KR100999723B1 - Tower Supporting Structure of Wind Turbine Equipment - Google Patents

Abstract

A tower support structure of a wind turbine installation is provided. The tower support structure of the disclosed wind turbine installation is made of a hollow cylindrical shape and is coupled to surround the outer circumferential surface of the pedestal plate, at least one communication hole is formed, the pedestal plate, the ring-shaped anchor is formed to extend The base plate has a ring shape that maintains a predetermined thickness and has an elastic member inserted and fixed to be in close contact with the inside of the communication hole.

The present invention inserts an elastic member into a communication hole formed in a pedestal plate and a base plate forming a tower support structure for supporting a steel hollow tower, and then loads applied to the pedestal plate and the base plate in such a way as to install reinforcing bars therebetween. By evenly dispersing, it is possible to reduce the deformation of the concrete introduced into the communication hole, thereby suppressing the initial crack occurrence.

Tower support structure, pedestal plate, base plate, elastic member

Description

Tower Supporting Structure of Wind Turbine Equipment

The present invention relates to a tower support structure of a wind turbine installation, and more particularly to a tower support structure secured structural stability to be suitable for large wind turbine installations.

Wind turbine facility is a system configured to convert the kinetic energy of the wind into electrical energy, can be divided into onshore (offshore) and offshore (offshore) according to the installed environmental conditions.

It is the role of the tower to place the wind power generation nacelle at a given height in order to obtain the desired power target in the wind turbine installation. There are horizontal and vertical wind turbines. Recently, the development and installation of horizontal wind turbines have been actively conducted in Korea and overseas. The type of the wind turbine tower is a monopile type, jacket type, branch support type, etc. Recently, large wind turbines are mainly used mono pile type tower, in particular, steel hollow monopile tower.

The junction for transferring the load on the steel hollow tower to the ground foundation is a pedestal. The pedestal is above the foundation and is usually a pedestal that is higher than the foundation, but sometimes the tower is directly joined to the foundation without the pedestal. The cross-sectional shape of the foundation is often polygonal or circular.

The existing type of pedestal, which is the connection between the steel hollow tower and the foundation, can be divided into anchor bolts and anchor rings. The anchor bolt method is a method that is mainly applied to small and medium wind turbines. When applied to a turbine, it may be a problem in structural stability.

Even in the anchor ring type, when applied to large wind turbines, excessive load is transmitted to the pedestal. Indeed, there may be a problem that the pedestal may be separated from the foundation of the ground in the event of extreme wind loads, such as when a typhoon is blowing.

SUMMARY OF THE INVENTION An object of the present invention for solving the above problems is to provide a tower support structure of a wind turbine installation having structural stability to be suitable for large wind turbines by improving the structure of the pedestal.

Tower support structure of the wind turbine installation according to the present invention for achieving the above object is made of a hollow cylindrical shape and at least one communication hole is formed pedestal plate, coupled to surround the outer circumferential surface of the pedestal plate and the bottom The base plate is formed to extend the ring-shaped anchor, the ring shape to maintain a predetermined thickness is provided with an elastic member that is inserted and fixed to be in close contact with the inside of the communication hole.

Here, the elastic member may be rubber.

The anchor of the base plate and the communication hole of the pedestal plate may be embedded in the reinforced concrete.

Preferably, the communication hole may be formed in an elliptic shape.

In addition, the communication hole may penetrate a plurality of rebars.

The present invention evenly distributes the load applied to the pedestal plate and the base plate by inserting an elastic member in the communication hole formed in the pedestal forming the tower support structure for supporting the steel hollow tower, and then install the reinforcing bars therebetween. By reducing the deformation of the concrete introduced into the communication hole has the effect of suppressing the occurrence of the initial crack.

The above objects, features and other advantages of the present invention will become more apparent from the following detailed description of the preferred embodiments of the present invention with reference to the accompanying drawings. Hereinafter, with reference to the accompanying drawings will be described in detail the tower support structure of the wind turbine installation according to an embodiment of the present invention.

1 is a block diagram showing a schematic structure of a wind turbine installation, Figure 2 is a view showing a schematic configuration of a tower support structure according to the present invention, Figure 3 is a communication hole, an elastic member, and reinforcing bar of FIG. 4 is a view showing the interaction between the elastic member and the reinforcing bar fastened to the communication hole of the pedestal plate.

First, with reference to Figure 1 will be described a schematic configuration of a wind turbine facility having a tower support structure according to an embodiment of the present invention.

First, a nacelle 110 is provided in which devices such as a speed increaser, a generator, and an inverter, not shown, are provided therein. The speed reducer is connected to the blade 120 through a hub spacer 127 and a hub 125. The nacelle 110 is seated at the top of the steel hollow tower 130 that is long and long in a cylindrical shape. Steel hollow tower 130 is fixed to the upper end of the tower support structure 200 located below, the tower support structure 200 is a base reinforced concrete member having a portion of its body embedded in the ground 150 ( 140 may be fastened.

When the wind blows to the blade 120, the kinetic energy generated by the low rpm (rpm) of the blade 120 is changed to the kinetic energy having a high rpm rotational speed by a speed increaser (not shown), The kinetic energy is converted into electrical energy by rectifiers such as generators and inverters.

On the other hand, the steel hollow tower 130 has to be able to withstand the load due to the strong wind, the tower support structure 200 is firmly embedded in the reinforced concrete member 140, the load acting The tower support structure 200 is dispersed by the interaction of the basic reinforced concrete member 140, thereby maintaining a structure that can withstand the working load.

With reference to Figures 2 to 4 will be described in detail the structure of the tower support structure 200 according to an embodiment of the present invention.

The tower support structure 200 includes a pedestal plate 210, a base plate 225, and an elastic member 240. The pedestal plate 210 has a hollow cylindrical shape and at least one communication hole 230 may be formed. The communication hole 230 is formed in a straight line to communicate the outer circumferential surface and the inner circumferential surface of the pedestal plate 210. The pedestal plate 210 is not limited to a cylindrical shape, but may be manufactured in a polygonal pillar manner such as a square or a pentagon according to the situation of a wind turbine facility.

The base plate 225 has a ring shape to maintain a predetermined thickness, and is buried in the base reinforced concrete member 140 embedded in the ground 150 to serve to support and fix the swing.

When a load such as a bending moment is transmitted to the tower support structure 200, a repulsive force acts on the base plate 225 embedded in the foundation reinforcement concrete member 140 or a stress acts on the pedestal plate 210. In order to prevent the tensile or compressive deformation of the 225 or the pedestal plate 210, the tower support structure 200 is provided with an elastic member 240 is inserted and fixed in close contact with the inner peripheral portion of the communication hole 230. can do.

As the elastic member 240, a lining rubber made of a rubber material which is easy to process and easy to install may be prepared. The lining rubber may be prepared due to elastic deformation of the lining rubber during tensile or compressive deformation of the pedestal plate 210. Deformation of the concrete introduced into the communication hole 230 is reduced, and as a result, it is possible to bring about an effect of suppressing the initial crack generation of the pedestal plate 210.

The communication hole 230 may be formed in an elliptic shape. Forming a hole closer to an ellipse than a circle is preferably formed as elliptical as possible since the stress generated by the large load is reduced.

A part of the tower support structure 200 is fixed to be fixed by being embedded in the basic reinforced concrete member 140, and the base plate 225 and the communication hole 230 may be embedded in the basic reinforced concrete member 140.

When embedded in the basic reinforcement concrete member 140 as described above, the communication hole 230 may be configured to penetrate the reinforcing bar 245, the reinforcing bar 245 has two reinforcing bars in one communication hole 230 It is preferable to penetrate, and in some cases, a communication hole 230 may be formed so that a single reinforcing bar or three or more bars may pass through. The reinforcing bar 245 is in direct contact with the elastic member 240 impinging on the basic reinforced concrete member 140 and the communication hole 230, by appropriate distribution of the load of the reinforcing bars 245 and elastic member 240 The tower support structure 200 can achieve a stable structure. Reference numeral 232 may be a concrete member inserted between the elastic member 240 and the reinforcing bar 245 in the process in which the communication hole 230 is embedded in the basic reinforced concrete member 140. The concrete member 232 serves as a buffer against the impact that may occur between the elastic member 240 and the reinforcing bar 245.

The tower support structure 200 will seat the steel hollow tower 130 on the top. The tower support structure 200 and the steel hollow tower 130 may have protrusions (not shown) formed on respective outer circumferential surfaces of the tower supporting structure 200 and the steel hollow tower 130, and a fastening flange 250 using the protrusions may be provided. The fastening flange 250 is formed so as to surround the tower support structure 200 and the steel hollow tower 130 in the state in which the projection is inserted into the hole is inserted into the hole formed in the joint portion is formed, Tightening by the bolt 252 may be prepared so that there is no swing. The fastening bolt 252 is preferably able to fully support the load applied to the fastening flange 250 by using a high tension bolt.

The tower support structure of the wind turbine installation according to the present invention is a method of installing a reinforcing steel bar between the base plate and the communication hole formed in the pedestal plate forming the tower support structure for supporting the steel hollow tower It can be configured, and by evenly distributing the load applied to the pedestal plate and the base plate to reduce the deformation of the concrete introduced into the communication hole has the effect of suppressing the occurrence of the initial crack.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

1 is a configuration diagram showing a schematic structure of a wind turbine facility,

2 shows a schematic configuration of a tower support structure according to the invention,

3 is a view showing a relationship between a communication hole, an elastic member, and reinforcing bars of FIG.

4 is a view for showing the interaction between the reinforcing bar and the elastic member fastened to the communication hole of the base plate.

<Description of the symbols for the main parts of the drawings>

100: wind turbine facility 110: nacelle

120: blade 125: hub

127: Herb Spacer 130: Steel Heavy Tower

140: basic reinforced concrete member 150: ground

200: tower support structure 210: pedestal plate

225: base plate 230: communication hole

240: elastic member 245: rebar

250: fastening flange 252: fastening bolt

Claims (5)

There is provided a wind turbine facility comprising a nacelle provided with wind power generators, a steel heavy tower having the nacelle supported thereon, and a blade connected to the nacelle. In the tower support structure for connecting and fixing the ground in which the steel hollow tower and reinforced concrete is poured, A pedestal plate having a hollow cylindrical shape and having at least one communication hole formed therein; A base plate extending in both directions from a lower end of the pedestal plate and configured in a ring shape; And A tower support structure of a wind turbine installation comprising a ring shape that maintains a predetermined thickness and is inserted and fixed to be in close contact with the inside of the communication hole. The method of claim 1, The elastic member is a tower support structure of a wind turbine installation, characterized in that the lining rubber (lining rubber). 3. The method of claim 2, The anchor of the base plate and the communication hole of the pedestal plate is a tower support structure of the wind turbine installation, characterized in that embedded in the reinforced concrete. The method of claim 1, The communication hole is a tower support structure of a wind turbine facility, characterized in that formed in an ellipse shape. The method of claim 4, wherein The communication hole is a tower support structure of a wind turbine facility, characterized in that a plurality of reinforcing bars penetrate.

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