KR102620725B1 - A floating tidal power generation system consisting of a vertical shaft turbine - Google Patents

Abstract

The present invention relates to a floating tidal power generation system consisting of a vertical axis turbine, which includes a tidal power generation unit that generates power from the flow energy of the tidal current, a floating body that floats the tidal power generation unit on the water surface, and a radial body that is spaced apart from the floating body at a predetermined distance. A hull portion arranged in multiple numbers to flow up and down by waves to relieve shock, a thrust portion connecting the floating body and the current power generation unit to the hull portion, one end of which is connected to the hull portion, and the other end of which is connected to the seafloor topography. It is characterized in that it includes a connected mooring part.

Description

{A FLOATING TIDAL POWER GENERATION SYSTEM CONSISTING OF A VERTICAL SHAFT TURBINE}

The present invention relates to a floating tidal power generation system consisting of a vertical axis turbine. More specifically, the vertical axis turbine is attached to a floating structure to convert the strong flow energy generated by the tidal range into mechanical energy of the turbine to produce electric power. It relates to a floating tidal power generation system consisting of a vertical axis turbine.

The need to develop marine energy is emerging to prepare for the transition to a carbon-neutral society and lead the Green New Deal, and as part of the Ministry of Oceans and Fisheries' efforts to meet the government's 2050 carbon neutral plan, research is being conducted on the development of a tidal energy-ESS linkage system. It is becoming.

In general, marine energy that produces electricity using seawater is divided into wave power, tidal power, tidal power, and ocean temperature difference power depending on the method. Wave power generation is a method of producing electricity using the up and down movement of the sea surface caused by waves, tidal power generation is a method of producing electricity using tidal energy generated by the gravitational force of the moon or sun, and tidal power generation is a method of generating electricity using tidal energy generated by the ebb and flow of the tide. This is a method of producing electricity using, and ocean temperature difference power generation is a method of producing electricity using the temperature difference between the surface and deep seawater.

Here, tidal power generation refers to producing electricity by installing a water turbine generator (turbine) in a place where the current is fast. Unlike tidal power generation that uses the difference in tides by installing a breakwater on the coast, dams or This method uses ocean currents to turn turbines installed in the sea without installing a breakwater.

This type of tidal power generation costs less than tidal power generation because there is no need to build dams or breakwaters to secure reservoirs, and it does not interfere with the movement of fish and does not affect the surrounding ecosystem as it allows free passage of ships. It can be said to be an environmentally friendly alternative energy system.

In particular, tidal power generation is evaluated as the most environmentally friendly power generation method in that it utilizes natural tidal flows.

The above-mentioned tidal power generation is a method of producing electricity using the kinetic energy of tidal currents, and is divided into a submerged method installed in the sea and a floating method using power generation lines floating on the sea.

Submerged tidal power generation is a method of installing power generation facilities on the underwater seabed and generating power using a propeller that rotates due to the current. However, construction is difficult because a huge structure must be built on the seafloor and the core part must be installed underwater. There is a problem that the installation location is extremely limited due to the limitation of the strong flow rate suitable for the propeller method.

In the case of conventional tidal power generation devices, most of them use submerged tidal power generation, but the support structure and installation costs for this traditional tidal power generation system account for about 41% of the total, which is a major obstacle to empirical research and commercialization.

In addition, due to the nature of the support method, installation and maintenance costs increase significantly in relatively deep water, so the use of tidal energy in medium and large water depths is limited to date.

On the other hand, in the case of floating tidal current power generation, power generation is generated using a water wheel rather than a propeller. Not only does it improve power generation efficiency by utilizing the high speed of water near the sea level, but it also makes it possible to manufacture it on land because the power generation facility is installed on a ship. This system generates power by attaching a tidal turbine to a floating structure and has the advantage of not being limited by water depth.

In addition, when selecting a sea area for application of the above-described tidal power generation-ESS system, if the water depth is 20 m or more, it may be more advantageous to apply floating tidal power generation with no depth restrictions.

However, floating tidal power generation also requires various auxiliary facilities to prevent the power generation line from moving for stable power generation, and there is a problem that it may capsize when exposed to typhoons or high waves.

In addition, ropes, nets, fishing gear, etc. floating in the sea flow into the water wheel and wrap around the blades of the water wheel, causing the water wheel to break down or stop.

Therefore, by connecting a plurality of hull cylinders to improve the motion stability of the floating body against waves to the floating body that floats the tidal power generation unit, and including a mooring section configured to determine the mooring line according to water depth and environmental conditions, a stable The development of a floating tidal power generation system is designed to enable power generation and reduce the risk of capsizing due to exposure to typhoons or high waves, as well as to selectively float the tidal power generation system depending on the environmental conditions of the sea floor in the area where the system is installed. It is being demanded.

[Patent Document] KR 10-1385564 (registration date 2014.04.09)

In order to solve the above problems, the present invention includes a tidal power generation unit that generates power from the flow energy of the tidal current, a floating body that floats the tidal power generation unit on the water surface, and a plurality of units arranged radially to be spaced apart from the floating body at a certain distance. , a hull part that flows up and down by waves to relieve shock, a thrust part that connects the floating body and the tidal power generation unit to the hull part, and a mooring part whose one end is connected to the hull part and the other end is connected to the seafloor topography. By being configured to include a vertical axis turbine that enables stable power generation and reduces the risk of capsizing due to exposure to typhoons or high waves, it is also configured to selectively float the tidal current power generation system depending on the environmental conditions of the sea floor in the area where the system is installed. The purpose is to provide a floating tidal power generation system consisting of.

A floating tidal power generation system consisting of a vertical axis turbine according to an embodiment of the present invention to achieve the above object includes a tidal power generation unit that generates power with the flow energy of the tidal current; A floating body that floats the tidal power generation unit on the water surface; A plurality of hull parts are arranged radially to be spaced apart from the floating body at a predetermined distance, and flow up and down by waves to relieve shock; A thrust unit connecting the floating body and the tidal current power generation unit to the hull unit; And a mooring part whose one end is connected to the hull and the other end is connected to the seafloor topography.

In addition, the tidal current power generation unit according to the present invention includes at least one vertical axis turbine fixed to the bottom of the floating body and rotating according to the ocean current; A power generation unit disposed at the top of the floating body and generating power using rotational energy of the vertical axis turbine; And a turbine shaft connecting the power generation unit and the vertical axis turbine.

In addition, the hull portion according to the present invention includes a longitudinal hull cylinder that alleviates the impact caused by waves; And a damping plate disposed at the bottom of the hull cylinder.

In addition, the thrust unit according to the present invention includes a first thrust connecting the hull cylinder and the floating body; a second thrust connecting the damping plate and the vertical axis turbine; And a third trust connecting the vertical axis turbine and the neighboring vertical axis turbine.

In addition, the mooring unit according to the present invention includes a plurality of anchors fixed to the seabed terrain; and a plurality of mooring lines connecting the anchor and the hull portion.

In addition, the mooring unit according to the present invention is characterized in that a plurality of anchors are fixed to the seabed terrain, and the mooring line is connected to the anchors.

In addition, the mooring unit according to the present invention includes an anchor fixed to the coastal terrain and an anchor fixed to the seabed terrain, respectively, and is characterized in that the mooring line is connected to the anchor.

In addition, the floating body according to the present invention includes an insertion groove into which the power generation unit is inserted; and an insertion hole through which the turbine shaft penetrates.

According to the floating tidal power generation system consisting of a vertical axis turbine according to the present invention as described above, a plurality of hull cylinders for improving the motion stability of the floating body against waves are connected to the floating body floating the tidal power generation unit, and the water depth and environment It is composed of a mooring section that allows the mooring line to be determined according to conditions, enabling stable power generation and reducing the risk of capsizing due to exposure to typhoons or high waves. In addition, the system can be selectively selected according to the environmental conditions of the seafloor in the area where the system is installed. It has the effect of floating a tidal power generation system.

In addition, when selecting sea areas for tidal power generation-ESS system application, the water depth limit is flexible as it can be applied to water depths of 20 m or more.

In addition, it has the effect of being able to be freely selectively used depending on the terrain adjacent to the coastal terrain or the terrain far from the coastal terrain.

In addition, the anchor of the mooring part consists of a concrete anchor that uses the concrete's own weight and a drilled anchor that is fixed to the seabed rock, allowing for selective use depending on the condition of the seafloor.

Figure 1 is a configuration diagram showing the overall configuration of a floating tidal current power generation system consisting of a vertical axis turbine according to the present invention.
Figure 2 is a state diagram showing the use state of a floating tidal power generation system composed of a vertical axis turbine according to an embodiment of the present invention.
Figure 3 is a top view showing the use state of a floating tidal power generation system consisting of a vertical axis turbine according to an embodiment of the present invention.
Figure 4 is a state diagram showing the use state of a floating tidal power generation system consisting of a vertical axis turbine according to another embodiment of the present invention.
Figure 5 is a top view showing the use state of a floating tidal power generation system consisting of a vertical axis turbine according to another embodiment of the present invention.
Figure 6 is a diagram showing the detailed configuration of a floating tidal current power generation system consisting of a vertical axis turbine according to the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the attached drawings. First of all, it should be noted that the same components or parts in the drawings are given the same reference numerals as much as possible. In describing the present invention, detailed descriptions of related known functions or configurations are omitted so as not to obscure the gist of the present invention.

Figure 1 is a configuration diagram showing the overall configuration of a floating tidal current power generation system composed of a vertical axis turbine according to an embodiment of the present invention, and Figure 2 is a diagram showing the use state of a floating tidal current power system composed of a vertical axis turbine according to an embodiment of the present invention. It is a state diagram, and Figure 3 is a top view showing the use state of a floating tidal current power generation system composed of a vertical axis turbine according to an embodiment of the present invention, and Figure 6 is a detailed view of the floating tidal current power system composed of a vertical axis turbine according to the present invention. It is a diagram showing the composition.

The tidal power generation system 1 consisting of a vertical axis turbine according to the present invention includes a tidal power generation unit 100, a floating body 200, a hull unit 300, and a thrust unit ( 400) and may include a mooring unit 500.

The tidal power generation unit 100 is configured to generate electric power using the flow energy of the tidal current. It floats on the sea by the floating body 200 and produces electric power using the tidal current generated by the ebb and flow of the tide.

Accordingly, the tidal current power generation unit 100 may include a vertical axis turbine 110, a power generation unit 120, and a turbine shaft 130.

The vertical axis turbine 110 is fixed to the bottom of the floating body 200 and consists of at least one rotating according to the ocean current.

Specifically, the vertical axis turbine 110 is configured to be perpendicular to the flow of seawater and rotate using tidal energy, and is configured to transmit the rotational energy of the blades to the power generation unit 120.

In addition, the vertical axis turbine 110 performs a rotational operation for tidal power generation below sea level by the support of the power generation unit 120 and the floating force of the floating body 200. According to the present invention, the unit It is preferable to be rotatably installed below the fluid 200, and thus rotated by marine currents below the sea level.

In addition, the vertical axis turbine 110 preferably has the shape of an elliptical column in order to efficiently transmit tidal energy. Although not shown, the length of the minor axis is relatively small compared to the major axis on a cross section cut in a direction parallel to the sea level. It may be a small oval shape.

Therefore, when the direction of the tidal current is parallel to the long axis, the drag force of the tidal current can be maximized, and when the direction of the tidal current is parallel to the long axis, the drag force of the tidal current can be minimized.

Additionally, the shape of the vertical axis turbine 110 is not limited to this and may be modified in various ways.

In addition, the vertical axis turbine 110 may be composed of a pair arranged adjacently as shown, but the number of vertical axis turbines 110 is not limited to this and allows for various applications.

The power generation unit 120 is disposed at the top of the floating body 200 and is configured to generate power using the rotational energy of the vertical axis turbine 110.

Specifically, the power generation unit 120 is configured to receive the rotational energy of the vertical axis turbine 110 and convert it into electrical energy, and the vertical axis turbine 110 is based on the central axis of the power generation unit 120 due to the current. When rotating, the rotational energy of the vertical axis turbine 110 is converted into electrical energy.

In addition, the power generation unit 120 is placed at the top of the floating body 200 and floats on the sea level by the buoyancy of the floating body, and the casing is covered on the exterior to be safely protected from external environments such as precipitation and waves. Let it happen.

The turbine shaft 130 connects the power generation unit 120 and the vertical axis turbine 110, and controls the rotation of the vertical axis turbine 110 while transferring the rotational energy of the vertical axis turbine 110 to the power generation unit ( 120).

The floating body 200 is configured to float the tidal current power generation unit 100 on the water surface.

Specifically, the floating body 200 is manufactured by foam molding to provide floating force to the tidal power generation unit 100 at sea and floats on the water surface, and is coupled to a portion of the tidal power generation unit 100. It can be configured.

Therefore, the floating body 200 may be made of expanded polypropylene (EPP) material, which is lightweight but has high elasticity and strength, but is not limited thereto, and is not limited to foam plastics such as EVA (Ethylene-Vinyl Acetate Copolymer) or Various buoyancy materials, such as synthetic rubber such as NBR (nitrile-butadiene rubber), can be handled within the technical scope of the present invention by those skilled in the art.

In addition, the floating body 200 may preferably be configured in the cylinder or cylindrical shape as shown in the drawing, but the shape is also only one embodiment proposed by the present invention, and those skilled in the art Of course, it can be designed in various ways within the technical scope of the present invention.

In addition, the floating body 200 can be radially connected to a plurality of hull parts 300, and can float in a certain area by the mooring part 500.

Additionally, the floating body 200 may be configured to include an insertion groove 210 into which the power generation unit 120 is inserted and an insertion hole 220 through which the turbine shaft 130 passes.

Therefore, the floating body 200 has a power generation unit 120 disposed in the center that converts the physical rotation of the vertical axis turbine 110 into electric power, and the power generation unit 120 is a vertical axis turbine (130) with a turbine shaft 130. 110).

The hull portion 300 is arranged radially in plural numbers to be spaced apart from the floating body 200 at a certain distance, and is configured to flow up and down due to waves to relieve impact.

Specifically, the hull portion 300 is connected to the floating body 200 with a thrust portion 400, and is arranged in plural numbers around the floating body 200 to move up and down by waves that change the height of the sea surface. It is structured so that

In addition, the hull portion 300 may be configured to include a longitudinal hull cylinder 310 that alleviates the impact caused by waves and a damping plate 320 disposed at the bottom of the hull cylinder 310.

As shown, the hull cylinder 310 is composed of a long pipe in the longitudinal direction perpendicular to the ocean current and has a cylindrical structure inside, thereby improving the stability of the movement of the tidal power generation system against waves.

In addition, the hull cylinder 310 is connected to the floating body 200 by a first trust 410, which will be described later, at the top, and the damping plate 320 is connected to the vertical axis by a second trust 420, which will be described later. It may be connected to the lower part of the turbine 110.

Therefore, in the tidal current power generation system (1) according to the present invention, a floating body (200) with a relatively large volume is disposed at the center, and four hull cylinders (310) are attached to the floating body (200) to improve motion stability against waves. It is placed in the periphery.

In addition, the hull cylinders 310 may be composed of four around the outer peripheral surface of the floating body 200 as shown, but the number of hull cylinders 310 is not limited to this and can be applied in various numbers. there is.

In addition, the hull cylinder 310 is connected to the mooring unit 500 at the top so that the tidal power generation system 1 can stay within a certain range of the sea.

The thrust unit 400 is configured to connect the floating body 200 and the tidal current power generation unit 100 to the hull unit 300.

Specifically, the thrust unit 400 is a configuration for connecting the hull unit 300 to the floating body 200 and the tidal current power generation unit 100, and the upper end of the hull cylinder 310 and the floating body ( 200, a first thrust 410 connecting the damping plate 320 and the lower end of the vertical axis turbine 110, and a vertical axis turbine 110 adjacent to the vertical axis turbine 110. ) may be configured to include a third trust 430 that connects.

Figure 4 is a state diagram showing the use state of a floating tidal current power generation system composed of a vertical axis turbine according to another embodiment of the present invention, and Figure 5 is a floating tidal current power generation system composed of a vertical axis turbine according to another embodiment of the present invention. This is a top view showing the state of use.

As shown in FIGS. 4 and 5, one end of the mooring unit 500 is connected to the hull unit 300, and the other end is connected to the seafloor topography to provide the tidal current power generation system 1 according to the present invention in a certain area. It is configured to be anchored at sea.

Accordingly, the mooring unit 500 includes a plurality of anchors 510 fixed to the seabed terrain 10 and a plurality of mooring lines 520 connecting the anchors 510 and the hull unit 300. .

The anchor 510 is a configuration for fixing the mooring line 520 to the seabed terrain 10. A concrete anchor using concrete's own weight can be used, or a drilled anchor fixed by drilling a hole in the seabed rock can be used. there is.

Therefore, the anchor 510 according to the present invention allows the concrete anchor or the drilled anchor to be selectively used depending on the environmental conditions of the sea floor in the area where the tidal power generation system 1 is installed.

Additionally, the anchor 510 may be fixed to the seabed terrain 10 or the coastal terrain 20.

This allows the tidal power generation system 1 according to the present invention to be deployed efficiently both when located in the sea adjacent to land and in the sea far from land.

As an embodiment, the mooring unit 500 is provided with a plurality of anchors 510 in the seabed terrain 10 when the tidal power generation system 1 is located in the sea far from land, as shown in FIGS. 2 and 3. ) and is configured to connect the mooring line 520 to the anchor 510.

In addition, the mooring unit 500 according to another embodiment of the present invention is a coastal terrain 20 when the tidal power generation system 1 is located in the sea adjacent to land, as shown in FIGS. 4 and 5. It may be configured to include an anchor 510 fixed to and an anchor 510 fixed to the seabed terrain 10, and the mooring line 520 is connected to the anchor 510.

Therefore, the mooring unit 500 according to the present invention can determine the mooring line 520 depending on the water depth and environmental conditions, and when located at sea close to land as shown in Figures 4 and 5, one side is on land. A method of mooring on the seabed and the other side on the seabed can be used.

According to the floating tidal power generation system consisting of a vertical axis turbine according to the present invention as described above, a plurality of hull cylinders for improving the motion stability of the floating body against waves are connected to the floating body floating the tidal power generation unit, and the water depth and environment It is composed of a mooring section that allows the mooring line to be determined according to conditions, thereby enabling stable power generation and reducing the risk of capsizing due to exposure to typhoons or high waves. In addition, the system can be selectively selected according to the environmental conditions of the seafloor in the area where the system is installed. It has the effect of floating a tidal power generation system.

In addition, when selecting sea areas for tidal power generation-ESS system application, the water depth limit is flexible as it can be applied to water depths of 20 m or more.

In addition, it has the effect of being able to be freely selectively used depending on the terrain adjacent to the coastal terrain or the terrain far from the coastal terrain.

In addition, the anchor of the mooring part consists of a concrete anchor that uses the concrete's own weight and a drilled anchor that is fixed to the seabed rock, allowing for selective use depending on the condition of the seafloor.

The terms and words used in the present specification and claims described herein should not be construed as limited to their usual or dictionary meanings, and the present inventor has appropriately used the concept of terms to explain his/her invention in the best way. It must be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle of definability.

Therefore, the configuration shown in the drawings and examples described in this specification is only one of the most preferred embodiments of the present invention, and does not represent the entire technical idea of the present invention, so they cannot be replaced at the time of filing the present application. It should be understood that various equivalents and variations may exist.

1: Floating tidal power generation system consisting of a vertical axis turbine
10: Undersea terrain 20: Coastal terrain
100: Tidal power generation unit 110: Vertical axis turbine
120: Power generation unit 121: Casing
130: turbine shaft 200: floating body
210: Insertion groove 220: Insertion hole
300: Hull part 310: Hull cylinder
320: Damping plate 400: Thrust part
410: 1st trust 420: 2nd trust
430: Third trust 500: Mooring unit
510: anchor 520: mooring line

Claims (8)

A tidal power generation unit that generates power from the flow energy of tidal currents;
A floating body that floats the tidal power generation unit on the water surface;
A plurality of hull parts are arranged radially to be spaced apart from the floating body at a predetermined distance, and flow up and down by waves to relieve shock;
A thrust unit connecting the floating body and the tidal current power generation unit to the hull unit; and
It includes a mooring part, one end of which is connected to the hull part and the other end of which is connected to the seabed terrain,
The tidal power generation department,
A plurality of vertical axis turbines fixed to the bottom of the floating body and rotating according to the ocean current;
A power generation unit disposed at the top of the floating body and generating power using rotational energy of the vertical axis turbine; and
It includes a turbine shaft connecting the power generation unit and the vertical axis turbine,
The vertical axis turbine,
A cross section cut in a direction parallel to the sea level is formed in the shape of an elliptical pillar with a relatively small short axis compared to the long axis.
The hull part,
A longitudinal hull cylinder that alleviates the impact of waves; and
It includes a damping plate disposed at the bottom of the hull cylinder,
The trust department,
A first thrust connecting the top of the hull cylinder and the floating body;
a second thrust connecting the damping plate and the lower end of the vertical axis turbine; and
It includes a third trust connecting the vertical axis turbine and the neighboring vertical axis turbine,
The mooring part,
Multiple anchors fixed to the seabed terrain; and
It includes a plurality of mooring lines connecting the anchor and the hull portion,
The floating body,
an insertion groove into which the power generation unit is inserted; and
an insertion hole through which the turbine shaft passes;
A floating tidal power generation system consisting of a vertical axis turbine, comprising:
delete delete delete delete According to clause 1,
The mooring part,
A floating tidal power generation system consisting of a vertical axis turbine, characterized in that a plurality of anchors are fixed to the seafloor, and the mooring line is connected to the anchors.
According to clause 1,
The mooring part,
A floating tidal power generation system consisting of a vertical axis turbine, comprising an anchor fixed to the coastal terrain and an anchor fixed to the seabed terrain, respectively, and the mooring line is connected to the anchor. delete