JP4391227B2 - Magnet apparatus and magnetic resonance imaging apparatus - Google Patents

Description

  The present invention relates to a magnet apparatus and a magnetic resonance imaging apparatus used in an MRI (Magnetic Resonance Imaging) apparatus (commonly referred to as “magnetic resonance imaging apparatus”) used for image diagnosis of a living body.

  In a magnetic resonance imaging apparatus using a magnet apparatus, a cylindrical uniform and a spherical uniform static magnetic field space region are formed between a pair of cryostats according to the shape of a cryostat incorporating a main magnet such as a superconducting coil. In recent years, the facing type, which is excellent in terms of the openness to the subject and the convenience of access to the subject by the diagnostic personnel, is becoming mainstream. In this opposed magnetic resonance imaging apparatus, the strength of the magnetic field in the spherical uniform static magnetic field space region is generally around 6000 to 10000 gauss, and its tolerance is usually several ppm. The size and weight of the opposing magnetic resonance imaging apparatus are, for example, about 3 m in height, about 2 m in maximum depth in the plane, and about 40 tons in weight.

  In the opposed magnetic resonance imaging apparatus as described above, a vertical type in which a pair of cryostats are arranged in a vertical direction is the mainstream, and as an example, for example, Japanese Patent Laid-Open No. 2002-52004 (Patent Document 1). There is a thing of description. Further, as described in Patent Document 1, in the opposing magnetic resonance imaging apparatus, a pair of gradient magnetic fields for making the uniform static magnetic field in the uniform static magnetic field space region an arbitrary gradient magnetic field. A coil is provided. Each of the pair of gradient coils has a weight of around 200 kg and is supplied with a pulse current of several hundred amperes, and vibrates and generates vibration sound during energization.

  As a countermeasure against this vibration, in Patent Document 1, for example, as specifically shown in FIGS. 1 and 2 and the description thereof, a pair of upper and lower vacuum vessels containing a main magnet is provided with the gradient magnetic field coil. The upper gradient magnetic field coil is coupled to a support that penetrates the central hole of the upper vacuum vessel so that vibration is not directly propagated, and the upper support supports a pair of upper and lower vacuum vessels that contain a main magnet. It connects with each upper end of two communicating pipes. Similarly, the lower gradient coil is coupled to a support that passes through the central hole of the lower vacuum vessel, and the lower support is coupled to the lower ends of the two communicating tubes.

Japanese Patent Application Laid-Open No. 2002-52004 (FIGS. 1 and 2 and description thereof)

  In the magnetic resonance imaging apparatus of Patent Document 1, as described above, the upper gradient coil is coupled to a support that passes through the central hole of the upper vacuum vessel, and the upper support includes a main magnet. Coupled to each upper end of two communicating pipes that support a pair of upper and lower vacuum vessels to be incorporated, similarly, the lower gradient coil is coupled to a support that penetrates the central hole of the lower vacuum vessel, Since the lower support is coupled to the lower ends of the two communication pipes, the support is structurally large and can withstand the vibration of the gradient magnetic field coil weighing about 200 kg. Robustness is required, and furthermore, the two communication pipes that support the pair of upper and lower vacuum vessels must be subjected to the weight of the support having a large structure and the vibration of the gradient magnetic field coil weighing about 200 kg. And extremely robust Thus communicating tube is also large, the influence of such leads to a decrease of the open of the diagnostic area around the homogeneous static magnetic field space region occurs.

  The present invention has been made in view of the above-described circumstances, and an object thereof is to suppress the influence of vibration of the gradient magnetic field coil.

The magnet device according to the present invention includes a first cryostat portion containing a first main magnet, a second cryostat portion containing a second main magnet, the first cryostat portion, and the second cryostat portion. A space is formed between the first cryostat portion and the second cryostat portion that secures a space for a uniform static magnetic field generated by the first main magnet and the second main magnet. A connecting column portion, a first gradient coil disposed outside the first cryostat portion corresponding to the first main magnet, and a second main magnet outside the second cryostat portion. correspondingly arranged second gradient coil to the any of the gradient the homogeneous static magnetic field by said first gradient coil, and and the first gradient coil from the leg portion and the leg portion And a arm portion extending in the direction of the serial second gradient coil, the air-tip of the arm portion to the first gradient coil and said second gradient coil
The vibrations of the first gradient coil and the second gradient coil are canceled via the tip portion, and both the first gradient coil and the second gradient coil are connected together. It is provided with a support part to support.

The present invention extends over a first cryostat section containing a first main magnet, a second cryostat section containing a second main magnet, the first cryostat section and the second cryostat section. A connecting column portion that forms a space between the first cryostat portion and the second cryostat portion to ensure a space of a uniform static magnetic field generated by the first main magnet and the second main magnet; A first gradient magnetic field coil disposed corresponding to the first main magnet outside the first cryostat portion, and disposed corresponding to the second main magnet outside the second cryostat portion. set by the second gradient coil to the first gradient coil and by said uniform static magnetic field of any gradient magnetic field, and the leg and from this leg the first gradient coil and said second inclined And a arm portion extending in the direction of the field coil, through the distal tip portion of the arm portion is the coupled in space to the first gradient coil and said second gradient coil Since the vibration of the first gradient magnetic field coil and the second gradient magnetic field coil is canceled , and the first gradient magnetic field coil and the second gradient magnetic field coil are provided together with a support portion, The vibration of the first gradient magnetic field coil and the vibration of the second gradient magnetic field coil are canceled by the support portion, and the influence on each part due to the vibration of the first gradient magnetic field coil and the vibration of the second gradient magnetic field coil. There is an effect that can be suppressed.

Embodiment 1 FIG.
Embodiment 1 of the present invention will be described below with reference to FIGS. FIG. 1 is a plan view showing an example of the configuration of the main part of the entire opposing magnetic resonance imaging apparatus, FIG. 2 is a longitudinal side view of the cross section taken along the line II-II in FIG. 1, and FIG. 2 is a cross-sectional plan view of the cross section taken along line III-III of FIG. 2 in the direction of the arrow, FIG. 4 is a plan view showing the relationship between the gradient coil support and the gradient coil, and FIG. 6 is a front view showing the relationship between the gradient coil support section and the gradient coil, and FIG. 7 is an enlarged view of the gradient coil position adjusting mechanism section of the support section. FIG. 8 is an enlarged plan view, and FIG. 8 is an enlarged side view showing the gradient magnetic field coil position adjusting mechanism portion of the support portion in an enlarged view. In addition, in each figure, the same code | symbol shows the same part.

  First, the overall structure and function of the first embodiment of the present invention will be described.

  1 to 5, the opposing magnetic resonance imaging apparatus includes a first cryostat portion 2 having an annular first main magnet 1 such as a superconducting coil main magnet and having a cylindrical appearance, and a superconducting coil. An annular second main magnet 3 such as a main magnet is built in and extends across the second cryostat portion 4 having a cylindrical appearance, the first cryostat portion 2 and the second cryostat portion 4. The first cryostat portion 2 and the second cryostat portion 4 are configured by a single substantially connecting column portion 5 that connects the cryostat portions 2 and 4 at the outer peripheral portion thereof.

  The first cryostat portion 2 and the second cryostat portion 4 are arranged so that the centers 6 of the annular first and second main magnets 1 and 3 are coaxial as shown in the figure. A predetermined space 7 is held between the opposing surfaces of the two by the connecting column portion 5. Note that a spherical uniform static magnetic field space region 8 necessary for image diagnosis of the subject exists in the space 7. In addition, a subject bed 71 on which the subject is placed is inserted into the space 7 in the direction of arrow a (see FIG. 1) or arrow b (see FIG. 1).

  As is well known, the first cryostat unit 2 includes a vacuum container unit 201 made of nonmagnetic metal, and helium (within the vacuum container unit 201 spaced apart from the wall of the vacuum container unit 201). He) a refrigerant container (not shown) such as a container and a space between the refrigerant container (not shown) and the vacuum container part 201 and spaced from the refrigerant container (not shown) and the vacuum container part 201. It mainly comprises a heat shield (not shown) that blocks radiant heat from the vacuum vessel 201 to the refrigerant container (not shown). The first main magnet 1 is built in the refrigerant container (not shown).

  The vacuum vessel portion 201 includes a nonmagnetic cylindrical portion 2011 having the coaxial 6 as a center line, disc-shaped nonmagnetic end wall portions 2012 and 2013 provided at both ends of the cylindrical portion 2011, and the cylinder. A non-magnetic peripheral wall portion 2014 that surrounds the portion 2011 and extends across the peripheral surfaces of the both end wall portions 2012 and 2013 is formed.

  The end wall portion 2013 on the space 7 side has a bottom wall portion 20131 forming a circular recess 20131 whose center is coaxial with the center of the spherical uniform static magnetic field space region 8 on the space 7 side. And a peripheral wall portion 201312 is provided. That is, in other words, the end wall portion 2013 on the space 7 side has a structure in which the vicinity of the outer peripheral portion protrudes toward the space 7 side, and the peripheral wall portions 2014 and 201312 connected to the protruding circular wall portion 2015 A donut-shaped recess 2016 is formed inside the vacuum vessel 201 by the circular wall portion 2015. In the donut-shaped dent 2016, the first main magnet 1 built in the refrigerant container (not shown) in the vacuum container 201 is disposed.

  In the first cryostat portion 2, an annular first adjusting magnet 91 is provided between the first main magnet 1 and the cylindrical portion 2011 so as to face the bottom wall portion 201311 of the circular recess 20131. It is arranged. In other words, the first adjusting magnet 91 surrounds the cylindrical portion 2011 and is surrounded by the first main magnet 1, and the center line thereof is coaxial with the center line 6. As the first adjustment magnet 91, for example, a superconducting coil built in the refrigerant container (not shown) in the vacuum container 201 is used.

  In the first cryostat portion 2, annular outer field magnetic field canceling magnets 10 and 11 that are coaxial with the coaxial 6 are provided. The outer field magnetic field canceling magnets 10 and 11 include a main magnet built in the refrigerant container (not shown) in the vacuum container part 201 or the inside of the vacuum container part 201 outside the refrigerant container (not shown). The non-main magnet provided in is used. Further, the outer field magnetic field canceling magnet 10 is provided in the vicinity of the peripheral wall portion 2014 of the vacuum vessel part 201, and the outer field magnetic field canceling magnet 11 is provided closer to the cylindrical part 2011 than the outer field magnetic field canceling magnet 10. ing.

  As is well known, the second cryostat unit 4 includes a vacuum container unit 401 made of non-magnetic metal, and helium (within the vacuum container unit 401 spaced apart from the wall of the vacuum container unit 401). He) a refrigerant container (not shown) such as a container, and a space between the refrigerant container (not shown) and the vacuum container part 401 and spaced from the refrigerant container (not shown) and the vacuum container part 401. It mainly comprises a heat shield (not shown) that blocks radiant heat from the vacuum vessel 401 to the refrigerant container (not shown). The second main magnet 3 such as a superconducting coil is built in the refrigerant container (not shown).

  The vacuum vessel portion 401 includes a nonmagnetic cylindrical portion 4011 centering on the coaxial 6, disk-like nonmagnetic end wall portions 4012 and 4013 provided at both ends of the cylindrical portion 4011, and the cylindrical portion The peripheral wall portion 4014 surrounds the portion 4011 and extends between the peripheral surfaces of the both end wall portions 4012 and 4013.

  The end wall portion 4013 on the space 7 side has a bottom wall portion 401311 forming a circular recess 40131 whose center is coaxial with the center of the spherical uniform static magnetic field space region 8 on the space 7 side. And a peripheral wall 401312 is provided. That is, in other words, the end wall portion 4013 on the space 7 side has a shape in which the vicinity of the outer peripheral portion protrudes toward the space 7 side, and the peripheral wall portions 4014 and 401312 connected to the protruding circular wall portion 4015 The circular wall portion 4015 forms a donut-shaped recess 4016 inside the vacuum vessel portion 401. In the donut-shaped recess 4016, the second main magnet 3 built in the refrigerant container (not shown) in the vacuum container 401 is disposed.

  In the second cryostat portion 4, an annular second adjusting magnet 92 is provided between the second main magnet 3 and the cylindrical portion 4011 so as to face the bottom wall portion 401311 of the circular recess 40131. It is arranged. In other words, the second adjustment magnet 92 surrounds the cylindrical portion 4011 and is surrounded by the second main magnet 3, and its center line is coaxial with the center line 6. As the second adjustment magnet 92, for example, a superconducting coil built in the refrigerant container (not shown) in the vacuum container 401 is used.

  In the second cryostat section 4, annular outer field magnetic field canceling magnets 12 and 13 that are coaxial with the coaxial 6 are provided. These outer field magnetic field canceling magnets 12 and 13 include a superconducting coil built in the refrigerant container (not shown) in the vacuum container 401 or the inside of the vacuum container 401 outside the refrigerant container (not shown). The non-main magnet provided in is used. Further, the outer field magnetic field canceling magnet 12 is provided in the vicinity of the peripheral wall portion 4014 of the vacuum vessel section 401, and the outer field magnetic field canceling magnet 13 is provided closer to the cylindrical portion 4011 than the outer field magnetic field canceling magnet 12. ing. In other words, the outer field magnetic field canceling magnet 13 surrounds the cylindrical portion 4011 and is surrounded by the outer field magnetic field canceling magnet 12.

  The connecting column portion 5 includes a nonmagnetic support bone portion 501 and a nonmagnetic outer wall portion 502 in which the support bone portion 501 is built, and is connected between the first and second main magnets 1 and 3. And the load of each part of the first and second cryostat parts 2 and 4.

  The supporting bone portion 501 is composed of a nonmagnetic front strut portion 5011, a nonmagnetic rear strut portion 5012, and nonmagnetic end strut portions 5013 and 5014. The front column 5011, the rear column 5012, and the end columns 5013 and 5014 are integrated by welding or the like. Further, the support bone portion 501 and the outer wall portion 502 are integrated by welding or the like.

  The outer wall 502 includes a nonmagnetic front wall 5021, a nonmagnetic rear wall 5022, nonmagnetic end walls 5023 and 5024, a nonmagnetic upper wall 5025, and a nonmagnetic bottom wall. It consists of 5026. Further, the front wall portion 5021, the rear wall portion 5022, the end wall portions 5023 and 5024, the upper wall portion 5025, and the bottom wall portion 5026 are integrated by welding or the like. Furthermore, the outer wall portion 502 and the supporting bone portion 501 are integrated by welding or the like to form one structure. It is also possible to connect a plurality of connecting pillar portions 5 which are one structure in the circumferential direction of the first and second cryostat portions 2 and 4 so that the plurality of connecting pillar portions serve as one structure. Good. That is, the connecting column portion 5 may be substantially one structure. In this way, when the connecting column part 5 is substantially one structure, the magnetic resonance image is compared with the case where two connecting column parts spaced apart from each other as described in Patent Document 1 are provided. -The freedom degree of arrangement | positioning of the said magnetic resonance imaging apparatus in the room which installs a zing apparatus improves.

  The connecting column portion 5 has a vacuum container whose inside wall 502 is a vacuum, and incorporates a refrigerant communication pipe 18 and a wire insertion pipe 181 (see FIG. 3), which will be described later, and the outer wall section 502. A heat shield 503 (see FIG. 3) for blocking radiant heat from the refrigerant to the refrigerant communication pipe 18 is also incorporated. The upper wall portion 5025 of the connecting column portion 5 is provided with a refrigerator 14 and a non-magnetic refrigerant inlet 15.

  The refrigeration machine 14 is powered by an electric motor and is located above or outside the upper wall portion 5025, and cools the refrigerant in the refrigerant container (not shown) in the vacuum vessel portion 201 to cool the refrigerant. While returning to the inside of the container (not shown) through the communication path 16, the heat shield (not shown) in the vacuum container part 201 is supplied to the temperature of the vacuum container part 201 and the refrigerant container (not shown). It is provided for cooling to a temperature intermediate to the temperature. The refrigerator 14 is disposed at a position higher than the liquid level 20171 of the liquid refrigerant 2017 in the refrigerant container (not shown). Therefore, when the refrigerant in the refrigerant container (not shown) is liquefied helium (He), that is, the first main magnet 1 and the second main magnet 3 in the refrigerant container (not shown) are liquefied helium ( In the case of a main magnet cooled to a very low temperature by He), the refrigerator 14 is liquefied by cooling helium (He) gas in the refrigerant container (not shown) in the vacuum container part 201. Helium (He) enters the communication path 16 by its own weight, and liquefied helium that has entered the communication path 16 returns to the refrigerant container (not shown) by its own weight. The refrigerator 14 has a weight of about 20 kg, and is removed from the upper wall portion 5025 during regular maintenance and inspection.

  The refrigerant inlet 15 is located above or outside the upper wall 5025 and is provided to inject into the refrigerant container (not shown) in the vacuum vessel 201 via the communication passage 17. Yes. When the liquid refrigerant in the refrigerant container (not shown) is liquefied helium (He), that is, when the first main magnet 1 and the second main magnet 3 in the refrigerant container (not shown) are main magnets. Then, liquefied helium (He) is injected from the refrigerant inlet 15 into the refrigerant container (not shown) in the vacuum container 201. The refrigerant inlet 15 is also used when extracting refrigerant gas from the refrigerant container (not shown) in the vacuum container 201.

  The refrigerant container (not shown) in the vacuum vessel part 201 of the first cryostat part 2 and the refrigerant container (not shown) in the vacuum container part 401 of the second cryostat part 4 are in communication with the refrigerant. The liquid refrigerant in the refrigerant container (not shown) of the first cryostat section 2 is communicated via the pipe 18 and into the refrigerant container (not shown) of the second cryostat section 4. 18 is supplied. When the refrigerant is liquefied helium (He), the liquid refrigerant is caused by its own weight from the refrigerant container (not shown) of the first cryostat unit 2 to the refrigerant container (of the second cryostat unit 4). Enter (not shown).

  A disc-shaped shim mounting member 191 is mounted on the bottom wall portion 201311 of the circular recess 20131 of the first cryostat portion 2 on the surface of the spherical uniform static magnetic field space region 8 side. The disk-shaped shim mounting member 191 is disposed coaxially with the center of the spherical uniform static magnetic field space region 8. In addition, a large number of shim mounting holes 1911 (see FIG. 3) are provided on the surface of the shim mounting member 191 on the side of the uniform static magnetic field space region 8, and a necessary one of the many shim mounting holes 1911 is required. A shim (hereinafter referred to as “first shim”) 19111 made of a magnetic piece is detachably screwed into the shim mounting hole at the position.

  Extending in the direction of the center line of the peripheral wall portion 201312 (that is, the center line of the peripheral wall portion 201312) on the inner peripheral surface (the surface on the spherical uniform static magnetic field space region 8 side) of the peripheral wall portion 201312 in the circular recess 20131 A large number of shims (hereinafter referred to as “second shims”) 202 extending in parallel with the peripheral wall portion 201312 are detachably attached to the peripheral wall portion 201312 at necessary intervals over the entire circumference of the peripheral wall portion 201312. It has been.

  A disk-shaped shim mounting member 192 is attached to the bottom wall portion 401311 of the circular recess 40131 of the second cryostat portion 4 on the surface of the spherical uniform static magnetic field space region 8 side. The disk-shaped shim mounting member 192 is disposed coaxially with the center of the spherical uniform static magnetic field space region 8. Further, the shim mounting member 192 has a number of shim mounting holes (not shown) on the surface of the uniform static magnetic field space region 8 side, similarly to the shim mounting member 191 on the first cryostat portion 2 side. As in the shim 19111 on the first cryostat portion 2 side, a shim made of a magnetic piece (hereinafter referred to as “the shim 19111”) is provided in a shim mounting hole at a required position among the plurality of shim mounting holes. (Referred to as “third shim”) (not shown) is detachably screwed.

  Extending in the direction of the center line of the peripheral wall portion 401312 (that is, the center line of the peripheral wall portion 401312) to the inner peripheral surface (the surface on the spherical uniform static magnetic field space region 8 side) of the peripheral wall portion 401312 in the circular recess 40131 A plurality of shims 203 (hereinafter referred to as “fourth shims”) detachably attached to the peripheral wall portion 401312 at necessary intervals over the entire circumference of the peripheral wall portion 401312. It has been.

  In the circular recess 20131 of the first cryostat portion 2, the first gradient magnetic field coil 211 is connected to the shim mounting member 191, the first shim 19111, and the second shim 202 via a predetermined gap g. Is provided. This first gradient magnetic field coil 211 is generally configured by integrating an X-axis gradient magnetic field coil, a Y-axis gradient magnetic field coil, and a Z-axis gradient magnetic field coil with an insulating material, and is adjacent to the bottom wall 201311. The heat shield (not shown) has a shield coil on the bottom wall 201311 side for suppressing an eddy current generated by a magnetic field generated by the X-axis gradient magnetic field coil, the Y-axis gradient magnetic field coil, and the Z-axis gradient magnetic field coil. Sometimes it is.

  The predetermined gap g means that the first gradient magnetic field coil 211 is caused by vibration of the first gradient magnetic field coil 211 that is generated when a pulse current of several hundred amperes is supplied to the first gradient magnetic field coil 211. The gradient magnetic field coil 211 is a gap secured so as not to contact each member such as the shim mounting member 191, the first shim 19111, and the second shim 202 on the first cryostat portion 2 side. .

  In addition, the first gradient coil 211 is formed by the support unit 24 described later in a non-contact manner with the first cryostat unit 2, the second cryostat unit 4, and the connecting column unit 5. Similar to the cryostat portion 4 and the connecting column portion 5, it is supported on the installation floor 22. A support portion 24 described later is attached to a portion between the first cryostat portion 2 and the second cryostat portion 4 of the connecting column portion 5 in a non-contact state with the second cryostat portion 4. It is also possible.

  A first high-frequency coil (also referred to as an RF coil) 231 is disposed on the side of the uniform static magnetic field space region 8 of the first gradient magnetic field coil 211 so as to correspond to the uniform static magnetic field space region 8. .

  The circular recess 40131 of the second cryostat portion 4 has a second inclination through the shim mounting member 192, the third shim (not shown), and the fourth shim 203 with a predetermined gap g. A magnetic field coil 212 is provided. The second gradient magnetic field coil 212 is generally configured by integrating an X-axis gradient magnetic field coil, a Y-axis gradient magnetic field coil, and a Z-axis gradient magnetic field coil with an insulating material, and is adjacent to the bottom wall portion 401311. The thermal shield (not shown) has a shield coil on the bottom wall portion 401311 side for suppressing eddy current generated by the magnetic field generated by the X-axis gradient magnetic field coil, the Y-axis gradient magnetic field coil, and the Z-axis gradient magnetic field coil. Sometimes it is.

  The predetermined gap g means that the second gradient magnetic field coil 212 is caused by vibration of the second gradient magnetic field coil 212 that is generated when a pulse current of several hundred amperes is supplied to the second gradient magnetic field coil 212. The gradient magnetic field coil 212 is ensured not to contact each member such as the shim mounting member 192, the third shim (not shown), the fourth shim 203, etc. on the second cryostat section 4 side. It is a void.

  Further, the second gradient magnetic field coil 212 is connected to the first gradient magnetic field coil 211 by a nonmagnetic support part 24 described later, and the second cryostat part 4 and the connection are connected by the support part 24. Similar to the column part 5, it is supported on the installation floor 22.

  A second high frequency coil (also referred to as an RF coil) 232 is disposed on the second gradient magnetic field coil 212 on the side of the uniform static magnetic field space region 8 so as to correspond to the uniform static magnetic field space region 8. .

  The support portion 24 includes a first side wall portion 241 and a second side wall portion 242 that extend in parallel with a predetermined interval in the circumferential direction of the first second main magnets 1, 3, The side wall portion 241 and the second side wall portion 242 are configured by a rear wall portion 243 that is coupled at the end portion far from the first and second gradient magnetic field coils 211 and 212.

  The first side wall portion 241 includes a first leg portion 2411 placed on the installation floor 22, and the first and second gradient magnetic field coils 211 and 212 from the upper end of the first leg portion 2411. And a first arm portion 2412 extending in the direction. A first auxiliary foot portion 2413 extending along the outer peripheral surface of the second cryostat portion 4 and mounted on the installation floor 22 is integrally attached to the outer surface of the first leg portion 2411. It has been. In addition, the first arm portion 2412 extends in the radial direction of the first and second gradient magnetic field coils 211 and 212 at the distal ends of the first and second gradient magnetic field coils 211 and 212 side. A first connecting portion 2414 is provided. In other words, the first connecting portion 2414 is inclined at a predetermined angle inward from the distal end portion of the first arm portion 2412.

The second side wall portion 242 includes a second leg portion 2421 placed on the installation floor 22, and the first and second gradient magnetic field coils 211, 212 from the upper end of the second leg portion 2421. And a second arm portion 2422 extending in the direction. A second auxiliary foot portion 2423 extending along the outer peripheral surface of the second cryostat portion 4 and placed on the installation floor 22 is integrally attached to the outer surface of the second leg portion 2421. It has been. In addition, the distal ends of the second arm portion 2422 on the first and second gradient magnetic field coils 211 and 212 sides extend in the radial direction of the first and second gradient magnetic field coils 211 and 212. A second connecting portion 2424 is provided. In other words, the second connecting portion 2424 is inclined at a predetermined angle inward from the distal end portion of the second arm portion 2422.

  The first gradient coil 211 is firmly attached to the surface of the first connecting portion 2414 and the second connecting portion 2424 on the first cryostat 2 side by screwing or the like. The second gradient coil 212 is firmly attached to the surface of the first connecting portion 2414 and the second connecting portion 2424 on the second cryostat portion 4 side by screwing or the like. In other words, the first gradient coil 211 and the second gradient coil 212 are connected by the plurality of connecting portions 2414 and 2424 of the support portion 24. That is, the first gradient coil 211 and the second gradient coil 212 are connected by the support portion 24.

  When the first and second gradient magnetic field coils 211 and 212 are energized, the first and second gradient magnetic field coils 211 and 212 are attracted to each other in relation to the direction of the generated magnetic field. Repel each other. Further, the vibrations depending on the pulse currents of the first and second gradient coils 211 and 212 are synchronized. Accordingly, the mutual attraction and repulsion of the first and second gradient coils 211 and 212 are canceled via the first and second connecting portions 2414 and 2424. That is, it is sufficient for the support portion 24 to support the weight of the first and second gradient magnetic field coils 211 and 212 without substantially receiving vibration of the first and second gradient magnetic field coils 211 and 212.

  In addition, the first side wall 241, the first leg 2411, the first arm 2412, the first connection 2414, and the first side wall are provided between the connection pillar 5 and the first side wall 241. A gap G exists over the entire area of the portion 242, the second leg portion 2421, the second arm portion 2422, and the second connecting portion 2424. That is, the first side wall part 241, the first leg part 2411, the first arm part 2412, the first connecting part 2414, the first side wall part 242, the second leg part 2421, The second arm portion 2422, the second connecting portion 2424, and the connecting pillar portion 5 are not in contact with each other. That is, the support portion 24 and the connecting column portion 5 are not in contact with each other.

  Although not clearly shown in the figure, the first side wall part 241, the first leg part 2411, the first arm part 2412, the first connecting part 2414, the first side wall part 242, The second leg portion 2421, the second arm portion 2422, and the second connecting portion 2424 are not in contact with the first and second cryostat portions 2 and 4, respectively. That is, the support portion 24 is not in contact with the first and second cryostat portions 2 and 4. The first arm portion 2412 and the second arm portion 2422 are not in contact with the first and second cryostat portions 2 and 4 and the second arm portion 2412 and the second arm portion 2422 are not in contact with each other. The substantial length of the arm portion 2422 in the direction of the center line 6 of the first and second annular main magnets 1 and 3 is that of the center line 6 between the first and second cryostat portions 2 and 4. It is shorter than the distance in the direction.

  Further, as described above, the first connecting portion 2414 and the second connecting portion 2424 of the support portion 24 extend in the radial direction of the first and second annular main magnets 1 and 3. In other words, since the first connecting portion 2414 and the second connecting portion 2424 are inclined inward as described above, the first connecting portion 2414 and the second connecting portion 2424 are inclined as shown in FIG. The distance W1 between the tip portions of the second connecting portion 2424 is shorter than the distance W2 between the root portions of the first connecting portion 2414 and the second connecting portion 2424.

  Here, the first connecting portion 2414 and the second connecting portion 2424 are not inclined with respect to the first arm portion 2412 and the second arm portion 2422 as shown by a one-dot chain line in FIG. The first gradient magnetic field coil 211 and the second gradient magnetic field coil 212 can be supported even if they extend in the shape of a circle, but in the space D indicated by the alternate long and short dashed line in FIG. As described above, the first connecting portion 2414 and the second connecting portion 2424 extend in the radial direction of the first and second annular main magnets 1 and 3 as described above. In other words, if the first connecting portion 2414 and the second connecting portion 2424 are tilted inward, the space indicated by hatching of the alternate long and short dash line becomes a space that can be accessed by the diagnostic personnel, Inclined from the first arm portion 2412 and the second arm portion 2422 as shown by a dashed line in FIG. The openness is improved as compared with the case where the straight line is extended.

  The support 24 adjusts the positions of the first gradient magnetic field coil 211 and the second gradient magnetic field coil 212 to predetermined positions via the first connection part 2414 and the second connection part 2424. , Has a mechanism part to set. The specific structure will be described with reference to FIGS.

  The first gradient magnetic field coil 211 and the second gradient magnetic field coil 212 are arranged in the radial direction of the first and second main magnets 1, 3, that is, the arrow X direction and the arrow Y direction in FIG. It is necessary to adjust and set the position to a predetermined position in the direction of the center line 6 of the first and second main magnets 1 and 3, that is, in the direction of arrow Z in FIG.

  This adjustment and setting are particularly performed between the first gradient magnetic field coil 211 and the first cryostat unit 2 and between the second gradient coil 212 and the second cryostat unit 4. In other words, the first gradient magnetic field coil 211 and the second gradient magnetic field coil 212 are connected to the first cryostat unit 2 side and the second gradient magnetic field coil 212, respectively. In the case of a magnet device having a structure arranged to float from the cryostat unit 4 side, the first gradient coil 211 and the second gradient coil 212 are connected to the first cryostat unit 2 side and the second gradient coil 212. Physical positioning elements of the first gradient coil 211 and the second gradient coil 212, such as a magnet device fixed to the cryostat unit 4 side, are It is important for not one of the cryostat part 2 side and the second cryostat section 4 side.

  In Embodiment 1 of the present invention, as shown in FIGS. 7 and 8, the first gradient coil 211 and the second gradient coil 212 are individually connected to the arrows X, Y, Z. The first connection is made in the direction opposite to the first gradient magnetic field coil 211 and the second gradient magnetic field coil 212, that is, in the direction of the center line 6, so that the position can be adjusted and set to a predetermined position in the direction of The connecting portion 2414a and 2424a for the first gradient coil 211 and the connecting portion 2414b for the second gradient coil 212, which are movable separately by dividing the portion 2414 and the second connecting portion 2424 into two parts (in the drawing) (Not shown in the figure), 2424b is provided.

  Similarly, the first arm portion 2412 and the second arm portion 2422 are arranged in the direction opposite to the first gradient magnetic field coil 211 and the second gradient magnetic field coil 212, that is, in the direction of the center line 6. Arm portions 2412a and 2422a for the first gradient magnetic field coil 211 and arm portions 2412b (not shown in the figure) and 2422b for the second gradient magnetic field coil 212, which are divided and individually movable, are provided. is there.

  Further, the individually movable connecting portions 2414a and 2424a for the first gradient coil 211 and the connecting portions 2414b and 2424b for the second gradient coil 212 and the individually movable first portions. The arm portions 2412a and 2422a for the gradient magnetic field coil 211 and the arm portions 2412b and 2422b for the second gradient magnetic field coil 212 are in the directions of the illustrated arrows x, y, and z in the same direction as the arrows X, Y, and Z. Each of the adjustment arm and the first and second legs 2411 and 2421 can be moved while being guided, as shown in the drawing through holes 244111 and 244121 (not shown in the figure), 244211, 244221, 245111, 245121 (not shown in the figure), 245211, 245221, 246111, 246121 (not shown in the figure), 246211, 246221 are provided. Adjusted fixing bolts 24411, 24421, 24511, 24521, 2461 penetrated through 1,24621 are provided.

  The individually movable connecting portions 2414a and 2424a for the first gradient coil 211 and the connecting portions 2414b and 2424b for the second gradient coil 212 and the individually movable first gradient magnetic field. Arms 2412a and 2422a for the coil 211 and arms 2412b and 2422b for the second gradient magnetic field coil 212, through long holes 244111, 244121, 244211, 244221, 245111, 245121, 245211, 245221, 246111, 246121, 262111, The adjustment mechanism 25 is configured by 246221 and post-adjustment fixing bolts 24411, 24421, 24511, 24521, 24611, 24621.

  Since the adjustment mechanism section 25 configured as described above is provided in the support section 24, the first gradient coil 211 mounted on the connecting sections 2414a and 2424a for the first gradient coil 211 and The second gradient coil 212 mounted on the connecting portions 2414b, 2424b for the second gradient coil 212 is adjusted, set to a predetermined length of the opposing distance in the arrow Z direction between them, and The center X of the first and second main magnets 1 and 3 at the center thereof, and the position adjustment and setting in the directions of the arrows X and Y to be coaxial with the center 6 can be accurately performed. After finishing the adjustments, the first and second gradient magnetic field coils 211 and 212 can be firmly fixed to the support portion 24 by the post-adjustment fixing bolts 24411, 24421, 24511, 24521, 24611, and 24621. Realizing the formation of the desired gradient magnetic field wear.

  Next, functions of the magnets and coils other than the first and second gradient magnetic field coils 211 and 212 described above, and relative functions of the magnets, coils, and shims will be described.

  The first main magnet 1 on the first cryostat portion 2 side and the second main magnet 3 on the second cryostat portion 4 side are both in the spherical uniform static magnetic field space region 8 and the vicinity thereof. A uniform static magnetic field is generated from the first cryostat unit 2 toward the second cryostat unit 4 as shown by the arrows in the figure.

  The first adjustment magnet 9 on the first cryostat portion 2 side, the second adjustment magnet 10 on the second cryostat portion 4 side, and the shim attachment member 191 on the first cryostat portion 2 side are attached. A first shim 19111 (see FIG. 3), a third shim (not shown) attached to the shim mounting member 192 on the second cryostat 4 side, and the first shim 19111 on the first cryostat 2 side. The second shim 202 and the fourth shim 203 on the second cryostat section 4 side thereby cause the first main magnet 1 and the second main magnet in the spherical uniform static magnetic field space region 8 to be the same. 3 to increase the uniformity of the uniform static magnetic field up to several ppm of the allowable error.

  The outer field magnetic field canceling magnets 10 and 11 on the first cryostat section 2 side and the outer field magnetic field canceling magnets 12 and 13 on the second cryostat section 4 side are arranged above the connecting column section 5 (the refrigerator 14). Of the first main magnet 1 and the second main magnet 3 in the parts A, B, C, D of the connecting column part 5 and the side far from the spherical uniform static magnetic field space region 8. Magnetic field in the direction to cancel the outer field magnetic field (the magnetic field indicated by the dotted arrow 131O in FIG. 2) (the magnetic field indicated by the one-dot chain line 1113 in the opposite direction to the dotted arrow in FIG. 2 (the magnetic field in the direction opposite to the outer magnetic field)) ) And the external magnetic field of the first main magnet 1 and the second main magnet 3 in the respective parts A, B, C, D of the connecting column part 5 (the magnetic field indicated by the dotted arrows in FIG. 2) ) Strength of the motor of the refrigerator 14 It is intended to suppress to a strength that does not cause a reduction or mitigation.

  In addition, each part A, B, C, D of the said connection pillar part 5 is on the projection surface which looked at the said connection pillar part 5 in the said extension direction (the direction of arrow C), ie, the said of the said connection pillar part 5. It exists on the projection surface in the extending direction.

  In addition, since the outer field magnetic field canceling magnets 10 to 13 are provided, the strength of the magnetic field by the first main magnet 1 and the second main magnet 3 in the spherical uniform static magnetic field space region 8 is slightly reduced. The strength of the magnetic field applied to the first main magnet 1 and the second main magnet 3 is larger than that in the case where the outer field magnetic field canceling magnets 10 to 13 are not provided, and the magnetic field in the spherical uniform static magnetic field space region 8 is increased. The strength of the magnetic field is set to a predetermined strength.

  Further, in the connecting column part 5, both the supporting bone part 501 and the outer wall part 502 are non-magnetic. However, when at least one of the supporting bone part 501 and the outer wall part 502 is made magnetic, the magnetic property is reduced. Since the magnetic field generated by the first main magnet 1 and the second main magnet 3 is concentrated on at least one of the supporting bone portion 501 and the outer wall portion 502 of the first and second support bone portions 501 and the outer wall portion 502, the so-called connecting columns such as the respective portions A, B, C, D, etc. Since the magnetic field on the projection surface in the extending direction of the part 5 becomes stronger, in this case, the outer field magnetic field canceling magnet that generates a magnetic field in a direction that cancels the outer field magnetic field of the first and second main magnets 1 and 3. The generated magnetic fields of 10, 11, 12, and 13 need to be increased as compared to the case where both the support bone portion 501 and the outer wall portion 502 are non-magnetic, and accordingly, the first main magnet 1 and Magnetism by the second main magnet 3 It is necessary to make the strength more strongly to the strength of the magnetic field at the spherical homogeneous static magnetic field space region 8 to a predetermined strength.

  Note that energization of the coils 3, 12, 13, 92 in the second cryostat section 4 is performed by the electric wires in the wire insertion pipe 181 (see FIG. 3) built in the connecting column section 5. (Not shown).

  In the embodiment of the present invention, as described above, the first cryostat portion 2 containing the first main magnet 1, the second cryostat portion 4 containing the second main magnet 3, and the first A space 7 that extends across the cryostat portion 2 and the second cryostat portion 4 and secures a space 8 of a uniform static magnetic field generated by the first main magnet 1 and the second main magnet 3. A connecting column portion 5 formed between one cryostat portion 2 and the second cryostat portion 4, and disposed outside the first cryostat portion 2 so as to correspond to the first main magnet 1. The first gradient magnetic field coil 211 and the first gradient magnetic field coil 211 arranged in correspondence with the second main magnet 3 outside the second cryostat unit 4 can be used to arbitrarily generate the uniform static magnetic field. The second gradient field The gradient magnetic field coil 212, the first gradient magnetic field coil 211, and the second gradient magnetic field coil 212 are connected in the space 7 to connect the first gradient magnetic field coil 211 and the second gradient magnetic field coil 212. Since both the first and second gradient magnetic field coils 211 and 212 are canceled by the support portion 24, the first and second gradient magnetic field coils 211 and 212 are canceled by the support portion 24. In addition, the influence and vibration noise on the first and second cryostat units 2 and 4 due to the vibration of the second gradient magnetic field coils 211 and 212 can be remarkably suppressed. It is sufficient to support the weights of the first and second gradient magnetic field coils 211 and 212 with almost no vibration of the second gradient magnetic field coils 211 and 212, and it is necessary to provide a large-scale solid support portion. There.

  Furthermore, in the embodiment of the present invention, as described above, the first gradient magnetic field coil 211, the second gradient magnetic field coil 212, and the support part 24 are all the first cryostat part 2. And the second cryostat section 4 is not in contact with the first and second cryostat sections 2 and 4, so that the vibration of the first and second gradient magnetic field coils 211 and 212 is propagated to the first and second cryostat sections 2 and 4. Nearly nothing.

  Further, in the embodiment of the present invention, as described above, since the support portion 24 is disposed in the vicinity of the connection column portion 5 and separated from the connection column portion 5, the connection column portion. 5 does not substantially reduce the openness of the space 7 between the first cryostat portion 2 and the second cryostat portion 4, and the first and second inclinations via the connecting column portion 5. The vibration of the magnetic field coils 211 and 212 is not propagated to the first and second cryostat units 2 and 4.

  Further, in the embodiment of the present invention, as described above, the support portion 24 has the first and second main magnets 1 and 3 from both sides in the circumferential direction of the first and second main magnets 1 and 3 of the connecting column portion 5. The main magnets 1 and 3 have a plurality of support arm portions 2414 and 2424 extending in the radial direction, and the plurality of support arm portions 2414 and 2424 have the first gradient coil 211 and the second gradient magnetic field. Since the magnetic field coil 212 is supported, the openability of the space 7 between the first cryostat unit 2 and the second cryostat unit 4 is improved as compared with the case where the support arm portions 2414 and 2424 are not provided. To do.

  In the embodiment of the present invention, as described above, the support 24 adjusts the distance between the first gradient coil 211 and the second gradient coil 212 to a predetermined length. Since the adjusting mechanism 25 to be set is provided, the first and second gradient magnetic field coils 211 and 212 are adjusted to the predetermined length of the facing distance between them, the setting, and the first and Position adjustment, setting, etc. to a predetermined position to be coaxial with the center 6 of the second main magnets 1 and 3 can be performed accurately.

Embodiment 2. FIG.
Hereinafter, the second embodiment of the present invention will be mainly described with reference to FIG. 9 with respect to differences from the above-described first embodiment of the present invention, and other descriptions will be omitted. FIG. 9 is a plan view showing another example of the relationship between the connecting column portion 5 and the support portion 24. In FIG. 9, the same or corresponding parts as those in FIGS.

  In the second embodiment of the present invention, as shown in FIG. 9, the wall surface 50211 near the first and second main magnets 1 and 3 of the connecting column portion 5 is replaced by the first connecting portion 2414 and the first connecting portion. The position of the wall surface 50211 in the first embodiment of the present invention shown in the dashed line in FIG. 9 is arranged on the same circular arc centering on the center line 6 and each tip surface of the two connecting portions 2424 As compared with the above, the support effective area of the connecting column part 5 is increased by the hatched area of the one-dot chain line by the amount of the wall surface 50211 closer to the center line 6, so that the supporting ability of the connecting column part 5 is improved. Further, the first and second main magnets 1, 3 of the first connecting portion 2414, the second connecting portion 2424 and the connecting column portion 5 as in the first embodiment of the present invention described above are used. The unevenness in the radial direction is eliminated, and the subject's fear does not occur.

Embodiment 3 FIG.
Hereinafter, the third embodiment of the present invention will be described mainly with respect to differences from the first and second embodiments of the present invention described above with reference to FIG. 10, and the other description will be omitted. FIG. 10 is a plan view showing another example of the relationship between the connecting column portion 5 and the support portion 24. In FIG. 10, parts that are the same as or correspond to those in FIGS. 1 to 9 are given the same reference numerals.

  In the second embodiment of the present invention, as shown in FIG. 10, a bridge connecting portion 24124 that is curved along the outer periphery of the first and second gradient magnetic field coils 211 and 212 is replaced with the first connecting portion 2414. And the second connecting portion 2424, the first and second gradient coils 211 and 212 are connected to the first and second connecting portions 2414 and 2424 and the bridge connecting portion. Since the first gradient magnetic field coil 211 and the second gradient magnetic field coil 212 are connected to each other by the 24124, the first gradient magnetic field coil 211 and the second gradient magnetic field coil 212 are connected to each other. As a result, the vibration of the first and second gradient coils 211 and 212 can be further suppressed as compared with the first and second embodiments of the present invention.

  In addition, the bridge connecting portion 24124 exhibits the vibration suppressing function even if it is linear as shown by a one-dot chain line in FIG. 10, but as shown by the solid line, when it has a curved shape as described above In this case, the area indicated by the one-dot chain line hatching becomes a space, and the aforementioned openness is improved.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows Embodiment 1 of this invention, and is a top view which shows an example of a structure of the principal part of the whole opposing magnetic resonance imaging apparatus. It is a figure which shows Embodiment 1 of this invention, and is the vertical side view which looked at the cross section in the II-II line | wire of FIG. 1 in the arrow direction. It is a figure which shows Embodiment 1 of this invention, and is the cross-sectional plan view which looked at the cross section in the III-III line of FIG. 2 in the arrow direction. It is a figure which shows Embodiment 1 of this invention, and is a top view which shows the relationship between the support part of a gradient magnetic field coil, and a gradient magnetic field coil. It is a figure which shows Embodiment 1 of this invention, and is a side view which shows the relationship between the support part of a gradient magnetic field coil, and a gradient magnetic field coil. It is a figure which shows Embodiment 1 of this invention, and is a front view which shows the relationship between the support part of a gradient magnetic field coil, and a gradient magnetic field coil. It is a figure which shows Embodiment 1 of this invention, and is an enlarged plan view which shows the gradient magnetic field coil position adjustment mechanism part of a support part with an enlarged view. It is a figure which shows Embodiment 1 of this invention, and is an enlarged side view which shows the gradient magnetic field coil position adjustment mechanism part of a support part with an enlarged view. It is a figure which shows Embodiment 2 of this invention, and is a top view which shows the other example of the relationship between a connection pillar part and a support part. It is a figure which shows Embodiment 3 of this invention, and is a top view which shows the other example of the relationship between a connection pillar part and a support part.

Explanation of symbols

1 first main magnet,
2 First cryostat section,
201 vacuum vessel,
2011 Cylindrical part,
2012 end wall,
2013 end wall,
20131 circular dent,
201311 Bottom wall,
201312 Perimeter wall,
2014 end wall,
2015 round wall,
2016 donut shaped dent,
2017 Liquid refrigerant,
20171 Liquid refrigerant level,
3 Second main magnet,
4 Second cryostat section,
401 vacuum vessel,
4011 cylindrical part,
4012 end wall,
4013 end wall,
40131 circular dent,
401311 bottom wall,
401312 perimeter wall,
4014 perimeter wall,
4015 circular wall,
4016 donut shaped dent,
5 connecting pillars,
501 support bone,
5011 front strut,
5012 rear strut,
5013 end struts,
5014 end struts,
50151 inclined part,
50161 slope,
50152 curved part,
50162 curved part,
502 outer wall,
5021 Front wall,
50211 wall surface,
5022 rear wall,
5023 end wall,
5024 end wall,
5025 Upper wall,
5026 bottom wall,
50271 slope,
50272 songs,
50273 songs,
50274 curved part,
50281 inclined part,
50282 songs,
50283 songs,
50284 bend,
503 heat shield,
6 Center (center line),
7 space,
71 Patient bed,
8 uniform static magnetic field space region,
91 first adjusting magnet,
92 second adjusting magnet,
10 outer field magnetic field canceling magnet,
11 Outer magnetic field canceling magnet,
12 outer field magnetic field canceling magnet,
13 Outer magnetic field canceling magnet,
14 refrigerator,
15 refrigerant inlet,
16 passages,
17 Communication path,
18 Refrigerant communication pipe,
181 Electric wire insertion tube,
191 shim mounting members,
1911 Shim mounting holes
19111 The first shim,
192 shim mounting members,
202 second shim,
203 4th shim,
211 a first gradient coil;
212 second gradient coil,
22 Installation floor,
231 a first high frequency coil;
232 second high frequency coil,
24 support part,
241 first side wall,
2411 first leg,
2412 first arm,
2412a Arm for the first gradient coil 211,
2412b arm for the second gradient coil 212,
24124 Bridge connection,
2413 first auxiliary foot,
2414 the first connection,
2414a connection for the first gradient coil 211,
2414b connection for the second gradient coil 212;
242 second side wall,
2421 Second leg,
2422 Second arm,
2422a arm for the first gradient coil 211,
2422b, an arm for the second gradient coil 212,
2423 second auxiliary foot,
2424 second connection,
2424a connection for the first gradient coil 211,
2424b connection for second gradient coil 212,
243 Rear wall,
24411 Fixing bolt after adjustment,
244111 Through long hole,
24421 Fixing bolt after adjustment,
244211 through hole,
244221 Through long hole,
24511 Fixing bolt after adjustment,
245111 through long holes,
24521 Fixing bolt after adjustment,
245211 through hole,
245221 through slot,
24611 Fixing bolt after adjustment,
246111 through-hole,
2462 Fixing bolt after adjustment,
246211 Through-hole,
246221 through hole,
25 adjustment mechanism,
D space,
Ho space,
F Space.

Claims (6)

A first cryostat unit containing the first main magnet;
A second cryostat section containing a second main magnet;
The first cryostat has a space that extends across the first cryostat portion and the second cryostat portion and secures a space for a uniform static magnetic field generated by the first main magnet and the second main magnet. Connecting column part formed between the part and the second cryostat part,
A first gradient coil disposed outside the first cryostat portion in correspondence with the first main magnet;
A second gradient magnetic field coil arranged outside the second cryostat portion corresponding to the second main magnet and having the uniform static magnetic field as an arbitrary gradient magnetic field by the first gradient magnetic field coil; and
A leg portion and an arm portion extending from the leg portion in the direction of the first gradient magnetic field coil and the second gradient magnetic field coil, and a tip portion of the arm portion includes the first gradient magnetic field coil and The first gradient magnetic field coil is coupled to the second gradient magnetic field coil in the space, and vibrations of the first gradient magnetic field coil and the second gradient magnetic field coil are canceled via the tip, and the first gradient magnetic field coil And the magnet apparatus provided with the support part which supports the said 2nd gradient magnetic field coil together.   2. The magnet device according to claim 1, wherein each of the first gradient magnetic field coil, the second gradient magnetic field coil, and the support portion is any of the first cryostat portion and the second cryostat portion. Magnet device characterized by being non-contact.   The magnet device according to claim 1, wherein the support portion is disposed in the vicinity of the connecting column portion and spaced apart from the connecting column portion. A first cryostat unit containing the first main magnet;
A second cryostat section containing a second main magnet;
A space extending across the first cryostat portion and the second cryostat portion to secure a space for a uniform static magnetic field generated by the first main magnet and the second main magnet
A connecting pillar portion formed between the first cryostat portion and the second cryostat portion;
A first gradient coil disposed outside the first cryostat portion in correspondence with the first main magnet;
A second gradient magnetic field coil arranged outside the second cryostat portion corresponding to the second main magnet and having the uniform static magnetic field as an arbitrary gradient magnetic field by the first gradient magnetic field coil; and
A magnet apparatus comprising a support unit that connects the first gradient magnetic field coil and the second gradient magnetic field coil and supports the first gradient magnetic field coil and the second gradient magnetic field coil together,
The support portion is disposed in the vicinity of the connection column portion and spaced from the connection column portion,
The support portion has a plurality of support arm portions extending in the radial direction of the first and second main magnets from both sides in the circumferential direction of the first and second main magnets of the connecting column portion, A plurality of support arm portions support the first gradient magnetic field coil and the second gradient magnetic field coil. A first cryostat unit containing the first main magnet;
A second cryostat section containing a second main magnet;
The first cryostat has a space that extends across the first cryostat portion and the second cryostat portion and secures a space for a uniform static magnetic field generated by the first main magnet and the second main magnet. Connecting column part formed between the part and the second cryostat part,
A first gradient coil disposed outside the first cryostat portion in correspondence with the first main magnet;
A second gradient magnetic field coil arranged outside the second cryostat portion corresponding to the second main magnet and having the uniform static magnetic field as an arbitrary gradient magnetic field by the first gradient magnetic field coil; and
A magnet apparatus comprising a support unit that connects the first gradient magnetic field coil and the second gradient magnetic field coil and supports the first gradient magnetic field coil and the second gradient magnetic field coil together,
The magnet device, wherein the support unit includes an adjustment mechanism unit that adjusts a distance between the first gradient magnetic field coil and the second gradient magnetic field coil.   A magnetic resonance imaging apparatus comprising the magnet apparatus according to claim 1.

Images