KR101938169B1 - Marine nuclear plant using gbs hull and its installing method - Google Patents

Abstract

A marine nuclear power plant and installation method using GBS hull are provided. A marine nuclear power plant using the GBS hull of the present invention includes a plurality of plant modules on which facilities including a power generation facility are mounted; (GBS) hull unit in which a plurality of plant modules are installed, and the GBS hull unit includes a plurality of GBS hulls which are moved to sea and mutually coupled at sea and installed on the seabed.

Description

{MARINE NUCLEAR PLANT USING GBS HULL AND ITS INSTALLING METHOD}

The present invention relates to a marine nuclear power plant and a method of installing the marine nuclear power plant using the GBS hull, and more particularly, to a marine nuclear power plant using a GBS hull capable of installing a marine nuclear power plant on a land- And an installation method.

In recent years, studies are underway to increase the stability of nuclear power plants and to install nuclear power plants in the ocean to overcome the limitations of installation sites.

The technology using GBS (Gravity Based Structure) to install a large plant on the sea is a technology that is already commercialized, and it is a technology that moves a large concrete structure to the sea and then sinks it into gravity.

There are technological and economic limitations in installing nuclear power plants in the ocean using conventional GBS. In other words, unlike other structures, nuclear power plants are too heavy and too large to be moved and installed using GBS.

In order to overcome this problem, it is possible to consider a modular method in which GBS is divided into several sections and then moved to the ocean. However, in the case of nuclear power plants, there are many interfaces such as piping, materials, and electricity between modular units. In order to prevent accidents such as radioactive leaks, strict interface conditions must be met.

Therefore, in order to satisfy the strict installation condition of the interface, precision is required, but it is difficult to connect the interface in the sea, and it is likely to be easily broken in the piping.

Korean Patent Registration No. 10-0231802 (Daewoo Corporation) 1999. 09. 01

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a marine nuclear power plant and a method of installing a nuclear power plant using a GBS hull capable of conveniently and safely installing a nuclear power plant at sea.

According to an aspect of the present invention, there is provided a plant module including: a plurality of plant modules on which a facility including a power generation facility is mounted; And a GBS (HVS) hull unit in which the plurality of plant modules are installed, wherein the GBS hull unit comprises a plurality of GBS hulls which are moved in the sea and mutually coupled at sea and installed on the seabed, A plant may be provided.

The plant module may be a floating type made of a steel material or a GBS type made of a concrete material.

The plurality of plant modules may be spaced apart from each other on the GBS hull.

The GBS hull may be a GBS barge.

And a drain pump installed in the GBS hull.

According to another embodiment of the present invention, there is provided a method of installing a marine nuclear power plant, comprising: moving a plurality of GBS hulls to a maritime area where the marine nuclear power plant is to be installed and landing on the seabed; Moving a plurality of plant modules on which facilities including a power generating facility are mounted into the plurality of GBS hulls; Coupling the plurality of GBS hulls to each other; And discharging the seawater introduced into the GBS hull, and landing the plurality of plant modules on the inner bottom of the GBS hull connected to each other. BRIEF DESCRIPTION OF THE DRAWINGS

The plurality of plant modules can be landed so as to be spaced apart from each other when landed on the GBS hull.

And interfacing the interfaces of the plurality of plant modules landed on the inner bottom of the interlinked GBS hull.

The plant module may be a floating type made of a steel material or a GBS type made of a concrete material.

The embodiments of the present invention can stably and conveniently work the GBS hull because the power plant can be installed on the sea under the same conditions as in the land, and the power plant is installed on the seabed using the GBS hull, There is no need for a separate weighting facility for sinking, or the weight of the power plant can be reduced by minimizing the weight.

1 is a perspective view schematically showing a marine nuclear power plant using a GBS hull according to an embodiment of the present invention.
FIG. 2 is a schematic view illustrating a process of installing a marine nuclear power plant using the GBS hull shown in FIG. 1. FIG.
3 is a flowchart illustrating a method of installing a marine nuclear power plant using a GBS hull according to another embodiment of the present invention.

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the accompanying drawings which illustrate preferred embodiments of the present invention.

Hereinafter, the present invention will be described in detail with reference to the preferred embodiments of the present invention with reference to the accompanying drawings. Like reference symbols in the drawings denote like elements.

FIG. 1 is a perspective view schematically showing a marine nuclear power plant using a GBS hull according to an embodiment of the present invention. FIG. 2 is a schematic view illustrating a process of installing a marine nuclear power plant using the GBS hull shown in FIG. Fig.

As shown in these figures, the marine nuclear power plant 1 using the GBS hull according to the present embodiment includes a plurality of plant modules 10 on which facilities including power generation facilities are mounted, a plurality of plant modules 10, And a GBS (Gravity Based Structure)

A plurality of plant modules 10 are provided and are moved to the sea and landed on a GBS hull 21 to be described later. Each of the plant modules 10 is connected to the reactor building 11 and the reactor building 11 A turbine building (not shown) including a complex building (not shown) and a turbine electrically or mechanically connected to a reactor (not shown) may be installed.

Also, the plant module 10 may be made of a concrete material capable of shielding radiation that may leak from the reactor building 11. [

In this embodiment, the plant module 10 includes a plurality of interfaces (not shown) capable of interconnecting the respective plant modules 10. In the present embodiment, the interface may be an electric wire pipe for electrically connecting the reactor building 11 and a complex building (not shown), or a cooling water pipe which is a passage of cooling water for cooling a reactor (not shown).

Also, in this embodiment, the plant module 10 may be provided in a floating type or GBS type. When the plant module 10 is of a floating type, a ballast structure may be provided inside the plant module 10 to float the plant module 10 at sea.

When the plant module 10 is a floating type, it can be made of a metal material such as steel. When the plant module 10 is made of a concrete material, it can be made of a concrete material.

In the present embodiment, the plant module 10 is installed on the seabed by the GBS hull 21, which is moved after being moved to the GBS hull 21, which will be described later, so that the plant module 10, It is not necessary to provide a separate weight facility in the plant module 10, which makes it possible to manufacture the plant module 10 with a reduced weight.

The GBS hull unit 20 provides a place where the plant module 10 can be installed. As shown in Fig. 2, a plurality of GBS hulls 21, which are moved in the sea and are coupled to each other and installed on the sea floor, .

In this embodiment, the GBS hull 21 can be made of a concrete type GBS barge type. GBS pants are pants that can be transported to the ocean, like normal pants, and can sink into their load in the area of the structure. In other words, the inside of the pants has a space that can be filled with water such as water or sand, and a ballast structure that sinks into the seabed by loads such as water or sand filled in the space.

In this embodiment, sea water introduced into the GBS hull 21 mutually combined in the sea is pumped to the outside of the GBS hull 21, and a plurality of plant modules 10) are naturally landed on the inner bottom portion of the GBS hull 21 to which they are coupled.

That is, in this embodiment, before the seawater introduced into the GBS hull 21 by the drain pump is pumped to the outside of the GBS hull 21, the plant module 10 is suspended inside the GBS hull 21, .

In this state, when the seawater inside the GBS hull 21 mutually combined is discharged to the outside of the GBS hull 21 connected to each other by the drain pump, the suspended plant module 10 is connected to the GBS hull 21, As shown in Fig. In this state, there is no seawater in the GBS hull 21, which is mutually combined, and the condition is the same as that in the land, so that the interface of the plant module 10 can be conveniently and stably operated.

3 is a flowchart illustrating a method of installing a marine nuclear power plant using a GBS hull according to another embodiment of the present invention.

A method of installing a marine nuclear power plant using a GBS hull according to the present embodiment includes a step (S100) of moving a plurality of GBS hulls 21 to a sea area where a marine nuclear power plant is to be installed and landing on a seabed, A step S200 of moving a plurality of plant modules 10 on which facilities including a power generation facility are mounted to the GBS hull 21 and a step S200 of moving a plurality of GBS hulls 21 to which the plurality of plant modules 10 are moved (Step S300); and discharging the seawater introduced into the GBS hull 21, which is coupled to each other, to land the plurality of plant modules 10 on the inner bottom of the GBS hull 21 S400) and interconnection of interfaces of a plurality of plant modules 10 landed on the inner bottom of the GBS hull 21 mutually coupled (S500).

A step S100 of moving a plurality of GBS hulls 21 to the sea area where the offshore nuclear power plant is to be installed and landing on the seabed is performed.

In this embodiment, a plurality of GBS hulls 21 can be sequentially landed on the seabed. That is, after one of the plurality of GBS ships 21 is first landed on the seabed, the plant module 10 is moved to the landed GBS ship 21, and the other GBS ship 21 is landed on the landed GBS It is possible to land close to the hull 21.

Next, the plant module 10 is moved to the upper sea level of the GBS hull 21 landed on the seabed and then is submerged in the GBS hull 21 (S200). In the present embodiment, when the plant module 10 is made of a concrete material, the plant module 10 can be moved to the upper sea level of the GBS hull 21 on a ship such as a barge line (not shown) And can be towed and moved to the ship.

The plant module 10, which is moved to the sea surface where the GBS hull 21 sinks, is submerged in the GBS hull 21 due to its own weight when it is made of concrete, and when it is made of steel, It can be submerged by filling with loads such as water or sand.

 Next, a plurality of GBS hulls 21 accommodating the plant module 10 are coupled to each other (S300).

Since the GBS hull 21 can be made of a concrete material in the present embodiment, the coupling of the plurality of GBS hulls 21 can be accomplished by a sealing member such as a rubber gasket (not shown) for waterproofing between the GBS hulls 21, And then the GBS hulls 21 can be joined together by fastening members (not shown). On the other hand, the movement of the GBS hull 21 can be moved by using a floating crane.

After the connection of the plurality of GBS hulls 21 is completed, the seawater introduced into the GBS hull 21 coupled to the GBS hull 21 is discharged using a drain pump provided in the GBS hull 21, So that they naturally land on the inner bottom of the combined GBS hull 21.

Finally, a step of interconnecting the interfaces of the landed plant modules 10 to the inner bottom of the mutually coupled GBS hull 21 is performed.

In this embodiment, since the operation of connecting the interface of the plant module 10 can be performed in the interior of the GBS hull 21 connected to each other, that is, in the environment like land without water, there is an advantage in that the interface connection operation is convenient and stable.

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. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

1: Marine nuclear power plant using GBS hull
10: Plant Module 11: Reactor Building
20: GBS Hull Unit 21: GBS Hull

Claims (9)

A plurality of plant modules on which facilities including power generation facilities are mounted; And
And a GBS (Gravity Based Structure) hull unit on which the plurality of plant modules are installed,
The GBS hull unit includes a plurality of GBS hulls that are moved in the sea and mutually coupled at sea and installed on the seabed,
The plurality of GBS hulls are each formed with a part of a partition wall surrounding a space in which a plant module is installed,
And the mutual coupling of the plurality of GBS hulls is such that the surfaces of the plurality of GBS hulls on which no partitions are formed are brought into contact with each other and joined together. The method according to claim 1,
Wherein the plant module is a floating type made of a steel material or a GBS type made of a concrete material. The method according to claim 1,
Wherein the plurality of plant modules are spaced apart from each other in the GBS hull. The method according to claim 1,
Wherein the GBS hull is a GBS barge. The method according to claim 1,
Further comprising a drain pump installed in the GBS hull to discharge seawater introduced into a space in which the plurality of GBS hulls are coupled to each other in the installation space of the plurality of plant modules. In the installation method of offshore nuclear power plant,
Moving a plurality of GBS hulls to the sea area where the offshore nuclear power plant is to be installed and landing on the seabed;
Moving a plurality of plant modules on which facilities including a power generating facility are mounted into the plurality of GBS hulls;
Coupling the plurality of GBS hulls to each other; And
And placing the plurality of plant modules on the inner bottom of the mutually coupled GBS hull by discharging the seawater introduced into the inter-coupled GBS hull,
The plurality of GBS hulls are each formed with a part of a partition wall surrounding a space in which a plant module is installed,
Wherein the plurality of GBS hulls are bonded to each other such that the surfaces of the plurality of GBS hulls on which the partitions are not formed are in contact with each other to engage with each other. The method of claim 6,
And landing the plurality of plant modules so as to be spaced apart from each other when the plurality of plant modules land on the GBS hull. The method of claim 6,
Further comprising interconnecting the interfaces of the plurality of plant modules landed on the inner bottom of the interlinked GBS hull. The method of claim 6,
Wherein the plant module is a floating type made of a steel material or a GBS type made of a concrete material.

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