KR102519404B1 - Odor reduction device of drainage system - Google Patents

Abstract

An odor reduction device for a sewage facility is disclosed. An odor reduction device for a sewage facility according to the present invention includes a malodorous gas treatment tank having an inlet through which odorous gas generated in a sewer pipe flows in on one side and an outlet through which air from which the odorous gas has been removed is discharged on the other side; and a malodorous gas concentration detection module provided in the malodorous gas treatment tank to detect the concentration of the malodorous gas distributed inside the malodorous gas treatment tank, and water inside the malodorous gas treatment tank corresponding to the concentration of the malodorous gas detected by the malodorous gas concentration detection module. and a malodorous gas removal unit having a water spraying module for spraying.

Description

Odor reduction device for sewage facilities {ODOR REDUCTION DEVICE OF DRAINAGE SYSTEM}

The present invention relates to a device for reducing odor in a sewage facility, and more particularly, to a device for reducing odor in a sewage facility for removing hydrogen sulfide, which is the main cause of odorous gas generated from sewage.

In general, sewage treatment facilities purify sewage according to procedures prescribed by the Ordinance of the Ministry of Environment, such as sedimentation and decomposition.

Sewage, including manure, etc. generated in the residential space is collected in a septic tank, and the sewage collected in the septic tank is discharged to a sewage pipe through a sewage pump.

At this time, in the sewage treatment facility, hydrogen sulfide (H ₂ S), which is the main cause of odor, is generated and emitted, and the hydrogen sulfide is moved along the sewer pipe and discharged through sidewalks or roads through rain gutters or manholes.

Therefore, mental stress is increased for people around sewer pipes, rain gutters, manholes, etc. due to headaches, vomiting, and discomfort caused by odorous gases discharged from sewage pipes, etc.

There are problems that affect the comfortable life of residents.

Accordingly, people in the vicinity of sewage pipes, rain gutters, manholes, etc., need devices capable of efficiently removing and reducing odorous gases discharged from sewage pipes and the like.

Republic of Korea Patent Publication No. 10-2018-0081663 (published on July 17, 2018)

Therefore, the technical problem to be solved by the present invention is to provide an odor reduction device for sewage facilities capable of efficiently removing hydrogen sulfide, which is the main cause of odor gas.

According to one aspect of the present invention, a malodorous gas treatment tank having an inlet through which malodorous gas generated in a sewage pipe flows in on one side and an outlet through which air from which the malodorous gas is removed is discharged on the other side; and

a malodorous gas concentration detection module provided in the malodorous gas treatment tank and detecting the concentration of malodorous gas distributed inside the malodorous gas treatment tank; An odor reduction device for a sewage facility may include an odor gas removal unit having a water injection module for injecting water therein.

The water spray module may include a water spray nozzle disposed inside the odor gas treatment tank to spray water; a water supply pipe connected to the water injection nozzle to supply water to the water injection nozzle; and a control unit for adjusting the amount of water supplied to the water supply pipe according to the concentration of the odor gas detected by the odor gas concentration detection module.

The water spraying module further includes a chemical supply pipe having one end connected to the water supply pipe and the other end connected to a medicine tank storing a medicine for removing hydrogen sulfide contained in malodorous gas, wherein the water spray nozzle is configured to supply water containing the medicine. and the control unit adjusts the amount of water supplied to the water supply pipe and the discharge amount of the chemical supplied from the chemical tank to the chemical supply pipe according to the concentration of hydrogen sulfide contained in the odor gas detected by the odor gas concentration detection module. can

The water spray nozzle sprays water containing the medicine in a spray form, and the water spray nozzles disposed adjacent to each other may cause the water containing the medicine to be sprayed to overlap each other.

The chemical further includes a mixed additive in which iron salt (FeCl ₃ ) and (A) montmorillonite filler, (B) magnesium chloride and (C) sodium alginate are mixed, and the chemical contains iron salt (FeCl ₃ ) 100 to 800 ppm, and the mixed additives are included in 5 to 10 ppm, (B) 1 to 5 parts by weight of magnesium chloride, (C) 1 sodium alginate based on 100 parts by weight of the (A) montmorillonite filler to 5 parts by weight.

It is provided on the inner bottom surface of the odor gas treatment tank, and is formed in a cone shape with a hollow interior and a cross-sectional area decreasing from the bottom to the top, the open bottom is disposed above the inlet, and the open top is the water spray nozzle It may further include a collection chamber disposed opposite to the inside, in which odor gas generated in the sewage pipe is introduced into and collected by an intake fan accommodated therein, and the collected odor gas is discharged toward the water injection nozzle.

According to another aspect of the present invention, a malodorous gas treatment tank into which water is accommodated and malodorous gas generated in a sewage pipe is introduced; and a malodorous gas removing unit which removes the malodorous gas flowing into the malodorous gas treatment tank, wherein the malodorous gas removal unit is provided in the malodorous gas treatment tank and detects the concentration of the malodorous gas distributed inside the malodorous gas treatment tank. a gas concentration detection module; a water injection module for injecting water into the odor gas treatment tank in response to the odor gas concentration detected by the odor gas concentration detection module; and a gas-liquid spraying unit disposed in the lower region of the malodorous gas treatment tank to spray water containing the malodorous gas, and a malodorous gas supply unit connected to the gas-liquid spraying unit and supplying malodorous gas to the gas-liquid spraying unit; An odor reduction device for a sewage facility may include a diffuser module having a pump for supplying water to the gas-liquid spraying unit through a water supply passage connected to the sap unit.

The malodorous gas removal unit may further include a carrier accommodating module that is immersed in the malodorous gas treatment tank containing water and accommodates a plurality of microbial carriers to which sulfur oxidizing microorganisms are attached.

The litter accommodating module is provided inside the odor gas treatment tank and is disposed above the gas-liquid injection unit, and includes a mesh network in which a plurality of the microbial carriers are accommodated to flow together with the flow of water contained in the odor gas treatment tank. The microbial support may have a specific gravity range of 0.7 to 1.1, and the mesh network may have a smaller size than the microbial support.

The gas-liquid jetting unit is disposed adjacent to at least one of one inner wall or the other inner wall of the malodorous gas treatment tank to inject malodorous gas, and an upper region of the malodorous gas treatment tank facing the gas-liquid jetting unit is disposed on the inner wall of the malodorous gas treatment tank. A guide member protruding to guide the circulation of water inside the odor gas treatment tank may be installed.

The gas-liquid spraying unit is installed in a lower area of the odor gas treatment tank, and the water supply passage is connected to a lower side and the odor gas supply unit is connected to an upper side; and a plurality of gas-liquid spray nozzles provided along the circumference of the sidewall of the spray body to spray water containing the odor gas towards the inner wall of the odor gas treatment tank.

The gas-liquid spray nozzle includes a first through-hole having a concave groove formed on one surface coupled to the spray body and a first through hole formed through the concave groove in a direction from one surface to the other surface and having a smaller diameter than the diameter of the concave groove. unit nozzle; and a second unit nozzle forming a space between one surface inserted into the concave groove and a bottom surface of the concave groove, and having a second through hole penetrating from one surface to the other surface, wherein the inside of the concave groove is A suction space extending from one surface to the other surface of the first unit nozzle and communicating with the odor gas supply part, the concave groove part, and the space part is formed, and the second through hole is formed on the other surface of the second unit nozzle. The diameter increases in this direction, and when water is sequentially discharged through the second through hole and the first through hole, odor gas is sucked into the space through the suction space and together with water through the first through hole. can be released through

The air supply unit includes an air supply passage having one end connected to an upper side of the spray body; and a check valve provided in the air supply passage to open and close the air supply passage to prevent water from flowing backward along the air supply passage from the injection body when the pump is stopped.

The malodorous gas removal unit further includes a temperature control module provided in the malodorous gas treatment tank to control the temperature of the water accommodated in the malodorous gas treatment tank, wherein the temperature control module is provided in the malodorous gas treatment tank to measure the temperature of the water sensor; a heating unit provided in the odor gas treatment tank to heat water; and a cooling unit provided in the odor gas treatment tank to cool water.

The malodorous gas removal unit further includes a pH concentration control module provided in the malodorous gas treatment tank to adjust the pH concentration of water accommodated in the malodorous gas treatment tank, wherein the pH concentration control module is provided in the malodorous gas treatment tank and A pH concentration sensor for measuring the pH concentration of water by being immersed; and a solution supply unit provided in the odor gas treatment tank to supply a pH concentration adjusting solution to the odor gas treatment tank.

Embodiments of the present invention introduce odor gas generated in a sewage pipe into an odor gas treatment tank and provide an odor gas removal unit in the odor gas treatment tank to remove hydrogen sulfide, which is the main cause of odor gas generated in sewage. It can effectively remove odorous gas.

1 is a conceptual diagram schematically showing an odor reduction device for a sewage facility according to the present invention.
2 is a cross-sectional view showing an odor gas removal unit according to a first embodiment of the present invention.
3 is a cross-sectional view showing an odor gas removal unit according to a second embodiment of the present invention.
4 is a cross-sectional view showing an odor gas removal unit according to a third embodiment of the present invention.
5 is a cross-sectional view showing a gas-liquid spraying unit according to a third embodiment of the present invention.
6 is a cross-sectional view showing an odor gas removal unit according to a fourth embodiment of the present invention.

In order to fully understand the present invention and its operational advantages and objectives achieved by the practice of the present invention, reference should be made to the accompanying drawings illustrating preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, the present invention will be described in detail by describing preferred embodiments of the present invention with reference to the accompanying drawings. Like reference numerals in each figure indicate like elements.

Hereinafter, the odor reduction device 100 for sewage facilities according to the first embodiment of the present invention will be described.

1 is a conceptual diagram schematically illustrating an odor reduction device for a sewage facility according to a first embodiment of the present invention, and FIG. 2 is a cross-sectional view showing a malodor gas removal unit according to a first embodiment of the present invention.

1 and 2, the odor reduction device 100 of a sewage facility according to the first embodiment of the present invention includes an odor gas treatment tank 110 into which odor gas generated in a sewage pipe P flows, and a sewage pipe A stink gas supply unit 125 provided in the connection pipe 120 connecting P and the stink gas treatment tank 110 to supply stink gas generated in the sewage pipe P to the stink gas treatment tank 110; The odor gas treatment tank 110 includes an odor gas removal unit 130 provided inside the odor gas treatment tank 110 to remove odor gas introduced into the odor gas treatment tank 110 .

The odor gas treatment tank 110 according to the present embodiment serves to accommodate the odor gas introduced from the sewage pipe P and provide a space for removing the odor gas.

The odor gas treatment tank 110 may be manufactured to have various sizes according to the amount of odor gas generated in the sewage pipe P, and the odor gas treatment tank 110 may have a cylindrical shape with a hollow inside. The scope of the invention is not limited thereto and may have various shapes.

The odor gas treatment tank 110 and the sewage pipe P are connected in communication with each other through a connection pipe 120 . In addition, the odor gas treatment tank 110 has an inlet 111 formed on one side through which the odor gas generated in the sewage pipe P flows through the connection pipe 120, and an outlet 111 through which the air from which the odor gas is removed is discharged on the other side ( 113) is formed. In addition, a centrifugal force type aspirator 115 is installed at the outlet 113 of the malodorous gas treatment tank 110, and when the aspirator 115 is rotated by the wind, the air from which the odorous gas in the malodorous gas treatment tank 110 is removed is removed. It is discharged to the outside through the aspirator 115.

The odor gas supply unit 125 according to the present embodiment is installed in the connection pipe 120 and serves to supply odor gas generated in the sewage pipe P to the odor gas treatment tank 110 . The odorous gas supply unit 125 according to the present embodiment includes at least one or more blowing fans provided in the connection pipe 120 .

The odor gas removal unit 130 according to the present embodiment is provided in the odor gas treatment tank 110 and serves to remove hydrogen sulfide, which is the main cause of odor gas.

Specifically, the odor gas removal unit 130 includes a odor gas concentration detection module 140 provided in the odor gas treatment tank 110 and detecting the concentration of odor gas distributed inside the odor gas treatment tank 110, and the odor gas concentration detection module 140. A water injection module 150 for spraying water into the odor gas treatment tank 110 in response to the concentration of the odor gas detected by the concentration detection module 140 is included.

The malodorous gas concentration detection module 140 is provided above the malodorous gas treatment tank 110 and measures the concentration of hydrogen sulfide, which is the main cause of the malodorous gas. The concentration of hydrogen sulfide detected by the odorous gas concentration detection module 140 is transmitted to the controller 154 to be described later. The control unit 154 controls the flow rate of water sprayed from the top of the odor gas treatment tank 110 by adjusting the flow control valve 153 according to the concentration of hydrogen sulfide. In addition, the control unit 154 controls a chemical control valve to supply a chemical capable of removing hydrogen sulfide to the water injection nozzle 151, which will be described later, when the concentration of hydrogen sulfide detected by the odor gas concentration detection module 140 is greater than a set value. (157) can be operated and adjusted.

The water spray module 150 is connected to the water spray nozzle 151 disposed inside the odor gas treatment tank 110 to spray water, and is connected to the water spray nozzle 151 to supply water to the water spray nozzle 151. A water supply pipe 152 having one end connected to the water supply pipe 152 and the other end connected to a medicine tank 156 storing a medicine for removing hydrogen sulfide containing odorous gas; The control unit 154 controls the amount of water supplied to the water supply pipe 152 and the amount of the chemical discharged from the chemical supply pipe 155 contained in the odorous gas detected by the detection module 140 and supplied to the chemical supply pipe 155. include

The water injection nozzle 151 is disposed above the odor gas treatment tank 110 and is connected to the water supply pipe 152 and the chemical supply pipe 155 in communication with each other. In addition, a plurality of water injection nozzles 151 may be installed to be spaced apart from each other in the width direction and the length direction of the odor gas treatment tank 110 . The water spray nozzle 151 is installed on the top of the odor gas treatment tank 110 and sprays water or water containing chemicals downward. This uses the property of dissolving hydrogen sulfide contained in odor gas in water, and when the concentration of hydrogen sulfide is high, it is possible to effectively remove hydrogen sulfide by supplying a chemical that selectively removes hydrogen sulfide.

The water spray nozzle 151 sprays water or water containing chemicals in a spray type that sprays water from the top of the odor gas treatment tank 110 downward, and the water sprayed from the water spray nozzle 151 is the odor gas. In order to prevent a dead space (dead sPe) in which water is not sprayed into the upper space of the treatment tank 110, the sprays overlap each other.

As shown in FIG. 2, the water spray angle sprayed from the water spray nozzle 151 is illustrated as having an angle of 65 degrees (°), but the water spray angle sprayed from the water spray nozzle 151 may have various angles. And this does not limit the scope of the present invention.

The water supply pipe 152 receives water from a water supply source (not shown) including a water supply pipe. Water is supplied to the water injection nozzle 151 through the water supply pipe 152, and when the water supply pipe is used as a water supply source, the water supply pipe is connected to the water supply pipe through a constant water hole so that the water supply pipe and the water supply pipe 152 communicate with each other. . In addition, a flow control valve 153 for adjusting the flow rate of water supplied to the water spray nozzle 151 is provided in the water supply pipe 152 .

On the other hand, the water injection nozzle 151 is supplied with a chemical for removing hydrogen sulfide through a chemical supply pipe 155. One end of the medicine supply pipe 155 is connected to the medicine tank 156 in which medicine is stored, and the other end is connected to the water supply pipe 152. The use of chemicals is optional, and when the concentration of hydrogen sulfide is high, the hydrogen sulfide removal effect can be maximized by selectively spraying the chemicals. In addition, a chemical control valve 157 for controlling the discharge amount of the chemical supplied to the water injection nozzle 151 is provided in the chemical supply pipe 155 .

The control unit 154 simultaneously or individually operates the flow control valve 153 and the chemical control valve 157 according to the concentration of hydrogen sulfide detected by the odor gas concentration detection module 140 .

The control unit 154 controls a larger amount of water to be supplied to the water spray nozzle 151 when the concentration of hydrogen sulfide detected by the odor gas concentration detection module 140 is greater than a set value (for example, the concentration of hydrogen sulfide is 1 ppm). Or, conversely, when the hydrogen sulfide concentration is below the set value or weak, the flow rate of water supplied to the water spray nozzle 151 is reduced or cut off. That is, the controller 154 controls the flow control valve 153 to adjust the flow rate of water supplied to the water spray nozzle 151 along the water supply pipe 152 .

In addition, when the concentration of hydrogen sulfide detected by the odor gas concentration detection module 140 is higher than the set value, the control unit 154 controls the chemical control valve 157 so that water and chemicals can be simultaneously injected from the water injection nozzle 151. is controlled so that the medicine together with water can be supplied to the water injection nozzle 151.

Meanwhile, an orifice (not shown) is installed in the water supply pipe 152 to which the medicine supply pipe 155 is connected so that the medicine is smoothly supplied to the water supply pipe 152 in conjunction with the water flowing through the water supply pipe 152 . This lowers the pressure in the drug supply pipe 155 in the area connected to the water supply pipe 152 by the water flowing through the orifice, so that the drug is interlocked with the water flowing through the water supply pipe 152, and the water supply pipe 152 is connected to the water supply pipe 152. ) to ensure a smooth supply. In addition, since the chemical control valve 157 is controlled by the control unit 154 and the chemical is naturally supplied to the water supply pipe 152 by the orifice installed in the water supply pipe 152, the chemical injection pump 177 ( Not shown) has the advantage of not having to use.

As such, the control unit 154 controls the flow control valve 153 and the chemical control valve 157 to interlock with each other, adjusts the discharge amount of the chemical supplied to the water supply pipe 152, and controls the top of the odor gas treatment tank 110. It is possible to optimize the amount of chemicals sprayed from

According to the first embodiment of the present invention, the chemical is a powder or solid hydrogen sulfide removal material, iron salt (FeCl ₃ ), (A) montmorillonite filler, (B) magnesium chloride, and (C) a mixed additive in which sodium alginate is mixed. include additional

Here, it was confirmed that the mixed additive completely removes even a small amount of hydrogen sulfide that was not removed even by a chemical containing only iron salt (FeCl ₃ ) and contributes to preventing hydrogen sulfide from being discharged into the atmosphere. However, for this purpose, the content of each component or It was confirmed that the following ratio is very important, and if it is out of any one content range or content ratio range, the effect of completely eliminating hydrogen sulfide emission cannot be achieved.

In particular, rather than using the mixed additives alone or selectively using them, hydrogen sulfide emission can be completely excluded only in the first chemical treatment step, and the use of auxiliary agents for aggregation can be avoided to easily remove impurities after removal. It is possible to lower the freezing point of water to lower the process operation cost and prevent the process from being stopped due to clogging, thereby improving the process operation time.

In addition, it is possible to easily remove fine contaminant particles or particulate chemicals contained in water, thereby reducing the process time and cost required for the secondary filtration process.

Furthermore, this effect is based on the organic bonding relationship between the above-mentioned components, and this also requires that the content or ratio of each component is as follows. , it was confirmed that the effects of freezing point depression, prevention of process operation stoppage due to clogging, etc. could not be achieved.

First, the chemical should contain iron salts (FeCl ₃ ) at 100 to 800 ppm and the mixed additives at 5 to 10 ppm.

In addition, the mixed additives should further include a mixed additive in which (A) montmorillonite filler, (B) magnesium chloride and (C) sodium alginate are mixed,

Based on 100 parts by weight of the (A) montmorillonite filler, (B) 1 to 5 parts by weight of magnesium chloride and (C) 1 to 5 parts by weight of sodium alginate should be mixed.

The average diameter of the montmorillonite filler is preferably 1.0 to 8.0 mm.

Hereinafter, an odor reduction device 100α of a sewage facility according to a second embodiment of the present invention will be described.

3 is a cross-sectional view showing an odor gas removal unit according to a second embodiment of the present invention.

Referring to FIG. 3, the odor reduction device 100a of a sewage facility according to the second embodiment of the present invention includes a odor gas treatment tank 110a into which odor gas generated in a sewage pipe P flows, and a sewage pipe P A malodorous gas supply unit 125a provided in the connection pipe 120a connecting the odor gas treatment tank 110a and supplying the odor gas generated in the sewage pipe P to the odor gas treatment tank 110a, and odor gas treatment A malodorous gas removal unit 130a provided inside the tank 110a to remove the malodorous gas introduced into the malodorous gas treatment tank 110a, and a malodorous gas removal unit 130a provided inside the malodorous gas treatment tank 110a to collect the malodorous gas It includes a collecting chamber (145a).

The malodorous gas treatment tank 110a, the malodorous gas supply unit 125a, and the malodorous gas removal unit 130a according to the second embodiment of the present invention are combined with the malodorous gas treatment tank 110 according to the first embodiment of the present invention. Since the odor gas supply unit 125 and the odor gas removal unit 130 are the same, a detailed description thereof will be omitted.

Hereinafter, the difference between the collection chamber 145a according to the second embodiment of the present invention will be described.

The collection chamber 145a according to the present embodiment is provided on the inner bottom surface of the odor gas treatment tank 110a and serves to primarily collect the odor gas introduced from the sewage pipe P.

The collecting chamber 145a has a hollow interior and is formed in a cone shape with a cross-sectional area decreasing from the bottom to the top. In addition, the collection chamber 145a has an open lower portion disposed above the inlet 111a of the odor gas treatment tank 110a and an open upper portion disposed to face the water spray nozzle 151a. The odor gas generated in the sewage pipe P flows into the collection chamber 145a through the inlet 111a of the odor gas treatment tank 110a and the lower part of the collection chamber 145a, and then flows into the collection chamber 145a. The odorous gas is discharged toward the water spray nozzle 151a through the open top.

Meanwhile, an intake fan 146a may be provided inside the collection chamber 145a, and the intake fan 146a removes odor gas from the inlet 111a of the odor gas treatment tank 110a to the lower and upper parts of the collection chamber 145a. Through it can be discharged in the direction of the water injection nozzle (151a).

As such, the odorous gas is discharged in the direction of the water injection nozzle 151α through the upper portion of the collection chamber 145a, thereby providing a water injection nozzle 151α without considering the dead space in which water is not injected in the odor gas treatment tank 110α. can reduce the number of In addition, since the odorous gas is discharged in the direction of the water injection nozzle 151α through the upper part of the collection chamber 145a, the spray angle of water injected from the water injection nozzle 151α can be narrowed, thereby removing the odorous gas more efficiently.

Hereinafter, an odor reduction device 100β of a sewage facility according to a third embodiment of the present invention will be described.

FIG. 4 is a cross-sectional view showing an odor gas removal unit according to a third embodiment of the present invention, and FIG. 5 is a cross-sectional view showing a gas-liquid spraying unit according to a third embodiment of the present invention.

4 and 5, the odor reduction device 100b of a sewage facility according to a third embodiment of the present invention includes an odor gas treatment tank 110b into which odor gas generated in a sewage pipe P flows, and a sewage pipe A malodorous gas supply unit 125b provided in the connection pipe 120b connecting P and the malodorous gas treatment tank 110b to supply the malodorous gas generated in the sewage pipe P to the malodorous gas treatment tank 110b; A malodorous gas removal unit 130b is provided inside the malodorous gas treatment tank 110b and removes the malodorous gas introduced into the malodorous gas treatment tank 110b.

In addition, the odor gas removal unit 130b includes a odor gas concentration detection module 140b provided in the odor gas treatment tank 110b and detecting the concentration of odor gas distributed inside the odor gas treatment tank 110b, and the odor gas concentration detection module 140b. A water injection module 150b for injecting water into the odor gas treatment tank 110b in response to the concentration of the odor gas detected by the concentration detection module 140b, and a lower part of the odor gas treatment tank 110b in which water is accommodated. It sprays water containing the odorous gas in the region to include an aeration module 160b.

The odor gas treatment tank 110b and the odor gas supply unit 125b according to the third embodiment of the present invention are the odor gas treatment tank 110b and the odor gas supply unit 125b according to the first embodiment of the present invention Since they are the same, a detailed description thereof will be omitted.

In addition, the odor gas concentration detection module 140b and the water injection module 150b of the odor gas removal unit 130b according to the third embodiment of the present invention are the odor gas removal unit 130b according to the first embodiment of the present invention. Since the odor gas concentration detection module 140b and the water spraying module 150b are the same as those of the above, a detailed description thereof will be omitted. Hereinafter, the aeration module 160b according to the third embodiment of the present invention, which is a difference, will be mainly described. do it with

In this embodiment, the inside of the odor gas treatment tank 110b is filled with water to a certain level, and the odor gas generated in the sewage pipe P is sprayed into the water accommodated in the odor gas treatment tank 110b by the diffusion module 160b. Soluble in water. In addition, in the present embodiment, a small amount of odor gas that is not dissolved in water contained in the odor gas treatment tank 110b corresponds to the concentration of hydrogen sulfide detected by the odor gas concentration detection module 140b provided on the top of the odor gas treatment tank 110b. According to the water spray module (150b) is dissolved in the water sprayed from the removed.

The diffuser module 160b according to the present embodiment includes a gas-liquid ejection unit 161b disposed in the lower region of the odor gas treatment tank 110b in which water is accommodated and spraying water containing the odor gas, and a gas-liquid ejection unit 161b. The odor gas supply unit 173b connected to the gas-liquid jetting unit 161b supplies odorous gas to the gas-liquid jetting unit 161b, and water is supplied to the gas-liquid jetting unit 161b through the water supply passage 176b connected to the gas-liquid jetting unit 161b. and a pump 177b.

The gas-liquid spraying unit 161b serves to inject water containing the odor gas into the water contained in the odor gas treatment tank 110b and to circulate or stir the water inside the odor gas treatment tank 110b.

The gas-liquid spraying unit 161b may be disposed adjacent to at least one of one inner wall or the other inner wall of the odor gas treatment tank 110b. As shown in FIGS. 4 and 5 , two gas-liquid injection units 161b may be disposed on one inner wall and the other inner wall of the odor gas treatment tank 110b to face each other.

The injection pressure and the injection flow rate of the gas-liquid injection unit 161b are not limited as long as water can be circulated inside the odor gas treatment tank 110b.

The gas-liquid spraying unit 161b includes a spraying body 162b installed in the lower area of the odor gas treatment tank 110b, to which the water supply passage 176b is connected to the lower side and the odor gas supply unit 173b is connected to the upper side; A plurality of gas-liquid spray nozzles 163b are provided along the circumference of the sidewall of the body 162b to spray water containing the odor gas toward the inner wall of the odor gas treatment tank 110b.

In the injection body 162b, water in the odor gas treatment tank 110b is introduced through the water supply passage 176b connected to the lower side, and odor gas is introduced through the odor gas supply unit 173b connected to the upper side.

In addition, water and odorous gas introduced into the spraying body 162b pass through a plurality of gas-liquid spraying nozzles 163b provided along the circumference of the sidewall of the spraying body 162b by the pressure of the pump 177b to the odor gas treatment tank 110b. is sprayed toward the inner wall of the

In this embodiment, when water is sprayed through the gas-liquid spray nozzle 163b, the odorous gas supplied into the spray body 162b is mixed with the sprayed water by a venturi effect and sprayed together with the water.

To this end, the gas-liquid injection nozzle 163b is formed by penetrating the concave groove 165b formed on one surface coupled to the spray body 162b and the concave groove 165b in the direction from one surface to the other surface, but smaller than the diameter of the concave groove 165b. A space portion 169b is formed between the first unit nozzle 164b having a first through hole 166b having a diameter, one surface inserted into and coupled to the concave groove portion 165b, and the bottom surface of the concave groove portion 165b. and a second unit nozzle 167b having a second through hole 168b penetrating from one surface to the other surface.

In addition, the first unit nozzle 164b extends from one surface to the other inside the concave groove 165b and communicates with the odorous gas supply unit 173b, the concave groove 165b, and the space 169b. ) is further included.

As described above, the gas-liquid spray nozzle 163b includes a first unit nozzle 164b and a second unit nozzle 167b, and water is supplied to the spray body 162b along the water supply passage 176b by the pump 177b. After being supplied to the second through hole (168b) and when discharged along the first through hole (166b), the diameter of the second through hole (168b) decreases in the direction from the other side of the second unit nozzle (167b) to one side. Therefore, in response to the pressure applied by the pump 177b, the flow rate of the water discharged from the outlet side of the second through hole 168b increases and the pressure decreases, and accordingly, the odorous gas passes through the suction space S to the space portion 169b. is inhaled with That is, when water is discharged through the second through-hole 168b by the Venturi effect, the odor gas supplied to the injection body 162b by the odor gas supply unit 173b passes through the suction space S to the space portion 169b. ), and is mixed with water and discharged through the first through hole 166b together with the water.

On the other hand, in the present embodiment, a guide member ( 170b) may be installed.

The guide member 170b is installed in the upper region of the malodorous gas treatment tank 110b opposite to the gas-liquid injection unit 161b installed in the lower region of the malodorous gas treatment tank 110b and is installed on the inner wall of the malodorous gas treatment tank 110b. protrudes inwards Water rising from the bottom of the odor gas treatment tank 110b to the top is guided to the inside of the odor gas treatment tank 110b in a flow direction by the guide member 170b, and is circulated inside the odor gas treatment tank 110b. .

As described above, the gas-liquid spraying unit 161b sprays water containing the odorous gas at high pressure toward the inner wall of the odorous gas treatment tank 110b through the plurality of gas-liquid spraying nozzles 163b. After the water sprayed from hits the inner wall of the odor gas treatment tank 110b, it rises to the top of the odor gas treatment tank 110b and is guided by the guide member 170b to form a circulation path to descend, forming a circulation path in the odor gas treatment tank ( 110b), it is possible to efficiently dissolve malodorous gas in water by stirring.

As shown in FIG. 4 , the malodorous gas supply unit 173b serves to supply malodorous gas to the gas-liquid dispensing unit 161b, specifically the spraying body 162b.

The odorous gas supply unit 173b is provided in the odorous gas supply passage 174b, one end of which is connected to the upper side of the spray body 162b, and the odor gas supply passage 174b, so that when the pump 177b is stopped, water flows through the spray body 162b. ) includes a check valve 175b that opens and closes the odorous gas supply passage 174b to prevent reverse flow along the odor gas supply passage 174b.

As such, the malodorous gas is supplied from the outside of the malodorous gas treatment tank 110b to the top of the spray body 162b along the malodorous gas supply passage 174b. In addition, as described above, in this embodiment, while water is sprayed from the injection body 162b, the odorous gas is naturally introduced into the injection body 162b along the odor gas supply passage 174b by the Venturi effect due to the pressure drop. It does not require a means for forcibly supplying odorous gas.

In addition, when the pump 177b in the odor gas treatment tank 110b is stopped, such as for maintenance of the odor gas treatment tank 110b, water may flow back into the odor gas supply passage 174b. A check valve 175b is provided in the supply passage 174b.

On the other hand, the water supply passage (176b) is connected to the injection body (162b) of the gas-liquid injection unit (161b) to supply water to the injection body (162b). At this time, the pump (177b) is connected in communication with the water supply passage (176b) to supply water to the injection body (162b). The pump 177b is connected to the water supply passage 176b in communication, and supplies water in the odor gas treatment tank 110b to the spray body 162b through the water supply passage 176b. In addition, the pump (177b) provides the injection pressure of the water injected from the gas-liquid injection nozzle (163b).

Hereinafter, an odor reduction device 100γ of a sewage facility according to a fourth embodiment of the present invention will be described.

6 is a cross-sectional view showing an odor gas removal unit according to a fourth embodiment of the present invention.

Referring to FIG. 6, the odor reduction device 100c of a sewage facility according to the fourth embodiment of the present invention includes a odor gas treatment tank 110c into which odor gas generated in a sewage pipe P flows, and a sewage pipe P A malodorous gas supply unit 125c provided in the connecting pipe 120c connecting the odor gas treatment tank 110c to the odor gas treatment tank 110c to supply the odor gas generated in the sewage pipe P to the odor gas treatment tank 110c, and odor gas treatment A malodorous gas removal unit 130c provided inside the tank 110c to remove the malodorous gas introduced into the malodorous gas treatment tank 110c is included.

In addition, the odor gas removal unit 130c includes a odor gas concentration detection module 140c provided in the odor gas treatment tank 110c and detecting the concentration of odor gas distributed inside the odor gas treatment tank 110c, and the odor gas concentration detection module 140c. A water injection module 150c for injecting water into the odor gas treatment tank 110c in response to the concentration of the odor gas detected by the concentration detection module 140c, and a lower portion of the odor gas treatment tank 110c containing water. In the region, water containing odor gas is sprayed to disperse the acid module 160c and the odor gas treatment tank 110c containing water and immersed in the odor gas treatment tank 110c contain a plurality of microbial carriers 181c to which sulfuric microorganisms are attached ( 180c), a temperature control module 190c provided in the odor gas treatment tank 110c to adjust the temperature of the water accommodated in the odor gas treatment tank 110c, and a odor gas treatment tank provided in the odor gas treatment tank 110c. (110c) includes a pH concentration control module (195c) for adjusting the pH concentration of the water accommodated inside.

The odor gas treatment tank 110c and the odor gas supply unit 125c according to the fourth embodiment of the present invention are the odor gas treatment tank 110c and the odor gas supply unit 125c according to the first embodiment of the present invention Since they are the same, a detailed description thereof will be omitted.

In addition, the odor gas concentration detection module 140c and the water injection module 150c of the odor gas removal unit 130c according to the fourth embodiment of the present invention are the odor gas removal unit 130c according to the first embodiment of the present invention. Since the odor gas concentration detection module 140c and the water injection module 150c are the same as those of the odor gas concentration detection module 140c and the water injection module 150c, a detailed description thereof will be omitted, and the diffusion module 160c of the odor gas removal unit 130c according to the fourth embodiment of the present invention will be omitted. ) is the same as the diffuse module 160c according to the third embodiment of the present invention, so a detailed description thereof will be omitted. Hereinafter, the difference between the tint receiving module 180c, the temperature control module 190c and the pH control module 195c according to the fourth embodiment of the present invention will be mainly described.

In this embodiment, the inside of the odor gas treatment tank 110c is filled with water to a certain height, the tint receiving module 180c is immersed in the odor gas treatment tank 110c, and the odor gas generated in the sewage pipe P is acidified. The module 160c is sprayed into the water contained in the odor gas treatment tank 110c and dissolved in the water, and at the same time hydrogen sulfide is oxidized by the tint receiving module 180c. In addition, in the present embodiment, a small amount of malodorous gas that is not soluble in water stored in the malodorous gas treatment tank 110c or whose hydrogen sulfide is not oxidized by the tint receiving module 180c is a malodorous gas provided at the top of the malodorous gas treatment tank 110c. Depending on the concentration of hydrogen sulfide detected by the concentration detection module 140c, it is dissolved in water sprayed from the water injection module 150c and removed.

The tint receiving module 180c according to the present embodiment is immersed in the water contained in the odor gas treatment tank 110c and oxidizes hydrogen sulfide contained in the odor gas. Further, the oxygenation module 160c injects water containing the odor gas into the odor gas treatment tank 110c to circulate the water inside the odor gas treatment tank 110c.

The litter accommodating module 180c according to the present embodiment is immersed in the water contained in the odor gas treatment tank 110c and disposed above the gas-liquid spraying unit 161c of the aeration module 160c, and includes a plurality of microbial carriers 181c. ) includes a mesh network 182c accommodated to flow along with the flow of water.

The microorganism carrier 181c is a medium in which sulfur oxidizing microorganisms for oxidizing hydrogen sulfide contained in odorous gas can attach and grow.

For example, the microbial support 181c may have various shapes such as a sponge shape, a mat shape, a hose shape, a string shape, and a honeycomb shape. Use a sponge type or string type that can be enlarged.

The plurality of microbial carriers 181c described above are accommodated in the mesh net 182c and freely flow along with the flow of water in the mesh net 182c. In addition, in order to ensure fluidity of the microbial carrier 181c, the specific gravity range of the microbial carrier 181c is preferably 0.7 to 1.1. When the specific gravity range is out of the above range, the microbial carrier 181c is suspended and concentrated in the upper region of the mesh 182c, or the microbial carrier 181c is precipitated and concentrated in the lower region of the mesh 182c and does not flow. .

In addition, when water is circulated inside the odor gas treatment tank 110c by the aeration module 160c, the microbial carrier 181c can freely flow in the vertical direction according to the flow of water inside the mesh 182c. , It is possible to prevent hydrogen sulfide removal efficiency from being concentrated in a certain area within the mesh network 182c.

In addition, in order to prevent the microbial carrier 181c from being separated from the mesh net 182c, the mesh net 182c has a smaller mesh 183c than the microbial carrier 181c.

Meanwhile, as described above, the gas-liquid spraying unit 161c of the diffuser module 160c according to the present embodiment is disposed below the dye receiving module 180c to circulate water inside the odor gas treatment tank 110c, In order to facilitate the circulation of water inside the odor gas treatment tank 110c, a guide member 170c protruding inward from the inner wall of the odor gas treatment tank 110c is installed in the upper region of the odor gas treatment tank 110c. do. As such, as the water circulation inside the odor gas treatment tank 110c proceeds smoothly by the gas-liquid spraying unit 161c and the guide member 170c, the oxidation reaction of the sulfating microorganism attached to the microbial support 181c is activated. can make it

Specifically, since the gas-liquid spraying unit 161c jets water including the odorous gas at high pressure toward the inner wall of the odorous gas treatment tank 110c through the plurality of gas-liquid spraying nozzles 163c, the gas-liquid spraying nozzles 163c After the sprayed water collides with the inner wall of the odor gas treatment tank 110c, it rises to the top of the odor gas treatment tank 110c and is guided by the guide member 170c to form a circulation path to descend, forming a circulation path in the odor gas treatment tank 110c. ), it is possible to efficiently dissolve malodorous gas in water, and at the same time, it is possible to activate the oxidation reaction of sulfated microorganisms attached to the microbial support (181c).

In addition, the odor gas removal unit 130c according to the present embodiment includes a temperature control module 190c provided in the odor gas treatment tank 110c to adjust the temperature of the water accommodated in the odor gas treatment tank 110c, and the odor gas treatment tank 110c. A pH concentration control module 195c provided in the treatment tank 110c to adjust the pH concentration of water received in the odor gas treatment tank 110c is further included.

The temperature control module 190c serves to control the temperature of wastewater received in the odor gas treatment tank 110c in order to maintain an optimum temperature for culturing sulfur oxidizing microorganisms.

To this end, the temperature control module 190c includes a temperature sensor 191c provided in the odor gas treatment tank 110c to measure the temperature of water, a heating unit 192c provided in the odor gas treatment tank 110c to heat water, A cooling unit 193c provided in the odor gas treatment tank 110c to cool water is included.

In this embodiment, the temperature of the water contained in the odor gas treatment tank 110c is maintained at 10 to 30° C., which is the optimum temperature for culturing sulfur oxidizing microorganisms, by the temperature sensor 191c in the odor gas treatment tank 110c. is measured in real time, and accordingly, the temperature of the water is maintained at the optimum temperature through the heating unit 192c or the cooling unit 193c.

In this embodiment, the pH concentration control module 195c serves to adjust the optimal pH concentration for the cultivation of sulfated microorganisms.

To this end, the pH concentration control module 195c includes a pH concentration sensor 196c provided in the odor gas treatment tank 110c to measure the pH concentration of water, and a pH concentration sensor 196c provided in the odor gas treatment tank 110c to It includes a solution supply unit (197c) for supplying a pH concentration adjusting solution. And, the pH concentration sensor 196c is disposed on the top of the odor gas treatment tank 110c and is immersed in water.

In this embodiment, the pH concentration of water accommodated in the odor gas treatment tank 110c is maintained at pH 7.5 to 7.8, and a 20% NaOH solution or the like may be used as a pH concentration adjusting solution in this embodiment.

If the pH concentration of the water in the odor gas treatment tank 110c is lowered to less than pH 7.5, the development of sulfated microorganisms may be hindered and the culture rate of sulfated microorganisms may be halved. In this case, there is no significant difference in the culture rate of sulfated microorganisms, but a large amount of pH concentration adjusting solution may be introduced and lost.

In the present embodiment, the pH concentration of water in the odor gas treatment tank 110c is measured in real time by the pH concentration sensor 196c so that the pH concentration of the water accommodated in the odor gas treatment tank 110c is maintained at pH 7.5 to 7.8, and the pH concentration of the water in the odor gas treatment tank 110c is maintained in the range of pH 7.5 to 7.8. The pH concentration adjusting solution is supplied into the odor gas treatment tank 110c through the supply unit 197c.

As such, the present invention is not limited to the described embodiments, and it is obvious to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. Therefore, it should be said that such modifications or variations fall within the scope of the claims of the present invention.

100, 100a, 100b, 100c: odor reduction device 110, 110a, 110b, 110c: odor gas treatment tank
120, 120a, 120b, 120c: connection pipe 125, 125a, 125b, 125c: stink gas supply unit
130, 130a, 130b, 130c: odor gas removal unit
140, 140a, 140b, 140c: Odor gas concentration detection module
145a: collection chamber 146a: intake fan
150, 150a, 150b, 150c: water injection module 151, 151a, 151b, 151c: water injection nozzle
152, 152a, 152b, 152c: water supply pipe 153, 153a, 153b, 153c: flow control valve
154, 154a, 154b, 154c: Control unit 155, 155a, 155b, 155c: Chemical supply pipe
156, 156a, 156b, 156c: Chemical tank 157, 157a, 157b, 157c: Chemical control valve
160b, 160c: Diffusion module 161b, 161c: Gas-liquid injection unit
162b, 162c: injection body 163b, 163c: gas-liquid injection nozzle
164b: first unit nozzle 165b: concave groove
166b: first through hole 167b: second unit nozzle
168b: second through hole 169b: space
170b, 170c: guide member 173b, 173c: odor gas supply unit
174b, 174c: odor gas supply passage 175b, 174c: check valve
176b, 176c: water supply passage 177b, 177c: pump
180c: Tint receiving module 181c: Microbial tint
182c: mesh 183c: mesh
190c: temperature control module 191c: temperature sensor
192c: heating unit 193c: cooling unit
195c: pH concentration control module 196c: pH concentration sensor
197c: solution supply unit

Claims (15)

an odor gas treatment tank having an inlet through which odor gas generated in the sewer pipe flows in on one side and an outlet through which air from which odor gas has been removed is discharged on the other side; and
a malodorous gas concentration detection module provided in the malodorous gas treatment tank and detecting the concentration of malodorous gas distributed inside the malodorous gas treatment tank; It includes a odor gas removal unit having a water injection module for spraying water therein,
The water injection module,
a water spray nozzle disposed inside the odor gas treatment tank to spray water;
a water supply pipe connected to the water injection nozzle to supply water to the water injection nozzle;
a control unit controlling the amount of water supplied to the water supply pipe according to the concentration of the odor gas detected by the odor gas concentration detection module; and
a chemical supply pipe having one end connected to the water supply pipe and the other end connected to a chemical tank storing a chemical for removing hydrogen sulfide contained in malodorous gas;
The water spray nozzle injects water containing the chemical, and the control unit discharges the chemical supplied from the chemical tank to the chemical supply pipe according to the concentration of hydrogen sulfide contained in the odor gas detected by the odor gas concentration detection module. And adjusting the amount of water supplied to the water supply pipe,
The drug is an iron salt (FeCl ₃ ); and. (A) a mixed additive in which montmorillonite filler (B) magnesium chloride and (C) sodium alginate are mixed; further comprising,
The iron salt is ferric chloride (FeCl ₃ ),
The iron salt (FeCl ₃ ) is added to water at 100 to 800 ppm (mg/kg), and the mixed additive is added at 5 to 10 ppm (mg/kg) to the water into which the iron salt (FeCl ₃ ) is added,
The mixed additives are (A) 1 to 5 parts by weight of magnesium chloride, (C) 1 to 5 parts by weight of sodium alginate, based on 100 parts by weight of montmorillonite filler. According to claim 1,
The water injection nozzle sprays water containing the chemical in a spray type,
The water spray nozzles disposed adjacent to each other cause the sprayed water containing the chemical to overlap each other. According to claim 1,
It is provided on the inner bottom surface of the odor gas treatment tank, and is formed in a cone shape with a hollow interior and a cross-sectional area decreasing from the bottom to the top, the open bottom is disposed above the inlet, and the open top is the water spray nozzle A odor reduction device for a sewage facility further comprising a collection chamber disposed opposite to the air intake fan, in which odor gas generated in the sewage pipe is introduced into and collected by an intake fan accommodated therein, and the collected odor gas is discharged toward the water injection nozzle. . an odor gas treatment tank into which water is accommodated and odor gas generated in the sewage pipe flows; and
A malodorous gas removal unit for removing the malodorous gas introduced into the malodorous gas treatment tank;
The odor gas removal unit,
a malodorous gas concentration detection module provided in the malodorous gas treatment tank and detecting the concentration of the malodorous gas distributed inside the malodorous gas treatment tank;
a water injection module for injecting water into the odor gas treatment tank in response to the odor gas concentration detected by the odor gas concentration detection module; and
a gas-liquid jetting unit disposed in the lower region of the malodorous gas treatment tank and spraying water containing the malodorous gas; a malodorous gas supply unit connected to the gas-liquid jetting unit and supplying malodorous gas to the gas-liquid jetting unit; and the gas-liquid jetting unit a diffusion module having a pump for supplying water to the gas-liquid spraying unit through a water supply passage connected to;
The water injection module,
a water spray nozzle disposed inside the odor gas treatment tank to spray water;
a water supply pipe connected to the water injection nozzle to supply water to the water injection nozzle;
a control unit controlling the amount of water supplied to the water supply pipe according to the concentration of the odor gas detected by the odor gas concentration detection module; and
A chemical supply pipe having one end connected to the water supply pipe and the other end connected to a chemical tank storing a chemical for removing hydrogen sulfide contained in malodorous gas;
The water injection nozzle injects water containing the drug,
The control unit adjusts the discharge amount of the chemical supplied from the chemical tank to the chemical supply pipe and the amount of water supplied to the water supply pipe according to the concentration of hydrogen sulfide contained in the odor gas detected by the odor gas concentration detection module;
The drug is an iron salt (FeCl ₃ ); and. (A) a mixed additive in which montmorillonite filler (B) magnesium chloride and (C) sodium alginate are mixed; further comprising,
The iron salt is ferric chloride (FeCl ₃ ),
The iron salt (FeCl ₃ ) is added to water at 100 to 800 ppm (mg/kg), and the mixed additive is added at 5 to 10 ppm (mg/kg) to the water into which the iron salt (FeCl ₃ ) is added,
The mixed additive is (A) 1 to 5 parts by weight of magnesium chloride, (C) 1 to 5 parts by weight of sodium alginate, based on 100 parts by weight of montmorillonite filler. According to claim 4,
The odor gas removal unit,
The device for reducing odor in a sewage facility further comprising a carrier module for receiving a plurality of carriers for microorganisms to which sulfated microorganisms are attached and immersed in the odor gas treatment tank containing water. According to claim 5,
The tint receiving module,
A mesh net provided inside the odor gas treatment tank and disposed above the gas-liquid spraying part, and accommodating a plurality of the microbial carriers together with the flow of water contained in the odor gas treatment tank,
The microbial carrier has a specific gravity range of 0.7 to 1.1, and the mesh net has a smaller size mesh than the microbial carrier. According to claim 6,
The gas-liquid injection unit is disposed adjacent to at least one of one inner wall or the other inner wall of the odor gas treatment tank to inject odor gas;
A guide member protruding from an inner wall of the odor gas treatment tank and guiding water circulation inside the odor gas treatment tank is installed in an upper region of the odor gas treatment tank facing the gas-liquid injection unit. According to claim 7,
The gas-liquid injection unit,
a spraying body installed in a lower region of the odor gas treatment tank, the water supply passage being connected to a lower side and the odor gas supply unit being connected to an upper side; and
and a plurality of gas-liquid spray nozzles provided along the circumference of the sidewall of the spray body to spray water containing the odor gas toward the inner wall of the odor gas treatment tank. According to claim 8,
The gas-liquid injection nozzle,
A first unit nozzle having a concave groove formed on one surface coupled to the spray body and a first through hole formed through the concave groove in a direction from one surface to the other surface and having a smaller diameter than the diameter of the concave groove; and
A space portion is formed between one surface inserted into the concave groove and a bottom surface of the concave groove, and a second unit nozzle having a second through hole penetrating from one surface to the other surface,
A suction space extending from one surface of the first unit nozzle to the other surface and communicating with the odor gas supply part, the concave groove part, and the space part is formed inside the concave groove part, and the second through hole is formed in the second unit nozzle. The diameter increases from one side of the nozzle to the other side, and when water is sequentially discharged along the second through hole and the first through hole, the odorous gas is sucked into the space through the suction space and together with the water. An apparatus for reducing odor of a sewage facility discharged through the first through hole. According to claim 8,
The odor gas supply unit,
an odorous gas supply passage having one end connected to an upper side of the ejection body; and
A device for reducing odor in a sewage facility including a check valve provided in the odor gas supply passage to open and close the odor gas supply passage to prevent water from flowing backward along the odor gas supply passage in the injection body when the pump is stopped. . According to claim 4,
The odor gas removal unit,
A temperature control module provided in the odor gas treatment tank to control the temperature of the water accommodated in the odor gas treatment tank;
The temperature control module,
a temperature sensor provided in the odor gas treatment tank to measure the temperature of water;
a heating unit provided in the odor gas treatment tank to heat water; and
An odor reduction device for a sewage facility including a cooling unit provided in the odor gas treatment tank to cool water. According to claim 4,
The odor gas removal unit,
It further includes a pH concentration control module provided in the odor gas treatment tank to adjust the pH concentration of water accommodated in the odor gas treatment tank,
The pH concentration control module,
a pH concentration sensor provided in the odor gas treatment tank and immersed in water to measure the pH concentration of water; and
An odor reduction device for a sewerage facility comprising a solution supply unit provided in the odor gas treatment tank and supplying a pH concentration adjusting solution to the odor gas treatment tank. delete delete delete

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