KR101613711B1 - Apparatus for selecting aerobic granule sludge - Google Patents

Abstract

The present invention relates to an aerobic granular sludge sorter, which comprises: a discharging means to discharge a reaction liquid inside a biological treatment reaction tank; a filtration means which is connected to the discharging means and separates the reaction liquid into anaerobic granular sludge and fine sludge having particle sizes smaller than the anaerobic granular sludge by filtering the reaction liquid discharged by the discharging means; and a returning means which connects the filtering means to the biological treatment reaction tank and returns the anaerobic granular sludge separated by the filtering means to the biological treatment reaction tank.

Description

Technical Field [0001] The present invention relates to an aerobic granule sludge,

The present invention relates to an aerobic granule sludge sorting apparatus that increases the purity of aerobic granule sludge and improves the efficiency of sewage / wastewater treatment and improves the stability of the aerobic granule sludge structure.

In the case of large-scale sewage treatment plants, continuous flow type advanced treatment methods are mainly applied. In the case of small and medium-sized ones, sequencing batch reactors (SBR) are applied in order to flexibly respond to inflow flows.

Continuous flow sewage treatment methods such as A / O and A ² / O are differentiated according to the substances to be treated. In Korea, many methods for simultaneously removing nitrogen and phosphorus are developed and applied.

Generally, in such a wastewater treatment plant system, floating sludge is continuously moved to each tank by continuous flow or sludge return by using floating sludge. Therefore, it is difficult to dominate by each condition of each tank, the efficiency of removing pollutants is decreased, Liquid separation such as bulking and foaming occurs frequently depending on the method, and various problems in the treatment efficiency.

Recently, in order to solve the disadvantages of floating sludge in Korea, an immersion type membrane separation process (MBR) has been applied in which solid - liquid separation by gravity sedimentation is replaced by membrane separation and the concentration of microorganisms in the reactor is increased to improve the treatment efficiency.

However, in the submerged membrane separation process, it is necessary to periodically change the membrane due to membrane contamination due to the membrane permeation time as in the conventional membrane separation process. In order to clean the membrane, excessive air is supplied into the aeration tank, And it is pointed out that a high energy is consumed due to this.

Efforts have been made to improve the problems of the above-mentioned conventional biological water treatment apparatuses and methods. As a part of such efforts, Korea Patent No. 0357042 and No. 0345451 disclose that floating sludge is granulated instead of suspended sludge, A water treatment apparatus and a method for treating water.

Specifically, Korean Patent Registration No. 0357042 discloses a water treatment system comprising an indirect aeration tank for supplying air and a granulation biological treatment tank provided with a stirrer for granulating suspended sludge as a core, and a water treatment system comprising an indirect aeration tank A method for treating sewage water by supplying an aeration mixture liquid to an biological treatment reaction tank in an upward flow manner to maximize the contact between floating sludge by a hydraulic force of an aeration mixture to achieve granulation.

In Korean Patent No. 0345451, an anaerobic granulating tank is additionally provided in addition to an indirect aeration tank and a biological treatment tank, which are the essential constituent devices of the above-mentioned Korean Registration No. 0357042, and the organic matter contained in the sewage , A water treatment apparatus and method for removing contaminants such as nitrogen and phosphorus are disclosed.

The common feature of these patents is that a method of generating granular sludge from floating sludge by controlling the operating conditions and the like in the water treatment apparatus is used. The production of granular sludge by floating sludge granulation is not only time consuming, It is difficult to handle the waste water and wastewater in a stable manner. Finally, the water treatment apparatus and method disclosed in the patent have a drawback in that an indirect aeration tank and a granular bioreactor must be added. Thus, the A / O or A ² / O process, which occupies most of the existing wastewater treatment facilities, (retrofitting) technology.

An anoxic tank, anaerobic tank, anaerobic tank, anaerobic granular sludge, anaerobic granular sludge, anaerobic granular sludge, and anaerobic granular sludge are installed in an anaerobic tank, an anoxic tank, a first aeration basin and a second aeration tank, respectively, which are equipped with separation plates in Korean Patent Publication No. 10-1336988, A second aerated granular sludge, and a nitrification particulate sludge, respectively, thereby greatly improving the treatment efficiency of contaminants such as organic matter, nitrogen and phosphorus in the wastewater.

However, a certain amount of sludge must be discarded in order to maintain a stable microbial concentration in the biological treatment tank. The aerobic granulated sludge and the suspended sludge are simultaneously discarded, thereby lowering the concentration of the aerobic granulated sludge in the biological treatment tank.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an aerobic granule sludge sorting device for separating aerobic granulated sludge discharged from a biological treatment tank and floating sludge, in order to increase concentration and purity of aerobic granulated sludge in a biological treatment tank The present invention has been made in view of the above problems.

According to an aspect of the present invention, there is provided an apparatus for sorting aerobic granular sludge according to an embodiment of the present invention, comprising: a discharging means for discharging a reaction liquid in a biological treatment tank; A filtering means connected to the discharge means for filtering the reaction liquid discharged by the discharge means to separate the aerobic granule sludge contained in the reaction liquid and the fine sludge having a particle size smaller than that of the aerobic granule sludge; And a returning means for returning the aerobic granulated sludge separated by the filtering means in the biological treatment tank in conjunction with the filtering means and the biological treatment tank.

Here, the filtering means may include a filter unit for filtering the reaction liquid to separate the aerobic granule sludge and the fine sludge from each other; And a storage unit in which each of the aerobic granule sludge and fine sludge separated by the filter unit is moved and stored.

At this time, the filter unit may include a filtering belt that is arranged and rotated so as to sequentially filter the aerobic granular sludge and the small aerobic granular sludge, which are relatively large in the aerobic granular sludge of the reaction liquid.

In one embodiment, a pair of said filtering belts are arranged laterally spaced apart and a filtering section for filtering the reaction liquid during rotation is moved towards each other, said storage unit comprising: A storage tank disposed in the storage tank; And an AGS water tank disposed below the pair of the filtering belts and storing the aerobic granular sludge, wherein the filtering unit is disposed between the pair of the filtering belts, And a moving unit for moving the reaction liquid from the water tank to the other filtering belt.

Wherein a pair of said filtering belts are arranged such that each of the drive pulleys disposed opposite each other is connected to one drive motor by a drive belt and rotates so that the direction changing sprocket is supported on the drive belt Can be connected.

The filtering means may include: a first guide plate disposed downwardly from the lower portion of the driving pulley and the driven pulley of the filtering belt toward each other; And a second guide plate disposed downwardly from the lower portion of each of the drive pulleys of the pair of the filtering belts toward each other.

In addition, the filtering means may include a backwash pump disposed in the storage tank; A reverse flow pipe extending from the backwash pump to between the filtering section and the return section of the filtering belt to move the reaction liquid in the storage tank to the upper side of the return section of the filtering belt with the backwash pump; And a backwash nozzle installed at an end of the retro-tubular tube and spraying the reaction solution to the return portion.

The return means may include: a return pump disposed in the AGS water tank; And a return pipe extending from the return pump to the biological treatment tank so as to return the reaction solution in the AGS water tank to the biological treatment tank with the return pump.

In addition, the filtering means may comprise a filtering belt, at a position where it is switched from the filtering belt to the filtering portion to filter the reaction liquid upon rotation on the filtering belt, so as to drop the aerobic granule sludge filtered by the filtering portion And a scraper disposed in contact with the base member.

The aerobic granule sludge sorting apparatus according to the present invention comprises filtering means for separating aerobic granular sludge and fine sludge contained in a reaction liquid by filtering a reaction liquid discharged from a biological treatment reactor and aerobic granular sludge separated by a filtering means The returning means for returning the aerobic granulated sludge as the micro sludge is maintained so that the concentration of the aerobic granulated sludge is maintained at a high level so that the aerobic granulated sludge is more entrained It is possible to suppress the production amount of floating sludge and to improve the efficiency of the treatment of wastewater and wastewater.

Further, by removing the suspended sludge attached to the aerobic granulated sludge, it is possible to further increase the efficiency of the treatment of aerobic granulated sludge in the biological treatment tank as the purity of the aerobic granulated sludge is returned to the biological treatment tank have.

In addition, as only the suspended sludge is discarded as described above, the organic matter necessary for polymer production for maintaining the structure of the aerobic granulated sludge is sufficient, so that the structure of the aerobic granulated sludge can be stably maintained.

1 and 2 are a perspective view and a side view schematically showing an aerobic granulated sludge sorter according to an embodiment of the present invention.
FIG. 3 is a view showing a pair of filtering belts in the aerobic granule sludge sorter of FIG. 1. FIG.

Hereinafter, exemplary embodiments of the present invention will be described in detail. In the drawings, like reference numerals are used to refer to like elements throughout the drawings, even if they are shown on different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

1 and 2 are a perspective view and a side view schematically showing an aerobic granulated sludge sorter according to an embodiment of the present invention.

According to the present invention, there is provided a bioreactor comprising: a discharging means for discharging a reaction liquid in a biological treatment tank; a filtering means for filtering the reaction solution in association with the discharging means; And returning means for returning.

Here, the discharging means is configured to discharge a reaction liquid in a biological treatment tank (not shown). To this end, a discharge pump (not shown) disposed in the biological treatment tank, and a reaction pump A discharge pipe 111 extending from the discharge pump to the filtering means and a discharge nozzle 113 mounted on the end of the discharge pipe 111 for spraying the reaction liquid onto the filtering belt 210. In this case, the discharging means may be configured to discharge the reaction liquid to the filtering means through the discharge pipe 111, but it is needless to say that any conventional discharging configuration can be adopted.

In addition, the filtering means, which is a main structural feature of the present invention, functions to filter the reaction liquid so as to recycle the aerobic granular sludge contained in the discharged reaction liquid.

Here, aerobic granule sludge (AGS) is referred to as aerobic granule sludge (AGS). The aerobic granular sludge is classified into physical and physical properties such as shape and color of granules according to various carbon sources and proteins according to biochemical characteristics of aerobic microorganisms in a sewage treatment plant. Shape is formed. The aerobic granulation process involves interactions between microorganisms, including biological, physical, and chemical phenomena. Unlike microbial membranes, aerobic granular sludge is formed by self-immobilization of microorganisms without the aid of mediators under aerobic conditions. It is a high-density microorganism aggregate composed of various bacterial species, and is capable of infecting millions of microorganisms with various biological functions . The aerobic granule sludge can be distinguished visually from floating sludge, and is mainly formed into a spherical shape having a spherical shape formed by a biopolymer produced by a microorganism in the sludge.

Biological reaction treatment using the aerobic granule sludge described above is performed by biological treatment of wastewater by putting aerobic granular sludge, which is not general suspended sludge, into a biological treatment tank, and gradually over time, suspended particles smaller than aerobic granular sludge Micro sludge such as sludge is generated, thereby lowering the purity of the aerobic granular sludge.

Thus, by using the aerobic granule sludge sorting apparatus of the present invention, it is possible to increase the purity of the aerobic granule sludge by disposing only fine sludge such as floating sludge having a particle size smaller than that of the aerobic granule sludge, Can be improved.

Specifically, the filtering means in the aerobic granule sludge sorting apparatus of the present invention filters the reaction liquid discharged by the discharging means to remove the aerobic granule sludge contained in the reaction liquid and the aerobic granule sludge And serves to separate small fine sludge.

Specifically, the filtering unit may include a filter unit that filters the reaction liquid to separate the aerobic granule sludge and the fine sludge, and a storage unit in which each of the aerobic granule sludge and the fine sludge separated by the filter unit is moved and stored have.

Wherein the filter unit may include a filtering belt 210 having a rotational drive structure such as a conveyor belt.

In order to increase the filtering effect, the filtering belt 210 may have a structure in which a plurality of particles are arranged and rotated so as to sequentially filter the aerobic granular sludge and the small aerobic granular sludge, which are relatively large in the aerobic granular sludge of the reaction liquid. have.

As shown in the drawing, the filtering belt 210 may be structured such that two pairs of filter belts 210 are horizontally spaced apart from each other and a filtering part 210a for filtering the reaction solution during rotation moves toward each other. The filtering unit 210a of the filtering belt 210 is located at the upper side of the filtering belt 210 to filter the reaction liquid and the return unit 210b is a part where the filtering belt 210 rotates And is returned to return to the position of the filtering unit 210a.

Specifically, the pair of filtering belts 210 are rotated by driving pulleys 211 disposed to face each other, as shown in FIG. 3, connected to one driving motor by a driving belt 214, The direction changing sprocket 215 is connected to the drive belt 214 so that the direction changing sprocket 210a moves toward each other. The drive belt 214 surrounds the left portion of the drive pulley 211 in the clockwise direction and the drive pulley 211 is rotated counterclockwise in the right drive pulley 211, And the direction changing sprocket 215 is disposed on the right side of the driving pulley 211 disposed on the right side so as to surround the upper portion of the driving belt 214 so as to rotate clockwise.

For reference, the drive pulley 211 is formed with an extension shaft 211a extending in the longitudinal direction so that the drive belt 214 does not interfere with other members. The extension shaft 211a is connected to the drive shaft (213) and the driving belt (214), and is rotatably driven.

1 and 2, the storage unit includes a storage tank 251 disposed below the respective filtering belts 210, and a storage tank 252 disposed below the pair of filtering belts 210, And an AGS water tank 252 in which the granular sludge is stored. As a result, the liquid passing through the filtering belt 210 in the reaction liquid falls away in the storage water tank 251, and the aerobic granular sludge filtered by the filtering belt 210 is moved by the filtering belt 210 to the AGS water tank 252 ), So that only the aerobic granule sludge is classified and stored in the reaction solution.

At this time, the filtering means is disposed between the first guide plate 221 and the second guide plate 221 so that the reaction liquid passing through the filtering belt 210 and the aerobic granule sludge filtered by the filtering belt 210 are smoothly and clearly classified and stored. 222). The first guide plate 221 may be inclined downwardly from the lower portion of the driving pulley 211 and the driven pulley 212 of the filtering belt 210 and the second guide plate 222 may be disposed in a pair The driving pulleys 211 of the filtering belt 210 may be inclined downwardly from each other.

In addition, the filtering means may further include a scraper 240 contacting the filtering belt 210. The scraper 240 is disposed at a position where the filtering unit 210a for filtering the reaction liquid when rotating on the filtering belt 210 is switched to the return unit 210b and the aerobic granule sludge filtered by the filtering unit 210a And falls off the filtering belt 210.

The filtering unit may further include a backwash unit to clean the filtering belt 210. The backwashing unit includes a backwash pump 231 disposed in the storage tank 251 and a backwash pipe extending from the backwash pump 231 to between the filtering unit 210a and the return unit 210b of the filtering belt 210 232), and a backwash nozzle (233) mounted at the end of the retrofit tube (232).

The reaction liquid in the storage water tank 251 is moved by the backwash pump 231 to the upper side of the return portion 210b of the filtering belt 210 along the tailpipe 232, As the reaction liquid is injected into the return portion 210b, the sludge which has not fallen off by the filtering belt 210 can be removed.

Then, in order to sequentially filter out the aerobic granular sludge and the small aerobic granular sludge, which are relatively large in the aerobic granular sludge of the reaction liquid, the filtration means converts the filtered reaction solution from one of the pair of filtering belts 210 to another And a mobile unit for moving the mobile unit. That is, the moving unit is configured to move the reaction liquid from the storage tank 251 disposed below one of the pair of filtering belts 210 to the other one of the filtering belts 210.

Specifically, the moving unit includes, as an example, a moving pump 262 disposed in the storage tank 251 at one side, a moving pump 262 for moving the reaction liquid to the right filtering side by the moving pump 262, A moving pipe 261 extending upward from the filtering belt 210 on the other side and a moving nozzle 263 mounted on the end of the moving pipe 261 and spraying the reaction liquid onto the filtering belt 210.

The moving unit may be configured so that the reaction liquid filtered by the filtering belt 210 when the plurality of filtering belts 210 are disposed can be moved to the next filtering belt 210. As for the specific structure, It goes without saying that the present invention is not limited by the invention.

On the other hand, the returning means functions to return the aerobic granular sludge separated by the filtering means to be recycled in the biological treatment tank in conjunction with the filtering means and the biological treatment tank. Specifically, the return means includes a return pump 312 disposed in the AGS water tank 252 and a return pump 312 for returning the reaction solution in the AGS water tank 252 to the biological treatment tank by the return pump 312 And a return pipe 311 extended to the biological treatment reaction tank.

As a result, as described above, the present invention provides a biological treatment apparatus comprising filtering means for filtering a reaction solution discharged from a biological treatment reaction tank and separating aerobic granular sludge and fine sludge contained in a reaction solution, aerobic granular sludge separated by a filtering means, The returning means for returning the sludge to be recycled in the reaction tank is constructed so that only suspended sludge which is fine sludge is discarded and the concentration of aerobic granulated sludge is maintained high so that the organic material into which the aerobic granulated sludge has flowed can be used more , It is possible to suppress the production amount of suspended sludge and to improve the treatment efficiency of the waste water and wastewater.

Further, by removing the suspended sludge attached to the aerobic granule sludge, the aerobic granular sludge in the biological treatment tank can be further improved in the efficiency of the treatment of the aerobic granular sludge by re-supplying the purity aerobic granular sludge with high purity in the biological treatment tank.

In addition, as only the suspended sludge is discarded as described above, the organic matter necessary for producing the polymer for maintaining the structure of the aerobic granulated sludge is sufficient, so that the structure of the aerobic granulated sludge can be stably maintained.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

111: discharge pipe 113: discharge nozzle
210: a filtering belt 210a:
210b: return portion 211: drive pulley
211a: extension shaft 212: driven pulley
213: drive shaft 214: drive belt
215: turning sprocket 221: first guide plate
222: second guide plate 231: backwash pump
232: Stationary tubing 233: Backwash nozzle
240: scraper 251: storage tank
252: AGS tank 261: moving pipe
262: transfer pump 263: transfer nozzle
311: return pipe 312: return pump

Claims (9)

A discharging means for discharging the reaction liquid in the biological treatment tank; A filtering means connected to the discharge means for filtering the reaction liquid discharged by the discharge means to separate the aerobic granule sludge contained in the reaction liquid and the fine sludge having a particle size smaller than that of the aerobic granule sludge; And return means for linking the filtering means and the biological treatment tank to return the aerobic granule sludge separated by the filtering means into the biological treatment tank,
Wherein the filtering means comprises: a filter unit for filtering the reaction liquid to separate the aerobic granule sludge and the fine sludge; And a storage unit in which each of the aerobic granular sludge and fine sludge separated by the filter unit is moved and stored,
Wherein the filter unit is provided with a plurality of rotating and filtering belts to sequentially filter out aerobic granular sludge and relatively small aerobic granular sludge particles from the aerobic granular sludge of the reaction liquid,
Wherein a pair of the filtering belts is disposed laterally spaced apart and a filtering section for filtering the reaction liquid upon rotation is moved toward each other, and the storage unit is disposed in the storage tank ; And an AGS water tank disposed below the pair of the filtering belts and storing the aerobic granular sludge, wherein the filtering unit is disposed between the pair of the filtering belts, Further comprising a moving unit for moving the reaction liquid from the water tank to the other filtering belt.
delete delete delete The method according to claim 1,
The pair of filtering belts are characterized in that the respective driving pulleys arranged to face each other are connected to a driving motor by a driving belt and rotate, and a direction changing sprocket is connected to the driving belt so that the filtering part moves towards each other Wherein the aerobic granular sludge is fed to the aerobic granular sludge sorting device.
The method according to claim 1,
Wherein the filtering means comprises:
A first guide plate disposed downwardly from the lower portion of the driving pulley and the driven pulley of the filtering belt toward each other; And
A second guide plate disposed to be inclined downward from the bottom of each of the driving pulleys of the pair of the filtering belts toward each other;
Wherein the aerobic granulated sludge is fed to the aerobic granular sludge sorting device.
The method according to claim 1,
Wherein the filtering means comprises:
A backwash pump disposed in the storage tank;
A reverse flow pipe extending from the backwash pump to between the filtering section and the return section of the filtering belt to move the reaction liquid in the storage tank to the upper side of the return section of the filtering belt with the backwash pump; And
A backwash nozzle attached to an end of the retro-tubular tube and spraying a reaction liquid to the return portion;
Wherein the aerobic granulated sludge is fed to the aerobic granular sludge sorting device.
The method according to claim 1,
The return means may include:
A return pump disposed in the AGS water tank; And
A return pipe extending from the return pump to the biological treatment tank so as to return the reaction solution in the AGS water tank to the biological treatment tank with the return pump;
Wherein the aerobic granule sludge separator comprises:
The method according to claim 1,
Wherein the filtering means comprises:
A scraper disposed in contact with the filtering belt at a position where the filtering unit is switched from the filtering belt to the filtering unit for filtering the reaction liquid upon rotation on the filtering belt so as to drop the aerobic granule sludge filtered by the filtering unit;
Wherein the aerobic granule sludge is fed to the aerobic granular sludge sorting device.

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