KR20100135354A - Topside load support structure of floating ocean construct - Google Patents

Abstract

PURPOSE: A top support structure and method of a floating marine structure are provided to effectively prevent the sagging of an upper wall and the deformation or breakage of an insulator for a storage tank. CONSTITUTION: A top support structure of a floating marine structure comprises one or more decks(32) in which facilities are installed as separate modules, a reinforcing member which is installed under an upper wall(14) of a hull(10) and supports the load, and a plurality of stools(30) which are installed between the decks and the upper wall and supports the decks in order to transmit the upper load to the upper wall. The reinforcing member is installed on chambers(22,24) formed at an angle on the top of a storage tank(20) inside the hull.

Description

Upper support structure of floating offshore structure and its method {TOPSIDE LOAD SUPPORT STRUCTURE OF FLOATING OCEAN CONSTRUCT}

The present invention relates to an upper support structure and a method of the floating marine structure, and more particularly, to an upper support structure and a method of the floating marine structure for effectively supporting the load of the structure installed on top of the floating marine structure It is about.

Floating offshore structures generally refer to structures and ships that are used floating on the sea at which flow occurs.

In the present specification, the floating offshore structure is a concept including both a structure and a vessel used while floating on the sea where a flow occurs while having a storage tank for storing a liquid cargo loaded at a cryogenic state such as LNG. For example, it includes both LNG carriers and LNG Regasification Vessels (RVs) as well as offshore structures such as LNG Floating, Production, Storage and Offloading (FPSO) or LNG Floating Storage and Regasification Units (FSRU).

LNG FPSO is used to produce natural gas by drilling the seabed, liquefy the produced natural gas directly from the sea and store it in the LNG storage tank, and transfer LNG stored in this LNG storage tank to the LNG carrier if necessary. Floating offshore structures. In addition, the LNG FSRU is a floating offshore structure that stores LNG unloaded from an LNG carrier in an LNG storage tank in a sea far from the land, and then vaporizes LNG as needed to supply it to land demand.

In particular, LNG FPSOs are equipped with LNG storage tanks for storing liquefied LNG in the hull, and various facilities are installed at the upper part of the hull to produce natural gas after drilling the seabed. heavy. As heavy facilities are installed on top of the hull of LNG FPSO, it is necessary to reinforce the strength of LNG FPSO's hull so that the hull of LNG FPSO can withstand the heavy load of its upper part. Due to the characteristics of the tank, the LNG storage tank is formed separately from the hull with a heat insulating member interposed between the hull. Therefore, a reinforcing member for reinforcing the hull cannot penetrate the LNG storage tank. There is a limit to deployment.

In the LNG FPSO, the deck covering the upper part of the hull is equipped with various equipments 50 necessary for liquefaction after producing the natural gas by drilling the seabed. These various installations 50 are made in the form of modules, the weight of which can reach thousands of tons.

However, in the related art, as these various facilities are installed, deflection may occur on the deck, and thus, the LNG storage tank 12 may be deformed. In addition, when deformation occurs in the LNG storage tank as described above, the insulation member installed to insulate the LNG storage tank may be deformed or damaged, which may cause LNG to leak from the inside. Therefore, the conventional floating offshore structures, such as LNG FPSO, are required to improve the upper support structure for transmitting the loads of various equipment installed on the hull to the hull, but there are various sizes and shapes of such floating offshore structures. Accordingly, the proper support structure of the upper support structure has not been proposed yet, and continuous research on this is required.

The present invention is to solve the above-described problems of the prior art, to provide an upper support structure that can minimize the deflection of the deck of the floating offshore structure, which is to deform or break the heat insulating member of the storage tank It is to provide an upper support structure and a method of the floating offshore structure to prevent it.

In order to achieve the above object, the upper support structure of the floating offshore structure according to the present invention is provided with two rows of storage tanks inside the hull, and floating offshore having facilities for internal operation on top of the upper wall of the hull. As a structure, the deck for at least one of the facilities for the internal operation is installed separately in a separate module, a reinforcing member is installed in the lower portion of the upper wall to support the load of the upper, between the deck and the upper wall And a plurality of stools for supporting the deck to transfer the load of the upper portion to the upper wall, wherein the stools are installed on an upper side of the upper wall on which the reinforcing member is installed.

In addition, it comprises a chamber formed inclined on the upper portion of the storage tank, the reinforcing member is preferably a deck girder (deck girder) installed to support the upper wall at the top of the chamber. In addition, the stool may be installed on the upper wall such that the central portion coincides with the central portion of the deck girder. In addition, a portion of the stool may be installed to span the upper portion of the upper wall where the deck girder is formed. In addition, the reinforcing member may be a non-tight girder installed in the lower portion of the upper wall to suppress the deflection of the upper wall.

In addition, in order to achieve the above object, the upper supporting method of the floating offshore structure according to the present invention, the storage tank is arranged in two rows in the interior of the hull, floating on the top of the upper wall of the hull having facilities for internal operation In the upper supporting method of the marine structure, the stool is installed to support the upper wall and the deck on which the equipment for the internal operation is installed so as to be located on top of the reinforcing member for supporting the upper wall.

The upper support structure and the method of the floating offshore structure according to the present invention configured as described above allows the deck of the floating offshore structure to be supported on top of the hull by a stool, and the stool installed therefor stably supports the hull. It is possible to effectively prevent the deflection of the upper wall, and to minimize the deflection to prevent the heat insulating member of the storage tank is deformed or broken.

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

1 is a schematic view of a floating offshore structure according to a first embodiment of the present invention. In the present specification, LNG FPSO will be described as an example of a floating offshore structure.

As shown in FIG. 1, the hull 10 of the LNG FPSO 1 is composed of both side walls 11 and 12, a lower wall 13, and an upper wall 14. In the LNG FPSO 1, the LNG storage tanks 20 are arranged in two rows in the width direction in the hull 10.

Specifically, the hull 10 of the LNG FPSO 1 is at an angle of approximately 45 degrees to the upper and lower sides of the LNG storage tank 20 to reduce the sloshing impact force of the LNG, in particular the sloshing impact force in the left and right directions. Inclined upper and lower chambers CHAMPER 22, 24 are formed. In addition, the upper chamber 22 extends in contact with the upper wall 14 to support the upper wall 14 toward the upper side, and a deck girder 15 that functions as a girder is installed.

In addition, the LNG storage tank 20 has an inner wall 18 installed to vertically divide the internal space of the floating offshore structure to support the load of the upper structure while reducing the effect of sloshing of the received LNG. Inner side shell). In addition, a cofferdam may be installed on the inner wall 18.

The LNG storage tank 20 may have two storage spaces without discontinuities in the insulation wall and the sealing wall due to the inner wall 18. That is, instead of separating one storage tank 20 into two spaces, the internal space of the floating offshore structure is divided along the longitudinal direction, and a separate storage tank 20 is installed in each of these spaces. It is a structure. In addition, a trunk portion TRUNK SPACE 19 is provided at an upper portion of the inner wall 18.

A stool 30 is installed on the upper wall 14 of the hull 10, and the stool 30 is decked with various equipment 35 necessary for liquefaction after drilling the seabed to produce natural gas. Support (32). Here, the deck 32 is formed of at least one, and the various equipments 35 installed on the upper portion of the equipment 35 for the internal operation is installed separated into modules.

Here, the stools 30 are installed in rows on the top wall 14 where each deck girder 15 is located. Accordingly, the weight of the deck 32 is transmitted to the deck girder 15 and the main strength members such as the respective chambers 22, the side walls 11 and 12, the inner wall 18, and the like through the stool 30. Can support the weight of the stably, it can block the sag of the upper wall (14).

In addition, the stool 30 may be installed on the upper wall 14 at the point where the center portion coincides with the center portion of the deck girder 15, whereby the load on the top can be installed stably.

On the other hand, the stool 30 does not always have to match the center of the deck girder 15 in the center portion, as shown in Figure 2 the stool 30 can be installed to be biased on the upper wall 14, the deck girder 15 is installed. have.

That is, referring to FIG. 2, which is a schematic view of the floating marine structure according to the second embodiment of the present invention, the center of the stool 30 and the center of the deck girder 15 may not coincide with each other. It is sufficient that only a part of the deck girder 15 is arranged to span.

As such, even if the centers of the stool 30 and the deck girder 15 do not coincide with each other, the weight delivered to the stool 30 may be transferred to the deck girder 15, so that the load of the upper portion may be applied to each chamber ( 22), and may be distributed along major strength members such as sidewall portions 11 and 12, inner wall 18, and the like.

3 is a schematic view of a floating offshore structure according to a third embodiment of the present invention. Referring to FIG. 3, in the present invention, a non-tight girder 16 is installed below the upper wall 14. And the stool 30 which supports the deck 32 is provided in the upper wall 14 in which this non-tight girder 16 was installed.

This non-tight girder 16 is not connected to the storage tank 20, but only to the top wall 14 and a web frame (not shown) for supporting the top wall 14. Therefore, the load of the deck 32 and the installations 35 installed thereon is not directly transmitted to the storage tank 20, and thus does not affect the deformation or damage of the heat insulating member.

Therefore, the load of the upper installations 35 is transmitted to the stool 30 through the deck 32, and the load is transmitted to the non-tight girder 16 and distributed to prevent sagging of the upper wall 14. have. In addition, as the load transmitted to the upper wall 14 by the non-tight girder 16 is distributed, and the deflection of the upper wall 14 is prevented, the direct influence on the storage tank 20 can be reduced, and the inside The possibility of deformation or damage of the insulating member can be minimized.

4 and 5 are schematic views of the floating offshore structure according to the fourth and fifth embodiments of the present invention. As shown in FIGS. 4 and 5, a non-tight girder 16 may be installed below the upper wall 14. In addition, the stool 30 supporting the deck 32 under load is supported to be supported by the deck girder 15 installed on the sidewall portion or the upper portion of the inner wall 18 or to be supported by the relief deck girder 15. Can be.

In addition, a plurality of non-tight girders 16 may be installed in accordance with the length of the upper wall 14, and the like, when a plurality of non-tight girders 16 are installed in this way, the stool (top) of the non-tight girders 16 It is also possible to distribute the load by additionally installing 30).

In this way, the non-tight girders 16 may be properly installed to distribute the load of the deck 32 and the facilities 35 installed thereon, and to reduce the deflection of the upper wall 14. In addition, as the non-tight girders 16 are distributed and installed, the stool 30 supporting the deck 32 can be more flexibly arranged, and the adjustment of the number of the stools 30 to be installed can be made more flexible. Can be.

The present invention is not limited to the above described embodiments, and various modifications and changes can be made by those skilled in the art, which are included in the spirit and scope of the present invention as defined in the appended claims.

1 is a schematic view of a floating offshore structure according to a first embodiment of the present invention;

2 is a schematic view of a floating offshore structure according to a second embodiment of the present invention;

3 is a schematic view of a floating offshore structure according to a third embodiment of the present invention;

4 is a schematic view of a floating offshore structure according to a fourth embodiment of the present invention.

5 is a schematic view of a floating offshore structure according to a fifth embodiment of the present invention;

Claims (6)

A floating marine structure having two storage tanks arranged inside the hull and having facilities for internal operation on an upper portion of the upper wall of the hull, Deck and at least one of the facilities for the internal operation is installed separated into a separate module, A reinforcing member installed at a lower portion of the upper wall to support a load of the upper portion; It is installed between the deck and the upper wall, and includes a plurality of stools for supporting the deck to transfer the load of the upper portion to the upper wall, The stool is an upper support structure of the floating offshore structure, characterized in that installed on the upper side of the upper wall is installed. The method according to claim 1, It comprises a chamber formed inclined on the upper portion of the storage tank, And the reinforcing member is a deck girder installed to support the upper wall at the top of the chamber. The method according to claim 2, The stool is a top support structure of a floating offshore structure, characterized in that the central portion is installed on the upper wall so that the center portion of the deck girder. The method according to claim 2, And a portion of the stool is installed to span the top of the upper wall on which the deck girder is formed. The method according to claim 1, And the reinforcing member is a non-tight girder installed below the upper wall to suppress the deflection of the upper wall. Storage tanks are arranged in two rows inside the hull, the upper support method of the floating offshore structure having facilities for the internal operation on the upper part of the upper wall of the hull, The upper part of the floating offshore structure, characterized in that installed on the top of the reinforcing member for supporting the upper wall a stool (stool) is installed to support the deck and the deck for installation of the internal operation for the upper wall Support method

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