KR19990075290A - Sewage Nutrients - Google Patents

Abstract

In the present invention, the wastewater purification apparatus is provided with a denitrification chamber 10, a nitrification chamber 20, and a precipitation chamber 30 in a single tank, thereby reducing facility installation costs and reducing the area of the denitrification chamber 10 and nitrification. The chamber 20 is partitioned independently by the partition plate 23 so that the microorganisms that perform the functions in each chamber can be accelerated while maintaining high concentration, so that the sewage treatment efficiency is improved, and the sewage is circulated separately. As a blower 51 achieves aeration, sewage transfer and agitation without the need for a pump, the circulation of sewage is smoothly achieved, thereby reducing power and maintenance costs for the operation of the sewage treatment facility, and reducing the denitrification chamber ( 10) and the nitrification chamber 20 is divided into two parts up and down to increase the volume of each chamber, and since the sewage flowing into the denitrification chamber 10 overflows the overflow wall 12 and is transferred to the nitrification chamber 20, Increased retention time of sewage It is directed to a nutrient removal system at a sewage which can efficiently remove the nutrients of the nitrogen contained in the wastewater and indeung.

Description

Sewage Nutrients

The present invention relates to a device for removing nutrients from sewage, and more particularly, to a device for biologically removing nitrogen and phosphorus, which are eutrophication causes substances contained in wastewater and wastewater, using microorganisms.

Biological removal of nitrogen in sewage is mainly in the form of ammonia nitrogen, and aerobic conditions with dissolved oxygen (DO) by Nitrosomonas or Nitrobacter, which nitrogen is contained in sewage, are nitrifying microorganisms. Is oxidized to nitrite nitrogen (NO ₂ -N) or nitrate nitrogen (NO ₃ -N), which is the oxidizing nitrogen at, and then the nitrogen oxide is reduced by the denitrification microorganism under anoxic conditions without dissolved oxygen. In the form, it is released into the atmosphere to remove nitrogen from the sewage.

Nitric oxide microorganisms consume inorganic carbon as a nutrient source to oxidize ammonia nitrogen to oxidized nitrogen, while denitrified microorganisms consume organic carbon as nutrients and use nitrous oxide as an electron acceptor under anoxic conditions. Reduced to gas to remove nitrogen.

On the other hand, phosphorus-removing microorganisms represented by Acinetobacters release phosphorus in cells while absorbing organic acids such as acetic acid in the body under anaerobic conditions, and nutrients such as organic acids absorbed under anaerobic conditions under aerobic conditions as nutrients. Since the intake of 4-7% of phosphorus is higher than that of 1-2% of the dry weight of normal cells, the sludge containing dephosphorization microorganisms is removed when the dephosphorization microorganisms ingest the phosphorus in aerobic conditions. By discharging to the outside, phosphorus contained in sewage is removed.

The nutrient removal equipment of the sewage according to the prior art for removing the biologically contained nitrogen and phosphorus in the sewage is, as shown in Figure 3, the sedimentation tank (1), anaerobic tank (2), anoxic tank (3), aerobic tank ( 4), consisting of a sedimentation tank (5), sedimentation sediment settled in the sedimentation tank (1) while the influent sewage separated through the anaerobic tank (2), anoxic tank (3), aerobic tank (4) and sedimentation tank (5) in sequence Nitrogen, phosphorus and sludge contained in the sewage are removed and discharged from the settling tank 5, and a part of the sewage passing through the aerobic tank 4 is circulated to the anoxic tank 3 through the pipeline 6 by a pump P ₁ . And, the sludge precipitated in the settling tank (5) is returned to the anaerobic tank (2) through the pipe line 7 by the pump (P ₂ ), a part of the sludge is discharged to the outside through the pipe line (8).

That is, sewage from which sediments and the like supplied from the sedimentation tank 1 has been removed is an anaerobic tank 2 in which no electron acceptors such as DO, NO ₂ , and SO ₂ are present. Phosphorus contained in the cells of the phosphorus removal microorganism is discharged to the body while being stirred with the sludge returned through the sludge, and the ammonia nitrogen contained in the sewage in the aerobic tank (4) is oxidized by the nitrifying microorganisms in the sewage through the anoxic tank (3). Oxygen is oxidized to nitrite nitrogen or nitrate nitrogen, which is natural nitrogen, and a part of it is circulated to the anaerobic tank 3 through the pipe line 6, in the anaerobic tank 3, from the sewage supplied from the anaerobic tank 2 and the aerobic tank 4; As the circulated sewage is stirred, the nitrogen oxides contained in the sewage are reduced by the denitrifying microorganisms and released into the atmosphere in the form of nitrogen gas.

On the other hand, in the aerobic tank (4) as described above, as the sewage introduced from the anoxic tank is aerated, ammonia nitrogen is oxidized to nitrogen oxide, and the phosphorus-removing microorganism is excessively ingested with phosphorus to circulate into the anoxic tank or flow into the settling tank. In 5) sludge is settled, the supernatant is discharged, and the sludge is returned to the anaerobic tank 2 through the pipeline 7 by the pump P ₂ , and the excess sludge is intermittently discharged to the outside through the pipeline 8.

However, the nutrient removal equipment of the sewage is not only requires a lot of installation area because the anaerobic tank (2), anaerobic tank (3), aerobic tank (4) and sedimentation tank (8) are separately manufactured and installed in a separate state from each other. In order to circulate the sewage and to return the sludge, pumps (P ₁ ) and (P ₂ ) are required, and power is required to operate the agitating facilities installed in the anaerobic tank (2) and anoxic tank (3). And maintenance costs were increased.

The present inventor has invented the "organic waste water purification apparatus" filed in Patent Application No. 95-14820 No. 95-14820 to solve the above problems of the prior art.

The prior application discloses an invention which can achieve the functions of the conventional anaerobic tank, anoxic tank, aerobic tank and sedimentation tank by a single septic tank. However, in the above-described invention, the denitrification part (DN) which achieves the function of the anaerobic tank and the nitric oxide part (OX) which achieve the function of the aerobic tank are installed in up and down communication with each other, so that a part of the air supplied to the nitrification part is introduced into the denitrification part. The denitrification effect in the denitrification unit is reduced, and the sewage flowing into the nitrification unit is mixed with the air sent by the blower and is circulated up and circulated through the draft pipe. In the draft pipe, sewage agitation introduced into the denitrification unit (DN) is stirred. There is a problem in that a rotary wheel for rotating the impeller is installed to interfere with the circulation of sewage rising through the draft pipe.

In addition, in the above-described invention, the mixing chamber in which the sewage introduced from the outside and the sewage circulated from the nitrification unit is mixed, and the denitrification unit for denitrifying the mixed sewage is separately partitioned at upper and lower positions, and the structure thereof is not only complicated, but also the volume of the denitrification unit. Since the sewage introduced into the denitrification part is discharged to the nitrification part connected to the lower side, there is a problem in that the retention time of the sewage in the denitrification part is shortened and the nutrient removal efficiency is reduced.

The present invention is to solve the above-mentioned problems of the present invention, so that the structure of the sewage treatment apparatus for removing nitrogen and phosphorus in the sewage while passing the sewage is simple, but the denitrification effect is increased and the circulation of the sewage is made smoothly. The purpose is to provide a sewage nutrient removal device that can further reduce the installation cost, installation area and maintenance cost of the sewage treatment device.

Another object of the present invention is to provide a nutrient removal device for sewage which rotates the stirring means for mixing sewage using sewage circulated without disturbing the circulation of sewage.

1 is a cross-sectional view of the nutrient removal device of sewage according to the present invention

2 is a cross-sectional view taken along the line A-A of FIG.

3 is a view schematically showing a nutrient removal facility of the sewage according to the prior art.

<Explanation of symbols for main parts of drawing>

10: denitrification chamber 11: inner tube

12,32: overflow wall 13: drip tray

14: inlet pipe 15: circulation pipe

20: nitriding chamber 21: riser

23: partition plate 30: sedimentation chamber

31: outer cylinder 34: discharge pipe

40: stirring means 41: pipe part

42: rotor blade 43: stirring blade

50: diffuser 51: blower

The present invention for realizing the above object is composed of an outer cylinder and an inner cylinder located inside the upper side of the outer cylinder, a denitrification chamber is formed in the inner cylinder, and a nitric oxide chamber is formed between the bottom surfaces of the inner and outer cylinders. In the sewage treatment tank in which the settling chamber is formed between the side walls, the inner cylinder is formed of a trumpet-shaped partition plate of upper and lower light beams so that the denitrification chamber and the nitrification chamber are partitioned independently, and the sewage introduced into the denitrification chamber on the upper side of the inner cylinder. The overflowing wall is formed, and a sewage circulation pipe is connected between the inner and outer cylinders so that the sewage passing through the overflow wall is transferred to the nitrification chamber, and a part of the sewage passing through the nitric oxide chamber in the center of the partition plate is denitrified. It is characterized in that the nutrient removal device of the sewage is connected to the riser in the vertical direction to circulate to the thread.

In addition, the present invention is characterized in that the stirring means for rotating around the riser in the denitrification chamber is installed so that the stirring means is rotated by the sewage passing through the outlet side of the riser.

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

1 and 2, the present invention is composed of an outer cylinder 31, and an inner cylinder 11 installed inside the upper side of the outer cylinder 31, wherein the inner and outer cylinders 11 and 31 have a cross-section. It is manufactured to have a spherical or square shape.

A bottom partition of the inner cylinder 11 is attached to the trumpet-shaped partition plate 23 of upper and lower light, so that the inner and outer cylinders 11 and 31 are partitioned independently so that the denitrification chamber 10 is formed in the inner cylinder 11. The nitric oxide chamber 20 is formed between the partition plate 23 and the bottom face of the outer cylinder 31.

The inner cylinder 11 is connected to the inlet pipe 14 through which the sewage flows into the denitrification chamber 10, and a side wall of the inner cylinder in which the overflow wall 12 is formed on the upper side wall of the inner cylinder and the flow wall 12 is formed. The lower side of the outer cylinder 31 is connected to the circulation pipe 15, the sewage introduced into the denitrification chamber 10 passes through the overflow wall 12 and passes through the circulation pipe 15 to the nitric oxide chamber 20. An air diffuser 50 connected to the blower 51 is installed below the nitrification chamber 20, and a riser 21 is connected to the center of the upper side of the partition plate 23 in a vertical direction, and the riser 21 is provided. The upper end of the) is formed with a plurality of radial outlets 22 arranged in a horizontal direction so that the sewage flowing into the nitrification chamber 20 is mixed with the air supplied from the diffuser 50 and raised by the buoyancy of the bubble to rise. The tube 21 is circulated to the denitrification chamber 10.

Meanwhile, a precipitation chamber 30 is formed in a space between the inner cylinder 11 and the side wall of the outer cylinder 31, and the overflow wall 32 protrudes above the side wall of the outer cylinder 31, and the overflow wall 32 is formed. A portion of the sewage transferred to the nitrification chamber 20 is connected to the discharge pipe 34 to the site, the sludge is sedimented and separated while the sedimentation chamber 30 rises, and the supernatant flows through the discharge wall 34 through the overflow wall 32. It is discharged to the outside.

The stirring means 40 is installed in the denitration chamber 10. The stirring means 40 is connected to the tubular portion 41 rotatably inserted into the riser tube 21, the rotor blade portion 42 connected to the upper tubular portion 41 and the tubular portion 4 The stirring blade portion 43 is configured to rotate the stirring means 40 while the sewage discharged from the discharge port 22 collides with the stirring blade portion 43.

In addition, the upper side of the inner cylinder 11, the drip tray 13 is installed on the lower side of the rotary blade portion 42, the sewage passing through the rotary blade portion 42 is connected to the circulation pipe 15 via the drip container (13) Part of the sewage returned to the nitrification chamber 20 through the pipeline 45 and introduced into the drip tray 13 is circulated to the denitrification chamber 10 through the pipeline 13a, and surplus sludge is passed through the pipeline 46. It is removed and then circulated to the denitrification chamber 10.

Referring to the operation of the present invention configured as described above are as follows.

When sewage from the sedimentation tank is removed, the sewage is supplied to the denitrification chamber 10 through the inflow pipe 14, and the nitrogen contained in the sewage is oxidized to nitric oxide in the nitrification chamber 20, and the crushing wing part with the sewage circulated. While stirring and mixing by 43, the nitrogen oxides are reduced by the denitrification microorganism and released in the form of nitrogen gas through the outlet pipe 19, so that nitrogen is removed, and the mixed sewage flows through the overflow wall 12. It overflows and is conveyed to the nitric oxide chamber 20 through the circulation pipe 15. The sewage transferred to the nitrification chamber 20 is contacted with and mixed with the air discharged from the diffuser 50, and the nitrogen contained in the sewage is oxidized to nitric oxide by the nitric oxide microorganisms, which rises due to buoyancy of the bubble to raise the pipe ( 21) and discharge into the inner cylinder 11 through the outlet 22.

On the other hand, a part of the sewage transferred to the nitrification chamber 20 rises along the sedimentation chamber 30, the sludge is sedimented and separated, and the supernatant is discharged to the outside through the discharge pipe 34 overflowing the overflow wall (32). The barrier wall 24 protrudes below the precipitation chamber, and the lower end 23a of the partition plate 23 protrudes toward the barrier wall 24 to prevent bubbles from rising to the precipitation chamber.

The sewage discharged to the discharge port 22 is passed through the rotary blade portion 42 while rotating the stirring means 40 around the shaft 41, and through the drip pipe 13 through the pipe passage 45 through the nitrification chamber ( 20, a part of which is circulated to the denitrification chamber 10 through the conduit 13a.

Another pipeline 46 is connected to the pipeline 45 to operate the valve to intermittently discharge sewage to remove excess sludge. The phosphorus removal microorganism ingested excess phosphorus under aerobic conditions of the nitrification chamber 20. The excess sludge is removed from the condition, so that the sidewalls contained in the sewage are removed.

Reference numerals 61 and 62 are brackets to connect the inner and outer cylinders and the drip trays to each other to fix them.

In this way, the present invention is the denitrification chamber 10, the nitrification chamber 20 and the precipitation chamber 30 is formed in a single tank to reduce the installation cost of the facility, the land area is reduced, the denitrification chamber 10 and the nitrification chamber 20 It is partitioned independently by the partition plate 23, so that microorganisms that perform functions in each chamber can be accelerated while maintaining high concentration, so that the efficiency of sewage treatment is improved, and a separate pump for circulating sewage is required. As a blower 51 is achieved without the aeration, sewage transfer and agitation function, the circulation of the sewage is smooth, so that the power and maintenance costs for the operation of the sewage treatment facility are reduced, and the denitrification chamber 10 and the nitrification in a predetermined space. The residence time of sewage in each chamber is divided into two chambers, the volume of each chamber increases and the sewage flowing into the denitrification chamber 10 flows over the overflow wall 12 and is transferred to the nitrification chamber 20. Is increased to sewage Yudoen there is an effect that it is possible to efficiently remove the nutrients of nitrogen and indeung.

Claims (4)

In the sewage treatment tank, which consists of an outer cylinder and an inner cylinder located on the upper side of the outer cylinder, a denitrification chamber is formed in the inner cylinder, a nitric oxide chamber is formed between the bottom surfaces of the inner and outer cylinders, and a sedimentation chamber is formed between the side walls of the inner and outer cylinders. The inner cylinder has a bottom surface formed of a trumpet-shaped partition plate of upper and lower light beams so that the denitrification chamber and the nitrification chamber are partitioned independently, and the overflow wall in which the sewage flowing into the denitrification chamber overflows is formed on the upper side of the inner cylinder. A circulation pipe is connected between the inner cylinder and the outer cylinder so that the sewage passing through the nitrification chamber is moved, and a vertical riser is connected so that a part of the sewage passing through the nitrification chamber is circulated to the denitrification chamber at the center of the partition plate. Sewage nutrient removal device. The method of claim 1, The nutrient removal apparatus of sewage, characterized in that the stirring means rotated by the sewage discharged from the riser inside the denitrification chamber. The method of claim 2, Wherein the stirring means is that the tubular portion rotatably inserted into the riser, the stator blade portion attached to the tubular portion, and the rotor blade portion formed by rotating the sewage discharged from the riser tube on the upper side of the tubular portion is formed. Sewage nutrient removal device characterized in that. A denitrification chamber is formed, and a nitrification chamber is formed below the denitrification chamber, and a rising pipe communicating with the nitrification chamber is provided in a central portion of the denitrification chamber, wherein the sewage treatment apparatus is formed at the tip of the rising pipe and disposed radially on a horizontal plane. A plurality of discharge ports, a rotary blade portion disposed at an outer circumference of the discharge hole and rotated by sewage discharged from the discharge port, and connected to the rotary blade portion and installed in the denitrification chamber and rotated according to the rotation of the rotary blade portion to discharge sewage in the denitrification chamber. Sewage nutrient removal device, characterized in that consisting of a stirring blade to mix, agitate.