KR102309589B1 - Method for Lifting and Transporting Wind Power Generator Tower using 2-Point Zig Apparatus - Google Patents

Abstract

The present invention relates to a method for lifting and installing an offshore wind power generation tower using a jig device of a two-point fastening configuration and a jig device for the same. According to the method for lifting and installing an offshore wind power generation tower using a jig device of a two-point fastening configuration, a jig device of a two-point fastening configuration is used, wherein the jig device comprises an upper horizontal fastening member (1) and a lower horizontal fastening member (2) connected by hanging below the upper horizontal fastening member (1) by a wire (3) to be sequentially fastened to enclose an offshore wind power generation tower at two points separated in the longitudinal direction of the offshore wind power generation tower from above to below to effectively prevent collapse or overturning of the offshore wind power generation tower in lifting and installing processes and lower the height of a point at which lifting power is applied in the offshore wind power generation tower to reduce the vertical height, scale, etc., of a crane used for lifting and installing the offshore wind power generation tower, thereby reducing construction costs and lowering the risk of collisions which can occur in the process of fastening the jig device to a tower structure and damage caused thereby to safely perform lifting and installing work of the offshore wind power generation tower.

Description

Method for Lifting and Transporting Wind Power Generator Tower using 2-Point Zig Apparatus}

The present invention relates to a method for lifting and installing an offshore wind power tower, and a jig device having a two-point support configuration used therein, and specifically, to lift the offshore wind power tower using a crane at an offshore construction site. In installing (raised) to be placed in a fixed position, it is fastened to surround the tower structure of the offshore wind power tower at two points spaced apart in the longitudinal direction of the offshore wind power tower, and the fastening at these two points is above, By using the "jig device having a two-point fastening point configuration" sequentially below, it is possible to effectively prevent the overturning or overturning of the offshore wind power tower during the lifting and installation process, and the point where the lifting force is applied from the offshore wind power tower It is possible to lower the height of the offshore wind power tower, so it is possible to reduce the vertical height and scale of the crane used for the lifting and installation of the offshore wind power tower, thereby reducing the construction cost, etc., as well as the process of fastening the jig device to the tower structure "A method for lifting and installing an offshore wind power tower using a jig device having a two-point fastening point configuration and a jig device for the same" is about

Ships will be used to transport the offshore wind power tower to the planned installation location. Republic of Korea Patent Publication No. 10-2020-0144341 discloses an example of a technology for transferring an offshore wind power tower, a blade at the top of a tower structure in the form of a column, equipment necessary for wind power generation, such as a generator In the state that they have all installed and virtually completed the offshore wind power tower, it is transported to the planned fixed location by the ship.

After the offshore wind power tower is transported to the vicinity of the planned fixed position by using a ship, the offshore wind power tower is lifted using a crane installed on the ship, lowered to the correct fixed position, and fixed. In order to prevent damage to the tower structure, it is forbidden to hang a hook for lifting directly on the tower structure. Therefore, in the prior art, a method of lifting a ring-shaped member using a crane was used in a state in which a protrusion was formed on the side of the tower structure and a ring-shaped member was installed to surround the circumference of the tower structure at the lower position of the protrusion. That is, in the conventional method, when the ring-shaped member is raised by the crane, the projection formed on the side of the tower structure is caught on the ring-shaped member, and as the ring-shaped member is raised, the tower structure, that is, the offshore wind power tower is will be raised

In the offshore wind power tower, essential facilities such as generators and blades are heavy weights, and since these heavy weights are installed on the top of the tower structure, the offshore wind power tower is always subjected to very large overturning or overturning during lifting and installation. There is a risk. However, since the prior art is a "one-point fastening method" in which a ring-shaped member surrounds the tower structure only at one point position of the vertical tower structure, there is a disadvantage in that the risk of overturning or overturning of the offshore wind power tower is quite high.

To reduce this risk of overturning/overturning, the ring member should be installed close to the top of the tower structure. That is, it is fastened to surround the tower structure so that the position of the fastening point at which the impression force is transmitted to the tower structure should be made at the top of the tower structure as much as possible. However, as the fastening point exists at the top of the tower structure, the length of the lower part of the fastening point becomes longer. As the size of the crane increases, the construction cost also increases significantly.

Republic of Korea Patent Publication No. 10-2020-0144341 (published on December 29, 2020).

The present invention has been developed to overcome the limitations of the prior art as described above, and the offshore wind power tower, in which the blade and the generator are combined at the top of the tower structure, is transferred to the installation position by a ship and then lifted and installed at the planned construction position. In this case, the jig device for lifting / installation wraps the tower structure at the two-point position of the tower structure, so that it is possible to effectively prevent overturning or overturning of the offshore wind power tower, and the height of the position where the impression force is transmitted to the tower structure is measured in the prior art The purpose of this is to provide a technology that can reduce the size of the crane required for lifting/installation and reduce the construction cost as it can be lowered than in the case of

In the present invention, in order to achieve the above object, the upper horizontal fastening member fastened to surround the tower structure of the offshore wind power tower and the upper horizontal fastening member are integrally provided by hanging under the upper horizontal fastening member by a wire to form a tower structure using a jig device having a lower horizontal fastening member fastened to wrap; The outer surface of the tower structure is provided with a protruding stopper; Connecting the lifting cable to the upper horizontal fastening member and suspending the jig device on the crane to lift it into the air; By approaching the crane to the tower structure so that the upper horizontal fastening member is fastened to the tower structure, the lower horizontal fastening member is not yet fastened to the tower structure by connecting a position control cable to the lower horizontal fastening member to apply tension; After the upper horizontal fastening member is fastened to the tower structure, reducing the tension of the position control cable so that the lower horizontal fastening member is fastened to the tower structure at a position below the locking jaw; And, after all of the upper and lower horizontal fastening members are fastened to the tower structure, the jig device is raised with a crane so that the lower horizontal fastening member touches the locking jaw so that the pulling force is applied to the locking jaw through the lower horizontal fastening member. There is provided a lifting installation method of an offshore wind power tower, characterized in that it comprises the step of raising the.

Since the jig device according to the present invention has two fastening points that are fastened at two fastening points to the tower structure of the offshore wind power tower, the risk of overturning or overturning of the tower structure in the process of lifting, transporting, and lowering the tower structure Since it can be significantly lowered, when the jig device of the present invention is used, the advantage of being able to improve the construction efficiency of the offshore wind power tower is exhibited.

In particular, when the jig device of the present invention is used, the position where the lifting force acts on the tower structure can be lowered, and accordingly, the height of the crane for raising the offshore wind power tower so as not to be caught on the ship can also be reduced, so that the crane The advantage of being able to significantly reduce the construction cost of offshore wind power towers by reducing the size and operating costs of equipment is demonstrated.

Above all, in the present invention, since the lower horizontal fastening member approaches the tower structure by adjusting the tension of the position control cable after fastening of the upper horizontal fastening member, the position and speed at which the lower horizontal fastening member approaches the tower structure are very controlled. It can be controlled precisely and easily to the desired degree, so it is possible to reduce the risk of collision and damage caused by the tower structure, crane, upper horizontal fastening member and lower horizontal fastening member, and therefore, it is possible to sea very safely even in the working environment of unstable sea. The advantage of being able to carry out the lifting and installation work of the wind power tower is demonstrated.

1 is a schematic perspective view showing a state in which the jig device of the present invention is suspended on a crane.
Figure 2 is a schematic perspective view of the circle A of Figure 1 showing the jig device of the present invention in detail.
FIG. 3 is a schematic plan view in a vertical direction along an arrow BB of FIG. 2 showing a planar shape of an upper horizontal fastening member.
FIG. 4 is a schematic plan view in a vertical direction along an arrow CC of FIG. 2 showing a planar shape of a lower horizontal fastening member.
FIG. 5 is a schematic perspective view of the circle E of FIG. 1 showing the sill formed at the lifting force action point of the tower structure.
FIG. 6 is a schematic side view in the horizontal direction for the state shown in FIG. 5 .
7 is a schematic horizontal cross-sectional view taken along the arrow DD of FIG. 2 showing the configuration of the lower horizontal fastening member in detail.
8 to 11 are schematic perspective views corresponding to FIG. 1 sequentially showing the process of raising the offshore wind power tower by fastening the jig device of the present invention to the tower structure of the offshore wind power tower, respectively.
12 to 16 are schematic side views corresponding to FIGS. 1 and 8 to 11, respectively.
17 and 18 are schematic cross-sectional views corresponding to FIG. 7 sequentially showing that the lower horizontal fastening member is engaged with the locking sill while ascending, respectively, and the tower structure is raised.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Although the present invention has been described with reference to the embodiment shown in the drawings, which is described as one embodiment, the technical idea of the present invention and its core configuration and operation are not limited thereby. For reference, in the present specification, a direction in which the tower structure is elongated is described as a "vertical direction" and a direction orthogonal thereto is described as a "horizontal direction".

1 is a schematic perspective view showing a state in which the jig device 100 of the present invention is suspended from the crane 300, and in FIG. 2, the circle A part of FIG. 1 showing the jig device 100 of the present invention in detail A schematic perspective view of the 3 is a schematic plan view in the vertical direction along arrow BB of FIG. 2 showing the planar shape of the upper horizontal fastening member 1, and FIG. 4 is FIG. 2 showing the planar shape of the lower horizontal fastening member 2 A schematic plan view in the vertical direction along the arrow CC is shown.

First, the configuration of the jig device 100 according to the present invention will be described with reference to FIGS. 1 to 4 illustrating an embodiment of the present invention. The jig device 100 of the present invention includes two horizontal fastening members, that is, an upper horizontal fastening member 1 and a lower horizontal fastening member 2 positioned at intervals in the vertical direction.

The upper horizontal fastening member 1 is a member fastened to surround the outer circumferential surface of the tower structure 200 at the first fastening point on the upper side of the tower structure 200 by approaching in the horizontal direction, as shown in detail in FIG. Consisting of one plate member, an opening 10 into which the tower structure 200 is horizontally fitted is formed on one side of the horizontal direction, and a central insertion portion 11 in which the tower structure 200 is located is formed in the center. . The opening 10 may be provided with an opening/closing device 12, the upper horizontal fastening member 1 approaches the tower structure 200, and through the opening 10, the tower structure ( After the 200) is positioned, the opening and closing device 12 operates to close the opening 10, so that the tower structure 200 unintentionally comes out from the central insertion part 11, and the upper horizontal fastening member 1 and to prevent separation. In the case of the embodiment illustrated in the drawings, the opening/closing device 12 is made of a bar member and has a configuration in which one end is slidably installed on one side of the opening 10 . When the tower structure 200 enters or exits the central insertion portion 11, the bar member is pushed to open the opening 10, and when the tower structure 200 is located in the central insertion portion 11 and maintains it, The bar member advances toward the other side of the opening 10 to block the opening 10 to close the opening 10 . However, the configuration of the opening and closing device 12 is not limited thereto.

The lower horizontal fastening member 2 is positioned at intervals in the vertical direction from the bottom of the upper horizontal fastening member 1 to surround the outer circumferential surface of the tower structure 200 at the lower second fastening point of the tower structure 200 . It is a fastening member. The upper horizontal fastening member (1) and the lower horizontal fastening member (2) are connected by a wire (3) and integrated. That is, the wire 3 is vertically hung at a plurality of positions on the lower surface of the upper horizontal fastening member 1, and the lower end of the wire 3 is coupled to the lower horizontal fastening member 2, whereby the wire 3 ), the lower horizontal fastening member (2) is connected to each other in a suspended state under the upper horizontal fastening member (1). Here, the wire 3 not only means wire rods such as iron wires and chains in the original meaning that do not have flexural rigidity, but also has flexural rigidity and both ends are hinged to the upper and lower horizontal fastening members 1 and 2. It should be understood to include the rigid body of the form.

Since the lower horizontal fastening member 2 is also a member fastened to surround the outer circumferential surface of the tower structure 200, it is made of a horizontal plate member like the upper horizontal fastening member 1, so that the tower structure 200 is horizontal on one side in the horizontal direction. An open portion 20 to be fitted is formed, and a central insertion portion 21 in which the tower structure 200 is located is formed in the center (see FIG. 4 ). In addition, even in the lower horizontal fastening member 2, the opening 20 may be further provided with an opening and closing device. The functions and effects of the opening and closing device and the specific configuration are the same as those described in relation to the upper horizontal fastening member 1 described above. Since the same applies, repeated description will be omitted.

When lifting the offshore wind power tower in the present invention, as described later, the locking jaw 210 protruding in the horizontal direction while forming a ring shape on the outer surface of the tower structure 200 is placed on the upper surface of the lower horizontal fastening member 2 However, a concave stepped portion 24 is formed along the edge of the opening 20 on the upper surface of the lower horizontal fastening member 2 so that the locking jaw 210 can be stably fitted thereinto. FIG. 5 is a schematic perspective view of the circle E of FIG. 1 showing the stopping protrusion 210 formed on the outer surface of the tower structure 200 at the point where the lifting force will act in the tower structure 200, FIG. 6 shows a schematic side view in the horizontal direction for the state shown in FIG. 5 .

As described above, the tower structure 200 has a locking jaw 210 is formed, and in particular, the locking jaw 210 is formed on the upper surface of the lower horizontal fastening member 2 in accordance with this, since the shape of the edge may be made of an inclined surface and a horizontal surface. The stepped portion 24 may also have a stepped shape concave by an inclined surface and a horizontal surface. 7 is a schematic horizontal cross-sectional view taken along the arrow D-D of FIG. 2 showing in detail the shape of the stepped portion 24 formed on the lower horizontal fastening member 2 .

The jig device 100 of the present invention having such a configuration is, as illustrated in FIG. 1 , a tower of an offshore wind power generation tower that has been transported by a ship while being suspended on the crane 300 of the sea by a lifting cable 310 . It is fastened to the structure 200 . 8 to 11 are schematic perspective views corresponding to FIG. 1 sequentially showing the process of raising the jig device 100 of the present invention by fastening it to the tower structure 200 of the offshore wind power tower, respectively. In addition, schematic side views corresponding to FIGS. 1 and 8 to 11 are shown in FIGS. 12 to 16 , respectively.

First, as illustrated in FIGS. 1 and 12 , the jig device 100 according to the present invention is suspended on the crane 300 by the lifting cable 310 (step S1). After connecting the crane 300 and the upper horizontal fastening member 1 with the lifting cable 310, by lifting the upper horizontal fastening member 1 with the crane 300 and lifting it into the air, the jig device 100 is craned (300) will be hung. Since the lower horizontal fastening member 2 is coupled to the upper horizontal fastening member 1 by a wire 3, when the upper horizontal fastening member 1 is lifted, the lower horizontal fastening member 2 is also lifted in the air. On the other hand, in order to sequentially fasten the upper and lower horizontal fastening members 1 and 2 with the tower structure 200 as described below, the lower horizontal fastening member 2 has the lower horizontal fastening member 2 to suppress the horizontal movement of the lower horizontal fastening member 2 . A position control cable 29 for controlling or permitting is connected. As illustrated in the drawing, one end of the position control cable 29 is coupled to the lower horizontal fastening member 2 , and the other end of the position control cable 29 is a winch so as to apply tension to the position control cable 29 . ) is wound around the device 290 .

As illustrated in FIGS. 8 and 9, and 13 and 14, the crane 300 approaches the tower structure 200, and the tower structure 200 moves to the opening 10 of the upper horizontal fastening member 1 The upper horizontal fastening member 1 is fastened to the tower structure 200 by entering and positioning it in the central insertion part 11 (step S2). At this time, what is important is that the tower structure 200 is not located in the central portion 20 of the lower horizontal fastening member 2 yet. As described above, since the position control cable 29 is connected to the lower horizontal fastening member 2 and the tension is applied, the upper horizontal fastening member 1 approaches the tower structure 200 and the upper horizontal fastening member ( Even in the state just before the tower structure 200 enters the opening 10 of 1), the lower horizontal fastening member 2 is only close to the tower structure 200 and the tower structure 200 is still a lower horizontal fastening member It is not in a state where it can enter the opening 20 of (2). To this end, the operator maintains the tension of the position control cable 29, even if the upper horizontal fastening member 1 approaches the tower structure 200, the lower horizontal fastening member 2 is attached to the upper horizontal fastening member 1 Go and avoid getting too close to the tower structure 200 . In particular, even after the tower structure 200 enters and locates into the opening 10 of the upper horizontal fastening member 1 as illustrated in FIGS. 9 and 14 , the lower horizontal fastening member 2 is still the tower structure 200 It is preferable not to bind to Reference numeral 290 denotes a winch device 290 installed as necessary to wind or unwind the position control cable 29 in order to generate tension in the position control cable 29 .

After the tower structure 200 enters into the opening 10 of the upper horizontal fastening member 1 and is located, the opening and closing device 12 operates to close the opening 10 so that the tower structure 200 is inserted into the central insertion part ( 11) is prevented from escaping. At this time, in a state where the tower structure 200 is located in the central insertion part 11 of the upper horizontal fastening member 1, when the upper horizontal fastening member 1 is pulled upward by a crane as described later, the upper horizontal fastening member ( 1) is freely raised up.

As above, the opening 10 of the upper horizontal fastening member 1 is blocked so that the tower structure 200 is stably positioned in the central insertion part 11 of the upper horizontal fastening member 1 and cannot be pulled out by the upper horizontal fastening. Only after the member 1 is fastened to the tower structure 200, the lower horizontal fastening member 2 further approaches the tower structure 200, and through the opening 20 of the lower horizontal fastening member 2, the tower structure ( 200) is fastened to be located in the central insertion portion 21 (step S3). In FIGS. 10 and 15, the tower structure 200 is located in the central insertion part 21 of the lower horizontal fastening member 2 by the operation subsequent to the state of FIGS. 9 and 14, respectively, so that the lower horizontal fastening member (2) A state in which the is fastened to the tower structure 200 is shown.

After the upper horizontal fastening member 1 is fastened to the tower structure 200 , the operator performs an operation of reducing the tension of the position control cable 29 pulling the lower horizontal fastening member 2 . The lower horizontal fastening member 2 is suspended from the upper horizontal fastening member 1 by a wire 3 and the upper horizontal fastening member 1 is already fastened to the tower structure 200 before the lower horizontal fastening member 2 Therefore, a horizontal force is applied to the lower horizontal fastening member 2 in the direction of the tower structure 200 . Therefore, when the operator reduces the tension that was pulling the position control cable 29, the lower horizontal fastening member 2 naturally approaches the tower structure 200 more. Accordingly, the tower structure 200 enters the opening 20 of the lower horizontal fastening member 2 and is positioned in the central insertion part 21 so that the lower horizontal fastening member 2 is fastened to the tower structure 200 . .

As will be described later, in the present invention, the lifting force is applied to the engaging jaw 210 by the rise of the lower horizontal fastening member 2 while the engaging jaw 210 formed in the tower structure 200 is caught on the lower horizontal fastening member 2 . do. In this way, in order for the lower surface of the locking jaw 210 to be caught by the lower horizontal fastening member 2, the size of the central insertion part 21 formed in the lower horizontal fastening member 2 must be small enough to allow the locking jaw 210 to be caught, To this end, the distance between the outer surface of the tower structure 200 and the inner edge of the central insertion part 21 of the lower horizontal fastening member 2 has to be very small. Therefore, in order for the tower structure 200 to enter and be fastened to the central insertion part 21 of the lower horizontal fastening member 2 without colliding or impacting each other, the horizontal movement of the lower horizontal fastening member 2 must be controlled very precisely. . In the present invention, in order to approach the lower horizontal fastening member 2 to the tower structure 200, the operator adjusts the tension of the position control cable 29 pulling the lower horizontal fastening member 2 as above. Since it can be precisely controlled to a desired degree, it is possible to fasten the lower horizontal fastening member 2 close to the tower structure 200 safely, quickly and precisely without risk of collision.

After the tower structure 200 enters into the opening 20 of the lower horizontal fastening member 2 and is located, the opening and closing device 22 operates to close the opening 20 so that the tower structure 200 is the lower horizontal fastening member It is prevented from escaping from the central insertion part 21 of (2). As described above, when the lower horizontal fastening member 2 is fastened to the tower structure 200 , the lower horizontal fastening member 2 is positioned below the engaging projection 210 provided in the tower structure 200 .

In this way, after all of the upper and lower horizontal fastening members 1 and 2 are fastened to the tower structure 200, by using the crane 300 to lift the jig device 100 of the present invention upward to raise the tower structure The offshore wind power tower including 200 is raised (step S4). Lifting cable 310 that raises the end of the crane 300 or suspends the upper horizontal fastening member 1 in a state in which both the upper and lower horizontal fastening members 1 and 2 are fastened to the tower structure 200, respectively. It raises the jig device 100 upward by pulling it, and thus raises the offshore wind power tower.

The upper horizontal fastening member 1 is suspended from the end of the crane 300 by the lifting cable 310, and the lower horizontal fastening member 2 is coupled to the upper horizontal fastening member 1 by the wire 3 , when the end of the crane 300 is raised, the upper and lower horizontal fastening members (1, 2) are also raised together. The outer surface of the tower structure 200 is provided with a locking jaw 210 protruding, and since the lower horizontal fastening member 2 is positioned and fastened under the locking jaw 210, the lower horizontal fastening member (2) As the locking jaw 210 comes into contact with the upper surface of the lower horizontal fastening member 2, an impression force is applied to the tower structure 200 through the locking jaw 210 as it rises. Therefore, when the upper and lower horizontal fastening members 1 and 2 are lifted by the lifting of the crane 300, the entire offshore wind power tower including the tower structure 200 is lifted as illustrated in FIGS. 11 and 16. is raised

17 and 18 are schematic cross-sectional views corresponding to FIG. 7 sequentially showing that the lower horizontal fastening member 2 is engaged with the locking protrusion 210 while rising, respectively, and the tower structure 200 is raised. As illustrated in FIGS. 17 and 18 , the locking jaw 210 of the tower structure 200 is stably positioned on the stepped portion 24 of the lower horizontal fastening member 2 having a concave shape corresponding thereto, and such As the lower horizontal fastening member 2 rises in the state, the tower structure 200 is also stably raised and raised.

In a state in which the offshore wind power tower is raised, the crane 300 or a ship on which the crane 300 is mounted is moved to transport the offshore wind power tower to a construction location. Although not illustrated in the drawings, after the offshore wind power tower is transferred to the construction location, the work is performed in the reverse order of the raising process of the offshore wind power tower described above to lower the offshore wind power tower to the construction location and install it. That is, by opening the opening/closing device 21 of the lower horizontal fastening member 2 and pulling the lower horizontal fastening member 2 by applying tension to the position control cable 29, the lower horizontal fastening member 2 becomes the tower structure ( 200) so that the fastening state is completely released. While maintaining this state, the opening/closing device 11 of the upper horizontal fastening member 1 is opened, and the crane 300 or the crane 300 is moved to move the vessel on which the upper horizontal fastening member 2 is mounted to the tower structure. Deviating from (200) is to allow the fastening state to be completely released.

In the present invention as above, when raising and transporting the offshore wind power tower, the jig device 100 of the present invention is fastened to the tower structure 200 at two fastening points in the vertical direction. That is, there are two fastening points: a first fastening point at which the upper horizontal fastening member 1 is fastened and a second fastening point at which the lower horizontal fastening member 2 is fastened. In particular, since the upper and lower horizontal fastening members 1 and 2 are vertically spaced apart, the first fastening point and the second fastening point are spaced apart from each other by a predetermined distance.

In the case of having two fastening points spaced apart in this way, even if a horizontal external force causing overturning or overturning of the tower structure 200 acts, the supporting force acts in the horizontal direction at each of the two fastening points spaced apart, so offshore wind power The risk of overturning or overturning of the power generation tower is greatly reduced.

In particular, when the jig device 100 of the present invention is used, the position where the pulling force directly acts on the tower structure, that is, the position where the locking jaw 210 is installed can be located further lower than the conventional one. That is, when using the jig device 100 of the present invention, since the risk of overturning (overturning) of the tower structure is greatly reduced, the position where the pulling force directly acts on the tower structure 200 can be further lowered. As such, when the position of the impression force acting, that is, the installation position of the locking jaw 210 is lowered, the length of the lower portion of the locking jaw 210 in the tower structure 200 is also reduced by that much. When the length of the lower part of the snag 210 is reduced, the height of the crane for raising the offshore wind power tower so as not to be caught on the ship can be reduced that much, and accordingly, the cost of the crane scale and the operation of the equipment is also reduced. This has the effect of significantly reducing the construction cost.

Above all, in the present invention, an upper horizontal fastening member (1) is provided in addition to the lower horizontal fastening member (2) to which the pulling force is applied by pushing the engaging jaw (210) from below, so that after the upper horizontal fastening member (1) is fastened It has a very useful advantage through the feature that the upper and lower horizontal fastening members are sequentially fastened to the tower structure 200 by the fastening of the lower horizontal fastening member (2).

As described above, in the present invention, while the locking jaw 210 formed in the tower structure 200 is caught on the lower horizontal fastening member 2 , the pulling force acts on the locking jaw 210 by the rise of the lower horizontal fastening member 2 . will do In this way, in order for the lower surface of the locking jaw 210 to be caught by the lower horizontal fastening member 2, the size of the central insertion part 21 formed in the lower horizontal fastening member 2 must be small enough to allow the locking jaw 210 to be caught, To this end, the distance between the outer surface of the tower structure 200 and the inner edge of the central insertion part 21 of the lower horizontal fastening member 2 has to be very small. That is, when the lower horizontal fastening member 2 is fastened to the tower structure 200 , the clearance between the lower horizontal fastening member 2 and the tower structure 200 is very small. Therefore, when fastening the lower horizontal fastening member 2 to the tower structure 200, the horizontal movement of the lower horizontal fastening member 2 must be controlled very precisely.

If using the prior art, the lower horizontal fastening member 2 should be installed by hanging directly on the crane 300, in this case, the crane 300 should be approached horizontally to the tower structure 200 very precisely. However, it is very difficult to horizontally approach the crane 300 to the tower structure 200 with high precision, and in particular, in the sea where waves, etc. exist, it is inevitably an extremely difficult task, and it can be said that it is practically almost impossible. In the end, when the lower horizontal fastening member 2 is directly hung and installed on the crane 300 and the crane 300 approaches the tower structure 200 to fasten the lower horizontal fastening member 2, the crane ( 300) or the lower horizontal fastening member 2 has a very high risk of hitting the tower structure 200, and accordingly, damage to the tower structure 200 as well as the crane 300 and the lower horizontal fastening member 2 There is a problem in that the risk of damage is greatly increased.

As described above, in the present invention, the lower horizontal fastening member 2 is suspended below the upper horizontal fastening member 1 by a wire 3 , and the upper horizontal fastening member 1 is preferentially fastened to the tower structure 200 . After that, by adjusting the tension of the position control cable 29 that was pulling the lower horizontal fastening member 2, the lower horizontal fastening member 2 approaches the tower structure 200, and the tower structure ( 200) will be entered into. In the case of the upper horizontal fastening member 1, since it is irrelevant to the engaging projection 210, sufficient clearance may exist between the inner edge of the upper horizontal fastening member 1 and the outer surface of the tower structure 200. Therefore, when the upper horizontal fastening member 1 is hung on the crane 300 to approach the tower structure 200 to fasten the upper horizontal fastening member 1 to the tower structure 200, the crane 300 or the upper horizontal fastening member The member 1 is less likely to collide with the tower structure 200 and the risk of damage is also low.

And in the present invention, since the lower horizontal fastening member 2 is approached to the tower structure 200 by adjusting the tension of the position control cable 29 after fastening of the upper horizontal fastening member 1, the tower structure 200 ), it is possible to control the position, speed, etc. of the lower horizontal fastening member (2) to a desired degree very precisely and easily. That is, even in a situation where the clearance between the lower horizontal fastening member 2 and the tower structure 200 is very small, the lower horizontal fastening member 2 and the lower horizontal fastening member 200 in a state in which no damage is applied to any of the tower structure 200 . It is possible to accurately and precisely position the fastening member 2 at the second fastening point under the locking jaw 210, and very quickly and easily. Therefore, according to the present invention, it is very safe by reducing the risk of damage to the tower structure 200, the crane 300, the upper horizontal fastening member 1 and the lower horizontal fastening member 2 even in the working environment of the sea where the position is unstable due to waves, etc. The advantage of being able to carry out lifting and installation of offshore wind power towers is demonstrated.

1: Upper horizontal fastening member
2: Lower horizontal fastening member
3: wire
100: jig device
200: tower structure

Claims (7)

The upper horizontal fastening member 1 that is fastened while surrounding the tower structure 200 of the offshore wind power tower, and the upper horizontal fastening member 1 by the wire 3 are integrally provided by hanging under the upper horizontal fastening member 1 in a spaced apart state. (200) using a jig device (100) having a lower horizontal fastening member (2) fastened while surrounding;
The outer surface of the tower structure 200 is provided with a locking protrusion 210;
Lifting the jig device 100 with the crane 300 by connecting the upper horizontal fastening member 1 with the lifting cable 310 to the crane 300 (step S1);
The crane 300 is approached to the tower structure 200 so that the upper horizontal fastening member 1 is fastened to the tower structure 200, but the lower horizontal fastening member 2 is connected to the position control cable 29 to increase the tension By giving the lower horizontal fastening member 2 is not yet fastened to the tower structure 200 (step S2);
After the upper horizontal fastening member 1 is fastened to the tower structure 200, the lower horizontal fastening member 2 approaches the tower structure 200 by adjusting the tension of the position control cable 29, and the locking jaw 210 Making it fastened to the tower structure 200 at the position below (step S3); and
After both the upper and lower horizontal fastening members 1 and 2 are fastened to the tower structure, the jig device 100 is lifted with a crane so that the lower horizontal fastening member 2 touches the locking jaw 210, so that the pulling force is lowered. Lifting installation method of an offshore wind power tower, characterized in that it includes the step of raising the tower structure (step S4) by being applied to the locking jaw 210 through the horizontal fastening member (2). According to claim 1,
The upper horizontal fastening member 1 of the jig device 100 is made of a horizontal plate member, and an opening 10 is formed on one side in the horizontal direction, and a central insertion part 11 is formed in the center, and the opening part (10) has a configuration provided with an opening and closing device (12) for opening and closing the opening (10);
When the upper horizontal fastening member 1 is fastened to the tower structure 200 in step S2, the upper horizontal fastening member 1 approaches the tower structure 200 so that the tower structure 200 is opened through the opening 10 After being positioned in the central insertion portion 11, the opening and closing device 12 operates to close the opening 10, so that the tower structure 200 comes out of the central insertion portion 11 and the upper horizontal fastening member (1) Lifting installation method of an offshore wind power tower, characterized in that it is fastened in a form that is prevented from being separated. 3. The method of claim 1 or 2,
The lower horizontal fastening member 2 of the jig device 100 is made of a horizontal plate member and has an open part 20 formed on one side in the horizontal direction and a central insertion part 21 formed in the center. ;
When the lower horizontal fastening member 2 is fastened to the tower structure 200 in step S3, the lower horizontal fastening member 2 approaches the tower structure 200 so that the tower structure 200 is opened through the opening 20 Lifting installation method of an offshore wind power tower, characterized in that it is fastened in a form to be located in the central insertion part (21). 4. The method of claim 3,
The locking jaw 210 is provided to protrude in the horizontal direction from the outer surface of the tower structure 200 while forming a ring shape;
The locking jaw 210 is placed on the upper surface of the lower horizontal fastening member 2, and a concave stepped portion 24 is formed along the edge of the opening 20 on the upper surface of the lower horizontal fastening member 2,
When the jig device 100 is raised in step S4, the lower horizontal fastening member 2 touches the locking jaw 210 so that the locking jaw 210 is fitted into the concave stepped portion 24, so that the impression force is applied to the locking jaw 210 ) Lifting installation method of an offshore wind power tower, characterized in that it is transmitted to the tower structure 200 through. delete delete delete

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