CN211742688U - Compact superconductive neutron polarization turner - Google Patents

Abstract

The utility model relates to a neutron polarization technical field, concretely relates to compact superconductive neutron polarization turner, it includes vacuum thermostat, superconductive diamagnetic body subassembly and direction magnetic field subassembly. The superconducting diamagnetic body component is arranged in the vacuum thermostat, the vacuum thermostat is used for providing a vacuum low-temperature environment for the superconducting diamagnetic body component, so that the superconducting diamagnetic body component forms a Mysner diamagnetic layer in the vacuum thermostat, the superconducting diamagnetic body component is combined with the guiding magnetic field component, and the front and back guiding magnetic fields of the superconductor are divided through the superconducting diamagnetic effect; the guiding magnetic field assembly is arranged at the periphery of the vacuum thermostat and used for forming two guiding magnetic fields with opposite magnetic field directions on two sides of the Meissner diamagnetic layer, and the guiding magnetic fields are used for guiding the polarization of neutrons passing through the guiding magnetic fields and enabling the polarization of the neutrons passing through the Meissner diamagnetic layer to be reversed. When the neutron polarization turner of this embodiment is adopted to turn over the polarization of neutron, easy operation, stable performance and turnover efficiency are high.

Description

Compact superconductive neutron polarization turner

Technical Field

The utility model relates to a neutron polarization technical field, concretely relates to compact superconductive neutron polarization turner.

Background

Neutrons have the characteristics of no electricity, magnetic moment and strong penetrability, can distinguish light elements, isotopes and adjacent elements, and are a powerful means for exploring the microstructure of substances. The polarized neutrons will further exert their advantages and be widely applied in many fields such as condensed physical and chemical, nano material, protein and biological, industrial nondestructive deep flaw detection, etc. In a polarized neutron experiment, the polarization of neutrons needs to be reversed to measure the proportion of different polarization states of the neutrons in the total beam current, which is necessary for calculating the neutron polarizability. The device for realizing polarization reversal is called a polarization reverser, and the current multi-wavelength neutron polarization reverser mainly depends on two modes of radio frequency alternating magnetic field modulation and current layer magnetic field reversal. The low-temperature superconductor polarization inverter is an optimized design of current layer magnetic field inversion, and realizes large-scale inversion by accurately constraining a magnetic field through complete diamagnetism of a superconductor. However, when the polarization of neutrons is reversed by adopting the existing polarization reversing device, the technical problems of low neutron transmittance, low reversing efficiency and low stability exist.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problems of low neutron transmissivity, low turnover efficiency and low stability when the polarization of neutrons is turned over by adopting the conventional polarization turner, the compact superconducting neutron polarization turner is provided.

A compact superconducting neutron polarization inverter comprises a vacuum thermostat, a superconducting diamagnetic body component and a guiding magnetic field component;

the superconducting diamagnetic body component is arranged in the vacuum thermostat, and the vacuum thermostat is used for providing a vacuum low-temperature environment for the superconducting diamagnetic body component, so that the superconducting diamagnetic body component forms a Mysner diamagnetic layer in the vacuum thermostat;

the guiding magnetic field assembly is arranged at the periphery of the vacuum thermostat and used for forming two guiding magnetic fields with opposite magnetic field directions on two sides of the Meissner magnetic resisting layer, and the guiding magnetic fields are used for guiding the polarization of neutrons passing through the guiding magnetic fields and enabling the polarization of the neutrons passing through the Meissner magnetic resisting layer to be reversed.

The vacuum thermostat comprises an accommodating cavity, and refrigerating equipment and vacuumizing equipment which are arranged on the accommodating cavity;

the superconducting diamagnetic body component is arranged in the containing cavity, the refrigerating device is used for providing a refrigerating source, so that the temperature of the superconducting diamagnetic body component in the containing cavity reaches below a phase-change temperature, and the vacuumizing device is used for vacuumizing the containing cavity to enable the containing cavity to be in a vacuum state.

The superconducting diamagnetic body assembly comprises a heat conducting seat, a heat conducting frame and a superconductor film;

the heat conduction seat is used for being fixedly connected with a heat conduction part of the refrigeration equipment, one end of the heat conduction frame is fixed on the heat conduction seat, the superconductor film is fixed in the heat conduction frame, and the heat conduction seat and the heat conduction frame are used for transmitting low temperature emitted by the heat conduction part to the superconductor film, so that the superconductor film is subjected to phase change to form the Maifaner diamagnetic layer.

The superconducting diamagnetic body assembly further comprises heat shields, wherein the heat shields are arranged on two sides of the superconductor film and used for isolating heat of the surrounding environment and avoiding heat radiation of the heat in the surrounding environment to the superconductor film.

The first magnetic field assembly and the second magnetic field assembly are respectively arranged outside two opposite side surfaces of the accommodating cavity and are respectively positioned on two sides of the superconductor film and used for forming a first guiding magnetic field and a second guiding magnetic field, and the magnetic field directions of the first guiding magnetic field and the second guiding magnetic field are opposite.

The first magnetic field assembly and the second magnetic field assembly respectively comprise a mounting frame, two magnetic poles and two coils, the two magnetic poles are respectively arranged on two opposite inner surfaces in the mounting frame, and the two coils are respectively sleeved on the two magnetic poles.

Furthermore, the superconducting thin film cooling device further comprises a magnetic field shielding groove, the accommodating cavity is detachably sleeved in the magnetic field shielding groove, and the magnetic field shielding groove is used for shielding an external magnetic field in the process of cooling the superconducting thin film.

A neutron penetrating part is arranged on one group of opposite surfaces, close to the first magnetic field assembly and the second magnetic field assembly, of the accommodating cavity and used for allowing neutrons to penetrate through the neutron penetrating part;

the first magnetic field component, the second magnetic field component, the superconductor thin film, and the center of the neutron transit portion are on the same straight line.

Furthermore, the superconducting device also comprises a temperature sensor arranged on the heat conducting seat or the heat conducting frame and used for measuring the temperature information of the superconductor film.

The refrigerating equipment comprises a refrigerator, a compressor, a temperature controller and a water chiller;

the refrigerator is arranged on the upper end face of the accommodating cavity, the heat conducting part of the refrigerator penetrates through the upper end face of the accommodating cavity to be arranged in the accommodating cavity, the refrigerator is further sleeved with a vacuum cover, the vacuum cover is communicated with the inside of the accommodating cavity, and the joint of the vacuum cover and the accommodating cavity and the joint of the vacuum cover and the refrigerator are hermetically connected;

the vacuum cover is provided with an electrical connector and a vacuumizing interface, and the temperature sensor is connected with the electrical connector; the electrical connector is used for connecting a temperature control instrument, and the vacuum interface is used for connecting the vacuumizing equipment; the refrigerator is connected with the compressor through a pipeline, and the water chiller is connected with the compressor through a pipeline.

The compact superconducting neutron polarization inverter according to the embodiment comprises a vacuum thermostat, a superconducting diamagnetic body assembly and a guiding magnetic field assembly. The superconducting diamagnetic body component is arranged in the vacuum thermostat, and the vacuum thermostat is used for providing a vacuum low-temperature environment for the superconducting diamagnetic body component, so that the superconducting diamagnetic body component forms a Mysner diamagnetic layer in the vacuum thermostat; the guiding magnetic field assembly is arranged at the periphery of the vacuum thermostat and used for forming two guiding magnetic fields with opposite magnetic field directions on two sides of the Meissner diamagnetic layer, and the guiding magnetic fields are used for guiding the polarization of neutrons passing through the guiding magnetic fields and enabling the polarization of the neutrons passing through the Meissner diamagnetic layer to be reversed. When the neutron polarization turner of this embodiment is adopted to overturn the polarization of neutron, easy operation, stable performance and upset are efficient, and whole small simultaneously, occupation space is little.

Drawings

Fig. 1 is a schematic overall structure diagram of an inverter according to an embodiment of the present application;

FIG. 2 is a schematic structural diagram of the inverter according to the embodiment of the present application in an assembled state;

FIG. 3 is a schematic structural view of the inverter of the embodiment of the present application in another assembled state;

FIG. 4 is an exploded view of a superconducting diamagnetic assembly according to an embodiment of the present application;

FIG. 5 is a schematic diagram of the overall structure of a superconducting diamagnetic body assembly according to an embodiment of the present application;

FIG. 6 is an exploded view of a guidance field assembly according to an embodiment of the present application;

fig. 7 is a schematic view of the overall structure of the guidance field assembly according to the embodiment of the present application.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings. Wherein like elements in different embodiments are numbered with like associated elements. In the following description, numerous details are set forth in order to provide a better understanding of the present application. However, those skilled in the art will readily recognize that some of the features may be omitted or replaced with other elements, materials, methods in different instances. In some instances, certain operations related to the present application have not been shown or described in detail in order to avoid obscuring the core of the present application from excessive description, and it is not necessary for those skilled in the art to describe these operations in detail, so that they may be fully understood from the description in the specification and the general knowledge in the art.

Furthermore, the features, operations, or characteristics described in the specification may be combined in any suitable manner to form various embodiments. Also, the various steps or actions in the method descriptions may be transposed or transposed in order, as will be apparent to one of ordinary skill in the art. Thus, the various sequences in the specification and drawings are for the purpose of describing certain embodiments only and are not intended to imply a required sequence unless otherwise indicated where such sequence must be followed.

The numbering of the components as such, e.g., "first", "second", etc., is used herein only to distinguish the objects as described, and does not have any sequential or technical meaning.

The vacuum thermostat in the embodiment of the present application refers to a device for providing a vacuum and low-temperature reaction environment for inversion of polarized neutrons, and in addition, neutrons in the embodiment refer to polarized neutrons.

The first embodiment is as follows:

referring to fig. 1, the present embodiment provides a compact superconducting neutron polarization inverter, which includes a vacuum thermostat, a superconducting diamagnetic body assembly, and a guiding magnetic field assembly; the superconducting diamagnetic body component is arranged in the vacuum thermostat, the vacuum thermostat is used for providing a vacuum low-temperature environment for the superconducting diamagnetic body component, so that the superconducting diamagnetic body component generates phase change in the vacuum thermostat, a Mysner diamagnetic layer is further formed in the vacuum thermostat, the Mysner diamagnetic layer has a magnetic field segmentation function, and in the vacuum thermostat, the superconducting diamagnetic body segments magnetic fields on the front surface and the rear surface into two mutually irrelevant parts due to the Mysner effect. The guiding magnetic field assembly is arranged at the periphery of the vacuum thermostat and used for forming two guiding magnetic fields with opposite magnetic field directions on two sides of the Meissner diamagnetic layer, and when neutrons pass through the two guiding magnetic fields, the guiding magnetic fields are used for guiding the polarization of the neutrons passing through the guiding magnetic fields and enabling the polarization of the neutrons passing through the Meissner diamagnetic layer to be reversed under the action of the guiding magnetic field with the opposite magnetic field direction. The superconducting diamagnetic body component is combined with the guiding magnetic field component, and the front and back guiding magnetic fields of the superconductor are divided through the superconducting diamagnetic effect to form the complete non-adiabatic transformation of neutron polarization from the front surface to the back surface of the superconductor within 200 nm. Finally, the reversal of the direction of the guide magnetic field is realized by the current control of the guide magnetic field assembly, the neutron polarization overturning is completed in the heat insulation connection with the guide field of the neutron spectrometer, and the neutron polarization overturning device of the embodiment is simple in operation, stable in performance and high in overturning efficiency when the neutron polarization overturning device overturns the polarization of neutrons.

As shown in fig. 2 and 3, the vacuum thermostat of the present embodiment includes an accommodating cavity 11, and a refrigeration device and a vacuum pumping device which are disposed on the accommodating cavity 11, wherein a superconducting diamagnetic body assembly is disposed in the accommodating cavity 11, the refrigeration device is configured to provide a refrigeration source, and to conduct a low temperature to the superconducting diamagnetic body assembly through a heat conduction component, so that a temperature of the superconducting diamagnetic body assembly in the accommodating cavity reaches a temperature below a phase transition temperature, the superconducting diamagnetic body assembly undergoes a phase transition in the vacuum thermostat, and a meissner diamagnetic layer is formed in the vacuum thermostat, and the meissner diamagnetic layer has a function of magnetic field segmentation. The vacuumizing equipment is used for vacuumizing the accommodating cavity 11 to enable the accommodating cavity 11 to be in a vacuum state, and a stable environment is provided for the polarization overturning process of neutrons.

As shown in fig. 4, the superconducting diamagnetic body assembly of the embodiment includes a heat conducting base 21, a heat conducting frame 22, and a superconductor film 23, where the heat conducting base 21 is used to be fixedly connected with a heat conducting portion of a refrigeration device, the refrigeration device of the embodiment selects a pulse tube refrigerator, one end of the heat conducting frame 22 is fixed on the heat conducting base 21 by a screw, the superconductor film 23 is fixed in the heat conducting frame 22 by a screw, and the heat conducting base 21 and the heat conducting frame 22 are used to transfer low temperature emitted by the heat conducting portion to the superconductor film 23, so that the superconductor film 23 undergoes phase change to form a meissner diamagnetic layer, and the meissner diamagnetic layer has a function of magnetic field division.

Further, heat radiation from the surrounding environment to the superconductor thin film 23 is avoided. The superconducting diamagnetic body assembly of the embodiment further comprises the heat shields 24, after the superconductor thin film 23 is installed in the heat conducting frame 22, the two heat shields 24 are also fixed on the heat conducting frame 22 through screws, the heat shields 24 are positioned on two sides of the superconductor thin film 23, and the heat shields 2 play a role of heat shielding, so that heat radiation of heat in the environment to the superconductor thin film 23 can be reduced, and stable working performance of the superconductor thin film 23 in a low-temperature environment is ensured.

As shown in fig. 6 and 7, the guiding magnetic field assembly includes a first magnetic field assembly and a second magnetic field assembly, the first magnetic field assembly and the second magnetic field assembly are respectively arranged outside two opposite side surfaces of the accommodating cavity 11 and respectively located on two sides of the superconductor thin film 23 and are used for forming a first guiding magnetic field and a second guiding magnetic field, the magnetic field directions of the first guiding magnetic field and the second guiding magnetic field are opposite and respectively located outside two opposite side surfaces of the accommodating cavity 11, when a neutron passes through the first guiding magnetic field, the polarization direction of the neutron under the guidance of the first guiding magnetic field is the same as the magnetic field direction of the first guiding magnetic field, after the superconductor thin film 23 forms a barrier for isolating the magnetic field, the first guiding magnetic field cannot pass through the superconductor thin film 23 to affect the second guiding magnetic field, after the neutron passes through the superconductor thin film 23, under the guidance of the second guiding magnetic field, the polarization direction of the neutron is opposite to the magnetic field direction of the second guiding magnetic field, so that the inversion of the neutron polarization is completed.

Wherein, first magnetic field subassembly and second magnetic field subassembly's structure is the same, it is different only that the magnetic field direction that it formed, first magnetic field subassembly and second magnetic field subassembly all include an installing frame 31 in this embodiment, two magnetic poles 32 and two coils 33, two magnetic poles 32 set up respectively on two relative internal surfaces in installing frame 31, two coils 33 suit respectively on two magnetic poles 32, let in current on two magnetic poles 32, can make first magnetic field subassembly and second magnetic field subassembly produce the magnetic field along specific direction, the current direction who lets in on magnetic pole 32 is opposite in first magnetic field subassembly and the second magnetic field subassembly, can make the first direction magnetic field of production and the direction opposite in second direction magnetic field.

Further, the inverter further comprises a magnetic field shielding groove 4, the accommodating cavity 11 can be sleeved in the magnetic field shielding groove 4, the magnetic field shielding groove 4 is used for shielding an external magnetic field in the process of cooling the superconductor film 23, when the superconductor film 23 is cooled to be subjected to phase change, the magnetic field shielding groove is taken out of the accommodating cavity 11, the first magnetic field assembly and the second magnetic field assembly are electrified, and then polarized neutrons are released.

Further, in this embodiment, a neutron passing portion is disposed on a group of opposite surfaces of the accommodating cavity 11 close to the first magnetic field assembly and the second magnetic field assembly, and is used for passing neutrons. The neutron of this embodiment passes the portion and includes sapphire piece 12 and sapphire clamp 13, and sapphire clamp 13 is used for fixing sapphire piece 12 on two sides that hold cavity 11, and sapphire piece 12 and sapphire clamp 13 are vacuum seal with holding cavity 11 and are sealed to guarantee to hold in the cavity 11 for vacuum environment.

Wherein the centers of the first magnetic field component, the second magnetic field component, the superconductor thin film 23, and the two neutron passing parts are on the same straight line.

Further, the inverter in this embodiment further includes a temperature sensor 25 disposed on the heat conducting base 21, the temperature sensor 25 is used for measuring the temperature information of the superconductor film 23, and in other embodiments, the temperature sensor 25 may also be disposed on the heat conducting frame 22.

The accommodating cavity 11 of the present embodiment is in a cube shape, the neutron penetration portion is disposed at the center of the left and right side surfaces of the accommodating cavity, two surfaces of the superconductor film 23 also face the two neutron penetration portions, and the first magnetic field assembly and the second magnetic field assembly are disposed on two sides of the two neutron penetration portions. The magnetic field shielding groove 4 is a cubic groove, the upper end of the magnetic field shielding groove is open, and the magnetic field shielding groove 4 is detachably sleeved outside the accommodating cavity 11.

The refrigeration equipment of the embodiment comprises a refrigerator 14, a compressor, a temperature controller and a water chiller; the refrigerator 14 is arranged on the upper end face of the accommodating cavity 11, the heat conduction part (namely, the cold head of the refrigerator 14) of the refrigerator passes through the upper end face of the accommodating cavity 11 and is arranged in the accommodating cavity 11, the refrigerator is further sleeved with a vacuum cover, the vacuum cover 17 is communicated with the inside of the accommodating cavity 11, the joint of the vacuum cover 17 and the accommodating cavity 11 and the joint of the vacuum cover 17 and the refrigerator 14 are in sealing connection through vacuum sealing rings, and therefore a sealed vacuum environment is formed inside the vacuum cover 17 and the accommodating cavity 11. The vacuum cover 17 is provided with an electrical connector 15 and a vacuum-pumping interface 16, and the lead of the temperature sensor 15 is connected with the electrical connector 15 after being wound along the refrigerator 14. The electrical connector 15 is used for connecting a temperature controller, and the temperature controller can monitor the temperature information of the superconducting diamagnetic body assembly in real time according to the temperature value acquired by the temperature sensor 15. The vacuum interface 16 is used for connecting a vacuum-pumping device to vacuum the accommodating cavity 11 and the cavity in the vacuum cover 17. The refrigerator 14 is connected to the compressor through a pipe, and the chiller is connected to the compressor through a pipe to supply cooling water to the compressor.

Specifically, in the embodiment, the superconductor film 23 is a second type of superconductor Yttrium Barium Copper Oxide (YBCO) film which is commercialized at present, the thickness of the superconductor film is 200nm, the superconductor film is vapor-deposited on a sapphire substrate with the thickness of 0.5mm, the critical temperature of the YBCO film is about 90K, and the superconductor film is highly transparent to neutrons, so that the transmittance of the neutrons is ensured. The YBCO film is clamped and fixed between the two heat conducting frames 22, the heat conducting frames 22 adopt oxygen-free copper frames with high heat conductivity, the YBCO film and the cryogenic refrigerator are connected by means of the good heat conductivity of the copper frames, and the good cryogenic conduction is ensured. In order to reduce the heat radiation of the ambient environment to the YBCO film, heat shields 24 are arranged on two sides of the YBCO film, and the heat shields 24 are 0.5mm aluminum heat shields, namely, two pieces of aluminum heat shields with the thickness of 0.5mm are respectively arranged on two sides of the YBCO film for heat insulation. The heat shield 24, the heat conducting frame 22 and the YBCO film are fixed together by screws and are tightly connected with the heat conducting base 21. The heat conducting seat 21 is provided with a thermometer for measuring the temperature of the superconducting diamagnetic body assembly, the heat conducting seat 21 is fastened on the cold head of the pulse tube refrigerator 14 through screws, and an indium sheet is additionally arranged at the joint of the heat conducting seat 21 and the cold head of the pulse tube refrigerator 14 to enhance heat conduction. Meanwhile, in order to enhance the measurement accuracy of the thermometer, the thermometer is coated with a thermal grease and then fastened to the thermal conduction base 21 with screws.

Specifically, the refrigerator of the present embodiment is a japanese Ulvac pulse tube refrigerator, the model is PDC08, the lowest temperature is 40K, and the refrigeration power is 5W at 77K. The material of the accommodating cavity 11 in this embodiment is 6061 aluminum, the thickness is 5mm, the accommodating cavity 11 and the refrigerator and the vacuum cover 17 are sealed by vacuum sealing rings, and the upper end surface of the vacuum cover 1 is provided with an electrical connector socket and a KF16 vacuum port. Sapphire sheets with the thickness of 2mm are arranged on the left side and the right side so as to ensure high neutron transmittance and reduce the back bottom. In the cooling process, a magnetic field shielding groove 4 is required to be sleeved outside the accommodating cavity 11, the magnetic field shielding groove 4 is made of permalloy, the permalloy is a high-permeability alloy and can shield a magnetic field and prevent magnetic retention in the YBCO film in the cooling process.

Wherein the mounting frames 31 of the first and second magnetic field assemblies are permalloy frames. The pole 32 is mounted on a permalloy frame and is wound with a coil 33 on the upper side. After being electrified, a uniform magnetic field with the size of more than 20Gs can be generated between the two magnetic poles 32, and the magnetic field range is more than 40mm multiplied by 40 mm. The design of the magnetic field matching with the YBCO film achieves the mirror symmetry of the magnetic fields at two ends of the superconducting diamagnetic surface, and the positive and negative conversion of the guide field is realized through the current reversal. The switched-field assembly magnetic field described in this patent is calculated by field simulation using a finite element method to ensure that the magnetic field generated by the electromagnet has sufficient strength and uniformity at the surface of the superconductor.

The superconducting polarization inverter in the embodiment is firstly installed and connected, and the installation process is as follows:

firstly, the pulse tube refrigerator 14 is installed on the vacuum cover 17, then the heat insulation cover 24, the heat conduction frame 22 and the YBCO film are aligned and compressed in sequence and are fastened by bolts penetrating through corresponding hole sites. The assembled assembly is then screwed onto the heat conducting base 21 with a thin indium sheet laminated therebetween. After the thermometer is coated with the thermal grease, it is fastened to the thermal pad 21 with screws. The thermometer lead is wrapped around the refrigerator 14 and soldered to the electrical connector 15 of the upper vacuum enclosure.

Sapphire sheet 12 is placed in sapphire clamp 13, the clamp is fastened to the left side and the right side of containing cavity 11 through screws, and the sapphire sheet 12 and the containing cavity 11 are sealed through vacuum sealing rings. The vacuum cap 17 is attached to the receiving chamber 11 by screws.

After the two magnetic poles 32 are uniformly wound with coils, the two magnetic poles are installed on the permalloy installation frame 31, and after the two magnetic poles are electrified, a uniform guiding magnetic field can be generated.

The system can be installed on the polarized neutron beam for use after being assembled. Firstly, a helium pipe and a driving power line of a refrigerator are connected with a compressor, and a cooling water pipe of the compressor is connected to a water chiller.

The electrical interface 15 is connected to a Lakeshore 336 temperature controller through a signal wire, and then a bellows is connected with a vacuum interface 16 and a vacuum pump set, so as to vacuumize the system to below 10^ -3 Pa. And after the vacuum degree is reached, a water cooler and a compressor are started to cool the system. In the system cooling process, the magnetic field shielding groove 4 is sleeved on the accommodating cavity 11, so that the magnetic retention in the YBCO film in the cooling process is prevented. After the temperature had dropped to 50K and stabilized, the permalloy magnetic field shield bath 4 was removed. All sealing positions of the accommodating cavity 11 are sealed by vacuum sealing rings. In order to reduce the waiting time on the beam line, the temperature of each component in the accommodating cavity 11 can be pre-reduced in advance.

After power is supplied to the first magnetic field assembly and the second magnetic field assembly, two magnetic fields which are parallel to the YBCO film and have opposite directions are generated. Through a plurality of tests, the turner of the embodiment can realize that the turning efficiency is more than 99 percent and realize

The above full wavelength flips.

Compared with similar foreign equipment, the neutron polarization turner provided by the embodiment has the advantages of compact structure, easiness in operation, stable performance and higher turning efficiency. The anti-magnetism application of the superconductor original paper is realized in the integral design, and the occupied space of the integral turner is compressed practically. The practical design is realized by the combined use of a specially designed low-temperature vacuum system and a matched guiding magnetic field. The finished compact superconducting polarization inverter has the overall size of 338.5mm multiplied by 213mm multiplied by 233 mm, and simultaneously adopts a small-volume closed-cycle refrigerator and an integrated vacuum pump set, so that the requirement and the space occupation of auxiliary equipment are reduced to the maximum extent. Finally, the universal polarization turning equipment with high efficiency, easy installation, simple operation and low maintenance cost is achieved.

The compact neutron polarization turner and the matched guide magnetic field provided by the embodiment realize simple deployment of the superconductor Meissner effect on a neutron spectrometer, so that a set of efficient polarization turner with low maintenance, less consumption, simple installation and convenient operation is designed. The low-temperature superconducting polarization inverter is a basic element of a low-temperature superconducting neutron device, the development of the technology has guiding and verifying significance for other complex neutron polarization regulation and control equipment based on the superconducting technology in future in China, and meanwhile, the technical blank in the design aspect of the polarization inverter in China is filled.

It is right to have used specific individual example above the utility model discloses expound, only be used for helping to understand the utility model discloses, not be used for the restriction the utility model discloses. To the technical field of the utility model technical personnel, the foundation the utility model discloses an idea can also be made a plurality of simple deductions, warp or replacement.

Claims (10)

1. A compact superconducting neutron polarization inverter is characterized by comprising a vacuum thermostat, a superconducting diamagnetic body component and a guiding magnetic field component;

the superconducting diamagnetic body component is arranged in the vacuum thermostat, and the vacuum thermostat is used for providing a vacuum low-temperature environment for the superconducting diamagnetic body component, so that the superconducting diamagnetic body component forms a Mysner diamagnetic layer in the vacuum thermostat;

the guiding magnetic field assembly is arranged at the periphery of the vacuum thermostat and used for forming two guiding magnetic fields with opposite magnetic field directions on two sides of the Meissner magnetic resisting layer, and the guiding magnetic fields are used for guiding the polarization of neutrons passing through the guiding magnetic fields and enabling the polarization of the neutrons passing through the Meissner magnetic resisting layer to be reversed.

2. The neutron polarization inverter of claim 1, wherein the vacuum thermostat comprises a receiving cavity and a refrigeration device and an evacuation device disposed on the receiving cavity;

the superconducting diamagnetic body component is arranged in the containing cavity, the refrigerating device is used for providing a refrigerating source, so that the temperature of the superconducting diamagnetic body component in the containing cavity reaches below a phase-change temperature, and the vacuumizing device is used for vacuumizing the containing cavity to enable the containing cavity to be in a vacuum state.

3. The neutron polarization inverter of claim 2, wherein the superconducting diamagnetic body assembly comprises a thermally conductive base, a thermally conductive frame, a superconductor film;

the heat conduction seat is used for being fixedly connected with a heat conduction part of the refrigeration equipment, one end of the heat conduction frame is fixed on the heat conduction seat, the superconductor film is fixed in the heat conduction frame, and the heat conduction seat and the heat conduction frame are used for transmitting low temperature on the heat conduction part to the superconductor film, so that the superconductor film is subjected to phase change to form the Maifaner diamagnetic layer.

4. The neutron polarization inverter of claim 3, wherein the superconducting diamagnetic assembly further comprises heat shields disposed on either side of the superconductor film for insulating thermal radiation from an environment surrounding the superconductor film.

5. The neutron polarization inverter of claim 3, wherein the guiding magnetic field assembly comprises a first magnetic field assembly and a second magnetic field assembly, the first magnetic field assembly and the second magnetic field assembly being respectively configured to be disposed outside of two opposite sides of the receiving cavity and respectively located on two sides of the superconductor thin film for forming a first guiding magnetic field and a second guiding magnetic field, the first guiding magnetic field and the second guiding magnetic field having opposite magnetic field directions.

6. The neutron polarization inverter of claim 5, wherein the first and second magnetic field assemblies each comprise a mounting frame, two magnetic poles respectively disposed on two opposing interior surfaces within the mounting frame, and two coils respectively sleeved over the two magnetic poles.

7. The neutron polarization inverter of claim 3, further comprising a magnetic field shielding slot, wherein the magnetic field shielding slot is detachably sleeved outside the accommodating cavity and is used for shielding an external magnetic field during the cooling process of the superconductor film.

8. The neutron polarization inverter of claim 5, wherein a set of opposing faces of the containment chamber proximate to the first and second magnetic field assemblies are each provided with a neutron pass-through for neutron pass-through;

the first magnetic field component, the second magnetic field component, the superconductor thin film, and the center of the neutron transit portion are on the same straight line.

9. The neutron polarization inverter of claim 3, further comprising a temperature sensor disposed on the heat conducting base or the heat conducting frame for measuring temperature information of the superconductor film.

10. The neutron polarization inverter of claim 9, wherein the containment cavity is cube-shaped, and the refrigeration equipment comprises a refrigerator, a compressor, a temperature controller, and a chiller;

the refrigerator is arranged on the upper end face of the accommodating cavity, the heat conducting part of the refrigerator penetrates through the upper end face of the accommodating cavity to be arranged in the accommodating cavity, the refrigerator is further sleeved with a vacuum cover, the vacuum cover is communicated with the inside of the accommodating cavity, and the joint of the vacuum cover and the accommodating cavity and the joint of the vacuum cover and the refrigerator are hermetically connected;

the vacuum cover is provided with an electrical connector and a vacuumizing interface, and the temperature sensor is connected with the electrical connector; the electrical connector is used for connecting a temperature control instrument, and the vacuum interface is used for connecting the vacuumizing equipment; the refrigerator is connected with the compressor through a pipeline, and the water chiller is connected with the compressor through a pipeline.

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