KR101041836B1 - An apparatus for water-inflowing using a diversion dam - Google Patents

Abstract

Disclosed is a seawater inflow device using a moon flow agent. The present invention can continuously maximize the amount of sea water imported from the outer port by the moon flow system, and can be applied even in areas where there is a large difference in tide. This seawater inflow device is located between the inner port and the outer port to distinguish the inner port and the outer port, and the structure 100 is provided with a water passage 110 for moving the seawater of the outer port into the inner port; And a monthly flow agent 500 installed on the outer port side to maintain a distance from the structure 100 to form a water reservoir 510 between the structure 100, and As the water level of the water reservoir 510 rises as the water level of the water reservoir 510 rises beyond the flow agent 500 and flows into the water reservoir 510, the water level of the water reservoir 510 where the water level rises is naturally the water passage 110. It is characterized by flowing into the inner port through. According to such a seawater inflow device, a large amount of seawater in the reservoir is stably and continuously flowing into the inland port due to the difference in the water level between the reservoir and the inland port, as the waves in the outer port break through and overwhelm the overcurrent system. By installing a means for varying the height of the wave over the Wolyu system, the height of the wave varies depending on the tide of the outer port or the bay, so that the seawater in the outer port can be stably and continuously introduced even in areas where there is a large difference in tide.

Description

Seawater inflow device using moon flow agent {AN APPARATUS FOR WATER-INFLOWING USING A DIVERSION DAM}

The present invention relates to a seawater inflow device using a moon flow agent, and more specifically, a breakwater in the open sea outside the breakwater by selectively adjusting the height of the seawater flow according to the height of the sea level so that it can be installed even in areas where tidal differences exist. The present invention relates to a seawater inflow device using a moon flow agent to maximize the inflow of seawater flowing into the inner sea.

Recently, due to the construction of the breakwater at the port, the seawater in the outer port and the inner port of the port are not distributed to each other and cannot be exchanged, causing the seawater in the port to become increasingly polluted and rotten. The port has not flowed and has settled in the port, and the port loses its self-cleaning ability, accelerating pollution of water and soil, making the port sick.

This problem occurred because the breakwater, which is an outward facility of the port, was designed only for the purpose of preventing the invading waves from the open sea and maintaining the calm temperature in the port.

Therefore, it is urgent to improve the communication and exchange of seawater in the installation of a breakwater in the port because the breakwater caused by the construction of the port not only hinders the natural activity of seawater by tidal and tidal currents, but also reduces the amount of oxygen present in the harbor water. .

In order to solve this problem, breakwaters capable of introducing seawater in various structures have been developed.

In particular, Figure 1 is a cross-sectional view showing the structure of a conventional seawater inflow breakwater.

As shown in these Figure 1, the conventional seawater inflow breakwater 10 is a mound 40, an upper concrete 30 installed on the upper surface of the mound 40, a tetrapod installed in the front portion of the mound 40 (T), it is composed of a water passage 20 provided on the lower side of the upper concrete (30).

The breakwater 10 of this structure, when the wave height is high, the seawater of the outer port flowed into the inner port through the water passage 20. Therefore, the water quality of the inner port could be improved by introducing clean seawater from the outer port into the inner port.

 By the way, in the conventional seawater inflow breakwater 10, when the water passageway 20 is submerged, many of the seawater flowing into the inner port comes out again through the water passageway 20 to the outward port, and the waterway passage 20 When is higher than the water surface, the seawater in the outer port did not flow well into the inner port. As described above, the seawater inflow breakwater 10 according to the related art has a problem in that clean seawater from the outer port cannot continuously flow into the inner port.

The technical problem of the present invention is to provide a seawater inflow means that allows a stable and large amount of seawater from an outer port to continuously flow into the inner port.

Another technical problem of the present invention is interlocked with the difference between the tides in the coastal area where there is a large difference in tidal current, and clean seawater from the outer port can continuously flow into the inner port, and a seawater inflow means that can maximize the inflow of seawater. To provide. to provide.

The technical problems to be achieved by the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned can be clearly understood by those skilled in the art from the following description. There will be.

The technical problem, according to the present invention, located between the inner port and the outer port to distinguish the inner port and the outer port, a structure made of a quay wall or a breakwater provided with a water passage for moving the seawater of the outer port to the inner port; And
Includes; is installed on the outer port by maintaining a distance from the structure to form a resin between the structure arcuate, semi-circular, elliptical, polygonal form formed of any one of the selected;
As the waves of the outer port break through and flow into the water reservoir beyond the above-mentioned overflow system, the water level of the water reservoir rises and the water level difference with the inner port occurs, so that the water level of the water reservoir with the increased water level flows into the inner port through the water passage,
In the overcurrent system, by varying the height of the wave over which the wave overtakes according to the tide of the open sea, the tide of the oversea and the wave height over which the wave overtakes coincide, thereby increasing the amount of seawater flowing into the inland port. Equipped with at least one means for varying the height of the moon to maximize the amount,
The moon height variable means,
An arc-shaped receiving groove concavely recessed from one side of the upper surface of the overflowing agent to the side of the reservoir;
It has an arcuate wave-shaped wave shaped part formed in an arc shape so that the side cross-sectional shape is curved, and an axis portion provided in the center point region of the wave-shaped part, and the curved convex curved surface of the wave-shaped part is in the receiving groove so as to face the open sea or outward port. Wall height forming plate to be seated;
An airtight maintenance means installed between the wall portion and the receiving groove so that seawater does not flow between the arc-shaped portion and the arc-shaped receiving groove;
A tower installed on the overflow agent and the shaft portion is rotatably coupled; And
The wall wave height forming plate is rotated around the shaft so that the height of the wall wave height forming plate is variable according to the tide level of the open sea, and the wall wave portion of the arc-shaped wave is along the receiving groove of the arc shape. It is achieved by a seawater inflow device using a moon flow agent characterized in that it consists of a driving device to be raised or protruded or lowered toward the upper side of the housing to be accommodated in the receiving groove to selectively vary.
In addition, a water passage installed on the land between the outer sea or the bay and the inner port of an area adjacent to the inner port so that the sea water of the outer sea or the bay moves to the inner port; And
It is installed on the open sea or bay side by maintaining a distance from the entrance side of the water passage, and includes a surplus agent formed in any one shape selected from arc, semicircular, elliptical, polygonal to form a water reservoir between the water passage entrance. So,
As the waves of the open sea or the bay break, the water level of the reservoir rises as the water flows over the moon-flow system and flows into the reservoir, so that the water level of the reservoir rises to the inner port through the passageway,
In the overcurrent system, by varying the height of the wave over which the wave overtakes according to the tide of the open sea, the tide of the oversea and the wave height over which the wave overtakes coincide, thereby increasing the amount of seawater flowing into the inland port. Equipped with at least one means for varying the height of the moon to maximize the amount,
The moon height variable means,
An arc-shaped receiving groove concavely recessed from one side of the upper surface of the overflowing agent to the side of the reservoir;
It has an arcuate wave-shaped wave shaped part formed in an arc shape so that the side cross-sectional shape is curved, and an axis portion provided in the center point region of the wave-shaped part, and the curved convex curved surface of the wave-shaped part is in the receiving groove so as to face the open sea or outward port. Wall height forming plate to be seated;
An airtight maintenance means installed between the wall portion and the receiving groove so that seawater does not flow between the arc-shaped portion and the arc-shaped receiving groove;
A tower installed on the overflow agent and the shaft portion is rotatably coupled; And
The wall wave height forming plate is rotated around the shaft so that the height of the wall wave height forming plate is variable according to the tide level of the open sea, and the wall wave portion of the arc-shaped wave is along the receiving groove of the arc shape. It is achieved by a seawater inflow device using a moon flow agent characterized in that it consists of a driving device to be raised or protruded or lowered toward the upper side of the housing to be accommodated in the receiving groove to selectively vary.
At this time, the driving device,
It is installed on the top of the tower, a hoist for driving the rotating shaft; And
One end is fixed to the wall height forming plate, the other end is wound on the rotating shaft to rotate the wall height forming plate in the forward or reverse rotation of the hoisting machine in the forward or reverse direction to vary the protrusion height of the wall height forming plate. It can be made of wire.
The driving device according to another embodiment,
A hydraulic generator installed on the ground or a tower to generate hydraulic pressure; And
One end is axially coupled to the wall height forming plate, the other end is axially coupled to the tower, and is tensioned/contracted by the hydraulic generator, thereby rotating the wall height forming plate in the forward or reverse direction to rotate the wall height forming plate. It may be made of a hydraulic cylinder that changes the protruding height.
The driving device according to another embodiment,
A hydraulic generator installed on the ground or a tower to generate hydraulic pressure;
One end is composed of a first link member that is axially coupled to the wall height forming plate, and one end is composed of a second link member that is axially coupled to the tower, and each other end of the first and second link members is axially coupled. Link member; And
One end is axially coupled to the second link member, and the other end is axially coupled to the tower to operate the link member while being tensioned/contracted by the hydraulic generator so that the wall height forming plate is rotated in the forward or reverse direction. It may be made of a hydraulic cylinder that changes the protruding height of the wall height forming plate.
On the other hand, the above technical problem is located between the inner port and the outer port to distinguish the inner port and the outer port, and a structure made of a quay wall or a breakwater provided with a water passage for moving the seawater of the outer port to the inner port; And
Includes; is installed on the outer port by maintaining a distance from the structure to form a resin between the structure arcuate, semi-circular, elliptical, polygonal form formed of any one of the selected;
As the waves of the outer port break through and flow into the water reservoir beyond the above-mentioned overflow system, the water level of the water reservoir rises and the water level difference with the inner port occurs, so that the water level of the water reservoir with the increased water level flows into the inner port through the water passage,
In the overcurrent system, by varying the height of the wave over which the wave overtakes according to the tide of the open sea, the tide of the oversea and the wave height over which the wave overtakes coincide, thereby increasing the amount of seawater flowing into the inland port. Equipped with at least one means for varying the height of the moon to maximize the amount,
The moon height variable means,
Each inclined guide groove formed in the structure for the forming plate provided on the upper surface of the overcurrent agent;
A wave height forming plate consisting of a wave wave passing wave and an operation portion that is formed to be provided with screw holes at both ends of the wave wave portion and is movably inserted into each of the inclined guide grooves to be inclined toward the outward side. ; And
A rotating screw rod screwed to the operating portion and rotatably installed inside the inclined guide groove, and an operating portion coupled to the rotating screw rod by rotating the rotating screw rod forward and backward along the longitudinal direction of the inclined guide groove. It can be achieved by a seawater inflow device using a moon flow agent, characterized in that it comprises a driving device made of a driving member for varying the protruding height of the wave height forming plate to be raised and lowered.
At this time, on the front surface of the moon wave height forming plate, the middle portion of one side toward the offshore side is convexly projected toward the offshore side so that the load height distribution plate is not deformed by the wave force and the load is distributed to both sides. .
On the other hand, the above technical problem is located between the inner port and the outer port to distinguish the inner port and the outer port, and a structure made of a quay wall or a breakwater provided with a water passage for moving the seawater of the outer port to the inner port; And
Includes; is installed on the outer port by maintaining a distance from the structure to form a resin between the structure arcuate, semi-circular, elliptical, polygonal form formed of any one of the selected;
As the waves of the outer port break through and flow into the water reservoir beyond the above-mentioned overflow system, the water level of the water reservoir rises and the water level difference with the inner port occurs, so that the water level of the water reservoir with the increased water level flows into the inner port through the water passage,
In the overcurrent system, by varying the height of the wave over which the wave overtakes according to the tide of the open sea, the tide of the oversea and the wave height over which the wave overtakes coincide, thereby increasing the amount of seawater flowing into the inland port. Equipped with at least one means for varying the height of the moon to maximize the amount,
The moon height variable means,
A structure for a forming plate provided on the upper surface of the overcurrent agent;
It is formed in a circular arc shape curved in the upper and lower directions so that the wave breaks through, and one end is coupled axially to the wave section and the other end is rotatably coupled axially to the structure for the forming plate as a forming plate support member. Consisting of a wave height forming plate; And
One end is rotatably coupled to the structure for the forming plate, the other end is axially coupled to the wave portion, and tension/contraction by a hydraulic generator causes the wave height forming plate to be centered around the rotation axis of the plate supporting member, It can be achieved by a seawater inflow device using a moon flow agent characterized in that it comprises a driving device made of a hydraulic cylinder to vary the height of the wall height forming plate to be rotated to the bottom.
In addition, the above-described technical problem is located between the inner port and the outer port to distinguish the inner port and the outer port, and a structure made of a quay wall or a breakwater provided with a water passage for moving seawater from the outer port to the inner port; And
Includes; is installed on the outer port by maintaining a distance from the structure to form a resin between the structure arcuate, semi-circular, elliptical, polygonal form formed of any one of the selected;
As the waves of the outer port break through and flow into the water reservoir beyond the above-mentioned overflow system, the water level of the water reservoir rises and the water level difference with the inner port occurs, so that the water level of the water reservoir with the increased water level flows into the inner port through the water passage,
In the overcurrent system, by varying the height of the wave over which the wave overtakes according to the tide of the open sea, the tide of the oversea and the wave height over which the wave overtakes coincide, thereby increasing the amount of seawater flowing into the inland port. Equipped with at least one means for varying the height of the moon to maximize the amount,
The moon height variable means,
A structure for forming plates provided on both sides of the upper surface of the overcurrent agent and having guide grooves formed on opposite sides;
It is provided slidably installed in the guide groove provided with a wave overhanging wave, and the middle portion of one side facing the open sea side is convex toward the open sea side so that the load is distributed to both sides without being deformed by the wave force on the front side facing the open sea or outward sea. A wall height forming plate that protrudes to form a curved portion;
A link member consisting of a fifth link member, one end of which is axially coupled to the upper portion of the wall wave part, and a sixth link member which is axially coupled to the fifth link member, and the other end of which is axially coupled to the structure for the forming plate. Wow, one end is axially coupled to the structure for the forming plate, and the other end is axially coupled to one side of the sixth link member to operate the link member in tension/contraction to selectively vary the height of the wall height forming plate. It can be achieved by a seawater inflow device using a moon flow agent, characterized in that it comprises a driving device made of a hydraulic cylinder for.
In addition, the driving device, a tide detection sensor for detecting the tide level of the open sea; And
Automatic control of the driving device so that the height of the wall height forming plate matches the level of the open sea by receiving and comparing the tide detection signal and the height detection signal from the wall height forming plate detection sensor that senses the height of the wall height forming plate. It may be configured by further comprising a control unit.

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

delete

And, the present invention for solving the above-described technical problems provides the following means.

That is, a) a step of installing a water passage for allowing the seawater of the outer port or the bay to flow into the inner port of any one selected from a quay wall, a breakwater, and a land separating the outer or bay from the inner port; And

b) Install an overcurrent system to allow the seawater of the reservoir to flow naturally into the inner port by forming a reservoir where the waves (seawater) of the outer port or bay are overwhelmed and stored in the outer port or bay area of the classification means. It provides a seawater inflow method using a moon flow agent characterized in that consisting of a step.

At this time, step b),

b-1) When the wave of the outer port or bay overtakes the overcurrent agent, the wall height variable means for increasing the amount of seawater flowing into the reservoir by varying the height of the overcurrent agent according to the tide level of the outer port or bay The method further includes a step of installing on the flow agent.

Step b-1) is,

b-2) a step of installing a wall-wave height forming plate for determining the wall-wave height on the forming plate structure so as to be erected or laid down by sliding or lowering the lower wall as an axis; And

b-3) Sliding the wall height forming plate installed on the forming plate structure up or down, or acting to stand or lay down the lower part as an axis to install driving means for varying the wave height, on the forming plate structure Further comprising steps.

According to the seawater inflow apparatus and method using the overflow agent according to the present invention, by installing a water passage in a structure such as a breakwater that separates the outer and inner ports, and then installing a water flow agent for forming a water reservoir at the entrance side of the water passage , As the waves of the outer port break through and overwhelm the overflowing agent and are accommodated in the reservoir, the seawater in the reservoir can naturally flow into the inner port due to the difference between the reservoir and the inner port. do.

On the other hand, by installing a means capable of varying the height of the wave at the overcurrent system that the waves overwhelm, the height of the wave height forming plate is changed according to the tide of the outer port or the bay so that the height of the wave is interlocked with the tide, so that the difference between tides is severe Even in the sea, it is possible to stably and continuously introduce seawater from an external port or bay, and to provide an effect of maximizing the amount of inflow.

1 is a schematic cross-sectional view showing the structure of a conventional seawater inflow breakwater.
Figure 2 is a schematic cross-sectional view showing a seawater inflow apparatus according to the present invention.
3 is a schematic plan view showing a state in which the seawater inflow device shown in FIG. 2 is applied to an area where land is located between an outer port and an inner port.
Figure 4 is a schematic cross-sectional view showing a seawater inflow device using a moon flow agent according to a first embodiment of the present invention.
Figure 5 is a schematic front view showing a seawater inflow device using the moon flow agent shown in Figure 4;
Figure 6 is a graph of the numerical value of the inflow of sea water according to the height and tide level of the moon flow.
7 is a schematic cross-sectional view showing a seawater inflow device using a moon flow agent according to a second embodiment of the present invention.
8 is a schematic cross-sectional view showing a seawater inflow device using a moon flow agent according to a third embodiment of the present invention.
9A, 9B, and 9C are schematic cross-sectional views, plan cross-sectional views, and partial perspective views showing a seawater inflow device using a moon flow agent according to a fourth embodiment of the present invention.
10A and 10B are schematic cross-sectional and perspective views showing a seawater inflow device using a moon flow agent according to a fifth embodiment of the present invention.
11 is a schematic cross-sectional view showing a seawater inflow device using a moon flow agent according to a sixth embodiment of the present invention.
12 is a schematic cross-sectional view showing a seawater inflow device using a moon flow agent according to a seventh embodiment of the present invention.
13 is a schematic cross-sectional view showing a seawater inflow device using a moon flow agent according to an eighth embodiment of the present invention.
14 is a schematic cross-sectional view showing a seawater inflow device using a moon flow agent according to a ninth embodiment of the present invention.
15 is a schematic cross-sectional view showing a seawater inflow device using a moon flow agent according to a tenth embodiment of the present invention.
16 is a schematic cross-sectional view showing a seawater inflow device using a moon flow agent according to an eleventh embodiment of the present invention.
17 is a schematic diagram schematically showing the configuration of an automatic water gate control system.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in describing the present invention, descriptions of already known functions or configurations will be omitted to clarify the gist of the present invention.

Of the accompanying drawings, FIG. 2 is a schematic cross-sectional view showing a seawater inflow device according to the present invention, and FIG. 3 is a schematic plan view showing a state in which the seawater inflow device shown in FIG. 2 is applied to an area where land is located between an outer port and an inner port 4 is a schematic cross-sectional view showing a seawater inflow device using a moon flow agent according to a first embodiment of the present invention. In addition, FIG. 5 is a schematic front view showing a seawater inflow device using the overflowing agent illustrated in FIG. 4, and FIG. 6 is a graph showing a numerical value of the inflow of seawater according to the height and tide level of the overflowing agent.

Hereinafter, with reference to FIGS. 2 to 6 of the accompanying drawings, the seawater inflow device using the moon flow agent according to the present invention will be described in more detail as follows.

As shown in Figure 2, the seawater inflow device using the moon flow agent according to the present invention is located between the inner port and the outer port to distinguish the inner port and the outer port, and the water passage 110 for moving seawater from the outer port into the inner port The structure 100 is provided, and is installed on the outer port side to maintain a distance from the structure 100, and includes a monthly agent 500 for forming a reservoir 510 between the structure 100. Since the structure or shape of the structure 100 such as a breakwater provided with the water passage 110 is already known, a detailed description is omitted, and the present invention can be applied to any structure of the structure 100 having the water passage 110. It is not limited to shape.

At this time, the structure 100 is made of a quay wall or a breakwater.

In addition, a plurality of tetrapods or concrete blocks (T) are installed on the inlet side of the water passage 110 or the outer port side of the overflow agent 500. This tetrapod or concrete block (T) is intended to prevent the wave force from directly acting on the overflowing agent 500 or the structure 100 and damaging the overflowing agent 500 or the structure 100. It also has the ability to break up, so that a large amount of oxygen is included in seawater.

On the other hand, an inclined induction plane is formed on the outer side of the overcurrent agent 500 to facilitate the over-wave of the waves. The waves of the outer port smoothly pass the overcurrent agent 500 along the inclined guideway.

It is preferable to make the height of the overcurrent agent 500 coincide with the tide level of the outer port or the average level of the outer port. This is because the highest amount of seawater can flow into the reservoir 510 when the height of the moon flow agent 500 coincides with the tide level of the outer port. That is, if the height of the overcurrent agent 500 is lower than the tide level of the outer port, the seawater flowing into the reservoir 510 is moved back to the outer port, and if the height of the overcurrent agent 500 is higher than the tide level of the outer port, the waves of the outgoing port are The overflow of the seawater (500) does not pass smoothly, reducing the inflow of seawater. Therefore, it is preferable that the height of the overcurrent agent 500 is equal to the tide level of the outer port.

Hereinafter, the height of the wave (H) is the height of the overcurrent agent 500 that can smoothly pass the waves of the outer port or the height of the structure provided in the overcurrent agent 500. That is, the height of the wave height (H) means the floor height of the overcurrent agent 500. In addition, it means the height of the upper end of the moon wave height forming plate (a type of water gate) provided in the moon flow agent 500 and the height is variable.

On the other hand, the overflow agent 500 forming the reservoir 510 may be formed in any one or more shapes selected from a circular shape, a semicircle shape, an oval shape, and a polygonal shape. That is, the planar shape of the overcurrent agent 500 is not limited to any one, and can form a reservoir 510 between the structure 100, effectively disperse wave power, and a large amount of seawater ( 510). In addition, since the two-sided agent 500 having various shapes is in contact with the structure 100, both sides of the overflow agent 500 are formed with a reservoir 510, which is a closed space between the monthly agent 500 and the structure 100.

In addition, the overflow agent 500 applied to the present application is made of concrete and installed, but is not limited thereto, and if it is a shape or structure capable of forming a reservoir 510 between the structure 100 and the material or structure, Unconstrained

The operation of the present invention configured as described above is as follows.

First, a process for introducing seawater through the present invention is as follows.

A water passageway 110 for installing the seawater of the outer port or the bay to the inner port is installed on any one of the separating means selected from the quay wall, breakwater, and land separating the outer port or the bay and the inner port. At this time, the dividing means may be a structure 100, such as a quay wall or a breakwater, or may be a land.

Subsequently, in the outer port or bay area of the separating means, the seawater of the outer port or bay is overwhelmed to form a reservoir 510 that is stored, so that the seawater of the reservoir 510 naturally flows into the inner port due to the difference between the reservoir 510 and the inner port. Install the overcurrent agent 500 for.

As shown in FIG. 2, when a wave is generated from the outer port in the state where the water reservoir 510 is formed by the inlet-side overflow agent 500 of the water passage 110, the wave is installed at the same height as the tide of the outer port. You will pass (500). Since the waves that have passed are trapped by flowing into the reservoir 510, the water level of the reservoir 510 rises.

This is because the waves of the outer port pass through the overflowing agent 500 and flows into the reservoir 510 and then flows back to the outward side. will be.

When the water level of the water reservoir 510 rises through this process, a water head difference occurs between the water surface of the water reservoir 510 and the water surface of the inner port, and thus, the sea water of the water reservoir 510 naturally goes to the inner port through the water passage 110. It will flow. That is, since the water level of the water reservoir 510 is higher than the water level of the inner port, the sea water of the water reservoir 510 naturally flows toward the inner port side.

As such, when the overcurrent agent 500 is installed on the outer port side of the structure 100, a large amount of seawater flows into the reservoir 510 continuously because the waves of the outer port overwhelm the overcurrent agent 500.

At this time, the wave that flows into the reservoir 510 by overtaking the overcurrent agent 500 is broken and becomes a foamy flow because the depth of water suddenly becomes shallow above the overcurrent agent in the course of the overpass, and thus, the inflow water contains a large amount of oxygen.

As described above, when fresh and clean seawater of the outer port enters the inner port through the water passage 110 in a state containing a large amount of oxygen, the water quality of the inner port can be significantly improved. That is, since the large amount of sea water of the outer port continuously flows into the inner port contaminated by stagnation and rot, and the inflow of wastewater, the flow also occurs in the inner port, and the water quality can be improved by supplying a large amount of oxygen. .

On the other hand, Figure 3 of the accompanying drawings shows a state in which the seawater inflow device using a moon flow agent according to the present invention is applied when there is land between the outer port or the bay and the inner port.

As illustrated in FIG. 3, the water passage 110 is installed on the open sea in an area adjacent to the inner port or between the bay and the inner port. In this way, by installing the overflow agent 500 in the outer port, the open sea, or the bay of the adjacent or other area, a water reservoir is formed between the overflow agent 500 and the entrance of the water passage 110, so that the inner port and the adjacent area or other Local seawater can be easily supplied to the inner port. Such a construction method can be usefully applied when it is difficult or difficult to install the overcurrent agent 500 on the breakwater of the inner port, and can also be applied when supplying seawater to an area far from the sea.

At this time, a structure 100 such as a quay wall or a breakwater may be installed at the entrance side of the water passage 110.

On the other hand, the seawater inflow apparatus according to the present invention changes the height of the wave (H) that the wave overtakes according to the tide of the open sea, so that the tide of the foreign sea and the height of the wave (H) overwhelms the wave, thereby bringing the seawater flowing into the inner port. To maximize the amount of seawater flowing into the reservoir 510 so as to increase the amount of the wave height variable means (600) is provided with at least one or more in the overflow agent (500).

That is, by providing the variable height wave height means (600) in the overflow agent (500), it is possible to continuously maximize the amount of seawater flowing into the reservoir (510), and in particular, in the region where the difference between tides is high, As H) is interlocked, it is possible to continuously maximize the inflow of seawater.

This will be described in more detail as follows.

6 of the accompanying drawings is a graph showing the result of measuring the change in the flow rate through the water passage through changing the tide level. In FIG. 6, hc is a value obtained by subtracting the tide level from the height of the overcurrent agent, and Hs is the wave height. As shown in FIG. 6, the amount of seawater inflow becomes maximum when hc=0 (when the height and tide level of the overcurrent agent coincide), and it is seen that as the absolute value of hc increases, it decreases significantly compared to hc=0. You can. This means that by continuously adjusting the height of the overcurrent agent 500 to match the tide level, a large amount of seawater in the outer port can always be introduced in an optimal state. That is, it means that a large amount of seawater can continuously flow into the reservoir 510 when the wave height (H) at which the wave is overwhelmed matches the tide level.

At this time, the moon height variable means 600 may be configured in various ways.

First, the wall height variable means 600 is a wall wave height forming plate 610 provided in the wall flow agent 500 and a wall wave height forming plate 610 provided in the wall flow agent 500 according to the tide level of the open sea. It is composed of a driving device 620 for selectively varying the wall height (H) by operating the wall wave height forming plate 610 so as to be variable.

On the other hand, the specific structure of the moon wave height variable means 600 is as follows.

That is, the wall wave height forming plate 610 is movably installed in a guide groove provided vertically or inclined to the wall flow agent 500, and the wall wave height is formed so that the height of the wall wave height forming plate 610 is variable according to the tide level of the open sea. The driving device 620 for selectively changing the height of the wave height H by moving the plate 610 selectively along the guide groove to the upper or lower portion H is installed in the overflow agent 500.

At this time, the driving device 620 may be composed of actuators of various configurations, and further comprises any one operation means selected from racks and pinions, nuts and screws, chains and sprockets, hoisters, wires and link members. That is, such a driving device 600 is to operate the operating means with the power of the actuator to protrude the wall wave height forming plate 610 to the upper surface of the overflow agent 500 to vary the wall wave height (H).

On the other hand, the moon wave height variable means 600 according to another structure is a wall wave height forming plate 610 that is rotatably installed with the lower end coupled to the surface of the area where the wave of the overcurrent agent 500 is overwhelmed, and of the open sea. The overflow agent (500) so that the height of the wall wave height (H) is selectively changed by rotating or rotating the wall wave height forming plate (610) around an axis so that the height of the wall wave height forming plate (610) varies according to the tide level. It is composed of a driving device 620 provided in the.

The wall height variable means 600 is to change the height of the wall height forming plate 610, that is, the wall height (H) by rotating the wall height forming plate 610 to be laid or erected about the lower axis.

At this time, the driving device 620 may be composed of actuators of various configurations as described above, and the operation means is made of any one selected from a plurality of gears, chains and sprockets, a winding machine, and wire and link members. That is, the driving means 620 may be configured to adjust the height of the wave height (H) through the operation of erecting or lying on the wall height forming plate 610, which is rotatably installed on one end.

Various embodiments of the seawater inflow device using the moon flow agent according to the present invention will be described in detail based on the accompanying drawings.

4 of the accompanying drawings shows a first preferred embodiment according to the present invention.

As illustrated in FIG. 4, the seawater inflow device according to the first embodiment is formed in a circular arc shape in which the wave height forming plate 610 is convexly curved to the offshore side with a side cross-sectional shape of the wave height 612. A shaft portion 614 is provided in the center point region of the formed over-wave portion 612 and is installed in an arc-shaped receiving groove 520 that is recessed from the upper side of the overflowing agent 500 toward the reservoir 510 side. The shaft portion 614 is rotatably coupled to the tower 700 installed in the 500, and the curved surface of the wave portion 612 is seated in the receiving groove 520 in a state facing the open sea or the outward port, and the shaft portion 614 is mounted. As it rotates along the receiving groove 520 as the center, it selectively operates to protrude toward the upper side of the overcurrent agent 500, and is operated so that the wall wave height H is variable.

At this time, the wall wave height forming plate 610 is formed in an arc shape as shown in FIG. 4, and the shaft portion 614 is formed at its center point, to more effectively disperse the wave force acting when the wave from the outer port is overpass , To prevent deformation. That is, when the wave force acts on the wall wave height forming plate 610 formed in an arc shape, the direction of action of the total wave force is concentrated at the center of the circle, that is, the shaft portion 614, and the phenomenon that the wall wave height forming plate 610 itself is deformed Is prevented. Due to these characteristics, the wave height forming plate 610 may be formed to be long in the horizontal direction.

In addition, between the arc-shaped wall wave portion 612 and the arc-shaped receiving groove 520 so that seawater does not flow between the arc-shaped wall wave portion 612 and the arc-shaped receiving groove 520 of the wall wave height forming plate 610. It is desirable to provide airtightness means for maintaining airtightness. For example, it is preferable to install a synthetic resin material or a rubber material in areas where they are in contact with each other so as not to interfere with the operation while maintaining airtightness.

On the other hand, the driving device 620 is installed on the top of the tower 700, as shown in Figures 4 and 5, the hoisting machine 624 for driving the rotating shaft 622, and one end of the wave height forming plate ( 610), the other end is wound on the rotating shaft 622 and rotates the wall height forming plate 610 in the forward or reverse direction during the forward and reverse rotation operation of the hoisting machine 624, thereby rotating the wall height forming plate 610. It consists of a wire 626 to vary the height of the protrusion.

The above-mentioned tower 700 is a structure in which a circular pipe-shaped pillar made of steel or stainless steel is mutually coupled, or is a concrete structure, and is built on the upper surface of the moon flow agent 500 to have a predetermined height.

On the other hand, the driving device 620, as shown in Figure 17, the tide detection sensor (S1) for detecting the tide level of the open sea, and the wave height forming plate detection sensor (S2) for detecting the height of the wave height forming plate (610) It further includes a control unit 800 for receiving each detection signal from the control unit 800 to control the driving device 620 so that the height of the wave height forming plate 610 matches the tide level of the open sea. This is for changing the height of the wave height forming plate 610, that is, the wave height (H) according to the tide level changing from time to time. The control unit 800 may be installed on the tower 700 or may be separately installed on land.

At this time, the system for automatically driving the wave height forming plate 610 may be configured as follows. When the tide level is constantly measured at the inspection station installed inside the port, and the height of the observation tide surface and the wave height forming plate 610 is compared at predetermined time intervals, and then the height of the wave height forming plate 610 coincides with the tide surface. To this end, an automatic control system for adjusting the height of the wave height forming plate 610 is constructed and operated. This memorizes the rotational initial value of the shaft portion 614 that can calculate the height of the wall wave height forming plate 610 at any position of the wall wave height forming plate 610, and the wall wave height forming plate 610 is used to rotate the shaft portion 614. After installing a sensor (e.g., emcoda) for measuring the rotation angle as a center on the wall height forming plate 610 or the shaft portion 614, the wall wave required to match the upper surface of the tide surface and the wall height forming plate 610 It is possible to configure an automatic system that automatically stops the adjustment when the height of the wave height forming plate 610 is adjusted by this angle by automatically calculating the rotation angle of the height forming plate 610.

At this time, the radius of the wave height forming plate 610 is r, the initial value of the rotation angle of the wave height forming plate 610 is called theta0, and the rotation angle to be adjusted is called theta. Y (upward direction +), which is the size obtained by subtracting the fixed floor height of 500, and c (positive number) is the vertical distance at which the shaft portion 614, which is the center of the arc of the wall height forming plate 610 installed from the fixed floor height, is installed downward. The following relationship is established between these values.

y +c = rsin(theta +theta0)

By modifying this equation, it is possible to calculate the angle theta to rotate the wave height forming plate 610 to match the height of the wave height forming plate 610 as follows.

theta = sin ^-1 ((y+c)/r)-theta0

Here, r, c, and theta0 are predetermined constants, and y is a value obtained by subtracting the fixed floor height of the overcurrent agent 500, which is a constant from the tidal plane at the time of consideration, and is a value calculated immediately by measuring the tidal plane at the checkpoint. .

If the tide is always measured, theta value can be easily calculated because only theta value is unknown in the above equation.

Therefore, the wall height forming plate 610 height automatic adjustment system is a hoisting machine 624 installed in the crane tower 700, a system for constantly measuring the tide level, at preset time intervals (for example, 5 minutes or 10 minutes, etc.) y and The driving means for calculating the theta value to operate the hoisting machine 624, the software and control measuring devices necessary to stop the operation of the wall height forming plate 610 when the wall height forming plate 610 rotates by theta, and operating them The power supply required for the Sikkim should be provided as the basis of the system.

In addition, if a wireless communication device is used, it is possible to wirelessly check whether the wall wave height forming plate 610 and the hoisting machine 624 operate normally, and the amount of tension applied to the wire 626 in a control room installed on the ground. In addition, the wave height forming plate 610 may be manually operated through radio. Therefore, when a high wave invades like a typhoon, it is possible to stop the movement by lowering the wave height forming plate 610 to the lowest position by using only wireless communication from the land control station without going to the site.

Since the tide can be accurately predicted for a long period of time, a tide station is not necessarily required to know the tide surface at any point, so the predicted value using software can be used as the tide value.

In addition, the wave force acting on the coastal structure becomes maximum at the stationary surface and becomes smaller as it moves up and down from the stationary surface. According to the present embodiment, since the moon flow agent 500 can be installed lower than the average sea level, the wave height forming plate 610 can be manually changed to the lowest position during a typhoon with a large wave power, thereby minimizing the total wave power acting on the body. You can. Therefore, the cross-sectional size (volume) of the overflowing body can be made smaller than the overflowing agent that does not change the height of the wave, thus reducing the construction cost.

The operation of the present embodiment configured as described above will be described with reference to FIGS. 4 and 5 as follows.

4 and 5, when the tide level of a coastal outer port is higher than the fixed floor height of the overcurrent agent 500, the height of the overpass (H) of the overcurrent agent 500 must be adjusted accordingly. To this end, the wall height forming plate 610 is rotated to adjust its height. That is, when the hoist height forming plate 610 is pulled upward by operating the hoisting machine 624 of the driving device 620, the moon height forming plate 610 rotates clockwise around the shaft portion 614. Therefore, the height of the wave height (H), that is, the floor height of the wave height forming plate 610 is consistent with the tide level of the outer port.

At this time, according to the control unit 800, the height of the wave height forming plate 610 may be adjusted in connection with the tide of the outer port.

As described above, since the floor height of the wave height forming plate 610 coincides with the tide level of the outer port, the seawater in the outer port can continuously flow into the reservoir 510.

In addition, since the wave height forming plate 610 is formed in an arc shape, deformation due to wave power can be prevented, and load distribution can be easily performed.

On the other hand, Figure 7 shows a second embodiment according to the present invention.

In the second embodiment as shown in FIG. 7, the driving device 620 is coupled to the hydraulic generator 627 for generating hydraulic pressure, one end is axially coupled to the wall height forming plate 610, and the other end is a tower ( 700) while being axially coupled to the tension/contraction operation by the hydraulic generator 627, the wall height forming plate 610 is rotated in the forward or reverse direction to vary the protrusion height (or floor height) of the wall height forming plate 610. It is the same as the above-described embodiment, except that it is configured as a hydraulic cylinder 628 to allow.

At this time, the hydraulic generator 627 may be installed on the tower 700, or may be installed on land.

As described above, the driving device 620 is composed of a hydraulic generator 627 and a hydraulic cylinder 628, thereby simplifying the configuration for operating the wave height forming plate 610.

On the other hand, of the accompanying drawings, Figure 8 shows a third embodiment according to the present invention.

As illustrated in FIG. 8, the third embodiment includes a hydraulic generator 627 for generating a hydraulic pressure by the driving device 620 and a first link member having one end axially coupled to a wall height forming plate 610 ( 629A), a link member (629), which is composed of a second link member (629B), one end of which is axially coupled to the tower (700), and each other end of the first and second link members (629A, 629B) is axially coupled Wow, one end is axially coupled to the second link member 629B, and the other end is axially coupled to the tower 700, thereby causing tension/contraction by the hydraulic generator 627 to operate the link member 629 to form a wall height. It is the same as the above-described embodiment, except that the plate 610 is made of a hydraulic cylinder 628 to change the protrusion height of the wall wave height forming plate 610 by rotating in the forward or reverse direction.

In other words, by operating the link member 629 using the hydraulic cylinder 628, the arc-shaped wave height forming plate 610 is rotated so that its height can be varied according to the tide of the outer port.

With this structure, the height of the tower 700 may be configured to be low and installed.

9A, 9B, and 9C of the accompanying drawings show a fourth embodiment according to the present invention.

That is, in the fourth embodiment, the wave height forming plate 610 is formed with a wave wave portion 612 through which waves wave, and a screw hole is formed at both ends of the wave wave portion 612, so as to be inclined toward the outward side. As shown, consists of an operation unit 615 that is movably inserted into and installed at each of the inclined guide grooves 540 formed in the structure 560 for the forming plate provided on the upper surface of the overflow agent 500, and is driven. The device 630 is screwed with the operation unit 615, as shown in Figure 9a or 9c, the rotating screw rod 632 rotatably installed inside the inclined guide groove 540, and the rotating screw rod (632) ) To rotate the forward and reverse rotation so that the operating portion 615 combined with the rotating screw rod 632 moves up and down along the longitudinal direction of the inclined guide groove 540 to vary the protrusion height of the wall height forming plate 620 It is the same as each of the above-described embodiments, except that the driving member 634.

At this time, the middle portion of one side facing the open sea side is convex toward the open sea side so that the wave height forming plate 610 is not deformed by the wave force and the load is distributed to both sides on the front surface of the wave height part 612 of the wave height forming plate 610. It is protruded so that the curved portion 616 is formed. The curved portion 616 may be formed in a horizontal direction as illustrated in FIG. 9B or may be formed in a vertical direction.

The rotating screw rod 632 and the driving member 634 are driven by power transmission means such as a bevel gear, a spur gear, and a worm gear.

As such, since the operation portion 615 of the wall height forming plate 610 is directly installed on the sidewall of the structure 560 for the forming plate, a high structure such as the tower 700 is unnecessary.

Meanwhile, FIGS. 10A and 10B show a fifth embodiment according to the present invention.

As shown in Figures 10a, 10b, the seawater inflow device according to the fifth embodiment is configured to have a variable wave height 600 as follows. That is, the wall wave height forming plate 610 is formed on the upper surface of the wall flow agent 500 to be formed at both end portions of the wall wave portion 612 and the wave wave portion 612, and to incline toward the outward side. Consists of an operating portion 615 that is movably inserted into the upper and lower portions of each inclined guide groove 540 formed in 560, and the driving device 630 has an operating portion 615 that is inclined guide groove 540. As shown in Figure 10a or 10b to guide it when moving up and down along the guide portion 635 is fitted to the operation portion 615 and installed in the inclined guide groove 540, and one end of the operation portion ( 615), the other end of the chain member 636 and the chain member 636 coupled to the lower end of the operating portion 615 through a guide hole 542 formed to communicate vertically with the inclined guide groove 540 ) To drive the chain member 636 in the forward or reverse direction by driving a plurality of sprockets 637 disposed on each element and one sprocket 637 among each sprocket 637 to move the operating part 615 ) Is the same as the above-described embodiment, except that it consists of a driving member 634 that changes the protruding height of the wave height forming plate 620 by allowing it to move up and down along the guide rod 635.

At this time, the middle portion of the one side facing the open sea side is convex toward the open sea side so that the wave height forming plate 610 is not deformed by the wave force and the load is distributed to both sides on the front surface of the wave height part 612 of the wave height forming plate 610. The curved portion 616 is protruded. And, for smooth operation of the chain member 636, it is preferable that a plurality of small sprockets are further provided.

On the other hand, Figure 11 shows a sixth embodiment according to the present invention.

In the sixth embodiment, the wave height forming plate 610 is provided with a wave wave portion 612 through which the wave passes, and the lower ends thereof are rotatable axially on the structure 560 for the plate provided on the upper surface of the moon flow agent 500. Combined, the driving device 640 is installed on the forming plate structure 560 so that the wall height forming plate 610 is erected or laid down so that the height of the wall wave forming plate 610 is rotationally driven around an axis. However, the driving device 640 has a third link member 642, one end of which is axially coupled to the wall height forming plate 610, and a fourth link member of which one end is axially coupled to the third link member 642. The link member 645 made of (644) and the other end of the fourth link member 644 are operated to forward or reverse rotation of the driven gear 646 to which the link member 645 is operated to form a wall height. It is the same as each of the above-described embodiments, except that it is made of a driving member 634 for changing the height of the wall wave height forming plate 610 by laying or standing (610).

As described above, the wall height (H) is variable as the end of the wall height forming plate 610 is laid or erected in a state where it is laid down, so the structure is simple and installation costs are reduced.

Meanwhile, FIG. 12 shows a seventh embodiment according to the present invention.

In the seventh embodiment, the driven device 640 is provided with a driven sprocket 647 provided on an axis supporting the wave height forming plate 610, and a top surface of the overcurrent agent 500 to maintain a distance from the driven sprocket 647 The drive sprocket 648 disposed on the upper surface of the structure 560 for forming plate provided in, the chain member 649 coupled to the driven sprocket 647 and the drive sprocket 648, and the drive sprocket 648 forward rotation Or it is the same as the above-described embodiment, except that it consists of a driving member 634 for changing the height of the wall-wave height forming plate 610 by laying or standing on the wall-wave height forming plate 610 by driving in reverse rotation.

Meanwhile, FIG. 13 shows an eighth embodiment according to the present invention.

As shown in FIG. 13, in the eighth embodiment, the driving device 640 has one end coupled to the wall height forming plate 610 and the other end coupled to the forming plate structure 560 axially to generate the hydraulic generator 627. ) Is the same as the above-described embodiment, except that it consists of a hydraulic cylinder 641 for varying the height of the wall wave height forming plate 610 by laying or standing the wall wave height forming plate 610 while being tensioned/contracted by.

The driving device 640 of the seawater inflow device according to the above-described eighth embodiment has a simple structure, so that installation and manufacturing costs are low.

Meanwhile, FIG. 14 shows a ninth embodiment according to the present invention.

In the ninth embodiment, the wall wave height forming plate 610 is formed in a circular arc shape curved toward the open sea side, and the wall wave portion 612 is configured to wave through, and one end is axially coupled to the wall wave portion 612, and the other end is walled. Consists of a forming plate support member 617 that is rotatably coupled to each inner surface of the forming plate structure 560 provided on the upper surface of the flow agent 500, and the driving device 650 has one end flow agent 500 ) Is rotatably coupled to the structure 560 for the forming plate provided on the upper surface, and the other end is axially coupled to the wave portion 612 while being tensioned/contracted by the hydraulic generator 627, thereby forming the wave height plate 610 ) Is made of a hydraulic cylinder 652 to vary the height of the wave height forming plate 610 by rotating it up and down about the rotation axis of the forming plate support member 617 and same.

As described above, since the wave height forming plate 610 is formed in an arc shape, a phenomenon that is deformed by wave power can be prevented.

Meanwhile, FIG. 15 shows a tenth embodiment according to the present invention.

In the tenth embodiment, the guide groove 541 is formed in the structure 560 for the forming plate provided on both sides of the upper surface of the overcurrent agent 500 by having the wave height forming plate 610 provided with a wave wave portion 612 through which waves are waved. ) Is slidably installed, and the driving device 660 has a rack gear 662 with one end coupled to a wall height forming plate 610 and a rack gear 662 on the upper side of the forming plate structure 560. The driven pinion 664 and the driving member 634 for varying the height of the wall height forming plate 610 by allowing the wall height forming plate 610 to rise or fall by rotating or reversing the pinion 664 forward or backward. It is the same as each of the above-described embodiments, except that consisting of.

At this time, the guide groove 541 may be formed vertically or inclined.

Meanwhile, FIG. 16 shows an eleventh embodiment according to the present invention.

In the eleventh embodiment, the guide groove 541 formed in the structure 560 for the forming plate provided on both sides of the upper surface of the overcurrent agent 500 is provided with the wave wave height forming plate 610 has a wave wave portion 612 through which waves are waved. ) Is slidably installed, the driving device 660 is coupled to the fifth link member 663, one end of which is axially coupled to the upper portion of the wave portion 612, and one end is axially coupled to the fifth link member 663. The other end is a link member 662 made of a sixth link member 664 that is axially coupled to the structure 560 for the forming plate, and one end is axially coupled to the structure 560 for the forming plate, and the other end is the sixth link Except that it consists of a hydraulic cylinder 666 for selectively changing the height of the wave height forming plate 610 by operating the link member 662 by tension/contraction on one end side of the member 664 by tension/contraction It is the same as each embodiment mentioned above.

At this time, the middle portion of one side facing the open sea side is convex toward the open sea side so that the wave height forming plate 610 is not deformed by the wave force and the load is distributed to both sides on the front surface of the wave height part 612 of the wave height forming plate 610. The curved portion 616 is protruded.

In the foregoing, although specific embodiments of the present invention have been described and illustrated, the present invention is not limited to the described embodiments, and it is common knowledge in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. It is obvious to those who have it. Therefore, such modifications or variations should not be individually understood from the technical spirit or viewpoint of the present invention, and the modified embodiments should belong to the claims of the present invention.

100: structure 110: water passage
500: monthly system 510: Reservoir
600: Wall height variable means 610: Wall height forming plate
620,630,640,650,660: Drive
800: control unit H: wave height
S1: tide level sensor S2: moon wave height forming plate detection sensor

Claims (37)

It is located between the inner port and the outer port to distinguish the inner port and the outer port, and a structure made of a quay wall or a breakwater provided with a passage for moving seawater from the outer port into the inner port; And
Includes; is installed on the outer port by maintaining a distance from the structure to form a resin between the structure arcuate, semi-circular, elliptical, polygonal form formed of any one of the selected;
As the waves of the outer port break through and flow into the water reservoir beyond the current flow, the water level of the water reservoir rises and the water level difference with the inner port occurs, so that the water level of the water reservoir with the increased water level flows into the inner port through the water passage,
In the overcurrent agent, by varying the height of the wave over which the wave overtakes according to the tide of the open sea, the tide of the oversea and the wave height over which the wave overtakes coincide, thereby increasing the amount of seawater flowing into the inland port. Equipped with at least one means for varying the height of the moon to maximize the amount,
The moon height variable means,
An arc-shaped receiving groove concavely recessed from one side of the upper surface of the overflowing agent to the side of the reservoir;
It has an arcuate wall wave portion formed in an arc shape so that the side cross-sectional shape is curved, and a shaft portion provided in the center point region of the wall wave portion, and the curved surface convexly curved in the wave portion faces the open sea or the outer port. Wall height forming plate to be seated;
Airtightness maintenance means installed between the wave-shaped portion and the receiving groove so that seawater does not flow between the arc-shaped wave-shaped portion and the arc-shaped receiving groove;
A tower installed on the overflow agent and the shaft portion is rotatably coupled; And
The wall wave height forming plate is rotated around the shaft so that the height of the wall wave height forming plate is variable according to the tide level of the open sea installed in the tower, so that the wall wave portion of the arc shape is along the receiving groove of the arc shape. The seawater inflow device using the current flow agent, characterized in that it consists of a driving device to be raised or projected or lowered to the upper side of the housing to be accommodated in the receiving groove to selectively vary the height of the wave. delete delete A passageway provided on the land between the outer sea or the bay and the inner port of an area adjacent to the inner port so that the sea water of the open sea or bay moves to the inner port; And
It is installed on the open sea or bay side by maintaining a distance from the entrance side of the water passage, and includes a surplus agent formed in any one shape selected from arc, semicircular, elliptical, polygonal to form a water reservoir between the water passage entrance. So,
As the waves of the open sea or the bay break, the water level of the reservoir rises as the water flows over the moon-flow system and flows into the reservoir, so that the water level of the reservoir rises to the inner port through the passageway,
In the overcurrent system, by varying the height of the wave over which the wave overtakes according to the tide of the open sea, the tide of the oversea and the wave height over which the wave overtakes coincide, thereby increasing the amount of seawater flowing into the inland port. Equipped with at least one means for varying the height of the moon to maximize the amount,
The moon height variable means,
An arc-shaped receiving groove concavely recessed from one side of the upper surface of the overflowing agent to the side of the reservoir;
It has an arcuate wave-shaped wave shaped part formed in an arc shape so that the side cross-sectional shape is curved, and an axis portion provided in the center point region of the wave-shaped part, and the curved convex curved surface of the wave-shaped part is in the receiving groove so as to face the open sea or outward port. Wall height forming plate to be seated;
An airtight maintenance means installed between the wall portion and the receiving groove so that seawater does not flow between the arc-shaped portion and the arc-shaped receiving groove;
A tower installed on the overflow agent and the shaft portion is rotatably coupled; And
The wall wave height forming plate is rotated around the shaft so that the height of the wall wave height forming plate is variable according to the tide level of the open sea, and the wall wave portion of the arc-shaped wave is along the receiving groove of the arc shape. The seawater inflow device using the current flow agent, characterized in that it consists of a driving device to be raised to the upper side of the projecting or descending to be accommodated in the receiving groove to selectively vary the height of the wave. delete delete delete delete delete delete delete delete delete delete delete delete The method of claim 1 or 4,
The driving device,
It is installed on the top of the tower, a hoist for driving the rotating shaft; And
One end is fixed to the wall height forming plate, the other end is wound on the rotating shaft to rotate the wall height forming plate in the forward or reverse rotation of the hoisting machine in the forward or reverse direction to vary the protruding height of the wall height forming plate. Seawater inflow device using a moon flow agent characterized in that it is made of a wire. The method of claim 1 or 4,
The driving device,
A hydraulic generator installed on the ground or a tower to generate hydraulic pressure; And
One end is coupled axially to the wave height forming plate, the other end is axially coupled to the tower, and is tensioned/contracted by the hydraulic generator to rotate the wave height forming plate in the forward or reverse direction to rotate the wall height forming plate. Seawater inflow device using a moon flow agent, characterized in that it consists of a hydraulic cylinder for varying the protruding height. The method of claim 1 or 4,
The driving device,
A hydraulic generator installed on the ground or a tower to generate hydraulic pressure;
One end is composed of a first link member that is axially coupled to the wall height forming plate, and one end is composed of a second link member that is axially coupled to the tower, and each other end of the first and second link members is axially coupled. Link member; And
One end is axially coupled to the second link member, and the other end is axially coupled to the tower to operate the link member while being tensioned/contracted by the hydraulic generator so that the wall height forming plate is rotated in the forward or reverse direction. Seawater inflow device using the overflow agent, characterized in that it consists of a hydraulic cylinder for varying the height of the protrusion height plate. delete delete It is located between the inner port and the outer port to distinguish the inner port and the outer port, and a structure made of a quay wall or a breakwater provided with a passage for moving seawater from the outer port into the inner port; And
Includes; is installed on the outer port by maintaining a distance from the structure to form a resin between the structure arcuate, semi-circular, elliptical, polygonal form formed of any one of the selected;
As the waves of the outer port break through and flow into the water reservoir beyond the current flow, the water level of the water reservoir rises and the water level difference with the inner port occurs, so that the water level of the water reservoir with the increased water level flows into the inner port through the water passage,
In the overcurrent agent, by varying the height of the wave over which the wave overtakes according to the tide of the open sea, the tide of the oversea and the wave height over which the wave overtakes coincide, thereby increasing the amount of seawater flowing into the inland port. Equipped with at least one means for varying the height of the moon to maximize the amount,
The moon height variable means,
Each inclined guide groove formed inclined toward the outward side in the structure for the forming plate provided on the upper surface of the overflow agent;
A wave portion over which the wave passes, a curved portion in which the front middle portion of the wave portion protrudes convexly toward the open sea side so that the load is distributed to both sides without being deformed by the wave force, and a screw hole at both ends of the wave portion It is formed with a, wave height forming plate consisting of an operating portion that is installed to be installed to be movable up and down in each inclined guide groove; And
A rotating screw rod screwed to the operating portion and rotatably installed inside the inclined guide groove, and an operating portion coupled to the rotating screw rod by rotating the rotating screw rod forward and backward along the longitudinal direction of the inclined guide groove. And a driving device made of a driving member for varying the protruding height of the wall wave height forming plate by lifting and descending. delete delete delete delete delete delete delete delete delete delete It is located between the inner port and the outer port to distinguish the inner port and the outer port, and a structure made of a quay wall or a breakwater provided with a passage for moving seawater from the outer port into the inner port; And
Includes; is installed on the outer port by maintaining a distance from the structure to form a resin between the structure arcuate, semi-circular, elliptical, polygonal form formed of any one of the selected;
As the waves of the outer port break through and flow into the water reservoir beyond the current flow, the water level of the water reservoir rises and the water level difference with the inner port occurs, so that the water level of the water reservoir with the increased water level flows into the inner port through the water passage,
In the overcurrent agent, by varying the height of the wave over which the wave overtakes according to the tide of the open sea, the tide of the oversea and the wave height over which the wave overtakes coincide, thereby increasing the amount of seawater flowing into the inland port. Equipped with at least one means for varying the height of the moon to maximize the amount,
The moon height variable means,
A structure for forming plates provided on both sides of the upper surface of the overcurrent agent and having guide grooves formed on opposite sides;
It is provided slidably installed in the guide groove provided with a wave overhanging wave, and the middle portion of one side facing the open sea side is convex toward the open sea side so that the load is distributed to both sides without being deformed by the wave force on the front side facing the open sea or outward sea. A wall height forming plate that protrudes so that a curved portion is formed;
A link member consisting of a fifth link member, one end of which is axially coupled to the upper portion of the wall wave part, and a sixth link member which is axially coupled to the fifth link member, and the other end of which is axially coupled to the structure for the forming plate. Wow, one end is axially coupled to the structure for the forming plate, and the other end is axially coupled to one side of the sixth link member to operate the link member in tension/contraction to selectively vary the height of the wall height forming plate. Seawater inflow device using the overflow agent, characterized in that it comprises a driving device consisting of a hydraulic cylinder for. The method of any one of claims 1, 4, 22, 33,
The driving device,
A tide detection sensor that detects tide levels in the open sea; And
Automatic control of the driving device so that the height of the wall height forming plate matches the level of the open sea by receiving and comparing the tide detection signal and the height detection signal from the wall height forming plate detection sensor that senses the height of the wall height forming plate. Seawater inflow device using a moon flow agent further comprising a control unit.


delete delete delete

Images