KR20180042074A - High position turbine tidal electric power generation system - Google Patents

Abstract

The present invention relates to a tidal power generation system which is to build a tidal power generation facility without cutting an estuary weir in an existing estuary weir in which the tidal power generation facility is not built, by using one among a tunnel, a pipe, and a tube. The tidal power generation system does not need to cut the estuary weir by installing the pipe connecting inner sea and outer sea on the existing estuary weir and generates the power by enabling water to flow due to a different water level of the inner sea and the outer sea into a water conveying pipe by connecting the pressure applied to the inner sea and the pressure applied to the outer sea by connecting the inner sea and the outer sea by the pipe. Also, the tidal power generation system enables tidal power generation by generating the different water level by ebb and flow without newly building the estuary weir in an estuary of a river meeting a sea. The tidal power generation system generates the different water level by connecting the lowest part in the ebb and an end in which seawater flows inside in the flow by the pipe and generates the power by using the different water level.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a tidal power generation turbine,

The present invention relates to a tidal power generation method, which is one of the methods of generating power using seawater. More particularly, the present invention is characterized in that the position of a power generating turbine rotated by a flow of algae is set at a position more than a water inlet or a water outlet.

The tidal power generation method is to construct a dam in the bay surrounded by the estuary or the land that is tangential to the sea, and a tunnel is formed in the lower part of the dam through the inland and offshore waters separated by the dam and the turbine is positioned in the middle of the tunnel. The water level difference between inland water and offshore water during tide and ebb is shown as the flow velocity, and the flow rate drives the generator by rotating the turbine to produce electric power.

At this time, the position of the turbine is lower than the water surface level of the outermost or inland water, and is horizontally laid out to the position of the water inlet and the water outlet.

In this case, the aberration wing and the turbine are located below the water surface. Therefore, in order to construct the tidal power generation facility, the dam construction should be carried out before the dam construction, and then the turbine installation work should be carried out inside the water dam facility.

If a tidal power plant is to be installed in an existing estuary dam without a tidal power plant, a part of the dam should be cut and a tidal power plant should be installed after part of the estuary dam is constructed.

In addition, tidal power can not be generated because it is impossible to generate a difference in water level between tide and ebb without constructing an estuary dam in the estuary of the river which is in contact with the sea. Because there is no estuary dam, it is not possible to create a difference in water level between tide and ebb.

Therefore, it is possible to construct a tidal power generation facility without cutting the existing estuary dam, and it is possible to generate the tidal difference between tide and ebb without constructing an estuary dam in the estuary of the river that touches the sea, , Clean energy, and the need for alternative energy sources.

In the tidal power generation system, the turbine generating electricity is located at a higher level than the sea surface or inland sea of the outer sea so that the tidal power generation facility can be constructed without constructing a water film for installing the turbine.

Another object of the present invention is to enable tidal power generation by generating a difference in water level between tide and ebb without installing an estuary dam in the estuary of the river which is in contact with the sea.

In the present invention, when tidal power is installed in an existing estuary dam in which a tidal power generation facility is not installed, the position of the turbine located inside the diverging pipe is higher than the sea level of the inland sea or the sea level of the outer sea, , Positioning the inlet and outlet at the seabed of the outer sea, positioning the outlet and inlet of the opposite side to the seabed of the seawater, positioning the turbine above the water surface of the seawater or the outer sea, And a step of providing an inhaler.

In addition, if tidal power is to be generated without building an estuary dam in the estuary which is in contact with the sea, a step of installing the inlet at the end of the sea level during the tide, a step of installing the outlet at the end of the sea level during the tide, a tunnel connecting the inlet and the outlet A step of installing a pipe which is one of pipes or pipes, and a step of installing a turbine in a pipe which is one of a tunnel, a pipe or a pipe connecting the inlet and the outlet.

The present invention can construct a tidal power generation facility without cutting the dam in an existing estuary dam in which tidal power is not built, and it is also possible to construct a tidal power generation facility without tidal dams Generate level difference to enable tidal power generation.

By placing the turbine generating electricity in the tidal power generation system higher than the sea level of offshore or inland sea, it is not necessary to construct a water barrier for the power generation facility, and it is possible to work in the state where the sea water is removed in case of a failure in the turbine during power generation .

Enabling tidal power without building an estuary in a river basin can save enormous funding for the construction of the estuary, and it does not have to destroy the tidal flat.

1 is a cross-sectional view showing a state of power generation during a tidal time of a general tidal power generation method.
Fig. 2 is a cross-sectional view showing a state of power generation at the time of low tide of a general tidal power generation method. Fig.
3 is a cross-sectional view showing the power generation state of the tidal power generation system in which the power generation turbine according to the present invention is higher than the water inlet or the water outlet in the existing barb
Fig. 4 is a cross-sectional view showing the power generation state of the tidal power generation system in which the power turbine according to the embodiment of the present invention is positioned higher than the water inlet or the water outlet,
Fig. 5 is a plan view showing the tide at the river mouth and the sea level at the time of ebb tide in contact with the sea.
6 is a cross-sectional view showing a power generation state of a tidal power generation system in which a power generation turbine according to an embodiment of the present invention is located at a higher position than a water inlet or a water outlet in a river mouth contacting the sea

The present invention will now be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view showing a state of power generation during a tidal time of a general tidal power generation method. The water level of the outer sea 11 is higher than the level of the inner sea 12 inside the dam, so that the water flows into the inlet / outlet 14 and the turbine is rotated while leaving the outlet 15. At this time, the position of the turbine 16 is lower than the water surface of the outer sea 11 and lower than the water surface of the inner sea 12.

2 is a cross-sectional view showing a state of power generation at the time of low tide of a general tidal power generation method. The water level of the internal water 12 is higher than the water level of the external water 11 at the time of ebb flow so that the water enters through the outlet port or inlet port 15 and rotates the turbine and exits the inlet / outlet port 14.

FIG. 3 is a cross-sectional view illustrating a power generation system in a tidal power generation system in which a power turbine according to the present invention is located at a higher position than a water inlet or a water outlet.

As shown in the figure, there is no tidal power generation facility in the existing estuaries. In this case, in order to construct the tidal power generation facility, it is necessary to install a trench in the part where the tidal power generation turbine is to be installed, cut a part of the riverbed, mount a tunnel or pipe that can reciprocate the water, and install the turbine therein. However, the present invention provides a method for constructing tidal power generation without cutting the harbor. As shown in the drawing, a pipe, which is one of a tunnel, a pipe or a pipe, having an internal resistance (12) and an external electric current (11), is laid on an overhang. One end of the water pipe 22 is installed in the outer sea 11 and is located lower than the water level at the time of ebb. The other end of the diaphragm pipe (22) is located in the deep sea water (12). In other words, even if the water level of the internal water 12 and the external water 11 is changed by tide and ebb, neither end of the water pipe 22 is exposed to air in any case. That is, no air is introduced.

After connecting the internal water 12 and the external water 11 with the water pipe 22, the air inhaler attached to one side of the water pipe 22 is opened and the air inside the water pipe is discharged to the outside by using the compressor. The water in the outer water 11 and the inner water 12 is sucked into the water pipe through both ends of the water pipe 22 when the air in the water pipe 22 escapes to the outside by the air suction unit and the compressor. When all the air inside the water pipe 22 finally passes out and water is filled in the water pipe 22 instead, the air inhaler is closed.

In this case, the external water 11 and the internal water 12 are connected by the water pipe 22. In other words, the pressure on the water surface of the seawater and the pressure on the surface of the seawater are transmitted to each other by the water pipe. As a result, since the water surface of the outer sea 11 is higher than the water surface of the inner sea 12, the water of the outer sea 11 flows to the inner sea 12 through the water pipe 22. Water flows through the inside of the water pipe (22), and the turbine (16) mounted inside the water pipe is rotated to generate electricity. The flow rate appears as the difference between the sea level and the sea level.

The shape of the water pipe can be a circular pipe.

The shape of a tunnel, pipe, or pipe is a circular shape, but not necessarily limited thereto, and may be formed in various shapes such as a square or a triangle. Tunnels, pipes and pipes are not necessarily limited to this, but may be constructed in various forms, such as water coming and going without coming out.

The material of the tunnel, pipe, and pipe may be concrete, PVC, but it is not limited to this, but it may be a material that blocks the inside and outside of the tunnel, pipe, and pipe so that outside air does not flow into the inside.

The position of the turbine is higher than the water surface of the outer sea (11) and higher than the water surface of the sea water (12). It is not necessary to specify the position of the turbine at the highest position of the riverbank. It may be mounted anywhere higher than the water surface of the outer sea (11) and the inner sea (12).

FIG. 4 is a cross-sectional view showing a state of power generation at an ebb of a tidal power generation system in which a power turbine according to the present invention is located at a higher position than a water inlet or a water outlet.

Because water surface of inland sea (12) is higher than water of outer sea (11) at low tide, water of inland water flows to outer sea through water pipe. The water thus generated is generated by rotating the turbine mounted inside the water pipe 22. As the tide and ebb tide are repeated, water circulates inside the water pipe 22 and the turbine is rotated to generate electricity. That is, the tidal power generation system in which the power generation turbine of the present invention is positioned higher than the water inlet or the water outlet is a system capable of tidal power generation without cutting off the dam, even in the existing dam, where the tidal power generation facility is not built.

Fig. 5 is a plan view showing the tide at the river mouth in contact with the sea and the sea level at the time of ebbing.

It is the estuary of the river where the riverbank is not constructed. At the end of the tide, the end of the sea level (31) is the end of the sea when the tide comes up. At low tide, the end of the sea level (32) is the last part of the sea to escape during low tide. In any case during the year, the level of seawater does not drop below the sea level (32) at low tide.

6 is a cross-sectional view showing a power generation system of a tidal power generation system in which a power generation turbine according to the present invention is located at a higher position than a water inlet or a water discharge port in a riverbed contacting the sea.

It is a system that enables tidal power generation using ebb and flow of tide and ebb tide in a river that has not been constructed.

The inlet port 45 is mounted on the end of the sea level surface 31 when tilting and the outlet port is mounted on the sea floor surface end point 32 when the tilted port is tapped. Then, the inlet port and the outlet port are connected with the water pipe 22. The compressor is connected to the air suction unit (21) installed on one side of the water pipe to discharge the air inside the water pipe to the outside of the water pipe. The air inside the water pipe 22 is drawn out to the outside by the air inhaler 21 and the compressor and the seawater and the river are sucked into the water pipe through both ends of the water pipe 22. When all the air inside the water pipe 22 finally passes out and water is filled in the water pipe 22 instead, the air inhaler is closed.

As a result, the sea 34 on the side of the discharge port 46 and the river 33 on the side of the inlet 45 are connected by the water pipe 22. Since there is no air in the water pipe 22 and it is filled with water only, the atmospheric pressure near the inlet port is transmitted to the outlet port. The water of the river 33 flows into the sea 34 through the water pipe 22 because the water surface of the river 33 is higher than the water surface of the sea 34. Water flows through the inside of the water pipe (22), and the turbine (16) mounted inside the water pipe is rotated to generate electricity. The flowing speed is represented by the difference between the water level near the inlet of the steel pipe connected to the water pipe and the water level near the sea outlet. As the water level difference is highest at low tide, the generation amount is the highest, and when the tide starts, the water level difference gradually decreases, and when the tide reaches the inlet 45, the water level difference does not occur. Thereafter, as the ebb tide proceeds again, when the water starts to fall off, a water level difference occurs, and the inside of the water pipe 22 flows and water starts to be generated.

The water level difference is different depending on where the inlet 45 is located. Since water always flows through the river, the water level differs depending on which part of the river the inlet is mounted to. It is not necessary to limit the inlet to the sea-level surface end 31 during tide. When the inlet is located at the end of the sea surface (31), the maximum water level difference between the tide and the ebb is obtained. If the inlet is located downstream of the sea edge (31), the difference between the tide and the ebb The water level difference can be obtained, and if it is positioned upstream of the end portion 31 of the sea surface during the tide, it is possible to obtain a water level difference larger than the tide difference between tide and ebb.

11; Outer Sea 12; Inland Sea
13; a bottom wall 14; an inlet and outlet
15; outlet and inlet 16; turbine
21, an air discharge switch 22, a water pipe
31; end of sea level at high tide 32; sea level end at low tide
33; river 34; sea
41; water level at high tide 42; water level at low tide
River water level 44;
45; an inlet port 46;

Claims (5)

In the tidal power generating electricity by the tide of the tide and the ebb tide, the step of installing the inlet and the outlet on the side of the sea, the step of installing the outlet and the inlet on the inland side, the pipe passing over the riverbank and the inlet and outlet, And a step of installing a power generation turbine inside the pipe, wherein the power generation turbine is positioned higher than the water inlet or the water outlet, The tidal power generation system according to claim 1, wherein the power generation turbine which places the power generation turbine inside the pipe higher than the inlet and outlet, the outlet and the inlet is higher than the water inlet or the water outlet, The tidal power generation system according to claim 1, wherein the power turbine in which the air suction device is installed on one side of the pipe is located higher than the water inflow port or the water discharge port, The method of claim 1, wherein the inlet of the sea-side pipe is positioned lower than the lowest tidal level of the year, and the inlet of the inner-side pipe is located at the deepest point of the inner- system In the estuary of the river in which the estuary is not constructed, the inlet is located at the end of the sea surface that flows into the river at the time of tide, and the outlet is located at a lower level than the lowest tide level of the year and is higher than the water inlet or water outlet Tidal power system in

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