KR102638287B1 - Double containment system for reactor building penetration area - Google Patents

Abstract

The present invention relates to a dual containment system for a nuclear reactor building penetrating section, comprising: a nuclear reactor building; A penetrating portion penetrating the wall of the reactor building; It is characterized in that it includes; a double containment part installed on the wall of the nuclear reactor building and surrounding the penetration part on the outside of the penetration part.

Description

Double containment system for reactor building penetration area}

The present invention relates to a dual containment system in the penetration part of a nuclear reactor building. More specifically, a double containment is installed in the penetration area where piping and electric cables pass from the nuclear reactor building to surrounding buildings, and the negative pressure and filtration system within the double containment is provided. It relates to a double containment system in the penetrating part of the reactor building that can prevent external leakage of radioactive materials by providing a joint filler in the space between the double containment part and the reactor building wall.

In general, a nuclear reactor building consists of a cylindrical wall and a hemispherical dome, and the reactor building consists of a single reactor building with a prestressed concrete shell structure. The reactor building is provided with a penetration area through which electric cables and pipes pass for supplying electricity inside the reactor building and transferring fluids into and out of the reactor building.

The conventional reactor building penetrating containment design provides a means of isolating the fluid system penetrating the reactor building to prevent radioactive materials released into the reactor building in the event of an accident within the reactor building from leaking into the environment outside the reactor building.

However, there is a problem that leakage occurring from penetrating parts and isolation valves cannot be effectively managed through such conventional methods. Recently, dual reactor buildings have been used to solve this problem.

However, when applying a dual reactor building, there is a problem that the construction period increases due to the lack of design and construction experience for the secondary reactor building, and there is a problem that the construction cost increases due to the expanded auxiliary building according to the application of the secondary reactor building.

In addition, when applying a dual reactor building, there is a problem of increased construction costs due to an increase in the equipment and design capacity of the air conditioning system (HVAC), which is additionally required to maintain the annular space between the primary reactor building and the secondary reactor building at negative pressure. there is.

The present invention relates to a double containment system in the penetration part of a nuclear reactor building. More specifically, the double containment is installed in the penetration area where piping and electric cables pass from the nuclear reactor building to surrounding buildings, and the negative pressure and filtration system within the double containment. It relates to a double containment system in the penetrating part of the reactor building that can prevent external leakage of radioactive materials by providing a joint filler in the space between the double containment part and the reactor building wall.

The dual containment system of the reactor building penetrating part of the present invention to solve the above-described problem is a system for containing the reactor building, including the reactor building; A penetrating portion penetrating the wall of the reactor building; It is characterized in that it includes; a double containment part installed on the wall of the nuclear reactor building and surrounding the penetration part on the outside of the penetration part.

In order to solve the above-mentioned problem, a separation space is formed between the wall of the reactor building and the double containment part of the double containment system of the nuclear reactor building penetrating part of the present invention, and a joint filler may be provided in the separation space.

In order to solve the above-described problem, the inside of the double containment portion of the double containment system of the penetrating portion of the reactor building of the present invention may be treated with epoxy lining.

In order to solve the above-mentioned problem, the double containment part of the dual containment system of the reactor building penetrating part of the present invention may be provided with a drain pipe.

The drain pipe of the dual containment system of the reactor building penetrating part of the present invention to solve the above-described problem includes an inlet pipe through which fluid flows in, an outlet pipe through which fluid is discharged, while being connected to the double containment section, and the inlet pipe and the The discharge pipe includes a connecting pipe, and the connecting pipe may be bent into a U shape.

In the dual containment system of the reactor building penetration part of the present invention to solve the above-described problem, the height at which the inlet pipe is installed from the ground may be higher than the height at which the discharge pipe is installed from the ground.

In order to solve the above-mentioned problem, the double containment part of the dual containment system of the penetrating part of the reactor building of the present invention may be provided with a pressure-resistant door.

The dual containment system of the reactor building penetrating part of the present invention to solve the above-described problem may further include a negative pressure and filtration system that supplies air to the double containment or discharges air from the double containment.

The negative pressure and filtration system of the dual containment system of the reactor building penetrating part of the present invention to solve the above-described problem includes an air conditioner that supplies air to the double containment, and air that filters and discharges air from the double containment. It includes a purifier, and as the amount of air discharged from the air purifier becomes greater than the amount of air supplied from the air conditioner, negative pressure may be formed in the double containment unit.

The present invention relates to a dual containment system in the penetration part of a nuclear reactor building. A double containment is installed in the penetration area where piping and electric cables pass from the reactor building to surrounding buildings, and a negative pressure and filtration system is installed in the double containment, There is an advantage in preventing external leakage of radioactive materials by providing a joint filler in the space between the double containment and the reactor building wall.

The present invention has the advantage of improving airtightness through a drain pipe equipped with a U-shaped connector and a pressure-resistant door, and the present invention maintains the inside of the double containment at negative pressure through a negative pressure and filtration system, thereby removing radioactive substances. It has the advantage of preventing external leakage.

The present invention has the advantage of improving economic feasibility by reducing construction costs compared to the double reactor building design while expecting the same effect as the double reactor building design through the double containment, joint filler, negative pressure and filtration system, drain pipe, and pressure-resistant door. .

1 is a diagram showing a dual containment system of a nuclear reactor building penetrating portion according to an embodiment of the present invention.
Figure 2 is a plan view of a double containment system in the penetrating part of a nuclear reactor building according to an embodiment of the present invention.
Figure 3 is a diagram showing that a separation space (Seismic gap) is provided between the wall of the nuclear reactor building and the double containment, and a joint filler is provided in the separation space (Seismic gap) according to an embodiment of the present invention. .
Figure 4 is a diagram showing a drain pipe provided with a U-shaped connection pipe according to an embodiment of the present invention.

This specification clarifies the scope of rights of the present invention, explains the principles of the present invention, and discloses embodiments so that those skilled in the art can practice the present invention. The disclosed embodiments may be implemented in various forms.

Expressions such as “includes” or “may include” that may be used in various embodiments of the present invention refer to the existence of the corresponding function, operation, or component that has been disclosed, and one or more additional functions, operations, or components. There are no restrictions on components, etc. In addition, in various embodiments of the present invention, terms such as "comprise" or "have" are intended to indicate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification. It should be understood that this does not exclude in advance the presence or addition of one or more other features, numbers, steps, operations, components, parts, or combinations thereof.

When a component is referred to as being "connected or coupled" to another component, the component may be directly connected or coupled to the other component, but there is no connection between the component and the other component. It should be understood that other new components may exist. On the other hand, when a component is said to be "directly connected" or "directly coupled" to another component, it will be understood that no new components exist between the component and the other component. You should be able to.

Terms such as first and second used in this specification may be used to describe various components, but the components should not be limited by the terms. Terms are used only to distinguish one component from another.

The present invention relates to a dual containment system in the penetration part of a nuclear reactor building. A double containment is installed in the penetration area where piping and electric cables pass from the reactor building to surrounding buildings, and a negative pressure and filtration system is installed in the double containment, This relates to a double containment system for the penetration part of a nuclear reactor building that can prevent external leakage of radioactive materials by providing a joint filler in the space between the double containment part and the reactor building wall. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings.

The dual containment system of the nuclear reactor building penetration part according to an embodiment of the present invention includes a reactor building 110, a penetration part 120, and a dual containment part 130.

Referring to Figures 1 and 2, the nuclear reactor building 110 is provided with a penetration part 120 through which pipes and electric cables pass. The reactor building 110 consists of a cylindrical wall and a hemispherical dome, and may be a primary reactor building with a prestressed concrete shell structure.

The penetration part 120 penetrates the wall of the nuclear reactor building 110, and equipment 121 related to piping and electric cables is connected to the reactor building 110 through the penetration part 120. (110) Can be extended externally.

Specifically, the nuclear reactor building may be equipped with equipment 121 for supplying electricity inside the reactor building and transporting fluids into and out of the reactor building, and the equipment 121 is connected to the reactor building through the penetration part 120. (110) may extend from the inside to the outside of the reactor building (110).

The double containment portion 130 is installed on the wall of the reactor building 110, and the double containment portion 130 surrounds the penetrating portion 120 from the outside of the penetrating portion 120.

Referring to FIG. 1, the double containment part 130 may be a structure that seals the penetration part 120, and inside the double containment part 130, there is an internal space into which the equipment 121 can be extended. It can be provided.

The double containment 130 may be a structure installed only in the area where the penetration part 120 is formed in the wall of the nuclear reactor building 110, and the double containment part 130 is connected to the area where the penetration part 120 is formed. When installed in an area, it is possible to prevent radioactive materials from leaking to the outside through the penetration part 120.

The double containment portion 130 may be installed only in the area where the penetration portion 120 is formed in the wall of the reactor building 110, and an auxiliary building 10 may be installed outside the reactor building 110. .

Referring to FIGS. 1 and 3, a separation space 141 is formed between the wall of the reactor building 110 and the double containment unit 130, and the separation space 141 is provided with a joint filler 140. It can be.

The separation space 141 is formed between the wall of the reactor building 110 and the double containment unit 130, and the separation space 141 may be a seismic gap.

The separation space 141 is formed for structural separation of the reactor building 110 and the double containment unit 130, and the double containment unit ( 130), it is possible to prevent seismic force from being transmitted.

More specifically, as shown in FIG. 1, the double containment portion 130 may be directly connected to the wall of the reactor building 110 in the area where the penetration portion 120 is formed. In areas other than the area, the separation space 141 may be formed between the reactor building 110 and the double containment unit 130.

Referring to FIG. 3, the space 141 may be filled with the joint filler 140. When the separation space 141 is formed, the reactor building 110 and the double containment unit 130 can be structurally separated, but there is a risk of radioactive materials leaking through the separation space 141.

The joint filler 140 is provided to prevent this, and airtightness can be maintained by filling the space 141 through the joint filler 140. The joint filler 140 may be made of various materials as long as it can airtight the space 141.

The dual containment system of the nuclear reactor building penetrating portion according to an embodiment of the present invention forms the separation space 141 and is provided with the joint filler 140 in the separation space 141, thereby forming the separation space 141 and the reactor building 110. By structurally separating the double containment portion 130, leakage of radioactive materials through the separation space 141 can be prevented.

The inside of the double storage unit 130 according to an embodiment of the present invention may be treated with epoxy lining. The interior of the double containment unit 130 may be epoxy lined to prevent leakage of radioactive materials and improve airtightness.

The double storage unit 130 according to an embodiment of the present invention may be provided with a pressure-resistant door 160. The pressure-resistant door 160 may be a pressure-resistant special door that guarantees airtightness, and the pressure-resistant door 160 may be a pressure-resistant special door (Pressure Resistant Door) that has better airtightness than a general door (hollow-metal door).

The double storage unit 130 according to an embodiment of the present invention may be provided with a drain pipe 150. The drain pipe 150 may be provided at the lower part of the double storage unit 130, and the drain pipe 150 may be a pipe for drainage.

In general, the drain pipes collected into the floor drain sump are designed by setting groups according to the radiation level of each compartment. In the case of penetrations through which electric cables pass, the drain pipes are designed by setting them as a non-radiation management area group, so that in case of an accident, the drain pipes are designed by setting them as a non-radiation management area group. There is a possibility that contaminants may spread from the penetration area through which the cable passes to other non-radiation control areas. In other words, when using a penetration part through which an electric cable passes, there is a risk of contaminants spreading through the drain pipe.

The drain pipe 150 according to an embodiment of the present invention is provided to prevent this, and the drain pipe 150 includes an inlet pipe 151, an discharge pipe 152, and a connection pipe 153.

Referring to FIG. 4, the inlet pipe 151 is connected to the double containment portion 130 and is a pipe through which fluid flows. The discharge pipe 152 is a pipe through which fluid is discharged, and the connection pipe 153 is a pipe connecting the inflow pipe 151 and the discharge pipe 152.

According to an embodiment of the present invention, the connection pipe 153 may be bent into a U shape, and the height at which the inlet pipe 151 is installed from the ground may be higher than the height at which the discharge pipe 152 is installed from the ground. there is.

The drain pipe 150 is made in the form of a trap that can retain part of the fluid. The drain pipe 150 allows part of the fluid to flow through the connection pipe 153, which is in the form of a bending pipe. can stay.

Specifically, as part of the fluid remains in the U-shaped connection pipe 153, the flow of air may be blocked between the inlet pipe 151 and the discharge pipe 152. In addition, as the height at which the inlet pipe 151 is installed above the ground becomes higher than the height at which the discharge pipe 152 is installed above the ground, fluid can be discharged from the inlet pipe 151 to the discharge pipe 152. .

According to an embodiment of the present invention, if there is no drainage through the drain pipe 150 for a long time, the water inside the connection pipe 153 may evaporate and the effect of blocking air may be lost. Therefore, it is desirable to maintain blocking performance by periodically replenishing fluid into the connection pipe 153 through a priming line.

The dual containment system of the reactor building penetrating part according to an embodiment of the present invention includes a negative pressure and filtration system 170 that supplies air to the double containment part 130 or filters and discharges air from the double containment part 130. More may be included.

According to an embodiment of the present invention, when the double containment unit 130 is maintained at negative pressure and discharged through filtration, it is possible to block radioactive materials from leaking to the outside through negative pressure and filtration, and the double containment unit 130 If maintained at negative pressure and discharged through filtration, the same effect as applying a double reactor building can be achieved.

The negative pressure and filtration system 170 is provided to maintain the inside of the double containment unit 130 at negative pressure and filter and discharge it. The negative pressure and filtration system 170 includes an air conditioner 171 and an air purifier ( 172).

Referring to FIG. 2, the air conditioner 171 supplies air to the double containment unit 130, and the air purifier 172 filters the air in the double containment unit 130 and then discharges it. will be. The air conditioner 171 and the air purifier 172 may be an auxiliary building emergency exhaust air conditioner and an auxiliary building emergency exhaust air purifier.

According to an embodiment of the present invention, the amount of air discharged from the air purifier 172 may be greater than the amount of air supplied from the air conditioner 171. The negative pressure and filtration system 170 determines the amount of air discharged from the double containment unit 130 through the air purifier 172 rather than the amount of air supplied to the double containment unit 130 through the air conditioner 171. By increasing , negative pressure can be created in the double containment unit 130, and radioactive materials are filtered and discharged through the high-efficiency particle filter and activated carbon filter in the air purifier 172.

By forming a negative pressure inside the double containment unit 130 through the negative pressure and filtration system 170 and filtering and discharging radioactive materials leaked into the double containment unit 130, the same effect as applying a double reactor building is achieved. By obtaining this, it is possible to block radioactive materials from leaking to the outside.

The dual containment system of the reactor building penetrating portion according to the embodiment of the present invention described above has the following effects.

The dual containment system of the nuclear reactor building penetration part according to an embodiment of the present invention installs a double containment in the penetration area where piping and electric cables pass from the reactor building to surrounding buildings, and installs a negative pressure and filtration system within the double containment. , there is an advantage in preventing external leakage of radioactive materials by providing a joint filler in the space between the double containment and the reactor building wall.

The dual containment system of the reactor building penetrating part according to an embodiment of the present invention has the advantage of improving airtightness through a drain pipe and pressure-resistant door provided with a U-shaped connecting pipe.

The double containment system in the penetrating part of the reactor building according to an embodiment of the present invention maintains the inside of the double containment at negative pressure through a negative pressure and filtration system, and filters and discharges the air in the double containment to prevent radioactive materials from leaking to the outside. There is an advantage to preventing it.

The dual containment system of the nuclear reactor building penetrating part according to an embodiment of the present invention is expected to have the same effect as the double reactor building design through the double containment, joint filler, negative pressure and filtration system, drain pipe, and pressure-resistant door, but has lower construction costs compared to the double reactor building design. It has the advantage of improving economic efficiency by reducing costs.

The dual containment system in the penetrating part of the reactor building according to an embodiment of the present invention significantly improves economic efficiency without significantly compromising safety compared to a dual reactor building through a double containment, joint filler, negative pressure and filtration system, drain pipe, and pressure-resistant door. There is an advantage to being able to do it.

As such, the present invention has been described with reference to an embodiment shown in the drawings, but this is merely illustrative and those skilled in the art will understand that various modifications and variations of the embodiment are possible therefrom. . Therefore, the true scope of technical protection of the present invention should be determined by the technical spirit of the attached patent claims.

110...reactor building 120...penetration part
121...equipment 130...double containment
140... joint filler 141... separation space
150...drain pipe 151...inlet pipe
152...discharge pipe 153...connector pipe
160...pressure-resistant door 170...negative pressure and filtration system
171...Air conditioner 172...Air purifier

Claims (9)

In the system for containing the nuclear reactor building,
nuclear reactor building;
A penetrating portion penetrating the wall of the reactor building;
It includes a double containment part installed on the wall of the reactor building and surrounding the penetration part from the outside of the penetration part,
A separation space is formed between the wall of the reactor building and the double containment,
A double containment system for the penetrating part of the nuclear reactor building, characterized in that the separation space is provided with a joint filler. delete According to paragraph 1,
A double containment system in the penetrating part of a nuclear reactor building, characterized in that the inside of the double containment is treated with epoxy lining. According to paragraph 1,
A double containment system in the penetrating part of a nuclear reactor building, characterized in that the double containment part is provided with a drain pipe. According to clause 4,
The drain pipe is,
It is connected to the double containment unit and includes an inlet pipe through which fluid flows in, an outlet pipe through which fluid is discharged, and a connection pipe connecting the inlet pipe and the discharge pipe,
A double containment system in the penetrating part of the nuclear reactor building, wherein the connector is bent into a U shape. According to clause 5,
A double containment system in the penetrating part of a nuclear reactor building, characterized in that the height at which the inlet pipe is installed from the ground is higher than the height at which the discharge pipe is installed from the ground. According to paragraph 1,
A double containment system in the penetrating part of a nuclear reactor building, characterized in that the double containment part is provided with a pressure-resistant door. According to paragraph 1,
A dual containment system in the penetrating portion of a nuclear reactor building, further comprising a negative pressure and filtration system that supplies air to the double containment or discharges air from the double containment. According to clause 8,
The negative pressure and filtration system is,
It includes an air conditioner that supplies air to the double containment unit, and an air purifier that filters and discharges air from the double containment unit,
A double containment system in the penetrating part of a nuclear reactor building, wherein the amount of air discharged from the air purifier is greater than the amount of air supplied from the air conditioner, thereby creating negative pressure in the double containment section.

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