KR20170109322A - Phosphorus adsorption advanced wastewater treatment system - Google Patents

Abstract

Provided is a phosphorus adsorption advanced wastewater treatment system comprising: a bioreactor biologically treating wastewater; a phosphorus adsorption tank in which treated water treated in the bioreactor flows; a phosphorus adsorption facility including phosphorus adsorption media installed in the phosphorus adsorption tank and adsorbing phosphorus in the treated water; a cleaning settling tank in which treated water treated from the phosphorus adsorption facility flows and which cleans, solidifies and deposits the treated water; and a dehydrating facility in which sediments flows in from the cleaning settling tank and which dehydrates the sediments. Accordingly, processing processes including phosphorus adsorption, cleaning and dehydration are sequentially systemized so maintenance is convenient. In addition, processes for automatically regenerating phosphorus adsorption media and treating phosphorus adsorption and phosphorus desorption are included.

Description

[0001] The present invention relates to a phosphorus adsorption advanced wastewater treatment system,

The present invention relates to a phosphorus adsorption elevation treatment system, and more particularly to a phosphorus adsorption elevation treatment system capable of enhancing phosphorus treatment.

In general, pollutants contained in sewage are classified into organic matter, nitrogen and phosphorus. Among these, the development of processes for removing nitrogen and phosphorus contained in wastewater and sewage is actively underway, and various methods are being put into practical use.

In recent years, the TN standard is 20 mg / L and the TP standard is up to 0,2 mg / L, but the sewage effluent quality is gradually strengthened to 5 mg / L or less and 0.1 mg / L or less in the future. The demand for technologies capable of high-efficiency treatment is continuously increasing. In particular, in the case of phosphorus, the anaerobic tank and the aerobic tank are treated for biological treatment, but the biological treatment is limited and the treatment is performed by using the flocculant.

However, in the case of using the coagulant as described above, a large amount of the coagulant is required to be treated to a concentration of 0.1 mg / L, the amount of the sludge is increased, the consumption of the chemical is increased and the operation cost is increased. There is a problem that can become an obstacle.

On the other hand, as an example of the wastewater treatment technique described above, Korean Patent Laid-Open Publication No. 10-2013-0118624 discloses that phosphorus adsorbed in an adsorption medium is desorbed through a desorbing liquid in the adsorption treatment apparatus and desorbed phosphorus is recovered as a product And a recovery step using a phosphorus recovery liquid so as to be recovered, and a method of the same.

However, the above-described conventional wastewater treatment system has a complicated system, has a problem in that the total number of facilities such as a tank and an additional pump is increased, a separate dewatering system is required for recovery after solid-liquid separation, There is a problem that the operation cost is increased due to an increase in the total energy consumption rate.

Further, as another embodiment of the wastewater treatment system, Korean Patent Registration No. 10-0969220 includes a biological reaction tank for biologically treating raw water to be introduced and a filtration net for filtering suspension or sediment, and a reverse detail for washing the filtration net Wherein at least one filtration screen device is provided, wherein the backwash water supplied to the backwash is treated by the biological reactor. ≪ Desc / Clms Page number 3 >

However, in the conventional wastewater treatment system, there is a problem in that a high-efficiency nitrogen treatment is difficult in the corresponding process line, the separation membrane is immersed in an aerobic tank, and out-of-line cleaning is required. In addition, There is a problem that there is no method for de-artificial reproduction and maintenance.

Korean Patent Publication No. 10-2013-0118624 Korean Patent No. 10-0969220

An object of the present invention is to provide a phosphorus adsorption advanced treatment system capable of enhancing phosphorus treatment using an adsorbent and increasing maintenance convenience and minimizing facilities with an automatic regeneration system.

According to an aspect of the present invention, there is provided a bioreactor for biologically treating wastewater; A phosphorus adsorption facility including a phosphorus adsorption tank into which the treated water treated in the bioreactor enters, and a phosphorus adsorption filter medium installed in the phosphorus adsorption tank to adsorb phosphorus in the treated water; A rinse settling tank for introducing treated water treated from the phosphorus adsorption facility and washing and solidifying the treated water to precipitate; And a dewatering device for introducing the sediment from the washing sedimentation tank and dehydrating the sediment.

According to another aspect of the present invention, there is provided a process for producing an anoxic tank, comprising: a first anoxic tank into which wastewater is introduced and in which an denitrification reaction proceeds in an anaerobic atmosphere; An anaerobic tank into which the treated water treated in the first anoxic tank is introduced and in which the effluent of the treated water proceeds in the anaerobic state; An aerobic tank into which the treated water treated in the anaerobic tank is introduced and in which excessive phosphorus intake and nitrification of the treated water proceed in an exhalation atmosphere; A second anoxic tank in which the treated water treated in the aerobic tank is introduced and the denitrification reaction of the treated water proceeds in an anoxic atmosphere; A separation membrane tank through which the treated water treated in the second anoxic tank is introduced and which filters the treated water; A degassing vessel for receiving and storing the treated water from the separation membrane tank and supplying the treated water to the first anoxic tank; A phosphorus adsorption equipment including a phosphorus adsorption tank through which the treated water treated from the separation membrane bath flows, and a phosphorus adsorption filter medium (Media) installed in the phosphorus adsorption tank for adsorbing phosphorus in the phosphorus treatment water; A rinse settling tank for introducing treated water treated from the phosphorus adsorption facility and washing and solidifying the treated water to precipitate; And a dewatering device for introducing the sediment from the washing sedimentation tank and dehydrating the sediment.

The phosphorus adsorption advanced treatment system according to the present invention provides the following effects.

First, since the treatment process including phosphorus adsorption, cleaning and dehydration is continuously systemized, maintenance is easy and includes both automatic regeneration of phosphorus adsorption media and phosphorus adsorption and phosphorus removal processes.

Second, since the conventional wastewater treatment system in which the dehydration facility is necessarily installed can be applied without additionally adding a dehydration facility for adsorption, the facility can be minimized.

Third, it is possible to simplify the tank and the process in the phosphorus adsorption treatment process, and the pump can be minimized, thereby reducing energy consumption.

Fourth, phosphorus treatment can be strengthened so that the phosphorus concentration of discharged water can be secured to 0.1 mg / L or less.

Fifth, the first anoxic tank and the second anoxic tank are disposed in front of the anaerobic tank and the second anoxic tank is disposed behind the oxic tank, respectively, to improve the nitrogen treatment efficiency. In the first anoxic tank, It is possible to improve the removal efficiency of phosphorus by allowing nitrate in the anaerobic tank to be released more effectively by pre-nitrifying nitrogen to be introduced into the anaerobic tank.

Sixth, it is possible to make the release of phosphorus from the anaerobic tank more easily by dividing the treated water into the first anoxic tank and the anaerobic tank, respectively. In addition, the denitrification in the first anoxic tank can be controlled by controlling the distribution ratio of the organic matter in accordance with the characteristics of the first anoxic tank and the anaerobic tank And the inside of the anaerobic tank can be optimized.

Seventh, it is possible to recycle highly dissolved oxygen of the membrane separation tank in the aerobic tank, and it is possible to reduce the amount of air sent from the aerobic tank through the blower, as well as to remove organic matter or carry out nitrification by utilizing the dissolved oxygen, .

Eighth, by separating and separating the aerobic tank and the membrane separation tank, it is possible to perform in-situ cleaning which can perform cleaning without putting out the separation membrane when cleaning the separation membrane of the separation tank, and maintenance is easy.

1 is a block diagram showing a configuration of a phosphorus adsorption altitude treatment system according to an embodiment of the present invention.
2 is a block diagram showing the configuration of a phosphorus adsorption altitude treatment system according to another embodiment of the present invention.

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

1, a phosphorus adsorption elevation treatment system 710 according to an embodiment of the present invention includes a biological reaction tank 100, a phosphorus adsorption facility 200, a cleansing settling tank 300, (600).

The bioreactor 100 biologically processes the wastewater and processes the treated wastewater from the phosphorus adsorption facility 200 through the treated water supply line 10 so as to be introduced into the phosphorus adsorption facility 200 do. A known reaction tank capable of treating wastewater can be applied to the bioreactor 100, and a detailed description thereof will be omitted.

The phosphorus absorption facility 200 is connected to the rear end of the bioreactor 100 to treat phosphorus more than the phosphorous to be discharged from the bioreactor 100 ), The phosphorus of the treated water is adsorbed and removed.

Although not shown, the phosphorus adsorption facility 200 includes a phosphorus adsorption tank into which the treated water flows from the bioreactor 100 and a phosphorus adsorption tank which is installed in the phosphorus adsorption tank to adsorb phosphorus in the treated water, But it is not limited thereto. Meanwhile, the phosphorus adsorbing material may be any known material capable of adsorbing phosphorus, and a detailed description thereof will be omitted.

The phosphorus adsorption elevation treatment system 710 includes a pH adjusting unit 210 circulatingly connected to the phosphorus adsorption facility 200 and circulatingly supplying the phosphorus adsorption tank with the pH of the treated water in the phosphorus adsorption tank . The pH adjusting unit 210 mechanically adjusts the pH of the phosphorus adsorbing material 200 to the optimal pH of the phosphorus adsorbing material 200 when the pH of the phosphorus adsorbing material 200 rises from the cleansing settling tank 300, Not shown) so that the pH of the treated water can be adjusted as needed.

After the phosphorus adsorption filter material is adsorbed in the phosphorus adsorption filter media 200, the cleaning and sedimentation filter 300 is rinsed with a washing solution and then is returned to a phosphorus adsorption facility 200) to be recycled. More specifically, when the treated water from the phosphorus adsorption facility 200 flows into the washing and sedimentation tank 300, the washing and sedimentation tank 300 cleans the treated water and solidifies and precipitates the treated water. The precipitate is sent to the dewatering facility 600, And then supplied to the phosphorus absorption facility 200 through the supernatant supply line 20 after the charging to reduce the generation of waste water as much as possible and to recycle it.

Herein, the cleaning and sedimentation tank 300 can provide the effect of lowering the water content by precipitating it in advance before being sent to the dewatering facility 600 as well as the above-mentioned recycling. In addition, The water content can be adjusted to be the same or close to the water content.

The cleaning liquid is a mechanism for removing phosphorus attached to the phosphorus adsorbing material of the phosphorus adsorption facility 200, and as shown, sodium hydroxide (NaOH) may be used, but the present invention is not limited thereto.

As described above, since the phosphorus adsorption treatment system 710 performs phosphorus adsorption through the phosphorus adsorption filter medium and phosphorus adsorption with the cleaning agent introduced into the phosphorus adsorption facility 200, the entire process is phosphorus adsorption , Phosphorus desorption, washing, and dehydration can be continuously carried out to thereby regenerate the phosphorus adsorption filter medium and process the desorption solution.

The phosphorus adsorption elevation treatment system 710 can solidify the desorbed phosphorus by a chemical reaction so that the phosphorus adsorption advanced treatment system 710 can dehydrate and treat the adsorbed phosphorus. So that the solidifying agent that solidifies can be injected to accelerate precipitation in the washing and sedimentation tank 300.

Here, the solidifying agent is injected through the solidifying agent injecting unit, and the solidifying agent can be injected in accordance with the concentration of phosphorus. The solidifying agent injecting unit includes a phosphorus concentration measuring sensor for measuring the phosphorus concentration in the treated water treated from the phosphorus adsorption facility 200 and a phosphorus concentration measuring sensor for measuring the phosphorus concentration of the solidifying agent And a solidifying agent injection means for injecting the solidifying agent at a predetermined injection amount.

The phosphorus concentration measuring sensor senses the concentration of phosphorus so as to confirm how much phosphorus is adsorbed and desorbed based on the phosphorus reaction rate. The phosphorus concentration measuring sensor is installed in the pretreatment water of the washing and sedimentation tank 300, It can be installed in the treated water.

The solidifying agent injecting means may have a different structure depending on the characteristics of the solidifying agent. In the case where the solidifying agent is a liquid, a known injection nozzle may be used. In the case where the solidifying agent is in a solid state, And a detailed description thereof will be omitted.

On the other hand, the solidifying agent can use calcium hydroxide (Ca (OH) ₂ ) or magnesium hydroxide (Mg (OH) ₂ ) as shown in the figure, but the present invention is not limited thereto.

The dewatering apparatus 600 has a function of allowing the sediment to flow in from the cleansing sedimentation tank 300 and to dewater the introduced sediment.

Further, the phosphorus adsorption elevation treatment system 710 may include a concentration tank 400 for introducing a part of the treated water of the bioreactor 100 to concentrate the treated water, a treatment unit 400 connected to the concentration tank 400, And a digester 500 for supplying water to the dewatering equipment 600. Here, in the concentrating tank 400 and the digester 500, a part of the sludge of the bioreactor 100 is taken out to the surplus sludge in consideration of newly generated microorganisms, and in order to minimize the amount of sludge at that time, And then it is sent to the dewatering equipment 600 for dehydration and treatment.

2 is a block diagram illustrating a wastewater treatment system 720 in accordance with another embodiment of the present invention. The wastewater treatment system 720 includes a first anoxic tank 110, an anaerobic tank 120, an oxic tank 130, a second anoxic tank 140, a separation membrane tank 150, A dephosphorization tank 160, a phosphorus adsorption facility 200, a cleansing settling tank 300, a dewatering facility 600, a concentration tank 400, and a digester 500. The wastewater treatment system 720 includes a phosphorus absorption facility 200, a cleaning and settling tank 300, a concentration tank 400, a digester 500, And the dewatering equipment 600 are substantially similar to each other. Therefore, a detailed description thereof will be omitted.

First, in the first anoxic tank 110, organic matter and nitrate nitrogen returned from the oxic tank 130 react with each other, and denitrification is performed by converting into nitrogen gas by denitrifying microorganisms. In the first anoxic tank 110, the treated water of the phosphorus adsorption facility 200 is introduced through the treated water supply line 10 and the treated water is supplied from the first anoxic tank return line 30 to the oxic tank 130 And the treated water of the degassing tank 160 is introduced.

The anaerobic tank 120 is disposed behind the first anoxic tank 110 and undergoes a phosphorus discharge reaction of the treated water in an anaerobic state. The treated water from the first anoxic tank 110 flows into the anaerobic tank 120 and the treated water flows into the anaerobic tank 120 through the second supply line 12, Phosphorus is released. The anaerobic tank 120 is disposed at a front end of the oxic tank 130 to allow the oxic tank 130 to consume excessive amounts of phosphorus and to induce excessive intake of the phosphorus do.

As described above, the wastewater treatment system 720 includes the first anaerobic fermentation unit 110 disposed at a front end of the anaerobic tank 120, and the nitrate nitrogen (NO ₃ -N ) Is denitrated with nitrogen gas (N ₂ ) to remove nitrate nitrogen before it is introduced into the anaerobic tank 120, so that the release of phosphorus in the anaerobic tank 120 is more likely to occur.

The wastewater treatment system 720 includes a first supply line 11 for branching the treated water supply line 10 to supply the treated water to the first anoxic tank 110, And a second supply line 12 branched from the first anoxic tank 110 and supplying the treated water to the anaerobic tank 120 so that the treated water is divided into the first anoxic tank 110 and the anaerobic tank 120 So that the phosphorus emission from the anaerobic tank 120 can be more easily generated.

Although not shown, the wastewater treatment system 720 includes a supply controller to regulate the amount of treated water flowing through the first supply line 11 and the second supply line 12, The amount of the organic matter supplied to the first anoxic tank 110 and the anaerobic tank 120 can be adjusted by controlling the flow rate of the treated water flowing into the first supply line 11 and the second supply line 12, respectively.

Accordingly, the wastewater treatment system 720 divides the treated water in accordance with the conditions and characteristics of the first anoxic tank 110 and the anaerobic tank 120 to divide the treated water into the first anoxic tank 110 and the anaerobic tank 120, The denitrification in the first anoxic tank 110 and the discharge in the anaerobic tank 120 can be performed optimally by varying the organic substance distribution ratio of the first anaerobic tank 120.

The aeration tank 130 is disposed behind the anaerobic tank 120 so that the treated water treated in the anaerobic tank 120 is introduced into the anoxic tank 120 and the excess phosphorus in the treated water and ammonia are removed by NO ₂ and NO ₃ The nitrification reaction proceeds. At this time, nitrification in the oxic tank 130 is carried to the first anoxic tank 110, so that denitrification can occur.

The second anoxic tank (140) is disposed behind the oxic tank (130), the treated water treated in the oxic tank (130) is introduced, and the dezincification nitrification reaction of the treated water proceeds in an anoxic atmosphere. The second anoxic tank 140 performs the additional denitrification of the treated water through the aerobic tank 130 because the aerobic tank 130 returns the treated water to the first anoxic tank 110, Because it has a flow rate that is 100% denitrification can not occur.

On the other hand, since the second anoxic tank 140 has used almost all of the organic substances in the previous process, there is no organic matter, and the original dead end denitrification is denitrified using old dead cells as an organic material.

Therefore, the wastewater treatment system 720 preferably injects an external carbon source for denitrification into the second anoxic tank 140 for further nitrogen treatment of the second anoxic tank 140 to enhance the quality of the treated water . In this case, the external carbon source may be injected through the external carbon injection unit 50, and the external carbon injection unit 50 may include a known injection nozzle and injection line. do.

Since the external carbon source injected into the second anoxic tank 140 is very easy to use, it is possible to rapidly denitrify a small amount of organic carbon so that the capacity of the second anoxic tank 140 can be reduced can do.

Meanwhile, the wastewater treatment system 720 may inject coagulant into the second anoxic tank 140 and the oxic tank 130.

In the separation membrane tank 150, the treated water treated in the second anoxic tank 140 is introduced, and the floating substances in the treated water are filtered to discharge the excess sludge. The separation membrane bath 150 may include a known filtration screen or the like, and a detailed description thereof will be omitted.

As described above, the wastewater treatment system 720 can separate the aerobic tank 130 and the separation membrane tank 150, thereby eliminating the need for removing the separation membrane when cleaning the separation membrane of the separation membrane tank 150 It is possible to carry out in-system cleaning which can be carried out in such a state that chemicals are put in the state, and maintenance is easy.

The wastewater treatment system 720 includes an aerobic tank conveying line 130 for supplying the dissolved oxygen of the separation membrane tank 150 to the oxic tank 130 by causing the treated water of the separation membrane tank 150 to be transported to the aerobic tank 130, (30). The oxic tank conveying line 30 may send the high dissolved oxygen of the separation membrane bath 150 to the oxic tank 130 to eliminate dissolved oxygen and reduce the amount of air sent from the oxic tank 130 through the blower In addition, the aerobic tank 130 can remove the organic matter or perform nitrification by utilizing the dissolved oxygen transported in the separation membrane tank 150, thereby providing energy saving effect.

The wastewater treatment system 720 includes a first anoxic tank return line 30 for returning a part of the treated water of the oxic tank 130 to the first anoxic tank 110, Can be prevented.

As described above, the wastewater treatment system 720 is divided into the first anoxic tank 110 and the second anoxic tank 140, and the first anoxic tank 110 is divided into the anoxic tank 110, And the second anoxic tank 140 removes the nitrate nitrogen completely, thereby allowing the nitrate nitrogen to be completely removed from the process, and it can be introduced into the separation membrane bath 150 to be sent to the treated water .

The wastewater treatment system 720 sequentially configures the first anoxic tank 110, the anaerobic tank 120, the oxic tank 130, the second anoxic tank 140, and the separation membrane tank 150 as described above The dissolved oxygen may be transported from the separation membrane bath 150 to the oxic tank 130 through the oxic tank conveying line 30 so that dissolved oxygen may be recycled in the oxic tank 130. In the oxic tank 130, The denitrification can be enhanced through the first anoxic tank return line 30.

The degassing vessel 160 is composed of a tank concept of a storage concept and supplies the treated water to the first anoxic tank 110 after receiving and storing the treated water from the separation membrane tank 150 do. The degassing vessel 160 may have a very high DO of 4 to 5 mg / L or more at the time of transporting the treated water in the separation membrane tank 150. The DO is maintained at a predetermined time (for example, about 30 minutes) So that it flows into the first anoxic tank (110).

In the meantime, the wastewater treatment system 720 does not constitute the deaeration tank 160 as a rear stage of the separation membrane bath 150, but is arranged in a step preceding the separation membrane bath 150. This is to reduce dissolved oxygen in the degassing vessel 160 to flow into the first anoxic tank 110 so that denitrification of the first anoxic tank 110 can be performed as well as possible. 150 can be transferred to the previous step or the surplus sludge discharge can be performed by one sludge discharge pump, so that the equipment cost can be reduced. In addition, the conveying line is composed of one dehairing conveying line 40, This is because maintenance can be done conveniently by reducing the number of lines.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10 ... treated water supply line 20 ... supernatant supply line
30 ... oxic tank conveying line 40 ... first anoxic tank conveying line
50 ... degassing tank supply line 60 ... solidifying agent injection unit
100 ... Bioreactor 110 ... First anoxic tank
120 ... anaerobic tank 0 ... aerobic tank
140 ... Second anoxic tank 50 ... Membrane tank
160 ... degassing vessel 200 ... phosphorus adsorption facility
210 ... pH adjusting unit 300 ... cleaning sedimentation tank
400 ... Enrichment tank 500 ... Digestion tank
600 ... Dehydration equipment 710,720 ... Waste water advanced treatment system

Claims (19)

A bioreactor for biologically treating wastewater;
A phosphorus adsorption facility including a phosphorus adsorption tank into which the treated water treated in the bioreactor enters, and a phosphorus adsorption filter medium installed in the phosphorus adsorption tank to adsorb phosphorus in the treated water;
A rinse settling tank for introducing treated water treated from the phosphorus adsorption facility and washing and solidifying the treated water to precipitate; And
And a dewatering facility for introducing the sediment from the rinse settling tank and dehydrating the sediment. The method according to claim 1,
And a pH adjusting unit circulatingly connected to the phosphorus adsorption unit to regulate the pH of the treated water in the phosphorus adsorption tank and circulate the phosphorus to the phosphorus adsorption tank. The method of claim 2,
Further comprising a supernatant supply line for supplying a cleaning agent to the sedimentation supernatant of the cleaning sedimentation tank and supplying the cleaning supernatant to the phosphorus adsorption tank. The method according to claim 1,
Further comprising a solidifying agent injecting unit injecting a solidifying agent reacting with phosphorus in the treated water treated from the phosphorus adsorption unit to solidify the solidifying agent and supplying the solidifying agent to the cleansing settling tank. The method of claim 4,
The solidifying agent injection unit
A phosphorus concentration measuring sensor for measuring the phosphorus concentration in the treated water treated from the phosphorus adsorption facility,
And solidifying agent injection means for injecting the solidifying agent at a predetermined injection amount corresponding to phosphorus concentration of the treatment water received from the phosphorus concentration measurement sensor. The method according to claim 1,
And a treatment water supply line for supplying treatment water treated from the phosphorus absorption facility to the bioreactor. The method according to any one of claims 1 to 6,
A concentrating tank connected to the bioreactor and concentrating a part of the treated water in the bioreactor;
And a digester unit connected to the thickener tank for digesting the treated water of the thickener tank and supplying the treated water to the dewatering unit. A first anoxic tank in which wastewater flows in and an denitrification reaction proceeds in an anoxic atmosphere;
An anaerobic tank into which the treated water treated in the first anoxic tank is introduced and in which the effluent of the treated water proceeds in the anaerobic state;
An aerobic tank into which the treated water treated in the anaerobic tank is introduced and in which excessive phosphorus intake and nitrification of the treated water proceed in an exhalation atmosphere;
A second anoxic tank in which the treated water treated in the aerobic tank is introduced and in which an escape oxidation reaction of the treated water proceeds in an anoxic atmosphere;
A separation membrane tank through which the treated water treated in the second anoxic tank is introduced and which filters the treated water; And
A degassing vessel for receiving and storing the treated water from the separation membrane tank and supplying the treated water to the first anoxic tank;
A phosphorus adsorption equipment including a phosphorus adsorption tank through which the treated water treated from the separation membrane bath flows, and a phosphorus adsorption filter medium (Media) installed in the phosphorus adsorption tank for adsorbing phosphorus in the phosphorus treatment water;
A rinse settling tank for introducing treated water treated from the phosphorus adsorption facility and washing and solidifying the treated water to precipitate; And
And a dewatering facility for introducing the sediment from the rinse settling tank and dehydrating the sediment. The method of claim 8,
And a pH adjusting unit circulatingly connected to the phosphorus adsorption unit to regulate the pH of the treated water in the phosphorus adsorption tank and circulate the phosphorus to the phosphorus adsorption tank. The method of claim 8,
Further comprising a supernatant supply line for supplying a cleaning agent to the sedimentation supernatant of the cleaning sedimentation tank and supplying the cleaning supernatant to the phosphorus adsorption tank. The method of claim 8,
Further comprising a solidifying agent injecting unit injecting a solidifying agent reacting with phosphorus in the treated water treated from the phosphorus adsorption unit to solidify the solidifying agent and supplying the solidifying agent to the cleansing settling tank. The method of claim 11,
The solidifying agent injection unit
A phosphorus concentration measuring sensor for measuring the phosphorus concentration in the treated water treated from the phosphorus adsorption facility,
And solidifying agent injection means for injecting the solidifying agent at a predetermined injection amount corresponding to phosphorus concentration of the treatment water received from the phosphorus concentration measurement sensor. The method of claim 8,
Further comprising a treatment water supply line for dividing the treated water treated from the phosphorus absorption facility and supplying the treated water to the first anoxic tank and the anaerobic tank, respectively,
Wherein the treated water supply line includes:
A first supply line for supplying the treated water to the first anoxic tank,
And a second supply line branched from the first supply line and supplying the treated water to the anaerobic tank. 14. The method of claim 13,
Further comprising a supply regulator for regulating the flow rate of the treated water flowing into the first supply line and the second supply line to regulate the amount of organic matter supplied to the first anoxic tank and the anaerobic tank, respectively, system. The method of claim 8,
Further comprising an external carbon injection unit injecting an external carbon source into the second anoxic tank for denitrification of the second anoxic tank. The method of claim 8,
And an oxic tank return line for supplying the treated water of the separation membrane bath to the oxic tank to supply dissolved oxygen in the separation membrane bath to the oxic tank. The method of claim 8,
And a first anoxic tank return line for carrying a part of the treated water of the oxic tank to the first anoxic tank for the escape oxidation of the oxic tank. The method of claim 8,
And a deaeration tank supply line for supplying the treated water treated in the separation membrane tank to the deaeration tank. The method according to any one of claims 1 to 18,
A concentrating tank connected to the bioreactor and concentrating a part of the treated water in the bioreactor;
And a digester capable of being connected to the thickener and supplying the treated water of the thickener to the dehydrating equipment.

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