KR100512557B1 - Reference plate using for X-ray examination and reference plate installing holder - Google Patents

Abstract

The present invention relates to a reference plate for X-ray imaging and the reference plate mounting holder. The reference plate is composed of a light transmission plate mounted to the rotating gantry head of the linear accelerator, a main scale formed in a predetermined pattern in the center of the light transmission plate, and a plurality of auxiliary scales extending perpendicular to the main scale, The auxiliary scale has a pattern extending in one direction from the main scale, and the scales viewed from the front and rear surfaces of the light transmitting plate have different shapes. In addition, the mounting holder comprises a holder case for receiving the reference plate, and a fixing screw for fixing the reference plate to the holder case.

The reference plate of the present invention made as described above is provided with a position indicator for indicating the position of the reference plate relative to the object to be photographed, it is easy to determine the position of the rotating gantry head portion relative to the object to be photographed at the time of shooting through the film. This allows the operator to clearly distinguish the front and back sides of the film. In addition, the mounting holder elastically supports the reference plate and is fixed with a fixing screw so that the installation position does not change even if the external shock or rotation gantry rotates.

Description

Reference plate using for X-ray examination and reference plate installing holder}

The present invention relates to a reference plate and reference plate mounting holder for X-ray imaging.

Among medically used radiations, especially therapeutic radiation, is applied to tumors of cancer patients to prevent cancer cells from propagating anymore, so that cancer cells die at the end of their lives or to alleviate the pain of patients.

Usually, radiation therapy is used to prevent recurrence if the cancer cells are more likely to remain after surgery, or if surgery is not possible, or if radiation therapy is more effective than surgery, or a combination of surgery and radiation therapy In order to improve the quality of life of the patient, or after the anticancer drug treatment in combination with anticancer drug treatment to maximize the anticancer effect.

The radiation treatment is performed by expensive medical equipment called a linear accelerator. The linear accelerator can output X-rays and electron beams, and can be used as a standard equipment for radiation therapy because of its various energy and high dose rates.

1 is a view showing an example of performing radiation therapy using a conventional linear accelerator for radiation therapy.

As shown, the linear accelerator 10 is generally composed of a main body 12 and a rotating gantry 14 connected to the main body 12 via a support shaft 13 and rotatable with respect to the main body 12.

The main body 12 is provided with a high voltage generator or a microwave generator, and the inside of the rotating gantry 14, the acceleration tube and the magnetic field generating device for accelerating electrons and the X-ray passing through the magnetic field generating device X-ray emitter to irradiate the need and collimator to adjust the area of the X-ray is built.

The main body 12 is fixed to the ground and supports the rotatable gantry 14 through the support shaft 13 to be rotatable. The rotary gantry 14 is axially rotated about the support shaft 13 and has a size appropriately designed so as not to hit the ground during rotation.

The treatment table 16 is installed on the side of the rotary gantry 14. The treatment table 16 is a place where the patient to be treated is exposed, and horizontal and vertical positions can be freely adjusted, and the imaging X-ray film F can be stored therein.

The mounting holder 20 is installed in the head portion 18 in which the X-rays are emitted from the rotating gantry 14. The mounting holder 20 can be disassembled from the head portion 18 as a fixing means for fixing the reference plate to be described later with respect to the head portion 18.

On the other hand, radiation treatment using a linear accelerator, as known, depends on the condition of the tumor, but usually lasts 2 to 6 weeks. During the treatment, the tumor size decreases to some extent and the weight of the patient usually decreases by 5 kg to 10 kg.

The tumor size should be taken at least once a week according to the weight change or tumor size change to reset the energy intensity and projection width of the appropriate X-ray corresponding to the remaining tumor size. In other words, in order to increase the cancer cure rate through radiation treatment, the area must be continuously photographed to observe the tumor's size or state of interest and then the necessary measures must be taken.

When the tumor is photographed using the linear accelerator, the reference plate is mounted on the linear accelerator so that the scale of the reference plate appears along with the shape of the object to be photographed on the X-ray film.

The reference plate is, for example, a transparent plate with a cross scale engraved in the center as shown in FIG. 3.

Since the reference plate is used to check the size of the tumor, it should be removed from the head 18 during the radiation treatment.

Figure 2a, 2b, 2c, 2d is a view showing the irradiation of X-rays while rotating the rotating gantry of the linear accelerator for radiation treatment is a state seen from the arrow Z direction of FIG.

As described above, the rotary gantry 14 of the linear accelerator for radiation therapy can be rotated about the support shaft (13 in FIG. 1) about its center axis, and the treatment table 16 can also be freely adjusted in its position so that all the needs of the tumor can be adjusted. X-rays can be irradiated to the site, so that the desired area can be taken sufficiently.

2A shows that the head 18 is located on the upper part of the patient and irradiates the X-ray downward. At this time, the distance between the x-ray emitting portion and the tumor that the x-rays are emitted is set to be 100cm, the rotation radius of the rotating gantry. As described above, when irradiating the therapeutic radiation to the patient, the reference plate must be removed from the mounting holder 20, and the reference plate is mounted when the diagnostic radiation for imaging is irradiated.

2B is a state in which the rotating gantry 14 is rotated 90 degrees in the direction of the arrow c in the state of FIG. 2A. As the rotary gantry 14 rotates as described above, the head 18 is positioned on the right side of the patient, thereby irradiating X-rays on the right side of the tumor.

FIG. 2C is a view in which the rotary gantry 14 is further rotated 90 degrees in the state of FIG. 2B, and the head 18 of the rotary gantry 14 is located at the lower part of the patient. Therefore, X-rays can be irradiated to the back of the tumor.

2D is a state in which the rotary gantry 14 is further rotated 90 degrees in the state of FIG. 2C. As shown in the figure, the head portion 18 may be located on the left side of the patient to irradiate X-rays on the left side of the tumor.

Figure 3 is a perspective view of a conventional reference plate that can be mounted and used in the radiation therapy linear accelerator.

As described above, when the tumor is photographed using the linear accelerator 10, a graduated reference plate 22 is inserted into the mounting holder 20 together with the shape of the photographed portion on the X-ray film. The scale can be projected to determine the size of the tumor.

Referring to FIG. 3, the conventional reference plate 22 includes a frame 26 having a handle 24 on one side and providing a square hole, and a plurality of fixing blocks 30 mounted on the square hole. And a floodlight panel 28 fixed to the frame 26.

The floodlight plate 28 is an acrylic plate through which X-rays pass, and a cruciform scale is engraved at the center thereof. The scale is drawn with a material having a property that does not pass through the X-ray so that it appears on the X-ray film when photographing the target region as shown in FIG.

4A, 4B, 4C, and 4D are diagrams of an X-ray film photographing an object with FIG. 1 mounted with the reference plate of FIG. 3 mounted on a linear accelerator. In addition, the head portion of the linear accelerator rotated 360 degrees, but shown in the state taken in the state of Fig. 2a, 2b, 2c, 2d.

FIG. 4A is an X-ray film taken by radiating X-ray downward from the upper part of the patient as shown in FIG. 2A. As shown, the scale of the reference plate (22 in FIG. 3) is shown on the film 1 together with the skull.

FIG. 4B is an X-ray film 2 showing the right shape of the skull and the scale of the reference plate photographed with the head 18 of the linear accelerator positioned on the right side of the patient as shown in FIG. 2B. FIG. 4C is the head 18 of FIG. ) Is a film 3 showing the posterior shape of the skull and the scale of the reference plate taken in the state shown in FIG. 2C. 4D is a film 4 showing the shape of the left side of the skull and the scale of the reference plate taken with the head of the linear accelerator positioned at the left side of the patient as shown in FIG. 2D.

On the other hand, it is very difficult to distinguish the front and rear surfaces of the X-ray film photographing the object, as known. Usually, the film is placed on a lighting plate with a built-in fluorescent lamp to check the contents of the film, and the front and back sides of the film are not clearly distinguished as described above. Therefore, even if the X-ray film is placed on the lighting plate, it may not be known. have.

For example, although the film 1 of FIG. 4A and the film 3 of FIG. 4C are photographed on the front and back of the skull, when the film 1 is reversed, it is very similar to the image of the film 3 to photograph the film of the front of the skull. It can also be mistaken for a film. Similarly, if the film 2 of FIG. 4B is reversed, it may be difficult to distinguish it from the film 4 of FIG. 4D, which may obscure which is the right side and which is the left side.

Film 2 and film 4, but the position of the scale number is relatively easy to see reversed, but film 1 and film 3 because the skull is symmetrical, it is difficult to distinguish between the two can lead to medical accidents. Applicant has actually seen several times that the X-ray film is interpreted as upside down and the wrong prescription is given and a medical accident has occurred.

After all, the conventional reference plate as described above tells the size of the subject to shoot, but can not tell the relative position of the head portion relative to the subject when shooting, it takes a lot of time to find the front and back of the film and in some cases medical accidents Could cause.

In addition, the reference plate is stored in the mounting holder in order to accurately photograph the position does not change, but there is no means for supporting the reference plate in the mounting holder because the mounting gantry rotates or when an abnormal impact from the external mounting holder There was a problem that the position of the reference plate with respect to the camera was slightly changed so that accurate shooting was not possible.

The present invention has been made to solve the above problems, by providing a position display means for indicating the position of the reference plate relative to the object to be photographed on the reference plate, the position of the rotating gantry head portion relative to the object at the time of shooting through the film The first object is to provide a reference plate that can be easily identified by the operator to clearly distinguish the front and back of the film, and also to the external impact by fixing the reference plate with a fixing screw and elastic support Another object of the present invention is to provide a reference plate mounting holder which does not change the installation position even if the rotating gantry rotates.

In order to achieve the above object, the X-ray photographing reference plate of the present invention is mounted on a rotating gantry head of a linear accelerator for radiation treatment, and is provided with a light transmitting plate installed at a predetermined distance from the X-ray emitting part in the head, and at the center of the light transmitting plate. It is formed in a predetermined pattern and the image is formed on the X-ray film after the X-ray film and the measuring means to determine the size of the object to be taken, the measuring means is a column based on the center point of the floodlight plate It consists of a main scale extending crosswise to form a right angle and a plurality of auxiliary scales extending at right angles to each of the main scales, wherein each of the auxiliary scales extend in parallel in one direction only with one end thereof in contact with the main scale. The overall shape of the scales seen from the front and back of the floodlight plate It is characterized by forming a ching.

In addition, the light transmitting plate; In order to form the main scale and the sub-scale, slits extending in a crisscross shape with respect to the center point of the light-transmitting plate to form a right angle with each other and having a predetermined gap and depth, and extending at right angles to each of the slits, one end of the slits A plurality of slits having a predetermined gap and depth are formed in parallel with one another while being in communication with each other, and the main and auxiliary scales are formed by filling lead or lead alloy in the slits formed in the pattern. It is done.

In addition, the depth of the slit is characterized in that 70% to 90% of the thickness of the transparent plate.

In addition, the lead or lead alloy is filled in each slit to form a strip having a predetermined width and thickness, and the width direction of the main scale and the sub-scale is toward the X-ray emitter, and only the thickness component of the main scale and the sub-scale is in the X-ray film. It is characterized by being projected.

In addition, the light transmitting plate is characterized in that the plate position indicator to further determine the position of the light-transmitting plate at the time of the shooting object through the photographed X-ray film.

In addition, the plate position indicator is characterized in that it provides a sealed inner space with respect to the outside and the flowable X-ray shielding liquid that the X-rays do not pass.

In addition, the inner space of the plate position indicator is composed of a first space and a second space communicating with each other and providing the same volume, the x-ray shielding liquid is located only in the first space according to the position of the light-transmitting plate with respect to the photographing object. Or located only in the second space or over the first and second spaces.

In addition, the first space provides a ring-shaped space and the second space provides a cylindrical space, so that the ring shape is projected onto the X-ray film when the X-ray shielding liquid is accommodated in the first space. When accommodated in the space is characterized in that the circular shape is projected.

In addition, the x-ray shielding liquid is characterized in that any one of a mixed liquid or mercury mixed with distilled water and lead powder.

In addition, the light-transmitting plate is a rectangular plate characterized in that the handle is integrally formed on one side of the edge, the pressing groove of a predetermined depth is formed on one of the edge portion of the edge and the neighboring edge where the handle is located.

In addition, the reference plate mounting holder of the present invention for achieving the above object is provided to the head portion of the rotating gantry to provide a mounting space for receiving and supporting the reference plate, by receiving a reference plate in the mounting space for reference A holder case for allowing the plate to be spaced apart from the X-ray emitting unit by a predetermined distance, and a fixing screw for fixing the reference plate to the holder case by penetrating one side wall of the holder case and being inserted into the pressing groove. It is done.

In addition, the inner wall surface constituting the mounting space of the holder case is characterized in that the elastic support means for elastically supporting the translucent plate toward the fixing screw side.

In addition, the elastic support means; It is characterized in that it comprises a pressing member which is in contact with the side of the edge of the translucent plate and provides a support force, and a spring for supporting the pressing member toward the translucent plate side.

In addition, the support side 74 is elastically supported by the pressing member is characterized in that it consists of at least two or more planes different in distance from the inner wall surface on which the pressing member is installed.

Hereinafter, one embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

Basically, the reference plate of the present invention divides the scale into a main scale and a sub-scale, but extends the sub-scale in a clockwise or counterclockwise direction so that the scale pattern viewed from the front and back of the reference plate is different. The plate position indicator is installed on the reference plate so that the plate position indicator knows the position of the reference plate relative to the photographed object at the time of photographing so that the front and back sides of the photographed X-ray film can be clearly distinguished.

5 is an exploded perspective view showing a reference plate according to an embodiment of the present invention that can be installed and used in the radiation therapy linear accelerator of FIG. 1.

Referring to the drawings, the reference plate 50 according to the present embodiment takes the form of a square plate and a light transmitting plate 52 having a handle 54 at one side thereof, and formed in a predetermined pattern on the light transmitting plate 52. It can be seen that the grid portion 58, and the plate position indicator 62 is mounted to the light transmitting plate (52).

The light transmitting plate 52 is an acryl plate having a predetermined thickness, and the pressing groove 64 is formed at one side of the side adjacent to the side where the handle 54 is located. In particular, the side surface 74 opposite to the side where the pressing groove 64 is formed is formed stepwise as shown in FIG. The pressing groove 64 and the supporting side 74 will be described later.

The light transmitting plate 52 is provided with an installation hole 60 to which the plate position indicator 62 can be fitted. The mounting hole 60 is a through hole penetrating the light transmitting plate 52, and a locking jaw 61 is formed therein. The locking jaw 61 is to support the plate position indicator 62 so as not to escape to the lower portion of the light transmitting plate (52). Since the plate position indicator 62 is supported by the latching jaw 61, the plate position indicator 62 can be removed from the light transmitting plate 52 by pushing the bottom surface of the indicator opening 62 upward.

A center point 56 is formed at the center of the floodlight plate 52. The center point 56 and the scale 58 to be described later are formed by digging the light transmitting plate 52 in a predetermined depth and pattern and filling lead or lead alloy therein. The lead alloy may use a known cerbenend. In addition, the holes and slits forming the center point 56 and the scale portion 58 do not penetrate the translucent plate 52, and the bottom thereof is positioned in the translucent plate 52 as shown in FIG. 6.

The center point 56 is a reference point that informs the center of the light transmitting plate 52. In order to form the center point 56, a hole having a predetermined diameter and a depth is vertically formed in the light transmitting plate 52, and the lead or lead alloy is filled in the hole.

The scale unit 58 extends crosswise with respect to the center point 56 and forms four main scales 84 perpendicular to each other, and one end thereof is connected to the main scale 84 and has a main scale ( 84) and a plurality of auxiliary scales 86 extending perpendicular to each other. In this figure, the auxiliary scale 86 extends clockwise.

In order to form the scale portion 58, the upper surface of the light transmitting plate 52 is dug to a predetermined width and depth to first make the slits 97 and 98 having the pattern, and lead or lead alloy is formed in the slits 97 and 98. Fill. The slits formed on the light transmitting plate 52 can be implemented any number through machining.

Of the graduations 58, the main scale 84 takes the form of a band having a predetermined thickness and width. The width component of the main scale 84 is perpendicular to the upper surface of the light transmitting plate 52 so that only the thickness component of the main scale 84 appears on the X-ray film after the photographing.

The auxiliary scales 86 extend in a direction perpendicular to the longitudinal direction of the main scale 84 and are connected to each of the four main scales 84. The minor scales 86 are parallel to one another and are spaced apart from one another, for example at 5 cm intervals. It is also possible to form a further 1cm spacing between each auxiliary scale 86.

In addition, the length of each auxiliary scale 86 is different from each other. The outermost minor division is, for example, 10 cm, then the inner minor division is 8 cm, then the inner minor division is 5 cm, and the innermost minor division is 2 cm.

In addition, the auxiliary scales 86 are inclined at a predetermined angle toward the center point 56 as shown in FIG. 6, and the inclination angle becomes larger toward the outside. That is, the virtual plane including the widthwise component of the auxiliary scale 86 meets the X-ray emitting unit X as shown in FIG. 6 so that only the thickness component of the auxiliary scale appears on the film after shooting.

On the other hand, the plate position indicator 62 to be fitted to the mounting hole 60 provides an inner space sealed to the outside, the inner space is provided with an X-ray shielding liquid (68). The plate position indicator 62 informs the angle of the light transmitting plate 52 with respect to the horizontal plane while being mounted on the light transmitting plate 52. In addition, the X-ray shielding liquid 68 may be a liquid material made of a material that does not pass through the X-ray, for example, a mixed liquid or mercury mixed with lead powder in distilled water.

The inner space of the plate position indicator 62 is composed of a first space (70 in FIG. 7) and a second space (72 in FIG. 7) communicating with each other, and blocking the X-rays according to the position of the light transmitting plate (52). The liquid 68 flows in and out between the first space 70 and the second space 72. The function of the plate position indicator 62 will be described later.

FIG. 6 is a cross-sectional view taken along the line VI-VI of FIG. 5.

As shown, the holes and slits constituting the center point 56 and the scale portion 58 do not pass through the translucent plate 52, but the lower end thereof is spaced apart from the bottom of the translucent plate 52 by w2. The separation distance w2 with respect to the thickness w1 of the light transmitting plate 52 may be about 5% to about 15%.

In addition, the auxiliary divisions 86 are inclined by a predetermined angle so that the X-rays emitted from the upper X-ray emitting unit X project only the thickness component of the auxiliary divisions 86.

7A is a cross-sectional view illustrating a plate position indicator when the reference plate according to an embodiment of the present invention is mounted in the linear accelerator and photographed in the state of FIG. 2A.

The plate position indicator 62 is sealed against the outside and the sealing case 66 for providing the first space 70 and the second space 72 therein, and is injected into the sealing case 66 X-ray shielding liquid 68 which is present. The first space 70 takes the form of a ring and the second space 72 takes the form of a cylinder and is positioned up and down.

In addition, the volume of the first space 70 and the volume of the second space 72 are equal to each other, and the X-ray shielding liquid 68 is replenished to fill the first space 70 or the second space 72 tightly. . Therefore, in the state where the reference plate 50 is located below the X-ray emitter (X in FIG. 6) (the state of FIG. 2A), the X-ray blocking liquid 68 fills the second space 72 as in FIG. 7A, On the contrary, when the reference plate 50 is positioned above the X-ray emitting unit (state of FIG. 2C), the X-ray blocking liquid is only accommodated in the first space 70.

In FIG. 7A, since the reference plate 50 is positioned below the X-ray emitter, the X-ray shielding liquid 68 is positioned in the second space 72 and takes the form of a cylinder.

FIG. 7B is a diagram illustrating an X-ray film taken in the state of FIG. 2A by mounting a reference plate according to an embodiment of the present invention.

As shown, the center point D by the center point C is formed in the center of the X-ray film 5, and the scale line L is shown around the center point D. As shown in FIG. Of course, the grid line L has a pattern of the grid portion formed on the reference plate 50.

The location mark A is also formed on the X-ray film 5. The location mark is formed by the X-ray shielding liquid 68 shown in FIG. 7A. Since the X-ray shielding liquid 68 is located in the second space 72 to take the form of a cylinder, the position indication point A takes the form of a disc.

As a result, it can be seen that the X-ray shielding liquid 68 was filling the second space 72 when the X-ray was photographed through the shape of the position mark A. Accordingly, the film 5 has a reference plate 50 at the bottom of the X-ray emitter. It can be inferred that the film was filmed while being positioned horizontally.

8A is a cross-sectional view illustrating a plate position indicator when the reference plate according to an embodiment of the present invention is mounted in the linear accelerator and photographed in the state of FIG. 2B.

Referring to the drawings, it can be seen that the reference plate 50 is positioned perpendicular to the horizontal plane so that the X-ray shielding liquid 68 may simultaneously cover the first space 70 and the second space 72.

When the X-ray is irradiated to the reference plate 50 in this state, a half moon position display point A is formed on the film as shown in FIG. 8B.

Referring to FIG. 8B, it can be seen that the half moon position mark A is formed on the film 6. The rounded circumferential portion of the position indication point A is directed toward the edge of the film 6.

In this way, the position indication point A has a half moon shape, and in particular, the X-ray shielding liquid 68 is formed in the first space 70 and the second space through the rounded circumferential portion facing away from the inner grid line L. It can be seen that the filling (72) and the film 6 is that the reference plate 50 is located vertically on the side of the X-ray emitting portion, but it can be seen that the film taken in the state of Figure 2b.

9A is a cross-sectional view illustrating a plate position indicator when the reference plate according to an embodiment of the present invention is mounted in a linear accelerator and photographed in the state of FIG. 2C.

As shown in FIG. 9A, since the reference plate 50 is inverted as compared with FIG. 7, the X-ray blocking liquid 68 is accommodated in the first space 70 and the second space 72 is empty. Since the X-ray shielding liquid 68 is accommodated in the first space 70, the X-ray shielding liquid 68 has a ring shape. In this state, when the X-ray is irradiated upward, the result of FIG. 9B is obtained.

FIG. 9B is a diagram illustrating an X-ray film taken in the state of FIG. 2C by mounting a reference plate according to an embodiment of the present invention.

Referring to the drawings, it can be seen that the location mark A marked on the film 7 takes the form of a ring. As such, it can be seen that the X-ray shielding liquid 68 fills the first space 70 through the position mark A having the shape of a ring. In the film 7, the reference plate 50 is horizontally disposed on the X-ray emitting portion. It can be seen that the film was taken by irradiating the X-ray upward in the state of being positioned.

10A is a cross-sectional view illustrating a plate position indicator when the reference plate according to an embodiment of the present invention is mounted in a linear accelerator and photographed in the state of FIG. 2D.

As shown, since the reference plate 50 is vertically positioned, the X-ray shielding liquid 68 is positioned over the first space 70 and the second space 72. In this state, the X-rays irradiated to the left form a half moon position mark A as shown in FIG. 10B.

FIG. 10B is a diagram illustrating an X-ray film taken in the state of FIG. 2D by mounting a reference plate in a linear accelerator according to an embodiment of the present invention.

Referring to the drawings, the position indication point A takes the form of a half moon, but the round outer circumferential surface thereof is formed to face the grid line L. In FIG. 8B, the rounded outer circumferential surface of the half moon-shaped position point is facing the edge of the film 6, and in the case of FIG.

In this way, it can be seen that the X-ray shielding liquid 68 is located in the first space 70 and the second space 72 through the half moon shape and the rounded outer circumferential surface thereof faces the inner grid line L. 8, the reference plate 50 is located vertically on the side of the X-ray emitter, but it can be determined that the film photographed in the state of Figure 2d.

FIG. 11 is a plan view schematically illustrating an entire outline of a reference plate according to an embodiment of the present invention.

Basically, the reference plate 50 according to the present embodiment has a form in which one side thereof is stepped like a stair so as to be easily inserted into the mounting holder 76. The one side is a support side 74 which is provided with an elastic force in the direction of the arrow f of FIG. 12 by the pressing member 80 to be described later.

On the support side 74, the width W3 of the reference plate 50 of the portion proximate to the handle 54 is wider than the width W4 of the opposite portion. The difference in the width (W3-W4) may be equal to the protruding distance of the pressing member (80 in FIG. 12) to be described later. In addition, the support side 74 is not inclined, and of course parallel to the side opposite to the pressing groove 64 is formed.

12 is a schematic cross-sectional view of a reference plate mounting holder for mounting a reference plate to a linear accelerator according to an embodiment of the present invention.

The mounting holder 76 is to be mounted to the head portion of the linear accelerator through the usual fixing means.

As shown in the drawing, the mounting holder 76 has a holder case 90 which provides a mounting space 88 for accommodating the reference plate 50, and is installed on the inner side of the holder case 90. A fixing screw for elastically supported by the 82 and the pressing member 80 for supporting the support side 74 and its end portion is inserted into the pressing groove 64 to press the reference plate 50 in the direction of the arrow g. It comprises 78.

In addition, it can be seen that the support side surface 74 is formed of at least two or more planes different from the inner wall surface on which the pressing member 80 is installed.

Since the fixing screw 78 is inserted into the pressing groove 64 through the holder case 90, the fixing screw 78 is rotated from the outside to adjust its protruding length so as to appropriately change the pressing force for pressing the pressing groove 64. Can be. In addition, since the end of the fixing screw 78 is inserted into the pressing groove 64, the reference plate 50 is firmly positioned in place without being pulled out.

In addition, the inner side of the holder case 90 is provided with a pressing member mounting groove 96 is formed on the inner side of the holder case 90, the support jaw 94 is formed on the edge thereof. A spring 82 is installed in the pressing member installation groove 96, and the pressing member 80 is supported by the rear end of the pressing member 80 to provide an elastic force in the direction of the arrow f.

The pressing member 80 is a cylindrical member whose rounded end is curved, and an annular protrusion 92 protrudes from the rear edge thereof. The annular protrusion 92 is caught by the support jaw 94 to prevent the pressing member 80 from escaping from the pressing member installation groove 96. Of course, the pressing member 80 may be installed in a plurality of places according to the embodiment.

In order to mount the reference plate 50 to the mounting holder 76 configured as described above, first, the fixing screw 78 is rotated so that its end portion is removed from the mounting space 88, and then the reference plate 50 is pushed. Put it in.

As described above, since the supporting side 74 has a stepped shape and the width of the opposite end of the side where the handle 54 is located is as small as the width difference W3-W4 described above, the end edge of the reference plate 50 is It may be naturally inserted without being caught by the pressing member 80.

If the reference plate 50 is fully inserted, the fixing screw 78 is turned to allow the end of the fixing screw 78 to be inserted into the pressing groove 64.

FIG. 13 is a view illustrating a reference plate accommodated in the mounting holder of FIG. 12.

As shown, the reference plate 50 is inserted into the mounting space 88 provided by the holder case 90. An end of the fixing screw 78 is inserted into the pressing groove 64 of the reference plate 50, and the opposite support side 74 is elastically supported by the pressing member 80 so that the reference plate 50 is mounted. It is firmly positioned with respect to the holder 76, and even when an external impact is applied or the rotating gantry is rotated, it is firmly positioned at a fixed position to enable precise shooting.

As mentioned above, although this invention was demonstrated in detail through the specific Example, this invention is not limited to the said Example, A various deformation | transformation is possible for a person with ordinary knowledge within the scope of the technical idea of this invention. .

X-ray imaging reference plate and the reference plate mounting holder of the present invention made as described above is provided with a position indicator for indicating the position of the reference plate relative to the object to be photographed, the position of the rotating gantry head portion relative to the object to be photographed at the time of shooting Can be easily identified through the film, allowing the operator to clearly distinguish the front and back sides of the film. In addition, the mounting holder elastically supports the reference plate and is fixed with a fixing screw so that the installation position does not change even if the external shock or rotation gantry rotates.

1 is a view showing an example of the treatment through a conventional linear accelerator for radiation therapy.

Figures 2a, 2b, 2c, 2d is a view showing the irradiation of X-rays while rotating the rotating gantry of the linear accelerator for radiation treatment.

Figure 3 is a perspective view of a conventional reference plate that can be mounted and used in the radiation therapy linear accelerator.

4A, 4B, 4C, and 4D are views illustrating an X-ray film photographing an object with the reference plate of FIG. 3 mounted on the linear accelerator of FIG. 1.

Figure 5 is an exploded perspective view showing a reference plate according to an embodiment of the present invention that can be installed and used in the radiation therapy linear accelerator of Figure 1;

6 is a cross-sectional view taken along the line VI-VI of FIG. 5.

7A is a cross-sectional view illustrating a plate position indicator when the reference plate according to an embodiment of the present invention is mounted in the linear accelerator and photographed in the state of FIG. 2A.

Figure 7b is a view showing the x-ray film taken in the state of Figure 2a by mounting a reference plate in a linear accelerator according to an embodiment of the present invention.

8A is a cross-sectional view illustrating a plate position indicator when the reference plate according to an embodiment of the present invention is mounted in the linear accelerator and photographed in the state of FIG. 2B; FIG.

Figure 8b is a view showing the x-ray film taken in the state of Figure 2b by mounting a reference plate in a linear accelerator according to an embodiment of the present invention.

9A is a cross-sectional view illustrating a plate position indicator when the reference plate according to an embodiment of the present invention is mounted in the linear accelerator and photographed in the state of FIG. 2C; FIG.

Figure 9b is a view showing the x-ray film taken in the state of Figure 2c by mounting a reference plate in a linear accelerator according to an embodiment of the present invention.

10A is a cross-sectional view illustrating a plate position indicator when the reference plate according to an embodiment of the present invention is mounted in the linear accelerator and photographed in the state of FIG. 2D.

FIG. 10B is a view illustrating an X-ray film taken in the state of FIG. 2D by mounting a reference plate to a linear accelerator according to an embodiment of the present invention. FIG.

FIG. 11 is a plan view schematically illustrating the overall outline of a reference plate according to an embodiment of the present invention; FIG.

12 is a schematic cross-sectional view of a reference plate mounting holder for mounting a reference plate to a linear accelerator according to an embodiment of the present invention.

FIG. 13 is a view illustrating a reference plate housed in the mounting holder of FIG. 12. FIG.

<Explanation of symbols for the main parts of the drawings>

10: linear accelerator 12: main body

13: support shaft 14: rotary gantry

16: treatment table 18: head

20, 76: Mounting holder 22, 50: Reference plate

24, 54: handle 26: frame

28: floodlight plate 30: fixed block

52: floodlight plate 56: center point

58: graduation 60: mounting hole

61: engaging jaw 62: plate position indicator

64: pressure groove 66: sealing case

68: X-ray shielding liquid 70: The first space

72: second space 74: support side

78: fixed screw 80: pressure member

82: Spring 84: Main scale

86: auxiliary scale 88: mounting space

90: holder case 92: annular protrusion

94: support jaw 96: pressure member mounting groove

A: location mark C: center point

D: Center point F: Film

L: Grid line X: X-ray emitter

Claims (14)

A light transmission plate 52 mounted on the head 18 of the rotary gantry 14 of the linear accelerator 10 for radiation treatment and installed at a predetermined distance from the X-ray emission unit X in the head unit 18, and the light transmission plate; It is formed in a predetermined pattern in the center of the 52 and the image is made of measuring means for appearing on the x-ray film after the X-ray and the object to be taken to determine the size of the shooting object, The measuring means may include a main scale 84 extending in a crisscross shape with respect to the center point of the floodlight plate 52 to form a right angle with each other, and a plurality of auxiliary scales extending at right angles with respect to the main scales 84. Each of the auxiliary scales 86 extends in parallel only in one direction with one end thereof in contact with the main scale 84 so that the overall shape of the grid viewed from the front and back of the light transmitting plate 52 is mutually symmetrical. X-ray photographing reference plate, characterized in that. The method of claim 1, The light transmitting plate 52 is; In order to form the main scale 84 and the auxiliary scale 86, the slits 97 extending in a crisscross shape with respect to the center point of the light-transmitting plate 52 to form a right angle and have a predetermined gap and depth, respectively, A plurality of slits 98 are formed extending at right angles to the slits 97 and extending in parallel in one direction with one end thereof in communication with the slits 97 and having a predetermined gap and depth. 84) and the auxiliary scale (86) is a reference plate for X-ray imaging, characterized in that formed by filling the lead or lead alloy in the slit formed in the pattern. The method of claim 2, The depth of the slit (97,98) is a reference plate for X-ray imaging, characterized in that 70% to 90% of the thickness of the transmissive plate (52). The method of claim 2 or 3, The lead or lead alloy is filled in the slits 97 and 98 to form a strip having a predetermined width and thickness, and the width direction of the main scale 84 and the auxiliary scale 86 is directed toward the X-ray emitting portion X. The x-ray film is a reference plate for X-ray photographing, characterized in that only the thickness component of the main scale 84 and the auxiliary scale 86 is projected. The method of claim 1, The transmissive plate 52 is a reference plate for X-ray imaging, characterized in that further provided with a plate position indicator 62 so that the position of the light-transmitting plate 52 at the time of the shooting to know through the photographed X-ray film . The method of claim 5, The plate position indicator (62) provides a sealed inner space with respect to the outside of the x-ray imaging reference plate, characterized in that the flow of the X-ray shielding liquid (68) that the X-rays do not pass. The method of claim 6, The inner space of the plate position indicator 62 is composed of a first space 70 and a second space 72 which communicate with each other and provide the same volume. The X-ray shielding liquid 68 may be located only in the first space 70 or only in the second space 72 or the first and second spaces 70, depending on the position of the light transmitting plate 52 with respect to the photographing object. A reference plate for X-ray imaging, characterized in that located over 72). The method of claim 7, wherein The first space 70 provides a ring-shaped space and the second space 72 provides a cylindrical space, so that the X-ray shielding liquid 68 is accommodated in the first space 70. And the circular shape is projected when the shape of the ring is projected in the second space (72). The method of claim 6, The x-ray shielding solution (68) is a reference plate for X-ray imaging, characterized in that any one of a mixture of mercury or distilled water and lead powder. The method of claim 1, The light transmitting plate 52 is a rectangular plate, the handle 54 is integrally formed at one edge thereof, and the pressing groove 64 having a predetermined depth is formed at one edge of the edge adjacent to the edge where the handle 54 is located. Reference plate for X-ray imaging, characterized in that formed. Is installed in the head portion 18 of the rotary gantry 14 of the linear accelerator for radiation treatment, takes the form of a square plate and a reference including a light-transmitting plate having a pressing groove 64 of a predetermined depth formed on one side thereof. A mounting space 88 is provided to accommodate and support the plate 50, and the reference plate 50 is accommodated in the mounting space 88 so that the reference plate 50 is spaced apart from the X-ray emitting unit X by a predetermined distance. Holder case 90, It characterized in that it comprises a fixing screw 78 penetrating one side wall of the holder case 90 and the end is inserted into the pressing groove 64 to fix the reference plate 50 to the holder case 90. Reference plate mounting holder. The method of claim 11, Reference plate mounting holder, characterized in that the inner wall surface constituting the mounting space 88 of the holder case 90 is provided with an elastic support means for elastically supporting the translucent plate 52 toward the fixing screw (78). The method of claim 12, The elastic support means; Reference plate, characterized in that it comprises a pressing member 80 in contact with the side of the edge of the light transmitting plate 52 to provide a support force, and a spring 82 for supporting the pressing member 80 toward the light transmitting plate 52 side. Mounting holder. The method of claim 13, The support side 74 which is elastically supported by the pressing member 80 is a reference plate mounting holder, characterized in that made of at least two planes different from the inner wall surface on which the pressing member 80 is installed.