KR200194171Y1 - Apparatus for treating wastewater - Google Patents

Abstract

The present invention is composed of anaerobic tank, anaerobic tank, aerobic tank and sedimentation tank, and activated sludge precipitated in the sedimentation tank is returned to the aerobic tank, and a portion of the treated water treated in the aerobic tank is returned to the anaerobic tank, and activated sludge in the conventional sewage treatment facility composed of only an aerobic tank. Not only does not change the conveying line, but also by installing only the partition wall using the PE panel in the existing aerobic tank relates to a wastewater treatment device that can be separated into anaerobic tank and anoxic tank and can be highly treated nitrogen and phosphorus.

The wastewater treatment apparatus of the present invention is composed of an anaerobic tank (1), an anaerobic tank (2), an aerobic tank (3), and a settling tank (5), and returns sludge deposited in the settling tank (5) to the aerobic tank (3). In addition, a dissolved oxygen reduction tank (4) is installed in the aerobic tank to carry out the internal transport to an anaerobic tank.

Influent for wastewater treatment is introduced into the anaerobic tank (1), the treated water treated in the anaerobic tank (1) is transferred to the anaerobic tank (2), a part of the treated water in the anaerobic tank (2) to the anaerobic tank to remove phosphorus The remaining water is returned to the aerobic tank 3 and the treated water treated in the aerobic tank 3 is partially returned to the anoxic tank 2 for the removal of nitrogen and a part is transferred to the settling tank 5. PAOs are transported internally to the anaerobic tank to release a large amount of phosphorus, and excess phosphorus is ingested in the aerobic tank to remove phosphorus, and ammonia nitrogen is converted to NO _x using nitrifying bacteria in the aerobic tank. Denitrification using denitrification bacteria in 2). In the settling tank 5, sludge is settled and the purified water is discharged to the outside, and a part of the sludge is supplied to the aeration tank 3 through the conveying line 6 again.

By passing the water returned from the aerobic tank 3 to the anaerobic tank 2 through the dissolved oxygen reduction tank 4 in the middle, the dissolved oxygen in the returned water is removed to improve the treatment efficiency in the anoxic tank 2.

Description

Apparatus for treating wastewater

The present invention relates to an advanced biological treatment device for wastewater. More specifically, it consists of anaerobic tank, anoxic tank, aerobic tank and sedimentation tank, the sludge precipitated in the sedimentation tank is returned to the aerobic tank, and a portion of the treated water in the aerobic tank is returned to the anaerobic tank, and the anaerobic tank is composed of only the aerobic tank by returning The present invention relates to a wastewater treatment apparatus capable of advanced treatment of wastewater without changing the return line in a conventional sewage treatment facility.

The conventional sewage treatment apparatus consists of only an aerobic tank, and the treated water treated in the aerobic tank is discharged after being precipitated in the sedimentation tank. However, this sewage treatment method has a low removal efficiency of nitrogen and phosphorus, which is a major factor of eutrophication when discharged into rivers.

In order to solve this problem, A ² / O sewage treatment, which consists of anaerobic tank, anaerobic tank and aerobic tank, has been developed and used. The A ² / O method installs anaerobic and anaerobic tanks in all stages of the aerobic tank, returns the treated water from the aerobic tank back to the anaerobic tank to remove nitrate nitrogen, and returns some of the activated sludge precipitated in the settling tank to the anaerobic tank. In addition to maintaining a constant microbial concentration, phosphorus is removed by releasing phosphorus in an anaerobic state and ingesting excess phosphorus in a subsequent aerobic bath.

However, this conventional method not only lowers the denitrification efficiency in the anoxic tank by returning oxygen dissolved in the process of returning the treated water treated in the aerobic tank to the anoxic tank, but is also active in order to apply it to the conventional sewage treatment apparatus composed of the aerobic tank alone. There is a problem that the sludge return line must be reinstalled.

It is an object of the present invention to provide a wastewater treatment apparatus capable of highly treating wastewater by adding an anaerobic tank and an anaerobic tank without modifying an activated sludge return line in a conventional sewage treatment apparatus composed of only an aerobic tank.

Another object of the present invention is to provide a wastewater treatment apparatus capable of increasing the treatment efficiency in the anaerobic tank by reducing the dissolved oxygen when conveying from the aerobic tank to the anoxic tank.

1 is a plan view of a wastewater treatment apparatus of the present invention.

2 to 4 is a plan view of another embodiment of the wastewater treatment apparatus of the present invention. Fig. 5 is a perspective view of an aerobic tank provided with a PE panel. Fig. 6 is a perspective view of an aerobic tank in which several PE panels are installed vertically.

<Description of the symbols for the main parts of the drawings>

1: anaerobic tank 2: anaerobic tank

3: aerobic tank 4: dissolved oxygen reduction tank

5: sedimentation tank 6: sludge return line

7: Aerobic Treatment Water Return Line 8: Bulkhead

9: anoxic treatment water return line

Wastewater treatment apparatus of the present invention is composed of anaerobic tank (1), anoxic tank (2), aerobic tank (3) and settling tank (5), the components are the same as the conventional A ² / O wastewater treatment apparatus. However, the conventional A ² / O wastewater treatment apparatus conveyed the activated sludge precipitated in the sedimentation tank (5) to the anaerobic tank, in the present design there is a difference in returning it to the aerobic tank (3).

Is introduced into the influent anaerobic tank (1) for treatment of waste water, and mixed in a mixer in the anaerobic tank (1) and at the same time to remove organic matter (BOD) by PAOs (Phosphorus Accumulating Organisms) which ingest going microorganism (PO ₄ ^{- -} P) is released, increasing the concentration of phosphorus in the bath. The treated water treated in the anaerobic tank 1 is transferred to the anoxic tank 2, and in the anoxic tank 2, the nitrogen and organics are removed by denitrification while being mixed by a mixer. The treated water treated in the anaerobic tank 2 is transferred to the aerobic tank 3 and a part of the treated water is returned to the anaerobic tank via the anaerobic tank treated water conveying line 9. As the treated water from which the NO _x is removed in the anaerobic tank is returned to the anaerobic tank, the phosphorus emission suppression by NO _x does not occur in the anaerobic tank, so that the final phosphorus removal efficiency is improved. In the aerobic tank 3, compressed air is blown from the bottom to supply oxygen to remove residual organic matter and ammonia nitrogen. The treated water treated in the aerobic tank 3 is partially returned to the anoxic tank 2 and part is returned to the settling tank 5 for the removal of nitrogen. In the settling tank 5, sludge is settled and the purified water is discharged to the outside, and a part of the activated sludge is supplied to the aeration tank 3 through the conveying line 6 again.

FIG. 2 is a plan view of another embodiment of the present invention, in which an oxygen-free tank is reduced by reducing the dissolved oxygen in the conveyed water by passing the dissolved oxygen-reducing tank 4 in the middle of the conveyed water returned from the aerobic tank 3 to the anoxic tank 2. The processing efficiency in 2) is improved.

Dissolved oxygen reduction tank (4) is installed in the inner corner of the exhalation tank (3) or is installed separately, unlike the exhalation tank (3) by installing a discharge line on the floor without injecting compressed air to extract the treated water near the bottom Transfer it to the anaerobic tank (2).

Since the height of the water tank wall surface of the dissolved oxygen reduction tank 4 is formed to be slightly lower than the level of the aerobic tank 3, the treated water flows into the dissolved oxygen reduction tank 4 from the aerobic tank 3 and the dissolved oxygen reduction tank 4 Since the transfer line 7 is installed at the bottom and the treated water is pumped up from the bottom, the treated water flowing into the dissolved oxygen reduction tank 4 gradually moves to the lower side of the dissolved oxygen reduction tank 4 and reduces the dissolved oxygen. Since the compressed air is not injected into the tank 4, the amount of dissolved oxygen gradually decreases in the process of moving downward of the dissolved oxygen reduction tank 4. Therefore, when flowing into the oxygen-free tank 2, the oxygen in the treated water is consumed almost so that the dissolved oxygen is injected in a state where there is little dissolved oxygen. In the denitrification process, NO _x is used as the electron acceptor. At this time, when dissolved oxygen is introduced, it is advantageous to use dissolved oxygen in terms of energy generation, and thus, denitrification efficiency is lowered. Therefore, as the dissolved oxygen reduction tank 4 is installed, the dissolved oxygen does not flow into the oxygen-free tank 2, thereby improving the nitrogen removal efficiency.

A nozzle is installed at the distal end of the conveying line 7 connected from the dissolved oxygen reduction tank 4 to the anaerobic tank 2 and the anaerobic tank 2 from the anaerobic tank 2, and the return water injected by the pump is removed. 2) and by spraying into the anaerobic tank (1) can be mixed without a separate mixing device.

Fig. 5 makes it possible to form a dissolved oxygen reduction tank 4 by providing a partition wall in the inner corner of the exhalation tank 3, and a PE panel can be used as the partition wall member. Dissolved oxygen reduction tank (4) is completed by caulking two angles on the corner wall surface of the aerobic tank (3) at regular intervals and installing the T-shaped and inserting a PE panel in the space between the angles. When using the PE panel can be quickly installed in the existing aerobic tank, PE panel has the advantages of waterproof and durable. Figure 6 can be installed by connecting a plurality of members of a wide width and a low height vertically without using the PE panel as a single large member, thereby adjusting the height of the dissolved oxygen reduction tank (4).

FIG. 3 illustrates a plug flow in the anaerobic tank 1 and the anaerobic tank 2 by forming a plurality of partitions 8 vertically in the anaerobic tank 1 and the anaerobic tank 2 in the embodiment of FIG. 1. It would be.

Install a plurality of bulkheads 8 vertically inside the anaerobic tank 1 and the anaerobic tank 2, one side of the bulkhead 8 is in close contact with the side wall of the anaerobic tank 1 or anoxic tank 2, the opposite side to some extent Spaced apart, the plug flow is generated in the anaerobic tank (1) and the anaerobic tank (2) by installing a plurality of partition walls in a zigzag. Plug flow is not only suitable for inducing endogenous respiration of microorganisms compared to complete mixing flow, but also has the advantage of improving the removal efficiency of contaminants through endogenous respiration. Therefore, this plug flow improves the processing speed in the anaerobic tank 1 or the anoxic tank 2 and finally increases the processing efficiency.

The barrier ribs can also be made of PE panels, and two angles are installed between the side walls of the anaerobic tank or anoxic tank and between the ceiling and the floor with a T-shape, and then the PE panels are inserted into the space between the angles, and then caulked. It is also possible to use a plurality of horizontally divided panels.

FIG. 4 is a plan view of a state where the dissolved oxygen reduction tank 4 is installed in the aerobic tank 3 in the embodiment of FIG. 3.

The conventional wastewater treatment system is composed of only an aerobic tank without an anaerobic tank or an anaerobic tank, transfers the treated water from the aerobic tank to a settling tank, precipitates sludge in the settling tank, discharges it to a stream, and returns a portion of the activated sludge back to the aerobic tank. . However, this method does not sufficiently remove nitrogen or phosphorus, which causes eutrophication of the stream. In order to solve this problem, an anaerobic tank and an anaerobic tank should be added to the front stage of the aerobic tank and the activated sludge return line should be connected to the anaerobic tank in the sedimentation tank.However, in order to reconnect the return line, it requires a lot of cost and effort. There is a problem that the operation must be temporarily stopped. However, the present invention conveys the sludge from the sedimentation tank to the aerobic tank, so the conventional wastewater treatment apparatus does not need to pipe the conveying line again, so the work is very easy, and the wastewater treatment apparatus does not need to be stopped. have.

In addition, by installing the dissolved oxygen reducing tank in the middle of conveying from the aerobic tank to the anoxic tank, the amount of dissolved oxygen flowing into the anoxic tank can be reduced, thereby improving the treatment efficiency in the anoxic tank. In addition, unlike the existing A ² / O process, the internal transport from the anaerobic tank to the anaerobic tank does not inhibit the release of phosphorus to NO _x in the anaerobic tank, and thus, the phosphorus intake rate is improved in the aerobic tank, resulting in excellent phosphorus removal efficiency.

In addition, by installing a zigzag partition wall inside the anaerobic tank and the anaerobic tank, it is possible to improve the treatment efficiency in the anaerobic tank and the anaerobic tank.

Claims (7)

An anaerobic tank (1) for treating the introduced wastewater by anaerobic bacteria; An anaerobic tank (2) for treating the treated water treated in the anaerobic tank (1) with denitrification bacteria and then returning part of the treated water to the anaerobic tank (1); An aerobic tank (3) for returning the treated water treated in the anoxic tank (2) to the anoxic tank (2) after the treatment with aerobic bacteria; And, A settling tank 5 which precipitates the treated water in the exhalation tank 3 and then discharges the purified water and returns a portion of the precipitate to the exhalation tank 2 through a transfer line 6; Waste water treatment apparatus, characterized in that consisting of. 2. The treated water of claim 1, wherein the return water returned from the aerobic tank 3 to the anoxic tank 2 flows into the dissolved oxygen reducing tank 4 in the middle to reduce dissolved oxygen in the dissolved oxygen reducing tank 4. Waste water treatment apparatus characterized in that for conveying to the anaerobic tank (2) through the conveying line (7). 3. The nozzle of claim 2, wherein a nozzle is attached to a tip of the conveying line 7 connected to the anaerobic tank 1 in the conveying line 7 or the anoxic tank 2 connected to the anaerobic tank 2 in the dissolved oxygen reducing tank 4; Waste water treatment apparatus characterized by mixing with the treated water in the anaerobic tank (2) or anaerobic tank (1) by the pressure of the pump. The anaerobic tank (1) and the anaerobic tank (2), one side perpendicular to the inside of the anaerobic tank (1) or the anaerobic tank (2) in close contact with the other side of the anaerobic tank according to any one of claims 1 to 3. (1) or a plurality of partitions (8) spaced apart from the wall surface of the anoxic tank (2) by zigzag to generate a plug flow to the treated water in the anaerobic tank (1) and the anoxic tank (2) Wastewater treatment device. 5. The dissolved oxygen removal tank (4) or the partition wall (8) has two angles vertically between the wall and the ceiling and the floor of the aerobic tank (3), anaerobic tank (1) or anoxic tank (2). It is installed in the shape of a waste water treatment apparatus characterized in that the PE panel is inserted into the space between the angle and the joint is produced by caulking. The wastewater treatment apparatus according to claim 5, wherein the PE panel is installed by connecting several sheets divided horizontally. The wastewater treatment apparatus according to claim 1, wherein the anaerobic tank and the anaerobic tank are formed by installing a partition wall with a PE panel in an aerobic tank of an existing wastewater treatment apparatus.