KR101538932B1 - Radioactive material reduction facility and nuclear power plant having the same - Google Patents

Abstract

The present invention provides a radioactive material reduction facility capable of reducing an exclusion area boundary and a nuclear power plant comprising the same. The radioactive material reduction facility includes: a cooling water storage part which is installed in a containment part and is formed to store cooling water; a boundary part which surrounds a reactor coolant system in order to prevent a radioactive material from being leaked into the inside of the containment part from the reactor coolant system installed in the containment part or a pipe connected to the reactor coolant system; a connection pipe which is connected to the cooling water storage part and the boundary part in order to induce the flow of the radioactive material formed within the boundary part to the cooling water storage part; and an injection part which is connected to the connection pipe to receive the radioactive material from the connection pipe, and is dipped into the cooling water to inject the radioactive material to the cooling water of the cooling water storage part. At least a part of the boundary part prevents occurrence of a coolant loss accident in an area between the boundary part and the containment part by fracture of a penetration pipe penetrating the containment part.

Description

TECHNICAL FIELD [0001] The present invention relates to a radioactive material abatement facility,

The present invention relates to a passive safety system, and more particularly, to a facility capable of lowering the concentration of radioactive material in a containment building due to a driving force when an accident occurs in a nuclear power plant.

A nuclear reactor is a separate reactor (eg commercial reactor: domestic) in which major equipment (steam generator, pressurizer, pump, etc.) is installed outside the reactor vessel depending on the installation position of the main equipment Yes, SMART reactor: Domestic).

In addition, reactors are divided into active reactors and passive reactors depending on how safety systems are implemented. An active reactor is a reactor that uses active equipment such as a pump operated by an electric power such as an emergency generator to drive the safety system. The passive reactor is operated by gravity or gas pressure to drive the safety system It is a reactor that uses passive devices. Passive safety systems in passive reactors are built into the system without an AC source of safety grade, such as an operator action or emergency diesel generator, for more than the time (72 hours) required by regulatory requirements in the event of an accident. It is a system in which the safety system maintains the nuclear reactor safely with only the natural force and after 72 hours, the safety system can be assisted by the operator measures or the non-safety system.

A compartment (a containment building, a reactor building, a containment vessel or a safety protection vessel) serving as a final barrier to prevent leakage of radioactive material from the reactor to the external environment may be a containment formed by reinforced concrete depending on the material constituting the pressure boundary A building (or reactor building), a containment vessel formed of a steel container, and a safety protection vessel. The containment vessel is a large vessel designed to be low pressure like a containment building, and the safety vessel is a small vessel designed to be small by increasing the design pressure. In the present invention, the containment, the reactor building, the containment vessel or the safety protection vessel are collectively referred to as a containment unit unless otherwise specified.

In order to reduce the pressure and temperature inside the compartment and the concentration of radioactive material, active and passive systems are used in various forms such as a compartment sprinkler system, a compartment cooling system, a decompression tank or a decompression tank. These facilities will be described below in order.

In case of accident, the active water storage system (Domestic Commercial Reactor, SMART Reactor, etc.) is used to discharge a large amount of cooling water by using a pump in case of an accident and to recover the cooling water by recharging the water storage tank or sump. Pressure, temperature, and concentration of radioactive material. The Active Spillage Sprinkler System is capable of long term water spill function, but it must be able to use the power system for pump drive.

(CANDU, Canada, etc.) system has a cooling water storage tank on the upper part of the containment building and discharges a large amount of cooling water in case of an accident, thereby lowering the pressure, temperature and concentration of radioactive material inside the storage part. The passive sprinkler system has a characteristic that it can not operate for a certain period of time because of the limitation of the storage capacity of the cooling water.

In this method, the vapor discharged into the compartment is led to the decompression tank by using the pressure difference inside the compartment and the decompression tank, and the steam is introduced into the decompression tank, To lower the pressure, temperature and concentration of the radioactive material inside the compartment. The decompression tank system operates only until the pressure inside the compartment is higher than the pressure inside the decompression tank.

Passive compartment cooling system system has the function of lowering the pressure, temperature and concentration of radioactive material inside the compartment by condensing the vapor inside the compartment by using a heat exchanger and a cooling water tank inside or outside the compartment. do. Since the cooling system of the passive compartment uses the natural circulation inside the compartment, the pressure, the temperature and the ability of reducing the radioactive material are relatively reduced as compared with the active watering system.

In addition, as a part of the passive compartment cooling system, iron enclosure is applied, the outer wall is cooled (spray, air), and the steam inside the containment vessel is condensed at the inner wall of the containment vessel to measure the pressure, temperature and concentration (AP1000: Westinghouse, Inc., USA). This method uses the natural circulation inside the compartment as same as the passive compartment cooling system, so that the pressure, temperature and radioactive material abatement ability are relatively reduced as compared with the active watering system.

Most of the systems described above have excellent performance in reducing the pressure and temperature inside the compartment. However, the radioactive material that can maximize the diffusion of radioactive material to the external environment during a nuclear accident is iodine, and iodine is most soluble when it comes into contact with water (solubility 0.029g / 100g (20 ° C )). Accordingly, the best performance for lowering the concentration of radioactive materials in the compartment of the compartment-related safety system is that the active pump is used to sprinkle a large amount of cooling water, and the cooling water is recirculated for a long period of time. Employment method).

The active safety system is required to supply emergency AC power to operate active devices such as pumps in the event of a nuclear accident, so there is no need for continuous operation of the power system or the active system, thereby increasing the demand for a relatively safe passive safety system . However, when the passive safety system is adopted as the safety system of the containment building, the concentration of the radioactive material inside the compartment is inevitably relatively high because the amount of cooling water is inferior compared to the active safety system.

For the safety of the general public, the Exclusion Area Boundary (EAB) is established and the residence of the general public is limited by assuming a nuclear accident. Therefore, safety of the nuclear power plant can be relatively increased when the passive safety system is applied compared to the active safety system. However, it is necessary to secure a relatively limited EAB in case of a nuclear accident . Expansion of the restricted area boundary can result in a disadvantage of significantly increasing the construction cost of the nuclear power plant.
In addition, the background art of the present invention refers to the following prior patent documents.
Patent Document 1. Japanese Unexamined Patent Application Publication No. 05-203778 (Oct.
Patent Document 2. Japanese Patent Application Laid-Open No. 06-331775 (December 02, 1994)

An object of the present invention is to provide a radioactive material abatement facility capable of contributing to safety improvement of a nuclear power plant. The present invention is to propose a radioactive material abatement facility capable of lowering the concentration of radioactive material emitted when a fatal accident occurs in a nuclear power plant.

Another object of the present invention is to provide a radioactive material abatement facility and a nuclear power plant having the same that can solve the problem of widening the boundary of the restricted zone that can be caused by introducing the passive safety system into the nuclear power plant.

It is another object of the present invention to provide a radioactive material abatement facility capable of saving the number of isolation valves and preventing re-volatilization of radioactive materials and a nuclear power plant having the same.

According to an aspect of the present invention, there is provided a radioactive material abatement system comprising: a cooling water storage unit installed inside a compartment and configured to store cooling water; A boundary portion surrounding the reactor coolant system to prevent leakage of the radioactive material from the piping connected to the reactor coolant system or the reactor coolant system installed in the compartment to the inside of the compartment; A connection pipe connected to the boundary portion and the cooling water storage portion to guide the flow of the radioactive material formed in the boundary portion to the cooling water storage portion; And a spraying part connected to the connection pipe to receive the radioactive material from the connection pipe and being immersed in the cooling water so as to spray the radioactive material to the cooling water in the cooling water storage part, And extends to a region adjacent to the storage portion while wrapping the through pipe so as to reduce leakage of the radioactive material to a region between the boundary portion and the storage portion by breaking the through pipe.

According to an embodiment of the present invention, the apparatus may further include an additive injection unit for supplying an additive to the cooling water storage unit to maintain the pH of the cooling water at a predetermined value or more so as to prevent volatilization of the radioactive material dissolved in the cooling water storage unit . In general, the additive preferably maintains the pH of the cooling water at 7 or higher.

The additive injection unit is installed at a predetermined height in the cooling water storage unit so as to be immersed in the cooling water due to a rise in the water level of the cooling water storage unit and the additive is dissolved in the cooling water as the additive injection unit is immersed in the cooling water .

According to another embodiment of the present invention, the apparatus may further include a vapor discharger installed at an upper portion of the cooling water storage to prevent the overheating of the cooling water storage, and to discharge steam into the storage.

The steam discharging part may protrude from the upper part of the cooling water storage part toward the inside of the storage part.

And an adsorbent or a filter disposed in the flow path of the vapor discharging portion to capture the radioactive material to be discharged to the storage portion together with the vapor through the vapor discharging portion.

And a cooling water recovery unit installed at an upper portion of the cooling water storage unit to recover condensed water formed by cooling the cooling water in the cooling water storage unit to the inside of the storage unit through the steam discharge unit and to recover the condensed water to the cooling water storage unit.

Further comprising an additive injection unit for supplying an additive to the cooling water storage unit to maintain the pH of the cooling water at a predetermined value or more so as to prevent volatilization of the radioactive material dissolved in the cooling water storage unit, And may be installed in the flow path of the coolant recovery section to dissolve the coolant. In general, the additive preferably maintains the pH of the cooling water at 7 or higher.

The steam discharging portion and the cooling water collecting portion may be formed so as to share the same flow path.

According to another embodiment of the present invention, the cooling water reservoir has an inlet through which the connection pipe is passed, and the inlet is connected to the cooling water reservoir to prevent the cooling water stored in the cooling water reservoir from flowing back into the boundary. And may be formed at a predetermined height from the bottom.

The connection pipe may extend to the inside of the boundary portion and the inside of the cooling water storage portion through which the atomizing portion is disposed to pass the radioactive material contained in the atmosphere to the injection portion.

According to another embodiment of the present invention, the boundary portion may form a sealing structure around the reactor coolant system to prevent the radioactive material from leaking through a path other than the connection pipe.

According to another embodiment of the present invention, at least a part of the boundary portion may be formed by a concrete structure inside the compartment or a coating member provided on the concrete structure.

According to another aspect of the present invention, the boundary includes: a partition wall formed to surround the reactor coolant system; And a cover formed to cover the upper portion of the reactor coolant system.

According to another embodiment of the present invention, the ejection unit may include a plurality of ejection openings formed to subdivide and eject the radioactive material.

According to another embodiment of the present invention, the jetting unit may form a predetermined flow path resistance so that the radioactive material is uniformly distributed to the respective jetting ports.

According to another embodiment of the present invention, the radioactive material abatement facility is formed to communicate with the inside of the boundary part and the inside of the compartment part, and when the pressure inside the compartment part is higher than the pressure inside the boundary part, And a pressure equalizing pipe for allowing the atmosphere inside the compartment to flow into the boundary so as to prevent the cooling water in the cooling water storage part from flowing back into the boundary.

The pressure balanced pipe may be branched from the connection pipe and extend to the inside of the compartment.

The radioactive material abatement facility may further include a check valve installed in the pressure equalizing pipe to prevent the atmosphere inside the boundary portion from being discharged into the compartment through the pressure equalizing pipe.

The radioactive material abatement facility may further include a check valve installed in the connection pipe to prevent the cooling water in the cooling water storage unit from flowing back to the inside of the boundary through the connection pipe.

In order to achieve the above object, the present invention also discloses a nuclear power plant equipped with a radioactive material abatement facility. Nuclear power plant, payment; A reactor coolant system installed inside the compartment; And a radioactive material formed to reduce the concentration of the radioactive material, the radioactive material being formed so as to set a boundary of the radioactive material between the compartment and the reactor coolant system, Wherein the radioactive material abatement equipment includes a cooling water storage unit installed inside the compartment and configured to store cooling water; A boundary portion surrounding the reactor coolant system to prevent leakage of the radioactive material from the piping connected to the reactor coolant system or the reactor coolant system installed in the compartment to the inside of the compartment; A connection pipe connected to the boundary portion and the cooling water storage portion to guide the flow of the radioactive material formed in the boundary portion to the cooling water storage portion; And a spraying part connected to the connection pipe to receive the radioactive material from the connection pipe and being immersed in the cooling water so as to spray the radioactive material to the cooling water in the cooling water storage part, At least a part of the boundary portion extends to a region adjacent to the storage portion while enclosing the through pipe so as to reduce leakage of the radioactive material to the region between the boundary portion and the storage portion.

According to an embodiment of the present invention, the nuclear power plant may further include a cooling facility configured to cool at least one of the cooling water storage unit and the storage unit.

According to the present invention having the above-described structure, when an accident occurs in which the reactor coolant leaks from the inside of the radioactive material abatement facility, the radioactive material contained in the atmosphere (air and steam) The concentration of the radioactive material inside the compartment can be suppressed. According to the present invention, leakage of the reactor coolant can be prevented early in the event of an accident that the reactor coolant leaks from the outside of the radioactive material abatement facility, so that the integrity of the storage portion can be maintained.

Further, the present invention can dramatically improve the safety of a nuclear power plant because the increase of the concentration of the radioactive material inside the compartment can be suppressed, the boundary distance of the restricted zone can be drastically reduced, and the leakage of the radioactive material to the outside environment can be minimized. Of course, the economic cost can be reduced.

Further, according to the present invention, it is possible to suppress the re-volatilization of the radioactive material by controlling the pH of the cooling water storage portion by a passive method without substantially increasing the number of the isolation valves, and even when the radioactive material is re-volatilized, The release of the substance can be suppressed.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a conceptual diagram of a radioactive material abatement facility and a nuclear power plant having the same according to an embodiment of the present invention. FIG.
FIG. 2A is a conceptual view of a nuclear reactor equipped with the facility for reducing radioactive material according to another embodiment of the present invention; FIG.
FIG. 2B is a conceptual diagram showing a normal operation state of the nuclear power plant shown in FIG. 2A. FIG.
FIG. 2C is a conceptual view showing a state of a virtual accident of the nuclear power plant shown in FIG. 2A; FIG.
3 is a conceptual diagram of a facility for reducing radioactive material according to another embodiment of the present invention and a nuclear power plant having the same.
FIG. 4 is a conceptual diagram of a nuclear reactor having a radioactive material abatement facility according to another embodiment of the present invention. FIG.
FIG. 5A is a conceptual diagram of a radioactive material abatement facility and a nuclear power plant having the same according to still another embodiment of the present invention. FIG.
FIG. 5B is a conceptual view showing a state of a virtual accident of the nuclear power plant shown in FIG. 5A. FIG.
FIG. 5C is a conceptual diagram showing a modification of the nuclear power plant shown in FIG. 5B. FIG.
FIG. 5D is a conceptual diagram showing another modification of the nuclear power plant shown in FIG. 5B. FIG.
6 is a conceptual diagram of a radioactive material abatement facility and a nuclear power plant having the same according to still another embodiment of the present invention.
7 is a conceptual diagram of a nuclear reactor equipped with the facility for reducing radioactive material according to still another embodiment of the present invention.
FIG. 8 is a conceptual diagram of a nuclear reactor equipped with the facility for reducing radioactive material according to still another embodiment of the present invention. FIG.
8 is a conceptual diagram of a nuclear material reduction facility and a nuclear power plant having the same according to still another embodiment of the present invention.
10 is a conceptual diagram of a radioactive material abatement facility and a nuclear power plant having the same according to still another embodiment of the present invention.
11 is a conceptual diagram of a radioactive material abatement facility and a nuclear power plant having the same according to still another embodiment of the present invention.
12 is a conceptual diagram of a nuclear reactor equipped with the facility for reducing radioactive material according to still another embodiment of the present invention.
FIG. 13 is a conceptual diagram of a radioactive material abatement facility and a nuclear power plant having the same according to still another embodiment of the present invention. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a radioactive material abatement facility and a nuclear power plant having the same according to the present invention will be described in detail with reference to the drawings. In the present specification, the same or similar reference numerals are given to different embodiments in the same or similar configurations. As used herein, the singular forms "a", "an" and "the" include plural referents unless the context clearly dictates otherwise.

1 is a conceptual diagram of a radioactive material abatement facility 100 and a nuclear power plant 10 having the same according to an embodiment of the present invention.

The compartment 12 is provided outside the reactor coolant system 11 to prevent leakage of the radioactive material. In the present invention, the storage part (12) collectively refers to a containment building, a reactor building, a containment vessel, a safety protection container, and the like in the nuclear power plant (10).

The radioactive material abatement facility 100 is provided inside the compartment 12 and is provided with a reactor coolant system 11 installed inside the compartment 12 in the event of an accident or pipes 13 and 13 connected to the reactor coolant system 11 ', 15c) to the cooling water storage unit (110). The radioactive material abatement facility 100 includes a cooling water storage unit 110, a boundary 120, a connection pipe 130, and a spraying unit 140.

The cooling water storage part (110) is installed inside the compartment (12). The cooling water storage unit 110 may be formed in the form of a tank or a water tank so as to store cooling water therein. Also, the cooling water storage unit 110 may use the internal water storage tank of the storage portion. The atmosphere (steam and air) and the radioactive material inside the boundary portion 120 are injected into the cooling water of the cooling water storage portion 110 by the operation of the radioactive material abatement facility 100 at the time of an accident.

The cooling water storage unit 110 may be shared with other systems of the nuclear power plant 10 in addition to the radioactive material abatement facility 100. For example, the radioactive material abatement facility 100 and the safety infusion system 15 may share the cooling water storage unit 110. In another example, the radioactive material abatement facility 100 and the residual heat elimination system (not shown) may share the cooling water storage unit 110.

The position where the cooling water storage part 110 is installed may be the upper or lower part of the space inside the compartment 12. [ The condensed water may be formed in the compartment 12 and fall down. The cooling water storage unit 110 is installed in the upper part of the internal space of the compartment 12 to collect condensed water falling down as shown in FIG. 1 .

The cooling water storage unit 110 has an inlet 111 through which the connection pipe 130 to be described below is passed. The inlet 111 may be formed at a predetermined height from the bottom of the cooling water storage part 110 to prevent the cooling water stored in the cooling water storage part 110 from flowing backward.

The boundary portion 120 is provided between the reactor coolant system 11 and the compartment 12 to form a boundary of the radioactive material. The boundary portion 120 is configured to prevent the radioactive material from leaking from the piping 13, 13 ', 15c connected to the reactor coolant system 11 or the reactor coolant system 11 to the storage portion 12, 11).

The boundary portion 120 forms a sealing structure around the reactor coolant system 11 to prevent leakage of the radioactive material to a path other than the connection piping 130 to be described below. Separate valves 13a, 13b, 13a ', and 15c', check valves 13b 'and 15c' and the like are installed in the pipes 13, 13 ', and 15c passing through the boundary 120, The valves 13a, 13b, 13a 'and 15c' and the check valves 13b 'and 15c' are closed at the time of an accident to maintain the sealing structure. The boundary portion 120 is formed at a design pressure capable of withstanding a pressure equal to or higher than the water head difference between the cooling water storage portion 110 and the jetting portion 140 described below. At least a part of the boundary 120 may be formed by a concrete structure inside the compartment 12 and a coating member (not shown) installed on the concrete structure.

The boundary portion 120 may include a partition wall 121 and a lid 122. The partition 121 is formed so as to surround the reactor coolant system 11. A cover 122 is formed to cover the upper portion of the reactor coolant system 11. The bottom surface (or double bottom surface) of the partition 121, the lid 122 and the compartment 12 may form a sealing structure around the reactor coolant system 11. [

The nuclear power plant 10 includes through pipes 13 and 13 'passing through the compartment 12 and the through pipes 13 and 13' are connected to the reactor coolant system 11 or connected to the secondary system. A plurality of isolation valves 13a, 13b, 13a 'or check valves 13b' may be provided in the through pipes 13, 13 'so as to be spaced apart from each other in order to close both sides of the rupture part. If the boundary portion 120 and the storage portion 12 are spaced apart from each other and the through pipes 13 and 13 'pass the region between the boundary portion 120 and the storage portion 12, A coolant loss accident may occur in a region between the coolant outlet 12 and the coolant outlet 12. When a coolant loss accident occurs in the region between the boundary portion 120 and the storage portion 12, there arises a problem that the radioactive material can not be confined in the inside of the radioactive material abatement facility 100. Therefore, when a coolant loss accident occurs in the region between the boundary portion 120 and the compartment 12, an isolation valve must be provided in the through-pipe 13, 13 'to prevent further leakage of the radioactive material.

However, since the isolation valve has a mechanism that is opened or closed by a signal of the relevant safety system, there is a possibility that the isolation valve malfunctions or does not operate. Further, it is not preferable to add the isolation valve in terms of simplification of the facility. To overcome such a problem, the present invention has a structure capable of preventing the leakage of the radioactive material even if the isolation valve is not additionally provided. Specifically, at least a part of the boundary portion 120 is formed in the through-pipes 13, 13 'so as to reduce the leakage of the radioactive material between the boundary portion 120 and the compartment portion 12 by the breakage of the through- 13 ') and extends to the area adjacent to the compartment 12. As a result, the through pipes 13 and 13 'passing through the compartment 12 into the compartment 12 are positioned within the boundary 120. Accordingly, the present invention can remarkably reduce the possibility of occurrence of a coolant loss accident due to breakage of the pipes 13 and 13 'in the region between the boundary portion 120 and the compartment portion 12, It is possible to prevent the leakage of the radioactive material.

The connection pipe 130 is connected to the boundary portion 120 and the cooling water storage portion 110 to guide the flow of the air formed in the boundary portion 120 to the cooling water storage portion 110. The atmosphere inside the boundary 120 includes steam or air, and radioactive materials may be included in the atmosphere when a coolant loss event occurs. If the pressure inside the boundary part 120 rises and the pressure difference inside the boundary part 120 and the pressure difference inside the compartment part 12 increase to H1 or more, the atmosphere inside the boundary part 120 is passively connected to the connection pipe 130 to the cooling water storage unit 110. [

The connection piping 130 passes through the inlet 111 of the cooling water storage portion 110 to transfer the atmosphere inside the boundary portion 120 and the radioactive material contained in the atmosphere to the spray portion 140 to be described later, And extends to the inside of the storage unit 110.

The sprayer 140 is connected to the connection pipe 130 to receive the atmosphere inside the boundary part 120 and the radioactive material contained in the atmosphere from the connection pipe 130. At least a part of the radiating part 140 is immersed in the cooling water of the cooling water storage part 110 so as to inject the radioactive material contained in the atmosphere and the atmosphere into the cooling water of the cooling water storage part 110.

The jetting unit 140 includes a plurality of jetting ports 141 formed to jet the air in the boundary 120 and the air contained in the atmospheric air. The jetting section 140 may form a predetermined flow path resistance in the internal flow path so as to evenly distribute the atmosphere inside the boundary section 120 and the radioactive material contained in the atmosphere to each injection port 141. [

The steam injected into the cooling water storage portion 110 through the jetting section 140 is condensed, and the air rises while being cooled. Most of the water-soluble radioactive materials are dissolved in the cooling water. The operation of the radioactive material abatement facility 100 is continuously maintained when the amount of cooling water in the cooling water storage unit 110 is maintained at a predetermined amount or more and the pressure difference between the boundary portion 120 and the compartment unit 12 is H1 or more.

When the connection pipe 130 and the jetting unit 140 are formed in a single unit, the radioactive material abatement facility 100 may become inoperable due to a failure of the connection pipe 130 or the jetting unit 140. Accordingly, the connection pipe 130 and the jetting unit 140 may be formed in plural in consideration of multiplicity.

The radioactive material abatement facility 100 may further include a vapor discharge unit 150 and a cooling water recovery unit 160.

The steam discharging unit 150 is installed at an upper portion of the cooling water storage unit 110 to prevent the overpressure of the cooling water storage unit 110 and discharges the steam into the storage unit 12. On the contrary, the cooling water recovery unit 160 recovers the vapor discharged from the cooling water storage unit 110. The cooling water in the cooling water storage part 110 evaporates and is discharged to the inside of the compartment 12 through the steam discharging part 150 and then cooled to form a condensed water. The cooling water recovery unit 160 is installed above the cooling water storage unit 110 to recover the condensed water to the cooling water storage unit 110. The connection between the cooling water recovery unit 160 and the cooling water storage unit 110 may be formed in the form of a pipe or in the form of a structure.

As shown in FIG. 1, the steam discharging unit 150 and the cooling water recovery unit 160 may be formed on the cooling water storage unit 110. More specifically, a part of the upper structure forming the cooling water storage part 110 is opened to form the steam emission part 150 and the cooling water recovery part 160. The steam discharging part (150) and the cooling water storage part (110) are installed in areas separated from each other. However, the steam discharging unit 150 and the cooling water collecting unit 160 may be formed to share the same flow paths.

In addition to the radioactive material abatement facility 100, various systems can be installed in the nuclear power plant 10. For example, as shown in Fig. 1, a passive safety injection system 15 may be installed in the nuclear power plant 10. [ The passive safety injection system 15 is a system for maintaining the water level of the reactor coolant system 11 by injecting the coolant into the reactor coolant system 11 in the event of an accident such as a loss of coolant. The passive safety injection system 15 may include various kinds of tanks such as the core replenishing tank 15a or the safety injection tank 15b. The core replenishment tank 15a or the safety injection tank 15b is connected to the reactor coolant system 11 by the safety injection pipe 15c and the pressure equalizing pipe 15d.

The coolant is injected into the reactor coolant system 11 from the tanks 15a, 15b through the safety injection piping 15c. When the radioactive material abatement facility 100 and the passive safety infusion system 15 are installed together in the nuclear power plant 10, the passive safety infusion system 15 is installed inside the boundary 120 to prevent the leakage of the radioactive material. .

The radioactive material abatement facility 100 proposed in the present invention does not form a high pressure boundary with the compartment part 12 unlike the case where the compartment compartment 12 is provided in a double manner, Can be minimized. In addition, the radioactive material abatement facility 100 has an advantage that the increase in the number of isolation valves can be minimized.

Hereinafter, another embodiment of the radioactive material abatement facility will be described.

2A is a conceptual diagram of a radioactive material abatement facility 200 according to another embodiment of the present invention and a nuclear power plant 10 having the same.

The steam discharging part 250 is formed to protrude from the upper part of the cooling water storage part 210 toward the inside of the compartment 12. [ The steam discharging part 250 has a flow path formed by a pipe or a structure. A filter or an adsorbent 270 for trapping the radioactive material which is going to pass through the cooling water storage part 210 is disposed in the channel.

When the pressure of the cooling water storage part 210 rises, the steam or the atmosphere inside the cooling water storage part 210 is discharged through the vapor discharge part 250. In this process, some of the radioactive materials dissolved in the cooling water in the cooling water storage part 210 may be re-volatilized and may escape to the storage part 12 through the steam discharging part 250 together with the steam or the air. If the radioactive material exits to the compartment 12, the radioactive material concentration in the compartment 12 can be increased.

The filter or adsorbent 270 is disposed in the flow path of the vapor discharge portion 250 to capture the radioactive material to be discharged into the storage portion 12 together with the steam through the vapor discharge portion 250. The filter or sorbent 270 is configured to pass a vapor or atmosphere and capture the radioactive material.

The filter can use a high efficiency particle filter (HEPA filter). The gaseous form of radioactive material contained in the vapor or atmosphere is removed as it passes through the filter. For example, when the radioactive material is iodine, the iodine is converted into iodic silver by binding with silver nitrate through the filter and removed from the vapor or air.

Activated carbon may be used as the adsorbent. The iodine organic compounds combine with the substances impregnated on activated carbon, converted into quaternary ammonium salt form, and adsorbed on activated carbon. The molecular form of iodine is bound to the activated carbon through chemical adsorption. Activated carbon is used as an adsorbent because it has a large internal bonding area due to its porous structure.

The filter and the adsorbent 270 may be disposed together, or only one of the filter and the adsorbent 270 may be disposed. However, the filter and the adsorbent 270 described above are only examples, and the types of the filter and the adsorbent 270 in the present invention are not necessarily limited to those described above.

The cooling water recovery unit 260 also includes a flow path formed by a pipe or structure like the vapor discharge unit 250. The flow path of the cooling water recovery unit 260 may be formed to be immersed in the cooling water storage unit 210. However, the cooling water storage part 210 and the cooling water recovery part 260 are formed not to be separated but to communicate with each other.

Hereinafter, the normal operation of the nuclear power plant 10 and the occurrence of an accident will be described with reference to FIGS. 2B and 2C, respectively.

FIG. 2B is a conceptual diagram showing a normal operation state of the nuclear power plant 10 shown in FIG. 2A.

The isolation valves 13a, 13b, 13a 'related to the systems for the normal operation of the reactor coolant system 11 and the nuclear power plant 10 are opened during normal operation of the nuclear power plant 10. [ During normal operation of the nuclear power plant 10, the water level of the reactor coolant system 11 is maintained at the normal water level. Therefore, the passive safety injection system 15 is kept in the standby state.

The radioactive material abatement facility 200 is a facility that operates passively by a pressure difference formed between the boundary portion 220 and the compartment portion 12. In the normal operation of the nuclear power plant 10, The radioactive material abatement facility 200 is also kept in the standby state because there is almost no pressure difference between the radioactive substance abatement facility 210 and the radioactive substance abatement facility 200.

FIG. 2C is a conceptual diagram showing a state of a virtual accident of the nuclear power station 10 shown in FIG. 2A.

When an accident such as a coolant loss accident occurs in the nuclear power plant 10 due to pipe breakage or the like, steam and radioactive material are discharged through the breakage portion 13 ". Then, the safety systems installed in the nuclear power plant 10 start operating .

In the event of an accident, the isolation valves 13a, 13b, 13a 'associated with the normal operation of the nuclear power plant 10 are closed by an associated signal. When the check valves 13b 'and 15c' 'that form the flow path in the direction toward the reactor coolant system 11 are provided, the flow in the direction coming out of the reactor coolant system 11 is blocked and the radioactive material reduction facility The isolation valves 13a, 13b, 13a ', 15c' can share the activation signal, so that when the isolation valves 13a, 13b, 13a ', 15c' The material abatement facility 100 is operated.

The nuclear power plant 10 includes a driven residual heat eliminating system 14 for removing sensible heat inside the reactor coolant system 11 and residual heat of the core 11a and a reactor coolant system 11 for releasing the water level of the reactor coolant system 11. [ 11). ≪ / RTI >

The isolation valve 15a 'and the check valve 15a' are installed in the piping connected to the core replenishing tank 15a and the isolation valve 15a 'and the check valve 15a' When the check valve 15a "is opened, the coolant in the core replenishing tank 15a is quickly injected into the reactor coolant system 11. [ When the isolation valve 15d 'provided in the pressure equalizing pipe 15d is opened to form a pressure balance between the reactor coolant system 11 and the safety injection tank 15b, the coolant of the safety injection tank 15b is also supplied to the reactor coolant System (11). Both the core replenishment tank 15a and the coolant of the safety injection tank 15b are injected into the reactor coolant system 11 through the safety injection pipe 15c.

The driven residual heat removing system 14 can remove the sensible heat of the reactor coolant system 11 and the residual heat of the core 11a. Depending on the needs of the nuclear power station 10, other systems besides the above-mentioned safety systems may be additionally provided.

When the steam is discharged from the rupture portion 13 ", the radioactive material is discharged together with the steam into the boundary portion 220 (see FIG. 2A). As the steam and the radioactive material are continuously discharged from the rupture portion 13" The pressure inside the chamber 220 gradually increases. When a pressure difference of H1 or higher is formed between the boundary portion 220 and the compartment portion 12 as the pressure in the boundary portion 220 rises, the pressure difference is increased from the relatively high pressure boundary portion 220 to the relatively low-pressure cooling water storage portion 210 The flow of the atmosphere (including steam, air and radioactive material) by the power is formed.

The connection pipe 230 guides the flow of the atmosphere formed by the pressure difference to the cooling water storage part 210. The air passing through the connection pipe 230 is injected into the cooling water through the injection part 240 immersed in the cooling water storage part 210. Thereby, the steam is injected into the cooling water and condensed, and the air rises as it is cooled. The water-soluble radioactive material is dissolved in the cooling water and is collected. Accordingly, the radioactive material abatement facility 200 can prevent the radioactive material from leaking to the external environment.

Particularly, iodine, which is the radioactive material that can maximize the diffusion concentration to the external environment among radioactive materials, is mostly dissolved in the cooling water. The operation of the radioactive material abatement facility 200 is continuously maintained when the amount of cooling water in the cooling water storage unit 210 is maintained at a predetermined amount or more and the pressure difference between the boundary portion 220 and the storage portion 12 is H1 or more.

The radioactive material abatement facility 200 condenses the vapor, which may raise the pressure inside the compartment 22, to the cooling water storage 210 through the dispenser 240. Therefore, the radioactive material abatement facility 200 can suppress the pressure buildup inside the compartment 12 and can lower the design pressure of the compartment 12.

The steam of the cooling water storage part 210 may be discharged through the steam discharging part 250 as time elapses. However, the radioactive material contained in the vapor is trapped while passing through the filter or additive 270, and is not discharged to the compartment 12. Some of the vapor discharged into the compartment 12 is condensed again and is recovered to the cooling water storage 210 through the cooling water recovery unit 260.

Hereinafter, still another embodiment of the present invention will be described.

3 is a conceptual diagram of a radioactive material abatement facility 300 and a nuclear reactor 10 having the same according to still another embodiment of the present invention.

The steam discharging portion 350 and the cooling water collecting portion 360 share the same flow path. The steam or the atmosphere of the cooling water storage portion 310 is discharged to the storage portion 12 through the steam discharge portion 350 with the passage of time. The condensed water formed in the compartment portion 12 is recovered to the cooling water storage portion 310 through the cooling water collection portion 360.

The filter or adsorbent 370 is disposed inside the cooling water storage part 310 as shown in Fig. Specifically, the filter or adsorbent 370 is installed at an upper portion of the internal space of the cooling water storage portion 310. Thus, the radioactive material contained in the vapor or the atmosphere is captured while passing through the filter or adsorbent 370, and is not emitted to the compartment 12.

4 is a conceptual diagram of a radioactive material abatement facility 400 and a nuclear power plant 10 having the same according to still another embodiment of the present invention.

The radioactive material abatement facility 400 may further include an additive injection unit 480. The additive injector 480 supplies the additive for maintaining the pH of the coolant to a predetermined value or more (generally, pH 7 or more) to prevent volatilization of the radioactive material dissolved in the coolant storage part 110, . The additive injection unit 480 may be installed in the flow path of the cooling water recovery unit 460 as shown in FIG.

The radioactive iodine dissolved in the cooling water is present in the form of anion. Radioiodine can greatly increase the amount of re-volatilization when the pH of the dissolved cooling water is low. This is because, in cooling water having a pH of 7 or lower, the amount of radioactive iodine converted into the volatile form of small-sized iodine (I ₂ ) is greatly increased.

The additive injection unit 480 injects the additive into the coolant storage unit 410 so that the radioactive material dissolved in the coolant is not re-volatilized. The additive may be, for example, trisodium phosphate. Trisodium phosphate controls the pH of the cooling water to prevent corrosion inside the compartment 12 and re-volatilization of the radionuclide. However, the kind of the additive in the present invention is not necessarily limited thereto. The additive may be added with boric acid which suppresses the reactivity of the core 11a or other additives for suppressing the corrosion of the equipment to passively control the quality of the cooling water storage part 410. [

Referring to FIG. 4, the condensed water in the compartment 12 is recovered to the cooling water storage part 410 through the cooling water recovery part 460. The additive injection unit 480 is installed in the flow path of the coolant recovery unit 460 to dissolve the additive in the condensed water to be recovered. As a result, the additive is dissolved in the condensed water flowing into the cooling water recovery portion 460, and the additive raises the pH of the condensed water to prevent the re-volatilization of the radioactive material. When the condensed water flows into the cooling water storage part 410 and is mixed with the cooling water, the pH of the mixed fluid of the condensed water and the cooling water can be maintained at 7 or more by the additive.

FIG. 5A is a conceptual diagram of a radioactive material abatement facility 500 and a nuclear power plant 10 having the same according to still another embodiment of the present invention.

The nuclear power plant 10 may be provided with a coin-driven cooling system along with the radioactive material abatement facility 500. The to-be-poured cooling system is a system for discharging the heat inside the compartment 12 to the outside by using the heat exchanger 16a so as to suppress the pressure rise inside the compartment 12. [ In the heat exchanger 16a, the atmosphere inside the compartment 12 and the cooling water in the cooling water storage part 410 are cooled. The vapor and air contained in the atmosphere inside the compartment 12 can be condensed or cooled, respectively. When the temperature inside the compartment 12 becomes low, some of the vapor or air in the compartment 12 condenses. Thus, the pressure rise inside the compartment 12 can be suppressed by the to-be-poured cooling system.

The heat exchanger 16a of the to-be-poured cooling system may be installed in the internal space of the compartment 12 and may be installed so as to be immersed in the cooling water of the cooling water storage part 510. [ The heat exchanger 16a may be installed so as to pass through the upper structure of the cooling water storage part 510. Some of the heat exchangers 16a shown in Fig. 5A are arranged in the space inside the compartment 12, and the other parts are arranged inside the cooling water storage part 510. Fig.

FIG. 5B is a conceptual diagram showing a state of a virtual accident of the nuclear power station 10 shown in FIG. 5A.

The steam and the radioactive material are discharged through the rupture portion 13 "when the rupture occurs in the piping connected to the reactor coolant system 11. The passive safety injection system 15 provided inside the boundary portion 520 is connected to the reactor coolant system And the driven residual heat eliminating system 14 removes the sensible heat of the reactor coolant system 11 and the residual heat of the core 11a.

The pressure inside the boundary portion 520 is raised by the release of the steam to a pressure higher than the pressure in the compartment portion 1212 and a flow due to the pressure difference is formed in the boundary portion 520. The connection pipe 530 guides the flow of the air to the cooling water storage part 510. The jetting unit 540 injects the air transferred from the connection pipe 530 and the radioactive material contained in the air into the cooling water. The water-soluble radioactive material is collected in the cooling water storage part (510). The isobaric dispensing cooling system 16 cools at least one of the compartment 12 and the cooling water reservoir 110.

As time passes, the steam or the atmosphere of the cooling water storage portion 510 is discharged into the inside of the compartment 12 through the vapor discharge portion 550. However, the radioactive material is trapped by the filter or adsorbent 570 installed in the flow path of the vapor discharging portion 550, and is not discharged to the storage portion 12. Some of the vapor that has been released into the compartment 12 is again condensed to form condensed water. The condensed water is recovered to the cooling water storage unit 510 through the cooling water recovery unit 560.

Fig. 5C is a conceptual diagram showing a modification of the nuclear power station 10 shown in Fig. 5B.

An equivalent copper load cooling system (16, 16 ') is formed to cool the compartment (12). The heat exchangers (not shown) of the coinage cooling systems 16 and 16 'may be installed in the internal spaces of the cooling water storage part 510 and the storage part 12, respectively. Operations of the radioactive material abatement facility 100, the passive safety infusion system 15, and the driven residual heat elimination system 14 in the event of an accident are the same as those described in FIG. 5B.

The steam or atmosphere evaporated from the cooling water storage portion 110 to the storage portion 12 through the steam discharge portion 150 is cooled and stored in the storage portion 12 because the cooled isothermal cooling system 16 and 16 ' Can be condensed. The condensed water formed by condensing the steam is recovered through the cooling water recovery unit 560 as described above.

Fig. 5D is a conceptual diagram showing another modification of the nuclear power station 10 shown in Fig. 5B.

The to-be-poured cooling system 16 is formed to cool the compartment portion 12 and the cooling water storage portion 510. The heat exchanger (not shown) of the coinage cooling system 16 may be formed to penetrate the upper structure of the cooling water storage part 510 to cool the storage part 12 and the cooling water storage part 510 at the same time. The other configuration is the same as described in Fig. 5C.

6 is a conceptual diagram of a radioactive material abatement facility 600 and a nuclear power plant 10 having the same according to still another embodiment of the present invention.

The cooling water storage unit 610 may be installed in a lower area of the internal space of the compartment 12. [ The connection pipe 630 passes through the inlet 611 of the cooling water storage portion 610 and extends toward the lower portion of the cooling water storage portion 610 as described in the other embodiments. The sprayer 640 is connected to the connection pipe 630 to receive the radioactive material that has passed through the connection pipe 630.

The steam discharging portion 650 protrudes into the inner space of the compartment 12 and a filter or an adsorbent 670 is installed in the passage of the vapor discharging portion 650. The cooling water recovery portion 660 is formed to recover the condensed water. The heat exchanger 16a of the to-be-poured cooling system is installed in the cooling water storage part 610 and cools the cooling water in the cooling water storage part 610. [

7 is a conceptual diagram of a radioactive material abatement facility 700 and a nuclear power plant 10 having the same according to still another embodiment of the present invention.

The radioactive material abatement facility 700 further includes a pressure equalization pipe 790. The pressure equalizing pipe 790 of the radioactive material abatement equipment 700 should be distinguished from the pressure equalizing pipe 15d of the passive safety inserting system 15. [ The pressure equalizing pipe 790 of the radioactive material abatement facility 700 is formed to communicate with the inside of the boundary portion 720 and the inside of the compartment portion 12, respectively. The pressure equalizing pipe 790 is formed to introduce the atmosphere inside the compartment portion 12 into the boundary portion 720 when the pressure inside the compartment portion 12 is higher than the pressure inside the boundary portion 720. Accordingly, it is possible to prevent the cooling water in the cooling water storage portion 710 from flowing back into the inside of the boundary portion 120. The pressure equalizing pipe 790 may extend from the connecting pipe 730 to the inside of the compartment 12. The pressure equalizing pipe 790 can pass through the structure above the cooling water reservoir 710 as shown.

The pressure equalizing pipe 790 may be provided with a check valve 791 for passing only one directional flow. The check valve 791 is formed to pass only one direction of flow. The check valve 791 is formed to prevent the atmosphere inside the boundary portion 720 from being discharged into the compartment 12 through the pressure equalizing pipe 790.

8 is a conceptual diagram of a radioactive material abatement facility 800 and a nuclear power plant 10 having the same according to still another embodiment of the present invention.

The pressure equalizing pipe 890 is formed so as to pass through the inside of the boundary portion 820 and the inside of the compartment portion 12, respectively. One end of the pressure balance pipe 890 may communicate with the boundary 820 and the other end may communicate with the compartment 12. The boundary 820 and the compartment 12 communicate with each other by the pressure equalizing pipe 890. 7, the pressure balanced pipe 890 may be formed independently of the connection pipe 830, not branched from the connection pipe 830. The pressure balanced pipe 890 may extend through the top of the boundary 820 and into the interior of the boundary 820. The check valve 891 can be installed in the pressure equalizing pipe 890, and the function of the check valve 891 is as described in FIG.

9 is a conceptual diagram of a radioactive material abatement facility 900 and a nuclear power plant 10 including the same according to still another embodiment of the present invention.

The connection pipe 930 is provided with a check valve 931 for passing only one directional flow. The check valve 931 prevents the cooling water in the cooling water storage portion 910 from flowing back to the boundary portion 920 through the connection pipe 930.

10 is a conceptual diagram of a radioactive material abatement facility 1000 and a nuclear power plant 10 having the same according to still another embodiment of the present invention.

The cooling water storage portion 1010 may be connected to the safety injection pipe 15c. The isolation valve 1032a and the check valve 1032b are installed in the pipe 1032 for connecting the cooling water storage unit 1010 and the safety injection pipe 15c. When the isolation valve 1032a and the check valve 1032b are opened, the cooling water stored in the cooling water storage unit 1010 is injected into the reactor coolant system 11.

11 is a conceptual diagram of a nuclear reactor 10 including the radioactive material abatement facility 1100 according to another embodiment of the present invention.

The passive safety injection system 15 can be selectively installed inside or outside the boundary 1120. [ The passive safety injection system 15 shown in FIG. 11 is installed outside the boundary 1120.

12 is a conceptual diagram of a radioactive material abatement facility 1200 and a nuclear power station 10 having the same according to still another embodiment of the present invention.

The nuclear power plant 10 includes a water supply system 17 and a water supply pipe 17a. An isolation valve 17b is provided in the water supply pipe 17a. The nuclear power plant 10 also includes a turbine system 18 and a steam line 18a. An isolation valve 18b is also installed in the steam pipe 18a. The water supply can be supplied to the reactor coolant system 11 through the water supply pipe 17a while the water is passing through the steam generator 11b to receive heat from the core 11a, The steam may be supplied to the turbine system 18 through the steam line 18a. The water supply pipe 17a and the steam pipe 18a also pass through the boundary portion 1220 and the storage portion 12.

The boundary portion 1220 extends to the region adjacent to the compartment 12 while enclosing the through pipes 13 and 13 ', the water supply pipe 17a and the steam pipe 18a. Therefore, even if the pipe breaks within the boundary 1220, the radioactive material can not escape from the boundary 1220. In addition, since the boundary 1220 extends to the area adjacent to the compartment 12, the possibility of an accident such as a loss of coolant in the area between the boundary 1220 and the compartment 12 is significantly lowered. Therefore, the isolation valve may not be provided in the region between the boundary portion 1220 and the compartment 12. As a result, the present invention can minimize the number of isolation valves for closing the piping when an accident occurs.

13 is a conceptual diagram of a radioactive material abatement facility 1300 and a nuclear power plant 10 having the same according to still another embodiment of the present invention.

The additive injection unit 1380 may be installed in the coolant storage unit 1310 and the coolant recovery unit 1360, respectively.

The additive injection unit 1381 provided inside the cooling water storage unit 1310 may be installed at a predetermined height so as to be immersed in the cooling water by the rise of the water level of the cooling water storage unit 1310. When the atmosphere of the boundary portion 1320 is continuously sprayed to the cooling water through the spray portion 1340, the water level of the cooling water storage portion 1310 gradually rises. When the water level of the cooling water storage portion 1310 becomes higher than that of the additive injection portion 1381, the additive injection portion 1381 is immersed in the cooling water. As the additive injecting section 1381 is immersed in the cooling water, the additive is dissolved in the cooling water.

The additive injection unit 1382 provided in the flow path of the cooling water recovery unit 1360 dissolves the additive in the condensed water recovered as described above.

The above-described radioactive material abatement equipment and the nuclear power plant having the same are not limited to the configurations and the methods of the embodiments described above, but the embodiments may be modified such that all or some of the embodiments are selectively combined .

10: Nuclear reactor 11: Reactor coolant system
12: Storage part 100: Radioactive material abatement equipment
110: cooling water storage part 120:
130: connection piping 140:
150: Vapor discharge part 160: Cooling water recovery part
170: filter or adsorbent 180: additive injection part
190: Pressure balanced pipe

Claims (22)

A cooling water storage unit installed inside the compartment and configured to store cooling water;
A boundary portion enclosing the reactor coolant system to prevent leakage of the radioactive material from the piping connected to the reactor coolant system or the reactor coolant system installed in the compartment to the inside of the compartment;
A connection pipe connected to the boundary portion and the cooling water storage portion to guide the flow of the radioactive material formed in the boundary portion to the cooling water storage portion; And
And a jetting part connected to the connection pipe to receive the radioactive material from the connection pipe and being immersed in the cooling water to jet the radioactive material to the cooling water in the cooling water storage part,
Wherein at least a part of the boundary portion surrounds the through-pipe so as to reduce leakage of the radioactive material to a region between the boundary portion and the compartment by rupture of the through-pipe through the compartment, Of the radioactive material. The method according to claim 1,
Further comprising an additive injection unit for supplying an additive to the cooling water storage unit to maintain the pH of the cooling water at a predetermined value or more so as to prevent volatilization of the radioactive material dissolved in the cooling water storage unit. 3. The method of claim 2,
The additive injection unit is installed at a predetermined height in the cooling water storage unit so as to be immersed in the cooling water due to a rise in the water level of the cooling water storage unit,
And the additive is dissolved in the cooling water as the additive injection unit is immersed in the cooling water. The method according to claim 1,
Further comprising a steam discharging unit installed at an upper portion of the cooling water storage unit to discharge steam into the storage unit to prevent overpressure of the cooling water storage unit. 5. The method of claim 4,
Wherein the steam discharging portion is formed to protrude from an upper portion of the cooling water storing portion toward the inside of the storage portion. 5. The method of claim 4,
Further comprising an adsorbent or a filter disposed in the flow path of the vapor releasing part to capture the radioactive material to be discharged to the storage part together with the steam through the steam discharging part. 5. The method of claim 4,
Further comprising a cooling water recovery unit installed at an upper portion of the cooling water storage unit for recovering the condensed water formed by cooling the cooling water in the cooling water storage unit to the inside of the storage unit through the steam discharge unit and cooling the cooling water storage unit. Material abatement equipment. 8. The method of claim 7,
Further comprising an additive injection unit for supplying an additive to the cooling water storage unit to maintain the pH of the cooling water at a predetermined value or more so as to prevent volatilization of the radioactive material dissolved in the cooling water storage unit,
Wherein the additive injection unit is installed in the flow path of the cooling water recovery unit to dissolve the additive in the condensed water. 8. The method of claim 7,
Wherein the vapor releasing part and the cooling water recovering part are formed to share the same flow path. The method according to claim 1,
Wherein the cooling water reservoir has an inlet for passing the connection pipe,
Wherein the inlet is formed at a predetermined height from the bottom of the cooling water storage part to prevent the cooling water stored in the cooling water storage part from flowing back into the inside of the boundary part. 11. The method of claim 10,
Wherein the connection pipe extends to the inside of the boundary portion and the inside of the cooling water storage portion through the inlet to transmit the radioactive material contained in the atmosphere to the injection portion, . The method according to claim 1,
Wherein the boundary portion forms a sealing structure around the reactor coolant system to prevent the radioactive material from leaking through a path other than the connection pipe. The method according to claim 1,
Wherein at least a part of the boundary portion is formed by a concrete structure inside the compartment or a coating member provided on the concrete structure. The method according to claim 1,
The boundary portion
A partition wall formed to surround the reactor coolant system; And
And a lid formed to cover an upper portion of the reactor coolant system. The method according to claim 1,
Wherein the ejecting unit comprises a plurality of ejection openings formed to subdivide and eject the radioactive material. 16. The method of claim 15,
Wherein the jetting unit forms a predetermined flow path resistance so that the radioactive material is uniformly distributed to each jetting port. The method according to claim 1,
And the air in the inside of the compartment is introduced into the boundary part when the pressure inside the compartment is higher than the pressure inside the boundary part, Further comprising: a pressure equalizing pipe for preventing the water from flowing back into the boundary. 18. The method of claim 17,
Wherein the pressure balanced pipe is branched from the connection pipe and extends to the inside of the compartment. 19. The method of claim 18,
Further comprising a check valve installed in the pressure equalizing pipe to prevent the atmosphere inside the boundary portion from being discharged into the compartment through the pressure equalizing pipe. The method according to claim 1,
Further comprising: a check valve installed in the connection pipe to prevent the cooling water in the cooling water storage unit from flowing back into the boundary through the connection pipe. Storage part;
A reactor coolant system installed inside the compartment; And
A radiological material abatement facility which is formed so as to set a boundary of a radioactive material between the compartment and the reactor coolant system and injects a radioactive material that can flow out into the compartment to coolant water to reduce the concentration of the radioactive material; Lt; / RTI >
The radioactive material abatement facility includes:
A cooling water storage unit installed inside the compartment and configured to store cooling water;
A boundary portion surrounding the reactor coolant system to prevent leakage of the radioactive material from the piping connected to the reactor coolant system or the reactor coolant system installed in the compartment to the inside of the compartment;
A connection pipe connected to the boundary portion and the cooling water storage portion to guide the flow of the radioactive material formed in the boundary portion to the cooling water storage portion; And
And a jetting part connected to the connection pipe to receive the radioactive material from the connection pipe and being immersed in the cooling water to jet the radioactive material to the cooling water in the cooling water storage part,
At least a part of the boundary portion is formed in a region adjacent to the storage portion while surrounding the through-pipe, so as to reduce leakage of the radioactive material to the region between the boundary portion and the storage portion by breaking of the through- Of the nuclear power plant. 22. The method of claim 21,
Further comprising a cooling facility configured to cool at least one of the cooling water storage unit and the storage unit.

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