JP2939156B2 - Sewage treatment equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

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

[0002]

2. Description of the Related Art Conventionally, there has been provided a sewage treatment apparatus in which membrane separation devices are arranged in two stages in order to treat wastewater such as human waste and septic tank sludge. FIG. 2 is a block diagram of a conventional sewage treatment apparatus for performing a two-stage membrane treatment. In the figure, reference numeral 11 denotes a screen for filtering wastewater such as human waste and septic tank sludge. The wastewater filtered by the screen 11 (hereinafter referred to as “residual waste liquid”) is sent to a remover waste liquid storage tank 12. The residue that has been collected and stored and separated by filtration is sent to a dehydrator 13 to be dehydrated into a dehydrated filtrate, and the dehydrated filtrate is sent to the residue-removed waste liquid storage tank 12.

[0003] Next, the waste sludge sent to the waste sludge storage tank 12 is mixed with the dehydrated filtrate to form mixed and adjusted urine. The mixed and adjusted urine is sent to the biological treatment tank 15. In the biological treatment tank 15, the mixed and adjusted urine is subjected to biological nitrification and denitrification (hereinafter referred to as "biological denitrification"), and the mixture is adjusted and the BOD component, COD component, nitrogen (TN) ) The components and the like are removed, and a biological treatment mixture of biological sludge and biological treatment water is formed. The biological treatment mixture,
Further, it is sent to the membrane separation device 16 and separated into biological sludge and biologically treated water by the membrane separation device 16. And
The biological sludge separated by the membrane separation device 16 is returned to the biological treatment tank 15 as return sludge, while the biologically treated water is sent to the coagulation treatment tank 17.

[0004] In the coagulation treatment tank 17, the biologically treated water is coagulated by adding a coagulant, and coagulated sludge is generated. At this time, phosphorus (phosphorus) (TP) components, COD components, chromaticity components, and the like remaining in the biologically treated water are fixed and removed in the flocculated sludge. Then, the coagulated sludge is sent to the membrane separation device 19 where the solid sludge is separated.

[0005] Further, the permeate of the membrane separation device 19 is sent to an activated carbon treatment device 20, where it is treated with activated carbon to remove COD components, chromaticity components, etc., and discharged as treated water. As described above, since the two-stage membrane treatment is performed, the quality of the treated water can be improved. However, it is necessary to provide two membrane separation devices 16 and 19, which increases the cost.

Therefore, the urine is subjected to coagulation / dehydration treatment to adjust the mixing before being sent to the biological treatment tank 15, and to carry out coagulation / dehydration treatment.
There is provided a sewage treatment apparatus that does not require the 7 and the membrane separation device 19. FIG. 3 is a block diagram of a conventional sewage treatment apparatus for performing one-stage membrane treatment. In the figure, reference numeral 11 denotes a screen for filtering wastewater such as human waste and septic tank sludge.

Next, the waste liquid sent to the waste liquid storage tank 12 is sent to a flocculation tank 21 where an inorganic flocculant and a polymer are added to the waste liquid and the waste liquid is removed. The floc is mixed to form a floc mixture in which flocs are formed. Then, the floc mixture is sent to a dehydrator 22 and dehydrated by the dehydrator 22 to become a dehydrated filtrate,
The dehydrated filtrate is sent to the biological treatment tank 24 via the storage tank 23.

In the biological treatment tank 24, the dewatered filtrate is subjected to a biological denitrification treatment, and the BOD component, CO
The D component, the nitrogen component, and the like are removed, and a biological treatment mixture of biological sludge and biological treatment water is formed. The biological treatment mixed solution is further sent to the membrane separation device 25, where it is separated into biological sludge and biological treatment water. The biological sludge separated by the membrane separation device 25 is returned to the biological treatment tank 24 as return sludge,
On the other hand, the biologically treated water is sent to the activated carbon treatment device 26. Then, the biologically treated water is treated with activated carbon to form C.
OD components, chromaticity components, etc. are removed and discharged as treated water.

[0009]

However, in the conventional sewage treatment apparatus, a chemical such as an inorganic coagulant or a polymer is charged for coagulation treatment in the coagulation tank 21 and dewatered. The balance (about 2.86: 1: 0.1) of the BOD component, the nitrogen component, and the phosphorus component necessary for the biological denitrification treatment caused by the above is lost.

That is, BOD components, C
Various components such as an OD component, an SS component, a nitrogen component, and a phosphorus component are contained.
Each component is removed at a different removal rate. In particular, since the removal rate of the BOD component, the SS component, and the phosphorus component is high, the load of the biological denitrification treatment by the BOD component is small. B required for biological denitrification
The OD component, the phosphorus component and the like become insufficient, and the activity of the activated sludge becomes insufficient.

Therefore, in order to replenish these components,
In some cases, it is necessary to put waste liquid, methanol, and the like into the biological treatment tank 24. However, biological treatment tank 24
When the waste liquid from the residue is added to the wastewater, the phosphorus component in the waste liquid from the residue is charged. In this case, since there is no coagulation treatment after the biological treatment, it becomes difficult to completely remove the phosphorus component. Therefore, it is necessary to arrange an anaerobic tank upstream of the biological treatment tank 24 to perform a biological dephosphorization treatment, or to add a flocculant downstream of the biological treatment tank 24 to remove residual phosphorus. is there.

Further, if methanol is charged into the biological treatment tank 24, the cost will increase accordingly. The present invention
It is an object of the present invention to provide a sewage treatment apparatus which can solve the problem of the conventional sewage treatment apparatus and can remove unnecessary phosphorus components, and does not need to put waste liquid, methanol and the like into a biological treatment tank. And

[0013]

For this purpose, in the sewage treatment apparatus according to the present invention, a screen for filtering wastewater and removing residue, and mixing the residue and excess sludge to form a sludge mixture, A sludge storage tank for storing the sludge mixed liquid, a flocculation tank for coagulating the sludge mixed liquid from the sludge storage tank to form a floc mixed liquid in which flocs are formed, and dewatering the floc mixed liquid from the flocculation tank. The dewatering machine that separates the dewatered cake and the dewatered filtrate, the wastewater that has been filtered on the screen, and the dewatered filtrate from the dewatering machine are mixed and adjusted to make urine, and the mixed and adjusted urine is stored. A waste treatment liquid storage tank, a biological treatment tank for subjecting the mixed and adjusted urine to a biological nitrification denitrification treatment to form a biological treatment mixture of biological sludge and biological treatment water, and a biological treatment from the biological treatment tank Agglomerate the mixed solution and activate A and the coagulation concentration and separation tank that is separated into a separated liquid, and a membrane separation device for solid-liquid separating liquid separated from aggregated concentration and separation tank.

The activated sludge separated in the coagulation / concentration / separation tank is sent to the sludge storage tank as surplus sludge, and the amount of the phosphorus component in the wastewater filtered by the screen is determined by the biological treatment. It is adjusted according to the amount of the phosphorus component required for the biological nitrification and denitrification treatment in the tank. In another sewage treatment apparatus of the present invention, a screen for filtering wastewater and removing sewage, a sludge storage tank for mixing the sewage and excess sludge to form a sludge mixture, and storing the sludge mixture And a flocculation tank for coagulating the sludge mixed liquid from the sludge storage tank to form a floc mixed liquid having flocs formed therein, and dewatering the floc mixed liquid from the flocculation tank to form a dewatered cake and a dewatered filtrate. A dewatering machine to be separated, a wastewater filtered through a screen, and a dewatered filtrate from the dewatering machine mixed and adjusted to form urine; a dedusting waste liquid storage tank for storing the mixed and adjusted urine; and the mixing adjustment. Biological nitrification denitrification treatment on night soil, a biological treatment tank that forms a biological treatment mixture of biological sludge and biological treatment water, and a biological treatment mixture from the biological treatment tank, an activated sludge and a separation liquid With a membrane separation device for solid-liquid separation That.

The activated sludge separated in the membrane separation device is sent to the sludge storage tank as surplus sludge, and the amount of the phosphorus component in the wastewater filtered by the screen is determined by the biological treatment tank. Is adjusted according to the amount of the phosphorus component required for the biological nitrification and denitrification treatment in the above.

[0016]

According to the present invention, as described above, in the sewage treatment apparatus, a screen for filtering wastewater and removing wastewater, and mixing the wastewater and excess sludge to form a sludge mixture,
A sludge storage tank for storing the sludge mixed liquid, a flocculation tank for coagulating the sludge mixed liquid from the sludge storage tank to form a floc mixed liquid in which flocs are formed, and dewatering the floc mixed liquid from the flocculation tank. The dewatering machine that separates the dewatered cake and the dewatered filtrate, the wastewater that has been filtered on the screen, and the dewatered filtrate from the dewatering machine are mixed and adjusted to make urine, and the mixed and adjusted urine is stored. A waste treatment liquid storage tank, a biological treatment tank for subjecting the mixed and adjusted urine to a biological nitrification denitrification treatment to form a biological treatment mixture of biological sludge and biological treatment water, and a biological treatment from the biological treatment tank Aggregate the mixture,
It has a coagulation / concentration / separation tank for separating the activated sludge and the separated liquid, and a membrane separation device for solid-liquid separation of the separated liquid from the coagulation / concentration / separation tank.

In this case, the wastewater sent to the screen is
The wastewater filtered by the screen is sent to a sediment waste liquid storage tank, and the residue removed by filtration is sent to a sludge storage tank. Then, in the sludge storage tank, the residue and excess sludge are mixed to form a sludge mixture. The sludge mixture is sent to a flocculation tank, and is flocculated in the flocculation tank, and becomes a floc mixture in which flocs are formed. The floc mixture is sent to a dehydrator, dehydrated by the dehydrator, and separated into a dehydrated cake and a dehydrated filtrate. Then, the dehydrated filtrate is sent to the waste liquid tank for removing residue.

In the waste liquid storage tank, the filtered waste liquid and the dehydrated filtrate are mixed and adjusted to form urine, and the mixed and adjusted urine is sent to the biological treatment tank. The biological treatment tank performs a biological nitrification denitrification treatment on the mixed and adjusted urine to form a biological treatment mixture of biological sludge and biological treatment water. Further, the biological treatment mixed solution is sent to the coagulation / concentration / separation tank, and is coagulated by the coagulation / concentration / separation tank to be separated into activated sludge and a separated liquid. The separation liquid is sent to a membrane separation device, and is subjected to solid-liquid separation.

The activated sludge separated in the coagulation / concentration / separation tank is sent to the sludge storage tank as surplus sludge, and the amount of the phosphorus component in the wastewater filtered by the screen is determined by the biological treatment. It is adjusted according to the amount of the phosphorus component required for the biological nitrification and denitrification treatment in the tank. In another sewage treatment apparatus of the present invention, a screen for filtering wastewater and removing sewage, a sludge storage tank for mixing the sewage and excess sludge to form a sludge mixture, and storing the sludge mixture And a flocculation tank for coagulating the sludge mixed liquid from the sludge storage tank to form a floc mixed liquid having flocs formed therein, and dewatering the floc mixed liquid from the flocculation tank to form a dewatered cake and a dewatered filtrate. A dewatering machine to be separated, a wastewater filtered through a screen, and a dewatered filtrate from the dewatering machine mixed and adjusted to form urine; a dedusting waste liquid storage tank for storing the mixed and adjusted urine; and the mixing adjustment. Biological nitrification denitrification treatment on night soil, a biological treatment tank that forms a biological treatment mixture of biological sludge and biological treatment water, and a biological treatment mixture from the biological treatment tank, an activated sludge and a separation liquid With a membrane separation device for solid-liquid separation That.

In this case, the wastewater sent to the screen is
The wastewater filtered by the screen is sent to a sediment waste liquid storage tank, and the residue removed by filtration is sent to a sludge storage tank. Then, in the sludge storage tank, the residue and excess sludge are mixed to form a sludge mixture. The sludge mixture is sent to a flocculation tank, and is flocculated in the flocculation tank, and becomes a floc mixture in which flocs are formed. The floc mixture is sent to a dehydrator, dehydrated by the dehydrator, and separated into a dehydrated cake and a dehydrated filtrate. Then, the dehydrated filtrate is sent to the waste liquid tank for removing residue.

In the waste liquid storage tank, the filtered waste liquid and the dehydrated filtrate are mixed to form mixed and adjusted urine, and the mixed and adjusted urine is sent to the biological treatment tank. The biological treatment tank performs a biological nitrification denitrification treatment on the mixed and adjusted urine to form a biological treatment mixture of biological sludge and biological treatment water. The activated sludge separated in the membrane separation device is sent to the sludge storage tank as surplus sludge, and the amount of the phosphorus component in the wastewater after being filtered in the screen is determined by the biological treatment in the biological treatment tank. It is adjusted in accordance with the amount of the phosphorus component required for the specific nitrification and denitrification treatment.

[0022]

Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 is a block diagram of a sewage treatment apparatus according to a first embodiment of the present invention. In the figure,
Reference numeral 11 denotes a screen for filtering wastewater such as night soil, septic tank sludge, and the like, and the waste liquid after filtration by the screen 11 is sent to and stored in a waste liquid waste storage tank 12.
The residue separated by the filtration is sent to a residue crusher 31, crushed by the residue crusher 31, and then sent to a sludge storage tank 32.

Here, the distribution ratio between the waste liquid sent to the waste liquid storage tank 12 and the residue sent to the residue crusher 31 is determined in advance by analyzing the components of the wastewater and corresponding to the components. You. In this example, the waste liquid from the debris was removed by 7 times.
The residue was set to 30%. For this purpose, control valves (not shown) are provided between the screen 11 and the waste liquid storage tank 12 and between the screen 11 and the residue crusher 31, respectively.

In the sludge storage tank 32, in addition to the sewage sent from the slag crusher 31, surplus sludge extracted from the coagulation / concentration / separation tank described later is sent. The residue and excess sludge are mixed to form a sludge mixture and stored. Next, the sludge mixture is sent to a coagulation tank 34, where an inorganic coagulant and a polymer are added. In addition, since the agglomerated pH range is usually neutral or lower, if necessary, for example, when an iron salt is used, the pH is adjusted to 4.5 to 4.5 by adding a pH adjuster.
It is desirable to adjust so as to be about 6.0. As a result, the fibers in the residue become a dehydration aid, and the sludge mixture forms a strong floc and becomes a floc mixture. At this time, the phosphorus component is almost completely removed.

Thereafter, the floc mixture is sent to a dehydrator 35, where it is dehydrated and separated into a dehydrated cake and a dehydrated filtrate. Then, the dehydrated cake is sent to a dryer (not shown), dried, and then incinerated in an incinerator. On the other hand, the dehydrated filtrate is sent to the waste liquid storage tank 12, and the waste liquid and the dehydrated filtrate are mixed in the waste liquid storage tank 12 to be adjusted and formed into urine. Therefore, when the amount of night soil, septic tank sludge, etc. supplied to the screen 11 fluctuates, the influence of the fluctuation can be eliminated by adjusting the distribution ratio.

Next, the mixed and adjusted urine is sent to the biological treatment tank 37, where the mixed and adjusted urine is subjected to biological denitrification in the biological treatment tank 37, and the BOD component and CO2 in the mixed and adjusted urine are adjusted.
The D component, the nitrogen component, and the like are removed, and a biological treatment mixture of biological sludge and biological treatment water is formed. By the way, the mixed and adjusted urine is sent to the biological treatment tank 37, and the waste liquid and the dewatered filtrate are removed so as to contain a phosphorus component slightly larger than the amount required for the biological denitrification treatment in the biological treatment tank 37. The amount has been set. For example, B
The ratio of the phosphorus component used to the OD component is set to about 2 to 4 [%] with a margin.

In this case, an amount of phosphorus necessary for the biological denitrification treatment in the biological treatment tank 37 can be secured, and the components other than the phosphorus component balance the water quality components originally required for the biological denitrification treatment. , The biological denitrification treatment in the biological treatment tank 37 can be stably performed. A coagulation / concentration / separation tank 38 is provided adjacent to the biological treatment tank 37. In the coagulation / concentration / separation tank 38, a coagulant is added to the biological treatment mixture, and the biological treatment mixture is separated from the activated sludge and the separation liquid. And separated. At this time,
The phosphorus component remaining slightly in the biological treatment mixture becomes a phosphorus compound and is suspended together with the activated sludge. Therefore,
Since the coagulant product remaining in the biological treatment tank 37 can be reduced, the influence of the coagulant product on the biological denitrification treatment can be reduced.

A part of the separated activated sludge is returned to the inlet side of the biological treatment tank 37 as returned sludge, and the remaining part is sent to the sludge storage tank 32 as surplus sludge. Therefore, the above-mentioned residue and excess sludge can be centrally managed. Moreover, since the excess sludge is dewatered by the dehydrator 35 together with the residue, the dewatering in the dehydrator 35 becomes easy, and the water content of the dewatered cake can be reduced.

On the other hand, the separated liquid separated in the coagulation / concentration / separation tank 38 is used as secondary treatment water as the membrane separation device 4.
Sent to 1. Then, in the membrane separation device 41, the separated liquid is subjected to solid-liquid separation. In this case, the coagulation concentration separation tank 38
As a result, the concentration of the SS component becomes low, and the coagulation tank 34
As a result, since the concentrations of the COD component and the chromaticity component are low, the removal rate of the COD component, the SS component, the chromaticity component, and the like in the separation liquid is high, and the transmission speed of the membrane separation device 41 can be increased. it can. Further, since the membrane of the membrane separation device 41 is less likely to be contaminated, the frequency of cleaning the membrane can be reduced.

Further, the permeated liquid of the membrane separation device 41 is sent as secondary treatment water to the activated carbon treatment device 42, where it is treated with activated carbon to remove COD components, chromaticity components, etc., and discharged as treated water. Thus, the screen 11
In the above, unnecessary phosphorus components other than the phosphorus component required for biologically denitrifying the waste liquid from the debris are removed together with the sewage and removed by the crushing machine 3.
1 and completely removed by the coagulation treatment in the coagulation tank 34.

Therefore, the balance of water components required for performing the biological denitrification treatment in the biological treatment tank 37 can be maintained, so that a stable biological denitrification treatment can be performed. FIG. 4 is a first diagram showing a component table for each process in the first embodiment of the present invention, and FIG. 5 is a second diagram showing a component table for each process in the first embodiment of the present invention.

In this case, the components of human waste and sludge from the septic tank sent to the screen 11 (FIG. 1), the components of the sludge waste liquid sent from the screen 11 to the sludge waste liquid storage tank 12, and the waste from the screen 11 to the waste crusher 31. The components of the residue, the components of the excess sludge sent from the coagulation / concentration / separation tank 38 to the sludge storage tank 32, the components of the dewatered filtrate sent from the dehydrator 35 to the waste liquid storage tank 12, and separated by the dehydrator 35. The components of the dewatered cake, the components of the process water added to the waste liquid storage tank 12, and the biological treatment tank 37
The components of the mixed and adjusted urine to be sent to the membrane separation device 38, the components of the secondary treated water sent to the membrane separation device 41 from the coagulation concentration separation tank 38, and the components of the treated water discharged from the activated carbon treatment device 42 are shown.

In FIG. 4, the flow rate of human waste is set at 0.
4 [Q], and the flow rate of the septic tank sludge was 0.6 [Q]. In FIG. 5, the flow rate of human waste is set to 0.1 [Q].
And the flow rate of the septic tank sludge was 0.9 [Q]. next,
A second embodiment of the present invention will be described. FIG. 6 is a block diagram of a sewage treatment apparatus according to a second embodiment of the present invention. In addition, about what has the same structure as 1st Example, the description is abbreviate | omitted by attaching | subjecting the same code | symbol.

In this case, a membrane separation device 41 is directly connected to the biological treatment tank 37, and the biological treatment mixed solution is supplied to the membrane separation device 4.
The activated sludge is separated into the activated sludge and the separated liquid by the membrane separation device 41. The permeate of the membrane separation device 41 is sent to the activated carbon treatment device 42 as secondary treatment water,
It is treated with activated carbon to remove COD components, chromaticity components, etc., and discharged as treated water. On the other hand, the membrane separation device 4
A part of the activated sludge separated into solid and liquid by 1 is returned to the inlet side of the biological treatment tank 37 as returned sludge, and the rest is sent to the sludge storage tank 32 as surplus sludge.

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

[0036]

As described above in detail, according to the present invention, in the sewage treatment apparatus, a screen for filtering waste water and removing residue, and a method of mixing the residue and excess sludge to form a sludge. A sludge storage tank for storing the sludge mixed liquid as a mixed liquid, a flocculation tank for aggregating the sludge mixed liquid from the sludge storage tank to form a floc mixed liquid having flocs formed therein, and a floc mixing from the flocculation tank A dehydrator for dehydrating the liquid to separate it into a dehydrated cake and a dehydrated filtrate, a wastewater filtered on a screen, and a dehydrated filtrate from the dehydrator are mixed and adjusted to make urine, and the mixing adjustment is performed. A waste liquid storage tank for storing human waste, a biological treatment tank for subjecting the mixed and adjusted urine to a biological nitrification and denitrification treatment to form a biological treatment mixture of biological sludge and biological treatment water, and a biological treatment tank Agglutinate biological treatment mixture from With the activated sludge and flocculation concentration and separation tank that is separated into a separated liquid, and a membrane separation device for solid-liquid separating liquid separated from aggregated concentration and separation tank.

In this case, the sludge residue and the excess sludge are mixed in the sludge storage tank to form a sludge mixture. Therefore, not only can the waste residue and the excess sludge be managed in a unified manner, but also the excess sludge is dewatered together with the waste residue, so that dehydration in the dehydrator becomes easy and the water content of the dewatered cake is reduced. Can be. Then, the sludge mixture is sent to the coagulation tank, and is coagulated by the coagulation tank. At this time, the fibers in the residue serve as a dehydration aid, so that the sludge mixture can form a strong floc. As a result, the phosphorus component can be almost completely removed by the coagulation treatment in the coagulation tank.

The activated sludge separated in the coagulation / concentration / separation tank is sent to the sludge storage tank as surplus sludge, and the amount of the phosphorus component in the wastewater filtered by the screen is determined by the biological treatment. It is adjusted according to the amount of the phosphorus component necessary for the biological denitrification treatment in the tank. In this case, the amount of phosphorus necessary for the biological denitrification treatment in the biological treatment tank can be secured, and the components other than the phosphorus component are:
Since the original balance of the water quality components of the residue liquid waste is maintained as it is, the biological nitrification and denitrification treatment in the biological treatment tank can be stably performed.

In another sewage treatment apparatus of the present invention, a screen for filtering wastewater and removing the residue, a mixture of the residue and excess sludge to form a mixed sludge, and storing the mixed sludge. A sludge storage tank, an agglomeration tank for aggregating the sludge mixed liquid from the sludge storage tank into a floc mixed liquid in which flocs are formed, and dewatering the floc mixed liquid from the flocculation tank to form a dewatering cake and a dewatering filter. A dehydrator that separates the liquid and the wastewater that has been filtered on the screen, and the dehydrated filtrate from the dehydrator are mixed and adjusted to make urine, and the decontaminated waste liquid storage tank that stores the mixed and adjusted urine, Biological nitrification and denitrification treatment of the mixed and adjusted urine, a biological treatment tank for forming a biological treatment mixture of biological sludge and biological treatment water, and a biological treatment mixture from the biological treatment tank, the activated sludge Membrane component for solid-liquid separation with separation liquid And a device.

In this case, the sludge residue and the excess sludge are mixed in the sludge storage tank to form a sludge mixture. Therefore, not only can the waste residue and the excess sludge be managed in a unified manner, but also the excess sludge is dewatered together with the waste residue, so that dehydration in the dehydrator becomes easy and the water content of the dewatered cake is reduced. Can be. Then, the sludge mixture is sent to the coagulation tank, and is coagulated by the coagulation tank. At this time, the fibers in the residue serve as a dehydration aid, so that the sludge mixture can form a strong floc. As a result, the phosphorus component can be almost completely removed by the coagulation treatment in the coagulation tank.

The activated sludge separated in the membrane separation device is sent to the sludge storage tank as surplus sludge, and the amount of the phosphorus component in the wastewater after being filtered by the screen is determined by the biological treatment tank. Is adjusted according to the amount of the phosphorus component required for the biological nitrification and denitrification treatment in the above. In this case, it is possible to secure an amount of the phosphorus component necessary for the biological denitrification treatment in the biological treatment tank, and the components other than the phosphorus component maintain the original balance of the water quality component of the waste liquid from the residue removal. Therefore, the biological nitrification and denitrification in the biological treatment tank can be stably performed.

[Brief description of the drawings]

FIG. 1 is a block diagram of a sewage treatment apparatus according to a first embodiment of the present invention.

FIG. 2 is a block diagram of a conventional sewage treatment apparatus for performing a two-stage membrane treatment.

FIG. 3 is a block diagram of a conventional sewage treatment apparatus for performing one-stage membrane treatment.

FIG. 4 is a first view showing a component table for each process in the first embodiment of the present invention.

FIG. 5 is a second diagram showing a component table for each process in the first embodiment of the present invention.

FIG. 6 is a block diagram of a sewage treatment apparatus according to a second embodiment of the present invention.

[Explanation of symbols]

 REFERENCE SIGNS LIST 11 screen 12 waste liquid storage tank for residue removal 32 sludge storage tank 34 coagulation tank 35 dehydrator 37 biological treatment tank 38 coagulation concentration separation tank 41 membrane separation device

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁶ Identification symbol FI C02F 9/00 504 C02F 9/00 504A 3/34 101 3/34 101C 11/14 ZAB 11/14 ZABA (56) References Special JP-A-2-59100 (JP, A) JP-A-4-4098 (JP, A) (58) Fields investigated (Int. Cl. ⁶ , DB name) C02F 9/00 501-504 C02F 3/34 101 C02F 11/14

Claims (2)

(57) [Claims] (1) a screen for filtering waste water and removing residue, and (b) a sludge storage tank for mixing the residue and excess sludge to form a mixed sludge and storing the mixed sludge. When,
(C) an aggregating tank for aggregating the sludge mixed liquid from the sludge storage tank into a floc mixed liquid having flocs formed therein;
(D) a dehydrator for dehydrating the floc mixture from the flocculation tank to separate it into a dewatered cake and a dehydrated filtrate, (e) wastewater filtered on a screen, and dehydration filtration from the dehydrator. A liquid waste mixing tank that mixes and adjusts the liquid to form urine, and a waste liquid waste storage tank that stores the mixed and adjusted urine; and A biological treatment tank for forming a biological treatment mixture,
(G) aggregating the biological treatment mixture from the biological treatment tank;
A coagulation-concentration separation tank for separating into activated sludge and a separation liquid,
(H) a membrane separation device for performing solid-liquid separation of the separated liquid from the coagulation / concentration / separation tank, and (i) activated sludge separated in the coagulation / concentration / separation tank as excess sludge in the sludge storage tank. (J) the amount of the phosphorus component in the wastewater after being filtered in the screen is adjusted in accordance with the amount of the phosphorus component required for the biological nitrification and denitrification treatment in the biological treatment tank. A sewage treatment apparatus characterized by the above-mentioned. 2. A sludge tank for filtering waste water and removing sludge; and (b) a sludge mixed tank for mixing the sludge and excess sludge to form a mixed sludge liquid. When,
(C) an aggregating tank for aggregating the sludge mixed liquid from the sludge storage tank into a floc mixed liquid having flocs formed therein;
(D) a dehydrator for dehydrating the floc mixture from the flocculation tank to separate it into a dewatered cake and a dehydrated filtrate, (e) wastewater filtered on a screen, and dehydration filtration from the dehydrator. A liquid waste mixing tank that mixes and adjusts the liquid to form urine, and a waste liquid waste storage tank that stores the mixed and adjusted urine; and A biological treatment tank for forming a biological treatment mixture,
(G) a membrane separation device for solid-liquid separation of the biological treatment mixed solution from the biological treatment tank into an activated sludge and a separated solution; and (h) the activated sludge separated in the membrane separation device, Sent to the sludge storage tank as excess sludge,
(I) The amount of the phosphorus component in the wastewater after being filtered in the screen is adjusted according to the amount of the phosphorus component necessary for the biological nitrification and denitrification treatment in the biological treatment tank. Wastewater treatment equipment.