KR20210033441A - Bottom water exclution apparatus for tide embankment - Google Patents

Abstract

The present invention relates to an apparatus for discharging, toward the open sea, the bottom water (99) of a lake and a marsh inside a tide embankment. A discharge outlet (31) is formed in a stop log (30) coupled to the channel of a floodgate (10), and a discharge pipe (40) is connected to an end of the discharge outlet (31) on a side of the lake and the marsh, so that the bottom water (99) is discharged by the differential head between waters on the side of the lake and the marsh and those on a side of the open sea without separate power. Therefore, the apparatus can effectively discharge the bottom water (99) of the lake and the marsh inside the tide embankment without extensive modifications to conventional embankment facilities or extensive replacement of the equipment of the floodgate (10), thereby preventing contamination of the lake and the marsh inside the tide embankment.

Description

Low-floor water exclusion device for seawall appeal {BOTTOM WATER EXCLUTION APPARATUS FOR TIDE EMBANKMENT}

The present invention relates to a device for excluding the bottom water 99 of the inner lake of the seawall to the outer sea side, and a waterproof port 31 is formed in the stop log 30 coupled to the sluice gate 10, and the waterproof port 31 The discharge pipe 40 is connected to the end of the lake side of the lake, so that the bottom water 99 is discharged by the difference in water head between the water area on the lake side and the water area on the outer sea side without additional power.

It is inevitable to form a bottom water 99 that is stagnant by an embankment in the lake inside the seawall, and this bottom water 99 acts as a factor that deteriorates the water quality in the lake.

In particular, as shown in FIG. 1, the low-floor water 99 in the area within the lake where the elevation below the bottom plate portion 21 of the sluice gate 10 is formed is not excluded even by the opening of the sluice gate 10, due to long-term congestion. It causes serious contamination of the bottom water 99 as well as the entire lake.

Various measures have been considered in order to exclude the bottom water (99) of the lake inside the seawall, and a brief description thereof is as follows.

First of all, there is a method of forming a spillway at the lower end of the seawall, which can be considered in the new seawall, but there are problems that are practically difficult to apply to the existing seawall, as well as reducing the stability of the seawall and maintaining the spillway and related opening and closing means. There is a problem that enormous cost is required for management.

In particular, the exclusion of the bottom water 99 from the lake inside the seawall does not have to be carried out at all times, and it is carried out periodically or intermittently when there is a concern about deterioration of water quality.

Thus, it is possible to consider a method of inducing water flow in the lower water by forming a small opening or a water pipe at the lower end of the sluice gate 10, and the related prior art may include Patent No. 1773826.

However, these facilities attached to the sluice gate (10) have a limitation that it is fundamentally impossible to drain the water below the bottom of the sluice gate (10). There is a problem that needs to be renovated, so it cannot be a practical alternative.

Thus, as a method applicable to the existing seawall, a pipeline connecting the bottom of the lake and the open sea is installed on the top of the seawall, and the pipeline is operated to behave as a siphon, or a pump is connected to the pipeline to provide low water (99). ) Can be considered, but this also has a significant problem.

First of all, in the method of configuring the siphon between the bottom of the lake and the open sea, the elevation of the top of the pipeline is inevitably higher than the top of the seawall, so a separate pressurization or suction means must be mobilized at the initial start-up, as well as connecting the bottom of the lake and the open sea. In terms of ships, considerable extensions are inevitable in the pipeline, and in view of the fact that there is a relatively small difference in water level between the head loss and the general seawall operation appeal, and the water level difference between the open seas, it is practically impossible or possible to operate without power. The flow rate cannot be secured.

On the other hand, the method of connecting the pump to the pipeline is substantially the same as suction dredging, and has a serious problem that enormous costs are required in mobilizing and operating equipment.

In view of the above-described problems, the present invention can be applied without major replacement or modification to existing facilities, as well as being devised so that no power is required during the operation process. In this, a waterway crossing the seawall is formed and a sluice gate 10 for opening and closing the waterway is installed, and a coupling part 25 to which the stop log 30 is coupled is formed on the lake side waterway wall 22, and the coupling part ( As the stop log 30 is coupled to the 25), the waterway on the appeal side of the sluice gate 10 is blocked, a waterproof opening 31 penetrating through the stop log 30 is formed, and a discharge pipe ( One end of 40) is connected and an inlet part 41 is formed at the other end of the discharge pipe 40, and the inlet part 41 is seated on the bottom of the lake so that the water level of the lake exceeds the level of the open sea, and the sluice gate 10 In the open state, the bottom water 99 of the lake is discharged to the open sea.

In addition, a valve 50 for opening and closing the discharge pipe 40 is installed between the water outlet 31 of the stop log 30 coupled to the coupling part 25 and the discharge pipe 40. In the coupling part 25, a plurality of stop logs 30 are stacked and combined, and a shaft 51 for opening and closing the valve 50 is mounted on the upper part of the valve 50, and the valve 50 is installed stop The stop log 30 stacked on the upper side of the log 30 has a bracket 37 protruding toward the hoso side, and the bracket 37 has a shaft concentric in a plane with the shaft 51 for opening and closing the valve 50 The shaft 51 of the stop log 30 stacked on the upper side of the stop log 30 on which the valve 50 is installed and the shaft 51 for opening and closing the valve 50 are coupled to be freely rotatable. Doedoe coupled to each other, a tip 53 of a non-circular cross-section and a socket 54 engaged with the tip 53 are formed at the ends of both shafts 51 to be combined.

Through the present invention, it is possible to effectively exclude the bottom water 99 of the lake inside the seawall without a major renovation of the existing seawall facility or a major replacement for the sluice gate 10 facility, thereby preventing contamination of the seawall lake. .

In particular, not only is the device configuration extremely simple, and since no power is required in the operation of the device, it is possible to secure economical efficiency in installation and maintenance.

1 is a representative cross-sectional view of a general seawall sluice channel
2 is an explanatory diagram of a method of installing a stop log for a general seawall sluice channel
Figure 3 is a representative cross-sectional view of a seawall sluice channel to which the present invention is applied
Figure 4 is a plan cross-sectional view of a seawall sluice channel to which the present invention is applied
Figure 5 is a partial cut-away perspective view of an excerpt of a stop log of the present invention
Figure 6 is an explanatory diagram of the stop log installation method of the present invention
7 is a representative cross-sectional view of an embodiment of the present invention to which a valve is applied
8 is an exploded perspective view of the stop log in the embodiment of FIG. 7
9 is a perspective view of an excerpt from an embodiment of the inlet of the present invention
10 is a cross-sectional plan view of an embodiment of the present invention to which a multi-heat discharge pipe is applied
11 is a perspective view of an excerpt from a modified embodiment of the inlet of the present invention

Figure 2 shows a method of using the stop log 30 in the waterway equipped with the sluice gate 10 of a general seawall, as shown in the upper part of the drawing, the stop log 30 at the top of the waterway structure of the sluice gate 10 As shown in the lower part of the drawing, the waterway is closed irrespective of the opening and closing of the sluice gate 10, thereby allowing access to the inside of the waterway during maintenance work of the sluice gate 10 and related facilities. It is done.

The sluice gate 10 mounting waterway illustrated in FIG. 2 is a type mainly applied to the seawall, and the waterway through the body is formed of the bottom plate part 21 and the waterway wall 22, and the sluice gate 10 crossing the waterway is It is installed, and the upper plate part 23 is formed between the two channel walls 22, and a hoist 11 for driving the sluice gate 10 is installed, and the upper surface of the upper plate part 23 is also utilized as a bridge connected to the upper road of the embankment.

As shown in the lower drawing of FIG. 2, the stop log 30, which is a shield plate temporarily closing the waterway, is installed in a manner in which a plurality of stop logs 30 are stacked up and down, and a gantry running on the upper surface of the upper plate 23 It is installed in such a way that the side ends of the stop logs 30 are coupled to the coupling portions 25 of the two channel walls 22 constituting the sluice gate 10 by means of equipment such as a gantry crane.

The coupling portion 25 formed on the waterway wall 22 is composed of a groove or a guide frame type to which the side end portion of the stop log 30 is coupled, and is not shown in the drawing, but as in a normal munbi facility, Rollers for activities may be installed or watertight materials may be installed to ensure watertightness.

The present invention is a device for excluding the seawall lake water 99 configured by utilizing such a stop log 30, and as shown in FIG. 3, the waterproof port 31 is connected to the stop log 30 and the waterproof port 31 in which a perforation is formed. It consists of a discharge pipe 40 and an inlet portion 41 formed at the end of the discharge pipe 40.

That is, in the present invention, as in FIGS. 3 and 4, a waterway crossing the seawall is formed and a sluice door 10 for opening and closing the waterway is installed, and a stop log 30 is coupled to the waterway wall 22 on the lake side. As the coupling portion 25 is formed, the stop log 30 is coupled to the coupling portion 25 so that the waterway on the appeal side of the sluice gate 10 is blocked, and as shown in FIG. 5, passing through the stop log 30 A waterproof port 31 is formed, and one end of the discharge pipe 40 is connected to an end of the water outlet 31, and an inlet part 41 is formed at the other end of the discharge pipe 40, as in FIGS. 3 and 4, The inlet 41 is seated on the bottom of the lake.

Therefore, as shown in FIG. 3, when the water level of the lake exceeds the level of the open sea and the sluice gate 10 is open, the bottom water 99 of the lake is discharged to the open sea. In addition, smooth operation is possible even when the water level difference between Hoso and the open sea is insignificant.

In other words, in the present invention, unlike the prior art of the siphon method described above, the discharge pipe of the low water 99 behaves as an orifice, and no pressure or suction is required during the initial startup as well as the operation process. As long as the water level and the water level of the lake inside the seawall that exceeds the water level and the stop log 30 and the waterproof opening 31 is formed, the low water 99 can be discharged.

On the other hand, Figure 6 illustrates the process of installing the stop log 30 to which the present invention is applied, and mobilization of special equipment is not required for the installation of the stop log 30 to which the present invention is applied, and the discharge pipe 40 is shown in the drawing. Ships such as a barge in which the distal end of the barge is loaded and a crane that pulls the distal end of the discharge pipe 40 are illustrated, but the stop log 30 may be installed in a state in which the discharge pipe 40 is already mounted on the bottom of the lake.

Referring to the situation illustrated in FIG. 6, the multi-layered stop log 30 is sequentially coupled to the coupling portion 25 of the waterway wall 22, but the stop log 30 to which the discharge pipe 40 is connected is located at the bottom. At the same time, the distal ends of the discharge pipe 40 including the inlet part 41 are loaded on the vessel located in the lake, and the stop log 30 is smoothly combined.

3 and 6, it is preferable to apply a flexible pipe capable of free bending as the discharge pipe 40 applied to the present invention, whereby the discharge pipe 40 when the stop log 30 is combined in the waterway In addition to the easy and stable handling of the bottom water (99), it is possible to closely settle the bottom surface of the discharge pipe (40) in the process of discharging the bottom water (99).

When the multi-layer coupling of the stop log 30 is completed, as shown in the middle part of FIG. 6, the inlet part 41 at the end of the discharge pipe 40 is pulled and moved, and when it reaches the desired position, the inlet part ( 41) descend and settle on the bottom of the lake.

The multi-layered combination of the stop log 30 as described above and the proper submersion of the discharge pipe 40 are performed in a state where the sluice gate 10 is closed and the water body inside the waterway and in the lake near the waterway is quiet, as shown in FIG. It is advantageous.

In a state in which the combination of the entire stop log 30 and seating in the correct position of the discharge pipe 40 is completed, as shown in the lower part of FIG. 6, when the sluice gate 10 is opened, the sluice gate 10 and the stop log 30 The water between) is first excluded to the outside sea side, and at the same time, the bottom water 99 in the lake is discharged to the open sea through the discharge pipe 40 and the water channel.

That is, as shown in the lower part of Figs. 3 and 6, the water outlet 31 of the discharge pipe 40 and the stop log 30 behaves as an orifice, while the low water 99 in the lake is in the inlet part 41, the discharge pipe It is discharged to the outside of the stop log 30 through the 40 and the waterproof opening 31, the discharged low water 99 is discharged to the open sea through the waterway of the sluice (10).

The device for removing the low-floor water 99 of the seawall of the present invention is not a facility that is always installed on the seawall or the waterway structure of the sluice gate 10, and is a device that can be freely attached and detached as needed, such as a normal stop log 30, Normally, when operating as a waterway equipped with a general sluice gate (10), but if there is a concern about contamination in the lake due to deposition of the low water (99), the stop log (30) applied to the present invention is combined with the waterway wall (22) in a state in which an appropriate water level condition is established. When the bottom water 99 is excluded by combining with the part 25, and the removal of the bottom water 99 is completed, the stop log 30 applied to the present invention can be separated from the waterway 10 and withdrawn.

On the other hand, Figures 7 and 8 show an embodiment of the present invention to which the valve 50 is applied, the water outlet 31 and the discharge pipe of the stop log 30 coupled to the coupling portion 25 of the water channel wall 22 A valve 50 for opening and closing the discharge pipe 40 is installed between the (40).

Therefore, as shown in FIG. 7, in discharging the bottom water 99 in the lake, the discharge flow rate may be adjusted by opening and closing the discharge pipe 40 as well as adjusting the opening degree of the valve 50. 99) Flexible operation of the exclusion device is possible, and in particular, the opening and closing of the discharge pipe 40 may be usefully utilized in the process of combining and separating the stop log 30.

As shown in FIG. 7, the stop log 30 to which the discharge pipe 40 is connected is mainly located at the lowermost part of the multi-layered stop log 30, so when the valve 50 is mounted on the stop log 30, this It needs to be configured so that it can be operated from the top of the waterway.

Accordingly, in the present invention, as shown in FIGS. 7 and 8, the vertical shaft 51 is installed on each stop log 30, and the shaft 51 of each stop log 30 when the stop log 30 is stacked and coupled. ) Are configured to be interconnected.

That is, as shown in FIG. 7, a plurality of stop logs 30 are stacked and coupled to the coupling portion 25, but as shown in FIG. 8, a shaft 51 for opening and closing the valve 50 on the upper portion of the valve 50 A bracket 37 protruding toward the hoso side is formed on the stop log 30 stacked on the upper side of the stop log 30 on which the valve 50 is installed, and the bracket 37 opens and closes the valve 50. The shaft 51 and the shaft 51 forming concentric in a plane are coupled so as to be freely rotatable.

In addition, as shown in FIG. 8, the shaft 51 of the stop log 30 stacked on the upper side of the stop log 30 on which the valve 50 is installed and the shaft 51 for opening and closing the valve 50 are mutually coupled. , At the ends of both shafts 51 to be coupled, a tip 53 having a non-circular cross-section and a socket 54 engaged with the tip 53 are formed, respectively, of the upper stop log 30. By binding the lower end of the shaft 51 and the upper end of the shaft 51 of the lower stop log 30, the shaft 51 of the entire stop log 30 can be rotated in a single axis in operation.

In the embodiment shown in FIG. 8, a socket 54 is formed on the upper end of the shaft 51 configured in the valve 50, and the socket 54 at the upper and lower ends of the shaft 51 configured in each stop log 30, respectively. And the tip 53 are formed, but on the contrary, the tip 53 may be formed at the upper end of the shaft 51 and the socket 54 may be formed at the lower end.

As shown in FIG. 7, the inlet 41 formed at the end of the discharge pipe 40 of the present invention is an inlet through which the low water 99 flows into the discharge pipe 40, and is stably fixed at the desired position in the lake. In the case of withdrawal, it needs to be configured to enable easy lifting.

In particular, the inlet part 41 and the discharge pipe 40 may cause impact or fluctuation in the process of entering the bottom water 99, and need to be configured to overcome this and maintain a seated state.

Accordingly, in the present invention, as shown in FIG. 9, the inlet part 41 is formed of a heavy material such as concrete, and the inlet part is formed to be enlarged compared to the discharge pipe 40, so that the inlet part 41 is settled and the low water level 99 enters I tried to reduce the impact.

In particular, as shown in FIG. 7, by connecting the buoy 49 to the inlet part 41, the position of the inlet part 41 in the water can be easily identified, and the discharge pipe 40 and the inlet part 41 The lifting and traction of the discharge pipe 40 and the inlet 41 performed during installation and withdrawal were also made to be easily performed.

As shown in FIG. 7, the buoy 49 is connected to the inlet part 41 by a mooring line, and as a mooring line, a stranded wire capable of exerting necessary strength when lifting and traction of the inlet part 41 is applied to the discharge pipe. When lifting and withdrawal of the 40 and the inlet 41, easy equipment wiring work was possible without underwater work.

As shown in FIG. 10, the apparatus for excluding the low-floor lake water 99 of the present invention may eliminate low-floor water 99 in a wide area by configuring a plurality of discharge pipes 40 in a single stop log 30, as shown in FIG. , As shown in FIG. 11, by applying the inlet 41 of a steel structure in which the lower end penetrates the bottom of the lake, the discharge pipe 40 and the inlet 41 can be stably fixed even on the soft ground of the bottom of the lake. .

10: sluice gate
11: Kwon Yang-gi
21: bottom plate
22: waterway wall
23: upper plate
25: coupling part
30: stop log
31: waterproof port
37: bracket
40: discharge pipe
41: inlet
49: buoy
50: valve
51: shaft
53: tip
54: socket
99: low floor water

Claims (2)

In the apparatus for removing the bottom water (99) of the seawall lake,
A waterway crossing the seawall is formed and a sluice gate 10 for opening and closing the waterway is installed, and a coupling part 25 to which the stop log 30 is coupled is formed on the waterway wall 22 on the lake side, and the coupling part 25 As the stop log 30 is coupled to the waterway of the sluice gate 10 is blocked;
A waterproof port 31 penetrating the stop log 30 is formed, and one end of the discharge pipe 40 is connected to the appeal side end of the waterproof port 31, and an inlet part 41 is formed at the other end of the discharge pipe 40;
The inlet part 41 is a seawall lake water elimination device, characterized in that the water level of the lake exceeds the level of the open sea and the water gate (10) is opened, and the low water (99) of the lake is discharged to the open sea. .
The seawall lake water of claim 1, wherein a valve 50 for opening and closing the discharge pipe 40 is installed between the waterproof opening 31 of the stop log 30 and the discharge pipe 40 coupled to the coupling part 25. Exclusion device.

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