KR101259935B1 - Variable micro-focus collimator - Google Patents

Abstract

The present invention relates to a small focal variable collimator that freely varies the size of the small focal point as well as easily defines a beam area even for a small focal point of 1 μm.
According to the present invention, the area can be defined for the small focal point by a simple method of moving the X-axis moving block and the Y-axis moving block until the pre-installed filler gauge is reached according to the selective manipulation of the entrance window control mechanism. The present invention is characterized in that the size of the small focal point can be freely changed using one collimator through a method of replacing the filler gauge installed between the movable block and the fixed block with various thicknesses.

Description

Small focus variable collimator {Variable micro-focus collimator}

The present invention relates to a technique for freely varying the size of the small focus as well as defining the area of the beam easily even for a small focus of 1 um.

Conventional collimators used in the measurement of radiation dose mean the number of radiation particles incident per unit area because it can shield the unnecessary scattering lines incident on the detector and determine the area of the beam to a desired size. The particle flunece can be measured.

In the conventional method for colliding such incident radiation, collimators of various standards have been manufactured by drilling holes in a lead or tungsten material using a drill or the like in a desired size.

However, the above-described method not only causes the trouble of producing a collimator according to each standard, but also requires a lot of manufacturing costs, and in particular, there is a problem that it is difficult to drill the hole of the incidence angle and the exact size when drilling the hole.

In addition, existing tools (drills) cannot be drilled in um-calibers, so the area of the beam cannot be defined for the small focal point.

The present invention is to actively solve all the problems that the collimator according to the prior art, and to reach the filler gauge pre-installed the X-axis moving block and Y-axis moving block in accordance with the selective operation of the entrance window control. The object of the present invention is to be able to define the area for the small focal point by a simple method of moving until

In addition, the present invention is to solve the problem that the size of the small focus can be freely changed by using a single collimator through a method of replacing the filler gauge installed between the mobile block and the fixed block with a variety of thickness. do.

The present invention is fixed to the X-axis block guider formed inside the front of the housing main body is formed in the inlet through the rear plate and guide grooves formed on the upper and lower sides as a means for solving the above problems, installed on one side of the guide groove The X-axis fixed block is installed to be movable in the X-axis direction along the guide groove in correspondence with the X-axis fixed block, and the X-axis spring is formed on both sides of the opposite surfaces of the X-axis fixed block and the X-axis movable block. Insert and install, and the spindle of the X-axis entrance window adjusting hole installed through the housing main body to find a technique to be in close contact with the side of the X-axis moving block.

In addition, the present invention is fixed to the Y-axis block guider formed in the inlet hole formed in the rear plate and the guide grooves on the left and right sides inside the rear of the housing body, corresponding to the Y-axis fixed block installed on one side of the guide groove The Y-axis moving block is installed to be movable in the Y-axis direction along the guide groove, and the Y-axis spring is inserted into the spring grooves formed on both sides of the opposite surfaces of the Y-axis fixed block and the Y-axis moving block. The technology of the Y-axis entrance window adjustment sphere installed through the housing main body is in close contact with the side of the Y-axis moving block.

In addition, the present invention devises a technique for integrally attaching a cover having an entrance hole on the front surface of the housing body, and fixing the cover and the housing body to a mounting plate mounted on a detector by penetrating the cover and the housing body with a fastening member.

According to the present invention, not only the area can be easily defined for a small focal point of 1 um, but the size of the small focal point is varied from 1 um to 1 mm by a very simple method, and there is no need to manufacture a large number of collimators according to the standard, and the radiation dose It provides the effect of minimizing manufacturing problems that may cause uncertainty in the measurement.

1 is a perspective view of a collimator to which the present invention is applied
2 is an exploded perspective view of the collimator of the present invention
3 is a front view of the collimator of the present invention
4 is a perspective view of the present invention the X-axis block guider
5 is an assembled longitudinal cross-sectional view of the X-axis block guider, the X-axis fixed block and the X-axis moving block of the present invention.
Figure 6 is a perspective view of the present invention Y-axis block guider
Figure 7 is a longitudinal cross-sectional view of the assembled Y-axis block guider, Y-axis fixed block and Y-axis moving block of the present invention
Figure 8 is a perspective view of the X-axis fixed block and Y-axis fixed block of the present invention
Figure 9 is a perspective view of the X-axis moving block and Y-axis moving block of the present invention
10 is a perspective view of the present invention filler gauge
11 is a state diagram in which the bending clearance surface is formed at the corners of the X-axis, Y-axis fixed block and the X-axis, Y-axis moving block of the present invention;
12 is a side view of a separated state of the housing body and the mounting plate of the present invention;

Preferred embodiments of the present invention will now be described in more detail with reference to the accompanying drawings.

Looking at the overall technical configuration according to the accompanying drawings in accordance with a preferred embodiment of the present invention, it is fixed to the inside of the front of the housing main body 10, the entrance hole 22 is formed on the rear plate 21, the upper and lower An X-axis block guider 20 having a pair of guide grooves 23 formed at both sides thereof; An X-axis fixed block 30 fixedly installed at one side of the guide groove 23; An X-axis moving block (30a) installed to move in the X-axis direction along the guide groove (23) corresponding to the X-axis fixed block (30); An X-axis spring (40) fitted to spring grooves (31) respectively formed on opposite sides of the X-axis fixed block (30) and the X-axis moving block (30a); An X-axis incidence window adjusting device 50 installed through the housing main body 10 and having a front end of the spindle 51 moving in accordance with a rotation operation in close contact with one side of the X-axis moving block 30a; The Y-axis block guider 60 is fixedly installed at the rear inner side of the housing main body 10 and has an entrance hole 62 formed at the rear plate 61 and a pair of guide grooves 63 formed at both left and right sides thereof. ; A Y-axis fixed block 70 fixedly installed at one side of the guide groove 63; A Y-axis moving block 70a installed to be movable in the Y-axis direction along the guide groove 63 in response to the Y-axis fixed block 70; A Y-axis spring 80 fitted to each of the spring grooves 71 formed on both sides of opposite surfaces of the Y-axis fixed block 70 and the Y-axis moving block 70a; A Y-axis incidence window adjusting device 90 installed through the housing body 10 and having a front end of the spindle 91 moving in accordance with a rotation operation in close contact with one side of the Y-axis moving block 70a; It can be seen that the organic coupling configuration of the mounting plate 100 is detachably assembled by the fastening member 1 in a state in close contact with the rear of the housing body 10.

Hereinafter, the present invention having the above-described schematic configuration will be described in more detail for facilitating the implementation.

First of all, the housing main body 10 of the present invention serves to accommodate the X-axis block guider 20 and the Y-axis block guider 60, and is formed in the form of a square frame in which front and rear both sides are open.

The X-axis block guider 20 is fixedly installed by the fastening member 1 in the front inner side of the housing main body 10.

The X-axis block guider 20 has a circular incidence through-hole 22 through which radiation can pass through the rear plate 21, and a pair of guide grooves 23 facing each other on the upper and lower sides are recessed. It is possible to guide the sliding movement of the shaft movement block (30a).

One side of the guide groove 23 is fixedly installed by the fastening member 1 while both sides of the X-axis fixing block 30 are fitted, and the X-axis moving block corresponding to the X-axis fixing block 30 ( 30a) is installed to be slidably movable in the X-axis direction along the guide groove 23 so that the X-axis fixed block 30 and the X-axis moving block 30a of the X-axis moving block 30a are moved according to the positional movement of the X-axis moving block 30a. As the gap generated between them changes, the size of the incident window in the X-axis direction can be adjusted.

The X-axis fixed block 30 and the X-axis moving block 30a are each recessed with spring grooves 31 on both sides of the surface facing each other, and the X-axis spring 40 is formed in the spring grooves 31. Both sides are fitted, and the X-axis incidence window control port 50 is installed through the housing body 10, and the X-axis incidence window control port 50 is moved by the rotational operation of the spindle 51. The tip is in close contact with one side of the X-axis moving block 30a.

The X-axis incidence window adjusting device 50 is made of the same structure as a conventional micrometer, so that the threaded spindle 51 can be moved finely according to the selective rotation operation, the structure thereof is well known technology In the present invention, further description will be omitted.

Accordingly, when the X-axis incidence window control device 50 is rotated forward, the spindle 51 pushes the X-axis moving block 30a to close the gap, and conversely, when the reverse rotation is performed, the X-axis spring 40 By the elasticity, the X-axis moving block 30a is restored to its original state, thereby opening the gap, thereby allowing the size of the X-axis direction incident window to be freely adjusted through simple rotational operation of the X-axis incident window adjusting device 50.

At this time, a pair of pin fitting grooves 24 are formed on the top and bottom of the rear plate 21 of the X-axis block guider 20, and the pin fitting grooves 24 abut on one side of the X-axis fixing block 30. As the stopper pin 25 is additionally fitted, the X-axis fixed block 30 can be prevented from being pushed in any case.

In addition, between the X-axis fixed block 30 and the X-axis moving block (30a) is a filler gauge 110 that can be replaced by various thickness is placed by the gap corresponding to the thickness of the filler gauge 110 precisely the size of the incident window Provides the effect of precise control.

Meanwhile, the Y-axis block guider 60 is fixedly installed in the rear inner side of the housing main body 10 by the fastening member 1, and the Y-axis block guider 60 has radiation on the rear plate 61. A rectangular incidence through-hole 62 that can pass through is formed, and a pair of guide grooves 63 facing each other are formed in the left and right sides to guide the sliding movement of the Y-axis moving block 70a.

At this time, the reason why the incidence through hole 62 of the Y-axis block guider 60 is formed in a rectangular shape can be easily replaced without replacing the filler gauge 110 when the rear surface of the housing body 10 is opened. To make it work.

One side of the guide groove 63 is fixedly installed by the fastening member 1 while both sides of the Y-axis fixed block 70 are fitted, and the Y-axis moving block corresponding to the Y-axis fixed block 70 ( 70a) is installed to be slidably moved in the Y-axis direction along the guide groove 63 so that the Y-axis fixed block 70 and the Y-axis moving block 70a are moved according to the positional movement of the Y-axis moving block 70a. As the gap generated therebetween changes, the size of the incident window in the Y-axis direction can be adjusted.

The Y-axis fixed block 70 and the Y-axis moving block 70a are each recessed with spring grooves 71 on both sides of the surface facing each other, and the spring grooves 71 of the Y-axis spring 80 are recessed. Both sides are fitted, and the Y-axis entrance window control unit 90 is installed through the housing body 10, and the Y-axis entrance window control unit 90 is moved by the rotational operation of the spindle 91. Since the tip is in close contact with one side of the Y-axis moving block 70a, the size of the Y-axis incidence window can be freely adjusted through a simple rotational operation of the Y-axis incidence adjusting device 90.

At this time, a pair of pin fitting grooves 64 are formed on the left and right sides of the back plate 61 of the Y-axis block guider 60, and the pin fitting grooves 64 abut on one side of the Y-axis fixing block 70. As the stopper pin 65 is additionally fitted, the Y-axis fixed block 70 can be prevented from being pushed in any case.

In addition, between the Y-axis fixed block 70 and the Y-axis moving block 70a, a filler gauge 110 that can be replaced for various thicknesses is placed so that the size of the incident window is exactly as large as the gap corresponding to the thickness of the filler gauge 110. Provides the effect of precise control.

The filler gauge 110 of the present invention as described above is formed with a thickness measuring plate 111 on one side, between the X-axis fixed block 30 and the X-axis moving block (30a) on one side of the thickness measuring plate 111. And a structure formed by extending the handle 112 exposed to the outside when fitted between the Y-axis fixed block 70 and the Y-axis moving block 70a, making replacement work easier and more precise. Enables adjustment of

In addition, one side edge portion of the surface facing the X-axis fixed block 30 and the X-axis moving block 30a, and one side of the surface facing the Y-axis fixed block 70 and the Y-axis moving block 70a. The bending portions 33 and 73 are formed to be inclined at the corners, so that even if the bending occurs at the tip of the filler gauge 110, the bending generation portions are exposed to the bending relief surfaces 33 and 73 to form a small focal point. It is possible to flexibly cover the occurrence of errors.

On the rear surface of the housing main body 10 is mounted and detachably assembled with the housing main body 10 by the fastening member 1 in a state in which the mounting plate 100 to be integrally mounted to the detector is in close contact, The front surface of the housing main body 10 is additionally attached to the cover 120, the entrance hole 121 is formed in the center.

In the present invention having such a configuration, the incident window in the X-axis direction and the incident window in the Y-axis direction are mutually harmonized to form a small focal point having a quadrangular shape, and in particular, an area can be easily defined even for a small focal point of 1 μm. The size of the small focal point can be varied in the range of 1um to 1mm.

In addition, the filler gauge 110 disposed between the X-axis fixed block 30 and the X-axis moving block 30a can be easily replaced through the incident window 121 of the cover 120, and the Y-axis fixed. When replacing the filler gauge 110 placed between the block 70 and the Y-axis moving block 70a, the housing body 10 is selectively separated from the mounting plate 100 so that the rear surface of the housing body 10 is replaced. You can replace it with open.

Herein, the present invention provides a pair of positioning pins 101 protrudingly formed on the front surface of the mounting plate 100, and the positioning pins 101 are inserted into pins respectively formed on the rear surface of the housing body 10. The addition of the technology to be fitted in the groove 12, even if the mounting plate 100 and the housing main body 10 is separated and assembled, it does not always change the position and provides the convenience that can be accurately assembled in the right position as well as the radiation dose measurement accordingly The accuracy of the experiment can be improved.

1: fastening member 10: housing body
12: Pin insertion groove 20: X axis block guider
22, 62: through hole 23, 63: guide groove
24, 64: pin recess 25, 65: stopper pin
30: X axis fixed block 30a: X axis moving block
31, 71: spring groove 33, 73: bending clearance
40: X axis spring 50: X axis entrance window control
51, 91: spindle 60: Y-axis block guider
70: Y-axis fixed block 70a: Y-axis moving block
80: Y axis spring 90: Y axis entrance window control
100: mounting plate 101: retaining pin
110: filler gauge 111: thickness measurement plate
112: handle 120: cover

Claims (9)

A housing main body 10 whose front and rear both sides are opened;
The X-axis block guider 20 is fixedly installed in the front inner side of the housing main body 10, and has an entrance hole 22 formed in the rear plate 21 and a pair of guide grooves 23 formed on both upper and lower sides thereof. ;
An X-axis fixed block 30 fixedly installed at one side of the guide groove 23;
An X-axis moving block (30a) installed to move in the X-axis direction along the guide groove (23) corresponding to the X-axis fixed block (30);
An X-axis spring (40) fitted to spring grooves (31) respectively formed on opposite sides of the X-axis fixed block (30) and the X-axis moving block (30a);
An X-axis incidence window adjusting device 50 installed through the housing main body 10 and having a front end of the spindle 51 moving in accordance with a rotation operation in close contact with one side of the X-axis moving block 30a;
The Y-axis block guider 60 is fixedly installed at the rear inner side of the housing main body 10 and has an entrance hole 62 formed at the rear plate 61 and a pair of guide grooves 63 formed at both left and right sides thereof. ;
A Y-axis fixed block 70 fixedly installed at one side of the guide groove 63;
A Y-axis moving block 70a installed to be movable in the Y-axis direction along the guide groove 63 in response to the Y-axis fixed block 70;
A Y-axis spring 80 fitted to each of the spring grooves 71 formed on both sides of opposite surfaces of the Y-axis fixed block 70 and the Y-axis moving block 70a;
A Y-axis incidence window adjusting device 90 installed through the housing body 10 and having a front end of the spindle 91 moving in accordance with a rotation operation in close contact with one side of the Y-axis moving block 70a;
Small focus variable collimator, characterized in that consisting of a mounting plate 100 is detachably assembled by the fastening member (1) in close contact with the back of the housing body (10).
The method of claim 1,
The filler gauge 110 is disposed between the X-axis fixed block 30 and the X-axis movable block 30a and between the Y-axis fixed block 70 and the Y-axis movable block 70a. 110) is a small focal variable collimator, characterized in that by placing by replacing the various thickness.
The method of claim 2,
Filler gauge 110 is a small focus variable collimator, characterized in that the thickness measuring plate 111 is installed on one side, the handle 112 is exposed to the outside installed on one side of the thickness measuring plate 111.
The method of claim 2,
When the filler gauge 110 placed between the Y-axis fixed block 70 and the Y-axis moving block 70a is replaced, the housing main body 10 is selectively separated from the mounting plate 100 so that the housing main body 10 can be removed. Small focus variable collimator, characterized in that to replace the open state.
The method of claim 1,
The incident aperture 62 formed in the Y-axis block guider 60 is a small focal variable collimator, characterized in that formed in a rectangle to facilitate the replacement of the filler gauge (110).
The method of claim 1,
Small focus variable collimator, characterized in that the front cover of the housing body 10 is further attached to the cover 120 is formed in the inlet 121.
The method of claim 1,
Pin fitting grooves 24 and 64 are formed in the rear plates 21 and 61 of the X-axis block guider 20 and the Y-axis block guider 60, respectively. A small focus variable collimator, characterized in that the stopper pin (25) (65) is further fitted to prevent the X-axis fixed block (30) and the Y-axis fixed block (70) push.
The method of claim 1,
On one side edge portion of the facing surface of the X-axis fixed block 30 and the X-axis moving block 30a, and one side edge portion of the opposite surface of the Y-axis fixed block 70 and the Y-axis moving block 70a. Small focus variable collimator, characterized in that the bending clearance surface (33) (73) is further inclined.
The method of claim 1,
A pair of positioning pins 101 protrude from the front surface of the mounting plate 100, and the positioning pins 101 are fitted into the pin insertion recesses 12 formed at the rear of the housing body 10. The mounting plate 100 and the housing body (10) is a small focus variable collimator, characterized in that always assembled correctly in the correct position when assembled.

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