KR101250801B1 - Radiation projector with alarm - Google Patents

Abstract

PURPOSE: A radiator with an alarming function is provided to confirm a position of a radiation source so that an operator enables to perform a work without being exposed to radiation. CONSTITUTION: A radiator with an alarming function comprises a container(100), a guide tube(200), a manipulation cable(300), a first alarm module(400), a second alarm module(500), and a third alarm module(600). A radiation source(120) protected by a shielding body(110) is embedded in the container. The guide tube reaches a specimen by being connected to one side of the container, and the radiation source is transferred along the inside of the guide tube. The manipulating cable is connected to the other side of the container and pulls and pushes the radiation source so that the radiation source is transferred. The first alarming module is arranged on the exterior surface of the container and includes a first sensor(410), a control unit, a battery, and a first alarm. The second alarming unit includes a second sensor(510), a control unit, a battery, and a second alarm, thereby generating alarming signals using the second alarm when the radiation source is passed. The third alarming module is arranged adjacent to the other end of the guide tube and includes a third sensor(610), a control unit, a battery, and a third alarm.

Description

Radiator with alarm function {RADIATION PROJECTOR WITH ALARM}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radiographic testing (RT), which is one of non-destructive tests, and relates to an irradiator having an alarm function that enables workers to work safely without being exposed to radiation.

Non-destructive Testing (NDT) is a comparison of standards by detecting changes in the transmission, absorption, scattering, reflection, penetration, leakage, etc. by giving some kind of input without changing the shape and dimensions. It refers to an inspection method for examining the presence or absence of abnormality, its size, and distribution state without destroying the test article. It is mainly used for inspection of welded products, castings, rolled materials, and the like.

Popular non-destructive testing methods include radiographic testing (RT), magnetic particle testing (MT), liquid penetration testing (PT), ultrasonic testing (UT), and eddy current testing. (ET: Eddy Current Testing), Leak Testing (LT).

Radiographic examination (RT) is mainly for inspecting internal defects of industrially produced products. After taking pictures using gamma rays among radiations emitted from radioactive materials such as iridium-192, they are developed. By analyzing the blackness by printing, the presence of internal defects in the product can be determined.

Non-destructive testing using radiation sources tends to increase in use because power is not needed.

However, because dangerous radioactive materials are used, operators must be extremely careful and pay close attention to the handling of equipment.

As a related art related to the present invention, there is a "radiation irradiator having a support frame for fixing a shielding body" (hereinafter referred to as "the prior art 1") of Republic of Korea Patent No. 10-1033633 (registered April 29, 2011), and another As a technique, there is a "radiation source transmission tube capable of detecting a radiation source location" (hereinafter referred to as "the prior art 2") of Republic of Korea Utility Model No. 20-0389799 (registered on July 6, 2005).

Prior art 1 discloses the concept of a non-destructive testing system including a radiation source assembly.

1 is a schematic diagram of a non-destructive testing system including a radiation source assembly, and FIG. 2 is a perspective view of the radiation source assembly.

A radiation source assembly 1 having the radiation source 2 inserted therein as shown, a radiation irradiator 3 for transporting and storing the radiation source assembly 1 inside to prevent leakage of radiation, A control cable assembly 5 for controlling the radiation source assembly 1 in connection with the radiation source assembly 1 and a guide connected to the radiation irradiator 3 for guiding the radiation source assembly 1 to the position of the inspection object during the non-destructive inspection. The tube 7 and the like are prepared. In addition, a variety of accessory preparations, including films, are used.

More specifically, the radiation source assembly 1 includes a capsule 25 in which iridium-192 is embedded as a radiation source that emits radiation as shown in FIG. 2, a wire 27 connected to one end of the capsule and the other end of the wire. The female connector 29 to be connected consists of one assembly.

The control cable assembly 5 is schematically mounted at the handle 15, the gear 17, the wire 19 and the end of the wire, and engages with the female connector 29 constituting the radiation source assembly 1. It is made of a male connector (not shown). The control cable assembly 5 is mounted on the front end face of the radiation irradiator 3 and is rotated by the handle 15 in the state connected with the female connector 29 of the radiation source assembly 1 via the male connector 1. ) To the subject or to return to the radiation irradiator (3) after the operation.

The guide tube 7 is connected to the connecting device located on the rear end plate of the radiation irradiator 3 with the nozzle 23 at the end positioned at the position of the subject, and is operated by the control cable assembly 5. The radiation source assembly (1) exiting 3) is guided to the subject.

Prior art 2 relates to a transmission tube of a radiation irradiator, FIG. 3 is a view showing an embodiment of a radiation irradiator transmission tube, and FIG. 4 is a side view of the transmission tube showing the light emission principle of the radiation irradiator transmission tube.

As shown in the drawing, the transmission tube further includes a detection layer having a light emitting layer made of a flash material for converting the light into the light of the first wavelength band in response to the radiation source radiated from the radiation source.

Therefore, the position of the radiation source in the transmission pipe can be visually confirmed.

The irradiator is useful and very dangerous and requires careful management and use, and prior art 2 allows the radiation source to be visually identified outside the transmission line for this purpose.

However, when using a radiation irradiator, the operator is located at a long distance to operate the radiation source to move so that it is not easy to accurately determine the position of the radiation source in the form as in the prior art 2.

In addition, since the radiation irradiator body is shielded, there is a problem in that it is not confirmed whether the radiation source exists in the radiation irradiator body. In other words, if the transmission pipe itself has a problem, the operator may misjudge that the radiation source is in the irradiator body.

1. Republic of Korea Patent No. 10-1033633 (registered April 29, 2011) 2. Republic of Korea Utility Model No. 20-0389799 (Registered July 6, 2005)

Therefore, the present invention is to provide a radiation irradiator having an alarm function so that the radiation irradiator can be used more safely.

The radiation irradiator having an alarm function of the present invention for achieving the problem as described is a container in which a radiation source is protected by a shield; A guide tube connected to one side of the container to reach near the sample and to move the radiation source along the inside; An operation cable connected to the other side of the container and pushing and pulling the radiation source to move the radiation source along the guide tube; A first sensor provided on an outer surface of the container and configured to detect whether the radiation source is present in the shield, a controller configured to determine whether an alarm is generated by receiving a detection signal from the first sensor, and a battery connected to the controller A first alarm module including a first alarm generating a signal according to a command of the controller; It is provided near one end of the guide tube connected to the container, a second sensor, a control unit for determining whether to generate an alarm by receiving a detection signal from the second sensor, a battery connected to the control unit, according to the command of the control unit A second alarm module that generates a warning signal through the second alarm when the radiation source passes, including a second alarm generating a signal; It is provided near the other end of the guide tube, a third sensor, a control unit for determining whether to generate an alarm by receiving a detection signal from the third sensor, a battery connected to the control unit, and generating a signal according to the command of the control unit And a third alarm module configured to generate a warning signal through the third alarm when the radiation source is located at the other end of the guide tube, including the third alarm, wherein the first sensor is predetermined from a wall surface of the shield. It is characterized in that it is inserted into the installation passage formed to a depth.

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And in the present invention, the installation passage is made of a form bent more than once, characterized in that the installation passage is provided with a shielding plug or shielding filler to block the leakage of radiation.

Irradiator having an alarm function according to the present invention can accurately determine whether the radiation source is located inside or outside the shield through a plurality of alarms has the effect that the operator can safely work without being exposed to radiation.

1 is a schematic diagram of a non-destructive testing system including a radiation source assembly.
2 is a perspective view of a radiation source assembly.
3 shows an embodiment of a radiation irradiator tube;
4 is a side view of a transmission tube showing the light emission principle of the irradiator transmission tube;
5 is a schematic configuration diagram of a radiation irradiator according to an exemplary embodiment of the present invention.
6 is a schematic enlarged view of an internal structure of a container;

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention in the drawings, portions not related to the description are omitted, and like reference numerals are given to similar portions throughout the specification.

Whenever a component is referred to as "including" an element throughout the specification, it is to be understood that the element may include other elements, not the exclusion of any other element, unless the context clearly dictates otherwise.

5 is a schematic configuration diagram of a radiation irradiator according to an exemplary embodiment of the present invention. 6 is a schematic enlarged view of an internal structure of a container.

As shown, the radiation irradiator according to the present invention includes a container 100, a guide tube 200, an operation cable 300, a first alarm module 400, a second alarm module 500, and a third alarm module 600. )

The irradiator according to the present invention can be used to read the presence or absence of defects on welds and the like, and is particularly suitable for use in a portable manner.

Container 100 is preferably a form that can be carried by the operator in the form of a box.

The container 100 has a radiation source 120 protected by the shield 110, the shield 110 is made of the same as lead (Pb) to shield the radiation.

The radiation source 120 is used, such as iridium-192, and the radiation source 120 is connected to one end of the wire 130, and the shield 110 has a passage through which the radiation source 120 and the wire 130 can be moved. Formed.

The guide tube 200 is connected to one side of the container 100, and the guide tube 200 is a long tube that reaches near the sample to be tested, and the radiation source 120 guides the inside of the guide tube 200. Up to 200).

An operation cable 300 is connected to the other side of the container 100, and the operation cable 300 pushes and pulls a wire 130 connected to the radiation source 120 by a worker operating a predetermined handle, thereby shielding 110. From the radiation source 120 is moved to the end of the guide tube 200 to be able to perform a non-destructive inspection. When the operation is completed, the handle is reversed and the radiation source 120 is pulled back into the shield 110.

Similar to the known irradiator, the irradiator of the present invention is also stored in the shield 110 inside the container 100 and is operated by using the operation cable 300 only when the inspection of the sample is to be performed. The radiation source 120 exits the shield 110 through the guide tube 200 and moves to the end of the guide tube 200. This general matter will be omitted.

In particular, the present invention is characterized in that a plurality of alarms are provided to be able to use the radiation irradiator more safely.

The first alarm module 400 is provided on an outer surface of the container 100, and the first alarm (not shown) may include a first sensor 410 capable of detecting whether the radiation source 120 is present inside the shield 110. ) To generate a predetermined signal. In addition, the first alarm module 400 includes a controller (not shown) connected to the first sensor 410 and a battery (not shown) for power supply. The control unit determines whether to generate a warning signal by receiving a signal provided by the first sensor 410, and when radiation of a predetermined value or more is detected, the control unit commands the first alarm to provide a predetermined warning signal in the first alarm. Automatic control so that can be generated.

The first sensor 410 is attached to the shield 110 as a sensor capable of detecting radiation, and the shield 110 has a considerable thickness so that the radiation cannot be transmitted, so the first sensor 410 is installed in the shield 110 in this embodiment. Leave the passage (111).

That is, an installation passage 111 recessed to a predetermined depth from any one outer wall surface of the shield 110 is formed, and the radiation source existing inside the shield 110 by embedding the first sensor 410 in the installation passage 111. 120 can be detected.

More preferably, the installation passage 111 is preferably a complicated passage form that is bent at least once as shown, which is a method for maximally suppressing the radiation passing through the shield 110. By making the installation path 111 in the form of a letter as in this example, the first sensor 410 in the deepest can minimize the distance between the first sensor 410 and the radiation source 120 while preventing the leakage of radiation. have.

After placing the first sensor 410 at the deepest portion of the installation passage 111, the installation passage 111 may include a shielding plug 112 or a shielding filler made of a shielding material having the same or similar performance as that of the shield 110. To be sealed by 112). Of course, the wire connected to the first sensor 410 extends to the outside of the shield 110 to be connected to the control unit of the first alarm module 400.

When the radiation source 120 is present in the shield 110, the first sensor 410 detects this and transmits an electrical signal to the control unit of the first alarm module 400, and the control unit determines this in the first alarm. Instructs certain predetermined signals to be generated.

Signals generated from the first alarm module 400, the second alarm module 500 and the third alarm module 600 to be described below may be predetermined lights or predetermined voice signals.

For example, in the case of the first alarm module 400, when the radiation source 120 is present inside the shield 110, the green light may be turned on in the sense of being safe.

The second alarm module 500 is provided near one end of the guide tube 200 connected to the container 100, and the second alarm module 500 includes a second sensor 510, a controller (not shown), and a battery. (Not shown) and a second alarm (not shown) are included.

The second sensor 510 detects the radiation source 120 passing through the guide tube 200 and provides a detection signal to the control unit. The control unit judges this, and when a radiation of a predetermined value or more is detected, a predetermined voice or light is detected by the second alarm. It is controlled so that a signal can be generated.

For example, when the radiation source 120 passes near the second alarm module 500 when the radiation source 120 inside the shield 110 to the guide tube 200 for inspection of the sample, the second sensor 510. The controller detects this and provides a detection signal to the controller, and the controller determines that the second alarm is operated to generate a predetermined signal.

Preferably, the second alarm is operated only while the second sensor 510 detects the radiation source 120. Therefore, when the radiation source 120 passes the second alarm module 500 toward the other end of the guide tube 200, the operation of the second alarm is stopped.

The red light can be turned on or generate a voice signal, and the light and sound can be generated at the same time.

The third alarm module 600 is provided near the other end of the guide tube 200, and the third alarm module 600 includes a third sensor 610, a controller, a battery, and a third alarm. The third sensor 610 detects that the radiation source 120 is located at the other end of the guide tube 200, the detection signal by the third sensor 610 is provided to the control unit and the control unit determines the third Determine and control the alarm operation.

When the radiation source 120 is sent near the other end of the guide tube 200 to check for defects on the sample, the third sensor 610 detects this and provides an electrical signal to the controller, and the controller The control command is issued to activate the alarm, and accordingly, the third alarm generates a warning message through lights or / and sounds.

When the radiation source 120 is located at the other end of the guide tube 200, a non-destructive test on the sample is performed.

Preferably, the third alarm is to continue to generate a predetermined warning signal during the test on the sample, the operation of the third alarm is stopped when the radiation source 120 is moved back to the shield 110 after the test is completed.

On the other hand, when the radiation source 120 passes the second alarm module 500 during the process of moving to the shield 110, the second sensor 510 detects this to operate the second alarm. When the radiation source 120 enters the shield 110, the operation of the second alarm is stopped.

That is, when the radiation source 120 in the shield 110 is sent out along the guide tube 200, first the second alarm generates a signal, and then the signal is also generated in the third alarm.

In the case of the first alarm, when the radiation source 120 exits the shield 110, the signal of the first alarm is stopped, and when the test is finished and the radiation source 120 enters the shield 110 again, the first alarm is again predetermined. To generate a signal.

When a signal is generated in the first alarm, the signal is not generated in the second alarm and the third alarm.

Irradiator having an alarm function according to the present invention as described above has the advantage that the operator can more easily identify the position of the radiation source through a visual or audio signal to enable safe operation.

In addition, since the first alarm, the second alarm, and the third alarm work organically with each other, even when one of the alarms malfunctions or malfunctions, the user can work while paying more attention through the operation of other alarms.

The foregoing description of the present invention is intended for illustration, and it will be understood by those skilled in the art that the present invention may be easily modified in other specific forms without changing the technical spirit or essential features of the present invention. will be.

It is therefore to be understood that the embodiments described above are intended to be illustrative, but not limiting, in all respects. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

The irradiator having an alarm function according to the present invention can be used for the purpose of nondestructively confirming the presence or absence of internal defects such as welded parts or castings.

100 container 110 shielding body
111: installation passage 120: radiation source
130: wire 200: guide tube
300: control cable 400: first alarm module
410: first sensor 500: second alarm module
510: second sensor 600: third alarm module
610: third sensor

Claims (3)

In the irradiator for reading the presence of defects in the sample,
A container having a radiation source protected by the shield;
A guide tube connected to one side of the container to reach near the sample and to move the radiation source along the inside;
An operation cable connected to the other side of the container and pushing and pulling the radiation source to move the radiation source along the guide tube;
A first sensor provided on an outer surface of the container and configured to detect whether the radiation source is present in the shield, a controller configured to determine whether an alarm is generated by receiving a detection signal from the first sensor, and a battery connected to the controller A first alarm module including a first alarm generating a signal according to a command of the controller;
It is provided near one end of the guide tube connected to the container, a second sensor, a control unit for determining whether to generate an alarm by receiving a detection signal from the second sensor, a battery connected to the control unit, according to the command of the control unit A second alarm module that generates a warning signal through the second alarm when the radiation source passes, including a second alarm generating a signal;
It is provided near the other end of the guide tube, a third sensor, a control unit for determining whether to generate an alarm by receiving a detection signal from the third sensor, a battery connected to the control unit, and generating a signal according to the command of the control unit And a third alarm module configured to generate a warning signal through the third alarm when the radiation source is located at the other end of the guide tube, including the third alarm.
And the first sensor is inserted into an installation passage formed at a predetermined depth from the wall surface of the shield. The method of claim 1,
The installation passage,
The radiation irradiator having an alarm function, characterized in that the bending is formed more than once, the installation passage is provided with a shielding plug or shielding filler to block the leakage of radiation.
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