KR101176204B1 - Telescopic decanter for a sequencing batch reactor - Google Patents

Abstract

The present invention relates to a decanter in which a series of treatment processes consisting of inflow-reaction-sedimentation-effluent of wastewater can be carried out in a single reactor, to separate and discharge the treated water from the reaction tank with activated sludge. More specifically, by installing a buoy at the top of a telescopic cord that is flexibly connected to a plurality of pipes providing a discharge passage of the treated water, when the waste water is introduced by the buoyancy buoyancy When the treated water is discharged, the decanter can be operated in a telescopic method in which the telescopic probe is reduced along the downward direction due to the weight of the buoy. This prevents the decanter from frequent failures or malfunctions, thereby discharging the treated water. Activated sludge deposited at the bottom of the reactor while ensuring more reliable operation Of the disturbance is suppressed as much as possible in the sludge component of a sequencing batch reaction quiet telescopic decanter to avoid leakage along with the treated water.
To this end, in the telescopic decanter 10 according to the present invention, a plurality of pipes 12a, 12b, 12c are installed in the vertical direction at the bottom of the continuous batch reactor 1 so as to be elastically connected to discharge the treated water. The telescoping rod 12 provides a passage, and is attached to the upper end of the telescoping rod 12 and is made up of a buoy 11 to induce the telescopic rod 12's stretching operation, the buoy ( 11) or the inflow passage of the treated water is provided on the upper side of the telescope 12, the treated water discharge pipe (3) is connected to the lower side of the telescope rod 12, the inflow passage of the treated water , And a porous pipe 15 connected to the upper pipe 12a of the telescope rod 12 at the lower portion of the buoy 11, and at the bottom of the continuous batch reactor 1 Telescopically mounted telescopic rod 12 is installed parallel to the rod 12 It further comprises a guide rail 13 for guiding operation.

Description

Telescopic decanter for a sequencing batch reactor

The present invention is to be installed in a continuous batch reactor to allow the decanter to separate the discharged treated water from the activated sludge with the activated sludge can be operated in a telescopic method using a telescope, to prevent frequent failures or malfunction of the decanter treatment The present invention relates to a telescopic decanter for a continuous batch reactor, in which the discharge of activated sludge deposited at the bottom of the reactor is prevented to the maximum while ensuring the discharge of water more reliably.

In general, there are known physical treatment methods, chemical treatment methods, and biological treatment methods to remove organic substances, nitrogen, and phosphorus from wastewater at the same time. Among them, physical and chemical treatment methods require a large amount of expensive chemicals. Not only is it undesirable in terms of economical treatment, but also has a high risk of secondary pollutants caused by the use of chemicals.

From the above point of view, the biological treatment method is not only economically advantageous over other methods, but also has advantages such as easy operation of the apparatus used for wastewater treatment and less risk of secondary pollutants from the treatment plant. It is a trend that has been actively applied in recent years, and a representative example thereof is a sequencing batch reactor (SBR).

The continuous batch reactor is a method of changing the process using the activated sludge cultured from microorganisms from a spatial concept to a temporal concept, giving aerobic and anaerobic conditions without any additional peripherals and various organic matter and nitrogen. And the phosphorus component can be removed, and a series of treatment processes including inflow-reaction-precipitation-outflow can be performed in a single reactor, thereby providing temporal and spatial advantages.

As shown in FIG. 1, the continuous batch reactor 1 is connected to a wastewater supply pipe 2 at an upper end side thereof, while at the lower end side thereof, the treated water treated by microorganisms is discharged by a discharge pump 3a. A treatment water discharge pipe 3 for discharging to the outside of the reaction tank 1 is connected, and the treatment water discharge pipe 3 is connected to a filtration tank not shown in which a filtration mechanism such as a membrane filter is built.

In addition, the inside of the continuous batch reactor (1), the stirring blade (5b) connected to the lower end of the motor shaft (5a) of the stirring motor (5), and the air disperser (4b) connected to the blower (4) by the air supply pipe (4a) And a decanter 8 for discharging the treated water, respectively, and a water level level sensor 6 is installed inside one side of the continuous batch reactor 1 while a sludge discharge pipe is installed at the bottom thereof. 7) This connection is installed.

The stirring blade (5b) performs a function of mixing the activated sludge cultured microorganisms in the continuous batch reactor (1) evenly with the waste water, the air disperser (4b) is a floating (浮上) and aerobic ( Nitrification) to perform the necessary oxygen supply function, the anaerobic (denitrification) reaction is carried out under the condition that the oxygen supply by the air disperser (4b) is not made.

As described above, after the biological treatment of wastewater by microorganisms is performed inside the continuous batch reactor 1, the activated sludge cultured with the microorganisms is precipitated to the bottom of the continuous batch reactor 1, and sludge is not included. The filtrate as untreated water is discharged to the outside of the continuous batch reactor 1 through the treated water discharge pipe 3 equipped with the discharge pump 3a.

In this case, the amount of treated water discharged from the continuous batch reactor 1 is adjusted to about 50% to 60%, because the discharge of activated sludge occurs when the amount of treated water discharged exceeds 60%. This is because it causes contamination of the treated water, as well as increases the filtration load of the treated water in the subsequent filtration step, so that the decanter 8 inside the continuous batch reactor 1 can control the discharge of the treated water. Is installed.

The decanter 8 is installed based on the buoy 8a floating on the surface of the waste water (treated water) stored in the continuous batch reactor 1, and provides the inflow passage of the treated water to the buoy 8a. On the other hand, by connecting the buoy 8a with the treated water discharge pipe 3 equipped with the discharge pump 3a, the filtrate as the treated water located on the upper side of the activated sludge which has been settled is discharged from the discharge pump 3a. According to the operation it performs a function to discharge sequentially from the water surface.

The decanter 8 is also a well-known component widely used in the continuous batch reactor 1, and various forms such as simple floating type or lever operated type are known according to its operation method, but in FIG. ) Is installed to the angular motion by the hinge lever (8c), it is shown as a representative example that is connected to the treated water discharge pipe (3) by the discharge tube (8b) of a flexible material.

However, according to the conventional decanter 8 as described above, the continuous batch reactor 1, the hinge lever 8c, and the buoy 8a are connected to each other by linkage, so that the buoy 8a and the hinge lever 8 There was a problem in that the installation strength of the decanter 8 including 8c) is weak, which causes the connection between the hinge lever 8c and the buoy 8a to be easily damaged or dropped during operation of the decanter 8. there was.

If the connection between the hinge lever 8c and the buoy 8a is damaged or dropped as described above, the decanter 8 may be broken or malfunction, and the discharge of the treated water may not be accurately performed. In this case, there is a problem that the waste water treatment operation itself is temporarily suspended until the decanter 8 is repaired.

In addition, since the motor shaft 5a, the stirring blade 5b, and the like cannot be positioned within the angular movement range of the buoy 8a by the hinge lever 8c, the continuous batch reactor including the decanter 8 ( Constraints occur in the setting and installation work of 1), while the range of angular movement of the buoy 8a by the hinge lever 8c and the adjustment range of the treated water discharge based on the hinge lever 8c are also known as the motor shaft 5a and the stirring blades. (5b) There was a problem that is limited by the position where the back is installed.

In particular, when the buoy (8a) is lowered along the surface of the treated water during the discharge of the treated water, the discharge tube (8b) connected to the lower end side of the buoy (8a) also with the buoy (8a) reaction tank ( It sinks to the bottom of 1), in this process the problem that the discharge tube 8b disturbs the activated sludge deposited on the bottom of the reaction tank (1), which causes a part of the precipitated activated sludge There was a problem that is diffused into the treated water and discharged together with the treated water.

As described above, according to the conventional decanter 8, since it is not possible to prevent the sludge component from being contained in the treated water discharged from the continuous batch reactor 1 more effectively, filtration such as a membrane filter in the subsequent filtration step. The apparatus is frequently clogged, which causes the cleaning and replacement cycles of the filtration apparatus to be relatively short, thereby preventing economic and rational wastewater treatment.

The present invention has been made to solve the conventional problems as described above, when the inflow of waste water, the telescope is extended to the upper portion by buoyancy of the buoys, when the discharge of the treated water telescopes by the weight of the buoys Provides telescopic decanters with telescopic decanters that shrink along the lower direction, making it easier and easier to install the decanters inside the continuous batch reactor, and prevent decanters from frequent breakdowns and malfunctions, making sure the discharge of treated water is more reliable. The technical problem is to prevent the sludge component from flowing out with the treated water by maximally suppressing the disturbance of activated sludge deposited at the bottom of the reactor.

Telescopic decanter according to the present invention as a means for solving the above technical problem, and the telescopic cord is installed in the vertical direction at the bottom of the continuous batch reactor in such a way that a plurality of pipes are elastically connected to provide a discharge passage of the treated water and The buoys are connected to the upper end of the telescope rod to be configured to induce the telescoping telescopic operation. The buoy or the upper side of the telescope rod is provided with an inflow passage for the treated water. It is connected to the lower end side of the telescope rod, characterized in that the inflow passage of the treated water is a porous pipe connected to the upper side pipe of the telescope rod directly under the buoy.

In addition, the decanter of the present invention, is installed in parallel with the telescope to the bottom of the continuous batch reactor, and further comprises a guide rail for guiding the telescoping expansion and contraction operation, the upper end of the pipe of the telescope The guide unit is connected and installed, and the front end side of the guide unit is installed into the guide rail, and the discharge pump is characterized in that the submersible pump is mounted to the treated water discharge pipe inside the continuous batch reactor.

In addition, the turbidity sensor for measuring the concentration of the activated sludge contained in the treated water is installed on the lower side of the porous pipe, the turbidity sensor is characterized in that the cleaning nozzle for the sensor is provided.

According to the present invention as described above, by operating the decanter by telescoping telescopic expansion and contraction, there is an effect of sufficiently securing the installation strength compared to the conventional decanter that was a linkage structure using a hinge lever, There is an effect of minimizing the failure or malfunction, and thus it is possible to accurately perform the discharge operation of the treated water, as well as to prevent the situation in which the waste water treatment operation is stopped by the decanter in advance.

In addition, since the buoy is connected to the upper side of the telescope rod and moves only in the vertical direction, the decanter is placed inside the continuous batch reactor without being bound by the position of the motor shaft or the stirring blade. It has an effect that can be easily and easily installed, and the discharge of treated water by the decanter also has an effect that can be easily adjusted to the pipe length of the lower side of the telescope.

In particular, when the buoy descends during discharge of the treated water, all other remaining pipes located on the upper side are inserted into the decanter from the lower side of the telescope rod to the inside of the pipe fixed to the bottom of the reactor. In the process of discharging the water by the telescope, there is an effect that the activated sludge deposited at the bottom of the reactor does not disturb at all.

Since the sludge component is discharged together with the treated water in the same manner as described above, the cleaning and replacement cycles of the filtration device such as the membrane filter can be extended to the maximum in the subsequent filtration step. This provides a very useful effect, such as being able to perform more economical and reasonable wastewater treatment than the conventional case.

1 is a schematic installation state diagram of a conventional decanter installed in a continuous batch reactor,
2 is a side cross-sectional view showing a telescopic decanter according to the present invention,
3 is a plan view of FIG.
Figure 4 is a side view showing an example of the turbidity sensor used in the telescopic decanter according to the present invention,
5 and 6 is a state diagram used in the telescopic decanter according to the present invention.

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

The telescopic decanter 10 according to the present invention is installed in the vertical direction at the bottom of the continuous batch reactor 1, as shown in Figures 2 and 3, respectively, the telescopic rod (to provide a discharge passage of the treated water ( Telescope-rod (12) and the buoy (11) connected to the upper end of the telescope rod 12 is installed to induce the telescopic rod (12) telescopic operation.

In the drawing, the telescope rod 12 has three pipes including a first pipe 12a on the upper side, a second pipe 12b on the center, and a third pipe 12c on the lower side. However, the number of pipes forming the telescope 12 according to the height required for the decanter 10 and the discharge amount of the treated water (the settling thickness of the activated sludge) may be at least two to five or more.

The third pipe 12c located at the lowermost part of the telescope rod 12 serves as a storage case of the other pipes 12a and 12b located at the upper side, while the decanter 10 of the present invention is substantially loaded. It serves as a pedestal to support, the height of the third pipe (12c) is installed, that is, the height of the lowest pipe of the telescope rod 12 is to be installed higher than the settling layer of the activated sludge.

In addition, an inflow passage for the treated water is provided at the upper end side of the buoy 11 or the telescope rod 12, while the treated water discharge pipe 3 is disposed at the lower end side of the third pipe 12c of the telescope rod 12. Is connected to the first pipe 12a and the second pipe 12b forming the telescope rod 12, and the connecting portion of the second pipe 12b and the third pipe 12c forming a sealing ring (16) ) Is installed.

The sealing ring 16 is installed between the lower flange of the pipe located on the upper side and the upper inner surface of the pipe located on the lower side, thereby preventing waste water from flowing into other parts except the treated water inflow passage. In addition, it is possible to have a bearing means for assisting the telescoping 12 telescopic operation of the telescopic rod 12 while having a watertight function in place of the sealing ring (16).

In addition, the buoy 11 is fastened to the bar bolt 14 in the state inserted along the rod bolt 14 fixed to the upper end side of the first pipe 12a of the telescope rod 12 in the drawing. The nut 14a is connected to the telescope cord 12 by the nut 14a, but the method of installing the buoy 11 on the telescope cord 12 may be applied in various ways.

In addition, the decanter 10 according to the present invention is installed in parallel with the telescope rod 12 at the bottom of the continuous batch reactor 1, the guide rail 13 for guiding telescopic operation of the telescope rod 12. ) And two guide rails 13 each having a cross section of an angle shape in the drawing (FIG. 2) are provided at both sides of the telescope rod 12.

On the other hand, a rod-shaped guide stand 17 is connected to both sides of the upper end surfaces of the first pipe 12a and the second pipe 12b of the telescope rod 12, and the tip side of the guide stand 17 is provided. By being inserted into the guide rail 13, the telescopic rod 12 is stretched and operated so that it can be accurately guided along the guide rail 13.

In some cases, the guide stand 17 provided in any one of the first pipe 12a and the second pipe 12b may be omitted, and the guide stand 17 may be replaced with the buoy 11. It is also possible to install on both sides of the lower outer circumference, and if the telescope rod 12 is made of five or more pipes, the number of pipes on which the guide stand 17 is installed is about two or three except for the lowermost side pipe. Is suitable.

In the decanter 10 of the present invention, the inflow passage for introducing the treated water along the inner space of the telescope cord 12 passes through the buoy 11 in the horizontal direction and the upper end of the telescope cord 12. It may be an inflow hole communicating with the side pipe 12a, or may be an inflow hole formed in the upper pipe 12a itself of the telescope rod 12. In addition, various types of treated water inflow passages may be attached to the buoy. 11 or the upper side pipe 12a of the telescope rod 12.

However, in the present invention, as shown clearly in FIGS. 2 and 3, four porous pipes radially connected to the upper pipe 12a of the telescope rod 12 directly underneath the buoy 11. By providing 15 as the treated water inflow passage, the treated water is divided and introduced evenly through the inlet hole 15a formed in each porous pipe 15, as a representative example.

When the porous pipe 15 is installed in the same manner as described above, in addition to the uniform inflow of the treated water through the telescope rod 12, the large particles of the suspended solids may be primarily filtered by the inlet hole 15a. On the other hand, even if one porous pipe 15 is blocked, it is possible to ensure the inflow of the treated water by the other porous pipe 15 of the other.

As described above, the four porous pipes 15 are radially installed, but the respective porous pipes 15 are disposed at positions displaced from the guide rails 13 so that the telescopic cords 12 do not interfere with the stretching operation. The turbidity sensor 20 is preferably installed at the end sides of the two porous pipes 15 facing each other with respect to the telescope rod 12.

In the case of the turbidity sensor 20, as shown in FIG. 4, the light emitting device 21 is installed in one sensor, and the light receiving device 22 is installed in the other sensor facing the light emitting device 21. As a representative example, a sensor module for measuring the intensity of transmitted light reduced and scattered due to the sludge component is emitted from the light emitting element 21 is a typical example.

However, as long as it is possible to control the operation of the decanter 10 by measuring the concentration of sludge contained in the treated water, other types of turbidity sensors may be used, as well as the light emitting device 21 and the light receiving device 22. In the case of using the turbidity sensor 20, the light emitting device 21 and the light receiving device 22 are adjacent to each other so as to prevent malfunction due to the attachment of sludge to the surfaces of the elements 21 and 22. It is preferable to install the washing nozzle 23 in the position.

The washing nozzle 23 may be an air spray nozzle connected to the blower 4 shown in FIG. 1, may be an injection nozzle of the treated water connected to the discharge pump 3a, or alternatively, a separate blower B may be provided with a spray pump for washing water (fresh water) may be connected to each washing nozzle (23).

In addition, the upper and lower surfaces of the guide rail 13 detect the storage level of the waste water or the treated water, and are mounted on the feed pump and the treated water discharge pipe 3, which are not shown, mounted on the waste water supply pipe 2. Although level switches 13a and 13b are provided to control the operation of the discharge pump 3a, the water level sensor 6 shown in FIG. 1 is replaced with the level switches 13a and 13b. It is also possible to apply, and also to the application of the sludge discharge pipe 7 shown in FIG.

Finally, as shown in FIGS. 5 and 6, the discharge pump 3a for discharging the treated water treated in the continuous batch reactor 1 to the outside along the treated water discharge pipe 3 is used as an underwater pump. Thus, when mounted to the treated water discharge pipe (3) connected to the decanter (10) inside the continuous batch reactor (1), the discharge pump (3a) can be configured as a single set together with the decanter (10) of the present invention. And, this can provide an advantage in terms of performing the setting and installation of the decanter 10 more easily.

When the telescopic decanter 10 of the present invention is installed and used inside the continuous batch reactor 1, when the wastewater flows into the reactor 1, the buoy 11 is shown in FIG. 5. In the case where the telescope cord 12 extends upward due to the buoyancy force and the treated water is discharged from the reaction tank 1, as shown in FIG. 6, the telescope cord 12 is caused by the weight of the buoy 11. Decreases along the downward direction.

As described above, the decanter 10 is operated in a telescopic method of telescoping 12 by the buoy 11, as compared to the conventional decanter 8, which has become a link structure using the hinge lever 8c. While the installation strength is excellent, it is possible to minimize the failure or malfunction of the decanter 10, thereby enabling the discharge of treated water accurately, as well as the waste water treatment operation by the decanter 10 The interruption situation can also be prevented.

In addition, since the buoy 11 is connected to the upper end side of the telescope rod 12 and moves only in the vertical direction, it is almost at a position such as the motor shaft 5a or the stirring blade 5b. The decanter 10 can be easily and easily installed inside the continuous batch reactor 1 without being bound by the discharge, and the discharged amount of the treated water by the decanter 10 is also the length of the lower pipe 12c of the telescope 12. It can be easily adjusted to fit.

In particular, when the buoy 11 is lowered in the process of discharging the treated water, located on the upper side into the pipe 12c fixed to the bottom surface of the reaction tank 1 at the lower side of the telescope rod 12. Since all other remaining pipes 12a and 12b are inserted, the telescoped 12 is completely free of activated sludge deposited at the bottom of the reactor 1 during the discharge of the treated water by the decanter 10. Do not disturb.

In this manner, since the telescopic decanter 10 of the present invention can effectively block the situation in which the sludge component is discharged together with the treated water, the cleaning and replacement cycle of the filtration device such as the membrane filter in the subsequent filtration step. Can be extended to the maximum, which makes the waste water treatment more economical and rational than conventional cases.

1: continuous batch reactor 2: waste water supply pipe 3: treated water discharge pipe
3a: discharge pump 4: blower 4a: air supply pipe
4b: Air Disperser 5: Stirring Motor 5a: Motor Shaft
5b: stirring blade 6: water level sensor 7: sludge discharge pipe
10 decanter 11: buoy 12: telescope
12a: 1st pipe 12b: 2nd pipe 12c: 3rd pipe
13: guide rail 13a, 13b: level switch 14: bar bolt
14a: nut 15: porous pipe 15a: inlet hole
16: sealing ring 17: guide 20: turbidity sensor
21 light emitting element 22 light receiving element 23 cleaning nozzle

Claims (5)

Installed in the continuous batch reactor (1) in a decanter to separate the treated water from the activated sludge according to the operation of the discharge pump (3a) attached to the treated water discharge pipe (3) treated in the reaction tank (1) In
The decanter 10 is a telescope rod which is installed in the vertical direction at the bottom of the continuous batch reactor 1 in such a way that a plurality of pipes 12a, 12b, 12c are elastically connected to provide a discharge passage of the treated water. (12), and is attached to the upper end of the telescope rod 12 is made of a buoy 11 to induce the telescopic operation of the telescopic rod 12,
An inflow passage for the treated water is provided at the upper side of the buoy 11 or the telescoped 12, and the treated water discharge pipe 3 is connected to the lower side of the telescoped 12,
The inflow passage of the treated water is a telescopic decanter for a continuous batch reactor, characterized in that the porous pipe 15 is connected to the upper pipe 12a of the telescope rod 12 directly under the buoy 11. . The guide rail (13) according to claim 1, wherein the decanter (10) is installed at the bottom of the continuous batch reactor (1) in parallel with the telescope (12) to guide telescopic operation of the telescope (12). ) With additional)
A guide stand 17 is connected to the upper end of the pipes 12a and 12b of the telescope rod 12, and the front end side of the guide stand 17 is inserted into the guide rail 13 to be installed. Telescopic Decanter for Continuous Batch Reactor. 3. The telescopic decanter according to claim 1 or 2, wherein the discharge pump (3a) is an underwater pump mounted to the treated water discharge pipe (3) inside the continuous batch reactor (1). delete The turbidity sensor 20 of claim 3, wherein a turbidity sensor 20 is installed below the porous pipe 15 to measure the concentration of activated sludge contained in the treated water.
The turbidity sensor 20 is a telescopic decanter for a continuous batch reactor, characterized in that the sensor for cleaning nozzle 23 is provided.

Images