KR102166934B1 - A Powerless Watergate structure - Google Patents

Abstract

The present invention provides an unpowered standing disaster prevention floodgate structure having a function of preventing seawater infiltration. The unpowered standing disaster prevention floodgate structure comprises: a chamber including a seawater inflow space dented downwards on land adjacent to seawater and formed to allow seawater to flow thereinto through an opened open surface by including the open surface in an upper portion thereof, and a drain formed from the seawater inflow space towards land to discharge seawater; a draining opening/closing unit provided in the chamber and linked to a water level in accordance with an amount of inflow seawater to selectively open and close the drain; an opening/closing floodgate unit including a buoyancy body provided on one surface therein to be erected by buoyancy in accordance with the water level of seawater, wherein one side thereof is rotatably coupled to the chamber to open and close the chamber; and a folding guide unit formed in a multi-joint structure having at least one joint to be linked to opening and closing of the opening/closing floodgate unit to be folded or unfolded, wherein both ends thereof are rotatably coupled to the bottom surface of the chamber and the inner surface of the opening/closing floodgate unit.

Description

A powerless watergate structure

The present invention relates to a non-powered standing disaster prevention sluice structure. Specifically, it relates to a hydrological structure that blocks seawater penetration by standing by buoyancy caused by seawater inflow without external power.

The content described in this section merely provides background information on the present invention and does not constitute the prior art.

In general, a tsunami is a natural disaster that causes enormous damage due to its infrequent frequency, and an earthquake occurring in the East Sea among the submarine earthquakes occurring around the Japanese archipelago with a developed seismic zone can have an effect on the Korean peninsula. In Korea, non-structural measures such as tsunami disaster prevention system construction are more effective when considering the frequency of tsunami occurrence and the magnitude of its damage, but in addition to the demand for structural measures, inundation prevention facilities are installed in major ports to prevent damage from tsunami. Is being reviewed and in progress. In addition, in general, it is concentrated in lowlands, and in places such as underground houses, underground shopping centers, and factories in residential areas, there is a concern about flood damage due to torrential rains during the rainy season every year. In particular, due to the nature of Korea's climate, intensive heavy rain is pouring out during the summer flood season (around July to August), causing a lot of inundation damage.In recent years, urbanization developed without detailed urban planning within the basin such as large-scale residential site development and road construction. As there is a concern that unexpected damage may occur due to a large change in the concentration of water due to the increase, etc., preparation for this is urgently required.

Conventionally, there is a technology that blocks the inflow of seawater, interlocks with the operation of a buoyant body according to the inflow of seawater and blocks a sluice gate in order to solve problems such as failure of electronic devices due to seawater and minimize power consumption. However, such a conventional technology simply functions to block the drainage section into which seawater is introduced, and the water level is higher than the height of the drainage section, and thus there is no standing sluice that can prevent seawater from penetrating. When introduced, there is a problem that cannot be prevented.

Therefore, there is a need to develop a comprehensive hydrogate structure having a function of preventing seawater penetration by standing up the sluice gate in connection with the increase in the water level of the internal space as the drainage part is blocked so as to solve the problems of the prior art.

The problem to be solved by the present invention is to provide a comprehensive hydrogate structure having a function of preventing seawater penetration by allowing the sluice gate to rise in connection with the increase in the water level of the internal space as the drainage part is blocked, which compensates for the disadvantages of the prior art mentioned above. To provide.

The present invention includes a seawater inflow space formed to be recessed toward the bottom of the land adjacent to seawater and the upper part is formed to allow seawater to flow into the interior through the open surface, and the land side in the seawater inflow space. A chamber formed toward and including a drain hole through which seawater is discharged; A drain opening/closing unit provided inside the chamber and configured to selectively open and close the drain port in association with a water level according to the amount of seawater introduced; An opening and closing sluice portion including a buoyant body provided on an inner side so that one side is rotatably coupled to the chamber so as to open and close the chamber and to be erected by buoyancy according to the level of seawater; And a folding structure, wherein both ends are rotatably coupled to the inner surface of the opening and closing sluice portion and the lower surface of the chamber, and are formed in a multi-joint structure having at least one joint, and are configured to be unfolded or folded in connection with the opening and closing of the opening and closing sluice gate. It is possible to provide a non-powered standing disaster prevention sluice structure including a guide part.
In the present invention, in the seawater inflow space and the seawater inflow space formed to be recessed toward the bottom in the land adjacent to seawater and formed to allow seawater to flow into the interior through the open surface, the upper part A chamber formed toward the land and including a drain hole through which seawater is discharged; A drain opening/closing unit provided inside the chamber and configured to selectively open and close the drain port in association with a water level according to the amount of seawater introduced; An opening and closing sluice portion including a buoyant body provided on an inner side so that one side is rotatably coupled to the chamber so as to open and close the chamber and to be erected by buoyancy according to the level of seawater; And a folding structure, wherein both ends are rotatably coupled to the inner surface of the opening and closing sluice portion and the lower surface of the chamber, and are formed in a multi-joint structure having at least one joint, and are configured to be unfolded or folded in connection with the opening and closing of the opening and closing sluice gate. Including a guide portion, the chamber is configured with a seawater inlet space two-stage recessed toward the land side, the first layer is provided with the folding guide portion, the second layer, the lowest layer, the drain opening and closing portion installed below the folding guide portion And the drain opening/closing part is configured to close the drain hole when seawater is introduced above the opening/closing water level, which is a preset water level, and the opening/closing sluice section is configured to stand up when the opening/closing water level is higher than the preset standing water level, The drain opening/closing unit includes a floating member that floats as seawater flows in, and an opening/closing control unit configured to move in connection with a floating operation; An opening/closing unit including an opening/closing member capable of opening and closing the drain hole, and connected to the opening/closing control unit and configured to open and close the drain hole by moving in conjunction with the movement of the opening/closing control unit; And an intermediate interlocking member connecting the opening/closing control unit and the opening/closing unit to enable interlocking between the two, wherein the opening/closing control unit includes: a 1-1 first rod rotatably installed at a lower side of the chamber; A floating member provided at one end of the 1-1 rod; A 1-2 rod that is coupled to the other side of the 1-1 rod at a predetermined angle to move in association with the movement of the 1-1 rod; And a first connecting portion provided in a circular ring shape at an end portion of the 1-2 rod, wherein the opening and closing portion includes: a second rod rotatably installed under the chamber; An opening/closing member provided on the second rod and configured to open and close the drain hole according to the movement of the second rod; And a second connecting portion provided at one end of the second rod and having a circular ring shape connected to the first connecting portion, wherein the intermediate interlocking member is movable to the first connecting portion and the second connecting portion, respectively. A flow coupler coupled together; And a connection member having the flow coupler at both ends to connect them, wherein at least a part of the flow coupler is recessed in a circumferential direction into one of the first connector and the second connector. It is possible to provide a non-powered standing disaster prevention sluice structure configured to be movable along the formed arc-shaped rail portion.

Additional solutions of the present invention will be described in part in the description that follows below, and can be partially easily identified from the description, or can be learned by practicing the present invention.

Both the foregoing general description and the following detailed description are illustrative and illustrative only and do not limit the invention described in the claims.

The non-powered standing disaster prevention sluice structure according to an embodiment of the present invention has an advantage of not consuming power since it blocks drainage and erects the sluice gate using buoyancy when it reaches a certain water level.

1 is a perspective view of a non-powered standing disaster prevention sluice structure according to an embodiment of the present invention.
2 is a side view showing the operation of the non-powered standing disaster prevention sluice structure according to an embodiment of the present invention.
3 and 4 are side views showing the operation of the drainage opening and closing of the non-powered standing disaster prevention sluice structure according to an embodiment of the present invention.
5 is a perspective view of a drain opening and closing portion and a bypass drain of the non-powered standing disaster prevention sluice structure according to an embodiment of the present invention.
6 is a side view showing an intermediate interlocking member of the drain opening and closing part of the non-powered standing disaster prevention sluice structure according to an embodiment of the present invention.
7 is a side view showing an intermediate interlocking member of a drain opening and closing portion of a non-powered standing disaster prevention sluice structure according to another embodiment of the present invention.
8 is a plan view showing an intermediate interlocking member of a drain opening and closing part of a non-powered standing disaster prevention sluice structure according to another embodiment of the present invention.

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

However, in describing a specific embodiment of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

The above objects, features and advantages of the present invention will become more apparent through the following detailed description in conjunction with the accompanying drawings. However, in the present invention, various modifications may be made and various embodiments may be included. Hereinafter, specific embodiments will be illustrated in the drawings and described in detail.

If it is determined that a detailed description of known functions or configurations related to the present invention may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. In addition, numbers used in the description process of the present specification are merely identification symbols for distinguishing one component from another component.

In addition, the suffix "unit" for the constituent elements used in the following description is used only to facilitate the writing of the specification or is used interchangeably, and does not itself have a distinct meaning or role.

1 is a perspective view of a non-powered standing disaster prevention sluice structure according to an embodiment of the present invention.

2 is a side view showing the operation of the non-powered standing disaster prevention sluice structure according to an embodiment of the present invention.

1 and 2, a non-powered standing disaster prevention sluice structure 100 according to an embodiment of the present invention includes a chamber (S), an opening/closing sluice gate part 200, a folding guide part 300, and a drain opening/closing part 400 It may include.

The chamber (S) may be formed to be recessed toward the bottom of the land adjacent to seawater and formed to include an open upper open surface. Before the seawater flows into the land, it first flows into the chamber (S), so that it can act as a buffer to mitigate the penetration of seawater into the land. In addition, one inner side of the chamber (S) may include a drain port to allow seawater to be discharged toward the land side, thereby temporarily storing seawater and then configured to discharge the seawater to the land or back through the drainage port.

One side of the opening/closing sluice portion 200 may be rotatably coupled to the chamber so as to open and close the chamber S. The opening and closing sluice unit 200 may be provided with a buoyancy body (not shown) on one surface facing the ocean side. Thereby, when seawater flows in and reaches a standing water level, which is a level sufficient to reach the buoyant body of the opening and closing sluice portion 200, the opening and closing sluice portion 200 may start to stand up by the buoyancy body. Then, as the water level continues to increase, the degree of standing of the opening and closing sluice portion 200 may be increased.

The folding guide unit 300 may have both ends rotatably coupled to the inner side of the opening and closing sluice unit and the lower side of the chamber, respectively. The folding guide part 300 may be provided in a multi-joint structure having at least one joint. In the drawing, the two rods are configured to be connected to one joint, but the number of joints and rods may increase in some cases, and is not limited thereto. The folding guide portion 300 may be configured to be unfolded or folded in conjunction with the opening and closing of the opening and closing water door portion 200.

The drain opening/closing part 400 may be provided inside the chamber and may be configured to selectively open or close the drain opening in connection with the water level according to the amount of seawater introduced. The drain opening/closing unit 400 may start an operation of closing the drain port when seawater flows into the floating member to the extent that it reaches the opening/closing level, which is the level at which seawater reaches the floating member to be described later. When seawater continues to flow above the opening and closing water level, the drain opening and closing part 400 may eventually close the drain opening.
The seawater inflow space into which seawater is introduced is composed of two stages, and the folding guide unit 300 described above is provided in the first tier, and the drainage opening and closing part 400 may be provided in the second tier of the lowest floor below. The seawater inflow space is composed of a two-stage space that is recessed into the land, so that the seawater capacity has a significantly greater advantage compared to the prior art, and a folding guide part 300 and a drainage opening and closing part 400 are arranged vertically in each fault of the seawater inflow space. There is an advantage that more efficient non-powered standing disaster prevention is possible.

Referring to FIG. 2, the drain opening and closing part 400 closes the drain 500 and opens and closes the first state (left) in which the drainage opening 500 is not closed and seawater is above the opening and closing water level and the standing water level. The second state in which the sluice portion 200 is erected (right side) can be compared and identified. As shown in the second state shown on the right, when seawater flows into the chamber S and reaches the opening/closing level, the drain opening/closing part 400 closes the drain 500 so that the seawater is no longer discharged through the drain. Thereafter, when the seawater continues to flow in and reaches the standing water level, the opening/closing sluice door 200 starts to stand up from this point, and may continue to stand up according to the rise in the water level. This can prevent seawater from penetrating into the land.

3 and 4 are side views showing the operation of the drainage opening and closing of the non-powered standing disaster prevention sluice structure according to an embodiment of the present invention.

5 is a perspective view of a drain opening and closing portion and a bypass drain of the non-powered standing disaster prevention sluice structure according to an embodiment of the present invention.

3 and 4, the drain opening/closing part 400 may include an opening/closing control part 410, an opening/closing part 420, and an intermediate interlocking member 430.

The opening/closing control unit 410 may include a floating member 411, a 1-1 rod 412, a 1-2 rod 413, a first connection part 414 and a rod fixing part 415.

The floating member 411 may be provided at one end of the 1-1th rod 412 to be described later. The floating member 411 may be made of a material that can float in seawater by buoyancy.

One side of the 1-1 rod 412 is rotatably installed on the lower side of the chamber S, and the 1-2 rod 413 is coupled to the other side of the 1-1 rod 412 at a predetermined angle. Can be. When the first-first rod 412 is moved, the first-second rod 413 may be configured to be moved in connection therewith.

The first connection 414 may be provided on one side of the 1-2th rod 413 to be connected to the second connection part of the opening/closing part 420 to be described later.

The rod fixing part 415 is installed on the lower side of the chamber S so that the 1-1 rod 412 and the 1-2 rod 413 can be rotated in a fixed state, and the 1-1 rod 412 ) And the 1-2 rod 413 may be connected to each other. The 1-1 rod 412 and the 1-2 rod 413 may be rotated around the rod fixing part 415.

The opening/closing part 420 may be connected by the opening/closing control part 410 and the intermediate interlocking member 430. The opening/closing part 420 may include an opening/closing member 421, a second rod 423, a second connection 424, and a rod fixing part 425.

The opening/closing member 421 may be configured to correspond to the size and shape of the drain port 500 so that the drain port 500 may be closed in some cases. In the drawings, the opening/closing member 421 is shown to have a circular shape or a spherical shape, but is not necessarily limited thereto, and any known type is possible as long as it has a shape and a size capable of closing the drain hole 500.

The second rod 423 has an opening and closing member 421 installed on one side, and one side along the lengthwise direction of the second rod 423 rotates on the rod fixing part 425 installed inside the chamber S to be described later. It can be combined as much as possible.

The second connection part 424 is provided at the other end of the second rod 423 in the longitudinal direction, and may be configured to be connected by the above-described first connection part 414 and the intermediate interlocking member 430.

The rod fixing part 425 may be installed on the inner bottom side of the chamber S, and may support one side of the second rod 423 so that the second rod 423 can be rotated while being fixed.

The intermediate interlocking member 430 may be configured to connect the opening/closing control unit 410 and the opening/closing unit 420 in the middle to move the opening/closing unit 420 according to the movement of the opening/closing control unit 410.

As shown in Fig. 4, when seawater is introduced and seawater is introduced above the opening and closing water level, the floating member 411 rises and the opening/closing control unit 410 starts to rotate in a clockwise direction based on the drawing, and the opening/closing unit 420 is interlocked therewith. Also, by rotating in a clockwise direction based on the drawing, the drain port 500 may start to be closed. When seawater continues to flow in and reaches the water level of the maximum rotational range of the opening/closing control unit 410, the opening/closing control unit 410 is rotated as much as possible in the clockwise direction, and in conjunction with this, the opening/closing unit 420 is also rotated as much as possible to the drain port 500 Can be closed.

When seawater is out of an emergency situation in which the seawater penetrates into the land, at least one of the opening/closing control unit 410 and the opening/closing unit 420 may be moved by applying an artificial external force in the direction in which the drain port 500 is opened to induce drainage.

Referring to FIG. 5, the drain opening/closing part 400 can be identified in three dimensions, and it can be seen that a bypass drain port 600 connected to the drain port 500 is provided on one side.

In some cases, the bypass drain 600 may be opened to bypass seawater when it is necessary to bypass seawater (for reasons such as experiments).

6 is a side view showing an intermediate interlocking member of the drain opening and closing part of the non-powered standing disaster prevention sluice structure according to an embodiment of the present invention.

The intermediate interlocking member 430 may include a connection member 431 and a flow coupler 432.

The connecting member 431 may be provided in the form of a wire having a predetermined rigidity. However, in response to the movement of the opening and closing control unit 410, the opening and closing unit 420 may be configured not to be bent so that it can be moved well. The connection member 431 may also be formed of a rigid body having a predetermined rigidity.

The flow coupler 432 may be provided with a pair at both ends along the length direction of the connection member 431. The pair of flow couplers 432 may be coupled to the first coupling portion 414 and the second coupling portion 424, respectively. The flow coupler 432 is coupled to the first coupling portion 414 and the second coupling portion 424 and may be provided to be fluidly movable on the first coupling portion 414 and the second coupling portion 424 . When the opening/closing control unit 410 and the opening/closing unit 420 are interlocked and rotated, the position of the flow coupler 432 is within a predetermined range so that the opening/closing unit 420 according to the movement of the opening/closing control unit 410 is well interlocked. It can be variable within.

Here, the flow coupler 432 may be configured to move within a predetermined range along the circumference of the first coupling portion 414 and the second coupling portion 424 formed in a ring or ring shape and formed in a ring shape. connect.

7 is a side view showing an intermediate interlocking member of a drain opening and closing portion of a non-powered standing disaster prevention sluice structure according to another embodiment of the present invention.

8 is a plan view showing an intermediate interlocking member of a drain opening and closing part of a non-powered standing disaster prevention sluice structure according to another embodiment of the present invention.

Referring to FIG. 7, a flow coupler 432 according to another embodiment is shown. The first connection part 414 and the second connection part 424 may include rail parts 414a and 424a in which at least a portion of the first connection part 414 and the second connection part 424 are recessed in a circumferential direction.

8 is a plan cross-sectional view of a state in which the first connector 414, the second connector 424, and the intermediate interlocking member 430 are connected.

The flow coupler 432 may be moved within a predetermined range when the opening/closing control unit 410 and the opening/closing unit 420 are interlocked with each other along the first rail part 414a and the second rail part 424a. . The first rail part 414a and the second rail part 424a may be formed to be open toward the outside, but both ends of the open surface in the width direction may not be opened. Accordingly, the flow coupler 432 can be moved without separating from the first rail part 414a and the second rail part 424a. The flow coupler 432 may be formed in a shape and size corresponding to the shape and size of the first rail part 414a and the second rail part 424a.

This embodiment is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the technical field to which the present invention pertains, various modifications and variations of the present embodiment can be made without departing from the essential characteristics of the present invention. It will be possible.

The present embodiment is not intended to limit the technical idea of the present invention, but to explain it, and thus the scope of the present invention is not limited by the present embodiment.

The scope of protection of the present invention should be construed by the claims, and all technical ideas recognized as equivalent or equivalent thereto should be construed as being included in the scope of the present invention.

100: the present invention
200: opening and closing water door part
300: folding guide part
400: drain opening and closing part
500: drain
600: bypass drain

Claims (8)

A seawater inflow space formed to be recessed toward the bottom in the land adjacent to seawater and the upper part including an open open surface to allow seawater to flow into the interior through the open surface, and the seawater inflow space toward the land side. A chamber including a drain port through which seawater is discharged;
A drain opening/closing unit provided inside the chamber and configured to selectively open and close the drain port in association with a water level according to the amount of seawater introduced;
An opening and closing sluice portion including a buoyant body provided on an inner side so that one side is rotatably coupled to the chamber so as to open and close the chamber and to be erected by buoyancy according to the level of seawater; And
A folding guide having both ends rotatably coupled to the inner surface of the opening and closing sluice portion and the bottom surface of the chamber, and formed in a multi-joint structure having at least one joint, and configured to be unfolded or folded in connection with the opening and closing of the sluice gate unit part
Including,
In the chamber, the seawater inflow space is configured to be recessed in two stages toward the land side, and the folding guide part is provided on the first floor, and the drainage opening and closing part installed below the folding guide part is provided on the second floor, which is the lowest layer,
The drain opening and closing part,
It is configured to close the drain hole when seawater is introduced above the opening/closing water level, which is a preset water level, and is configured to erect the opening/closing sluice when the water reaches a preset standing water level higher than the opening/closing level
The drain opening and closing part,
An opening/closing control unit configured to move in association with the floating operation, including a floating member that floats as seawater is introduced;
An opening/closing unit including an opening/closing member capable of opening and closing the drain hole, and connected to the opening/closing control unit and configured to open and close the drain hole by moving in conjunction with the movement of the opening/closing control unit; And
It includes an intermediate interlocking member connecting the opening and closing control unit and the opening and closing unit to enable interlocking of both,
The opening and closing control unit,
A 1-1 rod rotatably installed under the chamber;
A floating member provided at one end of the 1-1 rod;
A 1-2 rod that is coupled to the other side of the 1-1 rod at a predetermined angle to move in association with the movement of the 1-1 rod; And
Including a first connecting portion provided in a circular ring shape at the end of the 1-2 rod,
The opening and closing part,
A second rod rotatably installed under the chamber;
An opening/closing member provided on the second rod and configured to open and close the drain hole according to the movement of the second rod; And
And a second connector provided at one end of the second rod and provided in a circular ring shape connected to the first connector,
The intermediate interlocking member,
A flow coupler that is movably coupled to the first connector and the second connector, respectively; And
It includes a connecting member that connects both by providing the flow coupler at both ends,
The flow coupler,
At least a part along the circumferential direction inside one of the first and second connectors
It is configured to be movable along the arc-shaped rail portion formed in the form of a groove
Non-powered standing disaster prevention hydrogate structure. delete delete delete delete delete delete delete

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