DE2200769A1 - Stabilized superconductors and processes for their manufacture - Google Patents

Description

DIpl.-Ing. Dipl. Öse. piiöl.

DIETRICH LEWINSKY -7

8 MBnchan 21 - Gotthardstr. 81

Telephone 56 17 62

6886 - V

Compagnie Fran <? Aise Thomson Houston - Hotchkiss Brandt, Paris 8eme, Boulevard Haussmann 173 (France)

"Stabilized superconductors and processes for their production" \

Priority of January 8, 1971 from the French patent application No. 71/00518

The invention relates to stabilized superconductors and processes for their production. In particular, this deals with Process for the production of stabilized superconductors based on materials with a tungsten-like ß-structure, i.e. crystallize with A 15 according to the international crystallographic classification.

Superconductors are often used to make solenoids that are capable of generating strong magnetic fields. Coincidentally, a small superconducting part that briefly loses its superconductivity comes across one of these solenoids electrical resistance - which does not have the value zero, the strong current flowing through it inevitably leads to a It releases a considerable amount of energy, which is more or less has destructive effects. In order to prevent this danger, the superconductors are known to be "stabilized" Stabilization; of a superconductor is that it is placed next to a non-superconducting support, which is very good Has heat and electricity conductor properties and that between see these two elements establish a close thermal connection. Occurs by chance in part of a stable

If the superconductor makes a transition from superconducting to normal, the strong current in the superconductor is diverted into the surrounding, stabilizing support. The temperature rise that occurs here is small in most cases. Since the density of the electric current in this part of the superconductor has decreased, this part can easily maintain its superconducting properties. The known, stabilized superconductors, which are produced from intermetallic mixtures and _{crystallize with an A-15 structure such as Nb 3} Sn, Nb ₃ Al, Nb ₃ Au, V ₃ Sn, V ₃ Ga, Ta ₃ Sn, etc. are either often associated with high costs or do not have the desired stability. These disadvantages are essentially due to the manufacturing processes used and in particular to those whose use either makes it impossible to dispense with expensive elements such as niobium, vanadium or tantalum or to limit their proportion, or a uniform stabilizing layer as the surrounding material of the superconductor. It should be mentioned here that the superconductors provided with a stabilization layer made of niobium, vanadium or tantalum are often associated with high costs. On the other hand, a poorly formed stabilization layer is often found in superconductors, the stabilization layer of which is achieved, for example, by electrolytic deposition. The same disadvantages are also found in superconductors made of Nb ₃ Sn, for example, in which the stabilization layer made of niobium is formed by a part of the niobium that is not detected in the diffusion / reaction treatment during the formation of the superconducting intermetallic mixture Nb ₃ Sn, since that The presence or absence of this niobium layer depends on the duration and temperature of this diffusion / reaction treatment.

In addition, these last-mentioned superconductors have other disadvantages such as strong anisotropy, which is only mediocre Stabilization quality against river fluctuations and insurmountable difficulties in the production of conductor crossings.

The aim of the invention is therefore to create stabilized superconductors and a method for their Manufacture, in particular those based on work. substances that crystallize according to an A-15 structure, with es'auf On the basis of this process it is possible to produce stabilized superconductors without the disadvantages mentioned. In the inventive Superconductors can be single-stranded or multi-stranded conductors.

A method according to the invention for the production of stabilized Superconductors, especially those that consist of: Materials that crystallize according to an A-15 structure,. consists of the following steps: Formation of blanks, each consisting of a core made of base materials of a superconducting, intermetallic Consist of a mixture that are concentric to one another: tidies and with an outer skin made of an elastic material good Thermal and electricity conducting properties are provided, furthermore an extraction of these blanks, either individually or in groups t with the help of a second sheathing of the same material as that

the sheaths of these blanks, with or without a subsequent Rolling out to either compact composite elements or ver. produce bundles of desired dimensions and finally j a heat treatment of these composite elements or composite groups, | this heat treatment may or may not be preceded by mechanical relocating and / or joining processes, which in place and Establish a diffusion and reaction of the base materials and consequently these materials can be converted into superconducting, intermetallic mixtures.

The invention will be described in the further course with the aid of a few exemplary embodiments ■ explained in more detail in connection with the accompanying drawings. Show it:

Figure 1 - a schematic perspective view of a blank section of a composite element according to the invention, from which a single-stranded .ger Superconductor results;

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- Figure 2 - is a schematic perspective view of a blank portion of another inventive composite element, from the results after the heat treatment, a superconducting single-stranded;

- Figure 3 - a schematic partial representation (in cross section)

of a blank of a composite group according to the invention, which consists of blanks according to FIGS. 1 or 2 is formed and from which a multi-strand superconductor results after a heat treatment and

- Figure 4 - a schematic partial representation (in cross section)

a composite group according to the invention, which is characterized by an extraction of the blank shown in Figure 3 results.

According to the method according to the invention for producing a single-strand superconductor Nb "Sn, a blank of a Composite element first formed from niobium, from tin and a ductile material that has good thermal and electrical conductivity properties owns. For this purpose, the niobium and the tin are arranged concentrically to one another and then covered by a jacket made of a material such as copper, nickel, bronze, brass, aluminum, Cu / Ni alloys, stainless steel or any other Surrounded by metal or any other alloy that is used as a more or less economical stabilizer for the hereby manufactured superconductors can be used. The example shown in Figure 1 shows a blank 1 of a composite element , which is made of tinned niobium wire 2, which is embedded in a jacket 3, which in turn is through a copper tube or is formed by a rolled up copper foil. In the example of FIG. 2, a blank 4 of a composite element is used formed from a niobium tube or from a rolled-up niobium foil 5 which is filled with tin or a tin wire 6 and which is arranged within a jacket 7, which consists of a copper tube or a rolled copper foil.

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According to the invention, the blank 1 or 4 formed in this way is subjected to an extraction process in order to produce a close connection between the copper jacket and the niobium / tin core and to obtain, after this treatment, a compact composite element of a desired diameter, which if necessary is subjected to a rolling process in order to obtain a compact composite strip and that before this compact composite element or the composite strip is subjected to a heat treatment which at. On the spot, the niobium / tin mixture is converted into an Nb ₃ Sn superconductor.

The concentric arrangement of the base materials (niobium tin) among each other in a stabilizing jacket (copper) results in an extremely uniform. Structure of the composite element which, after heat treatment, results in a stabilized superconductor with excellent properties. For example, an Nb-Sn superconductor can have a stabilizing jacket made of niobium. In contrast, however, a stabilization jacket made of niobium leads to a price increase for the superconductor,! which is due to the high price of niobium and makes it considerably more difficult to carry out the heat treatment in the formation of the Nb ₃ Sn by diffusion and reaction on site, this fact being due to the fact that the strength of the niobium jacket or its very presence is linked to the temperature and duration of this treatment. The use according to the invention of a stabilizing jacket made of a reasonably priced, stretchable material with good heat and electricity conducting properties leads to the elimination of the above-mentioned disadvantages in the manufacture of the superconductor. The invention can be applied to the production of any superconductor that is produced on the basis of intermetallic mixtures with an A-15 structure such as Nb ₃ Au, Nb ₃ Al, Nb ₃ AlGe, Nb ₃ Sn, Nb ₃ Crystallize Ga, V ₃ Ga, V ₃ Sn, Ta ₃ Au, Ta ₃ Sn, etc. Depending on the type of A-15 mixture to be formed, the heat treatment carried out generally consists of an intermediate

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five minutes and twenty hours heating to a temperature lying between 600 and 130o C ⁰ C or preferably one from ten minutes to ten hours at a temperature between 800 ⁰ C and 1000 ° C.

According to the invention, the stabilized, multi-strand superconductors are made from a blank 'of a composite group which is formed from composite elements of the type of blanks 1 to M and from a jacket made of the same material as the jacket of these composite elements. In the production of a multi-strand superconductor Nb ₃ Sn, for example, the blanks 1 or 1 or the composite elements resulting therefrom, which have a copper jacket 3, are first combined in a copper jacket 9 in order to form a blank 8 of a composite group 10, which in a partial view is shown in Figures 3 and 4. The blanks 1 or H or the composite elements resulting therefrom can be arranged parallel to the axis of the composite group 10 or form a strand within the jacket 9. This blank 8 of the composite group 10 is then drawn out in order to produce a close contact between the jackets 3-9 and the cores Nb-Sn and in order to obtain a compact composite group 10 of a desired diameter. After this extraction process, the copper jackets 3 and 9 form a homogeneous mass 11 which encloses the niobium / tin souls. The composite group 10 can then be rolled out in order to thereby obtain a strip which has the desired dimensions (not shown). If the composite group 10 (FIG. 4) is subjected to a known diffusion / reaction heat treatment, its niobium / tin cores are converted _{into superconducting Nb 3 Sn cores on the spot.} The homogeneous copper mass ^: 11, which is firmly connected to the surfaces of these superconducting souls, serves the latter in an effective form as a stabilizing jacket.

The compact composite elements resulting from the blanks 1 and 2 can be combined with the compact composite unit 10 further conditions are applied, i.e. mechanical connection processes are subjected to these conditions, to which a Then cutting to the desired dimensions.

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Certain crossings can also be made in this context which consist in the fact that the axis of their souls is inclined in a certain form with respect to that of the superconducting end product will. According to the invention, each conversion process has to take place before the diffusion / reaction heat treatment in which the composite souls be transformed into superconducting souls.

According to the invention, the compact composite elements formed from the blanks 1 and / or, together with the compact Composite unit 10 also after the extraction process and, if necessary, a whale process carried out immediately after a heat treatment be subjected to conversion into superconductors *

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Claims (1)

Uipl.-ifio. ϋ, μ .. uou imlm. DIETRICH LEWIMSKY. _{7th 1070} PAT ΓίΤΛ. J ₁ VALT £ ' MBnchen 21 - Gotthardstr. 81 Telephone 56 17 62 6886 - V Compagnie Francjaise Thomson Houston - Hotchkiss Brandt, Paris 8eme, Boulevard Haussmann 17 3 (France) Pat ent claims 1./Verfahren for the production of stabilized superconductors based on materials which crystallize according to an A-15 structure, characterized in that this consists of the following steps: Formation of blanks, each consisting of a core of base materials of a superconducting, intermetallic mixture exist, are arranged concentrically to one another and are provided with an outer skin or a jacket made of an elastic material with good heat and electricity conductor properties, furthermore an extraction of these blanks either individually or in groups with the help of a second coating of the same material as the one of the sheaths of these blanks in order to produce either compact composite elements or composite groups of a desired diameter and finally a heat treatment of these composite elements or composite groups, this heat treatment being preceded by mechanical conversion and joining processes and this heat treatment . Treatment consists in heating between five minutes and twenty hours at temperatures between 60O ⁰ C and 1300 ⁰ C, causing a diffusion and reaction of the basic materials of the souls on site and consequently a conversion of these latter ii superconducting, intermetallic Mixtures takes place. 209830/0775 2. Process for the production of stabilized single-stranded Nb ₃ Sn superconductors according to claim 1, characterized in 'that it consists of the following steps: formation of raw> lingen (1) by tinning of Niobiumdrähten and ^{introduction!} this tinned niobium wires in a sheath made of, for example, copper; fer, nickel, aluminum, bronze, brass, Cu / Ni alloy, stainless steel, and an extension of these blanks (1) in order to herzu- compact composite elements of a desired diameter. and finally a heat treatment of these .Verbundele-j elements, which ^{consists of heating between ten minutes and ten hours at temperatures between 800 0} C and 1000 ⁰ C and a diffusion and reaction of the niobium / tin- ^{1 on site} . Mixture, the formation of Nb ₀ Sn and consequently the conversion ^d Ί of their niobium / tin souls into superconducting souls. 3. The method according to claim 2, characterized in that this includes rolling out the compact composite elements to convert these into strips before they undergo a heat treatment to convert the niobium / tin mixture into superconducting Nbο Sn are subjected. 4. A method for producing single-stranded, stabilized Nb ₀ Sn superconductors according to claim 1, characterized in that it consists of the following steps: Forming blanks (4) by dispensing niobium tubes (5) or rolled niobium foils with tin (6) and by introducing each of these tubes thus formed into a jacket made of a material such as copper, nickel, aluminum, bronze, brass, Cu / Ni alloy, stainless steel, and also drawing out these blanks (4) to form compact composite elements of a desired from the latter Manufacture diameter and finally a heat treatment of these composite elements, which consists of a heating between ten minutes and ten hours at temperatures between 800 ⁰ C and 1000 ⁰ C and on the spot a diffusion and reaction of the niobium / tin mixture, the formation of superconducting Nb ₀ Sn and thus enables the transformation of their souls into superconducting souls. 209830/0775 The method according to claim 4, characterized in that this
includes rolling the compact composite members to
to convert these into strips before they are subjected to a heat treatment to convert the niobium / tin mixture into superconducting Nb ₃ Sn. Process for the production of multi-stranded, stabilized
Nb "Sn superconductors according to claim 1, characterized in that
that this consists of the following steps: Forming blanks (8) with a plurality of composite elements, which are produced in accordance with those described in claim 2 by combining these composite elements in a casing made of
consists of the same material as that of the composite elements, furthermore an extraction of these blanks (8) in order to produce compact composite units (10) of a desired diameter from the latter, and finally a heat treatment of these composite elements! units (10), which consists of a heating between five minutes and twenty hours at temperatures between 600 ⁰ C and 1300 ° ci and on site a diffusion and reaction of the j niobium / tin mixture and consequently the conversion of the Ni ! bium / tin souls of the composite elements of these composite units j in superconducting Nb ₀ Sn souls. i Process for the production of multi-stranded, stabilized j Nbo Sn superconductors according to Claim 1, characterized in that J that this consists of the following steps: Formation of raw j lingen (8) with several composite elements that correspond to the! described in claim 4 by Zuaanmenfassung this ver; bundle elements are produced in a sheathing made of! consists of the same material as that of the composite elements, Ί also an extraction of these blanks (8) in order to produce the latter
compact composite units (10) of a desired diameter
produce and finally a heat treatment of this composite units (10), the grooves in a heating between ten micro 'and is ten hours at temperatures between 800 ⁰ C and j 1 000 ⁰ C and in place a diffusion and reaction i tion of niobium / Tin mixture and consequently the conversion> 20983Q / G775 - 4 - _ Lto _ the niobium / tin core of the composite elements of these composite units in superconducting Nb Sn souls. 8. The method according to any one of claims 6 or 7, characterized in that that this includes rolling out the compact composite units to convert them into strips before these are subjected to a heat treatment to convert the niobium / tin mixture into superconducting Nb "Sn. 9. A method for the production of superconductors according to claim 1, characterized in that this for the production of stabilized superconductors based on Nb ₃ Au, Nb ₃ Al, Nb ₃ Sn, Nb ₃ Al Ge, Nb ₃ Ga, V ₃ Ga, V ₃ Sn, Ta ₃ Ga, Ta ₃ Au, Ta ₃ Al, Ta ₃ Sn 'is applicable. 10. Stabilized superconductors based on base materials, i which crystallize according to an A-15 structure, characterized in that that these are produced by the method described in claim 1. 11. Stabilized superconductors based on a niobium / tin mixture, characterized in that these are produced by the method described in one of claims 2, 3, 4, 5, 6, 7 or 8 is described. 209830/0 77 5 L e r s e i t e