KR100358472B1 - Drainage culvert to exclude sediment in front of gates in estuary - Google Patents

Abstract

The present invention is to provide a culvert for soil removal of the river drainage door that can effectively cope with the opening and closing function of the flap gate installed in the drainage gate due to the sediment deposited in front of the drainage door, or to prevent malfunction. The lower end (3) is short in the center and is made of V-shape that is long toward the edge, and has a tubular culvert (1) with only upper and lower ends (2,3), and has a predetermined interval in the inner space of the culvert (1). The main partition (7) is set up and divided into a plurality of sub-drains (8), and the downstream end of the sub-drain (8) is divided into sub-partitions (9) to form a plurality of branch drains (10), branch drains The subflop gate 11 is provided in (10).

Description

Drainage culvert to exclude sediment in front of gates in estuary}

The present invention relates to a sewage removal culvert of a river drainage door that can effectively cope with the opening and closing or preventing malfunction of the flap gate installed in the drainage door due to the soil deposited outside the drainage door.

On the south and west coasts of our country, there are many large and small rivers. Drainage gates are installed in the estuaries where these rivers come into contact with the sea, and gates are installed in the drainage gates to prevent freshwater drainage and seawater inflow. Large drainage gates, such as the Asan rudder, the shoddy pier, and Chunsu Bay, are difficult to open and close depending on manpower or water pressure, so most of them are powered by electric devices, and the small drainage gates are opened by river water with high water levels at low tide. The city is a flap gate, a so-called self-opening and closed door gate closed by sea water pressure reversed to superior water level, and the upper side is hingedly installed on the pit of the drain.

However, depending on the regional characteristics of the river, there may be a situation where the flap gate cannot be opened because soil is accumulated outside the drainage gate, especially in front of the gate. If the automatic opening / closing doors are not opened in time due to the soil piled up outside the drainage gate during the flooding, the farmland, low-lying houses, vinyl houses, barns, and agricultural facilities can cause severe flooding damage. It is necessary to prepare.

Soils that have been deposited in front of drainage ditches or drainage gates have been mainly used to forcibly open automatic gates by dredging or hoisting special equipment. However, this method is not only costly, but also unable to cope with untimely flooding in a timely manner. Therefore, the necessity of the sediment removal method to prevent the deterioration of the automatic gate opening due to the sediment is emerging.

The present invention is to provide a sewage removal culvert of the river drain can be removed at a low cost and very efficiently without the sediment removal work or equipment mobilization of the automatic opening and closing gate due to the sediment of the drain.

The present invention is installed at the bottom of the drainage door, the downstream end is made of V-shaped shorter in the middle and longer toward the edge of the tubular culvert, open only the upper and lower ends, the main space of the culvert at a predetermined interval A partition is divided into a plurality of sub-drains, and the downstream end of the sub-drain is divided into sub-dividers to provide a plurality of branch drains, and branch drains provide a sewage removal culvert for a river drain having a subflop gate. .

The present invention also provides a culvert for soil removal of a river drain that facilitates the flow of the river bottom water drained to the sub-drain by causing the culvert to gradient from the upstream end to the downstream end.

1 is a partial cutaway plan view of a state in which the soil removal culvert of the present invention is installed on the bottom of the drain hole

2 is a cross-sectional view taken along the line I-I of FIG.

3 is a view seen from the direction "D" of FIG.

Figure 4 is a construction example of the present invention Figure 5 is a structural diagram of the sub-flop gate installed at the end of the branch drain

<Explanation of symbols for the main parts of the drawings>

1: (for soil removal) culvert 2: upstream

3: downstream 4: upper surface

5: bottom 7: main partition

8: sub-drain 9: sub-division

10: branch drain 11: buple gate

In Fig. 1, except for the upstream end 2 and the downstream end 3, the soil removal culvert 1 has a tubular shape in which the upper surface 4, the bottom surface 5, and the side surface 6 are covered with a slab. The height of 1) is determined based on the maximum deposition. The lower the culvert 1, the faster the flow rate of the river water to be drained, the greater the removal effect of the sediment. Therefore, it is desirable to lower the height of the culvert 1 as much as possible in consideration of on-site investigation of the river and reduction of sediment deposition after completion.

The surfaces of the upper surface 4 and the lower surface 5 of the culvert 1 are formed to be as smooth as possible to provide smooth water flow. And, as shown in Figure 2, the culvert 1 is a lower end 3 is gradientd lower than the upstream end 2 to facilitate more water flow and increase the flow rate.

Further, the downstream end 3 of the culvert 1 has a V-shape which is short in the center and gradually longer toward the edge. This is derived from consideration to increase the likelihood of sediment removal along the ditches by inducing the sewage into the stronger stream towards the edge of the ditches where sediment is likely to be deposited when the stream is drained. .

In the space between the upper surface 4 and the lower surface 5, a long main partition 7 extending from the upstream end 2 to the downstream end 3 at regular intervals is raised to increase the stress on deformation and breakdown, and at the same time, Secure the secondary drain (8).

The downstream end of each sub-drain 8 is further subdivided into several short sub-divisions 9 to form branch drains 10. In this way, the strength of the sub-drain 8 to be received due to the drainage pressure of the stream water drained to the branch drain 10 and the load due to the water flow at the downstream end 3 is increased, and the water flow is also thinned, as if high-pressure water is injected from the nozzle. This drainage increases the removal pressure on the deposited soil.

All the sub-drains 8 are provided at the downstream end thereof with a small sub-flap gate 11 that fits therein to open and close the branch drain 10 individually. The baffle gate 11 prevents the river water flowing into the branch drain 10 or the river water outside the branch drain 10 from flowing back to the branch drain 10, and is opened by the water flowing into the branch drain 10 and branched. When the water pressure outside the drain port 10 overwhelms the water pressure therein, it is a hinged doormat or an elastic rubber plate door that is pushed and closed by the water pressure. The subflap gate 1 may be installed as a single door to be shared by a plurality of branch drains 10 bound to each of the sub drains 8. FIG. 5 illustrates the case of the gate-type subflap gate 11 made of elastic rubber sheet.

In addition, the upper surface (4) of the upstream end (2) is covered as shown in A of Figure 1 or peeled off altogether like B so that the river water flows more smoothly into the sub-drain (8).

In FIG. 4, when constructing a drainage door a in an estuary, the bottom foundation 6 for the culvert 1 has the same elevation, including the occupied area of the culvert 1 and the V-shaped margin of the downstream end 3. Pour curing.

In the natural ground topography, in general, the middle of the bottom of the drainage channel has deep valleys, so the drainage is concentrated there. In order to suppress the sedimentation of the drainage path, it is important to exclude the water flow biasing, so that the concrete is poured into the V-shaped section of the downstream end 3 at the same elevation to flatten it. When the bottom is adjusted evenly, the flow of water drained through the culvert 1 is not concentrated to any one place, and the overall flow of water appears.

The culvert 1 is installed on the bottom foundation 6. The culvert 1 may be constructed on-site, but may be divided and fabricated by various operations as a block in a factory and transported to a construction site to be fixed on the ground foundation 6.

One change is possible here. For example, in any method of construction, once the culvert 1 is installed, a drainage door a is installed above the upstream end 2, and a concrete drifting wall 12 is installed at the inflow portion of the stream where the upstream end 2 is connected. Stand up. The dike wall 12 is for preventing or preventing the river water flowing toward the drainage door a from being concentrated in the center. The conditions such as length and installation angle are determined according to the local conditions of the river. In some cases, the dividing wall 12 is divided into a long dividing wall 12a and a short dividing wall 12b, and the long dividing wall 12a is installed at a position slightly inward from the edge of the stream water inlet, so that the inflow water is formed at the edge. The short drip wall 12b is connected to the main partition 7a of the bare side drainage port 8a so that the water guided by the long drip wall 12a is returned to the farmost edge drain 8a. To drive the drainage to the strongest waterways with high potential for sediment deposition. The length, number, and installation angles of the dike walls 12 are set to be suitable for the drainage conditions of local rivers.

Alternatively, when the culvert 1 is installed under the existing drain door a, the flap gate is removed to cut off the lower end portion corresponding to the height of the culvert 1 from the bottom of the drain hole b of each drain port a. , Insert the culvert unit made to have a width equal to the width of the drain hole (b) for each drain hole (b) and fill it with mortar to ensure watertightness, and then proceed to re-install the reduced doors.

Another way to install the culvert (1) under the existing drain (a) is to support the stanchion to stabilize the existing drain door (a) so that it does not collapse or break, and in this state the floor is grounded (6) and culvert Excavation to the depth in consideration of the thickness of (1) to pour the bottom foundation (6), and then after the culvert (1) is installed, the holding neck is removed, or even after the ditch wall 12 is installed to remove the holding wood.

At low tide, when the water surface falls below the upper surface (2) of the culvert (1) and reaches the point where the water pressure of the river water can no longer be overcome, the buplap gate (11) has a secondary drain (8) and a branch drain (10). When the water flows into the river, the water flows out of the air, leaving the water.

In this way, in the lower water drained by the sub-drain 8, the water flowing out to the outer branch drain 10 of the edge side sub-drain 8a is the strongest. And this stream flows along the drainage path. Therefore, if there is sediment along the drainage road, it will be washed away in such a strong stream, and if it is washed out in the stream, it will also be carried to the shore. Thus, the soil is deposited before the flap gates of the drains, especially in the drains, which are located along the drains, making them safe from damage caused by the opening and closing.

The present invention as described above can prevent the sediment deposited in front of the drainage door, in particular in front of the side of the drainage drainage gate with high possibility of sedimentation by utilizing the lower water flowing out to the drainage door as a pressure means, and the sediment deposited therein is also strong As a culvert for drainage doors configured to be removed, the opening and closing function of the drainage door can be effectively prevented from being lost or lost due to sedimentary sediment on the drainage path.

Moreover, this soil removal type culvert is very economical because there is no reason to incur soil removal costs other than the initial installation and maintenance costs, and there is no risk involved in the removal work of sedimentary soil.

Claims (2)

The downstream end (3) below the drainage port (a) has a V shape shorter in the middle and longer toward the edge and has a tubular culvert (1) with only the upper and lower ends (2,3) open. In the inner space, a main partition 7 is formed at predetermined intervals and divided into a plurality of sub-drains 8, and the inside of the downstream end of the sub-drain 8 is divided into sub-parts 9 to divide a plurality of branch drains 10. And a subflop gate (11) provided in the branch drain port (10). The sewage removal culvert of claim 1 wherein said culvert (1) is drained from an upstream end (2) to a downstream end (3).