KR102639354B1 - Belt for radiographic examination - Google Patents

Abstract

The present invention relates to a radiographic inspection belt used during non-destructive testing of pipes. More specifically, when performing a radiographic inspection, an identification number is assigned to the detection area so that the inspection can be performed without missing the detection area. It relates to a belt for radiography that is installed to surround the circumference.

Description

Belt for radiographic examination}

The present invention relates to a radiographic inspection belt used during non-destructive testing of pipes. More specifically, when performing a radiographic inspection, an identification number is assigned to the detection area so that the inspection can be performed without missing the detection area. It relates to a belt for radiography that is installed to surround the circumference.

In general, radiographic testing, one of the non-destructive tests, is widely used because of its excellent clarity, but exposure to light sources is harmful to humans, so the type of light source and exposure time are strictly limited in accordance with domestic and foreign nuclear energy laws.

In particular, defect inspection must be performed after welding pipes, ships, etc., where reliability verification is important, such as joining large water pipes or structures with various types of welds in long lengths.

Non-destructive tests used to inspect welded areas include Radiographic Testing (RT), Ultrasonic Testing (UT), Magnetic Particle Testing (MT), and Liquid Penetrant Testing (PT). , Eddy Current Testing (ETC), Leak Testing (LT), etc. are being conducted.

In particular, radiographic inspection is adopted to inspect the welded area without damaging it. Radiographic examination is a method of taking radiographs of the welded part and using the film to find defects inside the welded part. Although there are concerns about radiation leakage, the examination is relatively simple and the results are accurate. In addition, radiography is widely used due to the advantage of permanently preserving the captured film and allowing the results to be checked at any time.

However, there are parts where inspection is difficult to perform depending on the pipe diameter, shape, and location of the weld area of the inspection object. In particular, there is a problem in that there are areas where inspection cannot be performed due to missing inspection locations.

Therefore, there is a need to develop a radiographic inspection belt for assigning an identification number to a film that captures the inspection location without being limited by the diameter and shape of the pipe through which the inspection is performed.

1. Publication Patent No. 10-2018-0039843 ‘Non-destructive inspection device through radiographic inspection’ (publication date 2018.04.19) 2. Registered Utility Model Publication No. 20-0470677 ‘Welded zone recognition belt for non-destructive testing’ (registration date 2013.12.27)

The present invention was devised to solve the above problems, and a radiography inspection belt is installed in a pipe so that a unique identification number can be assigned to the film taken through radiography inspection to recognize the welded part of the pipe on which the inspection was performed. The purpose is to provide.

The radiographic examination belt of the present invention includes a belt portion (100); At least one socket (200) fixed to one side of the belt unit (100), one side of which is open, and a receiving space (S) provided therein; A recognition unit 300 that can be accessed through one open side of the socket 200; and a fixing means 400 provided on the other side of the belt unit 100 to secure the belt unit 100 to the inspection object 10.

In the present invention, a coupling rod 110 extends to a predetermined length at one end of the belt unit 100 and has a fastening protrusion 111 protruding from the end; The coupling rod 110 is inserted into the other end of the belt unit 100, and a coupling groove 120 is further formed in which a coupling groove 121 into which the fastening protrusion 111 is inserted is formed.

In addition, a coupling groove 301 recessed to a predetermined depth may be formed on the upper and lower surfaces of one side of the recognition unit 300, and the coupling groove 301 may be formed on the inner surface of the socket 200 when the recognition unit 300 is inserted. A pair of fixing protrusions 201 that are inserted into the 301 and fix the recognition unit 300 are formed to protrude.

In the present invention, an elastic part 210 made of an elastic material is further provided to provide elasticity to the fixing protrusion 201 inside the socket 200, and the elastic part 210 is provided with the fixing protrusion 201. It is characterized in that it includes a pair of pressing parts 211 that form a convex shape in the direction in which it protrudes, and a connection plate 212 that connects the pressing parts 211 and provides elasticity.

Meanwhile, the recognition unit 300 of the present invention includes an identification unit 310 made of a radiation blocking material; Includes an insertion pad 320 surrounding the identification portion 310 and inserted into the socket 200, wherein the inside of the socket 200 is in contact with the edge of the insertion pad 320 and the insertion pad ( It is characterized in that a support portion 230 supporting 320) is further provided.

The present invention can be easily attached around a welded area while surrounding a pipe, and the welded area where a defect appears can be easily detected through an identification number assigned to the film paper.

In addition, the present invention has the advantage that it can be used by extending it according to the diameter of the pipe, the user can select and adjust the position where the identification number is located, and the pocket and identification pad can be easily attached and detached.

Figure 1 is a perspective view showing an embodiment of the present invention mounted on an inspection object.
Figure 2 is a perspective view showing the main components of the present invention and an embodiment in which the recognition unit is inserted.
Figure 3 is a bottom perspective view showing a fixing means provided on the bottom of the present invention.
Figure 4 is a perspective view showing an embodiment in which a plurality of the present invention is formed and connected.
5 and 6 are cross-sectional views and schematic diagrams showing various embodiments of the socket and recognition unit of the present invention.

Hereinafter, this embodiment will be examined in detail with reference to the accompanying drawings. However, the scope of the invention of this embodiment can be determined from the matters disclosed in this embodiment, and the spirit of the invention of this embodiment can be defined by adding, deleting, or changing components with respect to the proposed embodiment. It will be said to include transformation.

The present invention is for radiography inspection, which can be installed on the inspection object 10 so that an identification number is assigned to the detection film obtained by performing a radiographic inspection on the inspection object 10, so that the missing inspection location and the inspection area can be confirmed. It's about belts.

Referring to Figures 1 and 2, the belt for radiography of the present invention includes a belt part 100, a socket 200, a recognition part 300, and a fixing means 400.

The belt portion 100 may have a predetermined thickness and may have a plate shape extending to a certain length. The belt portion 100 is preferably made of an elastic material such as silicone or rubber. In general, the inspection object 10 may be a cylindrical pipe with a predetermined diameter, and the presence or absence of defects in the welded area where the pipe is connected is inspected.

The belt portion 100 surrounds the outer peripheral surface of the inspection object 10, is in close contact with the side of the inspection object 10, and one side and the other end of the belt portion 100 meet each other and are fixed to the inspection object 10. It is possible. At this time, separate detachment means such as Velcro may be provided on one end and the other end of the belt unit 100.

Meanwhile, a separate coating layer may be formed on the surface of the belt portion 100 in contact with the side of the inspection object 10 to increase friction with the inspection object 10. As a result, even if a predetermined load is applied to the belt portion 10, it is possible to prevent the belt portion 10 from slipping from the inspection object 10.

In addition, as the belt portion 100 is formed of an elastic material and stretches, the belt portion 100 can be mounted on the inspection object 10 in response to various diameters of the inspection object 10.

The socket 200 is fixed to one side of the belt unit 100. The socket 200 may be formed of the same material as the belt portion 100 and may form one body with the belt portion 100. One side of the socket 200 is open, and a receiving space (S) is provided inside. It is preferable that at least one socket 200 is provided, and a plurality of sockets 200 may be provided at predetermined intervals along the extending longitudinal direction of the belt unit 100.

Meanwhile, in one embodiment of the socket 200, the socket 200 can be detached from the belt unit 100. As a result, the examiner can adjust the distance between one socket 200 that serves as a reference and the other sockets 200 that are adjacent to each other.

The recognition unit 300 may be inserted or pulled out into one open side of the socket 200. The recognition unit 300 may be made of a material that can block radiation, such as lead, and may be formed in the form of identifiable letters or numbers on the film. The recognition unit 300 may be inserted into any one socket 200 selected by the examiner among the plurality of sockets 200.

Referring to FIG. 3, a fixing means 400 is further provided on the other side of the belt portion 100 to attach the belt portion 100 to the other side. Typically, the inspection object 10 is a magnetic metal body, and the fixing means 400 corresponds to a magnet. Therefore, when the fixing means 400 is mounted on the belt unit 100, the belt unit 100 moves the inspection object 10. ) can be attached to.

Accordingly, the belt unit 100 can be attached to the side of a large diameter pipe (inspection object 10) where both ends of the belt unit 100 do not meet.

Meanwhile, the fixing means 400 may be in the form of a string magnet that is flexible and has a predetermined length. The fixing means 400 of this shape is arranged in a ring shape along the edge of the other side of the belt unit 100, improving the fixation power of the belt unit 100 and the inspection object 10 and fixing the other side of the belt unit 100. It can be placed in close contact with the side of the inspection object (10).

[Example 1]

Referring to Figure 4, the belt portion 100 further includes a coupling rod 110 and a coupling groove 120. The coupling rod 110 is formed to extend from one end of the belt unit 100 to a predetermined length. A fastening protrusion 111 is formed to protrude at the end of the coupling rod 110. The fastening protrusions 111 may be formed on the left and right sides of the coupling rod 110, respectively.

The coupling groove portion 120 is formed at the other end of the belt portion 100. The coupling groove portion 120 has the same shape as the coupling rod 110 and the coupling rod 110 can be inserted. In addition, a fastening groove 121 into which the fastening protrusion 111 is inserted is further formed in the coupling groove 120, thereby improving the binding force of the coupling rod 110.

Therefore, when the belt portion 100 is mounted surrounding the inspection object 10, the coupling rod 110 can be fixed by being coupled to the coupling groove portion 120, and can be used by further connecting at least one belt portion 100. You can.

[Example 2]

Referring to FIG. 5 , it is assumed that the recognition unit 300 has the shape of a pad inserted into the socket 200 and is formed in the shape of numbers or letters made of radiation blocking material.

On one side of the recognition unit 300, a coupling groove 301 recessed to a predetermined depth is formed on the upper and lower surfaces, respectively. The coupling groove 301 may be formed at a position adjacent to one side of the recognition unit 300 that is first inserted into the socket 200. (See Figure 5(a))

When the recognition unit 300 is inserted into the socket 200, a pair of fixing protrusions 201 that are inserted into the coupling groove 301 of the recognition unit 300 are protruding from the inner surface of the socket 200. As a result, it is possible to prevent the recognition unit 300 from easily falling in or being separated from the socket 200.

[Example 3]

Referring to FIG. 5, the inside of the socket 200 is further provided with an elastic part 210 to press the recognition part 300 inserted into the socket 200 with a stronger elastic force to maintain the fixing force of the recognition part 300. Let it happen.

The elastic portion 210 includes a pressing portion 211 and a connection plate 212. The pressing portion 211 has a convex shape in the direction in which the fixing protrusion 201 protrudes and is provided as a pair. As the pressing portion 211 maintains a convex shape with a predetermined radius of curvature, the recognition portion 300 can be fixed with improved fixing force. The connection plate 212 connects the pair of pressing parts 211 and provides elasticity while drawing a predetermined radius of curvature. Therefore, if the recognition unit 300 inserted into the socket 200 is stably fixed and the recognition unit 300 is pulled with a force greater than the elastic force, the recognition unit 300 can be pulled out.

[Example 4]

Referring to FIG. 6 , the recognition unit 300 includes an identification unit 310 and an insertion pad 320. The identification unit 310 is made of a radiation blocking material and has the shape of numbers or letters. The insertion pad 320 surrounds the identification portion 310 and forms a square plate shape with a predetermined thickness. The insertion pad 320 is inserted into the socket 200.

The left and right edges of the insertion pad 320 may have a smooth curved shape with a predetermined radius of curvature. As a result, the contact area with the left and right edges of the socket 200 can be increased and at the same time, wear and tear of the socket 200 due to frequent entry and exit of the recognition unit 300 can be prevented.

Meanwhile, a support portion 230 may be further provided inside the socket 200 to contact the edge of the insertion pad 320 and support the insertion pad 320.

The support portion 230 is made of a material having the same elasticity as the socket 200 and may have a shape whose cross-sectional area gradually increases in the direction in which the insertion pad 320 is inserted. Due to this shape, when the insertion pad 320 is completely inserted into the socket 200, the support part 230 can fix the recognition unit 300 by pressing the left and right sides of the insertion pad 320 with a predetermined pressure. .

At this time, when the socket 200 is made of a material such as elastic rubber or silicon, when the left and right sides of the socket 200 are pulled in different directions, the support portion 230 is spaced away from the side of the insertion pad 320 and the socket 200 The recognition unit 300 inserted into can be slid upward. (Upward direction based on FIG. 6) Therefore, the recognition unit 300 can be smoothly replaced.

The radiographic examination belt of the present invention can be easily mounted on an inspection object and easily attached around a weld, can be extended according to the diameter of the pipe, and has the advantage of easy replacement of the recognition unit 300. there is.

100: belt part 200: socket
300: Recognition unit 400: Fixing means

Claims (5)

Belt portion 100;
At least one socket (200) fixed to one side of the belt unit (100), one side of which is open, and a receiving space (S) provided therein;
A recognition unit 300 that can be accessed through one open side of the socket 200;
A fixing means 400 provided on the other side of the belt unit 100 to secure the belt unit 100 to the inspection object 10,
A coupling groove 301 recessed to a predetermined depth is formed on one upper and lower surface of the recognition unit 300,
When the recognition unit 300 is inserted, a pair of fixing protrusions 201 are protruding from the inner surface of the socket 200 and are inserted into the coupling groove 301 to secure the recognition unit 300.
A belt for radiography, characterized in that an elastic portion 210 made of an elastic material is further provided to provide elasticity to the fixing protrusion 201 inside the socket 200.
According to claim 1,
A coupling rod 110 extending to a predetermined length at one end of the belt unit 100 and having a fastening protrusion 111 protruding from the end;
Characterized in that a coupling groove portion 120 is further formed at the other end of the belt portion 100 into which the coupling rod 110 is inserted and a coupling groove 121 into which the fastening protrusion 111 is inserted is formed. A belt for radiographic examination. delete According to claim 1,
The elastic portion 210 connects a pair of pressing portions 211 having a convex shape in the direction in which the fixing protrusion 201 protrudes and the pressing portion 211, and is a connecting plate 212 that provides elasticity. A belt for radiography, characterized in that it includes; According to claim 1,
The recognition unit 300 includes an identification unit 310 made of a radiation blocking material;
Including an insertion pad 320 surrounding the identification portion 310 and inserted into the socket 200,
A radiographic examination belt, characterized in that the interior of the socket 200 is further provided with a support portion 230 that contacts an edge of the insertion pad 320 and supports the insertion pad 320.