KR102437639B1 - Floating wind power generator that enables load reduction through the arrangement of buoyancy bodies and mooring lines - Google Patents

Abstract

Floating wind power generator according to the present invention, a tower portion for supporting the blade and the nacelle; a support structure coupled to the lower end of the tower part; a plurality of buoyancy bodies coupled to the support structure; and a plurality of mooring lines connected between the lower end of the support structure and the seabed, wherein the plurality of buoyancy bodies are a main buoyancy body disposed in the center of the support structure and an edge of the support structure around the main buoyancy body It is characterized in that it comprises a plurality of auxiliary buoyancy body disposed on.

Description

Floating wind power generator that enables load reduction through the arrangement of buoyancy bodies and mooring lines

The present invention stably supports the weight of the wind turbine through a structure in which a plurality of auxiliary buoyancy bodies are radially disposed on the edge of the support structure around the main buoyancy body in the center of the triangular-shaped support structure supporting the blade and the turbine. It relates to a floating wind power generator to reduce the stress applied to the support structure.

Offshore wind power is divided into two types depending on the installation method. It is divided into a fixed offshore wind generator, which is installed by driving a foundation structure in shallow water, and a floating offshore wind generator, which floats on the deep sea.

When a fixed wind power generation system is installed in large water depth, the construction cost of a fixed support structure increases rapidly as the water depth increases. This is a floating offshore wind turbine.

Floating offshore wind turbines use conventional fixed wind turbines on top of a floater. Since the floating offshore wind turbine is shaken by ocean waves, the load acting on the support structure connecting the floating body part and the wind turbine part increases compared to the fixed type. This unstable fluctuation is very important because it adversely affects the soundness of the floating wind turbine and the fatigue load acting on the support structure.

At sea, there are various environmental loads different from those on land due to waves and strong winds. Unlike onshore wind turbines, offshore wind turbines are subjected to strong environmental loads such as waves. In designing a floating wind turbine, it is necessary not only to withstand these loads, but also to generate a stable restoring force.

Since the platform technology with high stability is the key to the floating offshore wind power system, excessive shaking puts a strain on the power turbine located at the top of the tower and acts as a cause of failure, reducing power generation efficiency. Therefore, in the field of floating offshore wind power, high stability floating platform technology with reduced shaking under wind and waves is evaluated as a core technology that enables stable wind power generation.

The most vulnerable part is the yaw bearing part, the part where the stress of the substructure is concentrated, and the part where the mooring line and the platform are connected to the mooring line is sheared by repeated loads, which is known as the most vulnerable part. . In particular, an offshore structure in which the connection between the constituent members is made by welding causes a stress concentration phenomenon due to the geometric shape. There is a problem that cracks occur in the above part to become a starting point of fatigue failure.

On the other hand, Korea Patent No. 10-1709126 provides a thrust control method of stabilizing the attitude of a system by system thrust control under a floating environment in the sea, and a method for stabilizing a floating offshore wind turbine and a rotor rotating by sea wind. By generating thrust on the plotter with respect to the pitch motion of the y-axis among the three-dimensional motion of the x, y, z coordinate system caused by the change of sea wind and waves, the plotter vertically erected a wind turbine that generates power by buoyancy. The change of the pitch motion is reduced and provides the contents to maintain the wind-gazing posture favorable to the rotation of the rotor.

(Korea Patent No. 10-1709126)

The present invention stably supports the weight of the wind turbine through a structure in which a plurality of auxiliary buoyancy bodies are radially disposed on the edge of the support structure around the main buoyancy body in the center of the triangular-shaped support structure supporting the blade and the turbine. To provide a floating wind power generator to reduce the stress applied to the support structure.

In addition, the present invention provides a floating wind power generator that extends the fatigue life by reducing the maximum stress in an area subjected to stress by making the coupling angle between a mooring line coupled to the seabed and a support structure having a triangular shape to be straight.

Floating wind power generator for achieving the above object, the tower portion for supporting the blade and the nacelle; a support structure coupled to the lower end of the tower part; a plurality of buoyancy bodies coupled to the support structure; and a plurality of mooring lines connected between the lower end of the support structure and the seabed, wherein the plurality of buoyancy bodies are a main buoyancy body disposed in the center of the support structure and an edge of the support structure around the main buoyancy body It is characterized in that it comprises a plurality of auxiliary buoyancy body disposed on.

The support structure includes a base plate having a triangular shape and a plurality of inclinations connecting the outer peripheral surface of the tower part at the edge tip of the base plate, and the plurality of auxiliary buoyancy bodies are each at the edge tip of the base plate. It may be desirable to place

The main buoyancy body may preferably have a larger volume than the auxiliary buoyancy body.

The plurality of mooring lines may include a plurality of first mooring lines disposed in a direct downward direction from the base plate and a plurality of second mooring lines disposed in a straight line with a line formed by the inclined portion in the base plate.

The floating wind power generator that enables load reduction through the arrangement of the buoyancy body and the mooring line according to the present invention as described above is an auxiliary part on the three corners forming the edge of the triangular-shaped support structure supporting the blade and the turbine. While placing the fluid, the main buoyancy body is placed in the center of the support structure to support most of the weight of the wind turbine, thereby reducing the load or stress applied to the triangular-shaped support structure.

By making the main buoyancy body arranged in the center of the support structure larger than the auxiliary floating body, the shaking caused by waves is reduced.

The present invention provides safe mooring by disconnection by connecting some of a plurality of mooring lines disposed under a triangular-shaped support structure at an inclined angle along a truss-shaped support structure and arranging the other part perpendicular to the seabed. , while suppressing yaw, surge, and sway motion, which are the chronic weaknesses of TLP.

In addition, the present invention makes it possible to extend the fatigue life by reducing the maximum stress in the high-stress area by making the side support part of the triangular-shaped support structure in line with the mooring line.

1 shows a conceptual diagram of a floating wind power generator according to an embodiment of the present invention.
Figure 2 shows the coupling between a plurality of buoyancy bodies coupled to the support structure and the support structure constituting the floating wind power generator.
3 shows a coupling between a support structure, a plurality of buoyancy bodies, and a plurality of mooring lines constituting a floating wind power generator.
4 shows a state in which the floating wind power generator is installed on the sea level.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms, and only these embodiments allow the disclosure of the present invention to be complete, and the scope of the invention to those of ordinary skill in the art. It is provided for complete disclosure. In the drawings, like reference numerals refer to like elements.

The present invention relates to a structure in which a plurality of auxiliary buoyancy bodies are radially disposed on the edge of the support structure around the main buoyancy body disposed in the center of the support structure having a triangular truss structure shape for supporting the blade and the turbine. It is a key feature to include a floating wind turbine to reduce the stress applied to the support structure by stably supporting the weight of the wind turbine.

1 to 4 , the floating wind power generator according to an embodiment of the present invention is characterized in that it enables a load reduction through the arrangement of a buoyancy body and a mooring line, and a tower supporting blades and nacelles The part 10, the support structure 20 coupled to the lower end of the tower part 10, a plurality of buoyancy bodies 30 coupled to the support structure 20, and the lower end of the support structure 20 and the seabed are connected and disposed In a state including a plurality of mooring lines 40; It includes a plurality of auxiliary buoyancy bodies (33) disposed on the edge of 20).

The floating wind power generator includes a plurality of blades, a hub to which a plurality of blades are coupled, a main shaft coupled to the blade and the hub, a speed increaser, a generator, a power converter, a nacelle, a tower part 10, and the like, wherein the tower part The configuration of the blade, the nacelle, etc. supported by (10) can employ the configuration of a general wind power turbine device.

The support structure 20 includes a base plate 21 having a triangular shape and a plurality of inclined members 23 connecting the outer peripheral surface of the tower part 10 at the edge tip of the base plate 21 .

The base plate 21 may be formed by welding the three outer base members to have a triangular shape. The plurality of inclined members 23 may connect the outer peripheral surface of the tower part 10 in an inclined state at the edge end of the base plate 21 . That is, it extends from the vertex of the base plate 21 having a triangular shape in a tilted state toward the tower portion 10 to enable stable fixing of the base plate 21 . Meanwhile, a separate horizontal reinforcing member 25 extending in a horizontal direction from the edge tip of the base plate 21 may be included. From the above content, the support structure 20 may be in the form of a hollow triangular pyramid with the base plate 21 as the center as a whole.

The main buoyancy body 31 is disposed at the lower end of the center of the base plate 21 and the direct lower end of the tower part 10 , while the plurality of auxiliary buoyancy bodies 33 are disposed at the edge tip of the base plate 21 , respectively. It may be desirable to be That is, the main buoyancy body 31 is disposed on the central lower end of the support structure 20 to effectively support high-load parts such as the blade and the nacelle supported by the tower part 10, and a plurality of auxiliary buoyancy bodies 33 The main buoyancy body 31 as a center may be disposed in a state of radially maintaining a certain interval. That is, in the present invention, the auxiliary floating body 33 is placed on the three end corners of the support structure 20, and the main buoyancy body 31 is placed in the center to support most of the weight of the wind turbine. It is made to reduce the stress of the supporting structure having the shape.

The main buoyancy body 31 has a larger volume than the auxiliary buoyancy body (33). That is, the central main buoyancy body 31 serves to support most of the load of the wind turbine in a larger state than the three auxiliary buoyancy bodies 33 disposed at the corners, while the three auxiliary buoyancy bodies 33 of the corners ) plays a role in reducing shaking caused by waves. On the other hand, in the existing semi-submersible (Semi-Submersible) wind turbine and TLP turbine, there was a method having four corners having a shape other than a triangular shape, but the structure manufacturing cost by making the bottom shape of the supporting structure 20 in a triangular shape It is most desirable for the minimization of

The present invention has a plurality of mooring lines 40 arranged connected between the bottom of the support structure 20 and the seabed.

The plurality of mooring lines 40 includes a plurality of first mooring lines 41 disposed in a direct downward direction from the base plate 21 and a plurality of second mooring lines disposed in a straight line with a line formed by an inclined member in the base plate 21 ( 43) has. The plurality of first mooring lines 41 may extend directly downward from the edge tip of the base plate 21 to reach the seabed. The plurality of second mooring lines 43 may be arranged so as to be on a continuous line along an inclined line formed by the inclined member 23 at the edge tip of the base plate 21 . That is, for example, three mooring lines among the six mooring lines may be arranged to extend in a direct lower direction, and at the same time, the other three mooring lines may be arranged to be continuous with a line formed by the inclined member 23 .

In the present invention, while devising a system for arranging each of the three points of the edge tip of the base plate 21 along the downward direction and the inclined direction, 6 anchors are used to ensure safe mooring by disconnection, and the existing TLP It can suppress the chronic weakness of yaw, surge, and sway motion.

In addition, by making the inclined member 23 and the second mooring line 43 forming the support structure 20 in a straight line, the maximum stress in the high-stress region is reduced, so that the fatigue life can be extended.

The floating wind power generator that enables load reduction through the arrangement of the buoyancy body and the mooring line according to the present invention is an auxiliary floating body on three corners forming the edge of the triangular-shaped support structure 20 supporting the blade and the turbine. On the other hand, by arranging the main buoyancy body in the center of the support structure 20 to support most of the weight of the wind turbine, the load or stress applied to the triangular-shaped support structure 20 is reduced.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

10: tower part
20: support structure
21: base plate
23: inclined member
25: horizontal reinforcement member
30: buoyant body
31: main buoyancy body
33: auxiliary buoyancy body
40 : mooring line
41: first mooring line
43: 2nd mooring line

Claims (4)

a tower part for supporting the blade and the nacelle;
a support structure coupled to the lower end of the tower part;
a plurality of buoyancy bodies coupled to the support structure; and
a plurality of mooring lines connected between the lower end of the support structure and the seabed;
The plurality of buoyancy bodies include a main buoyancy body disposed in the center of the support structure and a plurality of auxiliary buoyancy bodies disposed on the edge of the support structure around the main buoyancy body,
The support structure includes a base plate having a triangular shape and a plurality of inclined parts connecting the outer peripheral surface of the tower part at the edge tip of the base plate,
The plurality of mooring lines 40 are a plurality of first mooring lines 41 disposed in a downward direction from the base plate 21 and a plurality of second mooring lines disposed in a straight line with a line formed by an inclined portion of the base plate 21 . having (43),
The plurality of first mooring lines 41 extend directly downward from the edge tip of the base plate 21 to reach the seabed,
The plurality of second mooring lines 43 are arranged so as to be on a continuous line along the inclined line formed by the inclined portion at the edge tip of the base plate 21,
Floating wind power generator, characterized in that the fatigue life is extended by reducing the maximum stress in a high stress region by making the inclined portion and the second mooring line a straight line.
The method of claim 1,
The plurality of auxiliary buoyancy bodies are each disposed at the edge tip of the base plate, the floating wind power generator.
The method of claim 1,
The main buoyancy body has a larger volume than the auxiliary buoyancy body, a floating wind power generator.
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