KR20160016390A - Ship for installing wind power generator - Google Patents

Abstract

The present invention relates to a ship for installing an offshore wind power generator, and more specifically, to a ship for installing an offshore wind power generator which can quickly and stably install an offshore wind power generator on the sea. According to the present invention, the ship for installing an offshore wind power generator comprises: a ship hull on which an installation hole is formed; a pair of a first and a second guide frame installed on a left and a right side of the installation hole to face each other, and wherein an offshore wind power generator is erected and loaded therebetween; a first jig which supports a lower surface of a column of the offshore wind power generator loaded between the first and the second guide frame, and is installed between the first and the second guide frame to be moved in a horizontal direction; a second jig which encloses and supports an outer surface of the column of the offshore wind power generator loaded between the first and the second guide frame above the first jig, and is installed between the first and the second guide frame to be moved in the horizontal direction; and a lift device disposed between the first and the second jig and installed between the first and the second guide frame to lift and vertically move the lower end of the offshore wind power generator which is transported to the installation hole by the first and the second jig.

Description

[0001] SHIP FOR INSTALLING WIND POWER GENERATOR [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a ship for installing an offshore wind power generator, and more particularly, to a ship for installing an offshore wind power generator on which an offshore wind power generator can be installed quickly and stably.

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. These offshore wind turbines consist of three parts: Tower, Nacelle, and Blade, which are the body of generator, and they are assembled according to size and load stability, It may be assembled at the installation site.

However, in recent years, as the required power generation capacity has increased, the size of the offshore wind turbine has increased and it has become very difficult to install a wind turbine generator on the sea using a large crane.

Therefore, it is required to develop a ship for installing an offshore wind turbine generator which can install the offshore wind turbine generator on the ship quickly and stably.

In order to solve the above problems, the present invention provides a hull comprising: a hull having an installation hole; A pair of first and second guide frames installed on opposite sides of the installation hole so as to face each other and loaded with an offshore wind turbine installed in the inside; A first jig supporting a supporting surface of an offshore wind power generator mounted between the first and second guide frames and horizontally movably between the pair of first and second guide frames; A second jig provided on the upper side of the first jig for supporting an outer surface of a strut of an offshore wind power generator stacked between the first and second guide frames and horizontally movably installed between the pair of first and second guide frames, ; A lift device installed on the first and second guide frames to vertically move the lower end of the offshore wind turbine, which is fed to the installation hole by the first and second jigs, is positioned between the first and second jigs The present invention provides a marine vessel for installing a marine wind power generator.

Here, a first guide rail for horizontally moving the first jig is provided on the upper surface of the hull between the first and second guide frames.

Specifically, first and second support plates extending in the horizontal direction are protruded from the first and second guide frames, and second guide rails for horizontally moving the second jig are installed on the upper surfaces of the first and second support plates do.

A first clamping device is installed on the upper surface of the first jig so as to horizontally move and surround an outer surface of the lower end of the pillar of the offshore wind power generator.

The first and second clamping devices include first and second pressing plates having bending portions on the front surface so as to respectively surround the left and right outer surfaces of the lower portion of the column of the offshore wind turbine placed on the upper surface of the first jig; The first and second piston devices horizontally move on the upper surface of the first jig while being coupled to the rear surfaces of the first and second pressure plates to horizontally move the first and second pressure plates.

A second clamping device is installed on the upper surface of the second jig to horizontally move and surround the outer surface of the strut of the offshore wind power generator.

The second clamping device includes: a third and a fourth pressure plate having bent portions for respectively covering left and right outer surfaces of the offshore wind power generator; The third and fourth piston devices horizontally move on the upper surface of the second jig while being coupled to the rear surfaces of the third and fourth pressure plates to horizontally move the third and fourth pressure plates.

In addition, a cutout portion through which the strut of the offshore wind power generator is received is formed at a central portion of the second jig, and a pair of rotating plates are installed on one side of the second jig for selectively opening and closing the cut- .

The lifting device includes a plurality of lifting wires, one end of which is coupled to an outer surface of a lower portion of a pillar of the offshore wind power generator; And a plurality of actuators for vertically moving the offshore wind power generator between the first and second guide frames by winding or loosening the other end of the lifting wire.

The actuators are respectively installed on the upper surfaces of the third and fourth support plates extending from the first and second guide frames.

A flange portion for coupling with the foundation pile is formed to protrude from a lower end portion of the offshore wind power generator, and one end of the lifting wire is coupled to the flange portion.

The lifting device may further include: a fastening device selectively coupled to an outer surface of a lower portion of a strut of the offshore wind power generator; A plurality of lifting wires connected to the fastening device; And a plurality of actuators for vertically moving the fastening devices by winding or loosening the lifting wires, respectively.

Here, the fastening device may include: a lifting bar surrounding the strut outer surface of the offshore wind power generator; And a plurality of fastening ropes, one end of which is coupled to the lifting bar and the other end of which is coupled to the outer surface of the lower portion of the strut of the offshore wind power generator.

The lifting bar is provided with at least a pair of pivot bars that are coupled to each other or separated from each other to open one side of the lifting bar.

Further, a flange portion for coupling with the foundation pile is formed on the lower end portion of the offshore wind power generator, and the other end of the building rope is coupled to the flange portion.

The ship for installing a offshore wind turbine generator according to the present invention stably lifts an offshore wind turbine generator from a hull without using a crane so that an offshore wind turbine generator can be installed exactly at a predetermined position.

1 and 2 are views showing a structure of a ship for installing a offshore wind power generator according to the present invention.
3 is a view showing a state in which a vertical movement of an offshore wind power generator is performed by a lifting device according to the present invention.
4 is a perspective view showing the structure of the first jig and the first clamping device according to the present invention in more detail.
5 is a perspective view showing the structure of the second jig and the second clamping device according to the present invention in more detail.
6 is a view showing another embodiment of the lifting apparatus according to the present invention.
FIG. 7 is a view showing a state in which the vertical movement of the offshore wind turbine is performed by the lifting device of FIG. 6;

Hereinafter, preferred embodiments of the present invention in which the above objects can be specifically realized will be described with reference to the accompanying drawings. In describing the present embodiment, the same designations and the same reference numerals are used for the same components, and additional description thereof will be omitted in the following.

1 and 2 are views showing the overall structure of a ship for installing a offshore wind power generator according to the present invention, and FIG. 3 is a view showing a state in which an offshore wind power generator is vertically moved by the lifting device of FIG.

1 to 3, a ship for installing a maritime wind power generator according to the present invention includes a ship 100, first and second guide frames 200 and 300, a first jig 400, a second jig 500, and a lifting device 600.

The hull 100 may be formed in various shapes as a main body of the ship. For example, the hull 100 may be formed in a rectangular shape in which four corners are gently cut.

An installation hole H for installing an offshore wind power generator 10 constituted by a strut 11, a nacelle 12 and a blade 13 is formed through the hull 100. Of course, not only the offshore wind power generator 10 is installed through the installation hole H, but is installed in the seabed and connected to the offshore wind power generator 10 such as a monopie, a jacket, Tripile) can also be installed.

The first and second guide frames 200 and 300 are installed on both sides of the installation hole H so as to face each other. The first and second guide frames 200 and 300 are installed to have a height enough to load the offshore wind turbine generator 10 having a height of tens of meters.

The first jig 400 is supported between the first and second guide frames 200 and 300 to support the lower surface of the strut 11 of the offshore wind power generator installed between the first and second guide frames 200 and 300, So that the first guide frame 10 and the second guide frame 200 can be stably stood upright between the first and second guide frames 200 and 300.

The first jig 400 is installed horizontally between the first and second guide frames 200 and 300 so that the offshore wind power generator 10 can be moved to the installation hole H. A first guide rail 110 coupled to a lower surface of the first jig 400 and guiding the horizontal movement of the first jig 400 is provided on the upper surface of the hull 100 between the first and second guide frames 200, Respectively.

A first clamping device 410 is installed on the upper surface of the first jig 400 to horizontally move the support 11 of the offshore wind power generator and surround the outer surface of the lower end of the support 11.

The first clamping device 410 presses the lower end of the strut 11 so that the offshore wind power generator 10 collapses due to an external impact or the like when the first jig 400 moves along the first guide rail 110, As shown in Fig.

4 is a perspective view showing the structure of the first jig and the first clamping device according to the present invention in more detail.

4, the first clamping device 410 includes first and second pressure plates 411 and 412 which surround the left and right outer surfaces of the lower end of the strut 11 of the offshore wind power generator, and first and second pressure plates 411 and 412, And the first and second piston devices 413 and 414 for pushing and pulling the first and second piston devices 413 and 414 horizontally.

A plurality of first and second piston devices 413 and 414 are provided and the first and second pressure plates 411 and 412 have a semicircular bent portion R corresponding to the outer shape of the support 11 on the inner side. Therefore, when the first and second piston devices 413 and 414 start operating and the first and second pressure plates 411 and 412 are pushed toward the offshore wind turbine generator 10, the left and right outer sides of the lower end of the column 11, Are wrapped by the bent portions R of the projections 411 and 412.

The second jig 500 is installed between the first and second guide frames 200 and 300 so as to surround the outer surface of the strut 11 of the offshore wind power generator from above the first jig 400.

5 is a perspective view showing the structure of the second jig and the second clamping device according to the present invention in more detail.

As shown in FIG. 5, at the center of the second jig 500, there is formed a cut-out portion C through which a strut 11 of an offshore wind power generator is received, A pair of swinging plates 510 for selectively opening and closing the incision portion C are provided.

The rotary plate 510 is separated by rotation when the offshore wind power generator 10 is mounted between the first and second guide frames 200 and 300 by a crane or the like to open the incision portion C, The support 11 of the offshore wind power generator can be accommodated and when the support 11 of the offshore wind power generator is accommodated in the incision portion C, 11) can not escape out of the incision (C).

Here, the pair of swing plates 510 may be installed at the front and rear of the incision C, respectively, as shown in FIG. In this case, depending on the direction in which the off-axis wind power generator 10 is conveyed by the crane, the front or rear of the incision C can be selectively opened.

A plurality of second jigs 500 may be installed for stable support and horizontal movement of the offshore wind turbine generator 10. For example, the second jig 500 may be installed on the upper side of the first jig 400 as shown in FIG.

The second jig 500 is horizontally moved between the first and second guide frames 200 and 300 so as to move the offshore wind power generator 10 together with the first jig 400 to the installation hole H, Lt; / RTI >

To this end, the first and second guide frames 200 and 300 are provided with a second guide rail 120 coupled to a lower surface of the second jig 500 to guide horizontal movement of the second jig 500.

Specifically, the second guide rail 120 is formed on the upper surfaces of the first and second support plates 130 and 140 extending in the horizontal direction in the first and second guide frames 200 and 300, .

When the first jig 400 horizontally moves along the first guide rail 110 while supporting the lower surface of the offshore wind power generator 10, And horizontally moves along the second guide rail 120 while supporting the outer surface of the offshore wind power generator 10 from the upper side.

A second clamping device 520 is installed on the upper surface of the second jig 500 to horizontally move the strut 11 of the offshore wind power generator and enclose the outer surface of the offshore wind power generator 10, do.

The second clamping device 520 includes third and fourth pressure plates 521 and 522 that surround the left and right sides of the outer surface of the offshore wind power generator 10, respectively, similar to the first clamping device 410 described above, And fourth and fifth piston devices 523 and 524 for pushing and pulling the first and second pistons 521 and 522 horizontally.

A plurality of third and fourth piston devices 523 and 524 are installed and the third and fourth pressure plates 521 and 522 are installed on the inner surface of the outer surface of the offshore wind turbine generator 10 in the same manner as the first and second pressure plates 411 and 412, And has a semi-circular bent portion R corresponding to the shape.

When the first and second jigs 400 and 500 move along the first and second guide rails 110 and 120 to move the offshore wind power generator 10 to the installation hole H, The outer surfaces of the first and second clamping devices 410 and 520 are pressed by the first and second clamping devices 410 and 520 so that stable movement is possible.

The lifting device 600 is installed in the first and second guide frames 200 and 300 so as to be positioned between the first and second jigs 400 and 500 and is supported by the first and second jigs 400 and 500, When the generator 10 is transferred to the installation hole H, the lower end of the offshore wind power generator 10 is lifted up and moved vertically as shown in FIG.

The lifting device 600 includes a lifting wire 610 and an actuator 620.

The lifting wire 610 is coupled to the outer surface of the lower end of the strut 11 of the offshore wind power generator, one end of which is loaded between the first and second guide frames 200 and 300, when the installation of the offshore wind power generator 10 proceeds.

A fastening ring 611 is formed at one end of the lifting wire 610 and a fastening ring 11a is formed at an outer surface of the lower end of the post 11 to which the fastening ring 611 is coupled.

A plurality of lifting wires 610 may be installed as needed. In this case, a plurality of fastening rings 11a are formed on the outer surface of the lower end of the strut 11 of the offshore wind power generator. For example, when four lifting wires 610 are installed, four fastening rings 11a are formed on the outer surface of the offshore wind power generator 10.

Of course, the lifting wire 610 may be directly coupled to the flange portion 14 formed at the lower end of the strut 11 of the offshore wind power generator for bolt tightening with the foundation pile, not the fastening ring 11a.

Here, the operation of accurately positioning the flange portion 14 at the upper end of the foundation pile and then fastening the bolt in the sea is very difficult due to the influence of waves and the like. Thus, the flange portion 14 may be prefabricated at the upper end of a foundation file such as a mono file, a jacket, a trifile, etc. instead of the post 11. In this case, the flange portion 14 refers to the head portion of the foundation pile.

The actuator 620 is installed on the first and second guide frames 200 and 300 to vertically move the offshore wind power generator 10 by winding or loosening the other end of the lifting wire 610 so that the off- H).

Specifically, the actuator 620 is installed on the upper surfaces of the third and fourth support plates 150 and 160 extending from the first and second guide frames 200 and 300, respectively. The first and second jigs 400 and 500 support the off- The other end of the lifting wire 610 is lifted to lift the offshore wind power generator 10 vertically upward as shown in FIG. 3, and then the other end of the lifting wire 610 is lifted up So that the offshore wind power generator 10 is lowered into the installation hole H and installed on the sea.

When the offshore wind turbine generator 10 is lifted up, the first jig 400 positioned in the upper right room of the installation hole H returns to the original position along the first guide rail 110, Open. When four lifting wires 610 are installed, four actuators 620 are installed (see FIG. 2)

The lifting device 600 configured as described above is installed on the upper side of the second jig 500, that is, the upper end of the first and second guide frames 200 and 300, and grips the upper end portion of the strut 11, May be moved vertically.

However, in this case, the load of the offshore wind power generator 10, which reaches several hundreds of tons applied to the lifting device 600, acts on the upper end of the first and second guide frames 200 and 300. In order to stably support the load, , The two guide frames 200 and 300 must have a sufficient height and size.

When the lifting device 600 is installed on the lower side of the second jig 500 to lift the lower end of the support 11 as described above, the load of the offshore wind power generator 10 is transmitted to the first and second guide frames 200 and 300 It is possible to lift the offshore wind power generator 10 stably without increasing the height or size of the first and second guide frames 200 and 300. [ Specifically, it has been confirmed that the height of the first and second guide frames 200 and 300 can be reduced by about 20 m when the structure is applied, depending on the size of the offshore wind power generator 10.

FIG. 6 is a view showing another embodiment of the lifting device according to the present invention, and FIG. 7 is a view showing a state in which the vertical movement of the offshore wind turbine is performed by the lifting device of FIG.

6 and 7, the lifting device 600 of the present invention may further include a lifting bar 630 and a fastening rope 640.

The lifting bar 630 surrounds the outer surface of the offshore wind power generator 10, which is mounted in a standing state between the first and second guide frames 200 and 300.

Specifically, the lifting bar 630 is opened by a crane such that when the offshore wind power generator 10 is loaded between the first and second guide frames 200 and 300, the lifting bar 630 is opened so that the offshore wind power generator 10 is positioned therein. And then covers the outer surface of the offshore wind power generator 10 as shown in FIG.

To this end, the lifting bar 630 is provided with at least one pair of pivoting bars 631 that are mutually coupled or separated to open one side of the lifting bar 630.

A plurality of lifting wires 610 are connected to the upper surface of the lifting bar 630. Accordingly, when the actuator 620 winds or releases the lifting wire 610 as described above, the vertical movement of the lifting bar 630 is performed.

One end of the fastening rope 640 is coupled to the lifting bar 630 and the other end of the fastening rope 640 is coupled to the outer surface of the lower end of the strut 11 when the offshore wind power generator installation work is performed.

A plurality of such fastening ropes 640 are provided and at the other end of each fastening rope 640 is formed a ring portion 641 which is inserted into a fastening ring 11a formed on the outer surface of the lower end of the post 11. The lifting bar 630 is naturally connected to the offshore wind turbine generator 10 when the annulus 641 is inserted into the fastening ring 11a of the offshore wind power generator 10. Thus, The vertical movement of the offshore wind power generator 10 is performed.

7, the fastening rope 640 may be directly connected to the flange portion 14 formed at the lower end of the strut 11 of the offshore wind power generator for engagement with the foundation file, not the fastening ring 11a, . Here, as described above, the flange portion 14 may be used as a term referring to the head portion of the foundation file.

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 within the scope of equivalents should be construed as falling within the scope of the present invention.

10: offshore wind power generator 11: holding
12: Nacelle 13: Blade
100: hull 110: first guide rail
120: second guide rail 130, 140: first and second support plates
150, 160: third and fourth support plates 200, 300: first and second guide frames
400: first jig 410: first clamping device
500: second jig 510: rotatable plate
520: second clamping device 600: lifting device
610: Lifting wire 620: Actuator
630: lifting bar 640: fastening rope
H: Installation hole

Claims (15)

A hull having an installation hole formed therein;
A pair of first and second guide frames installed on opposite sides of the installation hole so as to face each other and loaded with an offshore wind turbine installed in the inside;
A first jig supporting a supporting surface of an offshore wind power generator mounted between the first and second guide frames and horizontally movably between the pair of first and second guide frames;
A second jig provided on the upper side of the first jig for supporting an outer surface of a strut of an offshore wind power generator stacked between the first and second guide frames and horizontally movably installed between the pair of first and second guide frames, ; And,
And a lift device installed on the first and second guide frames so as to be positioned between the first and second jigs and lifting a lower end portion of the offshore wind power generator being vertically moved by the first and second jigs to the installation hole, For the installation of offshore wind turbines. The method according to claim 1,
And a first guide rail for horizontally moving the first jig is provided on an upper surface of the hull between the first and second guide frames. The method according to claim 1,
First and second support plates extending in the horizontal direction are protruded from the first and second guide frames and a second guide rail for horizontally moving the second jig is provided on the upper surfaces of the first and second support plates For the installation of offshore wind power generators. The method according to claim 1,
And a first clamping device is installed on the upper surface of the first jig to horizontally move and surround an outer surface of a lower portion of a pillar of the offshore wind power generator. 5. The method of claim 4,
Wherein the first clamping device comprises:
A first and a second pressing plate having front and rear bent portions for respectively covering left and right outer side surfaces of a lower portion of a supporting post of an offshore wind power generator placed on an upper surface of the first jig; And,
And a first and a second piston device horizontally moving on the upper surface of the first jig while being coupled to the rear surfaces of the first and second pressure plates to horizontally move the first and second pressure plates. The method according to claim 1,
And a second clamping device is installed on the upper surface of the second jig so as to horizontally move and surround the outer surface of the strut of the offshore wind power generator. The method according to claim 6,
Wherein the second clamping device comprises:
Third and fourth pressure plates each having a bent portion that surrounds left and right outer surfaces of the offshore wind power generator; And,
And a third and fourth piston device horizontally moving on the upper surface of the second jig while being coupled to the rear surfaces of the third and fourth pressure plates to horizontally move the third and fourth pressure plates. Ship for installation. The method according to claim 1,
And a pair of rotating plates are installed on one side of the second jig for selectively opening and closing the cut-off portion. For the installation of offshore wind power generators. The method according to claim 1,
The lifting device comprises:
A plurality of lifting wires, one end of which is coupled to an outer surface of a lower portion of a pillar of the offshore wind power generator; And,
And a plurality of actuators for vertically moving the offshore wind power generator between the first and second guide frames by winding or loosening the other end of the lifting wire. 10. The method of claim 9,
Wherein the actuator is installed on upper surfaces of third and fourth support plates extending from the first and second guide frames, respectively. 10. The method of claim 9,
Wherein a flange portion for engaging with a foundation pile is formed in a lower end portion of the offshore wind power generator, and one end of the lifting wire is coupled to the flange portion. The method according to claim 1,
The lifting device comprises:
A coupling device selectively coupled to an outer surface of a lower portion of a pillar of the offshore wind power generator;
A plurality of lifting wires connected to the fastening device; And,
And a plurality of actuators for vertically moving the fastening devices by winding or loosening the lifting wires, respectively. 13. The method of claim 12,
The fastening device includes:
A lifting bar surrounding the strut outer surface of the offshore wind power generator; And,
And a plurality of fastening ropes, one end of which is coupled to the lifting bar and the other end of which is coupled to an outer surface of a lower portion of a pillar of an offshore wind turbine generator. 14. The method of claim 13,
Wherein the lifting bar is provided with at least one pair of pivoting bars that are mutually coupled or separated to open one side of the lifting bar. 14. The method of claim 13,
Wherein a flange portion for engaging with a foundation pile is protruded and formed at a lower end portion of the offshore wind power generator, and the other end of the fastening rope is coupled to the flange portion.

Images