JP4476096B2 - Construction method of large high-rise wind farm - Google Patents

Description

The present invention is, for example, in the technical field of constructing a large-scale, high-rise, high-output wind power plant, particularly a reinforced concrete structure (hereinafter sometimes abbreviated as RC structure) or a steel reinforced concrete structure (hereinafter abbreviated as SRC structure). large high-rise tower body.), the mobile frame construction method, or while building a prefabricated form System (PCF method) using precast concrete formwork, in which a large weight, which are a major component of the wind power plant Power generators (hereinafter sometimes referred to as nacelles), heavy cranes such as small cranes, and other heavy equipment are mounted on a moving stage (hereinafter referred to as a climbing stage) in advance to double the construction of a large high-rise tower. Yuki lifted along with the climbing stage Te, after completing the construction of large-scale high-rise tower body, installed power generation equipment on the climbing stage to the tower body, the rotor Until the attachment, the construction without using a large-scale crane, belonging to the technical field of construction method of large-scale high-rise wind power plant.

As the demand for conservation and protection of the global environment increases, the construction of wind power plants is increasing rapidly. Currently, it is said that the wind power output in Japan is about 700,000 KW, but it will reach 3 million KW in 2010 and is likely to increase further thereafter.
As expectations for wind power generation as described above have increased, it has become necessary to increase the output per unit and reduce the unit price of power generation. Incidentally, it is estimated that when the output is doubled, the unit price of power generation is reduced to 0.7 times.
Increasing the power output of a wind power plant will ultimately increase the tower diameter and the rotor diameter. The height of the existing 600 KW class tower is about 40 m, but the height of the 1.5-2 MW class tower under construction reaches 65 m. The rotor diameter of the 5 MW class, which is being considered for future construction, is over 110 m, the height of the tower is over 120 m, and the height of the 10 MW class tower is estimated to be up to 170 m.

The tower required for the construction of a large wind power plant as described above is said to be superior in RC construction when the height of the tower is 100 m or more. From steel construction to reinforced concrete construction (RC construction) or steel reinforced concrete construction ( It is forced to change to SRC construction.
In any case, regarding the construction of large-scale wind power plants, it is said that the proportion of towers in the total material cost ranges from 20 to 35%, and it is known that the construction period of towers greatly affects the entire construction period. It is clear that the rationalization of wind power plant construction depends on the cost reduction of tower construction and the shortening of construction period.

  Conventionally, as means for constructing a large RC or SRC tower, a slip foam apparatus as disclosed in the following Patent Document 1 and a slip foam method using the slip foam apparatus have been widely adopted. Patent Document 2 discloses a technique in which when a high-rise tower body is constructed with a slip foam apparatus, a vibration damping device including a water tank is installed on the work floor of the apparatus.

Further, Patent Document 3 below discloses an assembling method and an assembling apparatus for constructing a wind power plant without using a large crane.
Patent Document 4 discloses a climbing apparatus that is convenient to lift and assemble a tower structure and a generator, blades divided into blocks using a small truck crane, and a construction method using the climbing apparatus.
Patent Document 5 discloses an example of a preformed frame method (PCF method) in which an RC structure is constructed using a precast concrete formwork.

Japanese Patent Publication No.59-33746 Utility Model Registration No. 2557184 JP 2001-254668 A JP 2003-184730 A Japanese Patent Laid-Open No. 7-80822

As a typical example of the existing technology, in FIGS. 5 (I) to (V), a steel tower block a divided into a plurality of blocks in the height direction by a super large crane P juxtaposed along the tower body, b, with the construction of a tower body T by annex sequentially lift the c, further power equipment (nacelle) installed by lifting the Q to the tower member T, the method of construction of the wind power plant by attaching a rotor R pivotal Conceptual steps.
6 (I) to 6 (VI), a RC tower body T is constructed in series by the movable mold apparatus S, and a generator (nacelle) Q is constructed by a super large crane P juxtaposed on the tower body T. Is conceptually shown as a main procedure of the construction method of constructing a wind power plant by attaching a rotor R to a tower T and then installing it on a tower T.
As described above, the use of a super-large crane P was indispensable for the construction of a large-scale wind power plant using the existing technology. However, it is said that the maximum height of the past applicable super large crane P is about 70 m.
The crane height required for a 5 MW class wind power plant that is planned for future construction is over 120 m, but at present there is no such super large crane in Japan. Even if such a super-large crane could be manufactured, it would be very expensive due to its low versatility, and it was expected to be a big difficulty due to the restrictions on road transportation. Is low.

  In consideration of the above circumstances, Patent Document 3 discloses an assembling method and an assembling apparatus for constructing a wind power plant without using a large crane. However, the specific height of the tower body in the publication is only 30 m (paragraph number [0002]). In addition, the tower body is a system that is completed by stacking three tower units in sequence, and the gate-type frame is a structure in which a lifting device is installed at the lower part and the pillars are raised and raised sequentially. Although it is possible to pay attention to the point that it is suspended and temporarily fixed to the cross girder of the frame, it is difficult to recognize that it is a technology that can be applied to the construction of towers exceeding 100 m.

  The climbing device disclosed in Patent Document 4 is also a technique that uses a small truck crane to lift and assemble a tower structure, a generator, and blades divided into blocks. It is not a technology that can be applied to the construction of the body.

An object of the present invention, the construction of large high-rise tower of 100m greater, as S RC structures or RC structure, the mobile frame construction method, or while building a prefabricated formwork construction method using a precast concrete formwork, in which to, it is mounted on a large weight of the power generation equipment (nacelle) and small crane or the like of the crane and other the required weight equipment in advance climbing stage on the main elements of the large-scale wind power plants, large-scale high-rise tower body of Yuki lifted in the construction process and climbing stage before Symbol weight equipment to together, after completing the construction of the tower body, a power generation device on the climbing stage using crane on the climbing stage to the tower member top installation, it attaches the rotor until the completion of the wind power plant of large-scale high-output, to build without using a large crane, provides a construction method of a wind power plant of large high-rise It is to be.

As a means for solving the above-described problems of the prior art, a construction method for a large high-rise wind power plant according to the invention described in claim 1 is:
Assemble the mobile frame 1 for搭体construction ground 搭体 construction position of a large high-rise wind power plant, built a plurality of struts 2 to the surrounding site, supported on the climbing device 6 for lifting the tower 2 and the climbing stage 3 is extended between the strut 2,2, power generation equipment 4 and small crane 5 is required on the wind power plant on the same climbing stage 3, crane and other heavy device such hoist And suspending the movable mold 1 under the climbing stage 3;
The small crane 5 on climbing stage 3, using the crane of the hoist is extended upward replenishing unit posts to the support 2, is raised along the climbing stage 3 to the support 2 by climbing device 6, the the method comprising advancing the construction of large high-rise tower body 10 of RC or SRC Concrete utilizing mobile frame 1 which is suspended in climbing stage 3,
To complete the construction of large high-rise tower body 10, after the pouring of concrete has been expressed a strong degree, the steps of removal and dismantling the mobile frame 1,
Installed a click Lai timing stage 3 power generation device 4, which is mounted on the large-scale high-rise tower body 10 using a crane small crane 5 and hoist or the like on the same stage three digits, also, the ground using the same crane Lifting the rotor 20 from the power generator 4 and attaching it to the power generator 4 to complete the assembly of the wind power plant ,
Then, using the hoist such as the small crane 5 and hoist, the column 2 is disassembled for each unit column , the climbing stage 3 is lowered to the ground, and then the climbing stage 3 is disassembled and removed. Features.

A construction method of a large-scale high-rise wind power plant according to the invention described in claim 2 is:
It built a plurality of struts 2 to the peripheral portion position of 搭体 construction position of the wind power plant of a large high-rise, the climbing stage 3 supported bridged between posts 2,2 climbing device 6 for lifting the tower 2, power equipment 4 and small crane 5 is required for the construction of the wind power plant on the same climbing stage 3, equipped with a crane and other heavy device such as a hoist, also under the click Rye timing stage 3 Similarly, a preformed frame work stage 21 supported by the climbing device 6 that moves up and down the column 2 is installed between the columns 2 and 2, and a preformed frame 22 for tower construction is installed on the preformed frame work stage 21. Stages,
Using a lifting machine such as the small crane 5 and hoist on the climbing stage 3, a unit column is added to the column 2 and extended upward, and the climbing stage 3 is first raised along the column 2 by the climbing device 6 . Subsequently, the preformed frame work stage 21 is lifted by the climbing device 6 , and the large-sized high-rise tower body 10 made of RC or SRC is constructed using the tower-built preformed frame 22 installed on the preformed frame work stage 21. And proceeding with
A step to complete the construction of large high-rise tower body 10, after the pouring of concrete has been expressed a strong degree of removal dismantle the prefabricated formwork work stage 21 and preformed mold 22,
Climbing stage 3 small crane 5 on the power generation device 4, which is mounted the stage 3 on, only installation to a large high-rise tower body 10 using a crane hoist, etc., also, from the ground using the same crane Lifting the rotor 20 and attaching it to the power generator 4 to complete the assembly of the wind power plant ;
Then, using the hoist such as the small crane 5 and hoist, the column 2 is disassembled for each unit column , the climbing stage 3 is lowered to the ground, and then the climbing stage 3 is disassembled and removed. Features.

The invention described in claim 3 is the construction method of the large high-rise wind power plant described in claim 1 ,
The vibration damping device 15 is installed on the climbing stage 3 , and the attitude control device 13 for the movable mold 1 is installed as a means for suspending the movable mold 1 from the climbing stage 3.

According to the construction method of large-scale high-rise wind farm according to the invention described in claim 1 to 3, large-scale wind farms heavy power devices, which are a major component (nacelle) 4, small crane 5 and the like crane of weight equipment which is other necessary is installed in advance on climbing stage 3, also mobile frame construction method also serves to build SRC Concrete or RC structures tower body 10 by the box-type frame method (PCF method), Yuki lifted along with the climbing stage 3, after completing the construction of large-scale high-rise tower body 10, installed using a crane such as a small crane 5 on the climbing stage 3 power generation equipment 4 to the tower body 10, and further the climbing stage the small crane 5 and the like on the 3 than attaching lifting the rotor 20 to the power generation device 4, so-called build and large large rise tower body 10 also 100m greater than without using large cranes A high-rise wind farm can be constructed . Then, the construction period of the reduction and cost reduction can Figure Rukoto, it is possible to build a large-scale high-rise wind power plants as the culmination of economically safely past technology.

Built posts 2 ... a plurality of the peripheral portion position of 搭体construction position of a large high-rise wind power plant, a climbing stage 3 supported bridged between posts 2 ... climbing device 6 for lifting the tower 2, the wind power equipment 4 and small crane 5 is required for the construction of the wind power plant, crane, such as hoist 8, the unit column other weight equipment mounted on the climbing stage 3, under the climbing stage 3 The movable mold 1 is suspended or a prefabricated frame work stage 21 is installed and a prefabricated frame 22 for tower construction is installed.
Then, the small crane 5 on climbing stage 3, by using the crane such as a hoist 8 is extended upward replenishing unit posts to the strut 2, the climbing stage 3 is the upper temperature by climbing device 6, the The construction of the large-sized high-rise tower body 10 made of RC or SRC is advanced using the movable form frame suspended on the climbing stage 3 or the pre-formed frame 22 for tower construction installed on the pre-formed frame work stage 21 .
Thus to complete the construction of large high-rise tower body 10, after the pouring of concrete expressed the strength and removed by disassembling the mobile frame 1, or ready-made mold work stage 21 and the ready-made mold 22.
Then, installing a small crane 5 on the click Rye timing stage 3 the same stage of the wind power generation device 4, which is mounted on the 3, using a crane, such as a hoist 8 to the large high-rise tower body 10. Moreover, the rotor 20 is lifted from the ground using the same lifting machine and attached to the wind power generator 4 to assemble the wind power plant .
Thereafter, the climbing stage 3 is lowered to the ground while the pillar 2 is disassembled and removed for each unit pillar using a lifting machine such as the small crane 5 and the hoist 8 , and then the climbing stage is disassembled and removed.

1 (I) to (VI) show the construction of a large high-rise tower body 10 by a moving stage equipped with the heavy equipment according to the first and third aspects of the invention , and the construction of a wind power plant by the large high-rise tower body 10. An embodiment of the method is shown conceptually as a key process diagram.
This construction method is merely indicate how so-called mobile frame construction method, FIG. 1 (I) constructs a pre Me concrete foundation 14 in construction position of a large high-rise tower body thereon, slip The movable mold 1 for the foam method or the jump form method is assembled and installed . Further, the movable mold 1 around the building struts 2 ... a plurality of the ground around the site of the assembles the strut 2 ... a along climbing stage supported by the climbing device for lifting and 3 (movable stage) Erection. And, on the climbing stage 3, heavy equipment such as a wind power generator (nacelle) 4 and a small crane 5 required for the construction of a wind power plant that uses the large high-rise tower body 10 is mounted, A stage in which the movable mold 1 is suspended under the climbing stage 3 is shown.

Incidentally, FIGS. 2 and 3 are produced by constructing four columns 2 around the large high-rise tower 10 to be constructed, and flooring the steel frame structure as light and rigid as possible. climbing stage 3, to the four posts 2, respectively show climbing device 6 by being Ri支 lifting the erection configurations having a self-rising function. Since the column 2 is dismantled and removed after the construction is completed, for example, a unit column prepared with a fixed unit length by providing joints at both ends of the steel pipe is prepared, and this is mounted on the climbing stage 3 as necessary. It is built sequentially by a method of lifting with a small crane 5 and adding it to extend upward . The climbing device 6 is already well known and well known, and therefore detailed illustration is omitted. For example, the lifting jack, the upper and lower locking mechanisms, and the support column disclosed in Japanese Patent No. 3388286 of the present applicant are omitted. It can be carried out by adopting a configuration comprising a reaction force plate or the like provided in the above. Naturally, a reaction force plate is provided in advance on the unit column.

As shown in FIG. 2 , the wind power generator (nacelle) 4 which is a precision instrument is provided with a hut 7 having a considerable size on the climbing stage 3 and is housed in the hut 7 for protection as much as possible. Mounted in a conserved structure.
As shown in FIG. 3, the bottom of the hut 7 is open in advance, and the wind power generator (nacelle) 4 is mounted in such a manner that a cradle that horizontally crosses the open surface is removably installed. , Ru Tei provided finally installing Lower to the top of the tower body 10 work. As shown in FIG. 3 , on the lower surface of the climbing stage 3, assembling work of steel frames and reinforcing bars necessary for the construction work of the RC tower body 10 by the movable mold 1, maintenance of the movable mold 1, ground concrete hoist 8 and running rail 9 and traverse rail 11 and the like are frequently used, such as the support of the concrete transport tube being pumped is provided from the pump wheel. At the hanger 12 that suspends the movable mold 1 from the climbing stage 3, an attitude control device 13 that should be called an automated turnbuckle mechanism that mainly expands and contracts the axial length of each hanger 12 is installed.
On the climbing stage 3, in addition to installing a vibration damping device 15 necessary for ensuring the safety and stability of super-high-rise work over 100m , centralized management and management of each climbing device 6 ... and attitude control device 13 for control, and centralized management and control panel 16 for performing communication, such as with the ground it is installed. The curing means for protecting workers on the climbing stage 3 and the means of transportation with the ground are not shown.

As for the movable mold 1 as well, for example, the slip-form device disclosed in the above-mentioned Patent Documents 1 and 2 is not mentioned, and the jump-up method and its device are already well-known and well-known, so they will be illustrated in detail. I omitted it. The pouring of assembly and concrete steel and reinforcing bars continuously performed better efficiency, for row cormorants configuration with high accuracy will not require Many of description. However, in the present invention, the mobile frame 1 than move pulled rise accordance self upward movement of climbing stage 3 by the climbing device 6, climbing jacks and the climbing jacks seen climbing device basically history There is no need for a climbing rod. Therefore, it will be particularly explained that the effect of reducing the degree of congestion of the steel frames and reinforcing bars of the SRC structure or RC tower 10 is great.
However, the period of full attitude control of the mobile frame 1, or at the means to achieve easiness, it is preferable that features a minimal climbing rods and climbing jack. For the sake of convenience, although not shown in the figure, an SRC structure or RC tower body 10 steel frame assembly, processing, reinforcing bar arrangement, concrete placement and other work scaffolding are provided on the outer periphery of the movable mold 1.

Returning to the description of FIG. In configuration described above, wind power equipment (nacelle) which is a bridging of the climbing stage 3 relative strut 2, required for the construction of a wind power plant utilizing the large rise tower body 10 on the climbing stage 3 4 and small When the installation of the heavy equipment such as the crane 5 and the assembly of the movable mold 1 and the preparation for the suspension to the climbing stage 3 are all completed, the process proceeds to the stage shown in FIG . In other words, was prepared in advance on the ground as described above, or climbing and lifting a small crane 5 on the stage 3 a unit posts that had piled up in advance on the same stage 3, also up hanging in a small crane 5, on top of the tower 2 by heavy I method plus adoptive loading to performs way built which extends up to the support column 2 sequentially upward.
Thereafter, the Ru climbing stage 3 is moved rises a mobile frame 1 which is suspended in the climbing stage 3 causes self raised by the climbing apparatus 6 ... synchronization control. The assembled steel or rebar using the mobile frame 1, and the reinforcement or the like, Me the task of pouring the concrete advances, a large etc. frustoconical gradually reduced in diameter as it goes upward Construction of the high-rise tower body 10 will proceed (FIG. 1 (II)). In the case of the slip form method, it is well known that the construction of the vehicle body is advanced by repeating the process of moving up and moving the movable mold 1 continuously, and in the case of the jump form method, jumping up by a certain stroke (or step). It is as follows.
Incidentally, it is estimated that the diameter of the lower end portion of the large high-rise tower body 10 exceeding 120 m above the ground is about 10 m to 12 m and the wall thickness is about 60 cm to 1 m.

FIG. 1 (III) shows the stage where the construction of the large high-rise tower 10 is completed to the top as described above, and after the cast concrete is developed to have the required strength, the movable form 1 is disassembled and removed. Show.
FIG. 1 (IV) shows a stage where the nacelle 4 on the climbing stage 3 is suspended and installed on the top of the large high-rise tower body 10 immediately below.
Further, FIG. 1 (V) shows a stage where the rotor 20 is lifted from the ground using the small crane 5 on the climbing stage 3.
FIG. 1 (VI) shows the stage where the rotor 20 is attached to the nacelle 4 to complete the assembly of the large-scale and large-output wind power plant, and the entire process from the disassembly and removal of the support column 2 and the climbing stage 3 is completed. ing.
Incidentally, demolition of the tower 2, removal is a central portion of the climbing stage 3, on which was disassembled to the extent that large high-rise tower body 10 constructed above passes to form a cavity (through portion), the Climbing Every time the stage 3 is lowered by a certain stroke, the operation of disassembling the support column 2 for each unit column using the small crane 5 is repeated. The climbing stage 3 descending to the ground completely dismantles and removes the outer peripheral portion remaining at the ground level.
As described above, the need for large crane was essential to the construction of conventional large-scale high-rise wind farms, makeshift et al is a small crane 5 on the climbing stage 3, is useless. Therefore, it is possible to construct a large high-rise wind power plant at low cost and in a short construction period. If the nacelle 4 and the rotor 20 are extremely large and heavy and are not in time for the small crane 5 on the climbing stage 3, a winch dedicated to lifting such heavy objects can be installed, or the climbing stage 3 It is necessary to take measures such as further increasing the number of small cranes 5 mounted on the top .

Next, FIG. 4 (I) ~ (VI) is an example of a construction method of a large high-rise wind farm utilizing the moving stage equipped with heavy component, conceptually illustrates the pivotal process chart.
The construction method of the present embodiment shows a method by a pre-formed frame method (PCF method) in which half precast concrete is usually used as a so-called pre-formed frame.
In FIG. 4 (I), a plurality of support pillars 2 are built around a concrete foundation 14 built in advance at the construction position of the large high-rise tower body 10 , and climbing supported by a climbing device that raises and lowers the support pillar 2. Stage 3 (moving stage) is installed at the upper level. Below that, a pre-formed frame work stage 21 is installed and installed in a structure supported by a climbing device that also lifts and lowers the column 2. The large rise tower body 10, and large-scale wind power plants require a by Ru wind power equipment 4 (nacelle) and the weight equipment of small crane 5 on the climbing stage 3, in the same manner as in Example 1 Install . FIG. 4 (I) shows that the prefabricated prefabricated frame 22 is installed on the prefabricated frame work stage 21, and the construction of the SRC or RC high-rise tower 10 is started using this. Shows the stage.
Since the structure of the climbing stage 3 and the configuration of the climbing apparatus are the same as those described in the first embodiment, the same reference numerals are used and the same description is not repeated here again. Further, the structure of the ready-made mold work stage 21, and configurations for such also climbing device, since the configuration for said climbing stage 3 common many as those described in Example 1 above, wherein by repeating again similar description Will be omitted.

Figure 4 (II) and (III), built to extend upwardly shirttail on SL support 2, is raised in advance the climbing stage 3, high followed scratch prefabricated formwork work stage 21 Construction of Ascending by minute (one step) , one after another, prefabricated frames for tower construction (... 22M, up to 22N) are assembled and installed, and steel frames and rebars are assembled and concrete is placed, and SRC or RC large high-rise building The stage in which the construction of the tower body 10 has been repeated is shown.

Next, FIG. 4 (IV) shows the generation of power on the climbing stage 3 by disassembling the pre-formed frame work stage 21 after the construction of the large high-rise tower body 10 is completed and the cast concrete exhibits the necessary strength. The stage where the apparatus (nacelle) 4 is lowered and installed on the large high-rise tower body 10 to assemble the wind power plant is shown.
Furthermore, FIG. 4 (V) shows the operation | work stage which lifts the rotor 20 from the ground using the small crane 5 on the climbing stage 3. FIG.
4 (VI), the rotor 20 is attached to the power generation device (nacelle) 4 to complete the assembly of the large-scale and large-output wind power plant (large-sized high-rise tower structure), and the support 2 and the climbing stage 3 are disassembled. , Showing the stage completed until removal.
As described in the first embodiment, the column 2 is disassembled and removed after the central portion of the climbing stage 3 is disassembled to the extent that the large-sized high-rise tower 10 that has been constructed passes therethrough. Each time 3 is lowered by a certain stroke, the process of disassembling the support column 2 for each unit column using the small crane 5 is repeated. Then, the climbing stage 3 descending to the ground completely dismantles and removes its outer peripheral portion at the ground level.
In this way, the construction of a large high-rise wind power plant can be carried out at a low cost and in a short construction period without requiring a large crane, which has been essential in the past.

  Although the present invention has been described above based on the illustrated embodiments, of course, the present invention is not limited to the above-described embodiments. As long as it does not deviate from the purpose and gist of the present invention, and the technical idea, it should be noted here that the present invention can be implemented in a wide variety of ways including design changes, modifications, and applications as necessary by those skilled in the art. .

(I)-(VI) is explanatory drawing which showed notionally the important process of Example 1 of this invention in order. It is the perspective view which showed the stage in the middle of construction with a bird's-eye view. It is the perspective view which decomposed | disassembled and showed the structure of the construction apparatus and the installation. (I)-(VI) is explanatory drawing which showed notionally the important process of Example 2 of this invention in order. (I)-(V) is explanatory drawing which showed notionally the important process of the conventional construction method in order. (I)-(VI) is explanatory drawing which showed notionally the important process of the conventional different construction method in order.

1 mobile form 2 support 3 climbing stage
4 Power generation equipment
6 Climbing device 10 Large high-rise tower
20 Rotor
21 Pre-formed frame work stage 22 Pre-formed frame 5 Small crane 8 Hoist 15 Damping device 12 Suspension means 13 Attitude control device

Claims (3)

Large high-rise on the ground 搭体 construction position of the wind power plant by assembling a mobile frame for搭体construction built plurality of supports on its periphery position, supported climbing stage climbing device for lifting said strut was bridged between posts, power generation equipment and small cranes are needed to build of the wind power plant, a crane and other heavy device such as a hoist mounted on the same climbing stage, under the climbing stage Suspending the movable form; and
Using a lifting machine such as the small crane and hoist on the climbing stage, the unit column was added to the column and extended upward , and the climbing stage was lifted along the column by the climbing device and suspended on the climbing stage . A stage of constructing a large high-rise tower of RC structure or SRC structure using a movable mold;
To complete the construction of large high-rise tower body, after the pouring of concrete has been expressed a strong degree, the steps of removal and dismantling the moving mold,
Click Rye timing small crane on the same stage of the power generation equipment that is mounted on the stage, only installation to a large high-rise tower body using a crane hoist, etc., also, said lifting the rotor from the ground using the same crane Attach to the power generation equipment and complete the assembly of the wind power plant ,
Thereafter, the small crane, while dismantling the supports for each unit column using crane hoist etc., lower the climbing stage to the ground, and wherein the step Toka Ranaru to then dismantle the climbing stage removal, Construction method for large high-rise wind farms . Built plurality of supports in the peripheral portion position of 搭体 construction position of a large high-rise wind power plant, a supported climbing stage bridged between posts climbing device for lifting the strut, the wind on the same climbing stage Power generation equipment required for the construction of the power plant , heavy cranes such as small cranes and hoists, and other heavy equipment are mounted, and also supported by a climbing device that lifts and lowers the props under the climbing stage. Installing a pre-formed frame work stage between the columns and installing a pre-formed frame for tower construction on this pre-formed frame work stage ;
Using a crane such as the small crane or hoist on the climbing stage, a unit column is added to the column and extended upward, and the climbing stage is first raised along the column by the climbing device , and then the prefabricated frame work stage is raised by the climbing device, comprising the steps of advancing the construction of RC or SRC Concrete large rise tower body by using a ready-made mold working stage tower body construction ready-made mold installed in,
And the stage to complete the construction of large-scale high-rise tower body, after the pouring of concrete was expressed a strong degree, to be removed by dismantling the off-the-shelf type frame work stage and off-the-shelf-type frame,
The power generation equipment that is mounted on a click Lai timing stage using a small crane, crane hoist or the like on the same stage installation to a large high-rise tower body, also, the power generation lifting the rotor from the ground using the same crane A stage to attach to the equipment and complete the assembly of the wind farm ,
Thereafter, the small crane, while dismantling the supports for each unit column using crane hoist etc., lower the climbing stage to the ground, and wherein the step Toka Ranaru to then dismantle the climbing stage removal, Construction method for large high-rise wind farms . Placing the damping device on the climbing stage, and wherein placing the attitude control system of the mobile frame in means for suspending the mobile frame from climbing stage, large high-rise wind power as set forth in claim 1 construction method of place.

Images