DE1918624B2 - DEVICE FOR CONTINUOUS REFRIGERATION OF OBJECTS - Google Patents

Description

of the helium passing through the evaporator element even at higher pressures above the Helium bath reached.

It can also be favorable that the helium bath with the emerging from the evaporator element Cold gas is in heat exchange. This enables the helium bath to be cooled using the Cold content of the cold gas reached, resulting in a

If the pressure is reduced to the respective setpoint value, the length of the evaporator element can be greater

is lowered. The object to be cooled is then 3 cm. Thus, a complete evaporation is generally immersed in the bath liquid. It is
also a device for automatic refilling
a helium (II) bath under reduced pressure is known, in which two of the 15
separate helium baths from which
one cools the object (working bath), while the
other is used for refilling. (Lit .: A. Eisner,
G. Hildebrandt, G. Klipping, Dechema-Mono-

graphie, Vol. 58 [1968], pp. 9 to 16). Such a pre-20 economic operation of the device contributes direction allows the continuous cooling To a uniform cooling of the object If objects are to reach temperatures in the range, it may be useful to place an object below 2.17 ° K, but is technically very reluctant to record the object within the Manoeuvrable, as two liquid baths in the cryostat have a direct heat-conducting refrigerant circuit required and two pumps as well as two regulating 25 contact with the outer surface of the evaporator circuit required are. The element is to be arranged accordingly.

drove complicated, and there are numerous disturbances. Be useful if the object holder, which is also known from the aerospace industry as a cooling surface for other application technology, bath cryostats can be used for holding liquid purposes in cryotechnology, as in the Beger refrigerant with a refrigerant Absorbing the wall surface of the surrounding vacuum, the porous material with a large pore volume is inserted into the container or from this in the gas filling in order to fix the refrigerant in a certain part of the space of the pumped cold gas protruding depth of the container. Such devices cooling part preferably made of highly thermally conductive enable the cooling of an object on the 35 material, eg. B. made of copper. The object boiling temperature of the refrigerant - in the case of a bracket, is separated from the evaporator element, liquid helium is 4.2 ° K. Furthermore, heat- The object to be cooled is then a functional exchanger for evaporator cryostats for generating moderately outside the refrigerant circuit and is at temperatures between 4.2 and 2.5 ° K and without opening the helium part in the cryostat easily known room temperature, at which a porous 40 is accessible. It also appears to be advantageous if the sintered metal insert is used in the evaporator and accommodates a highly thermally conductive deep-freeze part through which liquid helium flows. The vacuum container consists of a porous sintered metal insert, which is a poor conductor of heat, has a large inner material, preferably stainless steel. Surface and is for helium gas as well as helium I. A device according to the invention has opposite (liquid helium at temperatures between 4.2 and 45 over known devices for cooling from 2.17 ° K) under all conditions, so that samples on temperature values below 2, 17 ° K, the refrigerant has ample advantages thanks to the use of sintered metal. It is characterized by a fan-shaped structure that is drawn in and drawn through it, as only a helium bath can be used. is applied and a pump for setting the ge-The invention is based on the task, 50 desired temperature on the object is sufficient. The one with respect to the prior art temperature of the helium bath (or the pressure on simplified apparatus for the continuous Küh- the bath) need not be kept constant, lung objects to temperatures below but may be between the normal boiling temperature 2.17 ⁰ K using a helium bath to fluctuate to the helium (4.2 ° K) and lower values, create. The distinguishing feature of the invention is 55 without affecting the target temperature of the object.

to see that a porous evaporator element with a pore size smaller than 10 ~ ⁴ cm with one of its end faces forms the bottom surface of a receptacle for the helium bath and that the

is influenced. Fluctuations in the level of the helium bath also have no effect on the object temperature. The pressure or temperature control can accordingly be carried out with simpler means than with

Length of the evaporator element is such that 60 known devices. Overall it will be one complete evaporation of the achieved by the multiplier and safer operation than with the

Liquid helium passing through to the outer surface of this element into a surrounding one Vacuum space protruding surface of the evaporator element takes place.

Such a device has compared to the known cooling devices with elements made of porous Materials have the advantage of being considerably deeper

previously common devices. Furthermore, the device is less complex due to the structure easier and cheaper to manufacture. 65 In the figures are various advantageous embodiments the invention shown; it shows

F i g. 1 shows a section through the device shown schematically with an object holder in FIG

3 4

Helium cycle on the outer surface of the exhaust gas stream symbolizing arrows at the upper end

damper element, the lifter 16 is indicated. That from the helium

2 shows a section through a section of the pre-bath 3 in the vacuum space 12 evaporating gas

direction with outside the helium circuit at one is via the exhaust pipe in the lever 16, which is also

Area element of the vacuum container arranged 5 if attached to the vacuum pump (not shown)

Object holder and is closed, pumped out. With the help of a level

F i g. 3 shows a section through the same section of the sensor 18 that the expansion valve 17 on the

Device in which a surface element of the vacuum with a storage container (not shown) for

container as a cold surface for the condensation of gases liquid helium related siphon 16

is trained. io controls the helium bath 3 in a known manner

As Fig. 1 shows, the fine-pored evaporator is refilled.

element 1 so in a receptacle 2 for the To accommodate the object to be cooled, a helium bath 3 is used that the upper end face of the object holder 19 is provided, which on the outer evaporator element 1 forms the bottom surface of the on-surface 6 of the evaporator element 1 such a container 2 . The receptacle 2 is held so that there is a good heat-conducting contact in its adjacent to the evaporator element 1 between the two parts. Depending on the type of Ma part, designed as a heat exchanger 4. terials from which the evaporator element 1 consists. The heat exchanger 4 here has the shape of a connection with the object holder 19 as a ribbed tube, the ribs 5 of which are formed with gluing, soldering or the like on the circumference. The object and horizontally offset bores 20 can be provided in the object holder 19 for generating a. It can, however, also have a different, well-thermally conductive connection, for example be formed, for example screwed, soldered or glued in as a porous sintered metal body. In any case, the heat exchanger 4 is arranged in such a way that it is suitable for materials different from that on the outer upper element 1 if the cold surface 6 of the evaporator element 1 has a pore size smaller than 10 ~ ⁴ cm, for example gas is flowed through, so that the helium bath 3 is cooled by wise aluminum silicate, aluminum oxide, carbon, the cold gas. Glass frits, sintered bodies made of metals (e.g. Ni, Ag, the receptacle 2 with the evaporator Cu) or the like. The dimensioning of the length of the evaporator element 1 is suspended from the lid 7 of the cryostat element 1 depends primarily on the im Up and surrounded by a vacuum container 8, the 30 receiving container 2 maximum expected pressure value is also carried by the cryostat cover 7. On and on the target vacuum container 8 to be set in each case on the object, a radiation protection shield 9 is heated. In particular, set at target temperatures which surrounds the predominant part of the near 2.17 ° K when certain vacuum containers 8 are exceeded and pressure values in the receiving container 2 are usually too low due to the heat exchange with the length of the vacuum container element 1, an undesired ter 8 cold gas flowing through and heat conduction, liquid escaping on the outer surface 6 is cooled to a temperature of about 100 ° K. of the evaporator element. If necessary, a plurality of analog vaporizer elements of more than 3 cm can also be used, this will certainly avoid radiation protection shields and other conventional ones.

Thermal insulation can be used. The device 40 F i g. 2 shows a section from FIG. 1 with a device is from the outer cryostat housing 10 around the other arrangement of the object holder 19. The give, which is completed by the cover 7 object holder 19 is here as a frozen in the is and can be evacuated via a shut-off valve 11, the bottom surface of the vacuum container 8 is in this way (insulating vacuum). assumes that it is from the one on the outer surface 6 in the cryostat cover 7 in the evaporating from 45 of the evaporator element 1 cold Vacuum container 8 enclosed vacuum space 12 gas flows against it and thus draining off at the setpoint temperature Exhaust pipe 13 is preferably cooled with a. The object holder 19 is off adjustable and controllable pressure regulator 14 used. a material that conducts heat well, for example Cu, A not shown is built up on this exhaust line, while the vacuum container 8 consists of one Vacuum pump connected, by means of which the 50 poorly thermally conductive material, for example Pressure within the vacuum space 12 on a stainless steel exists.

corresponding to the target temperature of the object. In this embodiment, the radiation

value is maintained. Keeping the protective shield 9 constant is useful from the vacuum housing

Pressure is done using known removable designs. Then that's in the object means by controlling the pressure regulator 14 (object to be used in the 55 holder 19 in the simplest way

F i g. 1 indicated by a control line 15) with manner by removing the cryostat housing 10 and

With the help of a reference pressure, accessible as a function of the radiation protection shield 9. The dem

the temperature of the object or the like. Parts of the device belonging to the helium cycle can be used

Different pressure regulators with a sufficiently high sensitivity do not need to be opened. to be used. 60 Fig. 3 also shows in the form of a section

In the cryostat cover 7 is also one of the another embodiment of the invention

Sealed device not shown for the sake of clarity. The bottom of the vacuum

connection screw connection forming a removable vacuum container 8, from the cold gas from the

jacket lifter 16 with relief valve 17 used. Steamer element 1 against which the flow is holding part 20 (Cu) The vacuum jacket lifter 16 should in known 65 here as a cold surface for the condensation of gases, i. H.

Way designed as a cryopump with an exhaust-gas-cooled radiation protection. Accordingly, the

be provided, which in the figure by the surrounding radiation protection shield 9 here in the area

entering liquid flow and the exiting its bottom surface in a known manner as also

Formed chevron system 21 cooled by heat conduction, and serves as an outer cryostat housing 10 for example a larger recipient that is evacuated with the aid of the cryopump.

In operation, the helium bath 3 is lifted

16 filled or topped up from the reservoir (not shown), the expansion valve

17 is actuated by hand or, more appropriately, automatically with the aid of the level sensor 18. In the vacuum container, with the aid of the vacuum pump (not shown) and the pressure regulator 14, a lower pressure value corresponding to the target temperature of the object (for example, 8.6 mm Hg for T = 1.7 ° K) is set and kept constant. The liquid helium from the bath 3, above which the pressure is higher (possibly normal pressure) than the regulated pressure in the vacuum chamber 12, now passes through the fine-pored evaporator element and evaporates completely on the outer surface 6 of the evaporator element 1. As a result of the evaporation, cooling occurs on the outer surface 6 of the evaporator element 1 until the temperature value corresponding to the set pressure value in the vacuum container 8 is reached. A temperature gradient is thus formed in the evaporator element 1 or the liquid helium contained in its pores. The cold helium gas accumulating on the outer surface 6 of the evaporator element 1 flows through the heat exchanger 4 while cooling the helium bath 3 and is pumped out via the exhaust pipe 13. The set target temperature can be kept constant for any length of time.

^{Since the helium bath 3} can be kept very small (for example 10 to 50 cm 3), the device is not a conventional bath cryostat, but has the advantages of a He evaporator cryostat. When the operation is terminated or interrupted, only minimal refrigerant losses occur, and operation can be interrupted without the loss of time caused by the evaporation of the refrigerant bath in the case of bath cryostats. This results in minimal cooling times and minimal refrigerant consumption during cooling, since no dead volumes need to be cooled. The refrigerant consumption in stationary operation is accordingly also minimal. Continuous operation of any length of time is possible due to the simple, safe mode of operation of the device.

Claims (6)

Patent claims: 1. Device for the continuous freezing of objects, preferably to temperatures below 2.17 ° K, using a refillable helium bath in a container which is partially filled with a porous material, characterized in that a porous evaporator element (1) with a pore size less than 10 ~ ⁴ cm with one of its end faces the bottom surface of a receptacle (2) for the helium bath (3) and that the length of the evaporator element (1) is dimensioned so that a complete evaporation of the evaporator element (1) to the outside Surface (6) passing liquid helium takes place on this surface (6) of the evaporator element (1) protruding into a surrounding vacuum space (12). 2. Apparatus according to claim 1, characterized in that the length of the evaporator element 1. Is taller than 3 cm. 3. Apparatus according to claim 1, characterized in that the helium bath (3) with the from the evaporator element (1) emerging cold gas is in heat exchange. 4. Apparatus according to claim 1, characterized in that an object holder (19) for Recording of the object within the refrigerant circuit in direct, heat-conducting contact is arranged with the outer surface (6) of the evaporator element (1). 5. Device according to one of the preceding claims, characterized in that the Object holder (19) than arranged in the area of the wall surface in the vacuum container (8), in the cold gas flow lying deep-freeze part is formed. 6. Apparatus according to claim 5, characterized in that the into the wall surface of the Vacuum container (8) used freezer part compared to the material of the wall parts of the Vacuum container (8) consists of a material that conducts heat well. 45 1 sheet of drawings