PL129560B1 - Cryostat for storing cryogenic liquids - Google Patents

Description

The invention relates to a cryostat for storing cryogenic liquids such as, for example, liquid nitrogen, liquid hydrogen or liquid helium. There are known designs of low temperature cryostats for liquefied gases made of sheets of, for example, copper, the wall thickness of the cryostat being approximately 1 mm to 10 mm depending on the size of the cryostat and the material used. In such a cryostat, between the walls there is a thermal insulation, eg diatomaceous earth. The known cryostat is relatively heavy and has a rigid structure, which does not allow its size to be reduced for the storage of empty cryostats. The storage of such cryostats requires rooms with a large surface area and volume, which makes it difficult, for example, to transport them. The rigid mechanical structure and relatively high weight of the known solutions of cryostats also make them vulnerable to increased accelerations occurring, for example, during the fall of a cryostat. Although cryostats are known for liquefied gases that are resistant to increased accelerations, but this is achieved by using additional elements strengthening the structure of the cryostat, which causes a further increase in its weight. The aim of the invention was to develop such a structure of the cryostat and the method of its production, that it was very light and that it had increased mechanical resistance. This goal was achieved by the use of flexible cryostat walls made of plastic foil with low gas permeability, and flexible thermal screens and super-insulation made of metallized plastic foil with insulating spacers that pump residual gases contained in the cryostat insulation space. 2 129 560 The cryostat according to the invention has an inner wall forming an inner container for the liquid, and a self-inflating super-insulation is placed on the surface of the container. The inner container with the super insulation is placed in the outer vacuum casing made of the same material as the container. The insulating space formed between the surfaces of the container and the enclosure is closed by a vacuum valve. In another embodiment, the cryostat according to the invention has walls consisting of an inner container for cryogenic liquid and an outer flexible vacuum envelope. A self-inflating super-insulation is placed on the surface of the container which extends up to 2/3 of the total height, while a flexible heat shield is connected at the same height along the circumference of the container. On the entire surface of the screen there are thin metal sticks insulated from each other and superinsulation applied to a height of 3/4 of the total height of the container. In turn, at this height there is a further flexible thermal screen with superinsulation, thermally compact with the container, placed to a height less than 20 mm to 100 mm from the total height. The container with the heat screens is placed in a flexible vacuum casing. The insulating space formed between the surfaces of the container and the enclosure is closed by a vacuum valve. The use of a self-inflating super-insulation or similar insulating material according to the invention having the property of absorbing residual gases is practically necessary because, due to the small thickness of the walls of the cryostat, the diffusion of the gas diffusion into the diffuser is significant, which would degrade the quality of the insulation and, consequently, degrade the thermal performance of the cryostat. The cryostat according to the invention, thanks to its flexible structure, has a significantly increased resistance to mechanical damage. Cryos-! tat is suitable for transport when folded up. The subject matter of the invention is shown in the drawing in which Fig. 1 shows a cross-section of the cryostat, Fig. 2 shows a cross-section of the cryostat, and Fig. 3 shows a fragment of the wall of the cryostat shown in Fig. 2. 1 has an inner container 1 for cryogenic liquid, in the shape of a cylinder closed at the bottom, which container is made of Teflon. A self-inflating super-insulation 2 is placed on the inner container 1, consisting of alternately arranged layers, a polyester foil metallized on both sides with aluminum, separated by insulating spacers made of glass, synthetic or natural fiber. It is preferable to use microfibers with a diameter of less than one micrometer, with sorption materials for residual gases such as zeolite crystallites, activated carbon dust or silica gel inserted into the interior of the spacer. The inner container 1 with the super-insulation 2 is placed in the outer vacuum sheath. The opening 3 is also made in the shape of a cylinder closed at the bottom, preferably of the same material as the inner container 1. The periphery 4 of the container 1 and the outer casing 3 are hot-welded or glued so as to obtain a vacuum-tight joint. The vacuum valve 5 is stuck or welded into the hole made in the lower part of the outer casing 3. The insulating space between the container 1 and the cover 3 is pumped out through the vacuum valve 5 to the appropriate residual gas pressure, and then the valve 5 is closed. ready for filling it with cryogenic liquid, or introducing into its interior the so-called If the cryostat made in this way is to be stored, it should be rolled up and placed in a box of any material. Example 11. Non-magnetic cryostat for liquid helium without a nitrogen blanket shown in Fig. 2 it has an inner container 6 made as in example I. The container 6 is provided with a superinsulation 7 also made as in example 1, the superinsulation being placed only up to a height h1 which is about 2/3 of the total height h of the container 6. A heat shield 129 560 3 is glued to the perimeter of the container 6 at the height h1, protecting the superinsulation. 7. The heat shield 11 is made of polyester foil, the entire surface of the screen is covered with thin copper wires 13 electrically insulated from each other. . * in order to ensure a proper thermal contact between the screen 11 and the container 6 at the height h1, it is necessary to meet the condition that the wires 13 extend above the height h1 by about 100 millimeters and are thermally short-circuited by gluing to the perimeter of the container 6 * After fixing of the screen 11 is placed on the * ninTsuperisolation 8, the super-insulation 7 is thus made, with the superinsulation 8 reaching above the screen 11 to a height h2 equal to about 3A of the height h. thermally bonded to the container 6 in the same way as the screen 11. After the screen 12 has been attached, it is positioned. on it, super-insulation 9 is made in the same way as super-insulation 7, where one of the sorbents introduced into the super-insulation 9 should be silica gel * The super-insulation 9 reaches a height of slightly less than about 50 mm than the height h. construction of the cryostat 10, as in example i. Further operations related to the construction of the cryostat are identical to those of example I. In addition to the examples of cryostat construction and filling mentioned above, insulation of their insulating space is also possible in intermediate variants in which can be used simultaneously in the same solution different solutions discussed in the examples. Although only the cylindrical form of the cryostat is given in the examples, for any other shape of the cryostat, such as the spherical symmetry of the solutions described herein, also apply. necks, i.e. tubes of selected diameters, through which vapors of cryogenic liquids are discharged outside. rf in order to ensure the flexibility of such a barrier and its good thermal insulating properties, it is advantageous, in the upper part of the internal tanks of the cryostats, to place a multilayer structure made of several dozen discs made of metallized polyester foil with a diameter similar to the diameter of the inner container with a It is also advisable to stick a stiffening ring in their part, on which the cryostat can be suspended during operation. Patent Claims 1 * Cryostat for storing cryogenic liquids, with a light flexible structure, whose spatial dimensions are smaller before its unfolding from the dimensions of the prepared to filling or keeping the cryogenic liquid low, characterized by the fact that it has walls consisting of a flexible container (1) for cryogenic liquid, and a self-inflating super-insulation (2) is placed on the surface of the container (1), while the container ( 1) in once with the super-insulation (2) it is placed in a flexible vacuum casing (3). the insulating space formed between the surfaces of the container (1), the sheathing (3) is closed by a vacuum valve (5). 2. A cryostat according to claim 1, characterized in that the cryogenic liquid container (1) has walls made of plastic foil with high flexibility and low gas permeability. 3. A cryostat for storing cryogenic liquids, with a light flexible structure, whose spatial dimensions are smaller before its development than the size prepared for filling cryogenic liquid or keeping it low temperature, characterized by the fact that it has walls consisting of a flexible container ( 6) for the cryogenic liquid, while on the surface of the container (6) there is a self-inserting super-insulation (7) »which is situated up to a height (h1) equal to 2/3 of the total height (h) of the container (6), at the same time at the same height (hi) is joined by a flexible thermal screen, the surface of which is covered with thin stamens (13) insulated from each other, and a self-installing super-insulation (9) applied to a height (h2) equal to 3/4 of the total height (h), and then in turn at the height (h2) there is a thermally compact with the container (6) another flexible thermal screen with super-insulation (11) placed up to a height lower by 20 mm to 10 0 mm from the total height (h), while the container (6) with the heat shields is placed in a flexible vacuum casing (10), the insulating space formed between the surfaces of the container (6) and the casing (10) being closed the vacuum valve (5). 4 # Cryostat according to claim The method of claim 3, characterized in that the cryogenic liquid container (6) has walls made of plastic film with high flexibility and low gas permeability. 5. A cryostat according to claims 3. A method as claimed in claim 3, characterized in that the flexible thermal screen (11) is made of a metallized plastic foil. Mintage 100 copies She 100 zl '129 560 A-A Fig. 3 PL

Claims (5)

Claims 1. * A cryostat for storing cryogenic liquids, with a light, flexible structure, the dimensions of which are smaller before its development than the dimensions of the cryogenic liquid prepared for filling or keeping it low temperature, characterized by the fact that it has walls that consist of from the flexible container (1) for the cryogenic liquid, while the self-inflating super-insulation (2) is placed on the surface of the container (1), while the container (1) with the super-insulation (2) is placed in a flexible vacuum casing (3). the insulating space formed between the surfaces of the container (1), the sheathing (3) is closed by a vacuum valve (5). 2. A cryostat according to claim 1, characterized in that the cryogenic liquid container (1) has walls made of plastic foil with high flexibility and low gas permeability. 3. A cryostat for storing cryogenic liquids, with a light flexible structure, whose spatial dimensions are smaller before its development than the size prepared for filling cryogenic liquid or keeping it low temperature, characterized by the fact that it has walls consisting of a flexible container ( 6) for the cryogenic liquid, while on the surface of the container (6) there is a self-inserting super-insulation (7) »which is situated up to a height (h1) equal to 2/3 of the total height (h) of the container (6), at the same time at the same height (hi) is joined by a flexible thermal screen, the surface of which is covered with thin stamens (13) insulated from each other, and a self-installing super-insulation (9) applied to a height (h2) equal to 3/4 of the total height (h), and then in turn at the height (h2) there is a thermally compact with the container (6) another flexible thermal screen with super-insulation (11) placed up to a height lower by 20 mm to 10 0 mm from the total height (h), while the container (6) with the heat shields is placed in a flexible vacuum casing (10), the insulating space formed between the surfaces of the container (6) and the casing (10) being closed the vacuum valve (5). 4. # Cryostat according to claim The method of claim 3, characterized in that the cryogenic liquid container (6) has walls made of plastic film with high flexibility and low gas permeability. 5. A cryostat according to claims 3. The method of claim 3, characterized in that the flexible thermal screen (11) is made of a metallized plastic foil. Circulation 100 copies She 100 zl'129 560 A-A Fig.3 PL