KR102069738B1 - Apparatus for preventing radiation exposure of an inspection apparatus of a calandria - Google Patents

Abstract

The present invention relates to a device for preventing radiation coating of the calandria internal structure inspection equipment that can perform visual inspection by inserting a measuring device for inspecting the internal structure through the observation hole provided in the calandria container, the internal structure of calandria A device for preventing radiation exposure of a system for inspecting a test apparatus by inserting it into a observation hole (VP) provided in a calandria container (10) and moving up and down in a vertical direction, wherein the observation hole (VP) of the calandria container (10) A chamber 500 provided at an upper part and provided in a transfer section of the rod part 200 at which the measuring device 100 is fixed at a lower end thereof; And a vacuum source 610 connected to the chamber 500 to generate a negative pressure.

Description

Apparatus for preventing radiation exposure of an inspection apparatus of a calandria}

The present invention relates to a device for preventing the radiation coating of the calandria internal structure inspection equipment capable of performing a visual inspection by inserting a measuring device for inspecting the internal structure through the observation hole on the top of the calandria container.

In general, the pressurized heavy water reactor is a reactor that uses heavy water as a coolant and a moderator. The CANDU model developed in Canada is representative, and Wolsong 1,2,3,4 are used in Korea.

Unlike pressurized water reactors (pressurized water reactors and boiling water reactors) using 2-5% low enriched uranium, pressurized heavy water reactors use unconcentrated natural uranium (about 0.7% of U-235) and are used as coolants and moderators. Heavy water absorbs almost no neutrons compared to ordinary water, so there is little loss of neutrons, so natural uranium is used as nuclear fuel.

On the other hand, the light water reactor replaces nuclear fuel after stopping the reactor, while the pressurized heavy water reactor uses 380 horizontal cylinder-shaped fuel pipes to replace the fuel during operation.

Specifically, the pressurized deuterium reactor has a cylindrical vessel called Calandria installed in the horizontal direction, and 380 pressure tubes of about 10 cm in diameter are also penetrated in the horizontal direction. Nuclear fuel is supplied in a pressure tube in the form of a fuel bundle, and a single fuel tube is usually configured to supply 12 fuel assemblies.

As the service life of heavy reactors increases, the necessity of directly inspecting the internal structure of the reactor is increasing, and the development of a device capable of directly inspecting the inside of the reactor is required.

In addition, the heavy water reactor is a structure that cannot be inspected during operation, and can be inspected internally when it is removed to replace the calandria tube and the pressure tube for the improvement of the facility. Visual inspection is performed through the observation hole on top of the Calandria vessel to verify the integrity of the internal structure without removing the dry and pressure tubes. Accordingly, there is a demand for the development of visual inspection equipment for inspecting the internal structure of the Calandria container, which has a high-level radiation environment and a complicated structure without the previously developed equipment.

1 is a view schematically showing a reactor structure of a general pressurized water reactor.

Referring to FIG. 1, a general pressurized heavy water reactor is provided with a calandria tube (CT) 20 horizontally in a cylindrical calandria vessel 10, and a pressure tube is installed inside the calandria tube 20. It is loaded with nuclear fuel and operated.

In addition, many tubes are installed in the calandria vessel 10 in addition to the calandria tube 20 in the horizontal or vertical direction, and in particular, the safety injection reactor (LIN) of the safety system is in the horizontal direction. It is installed at right angles to the tube (20).

The horizontally installed calandria tube 20 sag due to tissue growth and creep in the material due to stress, radiation, etc. as the operation history of the power plant increases. In this case, the calandria tube 20 may be in contact with the reactor stop material injection tube, which may affect the safe operation of the power plant. Therefore, there is a need to identify the distance between the calandria tube and other tubes (especially the injection tube) in the reactor in an appropriate manner during the lifetime of the reactor.

Conventionally, the distance between the calandria tube and the reactor stop material injection tube has been proposed to measure directly or indirectly, for example, a method using a reactor stop material injection tube, horizontally arranged between the calandria pipe. The method of using a horizontal neutron flux detector (Horizontal Flux Detector), the method of using a vertical flux flux (Vertical Flux Detector), or the method of using a viewing port (VP).

Observation holes (VPs) are used for internal observation in two places perpendicular to the upper part of the calandria, and during the initial operation of the reactor, a start-up unit including a neutron source is inserted. It is a hole and there is no use after that. Therefore, the method through the observation hole (VP) can be directly measured while minimizing preliminary work such as site design change or neutron flux detector, which is advantageous in terms of convenience, economical efficiency and other reliability.

However, when the measuring instrument is inserted through the observation hole (VP) and the inspection is carried out, the depth is more than 10 meters and it is not easy to insert the measuring instrument stably. If it remains inside, it cannot be recovered and can seriously affect the operation of the reactor.

Therefore, to inspect the internal structure through the observation hole (VP) it is very important to minimize the risk of such accidents to prevent safety accidents to perform a stable inspection.

Publication No. 10-2014-0042009 (published date: 2014.04.07)

The present invention provides a calandria internal structure inspection equipment for inspecting the calandria internal structure of the pressurized water reactor by using a measuring instrument (VP) on the upper part of the calandria container, through a measuring device, to prevent radiation exposure of the worker during operation. It is to provide a device (hereinafter also abbreviated as "radiation coating prevention device") that can be.

In the radiation exposure preventing apparatus according to the present invention for achieving the above object, in the radiation exposure prevention device of the system for inspecting by lifting up and down in the vertical direction by inserting the calandria internal structure inspection device into the observation hole provided in the Calandria container, A chamber provided at an upper portion of the callandria container in which the observation hole is located and provided in a transport section of the rod part in which the measuring device is fixed to the lower end, and a space formed to block the outside; It includes a vacuum source for generating a negative pressure inside the chamber.

Preferably, the chamber, the first chamber for blocking the outflow of radioactive heavy water; And a second chamber partitioned from the first chamber, under which a negative pressure by the vacuum source acts.

More preferably, the first chamber includes an inverted cone-shaped blocking block surrounding the outer circumferential surface of the rod portion.

The radiation exposure prevention apparatus of the present invention includes a chamber which is located in the upper portion of the callandria container in which the observation hole is located and is provided in the transport section of the rod portion, and a vacuum source connected to the chamber to generate negative pressure. There is an effect to prevent the operator from being exposed to high-level radiation by preventing the radioactive heavy water from being released to the outside during the lifting, in particular the withdrawal of the rod.

1 is a schematic view showing the structure of a calandria reactor in a general pressurized water reactor,
2 is an overall configuration diagram of a callandria internal structure inspection equipment equipped with a radiation exposure prevention apparatus according to the present invention,
Figure 3 is an enlarged configuration of the main portion of the radiation exposure preventing apparatus according to the present invention.

Specific structural or functional descriptions presented in the embodiments of the present invention are only illustrated for the purpose of describing the embodiments according to the inventive concept, and the embodiments according to the inventive concept may be implemented in various forms. In addition, it should not be construed as limited to the embodiments described herein, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

Meanwhile, terms such as first and / or second in the present invention may be used to describe various components, but the components are not limited to the terms. The above terms are for the purpose of distinguishing one component from other components only, for example, within the scope not departing from the scope of rights according to the concept of the present invention, the first component may be named as the second component, Similarly, the second component may also be referred to as the first component.

When a component is referred to as being "connected" or "connected" to another component, it is to be understood that the component may be directly connected or connected to that other component, but other components may be present in between. something to do. On the other hand, when a component is said to be "directly connected" or "directly contacted" to another component, it should be understood that no other component exists in the middle. Other expressions for describing relationships between components, such as "between" and "immediately between" or "adjacent to" and "directly adjacent to", should likewise be interpreted.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. The terms "comprises" or "having" herein are intended to indicate that there is a feature, number, step, action, component, part, or combination thereof that is implemented, and that one or more other features or numbers, It is to be understood that it does not exclude in advance the possibility of the presence or addition of steps, actions, components, parts or combinations thereof.

Hereinafter, with reference to the accompanying drawings will be described a specific embodiment of the present invention.

Figure 2 is an overall configuration of the apparatus for inspecting the internal structure of the Kalandria equipped with a radiation exposure preventing apparatus according to the present invention.

Referring to FIG. 2, the calandria internal structure inspection equipment includes a measurement device 100, a rod part 200 to which the measurement device 100 is fixed at a lower end thereof, and a vertical drive for lifting up and down the rod part 200. It is connected to the chamber 500 and the chamber 500 provided in the transport section of the means 300, 400, the rod portion 200 provided on the upper part of the Kalandria container 10 in which the observation hole VP is located. And a vacuum source generating negative pressure.

The measuring device 100 may include a camera for visually inspecting the internal structure, a laser distance measuring unit for calculating a distance of a target object, a lighting device, and the like. Protected by lead glass or the like, the signal can be transmitted by the shielded cable 110 for the noise effect of the transmission signal due to radioactivity.

The rod part 200 may be a rod of a rigid body capable of vertically moving by supporting the measuring device 100 provided at a lower end thereof. The rod part 200 may be manipulated vertically by vertical driving means provided on the upper part of the Calandria container 10. This is done.

Meanwhile, the rod part 200 may be a pipe in which a hollow receiving hole is formed, and a cable 110 for transmitting an electric signal of a measuring device in the measuring device 100 or power for driving an electric machine may be received therein. Can be. The cable 110 may be drawn out along the rod part 200 and connected to a controller including a monitor.

On the other hand, the rod 200 may be composed of a plurality of unit rods that can be connected to each other in multiple stages by the fastening member. Preferably, the stopper 210 protrudes in the horizontal direction on the top of the rod part 200.

The stopper 210 is for preventing the rod 200 from falling freely and falling down into the calandria container 10 due to an undesired situation. The stopper 210 is provided within the transport section of the rod 200. The stopper 210 may be provided with a drop preventing means capable of supporting the stopper 210 so that the stopper 210 filters the fall preventing means when the rod part 200 freely falls to prevent the rod part 200 from falling. In this embodiment, the chamber 500 has a hole through which the rod part 200 passes, and the hole is smaller than the size of the stopper 210, and thus the chamber 500 may function as a drop preventing means.

The vertical driving means 300 includes at least two clamps 310 and 320 for fixing the rod part 200 and a first driving part for raising and lowering the clamps 310 and 320.

In this embodiment, the clamps 310 and 320 are composed of a first clamp 310 and a second clamp 320 provided at a lower end of the first clamp 310, and the first clamp 310 and the second clamp. 320 is fixed to the clamp transfer block 330, the vertical movement of the clamp transfer block 330 is made by the first drive. The first clamp 310 and the second clamp 320 may be a clamp having the same structure that can be attached or detached, or may be a known clamp having a structure with each other.

The first driving part and the body portion 341, the screw 342 is installed vertically to the body portion 341 and can be rotated to raise and lower the clamp transfer block 330 in accordance with the rotation direction, and the screw 342 It includes a drive motor (343) for rotating or reverse rotation, and may further include a bearing 344 for supporting the rotational movement of the screw (342).

In addition, the vertical driving unit 400 may further include a second driving unit 412 for rotationally driving a wheel for winding or unwinding the wire 411, and the second driving unit 412 It can be provided by a well-known electric motor capable of forward or reverse rotation driving. In addition, one or a plurality of pulleys 413 may be provided to guide the winding direction of the wire 311.

The chamber 500 is provided on the upper part of the calandria container 10 in which the observation hole VP is positioned to form a negative pressure therein by a vacuum source, thereby effectively removing radioactive substances that may be emitted to the outside through the observation hole VP. can do.

The chamber 500 may be directly seated on the upper part of the Calandria container 10, or may be provided at an appropriate position in the transfer section of the rod part 200 on the upper part of the Calandria container 10. In this embodiment, the chamber 500 is illustrated above the plate 345 in which the first driving unit and the other structures are installed.

The vacuum source may generate a negative pressure inside the chamber 500, and may be provided by a well-known vacuum pump 610. Preferably, the discharge end of the vacuum pump 610 may be used to purify exhaust gas. The purification processor 620 may be provided.

The purification processing unit 620 removes radioactive material in exhaust gas and discharges the purified gas into the atmosphere.

Figure 3 is an enlarged configuration of the main portion of the radiation exposure preventing apparatus according to the present invention.

Referring to FIG. 3, the exposure prevention device may include two first chambers 520 and a second chamber 530 partitioned by the separating plate 510, and the first chamber 520 may be an observation hole ( The discharge of heavy water can be prevented adjacent to the VP), and the second chamber 530 prevents negative pressure from being directly emitted to the outside by a negative pressure generated by a vacuum source connected to the vacuum port 531.

Preferably, the first chamber 520 may be provided with a blocking block 521 of the reverse cone shape to surround the outer peripheral surface of the rod 200, the blocking block 521 and the outer peripheral surface of the rod 200 A constant friction is made to remove the radioactive heavy water on the surface of the rod 200 when the rod 200 is raised, and the removed heavy water is returned to the Kalandria container through the observation hole VP.

The blocking block 521 generates frictional force with the outer circumferential surface of the rod part 200 within a range that does not interfere with the up and down of the rod part 200, and if necessary, only a part of the block block 521 may be loaded. The friction protrusion 521a which is in friction with the 200 may be provided to remove heavy water from the surface of the rod part 200 without generating a large load when the rod part 200 is elevated.

In the present embodiment, the lower portion of the chamber 500, the plate 345 is formed with a predetermined inclined surface 345a toward the observation hole (VP), so that some of the heavy water removed by the blocking block 521 is accumulated on the plate 345. prevent.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various substitutions, modifications, and changes are possible within the scope without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

100: measuring device 200: rod
300, 400: vertical drive means 500: chamber
510: separator 520: first chamber
530: second chamber 610: vacuum pump
620: Purification processing unit

Claims (3)

In the radiation exposure prevention device of the system for inspecting the internal structure inspection device of the calandria into the observation hole provided in the calandria container by lifting up and down in the vertical direction,
A chamber which is directly seated on an upper portion of the callandaria container in which the observation hole is located and is provided in a transport section of the rod part in which the measuring device is fixed at the lower end, and a space formed to block the outside;
And a vacuum source generating a negative pressure inside the chamber.
The chamber,
A first chamber for blocking the outflow of heavy water;
And a second chamber which is partitioned from the first chamber and in which a negative pressure by the vacuum source acts. delete The radiation exposure preventing apparatus of claim 1, wherein the first chamber comprises an inverted cone-shaped blocking block surrounding the outer circumferential surface of the rod portion.

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