JP5894857B2 - Waste water treatment apparatus and waste water treatment method - Google Patents

Description

  The present invention relates to a wastewater treatment apparatus and a wastewater treatment method, and more particularly to a wastewater treatment apparatus and a wastewater treatment method for purifying wastewater under anaerobic conditions using a carrier holding microorganisms.

  For example, wastewater treatment that purifies wastewater under anaerobic conditions using a carrier holding microorganisms includes denitrification treatment of wastewater containing nitric acid or nitrous acid, and anaerobic ammonia of wastewater containing ammonia and nitrous acid Examples include oxidation treatment and methane fermentation treatment of organic wastewater.

  Of these, methane fermentation treatment of organic wastewater produces flammable methane, a greenhouse gas, and toxic gas, hydrogen sulfide, etc., so the anaerobic reaction tank is sealed and the generated gas is collected. It needs to be handled appropriately. For example, the generated gas is passed through a desulfurizing agent to remove hydrogen sulfide and the like, and then burned. If necessary, heat recovery is performed by a boiler.

  Further, when waste water is treated in an anaerobic reaction tank using a carrier, for example, the carrier is separated from the treated water using a screen or the like, but the screen may be clogged.

  For example, in Patent Document 1, a draft tube that is vertically installed inside a reaction tank that stores a carrier and that opens upward and downward forms a downward flow in the draft tube, and between the draft tube and the inner wall surface of the reaction tank. Provided as an output adjusting means for adjusting the impeller device that forms the upward flow and the impeller device output that suppresses the region where the carrier rising with the upward flow by the impeller device is substantially below the upper end of the draft tube There has been proposed an apparatus that has an inverter for changing the rotation speed of an impeller device, and that separates the carrier by a screen that separates the carrier installed in the upper part of the reaction vessel. In Patent Document 1, it is proposed that the presence rate of the carrier in the vicinity of the screen is reduced and the clogging of the screen is suppressed by adjusting the interface of the carrier.

  Patent Document 2 proposes an apparatus including a screen in a reaction tank, a guide plate that forms a flow path, and a nitrogen gas jetting unit that jets nitrogen gas from below the screen.

  In the devices of Patent Document 1 and Patent Document 2, clogging of the screen can be suppressed to some extent, but in long-term operation, foreign matters flowing from raw water, microbial mass that has grown, carriers and partial carriers are crushed. It is difficult to avoid clogging due to damaged materials. Further, the carrier may flow out due to a partial breakage of the screen.

  When the screen is clogged, it is effective to wash from the upper part of the tank with high-pressure water or a brush. In addition, it is necessary to open the top of the screen for maintenance work such as repairs. However, as described above, in particular, in methane fermentation treatment of organic wastewater, flammable and greenhouse gas such as methane and toxic gas such as hydrogen sulfide are generated. It is necessary to take measures such as stopping the treatment and sufficiently replacing the gas inside the tank, and a very complicated and dangerous work occurs.

  On the other hand, Patent Document 3 proposes an apparatus in which treated water containing a carrier is passed through a carrier separator having a guide plate and a baffle plate, the carrier is settled and separated, and then returned to the reaction tank.

  In the apparatus of Patent Document 3, the apparent specific gravity increases due to the attachment and retention of microorganisms, and thus the carrier tends to be deposited on the bottom. On the other hand, in the denitrification treatment, nitrogen gas is used, and in methane fermentation treatment, methane gas is used. Since the apparent specific gravity is reduced inside the carrier, there is a concern that the carrier floats on the liquid surface or stays. That is, the change in the apparent specific gravity of the carrier is large and is substantially unpredictable. Patent Document 3 assumes that the carrier is separated by settling, but it is not assumed that the carrier is reduced in specific gravity or floats as described above, and it is difficult to separate the carrier having lowered sedimentation. is there.

Japanese Patent No. 4544583 JP 2008-194620 A Japanese Patent No. 3796029

  An object of the present invention is to provide a wastewater treatment apparatus and a wastewater treatment method capable of easily maintaining a screen for separating a carrier in wastewater treatment for purifying wastewater under anaerobic conditions using a carrier holding microorganisms. It is to provide.

The present invention is a wastewater treatment apparatus for purifying wastewater under anaerobic conditions using a carrier holding microorganisms, the anaerobic reaction tank for storing the carrier and performing anaerobic reaction; and the anaerobic reaction tank A draft tube that is vertically installed in the inside and has an upper and lower opening; an impeller device that forms a downward flow in the draft tube and forms an upward flow between the draft tube and the inner wall surface of the anaerobic reaction tank A wastewater treatment apparatus comprising: a screen for receiving anaerobic treated water by the anaerobic reaction and separating the carrier; and a screen tank having a diffuser for aspirating oxygen-containing gas in the tank.

Further, in the wastewater treatment apparatus, pH adjustment means for adjusting the pH in the screen tank, and pH adjustment for returning the pH adjusted water adjusted by the pH adjustment means to the anaerobic reaction tank or the previous stage of the anaerobic reaction tank And a water return means. The present invention is also a wastewater treatment apparatus for purifying wastewater under anaerobic conditions using a carrier holding microorganisms, the anaerobic reaction tank for storing the carrier and performing anaerobic reaction; A screen tank having a screen for receiving anaerobic treated water by reaction and separating the carrier; and an air diffuser for diffusing an oxygen-containing gas in the tank; pH adjusting means for adjusting the pH in the screen tank And a pH-adjusted water returning means for returning the pH-adjusted water adjusted by the pH adjusting means to the anaerobic reaction tank or the previous stage of the anaerobic reaction tank.

  The waste water treatment apparatus preferably includes a carrier returning means for returning the carrier separated in the screen tank to the anaerobic reaction tank or a front stage of the anaerobic reaction tank.

Further, the present invention is a wastewater treatment method for purifying wastewater under anaerobic conditions using a carrier holding microorganisms, an anaerobic reaction step of performing an anaerobic reaction using the carrier in an anaerobic reaction tank, in the anaerobic reaction screen tank to accept the anaerobic treatment water by, and aeration oxygen-containing gas, see containing and a carrier separation step of separating the carrier by a screen, the anaerobic reaction vessel, the interior of the anaerobic reactor A draft tube installed vertically at the top and bottom, and an impeller device that forms a downward flow in the draft tube and forms an upward flow between the draft tube and the inner wall surface of the anaerobic reaction tank. A wastewater treatment method provided .

Further, in the wastewater treatment method, a pH adjustment step for adjusting the pH in the screen tank, and a pH adjustment for returning the pH-adjusted water adjusted in the pH adjustment step to the anaerobic reaction tank or the previous stage of the anaerobic reaction tank And a water return step. Further, the present invention is a wastewater treatment method for purifying wastewater under anaerobic conditions using a carrier holding microorganisms, an anaerobic reaction step of performing an anaerobic reaction using the carrier in an anaerobic reaction tank, In a screen tank that receives anaerobic treated water by the anaerobic reaction, an oxygen-containing gas is diffused, and a carrier separation process for separating the carrier by a screen; a pH adjustment process for adjusting the pH in the screen tank; and the pH And a pH-adjusted water returning step of returning the pH-adjusted water adjusted in the adjusting step to the anaerobic reaction tank or the preceding stage of the anaerobic reaction tank.

  The waste water treatment method preferably includes a carrier returning step of returning the carrier separated in the screen tank to the anaerobic reaction tank or the previous stage of the anaerobic reaction tank.

  According to the present invention, separately from the anaerobic reaction tank, a screen tank provided with a screen for receiving anaerobic treated water by an anaerobic reaction and separating the carrier, and an air diffuser for diffusing oxygen-containing gas in the tank. By providing the above, it is possible to provide a wastewater treatment apparatus and a wastewater treatment method capable of easily performing screen maintenance.

It is a schematic block diagram which shows an example of the waste water treatment equipment which concerns on embodiment of this invention.

  Embodiments of the present invention will be described below. This embodiment is an example for carrying out the present invention, and the present invention is not limited to this embodiment.

  An outline of an example of a wastewater treatment apparatus according to an embodiment of the present invention is shown in FIG. The wastewater treatment apparatus 1 is a wastewater treatment apparatus that purifies wastewater under anaerobic conditions using a carrier holding microorganisms. The wastewater treatment apparatus 1 stores a carrier 24, an anaerobic reaction tank 10 whose upper part is sealed and substantially blocked from outside air, and a screen for receiving anaerobic treated water in the anaerobic reaction tank 10 and separating the carrier. 16 and a screen tank 12 having an air diffuser 18 as an air diffuser for diffusing an oxygen-containing gas into the tank from below the screen 16. The wastewater treatment apparatus 1 may include a pH adjusting unit that adjusts the pH in the screen tank 12, and the pH adjusted water adjusted by the pH adjusting unit is returned to the anaerobic reaction tank 10 or the previous stage of the anaerobic reaction tank 10. A pump 28 may be provided as the adjustment water returning means. In the wastewater treatment apparatus 1, the pump 28 may function as a carrier returning means that returns the carrier separated in the screen tank 12 to the anaerobic reaction tank 10 or the previous stage of the anaerobic reaction tank 10. In addition, an adjustment tank (not shown) may be installed in the front stage of the anaerobic reaction tank 10.

  In the waste water treatment apparatus 1 of FIG. 1, the anaerobic treated water outlet 36 of the anaerobic reaction tank 10 and the inlet of the screen tank 12 are connected by an anaerobic treated water pipe 32. In the anaerobic reaction tank 10, a draft tube 14 that is installed substantially vertically inside the anaerobic reaction tank 10 and has an open top and bottom, and a downward flow is formed in the draft tube 14. The draft tube 14 and the anaerobic reaction tank 10 An impeller device 20 that forms an upward flow with the wall surface, and an inverter 22 for changing the rotation speed of the impeller device 20 provided as output adjusting means for adjusting the output of the impeller device 20 are installed. The impeller device 20 and the inverter 22 are connected by electrical connection means or the like. In addition, the structure of this anaerobic reaction tank 10 is an example, Comprising: It is not limited to this structure.

  A screen 16 is installed in the screen tank 12 so as to surround the treated water outlet, and an air diffuser 18 is installed below the screen 16. A pump 28 is installed in the screen tank 12, and the pump 28 is connected to the upper part of the anaerobic reaction tank 10 by a carrier return pipe 34. A guide plate 26 disposed substantially in parallel with the screen 16 may be provided between the air diffuser 18 and the pump 28. The screen tank 12 is provided with a pH measuring device 30 as a pH measuring means.

  The operation of the wastewater treatment method and the wastewater treatment apparatus 1 according to the present embodiment will be described.

  FIG. 1 shows the wastewater treatment apparatus 1 according to the present embodiment and the flow state of the carrier 24 during operation of the wastewater treatment apparatus 1. In the anaerobic reaction tank 10, a carrier 24 holding microorganisms is stored. Water to be treated (raw water) is introduced into the anaerobic reaction tank 10 from the inlet, and an anaerobic reaction is performed in the anaerobic reaction tank 10 using the carrier 24 (anaerobic reaction step). The anaerobic treated water after the anaerobic reaction flows from the anaerobic treated water outlet 36 through the anaerobic treated water pipe 32 to the screen tank 12 provided with the screen 16 for carrier separation. In the anaerobic reaction tank 10, most of the carrier 24 flows in a region below the anaerobic treated water outlet 36, and among them, at least a part of the floated carrier 24 goes to the screen tank 12 together with the anaerobic treated water. Inflow. In the screen tank 12, the carrier is separated by the screen 16 (carrier separation step) while the oxygen-containing gas is diffused by the air diffuser 18 to obtain treated water. The treated water is discharged from the outlet of the screen tank 12. On the other hand, the separated carrier may be returned by the pump 28 to the anaerobic reaction tank 10 or a preconditioner of the anaerobic reaction tank 10 through the carrier return pipe 34 (carrier return step).

  In the present embodiment, the screen tank 12 for separating the carrier by the screen 16 is provided separately from the anaerobic reaction tank 10 and further diffused (aerated) with an oxygen-containing gas, so that the screen 16 of the screen tank 12 can be used even in a water-flowing state. The upper part is opened, and maintenance work such as cleaning and repair can be performed safely and easily.

  Furthermore, even if residual gases such as methane and hydrogen sulfide are slightly dissolved in the waste water, the residual gas can be stripped or oxidized by the oxygen-containing gas, preventing the generation of off-flavors in the subsequent stage. Residual COD can be reduced.

  The anaerobic reaction tank 10 is provided with a draft tube 14 that is installed substantially vertically and has an open top and bottom. In the draft tube 14, a downward flow is formed in the draft tube 14, and the draft tube 14 is anaerobic. An impeller device 20 that forms an upward flow between the inner wall surface of the reaction tank 10 is provided.

  The region where the carrier 24 rising due to the upward flow generated by the operation of the impeller device 20 is present is, for example, substantially below the upper end of the draft tube 14 and below the anaerobic treated water outlet 36 so as to be suppressed. The device output is adjusted.

  Here, the upper end of the region where the carrier 24 is present may be detected using an interface detector such as an interface meter, and the output of the impeller device 20 may be adjusted based on the detection result.

  As a result, most of the carrier 24 is kept in a state of hardly flowing up to the vicinity of the liquid level of the anaerobic reaction tank 10 and kept in a state of hardly depositing at the bottom of the anaerobic reaction tank 10. Most of the carrier 24 is almost present in a predetermined region between the draft tube 14 and the inner wall surface of the anaerobic reaction tank 10 (that is, a region suppressed below the upper end of the draft tube 14). It flows in and contacts with the water to be treated.

  Then, a part of the carrier holding the bubbles (a carrier having a reduced apparent specific gravity) rises (floats) to the upper part of the anaerobic reaction tank 10 and is sucked and circulated from the upper end of the draft tube 14 when passing through the impeller device 20. Defoamed by the shearing force of That is, most of the carrier 24 flows in the specific region, and a part of the carrier that is desirably defoamed is sucked from the upper end of the draft tube 14 and efficiently defoamed by the shearing force when passing through the impeller device 20. The Therefore, when viewed from the total amount of the carrier, the frequency of the carrier passing through the impeller device 20 does not become too high, and the carrier is prevented from being excessively worn.

  According to this configuration, by suppressing the region where the carrier 24 is present below the anaerobic treated water outlet 36, a small part of the carrier that has floated and held air bubbles flows into the screen tank 12. .

  Here, for example, in the technique of the above-mentioned Patent Document 1, it is necessary to adjust the output of the impeller device so that the carrier interface is lowered so that the presence rate of the carrier near the screen is reduced. On the other hand, in this embodiment, since the screen tank 12 including the screen 16 is provided separately from the anaerobic reaction tank 10, the carrier interface in the anaerobic reaction tank 10 is at least below the anaerobic treated water outlet 36. Adjust it. That is, it is possible to adjust the carrier interface to a higher position than before. As a result, it is possible to set the carrier filling rate high. For example, the carrier filling rate can be about 30 to 60% by volume with respect to the capacity of the anaerobic reaction tank 10.

  As described above, the carrier that has flowed into the screen tank 12 may be defoamed by aeration and agitation, and may be returned to the anaerobic reaction tank 10 by the pump 28 as a carrier return means. As a result, the carrier can be activated again in the anaerobic reaction tank 10 despite a temporary decrease in activity in the screen tank 12.

  Further, the screen tank 12 is provided with a pH adjusting means, the pH in the screen tank is adjusted (pH adjusting step), and the pH adjusted water and the carrier which have been decarboxylated and adjusted by the pump 28 as the pH adjusted water returning means are anaerobically mixed. You may return to the reaction tank 10 or the adjustment tank of the front | former stage of the anaerobic reaction tank 10, etc. (process water return process). Thereby, pH in the anaerobic reaction tank 10 can be maintained in an appropriate range.

  In the methane fermentation treatment of organic wastewater, carbonic acid, which is a weak acid, is generated and dissolved in the liquid with the reaction, and the pH may be lowered due to some organic acid remaining. And if the pH in the anaerobic reaction tank 10 is less than 6.5, there is a concern that the efficiency of the anaerobic reaction may be reduced. Furthermore, since the hydrogen sulfide produced by the anaerobic reaction is liberated and easily gasified at a low pH, odor is likely to be generated in the screen tank 12 and the subsequent stage. In this case, a pH adjusting means can be installed in the anaerobic reaction tank 10 and a pH adjusting agent such as an alkaline agent can be added to adjust the pH. However, the amount of the alkaline agent used may increase.

  According to the configuration of the present embodiment, since air is diffused by the air diffuser 18 in the screen tank 12, a carbonic acid removal (decarbonation) effect can be obtained. Since the pH increases with decarboxylation, the amount of a pH adjusting agent such as an alkaline agent required for neutralization can be reduced. Then, by decarboxylation and returning pH-adjusted water adjusted by pH adjusting means as necessary to the anaerobic reaction tank 10 or the adjustment tank in front of the anaerobic reaction tank 10 or the like, The pH can be adjusted to an appropriate range.

  Examples of the pH adjuster include acids such as hydrochloric acid and alkali agents such as caustic soda. The pH in the anaerobic reaction tank 10 should just be adjusted in the range of 6.5-8.5, for example. Moreover, as pH in the screen tank 12, for example, when the pH of the reaction tank 10 is lowered to less than 6.5, by adding alkali and returning wastewater adjusted to about pH 7-10, For example, when the pH of the reaction tank 10 exceeds 8.5, it is possible to add acid and return the wastewater adjusted to about pH 4-7. Thus, an increase in pH of the reaction vessel 10 can be suppressed.

  The carrier used in the present embodiment is not particularly limited, but is a porous body containing cellulose, polyethylene, polypropylene, polyurethane, etc., a gel-like body containing polyvinyl alcohol, polyethylene glycol, etc. Is mentioned. The larger the pore size of the carrier, the more the oxidized nitrogen and hydrogen donor state in the water to be treated diffuses to the inside of the carrier, and the gas generation inside the carrier tends to occur (easily floats and is difficult to degas). A material having a small pore size (for example, about several μm to several tens of μm) is preferable.

  Further, the shape of the carrier is not particularly limited, but a rectangular shape such as a spherical shape or a cubic shape (cube shape) of about 0.5 mm to 10 mm is preferable. Further, in order to form a fluid state as shown in FIG. 1, the specific gravity of the carrier is at least greater than 1.0, and the true specific gravity is 1.1 or more, or the apparent specific gravity is 1.01 or more. preferable.

  The filling rate of the carrier stored in the anaerobic reaction tank 10 may be about 5 to 40%, for example, but as described above, the filling rate can be as high as about 30 to 60% by volume. The shape of the anaerobic reaction tank 10 may be rectangular or cylindrical, and is not particularly limited. In order to suppress the deposition of carriers on the bottom corner of the anaerobic reaction tank 10, the bottom corner of the anaerobic reaction tank 10 is preferably tapered as shown in FIG. It is preferable that the taper be at least. In order to keep the inside of the anaerobic reaction tank 10 in an anaerobic state, and when used for methane fermentation treatment of organic wastewater, etc., the generated methane gas, hydrogen sulfide gas, etc. are collected and treated appropriately. The upper part of the reaction vessel 10 has a sealed structure that is substantially shielded from the outside air.

  And when methane gas etc. generate | occur | produces, the generated methane gas etc. are discharged | emitted via gas discharge piping etc., for example, as a fuel etc., such as a boiler which produces warm water and steam, a gas engine for power generation, a gas turbine, etc. It can be used effectively. Here, if hydrogen sulfide or the like is contained in the gas, sulfur oxides or the like are generated during the combustion process, which may cause problems such as corrosion of the boiler or the like. You may perform pre-processing, such as making it contact with materials etc. (not shown).

  The anaerobic treated water pipe 32 to the screen tank 12 is preferably connected so as to allow anaerobic treated water to flow at a position lower than the liquid level of the screen tank 12. 10 can be prevented from flowing out.

  Although the shape of the screen 16 is not particularly limited, an arbitrary shape such as a wedge wire, a punching metal, a wire mesh, or the like can be used as long as the mesh is sufficiently small as compared with the size of the carrier. From below the screen 16, air is aerated (aerated) with an oxygen-containing gas such as air. Due to the aeration, the carrier accumulation on the screen 16 is suppressed, and the frequency of clogging of the screen 16 can be greatly reduced.

  The diffuser 18 is not particularly limited as long as it can diffuse an oxygen-containing gas into the screen tank 12, and examples thereof include a diffuser tube and a diffuser plate. The installation position of the air diffuser 18 is not particularly limited as long as the oxygen-containing gas can be diffused into the screen tank 12. However, in order to effectively suppress the deposition of the carrier on the screen 16 by the air diffuser. Further, it is preferably below the screen 16.

  Here, in order to enhance the cleaning effect of the screen 16, as described above, the guide plate 26 disposed approximately in parallel with the screen 16 may be provided between the air diffuser 18 and the pump 28. By providing the guide plate 26, it is possible to restrict the rising flow path of the bubbles and suppress the mixing of bubbles into the pump 28. And with aeration, while stripping, oxidation effects, etc., such as methane and hydrogen sulfide, etc. are obtained, dissolved carbonic acid is decarboxylated, and the pH of the treatment liquid rises.

  The pump as the carrier returning means and the pump as the pH adjusted water returning means may not be the same, and the treated water whose pH has been adjusted from the outlet of the screen 16 may be returned as pH adjusted water. By making it the same, equipment can be simplified.

  The suction port of the pump 28 is preferably at a position where no bubbles are mixed, and is preferably at a position below the screen tank 12 and far from the air diffuser 18 which is an air diffuser.

  The pump as the carrier return means and the pump as the pH-adjusted water return means are not particularly limited, but a submersible pump, a mono pump, a hose pump with high foreign substance passage performance so as not to damage the carrier as much as possible. Etc. can be used.

  Examples of wastewater treatment for purifying wastewater under anaerobic conditions in the present embodiment include denitrification treatment of wastewater containing nitric acid or nitrous acid, anaerobic ammonia oxidation treatment of wastewater containing ammonia and nitrous acid, and organic wastewater. Methane fermentation treatment and the like. The wastewater treatment apparatus and the wastewater treatment method according to the present embodiment can be suitably applied particularly to methane fermentation treatment of organic wastewater.

  Thus, according to the waste water treatment apparatus and the waste water treatment method according to the present embodiment, the screen is easily maintained in the waste water treatment apparatus including the anaerobic reaction tank filled with the carrier without complicated and dangerous work. And clogging of the screen can be suppressed even during long-term operation. Further, the odor of treated water, residual COD, and the like can be reduced, and the pH of the anaerobic reaction tank can be adjusted with a small amount of a pH adjusting agent such as an alkaline agent.

  DESCRIPTION OF SYMBOLS 1 Waste water treatment apparatus, 10 Anaerobic reaction tank, 12 Screen tank, 14 Draft tube, 16 screen, 18 Air diffuser, 20 Impeller apparatus, 22 Inverter, 24 Carrier, 26 Guide plate, 28 Pump, 30 pH measuring apparatus, 32 Anaerobic Treated water piping, 34 carrier return piping, 36 anaerobic treated water outlet.

Claims (8)

A wastewater treatment apparatus for purifying wastewater under anaerobic conditions using a carrier holding microorganisms,
An anaerobic reaction tank for storing the carrier and performing an anaerobic reaction;
A draft tube installed vertically inside the anaerobic reaction tank and opened at the top and bottom;
An impeller device that forms a downward flow in the draft tube and forms an upward flow between the draft tube and the inner wall surface of the anaerobic reaction tank;
A screen tank having a screen for receiving anaerobic treated water by the anaerobic reaction and separating the carrier; and an aeration means for diffusing an oxygen-containing gas in the tank;
A wastewater treatment apparatus comprising: A wastewater treatment apparatus according to claim 1,
PH adjusting means for adjusting the pH in the screen tank;
PH adjusted water returning means for returning the pH adjusted water adjusted by the pH adjusting means to the anaerobic reaction tank or the previous stage of the anaerobic reaction tank;
A wastewater treatment apparatus comprising: A wastewater treatment apparatus for purifying wastewater under anaerobic conditions using a carrier holding microorganisms,
  An anaerobic reaction tank for storing the carrier and performing an anaerobic reaction;
  A screen tank having a screen for receiving anaerobic treated water by the anaerobic reaction and separating the carrier; and an aeration means for diffusing an oxygen-containing gas in the tank;
  PH adjusting means for adjusting the pH in the screen tank;
  PH adjusted water returning means for returning the pH adjusted water adjusted by the pH adjusting means to the anaerobic reaction tank or the previous stage of the anaerobic reaction tank;
  A wastewater treatment apparatus comprising: The waste water treatment apparatus according to any one of claims 1 to 3 ,
A wastewater treatment apparatus comprising a carrier returning means for returning the carrier separated in the screen tank to the anaerobic reaction tank or a front stage of the anaerobic reaction tank. A wastewater treatment method for purifying wastewater under anaerobic conditions using a carrier holding microorganisms,
An anaerobic reaction step of performing an anaerobic reaction using the carrier in an anaerobic reaction tank;
A carrier separation step in which an oxygen-containing gas is diffused and the carrier is separated by a screen in a screen tank that receives anaerobic treated water by the anaerobic reaction;
Only including,
The anaerobic reaction tank is a draft tube that is installed vertically inside the anaerobic reaction tank and is open at the top and bottom, forms a downward flow in the draft tube, and the draft tube and the inner wall surface of the anaerobic reaction tank A wastewater treatment method comprising: an impeller device that forms an upward flow therebetween . A wastewater treatment method according to claim 5 ,
A pH adjusting step for adjusting the pH in the screen tank;
A pH-adjusted water returning step for returning the pH-adjusted water adjusted in the pH adjusting step to the anaerobic reaction tank or the previous stage of the anaerobic reaction tank;
The waste water treatment method characterized by including. A wastewater treatment method for purifying wastewater under anaerobic conditions using a carrier holding microorganisms,
  An anaerobic reaction step of performing an anaerobic reaction using the carrier in an anaerobic reaction tank;
  A carrier separation step in which an oxygen-containing gas is diffused and the carrier is separated by a screen in a screen tank that receives anaerobic treated water by the anaerobic reaction;
  A pH adjusting step for adjusting the pH in the screen tank;
  A pH-adjusted water returning step for returning the pH-adjusted water adjusted in the pH adjusting step to the anaerobic reaction tank or the previous stage of the anaerobic reaction tank;
  The waste water treatment method characterized by including. A wastewater treatment method according to any one of claims 5 to 7 ,
A wastewater treatment method comprising a carrier returning step of returning the carrier separated in the screen tank to the anaerobic reaction tank or a preceding stage of the anaerobic reaction tank.