KR20120040507A - Check apparatus for retrieval of a radiographic testing source and check method thereof and nondestructive testing equipment - Google Patents

Abstract

PURPOSE: Checking apparatus for retrieval of a radiographic testing source and a checking method thereof and nondestructive testing equipment are provided to certainly and stably check by a user by directly confirming the difference of using radiate ray source and after using radiate ray source. CONSTITUTION: Checking apparatus for retrieval of a radiographic testing source comprises a housing, an alarming unit, a power supplying unit, and a sensing unit. The housing is connected to the inlet for transferring radiate ray source formed on a storing unit. The alarming unit is formed on one side of the housing. The power supplying unit is formed in the housing. The sensing unit senses the presence or not of the radiate ray source, thereby controlling the power supply of the power supplying unit.

Description

CHECK APPARATUS FOR RETRIEVAL OF A RADIOGRAPHIC TESTING SOURCE AND CHECK METHOD THEREOF AND NONDESTRUCTIVE TESTING EQUIPMENT}

The present invention relates to a radiographic recovery source recovery check device and a source recovery check method for checking the recovery of radioisotope sources used in radiographic examinations and to a non-destructive inspection device having the same, and more particularly to radioisotopes. The source recovery check for radiographic inspection that prevents radiation overcoat accidents due to incomplete source recovery, prevents physical and physical damages, and handles radiation more safely by checking the source safely and reliably after exposure. Apparatus, source recovery check method, and non-destructive inspection device.

In general, there is a non-destructive inspection method for investigating an internal defect or condition of a product or structure without destroying the product or structure.

One of these nondestructive testing methods, radiographs (nondestructive testing devices) is to be examined using radioisotope sources. 1 is a configuration diagram showing the configuration of a general radiographic inspection apparatus.

As shown in Fig. 1, a general radiographic inspection apparatus includes a source storage unit 2 for storing a radioisotope source (radiation source) 1; A source guide tube (3) for guiding the source (1) through a designated path from the source storage unit (2) to an exposed position where the test object (P) is located; One end of the source guide tube (3) is fixed and the height adjustable stand (4); A remote operation unit 5 connected to the source storage unit 2 and operating to move the source 1 along the source guide tube 3; And a radiation source fixture 6 which is provided at one end of the source guide tube 3 and temporarily fixes the moved source 1 to face the test body P at a predetermined distance.

Reference numeral F is a film which is adhered to the lower surface of the test body P and is exposed by the radiation emitted from the radiation source 1 to receive and receive a planar projection image of the test body P.

Such a general radiographic inspection apparatus moves the radiation source 1 located in the source storage unit 2 along the source guide tube 3 by manipulating the handle of the remote operation unit 5. When the radiation source 1 is located in the radiation source fixture 6, the radiation emitted from the radiation source 1 is transmitted through the test body P for a predetermined time.

After exposing the film F to radiation for a certain time, the handle of the remote operation unit 5 is operated (in the opposite operation to the radiation source guide operation) to move the radiation source 1 into the source storage unit 2 and store it. do.

Subsequently, the radiation that passes through the test body P photosensitizes the film F, and the photosensitive film F is separated from the test body P to obtain a radiographic image by developing in a dark room. Through this transmission picture, it is possible to identify a defect present in the test body P.

In the radiation source recovery process of such radiographic examination, it is essential to perform a process of confirming whether the radiation source (1) is safely recovered to the source storage unit (2) in order to prevent unnecessary exposure by radiation.

Exposure to radiation sources If, after use, the safe recovery to the source storage unit 2 is not clearly identified, if the source continues to be handled in a state in which the radiation source has not been recovered to the source storage unit, the physical properties of the radiation overexposure may occur. Serious damage will result.

As described above, in order to confirm the recovery to the source storage unit after the exposure of the radiation source, the recovery status is indirectly confirmed through a radiation measuring apparatus such as an alarm monitor or survey meter, but there is a limit in confirming the recovery status. In the process of confirming the recovery to the source storage unit, there is still a problem of overexposure due to the inspection in the incomplete recovery state.

Therefore, a series of devices that can directly check the recovery situation is required in the process of recovery to the source storage unit after exposure to the radiation source, especially the study of safety devices for radiation exposure that can cause serious damage is urgently needed. .

The present invention has been proposed in order to solve the above-mentioned problems, and has a source recovery check device and a source recovery check method for radiographic inspection that can be carried out in a series of processes from the radiographic inspection to the confirmation of safe source recovery and the same The purpose is to provide a non-destructive testing device.

In addition, the present invention allows the operator to directly check the difference when the radiation source is in use during exposure and when the radiation source is recovered to the source storage unit after the use of the exposure to check the difference safely and reliably to prevent human and physical damage. Another object of the present invention is to provide a radiation recovery inspection source recovery check device, a source recovery check method, and a non-destructive inspection device having the same, which can be prevented in advance and promote safer radiation exposure prevention.

According to a first aspect of the present invention for achieving the above object, in the non-destructive inspection device including a radiation source storage unit and a source guide tube, as a device for checking the number of sources, the source movement pull-in formed in the radiation source storage unit A housing connected to the outlet; Notification means provided on one side of the housing; Power supply means for supplying power to the notification means; And a detecting means provided in the housing, the detecting means for detecting the presence or absence of a moving state of the source moving through the source moving inlet / outlet and controlling the power supply of the power supply means. to provide.

The housing has a connection adapter which is provided to be connected to the source moving inlet and outlet of the radiation source storage unit on one side; A source guide tube fastener provided on the other side to be connected to the source guide tube; A power supply means arranging unit which is formed such that the power supply means is disposed inside one side; Notification means arrangement unit is formed so that the notification means is disposed inside the other side; And it may include a movement passage for communicating between the connection adapter and the source guide tube fastener.

Preferably, the sensing means is installed at one end of the moving passage, that is, at one end of the moving passage adjacent to the source storage unit.

The notification means may be composed of a light emitting unit, a sound generating unit, or a light emitting unit and a sound generating unit integrated module.

In one embodiment, the sensing means is preferably configured as a proximity sensor, and in this case, the proximity sensor is preferably formed in an annular shape.

In another embodiment, the sensing unit includes an optical sensor including a light emitting unit and a light receiving unit; And a control unit for controlling the power supply of the power supply means based on the detection signal of the optical sensor.

According to a second aspect of the present invention, the source storage unit is located between the source storage unit for storing the radioisotope source and the source guide tube for guiding the source through a designated path from the source storage unit to the exposure position where the test object is located; Provided is a non-destructive inspection device comprising a radiographic inspection source recovery check device of the first aspect as described above to confirm the presence or absence of a moving state of the source recovered to the unit.

In the non-destructive inspection device, the source recovery check device is preferably installed immediately in front of the source storage unit,

According to a third aspect of the invention, a source storage unit for storing a radioisotope source; A source guide tube for guiding the source through a designated path from the source storage unit to an exposure position where the test object is located; A source recovery check device provided between the source guide tube and the source storage unit and installed immediately in front of the source storage unit; And a remote operation unit connected to the source storage unit and operating to move the source along the source guide tube.

According to a fourth aspect of the present invention, a non-destructive inspection apparatus including a radiation source storage unit and a source guide tube, the method for checking the number of sources, detecting the presence or absence of a state of movement of the source in front of the source storage unit A detecting step; And a notification step of informing the presence or absence of the movement state of the source based on the detection result detected in the detection step.

The detecting step may detect the presence or absence of a moving member or a moving member for moving the source through a proximity sensor or an optical sensor.

Preferably, the notifying step notifies the operator by at least one of a visual signal and an audio signal according to the detection result in the detecting step.

According to the present invention, there is an effect of preventing human physical damage to the radiation overexposure accident in advance.

In addition, according to the present invention, by performing a series of processes in the radiographic inspection process after the use of the radiation source exposure confirmation, there is an effect that can not only increase the work efficiency but also improve the working environment.

1 is a block diagram showing the configuration of a general radiographic inspection apparatus.
Figure 2 is a view showing a housing unit constituting the radiographic inspection source recovery check device according to the present invention, respectively (a) is a front view, (b) is a side view and (c) is a rear view.
Figure 3 is a block diagram showing the internal structure of the housing unit constituting the source recovery check device for radiographic inspection according to the present invention.
Figure 4 is a block diagram showing the notification means and the detection means and the circuit configuration of the main portion of the radiation recovery inspection source recovery check apparatus according to the present invention.
Figure 5 is a front view for explaining the configuration of the sensing means for constituting the radiation recovery check source recovery check apparatus according to the present invention.
Figure 6 is a block diagram for explaining the overall configuration of the non-destructive inspection device having a source recovery check apparatus according to the present invention.
7 is a partial configuration diagram showing a main portion of a non-destructive inspection device having a source recovery check device according to the present invention.
8 is a photograph showing a prototype of a non-destructive inspection device equipped with a source recovery check device manufactured by the present inventors.

Further objects, features and advantages of the present invention can be more clearly understood from the following detailed description and the accompanying drawings.

The radiation recovery inspection source recovery check apparatus according to the present invention basically comprises a housing connected to the source moving inlet and outlet of the radiation source storage unit; Notification means provided on one side of the housing; Power supply means for supplying power to the notification means; And sensing means provided in the housing and detecting the presence or absence of a moving state of the source moving through the constant source moving inlet / outlet.

In addition, the present invention provides a radiographic inspection apparatus including the source recovery check apparatus for radiographic examination.

In addition, the present invention provides a method for checking the recovery state of the source located in the source storage unit of the non-destructive inspection device, the detection step of detecting the presence of the movement state of the source in front of the source storage unit; And a notification step of informing the presence or absence of the movement state of the source based on the detection result detected in the detection step.

Hereinafter, a preferred embodiment of the radiation recovery source recovery check device of the present invention will be described in detail with reference to FIGS. The drawings referred to in the description show preferred embodiments of the invention, but are not limited thereto.

Figure 2 is a view showing a housing unit constituting the source recovery check device for radiographic inspection according to the present invention, respectively (a) is a front view, (b) is a side view and (c) is a rear view, Figure 3 It is a block diagram which shows the internal structure of the housing unit which comprises the radiation collection inspection source collection | recovery check apparatus which concerns on this invention. Figure 4 is a block diagram showing the configuration of the notifying means and the detection means and the circuit of the main portion of the radiographic inspection source recovery check apparatus according to the present invention, Figure 5 is a radiation recovery check source recovery check apparatus according to the present invention It is a front view for demonstrating the structure of the sensing means.

As shown in Figures 2 to 4, the radiographic inspection source recovery check apparatus according to the present invention, the housing 10 is connected to the source moving inlet and outlet (not shown) of the radiation source storage unit (described later); Notification means 20 provided on one side of the housing 10; Power supply means 30 for supplying power to the notification means 20; And sensing means provided in the housing 10 and detecting the presence or absence of a moving state of the source moving through the source moving inlet / outlet to control the operation of the notification means by opening and closing the power supply of the power supply means 30. And 40.

The housing 10 is made of a housing having an accommodation space therein. One side of the housing 10 is provided with a connection adapter 11 connected to the source moving inlet and outlet of the radiation source storage unit (see (b) and (c) of Figure 2), the other side of the housing 10 A source guide tube fastener 12 connected to a source guide tube (not shown) for guiding the source to the test object to be inspected is formed.

On one side of the housing 10 is formed a power supply means placement unit 13 is arranged the power supply means 30, the other side of the housing 10 is notified means 20 to be described in detail below Notification means arrangement unit 14 is disposed is formed. As will be described later, the notification means 20 is located so that one surface is exposed in the housing 10 to notify the operator of the notification status generated by the notification means.

In addition, a moving passage 15 for communicating between the connection adapter 11 and the source guide tube fastener 12 is formed inside the housing 10, and is connected to the source guide tube from the source moving inlet / outlet of the radiation source storage unit. Guide the movement of the crew.

Next, the notification means 20 is a means for notifying the operator of the visual signal, the audio signal, or both the visual and audio signals by opening and closing the circuit of the power supply means 30 according to the detection of the sensing means 40. to be.

As an example, in the embodiment shown in the drawing, the notification means 20 shows an example of a light emitting unit composed of LEDs.

The notification means 20 may be configured as a sound generating unit such as a speaker configured to generate sound by opening and closing the circuit of the power supply means 30 according to the detection of the sensing means 40.

In addition, the notification means 20 may be composed of a module incorporating a light emitting unit for emitting light and a sound generating unit for generating sound by opening and closing the circuit of the power supply means 30 according to the detection of the sensing means (40). Can be.

In the description of the notification means 20, the embodiment is described as being composed of a light emitting unit or a sound generating unit, but the operator to determine the presence or absence of a moving state of the source according to the detection of the detection means 40. It will be apparent to those skilled in the art that the means for notifying the user in various ways is not limited thereto.

Next, the detecting means 40 for detecting the presence or absence of a moving state of the source moving through the source moving inlet and outlet, the opening and closing the power supply of the power supply means 30, the connection adapter 11 of the housing 10 It is composed of a proximity sensor 41 provided on the side (see Fig. 5).

The proximity sensor 41 is preferably made of an annular (ring type). As will be described later, this prevents malfunction due to eccentricity when the moving member 1a (pigtail or drive wire) for fixing and moving the source 1 (see FIG. 4) passes through the proximity sensor 41, It is composed of an annular (ring type) to secure the detection.

In addition, the sensing means 40 of the proximity sensor 41 method further includes a sensitivity adjuster 42 that can adjust the detection intensity.

The sensing means 40 is not limited to the proximity sensor 41, and when the moving member 1a (pigtail or drive wire) for moving the source 1 and the source 1 approaches or passes therethrough, If it is a configuration that detects the presence or absence of a closed circuit to supply power, or detects the presence of the source 1 or the moving member (1a) (pigtail or drive wire) and the power is supplied by the detection signal It can be configured in any configuration.

For example, the sensing means 40 may be formed of an optical sensor including a light emitting part and a light receiving part. In this case, it includes a control unit for controlling the power supply of the power supply means 30 based on the detection signal of the photosensor.

Accordingly, in the case of the optical sensor, when the source 1 or the moving member 1a (pigtail or drive wire) passes, the amount of light received by the light receiving unit is reduced or blocked, indicating that the moving member exists. The detection signal is provided to the control unit so as to maintain a closed circuit state in which power is supplied to notify the operator through the notification means 20.

Operation of the radiographic inspection source recovery check apparatus according to the present invention configured as described above will be described in the configuration employed in the non-destructive inspection device to be described later.

Next, the present invention provides a non-destructive inspection apparatus employing the above-mentioned source recovery check apparatus for radiographic examination.

In the non-destructive inspection device of the present invention, the radiation recovery inspection source recovery check device described above is formed integrally in front of the source storage unit. Specifically, a non-destructive inspection device having a radiation recovery source recovery check device according to the present invention will be described with reference to FIGS.

Figure 6 is a block diagram for explaining the overall configuration of the non-destructive inspection device with a source recovery check device according to the present invention, Figure 7 is a part showing the main part of the non-destructive inspection device with a source recovery check device according to the present invention. It is a block diagram. 8 is a photograph showing a prototype of a non-destructive inspection device equipped with a source recovery check device manufactured by the present inventors.

6 to 8, the non-destructive inspection device having a radiographic inspection source recovery check device according to the present invention, the source storage unit 100 that stores a radioisotope source (radiation source) (1) And a source guide tube 200 for guiding the source 1 through a designated path from the source storage unit 100 to an exposure position at which the test object P is located, and is recovered to the source storage unit 100. It includes a source recovery check device 300 for confirming the presence or absence of a moving state of the source.

The source recovery check device 300 is preferably installed immediately in front of the source storage unit (100).

Specifically, the non-destructive testing device according to the present invention is a source storage unit 100 for storing a radioisotope source (radiation source) (1); A source guide tube (200) for guiding the source (1) through a designated path from the source storage unit (100) to an exposed position at which the test object (P) is located; A source recovery check apparatus 300 provided between the source guide tube 200 and the source storage unit 100 and installed immediately in front of the source storage unit 100; One end of the source guide tube 200 is fixed and height adjustable stand 400; A remote operation unit 500 connected to the source storage unit 100 and operating to move the source 1 along the source guide tube 200; And a radiation source fixture 600 provided at one end of the source guide tube 200 and temporarily fixing the moved source 1 to face the test body P at a predetermined distance.

Reference numeral F is a film which is adhered to the lower surface of the test body P and is exposed by the radiation emitted from the radiation source 1 to receive and receive a planar projection image of the test body P.

Since the source recovery check device 300 is configured as described above, a description thereof will be omitted.

Hereinafter, the operation of the non-destructive inspection device according to the present invention will be described.

The operator operates the handle of the remote operation unit 500 to move the radiation source 1 located in the source storage unit 100 along the source guide tube 200. At this time, the moving member 1a for moving the radiation source 1 passes through the source recovery check apparatus 300, so that the sensing means 40 detects that the source 1 or the moving member 1a exists. do.

Accordingly, based on the detection result of the sensing means 40, the power supply circuit for power supply is in a closed circuit state (for example, in the case of the approach sensor 41), and the notification signal by the notification means 30 is visually displayed. Signals, audio signals, or both visual and audio signals continue to occur. Therefore, the operator can check the state (state not accommodated) in which the source is currently moved from the source storage unit 100.

Subsequently, when the radiation source 1 is positioned in the radiation source fixture 600, the radiation emitted from the radiation source 1 is transmitted through the test body P for a predetermined time.

After exposing the film F to radiation for a certain period of time, the radiation source 1 is stored via the source recovery check device 300 by operating the handle of the remote operation unit 500 (in the opposite operation to the radiation source guide operation). It is moved into the unit 100 and stored.

At this time, the radiation source 1 and the moving member (1a) for moving it is passed through the source recovery check device 300, and continuously detects whether the source (1) or moving member (1a) is present ( 40) is detected.

When the radiation source 1 or the moving member 1a is detected as still present by the sensing means 40, the notification is continuously made by the notification means 20, but passes out of the sensing means 40 When the power supply circuit 1 is drawn into the source storage unit 1, the power supply circuit is in an open state (for example, in the case of the access sensor 41), and the notification signal by the notification means 30 is stopped.

An operator can further manipulate the remote operation unit 500 to store the radiation source 1 at an optimal location of the source storage unit 100, and the operator recognizes that the recovery of the source is smooth and stable. .

On the other hand, the present invention provides a method for checking the recovery state of the source located in the source storage unit of the non-destructive inspection device.

The source recovery check method in the non-destructive inspection device according to the present invention includes a detection step of detecting the presence of a moving state of the source in front of the source storage unit; And a notification step of notifying the presence or absence of the movement state of the source based on the detection result detected in the detection step.

The detecting step may detect the presence or absence of a moving member or a moving member for moving the source through a proximity sensor or an optical sensor.

The notification step may notify the operator by at least one of a visual signal and an audio signal according to the detection result in the detection step. In this notification, the visual or audio signal or both signals are preferably executed by opening and closing the power supply.

As described above, the radiation recovery check source recovery check device and the source recovery check method and the non-destructive inspection device provided with the same can be executed in a series of processes from the radiographic inspection to the confirmation of safe source recovery, thereby improving work efficiency. Can be improved.

In addition, the present invention allows the operator to directly check the difference when the radiation source is in use during exposure and when the radiation source is recovered to the source storage unit after the use of the exposure to check the difference safely and reliably to prevent human and physical damage. This can be prevented in advance, and safer radiation exposure can be prevented.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes within the scope not departing from the technical spirit of the present invention are possible in the art. It will be evident to those who have knowledge of.

1: radiation source
10: housing
20: notification means
30: power supply means
40: sensing means
41: proximity sensor
100: sailor storage unit
200: sailor information tube
300: source recovery check device
400: stand
500: remote control unit
600: radiation source fixture
P: test body
F: film

Claims (15)

An apparatus for checking the number of sources in a non-destructive inspection device comprising a radiation source storage unit and a source guide tube,
A housing connected to a source moving inlet / outlet formed in the radiation source storage unit;
Notification means provided on one side of the housing;
Power supply means for supplying power to the notification means; And
And sensing means provided in the housing and controlling the power supply of the power supply means by detecting the presence or absence of a moving state of the source moving through the source moving inlet / outlet.
Source recovery check device for radiographic examination.
The method of claim 1,
The housing
A connection adapter provided at one side to be connected to a source moving inlet / outlet of the radiation source storage unit;
A source guide tube fastener provided on the other side to be connected to the source guide tube;
A power supply means arranging unit which is formed such that the power supply means is disposed inside one side;
Notification means arrangement unit is formed so that the notification means is disposed inside the other side; And
It includes a movement passage for communicating between the connection adapter and the crew guide tube fasteners;
Source recovery check device for radiographic examination.
The method of claim 2,
The sensing means is installed at one end of the movement passage
Source recovery check device for radiographic examination.
The method of claim 1,
The notification means is composed of a light emitting unit
Source recovery check device for radiographic examination.
The method of claim 1,
The notification means is composed of a sound generating unit
Source recovery check device for radiographic examination.
The method of claim 1,
The notification means comprises a module in which the light emitting unit and the sound generating unit are integrated.
Source recovery check device for radiographic examination.
The method of claim 1,
The sensing means is composed of a proximity sensor
Source recovery check device for radiographic examination.
The method of claim 7, wherein
The proximity sensor is formed in an annular shape
Source recovery check device for radiographic examination.
The method of claim 1,
The sensing means
An optical sensor including a light emitting unit and a light receiving unit; And
And a control unit controlling a power supply of the power supply means based on the detection signal of the optical sensor.
Source recovery check device for radiographic examination.
A moving state of a source that is recovered between the source storage unit for storing the radioisotope source and the source guide tube for guiding the source through the designated path from the source storage unit to the exposure position where the test object is located is recovered to the source storage unit. Claims 1 to 9 to confirm the presence of a radiographic inspection source recovery check device according to any one of claims 1 to 9
Non-destructive testing device.
The method of claim 10,
The source recovery check device is installed directly in front of the source storage unit
Non-destructive testing device.
A source storage unit for storing a radioisotope source;
A source guide tube for guiding the source through a designated path from the source storage unit to an exposed position where the test object is located;
Claim 1 to 9 provided between the source guide tube and the source storage unit, the source recovery check device of any one of claims 1 to 9 installed in front of the source storage unit; And
It is connected to the source storage unit, including a remote operation unit for operating to move the source along the source guide tube;
NDT device.
A method for checking the number of sources in a non-destructive inspection device comprising a radiation source storage unit and a source guide tube,
A detection step of detecting the presence or absence of a moving state of the source in front of the source storage unit; And
A notification step of notifying the presence or absence of a movement state of the source based on the detection result detected in the detection step;
Source recovery check method for radiographs.
The method of claim 13,
The detecting step detects the presence or absence of a moving member or moving member for moving the source through a proximity sensor or an optical sensor.
Source recovery check method for radiographs.
The method according to claim 13 or 14,
The notifying step informs the operator by at least one of a visual signal or an audio signal according to the detection result in the detecting step.
Source recovery check method for radiographs.

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