KR101999165B1 - Chemical solution cleaning device using advanced oxidation process - Google Patents

Abstract

The present invention relates to a deodorization device using an advanced oxidation process and, more specifically, to a chemical liquid cleaning device which is configured to remove bad odor by using catalytic water and comprises: an outer cleaning housing having a cleaning water tank formed on an inner lower portion and including a central cleaning water tank, an inner cleaning water tank, and an outer cleaning water tank, and a cleaning inlet; a housing main body disposed on an inner side of the outer cleaning housing and including a cleaning outlet formed on an upper side and an inner cleaning housing in which annular cleaning barrier panels are formed at regular intervals along a longitudinal direction; a cleaning nozzle unit installed in the housing main body; and a catalytic water generating device configured to supply catalytic water to the outer cleaning housing and the inner cleaning housing of the housing main body, wherein the inner cleaning housing is provided in the outer cleaning housing, and the annular cleaning barrier panels are sequentially stacked on the inner cleaning housing, such that injected odorous gas is cleaned while sequentially moving, and thus, a retention time of the odorous gas is extended, thereby increasing cleaning efficiency, and different types of chemical liquid are injected to the outer cleaning housing and the inner cleaning housing, thereby further increasing the cleaning efficiency.

Description

[0001] The present invention relates to a deodorization apparatus using a high-level oxidation process,

The present invention relates to a deodorization apparatus using an advanced oxidation process (AOP), and more particularly, to a deodorizing apparatus using an advanced oxidation process (AOP). More particularly, the present invention relates to a deodorization apparatus having a cleaning inner housing inside a cleaning outer housing, The panel is formed and the introduced malodor gas is circulated and rotated to be cleaned so as to increase the retention time of the malodorous gas to increase the cleaning efficiency and to improve the cleaning efficiency by spraying various chemical solutions to the cleaning outer housing and the cleaning inner housing The present invention relates to a deodorization apparatus using an advanced oxidation process.

Conventionally, the emission level of pollutants or harmful gas is simply regulated. As the industry develops highly and exhaust gas standards are strengthened globally, pollution caused by odor is treated as serious social pollution.

In addition, various complaints related to the odor are increasing day by day, but the technology to remove the odor is not realistic in reality. In developed countries, the content that prevents the generation of odor is enacted as a law to minimize the generation of odor. .

On the other hand, harmful components such as SOx, NOx, formaldehyde, H2S, O3 and VOCs are contained in food waste disposal facilities, leather processing plants and sludge treatment of sewage treatment plants. And the gas caused by the loss of stinking bacteria).

Soil deodorization method, adsorption method, microbial treatment method, biofilter method and general cleaning method are used as measures to reduce the emission of harmful gas, which is harmful gas. However, installation cost and maintenance cost are excessive, In particular, it is pointed out that there is a serious problem that the cleaning efficiency of the odor removing efficiency is lowered due to the problem of the management of the spray nozzles and the filling materials and the discharge of the washing water fine particles to the atmosphere after the cleaning.

As described above, the cleaning apparatus according to the general cleaning method has been filed as a utility model, and the above-described degassing washer is disclosed in U.S. Utility Model Laid-Open No. 20-1997-20990, June 18, 1997 , A dust collecting plate in which a plurality of vortex passages are arranged in a radial pattern at a predetermined interval on the outer periphery of the distribution plate is interposed and a shaft and a rotating disk which are interlocked with the motor are installed in a driving part provided on the lower side, At the upper part of the plate, a jetting port connected to the water supply pipe is provided, and the jetted water is crushed by rotating the rotary disk, so that the water molecules of the particulate form adsorb the harmful components of the harmful gas, and then drops and discharges harmful components.

In another structure, a cleaning liquid containing a chemical is sprayed into the deodorizer to adsorb the harmful components of the harmful gas flowing into the cleaner and then discharged to the outside.

However, since the conventional gas scrubber has a complicated structure and has a single cleaning structure, there is a problem that the gas cleaning efficiency is lowered. In addition, there is a problem that the cleaning efficiency is lowered because the harmful gas is directly injected into the cleaning liquid, The retention time is short and the proper purification efficiency can not be obtained, so that there is a problem of double purification.

The above-mentioned invention means the background art of the technical field to which the present invention belongs, and does not mean the prior art.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a cleaning inner housing in a cleaning outer housing and an annular cleaning partition wall panel sequentially stacked in a cleaning inner housing, It is possible to increase the retention efficiency by increasing the residence time of the odor gas and to improve the cleaning efficiency by raising the cleaning efficiency again by spraying various chemicals into the cleaning outer housing and the cleaning inner housing (AOP), which is an object of the present invention.

The present invention relates to a chemical liquid cleaning apparatus for removing odors by using a catalytic number, comprising: a cleaning outer housing having a cleaning water tank portion having a central cleaning water tank, an inner cleaning water tank and an outer cleaning water tank, A housing main body including a cleaning inner housing which is disposed on the inner side of the housing and has a cleaning discharge port formed on the upper side thereof and in which annular cleaning partition wall panels are formed at regular intervals along the longitudinal direction, And a catalytic water generating device for supplying catalytic water to the cleaning outer housing and the cleaning inner housing of the housing main body.

Further, the present invention is characterized by comprising cleaning nozzle units installed inside the housing main body.

Further, the housing body is provided with a spray nozzle, and the spray nozzle unit is composed of a cleaning agent 1 spray nozzle formed on the inner upper side of the cleaning inner housing and a cleaning agent 2 spray nozzle formed on the inner lower side of the cleaning inner housing .

The gas-liquid separator further includes a gas-liquid housing formed on a bottom surface of the cleaning partition wall panel, a gas-liquid separator disposed inside the gas-liquid housing, and a gas-liquid separator disposed on the bottom surface of the gas- And a tube.

Also, the housing main body is provided with a gas-liquid mixing section, and the gas-liquid mixing section comprises gas-liquid mixers formed in the housing main body, wherein the gas-liquid mixer is installed between the cleaning outer housing and the cleaning inner housing .

The housing body may further include a sensor for sensing the concentration of the malodorous gas flowing into the housing body and the concentration of contaminants in the washing water tank.

In addition, it includes a flotation material removing device for filtering and removing flotation material floating by the rotation stirring and micro bubbles in each water tank, so that it is discharged to the outside through the treatment tank discharging line, and the purified treated water is re- .

The deodorization apparatus using the advanced oxidation process according to the present invention is characterized in that a cleaning inner housing is provided in a cleaning outer housing and an annular cleaning partition wall panel is sequentially stacked on the cleaning inner housing to sequentially move the odor gas, The micro-nano catalytic oxidation water injected to prevent air-winter wave, prevent gas-liquid separation and scale inside the tower, and increase the retention time of the malodorous gas. Thus, the cleaning efficiency can be increased, and the cleaning outer housing and the cleaning inner housing It is effective to increase the cleaning efficiency again by spraying various chemical solutions.

1 is a front view showing a deodorizing apparatus using an advanced oxidation process according to the present invention.
FIG. 2 is a view showing that a chemical solution is supplied to a deodorizing device using a high-level oxidation process according to the present invention.
FIG. 3 is a view showing a micro bubble generator of a deodorizing apparatus using an advanced oxidation process according to the present invention.
4 is a view illustrating a housing body of a deodorizing apparatus using an advanced oxidation process according to the present invention.
FIG. 5 is a view illustrating a process of moving a deodorizing device using a high-level oxidation process according to the present invention while purifying odor.
Fig. 6 is a plan view showing the apparatus for treating a polluted-water source of circulating water (washing water). Fig.
Fig. 7 is a side view of Fig. 6. Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

In addition, the following embodiments are not intended to limit the scope of the present invention, but merely as an example, and various embodiments may be implemented through the present invention.

FIG. 1 is a front view showing a deodorizing apparatus using an advanced oxidation process according to the present invention, FIG. 2 is a view showing that a chemical liquid is supplied to a deodorizing apparatus using an advanced oxidation process according to the present invention, and FIG. FIG. 4 is a view showing a housing body of a deodorizing apparatus using a high-level oxidation process according to the present invention, and FIG. 5 is a view showing a state in which a high- FIG. 2 is a view showing a process of moving a malodor of a deodorizing device using purified water.

As shown in the drawing, a deodorizing apparatus 10 (hereinafter, referred to as a deodorizing apparatus for convenience of description) using the advanced oxidation process of the present invention cleans the odor gas flowing into the deodorizing apparatus using the chemical solution and the catalyst water, The deodorizing device includes a housing main body 10, an external cleaning housing 20, an internal cleaning housing 30, a cleaning nozzle unit 40, and a catalyst water generating device 50 .

Using an oxidation auxiliary agent, such as an oxidation process (method) using a radical, hypochlorite oxygen, ozone, chlorine dioxide ^- is the catalytic oxidation of the OH: The term of "(Advanced Oxidation Process AOP) advanced oxidation processes" as used in the present invention OH ^- radicals and treating organic matter.

The housing main body 10 of the present invention has a washing water receiving portion 21 formed by a central washing water tank 211, an inner washing water tank 212 and an outer washing water tank 213 at an inner lower portion thereof, And an annular cleaning bulkhead panel (31) arranged inside the cleaning outer housing (20) and having a cleaning discharge port (32) formed on the upper side thereof, And a cleaning inner housing 30 formed with a gap maintained therebetween.

A lower end of the cleaning inner housing 30 is formed on the upper side of the cleaning finishing panel so as to be spaced apart from the cleaning finishing panel. The cleaning inner housing 30 is fixedly connected to the cleaning outer housing 20 by an annular finishing panel or shaft.

The number of catalysts injected from the cleaning nozzle unit 40, wash water, and sodium hypochlorite solution are filled into the central cleaning water tank 211, the inner cleaning water tank 212, and the outer cleaning water tank 213.

At this time, it is also possible that the number of catalysts, the washing water and the sodium hypochlorite solution filled in the washing water-containing portion 21 are circulated by a pump to be filtered and then supplied again to the cleaning nozzle portion 40.

The number of catalysts is obtained by supplying water containing microbubble-oxidized water to a catalyst tank 51 filled with a metal oxide (for example, platinum) and ionizing it, and is supplied from the catalyst tank 51.

The cleansing water is formed by mixing the microbubble-oxidized water supplied from the microbubble-oxidized water generator 90 with the water supplied from the washing water tank 52.

The sodium hypochlorite solution is formed by mixing the microbubble-oxidized water supplied from the microbubble-oxidized water generator 90 with sodium hypochlorite supplied from the sodium hypochlorite tank 53.

The micro bubble oxidation water generator 90 includes a housing body 91, an impeller 92, a medicine supplier 93, a separation protrusion 94, and an air hole 951.

A water inlet pipe 911 is formed on the outer surface of the housing main body 91 so as to be connected to the operation space so that the microbubble oxidation water formed in the operation space is discharged, And a micro bubble oxidation water discharge pipe 912 is formed on the outer surface so as to communicate with each other. The micro bubble discharge pipe 912 is further provided with a discharge groove 912c so that the micro bubble oxidized water discharged into the discharge groove 912c is vortexed and discharged.

The water inlet pipe 911 is connected to a pump to transmit external water to the housing main body 91 through the water inlet pipe 911. The water inflow pipe 911 further includes an inflow groove 911a to allow the inflow water to flow into the inflow groove 911a and then flow into the inflow groove 911a to increase the efficiency of forming the microbubble oxidation water.

The operating space formed inside the housing main body 91 is formed in a circular shape so that the impeller 92 having a disk shape is disposed and rotated.

The housing main body 91 may be formed of a metal material or a synthetic resin material.

The impeller 92 is disposed inside the housing body 91 and is rotated. A driving motor is installed in the housing main body 91 to rotate the impeller 92. The rotating shaft of the driving motor is disposed in the operating space and the bottom surface of the impeller 92 is fixed to the rotating shaft And the impeller 92 is rotated by driving the driving motor.

On the upper and lower surfaces of the impeller 92, stirring vanes 921 are formed to be annularly arranged to form micro bubble oxidation water by rotation of the impeller 92. The stirring vane 921 is formed at a predetermined interval on the rim of the upper surface and the bottom surface of the impeller 92. The stirring blades 921 formed on the upper and lower surfaces of the impeller 92 are preferably formed so as to cross each other.

The water and the chemicals flowing into the working space rub against the rotating impeller 92, the stirring vane 921 formed on the impeller 92 and the inner surface of the housing body 91, and are stirred while forming micro bubble oxidation water .

The medicine supply part 93 is formed in the housing body 91 to supply medicine.

The medicine supply part 93 is formed in a tubular structure and is formed to communicate with the operation space on the outer surface of the housing main body 91. A medicine supply pump is connected to the medicine supply part 93, Into the working space.

The separating protrusion 94 is formed inside the housing body 91 and has a through hole 941 formed therethrough.

The separating protrusion 94 is formed integrally with the inner surface of the housing main body 91 at one end and is disposed adjacent to the outer surface of the separating protrusion 94 at the other end, The water inflow pipe 911 is formed on one side of the micro bubble oxidation water discharge pipe 911 and the micro bubble oxidation water discharge pipe 912 is formed on the other side thereof to partition the water inflow pipe 911 and the micro bubble oxidation water discharge pipe 912 into each other.

The water and the chemicals flowing into the working space are rotated along the rotating direction of the impeller 92, and micro bubble oxidation water is formed and then discharged to the outside through the micro bubble discharge pipe.

The air supply unit 95 supplies air to the connector 941.

The air supply unit 95 includes an air hole 951 formed in the housing main body 91 to communicate with the connection hole 941 and an air pump for supplying air to the air hole 951.

At this time, the micro bubble to be rotated in the operating space along the rotation direction of the impeller 92 is discharged through the micro bubble discharge pipe, and the impeller 92, which is rotated partly, And moves to a position where the water supply pipe is disposed together with the air flowing through the air hole 951 to be mixed with the water flowing through the water supply pipe.

That is, since micro bubbles mixed with air are supplied to the water introduced from the water supply pipe through the connection port 941, the amount of bubbles formed when the air is supplied directly to the operation space from the air supply unit 95 The size of the bubble to be formed can be reduced, and the efficiency of forming micro bubbles can be increased.

Vortex grooves 913 are formed in the housing body 91 to communicate with the operating space.

The water and the medicines moved by the impeller 92 are drawn into the vortex groove 913, vortexed and stirred, and friction or collide with the vortex groove 913, thereby increasing the efficiency of forming micro bubbles.

A curved bubble guide surface 913a is further formed in the vortex groove 913.

The bubble guide surface 913a prevents the micro bubble formed in the vortex groove 913 from being caught in the vortex groove 913 during the discharge.

The vortex groove 913 is formed with a predetermined gap on the inner side surface thereof to further form an engaging groove so that the vortexed water flowing into the vortex groove 913 or the microbubble oxidation water formed therein is caught and collided with the engaging groove, It is desirable to increase the formation efficiency of the micro bubble oxidation water.

An air replenishment unit 912a is further provided in the microbubble-oxidized water discharge pipe 912 so that air is further mixed with the discharged microbubbles, so that air is mixed with microbubbles discharged through the microbubble discharge pipe 912, And the injection efficiency can be increased, and the discharge capacity can be increased.

The air replenishing unit 912a is connected to an air pump 951 to supply external air to the micro bubble discharging pipe 912. The air replenishing unit 912a has a tubular structure, It is preferably formed integrally with the micro bubble oxidation water discharge pipe 912.

The micro bubble oxidized water discharge pipe 912 is further provided with a water replenishment unit 912b for further mixing water into the micro bubble oxidized water discharged from the micro bubble oxidized water discharge pipe 912, The discharge efficiency and the injection efficiency can be increased, and the discharge capacity can be increased.

A water supply pump is connected to the water replenishing unit 912b to supply water from the outside. The water replenishing portion 912b has a tubular structure.

It is preferable that the vibrator which is a vibrator is further screwed to the outer surface of the housing main body 91 so as to increase the efficiency of forming micro bubbles by the rotation of the impeller 92 and the vibration of the vibrator.

One end of the vibrating fins is further welded to the stirring vane 921 so that the vibration transmitted from the vibrator is transmitted to the vibration pin and is transferred to the water and the medicine, Do.

The vibrating pin may be formed of a metal material, or alternatively may be formed of a synthetic resin material having elasticity.

In addition, striking fins are further formed on the inner surface of the housing main body 91 so that the impeller 92 strikes the striking pin in the course of the rotation of the impeller 92 to swirl the water by the vibration or the locking phenomenon, It is preferable to increase the efficiency of forming bubbles.

The striking pin may be formed of a synthetic resin material having elasticity, and one end may be fixed to the inner surface of the housing body 91 by fusion or adhesion. Alternatively, it may be formed of a metal material having elasticity.

The washing partition wall panel 221 is welded to the lower inner side and upper side of the washing inner housing 30, and welded to the middle part to provide a total of three, and the washing partition wall panel 221 is formed to be spaced apart from each other. At this time, the number of the washing partition wall panels 221 may be three or less, or three or more.

The cleaning nozzle unit 41 of the cleaning nozzle unit 40 is disposed between the cleaning outer housing 20 and the cleaning inner housing 30 and is provided with a cleaning Are disposed on the upper and lower sides of the partition wall panel (31), and are disposed on the inner lower side of the cleaning outer housing (20). The cleaning nozzle units 41 are welded and fixed to the cleaning outer housing 20 and the cleaning inner housing 30 by a connecting bar.

A cleaning nozzle unit 41 disposed between the cleaning outer housing 20 and the cleaning inner housing 30 and a cleaning nozzle unit 41 disposed above the cleaning inner housing 30 receive the number of catalysts The cleaning nozzle unit 41 disposed below the cleaning inner housing 30 receives and feeds the sodium hypochlorite chemical solution to clean the malodorous gas, and the cleaning outer housing 20 , The cleaning nozzle unit 41 is supplied with cleaning water and injects cleaning water to clean the malodorous gas.

The cleaning apparatus having the above-described structure is configured to clean the malodorous gas flowing into between the cleaning outer housing 20 and the cleaning inner housing 30 by the catalytic number, and then the cleaning partition wall panel 31 is formed in multiple stages, The odor gas is introduced into the cleaning inner housing 30, and the cleaning solution is sequentially moved while being cleaned by the cleaning water. Thus, the cleaning efficiency is increased while being moved along a predetermined path, and the retention time is increased and the cleaning efficiency can be increased again.

In addition, a certain space (air layer) is formed between the cleaning outer housing 20 and the cleaning inner housing 30 to move the malodorous gas and to prevent the winter wave from being generated.

The catalytic water generating device 50 supplies the catalytic number and the washing water to the housing main body 10.

The catalytic water generator 50 includes a micro bubble oxidation water generator 52 for discharging cleaning water mixed with microbubbles, an oxidizer, and air into water, a micro bubble oxidation water generator 52, And a catalytic tank 51 for discharging the catalyst water formed by ionizing the mixed cleaning water with a metal oxide (e.g., platinum). The catalyst tank 51 is filled with a metal oxide (a metal having a magnetic substance, for example, platinum).

The housing main body 10 is provided with a cleaning nozzle unit 40 composed of cleaning nozzle units 41 for spraying cleaning water containing microbubble oxidation water or a catalyst number for cleaning the malodorous gas, 40 are composed of a cleaning outer housing of the housing main body 10 and cleaning nozzle units 41 installed inside the cleaning inner housing.

A filter structure demister 33 made of a disc-shaped synthetic fiber material is adhered or screwed on the inside upper part of the cleaning inner housing 33 to filter the odor component of the odor gas traveling along a predetermined path again In addition, the water contained in the odor gas is removed.

The housing main body 10 is provided with a spray nozzle unit 60. The spray nozzle unit 60 includes a cleaning agent 2 spray nozzle 61 formed at an inner upper portion of the cleaning inner housing 30, And a cleaning agent 1 spraying nozzle 62 formed on the inner lower side of the cleaning agent spraying nozzle 30.

The injection nozzle unit 60 includes a cleaning agent 1 spray nozzle 61 welded to the inside upper part of the cleaning inner housing 30 and a cleaning agent 2 spray nozzle 62 welded to the inner lower part of the cleaning inner housing 30 The cleaning agent 1 spray nozzle 61 and the cleaning agent 2 spray nozzle 62 are composed of an annular support panel and a spray unit welded to be communicated with the spray holes formed in the support panel, Or a tube structure in which the inner diameter becomes narrower toward the upward direction, thereby accelerating the moving odor gas.

The gas-liquid separator 70 is welded to the bottom surface of the washing partition wall panel 31 so that the purified gas is introduced into the washing- Liquid separator 72 disposed in the gas-liquid housing 71 so as to be rotated by a blower, and a gas-liquid separator 72 formed on the bottom of the gas-liquid housing 71. The gas- And a guide tube (73).

Liquid separator 72 separates the chemical liquid such as the washing water and the catalyst contained in the cleaned odor gas traveling through the cleaning inner housing 30 and separates the separated chemical liquid through the guide tube 73 Liquid separation unit 70 or the washing water-collecting unit 21 in sequence. The gas-liquid separator 72 has an impeller structure.

At this time, it is preferable that the bottom surface of the gas-liquid housing 71 is formed to be tapered downward toward the medial center so that the separated chemical liquid is transferred to the guide tube 73.

Liquid mixing unit 80 is provided in the housing main body 10 and the gas-liquid mixing unit 80 is composed of a gas-liquid molar massagers 81 installed in the housing main body 10, (81) is screwed between the cleaning outer housing and the cleaning inner housing.

The chemical liquid injected from the cleaning nozzle unit 40 is mixed with the malodor gas through the gas-liquid molar blower 81, so that the malodor component contained in the malodor gas can be effectively purified. The gas-liquid molar massager 81 is formed of an impeller structure, and is provided with a plate having an inclined structure for rotating the gas-liquid molar massager 81.

The cleaning apparatus further includes a detection sensor for detecting the concentration of the malodorous gas flowing into the cleaning apparatus and the contamination concentration of the cleaning water tank. The concentration of the malodorous gas injected through the cleaning nozzle unit 40 Concentration and micro bubble oxidation water in the washing water tank and the amount of the catalyst water can be controlled.

Next, a method (AOP) for treating the circulating water (washing water) generated in the deodorizing apparatus according to the present invention will be briefly described.

6 is a plan view showing a circulation water (washing water) tank contamination source treatment apparatus, and Fig. 7 is a side view of Fig.

As shown in the figure, floating substances (scum and foreign substances) floating by rotation stirring and micro bubbles in the respective water tanks (micro / nano bubble water tank, micro / nano bubble oxidation water tank and micro / nano bubble catalyst oxidation water tank) (Catalyst), oxidation water, washing water, and the like) is re-supplied to the line and is reused (discharged) through the line 291. The purified water is discharged to the outside through the discharge line 291a, .

In the above process, the pollutants are oxidized and decomposed by the catalytic oxidation water by the annular rotation, and the pollutants are oxidized and decomposed while being rotated by the secondary oxidized water. As a result of the third treatment by the micro- And is separated and discharged.

The deodorization apparatus using the altitude oxidation process according to the present invention as described above allows the odorous gas containing odorous components to be cleaned while being sequentially moved while being rotated in the cyclone structure inside the cleaner to increase the residence time It is possible to prevent the deterioration of the cleaning efficiency caused by the technique, and the cleaning efficiency can be greatly improved.

It will be apparent to those skilled in the art that various modifications and equivalent arrangements may be made therein without departing from the scope of the present invention as defined by the appended claims and their equivalents. . Therefore, it is to be understood that the present invention is not limited to the above-described embodiments. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims. It is also to be understood that the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

10: housing body 20: cleaning outer housing
21: washing water portion 211: central washing water tank
212: inner washing water tank 213: outer washing water tank
214: cleaning inlet 30: cleaning inner housing
31: Cleaning bulkhead panel 32: Cleaning outlet
33: Demister 40: Cleaning nozzle part
41: Cleaning nozzle unit 50: Catalytic water generator
51: catalytic tank 52: rinse water tank
53: Soda hypochlorite tank 60: Injection nozzle part
61: cleaning agent 1 jetting nozzle 62: cleaning agent 2 jetting nozzle
70: gas-liquid separator 71: gas-liquid housing
72: gas-liquid separator 73: guide pipe
80: gas-liquid mixing section 81:
90: micro bubble oxidation water generating device
91: Housing main body 911: Water inlet pipe
911a: inlet groove 912: micro bubble oxidation water outlet tube
912a: Air replenishing portion 912b: Water replenishing portion
912c: discharge groove 913: vortex groove
913a: bubble guide surface 92: impeller
921: stirring blade 93: drug supply part
94: separating protrusion 941: connector
95: Air supply part 951: Air ball
531: Water tank contamination source treatment device of circulating water (washing water)
291: Micro Nano Bubble Tank
292: micro-nano bubble oxidation tank
293: micro-nano bubble catalytic oxidation water tank
294: Removal of flotation material by micro bubble water (exhaust) device
291a: Pollutant and treatment tank discharge line

Claims (6)

A chemical liquid cleaning apparatus for removing odors by using a catalytic water,
A cleaning outer housing having a cleaning water tank portion composed of a central cleaning water tank, an inner cleaning water tank, and an outer cleaning water tank and formed with a cleaning inlet,
A housing body including a cleaning inner housing disposed at an inner side of the cleaning outer housing and having a cleaning outlet formed at an upper side thereof and annular cleaning partition wall panels formed therein at regular intervals along the longitudinal direction;
A cleaning nozzle unit installed in the housing main body;
A catalytic water generating device for supplying catalytic water to the cleaning outer housing and the cleaning inner housing of the housing main body; And
And a micro bubble oxidation water generating device (90) for supplying microbubble oxidation water to the cleaning nozzle part,
The micro bubble oxidation water generator includes a water inlet pipe formed in a circular operation space and having a water inlet at one side thereof and a micro bubble oxidation water outlet pipe formed at the operation space to discharge the micro bubble oxidation water to the outside, An impeller disposed inside the housing body and rotated to form micro bubble oxidation water by stirring the water and air introduced into the housing body, a medicine supply part formed in the housing body to supply the medicine to the operation space, And an air supply unit for supplying air to the connection port. The micro bubble oxidation water flows into the interior of the housing body to be vortexed and discharged, Grooves < RTI ID = 0.0 > Deodorizing device using the oxidation process.
The method according to claim 1,
Wherein a dehumidifier is further disposed in an inner upper portion of the cleaning inner housing.
delete The method according to claim 1,
Wherein the cleaning nozzle unit comprises cleaning nozzle units installed inside the housing main body.
The method according to claim 1,
Wherein the housing main body is provided with a spray nozzle portion, the spray nozzle portion comprises a cleaning agent 1 spray nozzle formed at an upper portion inside the cleaning inner housing and a cleaning agent 2 spray nozzle formed at an inner lower portion of the cleaning inner housing,
The gas-liquid separator further includes a gas-liquid housing formed on a bottom surface of the cleaning bulkhead panel, a gas-liquid separator disposed in the gas-liquid housing, and a guide pipe formed on a bottom surface of the gas- Lt; / RTI >
Wherein the gas-liquid mixing section is provided in the housing main body, and the gas-liquid mixing section comprises gas-liquid mixers formed in the housing main body, and the gas-liquid mixer is installed between the cleaning outer housing and the cleaning inner housing. Deodorizing device using process.
The method according to claim 1,
And a flotation material removing device for filtering and removing flotation materials floating by microbubbles in the respective tanks in order to rotate and to discharge the purified water to the outside through the treatment tank discharging line and reuse the purified treated water into the line for reuse A deodorizing device using an advanced oxidation process.

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