KR101399452B1 - Construction method for offshore structure - Google Patents

Abstract

The present invention provides a method for building a marine structure (200) including a process of placing an FD line (40) close to an inner wall (1); a lower member manufacturing process of manufacturing a lower member (210) of the marine structure (200) on the FD line (40) while installing a buoyancy reinforcing member (100) for reinforcing the buoyancy of the lower member (210); a flooding process of flooding the FD line (40), the lower member (210), and the buoyancy reinforcing member (100) to lower the altitude of the lower member (210); an assembly process of forming the marine structure (200) by assembling an upper member (220) with the upper part of the lower member (210); a floating process of floating the FD line (40), the marine structure (200), and the buoyancy reinforcing member (100); a transporting process of transporting the FD line (40), the marine structure (200), and the buoyancy reinforcing member (100) to an installation position; and an installation process of installing the marine structure (200) and the buoyancy reinforcing member (100) by flooding them on the installation position. The method has excellent constructability and enables construction with less influence by weather.

Description

TECHNICAL FIELD [0001] The present invention relates to a method of constructing an offshore structure,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a construction field and, more particularly, to a method of constructing an offshore structure.

Recently, the demand for offshore wind power is increasing due to the noise problem caused by the enlargement of wind power generators over 3MW and quality problems of the affluent resources (Fig. 1).

There are various types of supporting structures for supporting the wind turbine, such as jacket, mono-pile, and tripod. However, due to the recent increase in steel price and the problem of workability in the soft ground, Is being actively carried out.

1 shows an offshore wind power generator 200a (gravity type structure) as an example of an offshore structure 200 and includes a main body 211, a tower 221 installed on the top of the main body 211, A nacelle 223 and a blade 222. [

The main body 211 is formed with a conical undesirable portion 212 at the bottom of the main body 211 to prevent the main body 211 from being conducted by strong winds, waves, tides, earthquakes or the like, To form a mound (5).

Since such a conventional offshore wind turbine generator 200a is a large-scale structure, it is general to take a method of assembling each member on the land and moving it to the field of the sea and assembling it.

However, due to the marine environment conditions such as wind, blue, and algae, it is difficult to construct the wind turbine. Especially, when the blade is installed, it can be installed only under cut-in wind speed (3-5m / s) It is a constraint condition.

Korean Patent Laid-Open Publication No. 2013-0054056 (method of constructing a superstructure for four-lag wind power generation), Korean Patent No. 1320689 (method of installing a slab foundation of a marine wind power generation tower) Korean Patent No. 995667 (system block for offshore wind power support structure and construction method using the same) are disclosed.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method of constructing an offshore structure that is superior in workability and is less affected by weather and can be constructed.

In order to solve the above problems, the present invention provides a method of manufacturing a fuel cell, comprising the steps of: positioning an FD line (40) adjacent to a wall (1); The lower member 210 of the offshore structure 200 is manufactured on the FD line 40 and the buoyancy reinforcing member 100 for reinforcing the buoyancy of the lower member 210 is formed on the lower member 210 A lower member manufacturing process for installing the lower member; A flooding step of flooding the FD line 40, the lower member 210 and the buoyancy reinforcing member 100 to lower the altitude of the lower member 210; An assembling process of assembling an offshore structure 200 by assembling an upper member 220 on an upper portion of the lower member 210; A floating process for floating the FD line 40, the offshore structure 200 and the buoyancy reinforcing member 100; A conveying step of conveying the FD line 40, the offshore structure 200 and the buoyancy reinforcing member 100 to an installation position; And an installation step of submerging the offshore structure 200 and the buoyancy reinforcement member 100 at the installed position and installing the buoyancy reinforcement member 100 on the sea floor.

The buoyancy reinforcing member 100 may be formed so that the hollow portion 101 is formed therein and the seawater can be received and drained to the hollow portion 101.

The buoyancy reinforcing member 100 is preferably disposed in a radially symmetrical structure around the lower member 210.

The lower member 210 is preferably formed to have a hollow inside and to receive and drain seawater from the hollow.

Preferably, the installing step includes a step of releasing the FD line 40 by flooding while the floating structure 200 and the buoyancy reinforcing member 100 are floated by buoyancy.

The buoyancy reinforcement member 100 is installed detachably with respect to the lower member 210 and the installation step is performed after the buoyancy reinforcement member 100 is attached to the lower member 210 ) By buoyancy to separate them from each other.

The present invention is a method of constructing an offshore wind power generator 200a using the method of constructing the offshore structure 200. The lower member 210 includes a main body 211 of the offshore wind power generator 200a, , And the upper member (220) includes a tower (221), a blade (222) and a nacelle (223) of the offshore wind power generator (200a) Together.

The buoyancy reinforcing member (100) includes a cylindrical wall body (110) having an installation space (111) formed therein; A hollow portion 101 formed inside the cylindrical wall body 110; And a valve 112 formed in the cylindrical wall 110 to allow the water to be supplied to and drain from the hollow portion 101.

It is preferable that the conduction preventing part 212 is installed in the installation space 111 and is provided on the inner wall of the buoyancy reinforcing member 100 by an anchor 120 having a truss structure.

The blade temporary supporting portion 130 is extended to the upper side of the buoyancy reinforcing member 100 and the assembling process includes a step of coupling the blade 222 of the upper member 220 to the blade temporary supporting portion 130 , And the step of installing the blade includes separating the blade (222) from the blade temporary support (130).

The present invention provides a method of constructing an offshore structure which is excellent in workability and can be applied while being less affected by the weather.

1 is a side view of a conventional offshore wind turbine generator.
2 is a perspective view illustrating a construction method according to an embodiment of the present invention.
2 to 4 are process drawings.
5 is a perspective view of the buoyancy reinforcing member,
6 is a side view of the lower member and the buoyancy reinforcing member.
7 is a side view of the FD line.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Hereinafter, the offshore wind power generator 200a will be described as an example of the offshore structure 200, but the construction method according to the present invention is applicable to other offshore structures 200 having a structure similar to that of the offshore wind power generator 200a Can be effectively applied.

As shown in FIG. 2 and subsequent drawings, the method of constructing the offshore structure 200 according to the present invention is constituted by the following process.

1) The FD line 40 is positioned adjacent to the sidewall 1 (Fig. 2).

Here, the floating dock (FD) line means a ship which is formed so as to be able to receive and drain seawater from the inside of the hull so that the hull can float and float (Fig. 7).

2) The lower member 210 of the offshore structure 200 is manufactured on the FD line 40 and the buoyancy reinforcing member 100 for reinforcing the buoyancy of the lower member 210 is installed on the lower member 210 (Fig. 3).

Here, the lower member 210 refers to a member constituting the lower structure of the offshore structure 200, and in the case of the offshore wind power generator 200a, the main body 211, the conduction preventing portion 212, and the like are included.

The buoyancy reinforcing member 100 is a member for reinforcing the buoyant force when the lower member 210 is lifted as described later. The buoyancy reinforcing member 100 has a hollow portion 101 formed therein, And a structure formed to enable drainage (Fig. 5).

3) The FD line 40, the lower member 210 and the buoyancy reinforcing member 100 are submerged to lower the altitude of the lower member 210 (Fig. 4).

This is to prevent a situation where the operation of the crane is difficult due to the high altitude in the case of the high-altitude offshore structure 200 such as the offshore wind power generator 200a.

4) The upper member 220 is assembled to the upper part of the lower member 210 to form an offshore structure 200 (FIG. 4).

Here, the upper member 220 refers to a member installed in a higher altitude area of the upper part of the offshore structure 200, such as the tower 221, the blade 222, and the nacelle 223 of the offshore wind power generator 200a.

The upper member 220 can be lifted by the crane 31 installed on the inner wall 1 and assembled to the upper part of the lower member 210. If the height of the crane 31 is insufficient, .

5) After the completion of the assembly of the offshore structure 200, the FD line 40, the offshore structure 200 and the buoyancy strengthening member 100 float up to the FD line 40, the offshore structure 200 and the buoyancy reinforcing member 100 to the installation position, the offshore structure 200 and the buoyancy reinforcement member 100 are submerged in the installed position and installed on the sea floor.

That is, in order to assemble and transport an offshore structure 200 having a high altitude such as an offshore wind power generator 200a in a region adjacent to the seawall 1, in order to prevent the operation of the crane from being difficult due to a high altitude, The assembled operation of the upper member 220 is performed by lowering the altitude by once dipping the lower structure member 40 and the lower structure member 210 and lifting the assembled offshore structure 200 and the FD line 40 to the installation position, .

In the case of the offshore structure 200 formed of a concrete material such as the offshore wind power generator 200a, buoyancy is insufficient as compared with the weight, so that there is a problem that the float is not lifted after immersion.

The upper buoyancy reinforcing member 100 has a structure for preventing such a problem and has the effect of facilitating the floating of the FD line 40 and the lower member 210 due to the structure of the inner hollow portion and the like.

The buoyancy reinforcing member 100 is not limited to any structure that can assist the lifting of the lower member 210. However, it is preferable that the buoyancy reinforcing member 100 is provided in a radially symmetrical structure around the lower member 210 for stable flooding and floating Do.

It is preferable that the lower member 210 is formed with hollows therein and that the seawater can be received and drained to the hollows for stable flooding and floating processes.

After the offshore structure 200 arrives at the installation position by the transportation of the FD line 40 and the floating structure 200 and the buoyancy reinforcement member 100 float by the buoyancy force, the FD line 40 is flooded It is preferable that the offshore structure 200 and the buoyancy reinforcing member 100 are submerged and installed in the installation position for stable construction.

The buoyancy reinforcing member 100 may be fixed to the lower member 210 of the offshore structure 200 so that the buoyancy reinforcement member 100 may be floated together with the buoyancy reinforcement member 100. The buoyancy reinforcement member 100 may be detachably attached to the lower member 210, It is preferable that the lower member 210 is floated by buoyancy to be separated and recycled from the viewpoint of efficiency.

When the lower member 210 is formed of a concrete material, it is preferable that the buoyancy reinforcing member 100 is also formed of a concrete material for structural stability.

Specifically, it includes a cylindrical wall body 110 having an installation space 111 for installing the lower member 210 in an inner area thereof; A hollow portion 101 formed inside the cylindrical wall body 110 (wall itself); And a valve 112 formed in the cylindrical wall body 110 so as to allow the water to be supplied to and drain from the hollow portion 101 (FIG. 5).

In this case, the conduction preventing portion 212 of the lower member 210 is provided in the upper installation space 111 and is provided on the inner wall of the buoyancy reinforcing member 100 by the anchor 120 of the truss structure Stable flooding, floatation, and subsequent separation process.

In order to prevent the blade 222 of the upper member 220 from moving due to the wind during the transportation and installation processes, the blade temporary supporting portion 130 is extended to the upper side of the buoyancy reinforcing member 100, It is preferable to temporarily connect to the blade temporary supporting member 130 and to separate the blade 222 from the blade temporary supporting member 130 after completion of the installation of the offshore structure 200 on the sea floor.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It is to be understood that both the technical idea and the technical spirit of the invention are included in the scope of the present invention.

1: Seal 30: Workbench
31: Crane 40: FD line
100: buoyancy reinforcing member 101: hollow portion
110: cylindrical wall 111: installation space
112: valve 120: anchor
130: blade temporary support 200: offshore structure
200a: offshore wind power generator 210: lower member
211: main body 212:
220: upper member 221: tower
222: blade 223: nacelle

Claims (10)

Placing the FD line (40) adjacent to the sidewall (1);
The lower member 210 of the offshore structure 200 is manufactured on the FD line 40 and the buoyancy reinforcing member 100 for reinforcing the buoyancy of the lower member 210 is formed on the lower member 210 A lower member manufacturing process for installing the lower member;
A flooding step of flooding the FD line 40, the lower member 210 and the buoyancy reinforcing member 100 to lower the altitude of the lower member 210;
An assembling process of assembling an offshore structure 200 by assembling an upper member 220 on an upper portion of the lower member 210;
A floating process for floating the FD line 40, the offshore structure 200 and the buoyancy reinforcing member 100;
A conveying step of conveying the FD line 40, the offshore structure 200 and the buoyancy reinforcing member 100 to an installation position;
And an installation step of submerging the offshore structure 200 and the buoyancy reinforcing member 100 at the installation position and installing the same on the sea floor
(200). ≪ RTI ID = 0.0 > 31. < / RTI > The method according to claim 1,
The buoyancy reinforcing member (100)
Wherein the hollow part (101) is formed inside the hollow part (101), and the seawater can be received and drained to the hollow part (101). 3. The method of claim 2,
The buoyancy reinforcing member (100)
Wherein the lower member (210) is provided with a radially symmetrical structure around the periphery of the lower member (210). 3. The method of claim 2,
The lower member (210)
Wherein a hollow is formed inside the hollow structure, and the seawater can be received and drained to the hollow. The method according to claim 1,
In the installation step,
The method of claim 1, further comprising the step of immersing the offshore structure (200) and the buoyancy reinforcement member (100) in a floating state to float the FD line (40). The method according to claim 1,
The buoyancy reinforcing member 100 is detachably installed to the lower member 210,
In the installation step,
Wherein the buoyancy reinforcement member (100) is lifted from the lower member (210) by floating force after the installation of the offshore structure (200). A method of constructing an offshore wind power generator (200a) using a method of constructing an offshore structure (200) according to any one of claims 1 to 6,
The lower member 210 includes the main body 211 of the offshore wind power generator 200a and the anti-reflection portion 212,
Wherein the upper member 220 includes a tower 221, a blade 222 and a nacelle 223 of the offshore wind turbine generator 200a. 8. The method of claim 7,
The buoyancy reinforcing member 100 is made of
A cylindrical wall body 110 having an installation space 111 formed therein;
A hollow portion 101 formed inside the cylindrical wall body 110;
A valve 112 formed in the cylindrical wall body 110 so that seawater can be received and drained to the hollow portion 101;
(200a) of the offshore wind power generator (200a). 9. The method of claim 8,
The detachment preventing portion 212 is installed in the installation space 111 and is installed on the inner wall of the buoyancy reinforcing member 100 by an anchor 120 having a truss structure. Construction method. 8. The method of claim 7,
The buoyancy reinforcing member 100 is provided with a blade temporary supporting portion 130 extending upward,
In the assembling step,
And coupling the blade (222) of the upper member (220) to the blade temporary support (130)
In the installation step,
And separating the blade (222) from the blade temporary supporting portion (130).

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