KR102351135B1 - Gaseous Pollutants Purifying Apparatus - Google Patents

Abstract

The present invention relates to a pollutant gas treatment modular unit for treating pollutant gas by using ozone or ozone water, which comprises: a modular unit structure (130) configured to form a sealed interior space; a gas inlet (110) formed on one side of the modular unit structure (130), through which a pollutant gas to be treated flows into an internal space of the modular unit structure (130); an ozone generator (140) for supplying ozone to an inner space of the modular unit structure (130); a modular unit rotating mesh (160) configured to rotate about a rotation axis to promote mixing and reaction of pollutant gas and ozone in the internal space of the modular unit structure (130); and a gas outlet (120) formed on the other side of the modular unit structure (130) for discharging the finished pollutant gas from the internal space of the modular unit structure (130) to the outside.

Description

Gaseous Pollutants Purifying Apparatus

The present invention relates to a polluting gas treatment modular unit for treating polluting gas discharged from a large-scale polluting gas generating facility, such as a livestock barn or a fertilizer production plant, and an apparatus including the same, and more particularly, to a polluting gas treatment module easily adapted to the quantity of polluting gas to be treated The present invention relates to a pollutant gas processing apparatus in which a polluting gas processing modularization unit is introduced so that a processing capacity can be increased or decreased.

The density of various bacteria and viruses, as well as odor components and dust, increases in the air of a livestock barn for raising a large number of livestock in a limited space or a production facility that produces fertilizer using organic materials. In order to maintain an appropriate working environment, ventilation of the facility is of paramount importance. However, if the air containing the odor emitted from the facility is discharged as it is, it directly affects the living environment of the residents living around the facility.

In order to obtain a sterilization effect while reducing odor in the facility, a method of supplying ozone into the facility has been proposed. There have been many research results regarding the sterilization and odor removal effects of ozone, and many products using it have been made. In particular, a method of removing contaminants such as odor components or volatile organic compounds contained in the air by ozone generated using a low-temperature plasma reaction is still being applied to some livestock houses. However, although ozone has effects such as odor removal and sterilization, it is harmful to livestock and the human body.

Furthermore, a technique of dissolving ozone in water stored in a water tank and spraying water in which ozone is dissolved (generally referred to as 'ozone water') into a facility to remove odors has also been proposed (Patent Document 1) and 2). When ozone is dissolved in water, OH radicals are formed, which are chemically very active and are known to oxidize by causing chemical reactions with bacteria, viruses, molds, and various harmful gas substances that generate odors in air or water. The decomposition rate of ozone is greatly affected by pH because it has the property of self-decomposition by OH radicals. In other words, ozone is maintained in a stable state in acid, but the decomposition rate increases as it becomes alkaline. And ozone is decomposed by the initially formed OH radical, and as an intermediate product, OH radical is generated through the intermediate path of hydroperoxy radical (HO2-), superoxide radical (O2-), and ozonide radical (O3-).

Since OH radicals also cannot completely guarantee safety, management of manpower and livestock present in the facility is essential when spraying within the facility. Furthermore, it is known that the half-life of OH radicals in water is about 20 minutes, and the proportion of OH radicals that are decomposed between the time from the dissolution of ozone to the actual spraying process is considerable, and it is actually used for odor removal/sterilization. The amount of OH radicals formed is significantly smaller than the amount of OH radicals generated by ozone dissolution.

Therefore, in many cases, it is not suitable to apply the method of directly spraying ozone or OH radicals within the facility. In this case, the method of inducing the polluting gas generated from the facility to the outside of the facility and then treating it using ozone or OH radical is used. It is preferable to do

However, it takes a lot of money and time to design and construct such a polluting gas treatment facility according to the polluting gas generating capacity. Furthermore, even in using the previously installed polluting gas treatment facility, if the amount of polluting gas to be treated increases, a new design/construction process is required to expand the facility, which is costly and time-consuming.

Registered Patent Publication No. 10-1893358 (Announcement date: 2018.10.04.) Registered Patent Publication No. 10-1005636 (Announcement date: 2011.01.05.) Registered Patent Publication No. 10-2096093 (Announcement Date: 2020.04.01.)

The present invention is to solve the problems of the prior art, and by modularizing the polluting gas processing facility, the polluting gas processing module is made capable of easily changing the polluting gas processing capacity without significantly changing the existing polluting gas processing facility. An object of the present invention is to provide a unit and a polluted gas treatment apparatus including the same.

The present invention relates to a polluting gas treatment modular unit for treating polluting gas using ozone or ozone water, comprising: a modular unit structure 130 for forming a sealed internal space; a gas inlet 110 formed on one side of the modular unit structure 130 , through which a pollutant gas to be treated flows into the internal space of the modular unit structure 130 ; an ozone generator 140 for supplying ozone to the inner space of the modular unit structure 130; a modular unit rotating mesh 160 rotating about a rotation axis to promote mixing and reaction of polluting gas and ozone in the internal space of the modular unit structure 130; And it is formed on the other side of the modular unit structure 130, characterized in that it comprises a gas outlet 120 for discharging the finished pollutant gas from the internal space of the modular unit structure 130 to the outside.

The polluting gas treatment modular unit according to the present invention includes a showerhead 151 for spraying water into the inner space of the modular unit structure 130; and a modular unit water supply pipe 150 for supplying water to the showerhead 151 .

In the polluting gas treatment modular unit according to the present invention, a gas return unit 170 for returning the pollutant gas containing more than a reference value even after the pollutant gas treatment is completed and introducing the pollutant gas into the internal space of the modular unit structure 130 ) It is characterized in that it further comprises.

Furthermore, the present invention relates to a polluting gas processing apparatus including a polluting gas processing modular unit, and a purification tower 200 for finally processing and discharging the polluted gas processed through the polluting gas processing modular unit to the outside. Further comprising a, wherein the purification tower 200 includes a purification tower inlet 220 for introducing a pollutant gas into the interior space of the purification tower 200; a purification tower outlet 230 for discharging the polluted gas that has been treated in the interior space of the purification tower 200 to the outside; and a purification tower gas return port 240 for returning the exhaust gas when the pollutant contained in the pollutant gas discharged to the purification tower outlet 230 is equal to or greater than a reference value, wherein the purification tower gas return port 240 is a gas It is characterized in that it is connected to the gas return unit 170 of the polluting gas treatment modular unit by a return duct 400 .

In addition, a plurality of polluting gas processing modular units 100 are connected, and the gas outlet 120 of one polluting gas processing modular unit 100 is adjacent to the gas inlet 110 of another polluting gas processing modular unit 100 and The gas outlet 120 of the polluting gas treatment modularization unit 100 closest to the purification tower 200 is connected to the purification tower inlet 220 and is connected to the purification tower 200 furthest away from the purification tower 200. The gas inlet 110 of the polluting gas treatment modularization unit 100 is characterized in that it is connected to a polluting gas generating facility.

In the inner space of the purification tower 200, a filler layer 251 for removing the contaminants by reacting with contaminants; And formed on the lower portion of the filler layer 251, the purification tower 200, the ozone water is injected through the inlet 220 to the polluted gas, and at the same time to promote the mixing and reaction of the polluted gas and ozone water, the center of rotation A purifying tower rotating mesh 260 that rotates may be further provided.

Finally, the pollutant gas treatment apparatus according to the present invention is installed at the outlet 230 of the purification tower, and an outlet sensor ( 231), wherein the purification tower outlet damper 232 is installed at the purification tower outlet 230 to open and close the purification tower outlet 230 when the concentration of the pollutant measured by the outlet sensor 231 is greater than or equal to the reference value. to close the purification tower outlet 230 and operate the exhaust air return fan 241 installed in the purification tower gas return port 240 to introduce the exhaust gas into the purification tower gas return port 240 characterized in that

A polluting gas processing modular unit and a polluting gas processing apparatus including the same according to the present invention provide a standardized polluting gas processing modular unit by integrating ozone supply means, mixing means, water supply means, and return means, so that pollutant gas processing facilities It can facilitate design, construction and expansion.

In particular, the polluting gas treatment modular unit according to the present invention is connected to an existing purification tower and used to pre-treat the air supplied to the air purification tower. have.

1 shows the configuration of a polluting gas processing apparatus according to the prior art.
2 and 3 show the overall configuration of the polluting gas treatment modularization unit.
4 shows an example of an ozone generator.
5 shows an embodiment in which the polluting gas treatment modular unit is connected to a purification tower.
6 shows the configuration of the purification tower.
7 and 8 show an embodiment in which a plurality of gas processing modularization units are connected to a purification tower.

Hereinafter, an overall configuration of a polluting gas processing modular unit and a polluting gas processing apparatus including the same according to the present invention will be described with reference to the drawings. Specific structural or functional descriptions presented in the embodiments of the present invention are only exemplified for the purpose of describing embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention may be implemented in various forms. In addition, it should not be construed as being limited to the embodiments described herein, and it should be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention.

FIG. 2 is an external view of the modular unit for treating a polluting gas according to the present invention, and FIG. 3 is a view showing an internal structure of the modular unit for treating a polluting gas according to the present invention. A gas inlet 110 is formed on one side of the modular unit structure 130 forming an enclosed space therein, and a gas outlet 120 is formed on the other side. The gas inlet 110 is connected to a polluting gas generating facility (H) such as a livestock barn or a fertilizer production facility through a pipe (duct), so that a high-odor polluting gas such as hydrogen sulfide (H2S) and ammonia (NH3) is discharged from the gas inlet It is introduced into the interior space of the modular unit structure 130 through the 110 . In addition, the pollutant gas that has undergone a purification action in the internal space of the modular unit structure 130 is discharged to the outside of the modular unit structure 130 through the gas outlet 120 .

The ozone generator 140 is mounted on the modular unit structure 130 , and ozone is supplied to the internal space of the modular unit structure 130 through the ozone supply port 141 . Ozone supplied to the interior space of the modular unit structure through the ozone supply port 141 reacts with the polluting gas introduced through the gas inlet 110 .

As the ozone generator 140, a conventional ozone generator as shown in FIG. 4 can be used. The ozone generator shown in FIG. 4 was developed by the inventor of the present invention and obtained a patent registration (registration number 10-1800230), which generates ozone by the ozone generating unit 130 using the air sucked through the suction port. At the back, it has a structure that discharges ozone to the outlet. Specifically, looking at the configuration of the ozone generating unit through FIG. 4(b), when the power supply port supplies electric power to the electric conductor, plasma is generated between the ceramic tube and the electric conductor, and the plasma again generates ozone radicals. . The ozone generator shown in FIG. 4 is only presented as an example of the prior art that can be applied to the polluting gas treatment modular unit, and the structure of the ozone generator 140 is not particularly limited, and any type of ozone generating means made in the prior art is not particularly limited. Those skilled in the art will readily understand that it can be used.

The polluted gas introduced through the gas inlet 110 reacts with ozone and moves toward the gas outlet 120. To facilitate this movement, a duct fan is installed near the gas inlet 110 or the gas outlet 120. It is also possible to In addition, a modular unit rotating mesh 160 may be provided to promote mixing and reaction of the polluting gas and ozone. The modular unit rotation mesh 160 is a mesh-shaped structure rotating about a rotation axis, and at one end of the axis of the modular unit rotation mesh 160, a modular unit rotation mesh driving unit 161 such as an electric motor is provided, so that the modular unit rotation mesh 160 ) is rotated at regular intervals.

Furthermore, a showerhead 151 and a modular unit water supply pipe 150 for supplying water to the showerhead 151 may be provided at the upper end of the inner space of the modular unit structure 130 . The modular unit water supply pipe 150 may be connected to a hose or an external pipe to supply water from the outside. Water (droplets) injected into the interior space of the modular unit structure 130 through the showerhead 151 removes odor components having hydrophilic polarity, such as ammonia, amines, ketones, aldehydes, lower organic acids, and phenol. Furthermore, ozone floating in the inner space of the modular unit structure 130 may be dissolved in minute droplets, in which case OH radicals are formed. Water in which OH radicals are formed is often called ozone water, but OH radicals have much superior oxidizing power than ozone, thereby maximizing odor removal and sterilization effects. The process of generating OH radicals was briefly mentioned in the technical part that is the background of the invention, and since it is a generally widely known part, an additional description will be omitted. Furthermore, a drain hole 180 may be formed at the lower end of the modular unit structure 130 so that water sprayed from the showerhead 151 through the drain hole 180 exits the internal space of the modular unit structure 130 . do.

Furthermore, a caster 190 may be installed at the lower end of the modular unit structure 130 for convenience of movement. The polluting gas processing modular unit 100 may be installed in addition to an existing polluting gas processing facility, or a plurality of polluting gas processing modular units may be installed in combination with each other depending on the scale of the polluting gas, so the polluting gas processing modular unit ( 100), storage and portability are important factors. In particular, the polluting gas processing capability can be calculated in advance by the ozone supply capability of the ozone generator 140 installed in one polluting gas processing modular unit 100, the size of the internal space of the modular unit structure 130, the capacity of the duct fan, etc. , the number of required polluting gas treatment modular units can be determined according to the situation.

Furthermore, a gas return unit 170 may be formed in a predetermined portion of the modular unit structure 130 , which, when the density of contaminants is not lowered below a certain standard even after the contaminant gas treatment process has been completed, may reduce the treatment process. It is an element for sending the finished polluting gas back to the modular unit structure 130 to be processed again. In this regard, it will be described in detail later.

5 shows a state in which the polluting gas treatment modularization unit 100 according to the present invention is connected to the existing purification tower 200 and used. A gas transfer duct 310 is connected to each of the gas inlet 110 and the gas outlet 120 of the modular unit 100 for treating polluting gas, and a water supply such as a hose is connected to the modular unit water supply pipe 150 to supply water from an external rotor. The receiving connector 320 may be connected. The polluted gas to be treated flows in through the gas transfer duct 310 connected to the gas inlet 110 , and the polluted gas that has been primarily treated in the polluted gas treatment modularization unit 100 is connected to the gas outlet 120 . It moves to the purification tower 200 through the gas transfer duct 310 to finally process the polluted gas. Furthermore, the upper portion of the purification tower 200 and the gas return unit 170 of the polluting gas treatment modularization unit 100 may be connected by a gas return duct 400 , which is a sensor provided at the top of the purification tower 200 . When the residual pollutant concentration sensed through the C is greater than or equal to the reference value, the pollutant gas that has been processed is not discharged, but instead returned to the polluting gas treatment modularization unit 100 through the gas return duct 400 to undergo a process again.

6 shows the configuration of the purification tower 200 . A purification tower inlet 220 is formed at the lower end of the purification tower 200 , and the purification tower inlet 220 is connected to the gas outlet 120 of the polluting gas treatment modular unit 100 by a gas transfer duct 310 and In this connection, the pollutant gas primarily processed by the polluting gas treatment modularization unit 100 is delivered. In order to smoothly introduce the pollutant gas into the purification tower 200 , a purification tower inlet fan 221 may be installed near the purification tower inlet 220 .

Ozone water is primarily sprayed on the polluting gas introduced into the purification tower 200 through the purification tower inlet 220 . More preferably, a purification tower rotating mesh 260 for promoting the reaction of polluting gas and ozone water while rotating inside the purification tower 200 may be provided. The top rotation mesh driving unit 261 may rotate at a predetermined period. More preferably, ozone water injection holes 262 are formed at predetermined intervals in the rotation shaft of the purification tower rotation mesh 260 and ozone water is supplied to the rotation shaft, so that ozone water is injected through the ozone water injection holes 262 and at the same time as the purification tower. A reaction between the polluting gas and the ozone water may be smoothly performed by the rotating mesh 260 .

Furthermore, a filling part 250 may be formed in a predetermined space inside the purification tower 200, which is a filling material supporting mesh 252 and a filling material layer 251 that can support a solid filling material while passing gas. includes The filler forming the filler layer 251 may be activated carbon (silica, alumina-based adsorbent) capable of adsorbing a specific gas component or a catalyst material for removing waste ozone.

A purification tower gas return port 240 may be formed in the upper portion of the purification tower 200 , and when the pollutant concentration is higher than the reference value even after all the treatment processes in the purification tower 200 have been performed, the pollutant gas that has been treated is removed from the purification tower Instead of being discharged through the outlet 230 , it is returned to the polluting gas treatment modularization unit 100 through the purification tower gas return port 240 .

An outlet sensor 231 capable of sensing the concentration of various pollutants may be provided near the purification tower outlet 230 . If the concentration of the pollutant gas contained in the air discharged through the outlet 230 is greater than or equal to the standard value, purification The tower outlet damper 232 is actuated to close the outlet 230 , and the pollutant gas is sent to the purification tower gas return port 240 . In order to smoothly transfer the pollutant gas to the purification tower gas return port 240 , the exhaust air return fan 241 may be operated.

7 is a view illustrating an installation state of a polluting gas treatment modular unit according to another embodiment of the present invention. In the embodiment of FIG. 7 , two polluting gas treatment modularization units 100 are connected in series, and when the discharge amount of the polluting gas to be treated exceeds the processing capacity of one polluting gas processing modular unit 100, in this way can constitute a polluting gas treatment device. A gas outlet 120 of one polluting gas treatment modular unit 100 may be connected to a gas inlet 110 of another adjacent polluting gas treatment modular unit 100 through a gas transfer duct 310 . Furthermore, the modular unit water supply pipes 150 of the two adjacent polluting gas treatment modular units 100 may be connected to each other through a water supply connection pipe 320 . In addition, the drain holes 180 of the two adjacent polluting gas treatment modular units 100 may be connected to each other by a drain connection pipe 330 .

The purification tower gas return port 240 and the polluting gas treatment modularization unit 100 may be connected by a gas return duct 400 , as in the embodiment of FIG. 7 , the polluting gas treatment modularization unit farthest from the purification tower 200 is It may be connected to the unit 100 , or it may be connected to all the polluting gas treatment modularization units 100 connected in series with the purification tower 200 as in the embodiment of FIG. 8 . When all the polluting gas treatment modular units 100 and the gas return duct 400 connected in series are connected as shown in FIG. 8 , the gas return duct 400 branched into each polluted gas treatment modular unit 100 is in the portion It is desirable to install a return duct damper 410 that can enable or block the movement of gas. Depending on the concentration level of the pollutant measured through the outlet sensor 231 , which pollutant gas treatment modular unit 100 will return the exhaust gas may vary. When the pollutant concentration is high, the purification tower 200 The return duct damper 410 connected to the polluting gas treatment modular unit 100 remote from that is opened, and the return duct damper 410 connected to the remaining polluted gas treatment modular unit 100 is closed. Conversely, when the concentration of the pollutant is higher than the reference value but the excess amount is not large, the exhaust gas is returned to the polluting gas treatment modularization unit 100 close to the purification tower 200 .

100: polluting gas treatment modularization unit 110: gas inlet
120: gas outlet 130: modular unit structure
140: ozone generator 141: ozone supply port
150: modular unit water supply pipe 151: showerhead
160: modular unit rotating mesh 161: modular unit rotating mesh driver
170: gas return unit 180: drain hole
190: caster
200: purification tower 210: purification tower outer wall structure
220: purification tower inlet 221: purification tower inlet fan
230: purification tower outlet 232: purification tower outlet damper
231: outlet sensor 240: purification tower gas return port
241: exhaust air return fan
250: filling unit 251: filler layer
252: mesh for supporting filler material 260: purifying tower rotating mesh
261: purifying tower rotation mesh driving unit 262: ozone water injection hole
310: gas transfer duct 320: water supply connector
330: drain connector
400: gas return duct 410: return duct damper

Claims (8)

It relates to a polluting gas treatment apparatus for treating a polluting gas using ozone or ozone water,
a modular unit structure 130 forming a sealed interior space; a gas inlet 110 formed on one side of the modular unit structure 130 , through which a pollutant gas to be treated flows into the internal space of the modular unit structure 130 ; an ozone generator 140 for supplying ozone to the inner space of the modular unit structure 130; a modular unit rotating mesh 160 rotating about a rotation axis to promote mixing and reaction of polluting gas and ozone in the internal space of the modular unit structure 130; a gas outlet 120 formed on the other side of the modular unit structure 130 for discharging the finished pollutant gas from the internal space of the modular unit structure 130 to the outside; and a gas return unit 170 configured to return the pollutant gas containing more than the reference value even after the pollutant gas treatment has been completed and introduce it into the internal space of the modular unit structure 130; ,
and a purification tower 200 for finally processing and discharging the polluted gas processed through the polluting gas treatment modularization unit to the outside,
The purification tower 200 includes: a purification tower inlet 220 for introducing a pollutant gas into the interior space of the purification tower 200; a purification tower outlet 230 for discharging the polluted gas that has been processed in the interior space of the purification tower 200 to the outside; and a purification tower gas return port 240 for returning the exhaust gas when the pollutant contained in the pollutant gas discharged to the purification tower outlet 230 is higher than the reference value,
The purification tower gas return port 240 is connected to the gas return portion 170 of the polluting gas treatment modular unit by a gas return duct 400,
A plurality of the polluting gas treatment modularization units 100 are connected,
The gas outlet 120 of one polluting gas treatment modular unit 100 is sequentially connected with the gas inlet 110 of another adjacent polluted gas treatment modular unit 100,
The gas outlet 120 of the polluting gas treatment modularization unit 100 closest to the purification tower 200 is connected to the purification tower inlet 220,
The polluting gas processing apparatus, characterized in that the gas inlet 110 of the polluting gas processing modular unit 100 farthest from the purification tower 200 is connected to a polluting gas generating facility.
The method according to claim 1, wherein the polluting gas treatment modular unit comprises: a shower head (151) for spraying water into the inner space of the modular unit structure (130); and
The polluted gas treatment apparatus further comprising a modular unit water supply pipe (150) for supplying water to the showerhead (151).
delete delete delete The method according to claim 1, wherein the inner space of the purification tower (200), a filler layer (251) for removing the pollutants by reacting with pollutants; and
It is provided in the lower part of the filler layer 251 and sprays ozone water to the polluted gas introduced through the inlet 220 of the purification tower 200 and at the same time promotes the mixing and reaction of the polluted gas and the ozone water. Polluted gas treatment apparatus, characterized in that it further comprises a rotating purifier rotating mesh (260).
The method according to claim 1, Installed at the outlet (230) of the purification tower, further comprising an outlet sensor (231) for measuring the concentration of pollutants contained in the pollutant gas that has been treated in the purification tower (200) pollutant gas treatment equipment.
The method according to claim 7, When the concentration of the pollutant measured by the outlet sensor (231) is greater than or equal to the reference value, the purification tower outlet damper (232) installed at the purification tower outlet (230) to open and close the purification tower outlet (230) is operated In addition to closing the purification tower outlet 230,
A polluted gas treatment apparatus, characterized in that the exhaust gas is introduced into the purification tower gas return port (240) by operating the exhaust air return fan (241) installed in the purification tower gas return port (240).

Images