JP2011078501A - Magnetic resonance diagnostic apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily improve airtightness and to efficiently reduce noise by suppressing the vibration of a cover. <P>SOLUTION: An airtight cover 12 has such an external shape as at least including a cylindrical section which has an external diameter smaller than the internal diameter of a first space formed inside a magnetostatic field magnet unit 1, at least the cylindrical section is disposed at a position in an end section side where the first space is opened, with respect to the disposal position of a gradient magnetic field coil unit 2 in the first space, to cover a region between the magnetostatic field magnet unit 1 and a bore tube 11 out of the opening. A vacuum seal 14 is disposed at a clearance between the inner circumferential face of the magnetostatic field magnet unit 1 and the cylindrical section to tightly seal the clearance. An O-ring 15 is disposed at a clearance between the bore tube 11 and the airtight cover 12 to tightly seal the clearance. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a magnetic resonance imaging apparatus to achieve noise reduction by sealing the periphery of the gradient coil unit.

  Japanese Patent Application Laid-Open No. 2004-151867 discloses a magnetic resonance imaging apparatus that uses a vacuum around the gradient magnetic field coil in order to reduce noise caused by the vibration of the gradient magnetic field coil and reduce noise.

  In the magnetic resonance imaging apparatus described in Patent Document 1, the spaces formed between the bore tube having a cylindrical shape and the static magnetic field magnet unit are respectively fixed to the side end of the bore tube and the side end surface of the static magnetic field magnet. It has a structure with a sealed cover.

JP-A-10-118043

  In the above conventional silencing structure, when sealing is performed to improve the airtightness between the static magnetic field magnet unit and the cover, a packing such as an O-ring is sandwiched between the end surface of the static magnetic field magnet unit and the cover. It was out.

  However, in order to sufficiently improve the airtightness by such a structure, the end face of the static magnetic field magnet unit needs to be a flat surface or a gentle aspect, and it is difficult to improve the airtightness when there are large irregularities. is there.

  Further, since the rigidity of the end plate of the static magnetic field magnet unit is generally not so high, vibration is easily transmitted from the end plate to the cover, which may be a cause of deteriorating noise reduction efficiency.

  The present invention has been made in consideration of such circumstances, and the object of the present invention is to make it possible to easily improve the airtightness and to efficiently reduce the noise by suppressing the vibration of the cover. An object of the present invention is to provide a magnetic resonance diagnostic apparatus capable of realizing the above.

  A magnetic resonance diagnostic apparatus according to an aspect of the present invention has an outer shape including at least a first cylindrical portion that forms a first space opened at one end, and a static magnetic field is generated in the first space. A static magnetic field generating unit for generating, and an external shape including at least a second cylindrical portion forming a second space therein, and disposed in the first space for adding to the static magnetic field A gradient magnetic field generating unit that generates a gradient magnetic field, and an outer shape including at least a third cylindrical portion that internally forms a third space for arranging a subject, at least the third cylindrical portion A part of the bore tube disposed in the second space, and an outer shape including at least a fourth cylindrical part having an outer diameter smaller than the inner diameter of the first space, Position of the gradient magnetic field generating unit in the space of 1 Also, at least the fourth cylindrical portion is disposed at a position on the end portion side where the first space is opened, and the gap between the static magnetic field generation unit and the bore tube in the opening of the first space. A cover that covers the region, a first sealing member that is disposed in a gap between the outer surface of the first cylindrical part and the fourth cylindrical part to seal the gap, the bore tube, and the cover And a second sealing member that seals the gap.

  According to the present invention, it is possible to easily improve the airtightness, and it is possible to efficiently realize silence by suppressing the vibration of the cover.

1 is a diagram showing a configuration of a magnetic resonance imaging apparatus according to an embodiment of the present invention. Sectional drawing which shows the structure in 1st Embodiment near the side end of the static magnetic field magnet unit and gradient magnetic field coil unit in FIG. Sectional drawing which shows the structure of the airtight cover in FIG. The perspective view which shows the structure of the airtight cover in FIG. Sectional drawing which shows the structure in 2nd Embodiment near the side end of the static magnetic field magnet unit and gradient magnetic field coil unit in FIG. Sectional drawing which shows the structure of the airtight cover in FIG. Sectional drawing which shows the structure in 3rd Embodiment near the side end of the static magnetic field magnet unit and gradient magnetic field coil unit in FIG. The figure which shows the state of the vacuum seal before attaching the airtight cover in FIG. 7 to a static magnetic field magnet unit. The top view of the vacuum seal in FIG. Sectional drawing which shows the structure in 4th Embodiment of the side end vicinity of the static magnetic field magnet unit 1 and the gradient magnetic field coil unit 2 in FIG.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  Figure 1 is a diagram showing a magnetic resonance imaging apparatus (MRI apparatus) 100 of the configuration according to the present embodiment. The MRI apparatus 100 shown in FIG. 1 includes a static magnetic field magnet unit 1, a gradient magnetic field coil unit 2, a gradient magnetic field power source 3, a bed 4, a bed control unit 5, a transmission RF coil 6, a transmission unit 7, a reception RF coil 8, and a reception. A section 9 and a computer system 10.

  The static magnetic field magnet unit 1 has a cylindrical outer shape that forms a columnar first space therein. The static magnetic field magnet unit 1 incorporates a superconducting magnet or a permanent magnet and generates a uniform static magnetic field in the first space. Generally, the static magnetic field magnet unit 1, to match the magnetic field direction of the axis and the static magnetic field.

  Gradient coil unit 2 has a cylindrical outer shape to form a cylindrical second space therein. The outer diameter of the gradient magnetic field coil unit 2 is smaller than the inner diameter of the static magnetic field magnet unit 1. The gradient magnetic field coil unit 2 is disposed in the first space in a state where the axis is substantially coincident with the static magnetic field magnet unit 1. In the gradient coil unit 2, three types of coils corresponding to the X, Y, and Z axes orthogonal to each other are combined. In the gradient coil unit 2, the above three coils are individually supplied with electric current from the gradient magnetic field power source 3, and the gradient magnetic field whose magnetic field intensity changes along the X, Y, and Z axes is set in the second space. appear. The Z-axis direction is the same as the magnetic field direction of the static magnetic field, for example. The gradient magnetic fields of the X, Y, and Z axes respectively correspond to, for example, the slice selection gradient magnetic field Gs, the phase encoding gradient magnetic field Ge, and the readout gradient magnetic field Gr. The slice selection gradient magnetic field Gs is used to arbitrarily determine an imaging section. The phase encoding gradient magnetic field Ge is used to change the phase of the magnetic resonance signal in accordance with the spatial position. The readout gradient magnetic field Gr is used for changing the frequency of the magnetic resonance signal in accordance with the spatial position. The gradient coil unit 2 may be either a non-shield type or a shield type, but is preferably a shield type. The shield-type gradient magnetic field coil includes a shield coil in addition to the above structure, and is also called an active shielded gradient coil (ASGC). The shield coil is driven so as to generate a magnetic field for canceling the magnetic field generated by the main coil and leaking outside the predetermined region. The gradient magnetic field coil unit 2 is shorter than the static magnetic field magnet unit 1 in the longitudinal direction. Further, the gradient coil unit 2 includes at least one tray slot that accommodates a shim tray that can hold a plurality of magnetic pieces (for example, iron shims). In the present embodiment, eight tray slots are provided. These tray slots all extend along the longitudinal direction of the gradient coil unit 2.

  The subject 200 is inserted into the second space while being placed on the top 4a of the bed 4. The couchtop 4a of the couch 4 is driven by the couch controller 5 and moves in the longitudinal direction and the vertical direction. Usually, the bed 4 is installed such that the longitudinal direction is parallel to the central axis of the static magnetic field magnet unit 1.

  The transmission RF coil 6 is disposed in the second space. The transmission RF coil 6 receives a high frequency pulse from the transmission unit 7 and generates a high frequency magnetic field.

  The transmission unit 7 transmits a high-frequency pulse corresponding to the Larmor frequency to the transmission RF coil 6.

  The reception RF coil 8 is disposed in the second space. Receiving RF coil 8 receives a magnetic resonance signal emitted from the subject by the influence of the high-frequency magnetic field. An output signal from the reception RF coil 8 is input to the reception unit 9.

  The receiving unit 9 generates magnetic resonance signal data based on the output signal from the reception RF coil 8.

  The computer system 10 includes an interface unit 10a, a data collection unit 10b, a reconstruction unit 10c, a storage unit 10d, a display unit 10e, an input unit 10f, and a main control unit 10g.

  The interface unit 10a is connected to the gradient magnetic field power source 3, the bed control unit 5, the transmission unit 7, the reception RF coil 8, the reception unit 9, and the like. The interface unit 10a inputs and outputs signals exchanged between these connected units and the computer system 10.

  The data collection unit 10b collects digital signals output from the reception unit 9 via the interface unit 10a. Data collection unit 10b is collected digital signals, that is, the magnetic resonance signal data, stored in the storage unit 10d.

  The reconstruction unit 10c performs post-processing, that is, reconstruction such as Fourier transform, on the magnetic resonance signal data stored in the storage unit 10d, and obtains spectrum data or image data of the desired nuclear spin in the subject 200. Ask.

  Storage unit 10d includes a magnetic resonance signal data and spectrum data or image data for each patient.

  The display unit 10e displays various information such as spectrum data or image data under the control of the main control unit 10g. As the display unit 10e, a display device such as a liquid crystal display can be used.

  The input unit 10f receives various commands and information input from the operator. As the input unit 10f, a pointing device such as a mouse or a trackball, a selection device such as a mode switch, or an input device such as a keyboard can be used as appropriate.

  The main control unit 10g includes a CPU, a memory, and the like (not shown), and controls the MRI apparatus 100 overall. The main control unit 10g has various control functions for implementing the well-known functions in the MRI apparatus 100.

(First embodiment)
FIG. 2 is a cross-sectional view showing the structure in the first embodiment near the side ends of the static magnetic field magnet unit 1 and the gradient magnetic field coil unit 2. FIG. 2 shows a cross section on a vertical plane passing through the center of the static magnetic field. The static magnetic field magnet unit 1 and the gradient magnetic field coil unit 2 show only the outer frame, and the internal structure is not shown. Further, FIG. 2 shows a side end on the side close to the bed 4 (hereinafter referred to as the bed side) and a side end on the side far from the bed 4 (hereinafter referred to as the anti-bed side) in the static magnetic field magnet unit 1 and the gradient magnetic field coil unit 2. Only one of them is shown. The other side end may have a structure symmetrical to the structure shown in FIG. 2 or may have a structure different from that shown in FIG. 2 as used in other existing MRI apparatuses. However, the side end shown in FIG. 2 is typically directed to the bed side.

  The second space, the bore tube 11 which has been omitted in FIG. 1 is disposed. The bore tube 11 has a cylindrical outer shape that forms a columnar third space therein. The third space is a space for placing the subject 200, and the bore tube 11 prevents the subject 200 placed in the third space from directly contacting the gradient coil unit 2.

  Further, in the vicinity of the side ends of the static magnetic field magnet unit 1 and the gradient magnetic field coil unit 2, as elements not shown in FIG. 1, there are a hermetic cover 12, a plurality of screws 13, a vacuum seal 14, an O-ring 15, and a holding plate. 16, a vibration isolating member 17, a plurality of screws 18, and a plurality of sealing caps 19 are arranged.

  Figure 3 is a sectional view showing the structure of a sealing cover 12, and shows a cross section in the same plane as FIG. FIG. 4 is a perspective view showing the structure of the hermetic cover 12.

  The hermetic cover 12 has a cylindrical shape at one end (the left end in FIG. 4, hereinafter referred to as a first end) of a cylindrical portion 12a having an outer diameter smaller than the inner diameter of the first space. A disk-shaped outer flange 12b is integrally formed so as to protrude in a direction perpendicular to the axis A of the portion 12a. The cylindrical portion 12a has a first end portion side portion (hereinafter referred to as an inlet side portion) having an opposite end portion (the right end portion in FIG. 4 and hereinafter referred to as a second end portion). ) Side portion (hereinafter referred to as the back side portion). The hermetic cover 12 has a disk-shaped inner flange 12c that protrudes toward the axis A from the vicinity of the center of the cylindrical portion 12a. A taper 12d is formed circumferentially on the first end side of the tip of the inner flange 12c.

  The cylindrical portion 12a is formed with a groove portion 12e, a plurality of screw holes 12f, a plurality of ribs 12g, a plurality of window portions 12h, and a plurality of screw holes 12i.

  The groove part 12e is formed in the outer peripheral surface of the cylindrical part 12a in the state extended along the circumferential direction. The screw hole 12f penetrates the back side portion of the cylindrical portion 12a. The plurality of screw holes 12f are all orthogonal to the axis A and along different directions. Each of the ribs 12g has a triangular plate shape, and each rib is perpendicular to the axis A and is formed along a direction different from each other, and reinforces the back side portion of the cylindrical portion 12a. The window portion 12h penetrates the inlet side portion of the cylindrical portion 12a. And plural opening portions 12h are both formed along respective different positions with parallel to the axis A. When the sealing cover 12 is provided on each of the bed side and the counter bed side, the window portion 12h in any one of the sealing covers 12 may not be provided. Typically, the window portion 12h in the sealing cover 12 provided on the counter bed side is omitted. The screw hole 12i is formed as a recess in the inlet side portion of the cylindrical portion 12a. The plurality of screw holes 12i are both formed along respective different positions with parallel to the axis A.

  The hermetic cover 12 is fitted into the opening of the first space as shown in FIG. 2 in a state where the gradient coil unit 2 is disposed in the first space. That is, the hermetic cover 12 is configured so that the rear side portion of the cylindrical portion 12a is fed into the rear side of the first space until the outer flange 12b contacts the end face of the static magnetic field magnet unit 1. It is inserted into the opening. The hermetic cover 12 has a plurality of screws 13 screwed into each of the plurality of screw holes 12f so as to contact the inner peripheral surface of the static magnetic field magnet unit 1 from the inside of the cylindrical portion 12a. It is fixed in a state of stretching on the peripheral surface. That is, since the plurality of screw holes 12 f are formed in different directions, the plurality of screws 13 are stretched in the circumferential direction of the static magnetic field magnet unit 1. Thus, the hermetic cover 12 covers a region between the static magnetic field magnet unit 1 and the bore tube 11 in the opening of the first space. In this state, the plurality of window portions 12h are positioned on the extended lines of the plurality of tray slots 2a provided in the gradient magnetic field coil unit 2.

  When the sealing cover 12 is fitted into the opening of the first space, the vacuum seal 14 is fitted into the groove 12e. The vacuum seal 14 has a ring shape and has a V-shaped cross section. The vacuum seal 14 is fitted into the groove 12e in such a posture that the bent portion faces the back side of the first space. The vacuum seal 14 may be bonded to the hermetic cover 12 or may not be bonded. The vacuum seal 14 only needs to have a portion having a V-shaped cross section, and may have a cross-sectional shape in which a portion having another shape is coupled to the V-shaped portion.

  The diameter of the opening formed inside the inner flange 12c is slightly larger than the outer diameter of the bore tube 11, and the bore tube 11 is inserted through this opening. A disc-shaped flange 11 a that protrudes in a direction orthogonal to the axis of the bore tube 11 is formed at the end of the bore tube 11. The outer diameter of the flange 11a is larger than the diameter of the opening formed inside the inner flange 12c. When the bore tube 11 is inserted into an opening formed inside the inner flange 12c, an O-ring 15 is attached to the bore tube 11 in the vicinity of the flange 11a. Thus, in a state where the bore tube 11 is sufficiently inserted into the opening formed inside the inner flange 12c, the O-ring 15 is sandwiched between the body of the bore tube 11, the flange 11a and the taper 12d as shown in FIG.

  The bore tube 11 is restrained and fixed by a disc-shaped restraining plate 16 having an opening in the center via a disc-shaped vibration isolating member 17 having an opening in the center. The holding plate 16 is fixed to the hermetic cover 12 by screwing a plurality of screws 18 into the plurality of screw holes 12i. The inner diameter of the bore tube 11, the diameter of the opening of the holding plate 16, and the diameter of the opening of the vibration isolation member 17 are substantially equal to each other.

  The plurality of sealing caps 19 are fitted into the plurality of window portions 12h, respectively. The sealing cap 19 is formed of an elastic resin or the like in a shape that can seal the window portion 12h. When the sealing cover 12 is provided on each of the bed side and the counter bed side, and the window portion 12h in any one of the sealing covers 12 is not provided, the sealing cap 19 is naturally not attached to the sealing cover 12. .

  Thus, with the structure as described above, a sealed space 30 surrounded by the static magnetic field magnet unit 1, the bore tube 11, and the sealed cover 12 is formed around the gradient coil unit 2. The air generated in the gradient magnetic field coil unit 2 can be prevented from being transmitted to the surroundings by discharging the air in the sealed space 30 with a vacuum pump (not shown) to make the sealed space 30 a vacuum. Since the sealed space 30 is evacuated as described above, the sealed cover 12 may be referred to as a vacuum container.

  When the sealed space 30 is evacuated, an atmospheric pressure is generated toward the sealed space 30 in the gap between the static magnetic field magnet unit 1 and the sealed cover 12. However, both ends of the vacuum seal 14 are expanded by the atmospheric pressure, and both ends of the vacuum seal 14 are pressed against the inner peripheral surface of the static magnetic field magnet unit 1 and the outer peripheral surface of the hermetic cover 12, respectively. As a result, the gap between the static field magnet unit 1 and the sealing cover 12 is sealed by the vacuum seal 14. On the other hand, the gap between the bore tube 11 and the sealing cover 12 is sealed by an O-ring 15. Thus, the sealed space 30 can be in a high vacuum state, and transmission of noise generated in the gradient coil unit 2 to the surroundings can be efficiently prevented.

  Since the vacuum seal 14 is in contact with the peripheral surface of the static magnetic field magnet unit 1, the gap between the static magnetic field magnet unit 1 and the sealing cover 12 is sealed regardless of the shape of the end surface of the static magnetic field magnet unit 1. be able to. As a result, the shape of the end plate can be determined without considering the sealing of the gap with the sealing cover 12, and the degree of freedom is improved. That is, in FIG. 2, although the end plate of the static magnetic field magnet unit 1 is represented as a flat plate, it is also possible to form complicated unevenness.

  Further, according to the above structure, the hermetic cover 12 is configured such that the screw 13 attached thereto abuts on the inner peripheral surface of the static magnetic field magnet unit 1 in the vicinity of the end of the static magnetic field magnet unit 1, thereby It is supported by. Since an end plate exists at the end of the static magnetic field magnet unit 1, the rigidity of the inner peripheral surface of the static magnetic field magnet unit 1 is higher in the vicinity of the end than in other positions. Thus, the hermetic cover 12 is supported by the static magnetic field magnet unit 1 at a position where the rigidity of the static magnetic field magnet unit 1 is high, that is, a position close to the vibration node of the static magnetic field magnet unit 1. Transmission of vibration to the hermetic cover 12 can be kept small.

  Moreover, according to said structure, since it is made to stretch on the internal peripheral surface of the static magnetic field magnet unit 1 with the some screw | thread 13, only locking the outer flange 12b to the end surface of the static magnetic field magnet unit 1, The atmospheric pressure when the sealed space 30 is evacuated can be received. For this reason, it is not necessary to fix the hermetic cover 12 to the end plate of the static magnetic field magnet unit 1, and the degree of freedom of the shape of the end plate is improved.

  According to the above structure, the bore tube 11 can be inserted into the second space from the opening of the hermetic cover 12 with the hermetic cover 12 attached. When inspecting the inside of the first space during maintenance, the bore tube 11 and the sealing cover 12 may be attached and detached collectively.

  Further, according to the above structure, the shim tray can be inserted into and removed from the tray slot 2a through the window 12h while the sealed cover 12 is attached. As a result, it is possible to easily adjust the arrangement of the magnetic pieces.

(Second Embodiment)
FIG. 5 is a cross-sectional view showing the structure in the second embodiment near the side ends of the static magnetic field magnet unit 1 and the gradient magnetic field coil unit 2. FIG. 4 shows a cross section in a vertical plane passing through the center of the static magnetic field regarding a portion below the center of the static magnetic field. In FIG. 5, the same parts as those in FIGS. 1 and 2 are denoted by the same reference numerals. Moreover, the static magnetic field magnet unit 1 and the gradient magnetic field coil unit 2 show only the outer frame. Further, FIG. 5 shows only one of the side ends on the bed side and the counter bed side in the static magnetic field magnet unit 1 and the gradient magnetic field coil unit 2. The other side end may have a structure symmetrical to the structure shown in FIG. 5, or may have a structure different from that shown in FIG. 5, which is adopted in other existing MRI apparatuses. However, the side end shown in FIG. 5 is typically directed to the bed side.

  In the second embodiment, a hermetic cover 20 and a vacuum seal 21 are provided in place of the hermetic cover 12 and the vacuum seal 14 in the first embodiment. In the second embodiment, a plurality of holding members 22 and a plurality of screws 23 are further provided.

  Figure 6 is a sectional view showing the structure of a sealing cover 20, and shows a cross section in the same plane as FIG. 6 that are the same as those in FIG. 3 are given the same reference numerals, and detailed descriptions thereof are omitted.

  As can be seen by comparing FIG. 6 with FIG. 3, the hermetic cover 20 has a structure common to the hermetic cover 12 in many respects. The sealing cover 20 is different from the sealing cover 12 in that the sealing cover 20 does not have the groove 12e and has a taper 20a and a plurality of screw holes 20b.

  The taper 20a is formed in a circular shape below the end portion of the back side portion of the cylindrical portion 12a.

  Each of the screw holes 20b is orthogonal to the axis A and extends in different directions.

  When the sealing cover 20 is provided on each of the bed side and the counter bed side, the window portion 12h in any one of the sealing covers 20 may not be provided. Typically, the window portion 12h in the sealing cover 20 provided on the counter bed side is omitted. Of course, the sealing cap 19 is not attached to the sealing cover 20 in which the window portion 12h is omitted.

  The vacuum seal 21 has a ring shape and has a wedge shape in cross section. The vacuum seal 21 is disposed along the inner peripheral surface of the static magnetic field magnet unit 1 with the wedge-shaped tip facing the opening of the first space before the hermetic cover 20 is attached to the static magnetic field magnet unit 1. Is done. After the hermetic cover 20 is attached to the static magnetic field magnet unit 1, the vacuum seal 21 is moved to the opening side of the first space, whereby the vacuum seal 21 is moved to the static magnetic field magnet unit 1 as shown in FIG. It is pushed between the inner peripheral surface and the taper 20a. The vacuum seal 21 only needs to have a portion having a wedge-shaped cross section, and may have a cross-sectional shape in which a portion having another shape is coupled to the wedge-shaped portion.

  The holding member 22 is fixed to the hermetic cover 20 by screwing a screw 23 penetrating the holding member 22 into the screw hole 20b. And in the state fixed in this way, the suppression member 22 suppresses the vacuum seal 21 as shown in FIG. By attaching the plurality of holding members 22 to the positions where the plurality of screw holes 20b are formed, the vacuum seal 21 is held at a plurality of different positions.

  According to the structure of the second embodiment, the gap between the static magnetic field magnet unit 1 and the sealing cover 20 is sealed by the vacuum seal 21.

  Even with the structure of the second embodiment, the same effect as that of the first embodiment can be obtained.

(Third embodiment)
FIG. 7 is a cross-sectional view showing the structure in the third embodiment near the side ends of the static magnetic field magnet unit 1 and the gradient magnetic field coil unit 2. FIG. 7 shows a cross section in a vertical plane passing through the center of the static magnetic field related to a portion below the center of the static magnetic field. In FIG. 7, the same parts as those in FIGS. 1 and 2 are denoted by the same reference numerals. Moreover, the static magnetic field magnet unit 1 and the gradient magnetic field coil unit 2 show only the outer frame. Further, FIG. 7 shows only one of the side ends on the bed side and the counter bed side in the static magnetic field magnet unit 1 and the gradient magnetic field coil unit 2. The other side end may have a structure symmetrical to the structure shown in FIG. 7, or may have a structure different from that shown in FIG. 7 as used in other existing MRI apparatuses. However, the side end shown in FIG. 7 is typically directed to the bed side.

  In the third embodiment, a hermetic cover 25 and a vacuum seal 26 are provided instead of the hermetic cover 12 and the vacuum seal 14.

  The sealing cover 25 is different in structure from the sealing cover 12 in that a groove 25a is formed instead of the groove 12e, but the other structure is the same as that of the sealing cover 12. The groove part 25a is formed in the outer peripheral surface of the cylindrical part 12a in the state extended along the circumferential direction. The groove 12e is formed in contact with the outer flange 12b, but the groove 25a is formed away from the outer flange 12b.

  When the sealing cover 25 is provided on each of the bed side and the counter bed side, the window portion 12h in any one of the sealing covers 25 may not be provided. Typically, the window portion 12h in the sealing cover 25 provided on the counter bed side is omitted. Of course, for the sealing cover 25 which window 12h is omitted, the sealing cap 19 is not mounted.

  The vacuum seal 26 is formed by forming an elastic material in a ring shape having a D-shaped cross section having a hollow portion 26a. Note that the flat surface portion and the curved surface portion in the D-shape face the inside and the outside of the vacuum seal 26, respectively. As shown in FIG. 8, the vacuum seal 26 is fitted into the groove 25 a before the hermetic cover 25 is attached to the static magnetic field magnet unit 1. The vacuum seal 26 may or may not be bonded to the hermetic cover 25. The vacuum seal 21 has a protruding amount from the outer peripheral surface of the cylindrical portion 12a in the state in which the vacuum seal 21 is fitted in the groove 25a in this way, between the outer peripheral surface of the cylindrical portion 12a and the inner peripheral surface of the static magnetic field magnet unit 1. It is larger than the gap.

  Since the vacuum seal 26 has a hollow portion 26 a, the vacuum seal 26 is sandwiched between the outer peripheral surface of the cylindrical portion 12 a and the inner peripheral surface of the static magnetic field magnet unit 1 when the hermetic cover 25 is attached to the static magnetic field magnet unit 1. Can be crushed. In this state, the vacuum seal 26 is in strong contact with the outer peripheral surface of the cylindrical portion 12a and the inner peripheral surface of the static magnetic field magnet unit 1 due to its elasticity.

  According to the structure of the third embodiment, the gap between the static magnetic field magnet unit 1 and the sealing cover 20 is sealed by the vacuum seal 26.

  Even with the structure of the third embodiment, the same effects as those of the first embodiment can be obtained.

  Incidentally, there may be a weld bead 1 a in the vicinity of the side end portion of the inner peripheral surface of the static magnetic field magnet unit 1. For this reason, the gap between the outer peripheral surface of the cylindrical portion 12 a and the inner peripheral surface of the static magnetic field magnet unit 1 is particularly narrow in the vicinity of the side end portion of the inner peripheral surface of the static magnetic field magnet unit 1. In the process of attaching the hermetic cover 25 to the static magnetic field magnet unit 1, the vacuum seal 26 can get over the weld bead 1a when the vacuum seal 26 is particularly crushed.

  The vacuum seal 26 only needs to have a hollow portion 26a and can be crushed, and the cross-sectional shape may be another shape such as a circle or an ellipse. However, the vacuum seal 26 can be crushed to such an extent that it can pass through the gap between the outer peripheral surface of the cylindrical portion 12a and the weld bead 1a, and the elasticity of the vacuum seal 26 and the static magnetic field magnet unit 1 The strength of elasticity, the size of the hollow portion 26a, and the like are adjusted so as to be able to make strong contact with the inner peripheral surface of each.

  For example, as shown in FIG. 9, the vacuum seal 26 may be formed with at least one, preferably a plurality of holes 26b that open the hollow portion 26a to either the outside or the inside of the first space. Thus, the process of attaching a sealing cover 25 to the static magnetic field magnet unit 1 can be simplified. The hole 26b does not need to be a round hole, and may have another shape such as a slit shape. FIG. 9 illustrates only a portion below the center of the static magnetic field in the hermetic cover 25.

  Alternatively, if an air valve is provided in the vacuum seal 26 so that the air pressure inside the hollow portion 26a can be adjusted, the workability of the process of attaching the hermetic cover 25 to the static magnetic field magnet unit 1 is improved and the hermetic space 30 is improved. It is possible to achieve both improvement of the sealing degree.

(Fourth embodiment)
FIG. 10 is a sectional view showing the structure in the fourth embodiment near the side ends of the static magnetic field magnet unit 1 and the gradient magnetic field coil unit 2. FIG. 10 shows a cross section on a vertical plane passing through the center of the static magnetic field with respect to the portion below the center of the static magnetic field. In FIG. 10, the same parts as those in FIGS. 1 and 2 are denoted by the same reference numerals. Moreover, the static magnetic field magnet unit 1 and the gradient magnetic field coil unit 2 show only the outer frame. Further, FIG. 10 shows only one of the side ends on the bed side and the counter bed side in the static magnetic field magnet unit 1 and the gradient magnetic field coil unit 2. The other side end may have a structure symmetrical to the structure shown in FIG. 10, or may have a structure different from that shown in FIG. 10 as used in other existing MRI apparatuses. However, the side end shown in FIG. 10 is typically directed to the bed side.

  In the fourth embodiment, instead of the bore tube 11, the sealing cover 12, the holding plate 16, and the vibration isolating member 17 in the first embodiment, the bore tube 31, the sealing cover 32, the holding plate 33, and the vibration isolating member 34 are used. Is provided. In the fourth embodiment, a nut 35 is further provided.

  The bore tube 31 is different from the bore tube 11 in that it does not have the flange 11a.

  The sealing cover 32 is different from the sealing cover 12 in that a through hole 32a is formed in the outer flange 12b. A plurality of through holes 32a are formed in a state of being arranged at appropriate intervals along the circumferential direction. A plurality of stud bolts 1b protruding from the side ends of the casing of the static magnetic field magnet unit 1 are inserted into the through holes 32a, respectively. Then, the sealed cover 32 is fixed to the static magnetic field magnet unit 1 by attaching the nut 35 to the stud bolt 1b.

  The holding plate 33 has a disk shape with an opening at the center. The opening diameter of the holding plate 33 is slightly larger than the outer diameter of the bore tube 31, and the bore tube 31 is inserted into the inside thereof. The holding plate 33 is fixed to the hermetic cover 32 by screws 18.

  The anti-vibration member 34 has an opening in the center and has a disk shape having a size that substantially fills the space surrounded by the bore tube 31, the sealing cover 32, and the holding plate 33. The opening diameter of the vibration isolation member 34 is slightly larger than the outer diameter of the bore tube 31, and the bore tube 31 is inserted inside. The vibration isolation member 34 is disposed in a space surrounded by the bore tube 31 and the restraining plate 33 and restrained by the restraining plate 33.

  Even with the structure of the fourth embodiment, the same effects as those of the first embodiment can be obtained.

  Furthermore, according to the fourth embodiment, the bore tube 11 can be attached and detached while the hermetic cover 32 is fixed to the static magnetic field magnet unit 1, and the maintenance work can be simplified.

  Further, in the structure of each of the embodiments so far, the assembly is performed even when the inner diameter of the bore tube 11 and the respective opening diameters of the holding plate 16 and the vibration isolating member 17 do not all match or they all match. If the accuracy is low, unevenness is generated on the wall surface of the space into which the subject 200 is inserted. However, according to the fourth embodiment, such unevenness is not generated.

  This embodiment can be variously modified as follows.

  Instead of the vacuum seals 14 and 21, another known sealing member such as an O-ring may be used.

  Instead of the O-ring 15, another known sealing member may be used.

  The detailed shape and position of each part can be arbitrarily changed.

  The present invention can also be applied to other types of magnetic resonance diagnostic apparatuses such as collecting medical data without performing imaging.

  One structure of the above embodiments may be adopted on the bed side, and another structure of the above embodiments may be adopted on the counter bed side.

  The fixing of the hermetic cover 32 to the static magnetic field magnet unit 1 by the stud bolt 1b and the bolt 35 in the fourth embodiment is performed in order to fix the hermetic covers 12, 20, 25 to the static magnetic field magnet unit 1 in other embodiments. It may be applied.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of components disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.

  DESCRIPTION OF SYMBOLS 1 ... Static magnetic field magnet unit, Stud bolt 1b, 2 ... Gradient magnetic field coil unit, 2a ... Tray slot, 3 ... Gradient magnetic field power supply, 4 ... Bed, 5 ... Bed control part, 6 ... Transmission RF coil, 7 ... Transmission part, 8 ... Receive RF coil, 9 ... Receiver, 10 ... Computer system, 11 ... Bore tube, 11a ... Flange, 12 ... Sealing cover, 12a ... Cylindrical part, 12b ... Outer flange, 12c ... Inner flange, 12d ... Taper, 12e ... groove, 12f ... screw hole, 12g ... rib, 12h ... window, 12i ... screw hole, 13 ... screw, 14 ... vacuum seal, 15 ... O-ring, 16 ... restraining plate, 17 ... vibration isolation member, 18 ... Screw, 19 ... Sealing cap, 20 ... Sealing cover, 20a ... Taper, 20b ... Screw hole, 21 ... Vacuum seal, 22 ... Holding member, 23 ... Screw, 25 ... Sealing cover, 26 ... Vacuum seal 26a ... hollow part, 26b ... hole, 30 ... sealed space, bore tube 31, sealing cover 32, through hole 32a, holding plate 33, vibration isolator 34, bolt 35, 100 ... magnetic resonance imaging apparatus (MRI apparatus), 200 … Subject.

Claims (9)

A static magnetic field generation unit that has an outer shape including at least a first cylindrical portion that internally forms a first space opened at one end, and generates a static magnetic field in the first space;
Gradient magnetic field generation having an outer shape including at least a second cylindrical portion that forms a second space therein, and generating a gradient magnetic field that is disposed in the first space and is added to the static magnetic field Unit,
It has an outer shape including at least a third cylindrical portion that forms a third space for placing a subject therein, and at least a part of the third cylindrical portion is in the second space. The bore tube to be placed;
The outer shape includes at least a fourth cylindrical portion having an outer diameter smaller than the inner diameter of the first space, and the first magnetic field generating unit is located in the first space with respect to the position where the gradient magnetic field generating unit is disposed. A cover that covers at least the fourth cylindrical portion at a position on the end side where the space is opened and covers a region between the static magnetic field generation unit and the bore tube in the opening of the first space. When,
A first sealing member disposed in a gap between the outer surface of the first cylindrical portion and the fourth cylindrical portion to seal the gap;
A magnetic resonance diagnostic apparatus comprising: a second sealing member disposed in a gap between the bore tube and the cover and sealing the gap.   The first sealing member is formed by forming an elastic material in a ring shape having a cross-sectional shape having a V-shaped bent portion, and is arranged with the bent portion facing the inside of the first space. The magnetic resonance diagnostic apparatus according to claim 1, wherein the apparatus is a magnetic resonance diagnostic apparatus.   The said 1st sealing member comprises the ring shape which has a cross-sectional shape with the wedge part which has a pointed end, The said pointed end is arrange | positioned toward the inner side of the said 1st space, It is characterized by the above-mentioned. The magnetic resonance diagnostic apparatus according to 1.   The magnetic resonance diagnostic apparatus according to claim 1, wherein the first sealing member is formed by forming an elastic material in a ring shape having a cross-sectional shape forming a hollow portion.   The magnetic resonance diagnostic apparatus according to claim 4, wherein the first sealing member has at least one hole that opens the hollow portion to either the outside or the inside of the first space.   The magnetic resonance diagnostic apparatus according to claim 1, wherein the cover is in contact with a wall surface of the first cylindrical portion facing the first space in the vicinity of an end of the static magnetic field generation unit. . The cover has a protruding portion that protrudes outward from the fourth cylindrical portion so as to engage with an end surface of the static magnetic field generation unit;
A plurality of members that are attached to the cover so as to protrude in different directions and that support the first sealing member with their sharp ends abutting against the wall surface of the first cylindrical portion facing the first space. The magnetic resonance diagnostic apparatus according to claim 1, further comprising a support member.   2. The magnetic resonance according to claim 1, wherein the cover has an opening that allows the bore tube to be inserted into and removed from the second space to pass in a state of being attached to the static magnetic field generation unit. Diagnostic device. The gradient magnetic field generating unit includes at least one tray slot that accommodates a shim tray capable of holding a plurality of magnetic body pieces,
2. The magnetism according to claim 1, wherein the front cover includes at least one opening that allows the shim tray inserted into and removed from the tray slot to pass in a state of being attached to the static magnetic field generation unit. Resonance diagnostic device.

Images