KR20140112198A - Safety System of Ocean System-integrated Modular Advanced Reactor - Google Patents

Abstract

The present invention relates to a safety system on the sea for a small nuclear power plant. According to the present invention, an integrated water tank is capable of storing cooling water in an ocean structure installed on the sea, and the safety system is formed to make a differential head seawater by unifying the exiting of the ocean structure to the outside to flow in an inner space of the integrated water tank. Therefore, the safety system can continuously supply seawater to the integrated tank and use the seawater as a cooling water regardless of the size of the integrated water tank; and the safety system can continuously perform a cooling function using the cooling water during an emergency in the nuclear power plant by the seawater supplied by the differential head to the integrated water tank. At the same time, the cooling water stored in the integrated water tank flows by weight into a plurality of cooling systems, and during an emergency such as a power interruption, the safety system can perform a passive cooling function normally and continuously even without an additional external power supply.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002]

FIELD OF THE INVENTION The present invention relates to a safety system dedicated to a small-sized water source. More particularly, the present invention relates to an integrated water tank which is capable of storing cooling water in a sea structure to be installed on the sea, and seawater existing outside the sea structure is introduced into the internal space of the integrated water tank by the water column difference, It is possible to continuously supply the seawater to the integrated water tank regardless of the size of the integrated water tank and utilize it as the cooling water, so that the cooling function using the cooling water can be continuously performed for a long time when the emergency situation of the nuclear power plant occurs, The cooling water stored in the integrated water tank is supplied to the plurality of cooling systems by its own weight so that the normal and continuous passive cooling function can be performed without any external power supply in case of an emergency such as power cut- Small-circle-only safety system.

In recent years, demand for nuclear power generation has been increasing due to the depletion of fossil fuels. In recent years, in addition to large-capacity power generation nuclear power plants for large-scale power generation, small- and medium-sized nuclear power plants Research and development is being carried out widely.

In Korea, SMART (System-integrated Modular Advanced Reac- tor) reactor has been developed as a compact single-module modular nuclear power plant. These small nuclear power plants can be easily installed both on land and offshore, and can be used to perform seawater desalination .

Generally, a nuclear plant is equipped with a cooling system as a safety device for stopping the reaction by cooling the nuclear plant in an emergency. The cooling system usually consists of a primary cooling system for removing heat from the reactor core and a secondary cooling system for transferring heat from the primary cooling system to the turbine side through the steam generator, And high temperature piping.

In the case of a nuclear power plant with a large capacity, cooling water is supplied to the steam generator inside the reactor through the cooling system to cool the reactor interior space, thereby eliminating residual heat in the reactor interior space. In this case, the cooling water supply is configured in an active manner through separate pump operation. That is, the cooling water is supplied only when external power for operating the pump is supplied. Therefore, if the electric power is cut off in an emergency situation, the pump operation can not be performed and the cooling water supply is not performed, so that a nuclear accident such as an external leakage of radioactivity may occur.

In the case of a small nuclear power plant, the passive type is widely adopted to cool the internal space of the reactor by supplying the cooling water for a predetermined time in a natural circulation manner even when the power supply is cut off. .

Since the components of the cooling system of such a small nuclear power plant operate passively without a separate input signal or an external power source, they are relatively more reliable than the existing active safety systems. However, a certain amount of cooling water There was a problem that it was difficult to inject continuously. In particular, in the case of a small-scale nuclear power plant having a small-sized nuclear power plant installed at sea, there was a problem in that the internal space of the reactor could not be cooled sufficiently because such seawater could not be used despite the presence of seawater.

SUMMARY OF THE INVENTION The present invention has been made to solve the problems of the prior art, and an object of the present invention is to provide an integrated water tank capable of storing cooling water in a sea structure installed on the sea, Is introduced into the internal space of the integrated water tank by means of the water hammer. Therefore, regardless of the size of the integrated water tank, the seawater can be continuously supplied to the integrated water tank and used as the cooling water. And to provide a safety system for a small-sized water source which can be continuously operated for a long time.

Another object of the present invention is to provide a system and a method for controlling a water supply system in which sea water is supplied to the integrated water tank by the water head difference and at the same time the cooling water stored in the integrated water tank flows into a plurality of cooling systems by its own weight, And to provide a safety system for a marine small-sized source capable of performing a normal and continuous passive cooling function.

The present invention relates to a safety system for a maritime nuclear power plant including a marine structure disposed in the sea and having a receiving space formed therein and a nuclear power plant installed inside the marine structure, An integrated water tank formed to store cooling water in an internal space; And a cooling unit for cooling the nuclear power generation facility using the cooling water stored in the integrated water tank, wherein the integrated water tank is formed such that seawater existing outside the sea structure can be introduced into the internal space by the water head difference And a safety system for a small-sized water source.

At this time, the bottom surface of the inner space of the integrated water tank may be disposed at a lower position than the sea surface.

In addition, the integrated water tank may be installed to be connected to the outer space of the sea structure through a separate seawater inflow pipe so that seawater can be introduced.

In addition, a ballast tank may be installed in the sea structure to allow seawater to flow therein, and the integrated water tank may be installed in communication with the ballast tank so that seawater can be introduced from the ballast tank.

Also, the seawater inlet pipe may include a first connection pipe connecting the outer space of the deck structure to the ballast tank so that seawater may flow into the ballast tank; And a second connection pipe connecting the ballast tank and the integrated water tank so that seawater is introduced into the integrated water tank.

The cooling unit may include a first cooling system for removing residual heat from the inside of the reactor of the nuclear power generation facility, a second cooling system for cooling the inside of the containment vessel of the nuclear power generation facility, And a third cooling system for supplying the cooling water to cool the nuclear reactor.

The first cooling system may include a heat exchanger disposed in the integrated water tank such that the internal heat medium is heat-exchanged with the cooling water in the integrated water tank; And a first cooling pipe connecting the heat exchanger and the steam generator so that the heat medium circulates through the heat exchanger and a steam generator disposed inside the reactor, and the heat medium is circulated through the heat exchanger and the steam generator As shown in Fig.

In addition, the second cooling system may include a heat exchanger disposed in the containment vessel inner space such that the heat medium inside thereof exchanges heat with the containment vessel inner space; And a second cooling pipe formed so that cooling water in the integrated water tank is heat-exchanged from the integrated water tank through the heat exchanger and then discharged to the outside of the containment vessel.

At this time, the cooling water may be configured to flow to the heat exchanger along the second cooling pipe by its own weight.

The second cooling pipe may include an inlet cooling pipe connecting the integrated water tank and the heat exchanger; And an exhaust cooling pipe having one end connected to the heat exchanger and the other end exposed to the outside of the containment vessel, and the exhaust cooling pipe may be provided with a filter.

Further, a separate sub discharge pipe may be connected to the discharge cooling pipe so that one end thereof is exposed to the inner space of the containment vessel, and the sub discharge pipe may be provided with an on-off valve.

The third cooling system may include a third cooling pipe connecting the integrated water tank and the reactor cavity so that cooling water in the integrated water tank may be introduced into a reactor cavity of the reactor.

At this time, the cooling water may be configured to flow into the reactor cavity along its third cooling pipe by its own weight.

According to the present invention, one integrated water tank capable of storing cooling water can be formed inside the sea structure installed on the sea, and seawater existing outside the sea structure can be introduced into the internal space of the integrated water tank by the water head difference , Regardless of the size of the integrated water tank, the seawater can be continuously supplied to the integrated water tank and used as the cooling water, so that the cooling function using the cooling water can be continuously performed for a long time when the emergency situation of the nuclear power plant is occurred.

In addition, since the seawater is supplied to the integrated water tank by the water hammer and the cooling water stored in the integrated water tank flows into a plurality of cooling systems by its own weight, it is possible to supply normal and continuous It is possible to perform the passive cooling function.

FIG. 1 is a conceptual diagram schematically showing a configuration of a safety system for marine small-sized water source according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 1 is a conceptual diagram schematically showing a configuration of a safety system for marine small-sized water source according to an embodiment of the present invention.

First, a marine nuclear power plant is a small integrated type module reactor such as SMART, and includes a marine structure 100 installed in the sea and having a receiving space therein, and a nuclear power plant 200 installed inside the marine structure 100 .

The present invention relates to an apparatus for cooling an atomic power generation plant 200 in an emergency situation and includes an integrated water tank 300 disposed inside the water structure 100 and configured to store cooling water R in an internal space, And a cooling unit 500 for cooling the nuclear power generation facility 200 using the cooling water R stored in the cooling unit 300.

The sea structure 100 may be constructed in the form of a suspended body floating on the sea, or may be configured to be fixedly installed on the sea, and a receiving space may be formed in the interior of the sea structure 100 to be shielded from the outside. The nuclear power plant 200 may be configured in a form that is generally applied to a small integrated module nuclear power plant. For example, as shown in FIG. 1, a reactor 210 is disposed inside a containment vessel 220, And the reactor cavity 240 is formed under the first reactor 210. At this time, a steam generator 230 capable of generating steam using internal heat is provided in the reactor 210. Such a configuration is the same as that of a general small-sized module nuclear power plant, and thus a detailed description thereof will be omitted here.

The integrated water tank 300 may be configured in the form of a container capable of storing the cooling water R in the internal space and the cooling unit 500 may be installed in the nuclear power generating facility 200 And may be configured to include at least one of a first cooling system 510, a second cooling system 520, and a third cooling system 530 according to one embodiment of the present invention. have. At this time, the first cooling system 510, the second cooling system 520 and the third cooling system 530 all use the cooling water R stored in one integrated water tank 300, ).

At this time, the integrated water tank 300 is formed so that the seawater R1 existing on the outside of the sea structure 100 can flow into the internal space of the integrated water tank 300 by the water head difference. For this purpose, as shown in FIG. 1, the height H1 of the inner space of the integrated water tank 300 may be arranged to be lower than the height H of the sea surface.

That is, according to an embodiment of the present invention, the safety system for small size water source is configured to have a passive cooling system capable of cooling the nuclear power generation facility 200 without a separate external energy source. The seawater R1 infinitely present in the outside is continuously supplied to the integrated water tank 300 by the water head difference H-H1 without supplying additional external power, and the sea water R1 supplied to the integrated water tank 300 R1) is utilized as cooling water (R) through the cooling unit (500).

The integrated water tank 300 may be installed to be connected to the external space of the sea structure 100 through a seawater inflow pipe 310 so that the seawater R1 may be introduced into the sea water inflow pipe 310, The ballast tank 400 may be connected to the ballast tank 400 so that the ballast tank 400 is connected to the ballast tank 400. The ballast tank 400 may be configured such that the sea water R1 existing outside the sea structure 100 directly flows into the integrated water tank 300, May be configured to receive the seawater (R1) That is, the ballast tank 400 may be provided in the interior of the sea structure 100 to maintain the balance of the sea structure 100. The ballast tank 400 may be configured such that the sea water R1 flows in from the outside of the sea structure 100, And the integrated water tank 300 can be mounted in communication with the ballast tank 400 so that the seawater R 1 can be introduced into the integrated water tank 300 from the ballast tank 400.

The sea water inflow pipe 310 includes a first connection pipe 311 connecting the outer space of the structure 100 to the ballast tank 400 so that the seawater R1 flows into the ballast tank 400, And a second connection pipe 312 connecting the ballast tank 400 and the integrated water tank 300 so that seawater is introduced into the ballast tank 300. It is preferable that the first connection pipe 311 is disposed at a position lower than the sea surface and the second connection pipe 312 is disposed at a lower position than the first connection pipe 311.

The cooling unit 500 cools the nuclear power plant 200 by using the cooling water R stored in one integrated water tank 300 as described above. The cooling system 500 includes a first cooling system 510, The system 520, and the third cooling system 530. [0053]

The first cooling system 510 is configured to remove residual heat inside the reactor 210 of the nuclear power generation facility 200 so that the internal heat medium is heat-exchanged with the cooling water R in the integrated water tank 300 A heat exchanger 511 and a steam generator 230 for circulating and heat-exchanging the heat medium through the heat exchanger 511 and the steam generator 230 disposed inside the reactor 210, And a first cooling pipe (512, 513) for connecting the first cooling pipe The first cooling pipes 512 and 513 include a liquid flow pipe 512 for connecting the heat exchanger 511 and the steam generator 230 so that the liquid heating medium flows from the heat exchanger 511 to the steam generator 230, And a steam flow pipe 513 connecting the steam generator 230 and the heat exchanger 511 so that the heat medium from the generator 230 flows into the heat exchanger 511.

The heat exchanger 511 is disposed at a higher position than the steam generator 230. The heat medium flows from the heat exchanger 511 to the steam generator 230 through its own weight, And then flows into the heat exchanger 511 in a vapor state to be heat-exchanged with the cooling water R. [ Since the circulation process is performed through the natural circulation process by the self weight of the heat medium, the residual heat in the reactor 210 can be removed through circulation of the heat medium to the steam generator 230 without additional external power in case of emergency in the nuclear power plant. have.

The second cooling system 520 is configured to cool the inner space of the containment vessel 220 of the nuclear power generation facility 200 and to cool the inner space of the containment vessel 220 so that the heat medium inside thereof exchanges heat with the inner space of the containment vessel 220 And a second cooling pipe which is formed such that the cooling water in the integrated water tank 300 is heat-exchanged from the integrated water tank 300 through the heat exchanger 521 and then discharged to the outside of the containment vessel 220, (522, 523).

The second cooling pipes 522 and 523 include an inlet cooling pipe 522 connecting the integrated water tank 300 and the heat exchanger 521 so that the cooling water R flows from the integrated water tank 300 to the heat exchanger 521, And a discharge cooling pipe 523 having one end connected to the heat exchanger 521 and the other end exposed to the outside of the containment vessel 220 so as to be heat-exchanged by the heat exchanger 521 and then discharged to the outside . A separate outlet port 301 may be formed in the integrated water tank 300 to connect the inlet cooling pipe 522 and a separate opening and closing valve (not shown) may be provided on the inlet cooling pipe 522 It may be mounted.

At this time, it is preferable that the cooling water R is introduced from the integrated water tank 300 into the heat exchanger 521 along the inflow cooling pipe 522 by its own weight. With this structure, cooling water R is supplied to the internal heat exchanger 521 of the containment vessel 220 and discharged therefrom without any additional external power when an emergency situation occurs in the nuclear power plant, thereby cooling the internal space of the containment vessel 220 Can be performed.

On the other hand, a separate filter 524 can be installed in the discharge cooling pipe 523, so that external radiation leakage or foreign matter leakage that may occur even if it is possible can be prevented once again. A separate sub discharge pipe 525 may be connected to the discharge cooling pipe 523 so that one end of the sub discharge pipe 525 is exposed to the inner space of the containment vessel 220. The sub discharge valve 525 is equipped with an on- . The air inside the containment vessel 220 can be directly discharged to the outside through the sub discharge pipe 525 and the cooling function for the containment vessel 220 can be performed through direct external discharge of the internal air.

The third cooling system 530 is configured to cool the reactor 210 by supplying the cooling water R to the reactor cavity 240 of the nuclear power generating facility 200 so that the cooling water R in the integrated water tank 300 And a third cooling pipe 531 connecting the integrated water tank 300 and the reactor cavity 240 to be introduced into the reactor cavity 240 of the reactor 210. (Not shown) may be mounted on the third cooling pipe 531 and an outlet port 302 may be formed in the integrated water tank 300 so that the third cooling pipe 531 is connected to the third cooling pipe 531 .

At this time, the cooling water (R) is configured to flow to the reactor cavity (240) along the third cooling pipe (531) by its own weight. Accordingly, the third cooling system 530 can also cool the internal space of the reactor 210 by supplying the cooling water R to the reactor cavity 240 without additional external power when an emergency situation occurs in the nuclear plant.

The second cooling system 520 and the third cooling system 530 described above are supplied by using the cooling water R of the integrated water tank 300 in common. The sea water and the water head difference are generated again. Therefore, the sea water R1 is supplied to the integrated water tank 300 through the sea water inflow pipes 311 and 312 described above. Therefore, since the water level of the cooling water R of the integrated water tank 300 is lowered and the seawater R1 is immediately supplied from the outside, the cooling water R is supplied through the second cooling system 520 and the third cooling system 530 Can be made continuously. Likewise, the heat exchange function of the first cooling system 510 with respect to the heat exchanger 511 can be maintained in a satisfactory state.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas falling within the scope of the same shall be construed as falling within the scope of the present invention.

100: Sea structure 200: Nuclear power plant
210: reactor 220: containment vessel
230: Steam generator 240: Reactor joint
300: Integrated water tank 310: Seawater inflow pipe
400: Ballast tank 500: Cooling unit
510: first cooling system 511: heat exchanger
520: second cooling system 521: heat exchanger
524: Filtration filter 530: Third cooling system

Claims (13)

1. A safety system for a small marine nuclear power plant including a marine structure disposed in the sea and having a receiving space formed therein, and a nuclear power plant installed inside the marine structure,
An integrated water tank disposed inside the sea structure and configured to store cooling water in an inner space; And
And a cooling unit for cooling the nuclear power plant using the cooling water stored in the integrated water tank
Wherein the integrated water tank is formed such that seawater present on the outside of the sea structure can be introduced into the internal space by the water head difference. The method according to claim 1,
And the bottom surface of the inner space of the integrated water tank is located at a lower position than the sea surface. 3. The method of claim 2,
Wherein the integrated water tank is installed so as to communicate with an external space of the sea structure via a seawater inflow pipe so that seawater can be introduced. The method of claim 3,
Wherein the ballast tank is installed in the inside of the sea structure so that seawater can flow into the ballast tank, and the integrated water tank is installed so as to communicate with the ballast tank so that seawater is introduced from the ballast tank. 5. The method of claim 4,
The seawater inflow pipe
A first connection pipe connecting the outer space of the floating structure to the ballast tank so that seawater flows into the ballast tank; And
And a second connection pipe connecting the ballast tank and the integrated water tank so that seawater flows into the integrated water tank,
And a safety system for a small-sized water source. 6. The method according to any one of claims 1 to 5,
The cooling unit
A first cooling system for removing residual heat from inside the reactor of the nuclear power plant; a second cooling system for cooling the inside of the containment vessel of the nuclear power generation facility; a cooling system for supplying cooling water to the reactor cavity of the nuclear power generation facility, And a third cooling system for cooling the first cooling system. The method according to claim 6,
The first cooling system
A heat exchanger disposed in the integrated water tank such that heat medium inside the integrated water tank is heat-exchanged with cooling water in the integrated water tank; And
The heat medium is circulated through the heat exchanger and the steam generator disposed inside the reactor, and the heat exchanger is connected to the steam generator through a first cooling pipe
Wherein the heating medium is formed so as to circulate the heat exchanger and the steam generator in a natural circulation manner. The method according to claim 6,
The second cooling system
A heat exchanger disposed in the containment vessel inner space such that heat transfer medium is exchanged with the containment vessel inner space; And
A second cooling pipe which is formed so that cooling water in the integrated water tank is heat-exchanged from the integrated water tank through the heat exchanger and then discharged to the outside of the containment vessel,
And a safety system for a small-sized water source. 9. The method of claim 8,
And the cooling water flows to the heat exchanger along the second cooling pipe by its own weight. 10. The method of claim 9,
The second cooling pipe
An inlet cooling pipe connecting the integrated water tank and the heat exchanger; And
And the other end is connected to the heat exchanger and the other end is exposed to the outside of the containment vessel.
And a filter filter is mounted on the discharge cooling pipe. 11. The method of claim 10,
Wherein a separate sub discharge pipe is connected to the discharge cooling pipe so that one end thereof is exposed to the inner space of the containment vessel, and the sub discharge pipe is equipped with an on-off valve. The method according to claim 6,
The third cooling system
And a third cooling pipe connecting the integrated water tank and the reactor cavity so that the cooling water in the integrated water tank flows into the reactor cavity of the reactor. 13. The method of claim 12,
Wherein said cooling water flows by self weight into said reactor cavity along said third cooling line.

Images