JPH05212012A - Magnetic resonance imaging system - Google Patents

Abstract

PURPOSE:To hold a permanent magnet at a prescribed temperature with simple configuration by detecting a temperature caused by heat generation at a gradient magnetic field coil and controlling a heat conducting means provided between the gradient magnetic field coil and the permanent magnet at a constant temperature. CONSTITUTION:On the plane of a magnetic pole piece 5a abutted to a permanent magnet 1a, heat pipes 10a forming plural parallel grooves are arranged, and a heat equalizing plate 15a in contact with this plane is arranged. The respective heat pipes 10a are connected in common at one terminal, pulled out to the outside of a heat insulating cover and connected to a fin 11a, a fan 13a is arranged near the fin 11a, and a heater 12a is fitted to the fin itself. A thermister 14a is arranged at a position where the heat pipe 10a is arranged and detects the temperature caused by the heat generation at the gradient magnetic field coil 13a and when the temperature is lower than a temperature around the permanent magnet 1a, the heater 12a is heated so as conduct heat to the heat pipes 10a. When the temperature is higher, the fan 13a is rotated so as to discharge heat from the heat pipes 10a.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a magnetic resonance imaging apparatus, and more particularly to improvement of a magnetic field generating apparatus thereof.

[0002]

2. Description of the Related Art A magnetic resonance imaging apparatus is designed to cause nuclear magnetic resonance in atomic nuclei constituting a living tissue and receive a magnetic resonance signal generated by the nuclear magnetic resonance in a receiving coil section. Then, a so-called Fourier transform is performed on the received magnetic resonance signal to reconstruct an image,
It is widely used to obtain a tomographic image of an arbitrary part of a subject.

In order to cause nuclear magnetic resonance at a portion corresponding to the tomographic image, it is necessary to generate a magnetic field having an intensity determined by the frequency of the high-frequency signal irradiated through the irradiation coil section at the portion. ..

For this reason, a gradient magnetic field coil and a permanent magnet are disposed so as to surround a portion where the subject is arranged and surround the gradient magnetic field coil, and a uniform magnetic field called a static magnetic field is generated by the permanent magnet. A gradient magnetic field is generated by the gradient magnetic field coil by superimposing it on this magnetic field. This gradient magnetic field can have its gradient set to an arbitrary value so that a magnetic field having a desired intensity can be generated at an arbitrary portion of the subject (for example, a portion where a tomographic image is to be obtained). Become.

However, in the magnetic resonance imaging apparatus having such a configuration, it is known that the gradient magnetic field coil generates heat when a current for generating the gradient magnetic field is applied to the gradient magnetic field coil. Then, heat is conducted to the permanent magnets arranged outside the gradient magnetic field coil, and the permanent magnets are brought into a high temperature state. As a result, the magnetic field strength decreases. This means that, for example, it becomes impossible to obtain a magnetic field having a predetermined intensity at a tomographic imaging position in the subject, which has a harmful effect of obtaining tomographic images at different points. ..

For this reason, conventionally, for example, there is known one in which a gradient magnetic field coil is exposed and a heat insulating cover surrounding the permanent magnet is provided so as to keep the periphery of the permanent magnet at a predetermined temperature. There is.

[0007]

However, even if the permanent magnet is surrounded by a heat insulating cover, a gradient magnetic field coil is exposed from the heat insulating cover and abuts on the gradient magnetic field coil to form the permanent magnet. As long as the permanent magnets are arranged, the thermal effect from the gradient magnetic field coil in the permanent magnet cannot be ignored, and it is difficult to keep the permanent magnet at a predetermined temperature.

In addition, by devising the structure of the heat insulating cover,
It may be possible to prevent the heat from the gradient magnetic field coil from being conducted to the permanent magnet side almost completely, but it is not appropriate because various other problems such as space are generated.

Therefore, the present invention has been made under such circumstances, and magnetic resonance imaging in which the permanent magnet can be surely held at a predetermined temperature despite having an extremely simple structure. To provide the equipment.

[0010]

In order to achieve such an object, the present invention basically provides a gradient magnetic field coil arranged across a space for arranging a subject and a gradient magnetic field coil of this gradient magnetic field coil. A magnetic resonance imaging apparatus including a permanent magnet that is disposed outside and that generates a static magnetic field, and a heat insulating cover that exposes the gradient magnetic field coil and surrounds the permanent magnet and that keeps the periphery of the permanent magnet at a predetermined temperature. At
Temperature detection means for detecting a temperature due to heat generation of the gradient magnetic field coil, heat conduction means provided between the gradient magnetic field coil and a permanent magnet, and when the temperature detection by the temperature detection means is lower than the predetermined temperature, A constant temperature control means for conducting heat to the heat conducting means and for radiating the heat from the heat conducting means when the temperature detected by the temperature detecting means is higher than the predetermined temperature is provided.

[0011]

According to the magnetic resonance imaging apparatus thus constructed, the temperature detecting means detects the temperature by the heat generation of the gradient magnetic field coil. First, when the detected temperature is lower than the predetermined temperature around the permanent magnet in the heat insulating cover. In addition, the constant temperature control means causes heat to be conducted to the heat conducting means provided between the gradient magnetic field coil and the permanent magnet.

By doing so, when the temperature on the permanent magnet side is higher than the temperature on the gradient magnetic field coil side, it is possible to reduce the temperature to a predetermined temperature or less of the permanent magnet due to the outflow of heat to the gradient magnetic field coil side. It is blocking.

The temperature detection by the temperature detection means is
When the temperature is higher than a predetermined temperature around the permanent magnet in the heat insulating cover, the constant temperature control means causes the heat conducting means to radiate heat.

By doing so, when the temperature on the side of the gradient magnetic field is higher than the temperature on the side of the permanent magnet, it is possible to prevent the temperature of the permanent magnet from rising to a predetermined temperature or more due to the outflow of heat to the side of the permanent magnet. is doing.

Therefore, from the above, the permanent magnet can be reliably maintained at the predetermined temperature at all times.

Moreover, the heat insulating cover formed surrounding the permanent magnet does not have to have a special structure, and the temperature detecting means,
A simple structure that includes only the heat conduction means and the constant temperature control means is sufficient.

[0017]

1 is a partially exploded perspective view showing an embodiment of a magnet gantry portion in a magnetic resonance imaging layer device according to the present invention.

In the figure, there is an envelope 50 formed by combining plate materials respectively covering the respective side surfaces, and a pair of plate materials facing each other is formed with a hole 51 in the center thereof. .. The hole 51 serves as a hole for inserting the subject, and the subject is positioned within the magnetic field formed by the magnet portions 52a and 52b incorporated in the envelope 50.

Magnets 52a, 5 incorporated in the envelope 50
2b are provided in each of the upper and lower parts with a gap A penetrating the hole 51 of the envelope 50 in between, and the magnet parts 52a, 52b are yokes provided at the respective four corners. It is arranged in parallel and at equal intervals through the columns 3.

Here, the magnet portions 52a and 52b will be described in detail with reference to FIG. 3, which is a sectional view taken along line III-III in FIG.

In the figure, the subject is positioned in the space A between the magnet portions 52a and 52b (the body axis direction is made to coincide with the front and back direction of the drawing). The receiving coil 33 is disposed so as to surround the receiving coil 33, and the irradiation coil 32 is disposed so as to surround the receiving coil 33. The irradiation coil 32 is a coil for causing an NMR phenomenon in the subject, and the receiving coil 32 is a coil for receiving an NMR signal from the subject.

Since the magnet portions 52a and 52b are constructed symmetrically with each other, only the magnet portion 52a side will be described here.

First, there is a gradient magnetic field coil 31a positioned on the side of the air gap A. This gradient coil 31a is
A coil for forming a gradient magnetic field having gradients in the axial direction, the Y-axis direction, and the Z-axis direction, so that a gradient magnetic field having a desired gradient can be formed by passing a current of a predetermined value. Is becoming It should be noted that the gradient magnetic field coil 31a
As described above, heat is generated.

The gradient magnetic field coil 31a is positioned in a recess formed in the surface of the magnetic pole piece 5a, and the magnetic pole piece 5a is arranged in contact with the permanent magnet 1a. Here, the pole piece 5a is the permanent magnet 1a.
Is provided to improve the uniformity of the static magnetic field.

Further, in the present embodiment, the constant temperature means is provided at the contact surfaces of the magnetic pole piece 5a and the permanent magnet 1a, but the details of this constant temperature means will be described with reference to FIG. See below.

The permanent magnet 1a is brought into contact with the yoke 2a, and the yoke 2a is a member fixed to the yoke support 3 as shown in FIG.

The magnetic pole piece 5a and the permanent magnet 1 are exposed by exposing the surface of the gradient magnetic field coil 31a.
A heat insulating cover 6 made of, for example, expanded polystyrene is formed so as to surround a and the yoke 2a. An aluminum plate 8 is attached to the inner wall of the heat insulating cover 6, and a planar heater 7 for heat insulation is fixed to a part of the aluminum plate 8.

Here, the planar heater 7 is a heating means for keeping the inside of the heat insulating cover 6, that is, the permanent magnet 1a at a predetermined temperature, and the permanent magnet 1a is arranged in the vicinity of the gradient magnetic field coil 31, and As described above, the temperature of the gradient magnetic field coil 31 is affected and the temperature cannot be reliably maintained at the predetermined temperature.

Next, the constant temperature means provided on the contact surfaces of the pole piece 5a and the permanent magnet 1a with each other will be described with reference to FIG. 1A is a plan view and FIG. 1B is a side view.

A plurality of parallel grooves are formed on the surface of the pole piece 5a in contact with the permanent magnet 1a, and a heat pipe 10a is arranged in each of these grooves. A soaking plate 15a that is in contact with each of these heat pipes 10a and is arranged between the magnetic pole piece 5a and the permanent magnet 1a is arranged.

The heat pipes 10a are commonly connected at one end in the same direction, and are drawn out of the heat insulating cover 6 shown in FIG. 3 and connected to the fins 11a. A fan 13a is arranged in the vicinity of the fin 11a, and a heater 12a is attached to itself. That is, the fin 11a has a function of radiating the heat at the boundary between the pole piece 5a and the permanent magnet 1a, that is, the portion where the heat pipe 10a is arranged, by driving the fan 13a, and drives the heater 12a. The pole piece 5
It has a function of applying heat to the boundary between a and the permanent magnet 1a.

In this way, the fan 13a or the heater 1
A control circuit for driving 2a will be described with reference to FIG. In FIG. 4, first, the thermistor 14a as a temperature detector
The thermistor 14a is arranged at a position where the heat pipe 10a is arranged as shown in FIG. 1 (a).

The output voltage corresponding to the temperature detected by the thermistor 14a is input to the + terminal of the comparator 60. A reference voltage is input to the negative terminal of the comparator 60, and it is determined whether the output voltage is large or small by this reference voltage, and the determination result is output as a logic value signal. ing. The reference voltage is set as a voltage corresponding to a reference temperature for switching and driving the fan 13a or the heater 12a.

When the output from the comparator 60 is, for example, a logical value "1", that is, when the detected temperature is lower than a predetermined value, the power supply circuit 61 is driven and the heater 12 is driven.
a is heated. Further, when the output from the comparator 60 is, for example, the logical value "0", that is, when the detected temperature is higher than the predetermined value, the fan 13a is output by the signal of the logical value "1" output via the inverter 62. It is designed to drive.

According to the magnetic resonance imaging apparatus shown in the above-mentioned embodiment, the thermistor 14a detects the temperature due to the heat generation of the gradient magnetic field coil 31a. First, the detected temperature is around the permanent magnet 1a in the heat insulating cover 6. When the temperature is lower than the predetermined temperature, the constant temperature control means conducts heat to the heat pipe 10a provided between the gradient magnetic field coil 31a and the permanent magnet 1a.

By doing so, the permanent magnet 1a
When the temperature on the side is higher than the temperature on the side of the gradient magnetic field coil 31a, the temperature drop below the predetermined temperature of the permanent magnet 1a due to the outflow of heat to the side of the gradient magnetic field coil 31a is prevented.

When the temperature detected by the thermistor 14a is higher than the predetermined temperature around the permanent magnet 1a in the heat insulating cover 6, the constant temperature control means causes the heat pipe 10a to radiate heat.

By doing so, when the temperature on the gradient magnetic field coil 31a side is higher than the temperature on the permanent magnet 1a side, the temperature rise of the permanent magnet 1a by a predetermined temperature or more due to the heat flow to the permanent magnet 1a side. It is blocking.

Therefore, from the above, the permanent magnet 1
The value a is always maintained at the predetermined temperature.

Moreover, the heat insulating cover 6 formed surrounding the permanent magnet 1a does not have to have a special structure, and the temperature detecting means such as the thermistor 14a, the heat conducting means such as the heat pipe 1a, and the constant temperature of the electronic circuit and the like. A simple structure with only control means is required.

In the above-mentioned embodiment, the temperature detecting means consisting of the thermistor 14a and the heat conducting means consisting of the heat pipe 10a are accurately arranged between the magnetic pole piece 5a supporting the gradient magnetic field coil 31a and the permanent magnet. It is a thing. However, the pole piece 5a can be regarded magnetically as a part of the gradient magnetic field coil 31a. Therefore, conceptually, the temperature detecting means or the heat conducting means may be arranged between the gradient magnetic field coil and the permanent magnet.

Further, in the above-described embodiment, the temperature on the side of the gradient magnetic field coil is set within the heat insulating cover when determining whether to conduct heat to the heat pipe 10 which is the heat conducting means or to radiate the heat from the heat pipe. Although it is determined whether the temperature is higher or lower than the predetermined temperature, it goes without saying that the predetermined temperature does not have to serve as a reference in a strict sense. It goes without saying that it may be a rough guide.

[0043]

As is clear from the above description,
According to the magnetic resonance imaging apparatus of the present invention, the permanent magnet can be reliably held at the predetermined temperature despite the extremely simple structure.

[Brief description of drawings]

FIG. 1 is a main part configuration diagram showing an embodiment of a magnetic resonance imaging apparatus according to the present invention, in which (a) is a plan view,
(B) is a side view.

FIG. 2 is a main part configuration diagram showing an embodiment of a magnetic resonance imaging apparatus according to the present invention, and is an exploded perspective view of a magnet gantry unit.

3 is a sectional view taken along line III-III in FIG.

FIG. 4 is a circuit diagram showing a control circuit for always maintaining a constant temperature state of a constant temperature means provided in a magnet gantry unit in the magnetic resonance imaging apparatus according to the present invention.

[Explanation of symbols]

1a ... Permanent magnet, 6 ... Thermal insulation cover, 10a ... Heat pipe, 14a ... Thermistor, 31a ... Gradient magnetic field coil.

Claims (1)

[Claims] 1. A gradient magnetic field coil disposed across a space for placing a subject, a permanent magnet disposed outside the gradient magnetic field coil to generate a static magnetic field, and exposing the gradient magnetic field coil. In a magnetic resonance imaging apparatus comprising a heat insulating cover surrounding a permanent magnet and holding the periphery of the permanent magnet at a predetermined temperature, a temperature detecting means for detecting a temperature due to heat generation of the gradient magnetic field coil, and the gradient magnetic field coil. A heat conduction means provided between the permanent magnet and
A constant temperature that conducts heat to the heat conducting means when the temperature sensing by the temperature sensing means is lower than the predetermined temperature and radiates heat from the heat conducting means when the temperature sensing by the temperature sensing means is higher than the predetermined temperature. A magnetic resonance imaging apparatus comprising: a control unit.