JP2010275705A - Method for extension and alteration of aerogenerator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for extension and alteration of an aerogenerator, which enables effective utilization of the existing aerogenerator even when a tower is removed, while extending and altering the existing aerogenerator. <P>SOLUTION: When building a new aerogenerator 2, the existing tower 13 of the existing aerogenerator 1 is removed, while an exiting foundation 11 and an existing pile 12 are left behind. A newly-built foundation 21 is constructed on the periphery of the existing foundation 11, and a newly-built pile 22 is driven below the newly-built foundation 21. Subsequently, a newly-built tower 23 is constructed above the newly-built foundation 21. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a method for extending and remodeling a wind power generator, and in particular, a wind power generator including a tower fixed to a foundation, a nacelle attached to an upper portion of the tower, and a windmill attached to the nacelle. It relates to extension and reconstruction methods.

  Conventionally, as this type of wind power generator that is generally used, a wind turbine generator in which a tower is fixed to a concrete foundation and a nacelle to which a windmill is attached is attached to the top of the tower is known. A generator and a speed increaser are accommodated in the nacelle, and a windmill is fixed to a rotor shaft protruding from the speed increaser. When the wind turbine blades receive wind and rotate, the speed increaser increases the rotational speed to a constant value, and the generator converts the rotational motion into electric power.

  This type of wind power generator is usually designed such that the useful life of the tower and the wind turbine is about 20 years. For this reason, after the designed service life has elapsed, the wind turbine generator is entirely dismantled from the foundation to the tower and then the wind turbine to construct a new wind turbine generator. However, when the wind power generator is removed, troubles for dismantling occur and waste increases.

  In order to mitigate this increase in labor and waste, the remaining strength of the first generation tower at the time of extension and renovation is specified, and the remaining strength of the first generation tower is used as part of the strength of the second generation tower. A method of expanding and reconstructing a generator is disclosed (for example, see Patent Document 1). According to this wind power generator expansion / reconstruction method, the second generation tower can use the remaining strength of the first generation tower, and therefore, the first generation tower can be reused. As a result, it is possible to reduce the labor and time for dismantling the wind power generator and the increase in waste.

JP 2009-68407 A

  However, in the method for expanding and remodeling a wind power generator disclosed in Patent Document 1, the residual strength of the first generation tower is used. For this reason, there is a problem that this method cannot be used when removing the first generation tower. Even if the first generation tower is left, the first generation tower may not be able to cope with the size depending on the size of the second generation tower. In such a case, there is a problem that the first generation tower may not be used efficiently.

  Accordingly, an object of the present invention is to provide a method for extending and remodeling a wind power generator that can effectively use the existing wind power generator even when the tower is removed when the existing wind power generator is expanded and remodeled. is there.

  A wind power generator expansion / reconstruction method according to the present invention that solves the above-described problem is a wind power generation comprising an existing tower fixed to an existing foundation, a nacelle attached to an upper portion of the existing tower, and a windmill attached to the nacelle. When expanding and remodeling the machine, the new foundation is built around the existing foundation in a state of being integrated with the existing foundation, and a new tower covering the periphery of the existing tower is built on the new foundation. .

  Generally, in this type of wind power generator, since the service life is determined according to the service life of the tower and the windmill, the foundation and the like will be removed even though the service life has not passed. . In this regard, in the method of extending and remodeling a wind power generator according to the present invention, a new foundation is constructed around the existing foundation in a state of being integrated with the existing foundation, and a new tower is newly installed in a state of covering the circumference of the existing tower. Build on the foundation. For this reason, it can be effectively used even in a wind power generator having an improved foundation with improved proof stress. As a result, the existing wind power generator can be used effectively. Moreover, since it is not necessary to remove the existing foundation, it is possible to reduce labor and waste associated with the removal of the existing foundation.

  Here, while constructing a new tower, or after constructing a new tower, the existing tower can be removed.

  Thus, the existing tower can be used for the construction of the new tower by constructing the new tower or by removing the existing tower after constructing the new tower. Specifically, for example, an existing tower can be used as a support such as a scaffold, or a lifting device can be provided and used as a lifting device if strength is allowed. Therefore, the existing tower can be effectively used for the construction of the new tower.

  Moreover, after constructing a new tower, the existing tower can be removed.

  Even when an existing tower is old and required to be removed, the existing tower may be used to construct a new tower. For this reason, by constructing a new tower and then removing the existing tower, even an existing tower to be removed can be effectively used.

  Furthermore, it can be set as the aspect which places a new pile in the lower part of a new foundation.

  Thus, the support force of the foundation which supports a new tower can be improved by driving a new pile in the lower part of a new foundation.

  Further, the new tower may be at least one of concrete and steel.

  As described above, the new tower can be made of either concrete or steel.

  Alternatively, in constructing a new tower, the lower part of the new tower can be made of concrete, and the upper part of the new tower can be made of steel.

  Thus, construction of the new tower can be facilitated by making the lower part of the new tower made of concrete and making the upper part of the new tower made of steel.

  And it can be set as the aspect whose concrete is prestressed concrete.

  Thus, since the concrete which comprises a newly built tower is prestressed concrete, the proof stress of a new tower can be made high.

  According to the method for extending and remodeling a wind power generator according to the present invention, when the existing wind power generator is remodeled, the existing wind power generator can be effectively used even when the tower is removed.

It is a side view of the wind power generator in which extension and reconstruction were performed according to the first embodiment. It is a plane sectional view of the wind power generator which was renovated. It is a side view of the foundation in the wind power generator in which extension and reconstruction were performed. It is a figure which shows the work process at the time of extending and remodeling a wind power generator. It is a figure which shows the operation | work process following FIG. (A) is a side view of the existing wind power generator in which extension and reconstruction are performed according to the second embodiment, and (b) is a side view of the new wind power generator after extension and reconstruction is performed. It is a figure which shows the result of the analysis at the time of determining the scale of the new foundation at the time of constructing a new wind power generator. (A) is a side view of the existing wind power generator in which extension and reconstruction are performed according to the third embodiment, and (b) is a side view of the new wind power generator after extension and reconstruction is performed.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. In each embodiment, portions having the same function are denoted by the same reference numerals, and redundant description may be omitted. First, a first embodiment of the present invention will be described. FIG. 1 is a side view of a wind power generator that has undergone extension / renovation, FIG. 2 is a plan sectional view thereof, and FIG.

  In the present embodiment, the existing wind power generator 1 indicated by a virtual line in FIG. As shown in FIGS. 1 to 3, the newly installed wind power generator 2 subjected to the extension and renovation according to the present embodiment includes an existing foundation 11 and a new foundation 21. The existing foundation 11 is a foundation that has been constructed before the extension and reconstruction are performed, and the new foundation 21 is a foundation that is newly established for the addition when the extension and reconstruction are performed. The existing foundation 11 and the new foundation 21 are both pile foundations, and the new foundation 21 is constructed so as to be integrated with the existing foundation 11.

  The existing foundation 11 includes an existing foundation lower step portion arranged at the lower stage and an existing foundation upper step portion arranged at the upper stage of the existing foundation lower step portion. The existing lower part of the foundation is a columnar body having a substantially regular hexagonal shape in plan view. Further, the existing foundation upper step portion is a columnar body having a substantially regular octagonal shape in plan view that is slightly smaller than the plan view shape of the existing foundation lower step portion.

  In addition, an existing pile 12 is driven under the existing foundation 11, and a new pile 22 is driven under the new foundation 21. The existing pile 12 is driven in the lower part of the existing foundation 11, and as shown in FIG. 2, eight existing piles 12 arranged in a circular shape and 1 in the center thereof are formed in the lower part of the existing foundation 11. The existing pile 12 of the book is driven.

  The new piles 22 are driven in the lower part of the new foundation 21, and eight new piles 22 arranged in a circular shape are driven in the lower part of the new foundation 21. These eight new piles 22 are arranged around the existing pile 12. Furthermore, as the new pile 22, a pile having a diameter larger than that of the existing pile 12 is used.

  A new concrete tower 23 is constructed on the new foundation 21. The new tower 23 has a circular cross-section, and the side view has a divergent shape with a narrow upper end and a wide lower end. A door serving as an entrance to the inside of the new tower 23 is provided at the lower end of the new tower 23.

  The interior of the new tower 23 is hollow. Furthermore, the new tower 23 is made of concrete as a whole, and its height is about 50 m. Further, the new tower 23 is fixed to the new foundation 21 by the PC steel material 24. The new tower 23 is supported not only by the new foundation 21 and the new pile 22 but also by the existing foundation 11 and the existing pile 12.

  A wind power generator 3 is provided at the upper end of the new tower 23. This wind power generator 3 is, for example, a 600 KW power generator. The wind power generator 3 includes a nacelle 31. In the nacelle 31, a generator and a speed increaser (not shown) are accommodated. Further, a rotor shaft (not shown) protrudes from the speed increaser, and a wind turbine hub 32 is fixed to the rotor shaft. Further, three blades 33 are fixed to the hub 32.

  The nacelle 31 is provided with a wind direction / anemometer main body (not shown), and measures the wind speed and the wind direction which change every moment. The nacelle 31 controls the direction of the windmill and the angle of the blade 33 in accordance with the wind speed and the wind direction measured by the wind direction / anemometer. Thus, efficient power generation is performed by controlling the direction of the windmill and the angle of the blade 33.

  Next, a procedure for extension and reconstruction of the wind power generator according to this embodiment will be described. In performing extension and reconstruction of the wind power generator according to the present embodiment, an existing wind power generator that has passed its useful life is used. FIG. 4A shows a side view of the existing wind power generator with the wind turbine removed. As shown in FIG. 4A, the existing wind power generator 1 includes an existing foundation 11. Further, an existing pile 12 is driven below the existing foundation 11. The existing foundation 11 and the existing pile 12 are used as a part of the new wind power generator 2 to be newly constructed.

  On the existing foundation 11, an existing tower 13 made of steel is provided. The existing tower 13 has a height of about 50 m, for example, and is as high as the new tower 23. The existing tower 13 is constructed on the existing foundation 11 and is supported by the existing foundation 11 and the existing pile 12. Thus, the pile foundation was used as a foundation also in the existing wind power generator. For the existing tower 13, a wind power generator equivalent to the 600 KW power generator provided in the new tower 23 is provided.

  In constructing the new wind power generator 2 by remodeling the existing wind power generator 1, first, as shown in FIG. 4 (a), the wind power generator is removed from the existing wind power generator 1, and the existing tower 13 is Let it remain. At this time, the existing foundation 11 and the existing pile 12 that support the existing tower 13 are left without being removed. Here, when the anchor ring which used the existing tower 13 as a fixing part is attached to the existing foundation 11, it is left as it is.

  Next, as shown in FIG. 4B, the lift-up jack R is transported to the top of the existing tower 13 by the large crane C, and the lift-up jack R is placed on the top of the existing tower 13 as it is. Further, a climbing formwork M is provided on the new foundation 21. At this time, the lower part of the new tower 23 is wide. For this reason, as the climbing formwork M, an outer frame and an inner frame are provided. Then, the lift-up jack R and the climbing formwork M are connected by the suspended steel material W.

  When the lift-up jack R and the climbing formwork M are connected, the reinforced concrete work at the bottom of the new tower 23 is performed. In carrying out this reinforced concrete work, a new pile 22 is driven around the existing pile 12, and a new foundation 21 is constructed around the existing foundation 11 so as to cover the existing foundation 11. The new foundation 21 is constructed above the new pile 22. Further, the new foundation 21 is constructed integrally with the existing foundation 11.

  Here, rebars and PC steel materials are incorporated in the lowermost part of the new tower 13, and these rebars and PC steel materials have a structure protruding from the lower end of the new tower 13. When constructing the new foundation 21, these reinforcing bars and PC steel are embedded in the new foundation 21. Thus, the new tower 13 is fixed to the new foundation 21 by the PC steel wire or the reinforcing bar.

  When the construction of the lowermost part of the new tower 13 is completed, the new tower 23 is gradually constructed from below as shown in FIG. When constructing the new tower 23, the new tower 23 is constructed for one lift of the climbing formwork M. When the construction of the new tower 23 for one lift of the climbing formwork M is completed, the climbing formwork M is pulled up by the lift-up jack R, and the construction of the new tower 23 is repeated.

  In order to repeat the construction of the new tower 23, as the climbing formwork M rises, it is necessary to assemble a scaffold at a high place. At this time, since the existing tower 13 remains, the existing tower 13 is used as a climbing formwork M and a support for the scaffold. As described above, by using the existing tower 13 as the climbing formwork M and the supporting column of the climbing formwork, the assembly of the climbing formwork M and the scaffolding is facilitated, and the construction can be facilitated.

  Thereafter, the construction of the new tower 23 is continued while raising the climbing formwork M until the inner frame of the climbing formwork M interferes with the existing tower 13. When the inner frame of the climbing formwork M interferes with the existing tower 13, the inner frame in the climbing formwork M is removed as shown in FIG. Meanwhile, the construction of the new tower 23 is continued by attaching the inner frame to the existing tower 13.

  Eventually, when the construction of the new tower 23 proceeds and the construction of the new tower 23 is completed, the lift-up jack R is disassembled and the climbing formwork M is removed. Thus, as shown in FIG. 5B, the new tower 23 is constructed outside the existing tower 13. Then, as shown in FIG. 5 (c), the existing tower 13 is removed from the top of the new tower 23. When the existing tower 13 is removed, the existing tower 13 is suspended and removed using a large crane.

  Thereafter, the newly installed wind turbine generator 2 is provided with the wind power generator 3 shown in FIG.

  Thus, in the extension and remodeling method of the wind power generator according to this embodiment, the existing foundation 11 and the existing pile 12 in the existing wind power generator 1 are used as they are as the foundation and pile of the new wind power generator 2 without being removed. is doing. For this reason, the proof stress in the existing foundation 11 and the existing pile 12 can be effectively utilized also in the new wind power generator 2. As a result, the existing wind power generator 1 can be used effectively. Moreover, it is not necessary to remove the existing foundation 11 and the new foundation 21. Accordingly, it is possible to reduce the labor and waste associated with the removal of the existing foundation.

  Further, in the method of expanding and remodeling a wind power generator according to this embodiment, the existing tower 13 is removed when the new tower 23 is being constructed. For this reason, the existing tower 13 can be used as a climbing formwork M or a scaffolding column. Therefore, since it is not necessary to separately provide these support columns, the new wind power generator 2 can be constructed efficiently correspondingly.

  Further, after the new tower 23 is constructed, the existing tower 13 is pulled out from the upper part of the new tower 23. For this reason. The existing tower 13 can be easily removed. Further, a new pile 22 is provided below the new foundation 21. For this reason, the support force which supports the new tower 23 can be made higher.

  Subsequently, a second embodiment of the present invention will be described. For example, in the above embodiment, an example in which the existing wind power generator and the new wind power generator have the same power generation capacity is shown, but the new wind power generator has a higher power generation capacity than the existing wind power generator. It can also be set as the aspect which is a wind power generator which has. In the present embodiment, a mode in which the newly installed wind power generator is a wind power generator having higher power generation capacity than the existing wind power generator will be described.

  In the present embodiment, for example, the new wind power generator 5 shown in FIG. 6B is larger than the existing wind power generator 4 shown in FIG. The existing wind power generator 4 shown in FIG. 6A includes an existing foundation 41 and an existing pile 42. The existing foundation 41 and the existing pile 42 are the same as those in the first embodiment. An existing tower 43 is provided above the existing foundation 41. On the existing tower 43, the wind power generator 3 (FIG. 1) similar to that of the first embodiment is provided. The existing tower 43 is made of steel as in the first embodiment.

  In addition, as shown in FIG. 6B, the new wind power generator 5 constructed by expanding and reconstructing the existing wind power generator 4 uses the existing foundation 41 as a foundation and is formed around the existing foundation 41. The new foundation 51 is also used. A new pile 52 is driven below the new foundation 51. The new foundation 51 and the new pile 52 are the same as those in the first embodiment.

  A new tower 53 is provided above the new foundation 51. The new tower 53 includes a new tower lower part 53A and a new tower upper part 53B, and the new tower lower part 53A and the new tower upper part 53B are joined by an adapter 54. The new tower lower portion 53A is made of concrete, and the new tower upper portion 53B is made of steel.

  The adapter 54 has a U-shaped cross section. In addition, bolt holes are formed in the upper end portion of the new tower lower portion 53A and the lower end portion of the new tower upper portion 53B, respectively. The new tower lower portion 53A and the adapter 54 are connected to each other by fastening a bolt that penetrates one piece of the adapter 54 into a bolt hole formed in the new tower lower portion 53A. Similarly, a bolt passing through a piece of the adapter 54 is fastened to a bolt hole formed in the new tower upper portion 53B, whereby the new tower upper portion 53B and the adapter 54 are connected. Thus, the new tower lower portion 53A and the new tower upper portion 53B are connected via the adapter 54.

  The new wind power generator 5 is obtained by increasing the size of the existing wind power generator 4, and the wind power generator provided in the existing wind power generator 4 is a 600 KW power generator, for example. The wind power generator provided in 53 is, for example, a 2000 KW power generator. For this reason, the new tower 53 is also enlarged, and its height is about 80 m in this case.

  In the extension and remodeling method of the wind power generator according to the present embodiment, the construction is performed up to the new tower lower portion 53A by going through the construction procedure similar to the construction procedure shown in the first embodiment and FIG. 4 and FIG. Here, in this embodiment, when the new tower lower portion 53A is formed, the adapter 54 is attached to the upper end portion of the new tower lower portion 53A, and then the existing tower 43 is removed.

  If the existing tower 43 is removed, the steel pipe used as the new tower upper part 53B will be conveyed above the new tower lower part 53A with a large crane, and it will match with the position of the adapter 54. Then, the new tower upper portion 53B is attached to the adapter 54 in a state where the steel pipe to be the new tower upper portion 53B is suspended by a large crane. After the installation work of the new tower upper portion 53B is completed, the wind power generator is attached to the upper end portion of the new tower 53, and the extension / remodeling of the wind power generator is completed.

  As described above, the method for extending and remodeling a wind power generator according to the present embodiment has the same effect as that of the first embodiment, and also has the effect of being able to be a large wind power generator. Become. Here, as the newly installed wind power generator 5 is enlarged, the supporting force required for the foundation also increases. On the other hand, although the proof strength remains about the existing foundation 41, it is difficult to reliably grasp the proof strength.

  Therefore, before the expansion and reconstruction of the wind power generator, the proof stress analysis is performed by the finite element method (FEM), and the support strength required for the newly installed wind power generator 5 and the proof strength required for the new foundation 51 are simulated. Is preferable. For example, as shown in FIG. 7 (a), a new wind power generator assumed as a construction target is divided into meshes, the stress state acting on each part of the existing foundation and the new foundation is grasped, and the existing foundation 41 is It is possible to design the new foundation 51 that can share the applied load with respect to the existing foundation 41 while effectively utilizing the proof strength possessed.

  Here, an example of the result of the FEM analysis is shown in FIG. In the FEM analysis here, the friction coefficient μ between the existing foundation 41 and the new foundation 51 was set to 0.6. As shown in FIG. 7 (b), in the existing foundation 41 and the new foundation 51, the internal stress is increased in the region X near the position where the existing pile 42 is provided and the position where the new pile 52 is provided. Further, in the new foundation 51, the internal stress becomes high in the region X in the vicinity of the portion to which the new tower 53 is connected.

  For example, even if the amount of reinforcing bars in the existing foundation 41 is small, if the amount of reinforcing bars as the structure of the newly installed wind power generator 5 is satisfied, the reinforcing bars in the existing foundation 41 are used as they are by increasing the amount of concrete. can do. In this case, the amount of reinforcing bars to be used can be reduced. Of course, when the amount of reinforcing bars is insufficient, it is possible to construct the necessary reinforcing bars on the new foundation 51.

  An economical new foundation 51 can be designed based on these analysis results. Furthermore, it is possible to grasp the difference in stress sharing due to the difference in adhesion between concrete in the existing foundation and the new foundation. Therefore, it is possible to select a new and old concrete adhesion method according to the design target. As described above, the new foundation 51 can be designed economically by designing the new foundation 51 after performing the FEM analysis.

  Subsequently, a third embodiment of the present invention will be described. In the method of expanding and remodeling a wind power generator according to this embodiment, the existing tower is left as it is inside the new tower without being removed. Here, the wind power generators that are the targets of the wind power generator expansion / reconstruction method according to the present embodiment are the existing wind power generator 6 shown in FIG. 8A and the new wind power generator 7 shown in FIG. 8B. And have the same height.

  The existing wind power generator 6 shown in FIG. 8A includes an existing foundation 61 and an existing pile 62. The existing foundation 61 and the existing pile 62 are the same as those in the first embodiment. An existing tower 63 is provided above the existing foundation 61. On the existing tower 63, the wind power generator 3 (FIG. 1) similar to that of the first embodiment is provided. The existing tower 63 is made of steel as in the first embodiment.

  Further, as shown in FIG. 8B, the new wind power generator 7 constructed by expanding and reconstructing the existing wind power generator 6 uses the existing foundation 61 as a foundation and is formed around the existing foundation 61. The new foundation 71 is also used. A new pile 72 is driven below the new foundation 71. These points are the same as those in the first embodiment. Furthermore, in the newly installed wind power generator 7 according to the present embodiment, the existing tower 63 is not removed and is left as it is.

  In the extension and remodeling method of the wind power generator according to the present embodiment, the new tower 73 is formed by performing the same construction procedure as the construction procedure shown in the first embodiment and FIGS. 4 and 5. Then, without removing the existing tower 63, a wind power generator is attached to the upper end part of the new tower 73, and the extension and remodeling of a wind power generator are completed.

  As described above, the wind turbine generator expansion / reconstruction method according to the present embodiment provides the same effects as those of the first embodiment. Furthermore, in the method for extending and remodeling a wind power generator according to this embodiment, the existing tower 63 is not removed and is left as it is. For this reason, it is possible to effectively use the existing tower 63 as it is. Moreover, since it is not necessary to remove the existing tower 63, it is possible to reduce the effort and the increase in waste.

  The existing tower 63 is considered to have no proof strength necessary for maintaining the power generation device, so it may be removed, but if it is used for other purposes, leave it as it is for other uses. Can be used. The existing tower 63 can be used as it is with the newly installed wind power generator 7 as it is for other purposes, such as a lifting ladder, landing, simple elevator, cable / electrical equipment, etc. that were originally installed in the existing tower 63. .

  The preferred embodiments of the present invention have been described above, but the present invention is not limited to the above embodiments. For example, in the second embodiment, when the wind power generator is increased in size, the new tower is made of two stages of concrete and steel. However, the new tower may be made of concrete or steel. Also in the aspect, the aspect of the new tower can be simply made of concrete or steel, or can be made of two stages of concrete and steel, or other combinations.

  Moreover, prestressed concrete can also be used as the concrete in the above embodiment. By using prestressed concrete as the concrete, the strength of the new tower can be increased.

  Furthermore, in each said embodiment, although the pile foundation is used as a foundation, another foundation, for example, a direct foundation, a caisson foundation, etc. can also be used. Moreover, when constructing a new foundation with concrete, prestressed concrete can also be used about the concrete used as this new foundation.

DESCRIPTION OF SYMBOLS 1, 4, 6 ... Existing wind generator 2, 5, 7 ... New wind generator 3 ... Wind generator 11, 11, 61 ... Existing foundation 12, 42, 62 ... Existing pile 13, 43, 63 ... Existing tower 21 , 51, 71 ... New foundation 22, 52, 72 ... New pile 23, 53, 73 ... New tower 24 ... PC steel 31 ... Nacelle 32 ... Hub 33 ... Blade 53A ... New tower lower 53B ... New tower upper 54 ... Adapter C ... large crane M ... climbing formwork R ... lift-up jack W ... suspended steel

Claims (7)

In extending and remodeling a wind power generator comprising an existing tower fixed to an existing foundation, a nacelle attached to an upper portion of the existing tower, and a windmill attached to the nacelle,
Build a new foundation around the existing foundation in a state integrated with the existing foundation,
A method for expanding and reconstructing a wind power generator, comprising: constructing a new tower covering the periphery of the existing tower on the new foundation.   The method for extending or remodeling a wind power generator according to claim 1, wherein the existing tower is removed while the new tower is constructed or after the new tower is constructed.   The method for extending or remodeling a wind power generator according to claim 2, wherein after the new tower is constructed, the existing tower is removed.   The method for expanding and remodeling a wind power generator according to any one of claims 1 to 3, wherein a new pile is driven in a lower portion of the new foundation.   The method for extending and remodeling a wind power generator according to any one of claims 1 to 4, wherein the new tower is at least one of concrete and steel.   5. The wind turbine generator according to claim 1, wherein when the new tower is constructed, the lower part of the new tower is made of concrete, and the upper part of the new tower is made of steel. 6. Renovation method.   The method according to claim 5 or 6, wherein the concrete is prestressed concrete.

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