JP4143517B2 - Construction method of tower structure - Google Patents

Description

  The present invention assembles a guide tower so as to surround the tower structure, provides a support mechanism between the tower structure and the guide tower, attaches a climbing device to the guide tower, and lifts and lowers the guide tower by the climbing device. The present invention also relates to a method for constructing a tower structure by lifting the tower structure, and more particularly, to a method for constructing a tower structure of a wind power generator.

In general, a high tower is constructed by connecting a plurality of block structures. In constructing the tower, the bottom block structure is erected on the foundation, and then the block structure is constructed. A high steel tower is constructed by lifting up objects with a truck crane and a climbing crane and stacking them in order.
In addition, towers such as wind power generators are constructed by building a steel tower structure, generators and blades, which are blocked in sequence, with a large truck crane or climbing crane. Wind generators are often constructed on mountains and coasts where roads are not maintained.First, a road for carrying large truck cranes used for building towers is prepared and a work place is set up for installing large truck cranes. I had to make sure. Thus, road maintenance at the preparation stage for constructing a steel tower has a problem that it greatly affects the construction period and construction cost for constructing a wind power generator.
In order to solve such problems, it is required to construct an efficient tower-like structure such as a wind generator, and in order to respond to this, a proposal for a method for constructing a tower-like structure such as a wind generator is proposed. (Patent Documents 1 and 2).
Japanese Patent Laid-Open No. 2002-242483 JP 2003-184730 A

The present invention further improves the previously proposed method for constructing a tower structure such as a wind power generator so that the work for constructing the tower structure of a wind power generator can be performed more safely. The guide tower is assembled so as to surround the tower structure, a support mechanism is provided between the tower structure and the guide tower, a climbing device is attached to the guide tower, and the guide tower is lifted and lowered by the climbing device. The present invention provides a method for constructing a tower-like structure in which a tower structure is lifted by a climbing device, and in particular, provides a method for more safely constructing a wind power generator.
The wind power generator is installed in a place with many wind days and strong winds, and it is natural that there are many wind days and winds during the construction work. It is necessary to perform construction work. Therefore, the present invention provides a block tower structure that is the lowermost part of the foundation, a tower structure that is connected to the block tower structure that is the lowermost part, and a column that constitutes the guide tower. It is an object of the present invention to provide a method for constructing a tower-like structure such as a wind power generator by improving the supporting mechanism to be attached so that the construction work of the wind power generator can be performed safely even if there is some wind.

  In the present invention, a block tower structure that is the lowest part is erected on the foundation, a guide tower composed of support columns is assembled so as to surround the lowermost block tower structure, and an extension mechanism is provided on the guide tower. And a climbing device having a carriage is attached, the climbing device is stopped, and the guide tower joint frame is connected and detached by the operation of lifting and lowering the guide tower by intermittent operation of the telescopic mechanism. The climbing device is a method of constructing a tower-like structure by lifting and lowering the tower structure along the guide tower by intermittent operation of its extension mechanism and connecting a plurality of block tower structures. A support mechanism is provided between the body structure and the guide tower, and the support mechanism includes a frame, a guide roller provided outside the frame, and an inner part thereof. A band body for fastening the tower body provided on the frame, a means for movably connecting the band body and a length adjusting means, and the support mechanism is connected to the inside of the frame. It consists of an upper band and a lower band that fasten the provided tower, and the upper band is connected to the upper plate and is connected to the upper plate so as to be swingable by a hinge. The lower belt is connected to the lower abutting plate, and is connected to the lower abutting plate so as to be swingable by a hinge. The hinge is connected to the lower abutting plate via a distance adjusting member. It is connected with a connection tool, and the upper connection tool and the lower connection tool are connected to a frame via a connection member.

In the tower-like structure construction method of the present invention, the support mechanism is configured such that the upper belt is connected to the upper holding plate via a fastening tool, and the lower belt is connected to the lower holding plate via a fastening tool. It is characterized by being.
In the tower-like structure construction method of the present invention, the support mechanism includes an upper contact plate, a hinge, an upper connection tool, a lower contact plate, a hinge, a lower connection tool, and a guide roller. It is characterized by being arranged substantially in a straight line between the substantially center and the support pillars constituting the guide tower.

Further, the tower-like structure construction method of the present invention is characterized in that the frame of the support mechanism is joined at the joint.
Furthermore, in the tower-like structure construction method of the present invention, a tower-like structure is constructed by connecting a plurality of block tower structures for lifting a plurality of blocked tower-like structures by a climbing apparatus, Further, the generator is assembled, and then the blades are assembled to the generator to construct a wind power generator.

  According to the present invention, the lowermost block tower structure is firmly erected on the foundation, and the guide tower is assembled so as to surround the block tower structure. A support mechanism to be attached between the tower structure connected on the block tower structure and the column constituting the guide tower is provided on the frame and the guide rollers provided on the outer corners and on the inner side thereof. In addition, the guide tower can be supported by the tower structure even if the guide tower is shaken by the wind. However, it is possible to safely construct a high tower structure such as a wind power generator without stopping the construction work.

  The wind power generator is installed in a place with many wind days and strong winds, and it is natural that there are many wind days and winds during the construction work. Construction work needs to be done. The present invention assembles a guide tower composed of support columns so as to surround the tower structure, and provides a support mechanism between the tower structure and the guide tower. The guide tower cannot be sufficiently supported by the tower structure, and the construction work must be stopped. Therefore, in the present invention, as a support mechanism, a frame, a guide roller provided outside the frame, a belt body for fastening the tower body provided inside the frame, and the belt body are connected to the frame through a member so as to be swingable. By using, a tower-like structure with a high wind power generator can be safely constructed without stopping construction work even in the wind.

  Moreover, this invention assembles the guide tower comprised by the support | pillar so that a tower structure may be enclosed, lifts a guide tower, connects a joint frame under it, and raises a guide tower. The guide tower is composed of four struts, and even if the struts are slightly bent or twisted, the bends or twists will increase as they become higher, and the support function of the guide tower may not be fulfilled. In the present invention, as a support mechanism, a frame, a guide roller provided outside the frame, a band for fastening the tower provided inside the frame, and a band connected to the frame through a member so as to be swingable are provided. By using it, it is possible to cope with the bending and twisting of the column. Further, it can cope with bending and twisting caused by the connection of the joint frame.

  The tower structure constructed in the present invention is a tower constructed by connecting blocked tower structures, and in particular, a tower is constructed by connecting blocked tower structures. A generator and blades are attached to the top of the tower, which is suitable for building a tower of a wind power generator.

Embodiments of the present invention will be described with reference to FIGS.
FIG. 1 is a perspective view schematically showing the construction of a tower structure according to an embodiment of the present invention. FIG. 2 is a perspective view schematically showing a support mechanism between the tower structure and the guide tower according to the embodiment of the present invention. 3 is a plan view showing a support mechanism between the tower structure and the guide tower, FIG. 4 is a cross-sectional view of the support mechanism of FIG. 3 along the broken line XX, and FIG. 5 is an enlarged view of the guide roller of the support mechanism. It is a figure. FIG. 6 is a view showing a support mechanism according to another embodiment of the present invention. 7 is a perspective view showing in detail an example of the climbing apparatus 5 in FIG. 1, FIG. 8 is a side view of FIG. 7, FIG. 9 is a plan view of FIG. 7, and FIG. .

  As shown in FIG. 1, a tower structure 1a having a lowermost block is erected on the base, and a guide tower comprising four columns 21 to 24 so as to surround the tower structure 1a being the lowermost block. 2 is assembled. The four struts 21 to 24 of the guide tower 2 are connected to each other by a beam 27 (a part of which is shown by a broken line) or a truss (not shown) to form a strong structure. Further, the columns 23 and 24 of the guide tower 2 are columns on the side where the lifted block tower structure or the like is loaded, and the position where the block tower structure or the like is loaded (in FIG. 1, the position above the guide tower 2). No), no beam or truss is provided between the columns 23 and 24.

Further, in FIG. 1, only a part of the tower structure 1a is shown, but the tower structure 1a of the lowermost block is constructed at the base of the tower to be constructed at the regular position. Yes, the tower structure of the block is sequentially connected on the tower structure 1a of the lowermost block to construct the steel tower of the wind power generator.
In addition, the guide tower 2 including the four support columns 21 to 24 performs operations such as lifting the tower structure of the block. The guide tower 2 has a joint frame connected to the lower portion thereof to raise the guide tower 2, and the raised guide tower 2 can lift the tower structure, generator, and blades to a higher position. To build a steel tower.

A support mechanism 3 is attached between the tower structure 1 a and the guide tower 2. The support mechanism 3 is for supporting the guide tower 2 on the tower structure 1a, and a plurality of support mechanisms 3 are attached to appropriate positions.
The support mechanism 3 includes two strips for fastening the frame and the tower body 1a provided on the inside thereof at the top and bottom, a member for connecting the strip to the frame, and a guide roller provided on the outside of the frame. It is what. A climbing device 5 having an expansion / contraction mechanism is attached to the guide tower 2.

Mounted on the climbing device 5 is a carriage 6 that holds the structure and moves it laterally. The climbing device 5 is moved up and down along the guide tower 2 by an expansion / contraction mechanism. The climbing device 5 lifts the tower structure and the like, and next blocks the tower structure on the lowermost block tower structure 1a. Are connected to construct a tower-like structure.
The climbing device 5 acts to stop and lift the guide tower 2. The climbing device 5 lifts the guide tower 2, and connects the joint frame below it to raise the guide tower 2.
The climbing device 5 is raised along the raised guide tower 2 to lift the tower structure, the generator, and the blades.

The support mechanism 3 between the tower structure 1a and the guide tower 2 will be described.
The perspective view of FIG. 2 shows the outline of the support mechanism between the tower structure and the guide tower. The tower body 1a is fastened by an upper band body 28a and a lower band body 28b. The upper belt member 28a is connected to the upper contact plate 29a, and is connected to the flange portion 30a of the contact plate 29a so that the hinge 32a can swing by a pin 32c. The screw shaft 34a connected to the hinge 32a is fixed to the upper connection tool 35a by the interval adjusting nuts 31a and 31c. The lower band 28b is connected to the lower contact plate 29b, and is connected to the flange 30b of the contact plate 29b so that the hinge 32b can be swung by a pin 32c. The screw shaft 34b of the hinge 32b is fixed to the lower connection tool 35b with a distance adjusting nut.

  The upper connection tool 35 a and the lower connection tool 35 b are connected to a connecting member 36, and the connecting member 36 is connected to a frame 38. The connecting member 36 is provided with a reinforcing member 39. A guide roller 37 is provided at the outer corner of the frame 38 in the mounting jig 42, and the groove 37 a of the guide roller 37 is adapted to the corners 21 a to 24 a of the columns 21 to 24.

Details of the support mechanism will be described with reference to FIGS.
As shown in the plan view of FIG. 3, the frame of the support mechanism is configured as a rectangular frame 38 by joining a frame member 38-1 and a member 38-2 at a joint portion 40. The rectangular frame 38 of the support mechanism is formed in a size that is located within the four columns 21 to 24.
The upper side of the tower 1a is the abutting plate 29a-1, the fastening tool 41, the belt body 28a-1, the abutting plate 29a-2, the fastening tool 41, the belt body 28a-2, the abutting plate 29a-3, the fastening tool 41, and the belt. The body 28a-3, the abutting plate 29a-4, the fastening tool 41, the band 28a-4, and the abutting plate 29a-1 are connected and wound around the periphery. By tightening the fastening tool 41, for example, the turnbuckle 41, the tower body 1a is fastened by the belt bodies 28a-1 to 28a-4.
In addition, in the top view of FIG. 3, in order to show the upper strip | belt body 28a and the upper contact plate 29a of the tower | column body 1a, and to wrap around the tower | column body 1a and to clamp | tighten, the band body 28a is 28a-1 4 and the upper abutting plate 29a are labeled 29a-1 to 29a-4.

  A hinge is connected to the plate 29a-1 so as to be swingable by a pin 32c. A screw shaft is connected to the hinge, and the screw shaft is connected to a connector 35 for adjusting its length. The connection tool 35 is connected to a connecting member 36, and the connecting member 36 is connected to a corner of the frame 38. The connecting member 36 is connected to the frame 38 by a reinforcing member 39. Similarly to the contact plate 29a-1, the contact plates 29a-2 to 29a-4 are coupled so as to be swingable by a hinge, and a screw shaft is connected to the hinge, and the screw shaft is a connecting tool for adjusting the length thereof. The connection tool 35 is connected to the connection member 36 and is connected to the corner of the frame 38.

With reference to the cross-sectional view of FIG. 4, the band and the support plate of the support mechanism for tightening the upper and lower sides of the tower 1 a will be described.
A band body 28a for tightening the upper side of the tower body 1a is connected to an upper contact plate 29a. A hinge 32a is connected to the plate 29a, and a screw shaft 34a is connected to the hinge 32a. The screw shaft 34a is connected to a connector 35a for adjusting the screw shaft. The pin 32c is inserted into the hole of the flange portion 30a of the abutting plate 29a, and the hinge 32a is swingably connected by the pin 32c. Further, the screw shaft 34a connected to the hinge 32a is fixed to the connecting device 35a with nuts 31a and 31c by adjusting the interval.

A belt body 28b for tightening the lower side of the tower 1a is connected to a lower plate 29b. A hinge 32b is connected to the plate 29b, and a screw shaft 34b is connected to the hinge 32b. The screw shaft 34b is connected to a connector 35b for adjusting the screw shaft. The hinge 32b is connected to the pin 32c so that the pin 32c is inserted into the hole of the flange portion 30b of the contact plate 29a so as to be swingable. Further, the screw shaft 34b connected to the hinge 32b is adjusted in distance and is fixed to the connection tool 35b with nuts 31b and 31d.
The upper connection tool 35 a and the lower connection tool 35 b are connected to a connecting member 36, and the connecting member 36 is connected to a frame 38. Further, the connecting member 36 is preferably connected to the frame 38 with a reinforcing member 39 for reinforcement.

  The support mechanism is provided with a guide roller 37 outside the frame 38. The guide roller 37 is provided on a mounting jig 42 at the corner of the frame 38 and faces the four columns 21 to 24. As shown in an enlarged view in FIG. 5, the guide roller 37 is provided with grooves 37 a corresponding to the corners 21 a to 24 a of the columns 21 to 24. In the groove 37a of the guide roller, the surfaces 37b and 37c in contact with the corners 21a to 24a of the columns 21 to 24 are convex curved surfaces. This is adapted so that the pillars 21 to 24 cannot be removed by the groove 37a of the guide roller 37, and when the guide roller 37 contacts the corners 21a to 24a of the pillars 21 to 24, two convex curved surfaces 37b and 37c are provided. It is possible to smoothly lift the columns 21 to 24 by bringing them into contact with each other.

As described above, the upper side of the tower structure 1a is fastened by the belt body 28a, and the lower side of the tower structure 1a is fastened by the belt body 28b. By tightening, the support mechanism is stably fixed to the tower structure and can stably support the guide tower.
Further, since the abutment plate 29a is provided with a hinge 32a, and the abutment plate 29b is provided with a hinge 32b, it is possible to cope with changes in the bending and twisting of the columns 21 to 24 of the guide tower 2, and It can cope with fluctuations caused by the shaking of the tower.

As shown in the broken line XX in FIG. 3 and FIG. 4, the abutting plates 29a and 29b, the hinges 32a and 32b, the screw shafts 34a and 34b, the connection tool 35a and the straight line from the substantially center O of the tower structure 1a. 35b, a connecting member 36, and a guide roller 37 are disposed. When the support towers 21 to 24 constituting the guide tower are twisted, when the guide tower or tower structure is shaken or twisted by the wind, or when the guide tower connected to the joint frame is twisted Even in this case, the hinges 32a and 32b are provided on the plates 29a and 29b, respectively, so that the support mechanism can cope with such changes.
Further, since the contact plates 29a and 29b of the two belt bodies 28a and 28b, the connecting member 36, and the grooved roller 37 are disposed substantially in a straight line from the substantially center O of the tower structure 1a, It is possible to stably support the structure and the guide tower, and to stably and smoothly raise and lower the guide tower lifted by the climbing device.

  Further, in the support mechanism, the upper band 28a has a contact plate 29a, a hinge 32a, and a screw shaft 34a connected to the connector 35a, and the screw shaft 34a can be adjusted with nuts 31a and 31c. The lower belt body 28b has a contact plate 29b, a hinge 32b, and a screw shaft 34b connected to the connector 35b, and the screw shaft 34b can be adjusted with nuts 31b and 31d. Is. In this way, the upper band body 28a and the lower band body 28b are connected to the connecting member 36 with the same force by adjusting the interval, so the two band bodies 28a and 28b The bottom is fastened and the support mechanism reliably supports the space between the guide tower and the tower structure.

  In general, the tower structure 1a is tapered so that the top is thin, and the interval between the abutting plate 29a of the upper band 28a and the connection tool 35a, and the lower band 28b. Although the space between the contact plate 29b and the connection tool 35b is different, the upper belt body 28a and the lower belt body 28b are adjusted by adjusting the space between the screw shaft 34a and the screw shaft 34b with nuts, respectively. The distance between the tower structure and the guide tower is supported by adjusting the distance so as to have the same force.

Further, the frame 38 of the support mechanism is obtained by joining the frame member 38-1 and the member 38-2 at the joint portion 40.
An upper contact plate 29a and a lower contact plate 29b, a hinge, a screw shaft, an upper connection tool 35a, a lower connection tool 35b, and a connecting member 36 are connected to the frame member 38-1 and the frame member 38-2, respectively. It is what. The upper member 29a and the lower member 29b, the hinge, the screw shaft, the upper connector 35a, the lower connector 35b, and the hum member 38-1 and the frame member 38-2, to which the connecting member 36 is connected, are divided into four. The support mechanism can be assembled by combining them and joining them at the joint 40. Further, by separating at the joint portion 40, the support mechanism can be easily disassembled into the respective frame members 38-1 and 38-2.

The support mechanism is attached by an upper contact plate 29a and a lower contact plate 29b, a hinge, a screw shaft, an upper connection tool 35a, a lower connection tool 35b, and a foam member 38-1 and a frame member 38 to which a connecting member 36 is connected. -2 are combined, the upper band 28a is spanned between the upper abutment plates 29a, the lower band 28b is spanned between the lower abutment plates 29b, and tightened to the tower body 1a with the clamp 41, The four guide rollers 37 are brought into contact with the four columns 21 to 24 so that the guide tower is supported by the tower structure.
Thus, since the frame member 38-1 and the member 38-2 are joined by the joint portion 40, the frame 38 of the support mechanism can be easily assembled and can be easily disassembled.

6 (a) and 6 (b) are views showing a support mechanism according to another embodiment of the present invention, and are connected to the connection tool 35a and the connection tool 35b provided in the support mechanism shown in FIGS. 4 is another embodiment of the connection of the member 36.
As shown in the plan view of FIG. 6 (a) and the side view of FIG. 6 (b), the tower structure 1a is fastened with a band 28a, a hinge 32a is connected to the abutting plate 29a, and a screw shaft 34a is connected. The screw shaft 34a is connected to a connector 35a for adjusting the screw shaft. Although the tower structure 1a is fastened with two belts, only the upper belt and the plate are shown in FIGS. 6A and 6B, and the lower belt and the plate are shown. Omitted.

The connecting member 36 is provided with an adjusting member 46, and the connection tool 35a is connected thereto. The adjustment member 46 of the connecting member 36 is provided with a plurality of screw holes 49 on both sides. The connecting tool 35a is provided with fractal portions 45 joined to the adjusting member 46 on both sides, and a plurality of screw holes 48 are provided in the fractal portions 45 on both sides.
By fixing the screw hole 49 of the adjustment member 46 and the screw hole 48 of the connection tool 35 a with bolts and nuts 47, the connection tool 35 a is connected to the connecting member 36.
By appropriately combining the screw hole 49 of the adjustment member 46 and the screw hole 48 of the connector 35a, the adjustment can be made in accordance with the distance between the tower structure and the guide tower.

  In the support mechanism shown in FIG. 3 and FIG. 4, the case where the interval is adjusted by the screw shaft 34a of the connection tool 35a is shown. However, in the support mechanism of another embodiment shown in FIGS. In addition to the adjustment by the screw shaft 34a of the tool 35a, the screw hole 49 of the adjustment member 46 and the screw hole 48 of the connection tool 35a are used to adjust according to the distance between the tower structure and the guide tower. Accordingly, even when the space between the tower structure and the guide tower is greatly changed, it is possible to cope with it, and the grooves 37a of the four guide rollers 37 can be stably brought into contact with the columns 21 to 24. it can. Further, when the guide tower is lifted by the climbing device, the guide tower to be lifted is brought into contact with the groove 37a of the guide roller 37 so that it can be raised stably and smoothly.

As shown in FIG. 1, the climbing device 5 is attached to the guide tower 2. The climbing apparatus will be described with reference to FIGS.
As shown in FIGS. 7 to 10, the climbing apparatus 5 forms a U-shaped frame with two beams 53 having overhanging portions 53 a and one end thereof by a connecting member 54, and lifts it to the other. It has the open part 55 which can carry in the tower body structure etc. laterally, and is attached to the outer periphery of the four support | pillars 21-24 which comprise a guide tower.
Moreover, as shown in FIG. 10, the U-shaped frame of the climbing apparatus 5 preferably reinforces the frame by connecting a member 54a (shown by a broken line) to the end of the overhang 53a.
The U-shaped frame is easy to work when the tower structure, the generator, and the blades are suspended from the suspension members 65 of the suspension gate frames 63 and 64. When lifting the climbing device 5 by suspending the tower structure, generator, and blades from the suspension member 65, by connecting the member 54a to the end of the overhanging portion 53a, The tower structure, generator, and blades can be lifted safely. As shown in FIGS. 9 and 10, the columns 21 to 24 constituting the guide tower are assembled so as to surround the tower structure 1a, and the support mechanism 3 is attached to the tower structure 1a. . The support mechanism 3 is shown in FIGS.

Further, the U-shaped frame of the climbing device 5 is provided with columnar legs 56 below each of the two beams 53 so as to correspond to the support columns 23 and 24 on the carry-in side of the guide tower. Each columnar leg 56 is provided with a telescopic mechanism 58 including a cylinder and a piston (see FIGS. 7 and 8). In addition, the piston of the expansion / contraction mechanism 58 is provided with a pin that engages with the elliptical engagement hole 26 of the carry-in side columns 23 and 24 (see FIG. 10).
The columnar legs 56 are provided with members 53b and 53c, and the members 53b and 53c are provided with rollers 60. The connecting member 54 is provided with a roller 59 (see FIGS. 7 and 8).
The climbing device 5 is attached to the guide tower by sandwiching the carry-in columns 23 and 24 of the guide tower with rollers 60. In addition, it is preferable that the columns 21 and 22 can be moved up and down smoothly by contacting with the rollers 59 of the connecting member 54 (see FIGS. 7 to 9).
7 to 9 show a case where the guide rail 25 is provided on the carry-in side pillars 23 and 24 of the guide tower, and the guide rail 25 is clamped by the concave portion of the roller 60 so that the guide rail 25 is stably raised and lowered. Although shown, it is not limited to these.

In the climbing device 5, a carriage 61 is placed on two beams 53 each having an overhang portion 53a. Rails 51 are provided on the two beams 53, and the carriage 61 is placed so that the wheels 62 can travel in the lateral direction.
The carriage 61 is provided with suspension gate-type frames 63 and 64, and a suspension member 65 is provided on the upper part thereof. In addition, each of the suspension gate-type frames 63 and 64 is provided with a spring 69 as a buffer member that holds the blades to be lifted.
Moreover, it is preferable to attach the pillar member 66 which provided the horizontal member 67 to the trolley | bogie 61 as shown with the broken line. A chain block and a hook 68 are attached to the horizontal member 67, whereby the portal frame 63 and the upper suspension member 65 are lifted, and the horizontal member 67 is rotatably attached to the column member 66, and the portal frame 63 is lifted. 64 and the upper suspension member 65 can be rotated as shown by arrows (see FIG. 7).

A large number of oval engagement holes 26 are provided in the carry-in columns 23 and 24 of the guide tower (see FIG. 8).
The pin of the expansion / contraction mechanism 58 is engaged with the engagement holes 26 of the carry-in side columns 23 and 24, and the climbing device 5 is moved up and down along the guide tower by intermittent intermittent operation of the cylinder and piston of the expansion / contraction mechanism 58. To do.
The climbing device 5 stops at the lower part, and engages the pins of the telescopic mechanism 58 with the engagement holes 26 of the carry-in side columns 23 and 24 to support the guide tower. Further, the pin of the expansion / contraction mechanism 58 of the climbing device 5 is engaged with the oval engagement hole 26 of the carry-in support columns 23, 24, and the guide tower is moved by the intermittent insect action by the cylinder and piston of the expansion / contraction mechanism 58. A lifting operation and a lowering operation of the guide tower are performed.

An embodiment of the present invention will be described with reference to FIGS.
FIGS. 11-20 is a figure which shows the construction process of the wind power generator of an Example.
First, as shown to Fig.11 (a), the tower structure 1a of the block used as the lowest part of a steel tower is erected in the foundation part 10. As shown in FIG. The tower structure 1a of the lowermost block is erected firmly at a regular position, not temporarily.
Next, as shown in FIG. 11 (b), the base 11 is installed, and the guide tower 2a and the guide tower 2b composed of four columns are connected and assembled so as to surround the tower structure 1a of the lowermost block. The guide towers 2a and 2b are placed so as to be lifted from the base 11. A guide tower is provided so that it can sufficiently withstand the load.

Next, as shown in FIG. 11C, the support mechanism 3 is attached between the tower structure 1a and the guide towers 2a and 2b. The support mechanism 3 is shown in FIGS. 2 to 6, and the guide towers 2 a and 2 b are supported on the tower structure 1 a by the support mechanism 3. A plurality of support mechanisms 3 are attached at appropriate positions between the tower structure 1a and the guide towers 2a and 2b.
As shown in the sectional view of X1-X1 in FIG. 11 (c), the support mechanism 3 is attached between the four columns 21-24 constituting the guide tower and the tower structure 1a. The four struts 21 to 24 are made into a strong structure with a beam 27 or a truss. Further, as shown in the sectional view of X2-X2 in FIG. 11 (c), the support mechanism 3 is attached between the four columns 21 to 24 constituting the guide tower and the tower structure 1a. The three columns of the four columns 21 to 24 are strengthened by beams 27 and trusses, but no lateral member is provided between the loading columns 23 and 24. This is so that the lifted tower structure can be carried in by a carriage.

  Next, as shown in FIG. 12D and its X3-X3 cross-sectional view, a support base 7 is provided in the vicinity of the carry-in columns 23 and 24, and as shown in FIG. The climbing device 5 is attached. The climbing device 5 is the one shown in FIGS. The columnar legs 56 of the climbing device 5 are positioned on the carry-in side columns 23 and 24 and are placed on the support base 7.

  Next, as shown in FIG. 12 (f), the tower structure 1b of the block is suspended by the suspension member 65 of the gate-type frame for suspending the carriage, and the climbing device 5 is expanded and contracted as shown in FIG. 13 (g). The mechanism is actuated and lifted as indicated by an arrow by the intermittent insect action, and the carriage is moved laterally as shown in FIG. 13 (h) and its X4-X4 cross-sectional view to block the block structure 1b. As shown by the arrow, the block tower structure 1a is carried into a position above the block tower structure 1a to connect the block tower structures 1a and 1b.

  Next, as shown in FIG. 13 (i), the carriage of the climbing device 5 is moved out of the guide towers 2a and 2b, the telescopic mechanism of the climbing device 5 is operated and lowered, and the columnar legs 56 are supported by the support platform. 7 is placed. The support mechanism 3 is also attached between the block tower structure 1b connected to the tower structure 1a and the guide tower 2b.

Next, as shown in FIG. 14 (j), the guide towers 2 a and 2 b are lifted by operating the expansion / contraction mechanism of the climbing device 5 on which the columnar legs 56 are placed on the support base 7. Since the support mechanism 3 shown in FIGS. 2 to 6 is attached between the tower structures 1a and 1b and the guide towers 2a and 2b, the guide towers 2a and 2b are smoothly lifted by the guide rollers of the support mechanism 3. It is done.
Next, as shown in FIG. 14 (k), the joint frame 2c is carried by the carriage 8 under the lifted guide towers 2a and 2b, and the joint frame 2c is added under the guide tower 2b. By repeating this process, as shown in FIG. 15 (l), the joint frame 2d and the joint frame 2e are joined together to raise the guide tower.

Next, as shown in FIG. 15 (m), along the raised guide towers 2a to 2e, the tower structure 1c of the block is suspended from the suspension member 65 of the carriage, and the climbing device 5 is lifted. As shown in (n), the carriage is moved laterally to bring the block tower structure 1c into a position above the block tower structure 1b, and the block tower structure 1c is transferred to the block tower structure 1b. Connect.
Next, as shown in FIG. 16 (o), along the guide towers 2a to 2e, the generator 1d is suspended from the suspension member 65 of the carriage, the climbing device 5 is raised, and the carriage is moved laterally to block. It carries in to the position (position with a broken line) on the tower body structure 1c, and connects the generator 1d to the block tower structure 1c.

Next, as shown in FIG. 17 (p), the climbing device 5 is lifted by hanging the blades 1e on the suspension member 65 of the carriage along the guide towers 2a to 2e, and the carriage is moved as shown in FIG. 18 (q). Is moved in the horizontal direction and the blade 1e is assembled to the generator 1d.
When hanging the blades 1e on the carriage, the blades are suspended by the suspension member 65 between 64 of the portal frame 63 shown in FIG. 7, and the blades of the blades are held by the spring 69 as a buffer member so as not to shake. To do. When the vane 1e is assembled to the generator 1d and the carriage is returned, as shown by the broken line shown in FIG. 7, the columnar members 66 and the lateral members 67 are used to form the portal frames 63 and 64 and the upper suspension member 65. Is raised and rotated as shown by the arrow to return the carriage so that the portal frames 63 and 64 do not interfere with the blades 1e.

As described above, after constructing the wind power generator through the steps shown in FIGS. 11A to 18Q, the joint frames 2c to 2e, which are the added portions of the guide towers 2a to 2e, are removed.
As shown in FIG. 19 (r), the climbing device 5 is lowered and the columnar leg portion 56 is placed on the support base 7. The climbing device 5 supports the guide towers 2a to 2e. This is to support the guide tower by engaging the pins of the expansion / contraction mechanism 58 of the climbing device 5 with the engagement holes 26 of the carry-in side columns 23 and 24.
Here, the joining of the joint frames 2d and 2e of the guide tower is released, and it is carried out horizontally by the carry-in cart 8.

Next, the guide towers 2a to 2d from which the joint frame 2e has been removed by the climbing device 5 are lowered. This is an operation in which the guide tower is lowered by engaging the pin of the expansion / contraction mechanism 58 of the climbing device 5 with the engagement hole 26 of the carry-in support columns 23 and 24 and intermittently removing the guide tower by the cylinder and the piston of the expansion / contraction mechanism 58. Is what you do.
The joint frames 2c and 2d of the lowered guide tower are released and are carried out sideways by the loading carriage 8. In this way, the joint tower 2c of the guide tower is also removed, and then the climbing device 5 is removed to dismantle the guide tower. In this way, a wind power generator composed of block tower structures 1a, 1b, 1c, a generator 1d, and blades 1e as shown in FIG. 20 (s) is constructed.

  As described above, the block tower structure at the bottom is firmly erected on the foundation, and the guide tower is assembled so as to surround the block tower structure. Between the tower structure and the four columns of the guide tower, The supporting mechanism to be attached is connected to the frame by a rectangular frame, a guide roller provided at the outer corner, a plurality of fastening bands provided inside, a contact plate, a hinge, a connector, etc. A tower-like structure like wind power generation can be safely constructed without stopping the work even with some wind.

  21 and 22, the mechanism for raising and lowering the climbing device will be described, and the mechanism for lifting the guide tower by the climbing device will be described with reference to FIGS. 23 and 24. This shows the intermittent intermittent operation of the telescopic mechanism of the climbing apparatus in the construction process of the wind power generator shown in FIGS.

FIGS. 21 to 24 are explanatory views of the cylinder and piston expansion / contraction mechanism 58 provided on the columnar leg portion 56 of the climbing apparatus 5 shown in FIGS. 7 to 10, and the positions corresponding to the expansion / contraction mechanism 58. It is explanatory drawing which expanded the carrying-in side support | pillars 23 and 24 of a guide tower. The telescopic mechanism 58 is shown as a cylinder, and the cylinder 58 is provided with an upper pin 57a and a lower pin 57b. In addition, an elliptical engagement hole 26 is provided in the carry-in side columns 23 and 24 of the guide tower, and the engagement holes are denoted by reference numerals 26a to 26g at intervals P in order to explain elevation. Although the engagement holes 26a to 26g are illustrated in the recesses in order to show the relationship with the support columns, penetrating engagement holes are used.
The reason why the engagement holes 26 provided in the carry-in side columns 23 and 24 of the guide tower are elliptical is to make it easier to engage the pins 57a and 57b of the expansion / contraction mechanism 58 with the engagement holes 26. . That is, even if there is a slight deviation between the position of the engagement hole 26 and the positions of the pins 57a and 57b of the expansion / contraction mechanism 58, the pin can be easily engaged with the hole.

The case where the climbing apparatus moves up along the guide tower will be described with reference to FIGS. 21 (a) to 21 (c) and FIGS. 22 (d) to 22 (f).
This is a scaled intermittent operation of the telescopic mechanism of the climbing device 5 in the steps of FIGS. 13 (g), 15 (m), 16 (o), and 17 (p) illustrating the construction process of the wind power generator. It is equivalent to.
First, as shown in FIG. 21 (a), the lower pin 57b is inserted in the direction of the arrow K1 and engaged with the hole 26b of the carry-in side columns 23 and 24 of the guide tower. The upper pin 57a is retracted in the direction of the arrow L1 to be released. In this state, the columnar leg 56 is placed on the support base 7 and stopped. The state where the columnar leg portion 56 is placed on the support base 7 and stopped is the state where the climbing device 5 is stopped.
Next, as shown in FIG. 21 (b), with the lower pin 57b engaged with the holes 26b of the columns 23, 24, the piston 58 is pushed out in the direction of the arrow M by the interval P, and the climbing device 5 is moved in the direction of the arrow A. To rise.
In FIG. 21A, the pin 57b is not in contact with the bottom of the elliptical engagement hole 26b, but the lower pin 57b is attached to the bottom of the elliptical engagement hole 26b with the piston 58 as shown in FIG. To raise.

Next, as shown in FIG. 21 (c), the upper pin 57a is inserted and engaged with the hole 26e in the direction of the arrow L2, and then the lower pin 57b is retracted from the hole 26b in the direction of the arrow K2 to be in the released state. .
Next, as shown in FIG. 22 (d), the piston 58 is contracted by pulling the space P in the direction of the arrow. Next, as shown in FIG. 21E, the lower pin 57b is advanced in the direction of the arrow K1 and engaged with the hole 26c. Thereafter, the upper pin 57a is retracted from the hole 26e in the direction of the arrow L1 to be released. 21 (c) to 22 (e), the pins 57a and 57b are engaged with any of the holes 26 of the columns 23 and 24, and the climbing device 5 is stopped on the guide tower.
Next, as shown in FIG. 22 (f), with the hole 26 c and the lower pin 57 b engaged, the piston 58 is pushed out in the direction of arrow M, and the climbing device 5 is raised as shown by arrow A.
Such an operation is repeated, and the climbing device 5 is raised along the guide tower by an intermittent intermittent operation, and is lowered.

The case where the guide tower is lifted by the climbing device will be described with reference to FIGS. 23 (a) to 23 (c) and FIGS. 24 (d) to 24 (f).
This corresponds to the intermittent intermittent operation of the telescopic mechanism of the climbing device 5 in the steps of FIG. 14 (j) and FIG. 15 (l) explaining the construction process of the wind power generator.
As shown in FIG. 23A, the climbing device is in a state where the columnar leg portion 56 is placed on the support base 7 and stopped. The lower pin 57b is advanced in the direction of the arrow K1 and engaged with the hole 26b of the carry-in side column 23, 24 of the guide tower, and the upper pin 57a is retracted in the direction of the arrow L1 to be in the released state.
Next, as shown in FIG. 23 (b), with the lower pin 57b engaged with the holes 26b of the columns 23, 24, the piston 58 is pulled in the direction of the arrow N, and the columns 23, 24 (guide tower) are connected to the D. Raise in the direction. In FIG. 23A, the pin 57b is not in contact with the upper part of the elliptical engagement hole 26b, but the piston 58 is pulled up in the direction of arrow N as shown in FIG. A pin 57b is brought into contact with the upper portion of the shaft, and the piston 58 is further pulled in the direction of arrow N to raise the columns 23 and 24 (guide tower) in the direction D.

Next, as shown in FIG. 23C, the upper pin 57a is advanced in the direction of the arrow L2 to engage with the hole 26d. Thereafter, the lower portion 57b is retracted from the hole 26b in the direction of the arrow K2 to be in a released state.
Next, as shown in FIG. 24D, the piston 58 is extended in the arrow M direction with the upper pin 57a engaged with the hole 26d. .
Next, as shown in FIG. 24E, the lower pin 57b is advanced and engaged with the hole 26b in the direction of the arrow K1, and the upper pin 57a is retracted in the direction of the arrow L1 to be in the released state.
Next, as shown in FIG. 24 (f), with the lower pin 57 b engaged with the holes 26 b of the columns 23, 24, the piston 58 is pulled in the direction of arrow N, and the columns 23, 24 (guide tower) are connected to D. Raise in the direction.
This operation is repeated to lift the guide tower and raise the guide tower by the intermittent insecticidal action of the climbing device, and to lower the guide tower by the intermittent insecticidal action of the climbing device. Is.

The perspective view which shows construction | assembly of the tower-like structure of embodiment of this invention The perspective view which shows the support mechanism of embodiment of this invention The top view of the support mechanism of an embodiment of the present invention Sectional drawing of the support mechanism of embodiment of this invention The figure which showed the guide roller of the support mechanism of embodiment of this invention The figure which showed the support mechanism of another embodiment of this invention. The perspective view of the climbing apparatus of embodiment of this invention The side view of the climbing apparatus of embodiment of this invention The top view of the climbing device of the embodiment of the present invention Sectional drawing of the climbing apparatus of embodiment of this invention The figure which shows the construction process of the Example of this invention The figure which shows the construction process of the Example of this invention The figure which shows the construction process of the Example of this invention The figure which shows the construction process of the Example of this invention The figure which shows the construction process of the Example of this invention The figure which shows the construction process of the Example of this invention The figure which shows the construction process of the Example of this invention The figure which shows the construction process of the Example of this invention The figure which shows the construction process of the Example of this invention The figure which shows the construction process of the Example of this invention The figure explaining the expansion-contraction mechanism of the climbing apparatus of the Example of this invention The figure explaining the expansion-contraction mechanism of the climbing apparatus of the Example of this invention The figure explaining the expansion-contraction mechanism of the climbing apparatus of the Example of this invention The figure explaining the expansion-contraction mechanism of the climbing apparatus of the Example of this invention

Explanation of symbols

DESCRIPTION OF SYMBOLS 1a-1c Block tower structure 1d Power generation record 1e Blade | wing 2, 2a, 2b Guide tower 2c, 2d, 2e Joint frame 3 Support mechanism 5 Climbing device 6, 61 Carriage 7 Support stand 10 Base part 21-24 Support | pillar 25 Guide rail 26 Long holes 27 Beams 28a, 28b Bands 29a, 29b Plates 32a Hinge 34a Screw shafts 35a, 35b Connecting devices 36 Connecting members 37 Guide rollers 38 Frames 39 Reinforcing members
40 Joining frame member
41 Fastening tool 42 Mounting jig 53 Beam 53a Beam projecting portion 54 Connecting member 55 Opening portion 56 Columnar leg portion 57 Pin of telescopic mechanism 58 Telescopic mechanism 63, 64 Portal frame for suspension 65 Suspension member
69 Buffer member

Claims (5)

The lowermost block tower structure is erected at the base, and a guide tower composed of columns is assembled so as to surround the lowermost block tower structure. The guide tower includes an extension mechanism and a carriage. The climbing device is attached, the climbing device is stopped, and the guide tower joint frame is connected and detached by lifting and lowering the guide tower by intermittent operation of the telescopic mechanism. A method of constructing a tower structure by lifting and lowering the tower structure along the guide tower by intermittent operation of a telescopic mechanism to connect a plurality of block tower structures, A support mechanism is provided between the guide towers, and the support mechanism is provided on the frame, guide rollers provided on the outside thereof, and on the inside thereof. Der what the strip tightening the tower body and the band body through means the length adjustment means for swingably connected are connected to the frame is, and the support mechanism is provided inside the frame The upper belt body is connected to the upper side plate, and is connected to the upper side plate so as to be swingable by a hinge. It is connected to the upper connector, the lower belt is connected to the lower contact plate, and is connected to the lower contact plate so as to be swingable by a hinge. The hinge is connected to the lower connection device via a distance adjusting member. And the upper connection tool and the lower connection tool are connected to the frame via a connection member . The support mechanism includes an upper strip member are connected to each other through a tool clamped in the upper wear plate and the lower side band of claim 1, characterized in that it is connected via a tool clamped in the lower contact plate Construction method of tower-like structure. The support mechanism includes an upper abutment plate, a hinge, an upper connection tool, a lower abutment plate, a hinge, a lower connection tool, and a guide roller, which are substantially between the center of the tower body and the support pillar constituting the guide tower. The tower-like structure construction method according to claim 1 or 2 , wherein the tower-like structure is arranged in a straight line. The said support mechanism has the frame joined by the junction part, The construction method of the tower-like structure in any one of Claims 1-3 characterized by the above-mentioned. A plurality of block tower structures that lift a plurality of blocked tower structures by a climbing device are connected to construct a tower structure, and a generator is assembled, and then blades are assembled to the generator. The method for constructing a tower structure according to any one of claims 1 to 4 , wherein the generator is constructed.

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