KR101073462B1 - Tidal power generation system - Google Patents

Abstract

The present invention relates to a tidal power generation system, and more particularly, a first reservoir having first and second floodgates; A second reservoir installed adjacent to the first reservoir and provided with third and fourth floodgates; A third reservoir installed adjacent to the first reservoir and the second reservoir, and connected to the second and fourth gates; It is installed between the first reservoir and the second reservoir, and comprises a power generation facility for discharging the water of the first reservoir to the second reservoir to rotate the aberration, and generate electricity by the rotation of the aberration.
In the tidal power generation system of the present invention, power generation is continuously performed by opening and closing operations of the first and second floodgates and the third and fourth floodgates, and thus tidal power generation is continuously performed not only at high tide and low tide but also at other empty times. And it is easy to adjust the power generation time, when using the same number of conventional aberrations, there is an advantage that the amount of power generation compared to the bipolar power generation.

Description

Tidal Power Generation System {TIDAL POWER GENERATION SYSTEM}

The present invention relates to an tidal power generation system capable of performing a bipolar power generation without changing the rotation direction of the aberration by the opening and closing operation of the water gate.

Tidal power generation is a power generation system that converts potential energy into kinetic energy and converts it into electrical energy from tidal water level difference.

In other words, the sea level rises gradually from low tide to high tide, and the tides move horizontally toward the coast. At this time, when the aberration is provided on the inflow direction of the tidal current, the aberration is rotated by the tidal power, and the way of generating electric power by driving the generator by the rotational force is tidal power generation. As long as the earth and moon exist, even tidal lateral movement is always performed, and much research on tidal power generation, a next-generation energy source, has been conducted.

This 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.

Forging knowledge is a development that uses a water level difference between seawater and a lake by forming a lake, and demodulation knowledge is generally used when two lakes can be formed on a terrain.

An example of a typical tidal power plant, the Lance tidal power plant in France is capable of single-flow, pumped and double-flow generation.

Single-flow power generation is a method in which unidirectional power generation is performed from the open sea to the lake, or from the lake to the open sea.

In addition, bipolar power generation is a method of generating power in both directions by using the water level difference between the open sea and the lake (George) generated at high and low tide. This method starts the development from the open sea to the lake and closes the gate when the water level between the open sea and the lake becomes equal. Later, when the water level of the lake is higher than that of the open sea, the gate is opened again and the water wheel is reversed to generate power.

Lance tidal power plants are more complicated than single-flow aberrations because they require the installation of two-way aberrations. In particular, the dual-generation power generation takes place from the offshore to the lake, and then again when the water level of the lake is higher than the offshore. This is a rather difficult problem to apply to terrain such as Korea.

In addition, the bipolar power generation is the same as performing the power generation twice by using the water level difference between the open sea and the lake, and thus, the amount of power generation is small because the water level difference between the open sea and the lake is lower than that of the single flow power generation. Therefore, there is a disadvantage in that the number of aberrations must be increased to maintain the same amount of power generation as in the case of two-stage power generation.

In addition, the tidal power plant of Sihwa Lake on the west coast of Korea, as shown in FIG. have.

Since the unidirectional power generation can be generated only at high tide, the utilization rate is low, and there is a disadvantage in that power supply and demand for a desired time period cannot be smoothly performed and power generation can not be arbitrarily adjusted. In addition, the west coast of Korea has a disadvantage in that the amount of power generation is not constant because the level change of tidal tides is not uniform.

The present invention is to provide a tidal power generation system capable of performing a bipolar power generation by the opening and closing operation of the water gate without changing the rotation direction of the aberration. This is to provide tidal power generation system that can perform continuous power generation in both directions using aberration equipment in one direction.

In addition, the present invention is to provide a tidal power generation system that can perform a bipolar power generation without affecting the change of the sea water (change of water level, such as high tide, low tide).

The present inventors have completed the present invention by knowing that the four gates installed in the three reservoir tanks can be properly opened and closed, and the bidirectional power generation can be performed even with a unidirectional aberration power generation facility.

Thus, the present invention includes a first reservoir having first and second floodgates; A second reservoir installed adjacent to the first reservoir and provided with third and fourth floodgates; A third reservoir installed adjacent to the first reservoir and the second reservoir and connected to the second and fourth gates; It is installed between the first reservoir and the second reservoir, and comprises a power generation facility for rotating the aberration by discharging the water of the first reservoir to the second reservoir, and generating electricity by the rotation of the aberration, A tidal power generation system in which power generation is continuously performed by opening and closing operations of first and second flood gates and third and fourth flood gates is provided.

The first and fourth gates may be opened and closed at the same time, and the second and third gates may be opened and closed at the same time, and the first and second gates may be opened and closed at intersections to continuously generate power.

In the first reservoir, the first water gate and the second water gate may be installed to face each other.

In the second reservoir, the third and fourth gates may be installed to face each other.

The first and third floodgates may be installed in a trend with each other.

The first and third sluice gates may have inflow and outflow of seawater.

The first and fourth gates may be opened, and the second and third gates may be closed to allow seawater to flow into the first gate and pass through the power generation facility and the fourth gate to be stored in the third reservoir.

The first and fourth gates may be closed, and the second and third gates may be opened to allow seawater stored in the third reservoir to flow into the second gate and flow out through the power generation facility and the third gate.

The present invention can use the aberration that rotates in a single direction, it is possible to perform a dual-flow power generation by continuing to operate the power generation facilities in other empty time as well as high water, low water.

In addition, the present invention is capable of the above-described dual-generation power generation, it is possible to control the level difference between the reservoir tank, it is easy to adjust the amount of power generation and the generation time.

In addition, since the present invention performs a bipolar power generation using aberrations rotating in a single direction, when the same aberrations are used, the amount of power generation is larger than that of the conventional bipolar power generation.

The following drawings, which are attached in this specification, illustrate preferred embodiments of the present invention, and together with the detailed description thereof, serve to further understand the technical spirit of the present invention. It should not be interpreted.
1 is a conceptual view of the development principle of tidal power plant in Sihwa Lake, west coast of the prior art,
2 and 3 are plan views of an example tidal power generation system according to the invention,
4 to 6 show the construction of an example tidal power generation system according to the present invention.

The tidal power generation system of the present invention includes a first reservoir having first and second sluices provided to face each other; A second reservoir installed adjacent to the first reservoir and provided with a third and fourth water gates facing each other; A third reservoir installed adjacent to the first reservoir and the second reservoir and connected to the second and fourth gates; It is installed between the first reservoir and the second reservoir, and comprises a power generation facility for discharging the water of the first reservoir to the second reservoir to rotate the aberration, and generate electricity by the rotation of the aberration.

The tidal power generation system continuously generates power by opening and closing operations of the first and second floodgates and the third and fourth floodgates.

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

2 and 3 show a plan view of the tidal power generation system according to the present invention, Figure 2 is when the sea water of the open sea 50 is high tide, Figure 3 is when the sea water of the open sea 50 is low tide.

The first reservoir 10 is provided with a first floodgate 11 and a second floodgate 12. It is preferable that the first floodgate 11 and the second floodgate 12 are installed in parallel with each other.

The second reservoir 20 is installed adjacent to the first reservoir 10.

The second reservoir 20 is provided with a third floodgate 21 and a fourth floodgate 22, and the third floodgate 21 and the fourth floodgate 22 are preferably installed in parallel with each other.

In addition, it is preferable that the first floodgate 11 of the first reservoir 10 and the third floodgate 21 of the second reservoir 20 are installed in series with each other.

The first floodgate 11 of the first reservoir 10 and the third floodgate 21 of the second reservoir 20 are connected to the outer sea 50 to inflow and outflow of seawater.

The second floodgate 12 of the first reservoir 10 and the fourth floodgate 22 of the second reservoir 20 are connected to the third reservoir 30.

Specifically, after power generation is performed from the first reservoir 10 to the second reservoir 20, the seawater stored in the second reservoir 20 flows out to the third reservoir 30 through the fourth water gate 22. In addition, the seawater stored in the third reservoir 30 is introduced into the first reservoir 10 through the second water gate 12.

It is preferable that the 2nd water gate 12 of the 1st water tank 10 and the 4th water gate 22 of the 2nd water tank 20 are installed in series with each other.

Each of the sluice gates 11, 12, 21 and 22 can be designed and arranged so that the inflow and outflow of seawater can be free, which is not particularly limited in the present invention.

Each of the sluices (11, 12, 21 and 22) can be opened and closed operation using a mechanical, hydraulic and pneumatic.

In addition, the water gate may appropriately select the position of the water gate, the size of the water gates, the distance between the water gates, the number of the water gates installed, and the water gate opening and closing method in consideration of the characteristics of the power plant installation topography, the power generation plan and the like. Preferably, 10 or more consecutively installed in each hydrologic position is preferable, but the present invention is not limited thereto.

After the tidal power generation is performed, the third reservoir 30 serves as a reservoir for removing water stored in the first reservoir 10 or the second reservoir 20 to continuously perform the next tidal power generation.

In addition, even if the sea water of the external sea is not supplied, it serves as a supply source for supplying water by flowing to the first reservoir 10 or the second reservoir 20 so that continuous tidal power generation can be performed.

The third reservoir 30 may be separately installed as shown in FIGS. 2 and 3.

In addition, the third reservoir 30 is a remaining portion of the lake after the construction of the scavenger and the first reservoir 10 and the second reservoir 20 as shown in the construction of the tidal power generation system of FIGS. Can be replaced.

4 to 6 is a construction state of the tidal power generation system according to the arrangement of the hydrology, respectively. In detail, FIG. 4 illustrates that the first gate 11 and the second gate 12 are installed in parallel with each other, the third gate 21 and the fourth gate 22 are installed in parallel with each other, and the first gate ( 11), the third floodgate 21, the second floodgate 12, and the fourth floodgate 22 are in a construction state provided in series with each other in series.

5 shows that the second floodgate 12 is installed in the lateral direction with respect to the first floodgate 11, the fourth floodgate 22 is installed in the lateral direction with respect to the third floodgate 21, and the first floodgate ( 11) and the third floodgate 21 are installed in series with each other in series, and the second floodgate 12 and the fourth floodgate 22 are installed in parallel with each other.

6 shows that the second floodgate 12 is installed in the lateral direction with respect to the first floodgate 11, the third floodgate 21 and the fourth floodgate 22 are installed in parallel with each other, and the first floodgate 11 is provided. ) And the third floodgate 21 are installed in series with each other in series.

The power generation facility 40 is installed between the first reservoir 10 and the second reservoir 20.

The power generation equipment 40 is particularly limited as long as it can discharge the seawater of the first reservoir 10 to the second reservoir 20 to rotate the aberration, and convert the rotational energy into electric energy by the rotation of the aberration. It doesn't.

The aberration of the present invention is used to rotate only by the water flow in one direction in consideration of economic aspects such as power generation efficiency improvement and power generation operation and maintenance costs. Specifically, the present invention rotates only by water flowing from the first reservoir tank 10 to the second reservoir tank 20.

The power generation facility 40 may be installed by adjusting the position, the interval and the number of gates in consideration of the planning of the amount of power generation. Preferably, at least 10 aberrations are provided.

In the tidal power generation system of the present invention, the first gate and the fourth gate are simultaneously opened and closed, the second gate and the third gate are simultaneously opened and closed, and the first gate and the second gate are opened and closed at the intersection to continuously generate power. . That is, bipolar power generation can be performed without changing the rotational direction of the aberration.

Specifically, when the open sea 50 is high water, as shown in FIG. 1, the first water gate 11 of the first reservoir 10 and the fourth water gate 22 of the second reservoir 20 are opened, and the first water reservoir The second floodgate 12 of 10 and the third floodgate 21 of the second reservoir 20 are closed. In this case, the seawater flows into the first water gate 11 of the first reservoir 10 to generate power by the power generation facility 40, and the seawater passing through the fourth water gate 22 of the second reservoir 20 is The third reservoir 30 is stored.

In addition, when the outer sea 50 is a low water, as shown in FIG. 2, the 1st water gate 11 of the 1st reservoir 10 and the 4th water gate 22 of the 2nd reservoir 20 are closed, and a 1st water tank The second floodgate 12 in (10) and the third floodgate 21 in the second reservoir 20 are open. In this case, the seawater stored in the third reservoir 30 flows into the second floodgate 12 of the first reservoir 10, and power generation is performed by the power generation facility 40, and the third floodgate of the second reservoir 20 is performed. Seawater passing through the 21 is discharged to the open sea (50).

The tidal power generation system of the present invention is capable of performing at least four consecutive generations per day, so that the current generation capacity of the Sihwa Lake is about 550 million Kw when maintaining the same generation installation terrain, water height difference, and aberration number as that of the Sihwa Lake. At least twice as much power as / h can be achieved.

In addition, the tidal power generation system of the present invention performs a dual-flow power generation using the aberration and the reservoir to rotate in a single direction, it is possible to control the water level difference between the reservoir. Since the water level difference between the water tanks can be controlled, when the same number of aberrations are used, there is an advantage in that the amount of power generation is larger than the bipolar power generation in which the water level difference gradually decreases as compared with the initial stage.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto, and the technical spirit of the present invention and the following will be understood by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

10: first reservoir
11: first floodgate 12: second floodgate
20: second reservoir
21: third floodgate 22: fourth floodgate
30: third reservoir
40: power generation equipment
50: Offshore

Claims (8)

A first reservoir having first and second floodgates;
A second reservoir installed adjacent to the first reservoir and provided with third and fourth floodgates;
A third reservoir installed adjacent to the first reservoir and the second reservoir and connected to the second and fourth gates;
It is installed between the first reservoir and the second reservoir, and discharges the water of the first reservoir to the second reservoir to rotate the aberration, and comprises a power generation facility for generating electricity by the rotation of the aberration,
An tidal power generation system in which power generation is continuously performed by opening and closing operations of the first and second flood gates and the third and fourth flood gates.
The tidal power generation system according to claim 1, wherein the first and fourth gates are opened and closed at the same time, and the second and third gates are simultaneously opened and closed. system.
3. The tidal power generation system according to claim 2, wherein the first reservoir is installed in parallel with each other.
The tidal power generation system according to claim 2, wherein the second reservoir has a third flood gate and a fourth flood gate installed in parallel with each other.
The tidal power generation system according to claim 3 or 4, wherein the first and third gates are installed in series with each other.
The tidal power generation system according to claim 5, wherein the first and third sluice gates have seawater flowing in and out of the sea.
The method of claim 6, wherein the first and fourth gates are opened, and the second and third gates are closed so that the seawater flows into the first gate, and passes through the power plant and the fourth gate and stored in the third reservoir. Tidal power generation system.
The method of claim 6, wherein the first and fourth gates are closed, the second and third gates are opened so that the seawater stored in the third reservoir enters the second gate and flows out through the power plant and the third gate. Tidal power generation system.

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