KR20160053429A - Offshore structure and construction method thereof - Google Patents

Abstract

The present invention provides a marine structure including: a floating member (100) installed on the water surface; an extension member (200) extended to the lower side of the floating member (100) to be submerged; a sinking member (300) joined to the lower part of the extension member (200) and installed in the seabed; a wire (400) of which an upper part is joined to a lower part of the floating member (100) or an upper part of the extension member (200); and a fixating member (410) installed to fixate a lower end of the wire (400) to be fixated in the seabed. Accordingly, excellent structural stability and excellent power generating efficiency are obtained even in the deep sea.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an offshore structure,

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

As the problem of the noise caused by the wind power generation structure of the land is pointed out, an attempt is made to construct and use the wind power generation structure at sea.

If the water depth is shallow, it is necessary to form a foundation on the sea floor and install the wind power generation structure thereon. However, if the water depth is deep, it is difficult to perform the foundation work of the sea floor.

1, a wire 20 is connected to a wind power generation structure composed of a tower 11, a propeller 12, and a float 13, and a lower end of the wire 20 is connected to a bottom surface Use a floating base to secure to the anchor (21).

However, such conventional floating bases have a problem in that the entire structure is shaken by the wind, resulting in poor structural stability and power generation efficiency.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an offshore structure and a method of constructing the same that can provide excellent structural stability and power generation efficiency even when the depth is deep.

In order to solve the above-mentioned problems, the present invention provides an image pickup apparatus, comprising: an image pickup element (100) An extension member (200) extending to the lower portion of the winning member (100) so as to be immersed in water; A sinking member 300 installed on the bottom surface of the water, coupled to a lower portion of the extension member 200; A wire 400 coupled to a lower end of the winning member 100 or an upper end of the extending member 200; And a fixing member 410 installed to fix the lower end of the wire 400 to the underwater floor.

It is preferable that the extension member 200 has a tubular structure in which a cavity is formed therein.

A connecting member 210 having a structure capable of being bent is provided between the extending member 200 and the sinking member 300.

The sinking member 300 includes a main body 310; A swirl type water immersion chamber 320 formed in a closed structure inside the main body 310 and formed in a swirl type channel structure; An inlet 303 formed at one end of the swirl-type water immersion chamber 320; An outlet (301) formed at the other end of the swirl-type water immersion chamber (320); .

One end of the swirl-type water immersion chamber 320 is formed at a central portion, and the other end of the swirl-type water immersion chamber 320 is formed at an edge portion.

The swirl-type water immersion chamber 320 may be formed by embedding a hose made of a flexible material into the concrete forming the main body 310.

A plurality of vortex-type water immersion chambers 320 are formed along the vertical direction. The inlet port 303 is formed at one end of the lower vortex water immersion chamber 320b of the plurality of vortex type water immersion chambers 320, The outflow port 301 is formed at the other end of the upper swirl type water immersion chamber 320a of the plurality of swirl type water immersion chambers 320 and the other end of the lower swirl type water immersion chamber 320b and the upper swirl type water immersion chamber 320a May be connected by the connection passage 302. [0054]

The present invention is an offshore wind power generation structure using the above-described offshore structure, wherein the above-mentioned award member (100) comprises: a tower (110) in which a power generation facility is installed; And a propeller 120 installed in the tower 110. The extension member 200 is coupled to a lower portion of the tower 110. [

The present invention relates to a method of constructing an offshore structure, comprising the steps of: installing the fixing member (410) on a floor underwater; Coupling the extension member (200) and the sinking member (300); A sinking member mounting step of sinking the extension member 200 and the sinking member 300 into water so that the sinking member 300 is seated on the underwater floor; Combining the winning member (100) and the extending member (200); And coupling the upper end of the wire 400 to the winning member 100 or the extending member 200 and coupling the lower end of the wire 400 to the fixing member 410. [ This paper presents a method of constructing an offshore structure.

The step of installing the sinking member (300) comprises the steps of lifting the sinking member (300) to a position where the sinking member (300) is installed, with the inlet (303) closed. And a sinking step of sinking the sinking member (300) by opening the inlet (303) to allow water to flow into the swirl-type water immersion chamber (320).

The sinking step may include a sinking speed control step of controlling the sinking speed of the sinking member 300 by repeating the closing and opening of the outlet 301 so that air in the swirling water immersion chamber 320 is slowly discharged; .

The sinking step reversely inflows air through the outflow port 301 so that the volume of the air in the swirl-type water immersion chamber 320 is slowly decreased, thereby controlling the sinking speed of the sinking member 300 The method further comprising:

The present invention provides a marine structure and a method of constructing the same that can obtain excellent structural stability and power generation efficiency even when the water depth is deep.

1 is a side view of a conventional marine structure.
2 shows an embodiment of the present invention,
2 and 3 are process drawings of a method of constructing an offshore structure.
4 is a cross-sectional view of the first embodiment of the sinking member;
5 is a sectional view taken along the line AA of Fig.
6 is a longitudinal sectional view of the second embodiment of the sinking member.
7 is a process chart of an embodiment of a method of constructing a sinking member.
8 is a cross-sectional view of a third embodiment of the sinking member.

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

As shown in FIG. 2 and subsequent drawings, the marine structure according to the present invention basically comprises an aquatic member 100 installed on a water surface; An extension member (200) extending to the lower portion of the winning member (100) so as to be immersed in water; A sinking member 300 attached to the lower part of the elongated member 200 and installed on the water floor; A wire 400 coupled to a lower end of the winning member 100 or an upper end of the extending member 200; And a fixing member 410 installed to fix the lower end of the wire 400 to the underwater floor.

Herein, the winning member 100 includes a tower 110 in which a power generation facility is installed; And a propeller 120 installed in the tower 110. In this case, the upper extension member 200 is coupled to the lower portion of the tower 110. [

The method of constructing an offshore structure according to the present invention is constituted by the following process.

The extension member 200 and the sinking member 300 are combined and the extension member 200 and the sinking member 300 are submerged in water to form the sinking member 300, (Fig. 2).

Since the installation of the sinking member 300 is completed by submerging the sinking member 300, no additional foundation work is required. The lower end of the extension member 200 is connected to the sinking member 300 to sink into the water, It is preferable for the upper part of the upper part 200 to be exposed to the water phase by a separate float for the subsequent process.

The upper end of the wire 400 is coupled to the winning member 100 or the extending member 200 and the lower end of the wire 400 is connected to the fixing member 100. [ Lt; / RTI >

That is, the offshore structure according to the present invention basically has a structure similar to that of the conventional floating base, and the extension member 200 and the sinking member 300 are coupled to the lower part of the piercing member 100, .

Therefore, even when the water depth is deep, the structural stability is excellent as compared with the conventional floating foundation, and the entire structure is not shaken by the wind and only the propeller 120 can be rotated.

It is preferable that the elongated member 200 has a tubular structure in which a cavity is formed inside as in a steel pipe so that the seawater is filled therein.

It is preferable that a connecting member 210 having a structure capable of being bent like a chain is provided between the extending member 200 and the sinking member 300 for easy installation of the sinking member 300.

The sinking member 300 basically comprises a main body 310; A swirl-type water immersion chamber 320 formed in a closed structure inside the main body 310 and formed in a swirl-type channel structure; An inlet 303 formed at one end of the swirl-type water immersion chamber 320; And an outlet 301 formed at the other end of the swirl-type water immersion chamber 320 (FIGS. 4 and 5).

This allows the sinking member 300 to be lifted to the installation position of the ocean while the inlet 303 is closed and water is introduced into the swirl-type submergence chamber 320 by opening the inlet 303, ) Is sunk.

When this configuration is adopted, water is slowly accumulated in the swirl-type water immersion chamber 320 along the structure of the water immersion chamber, so that a stable buoyancy structure is achieved and lateral flow of the offshore structure is not caused.

In addition, since the speed at which the water flows into the swirl-type water immersion chamber 320 will be considerably slow, as the sinking speed becomes slow, it is possible to prevent the marine structure from colliding with and damaging the seabed surface or the pre- .

Further, when dismantling the offshore structure at a later time, it is necessary to adopt a method of floating the offshore structure by injecting air backward through the outflow port 301, so that there is added an advantage that disassembly work is easy.

In the case where one end of the swirl type water immersion chamber 320 in which the sea water inflow port 303 is formed is formed at the center and the other end of the swirl type water immersion chamber 320 in which the outflow port 301 is formed is formed at the edge portion, The water flows slowly toward the edge from the center of the water immersion chamber 320, so that lateral flow of the offshore structure can be prevented more stably.

Such a swirl-type water immersion chamber 320 can be realized by a method of deforming a hose made of a flexible material into a whirlpool structure to be embedded in concrete when concrete is poured to form the main body 310.

The swirl-type water immersion chamber 320 may have a plurality of structures formed along the vertical direction (Fig. 6).

That is, an inlet port 303 is formed at one end of the lower vortex water immersion chamber 320b of the plurality of vortex water immersion chambers 320, and an inlet port 303 is formed at one end of the upper vortex water immersion chamber 320a And the other end of the lower vortex water immersion chamber 320b is connected to the other end of the upper vortex water immersion chamber 320a by a connection passage 302. [

When this configuration is adopted, water gradually flows from the lower vortex water immersion chamber 320b of the plurality of water immersion chambers 320. At this point, water is present in the lower part of the offshore structure, The buoyant structure can be stabilized and the lateral flow of the offshore structure can be prevented more stably.

In addition, since the submerged water is supplied from the lower vortex water immersion chamber 320b to the upper vortex water immersion chamber 320a through the connection passage 302, the submerged water is not completely filled until the sinking speed becomes slow, It can be prevented from colliding with and damaging the existing offshore structures at a high speed.

The rate of sinking of an ocean structure with this structure can be controlled by the following method.

First, closing and opening of the outlet 301 are repeated to allow the air in the swirl-type water-immersion chamber 320 to be slowly discharged, so that the sinking speed of the sinking member 300 can be controlled.

That is, the discharge speed of the air through the outlet port 301 is proportional to the inflow speed of the seawater through the inlet port 303, so that the inflow speed of the seawater can be adjusted by controlling the discharge speed of the air.

Secondly, a method of regulating the sinking speed of the sinking member 300 can be adopted by allowing the air to flow backward through the outlet port 301 and gradually decreasing the volume of the air in the swirl-type water immersion chamber 320.

The buoyancy of an object is proportional to the volume occupied by the object in water. In the case of a compressible fluid such as air, the buoyancy becomes smaller as the volume becomes smaller by the water pressure as it enters a deep water depth.

Therefore, in the case of a large scale offshore structure installed in a high degree of water, the air is flowed backward through the outlet port 301 by the high-pressure air injector 200 or the like, It is more desirable to adjust the sinking speed by allowing the volume of the water to slowly decrease in spite of the state of high severity (Fig. 7).

The swirl-type water immersion chamber 320 may have a circular structure as described above, or may have a rectangular structure according to the structure of the main body 310 (FIG. 8).

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.

100: award member 110: tower
120: propeller 200: extension member
300: sinking member 301: outlet
302: connection passage 303: inlet
310: main body 320: spiral type water immersion chamber
400: wire 410: fixing member

Claims (12)

(100) installed on a water surface;
An extension member (200) extending to the lower portion of the winning member (100) so as to be immersed in water;
A sinking member 300 installed on the bottom surface of the water, coupled to a lower portion of the extension member 200;
A wire 400 coupled to a lower end of the winning member 100 or an upper end of the extending member 200;
A fixing member 410 installed to fix the lower end of the wire 400 to the underwater floor;
≪ / RTI > The method according to claim 1,
Wherein the extension member (200) has a tubular structure in which a cavity is formed therein. The method according to claim 1,
Wherein a connecting member (210) having a structure capable of being bent is provided between the extending member (200) and the sinking member (300). The method according to claim 1,
The sinking member (300)
A body 310;
A swirl type water immersion chamber 320 formed in a closed structure inside the main body 310 and formed in a swirl type channel structure;
An inlet 303 formed at one end of the swirl-type water immersion chamber 320;
An outlet (301) formed at the other end of the swirl-type water immersion chamber (320);
≪ / RTI > 5. The method of claim 4,
Wherein one end of the swirl-type water-immersion chamber (320) is formed at a central portion, and the other end of the swirl-type water-immersion chamber (320) is formed at an edge portion. 6. The method of claim 5,
Wherein the swirl-type water immersion chamber (320) is formed by embedding a hose made of a flexible material into the concrete forming the main body (310). 6. The method of claim 5,
A plurality of the swirl-type water immersion chambers 320 are formed along the vertical direction,
The inlet port 303 is formed at one end of the lower vortex water immersion chamber 320b of the plurality of vortex water immersion chambers 320,
The outlet (301) is formed at the other end of the upper vortex water immersion chamber (320a) of the plurality of vortex type water immersion chambers (320)
And the other end of the lower vortex water immersion chamber (320b) and one end of the upper vortex water immersion chamber (320a) are connected by a connection passage (302). An offshore wind power generation structure using an offshore structure according to any one of claims 1 to 7,
The winning member (100)
A tower 110 in which a power generation facility is installed;
And a propeller (120) installed in the tower (110)
Wherein the extension member (200) is coupled to a lower portion of the tower (110). A method of constructing an offshore structure according to any one of claims 1 to 7,
Installing the fixing member (410) on an underwater floor surface;
Coupling the extension member (200) and the sinking member (300);
A sinking member mounting step of sinking the extension member 200 and the sinking member 300 into water so that the sinking member 300 is seated on the underwater floor;
Combining the winning member (100) and the extending member (200);
Coupling the upper end of the wire 400 to the winning member 100 or the extending member 200 and coupling the lower end of the wire 400 to the fixing member 410;
The method comprising the steps of: 10. The method of claim 9,
In the step of installing the sinking member 300,
A lifting step of lifting the sinking member (300) to an installation position of the ocean while the inlet (303) is closed;
A sinking step of sinking the sinking member (300) by opening the inlet (303) to allow water to flow into the swirl-type water immersion chamber (320);
Wherein the method comprises the steps of: 11. The method of claim 10,
The sinking step
Adjusting the sinking speed of the sinking member (300) by repeating the closing and opening of the outlet (301) so that air in the swirling water immersion chamber (320) is slowly discharged;
The method comprising the steps of: 11. The method of claim 10,
The sinking step
A sinking speed adjusting step of regulating the sinking speed of the sinking member (300) by allowing the air to flow back through the outlet (301) so that the volume of the air in the swirling water immersion chamber (320)
The method comprising the steps of:

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