KR101434603B1 - Offshore structure and construction method thereof - Google Patents

Abstract

The present invention includes a main body 110; A water immersion chamber 120 formed in a closed structure inside the main body 110 and having a plurality of upper and lower portions; An inlet 103 formed in a lower portion of the lowermost water immersion chamber 120c of the plurality of water immersion chambers 120; A connection passage (102) connecting the plurality of immersion chambers (120); And an outflow port (101) formed in the upper part of the uppermost water immersion chamber (120a) of the plurality of water immersion chambers (120), whereby the lateral flow during sinking of the offshore structure And to adjust the sinking speed.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a submerged offshore structure having a plurality of submergence chambers,

Field of the Invention [0002] The present invention relates to a civil engineering field, and more particularly, to a method of constructing an offshore structure.

It is very difficult to construct an offshore structure on the sea floor such as the foundation of bridge bridges and the foundation of offshore wind power generation structures because it is very difficult to construct by concrete casting in the field. , Sinking (submerging) method which is installed on the sea floor is commonly used.

1 and 2 are process drawings for explaining a conventional method of constructing a submerged offshore structure.

The conventional submerged offshore structure 10 generally has a structure in which an upper portion is opened and a receiving space 11 for seawater is formed therein and seawater flows into the receiving space 11 to sink the offshore structure 10 .

However, when such a conventional method is applied, since the seawater does not constantly flow into the storage space 11 during flooding, the offshore structure 10 sinks while flowing left and right, and there is no way to control the sinking speed. There is a problem that the offshore structure 10 collides with the ocean floor or the installed offshore structure to cause damage.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a submerged offshore structure and a method of constructing the submerged offshore structure, which can prevent a lateral flow when a marine structure sinks and control a sinking speed .

In order to solve the above-described problems, the present invention provides a display apparatus including a main body 110; A water immersion chamber 120 formed in a closed structure inside the body 110 and having a plurality of upper and lower portions; An inlet 103 formed in a lower portion of the lowermost water immersion chamber 120c of the plurality of water immersion chambers 120; A connection passage (102) connecting the plurality of immersion chambers (120); And an outflow port (101) formed on an upper part of the uppermost water immersion chamber (120a) of the plurality of water immersion chambers (120).

The width of the water immersion chamber 120 is preferably larger than the width of the inlet 103, the connection passage 102 and the outlet 101.

The width of the water immersion chamber 120 is preferably larger than the height.

The present invention relates to a method of constructing the sinking offshore structure (100), comprising the steps of lifting the sinking offshore structure (100) to a position where the sinking structure is installed, with the inlet (103) closed; And a sinking step of sinking the sinking offshore structure (100) by opening the inlet (103) to allow water to flow into the water immersion chamber (120). Together.

The sinking step may include a sinking rate control step of controlling the sinking rate of the sinking-type offshore structure 100 by repeating the closing and opening of the outflow port 101 so that the air in the sinking room 120 is slowly discharged; .

In the sinking step, the volume of the air in the water immersion chamber 120 is slowly decreased by reversely flowing air through the outlet 101 to adjust the sinking speed of the sinking water structure 100 The method further comprising:

The present invention proposes a submerged offshore structure and its construction method that can prevent lateral flow when sinking an offshore structure and control the sinking speed.

1 and 2 are process drawings for explaining a conventional method of constructing a submerged offshore structure.
3 shows the embodiment of the present invention,
3 is a cross-sectional view of one embodiment of a sinking offshore structure.
4 and 5 are process drawings of a first embodiment of a method of constructing a submerged offshore structure.
6 is a process diagram of a second embodiment of a method of constructing a submerged offshore structure.

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

3, the submerged offshore structure 100 according to the present invention basically comprises a main body 110; A water immersion chamber 120 formed in a closed structure inside the main body 110 and having a plurality of upper and lower portions; An inlet 103 formed in a lower portion of the lowermost water immersion chamber 120c of the plurality of water immersion chambers 120; A connection passage (102) connecting the plurality of immersion chambers (120); And an outlet (101) formed in an upper part of the uppermost water immersion chamber (120a) among the plurality of water immersion chambers (120).

This allows the submerged offshore structure 100 to be lifted to the installation position of the ocean while the inlet 103 is closed and water is introduced into the submergence chamber 120 by opening the inlet 103, (100) is sunk.

When this configuration is adopted, water slowly flows from the lowermost water immersion chamber 120c among the plurality of water immersion chambers 120. At this point, water is present in the lower part of the ocean structure 100, So that the buoyancy structure is stabilized and the lateral flow of the offshore structure 100 does not occur.

Since the submergence of the water from the lowermost water immersion chamber 120c to the uppermost water immersion chamber 120a through the connection passage 102 is completed, It can be prevented from colliding with the installed offshore structure at a high speed to be damaged.

Further, when the offshore structure 100 is to be dismantled, the offshore structure 100 may be floated by injecting air through the outflow port 101, so that the disassembly operation is facilitated.

It is preferable that the width of the water immersion chamber 120 is formed larger than the width of the inlet 103, the connecting passage 102 and the outlet 101.

That is, it is necessary that the width of the inlet port 103, the connecting passage 102 and the outlet port 101 is formed to be considerably smaller than the width of the water immersion chamber 120.

In addition, it is preferable that the width of the water immersion chamber 120 is made larger than the height (flat structure) in terms of stably and slowly bringing water upward.

The sinking speed of an offshore structure 100 having such a structure can be controlled by the following method.

First, a method of regulating the sinking speed of the sinking-type offshore structure 100 by repeating the closing and opening of the outflow opening 101 and allowing the air in the water immersion chamber 120 to be slowly discharged.

That is, the discharge speed of the air through the outlet 101 is proportional to the inflow speed of the seawater through the inlet 103, so that the inflow speed of the seawater can be adjusted by adjusting the discharge speed of the air.

Secondly, it is possible to regulate the sinking speed of the sinking-type offshore structure 100 by allowing air to flow in through the outflow port 101 to slowly decrease the volume of the air in the water immersion chamber 120.

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-altitude water, the air is flowed backward through the outlet 101 by the high-pressure air injector 200 or the like as in the present embodiment, (FIG. 6), by slowing down the rate of sinking despite the high degree of severity.

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: sinking type offshore structure 101: outlet
102: connecting passage 103: inlet
110: main body 120: water immersion chamber

Claims (6)

A method of constructing a sinking offshore structure (100)
A body 110;
A water immersion chamber 120 formed in a closed structure inside the body 110 and having a plurality of upper and lower portions;
An inlet 103 formed in a lower portion of the lowermost water immersion chamber 120c of the plurality of water immersion chambers 120;
A connection passage (102) connecting the plurality of immersion chambers (120); And
And an outflow port (101) formed in an upper part of the uppermost water immersion chamber (120a) among the plurality of water immersion chambers (120). The immersion type offshore structure (100)
A salvage step of lifting the sinking offshore structure (100) to an installation position of the ocean while the inlet (103) is closed;
A sinking step of sinking the sinking offshore structure (100) by opening the inlet (103) to allow water to flow into the water immersion chamber (120); And
And disassembling the submerged offshore structure (100)
The width of the water immersion chamber 120 is formed to be larger than the width of the inlet 103, the connection passage 102 and the outlet 101,
The width of the water immersion chamber 120 is larger than the height of the water immersion chamber 120,
The inlet (103), the outlet (101), and the connecting passage (102) are formed along the central axis of the main body (110)
The sinking step
And controlling the sinking speed of the submerging offshore structure (100) by repeating the closing and opening of the outlet (101) so that the air in the submergence chamber (120) is slowly discharged,
The sinking step
Further comprising the step of regulating the sinking rate of the submerging offshore structure (100) by allowing the air to flow back through the outlet (101) to reduce the volume of air in the submergence chamber (120)
The method of claim 1,
And injecting air back through the outlet (101) to float the sinking offshore structure (100).
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