SU1717909A1 - Portable flow optic cryostat for polarized microscope - Google Patents

Abstract

The invention relates to a low-temperature technique and can be used when conducting physical research in the temperature range from 5 to ZOOK. The purpose of the invention is to improve the usability by protecting the object of research and windows from the cryogenic condensation of gases. The cryostat contains an outer casing 1 with a lid 2 and windows 3, a heat exchanger 4 mounted with the possibility of moving the heater 5, tubes for g A-L supply and removal of the refrigerant. The cryostat is provided with cold wire 8, made in the form of a rod, one end of which is located in the heat exchanger 4, and the other end has a recess intended for installation of sample 9, and is placed outside the heat exchanger 4. Heater 5 is placed in the recess of the choled line 8, the rod of which is made the ratio of length to diameter is from 2 to 5. Radiation screen 10 is installed in case 1 of the cryostat, and quote screws 13 are placed on the wall of case 1. Cooling pipe 8 is made of a material having a higher thermal conductivity at temperature Hurray below 80K and lower thermal conductivity at higher temperatures, such as sapphire or ruby. The cold line 8 eliminates thermal deformations in the cooled parts of the cryostat, and the low temperature of the heat exchanger 4 when the sample 9 is heated maintains a high vacuum in the cryostat, which eliminates moisture condensation on the external windows of the cryostat. 1 hp f-ly, 2 ill. 1 5 8 SL C

Description

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Phys. 1

The invention relates to a low-temperature technique and can be used when conducting physical research in the temperature range from 5 to 300 K.

The purpose of the invention is to improve the usability by protecting the object of research and windows from the cryogenic condensation of gases.

FIG. 1 shows a cryostat in plan, a general view; figure 2 - section aa in figure 1.

The cryostat contains an outer casing 1 with a lid 2, windows 3, a heat exchanger 4, a heater 5 mounted for movement, pipes for supplying 6 and evacuating 7 of the refrigerant, cooling pipe 8.

The cold line 8 is made in the form of a rod, one end of which is installed in the heat exchanger 4, and the other end has a recess to accommodate the test object 9, and is located outside the heat exchanger 4.

The heater 5 is placed in the recess of the cold line 8.

The core of the cold line 8 is made with a ratio of length to diameter from two to five.

The cold line 8 is made of a material having a higher thermal conductivity at a temperature below 80K and a lower thermal conductivity at higher temperatures.

As the material of the conduit 8, for example, sapphire or ruby is used.

Inside the cryostat casing 1, a radiation shield 10 is installed, and on the wall of the casing 1 there is an electrical connector 11 for powering the heater 5, the pumping valve 12, and the adjustment screws 13.

The cryostat operates as follows.

The refrigerant is fed through the tube 6 to the heat exchanger 4 and cooled to the lowest possible temperature (5-7K), at which the thermal deformations of all the cooled parts of the cryostat reach the maximum level. Due to the high thermal conductivity of the cold line 8, the test object 9 has the temperature of the heat exchanger 4.

When the heater 5 is turned on, the temperature of the object under study 9 rises, and the temperature of the heat exchanger 4 remains unchanged, since the thermal conductivity of the cold pipe significantly decreases, which eliminates thermal deformations in the cooled parts of the cryostat and allows for precise optical measurements without additional adjustment and focusing over a wide range temperatures from 5 to 300 K.

Since the temperature of the heat exchanger 4 remains low when the test object 9 is heated, a high vacuum is maintained in the cryostat, which eliminates moisture condensation on the outer windows 3 of the cryostat.

The cold line 8 allows you to quickly change the temperature of the test object 9.

Claims (2)

1. A compact flow-through optical cryostat for a polarization microscope, comprising an outer casing with a lid and windows, a heat exchanger mounted for movement, a heater, refrigerant supply and discharge tubes, characterized in that, in order to improve ease of use by protecting the object of research and windows from cryocondensation of gases, the cryostat is equipped with a cooling pipe made in the form of a rod, one end of which is installed in the heat exchanger, and the other end has a recess intended for ovki sample and placed outside the heat exchanger, a heater situated in the recess holodoprovoda, holodoprovoda rod is made with a ratio of length to diameter 2-5, wherein holodoprovod made of a material having a high thermal conductivity at a temperature below 80 K and a low thermal conductivity at higher temperatures. 2. A cryostat according to claim 1, characterized in that the cold line is made of sapphire or ruby.