JP4231914B2 - Medical imaging device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a medical imaging apparatus, and more particularly to a medical imaging apparatus that can reduce the impedance of a ground circuit.
[0002]
[Prior art]
FIG. 9 shows an example of a conventional MRI (Magnetic Resonance Imaging) apparatus. The MRI apparatus 600 includes a shield room SR surrounded by a magnetic shield material s and an interior material i, a magnet M installed in the shield room SR, and a subject placed in the shield room SR. The table T that moves the subject to the magnetic field space inside the magnet M, the shield room power supply P that is installed in the shield chamber SR and supplies power to the table T, and the like, and is installed outside the shield chamber SR. An operator console OC for displaying an image photographed by the magnet M, a centralized power supply IPS that is installed outside the shield room SR and supplies power to the magnet M and the operator console OC, and a gradient current to the magnet M And a gradient power supply GPS.
[0003]
The operator console OC is grounded to the ground terminal of the centralized power supply IPS by a ground cable 61, and the gradient power supply GPS is grounded to the ground terminal of the centralized power supply IPS by a ground cable 63.
The table T is grounded to the ground terminal of the magnet M by a ground cable 65, and the shielded room power source P is grounded to the ground terminal of the magnet M by a ground cable 67.
Further, the ground terminal of the magnet M is grounded to the ground terminal of the centralized power supply IPS by ground cables 68 and 69.
The ground cable 68 in the shield chamber SR and the ground cable 69 outside the shield chamber SR are connected via a through plate PP.
[0004]
In addition, FL is an installation floor and f is a flooring.
[0005]
[Problems to be solved by the invention]
FIG. 10 shows a ground circuit in the conventional MRI apparatus 600.
Z61 is the impedance of the ground cable 61, Z63 is the impedance of the ground cable 63, Z65 is the impedance of the ground cable 65, Z67 is the impedance of the ground cable 67, Z68 is the impedance of the ground cable 68, Z69 is the impedance of the ground cable 69.
[0006]
When the penetrating plate PP is set to the shield room reference potential, Z68 becomes a common impedance of the magnet M, the table T, and the shield room power supply P. If the ground cable 68 has a DC resistance value of 0.947 Ω / km and a length of 20 m, Z68 is 19 mΩ.
[0007]
Further, when the ground terminal of the concentrated power supply IPS is set to the system reference potential, (Z68 + Z69) is a common impedance for the magnet M, the table T, and the shielded room power supply P. If the ground cable 68 has a DC resistance value of 0.947 Ω / km and a length of 20 m, Z68 is 19 mΩ. If the ground cable 69 has a DC resistance value of 0.947 Ω / km and a length of 20 m, Z69 will be 19 mΩ. Therefore, the common impedance is 38 mΩ. If the ground cable 65 has a DC resistance value of 0.947 Ω / km and a length of 5 m, the impedance (Z65 + Z68 + Z69) from the table T to the ground terminal of the centralized power supply IPS is 43 mΩ.
[0008]
Further, in the ground cables 61, 63, 65, 67, 68 and 69, the impedance in the high frequency band is increased due to the skin effect.
[0009]
As described above, in the conventional MRI apparatus 600, since the ground cables 61, 63, 65, 67, 68 and 69 become longer due to routing, the impedance of the ground circuit is large both in terms of direct current and high frequency. Therefore, there is a problem that this causes deterioration in image quality and generation of noise.
Therefore, an object of the present invention is to provide a medical imaging apparatus that can reduce the impedance of a ground circuit.
[0010]
[Means for Solving the Problems]
In a first aspect, the present invention provides an imaging unit that images a subject, a display unit that displays an image captured by the imaging unit, and a power source unit that supplies power to the imaging unit and the display unit. A medical imaging apparatus installed as a separate body, wherein a grounding plate extending to the immediate vicinity of the imaging means, the display means, and the power supply means is installed, and the imaging means, the display means, and the power supply means are installed in the immediate vicinity. Provided is a medical imaging apparatus that is grounded to the ground plate.
In the medical imaging apparatus according to the first aspect, a ground plate extending to the immediate vicinity of the imaging means, the display means, and the power supply means is installed. The conventional grounding cable is a wire and becomes long due to routing, and is greatly affected by the skin effect. On the other hand, the grounding plate of the present invention is a surface, does not lead, and can connect the photographing means, the display means, and the power supply means in the shortest time. Moreover, the influence of the skin effect is small. Therefore, the impedance of the ground circuit can be reduced, and degradation of image quality and noise generation can be prevented.
[0011]
In a second aspect, the present invention relates to a shield room surrounded by a conductive shield material, an imaging unit installed in the shield room for imaging a subject, and an imaging unit installed outside the shield room. A medical imaging apparatus comprising: display means for displaying an image; and power supply means installed outside the shield room and supplying power to the imaging means and the display means, wherein the shield room, the display means, and the power supply means A grounding plate extending to the nearest side, the photographing means is grounded to the shielding material in the immediate vicinity thereof, and the shielding material, the display means and the power source means are grounded to the grounding plate in the immediate vicinity thereof. A medical imaging apparatus is provided.
In the medical imaging apparatus according to the second aspect, the ground plate extending to the immediate vicinity of the shield room, the display means, and the power supply means is installed. The conventional grounding cable is a wire and becomes long due to routing, and is greatly affected by the skin effect. On the other hand, the grounding plate of the present invention is a surface, does not lead, and can connect the shield room, the display means, and the power supply means in the shortest time. Moreover, the influence of the skin effect is small. Therefore, the impedance of the ground circuit can be reduced, and degradation of image quality and noise generation can be prevented. Furthermore, since the shield material is used, the size of the ground plate can be reduced.
[0012]
In a third aspect, the present invention is a medical imaging apparatus comprising: a shield room surrounded by a conductive shield material; and an imaging unit that is installed in the shield chamber and images a subject. The medical imaging apparatus is characterized in that is grounded to the shield material in the immediate vicinity thereof.
In the medical imaging apparatus of the third aspect, the imaging means is grounded using a shield material. The conventional grounding cable is a wire and becomes long due to routing, and is greatly affected by the skin effect. On the other hand, the shield material is a surface, and is not routed, so that the photographing means can be grounded in the shortest time. Moreover, the influence of the skin effect is small. Therefore, the impedance of the ground circuit can be reduced, and degradation of image quality and noise generation can be prevented. Furthermore, since a shield material is used, a ground cable is not necessary.
[0013]
In a fourth aspect, the present invention provides a medical imaging apparatus including a shield room surrounded by a shield material and an imaging unit that is installed in the shield room and images a subject. And a medical imaging apparatus characterized in that the imaging means is grounded to the grounding plate in the immediate vicinity thereof.
In the medical imaging apparatus according to the fourth aspect, a ground plate is laid in the shield room. The conventional grounding cable is a wire and becomes long due to routing, and is greatly affected by the skin effect. On the other hand, the grounding plate is a surface and does not lead, so that the photographing means can be grounded in the shortest time. Moreover, the influence of the skin effect is small. Therefore, the impedance of the ground circuit can be reduced, and degradation of image quality and noise generation can be prevented. Furthermore, the shield material may be non-conductive.
[0014]
The medical imaging apparatus according to the present invention includes an MRI apparatus, a CT apparatus, and an X-ray imaging apparatus.
The shielding material according to the present invention is a material capable of shielding one or more of magnetism, X-rays, radio waves, static electricity, and the like, and includes silicon steel plate and lead.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described in more detail with reference to embodiments shown in the drawings. Note that the present invention is not limited thereby.
[0016]
-First embodiment-
FIG. 1 is a block diagram showing an MRI apparatus according to the first embodiment of the present invention. The MRI apparatus 100 includes a shield room SR surrounded by a silicon steel shield material s and an interior material i, a magnet M installed in the shield room SR, and a subject installed in the shield room SR. A table T on which the subject is moved to the magnetic field space inside the magnet M, a shield room power supply P that is installed in the shield room SR and supplies power to the table T, and the like, and is installed outside the shield room SR. An operator console OC for displaying an image photographed by the magnet M, a centralized power supply IPS that is installed outside the shield room SR and supplies power to the magnet M and the operator console OC, and a gradient current to the magnet M A gradient power supply GPS is provided.
[0017]
Between the installation floor FL and the floor material f, a grounding plate 10 made of brass is laid extending to the bottoms of the shield room SR, the concentrated power source IPS, the gradient power source GPS, and the operator console OC.
[0018]
The operator console OC is grounded to the ground plate 10 by the ground wire 1 in the immediate vicinity, the concentrated power source IPS is grounded to the ground plate 10 by the ground wire 2 in the immediate vicinity, and the gradient power source GPS is in the immediate vicinity. The ground wire 3 is grounded to the ground plate 10.
The shield chamber 4 is grounded to the ground plate 10 by the ground wire 4 in the immediate vicinity thereof, the table T is grounded to the ground plate 10 by the ground wire 5 in the immediate vicinity, and the magnet M is proximate to the ground wire 10. 6 is grounded to the grounding plate 10, and the shield room power supply P is grounded to the grounding plate 10 by a grounding wire 7 in the immediate vicinity thereof.
[0019]
As shown in FIG. 2, the ground lines 1 to 7 are fixed to the ground plate 10 by screws 1 a to 7 a.
In addition, as shown in FIG. 3, you may use the earthing | grounding metal fittings 1b-7b, the screws 1c-7c, and the studs 1d-7d instead of the grounding wires 1-7 and the screws 1a-7a.
[0020]
When the volume resistivity of the ground plate 10 is 6.8 × 10 ⁻⁸ Ωm, the thickness is 6 mm, the current path width is 10 mm, and the current path length from the table T to the centralized power supply IPS is 7 m, the ground plate 10 is concentrated from the table T. The impedance of the ground circuit to the power supply IPS is 7.9 mΩ (= 6.8 × 10 ⁻⁸ Ωm × 7 m ÷ 6 mm ÷ 10 mm).
[0021]
According to the MRI apparatus 100 according to the first embodiment, the ground plate 10 is a surface, and there is no routing, and the ground circuit can be minimized. Moreover, the influence of the skin effect is small. Therefore, the impedance of the ground circuit can be reduced, and degradation of image quality and noise generation can be prevented.
[0022]
The ground plate 10 may be laid only on necessary portions of the bottoms of the shield room SR, the concentrated power supply IPS, the gradient power supply GPS, and the operator console OC, or may be laid on the entire surface of the installation floor FL. May be. Further, the grounding plate 10 may be laid on a wall or ceiling instead of or in addition to the installation floor FL.
[0023]
-Second Embodiment-
FIG. 4 is a block diagram showing an MRI apparatus according to the second embodiment of the present invention. The MRI apparatus 200 includes a shield room SR surrounded by a shield material s and an interior material i made of silicon steel, a magnet M installed in the shield room SR, and a subject installed in the shield room SR. A table T on which the subject is moved to the magnetic field space inside the magnet M, a shield room power supply P that is installed in the shield room SR and supplies power to the table T, and the like, and is installed outside the shield room SR. An operator console OC for displaying an image photographed by the magnet M, a centralized power supply IPS that is installed outside the shield room SR and supplies power to the magnet M and the operator console OC, and a gradient current to the magnet M A gradient power supply GPS is provided.
[0024]
A floor material f is laid on the installation floor FL, and extends on the floor material f from the immediate vicinity of the shield room SR to the bottoms of the concentrated power source IPS, the gradient power source GPS, and the operator console OC. A ground plate 11 made of brass is laid.
[0025]
The operator console OC is grounded to the ground plate 11 by the ground wire 1 in the immediate vicinity, the concentrated power source IPS is grounded to the ground plate 11 by the ground wire 2 in the immediate vicinity, and the gradient power source GPS is in the immediate vicinity. The ground wire 3 is grounded to the ground plate 11.
The shield chamber 4 is grounded to the ground plate 11 by the ground wire 4 in the immediate vicinity.
[0026]
On the other hand, the table T is grounded to the shield material s by the ground wire 5 in the immediate vicinity, the magnet M is grounded to the shield material s by the ground wire 6 in the immediate vicinity, and the shield room power supply P is grounded to the nearest. The wire 7 is grounded to the shield material s.
[0027]
As shown in FIG. 5, each ground line 1 to 7 is fixed to the ground plate 11 or the shield material s by screws 1 a to 7 a.
As shown in FIG. 6, the grounding metal 1b and the screw 1a are used instead of the grounding wire 1 and the screw 1a (the same applies to the grounding wires 2 to 4), and the grounding metal 7b and 7c are used instead of the grounding wire 7 and the screw 7a. And stud 7d may be used (the same applies to ground lines 5 and 6).
[0028]
When the volume resistivity of the ground plate 11 is 6.8 × 10 ⁻⁸ Ωm, the thickness is 6 mm, the current path width is 10 mm, and the current path length from the shield room SR to the centralized power supply IPS is 5.5 m, the shield The impedance of the ground circuit from the room SR to the centralized power supply IPS is 6.2 mΩ (= 6.8 × 10 ⁻⁸ Ωm × 5.5 m ÷ 6 mm ÷ 10 mm). If the volume resistivity of the shielding material s is 60 × 10 ⁻⁸ Ωm, the thickness is 6 mm, the current path width is 10 mm, and the current path length from the table T to the ground plate 11 is 1.5 m, the table T The impedance of the ground circuit from the ground plate 11 to the ground plate 11 is 15 mΩ (= 60 × 10 ⁻⁸ Ω / m × 1.5 m ÷ 6 mm ÷ 10 mm). Therefore, the impedance of the ground circuit from the table T to the centralized power supply IPS is 21.2 mΩ (= 6.2 mΩ + 15 mΩ).
[0029]
According to the MRI apparatus 200 according to the second embodiment, the ground plate 11 and the shield material s are planes, and can be connected from the operator console OC to the shielded room power supply P in the shortest time without being routed. Moreover, the influence of the skin effect is small. Therefore, the impedance of the ground circuit can be reduced, and degradation of image quality and noise generation can be prevented. Furthermore, since the shield material s is used, the size of the ground plate 11 can be reduced.
[0030]
-Third embodiment-
FIG. 7 is a block diagram showing an MRI apparatus according to the third embodiment of the present invention. The MRI apparatus 300 includes a shield chamber SR surrounded by a shield material s and an interior material i made of silicon steel, a magnet M installed in the shield chamber SR, and a subject installed in the shield chamber SR. A table T on which the subject is moved to the magnetic field space inside the magnet M, a shield room power supply P that is installed in the shield room SR and supplies power to the table T, and the like, and is installed outside the shield room SR. An operator console OC for displaying an image photographed by the magnet M, a centralized power supply IPS that is installed outside the shield room SR and supplies power to the magnet M and the operator console OC, and a gradient current to the magnet M A gradient power supply GPS is provided.
[0031]
A floor material f is laid on the installation floor FL, and extends on the floor material f from the immediate vicinity of the shield room SR to the bottoms of the concentrated power source IPS, the gradient power source GPS, and the operator console OC. A ground plate 11 made of brass is laid.
A grounding plate 12 made of brass is laid between the shield material s and the interior material i at the bottom of the shield chamber SR.
[0032]
The operator console OC is grounded to the ground plate 11 by the ground wire 1 in the immediate vicinity, the concentrated power source IPS is grounded to the ground plate 11 by the ground wire 2 in the immediate vicinity, and the gradient power source GPS is in the immediate vicinity. The ground wire 3 is grounded to the ground plate 11.
The shield chamber 4 is grounded to the ground plate 11 by the ground wire 4 in the immediate vicinity.
[0033]
On the other hand, the table T is grounded to the ground plate 12 by the ground wire 5 in the immediate vicinity thereof, the magnet M is grounded to the ground plate 12 by the ground wire 6 in the immediate vicinity, and the shield room power supply P is grounded to the nearest. The wire 7 is grounded to the ground plate 12.
The ground plate 12 is grounded to the ground plate 11 by ground wires 8 and 4 in the immediate vicinity thereof.
[0034]
As shown in FIG. 8, the ground lines 1 to 7 are fixed to the ground plate 11 or the ground plate 12 with screws 1 a to 7 a.
[0035]
When the volume resistivity of the ground plate 11 is 6.8 × 10 ⁻⁸ Ωm, the thickness is 6 mm, the current path width is 10 mm, and the current path length from the shield room SR to the centralized power supply IPS is 5.5 m, the shield The impedance of the ground circuit from the room SR to the centralized power supply IPS is 6.2 mΩ (= 6.8 × 10 ⁻⁸ Ωm × 5.5 m ÷ 6 mm ÷ 10 mm). Further, if the volume resistivity of the ground plate 12 is 6.8 × 10 ⁻⁸ Ωm, the thickness is 6 mm, the current path width is 10 mm, and the current path length from the table T to the ground plate 11 is 1.5 m, The impedance of the ground circuit from the table T to the ground plate 11 is 1.7 mΩ (= 6.8 × 10 ⁻⁸ Ω / m × 1.5 m ÷ 6 mm ÷ 10 mm). Therefore, the impedance of the ground circuit from the table T to the concentrated power source IPS is 3.2 mΩ (= 1.5 mΩ + 1.7 mΩ).
[0036]
According to the MRI apparatus 300 according to the third embodiment, the ground plates 11 and 12 are surfaces, and can be routed from the operator console OC to the shielded room power supply P in the shortest time without being routed. Moreover, the influence of the skin effect is small. Therefore, the impedance of the ground circuit can be reduced, and degradation of image quality and noise generation can be prevented. Furthermore, the shield material s may be a non-conductor.
[0037]
【The invention's effect】
According to the medical imaging apparatus of the present invention, it is not necessary to use a grounding cable that is a line and becomes long due to routing and has a great influence on the skin effect, and the respective means are connected in the shortest without being routed. In addition, since a ground plate or a shield material that is less affected by the skin effect is used, the impedance of the ground circuit can be reduced, and image quality degradation and noise generation can be prevented.
[Brief description of the drawings]
FIG. 1 is a schematic diagram showing an MRI apparatus according to a first embodiment of the present invention.
FIG. 2 is a cross-sectional view showing an example of a grounding method in the MRI apparatus of FIG.
3 is a cross-sectional view showing another example of a grounding method in the MRI apparatus of FIG. 1. FIG.
FIG. 4 is a schematic diagram showing an MRI apparatus according to a second embodiment of the present invention.
5 is a cross-sectional view showing an example of a grounding method in the MRI apparatus of FIG.
6 is a cross-sectional view showing another example of a grounding method in the MRI apparatus of FIG.
FIG. 7 is a schematic diagram showing an MRI apparatus according to a third embodiment of the present invention.
8 is a cross-sectional view showing an example of a grounding method in the MRI apparatus of FIG.
FIG. 9 is a schematic diagram showing an example of a conventional MRI apparatus.
10 is a circuit diagram showing the impedance of a ground circuit in the MRI apparatus of FIG. 9. FIG.
[Explanation of symbols]
100, 200, 300 MRI apparatus 1-8 Ground wire 10, 11, 12 Ground plate s Shield material SR Shield room

Claims (4)

A medical imaging apparatus in which imaging means for imaging a subject, display means for displaying an image taken by the imaging means, and power supply means for supplying power to the imaging means and the display means are installed separately. A grounding plate extending to the immediate vicinity of the photographing means, the display means, and the power supply means is installed, and the photographing means, the display means, and the power supply means are grounded to the grounding plate in the immediate vicinity thereof. Medical imaging device. A shield room surrounded by a conductive shield material; imaging means installed in the shield room for imaging a subject; display means installed outside the shield room for displaying images taken by the imaging means; and the shield A medical imaging apparatus provided with a power supply means for supplying power to the imaging means and the display means installed outside the room, the grounding plate extending to the immediate vicinity of the shield room, the display means and the power supply means, The medical imaging apparatus characterized in that the imaging means is grounded to the shield material in the immediate vicinity thereof, and the shield chamber, the display means and the power supply means are grounded to the grounding plate in the immediate vicinity thereof. A medical imaging apparatus comprising a shield room surrounded by a conductive shield material and an imaging means installed in the shield room for imaging a subject, wherein the imaging means is grounded to the shield material in the immediate vicinity thereof A medical imaging apparatus characterized by that. A medical imaging apparatus comprising a shield room surrounded by a shielding material and an imaging unit installed in the shield room for imaging a subject, wherein a grounding plate is installed in the shield room, and the imaging unit is disposed nearest to the imaging unit. A medical imaging apparatus characterized by being grounded to the ground plate.

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