KR102168220B1 - Accuracy measurement appratus of radiation for linac - Google Patents

Abstract

Disclosed is a radiation rotation center consistency measuring device for a linear accelerator. The apparatus for measuring the coincidence of the rotational center of radiation for a linear accelerator according to the present invention includes: a chamber for measuring a photon beam or an electron beam; And a control module mounted on the chamber and installed on the gantry or the couch, wherein the chamber is positioned in a direction of one or more axes by the control module. According to the present invention, it is possible to provide a radiation rotation center coincidence measuring device for a linear accelerator, which is made to accurately position the ion chamber at the isocenter of the linear accelerator or to be spaced apart from the iso-dose center by an easy operation. You will be able to.

Description

Radiation rotation center consistency measurement device for linear accelerators {ACCURACY MEASUREMENT APPRATUS OF RADIATION FOR LINAC}

The present invention relates to a radiation rotation center coincidence measuring apparatus for a linear accelerator, and more particularly, to a radiation rotation center coincidence measuring apparatus for a linear accelerator configured to measure the radiation rotation center coincidence according to a gantry rotation.

The linear accelerator is one of several types of radiation generating devices that produce radiation such as X-rays and electron beams, and it is named because a tube that accelerates electrons is made of a straight line.

In English, it is called'LINEAR ACCELERATOR', but it is often called'LINAC' for short. A therapeutic linear accelerator will accelerate electrons between 4 million volts (4 MeV) and 25 million volts (25 MeV). Depending on the type, linear accelerators can be divided into those that can generate only electron beams, those that can generate only one X-ray, and those that can generate more than one X-ray and both electron beams.

The Nuclear Safety Committee has established 『Technical Standards for Radiation Safety Management in the Medical Field』 and announced the quality control items of radiation devices for treatment. The quality control of the linear accelerator consists of items related to the safety of facilities and devices, dosimetric inspection items according to radiation transmission, and items that inspect the mechanical accuracy of treatment devices.

Linear accelerator mechanical accuracy check items are items that check the accuracy of display values according to movement of the gantry, collimator and treatment table of the linear accelerator, items that check the alignment of the rotation center of radiation according to the rotation of the gantry, collimator, and treatment table, and electron beams. Includes items such as linkage of accessories such as cones and wedges, laser alignment and distance indicator inspection.

The items to check the alignment of the rotation center of radiation according to the rotation of the gantry include X-ray output matching according to the gantry angle, electron beam output matching according to the gantry angle, electron beam according to the gantry angle, and X-ray axis deviation coefficient matching. There is this.

Since the measurement of the coincidence of the rotation center of the radiation according to the rotation of the gantry must be measured by changing the angle of the gantry, the reliability of the measured value is poor when the water phantom, which is commonly used for setting the radiation beam at a gantry angle of 0°, is used. . Since the water phantom is a known technology as disclosed in Korean Patent Application Publication No. 1197397, a detailed description will be omitted.

Until now, separate brackets to attach ion chambers have been manufactured for each hospital, and these are temporarily attached to the gantry or couch to measure the alignment of the center of radiation rotation according to the rotation of the gantry. The measurement of radiation rotation center consistency is a very important check item in terms of accuracy and efficiency of linear accelerator treatment. Therefore, there has been a demand for the development of a device capable of accurately positioning the ion chamber at the isocenter of the linear accelerator and also spaced apart from the isocenter at a certain interval.

Korean Patent Publication No. 1197397 (Registration Date: 2012.10.29)

It is an object of the present invention to provide a radiation rotation center coincidence measuring device for a linear accelerator, which can accurately position an ion chamber at an isocenter of a linear accelerator or to be spaced apart from an iso-dose center by an easy operation. Is to do.

The above object is, according to the present invention, as an apparatus for measuring the coincidence of the rotation center of the radiation according to the rotation of the gantry, the photon beam or electron beam measurement chamber; And a control module mounted on the chamber and installed on the gantry or couch, wherein the chamber is positioned in a direction of one or more axes by the control module. Is achieved by

An electron applicator is mounted on the head of the gantry, and the adjustment module includes: an adjustment block into which the chamber is inserted and mounted; A frame forming a horizontal moving boundary of the adjustment block; A support unit mounted to be adjustable in position inside the frame and supporting the control block; And a leg connecting the frame and the electron applicator.

The control module may include a control block into which the chamber is inserted and mounted; A frame forming a horizontal moving boundary of the adjustment block; A support unit mounted to the frame to be position adjustable and supporting the adjustment block; And a leg connecting the frame and the couch.

The frame, a pair of first border frames parallel to the length direction of the couch; And a pair of second boundary frames parallel to the width direction of the couch, wherein the support unit comprises: a first support member mounted on the pair of first boundary frames so as to be adjustable in position; And a second support member mounted on the pair of second boundary frames so as to be position adjustable, and supporting the adjustment block together with the first support member.

A first rail groove is formed in each of the pair of first boundary frames, and the first support member includes: a first slider mounted to each of the first rail grooves to be slidably mounted; And a first support bar connecting the first slider, and a first through hole through which the first support bar passes may be formed in the control block.

A second rail groove is formed in each of the pair of second boundary frames, and the second support member includes: a second slider mounted to each of the second rail grooves to be slidably mounted; And a second support bar connecting the second slider, and a second through hole through which the second support bar passes may be formed in the control block.

The first support bar has a plurality of concave portions formed along the longitudinal direction, and the adjustment block includes a convex member inserted into the concave portion; And an elastic member that pushes the convex member toward the concave portion.

A plurality of concave portions are formed in the first rail groove along a longitudinal direction, and the first slider includes a convex member inserted into the concave portion; And an elastic member that pushes the convex member toward the concave portion.

The leg, a first rod coupled to the frame; A clamp mounted on the electron applicator or the couch; A second rod coupled to the clamp and inserted into the first rod; And a blocking member blocking the relative movement of the first rod and the second rod.

An extension part is mounted on the couch, and the adjustment module includes: an adjustment block into which the chamber is inserted and mounted; And a rail formed on the extension part and on which the adjustment block is slidably mounted.

The rail has a plurality of concave portions formed along the length direction, and the control block includes a convex member inserted into the concave portion; And an elastic member that pushes the convex member toward the concave portion.

According to the present invention, since the chamber is positioned in a direction of one or more axes by the control module, the ion chamber can be accurately positioned at the isocenter of the linear accelerator or separated from the iso-dose center by a certain interval by easy operation. It is possible to provide a radiation rotation center coincidence measuring device for a linear accelerator.

1 is a view showing a linear accelerator.
Figure 2 is a perspective view showing a linear accelerator radiation rotation center coincidence measuring device according to an embodiment of the present invention.
3 is a view showing a state in which the radiation rotation center coincidence measurement device for the linear accelerator of FIG. 2 is installed on the electron applicator.
Figure 4 is a view showing a control block of the radiation rotation center coincidence measurement device for the linear accelerator of Figure 2;
Figure 5 is a cross-sectional view showing a control block of the linear accelerator radiation rotation center coincidence measuring device of Figure 2;
6 is a cross-sectional view showing a frame and a support unit of the apparatus for measuring the alignment of the rotational center of radiation for the linear accelerator of FIG. 2;
7 is a view showing a state in which the radiation rotation center coincidence measuring device for the linear accelerator of FIG. 2 is installed on a couch.
8 is a view showing a state installed on the couch of the radiation rotation center coincidence measurement device for a linear accelerator according to another embodiment of the present invention.
9 is a cross-sectional view showing a control block and a rail of the apparatus for measuring the alignment of the rotational center of radiation for the linear accelerator of FIG. 8;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in describing the present invention, a description of a function or configuration that is already known will be omitted in order to clarify the gist of the present invention.

The apparatus for measuring radiation rotation center coincidence for a linear accelerator of the present invention is made to accurately position the ion chamber at the isocenter of the linear accelerator or to be spaced apart from the iso-dose center by an easy operation.

1 is a diagram showing a linear accelerator, FIG. 2 is a perspective view showing a radiation rotation center coincidence measuring device for a linear accelerator according to an embodiment of the present invention, and FIG. 3 is a radiation rotation center coincidence for the linear accelerator of FIG. It is a diagram showing a state in which the measuring device is installed on the electron applicator.

FIG. 4 is a view showing an adjustment block of the apparatus for measuring radiation center of rotation coincidence for the linear accelerator of FIG. 2, and FIG. 5 is a cross-sectional view showing the control block of the apparatus for measuring alignment of radiation center of rotation for the linear accelerator of FIG.

FIG. 6 is a cross-sectional view showing a frame and a support unit of the apparatus for measuring radiation center of rotation for the linear accelerator of FIG. 2, and FIG. 7 is a view showing a state where the apparatus for measuring alignment of radiation center of rotation for the linear accelerator of FIG. 2 is installed on a couch. to be.

FIG. 8 is a view showing a state installed on the couch of the linear accelerator radiation rotation center coincidence measuring device according to another embodiment of the present invention, and FIG. 9 is a control block of the radiation rotation center coincidence measuring device for the linear accelerator of FIG. It is a cross-sectional view showing a rail.

As shown in FIGS. 2 and 3, the apparatus 10 for measuring radiation rotation center coincidence for a linear accelerator according to an embodiment of the present invention is a device for measuring radiation rotation center coincidence according to rotation of the gantry 1A. As, it is configured to include the chamber 100 and the control module 200.

As shown in FIG. 4, the chamber 100 is configured to measure photon rays or electron beams, and is provided as a photon beam measurement chamber (farmer type chamber) or an electron beam measurement chamber (electron chamber). Chambers for measuring photon or electron beams are available from manufacturers of radiation related equipment such as PTW and Fluke. 4(a) shows an electron beam measurement chamber 100, and FIG. 4(b) shows a photon beam measurement chamber 100.

3 and 7, the control module 200 is a configuration for positioning the chamber 100 based on the gantry 1A or the couch 2, the chamber 100 is mounted to the gantry (1A) ) Or installed on the couch (2).

1 shows a state before the adjustment module 200 is installed on the gantry 1A or the couch 2, and FIGS. 2 and 3 show a state in which the adjustment module 200 is installed on the gantry 1A. The adjustment module 200 is installed on the gantry head 1B in a form mounted on an electron applicator (AP). 7 shows a state in which the adjustment module 200 is installed on the couch 2.

As shown in FIGS. 2, 3 and 7, the adjustment module 200 includes an adjustment block 210, a frame 220, a support unit 230, and a leg 240.

As shown in FIG. 4, the control block 210 is a configuration in which the chamber 100 is inserted and mounted, and is formed in a hexahedral shape. An insertion groove 211 into which the chamber 100 is inserted is formed in the control block 210. As shown in FIG. 4(a), the electron beam measurement chamber 100 is inserted into the insertion groove 211 while being inserted into the build-up cap 110.

A first through hole 212 and a second through hole 213 are formed in the control block 210. The first through hole 212 is a hole through which the first support bar 231B passes, and forms a shape that penetrates the control block 210 in the width direction of the couch 2.

The second through hole 213 is a hole through which the second support bar 232B passes, and forms a shape that penetrates the adjustment block 210 in the longitudinal direction of the couch 2. The first through hole 212 and the second through hole 213 are vertically spaced apart and do not cross each other.

As shown in FIGS. 2 and 7, the frame 220 is configured to form a horizontal moving boundary of the adjustment block 210, and forms a rectangular frame shape. The frame 220 includes a pair of first boundary frames 221 and a pair of second boundary frames 222.

A pair of first boundary frames 221 form a shape parallel to the longitudinal direction of the couch 2, and a pair of second boundary frames 222 form a shape parallel to the width direction of the couch 2. The first boundary frame 221 and the second boundary frame 222 are connected to each other at ends.

First rail grooves 221H are formed in the pair of first boundary frames 221, respectively. The first rail groove 221H is formed along the length direction of the first boundary frame 221. The pair of first rail grooves 221H form a shape facing each other.

Second rail grooves 222H are formed in the pair of second boundary frames 222, respectively. The second rail groove 222H is formed along the length direction of the second boundary frame 222. The pair of second rail grooves 222H form a shape facing each other.

As shown in FIGS. 2 and 7, the support unit 230 is configured to support the adjustment block 210, and is mounted to be adjustable in position inside the frame 220. The support unit 230 includes a first support member 231 and a second support member 232. The first support member 231 and the second support member 232 together support the adjustment block 210.

The first support member 231 is mounted to be position adjustable on a pair of first boundary frames 221, and the second support member 232 is mounted to be position adjustable on a pair of second boundary frames 222 do.

Referring to FIG. 6, the first support member 231 includes a pair of first sliders 231A and a first support bar 231B.

As shown in FIG. 6, the first sliders 231A are mounted to each of the first rail grooves 221H to be slidably moved. The first support bar 231B connects the pair of first sliders 231A.

The rotational motion of the first slider 231A is restricted by interference with the inner surface of the first rail groove 221H. Accordingly, when an external force is applied, the first support member 231 can only slide in a direction parallel to the first rail groove 221H, that is, in the longitudinal direction of the couch 2.

The second support member 232 includes a pair of second sliders (not shown) and a second support bar 232B. Although not shown in detail, the second slider is mounted to each of the second rail grooves 222H so as to be slidable. The second support bar 232B connects a pair of second sliders.

The rotational motion of the second slider is restricted by interference with the inner surface of the second rail groove 222H. Accordingly, when an external force is applied, the second support member 232 can only slide in a direction parallel to the second rail groove 222H, that is, in the width direction of the couch 2.

As shown in FIG. 4, the first support bar 231B passes through the first through hole 212 and the second support bar 232B passes through the second through hole 213.

The first support bar 231B supports the control block 210 within the first through hole 212, and the second support bar 232B supports the control block 210 within the second through hole 213. do. The rotational motion of the adjustment block 210 is restricted by the first support bar 231B and the second support bar 232B.

When the user pushes the adjustment block 210 in the longitudinal direction of the couch 2, the adjustment block 210 moves along with the first support member 231 in the longitudinal direction of the couch 2. At this time, the second support member 232 maintains a stopped state.

When the user pushes the adjustment block 210 in the width direction of the couch 2, the adjustment block 210 moves along with the second support member 232 in the width direction of the couch 2. At this time, the first support member 231 maintains a stopped state.

Therefore, when the user pushes the adjustment block 210 between the length direction and the width direction of the couch 2, the adjustment block 210 is the couch 2 together with the first support member 231 and the second support member 232 ) In the longitudinal and width directions.

As shown in Figure 5, the first support bar (231B) is formed with a plurality of concave portions (C) in the longitudinal direction, the adjustment block 210, a convex member 214 inserted into the concave portion (C) Is equipped. The convex member 214 is pushed toward the concave portion C by the elastic member 215.

In order to move the adjustment block 210 in the longitudinal direction of the first support bar 231B, an external force capable of disengaging the convex member 214 from the concave portion C is required. Accordingly, the adjustment block 210 is blocked from unintended movement (in the longitudinal direction of the first support bar 231B) due to the rotational force of the gantry 1A.

Although not shown in detail, a plurality of concave portions (C) are formed along the length direction in the second support bar (232B), and a convex member (214) inserted into the concave portion (C) is provided in the adjustment block 210 do. The convex member 214 is pushed toward the concave portion C by the elastic member 215.

In order to move the adjustment block 210 in the longitudinal direction of the second support bar 232B, an external force capable of disengaging the convex member 214 from the concave portion C is required. Accordingly, the adjustment block 210 is blocked from unintended movement (in the longitudinal direction of the second support bar 232B) due to the rotational force of the gantry 1A.

As shown in FIG. 6, a plurality of concave portions C are formed in the longitudinal direction on the inner surface of the first rail groove 221H, and a convex member inserted into the concave portion C in the first slider 231A (B) is provided. The convex member (B) is pushed toward the concave portion (C) by the elastic member (E).

In order to move the first support member 231 in the longitudinal direction of the first rail groove 221H, an external force capable of disengaging the convex member B from the concave portion C is required. Accordingly, the first support member 231 is blocked from unintended movement (in the longitudinal direction of the first rail groove 221H) due to the rotational force of the gantry 1A.

A plurality of concave portions C are formed on the inner surface of the second rail groove 222H along the longitudinal direction, and a convex member B inserted into the concave portion C is provided in the second slider. The convex member (B) is pushed toward the concave portion (C) by the elastic member (E).

In order to move the second support member 232 in the longitudinal direction of the second rail groove 222H, an external force capable of disengaging the convex member B from the concave portion C is required. Accordingly, the second support member 232 is blocked from unintended movement (in the longitudinal direction of the second rail groove 222H) due to the rotational force of the gantry 1A.

2, 3 and 7, the leg 240 is a configuration that connects the frame 220 and the electron applicator (AP) or the couch 2, the first rod 241, the second rod It is configured to include (242), a clamp (243) and a blocking member (244).

The first rod 241 and the second rod 242 are configured to form a distance between the frame 220 and the electron applicator (AP) or the couch 2, and form a tube shape. The second rod 242 is inserted inside the first rod 241. A scale indicating a distance between the frame 220 and the electron applicator AP or the couch 2 may be formed on the second rod 242.

The first rod 241 is coupled to the frame 220. The first rod 241 is coupled to the frame 220 by bolting. As shown in FIGS. 2 and 7, a coupling portion 223 to which the first rod 241 is coupled may be formed in the frame 220. The first rod 241 is coupled to the coupling portion 223 by bolting. The coupling portion 223 may be coupled to the frame 220 by bolting.

2, 3 and 7, the second rod 242 is mounted on the electron applicator AP or the couch 2 by a clamp 243. Although not shown in detail, the clamp 243 has a structure in which a movable jaw, which moves by operation of a thumbscrew, bites the electron applicator (AP) or the couch (2) together with a fixed jaw. Can be formed.

The blocking member 244 is formed of a knob that is screwed to the first rod 241 to block the movement of the second rod 242. Therefore, the user adjusts the distance between the frame 220 and the electron applicator (AP) or the couch 2 and controls the relative movement of the first rod 241 and the second rod 242 through the operation of the blocking member 244. Can be blocked.

Until now, separate brackets to attach the ion chamber have been manufactured for each hospital, and these are temporarily attached to the gantry (1A) or the couch (2) to measure the radiation rotation center consistency according to the rotation of the gantry (1A). . Radiation rotation center consistency measurement is a very important check item in terms of accuracy and efficiency of linear accelerator (AP) treatment. Therefore, there has been a demand for the development of a device capable of accurately positioning the ion chamber at the isocenter of the linear accelerator (AP) and also allowing the ion chamber to be spaced apart from the isocenter at a certain interval.

The linear accelerator radiation rotation center coincidence measuring device 10 of the present invention, the position of the chamber 100 by the adjustment module 200 in the three-axis direction, that is, the length direction of the couch (2), the couch (2) By easily adjusting in the width direction and in the direction closer to or away from the electron applicator (AP) or couch (2), the chamber 100 is accurately positioned at the isocenter of the linear accelerator (AP) or by easy operation. It can be separated from the iso-dose center by a certain distance.

8 and 9, the linear accelerator radiation rotation center coincidence measuring device 20 according to another embodiment of the present invention may be configured to include an adjustment block 210 and a rail 250 have.

The control block 210 is a configuration in which the chamber 100 is inserted and mounted, and is formed in the form of a long rod in one direction. An insertion groove 211 into which the chamber 100 is inserted is formed in the control block 210. Referring to FIG. 4A, the electron beam measuring chamber 100 is inserted into the insertion groove 211 while being inserted into the build-up cap 110.

The rail 250 is a configuration in which the adjustment block 210 is slidably mounted, and is formed to be elongated in the width direction on the extension part 2a. The extension portion 2a is configured to extend the length of the couch 2 and forms a flat plate shape having the same width as the couch 2. The extension 2a is coupled to or separated from the couch 2. The width direction of the extension 2a should be understood to be the same as the width direction of the couch 2.

Elekta and older varian couches have a structure that allows them to extend their length if necessary. The new Varian's couch can be combined with the extension 2a using a lock bar.

As shown in Figure 9, the rail 250 is formed with a plurality of concave portions (C) along the longitudinal direction, the adjustment block 210 is provided with a convex member 214 inserted into the concave portion (C). . The convex member 214 is pushed toward the concave portion C by the elastic member 215.

In order to move the adjustment block 210 in the longitudinal direction of the rail 250, an external force capable of disengaging the convex member 214 from the concave portion C is required. Accordingly, the adjustment block 210 is blocked from unintended movement (in the longitudinal direction of the rail 250) by an external force. Therefore, by easily adjusting the position of the chamber 100 in the width direction of the couch 2 by the control module 200, the chamber 100 is accurately positioned at the isocenter of the linear accelerator (AP) or It can be separated from the iso-dose center by a certain distance by easy operation.

According to the present invention, since the chamber is positioned in a direction of one or more axes by the control module, the ion chamber can be accurately positioned at the isocenter of the linear accelerator or separated from the iso-dose center by a certain interval by easy operation. It is possible to provide a radiation rotation center coincidence measuring device for a linear accelerator.

In the above, although specific embodiments of the present invention have been described and illustrated, the present invention is not limited to the described embodiments, and various modifications and variations can be made without departing from the spirit and scope of the present invention. It is self-evident to those who have. Therefore, such modifications or variations should not be individually understood from the technical spirit or point of view of the present invention, and the modified embodiments should be said to belong to the claims of the present invention.

10: measuring device
100: chamber 110: cap
200: control module 210: control block
220: frame 211: insertion groove
221: first boundary frame 212: first through hole
221H: first rail groove 213: second through hole
222: second boundary frame 214: convex member
222H: second rail groove 215: elastic member
C: recess 230: support unit
223: coupling portion 231: first support member
240: leg 231A: first slider
241: first rod 231B: first support bar
242: second rod B: convex member
243: clamp E: elastic member
244: blocking member 232: second support member
1: linear accelerator 232B: second support bar
1A: Gantry 250: Rail
1B: Head C: Recess
AP: Electron applicator
2: Couch
2a: extension

Claims (11)

As a device that measures the coincidence of the center of radiation rotation according to the rotation of the gantry,
A chamber for measuring photon or electron beams; And an adjustment module to which the chamber is mounted and installed on the gantry or the couch,
The chamber is positioned in a direction of at least one axis by the control module,
An extension part is mounted on the couch,
The control module,
An adjustment block into which the chamber is inserted and mounted; And a rail formed on the extension part and on which the adjustment block is slidably mounted,
The rail has a plurality of recesses formed along the length direction,
In the control block,
A convex member inserted into the concave portion; And an elastic member that pushes the convex member toward the concave portion. The method of claim 1,
An electron applicator is mounted on the head of the gantry,
The control module,
An adjustment block into which the chamber is inserted and mounted;
A frame forming a horizontal moving boundary of the adjustment block;
A support unit mounted to be adjustable in position inside the frame and supporting the control block; And
Radiation rotation center coincidence measuring apparatus for a linear accelerator, comprising a leg connecting the frame and the electron applicator. The method of claim 1,
The control module,
An adjustment block into which the chamber is inserted and mounted;
A frame forming a horizontal moving boundary of the adjustment block;
A support unit mounted to the frame to be position adjustable and supporting the adjustment block; And
Radiation rotation center coincidence measuring apparatus for a linear accelerator, comprising a leg connecting the frame and the couch. The method according to claim 2 or 3,
The frame,
A pair of first boundary frames parallel to the length direction of the couch; And
It includes a pair of second boundary frames parallel to the width direction of the couch,
The support unit,
A first support member mounted in a position adjustable to the pair of first boundary frames; And
Radiation rotation center consistency measuring device for a linear accelerator, characterized in that it is mounted to the pair of second boundary frames so as to be position adjustable, and comprises a second support member supporting the adjustment block together with the first support member. . The method of claim 4,
A first rail groove is formed in each of the pair of first boundary frames,
The first support member,
A first slider mounted to each of the first rail grooves to be slidably moved; And
Including a first support bar connecting the first slider,
A radiation rotation center consistency measuring apparatus for a linear accelerator, wherein a first through hole through which the first support bar passes is formed in the control block. The method of claim 5,
Each second rail groove is formed in the pair of second boundary frames,
The second support member,
A second slider mounted to each of the second rail grooves to be slidably moved; And
Including a second support bar connecting the second slider,
Radiation rotation center consistency measuring apparatus for a linear accelerator, characterized in that the control block is formed with a second through hole through which the second support bar passes. As a device that measures the coincidence of the center of radiation rotation according to the rotation of the gantry,
A chamber for measuring photon or electron beams; And an adjustment module to which the chamber is mounted and installed on the gantry or the couch,
The chamber is positioned in a direction of at least one axis by the control module,
The control module,
An adjustment block into which the chamber is inserted and mounted; A frame forming a horizontal moving boundary of the adjustment block; And a support unit mounted to the frame so as to be position adjustable and supporting the control block,
The frame,
It includes a pair of first boundary frames parallel to the length direction of the couch,
The support unit,
Including a first support member mounted to the position adjustable to the pair of first boundary frames,
A first rail groove is formed in each of the pair of first boundary frames,
The first support member,
A first slider mounted to each of the first rail grooves to be slidably moved; And a first support bar connecting the first slider,
A plurality of concave portions are formed in the first support bar along the longitudinal direction,
In the control block,
A convex member inserted into the concave portion; And an elastic member that pushes the convex member toward the concave portion. As a device that measures the coincidence of the center of radiation rotation according to the rotation of the gantry,
A chamber for measuring photon or electron beams; And an adjustment module to which the chamber is mounted and installed on the gantry or the couch,
The chamber is positioned in a direction of at least one axis by the control module,
The control module,
An adjustment block into which the chamber is inserted and mounted; A frame forming a horizontal moving boundary of the adjustment block; And a support unit mounted to the frame so as to be position adjustable, and supporting the adjustment block. And
The frame,
It includes a pair of first boundary frames parallel to the length direction of the couch,
The support unit,
Including a first support member mounted to the position adjustable to the pair of first boundary frames,
A first rail groove is formed in each of the pair of first boundary frames,
The first support member,
A first slider mounted to each of the first rail grooves to be slidably moved; And a first support bar connecting the first slider,
A plurality of concave portions are formed in the first rail groove along the length direction,
In the first slider,
A convex member inserted into the concave portion; And an elastic member that pushes the convex member toward the concave portion. The method of claim 2,
The leg,
A first rod coupled to the frame;
A clamp mounted on the electron applicator or the couch;
A second rod coupled to the clamp and inserted into the first rod; And
And a blocking member that blocks the relative movement of the first rod and the second rod. delete delete

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