KR20200129745A - Deodorizing apparatus with the function of promoting microbial decomposition - Google Patents

Abstract

The present invention relates to a deodorizing device having a function of promoting microbial decomposition and, more specifically, to a deodorizing device which removes odor by introducing gas into a main body and making the gas in contact with a cleaning liquid sprayed from the inside. The deodorizing device is divided into a plurality of zones including a rectangular space by a partition wall located inside the main body, wherein the plurality of zones are arranged in two layers, upper and lower layers, at least two or more are arranged sideways, and the zones are configured to be introduced from one side and discharged to the other side, so that the gas introduced into the main body passes through all the zones. The present invention has an effect of increasing the deodorization performance by increasing the contact time between the gas and the cleaning liquid by sequentially passing all of the areas divided by internal partition walls, thereby capable of manufacturing a deodorizing device with a smaller size. In addition, it is effective to further increase the contact time between the gas and the cleaning liquid by installing a directional partition wall adjusting the direction of the gas when entering the area inside the main body and thus allowing the gas to be reflected and moved inside before being discharged from the area. Furthermore, the deodorizing device of the present invention has an excellent effect of promoting the deodorization treatment of aerobic microorganisms by increasing the residence time of the gas and the contact time with the cleaning liquid.

Description

DEODORIZING APPARATUS WITH THE FUNCTION OF PROMOTING MICROBIAL DECOMPOSITION}

The present invention relates to a deodorizing device, and more particularly, to a deodorizing device using a cleaning liquid.

In general, in places such as sewage treatment plants, excreta treatment plants, food waste treatment facilities, livestock facilities, etc., various organic or inorganic gases are generated to generate complex odors, and a deodorizing device to remove such odors is used.

Among various methods for removing odors, a deodorizing device for removing odor-generating substances by spraying a cleaning liquid such as water or a chemical solution onto a gas containing odor-generating substances has been applied.

The conventional deodorizing apparatus is configured to remove odor-generating substances while the sprayed cleaning liquid contacts the gas by injecting gas from the lower part of the space where the cleaning liquid is sprayed and raising it upward. However, there is a disadvantage in that the contact time between the gas and the cleaning liquid is not long, and in order to solve this, a very long tower-shaped deodorizing device had to be removed, and the size and shape of such a deodorizing device had very limited application fields.

On the other hand, a deodorizing device having a reaction time increasing means for increasing the contact time between the gas and the cleaning liquid has been studied, but since it is a technology applied in the form of a basic deodorizing device, the effect of miniaturizing the deodorizing device cannot be obtained.

Korean Patent Registration 10-1287058

An object of the present invention is to provide a deodorizing apparatus capable of miniaturizing the apparatus by increasing the contact time between a gas and a cleaning liquid as to solve the problems of the prior art.

A deodorizing device having a function of promoting microbial decomposition according to the present invention for achieving the above object is a deodorizing device that removes odor by introducing gas into the body and contacting the gas with the cleaning liquid sprayed therein, and is located inside the body. It is divided into a plurality of zones including a space of a rectangular parallelepiped by a partition wall, and the plurality of zones are arranged in two layers of the upper and lower layers, and at least two are arranged sideways, and the zones are introduced from one side and the other side It is configured to be discharged, characterized in that the gas introduced into the body is configured to move through all the zones.

The deodorizing apparatus of the present invention performs a function of promoting the deodorization treatment of aerobic microorganisms by increasing the residence time of the gas and the contact time with the cleaning liquid.

At this time, when the cleaning solution contains an organic peroxide or peroxide material, a polymerization reaction is caused while forming active radicals. Oxygen compounds are generated to maintain an appropriate oxygen concentration. In the end, it is possible to solve various problems such as increasing the activity of the carrier and increasing oxygen, removing organic matter by maintaining the pH, and removing the pressure loss of power, and further promoting the deodorization treatment of aerobic microorganisms.

At least one of the plurality of zones is provided with a directional partition wall for adjusting the direction of the gas on the side where the gas is introduced, and the directional partition allows the gas to move toward the first reflective wall facing the side where the gas is discharged. desirable.

At this time, the directional partition wall is a gas so that the gas that has moved toward the first reflective wall is reflected by the first reflective wall and then is reflected back to the second reflective wall disposed adjacent to the first reflective wall to be discharged to the discharge surface. The direction of can be adjusted.

The directional partition wall is a perforated plate in which a plurality of perforations are formed, and may be to control a direction of a gas by a burr formed in a perforating process.

Each of the plurality of areas is composed of a separately manufactured module, and it is possible to modularize the main body by assembling each module. At this time, the number of modules constituting the main body may be adjusted based on the deodorization performance.

A deodorizing device is operated based on the value measured by the sensor of the inlet by further comprising an inlet through which gas is introduced into the main body and an outlet through which gas is discharged to the outside of the main body, and a sensor for detecting odor is installed at the inlet. Can be controlled.

In addition, when a sensor for detecting an odor is further installed at the outlet, the deodorization efficiency can be checked through comparison with a sensor at the inlet.

Since the deodorizing device of the present invention is manufactured in a smaller size compared to the conventional deodorizing device, a movable deodorizing device can be configured by installing a wheel on the main body.

The present invention configured as described above has the effect of increasing the deodorization performance by increasing the contact time between the gas and the cleaning liquid by configuring the gas to pass through all of the zones divided by the internal partitions in sequence, thereby producing a deodorizing device with a smaller size. have.

In addition, by installing a directional partition wall that adjusts the direction of the gas when it enters the area inside the body, it is effective to further increase the contact time between the gas and the cleaning liquid by allowing the gas to be reflected and moved inside before being discharged from the area. .

Furthermore, the deodorizing apparatus of the present invention has an excellent effect of promoting the deodorization treatment of aerobic microorganisms by increasing the residence time of the gas and the contact time with the cleaning liquid.

1 is a cross-sectional view for explaining the structure of a deodorizing apparatus according to an embodiment of the present invention.
2 is a view for explaining the flow of air in the deodorizing apparatus according to an embodiment of the present invention.
3 is a view for explaining in detail the flow of air for each movement zone included in the deodorizing apparatus according to an embodiment of the present invention.

An embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

However, the embodiments of the present invention may be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. The shapes and sizes of elements in the drawings may be exaggerated for clearer description, and elements indicated by the same reference numerals in the drawings are the same elements.

And throughout the specification, when a part is "connected" to another part, this includes not only the case of being "directly connected", but also the case of being "electrically connected" with another element interposed therebetween. In addition, when a part "includes" or "includes" a certain component, it means that other components are not excluded and other components may be further included or provided unless otherwise specified. do.

In addition, terms such as "first" and "second" are used to distinguish one component from other components, and the scope of the rights is not limited by these terms. For example, a first component may be referred to as a second component, and similarly, a second component may be referred to as a first component.

1 is a cross-sectional view for explaining the structure of a deodorizing apparatus according to an embodiment of the present invention.

The main body of the deodorization device of this embodiment includes a plurality of areas (100, 210, 220, 230, 240, 250, 260, 300) divided by a partition wall, and the gas introduced into the deodorization device sequentially passes these areas. As it passes, the path passing through the inside of the deodorizing device increases and the deodorization efficiency is improved. The areas inside the body (100, 210, 220, 230, 240, 250, 260, 300) have a rectangular parallelepiped inner space including the front and rear walls.

Specifically, the zones 100, 210, 220, 230, 240, 250, 260, and 300 of the deodorizing device are divided into two layers, an upper layer and a lower layer, and are connected in a plurality in a lateral direction. At this time, four zones are arranged as a unit so that the gas that has flowed into the interior through the upper zone located on one side in the horizontal direction can be discharged through each zone and through the upper zone located on the other side in the horizontal direction. .

In FIG. 1, when gas is introduced through the inlet zone 100 of the upper layer located on the left, it sequentially passes through the internal movement zones 210, 220, 230, 240, 250, 260, and It is discharged through the discharge zone 300. To this end, each of the zones 100, 210, 220, 230, 240, 250, 260, and 300 is configured such that gas is introduced from one side and discharged to the other side.

The inlet zone 100 is a portion into which a gas containing an odor generating substance is introduced, and is connected to the inlet 110 and the inlet pipe 120. In the present embodiment, gas is conveyed and introduced into the inlet pipe 120 from a separate space, but when a deodorizing device is installed in the odor generating space, the inlet pipe 120 may not be present.

A sensor for measuring odor may be attached to the inlet 110, and the operation performance of the deodorizing device may be adjusted based on the degree of odor measured by the sensor.

Movement zones (210, 220, 230, 240, 250, 260) are parts where the gas flowing into the inlet zone (100) is deodorized by the cleaning liquid and is sprayed from the inside by lengthening the movement path of the gas. This is a part that increases deodorization efficiency by increasing contact with the cleaning liquid.

In order for the gas introduced into the inlet zone 100 to pass through all of the moving zones (210, 220, 230, 240, 250, 260) sequentially and be discharged through the discharge zone 300, the moving zones 210, 220, 230, 240, 250, 260) vertically moving and horizontally moving from left to right are alternately performed. First, the gas introduced into the inlet zone 100 moves vertically downward and moves to the first moving zone 210 located under the inlet zone 100, and then the gas moves horizontally to the right and moves to the second moving zone 220. do. Next, the aircraft moves vertically upward and moves to the third moving zone 230, horizontally moves to the right, moves to the fourth moving zone 240, and then vertically moves downward and moves to the fifth moving zone 250. After the gas moves horizontally to the right again and moves to the sixth movement zone 260, the gas finally moves vertically upward and moves to the discharge zone 300.

According to the above description, the unit of gas circulation can be that the gas moves down once, moves once to the right, and then moves up again, and there are four basic areas including the moving area in the inlet and discharge areas. It can be seen that adjustment is possible in units. For example, FIG. 1 is a configuration in which two basic units are applied, and when a deodorizing device is configured with only one basic unit, the discharge area may be positioned at the place of the third moving area 230. Conversely, in the case of adding one unit in the configuration of FIG. 1, the same configuration as the third moving zone 230 may be installed in the place of the discharge zone 300, and the fourth moving zone 240 to the discharge zone may be added. . As described above, as the number of basic units composed of four zones increases, the path of the gas becomes longer and the deodorization efficiency increases, so the size of the deodorization apparatus can be adjusted according to the required deodorization capacity.

The conventional deodorization apparatus has a problem that the gas moves only in the vertical direction, and the size of the deodorization apparatus is very large and vertically long for sufficient contact with the cleaning liquid. On the other hand, the deodorizing device of the present invention has the advantage that the vertical movement proceeds up and down through the horizontal movement, so that the height of the device can be lowered, and the device can be downsized. In particular, by adding a moving area in the horizontal direction, the deodorizing capacity can be adjusted, and even when the deodorizing capacity is increased, the deodorizing capacity is increased in the horizontal direction, so that it can be installed indoors. Accordingly, it is possible to apply a cleaning liquid-type deodorizing device to areas where it was difficult to apply a cleaning liquid-type deodorizing device such as a meat house.

On the other hand, the deodorization device of the present invention increases the path of the gas while moving the movement zones 210, 220, 230, 240, 250, 260, and gives direction in the process of gas entering each zone, The cleaning time by is increasing, which will be described in detail later.

The discharge zone 300 is a discharge pipe 320 in order to discharge the gas from which the odor generating substance has been removed by the cleaning liquid to the outside of the device while sequentially moving the moving zones 210, 220, 230, 240, 250, 260 This connected outlet 310 is formed.

In the present embodiment, the discharge pipe is discharged to a separate space through the discharge pipe 320, but the discharge pipe 320 may not be provided when a deodorizing device is installed in the odor generating space.

A sensor for measuring odor may be attached to the outlet 310, and the operation performance of the deodorizing device may be adjusted based on the degree of odor measured by the sensor, and the result measured by the sensor installed at the inlet 110 and the outlet 310 You can also check the odor removal efficiency by comparing the results measured by the sensor installed in ).

A spray pipe 400 for spraying a cleaning liquid is located inside the body of the deodorizing apparatus according to the present embodiment, and the spray pipe 400 is installed on an upper layer among areas divided into two layers to increase cleaning efficiency. As shown, a cleaning liquid such as water or a chemical solution may be directly sprayed through the spray pipe 400, or a configuration of spraying the cleaning liquid through a separate spray nozzle is also possible.

As shown in the figure, the cleaning liquid is stored in the lower layer of the zones or in a separate recovery unit, and the pump 410 circulates and supplies the cleaning liquid to the injection pipe 400 through the transfer pipe 420. In addition, a drain valve 430 for removing the cleaning liquid is formed on one side of the lower layer, and a drain pipe 432 may be connected. On the other hand, since this embodiment is configured to circulate and use the cleaning liquid accumulated inside the device, the water supply port 440 and the water supply pipe 442 for supplying the cleaning liquid are connected, and unlike the illustrated one, the cleaning liquid may be directly supplied to the injection pipe. have.

When the cleaning liquid is excessively collected inside the body of the deodorization device, it is difficult to move the gas, so it is preferable to install a water level sensor 450 that detects the level of the cleaning liquid.

In addition, it is preferable to install a sieve 500 for filtering foreign substances floating in the washing liquid. In this embodiment, a sieve 500 is installed in the moving zone 210 on the side where the drain valve 430 is formed.

On the other hand, the motor or pump for transporting the gas so that the gas is introduced into the deodorization device through the inlet zone 100 and the odor-removed gas is discharged through the discharge zone 300, the inlet 110 and the outlet 310 ) Can be installed in one place or both sides.

In addition, although not shown in FIG. 1, since the deodorizing device of this embodiment is smaller in size than the conventional deodorizing device, it may be configured to move by attaching a wheel or the like under the device.

Hereinafter, a configuration for increasing the path of the gas in each movement zone in which the gas moves will be described.

2 is a view for explaining the flow of air in the deodorizing device according to an embodiment of the present invention, Figure 3 is a detailed description of the air flow for each movement zone included in the deodorizing device according to an embodiment of the present invention It is a drawing for.

As shown in FIG. 2, the deodorizing apparatus of this embodiment is characterized in that the gas flowing into each of the moving zones 210, 220, 230, 240, 250, and 260 is given directionality. Specifically, the moving zones are introduced in one of the four directions of up, down, left and right, and are discharged in one of the four directions, up, down, left, and right, and the opposite side of the discharge side is formed by a directional bulkhead located on the inlet side of each moving zone The flow of gas is controlled so that it is directed

The direction in which the gas flows in each of the movement zones shown in FIG. 3 will be described as follows. In each case, the direction of gas inflow and outflow is indicated by a large arrow, and the flow of gas inside is indicated by a dotted line.

First, gas is introduced into the first moving zone 210 from above and discharged to the right. At this time, the direction is adjusted to the left by the directional partition wall 212 located on the inlet side so that the gas faces the first reflective wall 214 facing the discharge side. The gas reflected by colliding with the first reflective wall 214 is bent toward the second reflective wall 216 facing the directional barrier 212, and the gas reflected by colliding with the second reflective wall 216 is discharged to the right. do.

In the second movement zone 220, gas is introduced from the left and discharged upward. At this time, the direction is adjusted downward so that the gas faces the first reflective wall 224 facing the discharge side by the directional partition wall 222 located on the inlet side. The gas reflected by colliding with the first reflective wall 224 is bent toward the second reflective wall 226 facing the directional barrier 222, and the gas reflected by colliding with the second reflective wall 226 is discharged upward. do.

In the third moving zone 230, gas is introduced from the bottom and discharged to the right. At this time, the direction is adjusted to the left by the directional partition wall 232 located on the inlet side so that the gas faces the first reflective wall 234 facing the discharge side. The gas reflected by colliding with the first reflective wall 234 is bent toward the second reflective wall 216 facing the directional barrier 232, and the gas reflected by colliding with the second reflective wall 236 is discharged to the right. do.

In the fourth moving zone 240, gas is introduced from the left and discharged downward. At this time, the direction is adjusted upward so that the gas faces the first reflective wall 244 facing the discharge side by the directional partition wall 242 located on the inlet side. The gas reflected by colliding with the first reflective wall 244 is bent toward the second reflecting wall 246 facing the directional barrier 242, and the gas reflected by colliding with the second reflective wall 226 is discharged downward. do.

The fifth movement zone 250 is the same as the first movement zone 210 in that gas is introduced from the top and discharged to the right, so a detailed description thereof will be omitted.

The sixth moving zone 260 is the same as the second moving zone 220 in that gas is introduced from the left and discharged upwards, so a detailed description thereof will be omitted.

In FIG. 2, the discharge area 300 has a discharge port 310 upward, so even if the direction of the gas is changed to the side, the path does not increase significantly, but a partition wall must exist between the sixth moving area 260. Since the contact between the cleaning liquid and the gas increases, a directional partition wall was installed.

As described above, in the present invention, the movement path of the gas is made to be very long by giving direction so that the gas is reflected inside each movement zone (210, 220, 230, 240, 250, 260). As the time increased, the deodorizing effect was greatly increased, and it could be manufactured in a smaller size than the conventional deodorizing device.

On the other hand, as summarized above, the directional bulkheads 212, 222, 232, 242, 252, 262 are located on the inlet side of each of the moving zones 210, 220, 230, 240, 250, 260 applied in the present invention. , The directional partition walls (212, 222, 232, 242, 252, 262) impart directionality so that the gas faces the first reflective wall (214, 224, 234, 244, 254, 264) facing the discharge side. It is the same in points. In the end, each of the moving zones 210, 220, 230, 240, 250, 260 can be manufactured as a module of the same type and modularized in which only the direction is changed during the assembly process. Therefore, only the inlet zone 100, the outlet zone 300, and the moving zone (210, 220, 230, 240, 250, 260) are separated, and if the inlet zone and the outlet zone are the same, two, the inlet zone and the outlet zone are different. In this case, it is possible to assemble by adjusting only the number and direction according to the required deodorizing performance after manufacturing in three shapes.

4 is a cross-sectional view illustrating a directional partition wall applied to a deodorizing device according to an embodiment of the present invention.

The deodorizing apparatus of the present invention includes a directional partition wall that adjusts the direction of travel so that the directional partition wall faces a surface facing the discharge side in order to increase the path of the gas inside the moving zone. Such a directional partition wall is not particularly limited and may be applied as long as it is configured so that the direction in which the gas flows is directed toward the side.

The directional partition wall 212 shown in FIG. 4 is a case in which a perforated plate having directional perforations is applied. The burr generated in the process of forming a plurality of perforations in the plate is configured to give direction to the flow of gas.

As described above, the deodorizing apparatus of the present invention can obtain another effect by increasing the reaction time with the cleaning liquid.

In general, biofilters are one of the methods of biologically treating pollutants in gases. An eco-friendly and economical treatment that decomposes pollutants into water, carbon dioxide and harmless salts by microbial metabolism by immobilizing microorganisms on a porous carrier. Say the construction method. The core technologies of these biofilters include the production technology of tinsel, which is the habitat of microorganisms, and the technology for selecting microorganisms that can effectively remove the cause of odor and VOC, and odor and harmful volatility generated from environmental facilities such as sewage treatment plants or industrial facilities. It can be applied to an odor removal device for treating waste gas containing (VOCs) substances. It can be harmonized with technologies such as microbial porous carriers that pass through a water film to improve treatment efficiency by exchanging waste gas and heat, and adsorb odor compounds contained in waste gas.

In the case of the biofilter method, which is a biological deodorization method, among the odor treatment methods that occur in various environmental and industrial facilities such as wastewater treatment plants, manholes, and sewers in the city, it is economical and non-selective compared to other deodorization methods. Is easy to treat and secondary pollutants are hardly generated during operation, so the frequency of use increases rapidly, and most of the deodorization methods used recently are made of biofilter.

Currently, the biofilter technology is recognized as an effective, inexpensive, and environmentally sound treatment method for treating low-concentration exhaust gases of several hundred ppmC. The scope of application includes the treatment of odors from wastewater treatment plants, composting facilities, and food processing plants, as well as the treatment of volatile exhaust gases generated during landfill gas and soil vapor extraction (SVC). A technique for this purpose is US Patent No. 6790653 "Biological filter apparatus with multiple filter units". This technology was developed to treat odorous substances including various volatile organic substances generated during the composting process. This technology is designed to pass odorous air through a multi-stage (three-stage) microbial membrane bed to increase treatment efficiency.

As such, the biofilter technology is limited in its use in that it requires a separate structure for culturing microorganisms and increasing treatment time.

On the other hand, in the present invention, since the residence time of the gas and the reaction time with the cleaning liquid can be sufficiently secured, only the advantages of the existing technology can be applied. Specifically, the present invention creates an environment in which aerobic microorganisms can be active without applying a bio filter or a separate culture tank, thereby increasing bio-promotion and microbial activity, and reducing the residence time (HRT) by dispersing air. There is a difference between raising and taking over

In particular, it is possible to increase the efficiency of deodorizing aerobic microorganisms that inevitably require oxygen. If the organic peroxide (a compound represented by the general formula R-O-O-R`) and a peroxide compound are properly maintained in the deodorizing device, microbial activity can be promoted and maximized. This solves the problem of efficient microbial elimination due to operating air volume, wind speed, and flow rate by physical pressure in the deodorization facility, which is pointed out as a disadvantage of the biofilter. As an oxygen-based compound, it can remove organic matters that interfere with the dominance of microorganisms, and at an appropriate concentration, it helps the activity of aerobic microorganisms. This optimum concentration can be easily measured by a dissolved or deodorant outlet, an internal oxygen concentration, a peroxide observer, an indication method, or a simple measurement method.

On the other hand, in the biofilter method, selecting the optimal deodorizing microorganism corresponding to the treatment of various odor components is a very important matter in operating a stable and excellent deodorizing facility and acts as a major factor in determining the success or failure of a biological deodorization facility. . However, in the case of microorganisms inoculating biofilters domestically and internationally, there are many cases of using microorganisms in aeration tanks (or anaerobic tanks) naturally occurring in sewage and wastewater treatment plants, or excess sludge from concentration tanks. In this case, naturally, among the numerous microorganisms in the sludge, microorganisms using odors as substrates dominate in accordance with the field conditions, and in conclusion, stable biological deodorization can be expected. However, the distribution of microorganisms that decompose odors among the initially inoculated sludge is not large. Therefore, it takes a very long time for microorganisms that decompose odors to become dominant and stabilize naturally in the deodorization equipment. When the deodorization efficiency is lowered, such as a shock, the problem cannot be solved immediately, and the deodorizing microorganism may be disadvantageous in the competitiveness of the substrate including oxygen compared to other microorganisms.Therefore, a large amount of unnecessary various microorganisms exist in the deodorization facility, and eventually the carrier is closed , Oxygen deprivation, pH decrease, pressure loss, and other various problems are caused, so that stable deodorization is not achieved.

In the present invention, by using an appropriate organic peroxide or an appropriate initiator belonging to peroxide in the cleaning solution, a polymerization reaction is caused while forming an active radical. Oxygen compounds are generated to maintain an appropriate oxygen concentration. In the end, it is possible to solve various problems such as increasing the activity of the carrier and increasing oxygen, removing organic matter by maintaining the pH, and removing the pressure loss of power. And finally, a stable deodorization is achieved. Sodium percarbonate (sodium carbonate), also called sodium percarbonate, which is a representative initiator used in this example, is an addition product of hydrogen peroxide, and the molecular formula is 2Na ₂ CO ₃ ㅇ3H ₂ O ₂ ) is a hygroscopic, colorless crystal, a solid soluble in water. Sodium percarbonate is included in some eco-friendly laundry products, and is also used in the production of anhydrous hydrogen peroxide in laboratories. The use of these safe agents among many types of initiators can also be recognized as an eco-friendly deodorization method.

As described above, the deodorizing apparatus of the present invention can improve the function of promoting microbial decomposition by adding an organic peroxide or peroxide to the cleaning solution, and the organic peroxide or peroxide included in the cleaning solution is not particularly limited, but sodium percarbonate It is desirable to select a type that is harmless to the human body, such as.

The present invention has been described above through preferred embodiments, but the above-described embodiments are only illustrative of the technical idea of the present invention, and various changes are possible within the scope not departing from the technical idea of the present invention. Those of ordinary knowledge will understand. Therefore, the scope of protection of the present invention should be interpreted not by specific embodiments, but by the matters described in the claims, and all technical ideas within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

100: inlet zone
110: inlet
120: inlet pipe
210, 220, 230, 240, 250, 260: moving zone
212, 222, 232, 242, 252, 262: Directional bulkhead
214, 224, 234, 244, 254, 264: first reflective wall
216, 226, 236, 246, 256, 266: second reflective wall
300: discharge area
310: outlet
320: discharge pipe
400: injection pipe
410: pump
420: transfer pipe
430: drain valve
432: drain pipe
440: water inlet
442: water supply pipe
450: water level sensor
500: strainer

Claims (11)

It is a deodorizing device that removes odor by introducing gas into the body and contacting the gas with the cleaning liquid injected from the inside.
It is divided into a plurality of zones including a rectangular parallelepiped space by a partition wall located inside the body,
The plurality of zones are arranged in two layers, the upper and lower layers, and at least two or more are arranged sideways,
The areas are configured to be introduced from one side and discharged to the other side, and the gas introduced into the main body is configured to move through all areas.
The method according to claim 1,
At least one of the plurality of zones is provided with a directional partition wall for adjusting the direction of the gas on the side where the gas is introduced,
The directional partition wall is a deodorizing device having a function of promoting microbial decomposition, characterized in that the gas moves toward the first reflective wall facing the side from which the gas is discharged.
The method according to claim 2,
After the gas moved toward the first reflective wall is reflected by the first reflective wall, the directional partition wall is reflected back to the second reflective wall disposed adjacent to the first reflective wall and discharged to the discharge surface. Deodorizing device having a function of promoting microbial decomposition, characterized in that to control.
The method according to claim 2,
The directional partition wall is a perforated plate in which a plurality of perforations are formed, and the direction of the gas can be controlled by a burr formed in the perforating process.
The method according to claim 1,
Each of the plurality of zones is composed of a separately manufactured module, the deodorizing device having a function of promoting microbial decomposition, characterized in that the body is configured by assembling each module.
The method of claim 5,
A deodorizing device having a function of promoting microbial decomposition, characterized in that the number of modules constituting the main body is adjusted based on the deodorizing performance.
The method according to claim 1,
Further comprising an inlet through which gas is introduced into the body and an outlet through which gas is discharged outside the body,
A deodorizing device having a function of promoting microbial decomposition, characterized in that a sensor for detecting odor is installed at the inlet.
The method of claim 7,
Deodorizing device having a function of promoting microbial decomposition, characterized in that controlling the operation of the deodorizing device based on the value measured by the sensor at the inlet.
The method of claim 7,
A deodorizing device having a function of promoting microbial decomposition, characterized in that a sensor for detecting an odor is further installed at the outlet to check the deodorizing efficiency.
The method according to claim 1,
A deodorizing device having a function of promoting microbial decomposition, characterized in that a wheel is installed in the main body to move.
The method according to claim 1,
A deodorizing device having a function of promoting microbial decomposition, characterized in that the washing liquid contains an organic peroxide or peroxide material.

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