central frame portion
512b: lattice frame portion
520: filter module
521: first filter element
521a, 522a: contact area increasing part
521b: first detachable coupling portion
522b: second detachable coupling portion
522: second filter element
530: spacing adjustment member
531: lattice frame unit
532: bonding protrusion
540: finish frame member
541: outer frame
542: grid frame
550: detachable coupling means
551: coupling flange portion (first coupling flange portion)
552: coupling flange portion (first coupling flange portion)
553: fastening hole
554: fastener
554a: fastening protrusion
554b: knob edition
600: control module unit
610: exhaust gas supply control unit
620: treated water supply control unit
630: carbon dioxide supply control unit
640: pH or electrical conductivity interlocking control unit
650: dissolution tank pressure control unit

Claims (10)

An alkaline waste gas treatment facility for neutralizing exhaust gas discharged from a facility generating exhaust gas, which is an alkaline waste gas,
waste gas treatment scrubber body;
an exhaust gas supply unit configured to supply exhaust gas to the waste gas treatment scrubber body and discharge the neutralized exhaust gas through treated water including carbon dioxide (CO _{2 ) from the waste gas treatment scrubber body;}
a treated water supply unit configured to supply treated water containing carbon dioxide gas to the waste gas treatment scrubber body;
a carbon dioxide supply unit for supplying the treated water supplied from the treated water supply unit to contain carbon dioxide;
a modular filter-demister means provided in the waste gas treatment scrubber body in a flow direction of the exhaust gas and configured to increase a contact area between the exhaust gas and the treated water; and
A control module unit configured to control the exhaust gas supply unit, the treated water supply unit, and the carbon dioxide supply unit
Alkaline waste gas treatment facility comprising a.
According to claim 1,
The exhaust gas supply unit includes an exhaust gas supply duct connected to the gas inlet of the waste gas treatment scrubber body, a treatment exhaust gas discharge duct connected to the waste gas treatment scrubber body, and a blower provided in the treatment exhaust gas discharge duct includes,
The treated water supply unit includes a treated water storage tank configured to communicate with the waste gas treatment scrubber body at a lower portion of the waste gas treatment scrubber body, and one end is provided so that treated water flows in from the treated water storage tank, and the other end is provided with the A treated water supply pipe configured to extend toward the upper side of the waste gas treatment scrubber body, and a branch pipe that is branched from the treated water supply pipe and is provided on the front side of the modular filter-demister means with respect to the flow direction of the exhaust gas; , a plurality of injection nozzles provided in the branch pipe to spray the treated water to the modular filter-demister means, and a pump provided in the treated water supply pipe and driven to pump the treated water under the control of the control module unit characterized by comprising
Alkaline waste gas treatment plant.
3. The method of claim 2,
The carbon dioxide supply unit,
a treated water flow pipe having one end connected to one side of the treated water storage tank and the other end connected to the other side of the treated water storage tank;
a circulation pump provided in the treated water flow pipe to pump the treated water stored in the treated water storage tank to circulate through the treated water flow pipe;
a circulating water flow meter and a circulating water pressure gauge provided in the treated water flow pipe to detect the flow rate and pressure of the circulated treated water;
a carbon dioxide supply pipe having one end connected to the carbon dioxide supply line and the other end connected to the treated water flow pipe;
a carbon dioxide supply control means provided in the carbon dioxide supply pipe to detect and control the flow rate and pressure of the supplied carbon dioxide;
a carbon dioxide-treated water mixing device provided at the junction of the treated water flow pipe and the carbon dioxide supply pipe, the carbon dioxide being included in the treated water;
a dissolution tank provided on a downstream side of the junction of the treated water flow pipe and the carbon dioxide supply pipe and configured to increase the dissolution rate of carbon dioxide in the treated water containing carbon dioxide; and
and an internal ejection pipe connected to the other end of the treated water flow pipe and extending into the treated water storage tank to eject the treated water containing carbon dioxide.
Alkaline waste gas treatment plant.
4. The method of claim 3,
The carbon dioxide-treated water mixing device,
A tubular body having both ends having an inlet connector and an outlet connector connected to the treated water flow pipe, the central part having one or more carbon dioxide inlet connectors connected to the carbon dioxide supply pipe, and having a mixing flow path therein characterized in that
Alkaline waste gas treatment plant.
5. The method of claim 4,
The mixing flow path has a relatively smaller diameter than the both end sides of the central portion, and is tapered to expand toward both ends with respect to the central portion, and the carbon dioxide inlet connector is formed in communication with the central portion. characterized
Alkaline waste gas treatment plant.
4. The method of claim 3,
The dissolution tank is
a tank body having a space inside which is closed;
a treated water inlet formed at one end of the tank body and into which treated water in which carbon dioxide is dissolved is introduced;
a treated water outlet formed at the other end of the tank body through which treated water in which carbon dioxide is dissolved is discharged; and
It is provided with a gap inside the tank body, and the treated water introduced through the treated water inlet flows in a zigzag manner and is discharged through the treated water outlet through a partition wall member for zigzag flow; characterized by comprising:
Alkaline waste gas treatment plant.
4. The method of claim 3,
The dissolution tank is
a tank body having a space inside which is closed;
a treated water inlet formed in the upper central portion of the tank body;
a treated water outlet formed in the center of the lower end of the tank body;
a support pipe provided on the inner lower surface of the tank body, communicating with the treated water outlet, protruding at a predetermined height, and having one or more treated water outlet holes formed at the lower end thereof;
The lower back surface is coupled to the upper end of the support tube, a cross-section "U"-shaped treated water internal receptor; and
and a partition wall member for flow provided on the inner wall of the tank body and the outer surface of the treated water internal receptor so that the treated water flows in a zigzag manner and is discharged to the treated water outlet through the treated water discharge hole.
Alkaline waste gas treatment plant.
4. The method of claim 3,
The internal jet pipe,
tubular body;
an ejection hole formed with a gap in the tubular body; and
A mixing member provided in the tubular body, the treated water is provided to be flowable, and agitating the treated water containing carbon dioxide; characterized in that it comprises a
Alkaline waste gas treatment plant.
4. The method of claim 3,
The carbon dioxide supply unit,
a dissolution tank internal pressure control module configured between the dissolution tank and the treated water storage tank to maintain a constant pressure in the dissolution tank; and
A pH or electrical conductivity detection module for controlling the supply of carbon dioxide by detecting the pH or electrical conductivity of the treated water to increase the treatment efficiency of the exhaust gas by the treated water containing carbon dioxide flowing into the waste gas treatment scrubber body; characterized by
Alkaline waste gas treatment plant.
According to claim 1,
The modular filter-demister means,
an enclosure-type outer frame member formed to allow air flow and having an opening on one side;
a plurality of filter modules stacked on the outer frame member to allow air flow;
a spacing adjusting member provided to adjust the spacing distance between the filter modules;
a closing frame member that covers and finishes the opening of the outer frame member and is formed to allow air flow; and
and a detachable coupling means configured to detachably couple the outer frame member, the finishing frame member, and the neighboring outer frame members.
Alkaline waste gas treatment plant.

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