JP5710032B2 - Radiography equipment - Google Patents

Description

The present invention relates to a radiation imaging apparatus. In particular, it is suitable for use in an X-ray imaging apparatus having a C-arm used in an operating room or the like.

  Conventionally, an X-ray imaging apparatus equipped with a C-shaped arm used in an operating room is required to be able to image a surgical site freely and to perform CT imaging by rotating 180 degrees. In recent years, there has been a demand for a function that can shorten the imaging distance instead of fixing the imaging distance for the purpose of reducing X-ray exposure by the patient and the operator.

  For example, the X-ray diagnostic apparatus disclosed in Patent Document 1 is connected to an articulated arm at the end of a C-type arm and moves an X-ray flat panel detector in order to capture images freely from multiple directions. It is possible. Also shown is a link mechanism in which the X-ray flat panel detector is movably held by a C-arm. The link mechanism extending from the C-shaped arm is composed of first, second arms, and first to third joints. The first joint is provided at the joint between the C-arm and the first arm, the second joint is provided at the joint between the first and second arms, and the third joint is provided at the joint between the second arm and the X-ray flat panel detector. The first to third joints have a rotation function, and rotate independently or in conjunction with each other to achieve a desired movement, for example, the distance between the focal point of the X-ray generator and the detection surface of the X-ray flat panel detector ( The X-ray flat panel detector is controlled to face the X-ray generation unit while keeping (SID) constant.

  An X-ray diagnostic apparatus disclosed in Patent Document 2 includes an X-ray tube, an X-ray detector, a grid disposed on an image receiving surface of the X-ray detector, an X-ray tube and an X-ray detector. And an arm for supporting the X-ray tube and the X-ray detector so that the distance from the image receiving surface can be changed. The X-ray diagnostic apparatus also includes an arm support device that supports the arm angle so that the angle of the arm can be changed, a storage device that stores a plurality of files of moire image data using a grid in association with at least one of a distance and an angle, and moire correction. It has a circuit etc. The moire correction circuit corrects the image data output from the X-ray detector based on the moire image data selectively read from the storage device according to at least one of the distance and the angle.

Japanese Patent Laid-Open No. 2000-116631 JP 2002-336220 A

  According to the X-ray diagnostic apparatus disclosed in Patent Document 1, it is possible to freely image a region to be imaged and to perform CT imaging rotated by 180 degrees. However, there is a problem that the articulated arm is linked to the end of the C-type arm, and it is difficult to control the articulated arm. In particular, when the X-ray tube is arranged toward the two-dimensional detector, it is assumed that the articulated arm occupies a large space in the C-type arm and becomes an obstacle.

Moreover, according to the X-ray diagnostic apparatus disclosed in Patent Document 2, the distance between the X-ray source and the two-dimensional detector can be changed without changing the imaging axis. However, when the length of the distance to be changed is increased, there is a problem that the slide mechanism for changing the length is increased, and the outer shape of the C arm is substantially increased. When the outer shape of the C-arm becomes large, it becomes difficult to use in an operating room with a small work area.
The present invention has been made in view of the problems as described above, the radiographic apparatus having the A over arm, the radiation imaging apparatus according to an operator it is possible to effectively utilize the space in the A over arm The purpose is to improve usability.

A radiation imaging apparatus according to the present invention includes a C-type arm that supports a radiation source that irradiates a subject with radiation, a two-dimensional detector that detects radiation transmitted through the subject, and a rotating unit. a, a supporting portion for rotating the C-arm about the axis of rotation of the rotating portion rotatably connected to the first to the C-arm an inner than an end portion of the C-arm A radiation source shift unit that moves the radiation source in a direction orthogonal to a straight line connecting the radiation source and the two-dimensional detector and in a direction parallel to the rotation axis of the rotation unit using a sub arm; It is characterized by that.

According to the present invention, it is possible to improve the usability of the radiation imaging apparatus according to an operator it is possible to effectively utilize the space in the A over arm.

1 is a diagram illustrating a configuration of a radiation imaging apparatus. It is a side view of the state which moved the X-ray tube and the two-dimensional detector. It is a figure for demonstrating the movement of the X-ray tube by a shift part. It is a figure for demonstrating the position which the sub arm connects with respect to a C-type arm. It is a figure for demonstrating the case where a sub arm is interlock | cooperated by the imaging | photography site | part.

Hereinafter, embodiments according to the present invention will be described with reference to the drawings.
FIG. 1 is a diagram illustrating a configuration of a radiation imaging apparatus according to the present embodiment. In the present embodiment, an X-ray imaging apparatus will be described as a radiation imaging apparatus. FIG. 1A is a side view showing an external configuration of the X-ray imaging apparatus. FIG. 1B is a diagram showing the configuration of the main body of the X-ray imaging apparatus.
As shown in FIG. 1A, the X-ray imaging apparatus 100 includes a main body 11. The main body 11 of the X-ray imaging apparatus 100 is provided with a rotation support portion 12 that supports the slide support portion 14. The slide support portion 14 can rotate with respect to the rotation support portion 12 with respect to a horizontal rotation axis Lh indicated by a two-dot chain line in FIG. The slide support portion 14 of the present embodiment can rotate with respect to the rotation support portion 12 at a rotation angle of about 180 degrees. Here, when the slide support portion 14 is rotated 180 degrees with respect to the rotation support portion 12, the upper and lower ends of the end portion of the C-arm 13 described later are switched as shown in FIG.
A subject (patient) bed 30 is disposed between both ends of the C-arm 13. Therefore, by rotating the C-arm 13 by 180 degrees, an imaging method (under tube) for generating X-rays from the back of the subject in the supine position and X-rays from the front of the subject in the supine position are generated. Photographing method (over tube).

The slide support portion 14 supports the C-shaped arm 13 so as to be slidable along the shape of the frame of the C-shaped arm 13 in the arrow A direction or the arrow B direction shown in FIG. Here, the slide angle of the slide support unit 14 is set to an angle at which CT imaging can be performed. Specifically, the slide angle is desirably an angle obtained by adding an X-ray fan angle to 180 degrees, that is, 180 degrees or more. Here, the fan angle indicates the horizontal spread of X-rays emitted from an X-ray tube 16 described later. If CT imaging is not required, the slide angle may be 180 degrees.
Accordingly, the C-shaped arm 13 slides at least 90 degrees in the A direction or 90 degrees in the B direction from the state shown in FIG. By sliding the C-arm 13 with respect to the slide support unit 14, for example, images can be taken from both side surfaces of the subject in the supine position or the supine position.

An X-ray tube 16 as a radiation source is disposed at one end of the frame of the C-shaped arm 13 via a first sub arm 15. The first sub-arm 15 is rotatably connected by a first joint 19a as a connecting portion provided on the frame of the C-type arm 13 and inside the one end of the C-type arm 13. Yes. The first joint 19a is a rotation mechanism, for example, a link shaft disposed in the horizontal direction. Further, a tube mounting portion 22 as a mounting portion of the X-ray tube 16 is rotatable at the end portion of the first sub arm 15 on the side opposite to the first joint 19a via the second joint 19b. It is connected. The second joint 19b is a rotation mechanism, for example, a link shaft disposed in the horizontal direction. The tube mounting portion 22 is provided with a handle 26 that is gripped by an operator to move the X-ray tube 16. In addition, the X-ray tube 16 is attached to the tube attachment part 22 via the shift part 28 mentioned later. As described above, the X-ray tube 16 as a radiation source is disposed on the one end side of the frame of the C-type arm 13 via the first sub arm 15.
Here, since the first joint 19a and the second joint 19b are link shafts arranged in the horizontal direction, the first sub arm 15 and the X-ray tube 16 are separated by the frame of the C-type arm 13. It can move in the plane to be formed.

In addition, a two-dimensional detector 18 that detects X-rays irradiated from the X-ray tube 16 through the second sub-arm 17 and transmitted through the subject is arranged at the other end of the frame of the C-shaped arm 13. It is installed. The second sub-arm 17 is rotatably connected by a third joint 19c as a connection portion provided on the frame of the C-type arm 13 and inside the other end of the C-type arm 13. Yes. The third joint 19c is a rotation mechanism, for example, a link shaft disposed in the horizontal direction. A detector mounting portion 23 as a mounting portion of the two-dimensional detector 18 is rotatable at the end of the second sub-arm 17 on the opposite side of the third joint 19c via the fourth joint 19d. It is connected. The fourth joint 19d is a rotation mechanism, for example, a link shaft disposed in the horizontal direction. The detector mounting portion 23 is provided with a handle 27 that the operator holds to move the two-dimensional detector 18. The two-dimensional detector 18 is attached to the detector attachment portion 23 via a shift portion 29 described later. Thus, the two-dimensional detector 18 for detecting X-rays is disposed on the other end side of the frame of the C-type arm 13 via the second sub-arm 17.
Here, since the third joint 19c and the fourth joint 19d are link shafts arranged in the horizontal direction, the second sub-arm 17 and the two-dimensional detector 18 are separated by the frame of the C-type arm 13. It can move in the plane to be formed.
With this configuration, the X-ray tube 16 and the two-dimensional detector 18 are arranged so as to face each other at both ends of the C-arm 13 with the subject bed 30 shown by a broken line in FIG. Established.

  Next, the configuration of the main body 11 of the X-ray imaging apparatus 100 will be described with reference to FIG. As shown in FIG. 1B, the main body 11 includes a control unit 50, an image processing unit 51, a storage unit 52, a high pressure generation unit 53, an operation unit 54, a display unit 55, and the like. The control unit 50 controls the entire X-ray imaging apparatus 100. Specifically, the program stored in the storage unit 52 is executed in accordance with the mode selection described later. The image processing unit 51 converts the X-ray data detected by the two-dimensional detector 18 into image data that can be confirmed and stored by the operator. The storage unit 52 is a memory such as a RAM or a ROM and a large capacity storage medium. The storage unit 52 stores a program or the like corresponding to the mode, or is used as a working memory by the control unit 50. The high voltage generator 53 supplies a high voltage to the X-ray tube 16. The operation unit 54 includes various operation switches. The display unit 55 is a display, on which image data converted by the image processing unit 51 is displayed.

  Next, the rotation angles of the first sub arm 15 and the second sub arm 17 will be described. The rotation angles of the first sub arm 15 and the second sub arm 17 are determined by various factors. The factors include, for example, the grid portion 24 disposed on the front surface (image receiving surface) of the two-dimensional detector 18, the X-ray diaphragm portion 25 disposed on the front surface of the X-ray tube 16, and the C-shaped arm 13. This is the relationship between the diameter of the frame and the length of each sub arm.

First, the grid part 24 arranged in front of the two-dimensional detector 18 has a function of removing scattered X-rays, that is, a function of cutting off X-rays incident obliquely. A thin lead plate is arranged on the grid portion 24 so as to converge at a certain distance.
Here, if the focusing distance of the grid portion is f0 as shown in FIG. 1, the use distance limit of the grid portion 24 is set so as to include the focusing distance f0. If the lower limit of the use distance is f1 and the upper limit of the use distance is f2, f1 ≦ f0 ≦ f2 is established. X-ray imaging cannot be performed by bringing the X-ray tube 16 and the two-dimensional detector 18 closer to each other than the use distance lower limit f1 of the grid portion 24. Therefore, the first to fourth joints 19a to 19d are two-dimensionally detected with the X-ray tube 16 via the first sub arm 15, the second sub arm 17, the tube mounting portion 22, and the detector mounting portion 23. The rotation is restricted so that the distance to the container 18 does not become shorter than the use distance lower limit f1.

In addition, the X-ray diaphragm unit 25 disposed in front of the X-ray tube 16 limits the X-ray irradiation range so that only a portion necessary for diagnosis is irradiated so that the subject is not exposed unnecessarily. . On the other hand, the X-ray irradiation range is expanded so that an area necessary for diagnosis can be observed at a time. Therefore, the proximity distance limit between the X-ray tube 16 and the two-dimensional detector 18 is determined by the minimum or maximum area that can be set by the X-ray diaphragm 25.
Thus, the rotation angles of the first to fourth joints 19a to 19d are determined by the characteristics of the grid part 24 or the X-ray diaphragm part 25.

  In the above description, the case where the first sub-arm 15 and the second sub-arm 17 move within the plane formed by the frame of the C-shaped arm 13 has been described. However, the present invention is not limited to this case. For example, the first sub arm 15 and the second sub arm 17 may be configured to be movable in a direction substantially perpendicular to the surface formed by the frame of the C-arm 13. In this case, a fifth joint and a sixth joint that rotate each sub arm in a direction perpendicular to the surface may be added between the C-arm 13 and each sub arm. With this configuration, the imaging region on the subject can be easily moved in the body axis direction of the subject. That is, since the X-ray tube 16 and the two-dimensional detector 18 can be moved in the body axis direction of the subject, the operator can easily perform X-ray imaging without moving the main body 11.

Next, the case where the distance between the X-ray tube 16 and the two-dimensional detector 18, that is, the imaging distance is changed will be described. A brake release switch (not shown) is provided at the end of the tube mounting portion 22 and the end of the detector mounting portion 23 at positions close to the grips 26 and 27, respectively.
For example, when the operator holds the handle 27 on the two-dimensional detector 18 side and presses the brake release switch, the brake of the rotation mechanism by the third joint 19c and the fourth joint 19d can be released. As shown in FIG. 2A, the operator changes the imaging distance by holding the handle 27 with the brake released and moving the two-dimensional detector 18 closer to the X-ray tube 16. be able to.

In the present embodiment, when the imaging distance is changed, the X-ray beam from the X-ray tube 16 is not obliquely incident on the two-dimensional detector 18, that is, with respect to the imaging axis Lc shown in FIG. The condition is that the two-dimensional detector 18 always moves in parallel so that the front surface of the two-dimensional detector 18 is orthogonal. Here, the imaging axis Lc is a line connecting the focal point of the X-ray tube 16 and the center of the two-dimensional detector 18. Thus, the rotational angles of the third joint 19c and the fourth joint 19d are uniquely determined by translating the two-dimensional detector 18 so that the front surface of the two-dimensional detector 18 is always orthogonal to the imaging axis Lc. Therefore, the control of the second sub arm 17 and the detector mounting portion 23 is easy.
In addition, by providing the second sub-arm 17, the space in the C-arm 13 can be increased when the shooting distance is increased or decreased. Note that the detector mounting portion 23 is not limited to being configured through the third joint 19c, the second sub-arm 17, and the fourth joint 19d, and may be configured by two or more joints (rotating mechanisms). Good.

Similarly, for example, the operator can release the brake of the rotating mechanism by the first joint 19a and the second joint 19b by holding the handle 26 on the X-ray tube 16 side and pressing the brake release switch. it can. As shown in FIG. 2B, the operator changes the imaging distance by holding the handle 26 with the brake released and moving the X-ray tube 16 closer to the two-dimensional detector 18. be able to.
Similarly, by rotating the X-ray tube 16 so that the front surface of the two-dimensional detector 18 is always orthogonal to the imaging axis Lc, the rotation angles of the first joint 19a and the second joint 19b are as follows. Therefore, it is easy to control the first sub arm 15 and the tube mounting portion 22.
In addition, by providing the first sub arm 15, the space in the C-arm 13 can be increased when the shooting distance is extended or shortened.
Note that the tube mounting portion 22 is not limited to the case of being configured through the first joint 19a, the first sub arm 15 and the second joint 19b, and may be configured of two or more joints (rotating mechanisms). Good.

Further, as described above, by preventing the X-ray light beam from the X-ray tube 16 from obliquely entering the two-dimensional detector 18, the grid unit 24 does not cut off X-rays effective for diagnosis, Effective X-ray imaging can be performed. Here, there are two modes of control for preventing the X-ray light beam from being obliquely incident.
First, when the operator changes the imaging distance by holding the handle 27 of the detector mounting portion 23, the perpendicular to the front surface of the two-dimensional detector 18 passes through the focal point of the X-ray tube 16. This is a mode for controlling the detector 18 (active side control mode). In the active side control mode, conversely, when the operator changes the imaging distance by holding the handle 26 of the tube mounting portion 22, the perpendicular to the front surface of the two-dimensional detector 18 passes through the focal point of the X-ray tube 16. The X-ray tube 16 is controlled to do so.
The other is that when the operator changes the imaging distance by holding the handle 27 of the detector mounting portion 23, the perpendicular to the front surface of the two-dimensional detector 18 passes through the focal point of the X-ray tube 16. This is a mode for controlling the X-ray tube 16 (passive side control mode). Conversely, in this passive side control mode, when the operator changes the imaging distance by holding the handle 26 of the tube mounting portion 22, the perpendicular to the front surface of the two-dimensional detector 18 passes through the focal point of the X-ray tube 16. Thus, the two-dimensional detector 18 is controlled.
The merit of the active side control mode is that it is easy to maintain the incident angle of the X-rays to the subject when the detector mounting portion 23 is moved. Further, the advantage of the passive side control mode is that when the operator moves the detector mounting portion 23 while holding the handle 27, the torque from the second sub arm 17 or the like is not felt. The two modes described above are switched by the control unit 50 according to the setting made by the operator via the operation unit 54.

  Further, the two-dimensional detector 18 and the X-ray tube 16 of the present embodiment can move in conjunction with each other. More specifically, the first sub arm 15 automatically moves in conjunction with the second sub arm 17. Further, the second sub arm 17 automatically moves in conjunction with the first sub arm 15. Here, a mode changeover switch (not shown) is provided at a position close to at least one of the handle 26 and the handle 27. The operator can switch between the single mode and the interlocking mode with the mode switch. In the single mode, only the gripping side sub-arms 15 and 17 of the handle 26 or the handle 27 and only the mounting part of the detector mounting part 23 or the tube mounting part 22 on the gripping side move. On the other hand, in the interlock mode, the sub-arms 15 and 17 on the side of the handle 26 or the handle 27 that are not gripped and the mounting portion on the side of the detector mounting portion 23 or the tube mounting portion 22 that is not gripped also move together. . The control unit 50 switches between the single mode and the interlocking mode according to the setting of the mode switch.

Furthermore, there are two types of interlocking modes. The shooting distance constant interlocking mode and the shooting distance change interlocking mode.
In the constant shooting distance interlocking mode, the sub-arms 15 and 17 on the side of the handle 26 or the handle 27 that are not gripped and the mounting portion on the side that is not gripped move in conjunction so that the shooting distance is not changed. That is, in the imaging distance constant interlocking mode, the sub arms 15 and 17 and the attachment portions 22 and 23 move so that the imaging distance between the two-dimensional detector 18 and the X-ray tube 16 is constant. For example, as the two-dimensional detector 18, that is, the second sub-arm 17 is moved away from the subject, the X-ray tube 16, that is, the first sub-arm 15 approaches the subject. In this case, it is possible to reduce the imaging region and increase the magnification of the subject without changing the opening of the X-ray diaphragm unit 25 and the imaging distance. Conversely, as the two-dimensional detector 18, that is, the second sub-arm 17 is moved closer to the subject, the X-ray tube 16, that is, the first sub-arm 15 moves away from the subject. In this case, it is possible to enlarge the imaging region and reduce the magnification of the subject.

  In the shooting distance change interlocking mode, the sub-arms 15 and 17 on the side of the handle 26 or the handle 27 that are not gripped and the mounting portion on the side that is not gripped move in conjunction so that the change of the shooting distance is accelerated. That is, in the imaging distance change interlocking mode, the sub-arms 15 and 17 and the attachment portions 22 and 23 move so that the two-dimensional detector 18 and the X-ray tube 16 move in opposite directions. For example, as the two-dimensional detector 18 or the second sub arm 17 is moved away from the subject, the X-ray tube 16 or the first sub arm 15 is also moved away from the subject. In this case, the shooting area can be changed while the enlargement ratio is generally maintained. Conversely, as the two-dimensional detector 18, that is, the second sub-arm 17 is moved closer to the subject, the X-ray tube 16, that is, the first sub-arm 15 approaches the subject. In this case, the shooting area can be changed while maintaining the enlargement ratio. That is, as shown in FIG. 2A, when the handle 27 is held and moved from the position of the two-dimensional detector shown by the broken line to the position of the two-dimensional detector 18 shown by the solid line, the X-ray tube shown by the broken line To the position of the X-ray tube 16 indicated by the solid line.

The operation as described above is controlled according to an instruction from the control unit 50. That is, in the control unit 50, for example, when the movement of the second sub-arm 17 on the handle 27 side gripped by the operator, that is, the rotation angle of the third joint 19 c is detected, the first rotation is performed according to the detected rotation angle. The rotation angle for rotating the joint 19a is calculated. Then, the first joint 19a rotates the first sub arm 15 based on the calculated rotation angle. The second joint 19b rotates the tube mounting portion 22, that is, the X-ray tube 16 in accordance with the rotation angle of the first joint 19a. Conversely, when the first sub arm 15 is moved, the third joint 19c rotates the second sub arm 17 based on the calculated rotation angle. Further, the fourth joint 19d rotates the detector mounting portion 23, that is, the two-dimensional detector 18, according to the rotation angle of the third joint 19c. In this way, the joints 19a to 19d perform an operation in which the imaging distance between the two-dimensional detector 18 and the X-ray tube 16 is moved constant or in the opposite direction.
Note that the control unit 50 switches between the shooting distance constant interlocking mode and the shooting distance change interlocking mode according to the setting of the mode switch. The processing as described above is realized by the control unit 50 executing a program corresponding to the mode stored in the storage unit 52.
Further, it is advantageous to link the two-dimensional detector 18 and the X-ray tube 16 based on the imaging region of the subject, which will be described later.

Next, the shift part 28 (radiation source shift part) provided in the tube attachment part 22 is demonstrated with reference to Fig.3 (a), (b). Hereinafter, the shift method by the shift unit to be described is a so-called active side control mode.
In the present embodiment, the first sub-arm 15 and the second sub-arm 17 are connected to the frame of the C-type arm 13 and inside the C-type arm 13 by the first joint 19a and the second joint 19c, respectively. It was set as the structure which changes an imaging distance by doing. Therefore, even if the shooting distance is increased, the first sub-arm 15 and the second sub-arm 17 move in the space in the C-type arm 13, so that the outer shape of the C-type arm does not substantially increase. However, the positional relationship between the line segment connecting the centers of the X-ray tube 16 and the two-dimensional detector 18 and the C-arm 13 may change according to the change of the imaging distance. Here, as shown in FIG. 3A, the first sub-arm 15 and the second sub-arm 17 are rotated so as to be close to the X-ray tube 16 and the two-dimensional detector 18. A line segment connecting 16 and the center of the two-dimensional detector 18 is defined as an imaging axis Lc. In the present embodiment, the photographic axis Lc is configured to be the same as a line connecting both ends of the C-shaped arm 13.
Here, as shown in FIG. 3A, the case where the X-ray tube 16 is disposed on the upper side and the two-dimensional detector 18 is disposed on the lower side will be described.

  As shown in FIG. 3A, the operator moves the first sub arm 15 indicated by a solid line so as to be close to the frame of the C-arm 13, that is, the first sub arm 15 indicated by a broken line. In this case, since the first sub-arm 15 rotates clockwise around the first joint 19a, the second joint 19b moves in the upper right direction. Then, the center of the X-ray tube 16 moves to the right of the imaging axis Lc, and the line segment connecting the center of the X-ray tube 16 and the two-dimensional detector 18 deviates from the imaging axis Lc, and the operator desires X-ray imaging of the imaging range to be performed cannot be performed. Therefore, in order to make the imaging axis Lc coincide with the line segment connecting the centers of the X-ray tube 16 and the two-dimensional detector 18, the X-ray tube 16 is orthogonal to the imaging axis Lc, that is, FIG. As shown in (b), it is necessary to shift to the left.

  Therefore, the shift unit 28 of the present embodiment shifts the X-ray tube 16 with respect to the tube mounting unit 22 in a direction perpendicular to the imaging axis Lc and in the plane direction formed by the frame of the C-shaped arm 13. It has the function to do. The shift unit 28 is, for example, a ball screw or a direct-acting slide device. The shift unit 28 shifts the X-ray tube 16 toward the inside of the C-type arm 13 as the imaging distance decreases, and shifts the X-ray tube 16 toward the outside of the C-type arm 13 as the imaging distance increases. . Note that the shift amount by which the shift unit 28 shifts the X-ray tube 16 is calculated by the control unit 50. Specifically, the control unit 50 detects the movement of the first sub arm 15, that is, the rotation angle of the first joint 19 a, and calculates the shift amount according to the detected rotation angle. The shift amount corresponding to the rotation angle may be calculated by storing a correspondence table or the like in advance in the storage unit 52 and calculating by the control unit 50 based on the correspondence table.

  As described above, the shift unit 28 shifts the X-ray tube 16 based on the shift amount calculated by the control unit 50, thereby, as shown in FIG. 3B, the imaging axis Lc and the X-ray tube. A line segment connecting the centers of the sphere 16 and the two-dimensional detector 18 can be matched. That is, the shift unit 28 can move the focal point of the X-ray tube 16 on the imaging axis Lc.

In the above description, the case where the X-ray tube 16 is shifted by the shift unit 28 has been described. Similarly, the shift unit (detector shift unit) 29 moves the two-dimensional detector 18 with respect to the imaging axis Lc. Shift in the orthogonal direction. That is, the two-dimensional detector 18 is shifted toward the inside of the C-type arm 13 as the photographing distance decreases, and the two-dimensional detector 18 is shifted toward the outside of the C-type arm 13 as the photographing distance increases. Note that the shift amount by which the shift unit 29 shifts the two-dimensional detector 18 is calculated by the control unit 50 in the same manner as the above-described operation.
As described above, the shift unit 29 shifts the two-dimensional detector 18 based on the shift amount calculated by the control unit 50, so that the imaging axis Lc, the X-ray tube 16, and the center of the two-dimensional detector 18 are shifted. It is possible to match the line segment connecting. That is, the shift unit 29 can move the center of the two-dimensional detector 18 on the imaging axis Lc.

Note that the operations of the shift units 28 and 29 differ depending on the set mode. That is, when the interlock mode is set by the above-described mode change switch, for example, when the imaging distance is changed by moving the detector mounting portion 23, the first sub arm 15 and the tube mounting portion 22 are also interlocked. Move. Therefore, the shift unit 29 shifts the two-dimensional detector 18 and the shift unit 28 shifts the X-ray tube 16.
On the other hand, when the single mode is set by the mode changeover switch, for example, even if the imaging distance is changed by moving the detector mounting portion 23, the shift unit 29 on the side that has been moved becomes the two-dimensional detector. It only shifts 18.

In the above description, at least one of the X-ray tube 16 and the two-dimensional detector 18 matches the imaging axis Lc that is a line segment connecting the centers of the X-ray tube 16 and the two-dimensional detector 18. Although the case of shifting in this way has been described, the present invention is not limited to this case.
Hereinafter, another shift method by the shift units 28 and 29 will be described. Hereinafter, the shift method described is a so-called passive control mode.
For example, if the operator moves the two-dimensional detector 18, the center of the two-dimensional detector 18 moves, so that a new imaging axis passing through the center of the two-dimensional detector 18 is passively determined. Therefore, the shift unit 28 on the X-ray tube 16 side shifts the X-ray tube 16 so as to match the new imaging axis.
On the other hand, if the operator moves the X-ray tube 16, the center (focal point) of the X-ray tube 16 is moved, so that a new imaging axis passing through the center of the X-ray tube 16 is passively determined. Is done. Therefore, the shift unit 29 on the two-dimensional detector 18 side shifts the two-dimensional detector 18 so as to match the new imaging axis.

Note that the shift amount by which the shift units 28 and 29 shift the X-ray tube 16 or the two-dimensional detector 18 is calculated by the control unit 50. That is, for example, the control unit 50 detects the movement of the first sub arm 15, that is, the rotation angle of the first joint 19 a, and calculates the position of a new imaging axis based on the detected rotation angle. Furthermore, the control unit 50 calculates the shift amount of the two-dimensional detector 18 that matches the calculated imaging axis. Then, the shift unit 29 on the two-dimensional detector 18 side shifts the two-dimensional detector 18 based on the calculated shift amount. Conversely, when the second sub arm 17 is moved, the control unit 50 calculates the shift amount of the X-ray tube 16. The shift unit 28 on the X-ray tube 16 side shifts the X-ray tube 16 based on the calculated shift amount. The above-described processing is realized by the control unit 50 executing a program corresponding to the mode stored in the storage unit 52.
As described above, since the X-ray tube 16 or the two-dimensional detector 18 on the side moved by the operator is not automatically shifted, the positioning of the X-ray tube 16 or the two-dimensional detector 18 is facilitated.
In addition, although the shift parts 28 and 29 demonstrated the case where it provided in the tube attachment part 22 and the detector attachment part 23, respectively, it is not restricted to this case. That is, the shift units 28 and 29 may be configured in any manner as long as the X-ray tube 16 and the two-dimensional detector 18 can be moved with respect to each sub arm.

Next, a preferred position range in which the first sub arm 15 and the second sub arm 17 are provided on the frame of the C-arm 13 will be described with reference to FIGS. 4 (a) and 4 (b).
One of the factors determining the position range is the grid portion 24. Assuming that the focusing distance of the grid portion 24 is f0, the use distance limit of the grid is set so as to include the focusing distance f0.
If the lower limit of the use distance is f1 and the upper limit of the use distance is f2, f1 ≦ f0 ≦ f2 is established. The use distance limit f1 ≦ f0 ≦ f2 indicates a range in which the amount by which the grid portion 24 cuts off X-rays effective for imaging is equal to or less than a specified value. Outside this range is a distance that is not suitable for X-ray imaging because the subject is exposed to a great deal of waste.
In general, the first sub-arm 15 and the second sub-arm 17 are preferably shorter. However, if the distance is too short, interference with the X-ray tube 16 and the two-dimensional detector 18 becomes a problem, so that there are suitable ranges for the positions of the first joint 19a and the third joint 19c.

First, the factor that determines the link position range is the lower limit f1 of the use distance. Here, as shown in FIG. 4A, when the center point of the semicircular C-shaped arm 13 is O, the angle from the end of the C-shaped arm 13 to the first joint 19a is defined as an angle α1. . Here, the end of the present embodiment coincides with an intersection where the imaging axis Lc connecting the centers of the X-ray tube 16 and the two-dimensional detector 18 and the C-arm 13 intersect or substantially intersect. The position of the first joint 19a at the angle α1 is a position that enables the shortest sub-arm length. The distance L1 between the first joint 19a and the second joint 19b is set so that the distance L2 between the first joint 19a and the end of the C-arm 13 is equal. Here, the case where the number of joints is one between the first sub-arm 15 and the tube mounting portion 22 is described. However, when there are a plurality of joints, the first joint 19a is farthest from the first joint 19a. The distance between the joints is a distance L1.
Here, when the distance from the center point O to one end of the C-shaped arm 13 is a radius R, the following equation is established: L1 = L2 (1)
2R = f1 + L1 × cos (α1) (2)
That is, the angle α1 is selected as the shortest sub-arm distance L1 that satisfies the expressions (1) and (2).

Next, an angle α2 that defines the longest sub-arm is defined. The restriction when the sub arm is made the longest is defined by the usability of the C-arm 13. That is, if the first sub-arm 15 is unnecessarily lengthened, the space in the frame of the C-shaped arm 13, that is, the arc space is reduced. As the arc space formed by the C-shaped arm 13 becomes smaller, the space occupied by the subject becomes smaller. Therefore, the angle α2 is defined by the following equation from the relationship shown in FIG. 4B, assuming that the cross section of the subject is rectangular.
f1 = R × (1 + cos (α2)) (3)

  As a result, the range in which the first joint 19a is provided is represented by α1 ≦ α ≦ α2, where α is the angle from one end of the C-arm 13 to the first joint 19a. 4A and 4B, the first sub-arm 15 is described as an example, but the third joint 19c is similarly applied to the second sub-arm 17 holding the two-dimensional detector 18. Can be defined. Note that, here, when the single mode is set, only one sub arm 15, 17 can move and the lower limit photographing distance f <b> 1 can be realized. Therefore, a case where only one sub arm 15, 17 moves will be described. ing.

Thus, the factor that regulates the range in which the first joint 19a and the third joint 19c are provided is the lower limit shooting distance f1 of the working distance. That is, if the lower limit photographing distance f1 of the grid portion 24 attached to the front surface of the two-dimensional detector 18 changes, the range in which the first joint 19a and the third joint 19c are provided also changes.
Therefore, the operator can input the lower limit shooting distance f1 of the grid unit 24 via the operation unit 54 of the main body 11. Then, the control unit 50 calculates a position where the first joint 19a and the third joint 19c move along the frame of the C-arm 13 according to the input lower limit photographing distance f1. The first joint 19a and the third joint 19c are configured to move along the frame of the C-arm 13 as shown in the direction of arrow C in FIG. May be. However, the movement range of the means for moving the joint is limited by the range of the shift distance of the shift units 28 and 29.

In the above description, the mode changeover switch is used to switch between the single mode and the interlock mode, and in the interlock mode, the movements of the first sub arm 15 and the second sub arm 17 are interlocked.
Next, a case where the sub-arm is controlled based on the imaging part information will be described with reference to FIG. The imaging region indicates, for example, the spine, abdomen, head, limbs (thigh, upper arm, etc.) and the like. The control unit 50 acquires imaging part information input by the operator via the operation unit 54 or acquires imaging part information according to the DICOM standard from a network input unit (not shown). The captured image data is output by the control unit 50 to another external device in accordance with the DICOM standard.

Here, as shown in FIG. 5A, it is assumed that the spine is operated as the region of interest 31 of the subject. At this time, even if the interlock mode is set by the mode switch, it is not preferable that the first sub arm 15 and the second sub arm 17 are interlocked because there is no moving space.
Further, as shown in FIG. 5B, it is assumed that head surgery is performed as the region of interest 31 of the subject. At this time, when the interlock mode is set by the mode changeover switch, it is preferable that the first sub arm 15 and the second sub arm 17 are interlocked because there is sufficient movement space. As described above, it may be determined whether or not the first sub-arm 15 and the second sub-arm 17 are interlocked based on the imaging region information.

In the above description, the case where the first joint 19a and the third joint 19c move along the frame of the C-arm 13 when the lower limit shooting distance f1 of the grid portion 24 is changed has been described.
Here, a case where the first joint 19a and the third joint 19c move based on the imaging part information will be described. It is assumed that the control unit 50 acquires imaging part information and determines that the imaging part is an imaging part having a large cross-sectional area such as a spine or an abdomen. In this case, at least one of the first joint 19a and the third joint 19c is directed along the frame of the C-type arm 13 so that the arc space of the C-type arm 13 becomes large under the instruction of the control unit 50. It moves to the end side of the C-arm 13. On the other hand, it is assumed that the control unit 50 determines that the imaging part is an imaging part having a small cross-sectional area such as a head or limbs. In this case, at least one of the first joint 19a and the third joint 19c is directed along the frame of the C-type arm 13 so that the arc space of the C-type arm 13 is reduced under the instruction of the control unit 50. Move to the inside of the C-arm 13.
Thus, the first joint 19a or the third joint 19c moves according to the imaging region, and the first sub arm 15 or the second sub arm 17 moves, so that the C-shaped arm 13 corresponding to the imaging region is moved. Can be changed in the arc space.

Next, the relationship between the arrangement direction of the lead plates constituting the grid portion 24 and the direction in which the shift portions 28 and 29 shift the two-dimensional detector 18 and the X-ray tube 16 will be described.
The grid portion 24 is formed by arranging a plurality of lead plates at predetermined intervals. That is, the direction in which the lead plates are arranged (hereinafter referred to as the stripe direction) refers to a direction orthogonal to the direction in which the gap between the lead plates continues. Here, in the present embodiment, the shift units 28 and 29 shift the X-ray tube 16 or the two-dimensional detector 18 in a direction orthogonal to the stripe direction of the grid unit 24. That is, as described above, the shift units 28 and 29 are configured so that the perpendicular line obtained by dropping the X-ray tube 16 or the two-dimensional detector 18 from the center of the two-dimensional detector 18 passes through the center of the X-ray tube 16. Align.
In addition, since the lead plate of the grid part 24 is arrange | positioned so that it may converge in a fringe direction, if alignment shifts | deviates to a fringe direction, the cutoff of X-ray will become large. Therefore, the X-ray cutoff effective for diagnosis can be made insensitive to misalignment.

  In each of the means constituting the radiation imaging apparatus and the steps of the radiation imaging apparatus control method in the embodiment of the present invention described above, the control unit 50 (computer) operates a program stored in RAM, ROM, or the like. Can be realized. This program and a computer-readable recording medium recording the program are included in the present invention.

  Further, the present invention can be implemented as, for example, a system, apparatus, method, program, or recording medium, and may be applied to an apparatus composed of a single device.

  The present invention supplies a software program for realizing the functions of the above-described embodiments directly or remotely to a system or apparatus. In addition, this includes a case where the system or the computer of the apparatus is also achieved by reading and executing the supplied program code.

DESCRIPTION OF SYMBOLS 100: X-ray imaging apparatus 11: Main body 13: C-type arm 15: 1st sub arm 16: X-ray tube 17: 2nd sub arm 18: Two-dimensional detector 19a-19d: 1st joint-4th Joint 22: Tube mounting portion 23: Detector mounting portion 24: Grid portion 28: Shift portion (radiation source shift portion)
29: Shift unit (detector shift unit)

Claims (11)

A C-type arm that supports a radiation source that irradiates the subject with radiation, and a two-dimensional detector that detects the radiation transmitted through the subject.
A support portion having a rotation portion and rotating the C- arm around a rotation axis of the rotation portion;
Using a first sub-arm which is rotatably connected to the C-arm an inner than an end portion of the C-arm, in the direction perpendicular to the line connecting the said two-dimensional detector and the radiation source And a radiation source shift unit that moves the radiation source in a direction parallel to the rotation axis of the rotation unit. The two-dimensional detector is disposed through a second sub-arm that is rotatably connected to the frame, inside the other end of the frame of the C -arm. The radiation imaging apparatus according to claim 1 . The radiation source shift unit moves the radiation source in accordance with the rotation of the first sub-arm so as to coincide with an imaging axis connecting the radiation source before being moved and the two-dimensional detector. The radiation imaging apparatus according to claim 1 . The image receiving surface of the two-dimensional detector has a grid portion for removing scattered radiation from radiation,
The radiation imaging apparatus according to claim 3 , wherein the radiation source shift unit moves the radiation source in a direction orthogonal to a stripe direction of the grid unit. Between the two-dimensional detector and the second sub-arm, a detector shift unit that moves the two-dimensional detector with respect to the second sub-arm,
The detector shift unit moves the two-dimensional detector according to the rotation of the second sub-arm so as to coincide with the imaging axis connecting the two-dimensional detector before the movement and the radiation source. The radiation imaging apparatus according to claim 2 . The image receiving surface of the two-dimensional detector has a grid portion for removing scattered radiation from radiation,
The radiation detector according to claim 5 , wherein the detector shift unit moves the two-dimensional detector in a direction orthogonal to a stripe direction of the grid unit. The two-dimensional detector is disposed via a second sub-arm that is inside the other end of the frame of the C-arm and is rotatably connected to the frame.
Between the two-dimensional detector and the second sub-arm, a detector shift unit that moves the two-dimensional detector with respect to the second sub-arm,
The radiation source shift unit moves the radiation source so as to coincide with the imaging axis passing through the center of the two-dimensional detector changed by the movement of the second sub-arm,
The detector shift unit, by the movement of the first sub-arm so as to coincide with the imaging axis passing through the center of the modified the radiation source, according to claim 1, characterized in that for moving the two-dimensional detector The radiation imaging apparatus described in 1. The two-dimensional detector is disposed via a second sub-arm that is inside the other end of the frame of the C-arm and is rotatably connected to the frame.
At least one of the connection portion between the first sub-arm and the C-type arm and the connection portion between the second sub-arm and the C-type arm is movable along the frame of the C-type arm. The radiation imaging apparatus according to claim 1 . The two-dimensional detector is disposed via a second sub-arm that is inside the other end of the frame of the C-arm and is rotatably connected to the frame.
Interlocking means for interlockingly rotating the second subarm according to rotation of the first subarm or interlocking means for interlockingly rotating the first subarm according to the rotation of the second subarm. The radiation imaging apparatus according to claim 1 . Having an input means for inputting imaging part information;
The radiographic apparatus according to claim 9 , wherein the interlocking unit interlocks the first sub arm or the second sub arm based on imaging part information input by the input unit. A C-type arm that supports a radiation source that irradiates the subject with radiation, and a two-dimensional detector that detects the radiation transmitted through the subject.
A support portion having a rotation portion and rotating the C-arm around a rotation axis of the rotation portion;
Using a sub-arm that is inside the end of the C-arm and is rotatably connected to the C-arm, the rotation is performed in a direction perpendicular to a straight line connecting the radiation source and the two-dimensional detector. And a detector shift unit that moves the two-dimensional detector in a direction parallel to the rotation axis of the unit.

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