KR102224619B1 - Radiation Prediction Collimator of Radiation Examination Device - Google Patents

Abstract

In the collimator connected to the radioisotope front guide of the radiographic inspection apparatus according to the present invention, the collimator is installed in the collimator and is provided to irradiate the laser to the imaging area, and the collimator is applied to the collimator. It includes a laser holder to fix the laser level. The source predictive collimator of such a radiographic inspection device displays the predicted path of the source that is not visible in the collimator in the imaging area, thereby reducing the imaging time and ensuring uniformity in the quality of the imaging film and the imaging safety regardless of the individual's skill level. Make.

Description

Radiation Prediction Collimator of Radiation Examination Device

The present invention relates to a source predictive collimator of a radiographic inspection apparatus, and more particularly, to a source predictive collimator of a radiographic inspection apparatus that blocks radiation leakage through a radioisotope passage.

The radiation irradiation device for non-destructive inspection is a non-destructive inspection equipment that inspects the welding condition of structures such as pipes or steel pipes or internal mechanical defects through radiographic imaging.

The radiation irradiation device includes a radiation source unit equipped with a capsule and a connector containing a radioactive isotope such as iridium, a container storing the radiation source in a shielded state, a cable operation unit connected to the connector of the radiation source to move the radiation source, and It is connected to the container and consists of a transmission pipe that guides the radiation source to the inspection position.

Radiation non-destructive testing is performed as follows using a radiation irradiation device. First, the transmission pipe is positioned and fixed to the inspection point, and then the film is attached to the outer surface of the object to be inspected. Connect and install the cable of the cable control part and the connector of the radiation source located inside the container. Next, the cable is moved along the inside of the container using the remote control unit of the cable operation unit, and the radiation source is transferred to the source mounting unit provided at the end of the transmission pipe to irradiate the radiation.

In radiation nondestructive testing, since radiation is irradiated in all directions, it affects the exposure to not only the radiation worker but also the people around it, so a collimator is usually connected to the source mounting part of the transmission pipe to reduce exposure and improve the quality of radiographic images. Has been.

As a prior art for a collimator, there is a collimator using a radioactive isotope (Ir-192) in Korean Patent Publication No. 10-0434579.

The collimator using the above radioactive isotope (Ir-192) is a lead molding with an insertion hole formed therein to enclose the collimator, a guide connector connected to inject a radioactive isotope into the collimator on one side of the lead molding, It is composed of a house surrounding the outer circumference of the lead molding and a handle formed on the upper part of the house to shield the radiation emitted from the collimator.

The collimator is made of a tungsten material, and radioactive isotopes are guided along the inner passageway and radiated to the outside, and the weld is projected to measure the precision of the weld.

On the other hand, when the radiation from the radioactive isotope in the collimator is accurately and uniformly irradiated onto the imaging area, a high-quality imaging image is produced.

Currently, radiographic inspection workers work on radiography by predicting the center path of the crew with their eyes, using a tape measure or a stick, in most cases, in order to create an imaging result of the ideal imaging quality of the object to be photographed.

Since the radiation source due to the radioactive isotope is not visible in the collimator, the predicted path is performed without the reference value for accurate measurement, so it takes a lot of time to shoot depending on the individual skill and condition, and many defects occur in the properties of the film. .

The present invention provides a source prediction collimator of a radiographic inspection apparatus that shortens the imaging time and ensures uniformity in the quality of the imaging film regardless of individual skill level by displaying the predicted path of the source that is not visible in the collimator in the imaging area. It is to do.

A collimator for predicting a source of a radiation inspection apparatus according to the present invention includes a collimator connected to a front guide of a radioisotope of a radiation inspection apparatus, comprising: a laser level meter installed on the collimator and provided to irradiate a laser into an imaging area; And a laser holder for fixing a laser level to the collimator, wherein the laser level is located at a connecting portion in which the front guide is connected toward the collimator, and the laser holder is provided with a steel band surrounding the connecting portion, and the laser holder Is fixed adjacent to the collimator, and the laser holder allows the laser to be accurately irradiated to the photographing area at a position where the collimator does not interfere with radiation irradiation, and is installed in the collimator and transferred from the front guide. It includes an isotope detection unit that detects the radioactive isotope so as to determine whether the isotope enters and has settled in the collimator.

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The laser level system may include a plurality of laser irradiation units for irradiating a plurality of lasers orthogonal to each other in the imaging area.

The plurality of laser irradiation units may have a cross shape.

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The isotope sensing unit may be provided as a contact or non-contact proximity sensor.

The present invention described above, by displaying the predicted path of the source invisible in the collimator in the imaging area, irrespective of the individual's skill level, the radiation inspection device capable of shortening the imaging time and ensuring uniformity in the quality of the imaging film Can provide crew prediction collimator of.

1 is a conceptual diagram of a source prediction collimator of a radiation inspection apparatus according to an embodiment of the present invention;
2 is a detailed view of the laser irradiation unit of FIG. 1,
3 is a conceptual diagram of a source prediction collimator of a radiation inspection apparatus according to another embodiment of the present invention.

Hereinafter, various embodiments of the present invention will be described with reference to specific embodiments shown in the accompanying drawings. Differences in the embodiments are not mutually exclusive and should be understood in a complex manner, and without departing from the spirit and scope of the present invention, specific shapes, structures, and characteristics described in relation to the embodiments are implemented in other embodiments. Can be.

The position or arrangement of individual components according to the embodiments of the present invention is changeable and should be understood as a combination of the drawings, and similar reference numerals in the drawings may indicate the same or similar functions over various aspects, and length, area, and thickness. The etc. may be exaggerated and expressed for convenience in description.

A source prediction collimator of a radiographic inspection apparatus according to an embodiment having high practical implementation and high industrial applicability among various embodiments of the present invention will be described with reference to the conventional matters as described above.

Hereinafter, main components of a source prediction collimator of a radiation inspection apparatus according to an embodiment of the present invention will be described based on the drawings.

1 is a conceptual diagram of a source prediction collimator of a radiation inspection apparatus according to an embodiment of the present invention, and FIG. 2 is a detailed view of a laser irradiation unit of FIG. 1.

1 and 2, the radiation source prediction collimator 10 of the radiographic inspection apparatus according to an embodiment of the present invention is a radioisotope front guide 40 connected to the container 30 of the radiographic inspection apparatus. As a collimator 10 connected to the collimator 10, a laser level 50 installed on the collimator 10 and provided to irradiate a laser to the photographing area, and a laser holder 60 for fixing the laser level 50 to the collimator 10 ). The radioactive isotope corresponds to the radiation source 20.

The laser level 50 is located at a connection portion to which the front guide 40 is connected toward the collimator 10. The laser holder 60 may be provided with a steel material, rubber, plastic band, etc. surrounding the connection part. As the laser holder 60, a steel band mainly used for fitting a pipe is suitable.

The laser level 50 may be detachably fixed by a band-shaped laser holder 60, and is fixed adjacent to the collimator 10 as the laser holder 60 is installed on a tubular connection. The laser holder 60 accurately irradiates the laser onto the imaging area at a position where the collimator 10 does not interfere with radiation irradiation.

The user may irradiate a laser to the photographing area from the laser level 50. The laser is accurately irradiated to the photographing area, and accurate radiation and uniformity of the source can be predicted by the vertical irradiation aspect. Radiographic imaging may be performed by correcting an error distance between the cross-shaped irradiation point of the laser level 50 and the actual imaging point.

The laser level 50 may be provided with a plurality of laser irradiation units 51 and 52 that irradiate a plurality of lasers orthogonal to each other in the imaging area.

A plurality of lasers having an orthogonal aspect irradiated by the plurality of laser irradiation units 51 and 52 provide an orthogonal line and an orthogonal point in the imaging area. The operator can predict whether the orthogonal aspect and the orthogonal point coincide with the photographing area and calculate it to predict the crew's irradiation point and uniform irradiation.

The plurality of laser irradiation units 51 and 52 may have a cross shape. The cross-shaped laser irradiation units 51 and 52 create a cross-shaped laser in the photographing area. The plurality of laser irradiation units 51 and 52 may be displayed in the same or different colors. As the laser irradiation units 51 and 52, those capable of irradiating red color may be used.

3 is a conceptual diagram of a source prediction collimator of a radiation inspection apparatus according to another embodiment of the present invention.

Referring to FIG. 3, the source prediction collimator 10 of the radiographic examination apparatus is installed in the collimator 10 and is an isotope detector 70 that detects radioactive isotopes transferred from the front guide 40. It may further include.

The isotope detection unit 70 may be provided as a contact or non-contact proximity sensor, and may include a wireless communication module for notifying the outside as one or more LEDs or detection signals as a light source for display to the outside. The LED can be implemented in the form of a warning light. As the wireless communication module, Bluetooth, Zigbee, and wireless LAN card may be used, and notifications may be made possible by installing an app on the worker's smartphone.

It was difficult for the operator to determine the isotope, which is the radiation source unit 20 that is guided and transferred to the collimator 10 through the front guide 40, but the isotope detection unit 70 is installed in the collimator 10. It is possible to check whether the collimator 10 has entered and has been settled.

The operator predicts the level of the source with respect to the imaging area and the irradiation point by the laser level 50 and the collimator 10 is fixed, the isotope detection unit 70 whether the radioactive isotope is seated in the collimator 10. ) To confirm and proceed with the filming. This ensures safety from radiation exposure at accurate imaging and imaging points.

The radiographic inspection apparatus according to the embodiments of the present invention as described above, by displaying the predicted path of the source not visible in the collimator in the imaging area, shortens the imaging time and uniformity in the quality of the imaging film regardless of the individual's skill level. Shooting safety can be secured.

Although the embodiments of the present invention have been described as above, based on this, if a person of ordinary skill in the relevant technical field does not depart from the essential technical idea of the present invention described in the claims, the addition or modification of components Various modifications and changes may be made to the present invention by deletion or addition, and this is also included within the scope of the present invention.

10: collimator 20: radiation source
30: container 40: front guide
50: laser level 51, 52: laser irradiation unit
60: laser holder 70: isotope detection unit

Claims (6)

In the collimator connected to the radioisotope front guide of the radiographic examination device,
A laser level system installed on the collimator and provided to irradiate a laser onto the photographing area; And
Including a laser holder for fixing the laser level to the collimator,
The laser level is located at a connection portion in which the front guide is connected toward the collimator, the laser holder is provided with a steel band surrounding the connection portion, the laser holder is fixed adjacent to the collimator, and the laser holder is the collimator. It is possible to accurately irradiate the laser to the imaging area from a position that does not interfere with radiation irradiation in the meta,
A source prediction collimator of a radiographic testing apparatus comprising an isotope detector installed in the collimator and configured to detect whether or not the isotope has entered the collimator by detecting the radioactive isotope transferred from the front guide. delete The method of claim 1,
The laser level meter is a radiation source prediction collimator of a radiation inspection apparatus including a plurality of laser irradiation units for irradiating a plurality of lasers orthogonal to each other in an imaging area. The method of claim 3,
The plurality of laser irradiation units is a ray source prediction collimator of a radiation inspection apparatus having a cross shape. delete The method of claim 1,
The isotope detection unit is a source prediction collimator of a radiographic inspection apparatus provided with a contact or non-contact proximity sensor.

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