KR100536068B1 - Dmr:(dai-ho microbe revolution) - Google Patents

Abstract

The present invention is composed of a structure in which a plurality of carrier units filled with composite carriers are installed along the circumferential direction of the inner housing, and the structure of the outer housing and the carrier unit can be improved to increase the inflow efficiency of the influent, and The present invention relates to a carrier rotor filled with a composite carrier for advanced treatment of sewage, which can maximize desorption, decomposition of organic matter and nitrogen and phosphorus removal efficiency.

To this end, the present invention is a cylindrical inner housing having a rotating shaft attached to both sides; A hollow carrier unit arranged along the outer diameter (circumference) direction of the inner housing and arranged along the longitudinal direction and having a plurality of holes on the entire surface thereof; A plurality of support plates that are vertically bent to form a flat iron of a predetermined length through which the coupling holes penetrate at equal intervals, and are inserted between the respective support plates in order to maintain a constant distance between the respective support plates to be aligned with the coupling holes An outer housing comprising a pipe to be connected to each other, a coupling hole of each of the supporting plates, and a round bar inserted into each pipe; Drive means connected to the rotary shaft; Provided is a carrier rotor filled with a composite carrier for the advanced treatment of sewage, characterized in that consisting of a control unit for controlling the drive of the drive means.

Description

Carrier rotator with composite carrier for advanced treatment of sewage {DMR: (Dai-ho Microbe Revolution)}

The present invention relates to a carrier rotor filled with a composite carrier for advanced treatment of sewage, and more particularly, comprising a structure in which a plurality of carrier units filled with a plurality of composite carriers are installed along a circumferential direction, the outer housing and Carrier filled with a composite carrier for advanced treatment of sewage to improve the structure of the carrier unit, increase the inflow efficiency of the influent, and further maximize the efficiency of desorption of sludge, decomposition of organic matter and removal of nitrogen and phosphorus. Relates to a rotator.

Generally, sewage, factory waste, and food waste sediment, livestock manure, and other contaminated water are the main pollutants in rivers.These sewage and contaminated water are purified by sewage treatment plants in each city. It is discharged to the river.

The sewage treatment plant installed in each city is designed and constructed to handle the amount of sewage drained per day in the city, but as the population density continues to increase, the amount of sewage drained increases. It should also be enlarged by enlargement. The expansion and new construction of such a large sewage treatment plant has various difficulties due to the complex selection of construction sites, budget and compensation issues, operation and securing of professional personnel.

Similarly, even in small and medium-sized cities with few inhabitants, new construction of sewage treatment plants has various difficulties such as budget and site selection.

However, it is clear that the sewage treatment plant treating domestic sewage and various polluted waters is an essential facility in consideration of the prevention of pollution of rivers and groundwater and the protection of river ecosystems. Therefore, the construction of sewage treatment plants for each city must be made.

Here will be described the existing sewage treatment facilities and construction methods.

FIG. 8 is a process chart showing the conventional A ² / O (Anarobic / Anoxic Aerobic) method, and an anoxic tank is installed between an anaerobic tank and an aerobic tank in the A / O (Air Products and Chemicals) method to simultaneously remove nitrogen and phosphorus. It shows the method to do. In the conventional A ² / O method, the F / M ratio is 0.15 to 0.25 kg · BOD / kg · MLVSS · day and the solids retention time (SRT) is 4 to 7 days. The hydraulic retention time (HRT) is 0.5-1.5 hours for anaerobic sections, 0.5-1.0 hours for anaerobic sections and 3.5-6.0 hours for aerobic sections, and the average MLSS of the aeration tank is maintained at 3,000-5,000 mg / l.

The conventional A ² / O method includes a circulation stage of the denitrification tank from the aerobic tank, where the circulated influent reaches 100-300% of the total influent and can remove about 70% of nitrogen, but the phosphorus removal rate is In addition, there is a disadvantage that the fall, and in order to process the high phosphorus sand filter or a separate chemical treatment device is required, in winter there is a disadvantage that the operating efficiency is greatly reduced.

9 is a process chart illustrating a conventional modified unified cape town (MUCT) method.

Existing MUCT method improves efficiency by separating anoxic tank into 1st anoxic tank and 2nd anoxic tank in order to compensate for the shortcomings of the above-mentioned A ² / O method. The first anoxic tank can reduce only nitrates in the conveying sludge. The second anaerobic bath receives and removes much more nitrate when receiving the mixed liquid returned from the nitrification zone.

However, such a MUCT method has a disadvantage in that the power cost is increased and maintenance is complicated by the addition of an internal transfer pump, and the microbial retention time is 10 to 30 days, which is longer than other methods.

10 is a flowchart illustrating a conventional VIP (Virginia Initiativ Plant) method.

The existing VIP method is another variation of the MUCT method, which provides an anaerobic zone at the multi-stage stage of anaerobic tank, anaerobic tank and aerobic tank, and has a solids residence time (SRT) of 5-10 days, which is shorter than the MUCT method and operates at a much higher load rate. . The mixed liquor to the anaerobic tank is drawn from the last anaerobic zone. Therefore, while the phosphorus removal ability is high, the removal rate of nitrogen is significantly lower than other methods.

11 is a flowchart illustrating a conventional Dae-woo Nutrient Removal (DNR) method.

The existing DNR method improves the efficiency of phosphorus release in the anaerobic tank by denitrifying nitrogen nitrate in the sludge storage tank, which is an advantage of the MUCT method and VIP method described above, to compensate for the shortcomings of the A ² / O method. It is a construction method. This method is suitable for low concentration influent and stable removal rate of nitrogen and phosphorus, but has a disadvantage of requiring a long residence time and a large land area because the reaction tank is too large.

Such a conventional sewage treatment method has a common focus on the removal of nitrogen and phosphorus, resulting in an increase in construction costs and maintenance costs, causing complex and difficult problems of maintenance and repair.

In this regard, the applicant of the present application has already been filed (Registration No. 0477841) for the "carrier rotor filled with a composite carrier and the advanced method for treating sewage using the same" in view of the above problems.

The above patents are passed through the carrier rotator which rotates and drives the influent flowing into the aerobic tank through the settling basin-first sedimentation tank-anaerobic tank as opposed to the inflow direction of the inflow water, and at the same time passes through the composite carrier filled therein. This is a technology that can maximize the efficiency of decomposition of organic matter and removal of nitrogen and phosphorus, and increase the efficiency of treatment of influent due to the short residence time of influent. Unlike conventional processes, the influent that passes through an aerobic tank is returned to the oxygen-free tank. There is no need for the process, which can greatly reduce the power cost, and there is no need for a separate chemical treatment facility, so the cost of the facility is low, and the operation is simple in the process, so it is easy to maintain and maintain.Small and small new sewage and wastewater treatment plants This technique can be usefully applied to.

Looking at the configuration of the carrier rotor disclosed in the above patent briefly, a hollow outer housing formed with a plurality of holes on the entire surface, the inner housing of the same length and forming a partition in the outer housing, the outer housing And a hollow carrier unit arranged along the circumferential direction in the space between the inner and the inner housing and arranged along the longitudinal direction, the hollow carrier unit having a plurality of holes formed on the entire surface thereof, and a plurality of composites filled in the inside of the carrier unit. And a carrier, a rotating shaft attached to both sides of the outer housing, a driving means connected to the rotating shaft, and a control unit for controlling the driving of the driving means.

The carrier rotator of this configuration is installed in the aerobic tank so as to rotate in a direction opposite to the inflow direction of the inflow water.

However, the carrier rotator disclosed in the Applicant's patent registered the inflow water to the inside of the carrier unit through a plurality of holes (pores) formed in the outer housing, the inlet water is the hole of the outer housing because the carrier rotator itself rotates There is a tendency to not flow smoothly into the carrier unit through.

In addition, a plurality of composite carriers are filled in the carrier unit in the carrier rotator, but the carriers are damaged due to the vibration of the carrier rotator being pulled to one side or collided with each other. .

When the composite carrier is damaged, the sludge desorption, the decomposition of organic matter, and the nitrogen and phosphorus removal efficiency are slightly reduced.

For reference, the composite carrier filled in the carrier unit is a microorganism-immobilized organic / inorganic composite carrier, which has been registered and registered by the applicant and the Korea Institute of Chemical Technology (Registration No. 0481973), and an inorganic material. Refers to a microbial composite carrier prepared by mixing and molding an organic material including a polymer with a pore-forming agent.

Therefore, the present invention is invented to solve the problems of the carrier rotor as described above, the outer housing and the inner housing of the carrier rotor is produced in a spherical shape using the flat iron, these flat irons in the axial direction using a round bar and pipe By installing them at equal intervals, the area where influent (sewage) can pass toward the carrier unit in the carrier rotator is increased, so that dissolved oxygen and mass transfer to the inside of the carrier unit can be made very smooth. It is an object to provide a carrier rotor filled with a composite carrier for treatment.

Another object of the present invention is to improve the structure of the carrier unit arranged in the carrier rotor to a structure having a perforated pressure plate and a support spring, so that the carriers in the carrier unit can be firmly fixed.

The present invention for achieving the above object is a cylindrical inner housing having a rotating shaft attached to both sides; A hollow carrier unit arranged along the outer diameter (circumference) direction of the inner housing and arranged along the longitudinal direction and having a plurality of holes on the entire surface thereof; A plurality of support plates that are vertically bent to form a flat iron of a predetermined length through which the coupling holes penetrate at equal intervals, and are inserted between the respective support plates in order to maintain a constant distance between the respective support plates to be aligned with the coupling holes An outer housing comprising a pipe to be connected to each other, a coupling hole of each of the supporting plates, and a round bar inserted into each pipe; Drive means connected to the rotary shaft; Provided is a carrier rotor filled with a composite carrier for the advanced treatment of sewage, characterized in that consisting of a control unit for controlling the drive of the drive means.

As a preferred embodiment, a threaded portion is formed at both ends of the round bar, and a circular block plate having a rotating shaft through hole formed in the threaded portion is coupled with a nut.

In a more preferred embodiment, the carrier unit is further arranged along the circumferential direction on the support plate of the outer housing and at the same time arranged further along the longitudinal direction to form a two-stage arrangement along the radial direction, the two-stage arranged carrier The external housing is further mounted on the unit.

In particular, the carrier unit is a cylindrical case formed with an open hole on one side and a plurality of holes on the entire surface; A plurality of composite carriers filled through the openings; A perforated pressure plate for pressurizing the composite carrier to prevent flow; As the configuration is attached while closing the opening hole, characterized in that consisting of a perforated plate with a spring attached to the inner surface to push the perforated pressure plate.

In addition, the perforated plate is further attached to the inside of the cylindrical case of the carrier unit along its longitudinal direction, and the inside of the cylindrical case is divided into three or four spaces along its radial direction.

On the other hand, the drive means is characterized in that consisting of a sprocket attached to the rotating shaft, a reducer, and a chain connecting the sprocket and the external reducer.

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

1 is an exploded perspective view showing a carrier rotor filled with a composite carrier for the advanced treatment of sewage according to the present invention, Figure 2 is an assembled perspective view.

The carrier rotator of the present invention is installed to rotate in the opposite direction to the inflow direction of the inflow water in the aerobic tank of the sewage treatment facility, a number of composite carriers filled in the carrier unit in the carrier rotator as described above, the applicant and the Korean Chemical Use the "Microorganism Immobilized Organic / Inorganic Hybrid Carrier" that the researcher co-filed and registered (Registration No. 0481973).

The inner housing 12 constituting the inner skeleton of the carrier rotor 10 according to the present invention has a cylindrical shape, and the rotating shaft 14 is integrally attached to both sides thereof.

At this time, a plurality of cylindrical carrier units 16 are arranged on the outer diameter surface of the inner housing 12, and the plurality of cylindrical carrier units 16 are arranged in close contact along the outer diameter (circumference) direction of the inner housing 12 and at the same time. Is placed.

The carrier unit 16 is a configuration in which the plurality of microbial complex carriers 18 are filled therein, the detailed structure of which is described below, and the carrier unit disposed on the outer diameter surface of the inner housing 12. (16) will be described first with respect to the outer housing 20 that is wrapped around.

The outer housing 20 is improved so that the inflow water can be easily introduced to the inside of the carrier unit 16, and the plurality of support plates 22 bent in a spherical shape and the interval between the support plates 22 are constant. It consists of a pipe 24 to maintain, and a round bar 26 to tie the support plate 22 and the pipe 24 to one.

More specifically, the support plate 22 is a structure in which a flat strip having a flat strip shape is vertically formed and then bent in a spherical shape, and a plurality of coupling holes 28 are formed in a bent state in proportion to the circumferential direction thereof. It is formed through at equal intervals.

Preferably, the inner diameter of the support plate 22 is formed to be equal to the outer diameter of the carrier units 16 disposed on the circumferential surface of the inner housing 12.

In addition, the pipe 24 is disposed between each support plate 22, and is disposed at a position coinciding with the coupling hole 28 formed in each support plate 22, the interval of each support plate 22 at a constant interval It acts as a sort of spacing bar to hold.

The round bar 26 is continuously inserted into the coupling hole 28 of each support plate 22 and the pipe 24 disposed between the support plates 22, thereby coupling each support plate 22 and the pipe 24 into one. It will play a role.

In addition, the circular blocking plate 30 is coupled to both ends of the round bar 26 by a nut.

At this time, a rotation shaft through-hole 32 through which the rotation shaft 14 of the inner housing 12 is formed is formed at the center of the circular blocking plate 30.

Therefore, the separation space of each of the support plates 22 is a passage through which the inflow water (sewage) can pass toward the carrier unit 16 in the carrier rotor 10, and eventually the passage of the inflow sewage compared to the conventional perforated external housing. As the area becomes much increased, dissolved oxygen and substance transfer to the inside of the carrier unit 16 in the outer housing 20 are made very smooth.

Here, the structure of the carrier unit will be described in more detail.

FIG. 4 is an exploded perspective view illustrating a carrier unit of a carrier rotor filled with a composite carrier for advanced treatment of sewage according to the present invention, and FIGS. 5A and 5B show that the inside of the carrier unit shown in FIG. 4 is divided. It is a cross section.

The carrier unit 16 is formed as an open hole on one side, a cylindrical case 34 formed with a plurality of perforation holes 52 on the entire surface, and a plurality of composite carriers filled in the cylindrical case 34 ( 18) and means for firmly fixing the composite carrier 18 so as not to flow by an external force.

That is, as a fixing means for preventing the flow of the composite carrier 18 and the contact / abrasion according to the flow, the punching plate 36 is inserted through the opening of the cylindrical case 34 of the carrier unit 18 It includes, as the perforated pressure plate 36 presses a plurality of composite carriers 18, the composite carriers 18 are kept in place.

At this time, while pressing the composite carrier 18, the punching plate 36 inserted through the opening of the cylindrical case 34 of the carrier unit 16 is maintained in a pressurized state by a separate punching finish plate 38 Done.

The perforated finish plate 38 is configured to pressurize the perforated pressure plate 36 in the cylindrical case 34 and seal the open hole, and to attach the perforated pressure plate 36 to the inner surface of the plurality of springs 40. ) Is attached.

On the other hand, the perforated splitting plate 42 is inserted into the inside of the cylindrical case 34 of the carrier unit 16 along its longitudinal direction. The perforated splitting plate 42 is cross-sectional or triangular when viewed in cross section. Is formed.

Thus, by the perforated plate inserted in the carrier unit 16 along its longitudinal direction, the interior of the cylindrical case 34 is divided into three or four spaces along its radial direction.

By filling the composite carriers 18 in the space divided by the perforated partition plate 42, the contact area between the composite carriers 18 can be reduced, and the wear phenomenon due to the contact between the composite carriers 18 can be reduced. It can be greatly reduced.

In addition, it is preferable that the cylindrical case 34, the punching plate 36, the punching plate 42, and the punching finish plate 38 of the carrier unit 16 are made of stainless steel resistant to corrosion. Alternatively, in the case of manufacturing with a non-metal (plastic, PE, PP, PLT) can be reduced in weight, the weight of the rotation can be reduced according to this weight.

On the other hand, a driving means is connected to the rotary shaft 14 of the inner housing 12, the driving means is a sprocket 44 attached to the rotary shaft 14, and a reducer 46 disposed outside the aerobic tank and , A chain 48 connecting the sprocket 44 and the external reducer 46, and the control unit 50 for speed control is connected to the reducer 46.

3 is a perspective view showing a state in which carrier units are arranged in two stages as a carrier rotor filled with a composite carrier for advanced treatment of sewage according to the present invention.

As shown in FIG. 3, in the case of a sewage treatment plant having a large treatment capacity, the carrier units may be arranged in two stages along the radial direction.

That is, the carrier units 16 and 16 'are arranged on the support plate 22 of the outer housing 20 by further arranging a plurality of carrier units 16' along the circumferential direction thereof. The two stages are arranged along the radial direction.

Of course, the outer housing 20 'of the same structure as described above is further mounted on the two-stage carrier unit 16'.

Here, looking at the advanced treatment of the sewage made by the carrier rotor of the present invention having the configuration as described above are as follows.

6a and 6b is a process chart for the advanced treatment of sewage using a carrier rotator packed with a composite carrier according to the present invention, Figure 7 is a carrier treatment device packed with a composite carrier according to the present invention advanced treatment of sewage Schematic diagram showing the arrangement in the aerobic tank.

Usually, the advanced treatment facility of sewage is arranged as a sedimentation basin-initial sedimentation cell-anaerobic tank-anaerobic tank-aerobic tank-final sedimentation cell, or distribution tank-anoxic tank-aerobic tank-final sedimentation cell-sludge storage tank-discharge tank, the carrier rotator of the present invention It is installed to be rotatable by dipping, but is installed to rotate in the opposite direction to the inflow direction of the influent.

Therefore, when the inflow water flows into the aerobic tank, the carrier rotor 10 is driven to rotate in the opposite direction to the inflow direction of the inflow water flowing into the aerobic tank, so that the influent is reversed while receiving the flow resistance by the carrier rotor (10) At the same time, the mixture is soaring upward, making contact with air more efficient.

On the other hand, a concentration sensor (BOD Meter) is installed at the inlet of the aerobic tank to measure the concentration of the influent, the concentration sensor (not shown) after detecting the concentration of the influent (BOD), the signal is The control unit 50 is transmitted to the control unit 50, and the control unit 50 sends a speed control signal to the speed reducer 46 which is the driving means.

That is, if the concentration of the influent flowing into the aerobic tank is detected at a high concentration with excessive sludge attachment, the rotation speed of the carrier rotor 10 is increased, and if the concentration of the influent is detected at a low concentration with no sludge, the carrier rotor 10 is Speed control to reduce the rotation speed.

Thus, inflow water flows inwardly through a passage (between the support plates) formed in the outer housing of the carrier rotor 10 in a state in which the carrier rotor 10 is rotated at a high speed or a low speed according to the concentration of the inflow water. 10, and flows therein through the perforation holes 52 of the plurality of carrier units 16 and 16 'disposed inside the composite carrier 18, which is filled in the respective carrier units 16 and 16'. ) The influent flows smoothly.

At this time, even if the composite carriers 18 in the carrier unit 16 are subjected to an external force (vibration during the rotational drive of the carrier rotor), they are firmly fixed by the punching press plate 36 and the punching finish plate 38. As a result, contact friction between each other is reduced and the wear of the composite carrier can be minimized.

As such, when the inflow water passes through the composite carrier 18 filled in the carrier unit 16, the microorganism is attached to the composite carrier having open / close pores having a diameter of 50 to 500 μm suitable for the microbial habitat environment. Because it rotates in the opposite direction to the influent, the contact efficiency is very high, and the adsorption power of the pollutants is very good, so that decomposition of organic matter and intake of nitrogen and phosphorus occur easily.

As seen from the above, according to the carrier rotator filled with a composite carrier for the advanced treatment of sewage according to the present invention, the inlet is rotatably installed in the aerobic tank of the sewage advanced treatment facility, the inflow of the carrier unit By allowing the composite carrier filled therein to pass more smoothly, it is possible to maximize the desorption of sludge and decomposition of organic matter and the removal efficiency of nitrogen and phosphorus, and the residence time of the influent can be shortened to increase the treatment efficiency of the influent.

In particular, according to the present invention, by improving the configuration of the external housing to the structure that can be introduced more water to the carrier unit, it is possible to further increase the high processing efficiency, such as decomposition of organic matter and intake of nitrogen and phosphorus.

In addition, by improving the structure of the carrier unit to include a punching plate, a punching finish plate having a spring, and a punching split plate, the carriers are firmly fixed to the composite carriers, and at the same time, the contact friction between them can be minimized to minimize wear. have.

Figure 1a is a carrier rotor filled with a composite carrier for the advanced treatment of sewage according to the present invention, is an exploded perspective view showing a state in which the carrier unit arranged in one stage, Figure 1b is a side cross-sectional view,

Figure 2 is an assembled perspective view showing a carrier rotor filled with a composite carrier for the advanced treatment of sewage according to the present invention,

Figure 3a is a carrier rotor filled with a composite carrier for the advanced treatment of sewage according to the present invention, an isolated perspective view showing a state in which the carrier unit is arranged in two stages, Figure 3b is a side cross-sectional view,

4 is an exploded perspective view showing a carrier unit of a carrier rotor filled with a composite carrier for the advanced treatment of sewage according to the present invention;

5a and 5b are cross-sectional views showing that the inside of the carrier unit shown in Figure 4 is divided;

6a and 6b is a process chart showing an example of the advanced treatment of sewage using a carrier rotor filled with a composite carrier according to the present invention,

7 is a schematic view showing that the carrier rotator filled with the composite carrier according to the present invention is disposed in an aerobic tank in an advanced treatment facility of sewage,

8 is a process chart showing a conventional A ² / O method,

9 is a process chart showing a conventional MUCT method,

10 is a process chart showing a conventional VIP method,

11 is a process chart showing a conventional DNR method;

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

10: carrier rotation 12: internal housing

14: rotating shaft 16, 16 ': carrier unit

18: complex carrier 20, 20 ': external housing

22: support plate 24: pipe

26: round bar 28: coupling hole

30: circular block plate 32: rotating shaft through hole

34: cylindrical case 36: punching plate

38: punching finish plate 40: spring

42: punching plate 44: sprocket

46: reducer 48: chain

50: control unit 52: drill hole

Claims (6)

A cylindrical inner housing having a rotating shaft attached to both sides; A hollow carrier unit arranged along the outer diameter (circumference) direction of the inner housing and arranged along the longitudinal direction and having a plurality of holes on the entire surface thereof; A plurality of support plates that are vertically bent to form a flat iron of a predetermined length through which the coupling holes penetrate at equal intervals, and are inserted between the respective support plates in order to maintain a constant distance between the respective support plates to be aligned with the coupling holes An outer housing comprising a pipe to be connected to each other, a coupling hole of each of the supporting plates, and a round bar inserted into each pipe; Drive means connected to the rotary shaft; Carrier rotor filled with a composite carrier for the advanced treatment of sewage, characterized in that consisting of a control unit for controlling the drive of the drive means. The carrier rotor of claim 1, wherein a screw part is formed at both ends of the round bar, and a circular block plate having a rotating shaft through hole formed in the screw part is coupled with a nut. The carrier unit of claim 1, wherein the carrier unit is further disposed along the circumferential direction on the support plate of the outer housing and at the same time, a plurality of the carrier units are arranged along the longitudinal direction to form a two-stage arrangement in the concentric direction. Carrier rotor filled with a composite carrier for the advanced treatment of sewage, characterized in that the outer housing is further mounted. The method according to claim 1, The carrier unit is: A cylindrical case in which an open hole is formed at one side and a plurality of holes are formed at an entire surface thereof; A plurality of composite carriers filled through the openings; A perforated pressure plate for pressurizing the composite carrier to prevent flow; The carrier rotor is filled with a composite carrier for the advanced treatment of sewage, characterized in that the configuration is attached while closing the opening hole, consisting of a perforated plate with a spring attached to the inner surface to push the perforated pressure plate. The method according to claim 1 or 4, wherein the perforated plate is further attached to the inside of the cylindrical case of the carrier unit along its longitudinal direction, the inside of the cylindrical case is divided into three or four spaces along the radial direction Carrier rotor filled with a composite carrier for the advanced treatment of sewage. The carrier rotor of claim 1, wherein the driving means comprises a sprocket attached to the rotating shaft, a reducer, and a chain connecting the sprocket and the external reducer.