JPH01110356A - Magnetic resonance imaging apparatus - Google Patents

Abstract

PURPOSE:To shorten the rising time of a system and to prevent the confirming omission of the residual amount of a cooling medium, by mounting a detection means for detecting the residual amount of the cooling medium, a data processing means for a detection result and a display means for displaying the change in the residual amount of the cooling medium with the elapse of time. CONSTITUTION:The residual amounts of liquid helium and liquid nitrogen for cooling the superconductive coil of a magnet apparatus 9 are respectively detected by a helium meter 6 and a nitrogen meter 8, and the detection data are transmitted to a host computer 1 through a detection means interface 5 and a computer interface 4 while the date data when the residual amounts of the cooling medii are detected is transmitted to the host computer 1 from a timer 7. These data are stored in a disk 3 under the control of the host computer 1. The memory content (the change in the residual amounts of the cooling medii with the elapse of time) of this disk can be displayed on a CRT display 2 if necessary. Therefore, the residual amounts of the cooling medii can be confirmed at the rising time of the system and a rising time can be shortened and the confirming omission of the residual amounts of the cooling medii can be prevented.

Description

[Detailed Description of the Invention] [Object of the Invention] (Industrial Application Field) The present invention provides magnetic resonance () fR: ma (lne
The present invention relates to a magnetic resonance imaging apparatus that obtains an MR image of a subject using the t i Cresonance phenomenon.

(Prior art) Magnetic resonance imaging device (hereinafter referred to as MRI device)
The method applies a -like static magnetic field to a desired part of the subject, and uses a transmitting RF coil to form an RF magnetic field perpendicular to the static magnetic field to produce a magnetic resonance phenomenon only in a specific slice part from which a tomographic image is obtained. Furthermore, the receiving RF coil detects the magnetic resonance signal (hereinafter referred to as MR multiplied signal) generated from the atomic nucleus after the RF magnetic field is released. A linear magnetic field gradient with a linear inclination is applied to the coordinate system) to obtain a composite MR multiplied signal, and this signal is Fourier transformed to rotate the X' axis of the sliced portion within the X-Y plane. -Y
An MR image can be formed by obtaining projection information in each direction within the plane.

By the way, some of these MRI apparatuses are equipped with a magnet device that increases the magnetic field strength by making use of superconducting technology, and such MRI apparatuses are particularly referred to as superconducting MRI apparatuses. Superconductivity is realized by cooling the magnet device, particularly the coil portion, with a cooling medium such as liquid helium (L-He).

The magnet device is usually equipped with a helium meter that displays the remaining amount of liquid helium, and this helium meter is used to check the remaining amount of the cooling medium.

(Problem to be solved by the invention) However, in the conventional method, it is necessary to check the remaining amount of coolant separately from the operation of the MRI apparatus using a helium meter placed in a room different from the operation room. This is the main factor that hinders the reduction of lifting time.

Furthermore, operator error may result in failure to confirm the remaining amount of cooling medium. Furthermore, there is another problem in that the replenishment time of the cooling medium cannot be accurately predicted.

Therefore, the present invention eliminates the above-mentioned drawbacks, and makes it possible to shorten system start-up time, prevent failure to check the remaining amount of cooling medium, and accurately predict when to replenish the cooling medium. The purpose is to provide an MRI device that can perform

[Structure of the Invention] (Means for Solving the Problems) The present invention has a magnet device that forms a predetermined magnetic field in a superconducting state due to the cooling action of a cooling medium, and a magnetic field of a subject placed in the magnetic field. In a magnetic resonance imaging apparatus that obtains a magnetic resonance image, a cooling medium detection means for detecting the remaining amount of the cooling medium, a data processing means for processing data of the residual amount detection result, and a cooling medium detection means for detecting the remaining amount of the cooling medium based on the data processing result. and display means for displaying changes in the remaining amount over time.

(Function) According to the above configuration, since the change over time in the remaining amount of cooling medium can be displayed on the display means, the operator can grasp the remaining amount of cooling medium on the console.
It is possible to shorten the system start-up time and prevent omissions in checking the remaining amount of cooling medium. Further, by displaying the above-mentioned changes over time, it is possible to easily predict when to replenish the cooling medium.

(Example) Hereinafter, the present invention will be specifically explained with reference to Examples.

FIG. 1 shows an embodiment of an MRI apparatus according to the present invention.

In the figure, a helium meter 6 is for detecting the remaining amount of liquid helium, and a nitrogen needle 8 is for detecting the remaining amount of liquid nitrogen, both of which are attached to a magnet device 9. Both liquid helium and liquid nitrogen are cooling media, which cool the superconducting coils of the magnet device 9. Here, the helium meter 6 and the nitrogen needle 8 are examples of the cooling medium detection means in the present invention. The detection results of the helium meter 6 and nitrogen needle 8 are transmitted to the host computer 1 via the detection means interface 5 and the computer interface 4. The host computer 1 also receives the date (
(February 1, 2017) information is now being imported.

The host computer 1 processes data regarding the remaining amount of cooling medium, and is an example of data processing means in the present invention.

The CRT display 2 displays changes over time in the remaining amount of coolant based on the results of data processing by the host computer 1, and is an example of display means in the present invention. However, this CRT
The display 2 is placed near the console of the MRI apparatus. Further, the disk 3 stores data regarding the remaining amount of cooling medium over a certain period of time in the past, and is under the control of the host computer 1.

Next, the operation of the embodiment device configured as described above will be explained.

The remaining amounts of liquid helium and liquid nitrogen that cool the superconducting coils of the magnet device 9 are detected by a helium meter 6 and a nitrogen needle 8, respectively, and the detected information is sent to the host combination 1-1 via the detection means interface 5 and the computer interface 4. 1. Further, date information at the time of detection of the remaining coolant is transmitted from the timer 7 to the host computer 1. Thus, this information is stored on the disk 3 under the control of the host computer 1.

The stored contents of the disk 3 (changes in the remaining amount of cooling medium over time) can be displayed on the CRT display 2 as necessary. Although various formats are conceivable as this display method, in the present embodiment, a graph is displayed on a part of the system initialization screen via the host computer 1. FIG. 2 shows an example of a graph display in this case. In the figure, MM is the “moon” and DD
is "day" and YY is "year". The remaining amount of cooling medium (vertical axis) is expressed as a percentage. N2 is a characteristic curve of the temporal change in the residual amount of liquid nitrogen, and He is a characteristic curve of the temporal change in the residual amount of liquid helium. In addition, the latest detection data is also displayed numerically (90.0%, a
O, O%). Additionally, a warning message will be displayed when the remaining amount of liquid helium and liquid nitrogen falls below 60% of the predetermined value (standard value), and a warning sound (alarm, buzzer, etc.) will be emitted when the remaining amount falls below 55%. You can do it like this.

The data processing related to the above display etc. is performed by the host computer 1.

Note that reconstruction of an MR image of a subject placed in a static magnetic field formed by the magnet device 9 is the same as that of the conventional device, so a description thereof will be omitted.

In this way, in the device of this embodiment, the change over time in the remaining amount of cooling medium is displayed on the CRT display 2, so it is possible to easily grasp the state of decrease in the amount of cooling medium. It is possible to accurately predict the replenishment time.

In addition, as mentioned above, information regarding the remaining amount of cooling medium is displayed on the CRT display 2, so the operator can check the remaining amount of cooling medium when starting up the system, and check the remaining amount of liquid helium. It is possible to prevent omissions in quantity confirmation. Moreover, since there is no need to go out of your way to a place where a liquid helium meter is installed to check the remaining amount of liquid helium, the time required to start up the system can be shortened.

Although one embodiment of the present invention has been described above, it goes without saying that the present invention is not limited to the above embodiment, and various modifications can be made.

For example, in the above embodiment, the helium meter 6. Although the cooling medium detection means is configured with the nitrogen meter 8, it is also possible to use only the helium meter 6 or the nitrogen meter 8, or to apply something other than a helium meter or a nitrogen meter depending on the type of cooling medium. .

[Effects of the Invention] As described in detail above, according to the present invention, it is possible to shorten the system start-up time, prevent failure to check the remaining amount of cooling medium, and further reduce the time required to replenish the cooling medium. It is possible to provide an MRI apparatus that can make accurate predictions.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an embodiment of an MRI apparatus according to the present invention, and FIG. 2 is an explanatory diagram of a display example in the apparatus of this embodiment. 1... host computer (data processing means), 2...
...CRT display (display means), 6. Helium meter (cooling medium detection means), 8. Nitrogen meter (cooling medium detection means), 9. Magnet device.

Claims (2)

[Claims] (1) In a magnetic resonance imaging apparatus that has a magnet device that forms a predetermined magnetic field in a superconducting state due to the cooling effect of a cooling medium, and obtains a magnetic resonance image of a subject placed in the magnetic field, residual cooling medium remains. A cooling medium detection means for detecting the amount of cooling medium, a data processing means for processing data of the residual amount detection result, and a display means for displaying changes over time in the residual amount of cooling medium based on the data processing results. Features of magnetic resonance imaging equipment. (2) The magnetic resonance imaging apparatus according to claim 1, wherein the display means graphically displays changes over time in the remaining amount of cooling medium.