KR20210156609A - System decontamination facilities - Google Patents

Abstract

According to an embodiment of the present invention, a system decontamination facility comprises: a nuclear reactor; a cooling system connected to the nuclear reactor and including a steam generator; and a decontamination device connected to the cooling system. The decontamination device comprises: a compression pump for injecting compressed air into the cooling system; a steel bead supply device that supplies a steel bead, which is inputted together with compressed air; and a pair of strainers spaced apart from each other when they are installed in the cooling system.

Description

SYSTEM DECONTAMINATION FACILITIES

The present invention relates to a system decontamination facility, and more particularly, to a system decontamination facility for decontamination of a primary system when a nuclear power plant is dismantled.

Nuclear power plants generate heat by artificially controlling chain fission reactions of fissile materials in a nuclear reactor, production of radioactive isotopes and plutonium, or formation of a radiation field.

A nuclear power plant consists of a system with many individual functions centered on the reactor, for example, the reactor coolant system (reactor pressure vessel, steam generator, pressurizer, main piping, etc.), chemical and volume control system, residual heat removal system, etc.

Radioactive substances exist in these systems, and workers may be exposed to radiation.

Therefore, immediately after the permanent shutdown of the nuclear power plant, in order to reduce the radiation exposure of the dismantling workers due to radioactive substances and to secure the easiness of dismantling and dismantling the power plant in advance, it is necessary to perform chemical system control on the entire system contaminated with radioactivity. there is

However, if chemical decontamination is not completely performed or the thickness of the oxide film formed on the inner wall of the system is thick, the oxide film is not completely removed, so the reduction in radioactivity concentration is not significantly reduced.

Accordingly, an object of the present invention is to provide a system decontamination facility capable of more effectively decontamination of the entire system when dismantling a nuclear power plant.

The system decontamination facility according to an embodiment of the present invention includes a nuclear reactor, a cooling system connected to the nuclear reactor and including a steam generator, and a decontamination device connected to the cooling system, wherein the decontamination device injects compressed air into the cooling system a compression pump, a steel ball supply device for supplying a steel ball introduced together with compressed air, and a pair of strainers spaced apart from each other when installed in the cooling system.

The compression pump is connected to the first part of the cooling system and the second part of the cooling system to inject the compressed air from different parts, and the first part is in the same direction as the flow of the fluid flowing through the cooling system, The second portion may be in a direction crossing the flow of the fluid.

It may further include a venturi connected between the compression pump and the first part of the cooling system.

The first part may be located outside the decontamination pipe positioned between the strainers, and the second part may be connected to a sidewall of the decontamination pipe.

The steel ball may include a metal bead, a chemical layer formed on the metal bead.

The metal beads may be made of steel balls or cast steel balls, and the chemical layer may include at least one of potassium permanganate, oxalic acid, and fluoroboric acid (HBF4).

The diameter of the steel ball may be 10mm ~ 30mm.

It may include a high-temperature tube connected between the nuclear reactor and the steam generator, and a low-temperature tube connected between the steam generator and the nuclear reactor and including a cooling pump.

The low-temperature tube may be connected in plurality.

The cooling system is connected in plurality, and any one series of cooling systems may further include a pressurizer.

According to an embodiment of the present invention, when a nuclear power plant is dismantled, by inserting a steel ball into the entire system, the flow inside the pipe is promoted to increase the wear effect of the oxide film, and at the same time, the inner film is constantly maintained due to the abnormal flow inside the pipe. to allow it to be removed.

1 is a schematic configuration diagram of a system decontamination facility according to an embodiment of the present invention.
FIG. 2 is a schematic configuration diagram of the decontamination apparatus included in FIG. 1 .

Hereinafter, with reference to the accompanying drawings, the embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them. The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

1 is a schematic configuration diagram of a system decontamination facility according to an embodiment of the present invention.

As shown in FIG. 1 , the system decontamination apparatus 300 according to an embodiment of the present invention may be connected to a nuclear reactor 100 and a cooling system connected to the nuclear reactor 100 .

The nuclear reactor 100 is located in a containment unit (not shown), and generates thermal energy by nuclear fission. In addition to the cooling system 200 , the nuclear reactor 100 may further include a chemical and volume control system for normal operation and various safety systems (not shown) for securing the safety of the nuclear power plant.

The cooling system absorbs reaction heat generated in the nuclear reactor 100 and cools the cooling water supplied from the water supply system (not shown) while circulating. The cooling system may be formed in plurality, and includes a cooling system of one series including a steam generator 10 and a pump 20, respectively, and a cooling system of another series, and each first cooling system ( CS1) and the second cooling system (CS2).

The first cooling system CS1 includes a high-temperature pipe H1, a steam generator 10, a pump 20, and a low-temperature pipe H2, and forms a circulation structure in which the coolant circulates, and the second cooling system CS2 ) includes a high-temperature pipe (H3), a steam generator (V2), a pump (CP2), and a low-temperature pipe (H4), and forms a circulation structure in which the coolant circulates. A plurality of low-temperature pipes H2 and H4 of the first cooling system CS1 and the second cooling system CS2 may be connected.

The thermal energy generated in the nuclear reactor 100 increases the temperature of the cooling water, and the high temperature cooling water passes through the high temperature pipes H1 and H3 and is supplied to the steam generator 10 .

The steam generator 10 forms a boundary between a primary fluid (reactor coolant) and a secondary fluid (feedwater, steam), and generates steam using heat transferred to the reactor 100 . The lower inlet of the steam generator 10 may be connected to a water supply system (not shown) by a water supply pipe, and the upper outlet of the steam generator may be connected to a turbine system (not shown) for power generation by a steam pipe.

The coolant cooled while passing through the steam generators V1 and V2 is then returned to the reactor 100 through the reactor coolant pumps CP1 and CP2 through the low-temperature pipes H2 and H4, thereby circulating the coolant.

A pressurizer 12 may be further installed in the first cooling system CS1. The pressurizer 12 maintains a pressurized state exceeding the saturation pressure in order to suppress boiling of the coolant.

The decontamination apparatus 300 is attached to the inner wall of various systems connected to the nuclear reactor 100, for example, the reactor coolant system (reactor pressure vessel, steam generator, pressurizer, main piping, etc.), chemical and volume control system, and residual heat removal system. Remove oxides.

The decontamination apparatus 300 may be selectively connected to a pipe for performing decontamination, for example, it may be connected to a pipe connecting between the steam generator 10 and the coolant pump 20 . Hereinafter, a pipe connecting between the steam generator 10 and the coolant pump 20 is referred to as a decontamination pipe 30 .

FIG. 2 is a schematic configuration diagram of the decontamination apparatus included in FIG. 1 .

As shown in FIG. 2 , the decontamination apparatus 300 includes a compression pump 31 , a steel ball feeder 32 , a venturi 33 and a strainer 34 .

The compression pump 31 is for injecting compressed air into the decontamination pipe 30 , and may be connected to the first part A and the second part B of the decontamination pipe 30 .

The first part (A) is for injecting compressed air in the same direction as the direction in which the fluid flows, and may be the front end of the decontamination pipe 30 . The second part (B) is for generating turbulence of the fluid in the decontamination pipe 30 , and may be supplied in a direction crossing the fluid flow in the decontamination pipe 30 . Accordingly, the second portion (B) may be a side portion of the decontamination pipe (30).

The steel ball supply device 32 is for supplying the steel balls, and may be delivered to the venturi 33 through a hopper (not shown), and may be introduced into the decontamination pipe 30 together with compressed air.

The steel ball 35 includes metal beads 3 made of iron or the like, and a chemical layer 5 formed on the metal beads 3 .

The steel ball 35 is a sphere made of iron and may have a size of about 10 mm to 30 mm. The chemical layer 5 may include at least one of potassium permanganate, oxalic acid, and fluoroboric acid (HBF _{4 ).}

The steel ball 35 moves randomly and actively in the decontamination pipe 30 due to the compressed air injected together, collides with the inner wall of the decontamination pipe 30, and a film formed on the inner wall of the decontamination pipe 30, for example, an oxide film and It collides so that the oxide film can be easily separated from the decontamination pipe 30 .

In addition, the chemical layer 5 formed on the outside of the steel ball 35 is a material for chemical decontamination, and may be a material that reacts with a radioactive material contained in the fluid in the decontamination pipe 30 .

In the chemical layer 5, as the chemical layer 5 outside the steel ball is primarily worn during friction due to the flow of the steel ball in the pipe, the chemical component contained in the chemical layer 5 acts simultaneously with the friction of the steel ball in the pipe. It can effectively remove the base metal and oxide film.

The venturi 33 is to give a venturi effect to the compressed air, and the diameter of the portion connected to the decontamination pipe 30 is smaller than that of the portion connected to the compression pump 31 .

On the other hand, a strainer 34 may be installed in the decontamination pipe 30 , and the strainer 34 is installed on both sides of the pipe to be decontaminated, respectively, and the decontamination pipe 30 is between the strainers 34 .

The strainer 34 is to prevent the steel ball 35 flowing into the decontamination pipe 30 from moving to an area other than the decontamination pipe 30, and is installed after the steel ball 35 is introduced into the decontamination pipe 30 can be

The strainer 34 is installed at both ends where large devices (coolant pumps, pressurizers, etc.) are removed first, or when decontamination is required before dismantling large devices, a pipe decontamination area is set and a penetration part (not shown) is made in a part of the pipe to make a strainer ( 34) can be installed.

When the decontamination using the steel ball in the decontamination pipe 30 is completed, after the steel ball is discharged together with the fluid in the decontamination pipe 30, only the steel ball can be separated and reused.

In the above, preferred embodiments of the present invention have been described, but the present invention is not limited thereto, and various modifications can be made within the scope of the claims, the detailed description of the invention, and the accompanying drawings. It is natural to fall within the scope of

3: Metal beads 5: Chemical layer
10: steam generator 20: cooling pump
30: decontamination piping 31: compression pump
32: steel ball feeding device 33: venturi
34: strainer 100: reactor
300: decontamination device

Claims (10)

nuclear pile,
A cooling system connected to the reactor and including a steam generator,
It includes a decontamination device connected to the cooling system,
The decontamination device is a compression pump for injecting compressed air into the cooling system,
A steel ball supply device for supplying a steel ball introduced together with the compressed air,
A pair of strainers spaced apart from each other when installed in the cooling system
A system decontamination facility comprising a. In claim 1,
The compression pump is connected to the first part of the cooling system and the second part of the cooling system to inject the compressed air from different parts,
The first part is in the same direction as the flow of the fluid flowing through the cooling system,
The second portion is a system decontamination system in a direction that intersects with the flow of the fluid. In claim 2,
The system decontamination plant further comprising a venturi connected between the compression pump and the first portion of the cooling system. In claim 2,
The first part is located outside the decontamination pipe located between the strainers,
The second part is a system decontamination system connected to the side wall of the decontamination pipe. In claim 1,
The steel ball is a metal bead,
a chemical layer formed over the metal beads
A system decontamination facility comprising a. In claim 5,
The metal beads are made of iron,
The chemical layer is at least one of potassium permanganate, oxalic acid, and fluoroboric acid (HBF4).
A system decontamination facility comprising a. In claim 1,
The diameter of the steel ball is 10mm ~ 30mm system decontamination equipment. In claim 1,
a high-temperature tube connected between the reactor and the steam generator;
a cryogenic tube connected between the steam generator and the nuclear reactor and including a cooling pump;
A system decontamination facility comprising a. In claim 8,
The low-temperature pipe is a system decontamination facility connected in plurality. In claim 1,
In the cooling system, a plurality of cooling systems are connected, and any one series of cooling systems is a pressurizer.
A system decontamination system further comprising a.

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