KR102099385B1 - Tidal power generation apparatus - Google Patents

Abstract

The present invention relates to a tidal power generating device installed in a seawall separating the seawater side from the seawater side and generating power by using the flow of seawater between the seawater side and the seawater side, and the seawater side inlet formed at one side of the seawater side contacting the seawater side , Located in the oblique direction of the seawater-side inlet, the first flow path connecting the reservoir-side outlet formed on one side of the seawater side and the reservoir side along the seawater-side inlet direction from the reservoir-side outlet, the other side of the seawall facing the reservoir side Connecting the water-side inlet formed in, and the seawater-side outlet formed on the other side of the seawater side in the oblique direction of the water-side inlet, the second flow path and the first formed to cross the first flow path The intersection formed in parallel with the installation direction of the seawall at the intersection of the flow path and the second flow path It includes a furnace and at least one power generation part installed on the crossing passage, by opening the sea water side inlet and the water side outlet, by the flow of sea water moving from the sea water side through the power generation part to the water side through the first flow path. It is characterized in that power generation is performed, and power generation is performed by a flow of seawater moving from the reservoir side to the seawater side from the reservoir side through the second flow path by opening the reservoir side inlet and the seawater side inlet.
According to the present invention as described above, it is possible to provide a tidal power generating apparatus capable of significantly reducing the construction cost accordingly while greatly improving the power generation efficiency.

Description

Tidal power generation apparatus

The present invention relates to a tidal power generating device, and more particularly, to a tidal power generating device capable of significantly reducing the construction cost accordingly while greatly improving the power generation efficiency.

In general, tidal power generation is a power generation method that converts potential energy into kinetic energy and converts it into electrical energy from the water level difference of tidal water.

In other words, the sea level gradually rises from low tide to high tide, and the tide moves horizontally toward the coast. At this time, when aberration is installed on the side of the inflow direction of the tide, the method of generating power by driving the generator by the rotational force and the aberration is rotated by the tide.

This means that as long as the Earth and the Moon exist, there is always a uniform tide horizontal movement, so much research has been conducted on tidal power generation, the next-generation energy source.

The tidal power generation is divided into forging knowledge and demodulation knowledge according to the number of lakes, and a single-flow type and a double-flow type according to the direction of use of seawater.

Here, the forging knowledge is a development that uses a water level difference between the seawater side and the reservoir by creating one reservoir, and the demodulation knowledge is usually used when two reservoirs can be formed on the topography, and uses the water level difference between the two reservoirs. Development.

In addition, the single-stream power generation is a creative development that develops using the flow of seawater from the seawater side to the reservoir side by using the difference in water level when the tide rises at the seawater side, and the water level at low tide when the water level at the seawater side falls. It is a method in which unidirectional power generation is performed, such as algae-type power generation that develops by using the flow of seawater from the water side to the seawater side using a car, and the double-flow power generation is the difference in water level between the seawater side and the reservoir side that occurs during high and low tide. It is a method that develops in both directions by using the flow of the sea water in both directions moving from the sea water side to the sea water side or from the sea water side through the water gate opening and closing control of a plurality of water tanks.

On the other hand, in the case of a single-stream power generation method, power generation is possible only at high tide or low tide, so there is a disadvantage in that it is impossible to arbitrarily adjust the amount of power generation because it is not possible to smoothly supply and receive the power required at a desired time. .

1 (a) and (b) is a view showing the operation of the tide and low tide of the conventional double tidal power generation system.

Referring to Figure 1, the conventional double tidal power generation system is installed adjacent to the first reservoir 10, the first reservoir 10 provided with the first and second sluice gates 11 and 12, and the third and third 4 Second reservoir (20) is provided with a water gate (21, 22), the first reservoir 10 and the second reservoir 20 is installed adjacent to the second water gate (12) and the fourth water gate (22) It is installed between the connected third water storage tank 30 and the first water storage tank 10 and the second water storage tank 20 and discharges water from the first water storage tank 10 into the second water storage tank 20 to rotate the aberration. It comprises a power generation facility 40 for generating electricity by the rotation of the.

As shown in FIG. 1 (a), the conventional dual current tidal power generation system is closed when the water level of the open sea 50 is high, while the second water gate 12 and the third water gate 21 are closed. Electricity by opening the first sluice 11 and the fourth sluice 22 to flow the seawater flowing from the foreign sea 50 into the first reservoir 10 through the power generation facility 40 into the second reservoir 20 Is generated, and the water of the second reservoir 20 is introduced into the third reservoir 30 through the fourth sluice 22 and stored.

And, as shown in Figure 1 (b), at the low tide when the water level of the open sea 50 is lowered, the second sluice 12 while the first sluice gate 11 and the fourth sluice gate 22 are closed. And opening the third water gate 21 to transfer the seawater flowing from the third water storage tank 30 to the first water storage tank 10 through the second water gate 12 through the power generation facility 40 to the second water storage tank 20. Electricity is generated by allowing it to flow in, and water from the second reservoir 20 is discharged to the open sea 50 through the third water gate 21.

As described above, the conventional double tidal power generation system greatly increases the amount of power generation compared to a single flow type as power generation occurs at low tide as well as high tide, but it is necessary to construct a large number of water tanks (10, 20, 30) for initial construction. In addition to the excessive increase in cost, the seawater flowing from the external sea (50) or the third reservoir (30) flows into the first reservoir (10) with a large area, and the seawater introduced into the first reservoir (10) is removed. 2 As the flow direction of the seawater changes during the flow into the reservoir 20, the flow rate of seawater passing through the power generation facility 40 is significantly reduced, and accordingly, a problem in that power generation efficiency is greatly reduced.

Korean Registered Patent No. 10-1073462 “tidal power generation system”

The present invention has been devised to solve the above problems, and an object of the present invention is to provide a tidal power generating apparatus capable of significantly reducing construction costs while significantly improving power generation efficiency.

According to the present invention for achieving the above object, in the tidal power generating device is installed in the seawater separating the seawater side and the reservoir side, and generating power by using the flow of seawater between the seawater side and the reservoir side, one side of the seaweed contacting the seawater side Located along the direction of the seawater side inlet from the first flow path and the reservoir side outlet connected to the seawater side inlet formed in the slant direction of the seawater side inlet and the reservoir side outlet formed on one side of the seawater side inlet. Connect the reservoir side inlet formed on the other side of the seawall contacting the reservoir side and the seawater side outlet formed on the other side of the seawall side facing the seawater side, and formed to cross the first flow path. Installation direction of the seawall at the intersection of the second flow path and the first flow path and the second flow path It includes a cross flow passage formed side by side and at least one power generation part installed on the cross flow passage, opening the sea water side inlet and the water side outlet to move from the sea water side to the water side through the power generation portion through a first flow path. Power generation is performed by the flow of sea water, and the power is generated by the flow of sea water moving from the water side to the sea water side through the second flow path through the second flow path by opening the water inlet and the sea water side inlet. A tidal power generation device is provided.

Here, it is preferable that the seawater-side inlet is installed at a higher position than the reservoir-side outlet, and the reservoir-side inlet is installed at a higher position than the seawater-side outlet.

And, the seawater-side inflow gate that regulates the opening and closing of the seawater-side inlet, the reservoir-side outflow gate that regulates the opening and closing of the inner-water-side outlet, and the reservoir-side inflow gate and the opening and closing of the seawater-side outlet that regulate the opening and closing of the inner-water-side inlet. A seawater side outflow gate to control the seawater, the seawater side inflow gate and the reservoir side inflow gate interlock the opening and closing of the seawater side inlet and the water side inlet by an interlocking and descending operation, each height being the It is formed at least twice the height of the seawater-side inlet and the reservoir-side inlet, and simultaneously shields the seawater-side inlet and the reservoir-side inlet at the same position with respect to the seawater-side inlet and the reservoir-side inlet, and at the same time either Even if one of the seawater-side inlet and the reservoir-side inlet is opened by elevating or descending, One shielding state is maintained, and the seawater-side effluent gate and the reservoir-side effluent gate control the opening and closing of the seawater-side outlet and the water-side outlet by interlocking and descending operations, respectively, each height being the seawater-side outlet. And it is formed at least twice the height of the water-side outlet, at the same position with respect to the seawater-side outlet and the water-side outlet, the seawater-side outlet and the reservoir-side outlet can be simultaneously shielded at the same time, either one is raised or lowered Thus, even if either one of the seawater side outlet and the reservoir side outlet is opened, the other shielding state is maintained.

According to the present invention as described above, it is possible to provide a tidal power generating apparatus capable of significantly reducing the construction cost accordingly while greatly improving the power generation efficiency.

1 (a) and (b) is a view showing the operation of the tide and low tide of the conventional double tidal power generation system.
Figure 2 is a schematic plan cross-sectional view of the tidal power generation apparatus according to an embodiment of the present invention.
3 is a schematic side cross-sectional view of a tidal power generating apparatus according to an embodiment of the present invention.
4A and 4B are views for explaining the operation of the tidal power generating apparatus according to an embodiment of the present invention.
5A to 5C are views for explaining the operating state of the water gate of the tidal power generating apparatus according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings. It should be noted that the same components in the drawings are denoted by the same reference numerals wherever possible. In addition, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the invention are omitted.

2 is a schematic cross-sectional schematic view of a tidal power generating apparatus according to an embodiment of the present invention, and FIG. 3 is a schematic side cross-sectional view of a tidal power generating apparatus according to an embodiment of the present invention.

2 and 3, the tidal power generator 1 according to an embodiment of the present invention is installed in a seawater side (B) separating the seawater side (S) and the reservoir side (R), the seawater side (S ) And is generated by using the flow of seawater between the reservoir side (R), the first flow path 10, the second flow path 20, the crossing passage 25, the power generation unit 30, the seawater side inflow gate 40 ), The reservoir side water sluice 50, the reservoir side inlet sluice 60 and the sea water side sluice gate 70.

The first flow path 10 is a seawater side inlet 11 formed on one side of the seawater side S and the seawater side S, and a seawater side inlet 11 positioned in a diagonal direction with respect to the seawater side inlet 11 and in contact with the water side R. (B) It connects the reservoir side outlet 12 formed in one side, and provides the movement path of the seawater from the seawater side S to the reservoir side R.

The second flow path 20 is located along the direction of the seawater side inlet 11 from the reservoir side outlet 12, and the reservoir side inlet 21 formed on the other side of the seawater side (B) and the reservoir side (R), and the reservoir side inlet (21) with respect to the seawater side (S) located in the oblique direction and connected to the seawater side outlet (22) formed on the other side of the seawater side (S), formed to cross the first flow path (10), and the water side (R ) To provide the movement path of the seawater from the seawater side (S).

The crossing passage 25 is formed at the intersection of the first flow path 10 and the second flow path 20 in parallel with the installation direction of the seawall, and provides an installation area of the power generation unit 30 to be described later.

Here, the present invention, as shown in Figure 3, the sea water side inlet 11 and the reservoir 21 is installed in a higher position than the sea water side outlet 12 and the reservoir side outlet 22, the first flow path ( 10) and the second flow path 20 is formed to be inclined downward with respect to the direction of movement of the sea water.

At this time, the crossing passage 25 is an area where the first flow path 10 and the second flow path 20 intersect, and is preferably formed horizontally since the flow of sea water in opposite directions is generated.

As described above, the present invention forms a first flow path 10 and a second flow path 20 that provide a movement path of sea water in the seawater side (B) separating the sea water side (S) and the water side (R). In addition to inducing a fast flow, as the first flow path 10 and the second flow path 20 are formed to be inclined downward with respect to the moving direction of the sea water, a faster flow of sea water is induced, thereby significantly improving power generation efficiency.

In addition, in the present invention, in designing the first flow path 10, the area of the first flow path 10 is gradually increased from the seawater side inlet 11 to the cross flow path 25 in which the power generation unit 30 to be described later is installed. Designed to be reduced to induce a rapid flow of seawater flowing into the power generation unit 30, and the area of the first flow path 10 from the cross passage 25 where the power generation unit 30 is installed to the reservoir 12 is stored. It can be designed to increase gradually again so that fast discharge of seawater can be induced.

Similarly, the area of the second flow path 20 is designed to gradually decrease from the reservoir inlet 21 to the cross passage 25 where the power generation unit 30 is installed, and the cross passage 25 where the power generation unit 30 is installed The area of the second flow path 20 may be designed to gradually increase from the back to the seawater side outlet 22.

The power generation unit 30 is installed on the cross flow passage 25 in which the flows of the first flow passage 10 and the second flow passage 20 cross, and the water side from the seawater side S through the first flow passage 10 It serves to produce electricity by using the flow of seawater moving to (R) and the flow of seawater moving from the reservoir side (R) to the seawater side (S) through the second flow path (20). It includes a propeller 31 and a generator 32.

In this embodiment, a structure including a propeller 31 and a generator 32 that rotates the power generation unit 30 is described, but the power generation unit 30 of the present invention is not limited to this, and rotates aberrations and generators. It can also be formed in a structure that includes, any configuration that generates electricity using the flow of sea water is possible.

In addition, in this embodiment, one power generation unit 30 is illustrated as being installed on the cross flow passage 25 in which the flows of the first flow path 10 and the second flow path 20 are crossed, but the present invention is limited to this. It is not possible, it may be provided to have a plurality of power generation unit 30 on the crossing passage 25 to improve the power generation efficiency.

The seawater-side inlet gate 40 is installed at the seawater-side inlet 11 and serves to control the opening and closing of the seawater-side inlet 11.

The reservoir-side effluent gate 50 is installed at the reservoir-side outlet 12 and serves to control the opening and closing of the reservoir-side outlet 12.

The reservoir-side inlet gate 60 is installed at the reservoir-side inlet 21 and serves to control the opening and closing of the reservoir-side inlet 21.

The seawater-side outlet water gate 70 is installed at the seawater-side outlet 22 and serves to control the opening and closing of the seawater-side outlet 22.

As described above, the tidal power generating device 1 according to an embodiment of the present invention forms a first flow path 10 and a second flow path 20 that provide a movement path of seawater in the seawater (B). In addition to inducing a fast flow, the first flow path 10 and the second flow path 20 are designed to induce a faster flow of seawater, thereby significantly improving power generation efficiency.

In addition, the present invention does not need to form a plurality of separate water tanks, such as the conventional double-flow tidal power generation system due to the structure installed in the seawall (B), thereby significantly reducing construction costs.

 4A and 4B are views for explaining the operation of the tidal power generating apparatus according to an embodiment of the present invention.

The tidal power generating device 1 according to an embodiment of the present invention is high-water in a state in which the seawater-side inlet 11, the reservoir-side outlet 12, the reservoir-side inlet 21, and the seawater-side outlet 22 are all shielded. When the water level on the seawater side is higher than the reservoir side due to the tide, as shown in FIG. 4A, the seawater side inlet 11 and the reservoir side outlet through the seawater side inlet gate 40 and the reservoir side outlet gate 50 12) the opening, and the reservoir side inlet 21 and the seawater side outlet 22 are shielded through the reservoir side inflow gate 60 and the seawater side outlet gate 70, so that the first flow path 10 is caused by the water level difference. ) To develop by using the flow of seawater moving from the seawater side to the reservoir side.

Then, when the water level and the water level at the time of refining reaches the same level, the sea water side inlet 11, the water side outlet 12, the water side inlet 21, and the sea water side outlet 22 are all shielded, When the water level on the seawater side becomes lower than the water level on the low tide during low tide, as shown in FIG. 4B, the reservoir side inlet 21 through the reservoir side inflow gate 60 and the sea side side outlet gate 70 and The seawater-side outlet 22 is opened, and the seawater-side inlet 11 and the reservoir-side outlet 12 are shielded through the seawater-side inlet gate 40 and the reservoir-side outlet gate 50, thereby eliminating the water level difference. It is developed by using the flow of seawater moving from the reservoir side to the seawater side through the 2 flow paths.

5A to 5C are views for explaining the operating state of the water gate of the tidal power generating apparatus according to an embodiment of the present invention.

The tidal power generation device 1 according to an embodiment of the present invention mutually intersects between the seawater-side inflow gate 40 and the reservoir-side inflow gate 60, and between the reservoir-side outlet gate 50 and the sea-side outlet gate 70. By connecting the wire means (not shown) and the power means (not shown) for providing the moving force in both directions to the wire means, the seawater-side inlet 11 and the reservoir-side inlet 21 are connected to each other by a vertical movement. ), The structure for controlling the opening and closing of the water outlet side 12 and the seawater side outlet 22, that is, when the seawater side inlet gate 40 is raised or lowered, the reservoir side inlet gate 60 is lowered or raised and lowered. When the water-side effluent gate 50 is elevated or lowered, the seawater-side effluent number 60 is lowered or elevated.

Therefore, the present invention can use the self-weight of the corresponding sluice when opening and closing the sluice, so relatively large power by the power means (not shown) is not required, thereby reducing energy.

In particular, the present invention, as shown in Figure 5a, the height of the seawater-side inflow gate 40, the reservoir-side inflow gate 60, the reservoir-side effluent gate 50 and the seawater-side effluent gate 70 correspond to each height It is formed at twice the height of the inlet and outlet, and at the same location with respect to the corresponding inlets and outlets, the seawater side inlet 11, the reservoir side inlet 21, the reservoir side outlet 12 and the seawater side outlet 22 Simultaneous shielding is possible.

Accordingly, in the present invention, when maintenance of the power generation unit 30 is required, the seawater-side inlet 11, the reservoir-side inlet 21, the reservoir-side outlet 12 and the seawater-side outlet 22 are all shielded. In the state, easy maintenance work is possible.

And, in the present invention, the height of the seawater side inlet gate 40, the reservoir side inlet gate 60, the reservoir side outlet gate 50 and the seawater side outlet gate 70 are respectively 2 of the heights of the corresponding inlets and outlets. As shown in FIG. 5B, even if the seawater-side inflow gate 40 is elevated and opens the seawater-side inlet 11, the state of the water-side inlet 21 is shielded by the reservoir-side inflow gate 60. Is maintained, and the seawater-side inlet at high tide as the shielding state of the seawater-side outlet 22 is maintained by the seawater-side outlet 70 even though the reservoir-side outlet 50 is elevated and the reservoir-side outlet 12 is opened. It is possible to provide a flow path of seawater through the first flow path 10 connecting 11 and the reservoir side outlet 12.

In addition, the present invention, as shown in Figure 5c, even if the reservoir side inlet gate 60 is elevated to open the reservoir side inlet 21, the shielding state of the sea side inlet 11 by the sea side inlet gate 40 Is maintained, even if the seawater-side effluent gate 70 is elevated and the seawater-side effluent 22 is opened, the water-side effluent 12 maintains the shielding state of the reservoir-side effluent 12 by the reservoir-side effluent gate 50, resulting in low water-side inlet during low tide. It is possible to provide a flow path of seawater through the second flow path 20 connecting 21 and the seawater-side outlet 22.

In this embodiment, the height of the sluice gate is illustrated as being formed twice as high as the height of the inlet and outlet, but the present invention is not limited to this, and the height of the sluice gate may be formed at least twice as high as the height of the inlet and outlet. .

Although the present invention has been described in connection with the above preferred embodiments, it is possible to make various modifications or variations without departing from the spirit and scope of the invention. Accordingly, the appended claims will cover such modifications or variations that fall within the spirit of the present invention.

1: tidal power generation device 10: 1st flow path
11: Sea water side inlet 12: Sea water side inlet
20: second flow path 21: reservoir side inlet
22: seawater outlet 25: cross passage
30: power generation unit 31: propeller
32: generator 40: seawater inflow gate
50: reservoir water outlet 60: reservoir water inlet gate
70: seawater side leakage gate B: seawall
S: Sea side R: Low side

Claims (3)

In the tidal power generation device is installed in a seawater separating the seawater side and the reservoir side, and generating power by using the flow of seawater between the seawater side and the reservoir side,
A first flow path connecting a seawater-side inlet formed on one side of the seawater side contacting the seawater side, and a water-side side outlet located in a diagonal direction of the seawater side inlet and formed on one side of the seawall side;
A reservoir side inlet formed on the other side of the seawall located along the direction of the seawater side inlet from the reservoir side outlet and formed on the other side of the seawall side, and a seawater side formed on the other side of the seawall side located in a diagonal direction of the reservoir side inlet. A second flow path connecting the outlet, and being formed to cross the first flow path;
A crossing passage formed at a crossing point of the first flow passage and the second flow passage in parallel with the installation direction of the seawall;
It includes at least one power generation unit installed on the cross passage,
The seawater-side inlet and the reservoir-side outlet are opened to generate electricity by the flow of seawater from the seawater side to the reservoir side through the first passage through the first flow path, and the reservoir-side inlet and the seawater-side outlet are opened. Tidal power generation device, characterized in that the power generation is made by the flow of seawater from the reservoir side through the second flow path to the seawater side through the power generation unit. According to claim 1,
The seawater-side inlet is installed at a higher position than the water-side outlet, the water-side inlet is installed at a higher position than the seawater-side outlet. According to claim 1,
A seawater-side inflow sluice for controlling the opening and closing of the seawater-side inlet;
A reservoir-side effluent gate that regulates opening and closing of the reservoir-side outlet;
A reservoir-side inflow gate for controlling the opening and closing of the reservoir-side inlet;
It includes a seawater side outflow gate to control the opening and closing of the seawater side outlet,
The seawater-side inflow gate and the water-side inflow gate interlock the opening and closing of the seawater-side inlet and the reservoir-side inlet by an interlocking elevation operation, but the height of the seawater-side inlet gate and the reservoir-side inlet gate is the seawater-side inlet and It is formed at least twice the height of the water-side inlet, and the seawater-side inlet and the water-side inlet can be simultaneously shielded at the same position with respect to the seawater-side inlet and the water-side inlet, and at the same time, either one is raised or lowered. The shielding state of the other is maintained even if either one of the seawater-side inlet and the reservoir-side inlet is opened,
The seawater-side effluent gate and the reservoir-side effluent gate are intermittently opened and closed to open and close the seawater-side outlet and the reservoir-side outlet by an interlocking and descending operation, wherein the height of the seawater-side outlet and the reservoir-side effluent is the seawater-side outlet and It is formed at least twice the height of the water-side outlet, and at the same position with respect to the sea-side outlet and the water-side outlet, simultaneous shielding of the sea-side outlet and the reservoir-side outlet is possible, and either one is raised or lowered. Tidal power generation device, characterized in that the other one of the shielding state is maintained even if any one of the water-side outlet and the water-side outlet.

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