KR20030097562A - Ecological Restoration Hydrological Assistance System - Google Patents

Abstract

PURPOSE: An ecological restoration water gate type automatic barrier system is provided to prevent the accumulation and loss of soil, to restore an ecosystem of rivers and to increase the containing water quantity of rivers. CONSTITUTION: The ecological restoration water gate type automatic barrier system contains: a concrete structure(10) provided with an underwater barrier(12) formed lower than an embankment(11) and formed correspondingly to the bottom of a river between underwater barriers(12); a water gate(25) installed between support frames(21) installed vertically between the underwater barriers(12); a water gate operating unit(20) installed on a floor slab fastened to the top of the support frame(21) and fixing the upper part of the water gate(25) to a rod(28) of a cylinder(27) connected to hydraulic, pneumatic pressure pump unit(26); a water gate support(30) supporting the support frame(21) to bear water pressure; a water level sensor installed to the support frame(21) to sense the water level of the river; and a control box controlling the water level by controlling the water operating unit(20).

Description

Ecological Restoration Stream Level Control System

The present invention forms a sluice in the concrete structure to open and close the sluice in the same way as the bottom surface of the river to prevent sedimentary sediment of the river to accumulate to prevent the loss of downstream sediment at the same time to form a plurality of sluice gates individually In order to maintain the soundness of the ecosystem by smoothing the flow of water during flooding and preventing flooding and smoothing the movement of fish by forming a hydrologic operation means to open or close at the same time. It is about.

In general, the beam of the river is to form the underwater beam of the beam of concrete higher than the bottom of the river to increase the water level of the river so that water flows naturally into the irrigation channel.

Because of the risk of flooding, such conventional beams cannot be installed above a certain height because of the risk of flooding, and there is no desalination effect. Because of the height of concrete beams, the upstream side of the beam is filled with sedimentary soil, and the downstream side is lost due to the fall of the beam. There was a problem of destroying the ecological environment of the river.

In addition, the movement of fish is active for a certain period of time after the flood, and because of the drop due to the height of the beam, the blockage of the fish's migration path restricts the spawning place of the fish and causes the destruction of the food chain, resulting in the reduction of fish species and the water poverty There were also defects that resulted in the destruction of enemy health.

Recently, in order to increase the freshwater volume of beams, automatic opening and closing gates were installed in the upper part of beams, but the desalination effect was slightly raised but it did not make up for the disadvantages of beams.

In addition, most of the hydrological flows from the river to the irrigation canal, and backflow prevention gates, are mostly operated manually or powered only by the operation. These floods are often damaged due to improper timing and fail to effectively use water. There are disadvantages.

The water gate provided by the present invention allows automatic opening and closing of the water gate by the water level measured by the water level measuring device, thereby contributing to safety as well as efficient use of water in case of emergency.

An object of the present invention is to restore the ecology of the environment by increasing the fresh water in the river, preventing the sediment deposition on the upstream of the river and the loss of the soil on the downstream side, and at the same time allowing the movement of fish freely. In order to provide a river level control system, in detail, the bottom surface and the upper surface of the stream to form a concrete structure and a plurality of water gates in the center of the structure, the water gate is in contact with the upper surface of the concrete structure of the river It is possible to prevent the sediment of sediment of rivers from accumulating at the time of opening the floodgate and to prevent the loss of downstream soil.

Another object of the present invention is to form a water net on one side of the concrete structure to automatically open and close the water gate by using a water level detection means based on the water level, the water gate is made of a plurality of water level in the water level Therefore, by opening and closing multiple floodgates individually or at the same time, the floodgates prevent flooding by smoothly flowing water during flooding, and by protecting the ecosystem of rivers by smoothly moving fish when opening floodgates. It is to provide automatic water level control system.

Ecological restoration type river level control system of the present invention for achieving the above object in the rivers each bank is formed on both sides with a predetermined height, each of which includes a submersible beam formed lower than the banks on both sides of the river, Concrete structures formed to match the floor surface; A water gate provided freely in a lift between a plurality of support frames vertically installed between the underwater beams; A hydrologic operation means installed on an upper plate fastened to the plurality of support frames and fixing an upper portion of the floodgate to a rod of a cylinder connected to a hydraulic / pneumatic pump unit; A hydrologic support for supporting the support frame to withstand water pressure; Water level sensing means provided in the support frame to monitor the level of the river; And control means for controlling the water level by opening and closing the water gate by controlling the watermark operating means based on the water level detection signal detected by the water level detecting means.

1 is a front view showing a water level control system of the present invention,

Figure 2 is a plan sectional view showing the whole structure of the present invention,

3 is a side cross-sectional view of the present invention;

4 is a cross-sectional view showing an operating state of the water level detecting means of the present invention,

5 is a front view showing an operating state of the present invention.

* Explanation of symbols for main parts of the drawing

10: concrete structure 11: dike

12: underwater walk 20: hydrologic operation means

21: support frame 22: top plate

23: guide member 25: water gate

26: hydraulic / pneumatic pump unit 27: cylinder

28: Rod 30: Sluice Support

40: water level detection means 41: main body

42. Sensor 43: Guide shaft

44: switch 45: float

46: magnet 50: control box

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings. 1 is a front configuration diagram showing the overall configuration of the present invention, the river level control system of the present invention is a concrete structure (between the dike 11 and the embankment 11 with respect to the width direction of the river to match the bottom surface of the river ( 10 is formed, and on the both sides of the upper surface of the concrete structure 10 forms a submerged beam 12 having a constant height lower than the height of the embankment 11.

The present invention by installing a plurality of support frames 21 vertically at regular intervals in the concrete structure 10 between the underwater beams 12, by installing a water gate 25 between the support frame 21 The water gate 25 and the underwater beam 12 to store the river water to ensure a constant fresh water amount. When reaching a certain water level it is to be discharged downstream through the water trap 13 formed in the underwater beam 12.

According to the present invention, the hydrological support means 20, the hydrological support means 30, and the support frame 21, which firmly support the support frame 21 of the hydrologic operation means 20, are configured to raise and lower the watermark 25 up and down. The control box 50 is formed on one side of the rear surface of the water level detecting means 40 for detecting the water level and the control means for controlling the hydrological operating means 20 in conjunction with the water level detection signal detected by the water level detecting means 40 It is included.

The river has embankments 11 formed at both sides of the river at a predetermined height to prevent inflow of water or to prevent flooding. The present invention forms a concrete structure (10) to match the bottom surface of the river between the dike (11) and the dike (11), on both sides of the concrete structure (10) submerged beams of somewhat lower height than the dike (11) ( 12) is formed in the upper center of the underwater beam 12 to form a water trap 13 so as to maintain a constant level of the river water, so the water trap 13 is a reference level of the river, that is, the maximum fresh water Set at the water level.

In the embodiment, the water trap 13 is formed to be recessed about 10 cm lower from the upper surface of the underwater beam 12 so that the river water is constantly supplied downstream.

The hydrologic operation means 20 is formed to have a plurality of hydrologic gates 25 between the two submerged beams 12 in which the water nugget 13 is formed, and in this embodiment, a plurality of H beams in the center of the submersible beams 12. A plurality of support frames 21 made of (200 × 300 × 6) are installed vertically in succession at 2m intervals.

When the installation of the support frame 21 is completed, the upper plate 22 having a predetermined width is installed on the upper portion of the support frame 21 to connect the support frame 21 and the safety railing on the outer periphery of the upper plate 22 ( By installing 21a) it is possible to prevent the fall during work.

In addition, one side of the support frame 21 to form a staircase handle (21b) so that when a problem occurs in the hydrological operating means 20 can be repaired.

The inner surface of the support frame 21 is formed to face the guide member 23 made of a U-shaped so that the water gate 25 is fitted therein to be moved up and down. At this time, the bottom of the guide member 23 to form a locking jaw (24) to prevent the stone or trees moving along the river flow into the farmland and the locking jaw (24) is formed with an inclined top surface and the water gate (25) Also, the bottom surface thereof is formed to be inclined in the same manner as that of the locking jaw 24 to secure the tight contact between the water gate 25 and the locking jaw 24, thereby maintaining airtightness and trapping foreign matter on the bottom of the water gate 25. This can be prevented.

A bracket 25a is formed at the upper center of the water gate 25 to be fixed to the rod 28 of the cylinder 27 and the bolt. Here, the cylinder 27 is fixed to the upper portion of the upper plate 22 and the hydraulic / pneumatic pump unit 26 is formed on one side of the cylinder 27 for raising and lowering the water gate 25 to control the cylinder 27. .

The sluice support 30 is formed on the front of the support frame 21 so that the support frame 21 can withstand the hydraulic pressure, one end is fixed to the upper portion of the support frame 21 by welding or bolts, and the other end thereof is a concrete structure ( 10) is fixed to the bottom surface.

The water level detecting means 40 is formed on the rear side of the support frame 21, that is, one side of the stream upstream, as shown in FIG. 2, and measures the level of the river based on the water spout 13 of the concrete structure 10. The water level detection signal is transmitted to the control box 50, and the opening and closing of the water gate 25 is performed by interlocking with the water level by a program set according to the water level signal applied from the water level sensing means 40 in the control box 50. Control.

4 shows an embodiment of the water level detecting means 40. Referring to the drawings, the water level detecting means 40 of the present invention includes a main body 41 made of a tubular hollow inside, the main body 41 is an inlet hole (41a) so that the water of the river flows into the outer periphery ) Is formed.

A sensor detecting portion 42 is formed on the upper portion of the main body 41, and a circular guide shaft 43 is installed in the vertical direction on the bottom thereof, and the lifting and lowering is freely performed depending on the water level on the outer circumference of the guide shaft 43. When 45 is coupled to change the water level, it is moved up and down along the guide shaft 43.

In addition, the switch 44 is formed in the longitudinal direction at regular intervals on the outer periphery of the guide shaft 43, the switch 44 is turned on and off by the magnetizing force of the magnet 46 formed inside the float 45 When activated, the sensor detecting unit 42 electrically connected to the switch 44 detects the electrical signal, and the detected signal is transmitted to the control box 50 and the water level signal transmitted to the control box 50 is The hydrology is controlled by a built-in program.

In addition, the bottom of the guide shaft 43 may be formed by a stopper 47 formed of a rubber ring so that the float 45 no longer descends to the bottom, thereby adjusting the distance of the float 45.

The control box 50 is installed on one side of the embankment 11 of the concrete structure 10 and electrically connected to the water level detecting means 40 to operate the hydraulic / pneumatic pump unit 26 according to the result of detecting the level of the river. The pneumatic pump unit 26 operates the cylinder 27 to raise and lower the rod 28 so that the water gate 25 can be raised or lowered.

In this case, the control box 50 may individually operate or simultaneously operate a plurality of sluice gates 25 formed according to the detection result of the water level detecting means 40.

For example, when the water level gradually increases, each of the gates 25 is individually controlled. On the contrary, when the inflow increases rapidly due to the heavy rainfall, the water level rises rapidly. .

According to the embodiment, the switch 44 is formed at 10 cm intervals, such as the reference water level of the water barrel 13, and the water gate 25 is controlled by 10 cm by the control of the control box 50 whenever the water level increases by 10 cm. Open it up.

In this case, if the inflow of the river is more than the amount discharged downstream by rainy season or heavy rain, the water level is gradually increased to maintain the level. That is, the water level is 10cm higher than the standard water level to open the sluice 25 by 10cm and 20cm to open 20cm higher, but the present invention is not limited to the above-described numerical value, the numerical value can be changed according to the size of the river Of course.

In the automatic water level control system of the water gate according to the present invention configured as described above, the water gate 25 maintains the bottom dead center, that is, the state facing the upper surface of the concrete structure 10. Therefore, the inflow of the stream is stored without moving downstream by the submerged beams 12 and the water gate 25 formed in the concrete structure 10, and then the water level is increased to the water spout 13 of the submerged beams 12 with increasing fresh water. As it rises, the influent flows out naturally through the water trap 13.

When the amount of inflow water flowing into the river by the small amount of precipitation as such is small, the fresh water is secured while the inflow of water flows out downstream through the water trap 13 without controlling the water gate 25.

On the contrary, when the inflow rate of the stream increases due to the summer rainy season or a local heavy rain, the water level rises by controlling the water gate 25 when the inflow rate gradually increases than the discharge amount discharged downstream through the water trap 13. To prevent flooding.

In this way, if the inflow water is increased and the inflow water is larger than the amount discharged through the water trap 13, the float 45 of the water level sensing means 40 gradually rises to detect the water level, and the detected signal is The sensor detection unit 42 transmits the water level detection signal to the control box 50.

The control box 50 controls the water level 25 to be opened by 10 cm every time the water level rises from the underwater level 12, that is, from the underwater beam 12, and then, when the water level rises further, the reference level is +1.0 m. Fully open.

When the water level reaches -0.3m after flooding, the water gate 25 is automatically closed one by one from both ends. When one or two central water gates are opened, it closes completely when the water level is 0.3m, and fresh water starts from this time. The excess water is then allowed to spontaneously discharge downstream through the spout (13).

At this time, when the water gate 25 is discharged through the water gate 25 before the water gate 25 is completely closed, there is no drop in the bottom of the river, so the fish moves smoothly, and the sediment of the river flows naturally with the water of the river downstream. Soil can be prevented from being lost.

On the other hand, the control box 50 of the present invention is to automatically adjust the water level, if the problem occurs to automatically adjust the control box 50 to manually switch the operator may be able to operate the water gate 25 arbitrarily .

In the present invention, in consideration of the fact that the level of the river is rapidly rising even in the local heavy rain or heavy rain in the rainy season in Korea will have to be set up in accordance with the characteristics of the river. And it is preferable to set the width of one hydrology 25 of the present invention to about 2m in height 2m to determine the number of continuous hydrology 25 according to the size of the river.

In the embodiment, the water gate 25 is limited to being operated by hydraulic pressure or pneumatic pressure. However, as another example, the water gate 25 may be operated by a gear type or a chain type using a motor, or the water gate may be operated in two to three stages. Of course, it is possible to reduce the height of the system by controlling the floodgates by overlapping them.

It is effective to use the water supply of the present invention in conjunction with the water quantity control of the water supply to send the water to the relevant water.

As described above, the automatic water level control system of the water gate according to the present invention is formed so that the bottom surface of the river and the bottom surface of the concrete structure coincide with each other, and the water gate is installed to be in contact with the bottom surface so as not to accumulate sediment of the river. It has the advantage of maintaining the natural ecosystem by preventing the deterioration of downstream downstream and improving the habitat environment to free the movement of fish during discharge.

The present invention is applied to rivers, and the sedimentary soil flows smoothly, and moves upstream at the time of abundant water after the spring flood, and the spawning fish moves downstream in the autumn flood and the wintering at a deep depth In preparation, the multiple gates are opened and closed individually to facilitate the movement of fish to improve the habitat environment.

The present invention improves the desalination effect by not being higher than a certain height due to the risk of flooding during flooding, so that the water flows to the bottom surface of the concrete structure by opening the floodgate during flooding, so that the water flows smoothly, The height of the beam can be increased by about 1m to 2m, increasing the freshwater amount, and as a result, the utilization of river water can be increased.

Claims (3)

In a river in which levees are formed at both sides at a predetermined height, A concrete structure including submerged beams formed on both sides of the edge and lower than the embankment, and formed to coincide with the bottom surface of the river between the submerged beams; A water gate provided freely in a lift between a plurality of support frames vertically installed between the underwater beams; A hydrologic operation means installed on an upper plate fastened to the plurality of support frames and fixing an upper portion of the floodgate to a rod of a cylinder connected to a hydraulic / pneumatic pump unit; A hydrologic support for supporting the support frame to withstand water pressure; Water level sensing means provided in the support frame to sense the level of the river; And Ecological restoration type river level control system comprising a; control means for adjusting the water level by opening and closing the water gate by controlling the water gate operation means based on the water level detection signal detected by the water level detection means. The method of claim 1, The hydrologic operation means is formed on each support frame so that the U-shaped guide member is opposed to the inner side of the H-shaped support frame, and the locking jaw protrudes upward from the bottom of the guide member, and the upper surface is inclined downward. Eco-restoration type river level control system characterized in that when combined with the water gate to prevent foreign substances caught in the water gate. The method of claim 1, The water level sensing means has a tubular body having an inlet formed in the outer periphery, a sensor sensing unit is provided in the upper portion of the body, and a guide shaft is formed in the longitudinal direction so that the float can be raised and lowered inside the bottom of the guide shaft. At the outer periphery, a plurality of switches electrically connected to the sensor detection unit are formed at regular intervals, and when the switch operates when contacting the magnet formed inside the float, the sensor detection unit transmits them to the control box. Regulation system.