UA118679U - Cryostat - Google Patents

Abstract

The cryostat contains a two-stage cryo cooler, a radiation shield covering the object of cooling placed in a vacuum casing, conductive contacts, the sample mine, the working chamber, the sample holder, the upper flange, and the first stage of the cryo cooler is connected to the flange the casing is vacuum heat-insulated contact, and the second stage of the cryo-cooler is connected by thermal conductive contact with the sample shaft. All thermally conductive contacts are made in the form of flexible thermally conductive elements, and the contact of the second stage is connected to the sample shaft through the refrigerator, which is a thermally conductive pipe that tightly covers the sample shaft and is placed in its lower part above the working chamber, with the cryo cooler is fixed on flanges of vacuum housing with vibration absorbing support.

Description

A useful model belongs to the cryogenic technique and can be used for

Mössbauer and optical research of materials in the range of 4.2 K - 325 K without the use of liquid cryogenic agents, and more precisely in scientific and industrial research where minimal vibrations affect the research process.

Cryostats without the use of liquid cryoagents are cryostats with a closed cycle, in which mechanical cryocoolers are used to cool the studied samples, which require low operating costs.

The well-known cryostat "Model UAM5 RTZNI-950-IT 1.5 K" (see (per:/Llumly.|api5sot/Rhodysiv/rhodisizomegmiem//15КСииозеасусиеКеитидегагсСтуовиагазрхж)), in which a two-stage mechanical cryocooler based on a pulsation tube is used to cool the studied samples. The pulsating tube has no moving parts at the cold end, which allows to reduce vibrations to minimum values. Thus, on the second stage of the crysocooler, the vibration is 4-7 μm along the axis and 2 μm perpendicular to the axis of the cold head. Model UAMI5 RTZNI-950-I T 1.5K is a closed cycle cryostat with upper loading of the test sample into a gas medium or vacuum.

The temperature regime for the sample is created by the stages of the cryocooler and is carried out by mechanical contact in a vacuum or gas environment. The cryostat allows you to replace the sample during operation. The cryostat can be used both in scientific research and in industrial, where minimal vibrations do not affect the research process.

The disadvantage of the known design of the cryostat is that the existing mechanical contacts connecting the object of cooling with the steps of the cryocooler transmit residual vibrations to the object of cooling, which limit the scope of its application.

The design of a cryostat for a superconducting magnet without the use of liquid helium and nitrogen is known (see pEer:/sguo.gy/Ipaeh.rpr?orip-sot sopiepibazk-miemvia-13185Netii-84). Cryostat

Stguoggeee 404 is designed to study the physical properties of various samples in a magnetic field at temperatures from 4 to 300 K. The creation and maintenance of a low temperature in the working area of the cryostat is carried out due to the operation of a cryocooler based on a pulsation tube with a power of 0.5 W at 4.2 K. Superconducting the magnet is rigidly connected to the 2nd stage of the cryocooler by a copper thermal bridge, constantly maintaining a temperature of 4.2 K. Thermal

The key also connects the 2nd stage of the crysocooler and the working chamber of the sample mine. It is two coaxially placed copper tubes. When filling the space between the tubes with the heat exchange gas He-4, the thermal key has a high thermal conductivity and cools the sample to 4.2 KC. When pumping gas in the space between the tubes, the thermal switch has low thermal conductivity, which allows the temperature of the sample to be raised to 300 K without heating the superconducting magnet, since the sample shaft and the superconducting magnet are separated by a vacuum space. Cooling object: a superconducting magnet with a thermal bridge, a sample shaft with a thermal key - to reduce heat flow, covered by a copper radiation shield and placed in a vacuum jacket. The copper radiation screen is rigidly connected by a heat-conducting contact to the 1st stage of the cooler and is suspended from the upper flange of the vacuum jacket by a heat-insulating contact. The sample holder is loaded into a vertical shaft filled with He-4 gas to improve heat transfer with the second cryocooler stage.

Regulation and stabilization of the temperature of the sample is carried out using a heater and a temperature sensor installed on the sample holder. The design of the cryostat allows you to change the sample without turning off the cryocooler. A closed-loop cryostat allows you to conduct long-term studies without the use of liquid helium, which is its advantage.

The main drawback of the known design of the cryostat is the rigid connection of the cooling object with the steps of the cryocooler, which causes the transfer of residual vibration to the cooling object.

The useful model is based on the task of improving the device by changing its design, which will eliminate the transfer of residual vibration from the working stages of the cryocooler to the cooling object in the heat exchange process.

The task is solved by the fact that in the cryostat, which contains: a two-stage cryocooler, a radiation shield covering the cooling object placed in a vacuum jacket, heat-conducting contacts, a sample shaft, a working chamber, a sample holder, an upper flange, while the first stage of the cryocooler connected to the radiation shield attached to the upper flange of the vacuum casing by a heat-insulating contact, and the second stage of the cryocooler is connected by a heat-conducting contact to the sample shaft, according to a useful model, all heat-conducting contacts are made in the form of flexible heat-conducting elements, and the contact of the second stage with connected to the sample shaft through a cooler, which is a heat-conducting pipe that tightly covers the sample shaft, and is placed in its lower part above the working chamber, while the cryocooler is fixed on the upper flange of the vacuum casing with a vibration-absorbing support.

Making all heat-conducting contacts in the form of flexible heat-conducting elements compensates for the transmission of vibration from the cryocooler to the cooling object.

The contact of the second stage is connected to the sample well through the refrigerator, which is a heat-conducting pipe that tightly covers the sample well and is placed in its lower part above the working chamber. This makes it possible to maintain the temperature of the second degree (4.2 K) in the working chamber and on the sample due to gas heat exchange, without having mechanical contact with the sample, and is aimed at eliminating sample vibrations.

Placing the cryocooler, namely fixing it on the upper flange of the vacuum casing with a vibration-absorbing support, allows you to eliminate the transmission of residual vibrations to the vacuum casing. It follows from the above that all essential features of a useful model are aimed at fulfilling a technical task, namely at eliminating the transmission of vibration from the cryocooler to the cooling object.

The claimed cryostat is presented in the drawing.

The cryostat consists of the following elements: 1 - cryocooler, 2 - first stage, C - flexible heat-conducting contact, 4 - copper radiation screen, 5 - second stage, 6 - flexible heat-conducting contact, 7 - refrigerator, 8 - sample shaft, 9 - working chamber, 10 - sample holder, 11 - rod, 12 - vacuum casing, 13 - upper flange, 14 - vibration-absorbing support, 15 - inlet pipe of the sample shaft.

In the claimed cryostat, cryocooler 1 is a two-stage pulsation tube BER-062. The first stage 2 is connected by a flexible heat-conducting contact 3, with a minimal opening in the form of a loop, with a copper radiation screen 4, which maintains a temperature of 65 K at a heat load of 30 W. The copper radiation screen 4 is suspended from the upper flange 13 of the vacuum casing 12. The flexibility of the heat-conducting contact 3 provides a set of copper stranded wires in the form of a loop, and the thinner the strands of the stranded copper wires, the greater the flexibility. Therefore, in the proposed design, the flexible heat-conducting contact is made of multi-core copper wires in the form of a loop, in which the diameter of one core is 0.38 mm, which made it possible to eliminate the rigid connection of the chair cooler 2 with the copper

With a radiation screen 4. The total cross-section of the flexible heat-conducting contact is determined for each stage of the cryocooler, according to the thermal power that is removed and the maintained temperature. The second stage 5 is connected to the refrigerator 7 by a flexible heat-conducting contact b in the form of a loop, which maintains a temperature of 4.2 K at a heat load of 0.5 W. The flexible heat-conducting contact b of the second stage is structurally similar to the first one, only with its cross-section. The refrigerator 7 is a heat-conducting pipe that tightly covers the sample shaft 8 above the working chamber 9 and allows it to maintain a temperature of 4.2 K in the presence of a heat exchange gas (Ned).

There is no mechanical contact between the test sample and the refrigerator, the working temperature is maintained only due to the heat exchange gas. A sample holder 10 with a heater and a temperature sensor is installed in the working chamber 9. The sample holder 10 is attached to the rod 11, which is hermetically inserted into the sample shaft 8 and fixed in the working chamber 9. The design of the cryostat allows you to insert and remove the sample holder 10 without turning off the cryocooler. The refrigerator 7 with its flexible heat-conducting contact 6, the second stage of the cryocooler 5 is covered by a copper radiation shield 4 and placed in the vacuum casing 12. The cryocooler 1 is installed on the upper flange 13 of the vacuum casing 12 and fixed on it with a vibration-absorbing support 14. Cryostat with flexible heat-conducting contacts C and 6, made of copper stranded wires in the form of a loop, allows you to eliminate the rigid connection of the steps of the cooler with the object of cooling, which means that it eliminates the transmission of vibration from the source of cooling to the sample under study.

The cryostat is equipped with a temperature control and maintenance device (thermocontroller), pumping means (vacuum pump) and heat exchange gas (helium).

The cryostat works as follows:

After installing the sample holder 10 in the working chamber 9, it is pumped out. Then the chair cooler is set to the required temperature, upon reaching which heat exchange gas (helium) is supplied to the working chamber 9. As a result, the refrigerator 7 and the working chamber 9 are cooled with the help of a flexible heat-conducting contact 6 to a given temperature due to the heat exchange of the working chamber with the cooled second stage 5 of the cryocooler 1.

When working at high temperatures (325 K), include the heating of the sample holder 10, excluding the cooler. When using a temperature control and maintenance device (thermocontroller) of type 332 5 manufactured by LakeKShore (USA), the temperature accuracy of the samples is 50.5 K.

Thus, it can be concluded that the proposed design of the cryostat makes it possible to eliminate the residual vibration from the working stages of the cryocooler to the cooling object during its operation, and thus to use the cryostat in scientific and industrial research, where minimal vibrations affect the research process, without the use of liquid cryoagents

Claims (1)

USEFUL MODEL FORMULA A cryostat comprising a two-stage cryocooler, a radiation shield covering the cooling object housed in a vacuum jacket, thermally conductive contacts, a sample shaft, a working chamber, a sample holder, an upper flange, the first stage of the cryocooler being connected to a radiation shield attached to the upper flange of the vacuum casing is a heat-insulating contact, and the second stage of the chair cooler is connected to the sample well by a heat-conducting contact, which is characterized by the fact that all the heat-conducting contacts are made in the form of flexible heat-conducting elements, and the contact of the second stage is connected to the sample well through a refrigerator, which represents is a heat-conducting pipe that tightly covers the sample shaft and is placed in its lower part above the working chamber, while the cryocooler is fixed on the upper flange of the vacuum casing with a vibration-absorbing support.