KR101805316B1 - Coolant tank, and containment passive cooling system including the same - Google Patents

Abstract

The present invention relates to a cooling water storage tank capable of preventing a reactor building from being re-pressed and re-heated when the reactor building is cooled in the event of a serious accident or a construction reference accident and discharging steam of a heat exchanger generated when the reactor building is cooled to the outside, and a passive cooling system for a reactor building including the same. The cooling water storage tank comprises: a storage tank storing cooling water; a dividing unit disposed in the storage tank, dividing the storage tank into first and second storage tanks so that the cooling water can be divided, and having an inlet through which the cooling water of the second storage tank is naturally introduced into the first storage tank according to the difference in a water level between the first and second storage tanks; a heat exchanger extending into the reactor building from the first storage tank and cooling the reactor building based on the cooling water of the first storage tank; and a steam discharge unit connected with the heat exchanger and discharging the steam generated in the heat exchanger to the outside of the heat exchanger.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cooling water storage tank,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cooling water storage tank and a nuclear reactor passive cooling system including the same, and more particularly, to a cooling water storage tank for cooling a reactor building and a reactor building passive cooling system including the same.

Generally, in the case of a design basis accident or a major accident at a nuclear power plant, radioactive material is discharged together with steam into the reactor building, which causes the temperature and pressure in the reactor building to rise sharply. Failure to adjust the rising temperature and pressure can destroy the reactor building. Therefore, reactor building cooling system is installed in the reactor building, so that the temperature and pressure that rise when a design basis accident or a serious accident occurs are controlled.

However, it is difficult for the operator to control the cooling system in case of design basis accidents and serious accidents, and there is a problem that the cooling system can not operate properly due to the problems such as the loss of the power for the extinguished power. Therefore, a passive cooling system has been applied. The passive cooling system may include a coolant reservoir installed outside the reactor building and a heat exchanger extending from the coolant reservoir into the reactor building.

This allows the reactor building to be cooled as the heat exchanger operates passively in the event of a design basis accident or major accident. Here, at the beginning of the accident, the thermal energy is smoothly removed by the low temperature of the cooling water. However, when the temperature of the cooling water rises due to the repeated heat exchange, the thermal energy can not be completely removed and the temperature and pressure of the reactor building rise again.

Korean Patent Registration No. 10-1552511 (Reactor Building Passive Cooling System)

It is an object of the present invention to provide a cooling water storage tank for preventing the reactor building from being repressed and reheating in cooling of the reactor building in case of a design basis accident and a serious accident, and a reactor building passive cooling system including the same.

It is another object of the present invention to provide a cooling water storage tank capable of discharging steam inside a heat exchanger generated in cooling of a reactor building to the outside, and a reactor building passive cooling system including the same.

The reactor building passive cooling system according to the present invention is a reactor building passive cooling system that is adjacent to an outer wall of a nuclear reactor building and capable of cooling the nuclear reactor building by passive operation. The system includes a storage tank for storing cooling water, The cooling water is divided into first and second storage tanks so that the cooling water is separated from the first storage tanks. The cooling water in the second storage tanks is naturally introduced into the first storage tanks according to the difference in the water level between the first and second storage tanks And a heat exchanger connected to the heat exchanger for cooling the reactor building on the basis of the cooling water of the first storage tank and the steam generated inside the heat exchanger, And a steam discharge unit for discharging the steam to the outside of the heat exchanger.

The steam discharging part may have one end communicating with the heat exchanger and the other end communicating with the first reservoir.

And the other end of the steam discharging portion may be communicated at a position higher than the water level of the cooling water accommodated in the first reservoir.

The capacity of the first reservoir may be less than the capacity of the second reservoir.

The partition may include a partition wall disposed between the upper wall and the lower wall of the storage tank.

The inlet may include at least one pipe disposed in the partition or a hole formed in the partition.

A plurality of the inflow portions may be provided, and the plurality of inflow portions may be provided at the same height.

The steam discharging unit may discharge the steam to the outside of the heat exchanger when boiling occurs in the heat exchanger.

The reactor building passive cooling system may further include a steam outlet formed in the first storage tank and forming a path for discharging the steam generated in the first storage tank to the outside of the storage tank.

The reactor building passive cooling system may further include a pressure regulator formed in the second reservoir and maintaining the internal pressure of the second reservoir equal to the external atmospheric pressure regardless of the internal pressure of the first reservoir.

According to another aspect of the present invention, there is provided a cooling water storage tank capable of cooling a building by passive motion. The cooling water storage tank includes a storage tank for storing cooling water and a first and a second cooling water heat exchanger disposed inside the storage tank, A second storage tank for storing cooling water in the first storage tank and a second storage tank for storing the cooling water in the first storage tank, A heat exchanger connected to the heat exchanger for cooling the building based on the cooling water of the first storage tank and a steam discharger for discharging the steam generated in the heat exchanger to the outside of the heat exchanger.

The cooling water storage tank and the reactor building passive cooling system including the same according to the present invention can quickly stabilize the performance of the nuclear reactor passive cooling system to prevent performance deterioration of the reactor building passive cooling system. And the flow instability due to the interaction of the steam and the steam can be minimized, so that the passive cooling system can be stably operated.

Also, the cooling water storage tank and the reactor building passive cooling system including the same according to the present invention can continuously reduce the pressure and the temperature of the nuclear reactor building, and it is possible to suppress the occurrence of the secondary accident such as the destruction of the reactor building.

The technical effects of the present invention are not limited to the effects mentioned above, and other technical effects not mentioned can be clearly understood by those skilled in the art from the following description.

1 is a conceptual view briefly showing a nuclear reactor passive cooling system according to the present embodiment,
FIG. 2 is a cross-sectional view of the passive cooling system for reactor building according to the present embodiment, taken along the line II '
FIG. 3 is a sectional view schematically showing a cooling water storage tank of a nuclear reactor passive cooling system according to the present embodiment,
FIG. 4 is a cross-sectional view of the cooling water reservoir of the reactor building passive cooling system according to the present embodiment taken along line II-II '
FIG. 5 is a graph showing changes in internal pressure and temperature of a nuclear reactor building using a cooling water storage tank of a conventional passive cooling system,
FIG. 6 is a graph showing changes in internal pressure and temperature of a nuclear reactor building using the cooling water storage tank of the passive cooling system according to the present embodiment,
7 is a flowchart showing the operation of the reactor building passive cooling system according to the present embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, it should be understood that the present invention is not limited to the disclosed embodiments, but may be implemented in various forms, and the present embodiments are not intended to be exhaustive or to limit the scope of the invention to those skilled in the art. It is provided to let you know completely. The shape and the like of the elements in the drawings may be exaggerated for clarity, and the same reference numerals denote the same elements in the drawings.

 FIG. 1 is a conceptual view briefly showing a nuclear reactor passive cooling system according to the present embodiment, and FIG. 2 is a cross-sectional view of a nuclear reactor passive cooling system according to the present embodiment taken along line I-I '.

1 and 2, a reactor building passive cooling system 100 (hereinafter, referred to as a cooling system) according to the present embodiment includes a cooling water storage tank 200.

The cooling water storage tank 200 may be disposed in an upper region of the outer circumference of the reactor building 10. The cooling water storage tank 200 can supply the cooling water to the inside of the reactor building 10 if necessary, and at this time, the cooling water can be supplied by the natural fall even if the main power of the reactor facility is lost, . However, if it is necessary to adjust the flow rate of the cooling water to the inside of the reactor building 10, the height of the cooling water storage tank 200 may be changed.

The number of the cooling water storage tanks 200 is not limited to the number of the cooling water storage tanks 200. The number of the cooling water storage tanks 200 is not limited thereto.

On the other hand, a heat exchanger 300 is connected to the cooling water storage tank 200. One side of the heat exchanger 300 is disposed inside the cooling water storage tank 200 and the other side extends into the reactor building 10. For example, the heat exchanger 300 is configured such that the outflow pipe 310 and the inflow pipe 320 extend into the coolant storage tank 200, and the heat exchange unit 330 is disposed inside the reactor building 10. Accordingly, the heat exchanger 300 allows the reactor building 10 to be cooled based on the cooling water accommodated in the cooling water reservoir 200 when a design basis accident and a major accident occur.

The heat exchanger 300 may be provided with a steam outlet 340 in the form of a pipe. One end of the steam discharge part 340 may be connected to the outflow pipe 310 and the other end may communicate with the cooling water storage tank 200. Here, the other end of the steam discharging part 340 may be communicated at a position higher than the water level of the cooling water accommodated in the cooling water storage tank 200.

When the cooling water circulates in the heat exchanger 300 and the reactor building 10 is cooled, the steam generated in the heat exchanger 300 can be discharged to the atmosphere. That is, in the heat exchanger 300, boiling may occur during the heat exchange process, and the steam discharging unit 340 may discharge the steam generated due to boiling, to the outside of the heat exchanger 300.

In this embodiment, the other end of the steam discharging unit 340 communicates with the inside of the cooling water storage tank 200. However, this is an example for explaining the present embodiment, and the other end of the steam discharging unit 340 It can be directly connected to the atmosphere if necessary.

On the other hand, the cooling water accommodated in the cooling water storage tank 200 can be accommodated in the cooling water storage tank 200 while being partitioned. Hereinafter, the cooling water storage tank 200 according to the present embodiment will be described in detail with reference to the accompanying drawings. However, the detailed description of the above-described components will be omitted, and the same reference numerals will be used to describe them.

FIG. 3 is a cross-sectional view schematically showing a cooling water storage tank of the reactor building passive cooling system according to the present embodiment, FIG. 4 is a cross-sectional view of the cooling water storage tank of the reactor building passive cooling system according to the present embodiment cut along the II- Sectional view.

3 and 4, the cooling water storage tank 200 according to the present embodiment includes a storage tank 200a. The storage tank 200a forms an outer shape of the cooling water storage tank 200 and may be supported on the outer wall of the reactor building 10. [ Here, the storage tank 200a forms a space for receiving the cooling water therein, and may be provided as a housing, but the shape of the storage tank 200a is not limited.

Inside the storage tank 200a, a partition 210 for partitioning the receiving space of the cooling water is provided. The partition 210 may be provided as a partition 210a. The partition wall 210a is disposed between the upper wall and the lower wall of the storage tank 200a and is divided into a first storage tank 200aa and a first storage tank 200aa adjacent to the reactor building 10 and a second storage tank 200ab ). Here, a heat exchanger 300 is connected to the first reservoir 200aa. The capacity of the second storage tank 200ab may be set larger than that of the first storage tank 200aa. For example, the capacity of the first storage tank 200aa may be 50% or less of the capacity of the entire storage tank 200a.

A vapor outlet H1 is formed in the upper wall of the first reservoir 200aa. The steam outlet H1 allows the steam generated as the cooling water in the first storage tank 200aa is heated in the cooling of the reactor building 10 to be discharged to the outside. Thus, it is possible to prevent the storage tank 200a from being damaged or damaged due to a change in internal pressure.

And a water level reduction delay unit 220 may be mounted on the steam outlet H1. The water level reduction delay unit 220 separates the droplets and moisture from the steam discharged from the first storage tank 200aa to the outside air so that the separated water is returned to the first storage tank 200aa.

The water level reduction delay unit 220 may be provided by a wet separator to delay the reduction of the water level of the cooling water in the storage tank 200a and to perform passive cooling of the reactor building 10 for a longer period of time.

A passive alarm unit 230 may be mounted on the water level reduction delay unit 220. The passive alarm unit 230 may alarm the performance of cooling of the reactor building 10 when a design basis accident and a serious accident occur. When the gas is introduced into the steam outlet H1, the passive alarm unit 230 may cause a sound based on the gas flow to be generated or an alarm lamp to be turned on.

For example, the passive alarm unit 230 may be provided with a sound alarm capable of generating noise according to pressure generation, or an emergency light alarm for lighting an emergency light according to a self-power generation facility such as a propeller rotating according to a gas flow.

However, this is an embodiment for explaining the present embodiment, and the passive alarm unit 230 may be provided in various configurations capable of performing an alarm by passive operation even if power is not supplied from the outside.

The passive alarm unit 230 alerts the occurrence of a cooling failure of the reactor building 10 when a design basis accident and a major accident occur, thereby enabling the occurrence of an accident to be recognized primarily around the periphery, And the degree of decompression can be recognized.

On the other hand, a pressure regulating portion H2 is formed on the upper wall of the second reservoir 200ab. The pressure regulator H2 maintains the internal pressure of the second reservoir 200ab equal to the external atmospheric pressure regardless of the internal pressure of the first reservoir 200aa.

Filters F1 and F2 are mounted on the steam outlet H1 and the pressure regulator H2, respectively. The filters F1 and F2 are used to prevent harmful substances such as radioactive materials from flowing into the storage tank 200a from the inside of the reactor building 10 when the heat exchanger 300 is broken or damaged, To prevent it.

Meanwhile, an inflow part for communicating the first reservoir 200aa and the second reservoir 200ab may be provided in the lower region of the partition 210a. This inlet may be provided as a connecting pipe 210aa. Here, a plurality of connection pipes 210aa may be provided.

However, if a plurality of connecting pipes 210aa are provided, they may be arranged at the same height to prevent the circulation of cooling water due to natural convection between the first and second storage tanks 200aa and 200ab.

4, three connection pipes 210aa are provided, but the number of connection pipes 210aa is not limited. In the present embodiment, the connection pipe 210aa is disposed in the partition 210a so that the first reservoir 200aa and the second reservoir 200ab communicate with each other. However, holes may be formed in the partition 210a except for the connecting pipe 210aa, and the holes may be formed in various shapes including circular shapes and slits.

Meanwhile, the connection pipe 210aa forms a path through which the cooling water accommodated in the second reservoir 200ab can be introduced into the first reservoir 200aa.

More specifically, the first storage tank 200aa to which the heat exchanger 300 is connected when the design basis accident and the major accident occur, reaches the saturation temperature quickly. This contributes to the stabilization of the heat removal performance of the cooling system 100, so that the temperature and pressure of the reactor building 10 are quickly stabilized. The reason why the capacity of the first reservoir 200aa is smaller than the capacity of the second reservoir 200ab as described above is for the purpose of exploiting this effect.

Thereafter, the first storage tank 200aa reaches the saturation temperature, and the cooling water accommodated in the first storage tank 200aa is heated and discharged to the outside through the steam outlet H1. Thus minimizing flow instability due to the interaction of water and steam. As the water level difference is generated between the first storage tank 200aa and the second storage tank 200ab, the cooling water in the second storage tank 200ab passes through the connection pipe 210aa to the first storage tank 200aa ≪ / RTI >

Accordingly, the cooling water storage tank 200 keeps the heat removal performance of the cooling system 100 constant from the beginning of the design basis accident and the serious accident, so that the pressure and the temperature of the reactor building 10 are gradually reduced. Therefore, in the conventional cooling system, the temperature and pressure of the reactor building 10 decrease, and the heat removal performance decreases due to the increase of the cooling water temperature, thereby solving the problem that the pressure and the temperature of the reactor building 10 are re-pressurized and reheated .

More specifically, the conventional cooling system and the cooling system 100 according to the present embodiment are compared as follows.

FIG. 5 is a graph showing changes in internal pressure and temperature of a reactor building due to use of a cooling water storage tank of a conventional passive cooling system. FIG. 6 is a graph showing changes in internal pressure and temperature of the reactor building according to the cooling water storage tank of the passive cooling system according to the present embodiment. Fig.

As shown in FIGS. 5 and 6, the conventional cooling system operates with the temperature and pressure rise of the reactor building 10 in the event of a design basis accident and a major accident. At this time, the conventional cooling system can reduce the temperature and pressure of the reactor building 10.

However, in the conventional cooling system, the efficiency of the cooling system 100 is drastically lowered according to the heating of the cooling water after a predetermined time has elapsed. As shown in the section "A " in FIG. 5, there is a problem that the temperature and pressure of the reactor building 10 are raised again. Particularly, in such a period where the temperature and the pressure of the reactor building 10 are elevated for a long period of time, there is a possibility that the original power source causes an erroneous operator action for securing additional cooling means in order to prevent repressurization of the reactor building 10.

However, even if the cooling water accommodated in the first storage tank 200aa is heated, the cooling system 100 according to the present embodiment allows the cooling water accommodated in the second storage tank 200ab to flow naturally into the first storage tank 200aa, do. Accordingly, as shown in FIG. 6, the temperature and pressure of the reactor building 10 are reduced smoothly in the event of a design basis accident and a major accident, and the problem of the temperature and pressure of the reactor building 10 rising again can be solved. In addition, since the steam discharging unit 340 is provided, it is possible to stably drive the cooling system 100, such as minimizing flow instability due to mutual wearing of water and steam.

Hereinafter, the operation of the reactor building passive cooling system according to the present embodiment will be described in more detail. However, the detailed description of the above-described components will be omitted and the same reference numerals will be given.

7 is a flowchart showing the operation of the reactor building passive cooling system according to the present embodiment.

As shown in FIG. 7, the cooling system 100 according to the present embodiment can be operated upon occurrence of a design basis accident and a serious accident (S100). At this time, steam and radioactive materials are discharged from inside the reactor building (10), thereby increasing the temperature and pressure inside the reactor building (10).

Thus, the cooling water in the heat exchanging part 330 is heated, and the heated cooling water flows into the first storage tank 200aa. At this time, the cooling water stored in the first storage tank 200aa flows into the heat exchanger 300 and is supplied to the heat exchanger 330. [ In this manner, the cooling system 100 repeats the inflow and outflow and causes the circulation of the cooling water based on the natural force to be performed (S200).

On the other hand, as the time elapses after the occurrence of the design basis accident and the major accident, the temperature of the cooling water in the first storage tank 200aa rises to the breaking point (S300). However, the cooling water stored in the second storage tank 200ab is maintained at the initial temperature in a state where the cooling water does not flow with the cooling water of the first storage tank 200aa.

 In addition, the time to reach the point at which the cooling water is broken in the first storage tank 200aa becomes shorter than the conventional cooling water storage tank having the same capacity as the cooling water storage tank 200 according to the present embodiment. Thus, the cooling system 100 according to the present embodiment is stabilized through a relatively short transient period.

In addition, as the cooling water of the first storage tank 200aa evaporates, the cooling water of the lower temperature of the second storage tank 200ab naturally flows into the first storage tank (S400). Accordingly, the heat removal performance of the cooling system 100 is lowered due to the increase in the temperature of the cooling water accommodated in the first storage tank 200aa, thereby solving the problem that the pressure and temperature of the reactor building 10 are re-pressurized and reheated.

Thus, the cooling water storage tank and the nuclear reactor passive cooling system including the cooling water storage tank can quickly stabilize the performance of the nuclear reactor passive cooling system, thereby preventing performance deterioration of the nuclear reactor passive cooling system.

Also, the cooling water storage tank and the nuclear reactor passive cooling system including the cooling water storage tank can continuously reduce the pressure and the temperature of the nuclear reactor building, and it is possible to suppress the occurrence of the secondary accident such as the destruction of the reactor building.

An embodiment of the present invention described above and shown in the drawings should not be construed as limiting the technical idea of the present invention. The scope of protection of the present invention is limited only by the matters described in the claims, and those skilled in the art will be able to modify the technical idea of the present invention in various forms. Accordingly, such improvements and modifications will fall within the scope of the present invention as long as they are obvious to those skilled in the art.

10: Reactor building
100: Reactor building passive cooling system
200: Reactor system
300: heat exchanger

Claims (11)

1. A reactor building passive cooling system adjacent to an outer wall of a nuclear reactor building and capable of passively cooling the nuclear reactor building,
A storage tank in which cooling water is stored;
Wherein the first and second storage tanks are divided into a first storage tank and a second storage tank so that the cooling water is separated from the first storage tank, A compartment having an inflow section for allowing natural inflow into the storage tank;
A heat exchanger extending from the first reservoir to the interior of the reactor building to cool the reactor building based on cooling water in the first reservoir; And
And a steam discharging unit connected to the heat exchanger and discharging steam generated in the heat exchanger to the outside of the heat exchanger,
The steam outlet
Wherein one end is communicated with the heat exchanger and the other end is communicated with the first reservoir.
delete The method according to claim 1,
The other end of the steam discharging portion
Wherein the cooling water is communicated at a position higher than a water level of the cooling water accommodated in the first storage tank.
The method according to claim 1,
The capacity of the first reservoir
And the capacity of the second storage tank is smaller than that of the second storage tank.
The method according to claim 1,
The partition
And a partition wall disposed between the upper wall and the lower wall of the storage tank.
6. The method of claim 5,
The inlet
And at least one pipe disposed in the partition or a hole formed in the partition.
6. The method of claim 5,
Wherein a plurality of the inflow portions are provided,
Wherein the plurality of inflow portions are provided at the same height.
The method according to claim 1,
The steam outlet
Wherein the steam is discharged to the outside of the heat exchanger when boiling occurs in the heat exchanger.
The method according to claim 1,
Further comprising a steam outlet formed in the first storage tank and forming a path for discharging the steam generated in the first storage tank to the outside of the storage tank.
10. The method of claim 9,
Further comprising a pressure regulator formed in the second reservoir and configured to maintain the internal pressure of the second reservoir equal to the external atmospheric pressure regardless of the internal pressure of the first reservoir.
A cooling water reservoir capable of cooling a building by passive motion,
A storage tank in which cooling water is stored;
Wherein the first and second storage tanks are divided into a first storage tank and a second storage tank so that the cooling water is separated from the first storage tank, A compartment having an inflow section for allowing natural inflow into the storage tank;
A heat exchanger extending from the first storage tank into the building and cooling the building based on the cooling water of the first storage tank; And
And a steam discharging unit connected to the heat exchanger and discharging steam generated in the heat exchanger to the outside of the heat exchanger,
The steam outlet
Wherein one end communicates with the heat exchanger and the other end communicates with the first reservoir.

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