KR101836561B1 - Concentrated Organic Waste Water Purifying System - Google Patents

Abstract

The present invention relates to a high concentration organic wastewater purification system, and more particularly, to a high concentration organic wastewater purification system which is located in a purification tank and includes an aerobic tank for receiving and reacting organic wastewater to be supplied, an oxygen supply for supplying oxygen to the wastewater of the aerobic tank, Wherein the aerobic tank is partitioned into a plurality of aerobic blocks in the vertical direction and the aerobic blocks adjacent to each other in the vertical direction are communicated with each other to supply oxygen in stages, And supplies them to the respective aerobic blocks of the oxic tank, alternately to the odd-numbered aerobic blocks and the even-arranged aerobic blocks among the aerated blocks arranged in the upper and lower directions.
According to the present invention, the wastewater can be reacted with oxygen, and the super-saturated oxygen can be supplied to the plurality of aerobic blocks to improve the reaction efficiency, and the aerobic block arranged in an odd number and the aerobic block arranged in an even number By alternately supplying oxygen super-strength cells, operating costs can also be reduced.

Description

[0001] Concentrated Organic Waste Water Purifying System [

[0001] The present invention relates to a wastewater purification system, and more particularly to a wastewater purification system that is divided into a plurality of aerobic blocks in the up and down direction, the aerobic blocks adjacent to each other in the vertical direction are communicated with each other, Concentration organic wastewater purification system capable of improving the organic wastewater purification efficiency.

Generally, pollutants in wastewater are mainly composed of organic matter and nutrients such as nitrogen and phosphorus. Accordingly, various attempts have been made to develop apparatuses for purifying wastewater by removing nitrogen and phosphorus.

Conventional purification apparatuses include biological nitrogen and phosphorus removal processes include an aerobic reaction tank (commonly referred to as an aeration tank) for nitrification and excessive intake of phosphorus, an anoxic tank for denitrification reaction, An anaerobic tank for releasing phosphorus, and the like.

Here, the conventional wastewater purification apparatus is disclosed in Korean Patent Laid-Open Publication No. 2009-22168 (entitled "Wastewater Wastewater Treatment Method and Apparatus"), Korean Patent Publication No. 10-0709456 (entitled "Wastewater Treatment Device and Wastewater As disclosed in Korean Patent Laid-Open Publication No. 1998-67740 (entitled "Method and Apparatus for Removing Nutrients in Waste Water Treatment"), an aerobic tank mainly composed of a box is connected to the lower part of an aeration tank Discloses a wastewater treatment apparatus in which air supplied from an air diffusing unit is mixed with wastewater to promote microorganisms to decompose and purify contaminants.

However, since the conventional wastewater treatment apparatus has a single structure in which the reaction takes place, the contact time with the oxygen is short because the wastewater passes through the aerobic reaction tank in a short time. As a result, the ability of the wastewater to decompose contaminants .

Accordingly, there is an urgent need to develop a technique capable of improving the reaction efficiency of decomposing pollutants by increasing the passage time of the wastewater and increasing the reaction time.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide an oxygen- Wherein the oxygen supply unit supplies oxygen to the oxygen storage tank and the oxygen storage tank to supply oxygen to the oxygen storage tank, To provide a highly concentrated organic wastewater purification system capable of reducing the operating cost by alternately supplying the oxygen super-strength bubbles to odd-numbered aerobic blocks and even-arranged aerobic blocks, The purpose is.

According to an aspect of the present invention, there is provided a method of controlling an oxygen supply system, the method comprising the steps of: providing an oxic tank located inside a septic tank for supplying organic wastewater to be supplied and reacting therethrough; an oxygen supply unit for supplying oxygen to the wastewater of the oxic tank; Wherein the aerobic tank is partitioned into a plurality of aerobic blocks in the vertical direction and the aerobic blocks adjoining in the up and down direction are communicated with each other to supply oxygen in stages and the oxygen supply unit supplies oxygen to each aerobic block of the aerobic tank And alternately supplies an odd-numbered call block and an even-numbered call block among the vertically arranged call blocks.

Preferably, the exhalation block includes an exhalation space part formed in the interior of the exhalation space part where oxygen supplied from the oxygen supply part mixes with wastewater, thereby generating exhalation reaction, an exhalation inlet for introducing wastewater into the exhalation space part, And a guiding part for guiding the wastewater supplied to the exhalation space part and the oxygen to be circulated in one direction by controlling the amount of the wastewater discharged from the exhalation space to the exhalation outlet by a predetermined distance to the lower side of the exhalation outlet .

The ventilation block located at the lowermost side of the exhalation block includes a ventilation inlet formed at one side of the lower end to introduce wastewater for generating an exhalation reaction, a vent outlet formed at the other end of the upper end, Are formed on the other side of the lower end so as to communicate with the vent outlet of the other ventilation block located at the lower side of the ventilation block.

In addition, a treatment tank in which a plurality of treatment blocks for moving the treated water reacted in the oxic tank is arranged in the vertical direction is further provided.

The treatment tank is an anaerobic treatment tank, and the treated water reacted in the oxic tank is introduced into a treatment block located on the uppermost side, and then sequentially passes through a plurality of treatment blocks arranged in the lower side.

Also, the treatment tank is an aerobic treatment tank, oxygen is supplied to each treatment block by the control unit, the treatment water is introduced into the treatment block located at the uppermost position, and then sequentially passes through the plurality of treatment blocks arranged at the lower side .

The treatment tank is composed of a first treatment tank connected to the oxic tank and a second treatment tank connected to the first treatment tank. The first treatment tank is an anaerobic treatment tank, and the treatment water reacted in the oxic tank is located on the uppermost side And the second treatment tank is an aerobic treatment tank, and the treatment water reacted in the first treatment tank is introduced into the treatment block located at the lowermost side And sequentially passes through a plurality of processing blocks arranged on the upper side.

The treatment tank is composed of a first treatment tank connected to the oxic tank and a second treatment tank connected to the first treatment tank. The first treatment tank is an aerobic treatment tank, and the treatment water reacted in the oxic tank And a plurality of processing blocks sequentially arranged in the lower side after flowing into the processing block, wherein the second processing vessel is an anoxic processing vessel, and the processing bath reacted in the first processing vessel is a processing block And sequentially passes through a plurality of processing blocks arranged upward.

The oxygen supply unit includes a supercritical air intake unit for supersonically riching oxygen, a bubble supply pipe for supplying the oxygen super-strong air bubble generated in the supercritical air intake unit to the aerobic tank, an air supply unit connected to the bubble supply pipe, A second branch pipe connected to the bubble supply pipe for supplying an oxygen super strong bubble to an even numbered breath block among the breath block, and a second branch pipe connected to the bubble supply pipe for supplying oxygen super strong force to the bubble supply pipe, And a supply valve for intermittently supplying the oxygen super-strength foam to the unit block in an alternating manner to the first branch and the second branch at the time of opening.

The ultracentrifugal aspiration unit includes an air compressor and a treatment water pump provided inside or outside the oxic tank. The treatment water in the oxic tank supplied by the treatment water pump and the gas supplied by the air compressor collide with each other in the mixing chamber It generates ultra-fine grained bubbles.

In addition, nozzles are provided in the first branch and the second branch located in the respective aerobic blocks, and each nozzle is positioned below the guide portion, and is directed toward the edge of the upper end where the vent outlet is not formed, The wastewater and the oxygen super-strength force are turned by the guide portion in a direction opposite to the direction guided by the vent outlet, thereby increasing the reaction time of the wastewater and the oxygen super strength force.

In addition, a lower guide portion for guiding the process water, which is moved to a certain portion of the lower end portion below the guide portion of each of the aerobic blocks, is turned upward.

As described above, according to the high concentration organic wastewater purification system of the present invention, the wastewater can be reacted with oxygen, and the ultra-high-saturation oxygen can be supplied to the plurality of exhalation blocks to improve the reaction efficiency, It is a very useful and effective invention that can reduce operating costs by supplying alternate oxygen super strength bombs with aerobic blocks and evenly arranged aerobic blocks.

1 is a view schematically showing a highly concentrated organic wastewater purification system according to the present invention,
2 is a view showing an exhalation block according to the present invention,
3 is a view showing an ultra-fine grained portion according to the present invention,
4 is a view showing another embodiment of the ultracentrifugal aspirator according to the present invention,
FIG. 5 is a view showing an installation state of a nozzle according to the present invention,
6 is a view showing a state where a lower guide is further provided in a breathing block according to the present invention,
FIG. 7 is a view showing another embodiment of the highly concentrated organic wastewater purification system according to the present invention,
8 is a view showing still another embodiment of the high concentration organic wastewater purification system according to the present invention.

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

It should be noted that the present invention is not limited to the scope of the present invention but is only illustrative and various modifications are possible within the scope of the present invention.

FIG. 1 schematically illustrates a high concentration organic wastewater purification system according to the present invention, FIG. 2 is a view showing a breathing block according to the present invention, FIG. 3 is a view showing the ultra- FIG. 5 is a view showing a state in which the nozzle according to the present invention is installed. FIG. 6 is a cross-sectional view of the aerobic block according to the present invention, FIG. 7 is a view showing another embodiment of the highly concentrated organic wastewater purification system according to the present invention, and FIG. 8 is a view showing another embodiment of the high concentration organic wastewater purification system according to the present invention. Fig.

As shown in the figure, the high concentration organic wastewater purification system 10 comprises an oxic tank 100, an oxygen supply unit 200, and a control unit 300.

The oxic tank 100 is located inside the septic tank 1 and is supplied with organic wastewater to be supplied and reacted. The oxygen supply unit 200 is provided to supply oxygen to the wastewater of the oxic tank 100.

The control unit 300 is provided to control the oxygen supply unit 200.

Here, the aerobic tank 100 is partitioned into a plurality of aerobic blocks 110 in the up-and-down direction, and the aerobic blocks 110 adjacent to each other in the up-and-down direction are communicated with each other to supply oxygen in stages.

The oxygen supply unit 200 alternately supplies oxygen to each of the exhalation blocks 110 of the oxic tank 100 and alternately supplies the odor-numbered exhalation blocks and the even-numbered exhalation blocks among the externally arranged exhalation blocks 110.

As shown in FIG. 2, the exhalation block 110 includes an exhalation space 111, an exhalation inlet 112, an exhalation outlet 113, and a guide 114.

The exhalation space part 111 is formed inside, and oxygen supplied from the oxygen supply part 200 and the wastewater are mixed to generate a breath reaction.

The expiratory air inlet 112 is provided to introduce wastewater into the expiratory space 111 and the expiratory air outlet 113 is provided to discharge the wastewater of the expiratory space 111.

The guide portion 114 is spaced a predetermined distance below the expiration opening 113 to adjust the amount of wastewater in the expiration space 111 discharged to the expiration opening 113, And oxygen to be turned in one direction.

The guide part 114 can increase the reaction time by turning the wastewater and oxygen in one direction, thereby improving the reaction efficiency.

The ventilation block 110-1 located at the lowermost side of the ventilation block 110 is formed with a ventilation inlet 112-1 at one side of the lower end to supply a wastewater to generate a venting reaction, Is formed on the other side of the upper end portion.

The wastewater flowing into the exhalation inlet 112-1 formed at one side of the lower end reacts with the oxygen supplied by the oxygen supplier 200 in the exhalation space 111-1 and then discharged through the exhalation outlet 113-1 to another aeronautical block 110-2 located on the upper side.

The exhalation blocks positioned above the lowermost exhalation block 110-1 are formed on the other side of the lower end to communicate with the exhalation outlet of the other exhalation block located below.

In other words, the exhalation inlet 112-2 of the second exhalation block 110-2 from the lower side is positioned to communicate with the exhalation outlet 113-1 of the lowest exhalation block 110-1.

The oxygen supply unit 200 includes an ultra-strong supporter 210, a bubble supply pipe 220, a first branch pipe 230, a second branch pipe 240, and a supply valve 250.

The ultracentrifugal aspiration unit 210 is configured to saturate the oxygen with ultra-high intensity and the bubble supply pipe 220 is provided to supply the oxygen storage tank 10 with the oxygen super strength produced in the ultra-

The first branch pipe 230 is connected to the bubble supplying pipe 220 and is provided to supply the oxygen-energetic bubble to the odor-numbered breathing block of the breathing block 110.

The second branch pipe 240 is connected to the bubble supply pipe 220 and is provided to supply the oxygen super-strength bellows to the even-numbered ventilation block among the ventilation blocks 110.

The supply valve 250 opens and closes the bubble supply pipe 220. When the bubble supply pipe 220 is opened, the supply valve 250 alternately communicates with the first branch pipe 230 and the second branch pipe 240 to intermittently supply the oxygen- .

As shown in FIG. 3, the ultra-fine-grained part 210 may be composed of only a conventional air compressor (or a compressor), or alternatively, And a process water pump (not shown) and an air compressor (not shown) provided outside.

A method of providing ultra-high strength wastewater (several nm to several mm) containing water produced by forcible mixing of the treated water in the aerosol tank supplied by the treatment water pump and the gas supplied by the air compressor in a mixing chamber (not shown) Also constitute an embodiment of the present invention.

5, the nozzles 260 are provided in the first branch pipe 230 and the second branch pipe 240 located in the respective nozzle blocks 110, The oxygen-enriched micro-bellows is sprayed toward the edge of the upper end of the guide unit 114 which is not formed with the vent outlet so that the wastewater and the oxygen-enriched micro-bellows are moved in the direction opposite to the direction guided by the guide unit Thereby increasing the reaction time of the wastewater and oxygen super-strength steel.

As shown in FIG. 6, the lower guide part 115 is further provided to guide the process water, which is moved to a lower part of the lower end of the lower part of the guide part 114 of each oxishing block 110, to be pivoted upward.

The lower guide part 115 guides upward the process water and oxygen which are circulated in the air space part 111 and can delay the discharge to the air outlet 113 to increase the reaction time.

As shown in FIG. 7, the treatment tank 400 further includes a plurality of treatment blocks 110 arranged in the vertical direction for moving the reacted treatment water in the oxic tank 100.

This treatment tank 400 is an example of an anaerobic treatment tank in which the treated water reacted in the oxic tank 100 flows into the treatment block 410 located at the uppermost site and then a plurality of treatment blocks arranged at the lower side Pass sequentially.

In another embodiment, the treatment tank 400 is an aerobic treatment tank, in which oxygen is supplied to each treatment block 410 by the control unit 300, the treated water is introduced into the treatment block located on the uppermost side, And sequentially passes through the plurality of arranged processing blocks.

In other words, the treatment tank 400 can be selected to be anaerobic or aerobic.

As shown in FIG. 8, the treatment tank 500 of another embodiment is composed of a first treatment tank 510 and a second treatment tank 520.

First, the first treatment tank 510 is connected to the oxic tank 100 to feed the treatment water to be moved in the oxic tank 100. The second treatment tank 520 is in communication with the first treatment tank 510, The treated water moving in the bath 510 flows in and the reaction occurs.

The first treatment tank 510 is an anaerobic treatment tank in which the treated water reacted in the oxic tank 100 flows into the treatment block 512 positioned on the uppermost side and then a plurality of treatment blocks arranged in the lower side are sequentially .

The second treatment tank 520 is an aerobic treatment tank in which treatment water reacted in the first treatment tank 510 flows into the treatment block 512 positioned at the lowermost position and then a plurality of treatment blocks arranged in the upper direction are sequentially As shown in FIG.

On the other hand, the first treatment tank 510 is an aerobic treatment tank, in which the treated water reacted in the oxic tank 100 flows into the treatment block 512 located at the uppermost side, and then a plurality of treatment blocks arranged in the lower side are sequentially .

The second treatment tank 520 is an anaerobic treatment tank in which the treated water reacted in the first treatment tank 510 flows into a treatment block 522 located at the lowermost position and then a plurality of treatment blocks arranged on the upper side are sequentially As shown in FIG.

10: purification system 100:
110: Exhalation block 200:
210: ultra-fine aspiration part 220: bubble supply pipe
230: 1st branch office 240: 2nd branch office
250: supply valve 300:
400, 500: Treatment tank

Claims (12)

Located inside the septic tank,
An aerobic tank in which the supplied organic wastewater flows and reacts;
An oxygen supply unit for supplying oxygen to the wastewater of the oxic tank; And
And a control unit for controlling the oxygen supply unit,
The ox-
And a plurality of aerobic blocks arranged in a vertical direction, the aerobic blocks adjacent to each other in the vertical direction are communicated with each other,
The oxygen supply unit includes:
Oxygen is supplied to each of the breathing blocks of the oxic tank, and alternate supply of the odd-numbered breathing blocks and the even-arranged breathing blocks among the upper and lower breathing blocks,
Each of the air-
An aerobic space formed inside the aerobic part and mixed with oxygen supplied from the oxygen supply part and wastewater to generate a breath reaction;
An exhalation inlet for introducing wastewater into the exhalation space;
A vent outlet for venting wastewater in the vent space; And
And a guiding part spaced a predetermined distance from the lower end of the expiration opening to adjust the amount of wastewater discharged from the expiration space to the expiration opening and guide the wastewater supplied to the expiration space and oxygen to be turned in one direction,
Wherein the lowest aerial block among the aeronautical blocks is a low-
A waste water inlet is formed at one side of the lower end to introduce wastewater for generating an exhalation reaction, a waste water outlet is formed at the other end of the upper end,
The aerobic blocks positioned above the lowermost aerobic block are,
The air inlet port is formed on the other side of the lower air outlet so as to communicate with the air outlet port of the other air outlet block located below,
Further comprising a treatment tank in which a plurality of treatment blocks for moving the treated water reacted in the oxic tank are arranged in the vertical direction,
Wherein,
A first treatment tank connected to the oxic tank, and a second treatment tank connected to the first treatment tank,
Wherein the first treatment tank is an aerobic treatment tank, the treated water reacted in the aerobic tank is introduced into a treatment block located on the uppermost side, and then sequentially passes through a plurality of treatment blocks arranged in the lower side,
The second treatment tank is an anaerobic treatment tank in which treatment water reacted in the first treatment tank is introduced into a treatment block located at the lowermost position and then sequentially passed through a plurality of treatment blocks arranged upward,
The oxygen supply unit includes:
Ultra-fine aspiration that saturates oxygen with ultra-high intensity;
A bubble supply pipe for supplying the oxygen super-strength foam produced in the ultra-fine grained part to the aerobic tank;
A first branch pipe connected to the bubble supplying pipe to supply an oxygen super strength bubble to an odd numbered aerobic block among the breathing blocks;
A second branch pipe connected to the bubble supplying pipe to supply an oxygen super strong force to an even numbered exhalation block of the breathing block; And
And a supply valve for intermittently supplying the oxygen super-strength container to the unit block by alternately opening and closing the bubble supply pipe and communicating with the first branch pipe and the second branch pipe when opened,
The ultra-
And a treatment water pump provided inside or outside of the oxic tank. The treatment water in the oxic tank supplied from the treatment water pump and the gas supplied by the air compressor collide with each other in the mixing chamber to generate ultra-
The nozzles are provided in the first branch and the second branch located in the respective unit blocks, and the nozzles are positioned below the guide portions, and the oxygen super-strength bellows is sprayed toward the corners of the upper end portions Thereby increasing the reaction time of the wastewater and the oxygen-enriched oxygen-enriched ointment, by rotating the wastewater and the oxygen-enriched oxygen-enriched ointment in the direction opposite to the direction guided by the air-
Further comprising a lower guide portion for guiding the process water, which is moved to a lower portion of a lower portion of a lower portion of a guide portion of each of the aerobic blocks, to be pivoted upward. delete delete delete delete delete delete delete delete delete delete delete

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