KR100938168B1 - Method for constructing semi-submersible structures on the sea and the semi-submersible structures constructed by the method - Google Patents

Abstract

The present invention relates to a marine drying method that can be dried directly on the sea without the need to launch a semi-submersible marine structure, such as a drilling ship in the sea after drying on the land, according to the present invention, the lower structure 11, and A semi-submersible offshore structure comprising a plurality of main pillars 12 and 13 standing on a lower structure and a top plate 20 supported by the main pillars is a method of drying at sea, which forms part of the top plate. Installing a top plate portion structure (21, 22) on each said main column; Tilting the main column to move the upper plate some structures toward the upper plate intermediate structure by sandwiching the upper plate intermediate structure 23 between the upper plate some structures installed on each of the main pillars and simultaneously deforming the lower structure Wow; Assembling the adjacent upper plate partial structure and the upper plate intermediate structure to each other to form the upper plate; There is provided a marine drying method of the semi-submersible marine structure, and dried semi-submersible marine structure comprising a.

Semi-submersible offshore structures, offshore construction methods, substructures, pontoons, columns, tops

Description

METHOD FOR CONSTRUCTING SEMI-SUBMERSIBLE STRUCTURES ON THE SEA AND THE SEMI-SUBMERSIBLE STRUCTURES CONSTRUCTED BY THE METHOD}

The present invention relates to a method for drying a semi-submersible offshore structure and thus a semi-submersible offshore structure, and more particularly, to dry a semi-submersible offshore structure such as a drilling ship on land and without launching it on the sea. The present invention relates to an offshore drying method which can be directly dried in a semi-submersible offshore structure.

In the construction of small and medium sized ships, ships are usually constructed by lifting a ship with a crane or the like after drying the ship near the inner wall of the shipyard or launching the ship from the stern or parallel using a launching platform consisting of a fixed rod and a runway. It was used to launch in such a way as to slide in the direction. In the case of large ships, the floating ship was used to build a ship by drawing water into the dock after building the ship in a dry dock.

However, as ships become larger in size, there are cases in which ships larger than the size of docks have to be built, and in addition, more ships need to be built at the same time than the number of docks provided in shipyards. In shipyards, the cost and time required to expand the docks is not only expensive and time-consuming, but also the ships cannot be built during that period, so the expansion of the docks is a matter of careful decision.

Accordingly, instead of using a dry dock, a method of building a ship directly on the sea using various auxiliary structures or assembling small parts manufactured on land has been recently proposed.

The method of building or assembling a ship at sea has the advantage that initial investment and maintenance cost can be reduced by not using a dock, while the construction cost is increased because a huge amount of auxiliary structures are essential. Have

Particularly in the case of a large floating structure, for example, a drilling vessel, it is a time-consuming and laborious task that, despite its enormous size, is dried on the ground and then moved to the sea using a bogie or the like. Had to be carried out.

On the other hand, in the case of a fixed structure that is fixed to a certain position on the sea by piles piled on the sea floor, the assembly is performed on the sea due to its characteristics, for the assembly of the sea by guides, bumpers, stabbing cones, waves Auxiliary structures such as fixing means for preventing flow are used. Such auxiliary structures are used in large quantities as much as 20% of the weight of the fixed structure to be installed, there is a problem that takes a considerable cost and time for the design, fabrication, installation and removal of the auxiliary structure.

The present invention for solving the above problems, the use of docking by utilizing the temperature change by the temperature and solar heat, so that the initial investment cost and maintenance cost can be reduced by not using the dock and minimize the use of auxiliary structures An object of the present invention is to provide a sea-drying method for drying a semi-submersible marine structure such as the sea directly and a semi-submersible marine structure thus dried.

According to an aspect of the present invention for achieving the above object, a semi-submersible marine structure comprising a lower structure, a plurality of main pillars erected on the lower structure, and a top plate supported by the main pillars at sea CLAIMS 1. A method of drying, comprising: installing a portion of a top plate constituting part of the top plate on each of the main pillars; Tilting the main column to move the upper plate some structures toward the upper plate intermediate structure by sandwiching the upper plate intermediate structure between the upper plate partial structures installed on each of the main pillars and simultaneously deforming the lower structure; Assembling the adjacent upper plate partial structure and the upper plate intermediate structure to each other to form the upper plate; There is provided a marine drying method of a semi-submersible marine structure comprising a.

Prior to the deforming of the substructure, it is preferable to further include the step of setting up one or more auxiliary pillars on the substructure so that the substructure can be deformed using the weight of the upper intermediate structure.

The height of the secondary pillar is preferably determined such that when the upper intermediate structure is supported on the secondary pillar, the upper intermediate structure is horizontal with the upper structure of some of the upper structures supported on the main pillar.

Preferably, the distance between some of the upper structures is set to be longer than the length of the upper intermediate structure before the lower structure is deformed, and less than or equal to the length of the upper intermediate structure after the lower structure is deformed.

Prior to the deforming of the substructure, it is preferable to further include filling the inside of the substructure in order to adjust the deformation amount of the substructure by changing the temperature of the substructure.

The water filled in the lower structure is not used in a low temperature winter, it is preferable that the amount of water used increases as the temperature rises.

According to still another aspect of the present invention, there is provided a semi-submersible marine structure, which is dried at sea by the above-mentioned method of marine drying of the semi-submersible marine structure.

According to the present invention as described above, by using the dock to reduce the initial investment and maintenance costs, and at the same time to minimize the use of auxiliary structures, by utilizing the temperature change by the temperature and solar heat such as drilling vessels There may be provided an offshore drying method which allows the submerged offshore structure to be directly dried at sea, and thus a semi-submersible offshore structure.

Hereinafter, a method of marine drying of a semi-submersible marine structure according to a preferred embodiment of the present invention will be described in detail with reference to the drawings.

1 and 2 are views for explaining the sea-drying method of the semi-submersible offshore structure according to the present invention, Figure 1 is shown immediately before the assembly of the top plate, Figure 2 is shown after the assembly of the top plate is shown It is.

The semi-submersible offshore structure shown in FIG. 1 and FIG. 2 is a type of floating structure, for example, a drilling vessel for drilling oil or natural gas. The illustrated semi-submersible offshore structure, that is, the drilling vessel, has a substructure pontoon 11, a plurality of pillars 12 and 13 standing on the pontoon 11, and a plurality of pillars 12 and 13. It consists of a top plate 20 which is supported by) and a structure (not shown) installed on the top plate 20.

In this specification, the floating structure means any structure that can float on the sea regardless of whether it can sail by magnetic force.

In addition, the semi-submersible offshore structure is a pontoon 11, which is a substructure when the ship is moving in the sea, as in the above-described drilling ship, slightly submerged in the sea surface, but when drilling at a predetermined position, etc. In addition to (11), it means a marine structure that is operated under the sea level to the lower part of the plurality of pillars 12 and 13.

In the marine drying method of the present invention, in detail, after assembling the pontoon 11 and the pillars 12 and 13 of the semi-submersible marine structure described above, during the process of assembling the upper plate on the pillars 12 and 13. It applies. That is, the present invention is not limited by the manufacturing method of the pontoon 11, the manufacturing method of the pillars 12 and 13, or the method of assembling the manufactured pontoon 11 and the pillars 12 and 13 with each other.

As shown in FIG. 1, on each of the pillars 12 and 13 installed on the pontoon 11, some structures constituting the upper plate 20 are installed. 1 and 2, only one pontoon 11 and a pair of pillars 12 and 13 installed on the pontoon 11 are included in the semi-submersible marine structure having two pontoons and four pillars. Is shown.

According to the present invention, the front pillars 12 and the rear pillars 13 are installed on the front and rear sides on the pontoon 11, the front top plate 21 is installed on the front pillars 12, and the rear pillars 13 The rear top plate 22 is installed on the back side. The intermediate top plate 23 is coupled between the front top plate 21 and the rear top plate 22 to complete the entire top plate 20.

At the time of installation of the intermediate top plate 23, it is preferable that at least one auxiliary pillar 14 capable of temporarily supporting the intermediate top plate 23 is installed on the pontoon 11. The height of this auxiliary pillar 14 is set longer than the front pillar 12 and the rear pillar 13 by the length indicated by d1 in FIG. 1 (about 10 to 15 mm). Although not shown in FIG. 1, the intermediate top plate 23 may be moved while being suspended by a crane or the like and positioned on the auxiliary pillar 14.

The height difference d1 between the front and rear pillars 12 and 13 and the secondary pillar 14 is an intermediate that occurs when the intermediate top plate 23 is supported on the secondary pillar 14 as shown in FIG. 2. This is to compensate for the deformation of the auxiliary pillar 14 and the pontoon 11 by the weight of the upper plate (23).

In addition, between the middle top plate 23 and the front top plate 21 before being installed, and between the middle top plate 23 and the rear top plate 22 before being installed, the lengths indicated by d2 and d3 in FIG. About 10 mm).

The gaps d2 and d3 between the front and rear top plates 21 and 22 and the middle top plate 23 are used to separate the middle top plate 23 between the front and rear top plates 21 and 22 when the middle top plate 23 is installed. The minimum spacing required for embedding. Preferably, the intervals d2 and d3 have the same value.

As described above, when the intermediate top plate 23 is supported on the auxiliary pillar 14, the shape of the pontoon 11 is deformed (see FIG. 2) by the weight of the intermediate top plate 23. Due to the deformation, the front and rear pillars 12, 13 are inclined in a direction in which their upper ends approach each other.

The gaps d2 and d3 are supported by the front and rear pillars 12 and 13 when the front and rear pillars 12 and 13 are inclined toward each other due to the deformation of the pontoon 11. And the rear top plates 21 and 22 are preferably determined to be in close contact with the middle top plate 23. That is, the distance between the front and rear top plates 21 and 22 after the pontoon 11 is deformed is preferably set to be equal to or smaller than the length of the intermediate top plate 23.

In order to assemble the entire top plate 20 by connecting the front and rear top plates 21 and 22 and the middle top plate 23 in close contact with each other by using the deformation caused by the self-weight, various variables, that is, the deformation by the own weight In addition, it is necessary to determine the height difference d1 and the intervals d2 and d3 in consideration of variables such as thermal deformation due to welding and expansion or contraction according to temperature.

According to the present invention, by utilizing the expansion and contraction of the top plate 20 and the pontoon 11 according to the temperature and solar heat, that is, the temperature of these variables, the semi-submersible marine structures such as drilling ships are minimized while minimizing the use of auxiliary structures. Allow to dry directly at. That is, when the middle top plate 23 is supported on the auxiliary pillar 14, the front and rear top plate (when designing in consideration of the deformation amount of the pontoon 11 and the degree of expansion or contraction of each top plate 21, 22, 23) The distances d2 and d3 between 21 and 22 and the intermediate top plate 23 are determined.

Since the semi-submersible offshore structure is manufactured outside, not indoors, each top plate, that is, the front and rear top plates 21 and 22 and the middle top plate 23 are affected by the weather. The temperature of each of the top plates 21, 22, and 23 varies according to weather, temperature, and the degree of irradiation of sunlight, and as the temperature increases, the size of each top plate is finely increased by thermal expansion of the members forming the top plate.

In addition, the pontoon 11 also changes in size and deformation amount depending on temperature. According to the present invention, the amount of deformation according to the temperature is adjusted by filling water into the internal space of the pontoon 11. The amount of water to be filled in the pontoon (11) depends on the season and the temperature, the largest amount of water in the summer (about 2000ton maximum) is used in the winter does not fill the water. In other words, the amount of water filled in the pontoon 11 is approximately 0 to 2000 tons.

If the temperature is constant, the larger the amount of water to be filled in the pontoon 11, the greater the inclination of the front and rear pillars 12 and 13, and the smaller the amount of the water to be filled, the smaller the inclination. This means that as the water is filled in the pontoon 11, the pontoon 11 sinks below the sea level, and the volume of the pontoon 11 increases below the sea level, thereby decreasing the portion affected by sunlight and the like. This is because the pontoon 11 is cooled by external water and thus the temperature of the pontoon itself does not increase much compared to when the water is not filled.

Therefore, in the winter when the structure is already contracted as a whole, when the water is filled in the pontoon 11, the distance between the front and rear top plates 21 and 22 is too close, and there is a fear that the assembly of the intermediate top plate 23 may fail. Therefore, it is preferable not to use water.

On the contrary, in the summer when the structure is fully expanded, when the water is not filled in the pontoon 11, the gap between the front and rear top plates 21 and 22 becomes too far, so that welding work is difficult during assembly of the middle top plate 23. In addition, it is preferable to use a lot of water because a large amount of welding material may be required.

When the intermediate top plate 23 is completely assembled with the front and rear top plates 21, 22, the auxiliary pillar 14 is removed. The removed secondary pillar 14 can later be recycled upon drying of another offshore structure.

As described above, according to the present invention, the height difference d1 between the front and rear pillars 12 and 13 and the auxiliary pillars 14, and the front and rear top plates according to temperature conditions such as heating by sunlight or weather. By setting the spacings d2 and d3 between the 21 and 22 and the intermediate top plate 23, it is possible to dry semi-submersible offshore structures, such as drilling ships, directly at sea while minimizing the use of auxiliary structures.

As described above, the marine drying method of the semi-submersible marine structure according to the present invention has been described with reference to the illustrated drawings, but the present invention is not limited to the embodiments and drawings described above, and is seen within the claims. Various modifications and variations can be made by those skilled in the art to which the invention pertains.

1 is a view for explaining the sea-drying method of the semi-submersible marine structure according to the present invention, a view showing a state immediately before assembly of the top plate,

2 is a view for explaining the sea-drying method of the semi-submersible marine structure according to the present invention, it is a view showing a state after assembling the top plate.

<Description of the reference numerals for the main parts of the drawings>

11: pontoon 12: front pillar

13: rear pillar 14: auxiliary pillar

20: top plate 21: front top plate

22: rear top plate 23: middle top plate

Claims (7)

A method for drying a semi-submersible offshore structure comprising a lower structure, a plurality of main pillars erected on the lower structure, and a top plate supported by the main pillars, Installing a portion of the upper plate, which forms part of the upper plate, on each of the main pillars; Tilting the main column to move the upper plate some structures toward the upper plate intermediate structure by sandwiching the upper plate intermediate structure between the upper plate partial structures installed on each of the main pillars and simultaneously deforming the lower structure; Assembling the adjacent upper plate partial structure and the upper plate intermediate structure to each other to form the upper plate; Including; Prior to the deforming of the substructure, semi-submersible, characterized in that the step of setting up one or more auxiliary pillars on the substructure to deform the substructure using the weight of the upper intermediate structure Method of offshore construction of offshore structures. delete The method according to claim 1, The height of the auxiliary pillar is semi-submersible, characterized in that when the upper plate intermediate structure is supported on the auxiliary pillar, the upper plate intermediate structure is set to be parallel to the structure of some of the upper plate supported on the main column Method of offshore construction of offshore structures. The method according to claim 1, The distance between some of the upper plate structure is set to be longer than the length of the upper plate intermediate structure before the lower structure is deformed, and less than or equal to the length of the upper plate intermediate structure after the lower structure is deformed Method of offshore construction of submersible offshore structures. The method according to claim 1, Before the deforming of the substructure, semi-submersible, characterized in that for filling the inside of the substructure in order to adjust the deformation amount of the substructure by changing the temperature of the substructure. Method of offshore construction of offshore structures. The method according to claim 5, The water filled in the lower structure is not used in the winter, the temperature is low, the water drying method of the semi-submersible marine structure, characterized in that the amount of water used increases as the temperature increases. A semi-submersible marine structure, which is dried at sea by a marine drying method of the semi-submersible marine structure according to claim 1.

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