KR101910473B1 - Localized leak detection apparatus for the metal containment vessel of nuclear power - Google Patents

Abstract

The present invention relates to a device for detecting local leakage of internal partitions in a containment vessel and a device for detecting local leakage of a nuclear power plant, A test head bar which is grounded at a local site to pressurize the air; a hydraulic ram which adjusts the distance and maintains the contact force by moving the test head bar back and forth by hydraulic pressure; and one side connected to the hydraulic ram, And a test apparatus body mounted on a crane and capable of performing leak detection through a local leak rate test. The present invention makes it possible to easily check the partial leakage of the inner wall of the containment vessel of the nuclear power plant to the steel plate.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a leak detection apparatus for a bulkhead,

More particularly, the present invention relates to an apparatus and method for detecting a local portion of a containment vessel internal part of a nuclear power plant, which is capable of easily checking partial leakage of an inner wall of a containment vessel to an iron plate .

In general, containment vessels of nuclear power plants form multiple firewalls based on nuclear fuel to prevent radiation leakage.

In order to prevent the leakage of the radioactive material in the containment vessel, a detection device is operated. The detection device has already been widely disclosed and is not described in detail. Registration No. 10-168062 entitled " Poor Inspection Device Using Pneumatic Actuator & No. 10-1525415 "Leak Tester", Registration No. 10-1432382 "Air Leak Measurement Apparatus", Registration No. 10-1137078 "Nuclear Power Plant Container Outside Inspection Apparatus", and the like.

On the other hand, nuclear fuel pellets serve as the primary barrier for solid state radioactive materials. The nuclear fuel cladding serves as a secondary barrier and acts as a tertiary barrier in the event of a defect in the nuclear fuel cladding tube, as shown in FIG. 1, in order to prevent leakage of the radiation material.

A containment vessel V2 is formed around the reactor pressure vessel V1 serving as the tertiary barrier wall to form a fourth barrier wall by a steel plate having a thickness of approximately 6 mm. Finally, the reinforced concrete structure (V3) with a thickness of 120 cm finally blocks the leakage of the radioactive material to the fifth barrier wall.

In addition, each of the firewalls is thoroughly managed in accordance with a periodic inspection process. Since the outer surface Vb of the containment vessel V2 is adjacent to the fifth-level barrier, that is, the reinforced concrete structure V3, it is difficult for people to approach it, and in particular, access to the upper portion is impossible.

Further, when a serious accident occurs in the primary system in the containment vessel (V2), a test is conducted to verify that leakage of radioactive material to the outside through the containment vessel (V2) is within an allowable range.

At this time, the current leaking allowance verification test is performed through the integrated leak rate test (ILRT) and the local leak rate test (LLRT).

Since the space inside the containment vessel is large and large, the total leakage rate test (ILRT) based on the above-mentioned Nuclear Power Law and applicable codes takes a minimum of 106 hours of pressurization and leakage test period, which requires excessive manpower and time.

On the other hand, the above-mentioned local leakage test is performed by the leakage rate test shown in each of the doors, the electric penetration portion, and the mechanical penetration portion fuel transfer passage reflected in the design of the inside of the container. For example, as a result of the planned preventive maintenance by the above test method, as shown in FIG. 2, a pinhole (H) was found as a result of thickness measurement of a steel plate located 30 m above the inner wall of the containment vessel V2. However, the necessity of checking the integrity of the site is emphasized, but a conventional leak detection apparatus that satisfies the partial maintenance test method has not been proposed.

Since the conventional leakage detection device is not proposed, the inner surface Va of the containment vessel V2 is subjected to the visual inspection during periodic operation of the power plant, but the visual inspection has a problem in that the reliability of the inspection is poor.

In addition, the dome section changing portion of the containment vessel V2 is likely to be damaged due to cyclic repeated load applied by repetitive movement of a polar crane. Therefore, the dome cross section is located at a height of 30 m or more from the ground. Therefore, it is difficult to carry out the inspection by the general method, and the inspection of this portion is also required.

Further, a coating state of a certain thickness must be maintained on the inner surface Va of the containment vessel V2. As the operation period of the power plant increases, there is a problem that the paint is extinguished and corroded and pinholes H are generated.

[Patent Document 0001] Registration No. 10-1680642 "Defect Inspection Device Using Pneumatic Actuator" (Announcement 2016.11.29) [Patent Document 0002] Registration No. 10-1525415 "Leak Tester" (Bulletin 2015.06.17) [Patent Document 3] Registration No. 10-1432382 "Air leak measuring device" (Announcement 2014.08.20) [Patent Document 0004] Registration No. 10-1137078 "Apparatus for inspecting outer surface of containment vessel of nuclear power plant" (Announcement 2012.04.19)

SUMMARY OF THE INVENTION An object of the present invention is to provide a method and apparatus for repairing partial damage of an inner wall of a containment vessel by applying a total leakage rate test method, It is possible to shorten the time and reduce the manpower required, and to facilitate the partial leakage check.

It is another object of the present invention to provide a method and apparatus for accurately detecting the corrosion degree of a pinhole and extending the service life of a nuclear power plant by allowing a test head bar to be located in a desired area of a containment vessel inner wall, So that the stability of the apparatus can be secured promptly.

It is a further object of the present invention to improve the efficiency of inspection by making it possible to inspect the inner wall of the containment vessel at a high level.

It is a further object of the present invention to provide a method for inspecting leakage of pinholes in the inner wall of a containment vessel by accurately and promptly grasping the leaked state of the pressurized air on the surface of suspicious local parts of the inner wall steel plate of the containment vessel, So that it can be blocked in advance.

The present invention relates to an apparatus for detecting local leakage of a bulkhead internal part of a containment vessel, comprising: a local leak rate testing apparatus, which is an apparatus for inspecting an inner wall leak of a nuclear power plant; and a local leak rate test apparatus, And a hydraulic ram for adjusting the distance of the test head bar to the hydraulic pressure and maintaining the contact force. The hydraulic ram is connected to one side of the hydraulic ram and the other side is connected to a polar crane to adjust a local leakage rate And a test apparatus body for allowing leak detection through a test.

Wherein the test head bar comprises a hollow body having one side open and the other side closed and an air chamber formed at the center, a ground surface on which a square ring is provided so as to maintain sealing at the time of grounding at the inlet side of the hollow body, A coupling shaft formed to be coupled with the hydraulic ram on the clogging side of the body, and a connector for air pressurization which is connected to the air chamber and is installed on the hollow body so as to connect the air hose.

Wherein the hydraulic ram includes a piston which is engaged with a coupling shaft of a hollow body and moves back and forth depending on whether hydraulic pressure is supplied to adjust the distance between the inner wall and the test head bar and maintain the contact force of the test head bar against the inner wall, And a coupling plate formed by bolting to one side of the cylinder and bolted to the body of the testing device.

The test apparatus body includes a cylindrical body formed on one side of a reinforcing plate which is configured to be capable of providing hydraulic pressure to the hydraulic ram and to which an engaging plate of the hydraulic ram is engaged and a cylindrical body formed on the other side of the reinforcing plate A support plate formed in a plate shape so as to be able to be supported by the polar brush and a silicone adhesive sheet adhered to the support plate with a predetermined thickness so that the support plate can be closely contacted with the ground surface.

The test head bar may be formed to have a large diameter and a small diameter on the basis of a predetermined diameter so that the test head bar can be used according to local regions of different sizes to be detected formed on the inner wall of the containment vessel.

The large-diameter test head bar and the large-diameter support plate of the containment vessel internal bulkhead local leakage detection device are provided with a plurality of reinforcing ribs for the test head bar radially attached to the boss fastened to the hydraulic ram, And a reinforcing rib for a cylindrical body formed so as to increase the stiffness in the direction of the outer peripheral surface 4 of the cylindrical body.

The hydraulic ram, when applied to a large diameter, is formed to have a shorter length and a smaller diameter than a hydraulic ram having a smaller diameter. When applied to a small diameter, the hydraulic ram has a longer length and a larger diameter than a hydraulic ram of a larger diameter.

The present invention provides an apparatus for detecting a local leakage of a bulkhead internal part of a containment vessel, wherein when the partial damage of the inner wall of the containment vessel is repaired by applying the total leakage rate test method, there is a disadvantage that an excessive inspection time and manpower are required, It is possible to shorten the time and reduce the manpower required.

In addition, even if the test head bar is placed in a desired area on the inner wall of the containment vessel and the leakage of the inner wall is easily checked, it is possible to accurately identify and repair the corrosion degree of the pinhole so as to quickly extend the life of the nuclear power plant and secure its stability. .

In addition, it is possible to widely inspect the inside of the containment vessel to the inner wall located at a high altitude, thereby improving the inspection efficiency.

Further, by examining the leakage state of the pressurized air on the surface of the suspicious local region of the steel plate inner wall of the containment vessel, it is possible to accurately check whether the pin hole formed in the inner wall of the containment vessel leaks, .

1 schematically shows a conventional nuclear power plant;
2A and 2B are photographs of pin holes formed on the inner wall of the container shown in Fig.
3 is a view showing a containment vessel internal part of a local area leak detecting apparatus according to the present invention.
Figs. 4A and 4B are photographs before assembling the rectangular rings of the test head bar shown in Fig.
5 is a view showing another embodiment of the containment vessel internal partition wall local leak detection apparatus according to the present invention.

For a better understanding of the present invention, a preferred embodiment of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified into various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. The present embodiments are provided to enable those skilled in the art to more fully understand the present invention. Therefore, the shapes and the like of the elements in the drawings can be exaggeratedly expressed to emphasize a clearer description. It should be noted that in the drawings, the same members are denoted by the same reference numerals. Further, detailed descriptions of well-known functions and configurations that may be unnecessarily obscured by the gist of the present invention are omitted.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 3 and 4, the containment vessel internal part local leakage detecting apparatus T1 according to the present invention includes a local leakage rate testing apparatus, which is an internal wall leakage checking apparatus of a nuclear power plant, a local leakage rate testing apparatus A test head bar 1a which is connected by an air hose and is grounded to pressurized air on a local area to be detected by the inner partition wall of the containment vessel V2; And a test apparatus body 4a which is connected to one side of the hydraulic ram 2a and the other side of which is mounted on a polar crane so that leak detection can be performed through a local leak rate test .

A test head bar 1a, which is selected from a large diameter and a small diameter according to the size and concentration of the pinhole H formed on the iron plate, is provided at a local site to be detected in the inner partition wall of the containment vessel V2.

In addition, since the container T1 can not be easily transported and installed to a check point in a high-altitude area when it is manufactured as a unit, it can be separated and transported, and can be assembled and installed in the field It is made in a light and detachable structure.

The test head bar 1a includes a hollow body 13a having one side opened and the other side closed and having an air chamber C formed at the center thereof, A fastening shaft 15a formed to be coupled with the hydraulic ram 2a at the clogging side of the hollow body 13a and a fastening shaft 15b fitted to the air cylinder C And an air pressurizing connector 7a which is connected to the hollow body 13a so as to connect the air hose.

The air pressurizing connector 7a is connected to an internal base floor, and a local leak rate test equipment is connected to a 30-m-meter ground by a Teflon hose. Therefore, the test head bar 1a is supplied with the air supplied by the operation of the local leak rate test equipment to be pressurized. The containment vessel internal part bulk local leak detecting apparatus T1 is subjected to a leak test through the pressurization of air.

On the ground surface 14a of the hollow body 13a is formed a ring groove 12a for preventing the contact surface from leaking when the projection forming portion of the surface where the inner wall (CLP: Containment Liner Plate) Two rectangular rings 6a are provided.

The hydraulic ram 2a is connected to the test head bar 1a to adjust the distance between the inner wall and the test head bar 1a and to adjust the distance between the inner wall and the test head bar 1a, A piston Sa for allowing the piston Pa to move forward and backward and a piston Sa which is formed by bolting to one side of the cylinder Sa and is provided with a test apparatus body 4a And an engaging plate 3a which is fastened with bolts (B).

Further, the hydraulic ram 4a is installed between the polar crane and the inner wall using the polar crane structure as a support. This hydraulic ram makes it possible to increase the contact force of the test head bar 1a with respect to the inner wall.

The test apparatus body 4a is provided with a reinforcing plate 16a which is configured to be able to supply hydraulic pressure to the hydraulic ram 2a and to which the engaging plate 3a of the hydraulic ram 2a is fastened, A support plate 10a formed to be attached to a cylindrical body 17a on the other side of the reinforcing plate 16a so as to be supported by the polar pillar and a supporting plate 10a, And a silicone adhesive sheet 5a adhered to the support plate 10a to a predetermined thickness so as to be adhered to the support plate 10a.

The test apparatus body 4a is constructed such that a containment vessel internal partition wall local leak detecting apparatus T1 is installed on the inner wall of the containment vessel V2 using a polar crane structure. That is, on the inner wall of the containment vessel V2, there is no equipment for installing the containment vessel internal part-wall local leak detector T1 in addition to the polar crane.

Therefore, the containment vessel internal bulkhead local leakage detector T1 is installed between the inner wall and the polar crane structure. Thus, the hydraulic ram 2a can be operated to change the separation distance between the pinhole H on the inner wall and the containment vessel internal partition wall local leak detecting apparatus T1. The hydraulic ram (2a) advances or retracts the test head bar (1a) during hydraulic operation so that the relative contact force is maintained.

As shown in FIG. 5, the containment vessel internal-part-wall local-area leakage detecting apparatus is constructed such that the diameter of a large-diameter And the test head bars 1a and 1b can be respectively formed as small capsules.

Since the test head bars 1a and 1b are in contact with each other according to the radius of curvature of the dome-shaped inner wall, the test head bars 1a and 1b can be selectively formed in a large diameter and small diameter. That is, even if the leakage test pressure of the test head bars 1a and 1b is the same, the magnitude of the force acting on the test head bars 1a and 1b increases to maintain the contact force. And is formed to fit the aperture. Therefore, the reliability of the local leak rate test is high because the maximum leak test area is reduced and the area where the defective parts such as the pinhole H are concentrated is selected as the minimum area.

The aforementioned large diameter test head bar 1b is formed with a plurality of reinforcing ribs L for test head bars radially attached to the bosses 20b fastened to the hydraulic rams 2b and projected so as to increase the stiffness .

The large-diameter support plate 21b may be provided with a cylindrical reinforcing rib L formed to adhere the contact sheet 5b and to increase the strength of bolt in the direction of the outer circumferential surface 4 of the cylindrical body 22b.

When the hydraulic ram 2b is applied to a large diameter, the length of the hydraulic ram 2b is shorter than that of a hydraulic ram of a small diameter, and the diameter thereof is smaller than that of a hydraulic ram of a small diameter. . Therefore, the hydraulic rams 2a and 2b are firmly formed so as to keep the test head bars 1a and 1b in close contact with each other.

Hereinafter, an example of the use of the containment vessel internal part bulk local leak detecting apparatus according to the present invention will be described.

First, the containment vessel internal partition wall local leak detecting apparatuses T1 and T2 are installed in a polar crane inside the containment vessel V2. That is, the test apparatus bodies 4a and 4b are installed using the structure of the polar crane, and the hydraulic rams 2a and 2b are operated to come in close contact with the ground surface around the pinhole H of the inner wall to be tested. The grounding surfaces of the test head bars 1a and 1b come into close contact with the containment vessel by the square rings 6a and 6b.

At this time, depending on the size and concentration of the inner wall plate pinhole H, the local leakage rate test can be performed by selecting the test head bars 1a and 1b necessary for the large diameter and small diameter. That is, one of the large diameter and the small diameter may be selected according to the size of the area where the pinhole H is formed and the radius of curvature of the inner wall of the dome shape.

When the above-described containment vessel internal partitions LA and T2 are installed, the hydraulic chambers 2a and 2b are advanced by hydraulic pressure generated by operating the test apparatus bodies 4a and 4b, 1a, 1b) are brought into close contact with the inner wall more closely.

Then, the local leakage rate test equipment is operated so that the air is supplied to the hollow body 13a or the air chamber C of the large diameter test head bar 1b through the air pressure connecting connectors 7a and 7b connected to the air hose . Air supplied to the air chamber C is leaked when the pinhole H is opened, and is not leaked when the pinhole H is closed.

Therefore, if the air pressure in the air chambers C of the test head bars 1a, 1b is low or maintained high, the local leakage rate test apparatus judges this and detects and displays local leakage.

The operator shall indicate the results of the operation of the containment vessel internal bulkhead leak detector (T1, T2) through the local leak rate test equipment.

Once the pinhole leakage detection is completed at one location inside the containment vessel, the localized bulkhead leakage detection devices (T1, T2) in the containment vessel are removed in the reverse order of installation.

Then, the polar crane is placed on the next pinhole to detect the leakage, and a local area leakage test is performed after installing a large-diameter or small-diameter inner diameter bulkhead internal leakage detecting device according to the size of the pinhole or the radius of curvature of the inner wall.

The embodiment of the containment vessel internal part of the present invention described above is merely exemplary in nature and various modifications and equivalent embodiments may be made without departing from the scope of the present invention. You can see that it is possible. Therefore, it is to be understood that the present invention is not limited to the above-described embodiments. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims. It is also to be understood that the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

1a, 1b: Test head bar 2a, 2b: Hydraulic ram 3a, 3b: Coupling plate
4a, 4b: Test apparatus body 5a, 5b:
6a, 6b: Square ring 7a, 7b: Air pressure connector
10a, 21b: Support plates 12a, 12b: Ring grooves
13a: hollow body 14a: ground plane
15a: fastening shafts 16a, 16b: reinforcing plate
17a, 22b: Cylinder body B: Bolt C: Air chamber
H: pinhole L: reinforcing rib
Pa, Pb: piston Sa, Sb: cylinder
T1, T2: Local vessel bulkhead leak detection device inside containment vessel
V2: Containment vessel

Claims (7)

A local leak rate test equipment which is an internal wall leak check equipment of a nuclear power plant;
A test head bar connected to the local leak rate test equipment and the air hose and pressurized to the local area of the containment vessel inner wall to be detected;
The distance between the inner wall and the test head bar is adjusted by adjusting the distance between the test head bar and the test head bar so that the gripping axis of the hollow body is coupled and the hydraulic pressure is supplied or not, A cylinder for allowing the piston to move forward and backward, and a coupling plate for being bolted to one side of the cylinder and fastened to the body of the testing device with a bolt;
And a test apparatus body which is connected to one side of the hydraulic ram and the other side of which is mounted on a polar crane to perform leak detection through a local leakage rate test,
Wherein the test head bar
A ground surface on which an air chamber is formed at one side of the hollow body and the other side thereof is closed and a square ring is provided at an inlet side of the hollow body so as to maintain a seal at the time of grounding; And a connector for air pressure inside the containment vessel, wherein the air pressure connector is connected to the air chamber and is installed on the hollow body so as to connect the air hose.
delete delete The method according to claim 1,
The test apparatus body comprises:
A cylindrical body formed on one side of the reinforcing plate, which is configured to be capable of providing a hydraulic pressure to the hydraulic ram and to which the coupling plate of the hydraulic ram is engaged, and a cylindrical body formed on the other side of the reinforcing plate, And a silicone adhesive sheet attached to the support plate at a predetermined thickness so that the support plate can be brought into close contact with the ground surface.
The method according to claim 1,
The containment vessel internal partition wall portion local leak detecting apparatus may further include:
Characterized in that the hydraulic ram is formed with a large diameter and a small diameter on the basis of a certain diameter so that it can be used according to local parts to be detected having different sizes formed in the containment vessel internal partitions. Device.
6. The method of claim 5,
In the large-diameter test head bar and the large-diameter support plate of the containment vessel internal part-wall local area leak detection device,
A plurality of reinforcing ribs for the test head bar are formed radially and protruded from the bosses fastened to the hydraulic ram to increase the bending strength,
Wherein a reinforcing rib for a cylindrical body is formed in such a manner that the adhesion sheet is adhered and the strengthening strength is increased in the direction of the outer peripheral surface 4 of the cylindrical body.
6. The method of claim 5,
The hydraulic ram
Wherein the diameter of the small-diameter hydraulic ram is smaller than that of the small-diameter hydraulic ram when applied to a large diameter, and the diameter is larger than that of the hydraulic ram of a large diameter when applied to a small diameter. Leak detectors.

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