KR200334822Y1 - carrying along for radiation equipment the smallest being bombed of radiation - Google Patents

Abstract

The present invention relates to a portable radiation device that minimizes the radiation exposure dose, is formed in a funnel shape to surround the radiation projection path between the radiation device 11 and the X-ray film 27 to form a lead plate 75 in the inner center A main shielding car 71 made of a lead plate having a triple structure in which both surfaces are covered with a steel plate 77, and the outer surface of the lead plate 85 is formed on the circumference adjacent to the projection window of the radiation device 11 with the steel plate 87. There is provided a stand of a portable radiation device, comprising: an upper auxiliary shield vehicle 81 formed of a coated double-walled lead plate and having a high radiation absorption coefficient, and having an opening and closing opening on one side thereof, thereby providing a radiation device. As a result, non-destructive inspection can minimize radiation leaking to the outside.

Description

Carrying along for radiation equipment the smallest being bombed of radiation

(Technology)

The present invention relates to a portable radiation device that minimizes radiation exposure dose, and more particularly, is equipped with a portable radiation device used for nondestructive inspection of structural defects using radiation, and shielding the radiation leaked from the radiation device. The present invention relates to a portable radiation device for minimizing the radiation exposure dose having a radiation shielding device.

(Background)

Non-destructive inspection is to inspect defects existing inside the various structures while maintaining the phenomenon of the structure. There are various methods such as radiographic inspection, ultrasonic inspection, and electromagnetic inspection.

Among these methods, the radiographic method is a method of detecting internal defects of a structure as a two-dimensional projection image using X-rays and recording them as it is in an X-ray film or the like, and is widely used because of its excellent objectivity and recordability. However, since the radiographic method uses radiation that causes fatal harm to the human body, stability due to radiation leakage is a problem.

In shipbuilding or steel bridge construction, which is the main task of joining many steel parts by welding, it is necessary to thoroughly inspect the defects of the welded part by securing the strength and stability of the target ship and the bridge. Radiation nondestructive testing is widely used.

As described above, the radiation non-destructive examination is required to reduce the radiation exposure dose as much as possible, and in nuclear power, the radiation dose per week for radiation workers is 100 mR or less, and the radiation dose for non-workers for 1 week is 10 mR or less. have. Therefore, in an industrial site such as a shipyard, it is common to carry out a radiation nondestructive inspection by bringing a structure (an inspector) into a shielding facility (for example, 20m × 15m × 1m size) of a concrete wall separately provided.

However, the radiation nondestructive method using such a concrete shielding facility is excessively expensive to prepare a shielding facility, and the inspection is moved from the production plant to the shielding facility using a crane and a transport vehicle, and the inspection is completed. Afterwards, the work required to be taken back to the production plant must be repeated, which requires excessive time and labor for preparation for inspection, and also causes a process loss due to a long inspection waiting time for bringing into a shielded facility. As a result, there was a problem of lowering productivity by increasing costs.

As a countermeasure for solving the problem of the inspection method using the concrete shielding facility, a method of performing a non-destructive inspection directly at the site where the inspection object is located using a portable radiation device is used.

As shown in FIG. 1, the portable radiation device 11 fills a Freon gas in a case 13 made of lead, mounts an X-ray tube 15 and a high voltage transformer 17 in the case 13, and installs a voltage cable ( It is configured to operate by the controller 21 connected to the 19, and the radiation generated from the X-ray tube 15 is emitted through the projection window 23 formed in the case 13 to pass through the test object 25 After that, a transmissive image is formed on the X-ray film 27. In FIG. 1, reference numeral 29 denotes a cold pan, and 31 denotes a handle.

However, although the portable radiation apparatus 11 having the above-described configuration is manufactured in consideration of the radiation exposure, the radiation emitted from the projection window 23 may not only leak to the outside, but also may be reflected on the test object 25. The radiation may also leak, which is not sufficient to reduce the radiation dose.

Therefore, an object of the present invention is to solve the problem of the radiation exposure dose of the portable radiation device for non-destructive inspection, and portable radiation to minimize the radiation exposure dose that can minimize the radiation dose leaked to the wrong part during non-destructive inspection It is to provide a device.

1 is a schematic cross-sectional view of a general radiological device for nondestructive testing.

2 is a schematic cross-sectional view showing an exemplary portable radiation device according to the present invention.

3 is a schematic front view of a main shield vehicle.

4 is a schematic front view of the upper auxiliary shield;

Explanation of symbols on the main parts of the drawings

11 portable radiation device 23 projection window

25 test specimen 27 X-ray film

51: stand 61 of the portable radiation device

71: main shield 81: upper auxiliary shield

89: opening and closing 91: upper secondary shield

93: film attachment plate 95: support plate

96: roller 97: actuator

99 control unit 100 rail

The object of the present invention described above is formed in a funnel shape so as to surround the radiation projection path between the radiation device 11 and the X-ray film 27 to put the lead plate 75 in the inner center and both sides to the steel plate 77 The main shield car 71 made of a coated lead plate having a triple structure, and a lead plate having a double structure in which the outer surface of the lead plate 85 is covered with a steel plate 87 at the periphery adjacent to the projection window of the radiation device 11. It is achieved by a portable radiation device that minimizes the radiation exposure dose, characterized in that it comprises an upper secondary shielding vehicle 81 formed by opening and closing on one side while forming a high radiation absorption coefficient.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the stand of the portable radiation device according to the present invention. The following specific examples are merely illustrative of the subject matter, and are not intended to obscure the scope of the present invention.

Figure 2 is a schematic perspective view showing an exemplary portable radiation device according to the present invention, Figure 3 is a schematic front view of the main shield, Figure 4 is a schematic front view of the upper auxiliary shield.

As shown in FIG. 2, the portable radiation device for minimizing the radiation exposure dose according to the present invention includes a stand 61 on which the portable radiation device 11 for non-destructive inspection is mounted, a main shield 71, and an upper auxiliary shield 81. ), The half-shape provided with the rail 100 also has the structure containing the film sticking apparatus 91. FIG.

The stand 61 is a member on which the portable radiation device 11 is mounted which projects X-rays through the projection window 23 to form a transmission image for the internal structure of the test object 25 on the X-ray film 27. It is a stand made of balance detective using steel pipe or steel bar. At the upper end of the stand 61, a recess 63 is formed to fit the outer shape (generally circular) of the radiation device 11 so that the radiation device 11 can be safely lifted. Wheel 65 is installed to facilitate, and the handle 67 is attached to the top.

The stand 61 is a height at which a clear image is formed on the X-ray film 27 and has a proper distance from the X-ray film 27.

In the inner space of the stand 61 formed between the test body 25 of the radiation device 11, as shown in Figs. 2 and 3, the main shield 71 in the shape of a funnel is installed, the main shield The upper end of the 71 is formed with a recess 72 so as to match the outer shape of the radiation device 11. The main shield 71 surrounds the radiation projection path from the projection window 23 of the radiation apparatus 11 to the X-ray film 27 to block the leakage of radiation to the outside, and has a high radiation absorption coefficient. It is made of a material, for example, a lead plate. As the main shield 71, for example, a lead plate of a triple structure in which a lead plate 75 is placed in the center and the both sides are covered with a stiff wave 77 can be used, and is firmly fixed to the stand 61.

An upper auxiliary shield 81 is provided around the radiation device 11 and at least around the radiation device 11 in a portion adjacent to the projection window 23, as shown in FIGS. 2 and 4. . The upper auxiliary shielding body 81 is for shielding the leakage of the radiation projected from the radiation device 11 and reflected on the test body 25 to the outside, and concave to fit the appearance of the radiation device 11 on one side. The part 83 is formed, and if it is a lower surface, it becomes an open hexahedron shape, and consists of a material which has a high radiation absorption coefficient, for example, a lead plate. As an example of the upper auxiliary shielding body 81, the lead plate of the double structure which coat | covered the outer surface of the lead plate 85 with the steel plate 87 can be used.

In addition, the opening and closing port 89 is formed on one side of the upper auxiliary shielding body 81, the opening and closing port 89 is closed during radiation inspection so that the radiation is shielded, and when the radiation is not irradiated, the opening and closing port 89 is opened to open the radiation device ( It is desirable to allow the heat generated in 11) to be released.

Next, the radiation device stand 51 according to the present invention uses the semi-automatic film applicator 91 as a film attachment plate to which the X-ray film 27 of the radiation device 11 is attached. When inspecting the specimen 25 with), the film can be easily moved under the specimen 25 to be in close contact with the specimen 25 and at the same time, the radiation passing through the specimen 25 scatters backwards. You can block them.

As shown in FIG. 2, the semi-automatic film attacher 91 includes a film attaching plate 93 made of a lead plate having a high radiation absorption coefficient in a tray shape, a support plate 95 supporting the attaching plate 93, An actuator 97 such as an air cylinder connecting the film attachment plate 93 to the support plate 95, and the air pressure of the actuator 97 to adjust the height of the film attachment plate 93 with respect to the support plate 95. It is the structure containing the control part 99 to adjust. In addition, a roller 96 is provided on the lower surface of the support plate 95 so that the semi-automatic film attaching device 91 can be moved along the high rail 100 under the test body 25.

When the film is pushed under the test body 25 for photographing, first, the actuator 97 is operated by the control unit 99 to push the film attaching plate 93 in close contact with the support plate 95, and the film The actuator 97 is operated by the control part 99 again to the number which set the attachment plate 93 to a desired position, so that the film attachment plate 93 may be in close contact with the bottom face of the test body 25.

When using the portable radiation device stand 51 according to the present invention having the configuration as described above, according to the inventors have investigated the radiation dose that can be exposed, it can be covered at maximum from 3 meters from the radiation device 11 The amount of radiation present was measured to be 15 mR / hr per hour. Since it takes one minute to take one radiographic film, the exposure dose per shot is 0.0083 mR / min. Therefore, considering that the legal allowable dose per week is 10mR (based on non-radiologists), 1200 shots can be taken per week, which is more than eight times the number of shots in a typical industrial site. This results in the safe use of a portable radiation device.

In the case of inspecting a defect of the test body 25 by using a portable radiation device that minimizes the radiation exposure dose according to the present invention described above, the main shielding body 71 receives radiation that may leak during operation of the radiation device 11. In addition, since the shield can be sufficiently shielded by the auxiliary auxiliary shield 81 and the semi-automatic film attaching device 91, there is an effect that can significantly reduce the radiation dose to the operator.

Claims (1)

In the portable radiation device used for the non-destructive inspection in which X-rays are projected through the projection window 23 to form permeability to the internal structure of the specimen 25 on the X-ray film to check for defects in the structure, It is formed in a funnel shape so as to surround the radiation projection path between the radiation device 11 and the X-ray film 27 to put a lead plate 75 in the inner center and the lead plate having a triple structure coated on both sides with a steel plate 77 The main shield car 71 made of, The upper side of the radiation device 11 formed with a double-sided lead plate coated with a steel plate 87 on the periphery adjacent to the projection window to form an opening and closing port on one side while having a high radiation absorption coefficient. A stand of a portable radiation device for minimizing the radiation exposure dose, characterized in that the auxiliary shield vehicle (81).