KR100795592B1 - Resource saving pump system for processed water at sewage treatment plant - Google Patents

Abstract

A system for transferring and pumping treatment water is provided to reduce the resources such as electricity for driving a pump, by using an underwater vertical turbine pump for pumping and transferring the treatment water. A system for transferring and pumping treatment water comprises a plurality of underwater vertical turbine pumps(30). Each of the underwater vertical turbine pumps includes a pumping unit(32) having an impeller, a column unit(34), a discharge unit(36), and a pumping driving unit(38). The pumping unit is installed in the treatment water. The discharge unit and the pumping driving unit are exposed to the outside through the ceiling of a water storage bath(20) to pump and discharge the treatment water stored in the water storage bath. A discharge pipe(40) is connected to the discharge unit of each underwater vertical turbine pump. A main pipe(50) collects the treatment water transferred from each discharge pipe to transfer a collector. A damper wall(22) opens an upper portion of one side of the water storage bath to prevent the overflow of extra treatment water, thereby maintaining the minimum water level for operating the underwater vertical turbine pumps and preventing the treatment water from flowing out through the ceiling of the water storage bath. Further, a turbulence preventing unit is additionally contained in the water storage bath.

Description

Resource saving pump system for processed water at sewage treatment plant}

The present invention relates to a transfer pump system, and more particularly, the treated water discharged from the sewage treatment plant is pumped by using a submersible vertical water turbine pump, which is highly efficient, and then transferred to a demand destination, such as electricity required for operation of the pump. In addition to saving resources, it is possible to improve the water quality of the treated water, to prevent vortices during pumping, and to allow time and space for the sediment in the treated water to be settled without being pumped directly. The present invention relates to a resource saving type treatment water transfer pump system in a sewage treatment plant.

In order to secure water resources all over the world, we have been promoting policies to secure water resources by constructing dams or reservoirs.However, due to the controversy of environmental destruction and opposition from submerged people, the development of alternative water resources has emerged in recent years. Increasing interest has resulted in less discharge of sewage, and sewage treatment plants are being installed in various places to improve the quality of discharged sewage. This is due to aesthetic rejection such as the presence and smell of pathogens such as bacteria and viruses contained in reused water. In addition, the pump power and landfill costs for transportation are becoming obstacles as the sewage treatment plant is far from the city's demand for reuse.However, the reuse rate is steadily increasing, and there is a shortage of agricultural water, industrial water, river maintenance water, and other fields. Its importance is increasing for alternative water resources.

Currently, most of the transfer pumps for pre- and post-treatment of sewage are submerged, and sometimes land pumps are used.

1 schematically shows a transfer pump system by a conventional submersible pump. As shown, a conventional transfer pump system using a submersible pump includes a reservoir 1 for temporarily storing the treated water and an underwater pump 2 installed in the treated water of the reservoir 1.

The submersible pump 2 has a structure in which the motor and the pump are directly connected to each other, and the motor and the pump assembly are all installed in the water, and a pump pipe is connected thereto to pump the pump. These submersible pumps have low pumping efficiency of about 40% when the pump head exceeds 50m due to the structure of the pump, and it is difficult to install and disassemble, so it is not easy to manage and maintain, and because both the motor and the pump are installed in water, There is an unmanageable disadvantage. In addition, the submersible pump must be lifted outward to check the submersible pump. Therefore, the upper surface of the reservoir should have a larger hole than the submersible pump body. There is a drawback in that it requires the addition of large scale deodorization equipment for its treatment. In addition, there is a risk of short circuit and electric shock because the power cable is used for driving the motor. In addition, as mentioned earlier, a large number of submersible pumps are required in a large sewage treatment plant because of low efficiency of the pump. Since such submersible pumps are operated 24 hours a day, 365 days a year, the electricity consumption for operating them is a serious problem. There is a situation.

Figure 2 schematically shows a transfer pump system using a conventional general land pump. As shown, in the case of the general land pump (3), since both the motor and the pump is installed in a state exposed to the land rather than underwater, a separate pump chamber (4) must be provided on one side of the reservoir (1) In addition, in order to pump and discharge the treated water temporarily stored in the reservoir, a suction pipe 5 connecting the reservoir and the pump should be additionally installed. The additional installation of the pump chamber is disadvantageous in terms of space and cost, and the installation of the suction pipe is also inefficient in space and cost because additional installation of piping materials, valve bodies, and strainers is required.

On the other hand, these conventional transfer pump systems do not have a structure for flushing their own pipe, whether the system using any of the submersible pump or the land pump, and the simple transfer function without additional treatment for water quality improvement in the conveying pipeline. It was a pump system equipped with a bay, and when the water quality deteriorated, the transfer pump system had no way of contributing to the improvement of the water quality. Therefore, it acted as a treatment load only for the sewage treatment device. Not presented.

Therefore, the present invention was devised to solve the problems of the conventional transfer pump system as described above, it can be expected to save 50% energy compared to the underwater pump by configuring a system with a high efficiency vertical turbine pump of 75-85%, By implementing a pump system without a pump room and suction pipe, it is possible to expect a resource and cost saving effect, and by installing auxiliary facilities such as vortex prevention means to increase the efficiency of the pump and provide convenience of maintenance and management, and It is an object of the present invention to provide a resource-saving sewage treatment water transfer pump system capable of achieving improved water quality of treated water.

The objects and advantages of the present invention will be described in more detail below, and will be further embodied by the examples. Further objects and advantages of the invention may be realized by the means indicated in the claims and combinations thereof.

The transfer pump system according to the present invention for achieving the object as described above, the reservoir 20 for temporarily storing the treated water discharged from the sewage treatment plant 10; A pumping part 32 of the turbine pump including an impeller 32a at a lower part, a column part 34 connected to an upper part of the pumping part 32, and a pumped part connected to an upper part of the column part 34. Discharge part 36 for discharging the treated water and the pumping drive portion 38 which is located above the discharge portion 36 to provide a driving force to the pumping portion 32, the pumping portion 32 and The column part 34 is installed in the treated water stored in the reservoir 20, and the discharge part 36 and the pumping drive part 38 are installed to penetrate the ceiling of the reservoir 20 to be exposed to the outside. A plurality of submersible vertical turbine pumps 30 for pumping the treated water stored in the reservoir 20 and discharging upwards; A discharge pipe 40 connected to the discharge portion 36 of each of the underwater vertical turbine pumps 30 and provided with a check valve 42 and a shutoff valve 44; A main pipe 50 which collects the treated water delivered from each discharge pipe 40 and delivers it to the receiving place; In order to maintain the minimum water level for the operation of the underwater vertical turbine pump 30 and to prevent the treated water from overflowing to the outside through the ceiling of the reservoir 20, one side of the reservoir 20 so that the excess treated water may overflow. And a damper wall 22 formed by opening the upper portion.

Here, the reservoir 20 is further provided with a vortex prevention means 60, the vortex prevention means 60, along the longitudinal direction on the side of the submersible vertical turbine pump 30 to prevent side vortex A vertical plate 62 extending vertically; A horizontal plate 64 arranged horizontally in a lower portion of the pumping portion 32 to prevent vortices occurring in the lower portion of the pumping portion 32 of the submersible vertical turbine pump 30; The support plate 66 which supports the vertical plate 62 and the horizontal plate 64 from the bottom and is fastened by the anchor 61 to the bottom of the reservoir 20, fastening the anchor 61 of the support plate 66 The long hole is formed in the portion is configured to allow the left and right movement of the support plate 66, a plurality of through holes are formed in the horizontal plate 64, the support rod 65 is fitted into the through hole, the support rod 65 The horizontal plate 64 is configured to be capable of adjusting the height of the horizontal plate 64 as fastened to the horizontal plate 64 by a nut in the upper and lower portions.

In addition, a reprocessing return pipe 70 branched from the main pipe 50 and connected to the sewage treatment plant 10 is added for reprocessing when the water quality of the treated water delivered through the main pipe 50 is low. It is provided with.

In addition, one end is connected to one side of the main pipe 50, the other end further includes a backwashing pipe 80 connected to the front end of the check valve 42 installed in the discharge pipe 40, the backwashing pipe 80 is provided with a backwash valve 82.

On the other hand, one side of the main pipe 50 is further provided with an ozone mixing unit 90, the ozone mixing unit 90 is the oxygen generator 94 for separating only oxygen from the mixed air; An ozone generator (96) for generating ozone by discharge from the oxygen generator (94); And an ozone mixer 98 which mixes and dissolves the ozone gas supplied from the ozone generator 96 with water introduced from the main pipe 50 to generate fine bubbles.

And, in front of the ozone mixing unit 90 of the main pipe 50, the flow meter 100 is provided to measure and adjust the flow rate of the treated water flowing through the main pipe 50 to maintain the proper ozone concentration in the treated water. do.

According to the present invention having the problem solving means as described above, the use of the underwater vertical turbine pump 30 in the transfer of sewage treatment water compared with the conventional water pump system installed on the bottom of the reservoir 20, the disadvantage of the underwater pump Replace the low efficiency pump with a high efficiency pump to improve energy efficiency (30-50% reduction in electricity consumption) and expose the underwater equipment to the land for easy monitoring and maintenance, and the power line is not submerged in the water tank The short circuit risk of (20) was solved.

 In addition, compared to the conventional land pump system, it is possible to construct a system that can omit a separate pump room and a suction pipe material (a shutoff valve, a strainer, a connecting pipe, a flange, a gasket, etc.) that must be installed next to the reservoir 20. This saves space and saves on piping.

In addition, the disassembly assembly and position adjustment is provided with a vortex prevention means 60, it is possible to effectively prevent the vortex generated from the side and the bottom of the pump, the size of the pump as an easy structure for repair and replacement of the pump The vertical plate 62 and the horizontal plate 64 can be moved up, down, left, and right to easily adjust the position, and the solid material contained in the treated water is separated from the bottom of the horizontal plate 64 and the reservoir 20. Provides the opportunity to settle on the bottom of the tank, not pumped immediately, and provides a storage function that can settle for long periods of time, minimizing intermittent operations and increasing maintenance costs by increasing the periodic cleaning cycles to remove solids deposited on the floor. You can save.

In addition, the reprocessing return pipe 70 is provided on one side of the main pipe 50, thereby improving the water quality by returning the treated water that has not reached the required water quality to the sewage treatment plant 10 to be treated again, and mixing with ozone. By condensing and mixing ozone into the treated water through the unit 90 to contribute to sterilization and water purification, it has an excellent effect of effectively improving the water quality of the treated water by increasing the efficiency of the entire system.

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

3 is a block diagram of a transfer pump system according to the present invention. As shown, the transfer pump system according to the present invention includes a reservoir 20, the submersible vertical turbine pump 30, the discharge pipe 40, the main pipe 50.

The reservoir 20 is a portion in which the treated water discharged from the sewage treatment plant 10 is temporarily stored, and a water tank screen for filtering foreign substances such as suspended solids present in the water at the inlet into which the treated water flows into the reservoir 20. It is preferable to be installed. Since the foreign matter having a large diameter that cannot pass through the impeller 32a of the underwater vertical turbine pump 30 to be described later by the water tank screen 21 is blocked, the impeller 32a by the large foreign matter is blocked. The risk of shutdown can be prevented in advance.

The reservoir 20 is provided with a pumping means for pumping out the temporarily stored treated water to the outside, as already mentioned, in the transfer pump system according to the present invention, the submersible vertical turbine pump 30 as the pumping means is Used. 4 (a) schematically shows an external configuration of the submersible vertical turbine pump 30, and FIG. 4 (b) shows an internal configuration of the submersible vertical turbine pump 30 in detail.

As shown, the submersible vertical turbine pump 30 is also called a line shaft turbine pump, and is composed of a pumping part 32, a column part 34, a discharge part 36, and a pumping driving part 38.

The pumping part 32 includes an impeller 32a installed therein and a bowl assembly 32b for accommodating the impellers 32a. The impeller 32a is accommodated inside the Paul assembly 32b, connected to a line shaft that is rotated according to the motor driving of the pumping driver 38 to be described later, and rotates together to suck the treated water into the Paul assembly 32b. It is the part that provides the driving force to move upward.

The column part 34 is located above the pumping part 32 and surrounds the line shaft and serves as a moving passageway of the treated water that is pushed up from the pumping part 32 and is singular or plural depending on the depth of the water tank. Is a column assembly connected to

On the other hand, the discharge portion 36 is connected to the upper end of the column portion 34 as the discharge head for discharging the treated water is moved up through the column portion 34 to the outside of the base bolt ( It is fixed and supported by (not shown), the discharge port 36a is formed in the side portion and the discharge pipe 40 is connected thereto.

The pumping driver 38 is provided on the discharge part 36. The pumping driving part 38 is a part for providing a driving force to the pumping part 32 described above, and includes a driving motor for rotating a line shaft having an impeller 32a installed at the bottom thereof.

In the submersible vertical turbine pump 30 having such a structure, the line shaft is rotated by the rotation of the motor or the engine driver of the pumping driving unit 38, and the impeller 32a located in the Paul assembly 32b is rotated by the line shaft. It is rotated with the pumped treatment water from the reservoir 20 to the top. The pumped treated water passes through the column part 34 and is discharged from the discharge part 36 to be supplied to the main pipe 50.

As shown in FIG. 3, the submersible vertical turbine pump 30 is installed in the treated water stored in the reservoir 20, and the upper portion is installed to penetrate the ceiling of the reservoir 20 to be exposed to the outside. Specifically, the pumping unit 32 including the Paul assembly 32b and the impeller 32a and the column portion 34 thereon are installed in the treated water stored in the reservoir 20, and the column portion 34 The upper end of the) penetrates through the upper ceiling of the reservoir 20, and the discharge portion 36 and the pumping drive portion 38 positioned thereon are installed to be exposed to the outside of the upper portion of the reservoir 20, that is, on land.

As such, since the pumping unit 32 is underwater and the pumping unit 38 is installed separately on the land, the pump efficiency of the pump can be utilized, and in particular, since the pumping unit 38 is exposed to the land. It has the advantage of easy monitoring and maintenance by the naked eye. In addition, since the submersible vertical turbine pump 30 can pull water vertically from the water of the reservoir 20 without the need for a separate suction pipe, the upper ceiling upper surface of the reservoir 20 becomes a pump room, and the pump is water There is no need for priming (filling the water inside to drain any air remaining in the pump or tube when the pump is running). In particular, the submersible vertical turbine pump 30 has a structure capable of single or multiple stages of the impeller (32a) to match the required pump pressure and is a system that combines only the advantages of the existing two pump system (underwater pump and land pump) It is possible to construct a pump system with space saving, suction pipe material saving and high efficiency.

The underwater vertical turbine pump 30 may be used alone, but in order to increase the transfer efficiency according to the size of the sewage treatment plant 10 or the reservoir 20, it is to use a plurality of installed as shown in FIG. desirable.

A discharge pipe 40 for transferring the discharged treated water to the main pipe 50 which will be described later is connected to the discharge side of the submersible vertical turbine pump 30, that is, the discharge port 36a of the discharge unit 36. The discharge pipe 40 is provided with a check valve 42 for preventing the back flow of the pumped water. The check valve 42 is a valve for quiet operation in which the flow speed of the fluid decreases to completely close when the flow rate becomes '0' in order to minimize the occurrence of water shock. It is desirable to. In addition, a shutoff valve 44 is to be installed at the rear end of the check valve 42 of the discharge pipe 40, and the discharge pipe is connected by a groove joint (not shown) type connector in consideration of expansion and expansion and seismic design. It is preferable to be installed in connection with 40.

Preferably, a damper wall 22 is formed at one side of the reservoir 20, specifically, at the other side of the reservoir 20 connected to the sewage treatment plant 10. The damper wall 22 simultaneously performs a water storage function and an overflow function. The damper wall 22 is one side wall of the reservoir 20, and as shown in FIG. 3, an upper portion thereof is opened. In order to operate the underwater vertical turbine pump 30, a predetermined amount or more of the treated water should be stored in the reservoir 20. However, when the excess treated water is supplied to the reservoir 20, the excess treated water overflows the treated water through the ceiling of the reservoir 20, ie, the hole in which the underwater vertical turbine pump 30 is installed, to the pumping drive part 38 and the like. Inflow can cause problems such as shutting down the pump. Therefore, the damper wall 22 is formed by opening the upper portion of the reservoir 20 so that the minimum water level maintaining function for the operation of the pump can be achieved and the excess treated water can overflow and flow to the outside.

In general, in the case of pumping water from the reservoir 20 by using a pump, a vortex (swirl) phenomenon occurs due to a spiral suction action at the inlet side of the pump, and air is introduced into the pump due to this phenomenon, thereby improving efficiency of the pump. This lowers or causes movement in the pump, causing the pump to break down. Therefore, in order to prevent such a vortex phenomenon, as shown in Figure 3, the transfer pump system according to the present invention is further provided with a vortex prevention means 60 in the reservoir 20.

5 and 6, the configuration of such vortex preventing means 60 is shown in side and plan views, respectively. The vortex preventing means 60 includes a vertical plate 62 and a horizontal plate 64.

The vertical plate 62 is formed to vertically extend along the longitudinal direction from the bottom of the water reservoir 20 to the side of the submersible vertical turbine pump 30 to prevent side vortex, and the horizontal plate 64 is vertical It is to prevent the vortices occurring in the lower portion of the pumping unit 32 of the turbine pump 30, it is installed in a horizontal arrangement in the lower portion of the pumping unit (32).

The vortex prevention means 60 is preferably configured to be disassembled and assembled, and to be able to adjust the position up, down, left and right as necessary. To this end, the vertical plate 62 and the horizontal plate 64 is preferably installed on the support plate 66 as shown in FIG. The support plate 66 is fixed to the bottom of the reservoir 20 by an anchor 61, and the anchor 61 is configured to be disassembled by being fastened with a nut or the like from the top. And, a long hole is formed in the portion of the support plate 66 to which the anchor 61 is fastened so that the support plate 66 can be moved to the left and right to adjust the position of the vortex preventing means 60 according to the diameter of the pump. do.

On the other hand, a plurality of through holes are formed in the horizontal plate 64 and the supporting rod 65 is fitted in the through holes. The support rod 65 is fixed to the horizontal plate 64 by nuts at the upper and lower portions of the horizontal plate 64. If necessary, the height of the horizontal plate 64 can be adjusted by loosening the nut and moving the horizontal plate 64 up and down along the support rod 65 and then fixing the nut again. The volume of the interior of the reservoir 20 corresponding to the height of the horizontal plate 64 and the bottom of the reservoir 20 can be adjusted to the cleaning cycle of the reservoir 20 by securing a deposition space of foreign matter that can be settled in the water. Make sure

If the vortex prevention means 60 is not installed, the pump should be installed close to the bottom of the reservoir 20 and the suspended solids contained in the sewage will be sucked by pumping. However, when the horizontal plate 64 capable of adjusting the height of the vortex preventing means 60 according to the present invention is installed to be ripe with the bottom of the reservoir 20, foreign substances are deposited so that they are not sucked immediately during pumping and the deposition time and the deposition space are As a result, the maintenance can be planned and the maintenance becomes easy.

Referring to FIG. 3 again, the discharge pipe 40 connected to the discharge side of the submersible vertical turbine pump 30 is connected to the main pipe 50. The main pipe 50 collects the treated water from the discharge pipe 40 connected to the discharge side of each underwater vertical turbine pump 30 and supplies the treated water to the demand destination of the treated water.

It is preferable that the back washing pipe 80 is branched to the main pipe 50 for back washing. One end of the back washing pipe 80 is connected to one side of the main pipe 50, and the other end thereof is connected to the front end of the check valve 42 installed in the discharge pipe 40, and a back washing valve 82 is provided. .

On the other hand, because the treated water passing through the main pipe 50 is used for preventing dry cloth or agricultural industry, etc., the water quality should be good to some extent. Therefore, when the water quality of the treated water flowing through the main pipe 50 is not good, reprocessing is required. To this end, the reprocessing return pipe 70 is branched to one side of the main pipe 50. The reprocessing return pipe 70 is connected to the sewage treatment plant 10. When the pumped water does not meet the discharge-side water quality standards, the treated water is returned to the sewage treatment plant 10 through the reprocessing return pipe 70 to undergo a reprocessing process. Through this reprocessing for reprocessing, it is possible to improve and maintain the treated water quality.

On the other hand, the main pipe 50 is preferably further provided with an ozone mixing unit 90 to improve the water quality of the treated water. The ozone mixing unit 90 is a part for further sterilizing and purifying the treated water by spraying the ozone gas in the state of fine bubbles to the treated water. As shown in FIG. 3, the ozone mixing unit 90 includes a compressor 92, an oxygen generator 94, an ozone generator 96, and an ozone mixer 98.

The compressor 92 compresses and discharges mixed air containing various gases including oxygen. The mixed air discharged from the compressor 92 flows into the oxygen generator 94.

The oxygen generator 94 is called O ₂ It is called PSA (Pressure Swing Adsorption). This is a device that separates oxygen by the difference in the adsorption degree of nitrogen and oxygen in the air mixed with nitrogen and oxygen. The oxygen separated from the oxygen generator 94 is supplied to the ozone generator 96.

The ozone generator 96 is an apparatus that artificially generates ozone by using silent discharge, electrolysis of a solution, or the like. Silent discharges are made of double glass tubes with a discharge tube of several centimeters apart. Tin foil is applied to the inside of the inner tube and the outside of the outer tube. Acoustic discharge is performed by applying an alternating voltage of 5 to 25 kV with a coil. Sending dry oxygen or air from one side turns some of the oxygen into ozone, resulting in a mixture of ozone and oxygen (air) with a content of about 10%. By electrolysis, about 20% of ozone can be generated by electrolysis using an electrode of platinum or lead peroxide in sulfuric acid solution.

Ozone gas generated from the ozone generator 96 flows into the ozone mixer 98. The ozone mixer 98 is a so-called bubble generator or microbubble generator, and acts as a factor for increasing the 'contact opportunity' when the generated ozone reacts with green algae or various fungi in the fluid. In other words, by minimizing the ozone gas to 20㎛ supply to the water to increase the contact opportunities with green algae or various fungi. In other words, ozone gas having a diameter of 20 μm is five times smaller than 100 μm, but the total number of bubbles indicating contact opportunity is 125 times, and the treatment effect is high. The ozone mixer 98 is composed of a overflow pump, which automatically sucks air containing ozone, and enables the flow from the stirring flow and the pump pressure up to the pressure dissolving and conveying of the air at once in the overflow pump.

The ozone dissolved in the water by the ozone mixing unit 90 as described above is decomposed into oxygen molecules (O ₂ ) and oxygen atoms (O) and has sterilization, disinfection, and deodorizing power due to its characteristics as a strong oxidizing agent. Dissolved oxygen gas, which is a residue, contributes to the purification of water by leaving no chemical residues, such as contributing to the activation of ecosystems.

The concentration of ozone dissolved in the treated water by the ozone mixing unit 90 as described above should be maintained at an appropriate value. To this end, the flow meter 100 is preferably provided in front of the ozone generator 96 of the main pipe (50). The flow meter 100 is used to measure the flow rate of the treated water flowing through the main pipe 50 so that only the appropriate flow rate flows to the demand destination. That is, based on the flow rate sensed by the flow meter 100 in the control panel to control the flow rate of the pump by controlling the number of pumps or adjusting the opening degree of the valve or the rotation speed of the pump. And it is comprised so that ozone injection amount may be controlled according to the flow signal. By measuring and adjusting the flow rate in this way, it is possible to keep the concentration of ozone dissolved in the treated water constant.

As described above in detail based on the embodiments of the present invention, the scope of the present invention is not limited thereto, and the scope of the present invention is included in the scope of the present invention to the extent substantially equivalent to the embodiments of the present invention.

1 is a schematic diagram of a conventional submersible pump type treated water transfer pump system;

Figure 2 is a schematic diagram of a conventional land pump type treatment water transfer pump system,

3 is a block diagram of a resource-saving treatment water transfer pump system in a sewage treatment plant according to the present invention;

4 is a configuration of the submersible vertical turbine pump according to the present invention,

5 is a side view of the vortex preventing means 60 according to the present invention;

6 is a plan view of the vortex preventing means according to the present invention.

Explanation of symbols on the main parts of the drawings

10: sewage treatment plant 20: reservoir

21: water tank screen 22: damper wall

30: submersible vertical turbine pump 32: pumping unit

32a: Impeller 32b: Paul Assembly

34: column portion 36: discharge portion

36a: discharge port 38: pumping drive part

40: discharge pipe 42: check valve

44: isolation valve 50: main piping

60: vortex prevention means 61: anchor

62: vertical plate 63: nut

64: horizontal plate 65: support rod

66: support plate 67,68: nut

70: reprocessing return pipe 80: backwash customs

82: backwash valve 90: ozone mixing unit

92 compressor 94 oxygen generator

96: ozone generator 98: ozone mixer

100: flow meter

Claims (7)

A reservoir 20 for temporarily storing the treated water discharged from the sewage treatment plant 10; A pumping part 32 including an impeller 32a at a lower part, a column part 34 connected to an upper part of the pumping part 32, and a pumped treatment water connected to an upper part of the column part 34 Discharge part 36 for discharging and a pumping drive part 38 which is located above the discharge part 36 to provide a driving force to the pumping part 32, the pumping part 32 and the column part ( 34 is installed in the treated water stored in the reservoir 20, the discharge portion 36 and the pumping drive 38 is installed to penetrate the ceiling of the reservoir 20 to be exposed to the outside, the reservoir 20 A plurality of underwater vertical turbine pumps (30) for pumping the treated water stored therein and discharging them upward; A discharge pipe 40 connected to the discharge portion 36 of each of the underwater vertical turbine pumps 30 and provided with a check valve 42 and a shutoff valve 44; A main pipe 50 which collects the treated water delivered from each discharge pipe 40 and delivers it to the receiving place; In order to maintain the minimum water level for the operation of the underwater vertical turbine pump 30 and to prevent the treated water from overflowing to the outside through the ceiling of the reservoir 20, one side of the reservoir 20 so that the excess treated water may overflow. Resource-saving treatment water transfer pump system in a sewage treatment plant comprising a damper wall (22) formed by opening the upper portion. The method of claim 1, The reservoir 20 is a resource-saving treatment water transfer pump system in the sewage treatment plant, characterized in that the vortex prevention means 60 is further provided. The method of claim 2, The vortex prevention means 60, A vertical plate 62 extending vertically along the longitudinal direction of the submerged vertical turbine pump 30 to prevent side vortices; A horizontal plate 64 arranged horizontally in a lower portion of the pumping portion 32 to prevent vortices occurring in the lower portion of the pumping portion 32 of the submersible vertical turbine pump 30; The support plate 66 which supports the vertical plate 62 and the horizontal plate 64 from the bottom and is fastened by the anchor 61 to the bottom of the reservoir 20, fastening the anchor 61 of the support plate 66 The long hole is formed in the portion is configured to allow the left and right movement of the support plate 66, a plurality of through holes are formed in the horizontal plate 64, the support rod 65 is fitted into the through hole, the support rod 65 Resource-saving treatment water transfer pump system in a sewage treatment plant, characterized in that the horizontal plate 64 is fastened to the horizontal plate 64 by a nut at the upper and lower portions of the horizontal plate 64. The method of claim 1, In order to reprocess when the water quality of the treated water delivered through the main pipe 50 is low, a reprocessing return pipe 70 branched from the main pipe 50 and connected to the sewage treatment plant 10 is further provided. Resource-saving treatment water transfer pump system in the sewage treatment plant. The method of claim 1, One end is connected to one side of the main pipe 50, the other end further includes a backwashing pipe 80 connected to the front end of the check valve 42 installed in the discharge pipe 40, the backwashing pipe 80 ), A backwash valve 82 is a resource-saving treatment water transfer pump system in a sewage treatment plant. The method of claim 1, One side of the main pipe 50 is further provided with an ozone mixing unit 90, the ozone mixing unit 90 is the oxygen generator 94 for separating only oxygen from the mixed air; An ozone generator (96) for generating ozone by discharge from oxygen generated in the oxygen generator (94); Resource-saving treatment water transfer pump in the sewage treatment plant comprising a mixer for mixing and dissolving the ozone gas supplied from the ozone generator 96 with the water flowing from the main pipe 50 to generate micro bubbles. system. The method of claim 6, In front of the ozone mixing unit 90 of the main pipe 50, the flow meter 100 is provided to measure and adjust the flow rate of the treated water flowing through the main pipe 50 to maintain the proper ozone concentration in the treated water. Resource-saving treatment water transfer pump system in the sewage treatment plant.

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