KR100329105B1 - Transporting and separating method of CRUD at Nuclear Power Plant - Google Patents

Abstract

The present invention is made as part of the radiation exposure measures when construction or repair, such as regular inspection of nuclear power plants. In various pipes directly or indirectly connected to the reactor pressure vessel of a nuclear power plant, the corrosion products due to general corrosion are radiated by neutron flux, and a substance with high radiation called CRUD (Chalk River Unidentified Deposit) is generated. In the case of repair or maintenance work in the vicinity of these deposits, the worker is in a very dangerous working environment under high radiation. Therefore, there is a need for means capable of reducing radiation exposure from the clad in advance during periodic inspection or retrofit work. Therefore, in the present invention, focusing on the fact that the clad is generally composed of fine particles including 50-70% of the magnetic particles, the clad accumulated in the pipe portion and the like that can be connected to the reactor pressure vessel in order to reduce the worker exposure In order to transfer by crossing magnetic movements, the progressive magnetic field excitation by alternating current is used among several methods for implementing this.

Description

Transport and separating method of CRUD at Nuclear Power Plant

The present invention relates to a method for transporting the clad to reduce the radiation exposure generated when the improvement work, such as regular inspection work of nuclear power plants. Flow of coolant such as horizontal parts of various pipes directly or indirectly connected to the reactor pressure vessel in a nuclear power plant, plates connected to nuclear pipes, safe end nozzles to which the pipes of the recirculation system are connected, and cavities between the silic sleeves installed in the nozzle This slow place is called the CRUD (Chalk River Unidnetified Deposit), which generates highly radioactive materials. When repairing or preserving near such deposits, the worker is very dangerous under high radiation. Put it in the environment. Therefore, it is required to make a means to reduce the radiation exposure from the clad in advance during the periodic inspection work or improvement work.

Radiation corrosion products (crudes) in a nuclear power plant are produced by the normal corrosion of structural materials in the primary system, which are then converted into highly radioactive material by radiation by neutron flux. Current methods for reducing this include chemical methods of adjusting pH and methods of using better structural materials. In other words, the method of suppressing the generation is mainly used, and the generated creed performs the purification function by filtering and ion exchanger in the chemical and volume system in the case of pressurized water reactor, but the function is not performed for the particle type creed. Incomplete In order to compensate for this, a fine filter is used, but it is difficult to continue using it because of the differential pressure.

FIG. 1 is a schematic view for explaining a method of reducing radiation exposure according to the prior art. As shown in FIG. 1, a welded portion of a safe end nozzle b protruding from a furnace wall of a reactor pressure vessel a may be regularly inspected. In this case, a ring-shaped lead shield (d) is built in the inner side of the smal sleeve (c) or the safe end nozzle (b), and the bio-shielding portion (e) is sealed with lead and the pack (f) is used. By completely sealing, it is necessary to reduce the radiation exposure from the clad accumulated in the cavity g between the safe end nozzle b and the simul sleeve c. Moreover, in the case of nuclear power plants, it is difficult to cut more than necessary, so it is virtually impossible to transfer the clad by external air or mechanical method. However, in the case where a shield other than lead is installed outside the structure in which the clad is accumulated as described above, the exposure dose of the contractor engaged in the construction of the shield is too high, and the heavy load is handled, so the risk is high and the handling work is performed. The number will grow. In addition, in the case of installing the blocker, the construction period must be lengthened, and the cost of the installation work and the demolition work is high. In addition, since the shape of the blocking body is determined, it is difficult to use it in other forms, and there is a problem of managing or storing the blocking body after construction. In addition, since the installation of a fairly thick lead to suppress the radiation dose there is a problem that the work space is narrowed, causing problems in the work.

Accordingly, an object of the present invention is to provide a method of transporting a clad in a nuclear power plant that maximizes the effect of reducing exposure by moving the clad by magnetic force.

1 is a schematic view for explaining a radiation exposure reduction method according to the prior art,

FIG. 2 is a schematic diagram for explaining a process of transferring a stacked stack between a safe end nozzle and a simul sleeve by using a cradle transfer method in a nuclear power plant according to an embodiment of the present invention;

3 is a conceptual diagram illustrating a magnetic field progress situation of the method illustrated in FIG. 2;

4 is a schematic diagram for explaining a process of transferring the clad accumulated in the horizontal portion of the pipe connected to the reactor pressure vessel by using the crude conveying method in a nuclear power plant according to an embodiment of the present invention,

5 is a schematic diagram for explaining the structure of the excitation main body shown in FIG.

6 is a cross-sectional view taken along the line A-A of the excitation main body shown in FIG.

Fig. 7 is a schematic diagram of the main body of the exciter by arranging the iron core of the exciter in a spiral form.

<Description of the symbols for the main parts of the drawings>

1. Reactor pressure vessel 2. Safe end nozzle

3. Simul sleeve 4, 12. Body of magnetic field exciter by alternating current

5. Power Unit 9. Cred

10. Direction of Cladding 11. Piping

The method of the present invention for achieving the above object is a cavity between a lower end of a horizontal pipe connected to the reactor pressure vessel, or a safe end nozzle connected to the piping of the recirculation system and a symmetric sleeve installed inside the nozzle. A method of conveying a clad having a property such as magnetic and nonmagnetic, which is deposited in a method, comprising the steps of: providing an exciter in a coaxial direction around a periphery of the horizontal pipe or inside the simul sleeve; Generating an alternating magnetic field by supplying an excitation current to the exciter, and sequentially driving the alternating magnetic field along a surface of the horizontal pipe or an inner surface of the simul sleeve to lower the surface of the horizontal pipe or the And conveying the deposited deposits to the cavity. As such, the present invention provides for the active removal of generated In view of the fact that a substantial amount of the clad can be separated by magnetism, the method can be applied to separate and transport the clad, which is applicable to high temperature and high capacity as compared to other separation and transfer methods. Embodiments will be described in the drawings. Although the present invention can be implemented in various ways, first, an example using an advanced magnetic field excitation by AC will be described.

FIG. 2 is a schematic diagram illustrating a process of transferring a stacked stack between a safe end nozzle and a simul sleeve by using a cradle transfer method in a nuclear power plant according to an embodiment of the present invention, and FIG. 3 is shown in FIG. Is a conceptual diagram to explain the progress of the magnetic field of the proposed method. As shown in FIG. 2, the safe end nozzle 2 is installed on the furnace wall of the reactor pressure vessel 1, and the safe end nozzle 2 has a hay-panel nozzle due to the temperature difference between the water and the cooling water. There is a built-in simulle sleeve 3 for mitigating the thermal effect. The magnetic field excitation main body 4 by alternating current is inserted in the symmetric sleeve 3. Then, the power supply device 5 of the excitation main body 4 is installed at a predetermined distance from the reactor pressure vessel 1, and the excitation main body 4 and the power supply device 5 are connected by an electric wire 6, thereby simul In the sleeve 3, a traveling magnetic field is formed by three-phase alternating current used in a linear motor or the like. In order to transfer the accumulated cladding between the safe end nozzle 2 and the simul sleeve 3, the magnetic effective range 7 of the excitation main body 4 is provided between the simul sleeve 3 and the safe end nozzle 2. After adjusting to the expected distribution position of the cladding 9 accumulated in the cavity 8, check the phase of the primary power supply (AC2000V3Φ) in the power supply device 5 in the connection phase rotation meter, and then set the voltage adjustment scale to '0'. Turn on the Fuse Brake (NFB) and operate the voltage regulator to supply the current to the excitation main body (4), which keeps the excitation main body (4) in motion and keeps it energized. . When connecting the power supply unit 5 to the excitation main body 4, care must be taken to match the three phases together so that the traveling direction of the magnetic field is aligned with the feed direction of the cradle (indicated by 10 in Fig. 3). In the opposite case, the movement of the clad 9 is reversed, and the amount of ambient radiation at the work site is significantly increased, which causes adverse effects.

However, the magnetic field proceeding by alternating current moves sequentially along the direction of travel as shown in FIG. 3, and unlike the direct current magnetic field, simply generates a magnetic field in the magnetic body to form an alternating magnetic field, and also impacts a stationary object. Since it is easy to carry out, it is possible to promote the movement of the non-magnetic material α-hematite in the clad 9 and to move weakly acidic particles and magnetic particles γ-hematite, magnetite, etc. More than 70-80% of the clad moves in the direction of travel (10). 4, 5 and 6 show an embodiment in the case of transporting the accumulated clad on the lower surface of the horizontal piping of the nuclear power plant 1, secondary system, the excitation main body 12 to the reactor pressure vessel (1) In this case, the excitation main body 12 is divided in the axial direction (three divisions in Fig. 5) to lighten the weight per one, and the divided excitation main bodies 12a and 12b. , 12c) by connecting the connection line 13 in phases and dividing each excitation main body 12a, 12b, 12c in the circumferential direction, so as to surround the pipe 11 at the same time and divide each of them. Side is connected by a connecting line (14). Then, the three-phase current having a predetermined phase is supplied to each of the excitation main bodies 12a, 12b, and 12c than the power supply device to move the clad 9 accumulated in the pipe 11 with the progress of the magnetic field.

In FIG. 4, reference numeral 17 denotes a living body shield, 18 denotes a jet pump holder, and 19 denotes a core. FIG. 7 is a schematic diagram of the excitation body arranged in a spiral shape and configured to form an excitation main body. In the excitation main body of FIG. 7, the iron core 16 wound around the coil 15 is arranged in a spiral shape so that the cladding is performed. It is configured to be transported along the inner circumferential surface, the excitation main body can be applied in any case, such as the input method, the external installation type described above.

In the above, an example of a flat-phase traveling magnetic field that relies on three-phase alternating current used in linear motors and the like as a method of magnetic conveyance of the clad has been described. It is possible to feed the crude by this.

Peeling and moving of the clad are most easily carried out in a state where the clad is immersed in water.

In addition, when the clad is immersed in water, ultrasonic waves may be used, or when the clad is not immersed in water, mechanical vibration may be used to facilitate peeling and movement of the clad.

In the nuclear power plant according to the present invention, the method of transporting a cradle forms a magnetic field through alternating current, thereby transferring the cradle, thereby providing a clear effect of reducing exposure. In addition, the device used in the present invention is small in volume, the work space is wide, the construction is simple, the exposure of the construction worker is small, the work cost is low. In addition, the device used in the present invention can reduce the storage space after construction, and because the alternating magnetic field is advanced, it is possible to easily transfer the crude material even in weak magnetic materials.

Claims (1)

It is deposited on the lower surface of the horizontal pipe connected to the reactor pressure vessel or the cavity between the safe end nozzle to which the pipe of the recirculation system is connected and the simul sleeve installed inside the nozzle. In the method of transferring the RUD (CRUD; Chalk River Unidnetified Deposit), Providing an exciter in a coaxial direction in the circumference of the horizontal pipe or in the inside of the simul sleeve, and supplying an excitation current to the exciter to generate an alternating magnetic field; And moving the alternating magnetic field sequentially along the surface of the horizontal pipe or the inner surface of the symal sleeve to transfer the clad deposited on the lower surface or the cavity of the horizontal pipe. Way.