KR102063317B1 - Air dispersion apparatus using water jet - Google Patents

Abstract

The present invention relates to an aeration device using a water jet. More specifically, the present invention relates to an aeration device for an aeration tank using a water jet. The aeration device is arranged in the aeration tank provided in a sewage treatment plant and applies high pressure wastewater into the aeration tank to form an aerated state in the wastewater stored in the aeration tank, thereby maximizing the amount of dissolved oxygen in the wastewater stored in the aeration tank and stably enabling biological treatment of wastewater.

Description

Air dispersion apparatus using water jet

The present invention relates to a diffuser apparatus using a waterjet, and more particularly, is disposed in the aeration tank provided in the sewage treatment plant to inject a high pressure to the waste water in the aeration tank to form an aeration state in the wastewater stored in the aeration tank, By maximizing the amount of dissolved oxygen, the present invention relates to an aeration tank apparatus for aeration tanks using a waterjet to stably implement biological treatment of wastewater.

In the treatment of various wastewater including the existing sewage and the like, a biological treatment process (standard activated sludge method) that is decomposed and removed by microorganisms is a key process in the treatment of wastewater containing a large amount of organic matter.

The standard activated sludge process, a biological treatment process developed in the UK in 1913, is currently used in most wastewater treatment plants and is the most used for the treatment of wastewater containing organic matter.

In addition, many variations are being studied as an aid to biological treatment methods today, and a very useful method for removing contaminants such as organic substances, nitrogen, and phosphorus in wastewater, and the standard activated sludge method is simply a primary sedimentation tank → aeration tank → It consists of a secondary sedimentation tank and removes organic matter in wastewater by decomposing and ingesting it using aerobic microorganisms.

In other words, the process of removing suspended solids from the primary sedimentation tank, dissolving soluble organic substances using aerobic microorganisms in the aeration tank, and partly synthesizing into microbial cells, converting the soluble materials into sludge, which is insoluble material, is precipitated in the secondary precipitation tank and to be.

In order to compensate for the disadvantages of the standard activated sludge treatment-oriented organic material treatment, a number of variations have been studied as described above, and representative examples include A / O and A2 / O.

Since biological treatment processes applied to the existing wastewater treatment process have to supply oxygen, which is necessary for the activity of aerobic microorganisms in the aeration tank, to the aeration tank, the aeration tank is equipped with an air supply means such as Root's Blower for 24 hours. The air should be supplied, and in the case of general aeration tanks, most of them have a depth of about 5 m. Install an air supply pipe at the bottom of the aeration tank, and install a number of diffusers by calculating the number of diffusers in accordance with the air supply. Supply oxygen.

By the way, the oxygen transfer rate is somewhat different depending on the type of diffuser and the water temperature in the aeration tank, but when the depth is 5m, the level is approximately 7-15%, and since the depth of the aeration tank is generally 5m, the pressure of Root's Blower Should be selected to be 0.5kg / cm2 or more.

As mentioned above, most of the methods for supplying air to the existing wastewater / sewage / wastewater treatment processes are operated 24 hours of Root's Blower of 0.5kg / cm2 or more, and air is supplied through the diffuser installed at the aeration tank depth of 5m or less. Most of the supply method can be said.

Existing aeration devices applied to various wastewater / sewage / wastewater treatment facilities break down air bubbles as finely as possible regarding how to increase the dissolved rate of air or oxygen under the same conditions, such as the temperature of a conventional wastewater / sewage / wastewater treatment reactor. How to implement the method of increasing the contact area with water and how to prevent the clogging of micropores in the diffuser, which usually have fine ventilation holes, are the key factors.

All the types of aeration devices that have been used to implement the above key points are air injection methods through diffusers.

Depending on the pore size of the diffuser or the material of the diffuser, the micro-bubble diffuser such as twister type, disc type, tube type, ceramic type, etc., and coarse bubble type diffuser type such as acid cylinder, bead filling type, acoustic resonance type, disc type, etc. However, the latter is partly used as a high concentration of livestock manure treatment plant or liquid fertilizer production tank due to low oxygen transfer efficiency, and is not used for general wastewater / sewage / wastewater treatment.

On the other hand, the former is much used because it has a higher oxygen transfer efficiency than the latter, but because the pore size of the diffuser is small, clogging occurs in the diffuser as the use time increases, the oxygen transfer efficiency is gradually reduced.

In the existing biological treatment process, if the concentration of BOD or nitrogen of raw water is increased or the inflow rate is increased due to the expansion of the plant and the addition of the process, the wastewater treatment is not possible without the expansion of the aeration tank, the increase of the amount of diffuser and the increase of the blower capacity Therefore, it is virtually impossible to cope with various field situations.

In the conventional diffuser method, since oxygen is supplied from the lower part of the aeration tank to the upper part, a blower having a pressure higher than the water pressure of the aeration tank depth of 5 m should be used, and a blower having a pressure of more than 0.5 kg / cm2 should be used. Since the engine is installed, it is possible to work only when the aeration tank is emptied, and when the replacement of the aeration tank occurs due to deterioration of oxygen transfer efficiency due to the clogging phenomenon of the existing diffuser, hardening of the components of the diffuser, etc. The operation is very difficult because the maintenance is possible to empty all.

For the above reasons, in case of aeration tank with existing diffuser installed, additional oxygen supply is difficult in case of fluctuation of inflow load and increase of inflow flow rate, so it is impossible to process with existing aeration tank capacity.

JP 2012110807 A KR 1020030071099 A KR 1020090051450 A

An object of the present invention devised to solve the above problems, is disposed in the aeration tank provided in the sewage treatment plant, by injecting the waste water into the aeration tank to form aeration state in the waste water stored in the aeration tank, the dissolved oxygen amount of the waste water stored in the aeration tank It is to provide an aeration tank device for an aeration tank using a waterjet to maximize the stability of the biological treatment of wastewater.

The above object is achieved by the following configuration provided in the present invention.

The diffuser device using the waterjet according to the present invention,

A circulation pump unit for forcibly circulating the wastewater stored in the aeration tank through the circulation supply pipe;

Disposed in communication with the circulation supply pipe, the waste water circulated and supplied along the circulation supply pipe, and a water jet reaction unit for ejecting aeration water mixed with external air downward into the aeration tank,

The waterjet reaction unit may include: at least one wastewater discharge pipe communicating with the circulation supply pipe, disposed upright in the aeration tank, and having a shaft pipe nozzle formed at a bottom thereof to form a reduced pressure by the shaft pipe;

One or more air supply pipes for introducing air into the shaft pipe nozzles of the wastewater discharge pipes and introducing air into the shaft pipe nozzles in which pressure is reduced by pressure deviation between the air and the shaft pipe parts; And

The upper end is installed to cover the outer wall of the shaft nozzle to form a waterjet reaction chamber, and the waste water discharged through the shaft tube nozzle and aeration water mixed with the air supplied into the shaft nozzle through the supply pipe of the air supply supply by decompression. It is characterized in that it comprises a mixed jet pipe for ejecting downward in the aeration tank.

Preferably, the waterjet reaction chamber is provided with re-suction holes for reflowing the wastewater stored in the aeration tank by pressure deviation into the waterjet reaction chamber by the pressure deviation due to the reduced pressure, so that the wastewater stored in the aeration tank is re-suction holes. It is re-introduced into the waterjet reaction chamber and then discharged downward through the mixing jet pipe.

More preferably, the waterjet reaction chamber is closed at the top to maintain a set pressure to prevent the air remaining in the aeration water ejected through the mixing jet pipe to rise and discharge,

One or more re-suction holes are formed on the sidewall of the water jet reaction chamber so that the wastewater stored in the aeration tank is re-introduced into the water jet reaction chamber through the re-suction holes and then discharged downward through the mixing jet pipe.

The wastewater discharge pipe and the mixing jet pipe are formed to have a flange corresponding thereto, and the mixing jet pipe is assembled to a flange formed on the wastewater discharge pipe to form a water jet reaction chamber in which the upper part is closed by the flange. Configured to form.

In addition, spiral guide pieces are disposed on an inner wall of the mixing jet pipe, and the aeration water mixed with the waste water is configured to discharge downward in a vortex form through the spiral guide piece.

In addition, a diffusion plate is disposed under the mixing jet pipe, but a plurality of permeation holes are formed in the diffusion plate, and some of the aeration water discharged by mixing is discharged downward through the permeation hole, and the remaining aeration water is discharged through the diffusion plate. While configured to diffuse outward,

The diffusion plate is disposed in an elevating structure through an elevating guide at an end of the mixed jet pipe and is elastically pulled upward by a traction spring, so that the diffuser is discharged while elastically elevating according to the amount and pressure of the jet ejected through the mixed jet pipe. It is configured to spread.

As described above, the diffuser apparatus using the waterjet according to the present invention forms a depressurized state of the wastewater circulated by the shaft pipe, and the external air is introduced and mixed through the air supply pipe by the depressurization, thereby being stored in the aeration tank and circulating. A large amount of air (oxygen) is mixed in the wastewater.

Therefore, in the diffuser apparatus according to the present invention, unlike the existing method, the circulation supply pipe, which is a waste water circulation line, and the air supply pipe, which is an air (oxygen) supply line, are located in the upper part of the aeration tank, so that the line (pipe) can be easily expanded without emptying the aeration tank. In addition, the oxygen supply principle increases the oxygen transfer efficiency by increasing the circulation rate of the wastewater rather than increasing the oxygen supply amount, thereby minimizing oxygen and increasing the contact efficiency with the wastewater. This much higher flow rate can be easily increased through the inverter control of the circulating pump, so the method of increasing the oxygen supply is very simple, and can actively cope with the influent load change.

Further, the diffuser device according to the present invention has a circulation supply pipe and an air supply pipe in the upper part unlike the existing diffuser method, and an intake pressure in which air is sucked by the rapid flow rate of the aeration water in which waste water and air are mixed is generated in the air supply pipe. Even if a very low pressure blower is used, there is no problem in the oxygen supply of the aeration tank.

Particularly, in the present invention, the waterjet reaction chamber is configured to have a closed upper portion in a “┏” shape, so that the air separated from the aeration water ejected through the mixing jet pipe is maintained by constantly maintaining a set pressure in the waterjet reaction chamber. Ejection is prevented.

Actually, as mentioned in the waterjet reaction section, the inventors of the present invention have a low pressure blower of 0.2 kg / cm2 or less because the suction pressure of air (oxygen) is generated in the oxygen supply line (air supply pipe) due to the high flow rate of the aeration water. Blower alone had no problem supplying enough oxygen to the aeration tank.

Also. The peculiarity of the air supply pipe is that oxygen is separately supplied through a separate line inside the wastewater circulation line, that is, a double line, so that the reaction of wastewater and air (oxygen) occurs in the waterjet reaction unit located above the aeration tank.

In addition, the circulation pump and the blower of the present invention was able to reduce power by about 20% or more in comparison with the power cost required for the diffuser type blower.

According to the present invention, when the aeration water in which waste water and air are mixed in the aeration tank is discharged downward into the aeration tank, the oxygen aeration efficiency of the conventional diffuser is about 7 to 15%, whereas the aeration device is about 50% or more under the same conditions. This was confirmed to be possible.

In addition, since the waterjet reaction part according to the present invention is made of stainless steel and is not a method of transferring oxygen (air) through the pores of the diffuser, the oxygen transfer efficiency is reduced due to the clogging phenomenon of the diffuser. Since no cracking or breakage due to hardening of the component occurs, it can be used semi-permanently instead of consumables like conventional diffusers.

1 and 2 show the construction state in which the diffuser device using the waterjet proposed as a preferred embodiment in the present invention disposed in the aeration tank,
Figure 3 shows the overall configuration of the diffuser device using a waterjet proposed as a preferred embodiment in the present invention,
4 and 5 are enlarged view of the action state of the 'A' portion and 'B' portion in FIG.

Hereinafter, with reference to the accompanying drawings will be described in detail the diffuser using a waterjet proposed as a preferred embodiment of the present invention.

1 and 2 show a construction state in which the diffuser device using the waterjet proposed as a preferred embodiment in the present invention disposed in the aeration tank, Figure 3 is an acid using a waterjet proposed as a preferred embodiment in the present invention 4 and 5 show the enlarged state of operation of the 'A' portion and the 'B' portion in FIG.

The diffuser device 1 using the waterjet proposed as a preferred embodiment of the present invention is installed in the aeration tank provided in the sewage treatment plant, as shown in Figs. 1 to 2, to force external air into the wastewater circulated in the aeration tank. It is a kind of air mixing device that promotes the biodegradation of the wastewater stored in the aeration tank by increasing the amount of dissolved oxygen of the wastewater stored and stored by mixing.

In addition, the diffuser device 1 using the waterjet according to the present embodiment, the circulation pump unit 100 forcibly circulating the wastewater stored in the aeration tank 10 through the circulation supply pipe 110 as shown in FIGS. 2 and 3. )Wow; It is disposed in communication with the circulation supply pipe 110, and includes a water jet reaction unit 200 for discharging the waste water circulated along the circulation supply pipe 110 and the aeration mixed with the external air downward in the aeration tank.

Therefore, the diffuser device 1 basically increases the flow rate of the waste water circulated through the shaft pipe through the shaft pipe nozzle 11a, and inhales outside air in the atmosphere through a waterjet reaction chamber in which pressure is reduced by increasing the flow speed. By doing so, the aeration in which wastewater and fine bubbles are mixed is a dedicated device that continuously supplies the aeration tank.

The circulation pump unit 100 is a flow rate control inverter 130 for controlling the driving speed of the circulation pump 120, a flow meter 140 for measuring the flow rate of the circulating wastewater, and a pressure gauge for measuring the pressure of the circulating wastewater 150 is provided.

Therefore, the circulation pump 120 is organically controlled by the driving speed according to the amount of dissolved oxygen of the wastewater stored in the aeration tank, the amount of wastewater, and the residual amount of organic matter contained in the wastewater by the control of the flow control inverter 130, The wastewater is configured to circulate in an amount suitable for the wastewater.

That is, the circulation pump 120 controlled by the flow control inverter 130 sucks the wastewater from the lower portion of the aeration tank and supplies water to the circulation supply pipe 110 to perform internal circulation of the wastewater stored in the aeration tank. One or more waterjet reaction units 200 are formed in the supply pipe 110 to mix a large amount of air into the wastewater supplied through the circulation pump 120 to be recycled to the aeration tank.

Here, the driving speed of the circulation pump 120 controlled by the flow control inverter 130 is the flow rate of the incoming wastewater, the characteristics, and the pollution load of each contaminant, the capacity of the aeration tank, the discharge limit, and the waterjet reaction unit It is adjusted according to the number of formation of the 200.

In addition, when the flow rate and characteristics of the influent wastewater in the future fluctuations in the load condition of the contaminants of each contaminant or to increase the amount of oxygen supply, to solve the problem by increasing the circulation amount of the circulation pump 120, or even insufficient in the circulation supply pipe (110) The water jet reaction unit 200 is disposed to increase the amount of aeration.

On the other hand, the waterjet reaction unit 200 to mix the air into the wastewater supplied by the circulation pump unit 100 and ejects into the aeration tank 10, the core function to induce a strong impact of the wastewater and air to generate microbubbles. Do this.

The waterjet reaction unit 200 is in communication with the circulation supply pipe 110 as shown in FIGS. 3 to 4 and is disposed upright in the aeration tank 10, the tube nozzle to form a reduced pressure state by the tube at the bottom ( One or more wastewater discharge pipes 210 formed thereon; The air supply end 221 is built in the shaft nozzle 211 of the wastewater discharge pipe 210 and the air flows into the shaft nozzle 211 in which the pressure is reduced by the pressure deviation between the atmosphere and the shaft nozzle 211. More air supply pipe 220; And the upper end is installed in a state surrounding the outer wall of the shaft tube nozzle 211 to form a waterjet reaction chamber 240, the waste pipe discharged through the shaft tube nozzle 211 and through the air supply pipe 220 by the pressure reducing pipe ( And a mixing jet pipe 230 which blows down the aeration incorporating air supplied into the air 211 into the aeration tank 10.

Here, the mixing blower pipe 230 is made of PE, which is a non-metallic material, and has a stable corrosion resistance and is light in weight so that it can be easily installed.

In addition, flanges 212 and 231 are formed on the outer diameter of the wastewater discharge pipe 210 constituting the waterjet reaction unit 200 and the upper portion of the mixed jet pipe 230 so as to correspond to the upper portion of the mixed jet pipe 230. Is assembled into a flange structure through the flanges (212, 231), the water jet reaction chamber 240, the upper portion is shielded by the flange 231 is formed on the top of the mixing jet pipe.

That is, the waterjet reaction chamber 240 has a closed top portion, and as described below, a resuction hole 241 is formed at an outer surface thereof, such that air that is raised along the mixing jet pipe may be formed into the resuction hole 241. The wastewater around the waterjet reaction chamber 240 is resorbed through the resuction hole 241 while preventing the leaked through the leak.

In particular, the waterjet reaction chamber 240 is closed at the upper portion of the "┏" type to maintain the set pressure to prevent the phenomenon that the air remaining in the aeration water ejected through the mixing jet pipe 230 is resuspended and discharged. .

Accordingly, a water jet reaction chamber 240 is formed in the upper portion of the mixing jet pipe 230 and accommodates the shaft nozzle 211 and is closed through the circulation supply pipe 110. The wastewater supplied to the water flows through the tube nozzle 211 disposed in the waterjet reaction chamber 240 to increase the flow rate, thereby forming a reduced pressure state of the waterjet reaction chamber 240.

At this time, the air supplied from the air supply pipe 220 separated from the wastewater rapidly supplied to the waterjet reaction chamber 240 through the tube nozzle 211 meets in the waterjet reaction chamber 240 and a very strong and rapid impact reaction is achieved. In the process, the air is scattered in the form of microbubbles, while the waste water forms very strong turbulence, which promotes faster diffusion of air.

That is, the waste water supplied from the shaft nozzle 211 and the air supplied through the air supply pipe 220 are rapidly mixed to form an aeration water, and the aeration water is downwardly lowered through the mixing jet pipe 230. The discharged water is mixed with the wastewater stored in the aeration tank 10 to increase the amount of dissolved oxygen in the wastewater.

The aeration water mixed with air and waste water in the waterjet reaction unit 240 is discharged from the upper portion of the aeration tank 10 to the bottom through the mixing jet pipe 230 together with the waste water, and dispersed in all directions in the aeration tank. 10) to rapidly increase the oxygen transfer efficiency of the wastewater stored in.

In particular, in the present embodiment, as shown in FIGS. 3 to 5, the mixing jet pipe 230 has a cyclone type in which a spiral guide piece 232 is disposed on an inner wall, and waste water and air in the waterjet reaction chamber 240. The mixed aeration water is discharged in the form of spiral vortex by the spiral guide piece 232 formed on the inner wall of the mixing jet pipe 230 in the process of ejecting downward through the mixing jet pipe 230.

In this configuration, the micro-bubbles generated in the waterjet reaction chamber 240 can be efficiently supplied to the lower portion of the aeration tank 10, which is an inflow direction of the wastewater, and the microbubbles and the wastewater including the same are further disposed below the aeration tank 10. It flows quickly and naturally to form spiral vortices.

In addition, the aeration water jetted to the bottom of the aeration tank 10 through the mixing jet pipe 230 diffuses up the entire flow through the flow of wastewater, and some of the microbubbles in the process are mixed again through the flow of wastewater. It is re-introduced into the waterjet reaction chamber 240 of 230 to increase the contact time with the waste water to maximize the air cutting efficiency.

To this end, in the present embodiment, as shown in FIGS. 1, 3, and 4, the aeration water of some of the aeration water jetted through the mixing jet pipe 230 is reintroduced into the sidewall of the waterjet reaction chamber 240, A re-suction hole 241 is ejected downward in the aeration tank 10 along the mixing jet pipe 230.

That is, one or more re-suction ports 241 are formed in the waterjet reaction chamber 240, and the aeration tanks 10 are formed through the re-suction holes 241 in the decompression section in which the decompression state is formed by the aeration tank 10 and the tube nozzle 211. Wastewater stored in the) is configured to be introduced into the waterjet reaction chamber 240, the resuction holes 241 are configured to be formed on the side of the mixing jet pipe (240).

Particularly, in the present embodiment, the induction pipe 242 is disposed in the resuction hole 241, and the suction end 242a of the induction pipe 242 is configured to have a relatively lower height than the resuction hole 241. In order to stably resorb the floating waste water while suppressing the phenomenon of re-emergence of the air ejected through the mixing jet pipe 230.

In addition, in the present embodiment, the diffusion plate 250 is disposed below the mixing jet pipe 230, and the wastewater discharged downward through the mixing jet pipe 230 is diffused outward through the diffusion plate 250. To be mixed with the wastewater stored in the aeration tank (10).

A plurality of permeation holes are formed in the diffusion plate 250 so that some of the aeration water mixed and discharged is discharged downward through the permeation hole 251, and the remaining aeration water is diffused outward through the diffusion plate 250.

In particular, in the present embodiment, the diffusion plate 250 is disposed in the lifting structure through the lifting guide 252 at the end of the mixing jet pipe and is elastically upwardly pulled by the traction spring 253, so that the mixing jet pipe 230 is provided. According to the amount and pressure of the aeration ejected through the elastically ascend to increase the number of aeration discharged.

More preferably, as shown in FIGS. 3 and 5, a ball joint coupling 254 is provided at an end of the elevating guide 252 so that a central portion of the diffusion plate 250 is provided at an end of the elevating guide 252. Assembled into a ball joint structure that can be deflected, and a plurality of pull springs 255 are radially disposed between the mixing jet pipe 230 and an edge of the diffusion plate 250 so that the diffusion plate 250 is By the pulling force of the pull spring (255) is to make the elastic pull state.

Accordingly, the diffusion plate 250 is all around the ball joint coupling 254 by the aeration pressure applied through the aeration water by the elastic pulling action of the ball joint coupling 254 and the pulling springs 255. Will cause the refractive fluctuation.

Thus, the aeration water sprayed through the mixing jet pipe 230 is partially diffused in the shielding and aeration tank 10 by the diffusion plate, so that the waste water stored in the more stable aeration tank 10 and the stable incorporation and waste water are stable. The flow increases the dissolved oxygen in the waste water stably in a short time.

In particular, the diffusion plate 250 is elastically up and down through the elevating guide 252 and the traction spring 253, and the elastic flexure through the ball joint coupling 254 and the pulling spring 255, As a result, the aeration water is dispersed and discharged in all directions, while foreign matter or organic matter remaining on the bottom of the aeration tank is floated by the diffusion plate 250 swinging up and down and in all directions, so that a stable mixing and decomposition with the aeration water can be achieved. have.

1. Diffuser using waterjet
10. Aeration tank
100. Circulation pump section 110. Circulation supply pipe
120. Circulating pump 130. Inverter for flow control
140. Flowmeter 150. Pressure gauge
200. Waterjet Reaction Unit 201. Waterjet Reaction Chamber
210. Wastewater discharge pipe 211. Shaft pipe nozzle
212.Flange 220.Supply pipe
221. Supply stage 230. Mixing blower pipe
231. Flange 232. Spiral guide
240. Waterjet reaction chamber 241. Resuction hole
242. Induction tube 242a. Suction
250. Diffusion Plate 251. Pitcher
252. Lifting guide 253. Traction spring
254. Ball Joint Coupling 255. Pull Spring

Claims (5)

A circulation pump unit for forcibly circulating the wastewater stored in the aeration tank through the circulation supply pipe;
Disposed in communication with the circulation supply pipe, the waste water circulated and supplied along the circulation supply pipe, and a water jet reaction unit configured to eject the aeration water mixed with external air downward into the aeration tank,
The waterjet reaction unit may include: at least one wastewater discharge pipe communicating with the circulation supply pipe and disposed upright in the aeration tank and having a shaft pipe nozzle formed at a lower end thereof to form a reduced pressure by the shaft pipe;
One or more air supply pipes for introducing air into the shaft pipe nozzles of the wastewater discharge pipes and introducing air into the shaft pipe nozzles in which pressure is reduced by pressure deviation between the air and the shaft pipe parts; And
The upper end is installed to cover the outer wall of the shaft nozzle to form a waterjet reaction chamber, and the waste water discharged through the shaft tube nozzle and the aeration water mixed with the air supplied into the shaft nozzle through the supply pipe of the air supply supply by decompression. And a mixing blowoff pipe ejecting downward into the aeration tank,
A diffuser plate is disposed under the mixed jet pipe, but a plurality of permeable holes are formed in the diffuser plate, so that some of the aerated water discharged by mixing is discharged downward through the perforated hole, and the remaining aerated water is discharged outward through the diffuser plate. While configured to spread,
The diffusion plate is disposed in an elevating structure through an elevating guide at an end of the mixed jet pipe, and is retracted upward by a traction spring, so that the diffuser is discharged while elastically lifting in accordance with the amount and pressure of the jet ejected through the mixed jet pipe. The diffuser device using a water jet, characterized in that configured to diffuse. The waterjet reaction chamber of claim 1, wherein the waterjet reaction chamber is provided with re-suction holes for reflowing the wastewater stored in the aeration tank by the pressure deviation into the waterjet reaction chamber by the pressure deviation caused by the reduced pressure, thereby re-suctioning the wastewater stored in the aeration tank. The balls are re-introduced into the waterjet reaction chamber and then ejected downward through the mixing jet tube,
The waterjet reaction chamber is closed at an upper part to maintain a set pressure to prevent the air remaining in the aeration water ejected through the mixing jet pipe floating and discharged,
One or more re-suction holes are formed on the side wall of the water jet reaction chamber so that the waste water stored in the aeration tank is re-introduced into the water jet reaction chamber through the re-suction holes and then discharged downward through the mixing jet pipe. Diffuser. According to claim 2, wherein the waste water discharge pipe and the mixing jet pipe is formed so as to correspond to the flange, the mixing jet pipe is assembled to the flange formed on the waste water discharge pipe, the upper portion is closed by the flange An diffuser apparatus using a water jet, characterized in that configured to form a water jet reaction chamber. The acid using a water jet according to claim 1, wherein spiral guide pieces are disposed on an inner wall of the mixed jet pipe, and the aeration water in which the waste water and air are mixed is discharged downward in a vortex form through the spiral guide pieces. Tracheal device. delete

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