KR102131743B1 - Bio-reactor for sewage treatment and sewage treatment system comprising the same - Google Patents

Abstract

The present invention relates to an SBR reaction tank for sewage treatment and a sewage treatment system including the same, and more specifically, the SBR reaction tank is a treatment tank in which the ammonium-containing lysate generated in the digestion tank flows in and remains; And
The treatment tank includes a hybrid strain separation tank for separating the ammonium-oxidizing bacteria (Anammox) granules and the desorption liquid containing the activated sludge,
The hybrid strain separation tank is a sewage treatment that flows down the injection solution injected into the interior of the hybrid strain separation unit located therein, passing through the separation filter located at the bottom of the pyramidal structure shape, separating ammonium-oxidized bacterial granules. For the SBR reactor.
The SBR reactor for sewage treatment provided by the present invention uses anaerobic ammonium-oxidizing bacteria to reduce the nitrogen content in the desorption liquid generated after the production of biogas, and separates the granules produced by anaerobic ammonium-oxidizing bacteria. By performing separation with high efficiency using a reactor, the treatment time can be shortened and the activated sludge separated can be reused, so that the sludge discharge amount can be significantly reduced.

Description

SBR Reactor for Sewage Treatment and Sewage Treatment System Containing the Same {{BIO-REACTOR FOR SEWAGE TREATMENT AND SEWAGE TREATMENT SYSTEM COMPRISING THE SAME}

The present invention relates to an SBR reactor for sewage treatment and a sewage treatment system including the same, more specifically, to lower the nitrogen content in the sewage in an energy-producing sewage treatment system, thereby improving the energy production efficiency in the sewage treatment process proceeding as a continuous process. The present invention relates to an SBR reactor for sewage treatment and a sewage treatment system including the same.

Conventional general sewage treatment facilities mainly use the standard activated sludge method or the added or modified method of the above method, and use A2/O process, UCT process, VIP process, etc. in foreign countries, and the process used in foreign countries is domestic The A2/O process is a biological treatment process that improves the A/O process to remove nitrogen and phosphorus, and the reaction tank is an anaerobic tank, anoxic tank. It consists of (Anoxic Tank), Aerobic Tank, and consists of Nitrifer Recycle to remove nitric nitrogen and sedimentation sludge return.In the anaerobic tank, phosphorus is released under anaerobic conditions, and microorganisms in the aerobic tank are excessive. The oxygen-free tank removes nitrogen and phosphorus by denitrifying the nitrate of the internal conveying water of the aerobic tank.

Through the A ₂ /O process, nitrogen and phosphorus are removed from the sewage to reduce nutrients in the sewage, but the focus is only on the removal of nitrogen and phosphorus from the sewage. There is a problem that it cannot be removed.

Most of the above sewage treatment plants are operated as a biological treatment method using a method in which contaminants are decomposed by microorganisms. The biological treatment method has been proven for a long time and is the most effective and safe method, but the problem is that excess sludge is generated.

Since surplus sludge is mostly an organic substance as a lump of microorganisms, it is easy to decay and treatment is a problem. So far, it has largely relied on ocean dumping, some of which have been landfilled or incinerated. As of 2012, the amount of surplus sludge generated more than 10,000 tons per day and more than 365 million tons per year, and will continue to increase in the future.

Regarding the treatment of surplus sludge, ocean dumping has been banned since 2012, and policies to promote renewable energy of organic waste such as waste resources, energyization and weight reduction have been promoted. In particular, treatment efficiency in the treatment of sludge through an anaerobic digester Solubilization pre-treatment process is carried out to increase the aforesaid, and the pre-treatment techniques include biological methods using high-temperature aerobic microorganisms, ultrasonic and hydrodynamic cavitation, physical methods using thermal hydrolysis and ball mill crushing equipment, ozone treatment and alkali chemical treatment. A chemical method, a complex treatment method in which a plurality of the above treatment methods are combined and treated, and an electric method using electrolysis are used, but there is a problem in that it is difficult to commercialize due to high cost or low loss efficiency.

As a sludge solubilization method for increasing the digestion efficiency of the anaerobic digester, Korean Patent No. 10-135458 treats the excess sludge generated in the wastewater treatment process with an alkali catalyst and methanol to soften or destroy the cell membrane of biodegradable microorganisms in the sludge. The difficulty of operation management and the above-mentioned management costs have been a problem as the efficiency of anaerobic digestion by anaerobic microorganisms in the digester is improved.

One object of the present invention is to provide a SBR reaction tank for sewage treatment, which has a simple structure and can minimize the site area while reducing treatment time, and can reuse the activated sludge.

Another object of the present invention is to reduce the amount of by-products and treatment time while minimizing the site area through a simple structure including the SBR reactor provided by the present invention, and to produce a sewage treatment system capable of producing and recovering biogas. Want to provide

Other objects and advantages of the present invention will become more apparent from the following detailed description of the invention, claims and drawings.

The embodiments of the present invention are provided to more fully describe the present invention to those of ordinary skill in the art, and the following examples may be modified in various other forms, and the scope of the present invention is as follows. It is not limited to the Examples. Rather, these examples are provided to make the present disclosure more faithful and complete, and to fully convey the spirit of the present invention to those skilled in the art.

In addition, the thickness or size of each layer in the drawings is assumed for convenience and clarity of explanation, and the same reference numerals in the drawings refer to the same elements. As used herein, the term “and/or” includes any and all combinations of one or more of the listed items.

The terminology used herein is used to describe a specific embodiment and is not intended to limit the present invention. As used herein, singular forms may include plural forms unless the context clearly indicates otherwise. Also, as used herein, “comprise” and/or “comprising” specifies the shapes, numbers, steps, actions, elements, elements and/or the presence of these groups. And does not exclude the presence or addition of one or more other shapes, numbers, actions, elements, elements and/or groups.

According to an embodiment of the present invention, the present invention is an SBR reaction tank applied to an energy-producing sewage treatment system, wherein the SBR reaction tank is a treatment tank in which ammonium-containing desorption liquid generated in a digestion tank flows in and stays; And a hybrid strain separation tank for separating the ammonium-oxidizing bacteria (Anammox) granules and active sludge of the treatment tank into a desorption solution, wherein the hybrid strain separation tank injects the injection solution injected into the hybrid strain separation unit located therein. By flowing downward, passing through a separation filter located at the bottom of the pyramidal structure shape, it relates to an SBR reactor for sewage treatment, which separates ammonium-oxidized bacterial granules.

According to an embodiment of the present invention, the hybrid strain separation tank of the present invention includes a housing; A hybrid strain separation part located inside the housing and having a truncated cone shape; An injection part for connecting the housing and the hybrid strain separation part through and connecting, and injecting the desorption liquid from the treatment tank into the hybrid strain separation part; And it may include a recovery unit for recovering the desorption liquid containing the activated sludge passed through the hybrid strain separation.

According to an embodiment of the present invention, the hybrid strain separation portion of the present invention has a conical structure shape in which the upper circle diameter is larger than the lower circle diameter, and the lysate injected into the hybrid strain separation portion is due to the difference in the upper and lower circle diameters. , It can flow downward by forming a vortex inside.

According to an embodiment of the present invention, the hybrid strain separation unit of the present invention may be composed of an upper vortex generation unit and a lower separation filter.

According to one embodiment of the present invention, the hybrid strain separator of the present invention further includes an ammonium-oxidizing bacteria transport pipe for transporting the ammonium-oxidizing bacteria (Anammox) granules that have not passed through the lower separation filter to the treatment tank. Can.

According to an embodiment of the present invention, the separation filter of the present invention may include a plurality of pores having a diameter of 50 to 150㎛.

According to one embodiment of the present invention, the activated sludge of the present invention may include one or more selected from the group consisting of AOA (Ammonia Oxidizing Archaea), AOB (Ammonia Oxidizing Bateria) and NOB (Nitrite Oxidizing Bacteria).

According to an embodiment of the present invention, the anaerobic ammonium-oxidizing bacteria (Anammox) of the present invention are Planctomycetes.

According to an embodiment of the present invention, the anaerobic ammonium-oxidizing bacteria (Anammox) of the present invention is Plancktomyces granules.

According to an embodiment of the present invention, the present invention is a primary settling tank for separating the sewage containing sludge into raw sludge and sewage; A bioreactor that adsorbs and separates organic substances in the sewage separated from the primary sedimentation tank and activated sludge, and proceeds with a denitrification process; A secondary sedimentation tank for precipitating excess sludge in sewage adsorbed with organic substances in the aeration tank; A dewatering tank for dewatering the raw sludge recovered by precipitating in the primary settling tank and the excess sludge recovered by precipitating in the secondary settling tank; A digester for producing biogas by anaerobic digestion of raw sludge and surplus sludge dehydrated in a dewatering tank; And the SBR reaction tank for removing nitrogen by reacting the ammonium-containing lysate generated in the digestion tank with anaerobic ammonium-oxidizing bacteria (Anammox).

According to an embodiment of the present invention, the SBR reaction tank of the present invention may include a hybrid strain separation tank for separating the ammonium-oxidizing bacteria (Anammox) granules and the desorption solution containing the activated sludge.

According to an embodiment of the present invention, the hybrid strain separation tank of the present invention includes a housing; A hybrid strain separation part located inside the housing and having a pyramidal structure; An injection part for connecting the housing and the hybrid strain separation part through and connecting, and injecting the desorption liquid from the treatment tank into the hybrid cell separation part; And it may include a recovery unit for recovering the desorption liquid containing the activated sludge passed through the hybrid strain separation.

According to an embodiment of the present invention, the hybrid strain separation unit of the present invention is composed of an upper vortex generation unit and a lower separation filter.

According to one embodiment of the present invention, the hybrid strain separation tank of the present invention may further include a desorption liquid supply unit for transferring the desorption liquid containing the activated sludge to the primary sedimentation tank.

According to one embodiment of the present invention, the activated sludge of the present invention may include one or more selected from the group consisting of AOA (Ammonia Oxidizing Archaea), AOB (Ammonia Oxidizing Bateria) and NOB (Nitrite Oxidizing Bacteria).

According to one embodiment of the present invention, the bioreactor of the present invention may further include an air injection device capable of injecting air for adsorption of activated sludge with organic substances in sewage.

According to an embodiment of the present invention, the bioreactor of the present invention may include a hybrid strain separation tank for separating activated sludge adsorbing organic substances.

According to an embodiment of the present invention, the anaerobic ammonium-oxidizing bacteria (Anammox) of the present invention are Planctomycetes.

According to an embodiment of the present invention, the anaerobic ammonium-oxidizing bacteria (Anammox) of the present invention is Plancktomyces granules.

According to an embodiment of the present invention, the biogas collector for collecting biogas generated in the digester of the present invention may be further included.

The SBR reaction tank for sewage treatment provided by the present invention produces energy in a digester on a sewage treatment system and reacts the generated desalination solution with anaerobic ammonium-oxidizing bacteria to lower the nitrogen content in the desalination solution, and supplies it to the sewage treatment system. Accordingly, it is possible to improve the energy generation efficiency on the sewage treatment system by maintaining the nitrogen content contained in the sewage on the entire sewage treatment system below a certain level.

In addition, by performing solid-liquid separation with high efficiency using a hybrid strain separation tank in the SBR reaction tank, the treatment time can be shortened and the activated sludge separated can be reused to significantly reduce the sludge discharge amount. Accordingly, the sewage treatment efficiency per unit area of the site can be further increased while minimizing the site area.

1 schematically shows the structure of an SBR reactor according to an embodiment of the present invention.
Figure 2 is for a hybrid strain separation tank according to an embodiment of the present invention.
Figure 3 schematically shows the structure of a sewage treatment system according to an embodiment of the present invention.
10: primary settling tank
20: bioreactor
30: secondary settling tank
40: dehydration tank
50: digester
60: SBR reactor
100: treatment tank
110: treatment tank desorption liquid
120: desalination solution containing activated sludge
130: isolated ammonium-oxidized bacterial granule
200: hybrid strain separation tank
210: vortex generation unit
220: separation filter

Hereinafter, preferred embodiments of the present invention will be described. However, embodiments of the present invention may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below. In addition, embodiments of the present invention are provided to more fully describe the present invention to those skilled in the art.

The SBR reactor for sewage treatment and the energy-producing sewage treatment system of the present invention will be described with reference to the drawings.

1 schematically shows the structure of an SBR reaction tank according to an embodiment of the present invention, and includes a treatment tank 100 and a hybrid strain separation tank 200. The treatment tank 100 is a place where the ammonium-containing tally liquid generated in the digestion tank flows in and stays, and reacts using anaerobic ammonium-oxidizing bacteria (Anammox) to lower the ammonium content of the ammonium-containing tally liquid.

The reaction-exhausted lysate contains a mixture of granules and activated sludge produced by anaerobic ammonium-oxidizing bacteria (Anammox). At this time, using the difference in particle size between the granule and the activated sludge, to separate the two and reuse each of them, the present invention is to use a hybrid strain separation tank 200.

The hybrid strain separation tank 200 will be described in more detail with reference to FIG. 2.

The hybrid strain separation tank 200 includes a housing; Located in the interior of the housing, the hybrid strain separation unit 210 in the shape of a truncated cone structure; An injection part for connecting the housing and the hybrid strain separator through and connecting, and injecting the detachment liquid 110 of the treatment tank into the hybrid strain separator; And a recovery unit for recovering the desorption liquid 120 including the activated sludge that has passed through the hybrid strain separation unit.

The desorption liquid 110 of the treatment tank is injected into the hybrid strain separation unit 210 through the injection unit at a constant rate. At this time, the injection portion may be composed of a tube penetrating the housing, connected to the hybrid strain separation unit 210.

The desorption liquid 110 injected at a constant rate through the injection portion is injected into a hybrid strain separation portion having a truncated cone shape, and the hybrid strain separation portion has a truncated cone shape having a larger diameter than the lower diameter. It is configured to be, the desorption liquid 110 is to form a vortex inside the shape of the truncated cone structure, it can flow downward.

That is, as the desorption liquid 110 is injected at a constant rate, it is introduced into the vortex formation portion 210 of the hybrid strain separation unit, and collides with the inner wall of the vortex formation portion 210, thereby forming a vortex. When the desorption liquid 110 forms a vortex, as the shape of the vortex forming portion 210 has a shape of a truncated cone structure larger than the diameter of the lower portion, a vortex is formed along the wall to flow downward. have.

When the desorption liquid 110 is formed as a vortex and flows downward, the desorption liquid 110 that flowed downwardly passes through the separation filter 220 located at the bottom of the hybrid strain separation unit and moves to the housing.

At this time, the separation filter 220 includes a plurality of pores of 50 to 150㎛, ammonium-oxidized bacterial granules having a particle size larger than the diameter of the pores do not pass through the separation filter 220, the hybrid strain separation It remains in the interior of the part, and the activated sludge having a small particle size and the desorption liquid 120 containing the same can move into the housing.

The desorption liquid 120 stays in the housing and can be transferred to the primary sedimentation tank through a recovery part of the housing at a certain level or higher.

In addition, the ammonium-oxidized bacterial granules staying in the hybrid strain separation unit are recovered and transferred 130 to the treatment tank 100. The ammonium-oxidized bacterial granules are transferred 130 to the treatment tank 100 and can be reused.

3 schematically shows the structure of a sewage treatment system according to an embodiment of the present invention, wherein the sewage treatment system of the present invention comprises a primary settling tank 10 according to the present invention; It may include a bioreactor 20, a secondary sedimentation tank 30, a dehydration tank 40, a digestion tank 50, and an SBR reaction tank 60.

In the present invention, after supplying the sewage to the primary sedimentation tank 10, the foreign matter contained in the sewage is precipitated with fresh sludge to recover the fresh sludge, and the sewage from which the saline has been removed can be supplied to the bioreactor 20. In more detail, when the sewage is supplied to the primary sedimentation tank 10, it is divided into a material having a specific gravity (water) and a material having a specific gravity of light (floating material), which is lighter than water (contamination material). Approximately 40% of the material can be removed.

In addition, in the present invention, the liquid sewage separated from the raw sludge in the primary sedimentation tank 10 may be supplied to the bioreactor 20.

The bioreactor is an aerobic tank; Hybrid strain separation tank according to an embodiment of the present invention; And anaerobic tanks. More specifically, an aerobic tank for adsorbing organic substances contained in sewage using activated sludge, the aerobic tank comprising an inlet for supplying sewage; A mixing cell for receiving the sewage and mixing the activated sludge; It is continuously coupled to the mixing cell and includes an aerobic reaction tank in which adsorption of activated sludge and organic substances in sewage occurs. The activated sludge is adsorbed with organic substances in sewage, and through this adsorption process, it is possible to remove a certain amount of pollutants present in the sewage within a short time.

In addition, the adsorption process of the activated sludge in the aerobic reaction tank proceeds through the injection of air, whereby an air injection device is connected to the aerobic reaction tank to inject air.

In addition, the aerobic reactor is intended to remove pollutants from sewage by activated sludge, and thus, suitable environmental conditions for the reaction of activated sludge in the aerobic reactor must be established.

Therefore, in general, it is important to maintain the temperature in the range of 10°C to 35°C, and to maintain a residence time sufficient for the activated sludge to proceed with the adsorption process, and the pH should be maintained at 6.5 to 8.5.

In the present invention, after supplying sewage to be treated through the inlet of the exhalation tank, the activated sludge is mixed and reacted to adsorb organic substances contained in the sewage, wherein the activated sludge is AOA (Ammonia Oxidizing Archaea) ), AOB (Ammonia Oxidizing Bateria) and NOB (Nitrite Oxidizing Bacteria). It consists of at least one selected from the group consisting of, and adsorbs organic substances through activated sludge.

In addition, in the present invention, by further comprising at least one stirrer in the mixing cell, it is possible to accelerate the mixing process of the sewage and the activated sludge.

In the present invention, the shape of the stirrer is not particularly limited, but may be an impeller type having wings. Here, the specific shape of the impeller-type stirrer is not particularly limited, but according to a preferred embodiment of the present invention, the impeller-type stirrer is formed by bending the outer wing portion toward the lower direction of the inner wing portion to collect water by hand. You can maximize the agitation effect by pushing as much water as possible in the desired direction and flowing as if you are pushing it out with force.

In the present invention, when there are a plurality of agitators, the blade diameters of the plurality of agitators may be the same or different, but preferably, a plurality of agitators having different blade diameters are arranged to decrease in diameter as they go from the upper chamber to the lower chamber side. As the influent moves from the top of the chamber to the bottom, it is possible to maintain a faster mixing speed.

At this time, the rotational speed (G-value) of the stirrer blade is not particularly limited, and may be appropriately selected according to the mixing and agglomeration scale or the size of the chamber, but may preferably be 30 to 110 sec ^-1 .

In addition, in the present invention, an auxiliary agent may be additionally added together with the above-mentioned activated sludge, wherein the auxiliary agent may be selected from the group consisting of clay, calcium hydroxide, cationic flocculants, anionic flocculants, and nonionic flocculants.

In the present invention, when the activated sludge adsorbs the organic material contained in the sewage in the aerobic tank as described above and grows as a floc, the treated sewage is supplied to the hybrid strain separation tank connected to the aerobic tank 21 as described above. The activated sludge adsorbed with organic substances contained in the sewage does not pass through the separation filter in the hybrid strain separation tank and remains as solid sludge. Therefore, in the present invention, it is possible to separate the sewage containing the floc into solid sludge and liquid primary treated water through a hybrid strain separation tank.

In the present invention, organic materials contained in sewage can be adsorbed or aggregated in activated sludge in the aerobic tank of the bioreactor, and then, in the hybrid strain separation tank, the sewage can be separated into solid sludge and liquid primary treated water. have. At this time, the primary treatment water is transferred to the anaerobic tank, and the denitrification process is performed, and the denitrification process in the anaerobic tank is duplicated as described above, and detailed description is omitted.

In the present invention, the solid-phase sludge having a water content of only about 70 to 80% can be separated from the sewage by the hybrid strain separation tank of the bioreactor 20, and unlike the bioreactor using a conventional separation filter, the present invention There is no need for a separate air injection device for removing foreign matter in the separation filter.

On the other hand, in the present invention, the hybrid strain separation tank is the same as the above description, but the detailed description is excluded. That is, the hybrid strain separation tank can be used in combination with the treatment tank of the SBR reaction tank, and can be used in combination with the biological reaction tank 20.

The treatment tank and the bioreactor 20 in the SBR reaction tank both generate granules using ammonium-oxidizing bacteria, and the generated granules cannot pass through the separation filter in the hybrid strain separation unit due to the large particle size. The granules that have not passed through the hybrid strain separation tank of the bioreactor 20 can be recovered and transferred to the previous step for reuse, and the treated water that has passed proceeds to the next step to proceed with the sewage treatment process. In addition, the granules that have not passed through the hybrid strain separation tank 200 in the SBR reaction tank are reused by transferring 130 to the treatment tank 100 again, and the desorption liquid containing the activated sludge passed back to the primary sedimentation tank 10 Transfer and reuse.

Under the system for sewage treatment, sewage precipitates the raw sludge in the primary sedimentation tank 10, separates the liquid sewage, and transfers it to the bioreactor 20, thereby exhaling the bioreactor 20; Hybrid strain separation; And through an anaerobic tank, the organic material is removed and denitrification processes are performed.

The secondary treated water, in which nitrogen is removed from the anaerobic tank, stays in the second sedimentation tank 30, removes excess sludge by precipitation, and is then discharged through a disinfection process.

The raw sludge and surplus sludge separated by sedimentation by the primary settling tank and the secondary settling tank are transferred to the dewatering tank 40 to proceed with the dewatering process. The concentrated sludge after the dewatering process is transferred to the digester 50.

In the present invention, the digester 50 may perform an anaerobic digestion process for the excess sludge and raw sludge using anaerobic microorganisms.

Here, the anaerobic digestion process is also referred to as "methane fermentation", a series of processes that convert organic matter contained in the excess sludge into methane by the decomposition action of various anaerobic microorganisms, and more specifically liquefy solid organic matter. , Hydrolysis process, vinegar acid, propionic acid, lower fatty acid to produce butyl acid (volatile organic acid, VFA), process to decompose them into vinegar acid and H ₂ gas, to produce methane using these products The process proceeds.

In the present invention, the digester 50 can recover energy with biogas called methane at the same time as processing concentrated sludge. Accordingly, the present invention may further include a biogas collector (not shown) for collecting biogas generated in the digester 50, and if necessary, biogas for separating methane and carbon dioxide contained in the biogas. A separation filter may be further included.

In the present invention, when the anaerobic digestion process is performed in the digester 50, digestion sludge and desalination liquid that are no longer recyclable are generated. The digested sludge can be disposed of, and the desorption liquid can be supplied to the SBR reactor 60.

The SBR reactor 60 is a sequential batch reactor, and uses a continuous batch activated sludge process. The conventional SBR process is a method in which one batch tank has functions of a reaction tank and a secondary sedimentation tank to repeatedly process the reaction and precipitation of the mixed solution, drainage of symbol water, and discharge of sedimentation sludge.

In the case of the conventional sewage treatment system, after performing an anaerobic digestion process using concentrated sludge in the digester 50, the resulting desorption liquid was transferred back to the primary sedimentation tank for reprocessing. However, in that case, the desorption liquid generated in the digester 50 includes NH ⁴⁺ or NO ^2-, and if the sewage treatment is performed in a continuous process, the concentration of nitrogen continues to rise and C (carbon) in the bioreactor 20 is increased. )/N (nitrogen) ratio exceeds 1, and finally, a problem in that energy production efficiency in the digester 50 is remarkably deteriorated.

In the present invention, in order to prevent the above problems, by transporting the desorption liquid generated in the digester 50 to the SBR reaction tank 60, and reacting with anaerobic ammonium-oxidizing bacteria (Anammox), NH ^{4 +} and NO ² contained in the desorption liquid ^- to convert to N ₂ can be removed with nitrogen.

In the present invention, the anaerobic ammonium-oxidizing bacteria may be planktomycetes (Planctomycetes). In general, AOB bacteria used as activated sludge in the bioreactor 20 can convert about 50% of the NH ⁴⁺ to NO ^2- , but Planktomyce used in the SBR reactor 60 in the present invention ( Planctomycetes) can convert both NH ⁴⁺ and NO ^2- to N ₂ . In addition, in the present invention, the Planktomycetes (Planctomycetes) is adsorbed with the surrounding organic matter to form a granule (granule), wherein the particle size of the granules, compared to AOA, AOB and NOB bacteria, relatively large particles Since the size can be indicated, it can be selectively separated according to the particle size in the hybrid strain separation tank 200 as described above.

In the present invention, as the nitrogen contained in the desorption liquid is removed from the SBR reaction tank 60 as described above, the final treatment water generated in the SBR reaction tank 60 is transferred to the primary sedimentation tank 10 to perform a sewage treatment process. Since the ratio of C (carbon)/N (nitrogen) in the bioreactor 20 can be maintained at ≤ 1, energy production efficiency can be maintained even in a continuous process for sewage treatment.

In the present invention, the desorption liquid transferred to the SBR reaction tank 60 may be accommodated inside the treatment tank 100. In the present invention, the lysate transferred to the treatment tank 100 is subjected to an anaerobic digestion reaction by anaerobic ammonium-oxidizing bacteria to form granules.

In the present invention, the pores of the separation filter have a diameter of 50 to 150 μm, so that the granules do not pass through the separation filter module, while bacteria such as AOA, AOB and NOB, which are active sludges in the bioreactor 20, are re-used. It can pass through the separation filter module.

In addition, in the present invention, the purified desorption liquid and bacteria, such as AOA, AOB, and NOB contained therein, can be recovered separately and re-supplied to the primary sedimentation tank 10 through the water supply pipe.

Hereinafter, the present invention will be described in more detail through specific examples. The following examples are only examples for helping the understanding of the present invention, and the scope of the present invention is not limited thereto.

Claims (20)

SBR reactor applied to energy production type sewage treatment system,
The SBR reaction tank is a treatment tank that proceeds the reaction using anaerobic ammonium-oxidizing bacteria (Anammox) while the ammonium-containing desorption solution containing the activated sludge generated in the digestion tank flows in and out; And a hybrid strain separation tank for separating the desorption liquid of the treatment tank into a desorption liquid containing ammonium-oxidized bacteria (Anammox) granules and activated sludge.
The hybrid strain separation tank is a housing; Located in the interior of the housing, the upper circumferential diameter is larger than the lower circumferential conical structure, and is composed of an upper vortex generating unit and a lower separation filter, and the treatment is injected due to the difference in the upper and lower diameters. A hybrid strain separation unit in which the crude desorption fluid flows downward while forming a vortex inside; An injection part for connecting the housing and the hybrid strain separator through and connecting, and injecting the desorption liquid of the treatment tank into the hybrid strain separator; A recovery unit for recovering the desorption liquid containing the activated sludge that has passed through the hybrid strain separation unit; And an ammonium-oxidizing bacteria transfer pipe for transferring the ammonium-oxidizing bacteria (Anammox) granules that have not passed through the separation filter to the treatment tank.
SBR reaction tank for sewage treatment, characterized in that it comprises a. delete delete delete delete According to claim 1,
The separation filter is a SBR reaction tank for sewage treatment including a plurality of pores having a diameter of 50 to 150㎛. According to claim 1,
The activated sludge SBR reactor for sewage treatment comprising at least one selected from the group consisting of AOA (Ammonia Oxidizing Archaea), AOB (Ammonia Oxidizing Bateria), and NOB (Nitrite Oxidizing Bacteria). According to claim 1,
The anaerobic ammonium-oxidizing bacteria (Anammox) is a SBR reaction tank for sewage treatment, which is Planctomycetes. According to claim 1,
The anaerobic ammonium-oxidizing bacteria (Anammox) is a SBR reaction tank for sewage treatment, which is Planckomyces granules. A primary sedimentation tank separating the sewage containing sludge into raw sludge and sewage;
A bioreactor that adsorbs and separates organic substances in the sewage separated from the primary sedimentation tank and activated sludge, and proceeds with a denitrification process;
A secondary sedimentation tank for precipitating excess sludge in sewage adsorbed with organic substances in the bioreactor;
A dewatering tank for dewatering the raw sludge recovered by precipitating in the primary settling tank and the excess sludge recovered by precipitating in the secondary settling tank;
A digester for producing biogas by anaerobic digestion of raw sludge and surplus sludge dehydrated in a dewatering tank; And
A sewage treatment system comprising the SBR reactor according to claim 1 to remove nitrogen by reacting the ammonium-containing leach solution generated in the digester with anaerobic ammonium-oxidizing bacteria (Anammox). delete delete delete The method of claim 10,
The hybrid strain separation tank is a sewage treatment system further comprising a discharging liquid supply for transferring the desalination solution containing the activated sludge to the primary sedimentation tank. The method of claim 10,
The activated sludge is a sewage treatment system comprising at least one selected from the group consisting of AOA (Ammonia Oxidizing Archaea), AOB (Ammonia Oxidizing Bateria) and NOB (Nitrite Oxidizing Bacteria). The method of claim 10,
The bioreactor further comprises an air injecting device capable of injecting air for adsorption of organic material and activated sludge in sewage. The method of claim 10,
The bioreactor tank is a sewage treatment system comprising a hybrid strain separation tank for separating the activated sludge adsorbed to the organic material. The method of claim 10,
The anaerobic ammonium-oxidizing bacteria (Anammox) is a Planktomycetes (Planctomycetes) sewage treatment system. The method of claim 10,
The anaerobic ammonium-oxidizing bacterium (Anammox) is a Planktomyces granules sewage treatment system. The method of claim 10,
A sewage treatment system further comprising a biogas collector for collecting biogas generated in the digester.

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