KR100221850B1 - Method and equipment for removal of nutrients from wastewater - Google Patents

Abstract

The present invention relates to a method and apparatus for removing nutrients such as nitrogen and phosphorus from sewage or wastewater, and by denitrification by internal circulation from an aerobic reactor (2) to an anaerobic reactor (1) by a pump for denitrification. In removing nitrogen, the water body under the precipitator 3 is drawn out by the pump 5, and a part thereof is circulated internally into the anoxic reactor 1, and inside the anoxic reactor 1 through the nozzle 11. The process of stirring the oxygen-free reaction tank 1 by spraying and a part of the water body drawn out from the pump 5 are sprayed through the ejector 6 installed in the aerobic reaction tank 2 while supplying the air supply pipe 7 to the ejector 6. Air is introduced into the aerobic reaction tank (2), and mixing and aeration are performed together, and the same pump pumps the sludge back to the oxygen-free reaction tank (1) for stirring and denitrification. By using the sewage and wastewater treatment method and the apparatus, which allow the circulation to be carried out simultaneously, the efficiency of removing nitrogen and phosphorus can be improved, the aeration efficiency can be improved, the hydraulic load of the reactor and the sedimentation basin can be increased, and The need for a small water tank, a small water pump, a blower and a blower chamber is eliminated, thus reducing maintenance costs such as facility and power costs.

Description

Method and apparatus for removing nutrients from sewage and wastewater treatment

The present invention relates to a method and apparatus for removing nutrients such as nitrogen and phosphorus from sewage or wastewater, and in particular, since the treatment plant is simple and can effectively remove nitrogen and phosphorus at the same time, it can reduce facility and maintenance costs. The present invention relates to a nutrient removal method and apparatus in sewage water treatment.

Pollutants in sewage are roughly divided into organic matter expressed in biochemical oxygen demand (BOD) and nutrients such as nitrogen and phosphorus. Up to now, the sewage treatment plant in Korea has been mainly treated with organic matter, and much of the nutrients nitrogen and phosphorus have not been removed, but have been discharged to rivers, lakes or oceans.

If the sewage is discharged with nutrients such as nitrogen and phosphorus, it causes eutrophication of rivers and lakes, and if it enters the ocean, it causes red tide. Severe eutrophication leads to odors and water pollution, as well as limited use of drinking water and waterways. Therefore, in order to prevent eutrophication, nutrients such as nitrogen compounds or phosphates should be sufficiently removed in sewage treatment plants.

Nitrogen and phosphorus removal processes used in sewage treatment plants consist of an oxygen-free or anaerobic reactor that does not supply oxygen, and an aerobic reactor that supplies oxygen. The function of each reactor is to convert organic nitrogen or ammonia nitrogen to nitrate nitrogen in the aerobic reactor, and to reduce the nitrate nitrogen to nitrogen gas in the anaerobic reactor to release it into the atmosphere and induce the release of phosphorus from the activated sludge. The phosphorus component thus released is overingested by the microorganisms in the aerobic reactor, and by removing the excess microorganisms in excess of phosphorus through the excess sludge, the treated water is finally removed nitrogen and phosphorus.

Nitrogen removal method of the conventional nutrient removal method is largely divided into a post-denitrification method and a total denitrification method. Among them, the post-denitrification method in which an anoxic reaction tank is installed after nitrification is slightly superior to the total denitrification method, but a large maintenance cost is required because an organic donor such as methanol / acetic acid must be injected as an electron donor for the denitrification reaction. there was.

On the other hand, the total denitrification method has the advantage of not injecting the organic material because the organic material in the sewage and wastewater is used as the electron donor without separately injecting the organic material such as methanol or acetic acid. All treatment plants adopt this method. However, the total denitrification process requires internal circulation of nitrified sewage into the denitrification tank of the previous stage. Therefore, additional pump facilities and additional power costs are required to install a separate internal circulation pump.

In addition, the pre-denitrification and post-denitrification methods commonly require sludge conveying facilities, aeration facilities, agitating facilities, and defoaming facilities. Thus, since these facilities are separated and installed, there are difficulties in cost of facility and maintenance. Especially in small sewage treatment plants, such as village-level sewage treatment plants, many problems are inherent in the selection of machinery because of the small size of the facilities.

In detail, a representative A ₂ O method and apparatus among the total denitrification methods which are preferred for economical efficiency in the conventional nutrient removal method, as shown in FIG. After the denitrification in the oxygen-free reaction tank 102 and the aerobic reaction tank 103 is composed of a process for decomposing nitrification and organic matter. The oxygen-free reaction tank 102 is provided with a stirring device 104 for mixing the internal circulating water containing a large amount of nitrate and the sewage containing organic matter so that the activated sludge does not deposit on the bottom. The aerobic reactor (103) is provided with an aeration device consisting of an aerator (105) and a blower (106) for supplying oxygen for the decomposition and nitrification of organic matter in the sewage. Internal circulation pump 107 should be installed.

By the way, since the aerators 105 and 106 and the agitator 104 or the internal circulation pump 107 are separately installed, the apparatuses are uneconomical in terms of facility cost and power cost and have many problems in terms of maintenance.

In particular, when the stirring device 104 is composed of an underwater rotating body that generates water flow, when the fluidized bed biofilm contact material is filled in the aeration tank to use the biofilm method for attaching and growing microorganisms by treating sewage, the biofilm contact material is It was not possible to apply the fluidized bed biofilm method because it collides with the underwater rotor of the stirrer.

In addition, the aerobic reaction tank 103 generates a large amount of bubbles in the aeration process for injecting air. Such a large amount of foaming is mainly caused by surfactants such as soaps and detergents contained in raw water or microorganisms that generate foam such as rocadia, and bubbles are severely generated when the wind blows. Often causes secondary pollution.

As a countermeasure against such foaming, a nozzle 108 is installed on the surface of the reactor to calm bubbles generated excessively in the reactor, and water is strongly sprayed through the nozzle 108. However, since the conventional defoaming device uses the treated sewage as the parcel water, the installation of the defoaming water tank 109 and the defoaming water pump 110 is inevitable in the next step of the final settling, so that the construction and machine construction cost, power cost, and maintenance cost are additionally burdened. It is shown in Figure 4, which is a conventional sewage treatment system that caused economic feasibility. In addition, the conventional defoaming apparatus by spraying a large amount of sewage treated in order to use as a defoaming water to the reaction tank 103, the hydraulic load corresponding to the flow rate of the defoaming water is increased, thereby shortening the actual residence time of the reaction tank and settling basin (111) ), There was a problem that the surface area load ratio of) is increased and the precipitation efficiency is lowered.

Accordingly, the present invention has been made to solve the above problems, can reduce the facility cost and maintenance costs, and can be efficiently applied to the total denitrification method to remove nitrogen and phosphorus in the sewage method And to provide a device.

In order to achieve the above object, the present invention provides an anoxic reaction tank, an aerobic reaction tank and a sedimentation basin, and removes nitrogen by a total denitrification method of internal circulation from an aerobic reaction tank to an anoxic reaction tank by a pumping facility for the purpose of denitrification. In the aerobic reaction tank to the anoxic reaction tank, the internal circulation method of the aerobic reaction tank via the sedimentation basin with a pump of the water of the mixture of water and sludge in the bottom of the precipitator to circulate the internal oxygen to the anoxic reaction tank and By spraying the inside of the anoxic reaction tank through the nozzle to agitate the anoxic reaction tank, the same pump can be used to simultaneously transport the sludge, agitate the anoxic reaction tank and internal circulation to the anoxic reaction tank for denitrification at the same time. Wastewater treatment method and method It is a device for realizing this.

That is, the present invention can be applied to a wide range of methods classified as a total denitrification method, and in the past, a method of internally circulating water in an aerobic reaction tank to an anoxic reaction tank was used for the denitrification reaction. The internal circulation to the anoxic reactor is used.

The characteristics of the device are to increase the capacity of the conventional sludge conveying pump, and to perform internal circulation and mixing to the anaerobic reactor, sludge conveying to the anaerobic reactor, mixing and aeration of the aerobic reactor, and taking out and defoaming the excess sludge. The number of installation of machinery that consumes power in the treatment plant has been greatly reduced.

Part of the effluent from the sludge return pump in the sedimentation basin is piped back to the anaerobic reactor in order to elute phosphorus. For the denitrification reaction, the flow rate of 3 ~ 5 times the amount of raw water inlet is circulated from the sedimentation basin to the anoxic reaction tank using a sludge return pump, but a nozzle is installed inside the anoxic reaction tank and the internal circulating water is injected through the nozzle to separate the stirring device. It is easy to obtain the desired mixing strength required in the oxygen-free reaction tank without.

In addition, a part of the return water is connected to the aeration ejector equipped with an air supply pipe installed in the aerobic reaction tank, and the air is sucked through the air supply pipe by the negative pressure formed in the ejector when the water body is injected into the reaction tank, thereby mixing the inside of the aerobic reaction tank. And oxygen supply to maintain the aerobic state for nitrification and organic decomposition.

On the other hand, in order to realize the defoaming device for removing bubbles generated in the aerobic reaction tank, the parcel water nozzle and the defoaming water pipe installed on the water surface of the aerobic reaction tank are connected to the above-mentioned sludge pump to separate the parcel by using the effluent water from the lower part of the sedimentation basin as the parcel water. In addition to the need for a water tank and a parcel water pump, the parcel water is withdrawn from the bottom of the sedimentation basin, unlike the conventional method, the hydraulic load is not increased on the surface of the sedimentation basin by the parcel water sprinkling.

By using the sludge pump as described above, the sludge conveying pump facility, the aerobic reaction tank stirring facility, the aeration device of the aerobic reaction tank, the internal circulation pump facility to the oxygen-free reaction tank, and also the antifoaming facility to suppress the foaming of the aerobic reaction tank by Economics can be achieved in terms of facility costs, power costs, and maintenance costs.

1 is a block diagram of the nutrient removal process and apparatus of the sewage and wastewater treatment plant according to the present invention.

2 is a block diagram of another embodiment of the nutrient removal process and apparatus of the sewage and wastewater treatment plant according to the present invention.

3 is a block diagram of another embodiment of the nutrient removal process and apparatus of the sewage and wastewater treatment plant according to the present invention.

4 is a configuration diagram of a nutrient removal process and apparatus of a conventional sewage and wastewater treatment plant.

* Explanation of symbols for main parts of the drawings

1: anoxic reactor 2: aerobic reactor

3: sedimentation basin 4: anaerobic reactor

5: pump 6: ejector for aeration

7: air supply pipe 8: aeration flow control valve

9: air control valve 10: foam nozzle

11 agitating nozzle 12 agitating flow control valve

13: agitator 14: sludge return pipe

15: liquid-liquid separation means 16: control valve

17: pump outflow pipe 18: excess sludge withdrawal pipe

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 shows one embodiment of the present invention for removing nitrogen mainly from nutrients contained in sewage.

The wastewater treatment process of the present invention consists of an oxygen-free reaction tank (1) for denitrification, an aerobic reactor (2) and a settling basin (3) for aerobic decomposition of nitrification and organic matter. In the removal of nitrogen by the total denitrification method of internal circulation from the reaction tank (2) to the oxygen-free reaction tank (1), the present invention withdraws the water body under the settling basin (3) with a pump (5) and part of the oxygen-free The internal circulation to the reaction tank (1), the step of spraying inside the anoxic reaction tank (1) through the nozzle (11) to agitate the anoxic reaction tank (1) and a part of the water extracted from the pump (5) is the aerobic reaction tank (2) The air is introduced by connecting the air supply pipe (7) to the ejector (6) while being injected through the ejector (6) installed in the) and the mixing and aeration in parallel to the aerobic reactor (2), the sludge with the same pump Of And, a waste water treatment method and apparatus characterized in that parallel to the sending and stirred in an oxygen-free reactor (1) and the circulation into the anoxic reaction tank (1) for NO x removal at the same time.

That is, the present invention is provided with a pump (5) having a capacity increase of the capacity of the sludge pump, which is conventionally used for the extraction of excess sludge for conveying sludge, and injecting water into the oxygen-free reaction tank (1). (11) and the outlet pipe (17) of the pump (5), the aeration ejector (6) installed inside the aerobic reactor (2) is connected to the outlet pipe (17) of the pump (5) The above process is to be made.

And the parcel is installed on top of the aerobic reaction tank (2) 10 is connected to the outlet pipe 17 of the pump 5 is to remove the bubbles generated in the aerobic reaction tank (2), withdrawal from the pump (5) Surplus sludge is to be discharged through the excess sludge withdrawal pipe (18).

Referring to the operation of each device applied to the present invention, first, by spraying water 3 to 5 times the sewage fraction into the oxygen-free reaction tank (1) at a predetermined flow rate through the stirring nozzle (11), the aerobic reaction tank (1) The nitrated water in the water is returned to the anoxic reactor (1) via the sedimentation basin (3) to return the internal circulation and the sludge to remove nitrogen and install the required flow rate of the stirring nozzle (11) without installing a separate stirrer. It is possible to maintain the mixing strength. In particular, in the oxygen-free reaction tank (1), microorganisms reduce nitrate to free nitrogen by using the combined oxygen in the form of nitrate to decompose organic matter. In this case, denitrification efficiency decreases when free oxygen is incorporated in the reaction tank. The denitrification efficiency of the oxygen-free reaction tank 1 could be lowered conventionally because the water body was internally returned from the aerobic reaction tank 2 having a high dissolved oxygen concentration to the oxygen-free reaction tank 1. However, in the present invention, since the water body passing through the sedimentation basin 3 is internally circulated, the dissolved oxygen concentration is reduced by the microorganisms in the sedimentation basin, and the denitrification efficiency of the denitrification tank 1 is prevented.

On the other hand, in the case of the sedimentation basin (3), the water in the aerobic reactor (2) having high dissolved oxygen concentration through the sedimentation basin (3) passes through the sedimentation basin (3). This will not elute. When anaerobic sedimentation basin (3) is anaerobic, phosphorus is eluted from the sludge in excess of phosphorus, and phosphorus flows out through the treated water, and nutrient removal efficiency is lowered. In the conventional treatment method, sedimentation basin (3) is easy to anaerobic. It was. In particular, even if the internal circulating water and the parcel water pass through the large amount of sedimentation basin 3, the flow rate affects the surface area load of the sedimentation basin 3 because the circulating water and the parcel water flow out from the lower part of the sedimentation basin 3. Since the sewage inflow flow rate does not increase and only the sewage inflow flow rate acts as the surface area load, the required capacity of the sedimentation basin is not increased compared with the conventional method, but rather the surface area loading rate of the sedimentation basin 3 is reduced by the amount of the parcel water flow.

In addition, the inlet pipe to the stirring nozzle 11 is provided with a stirring flow control valve 12 to adjust the internal circulation flow rate in the mixed strength of the oxygen-free reaction tank 1.

The aeration ejector 6 installed inside the aerobic reaction tank 4 is provided with an air supply pipe 7. When the pump 5 is operated, the outflow of the pump 5 is injected through the ejector 6 at a predetermined speed. do. As a result, a negative pressure is formed around the nozzle installed in the ejector 6, and the air in the air is sucked into the ejector 6 through the air control valve 7 and the air supply pipe 5, and the water flow mixed with the fine air bubbles is generated. It is injected from the ejector 6 into the aerobic reaction tank 2. At this time, oxygen is dissolved into the water body inside the aerobic reaction tank 2 at the gas-liquid contact interface of the air bubble so that the aerobic reaction tank 2 maintains an aerobic state. The oxygen concentration and the mixed strength in the aerobic reactor 2 can be controlled by operating the air control valve 9 and the aeration flow control valve 8.

In the aerobic reaction tank (2), air bubbles mixed through the aeration ejector (6) rise to the surface of the reaction tank (2) to generate a large amount of bubbles. A part of the effluent of the pump (5) is sprayed strongly on the surface of the aerobic reaction tank (2) through the defoaming nozzle (10) to suppress the generation of bubbles, and the aerobic reaction tank (2) with the dissolved oxygen concentration almost saturated in the parcel water. Since it reaches, the synergistic effect of aeration efficiency is also brought about.

In the present invention, since it is composed of a device that uses a large number of nozzles, when a large particle size of the mixed substances are mixed in the reaction tank, the nozzle may be closed, so that the inflow of the contaminants in the pretreatment process such as a screen is blocked as much as possible and the diameter of the nozzle is as large as possible. It is preferable to use a strainer in the suction pipe or the outlet pipe 17 of the pump 5.

2 is another embodiment of the present invention for removing nitrogen and phosphorus contained in the sewage, the agitator 13 in the above process consisting of an oxygen-free reaction tank (1) and aerobic reaction tank (2) mainly to remove nitrogen The anaerobic reaction tank 4 equipped with this is further provided, and it carries out the process which conveys a sludge to the anaerobic-phase reaction tank 4 through the sludge conveying piping 14, stirring.

The anaerobic reactor (4) is sludge introduced through the sludge return pipe 14 by using the characteristics of activated sludge which elutes phosphorus in the anaerobic state (Bleed Back) and excess uptake of phosphorus in the aerobic state (Luxury Uptake) It is to keep the anaerobic state so that phosphorus is eluted. In the aerobic reaction tank (2), the phosphorus is removed again by drawing out some of the sludge in excess of the ingested sludge to the outside through the excess sludge withdrawal pipe (18).

FIG. 3 shows that sludge and liquid are separated from the effluent drawn out by the pump 5 under the sedimentation basin 3 so that the solid-liquid separation means 15 is installed next to the outlet of the pump 5 so that the water body having low solids concentration is Pipes are connected to enter the agitation nozzle 11 of the anoxic reaction tank 1, the aeration ejector 6 of the aerobic reaction tank 2, and the defoaming nozzle 10, and the water body having a high concentration of solids, that is, activated sludge, is anaerobic. It is a structure connected to the withdrawal pipe 18 to be introduced into the reactor (4) or withdrawn to the excess sludge.

Since activated sludge releases phosphorus in anaerobic state, anaerobic reactor 4 was installed for the purpose of releasing phosphorus from activated sludge. Therefore, sludge circulating in the system should go through anaerobic reactor 4 to increase the efficiency of phosphorus treatment. It becomes possible.

By providing the solid-liquid separation means 15, it is possible to return the water body with a high sludge concentration to the anaerobic reaction tank 4, thereby improving the efficiency of phosphorus removal and introducing a high concentration of sludge to the hydraulic retention time of the anaerobic reaction tank 4 Can be reduced. In addition, by the solid-liquid separation means 15 to prevent the closing of the device consisting of the nozzle.

The solid-liquid separation means 15 adopts solid-liquid separation means capable of maintaining the pressure of the water body even after the solid-liquid separation such as water cyclone, so that the nozzles 10 and 11 and the ejector (10, 11) without large reduction in the discharge head of the pump 5 Through 6) it is possible to maintain the head that can be injected into the reactor (1, 2) at the flow rate required for the water body.

In the piping reaching from the pump 5 to the nozzles 10, 11 and the ejector 6, it is preferable to configure the device so that the leakage of pressure is minimized. The sludge withdrawal pipe under the solid-liquid separation means 15 is always opened. In this case, since the leakage of pressure is increased and the required lift of the pump 5 is increased, power consumption is caused. Therefore, the control valve 16 is attached to the lower part of the solid-liquid separation means 15, but it is composed of an automatic valve. It is preferable to open and close automatically in conjunction with a suspended solids controller (Mlss Controller) or a timer (Timer) for detecting the concentration of suspended solids in the).

With the same pump, it is possible to carry out the sludge conveyance, the aerobic reaction tank (1) and internal circulation to the anoxic reaction tank (1) for denitrification at the same time, and to improve the efficiency of removing nitrogen and phosphorus, and improve the aeration efficiency and the reaction tank. It also reduces the hydraulic load on the sedimentation basin, and eliminates the need for a separate parcel tank, a parcel water pump, a blower and a blower chamber, thereby reducing maintenance costs such as facility and power costs.

Claims (16)

Total denitrification, which is equipped with an oxygen-free reaction tank (1), aerobic reaction tank (2), and sedimentation basin (3), etc. in the sewage treatment plant, and is internally denitrified to internally circulate from the aerobic reaction tank (2) to the anoxic reaction tank (1) by a pumping facility for the purpose of denitrification In removing nitrogen by the method, the water body under the settling basin (3) is drawn out by the pump (5) to be internally circulated to the oxygen-free reaction tank (1) and the aerobic reaction tank (2), and the excess sludge is discharged. The stirring nozzle 11 is installed in the reaction tank 1, the water body is sprayed into the oxygen-free reaction tank 1 through the stirring nozzle 11, and the oxygen-free reaction tank 1 is stirred, and the aerobic reaction tank 2 is provided. An ejector 6 having an air supply pipe 7 installed therein and spraying the water body into the aerobic reaction tank 2 through the ejector 6 to generate a negative pressure inside the ejector 6. Air to the air supply line (7) By using the method of injecting the aspirator and the aerobic reactor into the ejector 6 together with the water body, the agitation and aeration can be performed in parallel, thereby conveying the sludge and stirring the anoxic reactor 1 with the same pump. Method for removing nutrients in sewage and wastewater treatment, characterized in that the aeration and aeration of the aerobic reaction tank (2) for nitrification and organic matter decomposition and the internal circulation to the oxygen-free reaction tank (1) for denitrification at the same time. . 2. The removal of nutrients in sewage and wastewater treatment according to claim 1, characterized in that the stirring nozzle (11) installed in the anoxic reaction tank (1) is provided with a flow control valve (12) to adjust the agitation intensity. Way. The method for removing nutrients in sewage and wastewater treatment according to claim 1, wherein the internal circulation flow rate from the sedimentation basin (3) to the oxygen-free reaction tank (1) is 3 to 5 times the amount of raw water inflow. The anaerobic reactor according to claim 1, wherein an anaerobic reactor (4) is additionally installed in the front stage of the anoxic reactor (1), and a portion of the water body drawn from the attached battery (3) by pump is introduced into the anaerobic reactor (4). In the reaction tank 4, the phosphorus contained in the sludge is eluted, so that the sludge is returned to the same pump 5, the agitation of the oxygen-free reaction tank 1, the agitation and aeration of the aerobic reaction tank 2 for nitrification and excess intake of phosphorus, and denitrification. Method for removing nutrients in sewage and wastewater treatment, characterized in that at the same time to the internal circulation to the anaerobic reaction tank (1) for. The method of claim 1, wherein a part of the water body withdrawn from the sedimentation basin (3) is sprayed through a small water spray nozzle (10) installed above the water surface of the aerobic reactor (2) to add a defoaming function to the same pump (5) A method for removing nutrients in sewage and wastewater treatment, characterized by the above-mentioned. The aeration flow rate control valve (8) and the air control valve (9) are installed in the aeration ejector (6) installed in the aerobic reactor (2) to adjust the dissolved oxygen concentration and the stirring strength. A method for removing nutrients in sewage and wastewater treatment. The method according to claim 4, wherein the water body drawn out by the pump (5) passes through the solid-liquid separation means (15) so that the separation liquid having a low concentration of solids in the separation liquid is agitated in the anoxic reaction tank (11), aerobic It is characterized in that the aeration ejector (6) and the defoaming nozzle (10) of the reaction tank (2) is introduced, and the separated liquid having a high solids concentration is introduced into the anaerobic reaction tank (4) or drawn out with excess sludge. Removal of nutrients in wastewater treatment. Total denitrification, which is equipped with an oxygen-free reaction tank (1), aerobic reaction tank (2), and sedimentation basin (3), etc. in the sewage treatment plant, and is internally denitrified to internally circulate from the aerobic reaction tank (2) to the anoxic reaction tank (1) by a pumping facility for the purpose of denitrification In removing nitrogen by the method, a pump 5 for drawing the water body under the settling basin 3 and circulating it internally into the oxygen-free reaction tank 1 and the aerobic reaction tank 2 is provided. The stirring nozzle 11 for agitating the anoxic reaction tank 1 by injecting the water body drawn in 5) into the anoxic reaction tank 1 is installed in the anoxic reaction tank 1, and the aerobic reaction tank 2 The ejector 6 is connected to the pump 5 so as to inject the water body of the lower part of the sedimentation basin 3 withdrawn from the pump 5 into the aerobic reaction tank 2, and to the negative pressure formed inside the ejector 6. Air inside the ejector (6) Air supply pipe (7) is installed in the aerobic reaction tank (6) to be injected together with the water body so that it can be stirred and aerated at the same time, so that the sludge is transported with the same pump and the oxygen agitation tank (1) is stirred and nitrified. And an aerobic reaction tank (2) for decomposing organic matter and internal circulation to an oxygen-free reaction tank (1) for stirring and aeration and denitrification at the same time. . 10. The nutrients according to claim 8, wherein a flow control valve (12) is installed in the stirring nozzle (11) installed in the anoxic reaction tank (1) to adjust the agitation strength. Removal device. 10. The method of claim 9, wherein an anaerobic reaction tank (4) is additionally installed in the previous stage of the anoxic reaction tank (1) so that a part of the water body drawn from the settler (3) to the pump (5) flows into the anaerobic reaction tank (4). To allow the phosphorus contained in the sludge to be eluted in the anaerobic reactor (4) so that the sludge is returned to the same pump (5), the agitation of the anaerobic reactor (1), the agitation and aeration of the aerobic reactor (2) for nitrification and excess intake of phosphorus. And nutrient removal device in sewage and wastewater treatment, characterized in that the internal circulation to the anoxic reaction tank (1) for denitrification is performed at the same time. The method of claim 8, wherein a part of the water body withdrawn from the settler (3) is sprayed through the squirt nozzle 10 installed above the water surface of the aerobic reactor (2) to add a defoaming function to the same pump (5) An apparatus for removing nutrients in sewage and wastewater treatment, characterized by the above-mentioned. The aeration flow control valve (8) and the air control valve (9) for controlling the dissolved oxygen concentration and the stirring strength are installed in the aeration ejector (6) installed in the aerobic reactor (2). A device for removing positive salts in sewage and wastewater treatment. The method according to claim 10, wherein the water body drawn out by the pump (5) passes through the solid-liquid separation means (15) so that the separation liquid having a low concentration of solids in the separation liquid is agitating nozzle (11), aerator ejector (6) and Solid-liquid separation means (15) for pumping the outflow pipe (17) to allow the inlet to the small nozzle (10) and to allow the separation liquid with a high solids concentration to flow into the anaerobic reactor (4) or to be withdrawn to excess sludge. An apparatus for removing nutrients in sewage and wastewater treatment, characterized in that installed in. 11. The apparatus for removing nutrients in sewage and wastewater treatment according to claim 10, wherein the solid-liquid separation means (15) is made of water cyclone. 11. The apparatus for removing nutrients in sewage and wastewater treatment according to claim 10, characterized in that a control pipe (16) is provided in a lower pipe of said solid-liquid separation means (15) from which water bodies with a high sludge concentration are drawn out. The method according to claim 15, wherein the opening and closing of the control valve 16 is operated in conjunction with a timer (Miss Controller) installed in the timer (Timer) or anaerobic reaction tank (4). Salt removal device.

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