SU815424A1 - Cryostat - Google Patents

Description

(54) CRYOSTAT

I

This invention relates to a cryogenic technique and concerns the construction of cryostats for the storage of cryogenic products.

A cryotisate is known that contains an outer shell, an inner vessel, a vacuum vacuum insulation, and an adsorbent. In such cryostats, the screen-vacuum thermal insulation is applied directly to the surface of the inner vessel, with the shell of which the adsorbent has thermal contact to ensure its operation and maintain a vacuum in the thermal insulation cavity 1.

However, during the operation of cryostats, during their manufacture and transportation, the smallest particles of adsorbent (dust) fall on the insulation screens and reduce their reflectivity, the device’s disadvantage is also the loss of thermal insulation efficiency.

Also known is a cryostat containing an outer shell, an inner vessel with supporting elements, an adsorption pump mounted between the shell and the vessel, screen-vacuum insulation and fixed on the inner vessel, equipped with a counting cover 2.

A disadvantage of the known cryostat is that during operation it is constantly encountered that sticking, compaction and vacuum-tight fit (wrap) of the perforated part of the housing of the adsorption pump are adjacent to adjacent layers of screen-vacuum insulation made, for example, of polyethylene terephthalate film, duplicated with glass veil or glass paper. As a rule, 20-30 layers are subjected to this.

INSULATIONS adjacent to the housing of the adsorption pump. Such compaction, sticking and wrapping of the perforated part of the casing of the adsorption pump is due to the fact that during the process of filling the vessel with a cryogenic product, the adsorption pump starts to work, and due to the pressure differential between the space surrounding the adsorbent and the interlayer gaps of the insulation, sealing and wrapping occur. perforated part of the housing of the adsorption pump with sealing holes in the pump housing, and this, in turn, creates additional resistance and hinders the passage of molecules and from heat-insulating space (from under layers

screens) to the adsorbent. As a result of this resistance, the vacuum in the insulation layers is much worse than near the adsorption pump, and this leads to an incomplete use of the heat-shielding properties of the screen but vacuum insulation, which is known to work effectively with a vacuum of 10 ~ iOt lOf-mm Hg Art.

The purpose of the invention is to ensure the efficiency of thermal insulation of a cryostat by improving the working conditions of the adsorption pump.

This goal is achieved by the fact that the inner vessel is provided with a layer of porous material placed between the adsorption pump and the screen-vacuum thermal insulation.

In addition, a layer of porous material is also located along the supporting elements.

The introduction of a buffer layer between the adsorption pump and the isolation of the fibrous material layer prevents the creation of resistance for the passage of gas molecules to the adsorbent and is like a battery of these molecules directly in front of the adsorption pump. This technical solution has allowed for the efficient operation of the insulation by improving the pumping of gas molecules from under the insulation layers.

The drawing shows a cryostat, a longitudinal section.

The cryostat consists of the following main components and parts: the outer shell 1, the inner vessel 2, the screen-vacuum thermal insulation 3 and the adsorption pump 4. The adsorption pump 4 is built into the body 5 of the inner vessel 2 and contains a dust collector 6 made, for example, of flannel in the form of a cover, worn on the perforated part 7 of the adsorption pump. Between the dust collector 6 and the heat insulating screens 8, a layer of porous material 9 is extended, made, for example, from glass wool to create microgluses, which connect the vacuum thermal insulation cavity 10 with the adsorption pump 4, while the layer 9 of porous material is laid along the supporting elements 11 with the screens crossing 8 to improve the communication of the cavities formed between the screens 8 with the vacuum cavity 10. The screen-vacuum thermal insulation 3 consists of a polyethylene terephthalate film aluminized on both sides and duplicated with a glass veil or glass paper. Valve 12 serves for

pumping gases from the heat insulating cavity 10 with a vacuum pump (not shown).

The cryostat operates as follows.

When the cryostat is filled with a cryogenic product; The adsorption pump 4 begins to work, which has thermal contact with the internal vessel 2. The absorption of gas and moisture molecules from the heat insulating cavity 10 occurs both from cavities that are not filled with thermal insulation and from the cavities between the insulation screens 8 of the insulation 3 filled with porous layers 9 glass or glass paper. The presence of the dust separator 6 ensures the preservation of the thermal insulation efficiency 3 by eliminating the adsorbent dust entering the screens 8 and preserving their enclosing ability. The presence of a layer 9 of a porous material also contributes to the efficient operation of thermal insulation 3 by improving the evacuation of gas molecules from under the layers of shields 8 and unhindered locking of gas molecules and moisture to the adsorption pump 4, and when evacuating the heat insulating cavity ID through the valve 12 to the vacuum one. nosy.

The proposed device of the cryostat ensures the safety of the efficiency of thermal insulation during the entire period of operation, both transport and stationary cryostats.

Claims (2)

1. Mikulin EI Cryogenic technique. M., “Mechanical Engineering, 1969, p. 227. 2. USSR author's certificate No. 602741, cl. F 17 C 3/00, 1976.