KR101334273B1 - Processing apparatus for organic waste water by aerobic and anaerobic microbes using micro-air bubble and ciculation - Google Patents

Abstract

The present invention relates to an apparatus for treating organic wastewater by using aerobic and anaerobic microbes. The purpose of the present invention is to enhance the treatment efficiency of organic wastewater by including both of an aerobic reactor and an anaerobic reactor in a small space and forming air bubbles in the process of supplying air to the end part of an inflow pipe for wastewater. For the purpose, the present invention provides an apparatus for treating organic wastewater by using aerobic and anaerobic microbes, comprising a storage tank (9) for storing organic wastewater; an inflow pipe (7) for wastewater; an aerobic reactor (1) for treating organic wastewater with aerobic microbes by including a circulatory guide (12) for aerobic wastewater; an anaerobic reactor (2) for treating organic wastewater with anaerobic microbes by including a guide (15) for anaerobic wastewater; an outlet (17) for discharging treated wastewater; and a cover (18), wherein the inflow pipe (7) for wastewater included in the circulatory guide (12) for aerobic wastewater has an end part formed in the veturi form of which the cross section decreases; an inflow pipe (11) for air is further included at the end part of the inflow pipe (7) for wastewater to generate air microbubbles by injecting air; and the circulatory pipe (6) for wastewater connected to the connection part (8) of the inflow pipe (7) for wastewater and a circulation pump (5) for supplying the wastewater treated by aerobic microbes to the connection part (8) of the inflow pipe (7) for wastewater are further included on the top of the aerobic reactor (1).

Description

Processed Apparatus for Organic Waste Water by Aerobic and Anaerobic Microbes Using Micro-Air Bubble and Ciculation}

The present invention relates to an aerobic and anaerobic microorganism treatment apparatus for organic wastewater, and more particularly, to maximize the growth rate of aerobic microorganisms in an aerobic reactor in an apparatus for treating organic wastewater by using aerobic and anaerobic microorganisms simultaneously By generating fine air bubbles and circulating the treated water in the aerobic reactor again with a circulation pump to increase contact with the aerobic microorganisms to increase the efficiency of organic matter treatment in a narrow space, while at the same time to remove the organic matter that the aerobic microorganisms did not process The present invention relates to an aerobic and anaerobic microbial treatment apparatus for organic wastewater that is to be discharged after treatment in an anaerobic reactor.

The treatment method of organic wastewater can be roughly divided into a method using an aerobic microorganism and a method using an anaerobic microorganism.

Reactive sludge method is a representative method of the aerobic microorganism treatment method.

The activated sludge process has an aeration tank for storing aerobic microorganisms, and requires a large space for the aerobic microorganisms to survive.

In addition, the activated sludge process must supply a large amount of oxygen for the growth of aerobic microorganisms. Accordingly, there is a disadvantage in that the cost of installing and driving the oxygen supply pipe is high.

On the other hand, in the anaerobic microorganism treatment method, there is a disadvantage to secure a closed space in order to increase the growth rate of anaerobic microorganisms.

The conventional aerobic and anaerobic microorganism treatment method requires a large area because it requires a lot of space, there is a problem that a lot of construction costs and expensive facility operation costs.

In addition, the conventional aerobic and anaerobic microbial treatment method, although the chemical oxygen demand (COD) and the biological oxygen demand (BOD) in organic wastewater is reduced, in order to process nitrogen components, a separate treatment process There is a problem that requires.

The present invention is to solve the above problems of the prior art, an object of the present invention is to provide an aerobic reactor and anaerobic reactor in a small space at the same time to maximize the treatment efficiency of organic wastewater to efficiently treat have.

Another object of the present invention, by injecting air to the end of the treated water inlet pipe to form fine air bubbles, by further miniaturizing the growth of aerobic microorganisms by air bubbles.

Still another object of the present invention is to make it possible to easily form fine air bubbles by separately forming a pipe into which organic wastewater is introduced and a pipe into which air is introduced.

Another object of the present invention is to improve the contact between microbubbles and aerobic microorganisms by circulating organic wastewater in an aerobic reactor to form a flow of organic wastewater in a small space into turbulent flow.

Still another object of the present invention is to make it possible to easily treat nitrogen components contained in organic wastewater.

Another object of the present invention is to improve the oxygen transfer rate and oxygen utilization rate to improve the concentration of aerobic microorganisms in an aerobic reactor.

It is still another object of the present invention to increase the contact opportunities of aerobic microorganisms and treated water in an aerobic reactor without installing a separate stirrer in the aerobic reactor.

Still another object of the present invention is to stably supply treated water treated in an aerobic reactor to an anaerobic reactor so that organic matter can be efficiently treated by anaerobic microorganisms.

Still another object of the present invention is to make construction easy and maintenance easy without requiring a large area.

Still another object of the present invention is to make it possible to easily remove odor generated in the aerobic reactor and the anaerobic reactor.

In order to achieve the above object, the present invention provides a storage tank in which organic wastewater is stored, a treated water inlet pipe for supplying the organic wastewater to an aerobic reactor, and aerobic treated water circulation guide provided at the center of the microbial treatment apparatus. An aerobic reactor for treating organic wastewater by aerobic microorganisms, an anaerobic reactor provided on the outer periphery of the aerobic reactor and equipped with an anaerobic treated water guide to treat organic wastewater by anaerobic microorganisms, and treated water treated in the anaerobic reactor In the aerobic and anaerobic microorganism treatment apparatus for organic wastewater comprising an outlet for discharging, and a lid covering the upper portion of the aerobic reactor and anaerobic reactor, the treated water inlet pipe provided in the aerobic treated water circulation guide, Venturi rudder whose end is reduced in cross section Is formed in, the end of the treated water inlet pipe, the air inlet pipe for injecting air to generate fine air bubbles is further provided, the upper portion of the aerobic reactor, connected to the confluence of the treated water inlet pipe A treatment water circulation pipe and a circulation pump for supplying the treatment water treated by the aerobic microorganism to the confluence of the treatment water inflow pipe are further provided.

In addition, the treatment water inlet pump is further provided in front of the confluence of the treatment water inlet pipe.

In addition, the treated water treated by the aerobic reactor is characterized in that it is raised to the top between the aerobic treated water circulation guide, and then lowered again to be supplied to the anaerobic reactor.

In addition, a plurality of supports are provided between the aerobic treatment water circulation guide and the anaerobic treatment water guide for supporting it.

In addition, the upper portion of the lid is further provided with a gas pipe for discharging the gas, characterized in that the odor generated in the aerobic reactor and anaerobic reactor is treated by the odor removal device.

In addition, a stirrer is further provided on the bottom of the anaerobic reactor.

In addition, the treated water inlet pipe is installed in a plurality of aerobic treatment water circulation guide, the treated water inlet pipe is characterized in that each of the air inlet pipe is formed.

In addition, the treated water inlet pipe is characterized in that a plurality of air inlet pipe is formed.

According to the present invention, since the aerobic reactor and the anaerobic reactor are simultaneously provided in a small space, the biological treatment efficiency is maximized, and as a result, the treatment efficiency of the organic wastewater can be increased.

In addition, by injecting air to the end of the treated water inlet pipe together with the supply of the treated water to form fine air bubbles, there is an effect that can further activate the growth of aerobic microorganisms by the micro air bubbles.

In addition, since the pipe in which the organic wastewater is introduced and the pipe in which the air is introduced are provided separately, there is an effect of easily forming fine air bubbles.

In addition, by circulating the organic wastewater in the aerobic reactor by the circulation pump to form the flow of the organic wastewater into turbulent flow, there is an effect that can improve the contact between the fine air bubbles and aerobic microorganisms.

In addition, there is an effect that can easily treat the nitrogen component contained in the organic wastewater.

In addition, it is possible to improve the oxygen transfer rate and the oxygen utilization rate to improve the concentration of aerobic microorganisms in the aerobic reactor.

In addition, there is no need to install a separate stirrer in the aerobic reactor, there is an effect that can increase the contact opportunity of the aerobic microorganism and the treated water in the aerobic reactor.

In addition, by allowing the treated water treated in the aerobic reactor to stably flow into the anaerobic reactor, there is an effect that the organic matter can be efficiently removed by the anaerobic microorganisms.

In addition, there is an effect that does not require a large land area, the construction is easy and the maintenance is convenient.

In addition, there is an effect that can easily remove the odor generated in the aerobic reactor and anaerobic reactor.

1 is a view schematically showing an aerobic and anaerobic microorganism processing apparatus according to the present invention.
2 is a view showing an example of the air bubble generating unit according to the present invention.
3 is a view showing another example of the bubble generation unit according to the present invention.
4 is a view showing another example of the bubble generation unit according to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The aerobic and anaerobic microorganism processing apparatus according to the present invention, as shown in Figure 1, the storage tank (9) in which the organic wastewater is stored, and the treated water inlet pipe (7) for supplying the organic wastewater to the aerobic reactor (1) And an aerobic reactor (1) provided at the center of the microbial processing apparatus and equipped with an aerobic treated water circulation guide (12) for treating organic wastewater by aerobic microorganisms, and on the outer periphery of the aerobic reactor (1). An anaerobic reactor (2) having a water guide (15) for treating organic wastewater by anaerobic microorganisms, an outlet (17) for discharging the treated water treated in the anaerobic reactor (20), and the aerobic reactor (1) And a lid 18 covering the top of the anaerobic reactor 2.

That is, the aerobic reactor 1 is provided at the center of the microbial processing apparatus according to the present invention, and the anaerobic reactor 2 is integrally provided at the outer circumference thereof. Accordingly, the treatment efficiency of organic wastewater can be improved by simultaneously using aerobic and anaerobic microorganisms.

A first cover 1 ′ is provided between the upper portion of the aerobic reactor 1 and the lid 18 to supply the treated water treated in the aerobic reactor 1 to the anaerobic reactor 2.

In addition, an outlet 17 for discharging the treated water treated in the anaerobic reactor is provided between the upper portion of the anaerobic reactor 2 and the lid 18.

Here, an end portion of the treated water inflow pipe 7 provided in the aerobic treated water circulation guide 12 is formed in a venturi type whose cross section is reduced as shown in FIG. 2.

In addition, an end portion of the treated water inlet pipe 7 is further provided with an air inlet pipe 11 for generating air bubbles by injecting air from the outside.

With the above structure, minute air bubbles are formed in the air bubble generating unit 3 which is the end of the treated water inlet pipe 7. Thereby, the contact with aerobic microorganisms can be increased to improve the treatment efficiency of organic wastewater by aerobic microorganisms.

In addition, the upper portion of the aerobic reactor (1), as shown in Figure 1, by the treated water circulation pipe (6) connected to the confluence portion 8 of the treated water inlet pipe (7) and by aerobic microorganisms A circulation pump 5 for supplying the treated water to the confluence 8 of the treated water inlet pipe 7 is provided.

The above-mentioned confluence unit joins the organic wastewater before the microbial treatment and the treated water treated by the aerobic microorganisms (hereinafter referred to collectively as 'treated water' for the organic wastewater before the microorganism treatment and the treated water after the microorganism treatment). It is fed back to the aerobic reactor (1).

The storage tank 9 may be provided at the top of the microbial processing apparatus so as to be naturally supplied to the aerobic reactor 1 by the potential energy, and as shown in FIG. 1, the confluence of the treated water inflow pipe 7 is shown. (8) A treatment water inflow pump 4 may be further provided in front.

As shown in FIG. 1, the treated water treated by the aerobic reactor 1 rises upward between the aerobic treated water circulation guides 12 and 12 ′, and then rides the anaerobic treated water guide 15. It descends again and is supplied to the anaerobic reactor 2.

By the above structure, the fine air bubbles generated in the aerobic reactor 1 almost disappear while rising upward, and the anaerobic reactor 2 is supplied with treated water in a state of little oxygen. Thereby, the processing efficiency by the anaerobic microorganisms in the anaerobic reactor 2 can be improved.

In addition, between the aerobic treatment water circulation guide 12 and the anaerobic treatment water guide 15, a first support 13, a second support 14, and a third support 16 for supporting them are provided. .

As shown in FIG. 1, the first support 13 is provided between the aerobic treatment water circulation guides 12 and 12 ′, and the second support 14 is the outer aerobic treatment water circulation guide 12 ′. ) And the anaerobic treated water guide 15, and the third support 16 is provided between the anaerobic treated water guide 15 and the outer wall 22 of the microbial treatment apparatus.

By the above first to third supports, the aerobic treatment water circulation guide 12 (12 ') and the anaerobic treatment water guide 15 are kept in a fixed state.

In addition, the upper portion of the lid 1 may be further provided with a gas pipe 20 and the odor removing device 21 for discharging the gas.

The gas pipe 20 is provided with a gas outlet 19 to discharge the odor generated in the aerobic reactor 1 and the anaerobic reactor 2 to the outside of the microorganism treatment device, the odor removal device 21 in the activated carbon, etc. Eliminate odors by

In addition, in the treated water inlet pipe 7, as shown in FIG. 3, a plurality of air inlet pipes 11 may be formed. According to this structure, the generation amount of air bubbles can be further increased.

In addition, as shown in FIG. 4, a plurality of treated water inflow pipes 7 may be provided in the aerobic treated water circulation guide 12 and 12 ′. In this case, it is preferable to form one air inlet pipe 11 in the treated water inlet pipe 7.

Hereinafter will be described the effect of the aerobic and anaerobic microorganism treatment apparatus according to the present invention.

First, the organic wastewater stored in the storage tank 9 is supplied into the aerobic reactor 1 through the treated water inlet pipe 7. In this case, the organic wastewater may be pumped into the treated water inflow pump 4.

In order to improve the treatment efficiency in the aerobic reactor 1, it is preferable to supply abundant dissolved oxygen to activate the aerobic microorganisms.

To this end, the fresh air is blown to the air inlet pipe 11 connected to the end of the treated water inlet pipe 7 through the air inlet 10. Blowing of the air may be performed by a blower (not shown) or an oxygen supply device.

Since the end portion of the treated water inlet pipe 7 is formed in a venturi type, the flow rate of the treated water is increased at the end of the treated water inlet pipe 7.

When air is supplied from the outside in this state, fine air bubbles are formed in the air bubble generating unit 3 which is an end of the treated water inlet pipe 7.

The aerobic microorganisms in the aerobic reactor 1 can be activated by the above fine air bubbles, and the growth rate of the aerobic microorganisms can be increased to increase the number of microorganisms. Accordingly, the treatment efficiency by aerobic microorganisms in the aerobic reactor 1 can be maximized.

The fine air bubbles generated by the air bubble generating unit 3 descend down to the lower side of the aerobic treated water circulation guide 12 along with the treated water, and then ride the aerobic treated water circulation guide 12 'outside. It disappears while moving upwards.

 Most of the treated water moved to the upper side through the aerobic treated water circulation guide 12 ′ of the outer part is moved to the treated water inlet pipe 7 through the treated water circulation pipe 6, and then again inside the aerobic reactor 1. Is supplied.

In addition, the new organic wastewater is supplied through the treated water inlet pipe 7, and the new organic wastewater is joined with the treated water at the confluence unit 8 and then supplied again into the aerobic reactor 1.

A part of the treated water moved upward by riding the outer aerobic treated water circulation guide 12 ′ is fed back to the anaerobic reactor 2 via the anaerobic treated water guide 15.

That is, as shown in FIG. 1, since the outside of the aerobic treated water circulation guide 12 ′ and the anaerobic treated water guide 15 is narrow, most of the treated water passes through the treated water circulation pipe 6. It is circulated back into the aerobic reactor 1 and only a part of treated water is supplied to the anaerobic reactor 2.

In this process, most of the air bubbles in the treated water are extinguished and the treated water without air bubbles is supplied to the anaerobic reactor 2. Thereby, in the anaerobic reactor 2, the treatment efficiency of organic matter by anaerobic microorganisms can be improved.

The treated water treated by the anaerobic microorganisms in the anaerobic reactor 2 is moved upward through the anaerobic treated water guide 15 and then discharged to the outside through the outlet 17.

At this time, the bottom of the anaerobic reactor 2 may be further provided with a stirrer 23 to facilitate the discharge of the anaerobic treated water.

On the other hand, the odor generated during aerobic and anaerobic treatment is supplied to the odor removing device 21 through the gas pipe 20 to be treated, and the sludge accumulated on the bottom is removed once or twice a year.

According to the present invention, the size can be reduced by providing the aerobic reactor 1 at the center and arranging the anaerobic reactor 2 at its outer circumference, and the majority of the treated water treated by the aerobic reactor 1 is again aerobic reactor. (1) Since the structure is circulated inside, the treatment efficiency of organic wastewater can be improved.

In addition, the treatment efficiency by the aerobic microorganisms in the aerobic reactor 1 by the fine air bubbles can be increased, and the treatment efficiency by the anaerobic microorganisms can also be increased by supplying the treated water without air bubbles to the anaerobic reactor 2. have.

In addition, since the treated water continuously circulates, it is not necessary to provide a separate stirrer in the aerobic reactor, and the contact between the aerobic microorganism and the treated water can be improved in the aerobic reactor.

In addition, there is an advantage that can save the construction cost and operating cost without requiring a large area.

According to the conventional aerobic treatment method, the oxygen transfer rate in the aeration tank ranges from 0.01 to 0.06 KgO ₂ / m ₃ .hr, but according to the present invention, the oxygen transfer rate is increased by about 50 times by supplying air bubbles, 0.5 to 3.0 KgO ₂ / m 3. hr.

In addition, the oxygen utilization rate in the conventional aeration tank was 5-11%, but the experimental results according to the present invention confirmed that the oxygen utilization rate is 50% or more.

In addition, the concentration of microorganisms in the aeration tank of the conventional aerobic treatment method was about 4,500 mg / L, but according to the present invention, the concentration of microorganisms (MLSS: Mixed Liquor Suspended Solid) in the aerobic reactor was 6,000 to 15,000 mg / L due to the high oxygen transfer rate. It appeared to increase.

In addition, although the volume load with respect to the chemical oxygen demand (COD) in the conventional aeration tank was 0.5 ~ 1KgCOD / ㎥.day, according to the present invention, the contact efficiency of the aerobic microorganism and the treated water in the aerobic reactor is improved, the chemical oxygen demand The volume loading for (COD) increased from 10 to 45 times from 5 to 45 KgCOD / ㎥.day.

In addition, the volume loading of total nitrogen (Total Nitrogen: NH) in the conventional aeration tank was 0.05 to 0.1 KgN-H / ㎥.day, but according to the present invention, the volume loading of total nitrogen was increased from 2 to 9 times from 0.1 to It was found to be 0.9KgN-H / m 3 .day.

The foregoing description of preferred embodiments of the present invention has been provided for purposes of illustration and description. Those skilled in the art will appreciate that various changes and modifications are possible within the scope of the technical idea of the present invention.

1: aerobic reactor 2: anaerobic reactor
3: air bubble generation unit 4: treated water inflow pump
5: circulation pump 6: treatment water circulation pipe
7: Treatment water inflow pipe 8: confluence
9: storage tank 10: air inlet
11: Air inlet line 12, 12 ': Aerobic treatment water circulation guide
13: 1st support 14: 2nd support
15: Anaerobic Treatment Water Guide 16: Third Support
17: outlet 18: lid
19: gas outlet 20: gas piping
21: odor removal device 22: outer wall
23: stirrer
A: Treated Water B: Air
C: air bubbles

Claims (8)

A storage tank 9 for storing organic wastewater, a treated water inlet pipe 7 for supplying the organic wastewater to the aerobic reactor 1, and aerobic treated water circulation guide 12 are provided in the center of the microbial processing apparatus. Anaerobic reactor (1) for treating organic wastewater by aerobic microorganisms, and an anaerobic reactor (1) provided on the outer periphery of the aerobic reactor (1) and equipped with an anaerobic treated water guide (15) to treat organic wastewater by anaerobic microorganisms ( 2) an organic wastewater comprising an outlet 17 for discharging the treated water treated in the anaerobic reactor 20, and a lid 18 covering the upper portion of the aerobic reactor 1 and the anaerobic reactor 2. In the aerobic and anaerobic microorganism processing apparatus of
The treatment water inflow pipe 7 provided in the aerobic treatment water circulation guide 12 is formed in a venturi type, the end of which is reduced in cross section,
At the end of the treated water inlet pipe 7 is further provided with an air inlet pipe 11 for injecting air to generate fine air bubbles,
On top of the aerobic reactor 1,
A treated water circulation pipe 6 connected to the confluence part 8 of the treated water inlet pipe 7,
A circulation pump 5 is further provided for supplying the treated water treated by the aerobic microorganisms to the confluence part 8 of the treated water inlet pipe 7 again.
Between the aerobic treatment water circulation guide 12 and the anaerobic treatment water guide 15 is provided with a plurality of supports (13, 14, 16) for supporting it by the fine air bubbles and treatment water circulation Aerobic and anaerobic microbial treatment apparatus for organic wastewater. The method of claim 1,
An aerobic and anaerobic microbial treatment apparatus for organic wastewater by micro air bubbles and treated water circulation, characterized in that the treatment water inlet pump (4) is further provided in front of the confluence (8) of the treated water inlet pipe (7). The method of claim 1,
The treated water treated by the aerobic reactor 1 rises upward between the aerobic treated water circulation guides 12 and 12 ′, and then descends again through the anaerobic treated water guide 15 to the anaerobic reactor 2. Aerobic and anaerobic microbial treatment apparatus for organic wastewater by microbubbles and treated water circulation, characterized in that is supplied to. delete The method of claim 1,
The upper portion of the lid 18 is further provided with a gas pipe 20 for discharging the gas, the odor generated in the aerobic reactor (1) and anaerobic reactor (2) is treated by the odor removal device (21) An aerobic and anaerobic microbial treatment apparatus for organic wastewater by microbubbles and treated water circulation. The method of claim 1,
An aerobic and anaerobic microorganism treatment apparatus for organic wastewater by microbubbles and treated water circulation further comprising a stirrer (23) on the bottom of the anaerobic reactor (2). The method according to any one of claims 1 to 3, 5 to 6,
The treated water inlet pipe (7) is provided in plurality in the aerobic treatment water circulation guide 12, the treated water inlet pipe (7) is characterized in that the air inlet pipe (11) is formed, respectively, Aerobic and anaerobic microbial treatment apparatus for organic wastewater by treatment water circulation. The method according to any one of claims 1 to 3, 5 to 6,
Aerobic and anaerobic microorganism treatment apparatus for organic wastewater by the fine air bubbles and treated water circulation, characterized in that a plurality of air inlet pipe (11) is formed in the treated water inlet pipe (7).

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