JP2886385B2 - Activated sludge 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 an activated sludge treatment apparatus.

[0002]

2. Description of the Related Art Conventionally, for example, an activated sludge treatment method has been employed to purify sewage, and an aeration tank is used as a treatment tank, and microorganisms such as bacteria and protozoa are cultured in the aeration tank. Then, oxygen is supplied by aeration for 4 to 8 hours (in the case of a sewage treatment plant). When the raw water is supplied to the aeration tank, the microorganisms eat organic matter in the raw water and purify the raw water. In this case, since the activity of the microorganism is high and the growth rate is high, the amount of activated sludge (microbial growth) is large.

On the other hand, in the oxidation ditch method using an oxidation ditch as a treatment tank, aeration is usually performed for 24 hours. Therefore, a long and endless circulation water channel is provided, aeration is performed by an aeration device, and a mixture of raw water and activated sludge is circulated. Therefore, the amount of organic matter given to the microorganisms cultured in a large amount in the oxidation ditch is reduced, and a starvation state is formed, and the microorganisms eat even organic substances that are hardly decomposable. As a result, the treated water in the oxidation ditch is highly purified, the amount of activated sludge generated is small, and the decay property is low.

By the way, raw water of various pollution levels is supplied to processing tanks such as the aeration tank and the oxidation ditch, and pretreatment is performed according to the pollution levels. FIG. 2 is a conceptual diagram of a conventional activated sludge treatment apparatus. In the figure, 11 is a processing tank such as an aeration tank or an oxidation ditch, 12 is a high-contamination drainage line for supplying high-concentration raw water to the processing tank 11, and 13 is a low-concentration raw water for supplying the processing tank 11. The low-contamination drainage line 14 is a dilution tank for diluting raw water having a high concentration.

In the case of treating raw water having a low concentration, there is no problem if the raw water is directly supplied to the treatment tank 11, but in the case of treating raw water having a high concentration, fresh water is supplied to the dilution tank 14. Then, it is mixed with raw water, diluted to a concentration corresponding to the processing capacity of the processing tank 11, and then supplied to the processing tank 11. In this case, if the amount of raw water with high concentration increases,
Since all of the diluted raw water is supplied to the processing tank 11, the processing tank 11 must be enlarged.

Therefore, an activated sludge treatment apparatus using a high-load activated sludge treatment system has been provided in order to convert raw water having a high concentration into raw water corresponding to the treatment capacity of the treatment tank 11 without diluting it. FIG. 3 is a schematic diagram of an activated sludge treatment apparatus using a conventional high-load activated sludge treatment system.

In FIG. 1, reference numeral 11 denotes a treatment tank such as an aeration tank or an oxidation ditch; 12, a highly-contaminated drainage line for supplying high-concentration raw water to the processing tank 11; And a low-contamination drainage line 15 for supplying a high-load activated sludge treatment system for treating high-concentration raw water to reduce the concentration. The high-load activated sludge treatment system 15 includes a reciprocating jet reactor 1
7. Foam destroyer 18 and sedimentation (den) tank 19
The raw water having a high concentration is received and treated, and the primary treated water is supplied to the treatment tank 11.

The reciprocating jet reactor 17 is cylindrical.
A large number of perforated disks are spaced at regular intervals
It is arranged without a gap, and the perforated disc is
The drive unit 22 is connected via a shaft 21 to the drive unit 22.
Activate the device 22 to move up and down at regular intervals
It reciprocates. The reciprocating jet rear
The lower end of the reciprocating jet reactor 17
24 and air for supplying highly concentrated raw water to
Supply line 25, discharges the mixture at the upper end
Line 26 is connected to the
Is further connected to the high-contamination drainage line 12 and has a high concentration.
A line 28 for supplying raw water to line 24, and
The activity which was connected to the precipitation tank 19 and precipitated in the precipitation tank 19
Return part of the sludge to the reciprocating jet reactor 17
Line 29 is connected. Lines 25 and 2
Pump P for 8 and 29₁, P_Two, P _ThreeAre arranged respectively
It is.

The raw water supplied to the reciprocating jet reactor 17, the air and the activated sludge returned through the line 29 (hereinafter referred to as “returned sludge”) flow in from the lower end of the reciprocating jet reactor 17. In the reciprocating jet reactor 17, the porous disk reciprocates up and down, so that a vortex is formed around the porous disk and a flow like a jet flow is generated. Since the porous disc is disposed in the reciprocating jet reactor 17 without any gap, the inside of the reciprocating jet reactor 17 is completely stirred by the action of the jet flow.

As a result, the bubbles of the activated sludge and the air are miniaturized and strongly mixed, so that the gas phase (bubbles) →
The mass transfer rate from the liquid phase to the activated sludge becomes very high, and the oxygen transfer rate becomes high and the oxygen dissolution efficiency becomes extremely large. In addition, the reciprocating jet reactor 17
Because it has a closed tank structure with a height of up to 9 [m],
The inside becomes pressurized, and the oxygen dissolving efficiency is further increased.

Therefore, the reciprocating jet reactor 1
Decomposition of organic matter in raw water (finally CO ₂ +
It becomes H ₂ O. ) Is very fast and violent, so that the mixture discharged from the reciprocating jet reactor 17 has many bubbles. Therefore, a foam destroyer 18 is provided to destroy air bubbles generated in the reciprocating jet reactor 17, and a line 2 is provided.
The mixed liquid discharged through 6 is foam destroyer 1
8 is supplied.

Then, the mixed liquid after the bubbles are destroyed in the foam destroyer 18 is supplied to the settling tank 19, in which the activated sludge is settled and separated from the primary treatment water. The settling tank 19 is connected to a line 30 for supplying the primary treated water to the processing tank 11 and a line 31 for discharging the settled activated sludge. The line 31 is further connected to a reciprocating jet reactor. It is connected to a line 29 for returning to the treatment tank 17 and a line 32 for supplying surplus sludge to the treatment tank 11. Incidentally, the pump P ₄ is disposed in line 32.

Therefore, the activated sludge separated from the primary treated water in the settling tank 19 is discharged through the line 31 and flows through the line 29 as returned sludge, and is returned to the line 24.
Is returned to the reciprocating jet reactor 17 to replenish the activated sludge in the reciprocating jet reactor 17. On the other hand, the remaining excess sludge is supplied to the treatment tank 11 through the line 30 to replenish the activated sludge in the treatment tank 11.

[0014]

However, since the conventional activated sludge treatment apparatus is provided with the high-load activated sludge treatment system 15, the high-concentration raw water is treated without increasing the size of the treatment tank 11. Can be
In addition to the reciprocating jet reactor 17, a foam destroyer 18 and a sedimentation tank 19 are required, which not only increases the cost, but also requires a site area, and requires maintenance and management, which complicates the work. .

An object of the present invention is to solve the problems of the conventional activated sludge treatment apparatus and to provide an activated sludge treatment apparatus that is low in cost, easy to maintain and manage, and can simplify the operation. And

[0016]

For this purpose, the activated sludge treatment apparatus of the present invention is provided with a drive device for disposing a large number of porous disks in a tank and reciprocating the porous disks up and down. It has a reciprocating jet reactor for treating raw water by mixing raw water, air and activated sludge inside.

Raw water and air are supplied to the reciprocating jet reactor, and a mixed liquid is discharged from the reciprocating jet reactor. The discharged mixed solution is supplied to the treatment tank without breaking bubbles and without separating activated sludge. Activated sludge can be returned from the treatment tank to the reciprocating jet reactor.

[0018]

According to the present invention, a large number of perforated disks are provided in the tank as described above, and a drive device for reciprocating the perforated disks up and down is provided.
It has a reciprocating jet reactor that mixes air and activated sludge to treat raw water. Therefore, by operating the driving device, the perforated disk reciprocates up and down, a flow like a jet flow is generated in the tank, and the raw water, air and activated sludge are mixed and stirred. During this time, the organic matter in the raw water is decomposed by activated sludge and air,
It becomes a mixture.

Therefore, raw water and air are supplied to the reciprocating jet reactor, and the mixed liquid is discharged from the reciprocating jet reactor. The discharged mixed solution is supplied to the treatment tank without destroying the bubbles and without separating the activated sludge, the bubbles are destroyed in the treatment tank, and the activated sludge is used together with the activated sludge in the treatment tank. You. Therefore, a foam destroyer for breaking bubbles and a sedimentation tank for separating activated sludge are not required.

Further, the activated sludge can be returned from the treatment tank to the reciprocating jet reactor. When the concentration of the raw water supplied to the reciprocating jet reactor is low, the activated sludge returned from the treatment tank can be supplied to the reciprocating jet reactor to enhance the function of the cultivation power.

[0021]

Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 is a schematic diagram of an activated sludge treatment apparatus showing a first embodiment of the present invention. In the figure, 1
1 is a treatment tank such as an aeration tank or an oxidation ditch, 12 is a high-contamination drainage line for supplying high-concentration raw water to the processing tank 11, and 13 is a low-contamination wastewater for supplying low-concentration raw water to the processing tank 11. Line.

A reciprocating jet reactor 17 is disposed to treat the highly concentrated raw water supplied from the highly polluted drainage line 12. The reciprocating jet reactor 1
7 receives raw water having a high concentration via a line 41 and treats it with activated sludge and air, and supplies the treated liquid mixture to the treatment tank 11 via a line 42. for that reason,
In the reciprocating jet reactor 17, a large number of perforated disks are arranged in a cylindrical tank at regular intervals without any gap, and the perforated disks are connected to a driving device 22 via a shaft 21. By actuating 22, it reciprocates up and down at a constant cycle.

At the lower end of the reciprocating jet reactor 17, a line 41 for supplying raw water having a high concentration to the reciprocating jet reactor 17 and a line 25 for supplying air are provided at the upper end. A line 42 for discharging the gas is connected. Lines 25 and 4
1 is provided with pumps P ₁ and P ₂ , respectively. FIG. 4 is a first state diagram inside a reciprocating jet reactor in an activated sludge treatment apparatus showing an embodiment of the present invention, and FIG. 5 is a second state diagram inside a reciprocating jet reactor in an activated sludge treatment apparatus showing an embodiment of the present invention. is there.

In the figure, reference numeral 45 denotes a perforated disk which is disposed in the reciprocating jet reactor 17 (FIG. 1) without any gap. The perforated disk 45 is, for example, a SUS having a thickness of several millimeters.
A plurality of perforated disks 45 are arranged vertically at a pitch of several tens of millimeters. The porous disc 45 has a diameter of 1
Many holes 46 of about 0 mm are formed. The holes 46 are formed at different positions with respect to each adjacent perforated disk 45, and are arranged in a so-called "staggered foot" shape.

The perforated disk 45 is indicated by an arrow A,
As shown in B, for example, when reciprocating up and down several tens centimeters for each stroke at a period of several tens [rpm], a vortex 47 is formed near the perforated disk 45, and a flow 48 like a jet flow is generated. I do. Since the porous disk 45 is disposed in the reciprocating jet reactor 17 without gaps, the reciprocating jet reactor 17
The inside is completely stirred by the action of the flow 48.

As a result, the bubbles of the activated sludge and the air are finely divided and mixed strongly, so that the gas phase (bubbles) →
The mass transfer rate from the liquid phase to the activated sludge becomes very high, and the oxygen transfer rate becomes high and the oxygen dissolution efficiency becomes extremely large. In addition, the reciprocating jet reactor 17
Because it has a closed tank structure with a height of up to 9 [m],
Since the inside is pressurized, the oxygen dissolving efficiency is further increased.

Therefore, the reciprocating jet reactor 1
Decomposition of organic matter in raw water (finally CO ₂ +
It becomes H ₂ O. ) Is performed very quickly and violently, so that the mixture discharged from the reciprocating jet reactor 17 contains many air bubbles.
2 to the processing tank 11. The treatment tank 11 is constituted by an aeration tank or an oxidation ditch,
When an aeration tank is used, microorganisms such as bacteria and protozoa are cultured in the aeration tank, and oxygen is supplied by aeration for 4 to 8 hours (in the case of a sewage treatment plant). . When the mixture is supplied to the aeration tank via the line 42, the microorganisms eat organic matter in the mixture and purify the mixture.

On the other hand, when an oxidation ditch is used as the treatment tank 11, aeration is usually performed for 24 hours. Therefore, a long and endless circulating water channel is provided, aeration is performed by an aeration device, and the mixed liquid and activated sludge are further mixed and circulated in the circulating water channel. Therefore, the amount of organic matter given to the microorganisms cultured in a large amount in the oxidation ditch is reduced, and a starvation state is formed, and the microorganisms eat even organic substances that are hardly decomposable. As a result, the treated water in the oxidation ditch is highly purified, the amount of activated sludge generated is small, and the decay property is low.

The bubbles generated in the reciprocating jet reactor 17 are destroyed while being aerated in the aeration tank or the oxidation ditch of the processing tank 11. Therefore, the form destroyer 18 (see FIG. 3) becomes unnecessary. Activated sludge is present in the mixed liquid discharged from the reciprocating jet reactor 17, but the activated sludge is supplied to the treatment tank 11 via the line 42 as it is, and is treated in the treatment tank 11. used.

When the concentration of the supplied raw water is high, the reciprocating jet reactor 17 functions as a culture tank, so that it is not necessary to replenish the activated sludge from the outside, and the sedimentation tank 19 becomes unnecessary. Next, a second embodiment of the present invention will be described. FIG. 6 is a schematic diagram of an activated sludge treatment apparatus showing a second embodiment of the present invention.

In the figure, 11 is a treatment tank, 12 is a highly-contaminated drain line for supplying raw water having a high concentration to the treatment tank 11,
Reference numeral 13 denotes a low-contamination drain line for supplying raw water having a low concentration to the treatment tank 11. A reciprocating jet reactor 17 is disposed to treat highly concentrated raw water supplied from the highly polluted drainage line 12. To the reciprocating jet reactor 17, high-concentration raw water from the high-contamination drainage line 12 is supplied via a line 41, and air is supplied via a line 25. In the reciprocating jet reactor 17, raw water is treated with activated sludge and air, and the treated liquid mixture is supplied to the treatment tank 11 via a line.

As described above, when the concentration of raw water supplied to the reciprocating jet reactor 17 is high, the reciprocating jet reactor 17 functions as a culture tank.
It is not necessary to replenish the activated sludge from the outside, but when the concentration of raw water is low, the cultivation power is reduced. Therefore, the line 24 and the processing tank 11 are connected by a line 51,
The activated sludge in the treatment tank 11 is returned via the line 51,
The activated sludge in the reciprocating jet reactor 17 can be replenished. Note that pumps P ₁ , P ₂ , and P ₅ are provided on the lines 25, 41, and 51, respectively.

FIG. 7 is a comparison diagram of a processing example between a conventional ultra-high load activated sludge treatment apparatus and an ultra-high load activated sludge treatment apparatus of the present invention. As shown, the reciprocating jet reactor 17
In addition to (Fig. 3), foam destroyer 18 and settling tank 1
It can be seen that there is no difference in the processing characteristics between the conventional activated sludge treatment apparatus which requires No. 9 and the activated sludge treatment apparatus of the present invention which does not require the foam destroyer 18 and the precipitation tank 19.

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

[0035]

As described above in detail, according to the present invention, a large number of perforated disks are arranged in a tank, and a driving device for reciprocating the perforated disks up and down is provided. , A reciprocating jet reactor that mixes air and activated sludge to treat raw water. Raw water and air are supplied to the reciprocating jet reactor, and the mixed liquid is discharged from the reciprocating jet reactor. The discharged mixed solution is supplied to the treatment tank without destroying the bubbles and without separating the activated sludge, and the bubbles are destroyed in the treatment tank.
The activated sludge is used together with the activated sludge in the treatment tank. Therefore, foam destroyers for breaking bubbles,
A sedimentation tank for separating the activated sludge, a pump for returning the activated sludge separated in the sedimentation tank, and the like are not required.

Further, the activated sludge can be returned from the treatment tank to the reciprocating jet reactor. When the concentration of raw water supplied to the reciprocating jet reactor is low, the returned activated sludge can be supplied to the reciprocating jet reactor for processing. Therefore, the cost can be reduced, the site area can be minimized, the maintenance and management become easy, and the operation is simplified.

[Brief description of the drawings]

FIG. 1 is a schematic diagram of an activated sludge treatment apparatus showing a first embodiment of the present invention.

FIG. 2 is a conceptual diagram of a conventional activated sludge treatment device.

FIG. 3 is a schematic diagram of an activated sludge treatment apparatus using a conventional high-load activated sludge treatment system.

FIG. 4 is a first state diagram in a reciprocating jet reactor in an activated sludge treatment apparatus showing an embodiment of the present invention.

FIG. 5 is a second state diagram inside the reciprocating jet reactor in the activated sludge treatment apparatus showing the embodiment of the present invention.

FIG. 6 is a schematic diagram of an activated sludge treatment apparatus showing a second embodiment of the present invention.

FIG. 7 is a comparison diagram of a conventional ultra-high load activated sludge treatment apparatus and a processing example of the ultra-high load activated sludge treatment apparatus of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 11 Treatment tank 12 High-contamination drainage line 13 Low-contamination drainage line 17 Reciprocating jet reactor 22 Drive unit 25, 41, 42, 51 Line 45 Perforated disk

Claims (2)

(57) [Claims] (A) A plurality of perforated disks are provided in a tank, and a drive device for reciprocating the perforated disks up and down is provided. The raw water, air and activated sludge in the tank are mixed to remove the raw water. A reciprocating jet reactor to be treated, (b) means for supplying raw water to the reciprocating jet reactor, (c) means for supplying air to the reciprocating jet reactor, and (d) a mixed liquid discharged from the reciprocating jet reactor Without breaking bubbles
An activated sludge treatment apparatus comprising means for supplying activated sludge to a treatment tank without separation. (A) A plurality of perforated disks are disposed in a tank, and a driving device for reciprocating the perforated disks up and down is provided. The raw water, air and activated sludge in the tank are mixed to remove the raw water. A reciprocating jet reactor to be treated, (b) means for supplying raw water to the reciprocating jet reactor, (c) means for supplying air to the reciprocating jet reactor, and (d) a mixed liquid discharged from the reciprocating jet reactor Without breaking bubbles
Further, an activated sludge treatment apparatus comprising: means for supplying activated sludge to a treatment tank without separation; and (e) means for returning activated sludge from the treatment tank to the reciprocating jet reactor.