JP3770026B2 - Magnetic measuring device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a magnetic measurement device, and more particularly, to a high-sensitivity magnetic measurement device suitable for use in measurement of a minute magnetic field generated from a living body or the like using a SQUID (Superconducting Quantum Interference Device). In particular, according to the present invention, in a multi-channel biomagnetic measurement device, environmental magnetic noise is prevented from being mixed into a biomagnetic signal detected by a pickup coil to deteriorate the sensitivity of the magnetic measurement device. Therefore, the present invention is suitable for a magnetic measurement apparatus that uses a reference coil that measures the magnetic noise of the environment and removes the magnetic noise of the environment picked up by the pickup coil based on the output of the reference coil.
[0002]
[Prior art]
In recent years, high-sensitivity magnetic measurement devices using SQUID have been used to measure minute magnetic fields generated from living bodies and the like. The SQUID magnetic measurement device can measure the weak biomagnetic field generated from the brain and heart, and if the distribution of the biomagnetic field can be known, the current source that generates the magnetic field can be estimated. Measuring devices are attracting attention as medical devices for diagnosing and elucidating brain functions and cardiac functions.
[0003]
When measuring biomagnetism, biomagnetism is very weak and is buried in environmental magnetic noise. Japanese Patent Laid-Open No. 5-297087 discloses a noise removal technique in which a reference coil for measuring magnetic noise in the environment is prepared and the measured value of the reference coil is subtracted from the measured value of the pickup coil. In this conventional example, the reference coil is provided at a position away from the biomagnetic source above the pickup coil.
[0004]
Unlike the pick-up coil that measures biomagnetic measurements, the reference coil must measure only the environmental magnetic noise. When biomagnetism enters the reference coil, when the measurement value of the reference coil 7 is subtracted from the measurement value of the pickup coil 6, the actual biomagnetism cannot be accurately measured. For this reason, the reference coil needs to be arranged at a position far from the biomagnetic source and the pickup coil. However, since the reference coil needs to be cooled to a temperature capable of maintaining a superconducting state with liquid helium or the like, it is considered that the reference coil is installed at a position close to the liquid helium surface above the container that houses the pickup coil. Yes.
[0005]
When the multi-channel biomagnetic measuring device is used for a long time, the liquid helium in the container containing the pickup coil evaporates due to heat entering from the outside, and the liquid level gradually decreases. When the liquid level decreases, the temperature of the vapor layer at the top of the container rises due to heat penetration from the outside, and the temperature of the reference coil placed at the top of the container is heated by the vapor layer, making it impossible to maintain the reference coil in a superconducting state. It will not function as a reference coil. Therefore, the liquid helium must be constantly replenished so that the reference coil is not exposed on the liquid helium surface, and the replenishment work becomes complicated. Due to gas inflow or the like, expensive liquid helium is lost, and the operating cost of the magnetic measuring device increases.
[0006]
[Problems to be solved by the invention]
An object of the present invention is to obtain a magnetic measuring device that can be installed separately from an upper portion of a pickup coil so that magnetic noise can be removed from the measured value of the pickup coil.
[0007]
Another object of the present invention is to make it possible to maintain the superconducting state of the reference coil even if the reference coil is exposed from the liquid helium surface.
[0008]
Still another object of the present invention is to obtain a magnetic measuring device capable of cooling a reference coil to a critical temperature or less that can maintain a superconducting state even if the reference coil is exposed from the liquid helium liquid level.
[0009]
[Means for Solving the Problems]
In order to achieve the above object, a first feature of the present invention is that an outer container filled with a refrigerant and an outer space that is installed so as to surround the inner container and that forms a heat insulating gap between the inner container and the inner container. A container, a pickup coil provided inside the inner container for detecting weak magnetism generated by the subject, and a reference coil provided inside the inner container for measuring environmental magnetic noise, In the magnetic measurement device configured to remove the magnetic noise of the environment picked up by the pickup coil based on the output of the reference coil, the pickup coil is positioned below the liquid level of the refrigerant at least during measurement, A heat insulating means disposed so as to surround the reference coil, the reference coil being disposed above the pickup coil; Directly Reference coil or indirectly thermally integrated, lies in that at least part of which is a heat conduction means arranged to be in contact with the liquid surface of the refrigerant at the time of measurement.
[0010]
A second feature of the present invention is that an inner container filled with a refrigerant, an outer container installed so as to surround the inner container by forming a space for heat insulation, and a subject provided in the inner container A magnet that detects the generated magnetism, and at least at the time of measurement, a pickup coil configured to be positioned below the liquid level of the refrigerant, and for measuring magnetic noise in the environment, A reference coil provided in the inner container, a heat insulating material arranged so as to surround the reference coil, and the reference coil are thermally integrated with each other, and at least a part is in contact with the liquid level of the refrigerant during measurement. And a magnetic measuring device configured to remove magnetic noise in the environment picked up by the pickup coil based on the output of the reference coil Located in.
[0011]
Here, when a plurality of the reference coils are provided, the heat insulating material may be provided for each of the reference coils or may be arranged so as to cover the periphery of the reference coil group. .
[0012]
According to a third aspect of the present invention, there is provided an inner container for storing the liquid refrigerant, an outer container installed so as to surround the inner container via a gap, and the liquid refrigerant provided in the inner container at least at the time of measurement. A pickup coil that is positioned inside and detects magnetism generated by the subject, a reference coil for detecting magnetic noise provided in the inner container above the pickup coil, and directly or indirectly with the reference coil The magnetic measuring device includes a thermal conductor that is thermally integrated and at least part of which is disposed so as to be in contact with the liquid refrigerant during measurement.
[0013]
According to a fourth aspect of the present invention, there is provided an inner container that contains the liquid refrigerant, an outer container that is installed so as to surround the inner container via a gap, and the liquid refrigerant that is provided in the inner container at least at the time of measurement. A pickup coil for measuring magnetism generated by the subject positioned inside, a reference coil for measuring magnetic noise provided in the inner container above the pickup coil, and provided around the reference coil, The magnetic measurement apparatus includes a heat conductor configured so that at least a part thereof is in contact with the liquid refrigerant during the measurement.
[0014]
The heat conductor is preferably composed of a strip-shaped copper plate or a small-diameter enamel-coated copper wire.
[0015]
According to a fifth aspect of the present invention, there is provided an inner container that stores the liquid refrigerant, an outer container that is installed so as to surround the inner container via a gap, and the liquid refrigerant that is provided in the inner container at least at the time of measurement. A superconducting material that is positioned inside and is provided in the inner container above the pick-up coil and that is higher than the superconducting temperature required for the pick-up coil. A superconducting material capable of maintaining the state, and a reference coil for measuring magnetic noise, the reference coil in the outer container or in the inner container at a portion below the superconducting temperature required for the reference coil It is in the magnetic measuring device that is arranged.
[0016]
Here, it is more preferable that the pickup coil is a SQUID element that is in a superconducting state at a critical temperature of 7K or less, and the reference coil is made of a material that is in a superconducting state at a high critical temperature of 90K or less.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 5 shows a magnetic measuring device using SQUID which is currently considered. In the figure, the magnetic measuring device 1 is installed so as to surround the inner container 3 by forming a heat insulating gap 4 between the inner container 3 filled with a liquid refrigerant 2 such as helium and the inner container 3. An outer container 5, a pickup coil 6 provided in the inner container 3 for detecting weak magnetism generated by the subject, a reference coil 7 provided in the inner container 3 for measuring environmental magnetic noise, The data processing device 8 is configured to perform processing for removing magnetic noise in the environment picked up by the pickup coil 6 based on the output of the reference coil 7.
[0018]
In addition, a heat shield plate 9 is installed so as to surround the inner container 3 and absorbs radiant heat from the room temperature portion and prevents the intrusion of radiant heat into the inner container 3. The heat shield plate 9 is provided with the inner container 3. It is thermally integrated with the low temperature part of the upper part of this through the flange 10 and cooled to a temperature of about 70K or less. A laminated heat insulating material (not shown) is wound around the heat shield plate 9. On the other hand, in the space above the inner container 3, an insert 11 formed by laminating a disk-shaped foam heat insulating material such as polyurethane is disposed, and heat intrusion from the upper room temperature portion is prevented. The refrigerant 2 is replenished from the refrigerant transfer pipe 12, and the evaporated gas of the refrigerant 2 is heated while cooling the inner surface of the inner container 3 and the outer surface of the insert 11, and is released from the exhaust port 13 to the atmosphere. The insert 11, the refrigerant transfer pipe 12 and the exhaust port 13 are supported by a flange 14. The pickup coil 6 and the reference coil 7 and the data processing device 8 are connected by a measurement line 15.
[0019]
The pickup coil 6 and the reference coil 7 are cooled by the refrigerant 2 such as liquid helium or liquid nitrogen to a cryogenic state that generates superconductivity, that is, a temperature at which the superconducting state can be maintained. Further, in order to perform efficient biomagnetism measurement and highly accurate current source estimation, the pickup coil 6 is multi-channeled to measure the magnetic field distribution over a wide area in the living body. Since biomagnetism is very weak, it is buried in environmental magnetic noise and it is difficult to measure biomagnetism. Therefore, a noise removal technique is used in which the reference coil 7 that measures the magnetic noise of the environment is used and the measurement value of the reference coil 7 is subtracted from the measurement value of the pickup coil 6. The reference coil 7 is disposed on the top of the pickup coil 6 that is remote from the biomagnetic source.
[0020]
The present invention covers the periphery of the reference coil with a heat insulating material and is directly or indirectly thermally integrated with the reference coil so that at least part of the reference coil is in contact with the liquid surface of the refrigerant (for example, liquid helium) during measurement. The heat conductor is provided, and the reference coil is cooled by the lower liquid refrigerant through the heat conductor. Thereby, even if the reference coil placed apart above the pickup coil is exposed, the reference coil can be cooled to a temperature at which the superconducting state can be maintained. Therefore, a highly accurate magnetic measurement value obtained by subtracting the measurement value of the reference coil from the measurement value of the pickup coil and removing magnetic noise can be obtained.
[0021]
Furthermore, in the present invention, since the superconducting state of the reference coil can be maintained even if the reference coil is exposed from the liquid refrigerant surface, the liquid refrigerant replenishment cycle can be extended, and the liquid refrigerant such as liquid helium at the time of liquid refrigerant replenishment can be extended. Loss can be reduced. Therefore, according to the magnetic measuring device of the present invention, it is possible to reduce the operating cost.
[0022]
Specific embodiments of the present invention will be described below with reference to FIGS. In addition, the same code | symbol is used for the part which is the same as that of FIG.
[0023]
In the figure, reference numeral 6 denotes a pickup coil, which is a SQUID element made of a material such as NbTi that becomes superconductive at a critical temperature of about 7K or lower (eg, liquid helium temperature at atmospheric pressure of 4.2K), or a temperature of about 90K. It is made of a material such as YBa ₂ Cu ₃ O ₇ that becomes a superconducting state at the following high critical temperature (for example, 77 K of liquid nitrogen temperature at atmospheric pressure). 2 is a cooling medium for these SQUID elements (pickup coil 6), and liquid helium or liquid nitrogen is generally used and enclosed in the inner container 3. Reference numeral 5 denotes an outer container provided so as to surround the inner container 3 and to form a heat insulating space 4 between the inner container 3. The inside of the inner container 3 is blocked from outside air by a flange 14. Reference numeral 15 denotes a measurement lead for guiding the measurement current from the pickup coil 6 to the outside of the cryogenic vessel 100 for storing the SQUID element. The inner container 3 and the outer container 5 are made of a non-magnetic material such as a glass epoxy resin such as a glass epoxy resin in order to prevent generation of eddy current due to the measurement magnetic flux. The measuring lead 15 is connected to an external data processing device 8 and calculates a magnetic flux distribution, a generated current distribution and the like from the measured value, and performs an imaging process and the like.
[0024]
In order to reduce the generation of noise eddy current due to magnetic field fluctuation from the outer container 5, as shown in FIG. 4, a heat shield composed of a strip-shaped copper plate 9a and a small-diameter enamel-coated copper wire 9b. A plate 9 is provided in the heat insulating space 4 so as to surround the cryogenic part of the inner container 3. Further, in order to prevent intrusion of radiant heat from the outer container 5, a laminated heat insulating material (not shown) such as aluminum vapor deposition mylar is wound around the heat shield plate 9.
[0025]
As shown in FIG. 2, the pickup coil 6 is formed by winding a superconducting wire in a loop shape around a plastic coil bobbin 20 in the reverse direction. The lower end side input loop 21 measures the magnetism generated by the subject and the external magnetism entering the input loop 21 (this external magnetism is approximately the same magnitude as the magnetism generated by the subject 99), and the upper part is reversely wound. External magnetism having the same vector value as the external magnetism entering the input loop 21 is measured by the cancel loop 22 on the side. By configuring the input loop 21 and the cancel loop 22 in series, the difference, that is, the magnetism generated by the subject is measured by the superconducting loop 23. The superconducting loop 23 includes a Josephson junction that operates as a transducer that converts a weak magnetic change into a large change in output voltage.
[0026]
As shown in FIGS. 3 and 4, the reference coil 7 is configured by winding an input loop 24 around a coil bobbin 25 in a loop shape, and penetrates a magnetic shield body made of, for example, Permalloy that shields external magnetism by the input loop 24. The external magnetism that has entered the magnetic shield body is measured by the superconducting loop 23. In general, the external magnetism entering the magnetic shield body is relatively larger than the magnetism generated by the subject.
[0027]
The periphery of the reference coil 7 is covered with a heat insulating material 16 made of foamed material such as polyurethane, foamed epoxy resin, ceramic or plastic. The reference coil 7 is covered with a heat conductor 18 formed of a strip-shaped copper plate 9a and a small-diameter enamel-coated copper wire 9b that are less likely to generate eddy currents that are generated by magnetic field fluctuations and become noise. The conductor 18 is extended to the lower part, and the lower part of the heat conductor 18 is soaked in the liquid helium 2 (see FIG. 1). Further, as shown in FIG. 3, a non-magnetic heat transfer medium 26 such as wax, wax, epoxy resin, or grease is enclosed inside the heat insulating material 16, and the reference coil 7 and the heat conductor 18 are heated. Integrated.
[0028]
When the multi-channel magnetic measuring device is used for a long time, the liquid helium 2 in the inner container 3 in which the pickup coil 6 is housed evaporates due to heat penetration from the outside, and the liquid level gradually decreases. When the liquid level decreases, the temperature of the vapor layer in the upper part of the inner container 3 increases due to heat penetration from the outside and rises to about 20K. For this reason, the temperature of the reference coil 7 disposed in the upper part of the inner container 3 is heated in the vapor layer, the superconductivity of the reference coil 7 is broken, and the reference coil 7 cannot be used. However, in this embodiment, as shown in FIG. 1, even when the liquid level of the liquid helium 2 is lowered, the reference coil 7 is heated by the heat insulating material 16 from the evaporated gas having a temperature of about 20K. Is prevented. Since the lower part of the heat conductor 18 is immersed under the liquid level of the liquid helium 2, the heat transfer medium 26 is cooled via the heat conductor 18, and the entire reference coil 7 is uniformly heated below the superconducting temperature by the heat transfer medium 26. Can be cooled to. According to the present embodiment, even if the reference coil 7 placed apart from the top of the pickup coil 6 is exposed on the liquid helium liquid surface, the reference coil 7 is cooled to the superconducting temperature, and the reference value is obtained from the measured value of the pickup coil 6. The magnetic noise can be removed by subtracting the measured value of the coil 7, thereby improving the accuracy of the magnetic measured value.
[0029]
Furthermore, according to the present embodiment, since the liquid helium replenishment cycle can be extended, the liquid helium loss at the time of liquid helium replenishment can be reduced, and the operating cost of the magnetic measuring device can be reduced. In addition, although the present Example demonstrated the case where heat conductor 9a, 9b (18) was arrange | positioned in the inner peripheral part of the heat insulating material 16, even if it arrange | positions in the outer peripheral part of the heat insulating material 16, the same effect is acquired. Can do.
[0030]
Another example of the present invention is shown in FIG. In this example, the periphery of the reference coil 7 is covered with a heat insulating material 16 made of a foamed material such as polyurethane, a bubbled epoxy resin, ceramic or plastic. In addition, inside the plastic coil bobbin 25, a heat conductor 18 composed of a strip-shaped copper plate or a small-diameter enamel-coated copper wire, the upper end portion of which is thermally integrated, is disposed. Is extended to the bottom and is configured to be immersed in liquid helium 2. Further, a nonmagnetic heat transfer medium such as wax, wax, epoxy resin, or grease may be enclosed in the heat insulating material 16 so that the reference coil 7 and the heat conductor 18 are thermally integrated. According to this example, even when the liquid level of the liquid helium 2 is lowered, the heat insulating material 16 prevents the reference coil 7 from being heated from the evaporated gas having a temperature of about 20 K, and the heat conductor 18 is liquid. Since it is immersed under the liquid level of helium 2, the reference coil 7 can be directly cooled by the heat conductor 18. Therefore, the entire reference coil 7 can be uniformly cooled below the superconducting temperature, and the same effect as the embodiment of FIG. 1 can be obtained.
[0031]
Still another example of the present invention is shown in FIG. In this example, the entire upper and side portions around the reference coil 7 group are covered with a heat insulating material 27 made of foamed material such as polyurethane, foamed epoxy resin, ceramic or plastic. Inside the plastic coil bobbin, there is disposed a heat conductor 18 composed of a strip-shaped copper plate whose upper end portion is thermally integrated or a small-diameter enamel-coated copper wire, and the heat conductor 18 is extended downward. The liquid helium 2 is immersed. The periphery of the reference coil 7 is surrounded by a nonmagnetic heat transfer medium 19 such as wax, wax, epoxy resin, or grease. The reference coil 7 and the heat conductor 18 are thermally transferred through the heat transfer medium 19. Is integrated. By doing so, even when the liquid level of the liquid helium 2 is lowered, the heat insulating material 27 can prevent the reference coil 7 from being heated from the gas layer portion of the evaporative gas outside thereof, and the heat conductor 18. Is immersed under the liquid surface of the liquid helium 2, the reference coil 7 can be directly cooled by the heat conductor 18, and the entire reference coil 7 group can be uniformly cooled below the superconducting temperature. Even if only the upper part of the group of reference coils 7 is covered with the heat insulating material 27, the same effect can be obtained.
[0032]
Another example of the present invention is shown in FIG. In this example, unlike the above examples, the reference coil 7 group can be cooled without using a heat insulating material. In this example, as shown in the figure, a group of heat conductors 18 composed of strip-shaped copper plates and small-diameter enamel-coated copper wires are arranged around the group of reference coils 7 so as to extend downward, and the bottom of the heat conductors 18 group. Is immersed in liquid helium 2. With this configuration, even when the liquid level of the liquid helium 2 is at the lower part, the temperature of the evaporated gas around the reference coil 7 group can be maintained below the superconducting temperature, and the temperature of the reference coil 7 group can be reduced. It can be maintained at about 5K. With this structure, the amount of evaporation of liquid helium in the steady state slightly increases, but the liquid helium replenishment cycle is only slightly shortened. Therefore, the liquid helium replenishment cycle can be extended as compared with the conventional case, and the loss of liquid helium at the time of liquid helium replenishment can be reduced.
[0033]
Another example of the present invention is shown in FIG. This example can also cool the reference coil 28 group without using a heat insulating material. As shown in the figure, when the liquid level of the liquid helium 2 is in the lower part, the temperature of the evaporated gas around the reference coil 28 group away from the liquid level of the liquid helium 2 is about 20K. Therefore, in this example, the reference coil 28 is made of a material such as YBa ₂ Cu ₃ O ₇ that is in a superconducting state at a high critical temperature of about 90 K or less (for example, 77 K at a liquid nitrogen temperature of atmospheric pressure), and the superconducting state Can be maintained. According to this example, even if the liquid level of the liquid helium 2 is lowered, it is possible to maintain the superconducting state by using the reference coil 28 group composed of the high-temperature superconducting material. By configuring the reference coil group 28 with a high-temperature superconducting material, it is possible to install the reference coil group 28 at a location where the temperature in the upper insert material 11 is about 77 K, thereby further separating the reference coil group 29 from the biomagnetic field source. Therefore, the measurement accuracy of the biomagnetic field can be further improved. In addition, it is possible to measure a wider range of external magnetic field noise by attaching the reference coil 30 to the heat shield plate 9 cooled to a temperature of about 70K or less in a thermally integrated manner.
[0034]
【The invention's effect】
According to the present invention, since the reference coil is provided above the pickup coil, magnetic noise can be removed from the measurement value of the pickup coil, and the accuracy of the biomagnetic measurement value can be improved.
[0035]
In addition, the reference coil can be set apart from the upper part of the pickup coil, and even if the reference coil is exposed from the liquid surface of the liquid helium, the superconducting state can be maintained. Therefore, the liquid helium replenishment cycle can be extended, and the liquid helium loss at the time of liquid helium replenishment can be reduced, so that the operating cost can be reduced.
[Brief description of the drawings]
FIG. 1 is a longitudinal sectional view of a magnetic measuring device showing an embodiment of the present invention.
FIG. 2 is a diagram showing a configuration of a portion of a pickup coil 6 in FIG.
3 is a diagram showing a configuration of a portion of a reference coil 7 in FIG. 1. FIG.
4 is an enlarged perspective cross-sectional view of the reference coil shown in FIG. 3. FIG.
FIG. 5 is a longitudinal sectional view of a magnetic measuring device using SQUID which is currently considered.
FIG. 6 is a longitudinal sectional view of a magnetic measuring device showing another example of the present invention.
FIG. 7 is a longitudinal sectional view of a magnetic measuring device showing still another example of the present invention.
FIG. 8 is a longitudinal sectional view of a magnetic measuring device showing still another example of the present invention.
FIG. 9 is a longitudinal sectional view of a magnetic measuring device showing still another example of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Magnetic measuring device, 2 ... Cooling medium (liquid helium), 3 ... Inner container, 4 ... Thermal insulation space, 5 ... Outer container, 6 ... Pick-up coil, 7, 28, 30 ... Reference coil, 8 ... Data processing Device: 9 ... Heat shield plate (9a ... Copper plate, 9b ... Enamel-coated copper wire) 10, 14 ... Flange, 11 ... Insert (material), 12 ... Refrigerant transport pipe, 13 ... Exhaust port, 15 ... Measuring wire, DESCRIPTION OF SYMBOLS 16 ... Heat insulating material, 18 ... Thermal conductor, 19, 26 ... Heat-transfer medium, 20, 25 ... Coil bobbin, 21, 24 ... Input loop, 22 ... Cancel loop, 23 ... Superconducting loop, 100 ... Cryogenic temperature for SQUID element storage container.

Claims (8)

An inner container filled with a refrigerant, an outer container installed so as to surround the inner container and forming a heat insulating gap between the inner container, and the contents for detecting weak magnetism generated by the subject A pickup coil provided inside the container and a reference coil provided inside the inner container for measuring environmental magnetic noise, and the magnetic noise of the environment picked up by the pickup coil is output from the reference coil. In a magnetic measuring device configured to be removed based on
At least at the time of measurement, the pickup coil is positioned below the coolant level, and the reference coil is installed above the pickup coil.
And heat insulating means arranged so as to surround the reference coil,
A magnetic measurement apparatus comprising: heat conduction means that is directly or indirectly thermally integrated with the reference coil and arranged so that at least a part thereof is in contact with the liquid surface of the refrigerant during measurement. . An inner container filled with a refrigerant;
An outer container installed so as to surround the inner container by forming a space for heat insulation;
A pickup coil provided in the inner container for detecting magnetism generated by a subject, and at least at the time of measurement, a pickup coil configured to be positioned below the liquid level of the refrigerant;
A reference coil provided in the inner container above the pickup coil for measuring environmental magnetic noise,
A heat insulating material arranged to surround the reference coil;
A thermal conductor that is thermally integrated with the reference coil and disposed so that at least a part thereof is in contact with the liquid surface of the refrigerant during measurement, and magnetic noise in the environment picked up by the pickup coil is detected by the reference coil The magnetic measuring device is configured to be removed based on the output of. 3. The magnetic measurement apparatus according to claim 2, wherein a plurality of the reference coils are provided, and the heat insulating material is disposed so as to cover the periphery of the reference coil group. An inner container for storing the liquid refrigerant;
An outer container installed so as to surround the inner container via a gap;
A pickup coil that is provided in the inner container and detects the magnetism generated by the subject by being positioned in the liquid refrigerant at least during measurement;
A reference coil provided in the inner container above the pickup coil for detecting magnetic noise;
A magnetic measurement apparatus comprising: a heat conductor that is directly or indirectly thermally integrated with the reference coil and disposed so that at least a part thereof is in contact with the liquid refrigerant during measurement. An inner container for storing the liquid refrigerant;
An outer container installed so as to surround the inner container via a gap;
A pickup coil that is provided in the inner container and that is positioned in the liquid refrigerant at least at the time of measurement to measure magnetism generated by the subject; and
A reference coil provided in the inner container above the pickup coil for measuring magnetic noise;
A magnetic measurement apparatus comprising: a heat conductor provided around the reference coil and configured to be in contact with at least a part of the liquid refrigerant during the measurement. 6. The magnetic measuring device according to claim 2, wherein the heat conductor is formed of a strip-shaped copper plate or a small-diameter enamel-coated copper wire. An inner container for storing the liquid refrigerant;
An outer container installed so as to surround the inner container via a gap;
A pickup coil made of a superconducting material that is provided in the inner container and that is positioned in the liquid refrigerant at least at the time of measurement to measure magnetism generated by the subject;
A reference coil for measuring magnetic noise, which is provided in the inner container above the pickup coil, is composed of a superconducting material capable of maintaining a superconducting state at a temperature higher than the superconducting temperature required for the pickup coil,
The magnetic measurement apparatus according to claim 1, wherein the reference coil is disposed in the outer container or in the inner container at a portion that is equal to or lower than a superconducting temperature required for the reference coil. 8. The pickup coil according to claim 7, wherein the pickup coil is a SQUID element that is in a superconducting state at a critical temperature of 7K or less, and the reference coil is made of a material that is in a superconducting state at a high critical temperature of 90K or less. Magnetic measuring device.

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