KR101500285B1 - Collimator transfer device of gamma-ray irrdiation apparatus for calibration - Google Patents

Abstract

The present invention relates to a collimator transfer device of a gamma-ray irradiation apparatus for calibration. The collimator transfer device facilitates work convenience and shortens working time by reciprocally transferring a collimator without replacing the collimator in accordance to the type of isotopes to be examined. Moreover, the collimator transfer device aims to improve work efficiency which makes the examination work of a measurement device easier by the gamma-ray irradiation apparatus for calibration. To achieve the above, the collimator transfer device of the gamma-ray irradiation apparatus for calibration examines a radiation measurement device by irradiating radiation through an irradiator having the collimator on one side thereof, and comprises: a transfer device (100) on one side of the irradiator (2), which reciprocally transfers the collimator (3) to a certain area in accordance to the type of isotopes, and allows the collimator to be carried out in the examination operation without an additional replacement in accordance to the type of isotopes.

Description

TECHNICAL FIELD [0001] The present invention relates to a collimator transfer device for a calibration gamma-ray irradiating device,

More particularly, the present invention relates to a collimator feeding apparatus for a calibrating gamma ray irradiating apparatus, and more particularly, to a collimator feeding apparatus for calibrating a gamma-ray irradiating apparatus, in which the collimator is not replaced according to the kind of isotope to be inspected, To a collimator transporting apparatus for a calibration gamma ray irradiating apparatus which improves the efficiency of work for facilitating the inspection work of the measuring apparatus through the calibration gamma irradiation apparatus.

In general, portable radiometers (also known as "survey meters") are used in military units, industries, medical institutions, and laboratories to measure the presence and amount of radioactive materials around them. Since radioactive materials may have extremely harmful effects on the human body, the accuracy and reliability of the performance of the radiation measuring instrument should be ensured. For this purpose, only the radiation measuring instrument which has been thoroughly tested and inspected is used with the passing test certificate.

In order to test, verify and calibrate the above-mentioned radiation meter to show the correct measurement value, the radiation is measured on the measuring instrument calibration and inspection apparatus, and the measured value is compared with the reference value through the measurement value of the radioisotope type and the irradiation distance .

As shown in FIG. 1, a conventional calibration gamma ray irradiation apparatus (or a calibration apparatus of a radiation measurement apparatus) is provided with an irradiation unit 2 having a radioisotope therein, The movable fixing table 4 on which the target measuring instrument is placed is movably positioned so as to adjust the distance between before and after. The irradiator 2 is seated on the upper side of the central axis adjusting device 1, and the bottom surface of the irradiator 2 is engaged. The collimator 3 for converting divergent light radiated from the irradiator 2 into collimated light is formed in the illuminator 2.

An X-axis feed device 5 provided with a guide rail 5a in front of the central axis adjusting device 1 is provided and a movable fixing table 4 to be moved along the guide rails 5a is provided above the X- .

The movable fixing table 4 is connected to the timing belt 5d which is connected to the timing pulley 5c and the X axis driving motor 5b and rotates in accordance with the operation of the X axis driving motor 5b, The distance between the irradiation devices 2 can be adjusted according to the operation of the X-axis driving motor 5b. That is, when the X-axis driving motor 5b rotates, the timing belt 5d moves, and the movable fixing table 4 connected thereto also moves along the guide rail 5a.

A measuring device to be inspected is mounted on the pedestal 4b in the movable fixing table 4, and a camera 4a is provided on the top. A CCTV camera 8 is installed on a wall surface of the guide rails 5a facing the central axis adjusting device 1 so that the CCTV camera 8 can be seen from the outside and the center point of the source 2 of the irradiator 2 and the center point of the laser beam are arranged below the guide rail 5a. The laser beam generator 7 is installed at a height corresponding to the entire area of the laser beam generator 7. A measuring device to be measured is fixed to the upper end of the pedestal 4b of the movable fixing table 4, and a laser is generated in the laser generating device 7. [

At this time, since the generated laser beams are collinear with the radiation beams generated in the radiation beam machine 2, the height of the pedestal of the movable beam table 4 is adjusted, and the path of the laser beam is aligned with the inspection point of the measuring instrument. When the radiation point of the laser generator 7 and the radiation point of the radiation irradiator 2 do not coincide with each other, the laser 2 is used to set the correct focus, , And it is adjusted by rotating it in the range of ± 5 ° to the right. In addition, the height of the pedestal 4b is adjusted in the movable fixing table 4 so that the inspection point of the measuring instrument is accurately aligned with the position of the laser.

After setting the precise position by using the irradiation device 2 and the movable fixing table 4, all the workers close the door and exit to the outside of the computer system. Then, the CCTV camera (8) Measurement can be performed while checking.

When a beam is generated with a certain diameter from a source such as a radioactive isotope placed in the irradiation apparatus 2, the generated beam starts to irradiate the measuring apparatus located at the upper end of the receiving base 4b.

During irradiation, the dose rate value displayed on the upper display of the measuring device is photographed through the camera 4a and transmitted to the examiner outside the laboratory. When the measurement is completed at the initial distance, the X-axis driving motor 5b is driven to move the movable fixing table 4 backward. When the measurement is made at a constant distance, the dose rate of the measuring apparatus is measured and checked.

2, the irradiator 200 includes a shielding housing 210 having a thickness of a few tens of centimeters, a radiation port 220 formed on one side thereof, and the air cylinder 230 and the loader 232 of the air cylinders (a, b, c) are arranged in a line. The collimator 3 is formed in the spinneret 220.

Each of the loaders 232 is moved up and down according to the control and various types of radioactive isotopes a1, a2 and a3 are located at the upper end of the loader 232. [ Since radioisotopes are characterized by distance and type, there are many kinds of radioisotopes to be selectively used depending on the object and purpose of inspection.

For example, when irradiation of a1 is required, the cylinder a is operated to draw the loader 232 upward. the drawn loader 232 is at its height until the radioisotope of a1 is positioned at the front of the radiating aperture 220 and the radiation from a1 passes through the collimator 240 formed in the radiating aperture 220 to the outside And reaches the measurement apparatus.

If a2 and a3 elements having different properties are to be inspected, the load 232 of the a cylinder 230 is lowered and then the b and c cylinders 230 are sequentially operated so that a2 and a3 elements are moved to the collimator 240, To the height of. In addition, since the irradiation doses irradiated from the elements a1 to a3 are different, the collimator 240 must be replaced accordingly.

However, in the case of replacing the collimator device, the collimator is made of lead having a high specific gravity, so that it is impossible to replace the collimator device by the force of the worker alone, which makes it unnecessary to waste unnecessary labor and to replace the collimator .

In addition, there is a risk that a safety risk of a worker can be covered by radiation.

Korean Patent No. 531258 (Registered on November 21, 2005) Korean Patent No. 805887 (Registered on February 14, 2008) Korea Patent No. 1169423 (registered on July 23, 2012) Korean Patent No. 1174384 (Registered on August, 2012)

SUMMARY OF THE INVENTION It is an object of the present invention to solve the problems described above and to provide a method and a device for controlling a collimator by exchanging a collimator according to a kind of isotope to be inspected, And an object of the present invention is to provide a collimator feeding device for a calibration gamma ray irradiating apparatus which improves the efficiency of work for facilitating the inspection work of the measuring apparatus through the calibration gamma ray irradiating apparatus.

According to an aspect of the present invention, there is provided a calibration gamma ray irradiation apparatus for irradiating a radiation measurement apparatus with radiation through an irradiation apparatus having a collimator on one side, And a conveying device that reciprocates the collimator to a predetermined area so that the collimator is not replaced but is performed in the inspection work depending on the kind of the isotope.

In the present invention, the conveying device may include a conveying part formed at one side of the irradiation device and generating a conveying force so that the collimator is reciprocated in accordance with the zone; A guiding part which is formed at one side of the irradiation device and has one end fixed to the collimator to support the collimator so as to reciprocate in a predetermined area; And a connection part connecting the conveying part and the guide part to allow the guide part to be conveyed according to the conveying force generated in the conveying part so that the collimator is conveyed in each zone.

In the present invention, the conveying unit includes: a cylinder that generates a reciprocating conveying force by a pressure externally provided; And a piston rod reciprocally transported by a transfer force generated from the cylinder and having one end fixed to the connection portion.

In the present invention, the cylinder is preferably of a recuperative type.

In the present invention, the irradiation device includes a shielding portion for preventing radiation from leaking through the collimator; The shield includes a first housing configured to prevent radiation from leaking while guiding the distance that the collimator is reciprocated by the transfer device; And a second housing configured to surround the outer circumference of the first housing to prevent radiation from leaking between the irradiator and the collimator.

According to the present invention, the inspection operation of the measuring device through the calibrating gamma ray irradiating device can be performed by exchanging the collimator according to the kind of the isotope to be inspected, There is an effect that the efficiency of the work for facilitating the operation is improved.

1 is a schematic front view of a conventional gamma-ray irradiation apparatus for calibration.
2 is a schematic cross-sectional view of a conventional irradiator.
3 is a schematic perspective view of an irradiator in which a collimator feeder according to the present invention is constructed.
FIG. 4 is a cross-sectional view showing a feeding state of the collimator feeding device according to the present invention,
4a is a point at a, 4b is at a point b, and 4c is at a point c.
5 is an enlarged cross-sectional view of a transfer device according to the present invention.
FIG. 6 is a schematic side view of a collimator feeding device according to the present invention. FIG.
7 is a view schematically showing an operating state of a cylinder constituted in a conveyance unit according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings (the same reference numerals are used for the same components as the conventional ones, and a detailed description thereof will be omitted).

As shown in FIG. 3, the irradiation device 2 of the calibration gamma irradiation device of the present invention is provided with a transfer device 100 for transferring the collimator 3 according to the kind of radiation irradiated through the irradiation device 2 .

The transporting device 100 transports the collimator 3 by a predetermined length according to the type of the radioactive isotope and irradiates the measuring device with smoothening light that is smooth depending on the kind of the isotope.

4 and 5, the transfer device 100 includes a shielding part 110 configured to surround the collimator 3 to prevent radiation from leaking, and a shielding part 110 formed on one side of the irradiation device 2 A conveying unit 120 for conveying the collimator 3 so that the collimator 3 can be reciprocated between points a and c and a conveying unit 120 for conveying the collimator 3 reciprocally by receiving the conveying force of the conveying unit 120. [ And a connection part 140 for connecting the transfer part 120 and the guide part 130 so as to smoothly transfer the transfer part.

The shielding portion 110 is a means for shielding radiation from leaking through the collimator 3 that reciprocates between points a to c.

The shield 110 surrounds the outer periphery of the collimator 3 and includes a first housing 112 for preventing the collimator 3 from being exposed to the outside when the collimator 3 is reciprocated, And a second housing 114 surrounding the outer periphery of the first housing 112 and shielding the radiation.

The first housing 112 is configured to be in surface-contact with the outer periphery of the collimator 3 so that the collimator 3 can be smoothly reciprocated. In this case, the first housing 112 may be formed of a metal or a nonmetal.

A first guide groove 113 is formed at one side of the first housing 112 so that one end of the guide part 130 is fixed to the collimator 3 and then is not interfered with the reciprocating movement. The first guide groove 113 may be formed in a rectangular shape. Of course, the present invention is not limited thereto, and any shape can be adopted as long as it does not interfere with the reciprocation of the guide portion 130.

The second housing 114 is a means for sealing the space between the irradiator 2 and the first housing 112 to prevent radiation leakage.

The second housing 114 is fixed to the irradiator 2 and is formed of cement or lead to enhance the radiation shielding efficiency.

A second guide groove 115 is formed at one side of the second housing 114 so as not to interfere with the reciprocating movement of the guide portion 130 for guiding the reciprocating movement of the collimator 3. The second guide groove 115 may be formed by cutting one side of the second housing 114 to smoothly guide the guide part 130. Of course, the present invention is not limited to this, and it may be formed in a rectangular shape, and any shape can be adopted as long as it does not interfere with the reciprocating movement of the guide portion 130.

At least one fixing groove is formed in the collimator 3 so as to be fixed to one end of the guide unit 130. Of course, the present invention is not limited thereto, and any means can be used as long as it is fixed to one end of the guide portion 130 and stably reciprocates.

The conveying unit 120 is fixed to one side of the irradiator 2 and is a means for providing a conveying force so that the collimator 3 can be accurately reciprocated.

The transfer unit 120 includes a cylinder 122 that generates a reciprocating transfer force and a piston rod 124 that reciprocates according to a reciprocating transfer force generated by the cylinder 122.

It is preferable that the cylinder 122 is constructed in a recuperative manner so that it can be accurately reciprocated and transported in each of the zones a to c.

For example, the cylinder 122 is composed of a first cylinder 1222 and a second cylinder 1224, as shown in FIG. The first piston rod 1242 configured in the first cylinder 1222 is connected to the second piston rod 1244 configured in the second cylinder 1224. In addition, the second piston rod 1244 protrudes outside the second cylinder 1242.

In this case, as shown in FIG. 7A, the end of the second piston rod 1244 is maintained at a position 'a'.

7 (b), when the forward input is provided to the first cylinder 1222 and the forward input is provided to the first cylinder 1222, The second piston rod 1244 connected to the first piston rod 1224 is advanced in parallel with the first piston rod 1224 and the end of the second piston rod 1244 is advanced by ' Lt; / RTI >

7 (c), when the second piston rod 1244 is provided with a positive input advancing forward to the second cylinder 1242, when the piston rod 1244 is to be transferred to the point 'c' 2 cylinder 1242, the end of the second piston rod 1244 is positioned at the point "c".

That is, by constituting the cylinder 122 with a double row, it is possible to provide a reciprocating feed force accurately for each of the zones a to c. Of course, the present invention is not limited to this, and any means can be used as long as it can precisely and precisely provide a conveying force to each of the points a to c. For example, various methods such as a screw shaft method, a mechanical method such as a rack and pinion method, or an electronic method using a sensor can be used.

The guide part 130 is formed on one side of the irradiation device 2 and has one end fixed to the collimator 3 to guide the reciprocating movement of the collimator 3.

The guide part 130 includes a guide rail 132 having one end fixed to the irradiator 2 and a transport block 134 positioned on the guide rail 132 and reciprocated along the guide rail 132, And a fixing block 136 for connecting and fixing the guide block 134 and the collimator 3.

The guide rail 132 has a predetermined length to guide the reciprocating distance of the collimator 3.

The transport block 134 is positioned on the guide rail 132 and is reciprocally transported stably along the guide rail 132.

Further, the guide rail 132 and the transport block 134 are preferably configured by an LM guide system. Of course, the present invention is not limited thereto, and any means can be used for supporting the collimator 3 so as to stably reciprocate the collimator 3.

The fixing block 136 connects the conveying block 134 and the collimator 3 to support the collimator 3 to be stably conveyed together with the conveying block 134. As shown in FIG. 4, the fixing block 136 may include a plurality of fixing blocks 136, but the present invention is not limited thereto. For example, the fixing block 136 may be a unit for supporting the collimator 3 to be stably transported along the transport block 134 Can be used.

The connection unit 140 connects and secures the transfer unit 120 and the guide unit 130 so that the transfer unit 120 stably transfers the transfer unit 120 to the guide unit 130 by the reciprocating transfer force generated by the transfer unit 120, Is a means for causing the collimator 3 to reciprocate.

4, the connection unit 140 may be formed in a plate shape that connects the piston rod 124 of the transfer unit 120 and the transfer block 134 of the guide unit 130 with each other. Of course, the present invention is not limited thereto, and any means can be used as long as it can stably connect and fix the transfer unit 120 and the guide unit 130.

In this case, one end of the guide part 130 may be directly fixed to the conveying part 120. In this case,

The irradiator 2 includes a cover 150 for protecting the transfer unit 120 and the guide unit 130. Of course, the cover 150 can be omitted, and it is possible to select a cooking course according to the purpose of use or the demand of the user.

The operation state of the collimator feeding device of the above-described gamma-ray irradiating apparatus for calibration will be described below.

First, as shown in FIG. 4A, when the inspection operation using the isotope of 'a' is performed, the air cylinder 230 in the 'a' zone constituted in the irradiation device 2 is operated and the collimator 3 Are located on the same axis line.

At this time, the collimator 3 is located at the point " a ".

Next, as shown in FIG. 4B, when the inspection work using the isotope 'b' is performed, the air cylinder 230 in the 'b' zone formed in the irradiation device 2 is operated.

Further, a forward feed force is generated in the cylinder 122 of the transfer unit 120, and thus the cylinder rod 124 is advanced. This is illustrated in FIG. 7 (b).

At this time, the guide part 130 is also advanced through the connection part 140 connected to the cylinder rod 124, and the collimator 3 is advanced to the position corresponding to 'b'.

Also, as shown in FIG. 4C, when the inspection work using the isotope 'c' is performed, the air cylinder 230 in the 'c' zone formed in the irradiator 2 is operated.

Further, a forward feed force is generated in the cylinder 122 of the transfer unit 120, and thus the cylinder rod 124 is advanced. This is shown in Fig. 7 (c).

At this time, the guide part 130 is also advanced through the connection part 140 connected to the cylinder rod 124, and the collimator 3 is advanced to the position corresponding to 'c'.

In this manner, the collimator 3 is reciprocated without being replaced depending on the kind of the isotope to be inspected, thereby reducing the convenience of the work and the work time, thereby improving the efficiency of the work.

Meanwhile, as shown in FIG. 3, the illuminator 2 includes a display unit 160. The display unit 160 allows the operator to easily determine how many times the sources a1, a2 and a3 in the irradiator 2 are operated and the collimator 3 is conveyed by the conveying apparatus 100 So that it can be grasped.

The above description is only one embodiment for carrying out the collimator transporting apparatus of the gamma ray irradiating apparatus for calibration, and the present invention is not limited to the above embodiment. It will be understood by those skilled in the art that various changes may be made without departing from the spirit of the invention.

100: transfer device 110: shielding part
112: first housing 114: second housing
120: transfer part 122: cylinder
124: piston rod 1222: first cylinder
1224: first piston rod 1242: second cylinder
1244: second piston rod 130: guide part
132: guide rail 134: conveying block
136: fixed base 140:
150: Cover 160: Display

Claims (5)

1. A calibration-use gamma-ray irradiation apparatus for irradiating a radiation through an irradiation device (2) having a collimator (3)
The conveyor 100 is provided at one side of the irradiator 2 so that the collimator 3 is reciprocated in accordance with the kind of the isotope so that the collimator 3 is carried out in the inspection work depending on the kind of the isotope and;
The transfer device 100 includes a transfer part 120 formed at one side of the irradiation device 2 and generating a transfer force so that the collimator 3 is reciprocated in accordance with the area.
A guiding part 130 formed on one side of the irradiator 2 and having one end fixed to the collimator 3 to support the collimator 3 in a reciprocating manner to a predetermined area; And
The guide unit 130 is connected to the feed unit 120 and the guide unit 130 so that the guide unit 130 is fed according to the feed force generated by the feed unit 120 so that the collimator 3 is fed A connection portion 140;
And a collimator feeding device for feeding the collimator to the irradiation gamma irradiation device.
delete [3] The apparatus according to claim 1,
A cylinder 122 which generates a reciprocating feed force by an externally provided pressure; And
A piston rod 124 reciprocated by a transfer force generated from the cylinder 122 and having one end fixed to the connection portion 140;
And a collimator feeding device for feeding the collimator to the irradiation gamma irradiation device.
4. The apparatus according to claim 3, wherein the cylinder (122)
Recurrent equation;
And a collimator for guiding the collimator.
The method according to any one of claims 1 or 3, wherein the irradiation device (2)
And a shield (110) for preventing radiation from leaking through the collimator (3);
The shield 110 includes a first housing 112 configured to prevent radiation from leaking while guiding the distance that the collimator 3 is reciprocated by the transfer device 100; And
A second housing 114 configured to surround the outer circumference of the first housing 112 to prevent radiation from leaking between the irradiator 2 and the collimator 3;
And a collimator for guiding the collimator.

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