KR20100097936A - Experimental container for high temperature superconducting phenomena with adiabatic vacuum chmber and the manufacturing method of it - Google Patents

Abstract

PURPOSE: An experimental container for high temperature superconducting phenomena with adiabatic vacuum chamber is provided to obtain accurate experiment data by easily forming a vacuum insulation state. CONSTITUTION: A high temperature superconductive vessel receives high temperature superconductive material. An extremely low temperature fluid is flowed into an enclosure body(10). The enclosure body comprises a space part(16). A side and a floor side are communicated through the space part. Carbon dioxide or argon gas(50) are filled into the space part. The carbon dioxide or the argon gas are solidified by the extremely low temperature fluid. The space part is a vacuum condition.

Description

Experimental container for high temperature superconducting phenomena with adiabatic vacuum chmber and the manufacturing method of it}

The present invention relates to a high-temperature superconducting experiment container for forming an adiabatic vacuum chamber and a method for manufacturing the same. The present invention provides a reliable and easy adiabatic vacuum by adopting a method of welding a container body composed of an inner shape and an outer shape in an atmosphere of carbon dioxide or argon gas. The present invention relates to a high temperature superconducting experiment container and a method of manufacturing the same, which form an adiabatic vacuum chamber in which a state is formed to enable accurate acquisition of experimental data.

For the high temperature superconductivity experiment, a high temperature superconductivity test vessel (hereinafter, referred to as 'container') of a metallic material, such as stainless steel, which is durable even when a cryogenic fluid such as liquid helium or liquid nitrogen is contained therein as shown in FIG. 1, In order to prevent the rapid evaporation of liquid nitrogen from the outside air, a space portion 5 is formed in which the side and bottom surfaces constituting the container 1 communicate with each other, but the space portion 5 must maintain an adiabatic vacuum.

To this end, the worker manufactures a container 1 having a connecting pipe 1 'formed with an outlet 2 as shown in FIG. 1 (a), and as shown in FIG. The exhaust pump 3 is connected and air is discharged from the space 5 through the outlet 2, and then the connecting pipe 1 'is removed as shown in FIG. Sealing the ends of the connection pipe 1 'creates an adiabatic vacuum.

However, the above method requires a separate equipment such as an exhaust pump 3 to create a vacuum state, so that unnecessary waste of power is inevitable, and welding 3 after air discharge by the exhaust pump 3 is inevitable. In the sealing process, a small amount or a significant amount of air is introduced again, there is a problem that it is difficult to make a perfect insulating vacuum state of the space (5).

The present invention has been made to solve the above problems, to provide a high-temperature superconducting experiment container and a manufacturing method for forming an adiabatic vacuum chamber to form accurate and easy adiabatic vacuum state to obtain accurate experimental data. Its purpose is to.

In order to achieve the above object, the present invention, in the container for high temperature superconductivity experiment to accommodate the cryogenic fluid in the container body and put the high temperature superconducting material to perform the experiment, the container body is a space in communication with the side and the bottom surface And a carbon dioxide or argon gas is filled in the space portion, and the carbon dioxide or argon gas is solidified by the cryogenic fluid accommodated in the container body, and the space portion is vacuumed.

In addition, the container body is an inner mold of a metal material having an upper side and an inner side and a bottom side; And an outer shape of the metal material having an upper portion and having an outer surface and a bottom surface, wherein the inner shape and the outer shape are combined with each other at the upper edges of the inner shape and the outer shape while being injected into an atmosphere of carbon dioxide or argon gas. Characterized in that the container body is made.

The inner mold further includes an outward coupling piece corresponding to an upper edge of the outer shape along an upper edge of the inner mold, and the outward coupling piece and an edge of the outer upper part of the inner mold are welded to each other.

The outer shape further includes an inward coupling piece corresponding to an upper edge of the inner shape along an upper edge of the outer shape, and the inward coupling piece and the edge of the upper shape of the inner shape are welded to each other.

Here, the combination of the inner mold and the outer mold is preferably made of mutual welding.

In addition, the present invention is a method for manufacturing a high temperature superconducting experiment container for accommodating cryogenic fluid and adding a high temperature superconducting material to perform the experiment, the inner and outer surfaces of the metal material having an inner side and a bottom side and the upper side is opened; A first step of injecting each of the outer shapes of the metal material having the bottom surface into the upper chamber into the chamber in which carbon dioxide or argon gas is filled; A second step of putting an inner mold into the outer mold; And a third step of fabricating a container body forming a space between the outer shape and the inner shape by welding the outer shape and the inner shape with each other, wherein the carbon dioxide or argon gas is solidified by the cryogenic fluid accommodated in the inner shape. The space part is made into a vacuum.

According to the present invention having the configuration described above, by adopting a method and a configuration for manufacturing the container body by mutually welding the inner shape and the outer shape in an atmosphere of carbon dioxide or argon gas, unnecessary waste of unnecessary equipment and power for creating an adiabatic vacuum state There are features that can be greatly reduced.

The present invention maintains a state in which carbon dioxide or argon gas is filled in the space by welding and bonding in an atmosphere of carbon dioxide or argon gas as compared with the conventional technique in which air may be introduced again in the process of performing airtight work after discharging air. By adopting a structure that allows a natural adiabatic vacuum to be formed by solidification of the carbon dioxide or argon gas by the accommodated cryogenic fluid, the accurate experimental data can be obtained, and the vaporization of the cryogenic fluid can be delayed. There is this.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

Figure 2 is a cross-sectional conceptual view showing the overall configuration of the high temperature superconducting experiment container for forming an adiabatic vacuum chamber according to the present invention, the high temperature superconductivity experiment container for forming a thermal insulation vacuum chamber according to the present invention as shown in the container body (10) It can be seen that the space portion 16 of the carbon dioxide or argon gas 50 is filled.

The container body 10 is provided with a space portion 16 which is in communication with each other on the side and the bottom surface, the carbon dioxide or argon gas 50 is filled in the space portion 16, the carbon dioxide or argon gas 50 ) Is solidified over the entire space portion 16 at 77 K or less by cryogenic fluid (not shown) such as liquid nitrogen or liquid helium contained in the container body 10 to insulate and vacuum the space portion 16. Will be made.

Here, the container body 10 is an inner mold 12 of a metal material having an open top and having an inner surface 12 'and a bottom surface 12 ", and an open top and an outer surface 14' and a bottom surface. The outer mold 14 of the metal member 14 having the " 14 " is formed, and the upper edge of each of the inner mold 12 and the outer mold 14 is welded to each other to form a weld 19.

In this case, the inner mold 12 is further provided with an outwardly engaging piece 11 corresponding to the upper edge of the outer mold 14 along the upper edge of the inner mold 12 as shown in FIG. Outwardly coupled piece 11 and the edge of the upper portion 14 is welded to each other.

In addition, the outer mold 14 further includes an inward engagement piece 13 corresponding to the upper edge of the inner mold 12 along the upper edge of the outer mold 14 as shown in FIG. 2 (b). The inward coupling piece 13 and the edge of the upper side of the inner mold 12 may be coupled to each other by welding 19.

The inner mold 12 and the outer mold 14 having the above-described configuration are made of a metal material having excellent durability and strength, such as stainless steel, due to the characteristics of the cryogenic fluid which causes almost all materials to be easily frozen and destroyed. 12 and the outer shape 14 are mutually coupled by welding as mentioned above, but welding can be performed by oxygen welding or the like.

The manufacturing method of the high temperature superconducting experiment container for forming the adiabatic vacuum chamber according to the present invention having the above configuration will be described.

Figure 3 is a block diagram showing a method for manufacturing a high temperature superconducting experiment container for forming a heat insulating vacuum chamber according to the present invention, the method for manufacturing a high temperature superconductivity experiment container for forming a thermal insulation vacuum chamber according to the invention as shown in the first It can be confirmed that the manufacturing through the step (S10), the second step (S20) and the third step (S30), it can be found in detail the manufacturing process through FIGS.

For reference, in the present invention, as shown in Figure 5 to Figure 7 (a) and the container body 10 according to the embodiment of Figure 2 (b) is shown as manufacturing at the same time, this is for convenience of description Simultaneously shown for the sake of simplicity, it will be understood that the container body 10 according to each embodiment is actually manufactured.

First, in the first step S10 according to the present invention, as shown in FIG. 4, the inner surface 12 ′ and the bottom surface 12 ″ of the chamber 30 are filled with carbon dioxide or argon gas 50 as shown in FIG. 5. The inner mold 12 and the outer surface 14 ′ and the bottom surface 14 ″ of the metal material having the upper side open with each other are supplied to each other.

Here, as described above, the upper edge of the inner mold 12 or the outer mold 14 may be provided with an outward coupling piece 11 or an inward coupling piece 13, respectively.

Subsequently, in the second step S20 according to the present invention, an operation of inserting the inner mold 12 into the outer mold 14 is performed as shown in FIG. 6, and the outer mold 14 and the inner mold 12 are coupled to each other. The carbon dioxide or argon gas 50 is naturally filled in the space 16, that is, the space 16 formed by communicating the side and the bottom surface with each other.

Subsequently, in the third step S30 according to the present invention, as shown in FIG. The container body 10 is manufactured by maintaining the airtight while forming a welded portion 19 which combines an edge or the inwardly coupled piece 13 and the upper edges of the inner mold 12 by oxygen welding.

As shown in FIG. 8 (a), liquid nitrogen or When the cryogenic fluid 60 such as liquid helium is injected, the carbon dioxide or argon gas 50 filled in the space 16 solidifies in the space 16 as shown in FIG. Filled with argon (50 ') to maintain adiabatic vacuum.

As described above, the present invention is to provide a high temperature superconducting experiment container and a method of manufacturing the same, which form an adiabatic vacuum chamber in which a reliable and easy adiabatic vacuum can be obtained to obtain accurate experimental data. It can be seen.

In addition, many other modifications and applications are possible to those skilled in the art within the scope of the basic technical idea of the present invention.

1 is a cross-sectional conceptual view showing a manufacturing process of a high-temperature superconducting experiment container according to the present invention.

Figure 2 is a cross-sectional conceptual view showing the overall configuration of the high-temperature superconducting experiment container for forming an adiabatic vacuum chamber according to the present invention.

Figure 3 is a block diagram showing a method of manufacturing a high temperature superconducting experiment container for forming an adiabatic vacuum chamber according to the present invention.

4 to 7 is a conceptual diagram showing a manufacturing process of a high-temperature superconducting experiment container for forming an adiabatic vacuum chamber according to the present invention.

8 is a cross-sectional conceptual view showing an application example of the high-temperature superconducting experiment container forming the adiabatic vacuum chamber according to the present invention.

* Description of the symbols for the main parts of the drawings *

10.Container body 12.

14 ... Appearance 16 ... Space

Claims (8)

In the high temperature superconducting experiment container for accommodating the cryogenic fluid in the container body and injecting a high temperature superconducting material, The container body 10 has a space portion 16 which is in communication with each other on the side and bottom surface, the space portion 16 is filled with carbon dioxide or argon gas 50, A high temperature superconducting experiment container for forming an adiabatic vacuum chamber, characterized in that the carbon dioxide or argon gas (50) is solidified by the cryogenic fluid (60) accommodated in the container body (10) and vacuums the space portion (16). . The method of claim 1, The container body 10, An inner mold 12 of metal material having an upper side and having an inner side 12 'and a bottom side 12 "; and A top of the metal opening 14 having an outer surface 14 'and a bottom surface 14 "; The inner mold 12 and the outer mold 14 are coupled to an upper edge of each of the inner mold 12 and the outer mold 14 in a state of being injected into an atmosphere of carbon dioxide or argon gas 50, and thus the container body 10. A high temperature superconducting experiment container for forming an adiabatic vacuum chamber, characterized in that made. The method of claim 2, The inner mold 12, Further along the upper edge of the inner mold 12 is provided with an outwardly engaging piece 11 corresponding to the upper edge of the outer mold 14, A high temperature superconducting experiment container for forming an adiabatic vacuum chamber, characterized in that the outward coupling piece (11) and the edge of the upper portion (14) is welded to each other. The method of claim 2, In the outline 14, Further provided with an inwardly engaging piece 13 corresponding to the upper edge of the inner mold 12 along the upper edge of the outer mold 14, A high temperature superconducting experiment container for forming an adiabatic vacuum chamber, characterized in that the inward coupling piece 13 and the edge of the upper side of the inner mold 12 are welded to each other. The method of claim 2, The combination of the inner mold 12 and the outer mold 14, A high temperature superconducting experiment container for forming an adiabatic vacuum chamber, characterized in that it consists of mutual welding. In the manufacturing method of a high-temperature superconducting experiment container for accommodating cryogenic fluid and injecting a high-temperature superconducting material to perform an experiment, Carbon dioxide or argon gas 50 is filled with each of the inner mold 12 of the metal member having an inner side and a bottom surface and having an open upper side, and the outer mold member 14 having an outer side and a bottom side having an upper side opened. First step (S10) to be injected into the chamber 30 of the atmosphere; A second step (S20) of introducing the inner mold 12 into the outer mold 14; And A third step (S30) of manufacturing a container body (10) forming a space (16) between the outer mold (14) and the inner mold (12) by welding the outer mold (14) and the inner mold (12) to each other; It consists of The high temperature superconducting experiment container for forming an adiabatic vacuum chamber, characterized in that the space 16 is vacuumed while the carbon dioxide or argon gas 50 is solidified by the cryogenic fluid 60 accommodated in the inner mold 12. Manufacturing method. The method of claim 6, The inner mold 12, Further along the upper edge of the inner mold 12 is provided with an outwardly engaging piece 11 corresponding to the upper edge of the outer mold 14, Method for producing a high-temperature superconducting experiment container for forming an adiabatic vacuum chamber, characterized in that the outward coupling piece (11) and the edge of the upper portion (14) is welded to each other. The method of claim 6, In the outline 14, Further provided with an inwardly engaging piece 13 corresponding to the upper edge of the inner mold 12 along the upper edge of the outer mold 14, A method for manufacturing a high temperature superconducting experiment container for forming an adiabatic vacuum chamber, characterized in that the inward coupling piece (13) and the edge of the upper side of the inner mold (12) are mutually welded.

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