KR101411934B1 - Assembling Method of Sea Wind Power Generator at Quay Wall - Google Patents

Abstract

The present invention relates to a method for assembling an offshore wind power generator in a quay. The present invention provides a method for assembling an offshore wind power generator in a quay, which includes: a ship berthing step of moving and berthing a work vessel to a quay; a step of mounting a pole of an offshore wind power generator while the pole stands uprightly using a crane located in the quay; a step of assembling a power generator body of the offshore wind power generator to the upright pole using the crane; and a step of mounting a propeller to the power generator body using the crane.

Description

[0001] The present invention relates to a method of assembling an offshore wind turbine generator on a quay wall,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for installing an offshore wind turbine generator, and more particularly, to a method for assembling and installing an offshore wind turbine generator installed on a ship using a seam.

Generally, a wind power generator is a generator that generates electricity using wind. Wind turbines can be classified into offshore wind turbines installed on the land and offshore wind turbines installed on the sea depending on where they are installed.

The offshore wind power generator is transported to the place where it will be installed using the ship, and construction is carried out. At this time, depending on the size of the offshore wind turbine and the stability of loading, transportation and installation methods will be different.

If the size of the offshore wind turbine generator is small, each component may be mounted on the ship in a state of being assembled and transported and installed directly at the installation site. However, if the capacity of the offshore wind turbine exceeds 5 MW, or if the offshore wind turbine is installed in an environment where marine climatic conditions are very bad, the offshore wind turbine is separated and moved to the condition that it is loaded on the ship. .

However, there is a problem in that it takes a lot of time and money to separate and install the offshore wind turbine generator, to ship it to the ship, and to assemble it in the construction site.

Korean Patent Laid-Open Publication No. 10-2012-0113013 (published on October 12, 2012)

As in the case of a conventional marine wind turbine installation vessel disclosed in Patent Document 1, when an offshore wind turbine generator is assembled and mounted on a ship and then transported by sea, the installation of an offshore wind turbine generator can be performed quickly .

However, according to the prior art, when the capacity of the offshore wind turbine exceeds 5 MW (in the case of 7 MW, the weight exceeds about 1100 tons), the offshore wind turbine is taken from the manufacturing factory to be mounted on the ship, It is practically impossible to install it by moving it to the installation site.

Therefore, the present applicant has proposed a patent for a method of assembling an offshore wind turbine at the seashore so that the offshore wind turbine, which is disassembled by parts in the manufacturing factory, can be assembled and installed on the ship at the same time.

The present invention relates to a marine vessel docking method comprising: A step of mounting on the working line a standing post of an offshore wind power generator using a crane located on the seawall; Assembling the generator body of the offshore wind power generator using the crane on the standing post in an upright state; And mounting the propeller to the generator body using the crane; A wind turbine, and a wind turbine.

Wherein the ship dipping step includes moving the work line so that the installation hole formed in the work line is adjacent to the sidewall; And anchoring the work line adjacent to the quay wall.

The step of moving the work line may further include a step of moving the moving part of the work line to cover the installation hole, and the support may be installed on the mobile mounting part.

The strut including a plurality of strut rods, the strut rods mounting stage being mounted on the work line with the plurality of strut ropes standing up by the crane, respectively; And a strut welding step for welding the adjacent strut rods.

The step of mounting the propeller on the generator body may further include returning the moving mounting part to open the installation hole.

According to another aspect of the present invention, Assembling the strand of the offshore wind power generator on the work line in a state where the strand of the offshore wind power generator is standing by using a crane located on the seawall; If the distance between the crane and the strut is shorter than a predetermined working distance, moving the upper strut, which has been raised using the crane, to a position below the installation hole of the work line to secure a working distance; Fixing the position of the support by using a lift part; Assembling the generator body of the offshore wind power generator using the crane on the standing post in an upright state; And installing a propeller on the generator body using the crane. The present invention also provides a method of assembling an offshore wind power generator on a quay.

The strut including a plurality of strut rods, the strut rods mounting stage being mounted on the work line with the plurality of strut ropes standing up by the crane, respectively; And a strut welding step for welding the adjacent strut rods.

Wherein the ship dipping step includes moving the work line so that the installation hole formed in the work line is adjacent to the sidewall; And anchoring the work line adjacent to the quay wall.

And moving the mounting portion of the work line to cover the installation hole after the ship riding step, wherein the support is installed on the mobile mounting portion.

The method may further include moving the first block of the mobile mounting unit to open the installation hole before the step of moving the upright upper support by a predetermined height below the installation hole using the crane to secure the working distance.

The step of mounting the propeller to the generator body may further include positioning the strut to the upper portion of the installation hole using the lift.

Moving the first block of the moving mount to cover the mounting hole when the strut is located above the mounting hole; And a step in which the lift is lowered and mounted on the first block of the mobile mount.

And the moving mount unit mounted with the support may return to open the installation hole.

According to the method for assembling the offshore wind turbine generator of the present invention, the components of the offshore wind turbine generator can be installed upright on the inner wall, safely assembled and mounted on the work line, and can be safely moved to the sea and installed quickly at the installation site.

Therefore, the Government of the Republic of Korea has announced and plans to implement a comprehensive offshore wind power generation plan to build a 2.5 GW offshore wind power generation plant near the Southwest Sea by 2019. The present invention is based on the government policy, Accurate, safe, and quick installation.

1 is a perspective view showing a schematic configuration of a work line for installation used in a method of installing a offshore wind turbine generator of the present invention.
Fig. 2 is a front view showing the embodiment in which the guide part, the moving mount part and the lift part in Fig. 1 are embodied.
FIG. 3 is a view showing the operation of FIG. 2. FIG.
FIG. 4 is an enlarged view showing the structure of the guide part and the moving part of FIG. 2;
5 is an enlarged view of the lift section area of Fig.
6 is a flowchart illustrating a method for installing a marine wind power generator according to an embodiment of the present invention on a quay wall.
7 is a side view showing the method according to FIG.
8 is a flowchart illustrating a method for installing a marine wind power generator according to another embodiment of the present invention on a quay wall.
Figs. 9 to 11 are side operation diagrams showing the method according to Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

The working line for installing an offshore wind turbine generator according to an embodiment of the present invention can be installed while assembling the offshore wind turbine generators of various capacities on a marine basis, and can be installed on a foundation file after moving to an installation site in a standing state.

For example, the working line of the present embodiment can perform a series of processes such as assembling, transporting and constructing a 7 MW offshore wind turbine having a capacity of 5 MW or more, that is, a height of 117 m and a weight of 1200 tons.

FIG. 1 is a perspective view showing a schematic configuration of an installation work line used in a method for installing a offshore wind turbine generator of the present invention, and FIG. 2 is a perspective view showing a guide part, a moving installation part and a lift part in FIG. 3 is a view showing the operation of FIG. 2, FIG. 4 is an enlarged view of the main part showing the structure of the guide part and the moving part of FIG. 2, and FIG. 5 is an enlarged view of the lift part area of FIG. 1 .

1 to 5, a working line 1 for installing an offshore wind power generator according to the present invention includes a ship body 100, a floating leg portion 200, a guide portion 300, a moving installation portion 400, A lift unit 500, and an anchor unit 600.

The offshore wind power generator 10 can be largely composed of three parts, that is, the support 11, the generator body 12, and the propeller 13. The column 11 has a long column shape and is installed on the sea. The generator body 12 is installed on the upper portion of the column 11. The propeller 13 is rotated by the wind so that the generator body 12 can generate electricity.

Here, the support 11 is a tower, the generator body 12 is a nacelle or a hub, and the propeller 13 is a blade. May be referred to as other names.

A plurality of hook rings (11a) used for transportation and installation can be attached to the pillars (11). For example, four hook rings 11a may be attached to the upper region of the column 11, which is a ring shape so as to hook the hooks 11a, and which is a position considering the center of gravity of the offshore wind power generator 10. The hook ring 11a may have various names such as a lug and a hook, and the number, size, and shape of the hook rings 11a may be variously modified.

In this embodiment, the offshore wind turbine generator 10 can be assembled and mounted on the ship in a state in which the support posts 11 are erected in the vertical direction, and the construction can be carried out immediately after the installation.

The ship body 100 may be referred to as a ship body, a barge body, a work line body, a hull, etc. as a main body. The ship body 100 may have various shapes. For example, a rectangular shape as a whole, but may have a shape in which four corner edges are gently cut.

An installation hole 110 through which the foundation file, the offshore wind power generator 10 and the like are installed may be formed through the ship main body 100. For example, the installation hole 110 may have a shape in which a front region in the traveling direction of the ship body 100 is recessed inward by a predetermined length. Of course, the installation hole 110 may be located on the opposite side or the side of the ship in the traveling direction, or may be a space adjacent to one side of the ship body 100 without being recessed inside the ship body 100.

The floating leg portion 200 is installed on the ship body 100 so as to move up and down. The floating leg portion 200 serves to fix the position of the ship body 100 in the sea so that the ship body 100 can float vertically in the sea. In other words, the floating leg portion 200 is distinguished from a jack-up leg (Patent Document 1) in which a conventional ship is raised and fixed on the sea surface because the position of the floating leg portion 200 is fixed in a floating state on the sea surface.

Since the jack-up type jack-up leg has to support the load of the ship itself in a state where the ship is elevated above the water level to a certain height, it is difficult to use the jack-up leg when the ship is large in size. For example, it is very difficult to fully support the load of a ship with a jack-up leg only in a situation where the size of a ship is very large, such as a work line for installing a 7 MW class offshore wind turbine.

Since the floating leg unit 200 can share the load of the ship with the seawater, there is an advantage that the offshore wind power generator can be installed while fixing the position of the ship efficiently even in a case where the size of the work line is very large.

The floating leg portions 200 may be formed of a plurality of legs. For example, the floating leg portion 200 may be provided at four edge regions of the ship body 100. The floating leg portion 200 may be configured to include the leg 210, the leg support 220, and the leg winch 230 in more detail.

The legs 210 are mounted so as to be vertically movable with respect to the ship body 100 and constitute a portion to be inserted into the sea floor. A leg hole is formed in the ship body 100 so that the leg 210 can be inserted into the ship body 100. The legs 210 may have a cylindrical shape having a sharp bottom so as to be inserted into the sea floor.

The leg supports 220 may be provided on the ship body 100 so as to be adjacent to the leg holes 210 to movably surround the legs 210. For example, the leg supports 220 may be configured to concentrically wrap the legs 210 so as to have an inside diameter that is slightly larger than the cross-sectional shape of the legs 210. The leg supports 220 allow the legs 210 to flow to some extent along the direction of rotation of the sea surface.

The leg winch 230 serves to raise and lower the leg 210. The leg winch 230 can be connected to the leg 210 to lower the leg 210 down to the sea level or to raise it back to the ship body 100. Of course, the leg 210 may be raised and lowered in various ways such as the self weight of the leg 210 and the inflow of the sea surface. And may further include a clutch 240 or 250 for fixing the position of the leg 210 so that the leg 210 can be fixed or moved in the leg support 220. The clutches 240 and 250 may be variously implemented by a bolt tightening method or a pressure contact tightening method capable of selective contact between the legs 210 and the leg supports 220.

The guide unit 300 serves to guide the installation of the offshore wind power generator 10 on the sea or by mounting the offshore wind power generator 10 on the installation hole 110. The guide part 300 may have a plurality of rails to form a plurality of layers in the vertical direction and may be arranged to face each other with the installation hole 110 as a center. A pair of opposing rails may be disposed long on the side (side) with respect to the installation hole 110. Since the guide portion 300 is located on the side of the installation hole 110, it may be referred to as a side structure.

The guide unit 300 may have various shapes, for example, a plurality of frame-shaped guide bodies 301 projecting in a vertical direction to the ship body 100. The guide body 301 may be provided with a plurality of rails. The configuration of the rails will be described later.

The mobile mounting part 400 stands up the offshore wind power generator 10 while mounting the pillar 11 of the offshore wind power generator 10 and mounts the offshore wind power generator 10 on the ship body 100. The moving mount section 400 can move the offshore wind power generator 10 to the installation hole 110 while moving along the pair of guide sections 300 described above.

The mobile mount part 400 may include a plurality of blocks movably installed along a pair of opposing rails and selectively fixing the position of the support 11.

At this time, the plurality of blocks may be formed of at least three so that the offshore wind power generator 10 can be stably fixed and moved. Of course, a plurality of blocks may have two or more numbers.

In this embodiment, the three blocks are sequentially composed of a first block 410, a second block 420, and a third block 430. Here, the first block 410, the second block 420, and the third block 430 may be referred to as a first panel, a second panel, and a third panel. The first block 410 to the third block 430 may be moved along the pair of guide portions 300 including the linear moving means. For example, the linear moving means may be a linear motor, a skid, or the like.

The first block 410 is positioned adjacent to the installation hole 110 and can fix the lower portion of the column 11. The first block 410 may include a mounting panel 411 and fixing protrusions 412 protruding from the upper portion of the mounting panel 411 to allow the lower portion of the column 11 to be inserted and fixed. A groove may be formed in the lower portion of the column 11 so that the foundation pile and the fixing protrusion 412 can be inserted. The mounting panel 411 has a size capable of covering the mounting hole 110 when the mounting panel 411 is positioned above the mounting hole 110.

The second block 420 may be installed to be movable along the guide part 300 while being spaced apart from the upper part of the first block 410 and fixing the column 11 to surround the column.

The third block 430 may be spaced apart from the upper portion of the second block 420 and may be movably installed along the guide portion 300 while being fixed to surround the strut 11.

Here, the second block 420 and the third block 430 may be configured to include the fixed panels 422 and 432 and the rotating panels 423, 424, 433, and 434, respectively, as shown in FIG. 7 have.

The fixing panels 422 and 432 are formed with post insertion holes 421 and 431 into which the post 11 is inserted. The pivoting panels 423, 424, 433 and 434 are rotatably mounted on the fixed panels 422 and 432 so as to open and close the pillar insert holes 421 and 431, have. The pillar insert holes 421 and 431 are formed to be slightly larger than the diameter of the pillar 11 so that the pillar 11 can be vertically moved while the pillar 11 is not displaced along the horizontal direction.

If necessary, the first block 410 may be returned to the original position to open the installation hole 110 after moving the column 11 to the upper portion of the installation hole 110. The second block 420 and the third block 430 maintain the positions of the columnar inserting holes 421 and 431 and the mounting holes 110 to be parallel to each other, Precise installation can be guided.

It has been described that the mobile mounting part 400 having such a configuration can be moved by the pair of guide parts 300. Here, the pair of guide portions 300 may have a number of rails corresponding to a plurality of blocks of the mobile platform 400.

That is, the pair of rails includes a first rail 310 that movably supports the first block 410 so as to be adjacent to the installation hole 110, a second rail 310 that movably supports the second block 420, 320, and a third rail 330 that movably supports the third block 430. As shown in FIG.

Therefore, the mobile mounting unit 400 can move toward the installation hole 110 or return to the original position through the guide unit 300 while selectively mounting the offshore wind power generator 10.

The lift unit 500 may lift the support 11 of the offshore wind turbine generator 10 moved to the installation hole 110 by the moving installation unit 400 and install the support 11 on a foundation file located under the installation hole 110 have.

The lift unit 500 may be mounted on the guide unit 300 to move up and down the offshore wind power generator 10. More specifically, the lift part 500 may be mounted on an upper area of the guide part 300 located in the upper area of the installation hole 110. The lift part 500 can be implemented in various forms such as a rope, a hook, a crane, and a gantry.

For example, the lift unit 500 may include a hook wire 510, a wire connecting member 520, a lifting rope 530, and a rope support 540 as shown in FIG.

The hook wires 510 may be formed in a plurality of hooks connected to the hook rings 11a of the pillars 11 located above the mounting holes 110. [

The wire connecting member 520 may be arranged to fasten the plurality of hook wires 510 and to surround the strut 11. [ For example, the wire connecting member 520 may be coupled to each other such that the four connecting bars 521 are rectangular. Four hooks 510 may be connected to the four hooks 11a of the strut 11 while four hooks 510 are fixed to the four edges of the four connecting bars 521. The connection bar 521 located at the rear side is rotatably configured to selectively open and close the inner space so that the support post 11 can be positioned inside.

One side of the ascending / descending rope 530 may be coupled to the wire connecting member 520, and the other side may be connected to a motor or a hydraulic device to receive power.

Therefore, the ascending / descending rope 530 can ascend and descend the wire connecting member 520 to move the column 11 up and down in the vertical direction. The rope support 540 movably supports the lifting rope 530 and can be coupled to the guide portion 300. Descending rope 530 movably installed on the rope support 540 can perform the ascending and descending operations of the strut 11 by a force acting in the opposite direction. For example, when the lifting rope 530 on the side connected to the motor or the hydraulic device is wound down vertically, the support 11 is lifted. On the other hand, when the lifting rope 530 is loosened, can do.

The lift part 500 having such a configuration can be connected to the support 11 when the mobile mounting part 400 to which the support 11 is fixed is moved to the installation hole 110. The lift unit 500 is moved upward by a predetermined height before the first block 410 of the mobile mounting unit 400 moved to the mounting hole 110 returns to the original position and the fixing protrusions 412 So that the lower part of the column 11 can be separated.

The first block 410 may then return to its original position after moving the pillars 11 to the top of the installation hole 110. At this time, the second block 420 and the third block 430 support the column 11 at the upper portion of the installation hole 110 without moving the column 11 so that the position of the column 11 is not shaken.

The lift unit 500 is lowered to lower the supporting posts 11 while keeping the positions of the foundation piles 421 and 431 and the foundation piles positioned above the installation holes 110 in parallel, So that the offshore wind turbine generator 10 can be installed.

The anchor portion 600 may serve to stably stow the ship body 100 together with the floating leg portion 200 before the offshore wind power generator 10 is installed on the foundation pile.

The anchor portion 600 may be mounted on an edge region of the ship body 100.

The anchor portion 600 includes an anchor 610 for anchoring the ship body 100 to the sea floor, an anchor portion 610 for attaching the anchor portion 600 to the bottom of the ship body 100, And a winch 620 for moving the anchor 610 up and down.

The present invention is generally described as a method for assembling an offshore wind power generator on a seam and a case where the size of an offshore wind power generator is increased and classified into two embodiments.

FIG. 6 is a flowchart illustrating a method for installing an offshore wind turbine according to an embodiment of the present invention, and FIG. 7 is a side view illustrating a method according to FIG.

A method for assembling and installing the offshore wind turbine of the present invention will be described with reference to FIGS. 6 and 7 and the above-described drawings.

The present invention can be assembled in a state where the offshore wind turbine generator 10 is standing upright from the seawall 5 by using the working line 1 for installing the offshore wind turbine generator.

Here, the quay (5) is a structure constructed on the shore, which means a facility that serves as a marina of a ship made to allow one side of the ship to be attached to the land. The quay wall 5 may also be called a rock wall or other name. As shown in FIG. 6, the seawall 5 can be constructed by installing a plurality of foundation files P on the sea and installing a structure such as concrete on the coast L and the foundation files P.

Each part constituting the offshore wind power generator 10 and the crane C can be located at the seawall 5. Here, the struts 11 constituting the offshore wind power generator 10 may be constituted by one or a plurality of strut rods 11-1 and 11-2 may be connected.

The crane (C) can lift the heavy object and can be a moving crane (C) equipped with moving means for use in the quay (5). Of course, if necessary, the crane C may be used as a fixing crane C which is fixed on the crane 5.

A method of assembling and installing the offshore wind turbine 10 of a general scale on the seam 5 includes a vessel riding step S100 of moving the work line 1 to rid the seam 5, A step S200 of mounting the strut 11 of the offshore wind power generator 10 on the work line 1 with the crane C located thereon and a step S200 of mounting the strut 11 of the off- A step S300 of assembling the generator body 12 of the offshore wind power generator 10 and a step S400 of mounting the propeller 13 on the generator body 12 using the crane C .

Herein, the ship riding step S100 is carried out first in such a manner that the work line 1 is moved so that the installation hole 110 formed in the work line 1 is adjacent to the rim 5. At this time, the mobile mounting part 400 can be accessed at a position where the mounting hole 110 is opened.

Then, a step of anchoring the work line 1 adjacent to the seam 5 is carried out. At this time, at least one of the legs 210 and the anchor 610 may be used to fix the work line 1 by fixing it. For example, only legs 210 and anchors 610 may be used, or both may be used.

After the step of docking the work line 1, the moving mount part 400 of the work line 1 may be moved to cover the installation hole 110. [ Therefore, the pillars 11 can be installed in the mobile mounting part 400. [ The lower portion of the column 11 is fixed to the first block 410 and the second block 420 is fixed to the first block 410. In this case, And the third block 430 in a state of being movable in the vertical direction.

On the other hand, the process of mounting the crane (C) on the work line (1) in a state where the crane (C) stands up can be completed by one operation when there is one support (11).

However, in the case where the support 11 includes a plurality of support rods 11-1 and 11-2, the plurality of support rods 11-1 and 11-2 are supported by the crane C, The step of mounting the support rods 11-1 and 11-2 mounted on the line 1 and the step of welding the support rods 11-1 and 11-2 for welding the adjacent support rods 11-1 and 11-2 . ≪ / RTI >

The generator body 12 and the propeller 13 are assembled and mounted sequentially by the crane C when the pillar 11 is mounted on the moving mount portion 400 in a standing state. At this time, an assembling process such as welding may be further included among the respective parts.

The struts 11, the generator body 12 and the propeller 13 may be mounted while being assembled by the mobile mounting part 400 located in the installation hole 110. [

Further, after the step of mounting the propeller 13 to the generator body 12, the step of returning the moving mounting part 400 to the original position so as to open the mounting hole 110 so that the working line 1 moves to the sea . In this case, the offshore wind turbine generator 10 is moved to the inner area of the ship together with the moving platform 400, and is more stably mounted on the ship.

FIG. 8 is a flowchart showing a method for installing a offshore wind turbine according to another embodiment of the present invention, and FIGS. 9 to 11 are side operation views showing a method according to FIG.

8, the method for assembling the offshore wind power generator 10 of the present embodiment on the seam 5 includes a ship sailing step S100 for moving the work line 1 to make a ridge on the seam 5, (200) assembling the strut (11) of the offshore wind power generator (10) with the crane (C) located in the crane (5) The step of moving the strut 11 standing up by using the crane C by a predetermined height below the installation hole 110 of the work line 1 to secure a working distance when the distance between the work 11 and the work 11 is smaller than the working distance A step S260 of fixing the position of the strut 11 by using the lift unit 500 and a step S260 of setting the position of the stratum 11 of the offshore wind turbine 10 using the crane C A step S300 of assembling the generator body 12 and a step S400 of mounting the propeller 13 to the generator body 12 using the crane C may be included.

Here, the working distance refers to the distance that the main boom of the crane C can safely be installed without being interfered with the lifted object, and includes a condition that the center of gravity of the crane C can be stably maintained .

If the distance between the crane C and the support 11 is less than the working distance, the center of gravity of the crane C may collapse or an impact may be generated between the crane C and the support 11, . For example, the working distance may be 10 m and may vary depending on the shape of the object or the location of the traction.

Therefore, when the distance between the crane C and the support 11 is closer than the work distance as described above, it is necessary to secure the work distance (S250).

The ship slinging step S100 includes a step of moving the work line 1 so that the installation hole 110 formed in the work line 1 is adjacent to the sidewall 5, 1). ≪ / RTI > The leg of the work line 1 descends as shown in Fig. 9, and the position of the work line 1 is fixed in a state where the stern wall 5 is stuck.

After the ship riding step S100, the moving mount 400 of the work line 1 may be moved to cover the installation hole 110. [ Therefore, the pillars 11 can be installed in the mobile mounting part 400. [ The lower portion of the column 11 is fixed to the first block 410 and the second block 420 is fixed to the first block 410. In this case, And the third block 430 in a state of being movable in the vertical direction.

In the step S200, the support 11 may be one, but it may include a plurality of support rods 11-1 and 11-2 as in the embodiment described above.

In this case, as shown in FIG. 9, a plurality of columnar rods 11-1 and 11-2 are supported by the columnar rods 11-1 and 11-2 mounted on the work line 1, respectively, , 11-2), and a step of welding the support rods 11-1 and 11-2 for welding the adjacent support rods 11-1 and 11-2.

In this embodiment, the pillars 11 are shown as being composed of two pillars 11-1 and 11-2, but the pillars 11-1 and 11-2 can have a larger number.

When the post 11 is assembled and mounted on the moving mount 400, the distance between the crane C and the post 11 may be shorter than the working distance. Here, the working distance is a distance at which the generator body 12 of the offshore wind power generator 10 and the propeller 13 can be stably operated by the crane C, as described above. Therefore, in this case, it is necessary to lower the height of the support post 11.

For this purpose, a step S250 is performed in which the strut 11 standing by using the crane C is moved below the installation hole 110 of the work line 1 by a predetermined height to secure a safe working distance.

10, the strut 11 is lifted up to a certain height by using a crane C to separate the first block 410 of the moving platform 400 from the strut 11 (S230) , The first block 410 of the mobile unit 400 is moved to open the installation hole 110 (S240).

11, the strut 11 passes through the installation hole 110 and the lower portion of the strut 11 is locked by a predetermined height into the sea using a crane (C) . At this time, after the lift part 500 fixes the support 11, the crane C releases the support 11.

The crane C is supported by the generator body 12 in a state in which a predetermined working distance is ensured so that the support 11 can be lowered and the crane C can safely assemble the generator body 12, Can be installed in the support 11. The generator body 12 and the pillars 11 can be fixed to each other by welding after welding.

13, when the propeller 13 is mounted on the generator body 12 using the crane C, the offshore wind power generator 10 can be assembled in an upright state. That is, the struts 11, the generator body 12, and the propellers 13 can be mounted while being assembled by the mobile mounting part 400 located in the installation hole 110 by the above-described series of processes.

Next, after the step of mounting the propeller 13 to the generator body 12, the following operation is further performed to stably mount the propeller 13 on the ship.

14, a step S500 of positioning the support 11 to the upper portion of the installation hole 110 is performed using the lift part 500, and the support 11 is mounted on the upper part of the installation hole 110 The step of moving the first block 410 of the moving part 400 to cover the installation hole 110 is performed (S510).

Subsequently, the step (S520) in which the lift is lowered to the support 11 and is mounted on the first block 410 of the mobile mounting part 400 is continued.

The struts 11, the generator body 12 and the propeller 13 may be mounted while being assembled by the mobile mounting part 400 located in the installation hole 110. [

Further, after the step of mounting the propeller 13 to the generator body 12, the step of returning the moving mounting part 400 to the original position so as to open the mounting hole 110 so that the working line 1 moves to the sea . In this case, the offshore wind turbine generator 10 moves to the inner region of the work line 1 together with the moving platform 400, and is more stably mounted on the work line 1.

As described above, according to the method of assembling the offshore wind turbine generator of the present invention, the parts of the offshore wind turbine generator can be installed upright and safely assembled to the work line and mounted at the same time. have.

Therefore, the Government of the Republic of Korea has announced and plans to implement a comprehensive offshore wind power generation plan to build a 2.5 GW offshore wind power generation plant near the Southwest Sea by 2019. The present invention is based on the government policy, Accurate, safe, and quick installation.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas falling within the scope of the same shall be construed as falling within the scope of the present invention.

1: Work line for installation of offshore wind power generator 10: Offshore wind power generator
11: support 12: generator body 13: propeller
100: Ship body 110: Installation hole 200: Floating leg portion
210: leg 220: leg support 230: leg winch
300: guide portion 301: guide body 310: first rail
320: second rail 330: third rail 400:
410: first block 420: second block 430: third block
411: Mounting panel 412: Fixing projection 421, 431:
422, 432: fixed panels 423, 424, 433, 434:
500: lift part 510: hook wire 520: wire connecting member
530: lifting rope 540: rope support 600: anchor portion
610: Anchor 620: Winch

Claims (13)

delete delete delete delete delete A ship berthing step for moving a work line and riding on a seawall;
Assembling at a work line by fixing a support of an offshore wind power generator in a standing position with a crane located on the seashore wall;
If the distance between the crane and the strut is less than a predetermined working distance, moving the strut upright by using the crane by a predetermined height below a mounting hole of the working line to secure a working distance;
Fixing the position of the support by using a lift part;
Assembling the generator body of the offshore wind power generator using the crane on the standing post in an upright state; And
And installing a propeller on the generator body using the crane. The method according to claim 6,
The strut includes a plurality of strut rods,
A strut rod mounting step of mounting the plurality of strut rods on the working line in a state where the strut ropes are respectively raised by the crane; And
Further comprising a step of welding the adjacent support rods to weld the adjacent support rods. 8. The method of claim 7,
The ship docking step
Moving the work line such that an installation hole formed in the work line is adjacent to the wall; And
And anchoring the work line adjacent to the seawall. ≪ RTI ID = 0.0 > 8. < / RTI > 9. The method of claim 8,
After the ship riding step
Further comprising the step of moving the moving mount of the work line to cover the installation hole, wherein the support comprises the marine wind power generator installed on the mobile mount. 10. The method of claim 9,
Before the step of securing the working distance by moving the standing pillars using the crane by a predetermined height below the installation holes
Separating the first block of the mobile unit from the strut by lifting the strut up to a certain height using the crane; And
And moving the first block of the mobile mount to open the installation hole. 11. The method of claim 10,
Further comprising the step of positioning the struts to an upper portion of the installation hole using the lift portion after mounting the propeller on the generator body. 12. The method of claim 11,
Moving the first block of the moving mount to cover the mounting hole when the strut is located above the mounting hole; And
Further comprising the step of lowering the pillar to mount the pillar to the first block of the mobile mount. 13. The method of claim 12,
Further comprising the step of returning the movable mount portion, on which the support is mounted, to open the installation hole.

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