KR100453116B1 - A discharge system for clean water - Google Patents

Abstract

PURPOSE: To provide a discharge system for clean water, which is capable of discharging the clean water treated by a sequencing batch reactor method excluding suspended solids existent on the surface of the clean water. CONSTITUTION: The discharge system comprises a discharge device, a water level changing detector (50) that detects change of the water level and a retractor (40) that allows the discharge device to rise and fall according to the change of the water level. The discharge device includes a plurality of buoyancy tanks (10) that allows an effluent tank (20) to float on clean water, the effluent tank that excludes the suspended solids existent on the surface of the clean water, allows only the clean water to be flown in and then continuously discharge a constant amount of the clean water and an effluent pipe (30) that is connected to the effluent tank to discharge the clean water to the outside.

Description

A discharge system for clean water

The present invention relates to a treatment water discharge apparatus, and more particularly, treatment water that can be discharged to the outside in a state of excluding suspended solids on the surface of treated water purified through a sequencing batch reactor (SBR) method. It relates to a discharge device.

Recently, due to the development of industry and the increase of population, large amounts of sewage and wastewater are discharged from industrial sites and homes.

Such sewage and wastewater contain a large amount of heavy metals, various organic matters, etc., which causes serious problems in destroying the environment and ecosystems such as rivers, soils, and oceans.

In order to solve the above problems, the sewage or wastewater is collected in a sewage treatment plant and then purified and discharged to rivers, thereby minimizing environmental pollution.

In general, as a method for treating sewage, there is an activated sludge method (AS), which uses aerobic microorganisms to purify through inflow, reaction, precipitation, discharge, and rest.

Recently, however, unlike the above-described activated sludge process (AS), all of the above purification processes are performed in one septic tank, and thus, a sequencing batch reactor (SBR) method, which has advantages such as a simpler structure and a smaller installation area, is used. It is used a lot.

The batch reactor (SBR) method is characterized in that the purification process is made in one place through the settling step of the purification process, the sediment is settled to the bottom of the septic tank, the treated water is located on top of the sediment.

The treatment water is discharged to the outside while the treatment water discharger provided in a predetermined region of the septic tank descending by a predetermined depth, even if the treated water has undergone a purification process, a small amount of suspended solids are present on the water surface.

Therefore, it is important to discharge the treated water except these suspended matter to the outside.

Figure 1 (a) shows an example of a batch reactor (SBR) method, as shown in this after the precipitation step in the septic tank 100, the treated water discharge device 200 adjacent to the water surface is proportional to the change in the water level As it descends, the process of continuously discharging the treated water from which the suspended matter is discharged to the outside through the discharge pipe 250 is performed.

Figure 1 (b) is a block diagram of a conventional treatment water discharge device 200, the square funnel-shaped water collecting port 210 is supported at both ends so as to be able to rotate about one axis at a predetermined position of the septic tank 100. The discharge pipe 250 is connected by a plurality of connection pipes 240.

One side of the two fixing plates 230 fixing both ends of the cylindrical floating block 220 is rotatably supported on one side of the water collecting port 210 about one axis.

The water collecting port 210 is moved up and down by the elevating device 260 fixed to one side of the septic tank 100 and one side of the plurality of connection pipes 240, this process is shown in Figure 1 (c) Is shown.

When the catching device 210 descends while turning around the center of the discharge pipe 250 by the elevating device 260, the float blocking device 220 first contacts the surface of the water and blocks the floating material.

When the catch port 210 continues to descend to the bottom of the water surface, the float block 220 is continuously floated on the surface by buoyancy, so the catch port 210 turns in the opposite direction and enters the water surface.

Through this entry process, the treated water in which the floating material is removed flows into the space created between the catchment port 210 and the floating water blocking port 220 and is discharged.

However, the treatment water discharge device 200 is a lot of disturbance occurs on the surface of the treated water in the process of entering the water collecting port 210, which is located in the outside of the portion of the device, the initial treatment water discharge operation Even if the float block 220 is present, there is a problem that the float enters the inner surface of the treated water and is discharged together.

In addition, when the treated water discharge device 200 enters the surface of the water, there is a problem in that a portion located therein interferes with sludge existing at the bottom of the septic tank 100 and it is difficult to discharge the treated water adjacent to the sludge. have.

It is an object of the present invention to provide a treatment water discharge apparatus capable of discharging the suspended solids existing on the surface of purified water through a batch reaction tank (SBR) method.

Another object of the present invention is to provide a treatment water discharge device having an advantage that the structure is simple and easy to manufacture and maintain.

1 is a block diagram of a continuous batch reactor (SBR) method and a conventional treatment water discharge device.

Figure 2 is a configuration of one embodiment and another embodiment of the treatment water discharge apparatus according to the present invention.

3 is a configuration diagram of one embodiment and another embodiment of the buoyancy tank in Figure 2;

4 is a configuration diagram of the discharge tank and the discharge pipe in FIG.

5 is an operating state of the treatment water discharge apparatus according to the present invention.

Figure 6 is a treatment water discharge process of the treatment water discharge apparatus according to the present invention.

* Description of the main parts of the drawings *

10, 10 ′: buoyancy tank 20: discharge tank

30: discharge piping 40: towing apparatus

50: level change detector 60: control unit

70 compressor 80 support

90: reducer 100: septic tank

The present invention for achieving the above object is filled with a buoyancy material therein to have a buoyancy buoyancy tank to float the discharge tank in the treated water, and blocks the floating material present on the surface of the treated water and the treated water only And a discharge tank including a discharge tank for discharging the internally and temporarily storing the discharge tank and continuously discharging a predetermined amount, and a discharge pipe connected to the discharge tank for discharging temporarily stored water; A water level change detector for detecting a change in water level; It characterized in that it comprises a traction device for elevating the discharge device in accordance with the change in water level.

When described in detail with reference to the accompanying drawings an embodiment of the present invention configured as described above are as follows.

Figure 2 (a, b) is a configuration diagram of one embodiment and another embodiment showing the configuration of the treatment water discharge apparatus according to the present invention.

Figure 2 (a) is a configuration diagram of an embodiment of the treatment water discharge device, as shown in the treatment water discharge device left and right buoyancy tank 10 is located, the discharge tank 20 in the center Is combined.

The buoyancy tank 10 is connected to the compressor 70 and the air pipe 71, the compressed air generated in the compressor 70 is introduced into the buoyancy tank 10 through the air pipe (71).

In addition, the upper portion of the buoyancy tank 10 is connected to the traction device 40, which is connected to the reducer 90 is fixed to a predetermined position of the support 80 through the traction rope 41 again.

The discharge pipe 30 is connected to the lower portion of the discharge tank 20, through which the treated water in the discharge tank 20 is discharged to the outside.

On the upper side of the septic tank 100, the water level change detector 50 is located in a state connected to the control unit 60.

Figure 2 (b) is a configuration diagram of another embodiment of the treatment water discharge device having a method that does not use compressed air as a buoyancy material, the basic structure is the same but the air pipe connecting the compressor 70 and the buoyancy tank (10 ') ( 71) is not provided.

3 is a configuration diagram of the buoyancy tanks 10 and 10 ′, which shows one embodiment and another embodiment.

Figure 3 (a) shows the configuration of one embodiment of the buoyancy tank 10 using the compressed air as a buoyancy material, as shown in the upper portion of the body 11, the lower opening is connected to the traction device 40 A plurality of traction rings 12 are provided at both ends, and a buoyant material entry and exit portion 13 is provided.

Figure 3 (b) shows the configuration of another embodiment of the buoyancy tank (10 '), as shown in the end of the upper end of the closed body (11') is provided with a traction ring (12). .

Figure 4 shows the configuration of the discharge tank 20 and the discharge pipe 30, the discharge tank 20 is facing the dunk bottom plate 23 is provided with a plurality of treated water outlet 24 on the upper surface The treated water inlet 21 is located symmetrically on both sides.

One side of the treated water inlet 21 is provided with a plurality of treated water inlet holes 22, through which the treated water flows into the discharge tank 20.

In addition, the discharge pipe 30 is connected to the plurality of treated water outlets 24 provided in the tank bottom plate 23, and discharges the treated water temporarily stored in the discharge tank 20 to the outside.

Hereinafter, the configuration and operation of the present invention as described above will be described in more detail.

First, the discharge tank 20, which temporarily stores the treated water in the septic tank 100 and continuously discharges a predetermined amount, is largely composed of the treated water inlet 21 and the tank bottom 23.

The tank bottom plate 23 constituting the discharge tank 20 has a rectangular plate shape, and a plurality of treated water outlets 24 are provided at an upper portion thereof.

The treatment water outlet 24 is welded to one side of the pipe having a hollow circular cross section with the tank bottom plate 23, and preferably has a flange at the end of the pipe so that the discharge pipe 30 It is coupled by a flange and bolts and nuts provided on one side.

The treated water inlet 21 is bent at a predetermined distance downward on both sides of the horizontal rectangular plate, but one side has a larger area than the other side, where a plurality of treated water inflow The hole 22 is provided.

The treated water inlet 21 is installed on two side surfaces of the tank bottom plate symmetrically such that the treated water inlet holes 22 face each other.

The treated water inlet 21 and the tank bottom plate 23 take a method of separately manufacturing and combining in accordance with the production method, it is also possible to be molded integrally in order to increase the efficiency in production.

In addition, the treated water inlet 21 and the tank bottom plate 23 are preferably made of stainless steel to prevent corrosion and maintain structural rigidity due to prolonged contact with the treated water. It is not limited to.

In another embodiment of the treated water inlet 21, the outer surface of the treated water inlet shown in FIG. 4 is removed to allow the suspended solids present on the treated water to flow into the treated water inlet 22 to be discharged to the outside. By doing so, it is possible to use the treated water discharge device for the purpose of removing the suspended matter.

A side buoyancy tank 10 is installed on the side of the discharge tank 20 in which the treated water inlet 21 is not installed to serve as a partition wall, and generates buoyancy to treat the discharge tank 20. It also serves to float the water.

The structure of the buoyancy tank 10 is shown in Figure 3 (a) as an embodiment.

The buoyancy tank 10 of Figure 3 (a) is a method of using compressed air as a buoyancy material,

The bottom face has an open rectangular parallelepiped body 11.

The upper one side of the body 11 is a hollow circular cross-section, buoyant material entry and exit 13 having a predetermined height is provided.

The buoyancy material inlet and outlet 13 is connected to the compressor 70 by an air tube 71. The air tube 71 moves up and down with the treated water discharge device when the treated water is discharged, thereby preventing damage to the pipe. For this purpose, a material such as rubber or synthetic resin is preferable.

And, the end of the buoyancy material inlet and outlet 13 is provided with an electric valve 14, and serves to adjust the inlet and outlet of the compressed air.

And, the upper portion of the body 11 is provided with a plurality of traction ring 12, it is connected to the traction device 40.

3 (b) is another embodiment of the buoyancy tank 10 ', as shown therein, the body 11' has the shape of a closed rectangular parallelepiped, and a plurality of the towing rings 12 thereon. Is provided.

The treatment water discharge device using the buoyancy tank (10 ') is not necessary because the compressor 70, the air tube 71, the electric valve 14, because the compressed air is not used to generate buoyancy.

The interior of the body (11 ') constituting the buoyancy tank (10') is a hollow state, it is also possible to fill the foam material such as styrofoam for the improvement of buoyancy.

The buoyancy tanks 10 and 10 'are preferably made of stainless steel to prevent corrosion and maintain structural stiffness caused by prolonged contact with treated water. It is not limited.

One end of the discharge pipe 30 for discharging the treated water of the discharge tank 20 to the outside is preferably provided with a flange, and is provided with a flange, a bolt and a nut provided in the treated water discharge port 24. Combined.

The discharge pipe 30 may be damaged when the other end of the discharge pipe is fixed to the septic tank 100 due to the downward movement in combination with the discharge tank 20 during the treatment water discharge operation.

Therefore, it is preferable to be made of a material such as rubber having a flexible property in order to prevent damage.

The towing device 40 is a device that allows the downward movement while maintaining the balance of the treated water discharge device, preferably has a square plate shape.

And, the upper portion is connected by the reducer 90 and the traction rope 41, the lower four corners are preferably a chain for fastening with the traction ring 12 provided in the buoyancy tank (10) It is provided.

The traction device 40 is the embodiment of the treatment water discharge device to which the buoyancy tank 10 is applied, its function is balanced, and is mainly limited to that used to install the treatment water discharge device on the upper septic tank, In another embodiment, the treated water discharge device using the buoyancy tank 10 'has a feature that the function is used for both lifting and lowering operations.

The traction device 40 is preferably made of stainless steel due to its high humidity and the ability to withstand the load of the treated water discharge device. However, the traction device 40 is not limited to a specific material.

5 is an operation state diagram of the treatment water discharge device, the treatment water discharge device located in the upper portion of the treatment water surface is lowered to come in contact with the water surface, and shows a state that is continuously discharged.

First, the traction rope 41 is connected to the traction device 40 on the reduction gear 90 fixed at a predetermined position of the support 80, which is in turn connected to the treatment water discharge device. Traction rope 41 has a main function when installing the treatment water discharge device in the upper portion of the septic tank.

The treatment water discharge device is lowered by the operation of the speed reducer 90, when the treatment water inlet hole 22 is locked to the treatment water, the treatment water is introduced into the discharge tank 20, and a certain amount of discharge pipe is continuously discharged. Ejected through 30.

As the treated water is discharged through the discharge operation, the water level is lowered. The water level change detector 50 connected to the controller 60 detects the change of the water level.

The detected water level change amount is transmitted to the controller 60, and the controller 60 discharges the compressed air in the buoyancy tank 10 so that the treated water inflow hole 22 of the treated water discharge device is separated from the water surface. Lower the proper height so as not to.

When the treatment water discharge device approaches the sludge existing at the bottom of the septic tank 100 through a discharge operation for a predetermined time, a detection signal of the water level change detector 50 is transmitted to the controller 60, and the sludge is discharged to the discharge tank 20. Compressed air generated by the compressor 70 is introduced into the buoyancy tank 10 through the air pipe 71 in order to prevent the flow into the air.

Then, the treated water existing in the buoyancy tank 10 is pushed out by the compressed air introduced for a predetermined time, the treated water discharge device has a certain buoyancy to rise to the treated water inlet 21 No more treated water is introduced.

6 is a cross-sectional view illustrating a process of discharging treated water through the treated water discharge device provided in the septic tank 100.

As shown in the drawing, when the treatment water discharge device enters the treatment water, the outer plate constituting the treatment water inlet 21 may have a float placed above the treatment water approaching the treatment water inlet hole 22. Prevent it.

The treated water, from which the suspended matter is excluded, proceeds between the outer and inner plates of the treated water inlet 21 by the pressure difference, and is gradually introduced into the discharge tank 20 through the treated water inlet 22. .

The treated water introduced into the process goes through a process in which a predetermined amount is continuously discharged to the treated water outlet 24 provided at the bottom of the discharge tank 20.

The treatment water discharge apparatus according to the present invention as described above has been described with reference to the illustrated drawings, but the present invention is not limited to the disclosed embodiments and drawings, and the technical field to which the present invention belongs without departing from the concept of the present invention. Various changes and modifications are possible by those skilled in the art.

As described above, the present invention can be discharged in a state except the suspended matter present on the surface of the treated water.

In addition, the structure is simple, there is an advantage that the production, maintenance and repair is convenient.

Claims (5)

The buoyancy material is filled inside the buoyancy tank having a buoyancy buoyancy floating in the treated water, and the floating water existing on the surface of the treated water blocking only the treated water flows into the inside temporarily stored after a certain amount A discharge device including a discharge tank for continuously discharging, and a discharge pipe connected to the discharge tank for discharging temporarily stored water; A level change detector for detecting a change in level; And a traction device for elevating the discharge device according to the change of the water level. According to claim 1, wherein the buoyancy tank is a rectangular parallelepiped-shaped body with an open bottom, Buoyant material is introduced into the upper portion of the body, buoyancy material entry and exit portion having a hollow circular cross section discharged; Located at both ends of the upper portion of the body treatment water discharge device characterized in that consisting of a traction ring coupled with the traction device. The method of claim 1, wherein the buoyancy tank is a body having the shape of a closed rectangular parallelepiped, Located at both ends of the upper portion of the body treatment water discharge device characterized in that consisting of a traction ring coupled with the traction device. According to claim 1, wherein the discharge tank is composed of two sides of the side of the buoyancy tank, Both sides of the horizontal rectangular plate is bent downward but the outer surface has a larger area, the inner surface is a treated water inlet having a plurality of treated water inlet, A horizontally connected inner surface of the treated water inlet is located symmetrically, the treatment water discharge device characterized in that consisting of a tank bottom plate provided with a treated water outlet on the horizontal surface. According to claim 1, wherein the discharge tank is composed of two sides of the side of the buoyancy tank, A treated water inlet having a plurality of treated water inlet holes on a side of the vertical rectangular plate, A treatment water discharge device comprising a tank bottom plate having a treatment water discharge port connected to the treatment water inlet horizontally and symmetrically disposed in a horizontal plane.