JP5099055B2 - Radiation tomography equipment - Google Patents

Description

  The present invention relates to a radiation tomography apparatus capable of acquiring a tomographic image of a subject, and in particular, radiation that rotates and moves while maintaining a relative positional relationship between a radiation source that irradiates radiation and a radiation detector that detects the radiation. The present invention relates to a tomography apparatus.

  There are various configurations of radiation tomography apparatuses that irradiate a subject with radiation and image transmitted radiation that has passed through the subject. For example, there is a configuration in which a radiation source for irradiating radiation and a radiation detector for detecting radiation are supported on both ends of a C-type support member (C-type arm). Such a radiation detector having a C-shaped arm is easy to inject a contrast medium into a subject while photographing a radiation projection image, and is used, for example, for an angiographic examination of a subject.

  First, the configuration of the conventional radiation tomography apparatus 51 will be described. As shown in FIG. 8, a conventional radiation tomography apparatus 51 detects a radiation, a top plate 52 on which a subject M is placed, a radiation source 53 that irradiates a radiation beam toward the subject M, and A radiation detector 54 in which detection elements are two-dimensionally arranged, a radiation source controller 56 that controls the tube power of the radiation source 53, a C-type arm 57 that supports the radiation source 53 and the radiation detector 54, A C-type arm drive mechanism 59 for driving this and a C-type arm drive control unit 60 for controlling the C-type arm drive mechanism 59 are provided. The C-shaped arm 57 is supported by a support column 58.

  Further, the C-type arm 57 can also rotate the C-type arm 57 around its center of curvature. That is, the C-arm 57 can be rotated in the direction indicated by the arrow G in FIG. 8 by changing the distance between the fulcrum where the column 58 supports the C-arm 57 and the radiation source 53. Further, if the radiation source 53 can be rotated in a direction away from the fulcrum, conversely, the radiation source 53 can also be rotated in a direction approaching the fulcrum.

  By rotating the C-arm 57, it becomes possible to irradiate radiation from an arbitrary angle, and the direction of seeing through the subject M can be changed according to the diagnosis. Further, if a plurality of radiographic images are taken while rotating the C-arm 57, these radiographic images can be reconstructed to obtain a tomographic image of the subject.

  The rotation mechanism of the C-type arm 57 will be described. FIG. 9 is a perspective view for explaining a conventional C-arm rotating mechanism. As shown in FIG. 9, a belt 60 is provided on the side of the back side of the C-arm 57 as viewed from the center of curvature. The belt 60 follows the shape of the C-shaped arm 57, and both ends thereof are fixed to the front ends of the C-shaped arm 57 by belt stops 61. The C-shaped arm 57 and the belt 60 are supported by a support plate 64. The support plate 64 is supported by the support column 58 described above.

  The support plate 64 is provided with a drive pulley 63 that drives the belt 60 and six rollers 62. Two rollers 62 are provided in the vicinity of the driving pulley 63, and the two rollers 62 and the driving pulley 63 are adjacent to each other with a gap through which the belt 60 passes. The belt 60 is Ω-shaped between the drive pulley 63 and the roller 62 in the vicinity of the drive pulley 63. Further, two separate rollers 62 are provided on each side surface of the C-shaped arm 57. Each of these rollers 62 supports a C-shaped arm 57.

  When it is desired to rotate the C-arm 57, the drive pulley 63 is driven. Then, since the belt 60 is driven by the drive pulley 63 and both ends of the belt 60 are fixed to the C-type arm 57, the C-type arm 57 is rotated following the driving of the belt 60. Such a configuration is described in Patent Document 1.

Japanese Patent Laid-Open No. 9-154836

However, the conventional configuration as described above has the following problems.
That is, when the C-type arm 57 is rotated, the C-type arm 57 bends accordingly. This problem will be described with reference to FIG. FIG. 10A is a diagram when the radiation source 53 is closest to the support plate 64. From this state, it is assumed that the C-type arm 57 is rotated so that the radiation source 53 as shown in FIG. The radiation source 53 is a heavy load due to the necessity of shielding radiation and handling high voltage. Accordingly, when the portion of the C-type arm 57 sandwiched between the radiation source 53 and the support plate 64 is lengthened in an attempt to keep the radiation source 53 away from the support plate 64, the C-type arm 57 bends vertically downward. It sinks to the position indicated by the dotted line 10 (b).

  In the case of FIG. 10, when the C-arm 57 is rotated, ideally, the radiation source 53 and the radiation detector 54 circularly move around the isocenter Q. In the circular motion, the radiation irradiated from the radiation source 53 always passes through the virtual circle R having the isocenter Q as the center. However, in the conventional configuration as described above, as the radiation source 53 moves away from the support plate 64, the C-arm 57 bends vertically downward, and the radiation source 53 is gradually positioned below the ideal position. That is, the radiation source 53 follows an elliptical locus according to the rotation of the C-arm 57 and does not move circularly around the isocenter Q. Then, a part of the radiation irradiated from the radiation source 53 does not pass through the virtual circle R, leading to distortion of the acquired radioscopic image. In particular, when acquiring a series of radiographic images while rotating the C-arm 57 and reconstructing them to acquire a tomographic image of the subject, such a problem becomes significant. That is, a series of calculations performed in the reconstruction is performed on the assumption that the radiation source 53 and the radiation detector 54 are circularly moving around the isocenter Q. Therefore, if the radiation source 53 is not accurately circularly moved, the acquired tomographic image is distorted.

  Such a problem is solved by increasing the rigidity of the C-arm 57 according to the conventional configuration. Then, the C-type arm 57 becomes heavy, and the support plate 64 and the support column 58 that support it become heavy.

  The present invention has been made in view of such circumstances, and an object of the present invention is to obtain a radiation tomographic image in which a tomographic image without distortion can be acquired by accurately moving the radiation source 53 and the radiation detector 54 in a circular motion. It is to provide a photographing apparatus.

In order to achieve the above-mentioned object, the present invention has the following configuration.
That is, the radiation tomography apparatus according to claim 1 is a radiation source that irradiates radiation, a radiation detection means that detects radiation, a support member that supports each of the radiation source and the radiation detection means at both ends, Inclination means for inclining the support member, inclination control means for controlling the same, image generation means for converting a detection signal output from the radiation detection means into a fluoroscopic image, and a subject by reconstructing a plurality of fluoroscopic images and a reconstruction means for obtaining a tomographic image, while the support member is inclined, the series of fluoroscopic images are acquired, reconstructed means, the radiation tomography apparatus for acquiring a tomographic image by reconstructing them A first base member that rotatably supports the support member, a second base member that supports the first base member, a third base member that supports the second base member so as to be movable in the vertical direction, and a second base member First The first base member includes a radiation source and a radiation detection means. The elevation movement means moves the support member by moving the three base members in the vertical direction, and the elevation movement control means controls the movement. The tilting means tilts the support member and the first base member with respect to the second base member so that the support member is rotated around the rotation axis passing through the first base member and orthogonal to the radiation irradiation axis to be tied. is, vertical movement means, with the inclination of the support member, so that the fixed point belonging to the line connecting the radiation source and the radiation detecting means is always the same height, the Rukoto move the support member in a vertical direction It is a feature.

  [Operation / Effect] The radiation tomography apparatus according to the present invention includes an inclination means for inclining the support member. Moreover, the tilting means tilts the support member together with the first base member. The first base member supports the support member. That is, in the radiation tomography apparatus according to the present invention, both ends of the support member (or the base portion of the support member. The base portion is connected to the first base member) and the first portion that supports the support member regardless of the inclination of the support member. The distance from the one base member does not change. On the other hand, according to the conventional configuration, it is a roller that supports the support member (C-type arm). During the rotation, the support member bends because the distance between the roller and the radiation source changes. According to the present invention, since the distance between the radiation source and the first base member that supports the support member does not change, the support member does not bend. Therefore, the radiation source and the radiation detection means can be moved as set by the tilting means. For example, the radiation source can be moved along a perfect circle.

  [Operation / Effect] According to the above-described configuration, the lifting / lowering means for moving the support member in the vertical direction is provided. As the support member is tilted, the fixed point in the line segment connecting the radiation source and the radiation detection means moves up and down, but the up-and-down movement means moves between the radiation source and the radiation detection means as the support member tilts. The support member is moved in the vertical direction so that the fixed points in the line segment connecting the two always have the same height. Therefore, the radiation source and the radiation detection means move in a perfect circle around the fixed point as the support member is inclined.

According to a second aspect of the present invention, in the radiation tomography apparatus according to the first or second aspect, the third base member is moved in a predetermined direction so as to be movable forward and backward, thereby moving the support member in the horizontal direction. And a horizontal movement means for controlling the horizontal movement means. The horizontal movement means moves the support member in a predetermined direction so that the fixed point is always at the same position in the predetermined direction as the support member is inclined. It is characterized by being moved.

  [Operation / Effect] According to the above-described configuration, the supporting member is provided with the horizontal moving means for moving the supporting member in a predetermined direction. As the supporting member is tilted, the fixed point in the line segment connecting the radiation source and the radiation detecting means moves in the horizontal direction. However, the horizontal moving means moves in the horizontal direction as the supporting member is tilted. Moves the support member in the predetermined direction so that the fixed point is always in the same position in the predetermined direction as the support member is inclined. Therefore, the radiation source and the radiation detection means move in a perfect circle around the fixed point as the support member is inclined.

According to a third aspect of the present invention, in the radiation tomography apparatus according to the third aspect, the support member is inclined with respect to the second base member in a state in which the positions of the fixed points in the predetermined direction and the vertical direction are maintained. The radiation source and the radiation detection means are rotated while drawing a circular arc track while maintaining the relative positional relationship, and the radiation source is Radiation fluoroscopic images are continuously shot by irradiating radiation toward the radiation detection means, and the reconstruction means reconstructs them to acquire a tomographic image.

  [Operation / Effect] According to the above-described configuration, a tomographic image can be obtained with certainty. That is, the tilting means, the raising / lowering movement control means, and the horizontal direction moving means are moved together so that the fixed point is at the same position in the predetermined direction and the vertical direction. By doing in this way, a radiation source and a radiation detection means carry out continuous radiographic image capture, carrying out the circular motion around a fixed point. In this way, tomography can be performed reliably.

  The radiation tomography apparatus according to the present invention includes tilting means for tilting the support member. Moreover, the tilting means rotates the support member by tilting the support member together with the first base member. The first base member supports the support member. That is, in the radiation tomography apparatus according to the present invention, the distance between both ends of the support member and the first base member that supports the support member does not change regardless of the inclination of the support member. Therefore, according to the present invention, the support member does not bend. Moreover, according to the structure of this invention, the raising / lowering movement means which moves a support member to a perpendicular direction can also be provided, and the horizontal direction movement means to move forward / backward in the predetermined direction with the support member can also be provided. Therefore, the radiation source and the radiation detection means perform a circular motion around a fixed point as the support member is tilted, and the tomographic image reconstructed by the reconstruction unit is not distorted and is useful for diagnosis. It is suitable.

  Embodiments of a radiation tomography apparatus according to the present invention will be described below with reference to the drawings. In addition, the X-ray in Example 1 is an example of the radiation which concerns on this invention.

  First, the configuration of the X-ray tomography apparatus 1 according to the first embodiment will be described. FIG. 1 is a functional block diagram illustrating the configuration of the radiation tomography apparatus according to the first embodiment. As shown in FIG. 1, the X-ray tomography apparatus 1 according to the first embodiment includes a top plate 2 that can move forward and backward along the body axis direction of the subject M on which the subject M is placed, and a top plate 2. An X-ray tube 3 for irradiating an X-ray beam provided on the lower side and a flat panel detector (FPD) 4 provided on the upper side of the top plate 2 and detecting X-rays transmitted through the subject M are provided. ing. The X-ray tomography apparatus 1 according to the first embodiment has an X-ray tube control unit 6 that controls the tube voltage, tube current, and X-ray beam pulse width of the X-ray tube 3. Each of the X-ray tube 3 and the FPD 4 corresponds to each of a radiation source and a radiation detection means.

  The X-ray tube 3 and the FPD 4 are collectively supported by the V-shaped arm 7. The arcuate V-shaped arm 7 whose both ends protrude in the direction A has two tips, and is provided with an X-ray tube 3 on one end side and an FPD 4 on the other end side. The V-shaped arm 7 is bent so as to avoid the top plate 2 so as not to interfere with the top plate 2. And this V-type arm 7 becomes a structure supported by the support | pillar 8 arrange | positioned on the floor surface of a test room. The V-shaped arm 7 corresponds to the support member of the present invention.

Further, the V-shaped arm 7 can be rotated. In other words, the X-ray tomography apparatus 1 is provided with a V-type arm rotation movement mechanism 11 and a V-type arm rotation movement control unit 12 for controlling the V-type arm rotation movement mechanism 11. It is rotatable and movable around a central axis P (parallel to the body axis direction of the subject M) parallel to the protruding direction A of the two tips. That is, in FIG. 1, as indicated by an arrow F, if the support 8 supports the V-shaped arm 7 as a center of rotation, the rotation is about the rotation axis P and can be rotated once clockwise. In addition, it is possible to make one rotation around the rotation axis P and counterclockwise (see FIG. 2). The state of this rotation is shown in FIG. The first base member 25, the base portion 7a, and the V-shaped arm 7 are connected along the rotation axis P in this order.

  The rotation axis P will be described. The rotation axis P is orthogonal to the X-ray irradiation axis (radiation irradiation axis of the present invention) connecting the X-ray tube 3 and the FPD 4 indicated by the double arrows in FIG. 3, and passes through the first base member 25 and the base portion 7a. It is an axis. The first base member 25 supports the V-shaped arm 7 so as to rotate around the rotation axis P. The V-shaped arm 7 rotates together with the base portion 7 a with respect to the first base member 25.

The V-shaped arm 7 is provided with a base portion 7a, and one arm extends from the base portion 7a in a direction A parallel to the rotation axis P and upward (in an obliquely upward direction). It protrudes away from the member 25. Further, the other arm protrudes from the first base member 25 downward from the base portion 7a and toward the direction A (downwardly obliquely). These base portion 7 a and the two arms constitute a V-shaped arm 7. The V-shaped arm 7 rotates around the rotation axis P around the base portion 7a. Therefore, the rotation axis P passes through the center of the base portion 7a.

  The base portion 7 a of the V-shaped arm 7 is supported by the first base member 25. That is, the V-arm rotational movement mechanism 11 is attached to the base portion 7a. This is shown in FIG. The first base member 25 is not inclined in the initial state, and at this time, the X-ray tube 3 provided on the V-shaped arm 7 is positioned vertically downward of the FPD 4. Further, the base portion 7 a is rotatably supported by the first base member 25. That is, one end of the first base member 25 is rotatably supported with the elevating member 26, and the other end of the first base member 25 rotatably supports the base portion 7 a of the V-shaped arm 7. However, the first base member 25 has a shaft (an X-ray irradiation axis connecting the X-ray tube 3 and the FPD 4 and a rotation axis P) along the width direction S of the V-shaped arm 7 with respect to the lifting member 26 The base portion 7a of the V-shaped arm 7 rotates about the axis along the protruding direction A of the V-shaped arm 7 with respect to the first base member 25 (axis parallel to the orthogonal axis) ( (See FIG. 2). That is, the direction of rotational movement of the V-shaped arm 7 relative to the first base member 25 is different from the direction of rotational movement of the first base member 25 relative to the lifting member 26. That is, the V-type arm 7 and the first base member 25 are inclined with respect to the elevating member 26, and the distance between the base portion 7 a of the V-type arm 7 and the first base member 25 is maintained at that time.

  As shown in FIG. 4, the first base member 25 is inclined with respect to the elevating member 26 so that the other end portion of the first base member 25 protrudes toward the V-arm 7. It can be tilted, or it can be tilted so as to protrude in the opposite direction. Such a change in the inclination angle of the first base member 25 with respect to the elevating member 26 is performed by the expansion and contraction of the hydraulic cylinder 27 provided at a position between them. That is, the V-shaped arm 7 can be tilted following the first base member 25. In other words, the V-shaped arm 7 is inclined together with the first base member 25. That is, as indicated by an arrow in FIG. 4, one end of the V-shaped arm 7 can be protruded in the direction A, and the other end of the V-shaped arm 7 can be retracted from the direction A.

  The elevating member 26 is supported by the column 8 so as to be movable in the vertical direction, and the elevating member 26 is movable in the vertical direction with respect to the column 8. The manner in which the V-arm 7 moves up and down as the elevating member 26 moves relative to the column 8 is shown in FIG. Moreover, the support | pillar 8 can slidely move on the floor surface R of a test room. Specifically, it can advance and retreat along the direction A in which the V-shaped arm 7 projects. This is illustrated in FIG.

  The movement of the first base member 25, the elevating member 26, and the support column 8 as described above is performed by the cooperation of each mechanism and each control unit in charge of them. The sliding motion of the column 8 with respect to the floor surface R is realized by a column sliding mechanism 28 that slides the column 8 and a column sliding control unit 29 that controls this. Moreover, the raising / lowering movement with respect to the support | pillar of the raising / lowering member 26 is implement | achieved by the raising / lowering drive mechanism 36 and the raising / lowering drive control part 37 which controls this. Specific configurations of the column sliding mechanism 28 and the lift drive mechanism 36 are, for example, a rack and a pinion, but this embodiment is not limited to this. It has already been explained that the change in the inclination angle of the first base member 25 with respect to the elevating member 26 is due to the hydraulic cylinder 27. The hydraulic cylinder 27 is controlled by a hydraulic cylinder control unit 38.

  The hydraulic cylinder 27 corresponds to the tilting means of the present invention, and the column sliding mechanism 28 corresponds to the horizontal direction moving means of the present invention. Moreover, the support | pillar sliding control part 29 is corresponded to the horizontal direction movement control means of this invention, and the raising / lowering moving mechanism 36 is equivalent to the raising / lowering moving means of this invention. And the raising / lowering movement control part 37 is corresponded to the raising / lowering movement control means of this invention, and the hydraulic cylinder control means 38 is equivalent to the inclination control means of this invention. In addition, the raising / lowering member 26 is corresponded to the 2nd base member of this invention, and the support | pillar 8 is equivalent to the 3rd term member of this invention.

  The X-ray tomography apparatus 1 includes an image processing unit 15 that converts a signal output from the FPD 4 into an X-ray fluoroscopic image, and a reconstruction unit 16 that reconstructs the X-ray fluoroscopic image and acquires a tomographic image. I have. The reconstruction unit 16 corresponds to a tomographic image acquisition unit of the present invention. In the X-ray tomography apparatus 1, the operator can change the position / posture of the V-arm 7 through the console 22.

  The X-ray grid 5 is provided so as to cover the X-ray detection surface of the FPD 4. In this X-ray grid 5, an absorbing foil that absorbs scattered X-rays generated inside the subject is arranged. By providing the X-ray grid 5, it is possible to obtain a tomographic image with high contrast. The X-ray tube 3 is provided with a collimator 9 that collimates the X-rays emitted from the X-ray tube 3. X-rays output from the X-ray tube 3 are emitted toward the subject M as a cone-shaped X-ray beam by the collimator 9. The opening degree of the collimator 9 is controlled by the collimator controller 10.

  Further, as shown in FIG. 1, the X-ray tomography apparatus 1 also includes a main control unit 24 that comprehensively controls the control units 6, 10, 12, 29, 36, 37, and 38. The main control unit 24 is constituted by a CPU, and realizes the control units 6, 10, 12, 29, 36, 37, and 38 by executing various programs. Each of the above-described controls may be executed by being divided into control devices in charge of them. In addition, the X-ray tomography apparatus 1 according to the first embodiment includes a display unit 23 that displays an X-ray fluoroscopic image of the subject M. The X-ray tomography apparatus 1 includes an inclination angle related information storage unit 13 that associates the inclination angle of the V-shaped arm 7, the lifting distance, and the horizontal sliding distance. Will be described later.

  Next, the operation of such an X-ray tomography apparatus 1 will be described. In order to acquire a tomographic image of a subject with the X-ray tomography apparatus 1 according to the first embodiment, the subject placement step S1 for placing the subject M on the top 2 and the V-shaped arm 7 are tilted and moved up and down. V-type arm moving step S2 for acquiring X-ray fluoroscopic images of the subject M one after another while moving horizontally, and reconstructing a series of acquired X-ray fluoroscopic images to acquire a tomographic image of the subject M Through each step with the configuration step S3. Details of each of these steps will be described in order with reference to the drawings.

<Subject placement step S1, V-shaped arm movement step S2>
First, the subject M is placed on the top 2 (subject placement step S1). At this time, it is assumed that the surgeon instructs the X-ray tomography apparatus 1 to acquire a tomographic image of the subject M through the console 22. Then, the X-ray tube 3 supported by the V-shaped arm 7 and the FPD 4 are circularly moved around the body axis of the subject M while maintaining a relative positional relationship. During that time, the X-ray tube 3 emits an X-ray beam toward the FPD 4, and a fluoroscopic image of the subject M is reflected in the FPD 4. Such an X-ray tube 3 and the FPD 4 are realized by rotating the V-shaped arm 7.

  Q shown in FIG. 3 is an isocenter which is the center when the X-ray tube 3 and the FPD 4 rotate. In the X-ray tomography apparatus 1 according to the first embodiment, the X-ray tube 3 and the FPD 4 are rotated while drawing a perfect circle around the isocenter Q.

  The isocenter Q will be described. The isocenter Q is the midpoint of the line segment connecting the X-ray tube 3 and the FPD 4 in the first embodiment. The X-ray tube 3 irradiates the cone-shaped X-ray beam toward the FPD 4. The central axis of the radiation beam passes through the center point of the flat FPD 4. The line segment serving as the reference for the isocenter Q coincides with the central axis of the radiation beam.

  In the V-type arm moving step S2, the V-type arm 7 is tilted, moved up and down, and slid horizontally before being irradiated with X-rays from the X-ray tube 3, and an initial state at the time of taking an X-ray fluoroscopic image Moved to. The state at this time is shown in FIG. That is, the inclination angle of the V-shaped arm 7 is set to the initial angle at which the X-ray tube 3 protrudes most in the direction A. For this operation, the related table stored in the tilt angle related information storage unit 13 is used. The main control unit 24 reads the related table from the tilt angle related information storage unit 13 and acquires the desired height of the V-arm 7 corresponding to the initial angle and the position in the direction A. Based on this, each of the control units 29, 37, and 38 sets the V-arm 7 to a predetermined height and a predetermined position in the direction A while inclining.

  At this time, the height of the V-shaped arm 7 and the position in the direction A are determined based on the isocenter Q. That is, the V-type arm 7 is moved up and down and slid so that the isocenter Q does not move as the V-type arm 7 is tilted from the state where the X-ray tube 3 is positioned vertically downward of the FPD 4. . Specifically, the elevation drive control unit 37 moves the V-type arm 7 vertically downward so that the isocenter Q always has the same height as the V-type arm 7 is inclined. Similarly, the strut control unit 29 moves the strut 8 in a direction away from the subject M so that the isocenter Q is always in the same position in the direction A with the inclination of the V-arm 7. In accordance with these, the hydraulic cylinder control unit 38 tilts the V-shaped arm 7. By doing in this way, even if the V-shaped arm 7 is inclined to the initial angle, the isocenter Q is not displaced. In other words, in the related table, each of the inclination angle, height, and position in the direction A where the isocenters Q are the same is associated.

  From this state, the X-ray tube 3 emits an X-ray beam toward the FPD 4 while the inclination angle of the V-shaped arm 7 is changed. In the change of the tilt angle at this time, the related table stored in the tilt angle related information storage unit 13 is also used. In other words, the hydraulic cylinder control unit 38, the lift drive control unit 37, and the column slide control unit 29 are based on the related table, according to the current inclination angle of the V-shaped arm 7, Determine the direction and degree of movement. Specifically, the elevation drive control unit 37 moves the V-type arm 7 vertically upward so that the isocenter Q always has the same height as the V-type arm 7 is inclined. Similarly, the strut sliding control unit 29 moves the strut 8 in a direction approaching the subject M so that the isocenter Q is always in the same position in the direction A with the inclination of the V-shaped arm 7. In accordance with these, the hydraulic cylinder control unit 38 tilts the V-shaped arm 7. By doing so, the X-ray tube 3 rotates around the isocenter Q, and the locus does not deviate from the perfect circle. Such a situation is the same also about FPD4.

  The V-shaped arm 7 is rotated and enters the state shown in FIG. In the X-ray tomography apparatus 1 according to the first embodiment, the rotation of the V-shaped arm 7 is continued even in this state, and the FPD 4 protrudes in the direction A from the X-ray tube 3. The inclination of the V-shaped arm 7 is continued until the final angle at which the FPD 4 protrudes most in the direction A is reached. Also at this time, the related table stored in the tilt angle related information storage unit 13 is used. Specifically, the elevation drive control unit 37 moves the V-type arm 7 upward so that the isocenter Q always has the same height as the V-type arm 7 is inclined. Similarly, the strut control unit 29 moves the strut 8 in a direction away from the subject M so that the isocenter Q is always in the same position in the direction A with the inclination of the V-arm 7. Each time the FPD 4 detects an X-ray beam, the FPD 4 sends an X-ray detection signal to the image processing unit 15 to obtain a plurality of X-ray fluoroscopic images.

<Reconfiguration step S3>
A plurality of fluoroscopic images are sent to the reconstruction unit 16. In a series of X-ray fluoroscopic images, the internal structure of the subject is reflected while changing the position. Since the rotation angles of the X-ray tube 3 and the FPD 4 are known in advance, the reconstruction unit 16 can assemble a tomographic image of the subject M based on a series of X-ray fluoroscopic images. As a specific method, for example, a back projection method is used. The reconstructed tomographic image is displayed on the display unit 23, and the acquisition of the tomographic image according to the first embodiment is completed.

  As described above, the X-ray tomography apparatus 1 according to the first embodiment includes the hydraulic cylinder 27 that tilts the V-shaped arm 7. Moreover, the hydraulic cylinder 27 inclines the V-arm 7 together with the first base member 25 with respect to the elevating member 26. The first base member 25 supports the V-shaped arm 7. In addition, the distance between the V-shaped arm 7 (base portion 7 a) and the first base member 25 does not change regardless of the operation of the hydraulic cylinder 27. That is, in the X-ray tomography apparatus 1 according to the present invention, the distance between the first base member 25 and both ends of the V-shaped arm 7 does not change regardless of the inclination of the V-shaped arm 7. In contrast, according to the conventional configuration, the roller 62 supports the C-shaped arm 57. During the rotation, the distance between the roller 62 and the radiation source 53 changes, so the V-shaped arm 7 is bent. According to the X-ray tomography apparatus 1, since the distance between the first base member 25 that supports the V-shaped arm 7 and the X-ray tube 3 does not change, the V-shaped arm 7 does not bend. Therefore, the X-ray tube 3 and the FPD 4 can be moved as set. For example, the X-ray tube 3 can be moved along a perfect circle.

  Further, according to the X-ray tomography apparatus 1 according to the first embodiment, the elevating drive mechanism 36 that moves the V-arm 7 in the vertical direction is provided. As the V-shaped arm 7 is tilted, the midpoint (isocenter Q) in the line segment connecting the X-ray tube 3 and the FPD 4 moves up and down. Accordingly, the V-shaped arm 7 is moved in the vertical direction so that the midpoint in the line segment connecting the X-ray tube 3 and the FPD 4 always has the same height. Therefore, the X-ray tube 3 and the FPD 4 move in a perfect circle around the midpoint with an inclination.

  The X-ray tomography apparatus 1 according to the first embodiment includes the column sliding mechanism 28 that moves the V-shaped arm 7 in a predetermined direction so as to freely move forward and backward. As the V-shaped arm 7 is tilted, the midpoint of the line segment connecting the X-ray tube 3 and the FPD 4 moves in the horizontal direction, but the column sliding mechanism 28 is moved along with the tilting of the V-shaped arm 7. Thus, the V-arm 7 is moved in the predetermined direction so that the midpoint is always at the same position in the predetermined direction. Therefore, the X-ray tube 3 and the FPD 4 move in a perfect circle around the midpoint with an inclination.

  Further, there is a degree of freedom in changing the structure of the X-ray tomography apparatus 1. That is, according to the conventional configuration, in order to cause the X-ray tube 3 and the FPD 4 to move circularly, the arm for indicating them must be an arc-shaped C-type. However, according to the X-ray tomography apparatus 1 in the present embodiment, the shape of the V-shaped arm 7 is not severely limited as in the conventional example. That is, the distance N between the X-ray tube 3 and the base portion 7a of the V-shaped arm 7 can be set freely, and the X-ray tube 3 and the FPD 4 can be more protruded in the direction A than the conventional configuration with respect to the subject M. it can. In this way, when the longitudinal direction of the top 2 is along the direction A as shown in FIG. 8, the range in which the X-ray tube 3 can move with respect to the subject M is increased, and the subject in the X-ray tomography apparatus 1 is increased. The portion where M can be seen through is wider.

  The present invention is not limited to the above configuration, and can be modified as follows.

  (1) In the above-described embodiment, the support column 8 that supports the V-shaped arm 7 is disposed on the floor surface R of the examination room, but the present invention is not limited to this. It is good also as a structure which arrange | positions the support | pillar 8 on the ceiling of a test room and suspends the V-shaped arm 7 on the support | pillar 8.

  (2) In the above-described embodiments, the FPD has been described as a specific example of the radiation detection means, but the present invention is not limited to this. As the radiation detection means, an image intensifier that converts radiation into visible light and displays it may be used.

  (3) In the embodiment described above, the X-ray tomography apparatus 1 is provided with the single V-shaped arm 7, but the present invention is not limited to this. The present invention may be applied to a biplane system provided with two V-shaped arms 7.

  (4) Each embodiment described above is a medical device, but the present invention can also be applied to industrial and nuclear devices.

  (5) The X-ray referred to in each of the above-described embodiments is an example of radiation in the present invention. Therefore, the present invention can be applied to radiation other than X-rays.

  (6) The above-mentioned isocenter Q is the midpoint of the line segment connecting the X-ray tube 3 and the FPD 4, but if it is a fixed point belonging to the line segment connecting the X-ray tube 3 and the FPD4, the fault Images can be acquired.

1 is a functional block diagram illustrating a configuration of a radiation tomography apparatus according to Embodiment 1. FIG. 6 is a perspective view illustrating movement of a V-shaped arm according to Embodiment 1. FIG. 6 is a perspective view illustrating movement of a V-shaped arm according to Embodiment 1. FIG. 6 is a perspective view illustrating movement of a V-shaped arm according to Embodiment 1. FIG. 6 is a perspective view illustrating movement of a V-shaped arm according to Embodiment 1. FIG. 6 is a perspective view illustrating movement of a V-shaped arm according to Embodiment 1. FIG. 6 is a perspective view illustrating movement of a V-shaped arm according to Embodiment 1. FIG. It is a functional block diagram explaining the structure of the radiation tomography apparatus in a conventional structure. It is a perspective view explaining the structure of the C-type arm in a conventional structure. It is a schematic diagram explaining the structure of the C-type arm in a conventional structure.

P Rotating shaft Q Isocenter (fixed point)
3 X-ray tube (radiation source)
4 FPD (radiation detection means)
7 V-shaped arm (support member)
8 Prop (third base member)
15 Image processing unit (image forming means)
16 Reconfiguration unit (reconfiguration means)
25 First base member 26 Lifting member (second base member)
27 Hydraulic cylinder (tilting means)
28 Strut sliding mechanism (horizontal movement means)
29 Strut control unit (horizontal movement control means)
36 Elevating mechanism (Elevating / moving means)
37 Elevation control unit (Elevation control unit)
38 Hydraulic cylinder control means (tilt control means)

Claims (3)

A radiation source for irradiating radiation; a radiation detection means for detecting the radiation; a support member for supporting each of the radiation source and the radiation detection means at the both ends; and an inclination means for inclining the support member; An inclination control means for controlling the image data; an image generation means for converting a detection signal output from the radiation detection means into a radioscopic image; and a plurality of radiographic images are reconstructed to obtain a tomographic image of the subject. and a reconstruction unit, while the support member is inclined, the series of fluoroscopic images are acquired, reconstructed means, the radiation tomography apparatus for acquiring the tomographic image by reconstructing them,
A first base member that rotatably supports the support member;
A second base member that supports the first base member ;
A third base member that supports the second base member movably in the vertical direction;
Elevating and moving means for moving the support member by moving the second base member in the vertical direction with respect to the third base member;
Elevating movement control means for controlling this ,
The first base member is supported so that the support member is rotated around a rotation axis passing through the first base member while being orthogonal to a radiation irradiation axis connecting the radiation source and the radiation detection means,
The tilting means tilts the support member and the first base member with respect to the second base member ,
The up-and-down moving means moves the support member in the vertical direction so that fixed points belonging to a line segment connecting the radiation source and the radiation detection means always have the same height as the support member is inclined. A radiation tomography apparatus. The radiation tomography apparatus according to claim 1 ,
Horizontal direction moving means for moving the support member by moving the third base member so as to freely advance and retract in the predetermined direction;
Further comprising a horizontal movement control means for controlling this,
The horizontal movement control means moves the support member in the predetermined direction so that the fixed point is always in the same position in the predetermined direction as the support member is inclined. Shooting device. The radiation tomography apparatus according to claim 2 ,
In a state in which the position of the fixed point in the predetermined direction and the vertical direction is maintained, the support member is moved in the vertical direction and the predetermined direction while being inclined with respect to the second base member,
Along with this, the radiation source and the radiation detection means are rotationally moved while drawing a locus of an arc while maintaining a relative positional relationship,
At that time, the radiation source irradiates the radiation detection means with radiation to continuously capture radiographic images, and the reconstruction means reconstructs them to obtain the tomographic image. A radiation tomography device.

Images