KR20100134947A - Water circulation system for prevention of hypolimnetic oxygen deficit - Google Patents

Abstract

PURPOSE: A reservoir deep anaerobic protecting water circulation device preventing the deterioration of the water quality with the circulation of the deep water is provided to improve an anaerobic state by descending the deep water by supplying the lifted deep water. CONSTITUTION: An inhaling unit inhales the deep water through an inlet(37). The suction part has inhaling pipes. An air supply unit(70) supplies the deep water. The entrance of the discharge unit is connected to the outlet of the suction tube. The discharge unit surrounds the suction tube of the upper section than inlet. An exit is formed in the lower part of the discharge unit. The discharge unit descends the deep water flowing in as described above to exit.

Description

Water circulation system for prevention of hypolimnetic oxygen deficit

The present invention relates to a deep reservoir anaerobic prevention device, and more particularly, after supplying air to the deep water pulled up from the deep layer and descending back to the deep layer to improve the anaerobic depth of the deep layer and to suppress the deterioration of water quality of the surface layer by the deep water. It relates to a reservoir deep anaerobic prevention water circulation system.

Multi-purpose dam reservoirs have a long depth of residence because of their depth and the size of their bodies. As a result, reservoirs are characterized by varying water temperature, dissolved oxygen, and nutrient concentrations with seasons.

In particular, as the water temperature of the surface layer becomes very high in the summer, organic matter is generated more and they settle and deplete the oxygen of the deep layer, causing the deep water anaerobic. In addition, the organic material introduced into the reservoir during the rainy season is deposited on the bottom of the reservoir and decomposed to deplete deep oxygen, which also promotes anaerobic deep water. As a result, deeper reservoirs in the deeper water reservoirs from the mid-to-late summer season show anaerobic phenomena, and their area expands over time.

In order to solve this problem, many reservoirs are trying to prevent deep anaerobic by installing underwater aeration device. Underwater aeration system pulls deep water to the surface layer, circulates deep water and surface water, and supplies oxygen to deep water to suppress anaerobic deepening.

However, since deep water with high concentrations of nutrients and metal ions rises to the surface, the concentration of nutrients and metal ions in the entire body of water increases, resulting in a problem of degrading the quality of water supplied to the intake facility. This causes a lot of water treatment costs in the water purification plant, a problem that the quality of the purified water falls.

Therefore, the object of the present invention is to increase the anaerobic deep water so as not to mix with the surface water, supply air to the elevated deep water to convert to aerobic state, and then send it down to the deep again to improve the anaerobic depth of the deep water It is to provide a deep reservoir anaerobic water circulation system that can suppress the deterioration of the water quality of the surface layer.

In order to achieve the above object, the present invention provides a deep reservoir anaerobic prevention water circulation device comprising a suction part, an air supply part and a discharge part. The suction part sucks the deep water in a horizontal direction to the water surface through a suction port formed on the outer side of the reservoir rather than the bottom surface of the reservoir, and has a suction pipe whose length is adjusted according to the water level of the reservoir. The air supply unit is disposed on the outlet side of the suction pipe, and supplies air to the drawn deep water to convert the deep water into an exhaled state. The discharge part has an inlet connected to the outlet of the suction pipe, and has an outlet connected to the inlet at the lower part of the suction pipe of the upper part rather than the suction port of the suction pipe, and converted into the exhaled state introduced through the inlet. Deep water is lowered toward the outlet and discharged in a direction horizontal to the water surface.

The water circulation device according to the present invention further includes an anchor positioned on the bottom surface of the reservoir and a connection member connecting the anchor and the bottom surface of the suction pipe.

In the water circulation device according to the present invention, the suction part comprises a main body, the suction pipe, a plurality of buoys, a drive motor and an impeller. The main body has a processing space formed at the center portion and an open portion formed at the bottom thereof. The suction pipe is connected to the opening of the main body is installed inside the opening, and extends below the water surface. The plurality of buoys are connected to the main body to float the main body on the surface of the water. The drive motor is installed above the main body, and the drive shaft extends toward the outlet of the suction pipe. The impeller is installed at the distal end of the drive shaft and draws up the deep water and supplies it to the discharge part.

In this case, the main body may include a frame, a casing, and a discharge guide tube. The drive motor is fixedly installed on the frame, and the plurality of buoys are connected to the outside. The casing is installed inside the frame to surround the impeller and is connected to the upper end of the suction pipe. The discharge guide tube surrounds an outer portion of the frame and is connected to the discharge portion, and is fixed to the casing.

The body further comprises a reducer for interfacing the casing and the suction pipe, and a diffuser installed between the upper end of the casing and the frame and diffusing deep water drawn up by the impeller. Can be.

An upper end of the discharge guide tube protrudes above the water surface of the reservoir to prevent inflow of the surface water.

In the water circulation device according to the present invention, the air supply unit is installed on the upper portion of the frame and the air blower (blower) for supplying air, the air blower and the case is connected, and received from the air blower And an air supply pipe for discharging air into the case to supply air to the drawn deep water.

In the water circulation device according to the present invention, the suction pipe is connected to the upper suction pipe, the lower end of the reducer, the flexible tube (flexible tube) is connected to the lower end of the upper suction pipe, the length is adjusted according to the level of the reservoir The lower suction pipe is connected to the lower end of the flexible tube and has a plurality of suction ports formed on an outer surface of a lower portion thereof. In this case, each of the upper suction pipe and the lower suction pipe may have a structure in which at least one pipe is connected to each other.

In the water circulation device according to the present invention, the discharge portion is discharge pipe surrounding the upper suction pipe, and discharged to be installed at the lower end of the upper suction pipe in the horizontal direction on the water surface spaced at a predetermined interval from the discharge pipe to form the outlet It is configured to include a guide plate.

The discharge unit may further include a fixing ring installed between the discharge tube and the upper suction tube to maintain a gap between the discharge tube and the upper suction tube.

The water circulation device according to the present invention draws deep water through the suction pipe in a horizontal direction on the surface of the water under the driving of the impeller, pulls it toward the surface so as not to be mixed with the surface water, and supplies air to the drawn deep water to convert it into aerobic state. The deep water, which has been converted into an aerobic state, is lowered to prevent it from being mixed with the surface water through the discharge pipe, and then discharged in a horizontal direction to the surface of the water. Therefore, the deep water is mixed with the surface water to deteriorate the water quality while improving the anaerobic depth of the water. Can solve the problem.

Deep water is sucked in the horizontal direction on the surface of the water, and the deep water that is converted into the aerobic state from the upper depth is discharged in the horizontal direction on the surface of water, rather than the point where the deep water is sucked, so that the deep water is circulated directly. The formation of deep water flow can effectively improve the anaerobicization of deep water. In addition, by absorbing deep water slightly above the bottom of the reservoir and circulating the deep water by releasing deep water converted into aerobic state from the top where the deep water is absorbed, the sediment and anaerobic layers at the bottom of the reservoir are weakened, Elution of metal ions can be suppressed.

In addition, the length of the flexible tube connected between the upper and lower suction pipes may be adjusted according to the water level of the reservoir to maintain the position of the water circulation device in the reservoir.

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

Reservoir deep anaerobic prevention water circulation device according to an embodiment of the present invention (100; hereinafter, referred to as' water circulation device)), as shown in Figures 1 to 3, the suction unit 10, air supply unit It comprises a 70 and the discharge part 80. The suction part 10 sucks the deep water 65a in the horizontal direction to the water surface 61 through the suction port 37 formed on the outer side of the reservoir 63 rather than the bottom surface 63 of the reservoir, and raises the water to the water surface 61. It has a suction pipe 30, the length of which is adjusted according to the level of. The air supply unit 70 is disposed at the outlet 39 side of the suction pipe 30 and supplies air to the deep water 65a that is pulled up to convert the deep water 65a into an exhaled state. In addition, the discharge part 80 has an inlet 87 connected to the outlet 39 of the suction pipe 30, and surrounds the suction pipe 30 of the upper portion rather than the suction port 37 of the suction pipe 30 and the inlet 87 ), An outlet 89 is formed, and the deep water 65b converted into the aerobic state introduced through the inlet 87 is lowered toward the outlet 89 and discharged in a horizontal direction on the water surface 61.

Meanwhile, the water circulation device 100 according to the present exemplary embodiment may further include an anchor 91 and a connection member 95 for fixing to a predetermined position of the reservoir. The anchor 91 is located on the bottom surface 63 of the reservoir. The connecting member 95 connects the anchor 91 and the bottom surface of the suction pipe 30. At this time, the connecting member 95 is fixed to the bottom surface of the suction pipe by a flange (97; flange) (97) and the fixing plate (95a) protrudes toward the anchor 91 from the anchor plate 93 and anchors through the link 93 A pipe 95b connected to 91.

Such a water circulation device 100 according to the present embodiment sucks the deep water 65a in the horizontal direction to the water surface 61, pulls it toward the water surface 61 so as not to be mixed with the surface water, and to the deep water 65a drawn up. Since the air is supplied to the exhaled state, and the deep water 65b converted into the exhaled state is lowered to the deeper layer so as not to be mixed with the surface water through the discharge unit 80, and then discharged in a horizontal direction to the water surface 61. In addition, the problem of deteriorating the water quality of the surface water by mixing the surface water with the surface water 65a drawn up while improving the anaerobic depth of the water surface can be solved.

The water circulation device 100 according to the present embodiment sucks the deep water 65a in the horizontal direction to the water surface 61, and converts the deep water 65b into an aerobic state at a deeper depth than the point where the deep water 65a is sucked. ) Is discharged in the horizontal direction on the water surface 61 to directly circulate the deep water 65a, 65b, so that a larger amount of deep water 65a, 65b flows with the same energy to form the deep water 65a, 65b. Effectively improve anaerobic. In addition, the deep water 65a is absorbed slightly above the bottom surface 63 of the reservoir, and the deep water 65b converted into the aerobic state is discharged from the upper portion rather than the point where the deep water 65a is absorbed, thereby extracting the deep water 65a and 65b. By circulating, the deposited layer and the anaerobic layer of the bottom surface 63 of the reservoir are weakened, and the nutrients and metal ions can be prevented from eluting.

And the length of the suction pipe 30 is adjusted according to the water level of the reservoir to maintain the position of the water circulation device 100 in the reservoir.

Specifically, the water circulation device 100 according to the present embodiment will be described.

The suction unit 10 includes a main body 20, a suction pipe 30, a buoy 40, a drive motor 50, and an impeller 53. The main body 20 has a processing space formed at a central portion thereof, and an open portion 22 is formed at a lower portion thereof. The suction pipe 30 has an outlet 39 connected to the opening portion 22 of the main body 20 and installed inside the opening portion 22 and extends below the water surface 61. The plurality of buoys 40 are connected to the main body 20 to float the main body 20 on the water surface 61. The drive motor 50 is installed above the main body 20, and the drive shaft 51 extends toward the discharge port 39 of the suction pipe 30. The impeller 53 is installed at the distal end of the drive shaft 51 and pulls up the deep water 65a to supply it to the discharge unit 80.

The main body 20 includes a frame 21, a casing 23, and a discharge guide tube 25.

The frame 21 is fixed to the drive motor 50 is installed in the central portion of the upper portion, a plurality of buoys 40 are connected to the outside. In this embodiment, three buoys 40 are disclosed in the radially connected to the outside of the frame 21, but is not limited thereto. For example, three or more buoys may be installed outside the frame. The handle 41 is installed at the connected portion of the buoy 40 and the frame 21, respectively, and adjusts the height of the buoy 40 according to the manipulation of the handle 41 so that the main body 20 sleeps 61. Level it up.

The casing 23 is installed inside the frame 21 to surround the impeller 53 and is connected to the upper end of the suction pipe 30. In this case, although the casing 23 has been disclosed to be fixed to the inner side of the frame 21 by welding, it may be fixedly installed by other fastening members such as riveting, fastening bolts and the like.

In addition, the discharge guide tube 25 surrounds the outer periphery of the frame 21 and is connected to the discharge unit 80, and is fixed to the casing 23. In this case, the discharge guide tube 25 may be connected and fixed to the flange 28 through the casing 23 and the fixing member 26. The fixing member 26 is provided between the discharge guide tube 25 and the casing 23. The fixing member 26 may have a fixing ring shape having a plurality of fixing bars or a plurality of spaces. Of course, the space portion is used as a passage through which the deep water 65b converted into the aerobic state can pass. The discharge guide tube 25 protrudes on the water surface 61 of the reservoir to prevent the inflow of surface water.

The drive shaft 51 of the drive motor 50 is provided at the center portions of the casing 23 and the suction pipe 30. The impeller 53 performs a function of increasing the dissolved oxygen of the deep water 65a by mixing air with the deep water 65a which is pulled up along with the function of raising the deep water 65a through the suction pipe 30. At this time, in order to prevent the vortex of the deep water 65a drawn up by the impeller 53, a guide 55 may be further installed below the portion where the impeller 53 is installed. Guide 55 is installed in the central portion of the casing 23, the upper portion is open and has a lower concave shape than the upper portion is wider than the upper portion.

Meanwhile, the body 20 may further include a reducer 27 and a diffuser 29. The reducer 27 mediates the connection between the casing 23 and the suction pipe 30 having different inner diameters. That is, the inner diameter of the casing 23 is larger than the inner diameter of the suction pipe 30, the reducer 27 connects the casing 23 and the suction pipe 30 using the flange 24. The diffuser 29 is installed between the upper end of the outer casing 23 and the frame 21 to diffuse the deep water 65b drawn up by the impeller 53. The deep water 65b diffused from the diffuser 29 moves to the discharge tube 80 through the discharge guide tube 25.

The air supply unit 70 includes an air blower 71 and an air supply pipe 73. The air blower 71 is installed on the upper part of the frame 21 and supplies air. The air supply pipe 73 connects the air blower 71 and the casing 23, and supplies air to the deep water 65a drawn up by supplying the air supplied from the air blower 71 into the casing 23. . At this time, the air supply pipe 73 directly protrudes through the connection hole formed in the outer surface of the casing 23 to supply air into the casing 23. Alternatively, the air supply pipe 73 is installed in close contact with the outer surface of the casing 23, and a plurality of fine holes are formed in the surface of the casing 23 in which the air supply pipe 73 is installed to supply air from the air supply pipe 73. Can be fed into the casing 23.

The suction pipe 30 includes an upper suction pipe 31, a flexible tube 33, and a lower suction pipe 35. The upper suction pipe 31 is connected to the lower end of the reducer 27 by a flange 24. The flexible tube 33 is connected to the lower end of the upper suction pipe 31 by the flange 32, the length is adjusted according to the level of the reservoir. And the lower suction pipe 35 is connected to the lower end of the flexible tube 33, a plurality of suction ports 37 are formed on the outer surface of the lower.

At this time, the upper suction pipe 31, the flexible tube 33 and the lower suction pipe 35 are connected in communication with each other, and extends vertically toward the bottom surface 63 of the reservoir with respect to the water surface 61 of the reservoir. Each of the upper and lower suction pipes 31 and 35 may have a structure in which at least one pipe is connected to each other. In the present embodiment, the lower suction pipe 35 has a structure in which two pipes are connected to each other. As the flexible tube 33, it is preferable to use a flexible tube capable of responding to changes in water level of several tens of meters.

The discharge unit 80 includes a discharge tube 81 and a discharge guide plate 83. The discharge tube 81 is connected to the opening 22 of the discharge guide tube 25 by a flange 28 and surrounds the upper suction tube 31. The discharge guide plate 83 is spaced apart from the discharge tube 81 at a predetermined interval to be connected to the lower end of the upper suction tube 31 in the horizontal direction on the water surface 61 by the flange 32 to form an outlet 89. Therefore, the deep water 65b moved through the discharge pipe 81 is discharged in a direction horizontal to the water surface 61 in accordance with the guide of the discharge guide plate 83.

At this time, the discharge portion 80 may be further configured to include a fixing ring 85 is installed between the discharge tube 81 and the upper suction tube 31 to maintain a gap between the discharge tube 81 and the upper suction tube 931. have. In the present embodiment has been described an example in which one fixing ring 85 is installed in the middle portion in the longitudinal direction of the discharge tube 81, a plurality of fixing rings may be installed at regular intervals.

Referring to the process of circulating the deep water (65a, 65b) with the circulation device 100 according to this embodiment as follows.

First, the water circulation device 100 according to the present embodiment is installed in the reservoir. At this time, the anchor 91 is fixed to the bottom surface 63 of the reservoir. Due to the buoyancy of the buoy 40, the upper end of the body 20 is floating on the water surface 61. The vertical length of the flexible tube 33 of the suction pipe 30 is adjusted according to the buoyancy of the buoy 40 and the depth of the reservoir to maintain the position of the main body 20 on the water surface 61.

Next, when the impeller 53 is rotated by driving the driving motor 50, the deep water 65a is sucked in the horizontal direction on the water surface 61 through the suction port 37 of the lower suction pipe 35. The deep water sucked in (65a) is moved along the lower suction pipe 35, the flexible tube 33, the upper suction pipe 31 and the reducer 27 to the casing (23). At this time, the deep water 65a sucked moves along the lower suction pipe 35, the flexible tube 33, the upper suction pipe 31, and the reducer 27, so that the deep water 65a is water-leveled without mixing with the surface water. To the side.

Next, the air supply unit 70 supplies air to the deep water 65a drawn up by supplying air into the casing 23 and converts it into an exhaled state. At this time, the impeller 53 mixes the drawn deep water 65a with air to increase the dissolved oxygen of the deep water 65a and converts it into an aerobic state. Further, the deep water 65a, which is out of the casing 23, is diffused in the diffuser 29.

Subsequently, the deep water 65b diffused from the diffuser 29 descends to the discharge tube 81 through the discharge guide tube 25. At this time, since the deep water 65b converted into the exhaled state moves to the deep water through the discharge pipe 81, it can be prevented from mixing with the surface water.

Further, through the outlet 89 formed by the discharge pipe 81 and the discharge guide plate 83, the deep water 65b converted into the exhaled state is discharged to the deep water in a direction parallel to the water surface 61 to deep water 65a and 65b. By circulating, it is possible to suppress that the deep water 65a drawn up is mixed with the surface water and deteriorates the water quality of the surface water while improving the anaerobicization of the deep water.

In particular, the water circulator 100 according to the present embodiment sucks the deep water 65a in the horizontal direction on the water surface 61, and converts the deep water into the aerobic state at the upper depth rather than the point where the deep water 65a is sucked ( Since 65b) is discharged in the horizontal direction on the water surface 61 to directly circulate the deep water 65a, 65b, a larger amount of deep water 65a, 65b is formed with the same energy to form the deep water 65a, 65b. Can effectively improve anaerobic digestion. In addition, the deep water 65a is absorbed slightly above the bottom surface 63 of the reservoir, and the deep water 65b converted into the aerobic state is discharged from the upper portion rather than the point where the deep water 65a is absorbed, thereby extracting the deep water 65a and 65b. By circulating, the deposition layer and the anaerobic layer of the reservoir bottom surface 63 are weakened, and nutrients and metal ions can be prevented from eluting.

On the other hand, the embodiments of the present invention disclosed in the specification and drawings are merely presented specific examples to aid understanding, and are not intended to limit the scope of the present invention. In addition to the embodiments disclosed herein, it is apparent to those skilled in the art that other modifications based on the technical idea of the present invention may be implemented. Meanwhile, in the present embodiment, the discharge guide plate is installed in a horizontal direction on the surface of the water to discharge the deep water, but the discharge guide plate may be formed to be slightly inclined downward or upward to smooth the flow of the deep water at the outlet of the discharge portion. have.

1 is a plan view showing a deep reservoir anaerobic prevention water circulation device according to an embodiment of the present invention.

FIG. 2 is a partial cross-sectional view taken along line II-II of FIG. 1.

3 is a view illustrating a process of circulating deep water with a deep water anaerobic prevention water circulation system according to an embodiment of the present invention.

Description of the Related Art [0002]

10: suction 20: main body

21 frame 23 casing

25: discharge guide tube 27: reducer

29: diffuser 30: suction tube

31: upper suction pipe 33: flexible tube

35: lower suction pipe 40: buoy

50: drive motor 53: impeller

70: air supply 71: air blower

73: air supply pipe 80: discharge part

81: discharge tube 83: discharge guide plate

85: retaining ring 91: anchor

93 link 95 connecting member

100: water circulation device

Claims (12)

A suction unit having a suction pipe that sucks deep water into a water surface in a horizontal direction to the water surface through a suction port formed on an upper outer surface of the reservoir rather than the bottom surface thereof, and whose length is adjusted according to the water level of the reservoir; An air supply unit disposed at an outlet of the suction pipe and configured to supply air to the drawn deep water to convert the deep water into an exhaled state; An inlet is connected to the outlet of the suction pipe, and an outlet connected to the inlet is formed at the lower part of the suction pipe of the upper part than the suction port of the suction pipe, and the deep water converted into the aerobic state introduced through the inlet is A discharge part which is discharged in a horizontal direction on the water surface by lowering toward the outlet; Reservoir deep anaerobic water circulation system comprising a. The method of claim 1, An anchor located on the bottom surface of the reservoir; A connection member connecting the anchor to the bottom surface of the suction pipe; Reservoir deep anaerobic water circulation device, characterized in that it further comprises a. The method of claim 2, wherein the suction unit, A main body having a processing space formed at a central portion thereof and having an opening formed at a lower portion thereof; The suction pipe is connected to the opening of the main body is installed inside the opening, the suction pipe extending below the water surface; A plurality of buoys connected to the main body to float the main body on the surface of the water; A drive motor installed at an upper portion of the main body and having a drive shaft extending toward an outlet of the suction pipe; An impeller installed at an end of the drive shaft and supplying the deep water to the discharge part; Reservoir deep anaerobic water circulation system comprising a. The method of claim 3, wherein the main body, A frame to which the driving motor is fixedly installed, and to which the plurality of buoys are connected; A casing installed inside the frame and surrounding the impeller and connected to an upper end of the suction pipe; A discharge guide tube surrounding an outer portion of the frame and connected to the discharge part and fixed to the casing; Reservoir deep anaerobic water circulation device comprising a. The method of claim 4, wherein the main body, A reducer which mediates the connection between the casing and the suction pipe; Reservoir deep anaerobic water circulation device, characterized in that it further comprises a. The method of claim 5, wherein the main body, A diffuser installed between an upper end of the outer casing and the frame and configured to diffuse deep water drawn up by the impeller; Reservoir deep anaerobic water circulation device, characterized in that it further comprises a. The method of claim 6, wherein the discharge guide tube, Reservoir deep anaerobic water circulation system, characterized in that the top protrudes above the water surface of the reservoir to prevent the inflow of surface water. The method of claim 7, wherein the air supply unit, An air blower installed at an upper portion of the frame to supply air; An air supply pipe connected to the air blower and the case and supplying air to the drawn deep water by discharging the air supplied from the air blower into the case; Reservoir deep anaerobic water circulation device comprising a. The method of claim 8, wherein the suction pipe, An upper suction pipe connected to the lower end of the reducer; A flexible tube connected to a lower end of the upper suction pipe and having a length adjusted according to the level of the reservoir; A lower suction pipe connected to a lower end of the flexible tube and having a plurality of suction ports formed on an outer surface of a lower portion of the flexible tube; Reservoir deep anaerobic water circulation device comprising a. The method of claim 9, wherein the upper suction pipe and the lower suction pipe, respectively, Reservoir deep anaerobic water circulation system, characterized in that the at least one tube has a structure connected to each other. The method of claim 10, wherein the discharge unit, A discharge tube surrounding the upper suction tube; A discharge guide plate spaced apart from the discharge pipe by a predetermined interval and installed at a lower end of the upper suction pipe in a horizontal direction on the surface of the water to form the outlet; Reservoir deep anaerobic water circulation device comprising a. The method of claim 11, wherein the discharge unit, A fixing ring installed between the discharge tube and the upper suction tube to maintain a gap between the discharge tube and the upper suction tube; Reservoir deep anaerobic water circulation device, characterized in that it further comprises a.

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