KR20180031085A - Method and device for biologically treating organic wastewater - Google Patents

Abstract

[PROBLEMS] In a multi-stage activated sludge method using a predation action of a micro animal, preference is given to a microorganism of a filtration predator type to improve the treatment efficiency and to reduce the sludge and to improve the quality of the treated water. [MEANS FOR SOLVING PROBLEMS] An organic wastewater is introduced into a first biological treatment tank (1), subjected to biological treatment with bacteria, and a first biological treatment water containing bacteria in a dispersed state from the first biological treatment tank (1) Water is passed through the biological treatment tank 2 to obtain the second biological treatment water, and the second biological treatment water is subjected to solid-liquid separation. The animal-animal support carrier 22 is installed in the second biological treatment tank 2 and a part of the sludge is taken out and treated in the anoxic tank 4 and then returned to the second biological treatment tank 2.

Description

TECHNICAL FIELD [0001] The present invention relates to a method and apparatus for biological treatment of organic wastewater,

The present invention relates to a biological treatment method and apparatus for organic wastewater which can be used for treatment of organic wastewater having a wide concentration range including domestic wastewater, sewage, food factory and pulp mill, and more particularly to a method and apparatus for biological treatment of organic wastewater, And more particularly to a biological treatment method and apparatus for organic wastewater which can reduce the amount of surplus sludge generated.

The activated sludge method used in the biological treatment of organic wastewater is widely used for sewage treatment and industrial wastewater treatment because of its advantages such as good treatment water quality and easy maintenance. However, since the BOD volume load in the activated sludge process is generally about 0.5 to 0.8 kg / m ³ / d, a large site area is required. Also, since 20 to 40% of the decomposed BOD is converted into cells, that is, sludge, a large amount of surplus sludge treatment also becomes a problem.

BACKGROUND ART [0002] With respect to high load treatment of organic wastewater, a fluidized bed method in which a carrier is added is known. When this method is used, it is possible to operate with a BOD volume load of 3 kg / m ³ / d or more. However, in this method, the amount of generated sludge is about 30 to 50% of the decomposed BOD, which is higher than that of the conventional activated sludge process.

 Japanese Patent Application Laid-Open No. 55-20649 discloses a method in which organic wastewater is first treated with bacteria in a first treatment tank to oxidize and decompose the organic matter contained in wastewater to convert into bacterial non-cohesive cells, It is described that the excess sludge can be reduced by eliminating predation in the animal. In addition, this method makes it possible to perform a high-load operation, thereby improving the treatment efficiency of the activated sludge process.

 A number of methods for treating wastewater using predators of protozoa or worms located at high levels of bacteria have been proposed.

 For example, Japanese Patent Application Laid-Open No. 2000-210692 proposes a countermeasure against deterioration of the treatment performance due to fluctuation of the water quality of the raw water which is a problem in the treatment method of Japanese Patent Application Laid-Open No. 55-20649. As a specific method, "the BOD variation of the water to be treated is adjusted to be within 50% of the median of the average concentration", "the water quality of the first treatment tank and the first treated water is measured with time" A method of adding a sludge or a microbial agent to the first treatment tank at the time of deteriorating the quality of the first treated water " has been proposed.

 Japanese Patent Publication No. 60-23832 discloses a method in which when the initial sedimentation sludge or excess sludge treated with bacteria, yeast, actinomycetes, algae, fungi or wastewater is fed to a protozoan animal or welfare animal, ultrasonic treatment or mechanical stirring A method of making the floc size of these food smaller than the mouth of the animal has been proposed.

Further, the invention relating to the multi-stage treatment of the fluidized bed and the activated sludge process is described in Japanese Patent No. 3410699. In this method, it is possible to significantly reduce the amount of sludge being extracted by self-oxidizing the sludge by operating the downstream activated sludge process with a low load of BOD sludge load of 0.1 kg-BOD / kg-MLSS / d.

The multi-stage activated sludge process using the predation of micro-animals is actually used for organic wastewater treatment. Depending on the wastewater to be treated, the treatment efficiency can be improved and the amount of generated sludge can be reduced by about 50%. The animalcules contributing to the sludge reduction include filtration predators and agglomerate predators. Among these, the animalcules of the agglomerate predation type may predation while swallowing the flourized sludge. Therefore, when the agglomerate predation type animal is prioritized, the quality of the treated water is deteriorated. Therefore, in order to improve the quality of the treated water, it is effective to prioritize the filtration type of animalcules among the animalcules. However, there has been no proposal of a method for controlling the propagation of the filtration-dominant small animal and the propagation of the flocculation- , There is a problem that unexpected treatment water quality deterioration occurs depending on the operation condition when the sludge is reduced by using the animalcules.

The activated sludge method includes a membrane separation activated sludge method using a membrane separation device for solid-liquid separation of sludge and treated water, and a sedimentation type activated sludge method using a sedimentation paper.

In the membrane separation activated sludge method, it is possible to operate at a high volumetric load by keeping the sludge concentration at a high level compared with the sedimentation type activated sludge method. Moreover, since the sludge management as in the sedimentation tank is not required, .

However, in the membrane separation activated sludge method, the membrane tends to be occluded depending on the nature and condition of the sludge in the activated sludge tank, and the cleaning frequency of the membrane is high.

Japanese Patent Application Laid-Open No. 9-294996 proposes a method of preventing the clogging of the membrane by reducing the adhesion of sludge to the membrane by adding a carrier to the aeration tank.

However, even in the method of adding a carrier to the aeration tank, occlusion of the membrane may not be sufficiently prevented.

In addition, even when the activated sludge treatment is operated at a low load, disassembly of the sludge causes fine SS to clog the membrane. In addition, if the number of animalcules predisposed to flocs in activated sludge increases due to water temperature, load, and SRT (solid retention time), the sludge becomes finer and promotes deterioration of the treated water. There is a problem that management becomes difficult.

1. Japanese Patent Application Laid-Open No. 55-20649 2. Japanese Patent Application Laid-Open No. 2000-210692 3. Japanese Patent Publication No. 60-23832 4. Japanese Patent No. 3410699 5. JP-A-9-294996

 According to a first aspect of the present invention (hereinafter referred to as " first invention ") provided in the present invention, in a multi-stage activated sludge method using a predation action of a animal, preference is given to a petiole- And to provide a method and apparatus for biological treatment of organic wastewater which further improves the quality of the treated water together with improvement of the quality of the sludge and reduction of the volume of the sludge (Problem 1).

The invention according to the second aspect (hereinafter referred to as " second invention ") provided in the present invention is a method for reducing the amount of generated sludge considerably in the biological treatment of organic wastewater to which a membrane separation activated sludge method is applied, (Ii) a method and an apparatus for biological treatment of organic wastewater which prevent clogging, lower the cleaning frequency of the membrane, improve treatment efficiency by high load operation, and stabilize treated water quality.

DISCLOSURE OF THE INVENTION The present inventors have intensively studied in order to solve the above Problem I. As a result, the inventors of the present invention have found that, by removing the biological treatment tank sludge at the downstream and passing the anoxic tank through the anaerobic tank, the proliferation of the swimming animal- It is possible to keep the fixed animal species of filtration type animal by holding the animal-animal support carrier in the biological treatment tank at the rear stage, and even if the sludge of the biological treatment tank at the downstream stage is taken out and introduced into the anoxic tank, Are not affected, and as a result, filtration predators can be prioritized.

 The first invention is achieved on the basis of these findings, and the gist of the invention is as follows.

The biological treatment method for organic wastewater according to the first aspect of the first invention is characterized in that organic wastewater is introduced into a first biological treatment tank of an aerobic biological treatment tank provided in two or more stages and subjected to biological treatment with bacteria, A method for biological treatment of organic wastewater, comprising passing a first biological treatment water containing bacteria in a dispersed state to a biological treatment tank after a second biological treatment tank, the method comprising: A part of the sludge in the biological treatment tank after the second biological treatment tank is taken out and treated in the anoxic tank, and then returned to the biological treatment tank after the second biological treatment tank.

The biological treatment method for organic wastewater according to the second aspect of the first invention is characterized in that in the first aspect at least part of the first biological treatment water is passed through the anoxic tank to the biological treatment tank after the second biological treatment tank It is characterized by.

The biological treatment method for organic wastewater according to the third aspect of the first invention is characterized in that in the first or second aspect, a part of the organic wastewater is introduced into the anoxic tank and the remainder is introduced into the first biological treatment tank .

The biological treatment method of the organic wastewater of the fourth aspect of the first invention is characterized in that, in the first to third aspects, the anoxic tank holds the carrier.

The biological treatment method for organic wastewater according to the fifth aspect of the first invention is characterized in that, in any one of the first to fourth aspects, a carrier for holding the animalcules is provided in the biological treatment tank after the second biological treatment tank .

The biological treatment method for organic wastewater according to the sixth aspect of the first invention is characterized in that, in any one of the first to fifth aspects, the SRT (solids retention time) of the biological treatment tank after the second biological treatment tank is 60 days or less And the sludge is taken out as much as possible.

The biological treatment method for organic wastewater according to the seventh aspect of the first invention is characterized in that, in any one of the first to sixth aspects, the treated water of the biological treatment tank after the second biological treatment tank is subjected to solid- To the biological treatment tank after the second biological treatment tank.

An apparatus for biological treatment of organic wastewater according to an eighth aspect of the first aspect of the present invention comprises an aerobic biological treatment tank provided in two or more tiered stages and introducing organic wastewater into the first biological treatment tank and biological treatment with bacteria, A biological treatment apparatus for an organic wastewater which passes first biological treatment water containing bacteria in a dispersed state from a treatment tank to a biological treatment tank after the second biological treatment tank for biological treatment, An anoxic tank provided with a carrier for holding animalcules in the treatment tank and a part of the sludge in the biological treatment tank after the second biological treatment tank is taken out and treated and then transported to the biological treatment tank after the second biological treatment tank .

The biological treatment apparatus for organic wastewater according to the ninth aspect of the first invention is the biological treatment apparatus for the organic wastewater according to the eighth aspect of the present invention which comprises at least a part of the first biological treatment water passing through the anoxic tank to the biological treatment tank after the second biological treatment tank .

The biological treatment apparatus for organic wastewater according to the tenth aspect of the first invention is characterized in that, in the eighth or ninth aspect, means for introducing a part of the organic wastewater into the anoxic tank and a means for introducing the remaining part of the organic wastewater into the first biological treatment tank And a means for introducing the liquid.

The biological treatment apparatus for organic wastewater according to the eleventh aspect of the first aspect of the present invention is characterized in that, in any one of the eighth to tenth aspects, the carrier is held in the anoxic tank.

The biological treatment apparatus for organic wastewater of a twelfth aspect of the first invention is characterized in that in any one of the eighth to eleventh aspects, a carrier for holding animalcules is provided in the biological treatment tank after the second biological treatment tank .

The biological treatment apparatus for organic wastewater according to the thirteenth aspect of the first invention is characterized in that, in any one of the eighth to twelfth aspects, the SRT (solids residence time) of the biological treatment tank after the second biological treatment tank is 60 days or less And the sludge is taken out as much as possible.

The biological treatment apparatus for organic wastewater according to the fourteenth aspect of the first invention is characterized in that, in any one of the eighth to thirteenth aspects, the treated water of the biological treatment tank after the second biological treatment tank is subjected to solid- And a means for transporting a part of the biological sample to the biological treatment tank after the second biological treatment tank.

DISCLOSURE OF THE INVENTION The present inventors have intensively studied in order to solve the above Problem II. As a result, in the multistage activated sludge process using the predation of animalcules, the present inventors found that a tank for treating an organic matter in a single- (Dispersed microorganism) is produced, and the necessary animalcules are actively prioritized in the downstream biological treatment tank, thereby suppressing the proliferation of aggregate (flock) predators which cause clogging of membranes; To this end, a microorganism retaining carrier is installed in the downstream biological treatment tank and efficiently retains the sticky filtration type microorganism which contributes to the solid-liquid separation of the sludge and the quality of the treated water by efficiently predating the dispersed microorganism; , It is possible to prevent clogging of the membrane in the membrane separation activated sludge method and to achieve stable high load treatment.

The second invention is achieved on the basis of this finding, and the gist of the invention is as follows.

The biological treatment method for organic wastewater according to the first aspect of the second invention is characterized in that organic wastewater is introduced into a first biological treatment tank of an aerobic biological treatment tank provided in two or more stages and subjected to biological treatment with bacteria, The first biological treatment water containing the bacteria in the dispersed state is passed through the biological treatment tank after the second biological treatment tank and subjected to biological treatment and the organic wastewater organisms In the treatment method, a carrier for holding the animalcules is provided in the biological treatment tank after the second biological treatment tank, and solid-liquid separation of the treated water in the biological treatment tank after the second biological treatment tank is performed by membrane separation treatment .

The biological treatment method of organic wastewater according to the second aspect of the second invention is characterized in that, in the first aspect, the membrane separation treatment is carried out in a bath-type separating apparatus.

The biological treatment method for organic wastewater according to the third aspect of the second invention is characterized in that, in the first or second aspect, the carrier provided in the biological treatment tank after the second biological treatment tank is a carrier fixed to the biological treatment tank .

The biological treatment method for organic wastewater according to the fourth aspect of the second invention is characterized in that, in any one of the first to third aspects, a part of the organic wastewater is passed through the second biological treatment tank In the biological treatment tank.

The biological treatment method for organic wastewater according to the fifth aspect of the second invention is characterized in that, in any one of the first to fourth aspects, the SRT (solids retention time) of the biological treatment tank after the second biological treatment tank is 60 days or less And the sludge is taken out as much as possible.

A biological treatment method of an organic wastewater according to a sixth aspect of the second invention is characterized in that, in any one of the first to fifth aspects, a part of the sludge in the biological treatment tank after the second biological treatment tank is taken out and treated in an anoxic tank To the biological treatment tank after the second biological treatment tank.

An apparatus for biological treatment of organic wastewater according to a seventh aspect of the second invention comprises an aerobic biological treatment tank provided in two or more stages in a multi-stage, wherein organic wastewater is introduced into the first biological treatment tank and subjected to biological treatment with bacteria, The first biological treatment water containing the bacteria in the dispersed state from the treatment tank is passed through the biological treatment tank after the second biological treatment tank for biological treatment and the treated water of the biological treatment tank after the second biological treatment tank is solid- Characterized in that a carrier for holding the animalcules is provided in the biological treatment tank after the second biological treatment tank, and the solid-liquid separation means for treating water in the biological treatment tank after the second biological treatment tank And a film separation processing apparatus.

An eighth aspect of the biological treatment apparatus for organic wastewater according to the eighth aspect of the present invention is characterized in that, in the seventh aspect, the membrane separation apparatus is a crude membrane separation apparatus.

The biological treatment apparatus for organic wastewater according to the ninth aspect of the second invention is characterized in that, in the seventh or eighth aspect, the carrier provided in the biological treatment tank after the second biological treatment tank is a carrier fixed to the biological treatment tank .

The biological treatment apparatus for organic wastewater according to the tenth aspect of the second invention is characterized in that, in any one of the seventh to ninth aspects, part of the organic wastewater is passed through the second biological treatment tank To the biological treatment tank of the biological treatment tank.

The biological treatment apparatus for organic wastewater according to the eleventh aspect of the second invention is characterized in that, in any one of the seventh to tenth aspects, the biological treatment tank after the second biological treatment tank has an SRT (solid retention time) of 60 days or less And the sludge is taken out as much as possible.

A biological treatment apparatus for organic wastewater according to a twelfth aspect of the second invention is characterized in that, in any one of the seventh to eleventh aspects, a part of the sludge in the biological treatment tank after the second biological treatment tank is taken out and treated, And an anoxic tank for returning to the biological treatment tank after the two biological treatment tanks.

In the first invention, in the multistage activated sludge method using the predation action of animalcules, the animal-animal holding carrier is provided in the biological treatment tank for holding the animalcules, the sludge in the biological treatment tank is taken out, treated in the anoxic tank, , It is possible to suppress the multiplication of the aggregate predator-type small animal and to preferentially multiply the filtration predator-type small animal in the small animal retention biological treatment tank, thereby improving the water quality.

In the second invention, in the multistage activated sludge method using the predation action of the animalcules, the animal-animal support carrier is provided in the biological treatment tank for holding the animalcules so that the dispersed bacteria are efficiently fed into the biological treatment tank, It is possible to maintain the filtration-trapped animalcules of the sticking type contributing to the separation and the quality of the treated water, thereby preventing the clogging of the membrane separating device for separating the biological treatment water of the biological treatment tank, .

Therefore, according to the first invention and the second invention, efficient biological treatment of organic wastewater becomes possible, and the following effects are exhibited.

1) Significant reduction of sludge generated in drainage treatment

2) Improvement of treatment efficiency by high load operation

3) Maintain stable water quality

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a systematic diagram showing an embodiment of a biological treatment method and apparatus for organic wastewater according to the first invention. FIG.
2 is a systematic diagram showing another embodiment of the biological treatment method and apparatus for organic wastewater of the first invention.
3 is a systematic diagram showing still another embodiment of the biological treatment method and apparatus for organic wastewater according to the first invention.
Fig. 4 is a system diagram showing still another embodiment of the biological treatment method and apparatus for organic wastewater according to the first invention. Fig.
5 is a system diagram showing still another embodiment of the biological treatment method and apparatus for organic wastewater according to the first invention.
6 is a systematic diagram showing an embodiment of a biological treatment method and apparatus for organic wastewater according to the second invention.
7 is a systematic diagram showing another embodiment of the biological treatment method and apparatus for organic wastewater according to the second invention.
8 is a systematic diagram showing still another embodiment of the biological treatment method and apparatus for organic wastewater according to the second invention.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of a biological treatment method and apparatus for organic wastewater of the present invention will be described in detail with reference to the drawings.

[First Invention]

1 to 5 are schematic diagrams showing embodiments of a biological treatment method and apparatus for organic wastewater according to the first invention.

1 to 5, reference numeral 1 denotes a first biological treatment tank, reference numeral 2 denotes a second biological treatment tank, reference numeral 3 denotes a sedimentation tank, reference numeral 4 denotes an anoxic tank, reference numeral 5 denotes a membrane separation device, Reference numeral 21 denotes a diffuser, reference numeral 22 denotes a supporting member for animalcules, reference numeral 41 denotes a stirring means, and reference numeral 42 denotes a carrier. .

In the embodiment of Fig. 1, the raw water (organic wastewater) is introduced into the first biological treatment tank 1 and is separated into 70% or more of the organic component (soluble BOD) by dissociable bacteria (non-coagulating bacteria) % Or more, and more preferably 90% or more. The pH of the first biological treatment tank 1 is set to 6 or more, preferably 8 or less. However, when raw water contains a lot of oil, the pH can be set to 8 or more.

The BOD volume load of the first biological treatment tank 1 is 1 kg / m ³ / d or more, for example, 1 to 20 kg / m ³ / d or more, m ³ / d and the HRT (raw water retention time) is 24 h or less, preferably 8 h or less, for example, 0.5 to 8 h, the treated water in which the dispersible bacteria are ignited can be obtained, It is possible to treat a drain with a low BOD concentration at a high load.

A part of the sludge from the biological treatment tank in the subsequent stage is conveyed to the first biological treatment tank 1, or the support is added to the first biological treatment tank 1 in two or more stages, A high load treatment with a volume load of 5 kg / m ³ / d or more is also possible.

When the carrier is added to the first biological treatment tank 1, the shape of the carrier is arbitrary, such as a sphere, a pellet, a hollow cylinder, a seal, a plate, etc., to be. In addition, the material of the carrier is arbitrary such as a natural material, an inorganic material, and a polymer material, and a gel-like material can be used. Further, when the filling rate of the carrier to be added to the first biological treatment tank 1 is high, no dispersed microorganisms are produced, and bacteria adhere to the carrier or proliferate of filamentous bacteria. Therefore, by setting the filling rate of the carrier to be added to the first biological treatment tank 1 to 10% or less, preferably 5% or less, it becomes possible to produce dispersed bacteria which are not affected by the concentration fluctuation and are easy to predation.

The concentration of dissolved oxygen (DO) in the first biological treatment tank 1 can be controlled to 1 mg / L or less, preferably 0.5 mg / L or less, thereby suppressing the growth of marsupial bacteria.

When the soluble organic matter is completely decomposed in the first biological treatment tank 1, flocs are not formed in the second biological treatment tank 2, and nutrients for animal animal breeding are also insufficient, so that only sludge with low compostability Right-burned biological treatment group. Therefore, it is preferable that the decomposition ratio of the organic component in the first biological treatment tank 1 is 95% or less, preferably 85 to 90%, instead of 100%.

The treated water (first biological treatment water) in the first biological treatment tank 1 is passed to the second biological treatment tank 2 in the subsequent stage, where the oxidative decomposition of remaining organic components, And the excess sludge is reduced by predation of animalcules.

In the second biological treatment tank 2, since the action of the animalcules with a slower growth rate and the autolysis of the bacteria are used as compared with the bacteria, the operation conditions for allowing the animalcules and the bacteria to stay in the system, . Therefore, it is preferable to use an activated sludge method or a membrane separation activated sludge method in which sludge is transported to the second biological treatment tank 2. The second biological treatment tank 2 may have two or more stages of multi-stage construction.

In the first invention, the animal-animal holding carrier (22) is provided in the second biological treatment tank (2) to increase the holding amount of the animalcules in the tank.

The shape of the carrier 22 provided in the second biological treatment tank 2 is arbitrary such as a spherical shape, a pellet shape, a hollow cylindrical shape, a thread shape, etc., in the case of a fluidized bed, and a diameter of about 0.1 to 10 mm . A fixed bed may be used. In this case, the shape of the carrier 22 is arbitrary such as a thread shape, a plate shape, and the like. The material of the carrier 22 is arbitrary such as a natural material, an inorganic material, and a polymer material, and a gel material can be used.

In the second biological treatment tank 2, the filling rate of the carrier to be added varies from 0.5 to 40%, depending on the type and material of the fluidized bed and fixed bed, because a large amount of foundation for holding the animalcules is required. .

In addition, as described above, in the second biological treatment tank 2, not only the filtration predators of the filtration predators, which predominate in the dispersed cells, but also the agglomerate predators which can predose the floc sludge are also proliferated. In the latter case, the flock is swallowed while swimming, so that when it is prioritized, the sludge is dirty and the sludge is scattered with the fine flock pieces. With such flock pieces, the concentration of treated water SS increases in the activated sludge of the settling terrain type, and the film becomes clogged in the membrane activated sludge. Therefore, in the first invention, an anoxic tank (4) is provided, and the sludge discharged from the second biological treatment tank (2) is allowed to stay in the anoxic tank (4) for a predetermined time to inhibit the proliferation of the swimming animal. do. In this case, since the animal-animal support carrier 22 is provided in the second biological treatment tank 2, and the filtrate-predation type animalcules are fixed on the support 22 side, they are taken out of the second biological treatment tank 2, (4), and therefore, the proliferation of the filtration predator-type animalcules is not inhibited. The sludge which has been taken out of the second biological treatment tank 2 and treated in the anoxic tank 4 is returned to the second biological treatment tank 2.

The amount of the sludge discharged from the second biological treatment tank 2 to the anoxic tank 4 and the residence time of the sludge in the anoxic tank 4 are appropriately determined in accordance with the treatment conditions. Normally, the amount of sludge to be drained is 1/30 Day / day, and the residence time of the sludge in the anoxic tank (4) is not less than 0.5 hour.

In the first invention, the anoxic tank (4) inhibits the proliferation of animalcules, and therefore it is necessary to set the ORP to 0 mV or lower. Therefore, in the anoxic tank (4), aeration is not performed, and it is preferable to perform only mechanical stirring. Further, in order to accelerate the lowering of the ORP, the first biological treatment water and the raw water can be passed through and the ORP can be lowered by an acid generation reaction or a denitrification reaction.

 In addition, a carrier may be added to the anoxic tank 4 in order to stably progress the ORP reduction (denitrification reaction, acid production reaction) in the anoxic tank 4. When the ORP in the anoxic tank 4 is low, the decrease in the activity of the swimming microorganism is promoted, so that the residence time of the second biological treatment tank sludge in the anoxic tank 4 can be shortened and the size of the anoxic tank 4 can be reduced . The shape of the carrier to be added is arbitrary in the form of a sphere, a pellet, a hollow cylinder or a thread in the case of a fluidized bed, and a size of 0.1 to 10 mm or so is arbitrary. A fixed bed can be used. In this case, the shape of the carrier 22 is arbitrary such as a thread shape, a plate shape and the like. In addition, any material such as a natural material, an inorganic material, and a polymer material may be used for the material, and a gel material may be used.

When the carrier is added to the anoxic tank 4, the filling rate is preferably from 0.5 to 40%, though the filling rate differs depending on the type of material in the fluidized bed and the fixed bed.

In such a second biological treatment tank 2, the sludge is periodically changed, that is, the SRT (solids retention time) is set to 60 days or less, preferably 45 days or less, more preferably 45 days or less, It is preferable to control it constantly within a range of 10 days to 45 days. However, when the sludge concentration (MLSS) in the second biological treatment tank 2 is 2000 mg / L or less, the SRT can be set to 60 days. Here, SRT = (the amount of the sludge in the sludge concentration X in the aeration tank) ÷ (the amount of sludge discharged from the sludge concentration X 1 per day), and the sludge concentration MLSS indicates the suspended sludge concentration.

In the first invention, when a large amount of organic matter remains in the first biological treatment water supplied to the second biological treatment tank 2, the oxidative decomposition is carried out in the subsequent treatment tank. When oxidative degradation of organic matter by bacteria occurs in the second biological treatment tank 2 in which a large number of animalcules are present, it is known that as a countermeasure to avoid predation of animalcules, it proliferates in a form difficult to predation, One bacterial group is not predated by animalcules, and decomposition thereof is dependent on self-extinguishing only, so that the effect of reducing the sludge generation amount is lowered. Therefore, as described above, in the first biological treatment tank, it is necessary to decompose most of the organic matter, that is, 70% or more, preferably 80% or more of the raw water BOD, into bacterial cells. Therefore, it is preferable to operate at 0.25 to 0.50 kg-BOD / kg-MLSS / d as the sludge load due to the soluble BOD in the downstream biological treatment tank. Again, MLSS refers to the concentration of suspended sludge and does not include the sludge of carrier attachment.

1, the treated water from the second biological treatment tank 2 is subjected to solid-liquid separation with sludge and treated water in the sedimentation tank 3, the separated water is taken out as treated water, and a part of the separated sludge is returned to the second Is returned to the biological treatment tank (2), and the remainder is discharged as excess sludge out of the system.

Further, instead of such a settling tank 3, a membrane separation device can be used as the solid-liquid separation means. Conventionally, in the membrane separation treatment of activated sludge, the problem of flux deterioration and chemical cleaning due to clogging of membranes has been a problem. However, according to the present invention, it is possible to prevent the sporadic sludge from being dispersed, .

In the embodiment shown in Fig. 2, a part of the first biological treatment treated water from the first biological treatment tank 1, for example, about 10 to 20% is introduced into the anoxic tank 4, 1 in that it is introduced into the treatment tank 2, and the other structures are the same. As described above, by introducing a part of the first biological treatment tidal water into the anoxic tank 4, the ORP of the anoxic tank 4 can be lowered and the effect of inhibiting the proliferation of the animalcules in the anoxic tank 4 can be enhanced.

The embodiment shown in Fig. 3 differs from the embodiment shown in Fig. 1 in that a part of raw water, for example, about 10 to 20% is directly introduced into the anoxic tank 4 and the remainder is introduced into the first biological treatment tank 1 And the others have the same configuration. As described above, by introducing a part of the raw water into the anoxic tank 4, the ORP of the anoxic tank 4 can be lowered and the effect of inhibiting the proliferation of the animalcules in the anoxic tank 4 can be enhanced.

4, the membrane separation apparatus 5 is used in place of the settling tank 3, the permeated water in the membrane separation apparatus 5 is taken out as treated water, and the concentrated water is introduced into the second biological treatment tank 2, And the excess sludge is taken out directly from the second biological treatment tank 2. The rest of the structure is the same as that of the embodiment shown in Fig. As described above, in the case of using the membrane separation device 5 as the solid-liquid separation means, according to the first invention, since the proliferation of the aggregate predator type small animal is suppressed, the problem of clogging of the membrane as in the conventional membrane separation treatment of activated sludge And the film flux can be stabilized, and the frequency of chemical cleaning can be reduced.

The embodiment shown in Fig. 5 differs from the embodiment shown in Fig. 1 in that a carrier 42 is added to the anoxic tank 4, and the other configuration is the same. As described above, by adding the carrier to the anoxic tank 4, the ORP of the anoxic tank 4 can be lowered and the effect of inhibiting the proliferation of the animalcules in the anoxic tank 4 can be enhanced.

1 to 5 illustrate an embodiment of the first invention, and the invention is not limited to the first invention. For example, the first biological treatment tank and the second biological treatment tank can have a multi-stage structure having two or more stages as described above, and therefore, the biological treatment tank can be provided in three or more stages in the first invention.

As the solid-liquid separating means, a membrane separating device, a floatation separating tank or the like can be used in addition to the sedimentation tank, and the membrane treating tank of the downstream stage is subjected to a membrane separation type exhalation treatment with a membrane submerged biological treatment tank serving also as a biological treatment tank and a solid- It is possible.

According to the first aspect of the present invention, the animal-animal support carrier is provided in the biological treatment tank after the second biological treatment tank, and the biological treatment tank sludge after the second biological treatment tank is treated in the anoxic tank, The priority of the animal can be suppressed, and both the sludge reduction and the improvement of the treated water quality can be achieved.

[Second invention]

6 to 8 are schematic diagrams showing embodiments of a biological treatment method and apparatus for organic wastewater according to the second invention.

6 to 8, reference numeral 1 denotes a first biological treatment tank, reference numeral 2 denotes a second biological treatment tank, reference numeral 4 denotes an anoxic tank, reference numeral 5 denotes a membrane separation device, (Scattering tube), 22 denotes a animal-animal holding carrier, and 41 denotes a stirring means, and members having the same functions in FIGS. 6 to 8 are denoted by the same reference numerals.

In the embodiment of Fig. 6, the raw water (organic wastewater) is introduced into the first biological treatment tank 1 and is separated into 70% or more of the organic component (soluble BOD) by dissociable bacteria (non-coagulating bacteria) % Or more, and more preferably 90% or more. The pH of the first biological treatment tank 1 is set to 6 or more, preferably 8 or less. However, if the raw water contains a large amount of oil, the pH may be 8 or more.

The BOD volume load of the first biological treatment tank 1 is 1 kg / m ³ / d or more, for example, 1 to 20 kg / m 2 ³ / d and the HRT (raw water retention time) is 24 h or less, preferably 8 h or less, for example, 0.5 to 8 h, the treated water in which the dispersing bacteria are ignited can be obtained, The waste water having a low BOD concentration can be treated at a high load.

A part of the sludge from the downstream biological treatment tank is conveyed to the first biological treatment tank 1, or two or more multi-stage structures of the first biological treatment tank 1 are added, or a carrier is added, A load of 5 kg / m ³ / d or more can be processed.

When the carrier is added to the first biological treatment tank 1, the shape of the carrier is arbitrary, such as a sphere, pellet, hollow cylindrical shape, thread shape, plate shape, etc., It is arbitrary. The carrier material may be any of natural materials, inorganic materials, polymer materials, and the like, and a gel material may be used. Further, when the filling rate of the carrier to be added to the first biological treatment tank 1 is high, no dispersed microorganisms are produced, and the microorganisms adhere to the carrier, or mossy bacteria multiply. Therefore, when the filling rate of the carrier to be added to the first biological treatment tank 1 is 20% or less, preferably 10% or less, it is possible to generate dispersed bacteria easily predominantly affected by the concentration fluctuation.

 In this first biological treatment tank 1, the concentration of dissolved oxygen (DO) is set to 1 mg / L or less, preferably 0.5 mg / L or less, so that the propagation of marsupial bacteria can be suppressed.

When the soluble organic matter is completely decomposed in the first biological treatment tank 1, no flocs are formed in the second biological treatment tank 2, and only nutrients for animal animal breeding are insufficient, so that only sludge with low compostability Is the right-handed biological treatment tank. Therefore, it is preferable that the decomposition ratio of the organic component in the first biological treatment tank 1 is 95% or less, preferably 85 to 90%, instead of 100%.

The treated water (first biological treatment water) in the first biological treatment tank 1 is passed through the second biological treatment tank 2 in the subsequent stage, where the oxidative decomposition of remaining organic components, And the excess sludge is reduced by predation of animalcules.

In the second biological treatment tank 2, since the action of the animalcules with a slower propagation speed and the autolysis of the bacteria are used as compared with the bacteria, it is necessary to use operating conditions and treatment devices in which the animalcules and bacteria stay in the system. Therefore, in the second biological treatment tank 2, it is preferable to use an activated sludge method or a membrane separation activated sludge method in which sludge is transported. The second biological treatment tank 2 may have two or more stages of multi-stage construction. In the case of the membrane separation activated sludge method, the membrane separation device can be both in the tank type and the tank outer shape. However, by using the outer shape, it is possible to prevent the clogging of the membrane due to the dispersed bacteria, .

In the second invention, by providing the animal-animal holding carrier (22) in the second biological treatment tank (2), it is possible to effectively feed the animalcules, especially the dispersed bacteria, and to improve the solid-liquid separation of the sludge, Thereby increasing the amount of the filtrate-rich animalcules retained in the bath.

In other words, in the second biological treatment tank 2, not only the filtration predators of the filtration predators which predominate in the dispersed cells but also the agglomerate predators which can predose the flooded sludge are also proliferated. The latter predates flocking while swimming, so if it is prioritized, the sludge will be dirty and become a sludge with scattered flock pieces. This flock piece causes clogging of the membrane in the membrane separation activated sludge method. Therefore, in the second invention, the sludge of the second biological treatment tank 2 is periodically changed, that is, the SRT (solid retention time) is preferably 60 days or less, more preferably, 45 days or less, more preferably 10 days or more and 45 days or less. However, when the sludge concentration (MLSS) in the second biological treatment tank 2 is 2000 mg / L or less, the SRT may be 60 days. Here, SRT = (the amount of the sludge in the sludge concentration X in the aeration tank) ÷ (the amount of sludge discharged from the sludge concentration X 1 per day), and the sludge concentration MLSS indicates the suspended sludge concentration.

Then, the animal-animal holding carrier 22 is installed in the second biological treatment tank 2 in order to keep the filtration-trapped animalcules predating the dispersed cells in the second biological treatment tank 2. That is, this kind of animalcules is fixed to the sludge flocs and is maintained in the system, but since the sludge is taken out of the system with a constant residence time, it is necessary to supply the source in the system. At this time, if the carrier is a granular or angular fluidized bed, it can not be stably maintained at a high concentration by a shear force for flow, and the organic matter in the fluidized bed is completely treated to make the sludge flocs fine, Resulting in occlusion of the membrane.

Therefore, in the second invention, at least a part of the carrier other than the fluid carrier as the carrier to be provided in the second biological treatment tank 2 is fixed to the fixed carrier < RTI ID = 0.0 > . The shape of the carrier 22 in this case is arbitrary such as a shape of a thread, a shape of a plate, and a shape of a rectangle. The material of the carrier 22 is arbitrary such as a natural material, an inorganic material, and a polymer material, and a gel material can be used. Preferably, the porous urethane foam is formed in a plate shape or a rectangular shape having a thickness of, for example, 100 to 400 cm X 50 to 200 cm X 0.5 to 5 cm, and is preferably provided at a position where it is not exposed to aeration air.

In the second biological treatment tank 2, a large amount of foundation for holding the animalcules is required. However, if the filling rate of the carrier is excessively large, insufficient mixing in the tank and sludge spoilage occur, It is preferably about 0.1 to 20%.

In the second invention, when a large amount of organic matter remains in the first biological treatment water to be supplied to the second biological treatment tank (2), the oxidative decomposition is carried out in the subsequent treatment tank. When oxidative degradation of organic matter by bacteria occurs in the second biological treatment tank 2 in which a large number of animalcules are present, it is known that as a countermeasure to avoid predation of animalcules, it proliferates in a form difficult to predation, One bacterial group is not predated by the animalcules, and decomposition thereof is dependent on self-extinguishing only, and the effect of reducing the sludge generation amount is lowered. Therefore, as described above, in the first biological treatment tank, it is necessary to decompose most of the organic matter, that is, 70% or more, preferably 80% or more of the raw water BOD, into bacterial cells. Therefore, it is preferable to operate at 0.25 to 0.50 kg-BOD / kg-MLSS / d as the sludge load due to the soluble BOD in the downstream biological treatment tank. Here again, MLSS refers to the concentration of suspended sludge and does not include the sludge of the carrier attachment.

6, the treated water from the second biological treatment tank 2 is fed to the membrane separating device 5 of the crude outer shape, the permeated water of the membrane separating device 5 is taken out as treated water, And the excess sludge is taken out directly from the second biological treatment tank 2. [0050] In the case of using the membrane separation device 5 as the solid-liquid separation means as described above, according to the second invention, since the propagation of the flocculation-type small animal is suppressed, the problem of clogging of the membrane as in the conventional membrane separation treatment of activated sludge is alleviated , It is possible to stabilize the membrane flux to reduce the cleaning frequency of the chemical agent and to prevent the sudden sludge from being dispersed and to facilitate the operation management of the membrane separation apparatus.

There is no particular limitation on the film-separating device 5 of the outer shape, and an ultrafiltration (UF) membrane separation device, a microfiltration (MF) membrane separation device, or the like can be used.

The embodiment shown in Fig. 7 is that the part of the raw water, for example, about 5 to 50%, is directly introduced into the second biological treatment tank 2 without going through the first biological treatment tank 1, And the other structures are the same. As described above, by introducing a part of the raw water directly into the second biological treatment tank 2, it is possible to avoid the load shortage of the second biological treatment tank at the time of changing the raw water (when the load is lowered).

8, a part of the sludge in the second biological treatment tank 2 for holding the animalcules is taken out, treated in the anoxic tank 4, and then returned to the anaerobic tank 4. In the embodiment shown in Fig. 8, And further suppressing the proliferation of the agglomerate predation type small animal to preferentially proliferate the filtrate-predation type small animal, and the other features are the same as those of the embodiment of Fig.

That is, the anoxic tank 4 is installed as described above, and the sludge discharged from the second biological treatment tank 2 is allowed to stay in the anoxic tank 4 for a predetermined time to inhibit the proliferation of swimming animals, thereby stabilizing the biological phase . In this case, the animal-animal support carrier 22 is provided in the second biological treatment tank 2, and the filtration-predominant type animalcules are maintained at a predetermined amount on the support 22 side, so that the proliferation of the filtration-predation type animalcules is not inhibited . The sludge which has been taken out of the second biological treatment tank 2 and treated in the anoxic tank 4 is returned to the second biological treatment tank 2.

The sludge amount extracted from the second biological treatment tank 2 to the anoxic tank 4 and the residence time of the sludge in the anoxic tank 4 are appropriately determined in accordance with the processing conditions, Day and the residence time of the sludge in the anoxic tank 4 is preferably 0.5 hour or more.

In the second invention, the anoxic tank (4) inhibits the proliferation of animalcules, and thus the ORP needs to be 0 mV or lower. Therefore, in the anoxic tank (4), aeration is not performed, and it is preferable that only mechanical stirring is performed. Further, in order to accelerate the lowering of the ORP, a part of the first biological treatment water and the raw water may be passed through, and the ORP may be lowered by acid generation reaction or denitrification.

 In addition, a carrier may be added to the anoxic tank 4 to stably progress the ORP reduction (denitrification reaction, acid production reaction) in the anoxic tank 4. When the ORP in the anoxic tank 4 is low, the decrease in the activity of the swimming microorganism is promoted, so that the residence time of the second biological treatment tank sludge in the anoxic tank 4 can be shortened and the size of the anoxic tank 4 can be reduced . The shape of the carrier to be added is arbitrary in the form of a sphere, a pellet, a hollow cylinder or a thread in the case of a fluidized bed, and a size of 0.1 to 10 mm is arbitrary. A fixed bed can be used. In this case, the shape of the carrier 22 is arbitrary such as a thread shape, a plate shape and the like. In addition, any material such as a natural material, an inorganic material, a polymer material, and the like may be used for the material.

When the carrier is added to the anoxic tank 4, the filling rate is preferably from 0.5 to 40%, though the filling rate differs depending on the type of material in the fluidized bed and the fixed bed.

Figs. 6 to 8 show an example of an embodiment of the second invention, and the second invention is not limited to that shown in Figs. For example, the first biological treatment tank and the second biological treatment tank can have a multi-stage structure of two or more stages as described above, and thus, the biological treatment tank can be provided in three or more stages in the second invention.

According to the second aspect of the present invention, in the second aspect of the present invention, the animal-animal support carrier is provided in the biological treatment tank after the second biological treatment tank to reduce priority of the flocculated animalcules, By separating the biologically treated water after the second biological treatment tank from the membrane separation device by solid-liquid separation, it is possible to prevent clogging of the membrane of the membrane separation device and to perform stable high load treatment.

[Example]

Hereinafter, the present invention will be described in more detail with reference to Examples and Comparative Examples.

Examples of the first invention and comparative example]

[Example I-1]

As shown in Fig. 1, a first biological treatment tank 1 having a capacity of 3.6 L, a second biological treatment tank 2 having a capacity of 15 L, an anoxic tank 4 having a capacity of 5 L, And organic wastewater according to the present invention was treated by using an experimental apparatus in which a settling tank 3 was connected. The raw water contains a population substrate of COD _Cr : 1000 mg / L and BOD: 640 mg / L.

The treatment conditions of each biological treatment tank were as follows.

≪ First biological treatment tank &

DO: 0.5 mg / L

BOD volume load: 3.85kg-BOD / m ³ / d

HRT: 4h

pH: 7.0

<Second biological treatment tank>

DO: 4 mg / L

Carrier packing rate: 2%

HRT: 17h

SRT: 30 days

pH: 7.0

<Anoxic tank>

ORP: -100mV

HRT (= SRT): 12h

As the carrier 12 of the second biological treatment tank 2, a plate-like polyurethane foam was used.

Further, the BOD volume load across the entire apparatus was 0.75 kg-BOD / m ³ / d, and the HRT throughout the apparatus was 21 h.

As a result, the sludge floc and the carrier in the second biological treatment tank 2 were preferentially filtered and fixed to the filtration predator type animal (ladybug, sandworm), and the sludge conversion rate was 0.1 kg-MLSS / kg-COD _Cr . The treated water (solid-liquid separated water in the sedimentation tank 4) remained in good condition at all times during the test period, with an SS concentration of less than 10 mg / L and a soluble COD _Cr concentration of less than 30 mg / L.

 [Example I-2]

A treatment was carried out under the same conditions as in Example I-1, except that the experimental equipment shown in Fig. 4 was used by using a UF membrane as a membrane separation device instead of the sedimentation tank. The water quality of the raw water, the treatment conditions of the first and second biological treatment tanks and the anoxic tank, and the total BOD volume load and HRT are the same as in Example I-1.

As a result, the sludge floc and the carrier in the second biological treatment tank were preferentially filtered and the sludge conversion rate was 0.075 kg-MLSS / kg-COD _Cr .

The treated water (permeated water of the membrane separator) remained in good condition at all times during the test period because the soluble COD _Cr concentration was less than 20 mg / L. In addition, there was almost no increase in intermembrane pressure difference, and a stable flux could be maintained without washing the chemical for one month or more.

[Comparative Example I-1]

The anoxic tank was omitted and treated in the same manner as in Example I-1, except that no carrier was provided in the second biological treatment tank.

The water quality of the raw water, the treatment conditions of the first and second biological treatment tanks, and the total BOD volume load and HRT are the same as in Example I-1.

As a result, the sludge conversion rate was 0.13 kg-MLSS / kg-COD _Cr . However, the aggregate predator-type animalcules (axilla) were preferentially administered at intervals of one month, while the concentrations of treated water SS and soluble COD _Cr increased to 80 mg / L and 150 mg / L, respectively.

 [Comparative Example I-2]

The anoxic tank was omitted and the same treatment as in Example I-2 was carried out except that no carrier was provided in the second biological treatment tank.

The water quality of the raw water, the treatment conditions of the first and second biological treatment tanks, and the total BOD volume load and HRT are the same as in Example I-1.

As a result, the sludge conversion rate became 0.12 kg-MLSS / kg-COD _Cr . However, at the interval of one month, the agglomerate predator-type small animal (water-repellant) was prioritized, and the intermembrane pressure increased frequently during this period, and the chemical cleaning of the membrane was required once for two weeks through the test period.

[Examples of the second invention and comparative example]

[Example II-1]

As shown in Fig. 6, using an experimental apparatus in which a first biological treatment tank 1 having a capacity of 3.6 L, a second biological treatment tank 2 having a capacity of 15 L, and a UF membrane separation apparatus 5 were connected And the organic wastewater according to the present invention was treated. The raw water contains a population substrate of COD _Cr : 1000 mg / L and BOD: 640 mg / L.

The treatment conditions of each biological treatment tank were as follows.

&Lt; First biological treatment tank &

DO: 0.5 mg / L

BOD volume load: 3.85kg-BOD / m ³ / d

HRT: 4h

pH: 7.0

<Second biological treatment tank>

DO: 4 mg / L

Carrier packing rate: 2%

HRT: 17h

SRT: 30 days

pH: 7.0

A plate-shaped polyurethane foam (15 mm x 300 mm x 50 mm / one piece) is used as the carrier 12 of the second biological treatment tank 2 and a position symmetrical with respect to the vertical plane of the center of the tank The bottom and the left and right sides were fixed to the wall surface of the jaw.

Further, the BOD volume load across the entire apparatus was 0.75 kg-BOD / m ³ / d, and the HRT throughout the apparatus was 21 h.

As a result, the sludge floc and the carrier in the second biological treatment tank 2 were preferentially filtered and fixed to the filtration predator type animal (ladybug and sandworm), and the sludge conversion rate was 0.1 kg-MLSS / kg-COD _Cr .

The treated water (permeated water of the membrane separator 5) had a soluble COD _Cr concentration of less than 20 mg / L and remained in good condition at all times during the test period.

In addition, there was almost no increase in the pressure difference between membranes of the membrane separator 5, and a stable flux could be maintained without performing chemical cleaning for one month or more.

 [Comparative Example II-1]

The first biological treatment tank was omitted, the capacity of the second biological treatment tank was set to 18.6 L, and a carrier was not provided in the second biological treatment tank.

The water quality of the raw water, DO and pH of the second biological treatment tank, total BOD volume load and HRT are the same as in Example II-1.

As a result, the sludge conversion rate was 0.20 kg-MLSS / kg-COD _Cr . However, at intervals of one month, the agglomerate predator-type small animal (water-repellant) was prioritized, and in the meantime, the chemical cleaning of the membrane was required once every two weeks due to an increase in the inter-membrane pressure difference. Also, the treated water quality deteriorated, and the soluble COD _Cr concentration rose to 70 mg / L or more.

[Example II-2]

As shown in Fig. 8, an anoxic tank 4 having a capacity of 5 L is installed, the sludge in the second biological treatment tank 2 is removed, the treated water is treated in the anoxic tank 4, Except that it was allowed to convey. The water quality of the raw water, the treatment conditions of the first and second biological treatment tanks, and the total BOD volume load and HRT are the same as in Example II-1.

The treatment conditions of the anoxic tank (4) were as follows.

<Anoxic tank>

ORP: -100mV

HRT (= SRT): 12h

As a result, the sludge floc and the carrier in the second biological treatment tank were preferentially filtered and the sludge conversion rate was 0.075 kg-MLSS / kg-COD _Cr .

The water quality of the treated water was such that the soluble COD _Cr concentration was less than 20 mg / L and remained always good during the test period. Further, there was almost no increase in the inter-membrane pressure difference, and a stable flux could be maintained even if the chemical cleaning was not performed for one month or more.

[Industrial applicability]

The biological treatment method and apparatus for organic wastewater according to the present invention can be used for organic wastewater treatment in a wide concentration range including domestic wastewater, sewage, food factory or pulp mill.

While the invention has been described in detail with reference to specific embodiments thereof, it will be apparent to those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention.

This application is based on Japanese patent application (Japanese Patent Application No. 2010-083136) filed on March 31, 2010, Japanese Patent Application (Japanese Patent Application No. 2010-164087) filed on July 21, 2010, (Japanese Patent Application No. 2011-044797) filed on March 2, 2011 and Japanese Patent Application (Japanese Patent Application No. 2011-044798) filed on March 2, 2011, all of which are incorporated by reference.

1 First biological treatment tank
2 Second biological treatment tank
3 sedimentation tank
4 anoxic tank
5 membrane separator

Claims (8)

The biological wastewater is introduced into the first biological treatment tank of the aerobic biological treatment tank provided in two or more stages and subjected to biological treatment by bacteria and the first biological treatment water containing the bacteria in the dispersed state from the first biological treatment tank is treated as the second biological A biological treatment method for organic wastewater, comprising the steps of passing a biological treatment tank through a biological treatment tank after the treatment tank, and subjecting the treated water of the biological treatment tank after the second biological treatment tank to solid-
A carrier for holding the animalcules is provided in the biological treatment tank after the second biological treatment tank,
Liquid separation of the treated water of the biological treatment tank after the second biological treatment tank is performed by a membrane separation treatment,
The membrane separation process was carried out by using an outer tank type (tank-off type)
Wherein the carrier provided in the biological treatment tank after the second biological treatment tank is fixed to the bottom surface, the side surface, or the upper surface of the biological treatment tank. The method according to claim 1,
Wherein a part of the organic wastewater is introduced into the biological treatment tank after the second biological treatment tank without going through the first biological treatment tank. 3. The method according to claim 1 or 2,
Wherein the sludge is removed so that the SRT (solid retention time) of the biological treatment tank after the second biological treatment tank is 60 days or less. 3. The method according to claim 1 or 2,
A part of the sludge in the biological treatment tank after the second biological treatment tank is taken out and treated in the anoxic tank, and then the biological treatment tank is returned to the biological treatment tank after the second biological treatment tank. Wherein the biological treatment tank is provided with two or more tiered aerobic biological treatment tanks, and organic wastewater is introduced into the first biological treatment tank and subjected to biological treatment with bacteria, and the first biological treatment water To the biological treatment tank after the second biological treatment tank for biological treatment, and the treated water of the biological treatment tank after the second biological treatment tank is solid-liquid separated.
A carrier for holding the animalcules is provided in the biological treatment tank after the second biological treatment tank,
And a membrane separation processing device as a solid-liquid separation means of the treated water of the biological treatment tank after the second biological treatment tank,
The membrane separation process was performed with a crude outer membrane separator,
Wherein the carrier provided in the biological treatment tank after the second biological treatment tank is fixed to a bottom surface, a side surface, or an upper surface of the biological treatment tank. 6. The method of claim 5,
And means for introducing a part of the organic wastewater into the biological treatment tank after the second biological treatment tank without going through the first biological treatment tank. The method according to claim 5 or 6,
And the sludge is taken out so that the SRT (solid retention time) of the biological treatment tank after the second biological treatment tank is 60 days or less. The method according to claim 5 or 6,
Wherein an anoxic tank for removing a part of sludge in the biological treatment tank after the second biological treatment tank and treating the same is transported to the biological treatment tank after the second biological treatment tank.

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