JP2021146116A - Biomagnetism measuring vacuum insulation device and biomagnetism measuring device - Google Patents

Abstract

To perform simple connection to a refrigerator.SOLUTION: A biomagnetism measuring vacuum insulation device 31 includes: an upper surface part 31Aa installed while being inclined relative to a horizontal plane; and a connection part 31B from which a refrigerant transfer pipe 24 can be inserted/removed at an angle inclined relative to the upper surface part 31Aa.SELECTED DRAWING: Figure 3

Description

The present invention relates to a vacuum insulation device for biomagnetic measurement and a biomagnetic measurement device.

Conventionally, for example, in Patent Document 1, a low-temperature container is arranged at an angle, and a pipe connected to the low-temperature container and forming a flow path for transferring a refrigerant is connected at an angle according to the inclination of the low-temperature container. The configuration is described.

In a biomagnetic measuring device such as a spinometer, for example, a high-sensitivity magnetic sensor such as a superconducting quantum interference element may be used, and liquid helium is used as a refrigerant in order to maintain a superconducting state. Alternatively, liquid helium is also used as a refrigerant in a physical property measuring instrument at an extremely low temperature. Since liquid helium vaporizes easily, it is necessary to circulate helium using a cryogenic refrigerator in order to use the measurement economically and continuously in the above-mentioned devices.

Here, the cryogenic refrigerator is provided by being connected to a vacuum heat insulating device that constitutes a dewa for cold biomagnetic measurement in order to cool the object to be cooled. If the cryogenic refrigerator is large enough to connect to a vacuum insulation device, or if the noise from the refrigerator is unacceptable to connect directly, the cooling unit is placed in the heat insulating unit (cryostat) that houses the cooling unit (cold head). A transfer tube (transfer tube) for transferring the refrigerant cooled in the above is provided, and the transfer tube may be inserted into a vacuum insulation device and interconnected.

On the other hand, in the biomagnetic measuring device, the vacuum insulation device may be tilted for the benefit. However, if the transfer pipe is also tilted, it must be inserted diagonally, which causes a problem that the mechanism for inserting is complicated. Further, the transfer pipe has a problem that the recondensing capacity is lowered when the invasion heat is large and long, and it is desirable to connect the transfer pipe by a short route.

The present invention has been made in view of the above, and an object of the present invention is to easily connect to a refrigerator.

In order to solve the above-mentioned problems and achieve the object, the vacuum insulation device for biomagnetic measurement of the present invention has an upper surface portion provided at an angle with respect to the horizontal surface and a refrigerant at an angle inclined with respect to the upper surface portion. It is provided with a connection portion provided so that the transfer pipe of the above can be inserted and removed.

According to the present invention, even if the upper surface portion is provided at an angle, the transfer pipe can be moved in the vertical direction with respect to the connecting portion to be inserted and removed, and the connection with the refrigerator can be easily performed.

FIG. 1 is a schematic configuration diagram showing an example of a biomagnetic measuring device. FIG. 2 is a schematic configuration diagram showing an example of a helium circulation system. FIG. 3 is an enlarged view of a main part of the cryogenic refrigerator. FIG. 4 is an enlarged view of a main part of the cryogenic refrigerator.

Hereinafter, embodiments of the vacuum insulation device for biomagnetic measurement and the biomagnetic measurement device will be described in detail with reference to the accompanying drawings.

FIG. 1 is a schematic configuration diagram showing an example of a biomagnetic measuring device.

The biomagnetic measuring device 100 is a biological information measuring device, and includes a nerve activity measuring device (also referred to as a measuring device) 101 and an information treatment device 102.

The nerve activity measuring device 101 is a spinometer (MagnetoSpinoGraphy (MSG)) for measuring the nerve activity of the cervical spinal cord of the subject 110 to be measured. The neural activity measuring device 101 has a dewar 1 on which the neck of the subject 110 is placed. The Duwa 1 is a vacuum insulation device for biomagnetic measurement in a cryogenic environment using liquid helium (hereinafter, also referred to as a vacuum insulation device). A large number of magnetic sensors 2 for measuring the spinal cord are arranged inside the Dewar 1. As the magnetic sensor 2, a superconducting Quantum Interference Device (SQUID) is used. The neural activity measuring device 101 collects a spinal signal from the magnetic sensor 2. The neural activity measuring device 101 outputs the collected biological signal to the information treatment device 102.

The information treatment device 102 displays the spinal signals from the plurality of magnetic sensors 2 on the waveform time axis. Spinal signals represent minute magnetic field fluctuations caused by the electrical activity of nerve cells (the flow of ionic charges that occur in the dendrites of neurons during synaptic transmission).

FIG. 2 is a schematic configuration diagram showing an example of a helium circulation system.

The above-mentioned neural activity measuring device 101 includes a helium circulation system 10 for setting the vacuum insulation device Duwa 1 in a cryogenic environment. The helium circulation system 10 includes a cryogenic refrigerator (refrigerator) 11, a dewar 1, an evaporative gas supply pipe 15, and a control unit 19.

The cryogenic refrigerator 11 constitutes a pulse tube refrigerator, and includes a cooling unit 21, a receiving unit 22, a heat retaining unit 23, a transfer pipe 24, and a drive system circulation unit 25.

The cooling unit 21 includes a main body 21A, a cylindrical first cylinder portion 21B, a cylindrical second cylinder portion 21C, a disk-shaped first cold stage 21D, and a disk-shaped second cold stage 21E. And. The main body portion 21A is a base portion of the cooling portion 21 and is arranged at the uppermost portion. The first cylinder portion 21B is provided so as to extend downward from the main body portion 21A. The second cylinder portion 21C is provided so as to extend downward from the first cylinder portion 21B. The first cold stage 21D is provided between the first cylinder portion 21B and the second cylinder portion 21C. The second cold stage 21E is provided at the extended lower end of the second cylinder portion 21C.

The receiving portion 22 is formed in a dish shape with an open upper end and a bottom 22A at the lower end. The receiving unit 22 is arranged directly below the cooling unit 21.

The heat insulating portion 23 is a vacuum-insulated cryostat, which is formed in a cylindrical shape by, for example, stainless steel or glass fiber reinforced resin, has an open upper end, and has a bottom 23A at the lower end. The heat retaining portion 23 is provided so as to accommodate the cooling portion 21 inside and surround the outer periphery of the cooling portion 21 at intervals. The upper end of the heat retaining portion 23 is sealed by the main body portion 21A of the cooling portion 21. Further, the receiving portion 22 is arranged inside the heat insulating portion 23. The heat retaining unit 23 functions to maintain the internal temperature.

The upper end 24a of the transfer pipe 24 is connected to the bottom 22A of the receiving portion 22, and is provided so as to communicate with the receiving portion 22. The transfer pipe 24 extends downward from the bottom 22A of the receiving portion 22, and the lower end 24b is provided downward through the inside of the heat insulating portion 23. The heat insulating portion 23 is formed so as to extend downward together with the transfer pipe 24 so that the bottom 23A surrounds the outer circumference of the transfer pipe 24 at intervals. The lower end 24b of the transfer tube 24 is connected to the dewar 1 of the neural activity measuring device 101. The transfer pipe 24 is also referred to as a first path for sending a liquid refrigerant from the cooling unit 21 to the dewar 1.

The drive system circulation unit 25 includes a compressor 25A which is a compressor and a valve motor 25B which is an operation unit. The compressor 25A compresses the compressed gas. The compressed gas is, for example, helium gas. The compressed gas compressed by the compressor 25A is supplied to the valve motor 25B. The valve motor 25B switches opening and closing so as to intermittently supply compressed gas to the main body 21A of the cooling unit 21. In the drive system circulation unit 25, the compressed gas is circulated between the compressor 25A and the cooling unit 21 by switching the valve motor 25B. The cooling unit 21 is activated by the intermittent supply of the compressed gas, and generates cold heat in the first cold stage 21D and the second cold stage 21E. The compressor 25A exhausts heat by water cooling or air cooling.

When the cryogenic refrigerator 11 is driven, a gas refrigerant is supplied to the cooling unit 21 inside the heat insulating unit 23. The gas refrigerant is, for example, helium gas, which is cooled by the cold heat generated in the first cold stage 21D and the second cold stage 21E and liquefied to become liquid helium, which is a liquid refrigerant, and reaches the bottom 22A of the receiving portion 22. It is dropped and put together. The liquid helium collected in the bottom 22A of the receiving portion 22 is sent to the outside of the cryogenic refrigerator 11 via the transfer pipe 24, and is supplied to the helium tank inside the duwa 1 of the nerve activity measuring device 101. As a result, the liquid helium of Duwa 1 of the neural activity measuring device 101 is retained. The liquid helium inside the dewa 1 gradually evaporates due to heat intrusion from the outside to become helium gas (also referred to as evaporative gas).

The evaporative gas supply pipe 15 is a pipe that connects the dewar 1 and the cooling unit 21. One end 15a of the evaporative gas supply pipe 15 is connected to the dewar 1 and the other end 15b is connected to the cooling unit 21 of the cryogenic refrigerator 11. The evaporative gas supply pipe 15 is provided with a pump 15c in the middle of the evaporative gas supply pipe 15 in order to send the evaporative gas from the dewar 1 to the cooling unit 21. Further, the evaporative gas supply pipe 15 is provided with an on-off valve 15d on the other end 15b side of the pump 15c in order to open and close the evaporative gas feed. The on-off valve 15d is controlled by the control unit 19.

The control unit 19 controls the helium circulation system 10, and is an arithmetic unit including a CPU (Central Processing Unit), a storage device, and the like. The control unit 19 controls the operation of the compressor 25A of the cryogenic refrigerator 11 and the pump 15c and the on-off valve 15d of the evaporative gas supply pipe 15.

Since the recondensing capacity of the cooling unit 21 is determined by the performance of the cooling unit 21 and the heat retaining unit 23 regardless of the evaporation amount of the dewar 1, the balance between the evaporation amount of the dewar 1 and the recondensing capacity of the helium circulation system 10 In other words, the control unit 19 controls the on-off valve 15d to prevent the pressure state of the dewa 1 part due to the excessive evaporation amount and the depressurization state of the dewa 1 part due to the recondensation amount too much. To adjust.

3 and 4 are enlarged views of a main part of the cryogenic refrigerator.

As shown in FIGS. 3 and 4, the cryogenic refrigerator 11 is provided so as to be movable in the vertical direction. Specifically, the cryogenic refrigerator 11 is provided with a slider 29A provided so as to be movable up and down with respect to the support column 29 installed on the floor G, and by being attached to the slider 29A, the cryogenic refrigerator 11 can be attached in the vertical direction. It is provided so that it can be moved. The slider 29A is provided so as to be movable up and down with respect to the support column 29 by a drive mechanism (not shown).

As shown in FIG. 3, when the cryogenic refrigerator 11 is moved downward, the lower end 24b of the transfer pipe 24 is connected to the dewar 1 shown in FIG. The dewar 1 is the vacuum adiabatic device (vacuum adiabatic device for biomagnetic measurement) 31 of the present embodiment and corresponds to the dewar 1 of the neural activity measuring device 101. The vacuum heat insulating device 31 is a vacuum container and functions to maintain the temperature of the liquid refrigerant sent from the cooling unit 21. The vacuum heat insulating device 31 has an apparatus main body 31A which is a vacuum container and a connecting portion 31B provided on the upper surface portion 31Aa of the apparatus main body 31A. The connecting portion 31B is formed, for example, in a cylindrical shape so as to insert the lower end 24b of the transfer pipe 24. The lower end 24b of the transfer pipe 24 inserted into the connection portion 31B is connected to the vacuum container of the apparatus main body 31A.

Further, as shown in FIG. 4, when the cryogenic refrigerator 11 is moved upward, the lower end 24b of the transfer pipe 24 is pulled out from the connection portion 31B of the vacuum insulation device 31. The lower end 24b of the transfer pipe 24 pulled out from the connection portion 31B is disconnected from the apparatus main body 31A.

By the way, in the biomagnetic measurement device 100, the nerve activity measurement device 101 has a dewar 1 on which the neck of the subject 110 is arranged as described above. When arranging the neck of the subject 110, the nerve activity measuring device 101 may be installed at an angle, and the vacuum heat insulating device 31 corresponding to the Duwa 1 is also installed at an inclination. Therefore, the vacuum heat insulating device 31 is provided with the upper surface portion 31Aa of the device main body 31A tilted with respect to the horizontal and the connecting portion 31B tilted. Then, the cryogenic refrigerator 11 that moves up and down so as to be inserted and removed from the connecting portion 31B is configured to move diagonally with respect to the vertical direction. The cryogenic refrigerator 11 provided at an angle is not preferable because a functional unit for cooling the gas refrigerant into a liquid refrigerant is diagonally arranged in the cooling unit 21 and the cooling performance is deteriorated.

In the vacuum insulation device 31 of the present embodiment, as shown in FIGS. 3 and 4, the device main body 31A is arranged so as to be inclined, and the upper surface portion 31Aa thereof is arranged so as to be inclined with respect to the horizontal. The vacuum heat insulating device 31 is provided so that the connecting portion 31B provided on the upper surface portion 31Aa arranged at an angle with respect to the horizontal can insert and remove the lower end 24b of the transfer pipe 24 at an angle inclined with respect to the upper surface portion 31Aa. ing. Specifically, in the vacuum heat insulating device 31 of the present embodiment, the connecting portion 31B is provided at an angle inclined with respect to the upper surface portion 31Aa because it is provided in the vertical direction, and the lower end 24b of the transfer pipe 24 is provided. It can be inserted and removed in the vertical direction.

In the vacuum heat insulating device 31 configured in this way, the connecting portion 31B is provided so that the connecting portion 31B faces in the vertical direction. Therefore, in order to insert and remove the transfer pipe 24 from the connection portion 31B of the vacuum insulation device 31, the cryogenic refrigerator 11 can be provided so as to move in the vertical direction. As a result, the vacuum insulation device 31 can be easily connected to the cryogenic refrigerator 11. Further, since the cryogenic refrigerator 11 can be provided so as to move in the vertical direction, the transfer pipe 24 whose recondensing capacity decreases when the invading heat is greatly lengthened can be connected by a short path, so that the cryogenic refrigerator 11 can be connected. Performance degradation can be prevented.

Further, in the vacuum heat insulating device 31, the connecting portion 31B has a movable portion 31C. The movable portion 31C is, for example, a flexible pipe formed in a bellows shape around a tubular shape, and has a connection port 31Ba of the connection portion 31B as shown in FIGS. It is provided on the attachment portion 31Bb to the upper surface portion 31Aa of the 31B. The connecting portion 31B is configured so that the position can be changed by the movable portion 31C. According to this vacuum insulation device 31, even if the relative positions of the lower end 24b of the transfer pipe 24 and the connection portion 31B in the cryogenic refrigerator 11 provided so as to be movable in the vertical direction are displaced, the connection portion 31B of the lower end 24b Can be inserted into.

Further, the biomagnetic measuring device 100 of the present embodiment is provided with the above-mentioned vacuum insulation device 31 and the cryogenic refrigerator 11 to prevent deterioration of the performance of the cooling unit 21 in the cryogenic refrigerator 11 and to prevent the performance of the cooling unit 21 from deteriorating. It is possible to prevent a decrease in measurement accuracy in the measuring device) 101.

11 Cryogenic freezer (freezer)
21 Cooling unit 24 Transfer pipe 31 Vacuum insulation device for biomagnetic measurement 31Aa Upper surface part 31B Connection part 31C Moving part 100 Biomagnetic measurement device 101 Nerve activity measurement device (measurement device)

Japanese Patent No. 6602456

Claims (4)

The upper surface, which is tilted with respect to the horizontal,
A connection portion provided so that the refrigerant transfer pipe can be inserted and removed at an angle inclined with respect to the upper surface portion, and
A vacuum insulation device for biomagnetic measurement. The vacuum insulation device for biomagnetic measurement according to claim 1, wherein the connection portion is provided so that the transfer pipe can be inserted and removed in the vertical direction. The vacuum insulation device for biomagnetic measurement according to claim 1 or 2, wherein the connecting portion has a movable portion. The vacuum insulation device for biomagnetic measurement according to any one of claims 1 to 3.
A refrigerator having a cooling unit for cooling the refrigerant and the transfer pipe so that the transfer pipe can be inserted and removed from the connection portion.
A measuring device that is cooled by the refrigerant sent to the vacuum insulation device for biomagnetic measurement, and
A biomagnetic measuring device.

Images