KR101211321B1 - Generator using low tide and high tide - Google Patents

Abstract

PURPOSE: Power generation equipment using sea level changes is provided to stably supply electricity regardless of the weather. CONSTITUTION: Power generation equipment using sea level changes comprises a water storage tank(100), a power generator(130), a containing tank(150), a regulating pulley(170), a regulating tank(190), and a drain tank(210). The water storage tank holds water flowing in the flood tide. The power generator generates electricity using the water dropping from the water storage tank. The containing tank temporally holds the sea water which is used for operating the power generator. The regulating pulley comprises first and second rotary bodies(173,175). The first rotary body interlocks with the first rotary body, and moving length of the outer surface of the second rotary body is longer than the first rotary body. The first and second regulating tanks(193,195) of the regulating tank are mounted on one and the other sides of the first rotary body, respectively. The seawater flows into the regulating tank in the flood tide. The first and second drain tanks of the drain tank are mounted on the one and the other sides of the second rotary body, respectively.

Description

Generating device using difference between tides {GENERATOR USING LOW TIDE AND HIGH TIDE}

The present invention relates to a power generation apparatus using a difference between tides, and more specifically, water generated at high tide is generated by using a drop, and the water used for power generation uses water generated by the difference between tides. It relates to a power generation apparatus using only the difference between tides.

Most of the energy used in modern civilization comes from fossil fuels. Fossil fuels are useful for their low cost and high efficiency, but they cause serious environmental pollution and consequent climate change. Thus, in recent years, interest in the way of generating power using natural forces such as solar, wind, tidal, and the like is increasing. In particular, recently, the depletion of fossil fuels such as petroleum is rising, and as a result, the development using natural power is getting more and more competitive as the international crude oil price rises every day.

Among them, tidal power is generated by using the difference between high and low tide, that is, the tidal tide, which is spotlighted in that it is possible to stably and mass-generate without being affected by weather, rainfall or wind.

However, it is not uncommon for the sea to be tidal-powered all over the world, and general tidal power generation has a problem of causing serious environmental destruction because a large amount of seawall is to be constructed. In addition, the construction of large tidal power generation facilities is not easy because the tidal flats are destroyed and seriously affect the fishermen's livelihoods.

The west coast of Korea is a very suitable terrain for tidal power generation because the difference between tides is very large. Therefore, if tidal power generation system is developed that does not cause problems such as environmental pollution or tidal-flat damage, its utilization and economic power are expected to be very large. In particular, as today is suffering from power shortages, it is very useful to build a small-scale power generation facilities using the differences between tides only when local residents have a strong reaction against nuclear power generation.

KR10-1042971 a1 KR1988-0002256 a1 KR1980-0001714 a1

The present invention is to solve the above problems, by using the difference between the tide is used for power generation seawater at high tide, the seawater used for power generation is also pulled up using the water entered at high tide, drainage at low tide The purpose is to provide a power generation device using only the difference between tides that can achieve stable power generation.

The present invention as a technical concept for achieving the above object, the storage tank for storing the water coming in when the tide; A generator provided at a lower position than the storage tank to generate power by using a drop falling from the storage tank; A receiving tank for temporarily receiving and storing the seawater driving the generator; A control pulley provided with a first rotating body and a second rotating body provided to interlock with the first rotating body and having a greater movement distance of an outer circumferential surface than the first rotating body; It consists of a first control tank provided on one side of the first rotating body, and a second control tank provided on the other side of the first rotating body, the control tank and the second provided so that the sea water can flow when the tide is high. It may include a first drain tank provided on one side of the rotating body, and a drain tank composed of a second drain tank provided on the other side of the second rotating body.

In a preferred embodiment of the present invention, the water tank may be provided at a position corresponding to the water level when the bottom surface is low tide.

In a preferred embodiment of the present invention, the control pulley may be provided at a position higher than the water level at least when the tide.

 In a preferred embodiment of the present invention, the control tank, the first control tank and the second control tank is a seesaw movement around the first rotating body, the position at the time of the rising of the control tank of the control tank The upper surface is a position corresponding to the sea level when the tide, and the position when the adjustment tank is lowered may be a position corresponding to the sea surface when the lower surface of the control tank at low tide.

In a preferred embodiment of the present invention, the drainage tank, the first drainage tank and the second drainage tank is a seesaw movement around the second rotating body, the position of the drainage tank when the rising of the drainage tank The bottom surface is a position corresponding to the position of the sea surface at the time of low tide, the position at the time of the drainage tank can be such that the upper surface of the drainage tank corresponds to the position of the lower surface of the receiving tank.

In a preferred embodiment of the present invention, the control tank may be further provided with a speed control means.

Power generation method using the difference between tides according to the present invention, the step of introducing the seawater into the reservoir tank at high tide; Generating the introduced seawater using a drop; Moving seawater used for power generation to a drain tank; Raising the drainage tank by introducing the seawater introduced when the tide flows into the control tank; At low tide it may be configured to include the step of draining the water of the drain tank and the control tank to the sea.

According to the power generation apparatus using only the difference between tides according to the present invention, there is an advantage that does not cause environmental pollution or environmental destruction because it can be installed on the land without the need to build a large scale embankment. In addition, there is an advantage that stable power supply and supply and demand can be controlled because power generation is always possible regardless of weather and climate. In addition, since the power plant can be installed onshore, there is an advantage that the construction cost is low.

1 is a view showing a state of the first stage of the power generation apparatus using the difference between tides according to the present invention.
2 is a view showing a state of the second stage of the power generation device using the difference between tides according to the present invention.
Figure 3 is a view schematically showing the installation position of the power generator using the difference between tides according to the present invention.

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

1 is a view showing a state of the first stage of the power generation apparatus using the difference between tides according to the present invention, Figure 2 is a view showing a state of the second stage of the power generation apparatus using a difference between tides according to the present invention 3 is a view schematically showing the installation position of the power generator using the difference between tides according to the present invention. At this time, the reference line 10 in the horizontal direction in Fig. 1 and 2 indicates a position corresponding to the sea level when the ebb tide, the water level 110 of the reservoir tank 100 is a position corresponding to the height of the sea level during high tide do.

First, referring to the schematic configuration of the generator using the difference between tides according to the present invention with reference to Figure 1, the generator using the difference between tides according to the present invention is the storage tank 100, the generator 130, It may be configured to include a receiving tank 150, the control pulley 170, the adjustment tank 190, the drainage tank 210. For the convenience of description of the present invention, a detailed configuration is omitted, but the tanks may be connected to each other by a water pipe, and the water pipe may be further provided with a control valve. The connection relationship of each tank is demonstrated in detail later.

The storage tank 100 is a tank for storing the seawater that has been pushed in when the tide is naturally introduced by using the water level difference without using any power. The capacity of the storage tank 100 can be adjusted in various ways by the interval between the width of the bottom surface and the wall surface. That is, if the width of the storage tank 100 is widened, the capacity increases by that much. However, since the seawater is introduced into the height of the sea level caused by the difference between tides without applying power, the water level that can be filled in the storage tank 100 becomes a position corresponding to the water level at high tide. In this case, the corresponding position means basically the same position, but there may be some differences due to the installation position of the power generation facility, the topography, the change of the tide and the ebb and the time difference between the inflow of the seawater, and the like. Concept. Hereinafter, the same meanings are used in the detailed description of the present invention.

The bottom surface of the storage tank 100 is preferably to be a position corresponding to the water level when the ebb tide. Since the difference between tides is almost constant, in general, the deeper the bottom surface of the reservoir tank 100 in the same area can increase the amount of storage. However, the seawater stored in the storage tank 100 should be dropped into the basement to generate power, and the seawater dropped to the basement must be pulled up again using only the difference between tides. It is not desirable to do so. However, if necessary, if the location is narrow, it is also possible to adjust the low capacity by making the floor somewhat deeper.

The reservoir tank 100 may be installed directly on the beach or as shown in FIG. 3, and may be installed at a position corresponding to the sea level when the bottom surface of the land is at low tide. In addition, the water storage tank 100 may be made of an artificial structure as a whole, or may be replaced by temporarily storing a portion of seawater as a water repellent or a beam, if necessary.

The generator 130 is provided at a lower position than the storage tank 100 to generate power using seawater falling from the storage tank 100. The generator 130 may be provided below a few meters or several tens of meters from the bottom surface of the water storage tank 100. However, when the position of the generator 130 is too low, it is difficult to raise the fallen sea water again, it is usually preferable to be provided within the range of 3 to 5 times the difference between tides only. For example, the difference between the tide of the west coast of our country is about 9m, so in this case, it is preferable to provide the location of the generator 130 within the range of about 30 to 40m underground. Generator 130 is a known technique, various kinds of known can be used, a detailed description thereof will be omitted.

The receiving tank 150 temporarily stores and stores the sea water used to generate power from the reservoir tank 100 to the generator 130. Water temporarily stored in the storage tank 100 is discharged to the outside by the control tank 190 and the drain tank 210 to be described later. The control tank 190 and the drain tank 210 and the drainage method thereof will be described later. The receiving tank 150 is a place where the seawater turned around the generator 130 is temporarily stored, it should be provided at a lower position than the generator 130.

The control pulley 170 is used to move in conjunction with the control tank 190 and the drain tank 210 to be described later, the movement of the outer circumferential surface than the first rotating body 173 and the first rotating body 173 The second rotating body 175 has a large distance. The first rotating body 173 and the second rotating body 175 are configured to rotate in conjunction with each other. That is, when the first rotating body 173 rotates, the second rotating body 175 also rotates together. As the simplest example of such a configuration, as shown in the drawing, the first and second rotary bodies 173 and 175 are arranged side by side with concentric circles to form a single body. Hereinafter, as shown in the drawings, the moving distance of the outer peripheral surface according to the size ratio of the rotors 173 and 175 will be described based on the control pulley 170 having different. However, this configuration is only an example of the present invention and is not necessarily limited thereto. If necessary, a speed increase or reduction gear may be further provided between the first and second rotational bodies 173 and 175. In addition, the rotational speeds of the rotating bodies 173 and 175 of the same size may be different from each other to change the moving distance of the outer circumferential surface.

On the other hand, the position of the control pulley 170 is preferably provided at a position higher than the water level at least when the tide. Because, the control tank 190 to be described later to reciprocate in the vertical direction by the difference between the tidal only, the maximum distance that the control tank 190 can move without the injection of power from the outside as much as the difference between the tides to be. Therefore, in order to take full advantage of this, the position of the control pulley 170 is preferably provided at a position higher than the position of the high water level.

The adjustment tank 190 generates power required to raise the drainage tank 210 to be described later, and includes a first adjustment tank 193 and the first adjustment tank provided at one side of the first rotating body 173 described above. It consists of a 2nd adjustment tank 195 provided in the other side of the 1st rotating body 173. As shown in FIG. The control tank 190 is connected to a smaller diameter rotating body (or a relatively slow rotating speed) of the control pulley 170, the first control tank 193 and the second control tank 195 is a chain Are connected to each other by a connecting means such as a wire or the like. Thus, the first control tank 193 and the second control tank 195 are to seesaw movement around the first rotating body 173 described above. That is, when the first control tank 193 goes down, the second control tank 195 provided on the opposite side goes up by the same distance, and when the first control tank 193 goes up, the second control tank 195 goes down by the same distance. It is configured to.

At this time, in a preferred embodiment of the present invention, the position of the control tank 190 at the time of ascending so that the upper surface of the control tank 190 corresponds to the position corresponding to the sea level when the tide, the of the control tank 190 The position at the time of descent is such that the lower surface of the control tank 190 corresponds to the sea level when the ebb tide. This is because the power generation efficiency can be improved because it is the maximum distance to move the control tank 190 by the difference between tides without supplying power from the outside. And the adjustment tank 190 is provided so that the means for introducing or discharging the seawater is introduced to the seawater at high tide, it is configured to discharge the seawater at low tide. This configuration is naturally possible by connecting the control tank 190 with the sea through a water pipe (not shown).

Looking at the principle of movement of the control tank 190, first, when the first control tank 193 is up, the second control tank 195 is down, when the sea water is introduced into the first control tank (193) The first adjustment tank 193 becomes heavy and descends, and the second adjustment tank 195 on the opposite side is raised. As described above, the position where the control tank 190 can be raised to the maximum is because the upper surface of the control tank 190 corresponds to the high water level, the water pipe connected to the first control tank 193 when the tide is high. When opened, the seawater naturally flows into the first control tank 193 to fill the first control tank 193 with seawater without additional power input. At this time, the adjustment tank 190 is further provided with a speed adjusting means to adjust the falling speed of the control tank 190 or to stop as needed. For example, while the seawater is introduced into the first control tank 193, the first control tank 193 is stopped, and when the seawater is filled to lower the first control tank 193 at a constant speed. You can make it descend.

On the other hand, the water of the first control tank 193 that has fallen to the bottom surface drains to the sea at low tide to leave the first control tank 193 empty. Then, when the high water enters the second control tank 195, the second control tank 195 is lowered, and the first control tank 193 is up. The second adjustment tank 195 filled with seawater at the high tide and descends to the bottom surface discharges and emptyes the seawater again at low tide. By repeating the above-described method, the control tank 190 has one reciprocating motion while the high tide and the low tide are introduced twice.

The drain tank 210 is for pumping up the water stored in the receiving tank 150 to the sea, the first drain tank 213 provided on one side of the second rotating body 175, and the second rotating body ( It is configured to include a second drain tank 215 provided on the other side of the 175. Thus, the first drain tank 213 and the second drain tank 215 interlock with each other according to the seesaw motion of the control tank 190 described above to perform the seesaw motion together.

At this time, the position at the time of rising of the drain tank 210 becomes a position corresponding to the position of the sea surface when the bottom surface is low tide, the position at the time of the drop of the drain tank 210 is the upper surface of the drain tank 210 is accommodated It is preferable to make the position corresponding to the position of the lower surface of the tank 150. The position at the time of rising and falling of the drainage tank 210 may be higher than the sea level at low tide or lower than the lower surface of the receiving tank 150, if necessary, in some cases lower than the sea level or the receiving tank ( It may also be slightly higher than the bottom surface of 150). However, if the position at the time of rise is higher than the sea level, more force is required to raise, but the effect is insignificant, and if it is lower than the sea level, the water contained in the drain tank 210 cannot be drained naturally at low tide. . And when the position is lower than the lower surface of the receiving tank 150, the effect is almost or insignificant due to the half need more force to raise again, if the higher than the lower surface of the receiving tank 150, receiving tank 150 ), There is a problem that can not be naturally transferred to the drain tank 210 without a separate power input. Therefore, the position at the time of the rise of the drain tank 210 is a position corresponding to the position of the sea level when the bottom surface is low, and the position at the time of the drop is the upper surface of the drain tank 210 of the lower surface of the receiving tank 150 The most efficient operation is possible when the position corresponds to the position. The drain tank 210 is connected to the receiving tank 150 and the water pipe in the position at the time of falling.

In the above configuration, when the first drain tank 213 falls down to a lower position than the receiving tank 150, the seawater contained in the receiving tank 150 is transferred to the first drain tank 213. The water in the receiving tank 150 flows naturally according to the level difference without a separate power input. That is, by connecting the receiving tank 150 and the first drain tank 213 with a water pipe, or the like, when the first drain tank 213 is completely dropped, it connects the receiving tank 150 and the first drain tank 213. Opening the water pipe to naturally flow the water in the receiving tank 150 to the first drain tank (213). When the first drain tank 213 rises, the water pipe is closed, and when the second drain tank 215 completely falls, the water pipe is opened again to move the water in the receiving tank 150 to the second drain tank 215. Let's do it.

In the same manner as above, when the first drain tank 213 falls and comes to a lower position than the receiving tank 150, the water in the receiving tank 150 is transferred to the first drain tank 213, and the first drain tank ( The water filled in 213 rises to sea level at low tide and is drained into the sea. Then, when the second drain tank 215 interlocked with the first drain tank 213 comes in a lower position than the receiving tank 150, the water of the receiving tank 150 is transferred to the second drain tank 215 again. Thus, when high water enters, the second drain tank 215 is lifted up and the first drain tank 213 is sent down.

Looking at the power generation method using the difference between tides according to the present invention with reference to Figures 1 to 3, the step of introducing the seawater into the storage tank 100 at high tide, the step of generating the introduced seawater using a drop, The step of moving the seawater used for power generation to the drainage tank 210, the step of raising the drainage tank 210 by introducing the seawater introduced in the tide into the control tank 190 and during the low tide drainage tank 210 and the control tank ( It may be configured to include the step of draining the water of 190) to the sea.

In Figure 3, the generator 250 using the difference between the tide according to the present invention because the power generation using the high tide and the ebb tide is installed on the ground corresponding to the sea level when the installation location is installed on the shore at low tide It is preferable. Thus, it is possible to generate power by having a water pipe 270 that can flow in the sea water at high tide and a water pipe 280 that can flow in the sea water at low tide. And in order to prevent the water from entering the land at high tide, a generator 290 and the like must be provided between the generator 250 and the sea water.

The step of introducing the seawater into the reservoir tank 100 is to fill the seawater in the reservoir tank 100 when the tide by using the difference between the tide only when the tide, when the low tide begins to close the water gate of the reservoir tank 100 It is.

The seawater filled in the reservoir tank 100 is rotated several meters or tens of meters underground to turn the generator 130. As such, the step of confining the seawater at high tide and generating power by using it does not have much difference from the conventional hydroelectric principle. Therefore, in the present invention, there is a great feature in the method of discharging water below a few meters to several tens of meters below the ground by not applying or minimizing energy. Therefore, the operation process of the drain tank 210 and the control tank 190 is very important.

As described above, the adjustment tank 190 is provided at both sides of the control pulley 170. First, as shown in FIG. 1, when the first control tank 193 is raised and the second control tank 195 is in a state in which high water enters, the first control tank 193 fills the sea water in the first control tank 193. At this time, the second adjustment tank 195 is in an empty state. In addition, since the first control tank 193 has an upper surface at a position lower than the high water level, when the water pipe connected to the sea is opened, water is naturally filled without additional power.

On the other hand, in a state where the first control tank 193 is up and the second control tank 195 is down, the first drain tank 213 is also up and the second drain tank 215 is down. Therefore, while the seawater is filled in the first control tank 193, the water in the receiving tank 150 is transferred to the second drain tank 215.

When the first control tank 193 is filled with seawater and the second drain tank 215 is filled with the water in the receiving tank 150, the first control tank 193 is lowered. When the first control tank 193 is lowered, the second control tank 195 moving in conjunction with this is raised, the first drain tank 213 is lowered, and the second drain tank 215 is raised.

At this time, since the first adjustment tank 193 is lowered by the difference between the tides, if the first rotation body 173 and the second rotation body 175 of the control pulley 170 is the same ratio, the drain tank 210 also It can only be lifted by the same ratio. However, for efficient power generation, the location of the generator 130 may be installed below 20 to 40m as needed. In this case, the second rotating body 175 to which the drainage tank 210 is connected is larger than the first rotating body 173 to which the control tank 190 is connected, or the first rotating body 173 and the second rotating body ( 175) is to be provided with an increase gear to vary the rotation speed. Hereinafter, an example in which the size ratio of the first rotating body and the second rotating body is different will be described. However, this description does not exclude the right of the apparatus equipped with the gearbox.

As the ratio of the first rotating body 173 to the second rotating body 175 increases, a height capable of raising the drain tank 210 also increases. However, when the ratio of the first rotor 173 to the second rotor 175 increases, more force is required to pull up the drainage tank 210. Therefore, it is necessary to configure the capacity of the control tank 190 larger than the capacity of the drain tank 210.

As a result of the experiment, when the ratio of the first rotating body 173 and the second rotating body 175 is about 1: 2.5, the amount of water filled in the control tank 190 and the drainage tank 210 is about 5: 2. Turned out to be. Therefore, when the position of the generator 130 is 30m underground and the difference between tides is 9m (the difference between only the maximum tides on the west coast of Korea is 9.16m), the first and second rotors 173 and 175 When the ratio is about 1: 2.5, and the capacity of the control tank 190 is about 2.5 times the capacity of the drain tank 210, the difference between the tides according to the present invention is used without any additional power. Operation of the generator will be possible.

As such, when the first adjustment tank 193 and the first drain tank 213 fall, and the second adjustment tank 195 and the second drain tank 215 are raised, the first adjustment tank 1 193 and the water contained in the second drain tank 215 are all discharged to the sea. Since the bottom surface of the first control tank 193 and the bottom surface of the second drain tank 215 are at a height corresponding to the sea level at low tide, when the water gate is opened at low tide, it can be easily discharged to the sea through a water pipe. . Then, the water of the receiving tank 150 is moved to the first drain tank 213 that is dropped, and the second adjusting tank 195 that is raised waits for high water to enter.

When the high water comes again, the second control tank (195) is filled with water, and the water storage tank (100) is optionally further filled with water as needed. That is, the water in the storage tank 100 is filled by using the high water, depending on the power generation capacity may be filled with the sea water every time the high water comes in or may fill the sea water once or twice.

When the second control tank 195 is filled with water, the second control tank 195 is lowered. Then, the first adjustment tank 193 and the first drain tank 213 are raised. Water of the second control tank 195 and the first drain tank 213 is discharged back to the sea when the ebb tide. While repeating the above process, it is possible to generate power using only the difference between tides.

Although the present invention has been described in connection with certain exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Therefore, the scope of the present invention should not be limited by the described embodiments, but should be defined by the appended claims and equivalents thereof.

100: water tank
130: generator
150: receiving tank
170: pulley
173: first rotating body
175: second rotating body
190: adjustment tank
193: first adjustment tank
195: second adjustment tank
210: drain tank
213: first drain tank
215: second drain tank

Claims (8)

Reservoir tank 100 for storing the water coming in at high tide;
A generator (130) provided at a lower position than the storage tank (100) to generate power by using a drop falling from the storage tank (100);
Receiving tank 150 for temporarily receiving and storing the sea water driving the generator 130;
A control pulley 170 including a first rotatable body 173 and a second rotatable body 175 provided to interlock with the first rotatable body 173 and having a greater movement distance of an outer circumferential surface than the first rotatable body;
It consists of a first control tank 193 provided on one side of the first rotating body 173, and a second control tank 195 provided on the other side of the first rotating body 173, when the sea water is tide Control tank 190 provided to be introduced; And
Drain tank 210 consisting of a first drain tank 213 provided on one side of the second rotating body 175, and a second drain tank 215 provided on the other side of the second rotating body 175. ;
Power generation device using the difference between the tidal wave is configured to include.
Reserving water to trap and store the water coming in at high tide;
A generator 130 which is provided at a lower position than the storage water return to generate power using a drop falling from the storage water return;
Receiving tank 150 for temporarily receiving and storing the sea water driving the generator 130;
A control pulley 170 including a first rotatable body 173 and a second rotatable body 175 provided to interlock with the first rotatable body 173 and having a greater movement distance of an outer circumferential surface than the first rotatable body;
It consists of a first control tank 193 provided on one side of the first rotating body 173, and a second control tank 195 provided on the other side of the first rotating body 173, when the sea water is tide Control tank 190 provided to be introduced; And
Drain tank 210 consisting of a first drain tank 213 provided on one side of the second rotating body 175, and a second drain tank 215 provided on the other side of the second rotating body 175. ;
Power generation device using the difference between the tidal wave is configured to include.
The method according to claim 1,
The water storage tank 100 is a power generation device using the difference between tides, characterized in that the bottom surface is provided at a position corresponding to the water level when the ebb.
The method according to claim 1,
The control pulley 170 is a power generation device using the difference between tides, characterized in that provided at a position higher than the water level at least when the tide.
The method according to claim 1,
The control tank 190,
The first control tank 193 and the second control tank 195 is a seesaw movement around the first rotating body 173,
The rising position of the control tank 190 is a position corresponding to the sea surface when the upper surface of the control tank 190 tide, the position of the adjustment tank 190 when the lowering of the control tank 190 The generator using the difference between tides, characterized in that the lower surface of the tide is a position corresponding to the sea level when the tide.
The method according to claim 1,
The drain tank 210,
The first drain tank 213 and the second drain tank 215 is a seesaw movement around the second rotating body 175,
The position at the time of the rise of the drain tank 210 becomes a position corresponding to the position of the sea surface when the bottom surface of the drain tank 210 is low, and the position at the time of the drop of the drain tank 210 is the drain tank ( The power generation apparatus using the difference between tides, characterized in that the upper surface of the 210 is a position corresponding to the position of the lower surface of the receiving tank (150).
6. The method according to any one of claims 1 to 5,
The control tank 190, the power generation apparatus using the difference between tidal, characterized in that the speed control means is further provided.
Inflowing sea water into the storage tank 100 when the tide;
Generating the introduced seawater using a drop;
Moving the seawater used for power generation to the drain tank 210;
Raising the drainage tank 210 by introducing the seawater introduced when the tide flows into the control tank 190;
Draining the water of the drain tank 210 and the control tank 190 to the sea at low tide;
Power generation method using the difference between tides, characterized in that configured to include.

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