JP2001198103A - Magnetic resonance diagnostic system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce a frequency of maintenance, to lengthen the service life of a vacuum pump, and to reduce a running cost by efficiently actuating the vacuum pump for exhausting inside air of a vacuum vessel for housing an inclined magnetic field coil. SOLUTION: This magnetic resonance diagnostic system is provided with a magnetostatic field magnet unit 1 for generating a magnetostatic field in a photographing area 21, the inclined magnetic field coil 2 for generating an inclined magnetic field in the photographing area 21 and the vacuum vessel 3 for housing the inclined magnetic field coil 2, and is further provided with an inclined magnetic field coil unit 41 arranged inside the magnetostatic field magnet unit 1, an RF coil unit 42 being arranged inside the inclined magnetic field coil unit 41, impressing a high-frequency magnetic field on a subject placed in the photographing area 21 and detecting a magnetic resonance signal emitted from the subject, the vacuum pump 7 for exhausting inside air of the vacuum vessel 3 and a control circuit 51 for intermittently actuating the vacuum pump 7.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a magnetic resonance diagnostic apparatus (MR) for medical diagnosis in which a gradient coil is housed in a vacuum vessel to reduce noise caused by the gradient coil as a vibration source.
I).

[0002]

2. Description of the Related Art As is well known, magnetic resonance phenomena occur when a group of nuclei having a unique magnetic moment is placed in a uniform static magnetic field, and a high frequency magnetic field rotating at a specific frequency. This is the phenomenon of absorbing energy resonantly. A magnetic resonance diagnostic apparatus is an apparatus that utilizes this magnetic resonance phenomenon to visualize chemical and structural microscopic information of a substance in a living body.

There are various types of imaging methods,
The mainstream is the two-dimensional Fourier transform method (2DFT). In the 2DFT, a gradient magnetic field is used to give spatial position information to a magnetic resonance signal in phase or frequency.
This gradient magnetic field is superimposed on a very strong static magnetic field of several kilograms to 10 kilogauss (1 Tesla). Therefore, the gradient magnetic field coil impregnated cylinder is severely deformed at the time of rising and falling of the gradient magnetic field, and accordingly, noise is generated intensely. In a high-speed imaging method represented by a recent echo planar method, since the gradient magnetic field is alternated at a high speed, the noise is 1%.
It can reach as high as 00 dB (A), and the wearing of earplugs and headphones is obligatory for the subject.

[0004] In order to reduce the intense noise, there has been proposed a method in which a gradient magnetic field coil impregnated cylinder is housed in a vacuum vessel so that noise is hardly leaked to the outside. No. 210, JP-A-10-1
No. 18043 (Japanese Patent Application No. 8-274609).

[0005] Maintaining the vacuum state of the vacuum vessel can be achieved by reducing the leak amount of the vacuum vessel to zero. In practice, however, a drive current is supplied to this vacuum vessel to the gradient coil. The current leads and cooling system are penetrated, and there are many joints.Mainly from these parts, the outside air flows into the vacuum vessel little by little, so it is possible to maintain the vacuum state for such a long time. It was impossible. For this reason, a relatively inexpensive rotary vacuum pump is continuously operated to constantly exhaust the internal air and maintain the inside of the vacuum vessel in a vacuum state.

However, when the vacuum pump is operated continuously, oil and parts are rapidly deteriorated, which necessitates frequent maintenance, and the life of the vacuum pump itself is shortened. Further, there is a problem that power consumption is large and running cost is increased.

[0007]

SUMMARY OF THE INVENTION It is an object of the present invention to efficiently operate a vacuum pump for evacuating air inside a vacuum vessel accommodating a gradient magnetic field coil, reduce the frequency of maintenance, and reduce the frequency of the vacuum pump. It is to extend the life and further reduce the running cost.

[0008]

(1) A magnetic resonance diagnostic apparatus according to the present invention comprises a static magnetic field magnet unit for generating a static magnetic field in an imaging region, and a gradient magnetic field coil for generating a gradient magnetic field in the imaging region. A vacuum container containing the gradient magnetic field coil, a gradient magnetic field coil unit provided inside the static magnetic field magnet unit, and a gradient magnetic field coil unit provided inside the gradient magnetic field coil unit and placed in the imaging region. An RF coil unit that applies a high-frequency magnetic field to the subject and detects a magnetic resonance signal emitted from the subject, and a vacuum pump that exhausts air inside the vacuum container,
And a control circuit for intermittently operating the vacuum pump.

(2) The magnetic resonance diagnostic apparatus according to the present invention
A static magnetic field magnet unit for generating a static magnetic field in the imaging region,
A gradient magnetic field coil that generates a gradient magnetic field in the imaging region, and a vacuum container that houses the gradient magnetic field coil,
A gradient magnetic field coil unit provided inside the static magnetic field magnet unit, and a high frequency magnetic field is applied to a subject mounted inside the imaging region and provided from the gradient magnetic field coil unit, and emitted from the subject. An RF coil unit that detects a magnetic resonance signal to be applied, a vacuum pump that exhausts air inside the vacuum container, a pressure sensor that detects the internal pressure of the vacuum container, and a pressure sensor that detects the internal pressure detected by the pressure sensor And a control circuit for intermittently operating the vacuum pump.

(3) The magnetic resonance diagnostic apparatus according to the present invention
A static magnetic field magnet unit for generating a static magnetic field in the imaging region,
A gradient magnetic field coil that generates a gradient magnetic field in the imaging region, and a vacuum container that houses the gradient magnetic field coil,
A gradient magnetic field coil unit provided inside the static magnetic field magnet unit, and a high frequency magnetic field is applied to a subject mounted inside the imaging region and provided from the gradient magnetic field coil unit, and emitted from the subject. An RF coil unit for detecting a magnetic resonance signal to be supplied, a vacuum pump for evacuating the air inside the vacuum vessel, and a control circuit for periodically operating the vacuum pump at a constant cycle.

(4) The magnetic resonance diagnostic apparatus according to the present invention
A static magnetic field magnet unit for generating a static magnetic field in the imaging region,
A gradient magnetic field coil that generates a gradient magnetic field in the imaging region, and a vacuum container that houses the gradient magnetic field coil,
A gradient magnetic field coil unit provided inside the static magnetic field magnet unit, and a high frequency magnetic field is applied to a subject mounted inside the imaging region and provided from the gradient magnetic field coil unit, and emitted from the subject. An RF coil unit that detects a magnetic resonance signal to be applied, a vacuum pump that exhausts air inside the vacuum container, a pressure sensor that detects the internal pressure of the vacuum container, and a pressure sensor that detects the internal pressure detected by the pressure sensor And a control circuit for operating the vacuum pump intermittently and periodically operating the vacuum pump at a constant cycle.

(5) The present invention relates to the magnetic resonance diagnostic apparatus of (1), (2), (3) or (4), wherein the power supply system of the vacuum pump and the control circuit is a main part of the magnetic resonance diagnostic apparatus. It is characterized by being independent of the power supply.

(6) The present invention relates to the magnetic resonance diagnostic apparatus of (1), (2), (3) or (4), wherein the control circuit is irrespective of whether a main power supply of the magnetic resonance diagnostic apparatus is on or off. The method is characterized in that the vacuum pump is controlled.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The preferred embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 is a cross-sectional view of the gantry of the magnetic resonance diagnostic apparatus according to the present embodiment, and FIG. 2 is a longitudinal sectional view of the gantry of the magnetic resonance diagnostic apparatus according to the present embodiment. This gantry has a static magnetic field magnet unit 1, a gradient magnetic field coil unit 41, and an RF coil unit 42, and a substantially central part is a photographing area 21.
, Which has a substantially cylindrical shape,
It is installed and fixed.

The static magnetic field magnet unit 1 includes the imaging area 2
1 generates a static magnetic field, and if it is a super-electric type, it is composed of a super-electric coil, a liquid helium container accommodating the super-electric coil, and a vacuum container 36 further accommodating the liquid helium container. You. RF coil unit 4
Reference numeral 2 denotes an RF coil vibrating cylinder 17 in which a high frequency magnetic field is applied to a subject placed in the imaging region and an RF coil for detecting a magnetic resonance signal emitted from the subject is vibrated in resin. And a cylindrical liner 31 made of fiber reinforced plastic.

The gradient magnetic field coil unit 41 has a gradient magnetic field coil impregnation cylinder 2 in which a so-called active shield type gradient magnetic field coil surrounding the main coil with a shield coil is impregnated with resin. The gradient magnetic field coil impregnated cylinder 2 is housed in a vacuum vessel 3 so that noise caused by vibration of the gradient magnetic field coil impregnated cylinder 2 is not transmitted. The inner wall of the vacuum vessel 3 is provided with an RF coil unit 42
Is shared with the liner 31. Further, a part 34 of the outer wall of the vacuum vessel 3 is shared with the inner wall of the vacuum vessel 36 of the static magnetic field magnet unit 1.

The air inside the vacuum vessel 3 is supplied to a vacuum pipe 6
The inside of the vacuum vessel 3 is maintained in a vacuum state by forcibly discharging the air through a vacuum pump 7 connected through the vacuum pump 7. Note that the degree of vacuum of the vacuum vessel 3 does not need to be a complete vacuum, but can be said to be sufficient to block the sound propagation, for example, about several torr. The sound insulation effect S
Is given by S = 20 log ₁₀ (P1 / 760) when the vacuum degree of the vacuum vessel 3 is P1, and about 40 dB when the vacuum degree P1 is 7 Torr.
Therefore, the sound insulation effect can be obtained. The operation of the vacuum pump 7 is controlled so that the internal pressure of the vacuum container 3 does not exceed 7 Torr at which a sufficient sound insulation effect of about 40 dB is obtained. The details will be described later.

The above-mentioned gradient coil is connected to an external gradient power supply (not shown) via a current lead 4. A cooling water flow path formed inside the gradient coil impregnated cylinder 2 is connected to a hose 5 by an external cooler (not shown).
Connected through. The gradient coil impregnated cylinder 2 is provided with anti-vibration rubbers 9 and 10, bolts 11 and 12, and an arm 1 so as to minimize mechanical propagation of the vibration.
3, supported by a base 15 via a shaft 14. Further, the shaft 14 is surrounded by a bellows 8 for the purpose of assembling and maintaining a vacuum.

FIG. 3 shows the configuration of an exhaust system for exhausting the air inside the vacuum vessel 3 according to the present embodiment. The operation of this exhaust system is controlled and managed by the control circuit 51. The control circuit 51 includes a vacuum pump dedicated power supply 5 for supplying driving power to the vacuum pump 7.
6, a clock circuit 53 that outputs real time data or oscillates a pulse at a constant cycle, a pressure sensor 54 for detecting the internal pressure of the vacuum vessel 3, and an electromagnetic valve 55 for opening and closing the pipe 6. It is connected. Although not shown,
An electromagnetic valve for opening to the atmosphere is provided between the vacuum pump 7 and the electromagnetic valve 55 in order to prevent the oil from flowing back in the vacuum pump 7 and reduce the load on the vacuum pump 7 at the time of starting. .

The control circuit 51 includes a sensing control mode for controlling the vacuum pump power supply 56 based on the internal pressure of the vacuum vessel 3 detected by the pressure sensor 54, and a clock circuit 53.
There are provided three types of modes: a cycle control mode for controlling the vacuum pump power supply 56 based on the output of the above, and a combined mode in which the sensing control mode and the cycle control mode are used in combination. The operator can freely select any one of these three operation modes by operating the operation panel 52.

The power supply system of this exhaust system is completely independent of the main power supply of the magnetic resonance diagnostic apparatus main body so that the exhaust system always functions regardless of whether the main power supply of the magnetic resonance diagnostic apparatus main body is on or off. Is provided. That is, even when the main power supply of the magnetic resonance diagnostic apparatus is turned off, the power supply of the exhaust system is always on unless the power switch of the exhaust system is turned off, and the exhaust operation is performed in one of three modes described later. Is to be continued around the clock.

FIG. 4A shows a temporal change in the internal pressure of the vacuum vessel 3 under the sensing control mode.
In the sensing control mode, the control circuit 51 compares the internal pressure of the vacuum vessel 3 detected by the pressure sensor 54 with the upper limit (7 torr) at which the above-described sufficient sound insulation effect is obtained, and when the internal pressure exceeds the upper limit. When the vacuum pump dedicated power supply 5
The control unit 6 controls the vacuum pump 7 to start supplying drive power to the vacuum pump 7 from the vacuum pump dedicated power source 56, and opens the solenoid valve 55 simultaneously or slightly later. Thereby, the vacuum pump 7 is started, and the evacuation of the air inside the vacuum vessel 3 is started.

When the internal pressure of the vacuum vessel 3 becomes lower than the lower limit of, for example, about 5 Torr, which is slightly higher than the load capacity of the vacuum pump 7, or when a predetermined period of time elapses after the start of the vacuum pump 7, At this time, the solenoid valve 55 is closed, and the power supply 56 for exclusive use of the vacuum pump is controlled to stop the supply of the driving power from the power supply 56 exclusively for the vacuum pump to the vacuum pump 7. Thereby, the vacuum pump 7 stops,
The evacuation of the air inside the vacuum vessel 3 ends. Note that the operation period of the vacuum pump 7 is at the end of the period.
Is set in advance according to the volume of the vacuum vessel 3, the exhaust capacity of the vacuum pump 7, and the like so that the internal pressure of the vacuum container 7 decreases to less than 7 Torr, for example, about 5 Torr.

FIG. 4B shows a temporal change in the internal pressure of the vacuum vessel 3 under the cycle control mode. In the cycle control mode, the control circuit 51
When a predetermined period has elapsed from the end of the previous evacuation operation based on the output of the above, the vacuum pump dedicated power supply 56 is controlled to start the supply of drive power from the vacuum pump dedicated power supply 56 to the vacuum pump 7, The solenoid valve 55 is opened with a slight delay. Thereby, the vacuum pump 7 is started, and the evacuation of the air inside the vacuum vessel 3 is started.

When a predetermined period has elapsed from the start of the vacuum pump 7, the control circuit 51 closes the solenoid valve 55 and controls the vacuum pump power supply 56 so that the power from the vacuum pump power supply 56 to the vacuum pump 7 is controlled. The supply of driving power is stopped. As a result, the vacuum pump 7 stops, and the evacuation of the air inside the vacuum vessel 3 ends.

The evacuation cycle is set so that the internal pressure of the vacuum vessel 3 does not exceed 7 Torr at the end of the period.
It is set in advance according to the leak amount of the vacuum vessel 3 and the like.
The operation period of the vacuum pump 7 is determined according to the volume of the vacuum container 3, the capacity of the vacuum pump 7, and the like such that the internal pressure of the vacuum container 3 is reduced to a value lower than 7 Torr, for example, about 5 Torr at the end of the period. It is set in advance.

In the mode in which the sensing control mode and the cycle control mode are used in combination, the evacuation operation by the vacuum pump 7 is periodically performed at a constant cycle, during which the internal pressure of the vacuum vessel 3 exceeds 7 Torr. In such a case, the exhaust operation is also performed at that time. In addition, the evacuation operation by the vacuum pump 7 is periodically performed at a constant cycle. During this time, if the evacuation operation is interrupted when the internal pressure of the vacuum vessel 3 exceeds 7 Torr, the starting point of the evacuation operation cycle May be reset to the start point of the exhaust operation performed by the interrupt.

As described above, according to the present embodiment, since the vacuum pump 7 operates intermittently, deterioration of oil and components of the vacuum pump 7 is delayed, and the frequency of maintenance is reduced accordingly. Further, since the operation time of the vacuum pump 7 can be reduced, the life of the vacuum pump can be extended. Moreover, power consumption can be reduced and running costs can be reduced. In the cycle control mode described above,
Since the operating time of the vacuum pump 7 can be grasped by the manufacturer or the maintenance company, there is also an advantage that oil replacement of the vacuum pump 7 and replacement of repair parts can be performed at an appropriate time.

The present invention is not limited to the above embodiment, but can be implemented in various modifications.

[0030]

According to the present invention, since the vacuum pump is operated intermittently, deterioration of oil and parts of the vacuum pump is delayed, and the frequency of maintenance is reduced accordingly. Also,
Since the operation time of the vacuum pump 7 can be shortened, the life of the vacuum pump can be extended. Moreover, power consumption can be reduced and running costs can be reduced.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view of a gantry of a magnetic resonance diagnostic apparatus according to an embodiment of the present invention.

FIG. 2 is a longitudinal sectional view of a gantry of the magnetic resonance diagnostic apparatus according to the embodiment of the present invention.

FIG. 3 is a configuration diagram of an evacuation system for a vacuum vessel shown in FIGS. 1 and 2;

4 (a) is a diagram showing a temporal variation of the internal pressure of the vacuum vessel by sensing control of the control circuit of FIG. 3, and FIG. 4 (b) is a time of the internal pressure of the vacuum vessel by cycle control of the control circuit of FIG. FIG.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Static magnetic field magnet unit, 2 ... Gradient magnetic field coil impregnation cylinder, 3 ... Vacuum container for gradient magnetic field coil, 4 ... Current lead, 5 ... Hose, 6 ... Vacuum hose, 7 ... Vacuum pump, 8 ... Bellows, 9 ... Prevention Vibration rubber, 10: Anti-vibration rubber, 11: Bolt, 12: Bolt, 13: Arm, 14: Shaft, 15: Base, 21: Photographing area, 22: Floor, 36: Vacuum container of static magnetic field magnet unit, 41 ... Gradient magnetic field coil unit, 42: RF coil unit, 51: control circuit, 52: operation panel, 53: clock circuit, 54: pressure sensor, 55: solenoid valve, 56: power supply for vacuum pump.

Claims (6)

[Claims] A static magnetic field magnet unit for generating a static magnetic field in an imaging area; a gradient magnetic field coil for generating a gradient magnetic field in the imaging area; and a vacuum container accommodating the gradient magnetic field coil, A gradient magnetic field coil unit provided inside a static magnetic field magnet unit, and a radio frequency magnetic field is applied to a subject placed inside the imaging region, which is provided inside the gradient magnetic field coil unit, and is released from the subject. A magnetic resonance diagnostic apparatus, comprising: an RF coil unit that detects a magnetic resonance signal, a vacuum pump that exhausts air inside the vacuum vessel, and a control circuit that operates the vacuum pump intermittently. 2. A static magnetic field magnet unit that generates a static magnetic field in an imaging area, a gradient magnetic field coil that generates a gradient magnetic field in the imaging area, and a vacuum container that houses the gradient magnetic field coil,
A gradient magnetic field coil unit provided inside the static magnetic field magnet unit; and a radio frequency magnetic field applied to a subject placed inside the imaging region provided inside the gradient magnetic field coil unit and emitted from the subject. An RF coil unit that detects a magnetic resonance signal to be applied, a vacuum pump that exhausts air inside the vacuum container, a pressure sensor that detects the internal pressure of the vacuum container, and a pressure sensor that detects the internal pressure detected by the pressure sensor. And a control circuit for intermittently operating the vacuum pump. 3. A static magnetic field magnet unit that generates a static magnetic field in an imaging area, a gradient magnetic field coil that generates a gradient magnetic field in the imaging area, and a vacuum container that houses the gradient magnetic field coil,
A gradient magnetic field coil unit provided inside the static magnetic field magnet unit; and a radio frequency magnetic field applied to a subject placed inside the imaging region provided inside the gradient magnetic field coil unit and emitted from the subject. A magnetic coil comprising: an RF coil unit for detecting a magnetic resonance signal to be applied; a vacuum pump for exhausting air inside the vacuum vessel; and a control circuit for periodically operating the vacuum pump at a constant cycle. Resonance diagnostic device. 4. A static magnetic field magnet unit that generates a static magnetic field in an imaging region, a gradient magnetic field coil that generates a gradient magnetic field in the imaging region, and a vacuum container that houses the gradient magnetic field coil,
A gradient magnetic field coil unit provided inside the static magnetic field magnet unit; and a radio frequency magnetic field applied to a subject placed inside the imaging region provided inside the gradient magnetic field coil unit and emitted from the subject. An RF coil unit that detects a magnetic resonance signal to be applied, a vacuum pump that exhausts air inside the vacuum container, a pressure sensor that detects the internal pressure of the vacuum container, and a pressure sensor that detects the internal pressure detected by the pressure sensor. A magnetic resonance diagnostic apparatus comprising: a control circuit that intermittently operates the vacuum pump and periodically operates the vacuum pump at a constant cycle. 5. The magnetic resonance diagnosis according to claim 1, wherein a power supply system of the vacuum pump and the control circuit is independent of a main power supply of the magnetic resonance diagnosis apparatus. apparatus. 6. The magnetic resonance diagnosis apparatus according to claim 1, wherein the control circuit controls the vacuum pump regardless of whether a main power supply of the magnetic resonance diagnosis apparatus is turned on or off. .