KR102086155B1 - Offshore wind power equipment - Google Patents

Abstract

The present invention is installed at the bottom of the wind power generator, wind power generator for producing power using the wind, and supports the wind generator to be disposed above the sea level relative to the vertical column, the wind generator and the vertical column at the designated position of the sea It is installed to extend downward from the bottom of the vertical column to support it, and is installed on the outer circumferential surface of the lower structure formed with the lifting guide so as to extend in the up and down direction, and connected to the lifting guide so as to move up and down on the lower structure. The present invention provides an offshore wind power generation apparatus including an eyepiece structure having buoyancy to enable berthing of an object to be docked while moving in an up and down direction according to a change in water level due to a difference between tides.

Description

Offshore wind power equipment

The present invention relates to an offshore wind power generation apparatus that generates electricity by using wind generated at sea.

In general, the introduction of wind power generators has been increasing in recent years because it is simple in structure and installation, easy to operate and manage, and unmanned and automated operation.

On the other hand, in the past, wind power structures were mainly installed on land, but environmental damages caused by noise and vibration continue to occur, and due to problems such as large capacity, aesthetics, and restrictions on places, wind power generation devices are recently being built on the sea.

By the way, when the maintenance of the offshore wind turbine is required, there is a limit to the movement by anchoring the barge on which the crane is mounted to a certain position after the anchor work. In addition, in the case of supply ships carrying supplies such as power system parts required on land, the ships are anchored by anchoring barges, but after the barges move to other places, there is no place to anchor them. By connecting the wind blows a little hard or the difference between the tidal sea is not easy to berthing can perform smooth work for maintenance and work in the emergency is not possible to operate the power plant. In addition, there is a problem that damage to the wind power generation structure and the ship due to the collision of barges or supply lines in the offshore wind power generator.

Such a conventional offshore wind power generator is presented in Korean Patent Publication No. 10-2013-0012106 (2013.02.01).

It is an object of the present invention to provide an offshore wind turbine generator that can reliably berth a vessel for maintenance regardless of differences between the marine environment and tides.

The present invention, a wind turbine for generating power using wind power, is installed at the bottom of the wind turbine, vertical pillars for supporting the wind turbine to be disposed above the sea level, the wind generator and the vertical plume designated It is installed to extend downward from the lower end of the vertical column to support in position, the outer circumferential surface is installed in the lower structure with the lifting guide is formed so as to extend in the up and down direction, connected to the lifting guide to move up and down on the lower structure, floating state at sea The present invention provides an offshore wind power generation apparatus including an eyepiece structure having buoyancy to enable berthing of an object to be docked while moving up and down on a lifting guide due to a change in water level due to a difference between a wave and a tidal wave.

In addition, the substructure is buoyant and can be arranged to float on the sea.

In addition, the lower end of the substructure can be fixedly coupled to the sea bottom.

In addition, the eyepiece structure has a buoyancy buoyancy to float on the sea, the eyepiece body is formed in the eyepiece groove is formed so that the eyepiece can be inserted, one end is connected to one side of the eyepiece body, the other end is up and down in the lifting guide It may include a connecting leg connected to be slidably movable in the direction.

The connecting leg may have a vertical cross-sectional shape in which a pair of unit leg members are bent.

In addition, the upper and lower ends of the elevating guide may further include a stopper to prevent the departure of the eyepiece structure.

In the offshore wind turbine generator according to the present invention, the lifting guide is formed to extend in the up and down direction on the outer surface of the lower structure, and the buoyancy structure having buoyancy to float in the sea is connected to the lifting guide to move up and down, The berthing structure is floated in the sea and is arranged to move up and down on the lifting guide according to the change of the water level due to the difference between the waves and tides, so that the berthing vessel can be docked regardless of the sea environment change.

1 is a perspective view of an offshore wind power generator according to an embodiment of the present invention.

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

1 is a perspective view of an offshore wind power generator according to an embodiment of the present invention. Referring to FIG. 1, an offshore wind turbine generator according to an embodiment includes a wind generator 200, a vertical pillar 200, a lower structure 300, and an eyepiece structure 400.

The wind generator 100 is disposed above the sea level through the vertical column 200 and the lower structure 300, which will be described later, is a power generation facility that generates power using wind generated at sea. Such, the wind generator 100 is installed coupled to the upper end of the vertical column 200 so that it can be disposed extending above the sea surface.

Here, the wind power generator 100 is connected to the upper end of the vertical column 200, the natsel 110 is provided with a generator for producing electricity inside, rotatably connected to one side of the natsel 110 Although shown as being configured as a blade 120 to produce power from the generator of the natsel 100 while rotating by the wind, of course, but not limited to this. At this time, the natsel 220 may be rotatably connected to the top of the vertical pillar (200).

The vertical column 200 is a pillar member for supporting the wind generator 100 to extend upwardly from the sea surface. The upper end of the vertical column 200 is installed to be connected to the lower side of the wind power generator 100, more specifically, the one side of the natsel 110 of the wind power generator 100. Here, the upper end of the vertical column 200 may be rotatably connected to one side of the natsel 110, but is not limited to this may also be fixedly installed to one side of the natsel 110 of course.

In addition, the lower end of the vertical pillar 200 may be rotatably connected to the upper end of the lower structure 300 to be described later. As such, when the lower end of the vertical column 200 is rotatably connected to the upper end of the lower structure 300, when the wind is generated more than a certain intensity prevents all the force is transmitted to the lower structure 300 generated by the wind shake By minimizing the structure, the lower structure 300 enables the wind turbine 100 and the vertical pillar 200 to be stably supported at sea.

The lower structure 300 is a structure for supporting the wind generator 100 to extend upwardly from the sea surface together with the vertical pillar 200 described above, and more specifically, the wind generator 100 and the vertical pillar 200. A structure that is supported at a specified location on the sea. Such, the upper end of the lower structure 300 is disposed to extend upward than the sea level, the lower end of the lower structure 300 is disposed in a locked state below the sea level. Here, although the lower structure 300 is illustrated as being formed in a cylindrical structure in FIG. 1, the lower structure 300 is not limited thereto and may have a structure capable of stably supporting the vertical pillar 200 and the wind power generator 100 at sea.

Here, the lower structure 300 is formed in a column structure having a buoyancy, it can support the wind turbine 100 and the vertical column 200 in a floating state at sea. Here, the lower structure 300 may be formed of a structure having a space portion filled with air therein, but not limited to the material itself has a buoyancy or to apply a structure having a separate buoyancy material coupled to the inside or the outside It may be. As such, when the substructure 300 has buoyancy to float on the sea, the lower end of the lower structure 300 may be provided with a weight addition (not shown) to increase the weight of the lower structure (300) have. Such, the weight addition lowers the center of gravity of the lower structure 300 in a state formed of a concrete structure or a metal structure to increase the weight of the lower structure 300, even if the additional mooring device is not installed the lower structure ( 300 makes it possible to maintain the wind turbine 100 in a stable floating state within a certain position area of the sea. When the substructure 300 is buoyant to float on the sea, it may be provided with a mooring wire (not shown) to allow the floating within a certain location area of the sea. That is, one end of the mooring wire in the longitudinal direction may be connected to one side of the lower structure 300, and the other end of the mooring wire in the longitudinal direction may be connected and fixed to the sea bottom.

In addition, the lower structure 300 may be fixedly coupled to the bottom of the lower structure 300 in the state having a columnar structure fixed. That is, the lower structure 300 is formed so that the lower end of the lower structure 300 extends to the sea bottom so that the lower structure 300 does not float on the sea, and may be fixedly coupled to the sea bottom.

The lifting guide 310 is formed on the outer surface of the lower structure 300 so as to extend in the vertical direction to guide the eyepiece structure 400 to be described later to be moved in the vertical direction. Such, the lifting guide 310 is formed by a plurality of side by side spaced apart from each other, the connection structure to support the eyepiece structure 400 can be made in a stable movement in the vertical direction.

Here, referring to Figure 3, the upper and lower ends of the elevating guide 310 may be provided with a stopper 320 for locking the eyepiece structure 400 to prevent the eyepiece structure 400 from being separated. . The stopper part 320 includes an upper locking end 321, a lower locking end 322, an upper shock absorbing member 323, and a lower shock absorbing member 324.

The upper locking end 321 is a bar portion extending in both directions from the upper end of the lifting guide 310. The upper end 321 is such that the eyepiece structure 400 is caught so as not to be separated from the upper end of the elevating guide 310.

The lower locking end 322 is a bar portion extending in both directions from the lower end of the lifting guide 310. The lower locking end 322 allows the eyepiece structure 400 to be locked so as not to be separated downward from the lower end of the lifting guide 310.

The upper shock absorbing member 323 is coupled to the lower side of the upper engaging end 321, the eyepiece structure 400 is moved to the upper end of the lifting guide 310 while the impact force when the upper engaging end 321 is caught. It is a member to absorb. The upper shock absorbing member 323 may selectively apply a plate member or a spring member having ductility.

The lower shock absorbing member 324 is coupled to the upper side of the lower engaging end 322, and the eyepiece structure 400 is moved to the lower end of the lifting guide 310 while the impact force when the lower engaging end 322 is caught. It is a member to absorb. The lower shock absorbing member 324 may selectively apply a plate member or a spring member having ductility.

The eyepiece structure 400 is a structure that enables the eyepiece of the eyepiece to be docked onto the lower structure (300). That is, the eyepiece structure 400 is a floating state on the sea, depending on the change in water level due to the difference between only the tide, the upper and lower direction moving on the lower structure 300, the eyepiece to the eye can be stable to the lower structure 300. Let's do it. This, the eyepiece structure 400 is buoyant to move in accordance with the change in the water level in the sea, and is installed to be connected to the eyepiece structure 400 to slide in the vertical direction along the lifting guide (310). Here, the eyepiece structure 400 includes the eyepiece body 410, the connecting leg 420.

The eyepiece main body 410 is a plate portion for eyepiece to be docked in the eyepiece. This, the eyepiece 410 is formed in a structure having a buoyancy to be floating on the sea. Here, the eyepiece groove 411 is formed at the side of the eyepiece 410 so as to place the eyepiece to be inserted into the eyepiece. In this way, the eyepiece groove 411 bar can be inserted into the eyepiece main body 410, the eyepiece bar 410, it is possible to minimize the effect of the blue. In addition, the side surface portion of the eyepiece body 410 in which the eyepiece groove 411 is formed may be provided with a shock absorbing member (not shown) to absorb the impact force when the eyepiece to be docked. Such, the shock absorbing member may be provided with a plurality of coupling to be spaced apart from each other in the side surface portion formed with the eyepiece groove 411 of the eyepiece body 410, wherein the shock absorbing member may be used to select a plate member or a spring member having a ductility Can be.

The connecting leg 420 is a part for slidably connecting the eyepiece 410 to the lifting guide 310 of the lower structure 300. One end of the connecting leg 420 is connected to the rear side of the eyepiece 410, and the other end of the connecting leg 420 is slidably connected to the lifting guide 310 in the vertical direction. Here, the other end of the connecting leg 420 is formed with a guide groove 421 is fastened corresponding to the lifting guide 310. In addition, the connection leg 420 is provided with a pair of symmetrical couplings on both sides of the eyepiece 410, respectively, so that the eyepiece 410 can maintain a stable connection to the lifting guide 310 of the lower structure 300. do.

In this case, the connecting leg 420 may be formed to have a vertical cross-sectional shape of a 'b' of a pair of unit leg members 420a. As such, when the connecting leg 420 is composed of a pair of unit leg members 420a, the load of the eyepiece 410 is transferred to the lifting guide part 310 in a dispersed state, and the lower structure 300 In the connected state to the elevating guide 310 of the eyepiece 410 in accordance with the wave or water level change or the eyepiece to be able to maintain a stable connection even when the eyepiece to the eyepiece 410.

As such, the offshore wind turbine generator according to an embodiment, the lifting guide 310 is formed to extend in the vertical direction on the outer surface of the lower structure 300, the eyepiece structure 400 having buoyancy to float in the sea Bar movably connected to the elevating guide 310, the eyepiece structure 400 is floating on the lifting guide 310 in the floating state in accordance with the water level change due to the difference between only the blue or tide It will be deployed to enable the docking of the ship to be docked regardless of the transformation of the marine environment.

Although the present invention has been described with reference to the embodiments illustrated in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

100: wind turbine 200: vertical column
300: substructure 310: lifting guide
400: eyepiece 410: eyepiece
411: eyepiece groove 420: connecting leg

Claims (6)

A wind power generator for producing electric power using wind power;
A vertical column installed at a lower end of the wind generator and supporting the wind generator to be disposed above the sea level;
A lower structure in which the wind generator and the vertical pillar are installed to extend downward from the lower end of the vertical pillar to support the designated position at the sea, and a lifting guide is formed on the outer circumferential surface thereof to extend in the vertical direction; And
It is connected to the elevating guide so as to move up and down on the undercarriage, and it is possible to berthing the ship to be docked while moving up and down on the elevating guide in accordance with the water level change due to the difference between the blue and tide in the floating state at sea. Includes eyepiece structure having buoyancy;
The eyepiece structure has a buoyancy to float in the sea, the eyepiece main body is formed with the eyepiece groove is formed so that the ship can be inserted into the eyepiece, one end is connected to one side of the eyepiece body, the other end in the vertical direction in the lifting guide It includes a connecting leg connected to the sliding movement,
The connecting leg is configured to transfer the load of the eyepiece to the elevating guide unit in a dispersed state while being connected to the elevating guide of the lower structure. In order to maintain a stable connection when a pair of unit legs are formed to have a '<' vertical cross-sectional shape,
The top and bottom of the elevating guide is provided with a stopper to prevent the departure of the eyepiece structure,
The stopper portion may have a bar-shaped upper engaging end extending in both directions from an upper end of the elevating guide and a bar-shaped lower engaging end extending in both directions from a lower end of the elevating guide and a lower end of the upper engaging end. Installed on the upper part, and the eyepiece structure moves up to the upper end of the lifting guide while the upper shock absorbing member absorbs the impact force when caught on the upper locking end, and is installed on the upper side of the lower locking end, so that the eyepiece structure is at the lower end of the lifting guide. Offshore wind turbine including a lower shock absorbing member for absorbing the impact force when caught in the lower locking end moving. The method according to claim 1,
The substructure is buoyant, offshore wind turbine is arranged to float on the sea. The method according to claim 1,
The bottom of the substructure is coupled to the offshore wind turbine is fixed to the bottom.

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