JPH07241596A - Treatment of waste water - Google Patents

Abstract

PURPOSE:To miniaturize a waste water treatment apparatus by stirring water to be treated in an immersion type membrane module biological treatment tank to form an anaerobic atmosphere to perform denitrification by denitrifying bacteria and aerating water to be treated to form an aerobic atmosphere to perform nitrification by nitrifying bacteria according to a short cycle batchwise activated sludge method. CONSTITUTION:The water to be treated in a conditioning tank 15 is sucked by a raw water pump P2 to be supplied to an immersion type membrane module biological treatment tank 71 and treated according to a short cycle batchwise activated sludge method while methanol is added to the water to be treated. When the water to be treated is supplied to the immersion type module biological treatment tank 71 and stirring is started, oxygen is rappidly consumed and an anaerobic atmosphere is formed in a moment. Denitrifying groups oxidize org. matter in water to be treated in a denitrification process. Org. matter remaining in water to be treated is oxidized in an aerobic atmosphere in a nitrification process and the reductive nitrogen compd. formed in the denitrification process is oxidized to a nitrite ion or a nitrate ion by nitrifying bacteria.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wastewater treatment method.

[0002]

2. Description of the Related Art Conventionally, human waste, urban sewage, other organic substances,
A biological denitrification method is used as a wastewater treatment method of wastewater containing nitrogen, and the biological denitrification method is a nitrification step,
It consists of steps such as denitrification. That is, in the nitrification step, wastewater is introduced into the nitrification tank as water to be treated, an aerobic atmosphere is formed in the nitrification tank, and in the aerobic atmosphere, nitrite-producing bacteria, nitrifying bacteria, etc. Ammonia and other nitrogen components in the treated water are oxidized to form nitrous acid, nitric acid, etc.

In this case, the reaction formula of the nitrite reaction by the nitrite bacterium is as follows. 2NH ₄ ⁺ + 3O ₂ → 2NO ₂ ⁻ + 2H ₂ O + 4H ⁺ The reaction formula of the nitrification reaction by the nitrifying bacteria is as follows. _{2NO 2 + O 2 → 2NO 3} - the to complete the nitrification process, as well as addition of oxygen required for the nitrite reaction and nitric acid reaction water to be treated, suitable for water to be treated nitrifying bacteria pH 6. It is necessary to keep the pH at 5 to 8.5, add an alkaline agent as necessary, and prevent the nitrifying bacteria having a slow growth rate from flowing out.

In the next denitrification step, an anaerobic atmosphere is formed in the denitrification tank, and in the anaerobic atmosphere,
Nitrous acid, nitric acid, etc. are reduced to nitrogen gas by an allotrophic denitrifying bacterium that requires an organic carbon source. The reaction formula when methanol is used as the organic carbon source is as follows.

[0005] ^{_{5CH 3 OH + 6NO 3 - →}} 5CO 2 +7
H ₂ O + 6OH ⁻ + 3N ₂ However, in the wastewater treatment method as described above, a nitrification tank for a nitrification process, a denitrification tank for a denitrification process, and a sludge separation device are used according to changes in the form of nitrogen. Since it is necessary to dispose a sedimentation tank, not only the wastewater treatment device becomes large, but also the operation operation becomes complicated.

In addition, it is necessary to add an alkaline agent in the nitrification process, and since organic substances are mostly oxidized in the nitrification tank, it is necessary to add an organic carbon source to the denitrification tank. Furthermore, since the alkali increases in the denitrification tank, the pH of the water to be treated may become too high. Therefore, a wastewater treatment device using a single denitrification / nitrification tank is provided.

[0007] Figure 2 shows wastewater using a conventional denitrification / nitrification tank.
The first schematic diagram of the treatment equipment, Fig. 3 shows the conventional denitrification / nitrification tank
The second schematic diagram of the used wastewater treatment equipment is shown in Fig. 4.
It is a schematic diagram of a nitrification / nitrification tank. In this case, suction from the landfill
The wastewater treatment equipment for treating the generated leachate is explained.
It

As shown in the figure, in the pretreatment system, the leachate from the landfill 11 is sucked by the pumping pump P1 arranged in the landfill 11 and is treated as water to be treated through the water collecting pit 13 and the line 14. It is supplied to the adjusting tank 15. A raw water pump P2 is arranged in the adjusting tank 15, and the water to be treated sucked by the raw water pump P2 is supplied to a denitrification / nitrification tank 19 through a line 18.

Next, in the biological treatment system, the denitrification / nitrification tank 19 performs the treatment by the short cycle batch type activated sludge method, and the water to be treated is nitrified / denitrified and the biological treatment water and the biological sludge are mixed. It becomes a mixed solution. Then, a part of the mixed liquid in the denitrification / nitrification tank 19 is discharged and supplied to the precipitation tank 21 via the line 20. The mixed solution is separated into biological treated water and biological sludge by the settling tank 21, the biological treated water is supplied to a mixing tank 24 through a line 23, and the biological sludge is sucked by a pump P3 and settled sludge through a line 25. Is supplied to the sludge thickening tank 26. In this case, 0.5 [wt%] (5 [kg / m ³ ]) of biological sludge can be precipitated and separated in the settling tank 21.

Subsequently, in the coagulation system, the biological treatment water in the mixing tank 24 is treated with a coagulant (eg FeC).
l ₃ ) is added to mix the biotreated water and the flocculant,
The pH is adjusted to weakly acidic pH 4 to pH 6. The mixing tank 24
A stirrer 22 is provided inside the stirrer 2.
2 is driven by a motor 27. Then, the biologically treated water discharged from the mixing tank 24 is supplied to the coagulation tank 29 through the line 28.

In the coagulation tank 29, the coagulated polymer is added to the biologically treated water, and the biologically treated water is flocculated. A stirrer 30 is disposed in the aggregating tank 29, and the stirrer 30 is driven by a motor 31. The biologically treated water discharged from the coagulation tank 29 is supplied to the coagulation sedimentation tank 33 via a line 32. The coagulating sedimentation tank 33
The biologically treated water supplied to the liquid is solid-liquid separated in the coagulation sedimentation tank 33, the liquid portion becomes treated water and is supplied to the neutralization tank 35 via the line 34, and the biological sludge as the solid portion is supplied to the line 36. Is discharged as excess sludge through the pump P
4 is sucked and supplied to the sludge thickening tank 26. A rake 58 is provided in the coagulation-sedimentation tank 33 so that the sludge settled on the bottom of the coagulation-sedimentation tank 33 can be scraped off by rotating the rake 58 with a motor 59. Has become.

Then, in the neutralization tank 35, NaOH as an alkaline agent is added to the treated water to adjust the pH of the treated water, and the treated water is neutralized. Neutralization tank 3
An agitator 38 is arranged in the apparatus 5, and the agitator 38 is driven by a motor 39. Then, the treated water discharged from the neutralization tank 35 is passed through the line 40 to the activated carbon raw water tank 4
2 is supplied.

On the other hand, the settled sludge supplied through the line 25 and the surplus sludge supplied through the line 36 are
The sludge is concentrated in the sludge thickening tank 26 and becomes concentrated sludge.
A pump P5 is arranged in the sludge thickening tank 26, and the thickened sludge sucked by the pump P5 is supplied to a sludge storage tank 45 via a line 44. Next, in the advanced treatment system, the treated water in the activated carbon raw water tank 42 sucked by the pump P6 is passed through the line 48 to the sand filtration tower 4
9 and then a downward flow type activated carbon adsorption tower 50,
It is supplied to the treated water tank 52 via 51.

In this case, SS (raw sludge) is removed from the treated water in the sand filtration tower 49, and the activated carbon adsorption tower 50,
At 51, COD component adsorption processing is performed. In addition,
The activated carbon adsorption towers 50 and 51 are usually arranged in a few towers,
The treated water is passed through the series. Then, when the amount of impurities contained in the treated water discharged from the treated water tank 52 approaches the regulated value, the activated carbon charged in the activated carbon adsorption towers 50, 51 is replaced and regenerated.

On the other hand, the concentrated sludge in the sludge storage tank 45 is sucked by the pump P7 and is passed through the line 55 to the dehydrator 5
6 and is dehydrated by the dehydrator 56 to form a dehydrated cake. Next, the treatment by the short cycle batch activated sludge method in the denitrification / nitrification tank 19 will be described.

In the denitrification / nitrification tank 19, the process of introducing water to be treated, the denitrification process by anaerobic stirring, the nitrification process by aeration (aeration) stirring, and the mixed liquid discharging process are periodically repeated to discharge the mixed liquid. The mixed liquid discharged in the step is supplied to the settling tank 21, and the organic sludge and nitrogen components are removed by precipitating and separating the biological sludge in the settling tank 21.

In this case, the precipitation step, which requires 1 to several hours, can be carried out in the precipitation tank 21 provided separately from the denitrification / nitrification tank 19, so that the time for one cycle can be shortened to 15 to 15. It can be set to 60 [min / time], and the removal rate of nitrogen components can be improved. Further, since the biologically treated water after removing the organic matter and the nitrogen component can be uniformly discharged, it can be applied to a large-scale wastewater treatment apparatus.

Therefore, first, in the process of introducing water to be treated, denitrification and denitrification were carried out in the mixed liquid discharging process of the previous cycle.
When the water to be treated in the next cycle is supplied to the residual liquid remaining in the nitrification tank 19 through the line 18 and stirring is started, oxygen dissolved in the residual liquid is promptly consumed and deoxidized. An anaerobic atmosphere is instantly formed in the nitrification / nitrification tank 19.
Therefore, in the denitrification process, the nitrate ions, nitrite ions, etc. in the residual liquid produced in the previous cycle are the process by which the denitrifying bacteria oxidize organic matter in the water to be treated in an anaerobic atmosphere (nitric acid respiration action). At, it is reduced to nitrogen gas and removed from the water to be treated. With this denitrification reaction, the amount of alkali increases quantitatively, and the alkali consumed by the nitrification reaction in the next nitrification step is stored.

In the nitrification step, the organic substances remaining in the water to be treated that are not used by the denitrification reaction in the denitrification step are oxidized in the aerobic atmosphere, and the reduced nitrogen compound (mainly in the denitrification step) is produced. Organic nitrogen compounds and ammonia) are oxidized to nitrite ions, nitrate ions, etc. by nitrifying bacteria. Then, when the organic matter is oxidized and the nitrification reaction is completed, part of the mixed liquid in the denitrification / nitrification tank 19 is discharged in the mixed liquid discharging step and supplied to the precipitation tank 21 via the line 20. The pHIC is a pH indicator controller.

In FIG. 4, 15 is an adjusting tank, 18, 2
0, 23, 25 are lines, P2 is a raw water pump, and P3 is a pump. Further, 61 is a motor for stirring the water to be treated in the denitrification / nitrification tank 19, 62 is a blower for supplying air to the denitrification / nitrification tank 19, and 64 is settled sludge discharged from the settling tank 21. For returning the nitrogen to the denitrification / nitrification tank 19, P8 is a pump disposed in the line 64, 68
Is a rake disposed at the bottom of the settling tank 21. Then, by rotating the rake 68 with the motor 69, the settled sludge settled on the bottom of the settling tank 21 can be scraped off.

[0021]

However, in the conventional wastewater treatment method described above, the precipitation tank 21 is provided in the biological denitrification treatment system, and in the flocculation treatment system, the mixing tank 24, the sludge thickening tank 26, and the flocculation tank 26 are used. Tank 29
Also, since it is necessary to dispose the coagulating sedimentation tank 33, the size of the wastewater treatment device becomes large.

It is an object of the present invention to provide a wastewater treatment method which can solve the problems of the conventional wastewater treatment methods and can downsize the wastewater treatment apparatus.

[0023]

Therefore, in the wastewater treatment method of the present invention, the water to be treated in the submerged membrane module biological treatment tank is agitated to form an anaerobic atmosphere, and deaerated in the anaerobic atmosphere. Denitrification is performed with nitrogen bacteria, and the water to be treated in the submerged membrane module biological treatment tank is aerated to form an aerobic atmosphere, and nitrification by a short cycle batch activated sludge method is performed by nitrifying bacteria in the aerobic atmosphere. Done,
The membrane module immersed in the submerged membrane module biological treatment tank membrane separates biologically treated water from biological sludge.

In another wastewater treatment method of the present invention, the membrane module is a flat membrane module. In still another wastewater treatment method of the present invention, a brush is arranged between the flat membranes of the flat membrane module, and the membrane surface is continuously washed by the brush. In still another wastewater treatment method of the present invention, the floating carrier is suspended in the submerged membrane module biological treatment tank to flow between the membrane surfaces.

In still another wastewater treatment method of the present invention, the biological treatment water is supplied to a submerged membrane module coagulation treatment tank, a coagulant is added to the biological treatment water in the submerged membrane module coagulation treatment tank, and Immersion type membrane module A membrane module disposed in the coagulation treatment tank separates coagulated water from coagulated sludge into a membrane.

[0026]

According to the present invention, as described above, in the wastewater treatment method, the water to be treated in the submerged membrane module biological treatment tank is agitated to form an anaerobic atmosphere, and the denitrifying bacteria are removed in the anaerobic atmosphere. Denitrification is performed by aerating the water to be treated in the submerged membrane module biological treatment tank to form an aerobic atmosphere, and nitrification is performed by a short cycle batch activated sludge method with nitrifying bacteria in the aerobic atmosphere. Therefore,
BOD components, COD components, etc. in the water to be treated are removed, and the water to be treated is nitrified and denitrified to become a mixed liquid of biologically treated water and biological sludge.

Then, the biotreated water is membrane-separated from the biological sludge by the membrane module immersed in the submerged membrane module biotreatment tank. In another wastewater treatment method of the present invention, the membrane module is a flat membrane module. In this case, the flat membrane module is formed by a plurality of flat membranes. In still another wastewater treatment method of the present invention, a brush is arranged between the flat membranes of the flat membrane module, and the membrane surface is continuously washed by the brush. In this case, the brush is activated when the permeability of the flat sheet membrane module decreases.

In still another wastewater treatment method of the present invention, the floating carrier is suspended in the submerged membrane module biological treatment tank to flow between the membrane surfaces. In this case, when the floating carrier flows between the membrane surfaces as the water to be treated is stirred in the submerged membrane module biological treatment tank, the membrane surfaces are automatically cleaned. In still another wastewater treatment method of the present invention, the biological treated water discharged from the submerged membrane module biological treatment tank is supplied to the submerged membrane module coagulation treatment tank. Then, a coagulant is added to the biologically treated water in the immersion type membrane module coagulation treatment tank to mix the biologically treated water and the coagulant. Further, the coagulated water is subjected to membrane separation from the coagulated sludge by the membrane module arranged in the immersion type membrane module coagulation treatment tank.

[0029]

Embodiments of the present invention will now be described with reference to the drawings.
While explaining in detail. FIG. 1 shows an embodiment of the present invention.
Immersion type membrane module Wastewater treatment equipment using biological treatment tank
FIG. 5 is a first schematic diagram of the immersion type in the embodiment of the present invention.
Second of wastewater treatment equipment using membrane module biological treatment tank
FIG. 6 is a schematic diagram of the sequencer in the embodiment of the present invention.
FIG.

In this case, a wastewater treatment device for treating the leachate sucked from the landfill will be described. As shown in the figure, in the pretreatment system, the leachate in the landfill 11 is sucked by the pumping pump P1 arranged in the landfill 11, and the treated tank is treated water through the water collecting pit 13 and the line 14. 15 are supplied. In the adjusting tank 15,
After sedimentation and impurities are removed from the water to be treated, it is stored and homogenized.

A Ca removing device (not shown) may be provided. For example, in a landfill mainly composed of incinerated ash, the concentration of Ca in the incinerated ash is high, and the scale adheres to a pipe or the like (not shown) of the wastewater treatment device. Therefore,
In order to remove Ca, sodium carbonate is added to the water to be treated by a Ca removing device to generate calcium carbonate on the alkali side, and the calcium carbonate is aggregated and subjected to precipitation treatment. Furthermore, inorganic carbonate (I
It is also possible to prevent the generation of scale by aerating C) with acid to diffuse it.

A raw water pump P2 is provided in the adjusting tank 15, and the water to be treated sucked by the raw water pump P2 is supplied to the submerged membrane module biological treatment tank 71 through a line 18. Next, in the biological treatment system, methanol is added to the water to be treated in the submerged membrane module biological treatment tank 71, and treatment by the short cycle batch activated sludge method is performed. In the present embodiment, the treatment by the short cycle batch activated sludge method removes BOD components, COD components, nitrogen components and the like in the water to be treated to obtain a mixed liquid of the biologically treated water and the biological sludge. Then, the mixed solution in the submerged membrane module biological treatment tank 71 is membrane-separated into the biological treated water and the biological sludge by the submerged membrane module 72, and the biological treated water is sucked by the biological treated water pump P11 and passed through the line 73. It is supplied to the submerged membrane module coagulation treatment tank 75, and part of the biological sludge is sucked by the pump P12 as excess sludge and supplied to the sludge storage tank 45 via the line 76. In this case, 1.5 [wt%] (15 [kg /
It is possible to maintain a biological sludge concentration of about m ³ ]).

As compared with the treatment by the conventional short cycle batch activated sludge method, not only the nitrogen load of 4 to 5 times can be treated, but also the precipitation tank 21 (see FIG. 2) becomes unnecessary, The wastewater treatment device can be downsized.
An aeration device 78 is disposed in the submerged membrane module biological treatment tank 71, and a blower 79 is connected to the aeration device 78 to supply air to the submerged membrane module biological treatment tank 71. A stirring pump P13 for stirring is arranged in the submerged membrane module biological treatment tank 71 to stir the water to be treated. By this aeration and stirring, the immersion type membrane module 72
The membrane surface of can be washed, and the permeation amount of biologically treated water is stabilized. In this case, the sequencer 81, as shown in FIG. 6, has the raw water pump P11 and the biological treated water pump P1.
1, a stirring pump P13, a methanol pump (not shown) for supplying methanol, and a blower 79 are operated by a timer.

At the beginning of the landfill of the landfill 11, the ratio B of the BOD component of the treated water to the total nitrogen load TN
When the OD / TN is 3 or more, it is not necessary to add methanol to the water to be treated. When the landfill 11 progresses to landfill and the ratio BOD / T-N becomes 1 to 2 or less, methanol is added to the water to be treated about 2.5 times the total nitrogen load T-N. There is a need.

A flat membrane module is used as the submerged membrane module 72, and an organic membrane such as hydrophilic polysulfone is used as the flat membrane. In this case, UF (ultrafiltration membrane) having a molecular weight cutoff of about 10 to 750,000 is suitable.
Further, the suction of the treated water by the biological treated water pump P11 is performed at about 5 to 50 [l / m ² · h].

By the way, as conventional biological denitrification methods for water to be treated, there are a rotary disk method, a catalytic oxidation method and an activated sludge method. Among the activated sludge methods, there are nitrification solution circulating activated sludge method and short activated sludge method. There is a cycle batch activated sludge method. The standard values of the nitrification load and the denitrification load in each of the biological denitrification methods are as follows.

[0037]

[Table 1]

In Table 1, d means "per unit day". Next, an example of equipment calculation is shown. In this case, the flow rate of the treated water is Q and the total nitrogen load is T-
Let N. Q = 300 [m ³ / d] BOD = 400 [mg / l] T−N = 120 [mg / l] The treated water obtained by treating the water to be treated is BOD = 10 [mg / l] l] T−N = 10 [mg / l].

Subsequently, in the coagulation treatment system, a coagulant (for example, FeCl ₃ ) is added to the biotreated water in the immersion type membrane module coagulation treatment tank 75 to mix the biotreated water and the coagulant, and weakly. It is adjusted to acidic pH 4 to pH 6. Then, COD components, chromaticity components, etc. remaining in the biologically treated water are efficiently removed. An immersion type membrane module 84 is disposed in the immersion type membrane module aggregation treatment tank 75,
With the immersion type membrane module 84, the coagulated water and 1-2
Membrane separation is carried out into coagulated sludge concentrated to a concentration of [%].
A stirring pump P14 for stirring is provided in the immersion type membrane module aggregation treatment tank 75 to stir the biologically treated water. By stirring this biologically treated water, the membrane surface of the immersion type membrane module 84 can be washed, and the permeation amount of the coagulated treated water is stabilized.

A flat membrane module is used as the submerged membrane module 84, and an organic membrane such as hydrophilic polysulfone is used as the flat membrane. In this case, the molecular weight cutoff is 1
A UF (ultrafiltration membrane) of about 0 to 750,000 is suitable. Then, the coagulated treated water is sucked by the pump P15 and is supplied to the neutralization tank 35 as treated water via the line 89, and the coagulated sludge is sucked by the pump P16 and the line 9 is supplied.
1 is supplied to the sludge storage tank 45.

In the neutralization tank 35, the treated water is neutralized by adding NaOH or the like as an alkaline agent to the treated water to adjust the pH of the treated water. A stirrer 38 is disposed in the neutralization tank 35, and the stirrer 38 is driven by a motor 39. The treated water discharged from the neutralization tank 35 is supplied to the activated carbon raw water tank 42 via the line 40.

By doing so, the mixing tank 24 (see FIG. 3), the sludge concentration tank 26, the flocculation tank 29 and the flocculation sedimentation tank 33 in the conventional wastewater treatment apparatus are not required, and the wastewater treatment apparatus can be downsized. it can. Also, no agglomerated polymer is required. The following is a comparison between the equipment of the agglomeration processing system and the equipment of a conventional agglomeration processing system in this example.

[0043]

[Table 2]

Next, in the advanced treatment system, the COD component remaining in the treated water is removed to the amount required for the discharge standard. Therefore, the treated water in the activated carbon raw water tank 42 is sucked by the pump P6 and supplied to the upward flow type activated carbon adsorption tower 93 through the line 48. In the activated carbon adsorption tower 93, fine-grained activated carbon (average particle size 0.5 to
1.0 [mm]) is filled and compacted, so that the adsorption treatment efficiency can be improved. Then, in the activated carbon adsorption tower 93, the treated water is caused to flow upward without flowing the activated carbon. The saturated activated carbon, that is, the saturated carbon is taken out at the lower end of the activated carbon adsorption tower 93, and new activated carbon is replenished at the upper end of the activated carbon adsorption tower 93.

By using the activated carbon adsorption tower 93, the adsorption rate can be increased 4 to 6 times and the adsorption amount can be increased 1.5 times or more as compared with the conventional activated carbon adsorption towers 50 and 51. Moreover, the activated carbon adsorption tower 93 can be downsized. In addition, the running cost of activated carbon is reduced.
Further, the treated water permeated by the submerged membrane module 84 is clearer than the treated water filtered by the conventional sand filtration tower 49, so that the sand filtration tower 49 becomes unnecessary. Further, since the treated water permeated by the submerged membrane module 84 has a low SS (suspended substance concentration), it is possible to reduce the pressure loss in the activated carbon adsorption tower 93 which uses fine-grained activated carbon.

The treated water discharged from the activated carbon adsorption tower 93 is supplied to the treated water tank 52. On the other hand, the coagulated sludge in the sludge storage tank 45 is sucked by the pump P7 and supplied to the dehydrator 56 through the line 55, and the dehydrator 5
It is dehydrated by 6 and becomes a dehydrated cake.

The activated carbon adsorption tower 93 may be replaced by activated carbon adsorption towers 50 and 51. The equipment of the advanced processing system in the present embodiment and the equipment of the conventional advanced processing system are compared as follows.

[0048]

[Table 3]

Next, the immersion type membrane module 72 and the immersion type membrane module 84 will be described. In this case, the immersion type membrane module 72 and the immersion type membrane module 84
Since the structure is the same as that of, the immersion type membrane module 72 will be described. FIG. 7 is a horizontal cross-sectional view of the submerged membrane module biological treatment tank in the embodiment of the present invention, FIG. 8 is a vertical cross-sectional view of the submerged membrane module biological treatment tank in the embodiment of the present invention, and FIG. 9 is an embodiment of the present invention. 10 is a plan view of the submerged membrane module biological treatment tank in FIG. 10, FIG. 10 is a sectional view of a main part of the submerged membrane module biological treatment tank in the embodiment of the present invention, and FIG. 11 is a submerged membrane module biological treatment tank in the embodiment of the present invention. FIG.

As shown in the figure, the submerged membrane module biological treatment tank 71 contains water 96 to be treated in a frame 95, and the submerged membrane module 72 is immersed in the water 96 to be treated. Further, an air diffuser type aeration device 78 is arranged in the submerged membrane module biological treatment tank 71, and a blower 79 (FIG. 1) is connected to the aeration device 78 to treat the submerged membrane module biological treatment tank 71. Supply the required amount of air to. The aeration device 78 has a plurality of air diffusing tubes 98 arranged at various places on the bottom surface of the submerged membrane module biological treatment tank 71, and each air diffusing tube 98 injects air to the entire submerged membrane module biological treatment tank 71. To do.

Therefore, the injected air becomes bubbles to form a diffused air flow (gas-liquid mixed liquid) together with the water to be treated 96,
The water to be treated 96 is circulated by the diffused air and an aerobic atmosphere is formed in the submerged membrane module biological treatment tank 71. Note that an oxygen-containing gas may be used instead of air. The submerged membrane module 72 is supported so as to form a space with the submerged membrane module biological treatment tank 71, and the aeration device 78 is disposed in the space.
A flat membrane module is used as the immersion type membrane module 72, and a plurality of flat membranes 99 are housed in a module frame 97 to be formed. Further, the module frame 97 is provided with a number of flat membranes 99 capable of ensuring an area required for treatment by the immersion type membrane module biological treatment tank 71, and four sides of the flat membranes 99 are membrane holders. 103
Supported by. The distance between the flat membranes 99 is 2
It is set to about 0 to 100 [mm], and a vertical passage for passing the diffused air is formed between the flat membranes 99.

A stirring pump P13 is provided in the submerged membrane module biological treatment tank 71, and the treated water 96
Stir. The membrane surface of the flat membrane 99 can be washed by the agitation and the agitation of the water 96 to be treated, and the permeation amount of the biologically treated water can be stabilized. In the submerged membrane module biological treatment tank 71 having the above-described configuration, a treatment water introduction step, a denitrification step by anaerobic stirring, and a nitrification step by aeration stirring are periodically repeated, while the submerged membrane module 72 removes biological sludge from the biological sludge. It is designed to separate biologically treated water into membranes.

In this case, since the precipitation step is not necessary, 1
The cycle time can be shortened, and the nitrogen component removal rate can be improved. Therefore, first, in the treated water introduction step, when the treated water 96 is supplied to the submerged membrane module biological treatment tank 71 and agitation is started, oxygen dissolved in the residual liquid is quickly consumed. Then, the anaerobic atmosphere is instantly formed in the submerged membrane module biological treatment tank 71.

Therefore, in the denitrification step, the denitrification group uses the nitrate ions, nitrite ions, etc. in the residual liquid produced in the previous cycle to remove the organic substances in the water 96 to be treated in an anaerobic atmosphere. Oxidizes (respiratory action of nitric acid). At this time, most of nitrate ions, nitrite ions and the like are reduced to nitrogen gas and removed from the water 96 to be treated. With this denitrification reaction, the amount of alkali increases quantitatively, and the alkali consumed by the nitrification reaction in the next nitrification step is stored.

In the nitrification step, the organic substances remaining in the water to be treated that have not been used by the denitrification reaction in the denitrification step are oxidized in the aerobic atmosphere, and the reduced nitrogen compound produced in the denitrification step (mainly in the denitrification step). Organic nitrogen compounds and ammonia) are oxidized to nitrite ion, nitrate ion and the like by nitrifying bacteria such as nitrite and nitrifying bacteria. Water to be treated 9 in the submerged membrane module biological treatment tank 71
The results of processing No. 6 are as follows.

[0056]

[Table 4]

In Table 4, d means "per unit number of days". Further, the film surface of the flat film 99 can be brush-cleaned. for that reason,
The brush 101 is movably arranged in the submerged membrane module biological treatment tank 71. Then, the brush 101
Is moved between the adjacent flat membranes 99 and rotated in the direction of arrow A, whereby the membrane surface can be washed. Also,
The brush 101 can be moved up and down in the direction of arrow B. In this embodiment, the traveling hoisting device 102 raises the brush 101 and lowers it by its own weight. Therefore, the brush 101 descends while rotating between the two flat membranes 99, and continuously cleans the membrane surfaces on both sides during that time.

Then, the brush 101 is moved up and down several times, then wound up by the traveling hoisting device 102 to wash the other flat film 99, and moved in the direction of arrow C. When a floating carrier (not shown) is floated in the submerged membrane module biological treatment tank 71 in order to improve the denitrification reaction, the floating carrier flows between the film surfaces of the flat membranes 99 so that the film surface is Can be washed automatically.

The present invention is not limited to the above-mentioned embodiments, but can be variously modified based on the spirit of the present invention, and they are not excluded from the scope of the present invention.

[0060]

As described in detail above, according to the present invention, in the wastewater treatment method, the water to be treated in the submerged membrane module biological treatment tank is stirred to form an anaerobic atmosphere,
Denitrifying with denitrifying bacteria in the anaerobic atmosphere,
The water to be treated in the submerged membrane module biological treatment tank is aerated to form an aerobic atmosphere, and nitrification is performed by a short cycle batch activated sludge method with nitrifying bacteria in the aerobic atmosphere. Therefore, the BOD component, COD component, etc. in the treated water are removed, and the treated water is nitrified and denitrified,
It becomes a mixed liquid of biologically treated water and biological sludge.

Then, the biologically treated water is membrane-separated from the biological sludge by the membrane module immersed in the submerged membrane module biological treatment tank. Therefore, the conventional settling tank becomes unnecessary, and the wastewater treatment device can be downsized.
In another wastewater treatment method of the present invention, the membrane module is a flat membrane module. In this case, since the flat membrane module is formed by a plurality of flat membranes, a cleaning brush can be arranged between the flat membranes.

In still another wastewater treatment method of the present invention, a brush is provided between the flat membranes of the flat membrane module,
The membrane surface is continuously washed with a brush. Therefore,
The membrane surface of the flat membrane can be washed without taking the flat membrane module out of the immersion type membrane module biological treatment tank.
In still another wastewater treatment method of the present invention, the floating carrier is suspended in the submerged membrane module biological treatment tank to flow between the membrane surfaces. Therefore, the membrane surface of the flat membrane can be automatically cleaned without taking out the flat membrane module from the immersion type membrane module biological treatment tank.

In still another wastewater treatment method of the present invention, the biological treatment water discharged from the submerged membrane module biological treatment tank is supplied to the submerged membrane module coagulation treatment tank. Then, a coagulant is added to the biologically treated water in the immersion type membrane module coagulation treatment tank to mix the biologically treated water and the coagulant. Further, the coagulated water is subjected to membrane separation from the coagulated sludge by the membrane module arranged in the immersion type membrane module coagulation treatment tank.

Therefore, the conventional settling tank, mixing tank, sludge concentrating tank, coagulating tank and coagulating sedimentation tank are not required, and the wastewater treatment apparatus can be downsized. Also, no agglomerated polymer is required.

[Brief description of drawings]

FIG. 1 is a first schematic diagram of a wastewater treatment apparatus using a submerged membrane module biological treatment tank according to an embodiment of the present invention.

FIG. 2 is a first schematic diagram of a conventional wastewater treatment device using a denitrification / nitrification tank.

FIG. 3 is a second schematic view of a conventional wastewater treatment device using a denitrification / nitrification tank.

FIG. 4 is a schematic view of a conventional denitrification / nitrification tank.

FIG. 5 is a second schematic view of a wastewater treatment apparatus using a submerged membrane module biological treatment tank in an example of the present invention.

FIG. 6 is an operation diagram of the sequencer according to the embodiment of the present invention.

FIG. 7 is a cross-sectional view of a submerged membrane module biological treatment tank according to an embodiment of the present invention.

FIG. 8 is a vertical cross-sectional view of a submerged membrane module biological treatment tank in an example of the present invention.

FIG. 9 is a plan view of a submerged membrane module biological treatment tank in an example of the present invention.

FIG. 10 is a sectional view of an essential part of a submerged membrane module biological treatment tank according to an example of the present invention.

FIG. 11 is a plan view of an essential part of the submerged membrane module biological treatment tank in the example of the present invention.

[Explanation of symbols]

 71 Immersion Type Membrane Module Biological Treatment Tank 72, 84 Immersion Type Membrane Module 75 Immersion Type Membrane Module Aggregation Treatment Tank 96 Treated Water 99 Flat Membrane 101 Brush

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Claims (5)

[Claims] 1. (a) Stirring the water to be treated in the submerged membrane module biological treatment tank to form an anaerobic atmosphere, and (b) denitrifying with denitrifying bacteria in the anaerobic atmosphere,
(C) aeration of the water to be treated in the submerged membrane module biological treatment tank to form an aerobic atmosphere, (d) nitrification by a short cycle batch activated sludge method with nitrifying bacteria in the aerobic atmosphere, (E) A method for treating wastewater, characterized in that biotreated water is membrane-separated from biological sludge by the membrane module immersed in the submerged membrane module biological treatment tank. 2. The wastewater treatment method according to claim 1, wherein the membrane module is a flat membrane module. 3. The wastewater treatment method according to claim 2, wherein a brush is provided between the flat membranes of the flat membrane module, and the membrane surface is continuously washed by the brush. 4. The wastewater treatment method according to claim 1, wherein the floating carrier is floated in the submerged membrane module biological treatment tank and allowed to flow between the membrane surfaces. 5. (a) supplying the biologically treated water to a submerged membrane module coagulation treatment tank, (b) adding a coagulant to the biologically treated water in the submerged membrane module coagulation treatment tank, and (c)
The wastewater treatment method according to claim 1, wherein the coagulated water is subjected to membrane separation from coagulated sludge by a membrane module arranged in the immersion type membrane module coagulation treatment tank.