KR102045580B1 - Modular wind tower - Google Patents

Abstract

The present invention is a modular wind tower formed by continuously stacking a plurality of polygonal modules in a height direction, wherein the polygonal modules are disposed at the corners of the polygonal modules and have the same shape so as to be commonly applied to the polygonal modules stacked. And a plurality of first module members provided between the plurality of first module members, and a plurality of second module members disposed between the first module members, the plurality of second module members having a smaller width of an external exposure surface as stacked on the first module member. Continuously connecting the member and the second module member in the circumferential direction to form a large cross section of the modular wind tower, to provide a modular wind tower that is reduced in diameter toward the top.

Description

Modular Wind Tower {MODULAR WIND TOWER}

The present invention relates to a modular wind tower, and more particularly, a modular wind tower formed by successively stacking a plurality of module members to form a large cross section of a modular wind tower by continuously stacking in a height direction a plurality of module members. It is about.

In general, a wind power generator is installed on land or at sea and converts wind power into electrical energy to produce electric power.

When the wind power generator according to the prior art is composed of an offshore wind power generator, a support structure which is supported on a substructure composed of a pile and a jacket and located at sea is installed.

In addition, a tower for supporting the nussel at a high position is installed on the support structure, and a rotating blade rotated by wind may be mounted on the nussel.

Recently, in order to cope with the large capacity of wind power generation, the diameter of the wind tower is also increased, and the diameter of the bottom of the wind tower for supporting a 10MW wind turbine is generally required to be about 8 m.

 However, the conventional round tube type is accompanied with restrictions during transportation, the maximum height that can be transported domestically is 4.2m when using a low-rise trailer, there is a problem that the restrictions occur in transporting wind towers reaching 8m.

 In order to solve this problem, a modular wind tower, which is split and transported in a longitudinal direction, is assembled and installed on site, has been proposed as an alternative.

The modular type refers to a type of constructing a structure designed by assembling a plurality of module members in a factory in advance in a factory in order to constitute a single product, transporting them to a site, and assembling each module member in a field.

However, since the wind tower has a large moment reaction force at the lower end, the conical shape that the diameter of the tower decreases from the lower end to the upper end is optimal.In order to produce a tower having such a shape in a modular form, the modules have different shapes by height. There is a problem to be produced by each.

In addition, in the conventional modular wind tower, the existing connection detail for combining the module and the module is a direction in which the bolts penetrate the inside and the outside of the cross section, and the work outside the tower must be accompanied. If the height of the tower is high, or if the wind tower is installed at sea, work outside the tower may cause injury.

In addition, the wind tower has a large moment reaction force occurs at the lower end, so to support this, when configured in a shape that the diameter of the tower becomes smaller from the bottom to the top, each module member has a width of the upper than the width of the lower It may be composed of a trapezoidal member, in this case, since the end of the rectangular steel sheet should be cut when manufacturing the trapezoidal module member, there is a problem that the steel material of the corner portion of the rectangular steel sheet is wasted.

The present invention is made by recognizing at least one of the needs or problems generated in the conventional modular wind tower as described above.

The present invention is to provide a wind tower utilizing a module member that is easy to transport, while meeting the required diameter of the wind tower to cope with the large capacity of wind power generation.

According to an aspect of the present invention, by using a module member that can be commonly applied to each of the multiple modules to be stacked, mass production of the module member is possible, thereby reducing manufacturing cost and construction cost according to the manufacture and installation of a wind tower. To provide a wind tower as possible.

The present invention as one aspect, provided to be connected to each other between the flanges of the adjacent module member inside the wind tower, to minimize the human injury caused by work outside the tower even when the construction of the wind tower offshore To provide a wind tower that can be.

As one aspect for achieving the above object, the present invention is a modular wind tower formed by continuously stacking a plurality of polygonal modules in the height direction, the polygonal module is disposed at the corner of the polygonal module, laminated A plurality of first module members provided in the same shape so as to be commonly applied to each of the plurality of modules; and a plurality of first module members disposed between the first module members and having a narrower width of an external exposure surface as stacked on the first module member. And a second module member, wherein the first module member and the second module member are continuously connected in a circumferential direction to form a large cross section of a modular wind tower, and the diameter thereof decreases toward an upper portion thereof. The cross-sectional area of the first module member is provided to decrease in shape, and the hypotenuse side of the two trapezoidal members is joined to the outer exposed surface of the first module member. It is provided in the form bent as a reference, the outer exposure surface of the second module member is provided as a rectangular member, the first module member and the second module member is provided at the same height, the second module member and the The trapezoidal members disposed at both ends in the circumferential direction of the second module member are disposed in a straight line in the circumferential direction, and are disposed at both ends of the lower width of the external exposure surface of the second module member stacked thereon and at both ends thereof. The sum of the lower widths of the outer exposed surfaces of the trapezoidal members of the module members is the upper width of the outer exposed surfaces of the second module members stacked below and the outside of the trapezoidal members of the first module members disposed at both ends thereof. It provides a modular wind tower, characterized in that the same as the sum of the upper width of the exposed surface.

Preferably, in the polygonal module, the first module member and the second module member are alternately arranged and connected in a circumferential direction, and the connection between the polygonal modules stacked up and down is adjacent to the adjacent first module stacked up and down. End portions of the members may be connected to each other, and end portions of the adjacent second module members stacked up and down may be connected to each other.

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Preferably, at least one flange portion separately prepared in advance is provided at a circumferential end portion and a height end portion of the module member which is at least one of the first module member and the second module member, and the flange portion is provided with the module member. In the pre-installed state, the flange portion may be connected in the interior of the modular wind tower and the flange portion facing the adjacent module member.

As another aspect for achieving the above object, the present invention is a modular wind tower formed by continuously stacking a plurality of polygonal modules in the height direction, the polygonal module is disposed at the corner of the polygonal module, A plurality of first module members provided in the same shape so as to be commonly applied to each of the polygonal modules to be stacked; and a plurality of first module members disposed between the first module members and narrowed in width as an upper exposure layer is disposed above. And a second module member, wherein the first module member and the second module member are continuously connected in a circumferential direction to form a large cross section of a modular wind tower, and a diameter thereof decreases toward an upper portion thereof. And at least one separately manufactured in advance in the circumferential end and the height end of the module member which is at least one of the second module members. A flange portion is provided, and in a state where the flange portion is pre-installed in the module member, the flange portion is connected to the inside of the modular wind tower and the flange portion that is opposite to the adjacent module member, and the flange portion of the module member. An L-shaped member including an inwardly protruding portion surrounding an outer surface and one end portion and protruding inwardly of the modular wind tower, and a plate-shaped member disposed on an inner surface of one end of the module member. The member and the plate-shaped member are connected to each other by bolts and installed at the end of the module member, and the inward protrusion of the flange portion of the module member adjacent to the inward protrusion of the flange portion is in the modular wind tower. Provides a modular wind tower, characterized in that the bolt is connected to.

Preferably, the flange portion, the one end of the module member is installed to be insertable, may include an inwardly projecting portion protruding inwardly of the modular wind tower.

Preferably, the flange portion may be connected in whole or part in the longitudinal or circumferential direction of the module member by bolting, riveting or welding.

Preferably, the vertical flange portion bent at both ends of the circumferential direction of the module member for continuous coupling in the circumferential direction between the module member which is at least one of the first module member and the second module member; For continuous coupling in the height direction, it may be provided with a horizontal flange portion bent at both ends of the height direction of the module member.

Preferably, between the module member which is at least one of the first module member and the second module member disposed adjacent to each other, and the polygonal modules stacked up and down may be joined by mutual welding.

According to an embodiment of the present invention as described above, by forming a plurality of module members continuously connected in the circumferential direction to form a multi-layered module to form a large cross section of the modular wind tower continuously in the height direction, to increase the wind power generation capacity In order to cope with the large diameter of the wind tower to meet the required requirements, the module member for the installation of the wind tower is easy to transport.

According to an embodiment of the present invention, by applying a plurality of first module members disposed in the corners of the polygonal module, the plurality of first module members having the same shape so as to be commonly applied to each of the polygonal modules stacked, it is commonly applied to each of the polygonal modules stacked By utilizing this possible module member, it is possible to mass production of the module member, it is possible to reduce the manufacturing cost and construction cost according to the production and installation of the wind tower.

According to an embodiment of the present invention, there is no need to bend and form the flange portion of the module member, the module member adjacent to the flange portion in a state in which the flange portion produced in advance in the factory is pre-installed on the module member By connecting to the opposite flange portion of the, the construction for bonding between adjacent module members and the laminated multiple modules can be facilitated, there is an effect that can shorten the construction period.

According to an embodiment of the present invention, by connecting the flange portion in the polygonal modular wind tower to the opposite flange portion of the adjacent module member, even when constructing the wind tower offshore to work outside the tower There is an effect that can minimize the human injury caused by.

1 is a perspective view of a modular wind tower according to an embodiment of the present invention.
2 is a plan view of a polygonal module according to an embodiment of the present invention.
3A is a view illustrating a first module member and a second module member before bending of a flange portion according to an embodiment of the present invention.
3B is a view showing the first module member and the second module member after the bending of the flange portion according to an embodiment of the present invention.
4A is a front view of a modular wind tower according to an embodiment of the present invention.
4B is an enlarged view of a portion A shown in FIG. 4A.
Figure 5a is a view showing a state in which the flange portion of one embodiment of the present invention is installed on the first module member and the second module member.
FIG. 5B is a view illustrating a state in which each of the first module members and the second module members provided with the flange of FIG. 5A are connected.
Figure 6a is a view showing a state in which the flange portion of another embodiment of the present invention is installed on the first module member and the second module member.
FIG. 6B is a view illustrating a state in which each of the first module members and the second module members provided with the flange of FIG. 6A are connected.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, embodiments of the present invention may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below. In addition, the embodiments of the present invention are provided to more completely explain the present invention to those skilled in the art. Shape and size of the elements in the drawings may be exaggerated for more clear description.

Hereinafter, with reference to the drawings will be described in detail with respect to the modular wind tower (10) according to an embodiment of the present invention.

1 to 6B, the modular wind tower 10 according to an embodiment of the present invention is a polygonal module that forms a large cross-section of the modular wind tower 10 by continuously connecting a plurality of module members in the circumferential direction. 400 can be formed by continuously stacking in the height direction.

The polygon module 400 may include a first module member 100 and a second module member 200, and may further include a flange portion 300.

Referring to FIG. 1, the modular wind tower 10 continuously connects a plurality of module members in a circumferential direction to sequentially stack a polygonal module 400 forming a large cross section of the modular wind tower 10 in a height direction. Can be formed.

The polygon module 400 may be configured of a first polygon module 410 stacked on the top and a second polygon module 420 stacked on the bottom.

In addition, the polygon module 400 is disposed at the corners of the polygon module 400, and the plurality of first module members 100 having the same shape so as to be commonly applied to the polygon modules 400 to be stacked. And a plurality of second module members 200 disposed between the first module members 100 and stacked on the upper side of the first module member 100 so that the width of the external exposure surface is narrower, and the diameter of the first module member 100 decreases toward the top. Can be configured.

1 and 2, the polygonal module 400 may be connected to the first module member 100 and the second module member 200 alternately arranged in the circumferential direction.

1 shows that the two polygon modules 400 are continuously stacked in the height direction, but the number of the polygon modules 400 shown is exemplary, and according to the required height of the wind tower, the polygon modules 400 are illustrated. Of course, the number of stacked layers may vary.

In addition, the polygonal module 400 is connected to the first module member 100 and the second module member 200 alternately arranged in the circumferential direction, the connection between the polygonal module 400 stacked up and down, End portions of the adjacent first module members 100 stacked up and down may be connected to each other, and end portions of the adjacent second module members 200 stacked up and down may be connected to each other.

As shown in FIG. 2, the first module member 100 and the second module member 200 which are alternately arranged in the circumferential direction are disposed in the inner direction of the first module member 100 and the second module member 200. The flange portion 300 to be formed can be connected by fastening with a bolt.

However, the connection between the module members and the vertical direction of the multi-layer module 400 to be stacked is connected to the conventional various connection methods such as connection and welding, riveting, bolting of the various embodiments of the flange portion 300 to be applied below Can be.

As shown in FIG. 1, the first module member 100 may be provided in the same shape so as to be commonly applied to the polygonal modules 400 that are stacked.

As shown in FIGS. 3A and 3B, the first module member 100 may be formed in a shape in which a cross-sectional area thereof decreases toward the top.

In addition, as shown in Figure 3b, the outer exposure surface of the first module member is joined to the hypotenuse of the two trapezoidal member 110, it may be provided in a form bent with respect to the hypotenuse.

4A and 4B, the second module member 200 may be disposed between the first module members 100. Of course, one second module member 200 may be disposed between the first module members 100 as shown, but is not limited thereto, and a plurality of second modules may be disposed between the first module members 100. It is also possible that the module member 200 is continuously connected and arranged.

In addition, as the second module member 200 is stacked on the upper portion, the width of the external exposure surface may be narrower. That is, the width of the outer exposed surface of the upper second module member 210 stacked on the upper portion may be provided to be narrower than the width of the outer exposed surface of the lower second module member 220 stacked on the lower portion.

As shown in FIG. 1, the external exposure surface of the second module member 200 may be provided as a rectangular member, and the width of the external exposure surface of the upper second module member 210 may be the lower second module member 220. It may be provided narrower than the width of the outer exposure surface of the).

As shown in FIGS. 4A and 4B, the first module member 100 and the second module member 200 are provided at the same height, and the second module member 200 and the second module member 200 are provided at the same height. The trapezoidal member 110 disposed at both ends of the circumferential direction of the c) is disposed in a straight line in the circumferential direction, and the lower width 211 and the both ends of the outer exposed surface of the upper second module member 210 stacked on the upper side. The sum of the lower width 111 of the outer exposed surface of the trapezoidal member 110 of the first module member 100 disposed in the upper width of the outer exposed surface of the lower second module member 220 stacked below ( 221 and the upper width 112 of the external exposure surface of the trapezoidal member 110 of the first module member 100 disposed at both ends thereof may be provided.

As a result, as shown in FIG. 1, the lower end surface of the first polygonal module 410 and the upper end surface of the second polygonal module 420 coincide with each other, thereby stacking the polygonal module 400 to form the modular wind tower 10. When forming the may be a continuous stacking of the polygonal module 400.

The flange portion 300 may be installed at an end of the module member. For example, at least one flange portion 300 manufactured separately in advance may be installed at the circumferential end portion and the height end portion of the module member. In a state where the flange portion 300 is pre-installed on the module member, the flange portion 300 may be connected to the inside of the polygonal modular wind tower 10 and the flange portion 300 facing the adjacent module member. have.

In addition, the flange portion 300 may be connected in whole or part in the longitudinal direction or the circumferential direction of the module member by bolting, riveting or welding.

As shown in FIGS. 5A and 5B, the flange part 300 surrounds an outer surface and one end portion of the module member, and has an inward protrusion part 311 formed to protrude inward of the polygonal modular wind tower 10. It is provided with an L-shaped member 310 and a plate-shaped member 320 disposed on the inner surface of one side end of the module member, the L-shaped member 310 and the plate-shaped member 320 by bolting Connected and installed at the end of the module member, the inward protrusion 311 of the flange portion 300 of the flange member 300 adjacent to the inward protrusion 311 of the flange portion 300 is the polygonal modular wind power Bolted in the tower 10 may be connected.

6A and 6B, the flange part 300 is installed so that one end of the module member can be inserted therein, and the inward protrusion part 311 protruding inwardly of the polygonal modular wind tower 10 is formed. The inwardly projecting portion 311 of the flange portion 300 facing the module member adjacent to the inwardly projecting portion 311 of the flange portion 300 may include the polygonal modular wind tower 10. It can be connected by bolted inside the.

In addition, as shown in Figures 2 to 3b, the flange portion 300 is a vertical flange portion which is bent inwardly at both ends in the circumferential direction of the module member for continuous coupling in the circumferential direction of the module member 300 and a horizontal flange 300 which is bent inwardly at both ends in the height direction of the module member for continuous coupling in the height direction of the module member.

In addition, the flange portion 300 is provided with a vertical flange portion 300 that is bent in the inner direction of the module member for continuous coupling in the circumferential direction of the module member is adjacent to the vertical flange portion 300 mutually Connected, at least one horizontal flange portion 300 is prepared separately in advance in the height direction of the module member for continuous coupling in the height direction of the module member, the flange portion 300 is the module member In the pre-installed state, the flange portion 300 may be connected in the interior of the polygonal modular wind tower 10 and the opposite flange portion 300 of the adjacent module member.

In addition, the flange portion 300 is provided with at least one vertical flange portion 300 separately prepared in advance for the continuous coupling in the circumferential direction of the module member, the flange portion 300 in advance to the module member In the installed state, the flange portion 300 is connected in the interior of the polygonal modular wind tower 10 and the opposite flange portion 300 of the adjacent module member, for continuous coupling in the height direction of the module member The horizontal flange portion 300 is formed to be bent in the inner direction of the module member is provided, the adjacent horizontal flange portion 300 may be connected to each other.

In addition, although not shown in the drawings, the polygonal modules 400 stacked up and down with the module members disposed adjacent to each other may not be connected to each other by welding together without including the flange portion 300.

First, the embodiments of the present invention have been described in detail above, but the scope of the present invention is not limited thereto, and various modifications and variations can be made without departing from the technical spirit of the present invention described in the claims. It will be apparent to those of ordinary skill in the art.

10: Modular Wind Tower
100: first module member
110: trapezoidal member
111: lower width of the outer exposed surface of the trapezoidal member
112: upper width of the outer exposed surface of the trapezoidal member
200: second module member
210: upper second module member
211: lower width of the outer exposed surface of the upper second module member
220: lower second module member
221: upper width of the outer exposed surface of the lower second module member
300: flange portion
310: L-shaped member
311: inward protrusion
320: plate-shaped member
400: polygon module
410: first polygon module
420: second polygon module

Claims (11)

In the modular wind tower formed by continuously stacking a plurality of polygonal modules in the height direction,
The polygonal module,
A plurality of first module members disposed at an edge of the polygonal module and provided in the same shape so as to be commonly applied to each of the polygonal modules to be stacked; And a plurality of second module members provided with a narrow width of the surface, and continuously connecting the first module member and the second module member in the circumferential direction to form a large cross section of a modular wind tower, and having a diameter toward the top. Is reduced,
The first module member is provided in a form in which the cross-sectional area is reduced toward the top,
The external exposure surface of the first module member is provided with a hypotenuse of the two trapezoidal members are joined, bent relative to the hypotenuse,
The external exposure surface of the second module member is provided as a rectangular member,
The first module member and the second module member is provided at the same height,
The trapezoidal members disposed at both ends of the second module member and the circumferential direction of the second module member are arranged in a straight line in the circumferential direction,
The sum of the lower width of the outer exposed surface of the second module member stacked on the upper side and the lower width of the outer exposed surface of the trapezoidal member of the first module member disposed at both ends thereof,
And a sum of an upper width of an outer exposure surface of the second module member stacked below and an upper width of an outer exposure surface of the trapezoidal member of the first module member disposed at both ends thereof. Wind Tower. The method of claim 1,
The polygonal module is connected to the first module member and the second module member are alternately arranged in the circumferential direction,
The connection between the polygonal modules stacked up and down, the end of the adjacent first module member stacked up and down are connected, respectively, characterized in that the end of the adjacent second module member stacked up and down are connected, respectively Modular wind tower. delete delete delete The method according to claim 1 or 2,
At least one flange portion separately prepared in advance is provided at a circumferential end portion and a height end portion of the module member which is at least one of the first module member and the second module member,
Modular wind tower, characterized in that the flange portion is pre-installed in the module member, the flange portion is connected in the interior of the modular wind tower and the flange portion facing the adjacent module member. In the modular wind tower formed by continuously stacking a plurality of polygonal modules in the height direction,
The polygonal module,
A plurality of first module members disposed at an edge of the polygonal module and provided in the same shape so as to be commonly applied to each of the polygonal modules to be stacked; and disposed between the first module members and externally stacked And a plurality of second module members provided with a narrow width of the surface, and continuously connecting the first module member and the second module member in the circumferential direction to form a large cross section of a modular wind tower, and having a diameter toward the top. Is reduced,
At least one flange portion, which is separately manufactured in advance, is provided at a circumferential end portion and a height end portion of the module member which is at least one of the first module member and the second module member,
In the state where the flange portion is pre-installed in the module member, the flange portion is connected to the inside of the modular wind tower and the flange portion facing the adjacent module member,
The flange portion,
An L-shaped member surrounding an outer surface of the module member and one end thereof, the L-shaped member including an inwardly projecting portion formed to protrude inwardly of the modular wind tower, and a plate-shaped member disposed on an inner surface of one end of the module member. The L-shaped member and the plate-shaped member are connected by bolts and installed at the end of the module member.
The inwardly projecting portion of the flange portion facing the inwardly projecting portion of the flange portion adjacent to the modular member is modular wind turbine, characterized in that connected to the bolted inside of the modular wind tower. The method of claim 6, wherein the flange portion,
One end of the module member is installed to be inserted, the modular wind tower, characterized in that it comprises an inward projection protruding inwardly of the modular wind tower. The method of claim 6,
The flange portion is a modular wind tower, characterized in that the whole or part is connected in the longitudinal direction or circumferential direction of the module member by bolting, riveting or welding. The method according to claim 1 or 2,
A vertical flange portion bent at both ends of the circumferential direction of the module member for continuous coupling in the circumferential direction between the module member which is at least one of the first and second module members;
Modular wind tower comprising a horizontal flange that is bent at both ends in the height direction of the module member for continuous coupling in the height direction of the module member. The method according to claim 1 or 2,
Modular wind tower, characterized in that between the module member which is at least one of the first module member and the second module member disposed adjacent to, and the polygonal modules stacked up and down are joined by mutual welding.

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