KR0167034B1 - Simultaneous biological elimination of nitrogen and phosphor from sewage waste water and its device - Google Patents

Abstract

The present invention relates to a method and apparatus for simultaneously removing biological nitrogen and phosphorus from sewage and sewage and wastewater, and including sewage and sewage and wastewater treatment methods combining an initial sedimentation tank, an anaerobic tank, an anaerobic tank, an aerobic tank, and a final sedimentation tank. The return sludge to the aerobic tank is controlled to 0.3 ~ 1 times the influent to control the reaction time due to the high concentration of dissolved oxygen by adjusting the return rate according to the concentration of organic materials.The return of excess sludge from the final settling tank to the anaerobic tank is submerged. In order to control the phosphorus release reaction time according to the phosphorus content and the properties of phosphorus compounds, the returning amount is 0.3 to 1 times that of the influent water, and the circulation of the microbial mixture from the aerobic tank to the anoxic tank is used to denitrify the nitrified nitrogen compound in the aerobic tank. Depending on the nitrogen content and the properties of the nitrogen compounds, the amount of circulation can be adjusted to control the denitrification reaction time. In the sewage and sewage and wastewater treatment apparatus which combines the biological nitrogen and phosphorus removal method of sewage and sewage and wastewater with 1 ~ 4 times compared with the acquisition, and the initial sedimentation tank, anaerobic tank, anaerobic tank, aerobic tank and final sedimentation tank , The end of the conveying sludge conveying tube conveying the conveying sludge from the final sedimentation tank to the aerobic tank, the end of the excess sludge conveying tube conveyed from the final sedimentation tank to the anaerobic tank, and the microbial mixed liquor circulating tube circulating the microbial mixed solution from the aerobic tank to the anaerobic tank At the end of each of the injection nozzle and the mixing radiator composed of a mixing spinneret which is fitted to the distal end of the injection nozzle and which has a plurality of suction holes perforated on the outer circumferential surface thereof, the biological nitrogen of sewage and wastewater, In addition, the present invention provides a simultaneous removal process of phosphorus, thereby removing nitrogen and phosphorus as well as decomposition of organic substances. It can be effectively carried out, and the mixing of microbial mixed liquid and conveying sludge and oxygen is made efficiently, and the return flow rate can be reduced, and it is possible to exclude the stirring device and the dome type recovery device, so that it is efficient and economical sewage and It will be possible to build a wastewater treatment system.

Description

Method and apparatus for simultaneous removal of biological nitrogen and phosphorus from sewage and sewage and wastewater

1 is a schematic diagram of a device for implementing a method for simultaneously removing biological nitrogen and phosphorus from sewage and wastewater according to the present invention.

2 shows a mixed spinning machine used in the present invention,

(a) is a longitudinal cross-sectional view.

(b) is sectional drawing along the line A-A of (a).

3 is a schematic diagram showing an A2 / O method, which is an example of a conventional advanced treatment process.

4 is a schematic diagram showing the Bardenpho method, which is another example of a conventional advanced treatment process.

5 is a schematic diagram showing the UCT method, which is another example of a conventional advanced treatment process.

6 is a schematic diagram showing a VIP method, which is another example of a conventional advanced treatment process.

7 is a cross-sectional view showing an example of a conventional conveying sludge conveying means.

8 to 10 are cross-sectional views showing a representative example of a conventional aeration device.

* Explanation of symbols for main parts of the drawings

10: first settling tank 20: anaerobic tank

30: anoxic tank 40: aerobic tank

50: final settling tank 60: conveying sludge conveying means

61: conveying sludge conveying pipe 62: conveying sludge conveying pump

63: meandering pipe reactor 64: pure oxygen feeder

65: pure oxygen supply pipe 70: excess sludge discharge means

80: surplus sludge conveying means 81: surplus sludge conveying pipe

82: surplus sludge return pump 90: microbial mixed solution circulating means

91: microbial mixed solution circulation tube 92: microbial mixed solution circulation pump

100: mixed spinning machine 101: injection nozzle

102: mixed radiation tube 103: suction hole

The present invention relates to a method for treating sewage, sewage, and various industrial wastewater, and apparatus thereof, and in particular, to remove organic substances, nitrogen, and phosphorus from pollutants in sewage, sewage, and wastewater by using a biological treatment method at the same time. An altitude processing method and apparatus therefor are provided.

To date, what are known as biological processes that can simultaneously remove nitrogen and phosphorus (hereinafter referred to as advanced processing) are the A2 / O method, the modified Bardenpho method, the UCT (University of Cape Town) method, and the VIP (Vieginia Initiative Plant). Law).

In the A2 / O method, as shown in FIG. 3, the inflow water of sewage, sewage, and wastewater from which the suspended solids are removed by sedimentation in the initial sedimentation tank (not shown) is removed. Treated and discharged through nothing, aerobic tank, and sedimentation tank. At this time, the aerobic tank returns 1-3 times (1 to 3Q) of the inflow water (Q) to an anoxic tank and inflows from the sedimentation tank. The return sludge of 0.5Q of flow volume is conveyed to an anaerobic tank.

On the other hand, in the modified Bandenpho method, as shown in FIG. 4, the inflow of sewage, wastewater, and wastewater which passed through the initial sedimentation tank is treated through an anaerobic tank, a first anoxic tank, a first aerobic tank, a second anoxic tank, a second aerobic tank, and a sedimentation tank. In this case, the 1st aeration tank conveys 4 times (4Q) of the inflow water quantity Q, and a return sludge of 0.5 times (0.5Q) of the inflow water quantity Q is returned to a precipitation tank in a sedimentation tank.

In addition, in the UCT (University of Cape Town Process) method, as shown in FIG. 5, inflows of sewage, sewage, and wastewater that have passed through the initial sedimentation tank are treated and discharged through anaerobic tanks, anaerobic tanks, aerobic tanks, and sedimentation tanks. 1 ~ 2 times (1 ~ 2Q) of the quantity (Q) is returned to the anaerobic tank, 1 ~ 2 times (1 ~ 2Q) of the inflow water (Q) is returned to the anaerobic tank in the aerobic tank, and inflow water (Q) in the settling tank 0.5 times (0.5Q) of return sludge is returned to the anaerobic tank.

In addition, in the VIP (Virginia Initiatve Plant) method, as shown in FIG. 6, inflows of sewage, sewage, and wastewater which have passed through the initial sedimentation tank are treated through anaerobic tanks, anaerobic tanks, aerobic tanks, and sedimentation tanks. 1 to 2 times the quantity Q (1 to 2Q) is conveyed, and in the aerobic tank and the settling tank, 1 times (1Q) of the return sludge is returned to the anoxic tank.

The reaction mechanism for each step in this advanced treatment process will be discussed.

First, in the process of phosphorus removal, the effluent from which the suspended solids have been removed from the initial settling tank flows into the anaerobic tank and is returned by the excess sludge conveying pump in the anaerobic state (the return rate is 0.3 to 1 times the amount of the influent). Phosphorus release begins at the same time as the ingestion and storage, and the phosphorus is removed by accumulating the polyphosphoric acid in the microorganism body together with the growth of the microorganism in the aerobic state of the subsequent process. In other words, the microorganisms involved in the removal of phosphorus have the ability to remove simple enzyme substrates in the anaerobic state, releasing phosphorus while assimilating it into storage products in the cell, and in the aerobic state, phosphorus is stored in excess of phosphorus in the form of multiple phosphates. This removal characteristic is used to remove phosphorus.

The principle of biological nitrogen removal is divided into two categories.

One is the nitrogen removal method through the assimilation of microorganisms, and the other is the nitrification process in which ammonia and organic nitrogen in the influent are converted to nitrate nitrogen and nitrite nitrogen under certain conditions. It is classified as undergoing a denitrification process in which a nitrogen compound is removed by being reduced in a treatment system and discharged to nitrogen gas in the atmosphere.

As the nitrogen removal apparatus in this step, nitrogenaceous nitrification occurs at the same time as the organic matter is decomposed using an open pure oxygen activated sludge treatment process treated by microorganisms under an aerobic state. When the nitrified liquid mixture is returned to the anoxic tank in a large amount (1 to 4 times the flow rate of inflow water), the nitrogen oxide is removed by the microorganism under the anoxic state, which causes denitrification to remove nitrogen.

In the organic material decomposition process, the mixed sludge (the return sludge-oxygen mixed liquid) and the microbial mixed liquid in the aerobic tank are decomposed and treated with the return sludge returned from the final settling tank to the aerobic tank.

However, in the above-described conventional high-treatment process, the conveying sludge is simply conveyed by the sludge conveying pump and the sludge conveying pipe, and even in the aeration tank, the aeration efficiency is lowered and the processing efficiency at each stage is lowered. there was.

That is, in conveying the conveying sludge to an anaerobic tank or an anaerobic tank, the sludge of the final sedimentation tank 1 is simply conveyed through the conveying pipe 2b by the conveying pump 2a as shown in FIG. In the aeration, the surface aeration device 4 is used as shown in FIG. 8 or the air blown from the blower 6a as shown in FIG. 9 is diffused through the diffuser 6b installed in the aeration tank 5. Therefore, the amount of dissolved oxygen in the return sludge conveyed to the aerobic tank 5 is extremely small and the amount of dissolved oxygen in the aerobic tank 5 is insufficient, so that the microbial mixed liquid and the return sludge-oxygen mixed liquid in the aerobic tank 5 cannot be effectively mixed. There was a problem in that the activated sludge concentration (MLSS) of the mixed solution was lowered and the decomposition treatment capacity of the organic material contaminated in water was lowered.

That is, in the conventional aeration device, the oxygen component dissolution rate is to be dissolved during the short residence time in which the air in the bubble state injected into the water is dissolved by the circulation of the water or simply bubbles rise to the surface. It is extremely low, resulting in a high volume of air injection, while the low efficiency of oxygen utilization makes it uneconomical and inefficient.

In addition, conventionally, a method of supplying oxygen from the oxygen supplier 8 by the blower 7 as in FIG. 10 is used, but this is also an acid-based process of blowing high-purity oxygen gas into water, so that the contact time is short and the dissolution efficiency is low. In addition, in order to reuse oxygen, which is lost to the outside, a dome-type collection facility and a recirculation blower, which require expensive facility investment, have to be provided.

In the conventional advanced treatment process, the conveying sludge is simply conveyed through the conveying pump and the conveying pipe in the return to the anaerobic tank, so that the sludge sinks and decays in the anaerobic tank. In order to prevent this, a separate stirring facility is installed. It should be because there is a problem that the facility cost is increased.

In addition, the anaerobic tank, anoxic tank, and aeration tank have to be enlarged due to the deterioration of treatment efficiency, resulting in excessive purchase cost and construction cost for the construction of them, as well as an increase in operating costs due to excessive recycle of microbial mixed liquor. There was a problem.

It is an object of the present invention to increase the aeration efficiency by using a mixed spinning machine in aeration in an aerobic tank to increase the aeration efficiency, so that the biological nitrogen of sewage, wastewater and wastewater can be more effectively and economically performed. It is an object of the present invention to provide a simultaneous removal method and a device thereof.

Another object of the present invention is to use a mixed spinning machine to return sludge to an anaerobic tank or an aerobic tank, or to return the microbial mixed solution in the aerobic tank to an anaerobic tank, thereby preventing the sludge in the anaerobic tank from sinking and decaying without a separate stirring facility. To provide a method and apparatus for the simultaneous removal of biological nitrogen, phosphorus from sewage and sewage and wastewater.

Another object of the present invention is to increase the amount of organic matter per unit area (active sludge water treatment capacity) by adding an anaerobic tank and an anaerobic tank while maintaining the area required for general biological wastewater treatment equipment, and further increases the water treatment capacity. Simultaneous removal of biological nitrogen and phosphorus from sewage, sewage and wastewater, which can reduce the cost of construction site purchase and construction cost, and do not have to provide separate agitator or blower equipment. And to provide a device.

It is another object of the present invention to provide a method and apparatus for simultaneously removing biological nitrogen and phosphorus from sewage and wastewater, which can reduce the cost of operation by minimizing the recycle amount of the microbial mixture.

In the sewage and wastewater treatment method combining the first settling tank, anaerobic tank, anoxic tank, aerobic tank, and the final settling tank to achieve the object of the present invention, the return sludge from the final settling tank to the aerobic tank according to the organic material concentration In order to control the reaction time due to the high concentration of dissolved oxygen, the amount of return is 0.3 ~ 1 times of the influent water, and the return of excess sludge from the final settling tank to the anaerobic tank depends on the content of phosphorus in the water and the properties of phosphorus compounds. The amount of return is 0.3 ~ 1 times that of the influent, and the circulation of the microbial mixture from the aerobic tank to the anoxic tank reduces the denitrification reaction time according to the nitrogen content and the properties of the nitrogen compound. Sewage, waste, and waste, characterized in that the amount of circulation to be controlled is 1 to 4 times that of the influent. A water biological nitrogen, phosphorus simultaneous removal process is provided.

In conveying the conveying sludge from the final settling tank to the aerobic tank, pure oxygen is injected into the conveying sludge in the middle of the conveying path to convey the conveying sludge-oxygen mixed liquid into the aerobic tank.

The purity of pure oxygen mixed in the conveying sludge is supplied to be 60% or more as gaseous oxygen.

The conveying sludge returned from the final settling tank to the aerobic tank, the surplus sludge conveyed from the final settling tank to the anaerobic tank, and the microbial mixed liquor circulated from the aerobic tank to the anaerobic tank are sprayed by spraying the mixed sludge into the aerobic tank, the anaerobic tank and the anoxic tank, respectively. The excess sludge and the microbial mixture are sprayed in a mixed state with the microbial mixture in the aerobic and anaerobic and anaerobic tanks.

In addition, in order to achieve the object of the present invention, in the sewage and sewage and wastewater treatment apparatus combining the initial settling tank, anaerobic tank, anoxic tank, aerobic tank, and final sedimentation tank, the end of the conveying sludge conveying pipe conveying the conveying sludge from the final sedimentation tank to the aerobic tank And an injection nozzle and an end portion of the injection nozzle at the end of the excess sludge conveying pipe conveyed from the final settling tank to the anaerobic tank and the end of the microbial mixed liquid circulation pipe circulating the microbial mixed solution from the aerobic tank to the anaerobic tank. Provided is a biological nitrogen, phosphorus simultaneous treatment apparatus for sewage and sewage and wastewater, characterized in that a mixing radiator composed of a mixing radiator tube having a plurality of suction holes perforated on its outer peripheral surface.

A pure oxygen feeder is connected to the pure oxygen feed pipe in the middle of the conveying sludge conveying pipe.

A meandering pipe reactor is installed in the middle of the conveying sludge conveying pipe.

Hereinafter, the biological nitrogen, phosphorus simultaneous treatment method and apparatus thereof for sewage, sewage and wastewater according to the present invention will be described in detail according to the embodiments shown in the accompanying drawings.

1 is a schematic diagram of a device for implementing a method for simultaneously removing the biological nitrogen and phosphorus of sewage and wastewater according to the present invention, 10 is the first settling tank, 20 is anaerobic tank, 30 is an anaerobic tank, 40 is an aerobic tank, 50 is Final sedimentation tank.

These initial settling tank (10), anaerobic tank (20), anoxic tank (30), aerobic tank (40) and the final settling tank (50) are connected by the sequential transfer path (11, 21, 31, 41), the final settling tank (5) The discharge passage 51 through which the treated water is discharged is provided.

The sludge discharge pipe 52 is connected to the lower portion of the final settling tank 50, and the sludge discharge pipe 52 is a sludge conveying sludge conveying means 60 for conveying the sludge to the aerobic tank and the surplus sludge to discharge the sludge treatment destination The sludge discharge means 70 and the excess sludge conveying means 80 for conveying the excess sludge to the anaerobic tank 20 are connected.

In addition, between the aerobic tank 40 and the anaerobic tank 30, a microbial mixed liquid circulating means 90 for circulating the microbial mixed liquid in the aerobic tank 40 to the anoxic tank 30 is installed.

The conveying sludge conveying means 60 is composed of a conveying sludge conveying pipe 61 connected to the sludge discharge pipe 52 and a conveying pump 62 provided in the conveying pipe 61.

A meandering piping reactor 63 is provided in the middle of the conveying sludge conveying pipe 61, and a pure oxygen supply 64 is connected to the pure oxygen supply pipe 65 in the piping reactor 63.

The end of the conveying sludge conveying pipe 61 comes to the bottom of the aerobic tank 40, the end of the mixed spinning machine 100 is provided.

In addition, a pure oxygen control valve 66 is installed in the middle of the pure oxygen supply pipe 65 so as to be controlled by the controller 68 according to a signal detected by the dissolved oxygen detector 67 immersed in the aerobic tank 40. .

The excess sludge discharge means 70 is the excess sludge discharge pipe 71 connected to the sludge discharge pipe 52 and the excess sludge discharge pump 72 and the excess sludge discharge pipe connected to the discharge pipe 71. It consists of 73.

The excess sludge conveying means (80) is constituted by the excess sludge conveying pipe (81) and the discharge valve (82) for opening and closing the excess sludge discharge pipe (73).

When the discharge valve 82 is closed, the excess sludge is returned to the anaerobic tank 20 through the excess sludge conveying pipe 81 when the discharge pipe 73 is closed. In addition to being discharged through, the excess sludge conveying pipe 81 side is blocked or only a small amount is conveyed to adjust the amount of excess sludge conveyed.

The end of the excess sludge conveying means 80 comes to the bottom of the anaerobic tank 20, the end of the mixing spinning machine 100 is installed.

The microbial mixed solution circulation means 90 is composed of a microbial mixed solution circulation tube 91 connecting the lower end of the aerobic tank 40 and the anoxic tank 30, and a circulation pump 92 installed in the middle of the circulation tube 91. .

The mixing radiator 100 is installed at the end portion of the circulation tube 91 at the anaerobic tank 30 side.

As shown in FIG. 2 (a), the mixed spinning machine 100 is a spray nozzle connected to the conveying sludge conveying tube 61, the excess sludge conveying tube 81, and the microbial mixed liquid circulation tube 91. (101) and a mixed radiating tube (102) fitted on the front end of the injection nozzle (101) with a plurality of hop-holes (103) perforated on the outer circumferential surface thereof.

The pipes 61, 81, 91 and the injection nozzles 101 are connected by fastening the flanges 61a, 81a, 91a and 101a with the bolt 104 and the nut 105, respectively.

It describes the treatment process by the biological nitrogen, phosphorous simultaneous removal device of sewage and sewage, wastewater according to the present invention.

If the sewage and waste water to be treated is introduced into the initial settling tank 10, after the suspended solids are precipitated and removed, the effluent is introduced into the anaerobic tank 20.

In the anaerobic tank 20, organic matter is ingested and stored in the microbial body returned from the final settling tank 50 through the excess sludge conveying tube 81 in the anaerobic state, and the phosphorus is released.

At this time, when the discharge valve 82 is closed, surplus sludge discharged by the discharge pump 72 is not discharged to the discharge tube 73, and the total amount is returned to the anaerobic tank 20 through the excess sludge conveying tube 81. When the discharge valve 82 is opened, the excess sludge is discharged to the discharge tube 73 and shut off to the transfer pipe 81 side or only a small amount is returned, so that the anaerobic tank is opened by opening and closing the discharge valve 82. 20) It is possible to control the amount of return of excess sludge, and the amount of return is 0.3 ~ 1 times the amount of inflow (Q) to adjust the reaction time (retention time) of phosphorus release according to the content of phosphorus in the water and the property of phosphorus compound. It is set to (0.3-1Q).

After being treated in the anaerobic tank 20 and introduced into the aerobic tank 40 through the anaerobic tank 30, in addition to the growth of the microorganism in the aerobic state in the aerobic tank 40, polyphosphoric acid is accumulated in the microorganism to remove phosphorus.

That is, the microorganisms involved in the removal of phosphorus have the ability to remove a simple enzyme substrate in the anaerobic state in the anaerobic tank 30 and release phosphorus while assimilating into the storage product in the cell, and under the aerobic state in the aerobic tank 40, Phosphorus is removed because it is stored in excess of phosphorus in the form.

Here, in the case of conveying the excess sludge conveying pipe 81 from the final settling tank 50 to the anaerobic tank 20, the mixed slitter 100 is installed at the tip of the excess sludge conveying pipe 81, so that the excess sludge conveyed is conveyed to the conveying pipe ( The pressure around the tip of the injection nozzle 101 is lower than atmospheric pressure by the Bernoulli theorem while the injection nozzle 101 connected to the end of the injection nozzle 101 is injected into the mixing radiator tube 102. Since the microbial mixed solution in the 20 is sufficiently mixed with the excess sludge which is sucked through the suction hole 103 perforated on the outer circumferential surface of the mixing radiating tube 102 and is injected and injected, the sludge goes out in the anaerobic tank 20. It will prevent you from sitting and decaying. In addition, since the returned sludge and the microbial mixed liquid in the anaerobic tank 20 are mixed very actively, the treatment performance is increased.

In the Hanfun, an aerobic tank 40, the pure oxygen activated sludge treatment process is performed to decompose organic materials, in which case nitrogen is nitrified.

When the nitrified microbial mixed solution in the aerobic tank 40 is circulated to the anoxic tank 30 by the microbial mixed solution circulating means 90, that is, the circulation tube 91 and the circulation pump 92, the nitric oxide is reduced by the microorganisms under the anoxic state while Nitrogen is removed by the denitrification process which is discharged as nitrogen gas.

The circulating amount of the nitrified microbial mixture circulated from the aerobic tank 40 to the anoxic tank 30 depends on the denitrification of the nitrified nitrogen compound in the aerobic tank 40 according to the nitrogen content and the properties of the nitrogen compound. 1) to 4 times (1 to 4Q) compared to the inflow quantity (Q) so that can be adjusted.

Here, even when the microbial mixed solution is circulated from the aerobic tank 40 to the anoxic tank 30, a mixed spinning machine 100 is installed at the tip of the microbial mixed solution circulation tube 91, so that the microbial mixed solution is sprayed at the injection nozzle 101 at a high speed. By being sucked through the suction hole 103 perforated on the outer circumferential surface of the mixing radiating tube 102 by the principle as described above in the mixture after being sufficiently radiated into the anoxic tank 30 at the tip of the mixing radiating tube 102 Sludge in the (30) can be reliably prevented from being decayed, and the microbial mixed solution in the aerobic tank 40 side circulating aerobic tank 30 is actively mixed with the treatment performance is increased.

In addition, the treated water introduced into the final sedimentation tank 50 is finally discharged after the sedimentation treatment, the treated water is discharged, the conveying sludge in order to control the activated sludge concentration (MLSS) in the aeration tank 40 is returned to .

That is, when the conveying pump 62 of the conveying sludge conveying means 60 connected to the lower part of the final sedimentation tank 50 is operated, the sludge in the final sedimentation tank 50 is conveyed to the aerobic tank 40 side through the conveying pipe 61. .

The amount of conveyed sludge returned from the final settling tank (50) to the aerobic tank (40) adjusts the conveying rate according to the concentration of organic material so as to adjust the reaction time (retention time) due to high concentration of dissolved oxygen (Q). It is 0.3-1 times the comparison.

At this time, the pure oxygen feeder 64 is connected to the pure oxygen feed pipe 65 in the middle of the conveying sludge conveying pipe 61, and the aerobic tank detected by the dissolved oxygen detector 67 immersed in the aeration tank 40 ( When the dissolved oxygen in the chamber 40 is low, the control valve 66 is opened by the controller 68 so that the pure oxygen of the pure oxygen supplier 64 is supplied to the conveying sludge conveying tube 61 through the supply tube 65 and conveyed. The sludge is mixed with the sludge, and the conveying sludge and the pure oxygen are sufficiently mixed during the passage of the meandering pipe reactor 63 to primarily increase the dissolved oxygen, and then the conveying sludge-oxygen mixed liquid is the end of the conveying sludge conveying pipe 61. High pressure jet spinning into the aerobic tank 40 through the mixed spinning machine 100 installed in.

The oxygen supplied from the pure oxygen supplier 64 is 60% or more in purity as gaseous oxygen.

In the process of conveying the sludge-oxygen mixed liquid from the mixed spinning machine 100, when the conveyed sludge-oxygen mixed liquid is injected into the mixed spinning tube 102 from the injection nozzle 101, the inside of the aeration tank 40 and the microorganism are The mixed liquid is sucked and mixed through the suction hole 103 drilled on the outer circumferential surface of the mixing radiating tube 102, and then the high-speed jet spinning prevents the sludge in the exhalation tank 40 from sinking and decay. Oxygen and microbial mixed solution in the aerobic tank 40 is actively mixed to increase the processing performance.

According to the experimental result, the pure oxygen from the pure oxygen supply device 64 is supplied to the conveying sludge conveying pipe 61 to the conveying sludge conveyed in this way, it is mixed in the piping reactor 63 primarily, and the mixing spinning machine 100 is carried out. By discharging the conveyed sludge-oxygen mixed liquid and the microbial mixed liquid in the aerobic tank 40 by pressurized jet spinning to the aerobic tank 40, the dissolved oxygen amount is two to three times or more than when aerated by a conventional aeration apparatus. In addition, it can be seen that the activated sludge concentration (MLSS) of the microbial mixed solution in the aerobic tank 40 is also maintained at more than two times, and thus, it is possible not only to drastically decompose contaminated organic substances in sewage, sewage, and wastewater. It was found that the processing capacity and efficiency were greatly improved.

Claims (7)

In the sewage and wastewater treatment method combining the first settling tank, anaerobic tank, anoxic tank, aerobic tank, and final sedimentation tank, the return sludge from the final settling tank to the aerobic tank is controlled by a high concentration of dissolved oxygen by controlling the return rate according to the concentration of organic matter. In order to control the time, the amount of return is 0.3 ~ 1 times that of the influent, and the return of excess sludge from the final settling tank to the anaerobic tank allows the amount of return to be adjusted to adjust the phosphorus release reaction time according to the content of phosphorus in the water and the properties of phosphorus compounds. 0.3 ~ 1 times, and the circulation of the microbial mixture from the aerobic tank to the anoxic tank is 1 ~ 1 compared to the influent so that the denitrification reaction of the nitrified nitrogen compound in the aerobic tank can be controlled according to the nitrogen content and the properties of the nitrogen compound. Simultaneous removal of biological nitrogen and phosphorus from sewage and wastewater Way. The wastewater and sewage and wastewater according to claim 1, wherein in the conveying sludge from the final settling tank to the aeration tank, pure oxygen is injected into the conveying sludge in the middle of the conveying path to convey the conveying sludge-oxygen mixed liquid into the aeration tank. Biological Nitrogen, Phosphorus Removal Treatment Method. The method of claim 2, wherein the pure oxygen mixed in the conveying sludge is supplied as gaseous oxygen with a purity of 60% or more. The method according to claim 1, wherein the return sludge returned from the final settling tank, the excess sludge returned from the final settling tank to the anaerobic tank, and the microbial mixed liquor circulated from the aerobic tank to the anaerobic tank are respectively mixed into the aerobic tank, anaerobic tank and anoxic tank as a mixed spinning machine. A method for simultaneously removing biological nitrogen and phosphorus from sewage and wastewater, characterized in that the injection sludge, the excess sludge and the microbial mixture are sprayed in a mixed state with the microbial mixture in the aerobic, anaerobic and anaerobic tanks. In the sewage and sewage and wastewater treatment apparatus combining an initial settling tank, anaerobic tank, anoxic tank, an aerobic tank, and a final sedimentation tank, the end of a conveying sludge conveying pipe conveying the return sludge from the final settling tank to the aerobic tank and the final settling tank are returned to the anaerobic tank. At the end of the excess sludge conveying pipe and the end of the microbial mixed solution circulation tube circulating the microbial mixed solution from the aerobic tank to the anaerobic tank, the injection nozzle and the tip of the injection nozzle are respectively fitted on the outer surface, and a plurality of hop holes are drilled on the outer peripheral surface thereof. Simultaneous removal of biological nitrogen and phosphorus from sewage and sewage and wastewater, characterized in that by installing a mixed spinner consisting of a mixed discharge pipe. 6. The apparatus for simultaneously removing sewage and sewage and wastewater from biological nitrogen and phosphorus according to claim 5, wherein a pure oxygen feeder is connected to a pure oxygen feed pipe in the middle of the conveying sludge conveying pipe. The biological nitrogen and phosphorus simultaneous treatment apparatus of sewage and sewage and wastewater according to claim 5 or 6, characterized in that a meandering pipe reactor is installed in an intermediate portion of the conveying sludge conveying pipe.