JPH04132108A - Nb3al superconductor - Google Patents

Abstract

PURPOSE:To provide a high magnetic field superconductor of a large capacity, which is employable for a pulse or AC application, by separating Nb3Al filaments from each other via a first high resistant layer, and disposing a second high resistant layer in an element wire. CONSTITUTION:A central Cu portion 1 is covered with a first diffusion barrier layer 2, which is covered with a jelly roll layer consisting of an Al foil 3 and an Nb foil 4 in a superposed relation. A stabilizing Cu layer 6 is disposed via a second diffusion barrier layer 5. The Cu layer 6 is covered with a first high resistant layer 7. In this way, a multiplicity of Nb3Al filaments 8 are arranged inside a Cu pipe, thus forming a billet so as to obtain an element wire. Inside stabilizing Cu 11 is located in the center of the element wire 15, and is covered with an Nb3Al filament portion 13 via a third high resistant layer 12. Furthermore, a second high resistant layer 14 is disposed. The Nb3Al filaments 8 are separated from each other via the first higher resistant layer 7.

Description

[Detailed Description of the Invention] [Industrial Field of Application] This invention relates to a large-capacity, high-field superconducting wire that can be used in pulsed superconducting coils for nuclear fusion reactors, superconducting generators, SMES, AC transformers, etc. It is.

[Prior art] Conventionally, large-capacity, high-field superconducting wires used in pulsed superconducting coils for nuclear fusion reactors, superconducting generators, etc.
There are NbTi superconducting conductors and Nb3Sn superconducting conductors.

NbTi superconducting conductors use alloy-based NbTi and therefore have excellent workability, but Hc2 is low and the magnetic field used is limited to 9T or less. Furthermore, since Tc is low and there is little margin for the stability of a large capacity conductor, a conductor having a current capacity twice or more of the operating current is used.

Since Nb3Sn superconducting conductor uses compound-based Nb3Sn, it becomes brittle after Nb3Sn is formed and has drawbacks such as being weak against the application of strain. Ideal for use around 18T. Furthermore, Tc is 23, which is twice as much as NbTi, and there is a large margin for stability, so Nb3Sn has been mostly used for high-magnetic-field, large-capacity conductors.

However, as mentioned above, Nb3Sn has a decisive drawback of being weak against strain, and when a compressive strain of 0°3% is applied, Ic decreases to 70% compared to the case without strain, which is 0.5%. When applying % compressive strain, Ic decreases to 50%.

In the case of large-capacity conductors, it is necessary to twist the wires together to form rectangular twisted wires, or to create a cable-in-conduit structure by stacking the first twists, and the application of strain between the wires is unavoidable. For this reason, with Nb3Sn, there are almost no examples in which the designed Ic has been sufficiently reached, and there is a definite drawback as a large-capacity conductor for high magnetic fields.

[Problem to be solved by the invention] Nb and Al essentially have a deterioration rate of Ic with respect to strain of Nb.
It is much smaller and better than 3Sn.

Therefore, if this Nb3Al is used, it should be possible to obtain an excellent large-capacity superconducting conductor for high magnetic fields.

However, conventional Nb3Al has a large capacity and is insufficient as a high-field superconducting conductor used particularly for pulse applications and AC applications.

An object of the present invention is to provide a large-capacity, high-field superconducting conductor that can be used for pulse applications or alternating current applications using a Nb3Al-based superconducting conductor.

[Means for Solving the Problems] The Nb3Al-based superconducting conductor of the present invention comprises a plurality of Nb3A
The Nb3Al-based filaments are separated from each other by a first high-resistance layer, and a second high-resistance layer is provided on the outer peripheral surface of the wire. It is characterized by

In this specification, the Nb, Al system includes not only Nb3Al but also Ge, 5n1Ti, and St.

It refers to a system that also includes a superconductor containing at least one of Hf, Ta, Zr, Mg, and Be.

The high resistance layer used in the present invention is preferably formed from a Cu-M alloy (M is at least one selected from the group consisting of Nt, Mn, Fe, Cr, and Si).

Further, in the present invention, it is preferable that the Nb3Al-based filament is formed by a jelly roll method in which Nb foil and Al foil are wound over each other.

Furthermore, it is preferable that a diffusion barrier layer made of Nb or Ta is provided between the jelly roll layer formed by overlapping Nb foil and Al foil and the stabilizing material.

[Operations and Effects of the Invention] In this invention, Nb3Al is used as a superconductor, and Hc2 is about 30 T, which is much larger than Nb3 Sn and can be used for high magnetic field applications. Moreover, Tc is also high at 17-18.

Furthermore, Nb3Al is a material that is more resistant to strain than Nb3Sn.

In this invention, the Nb3Al filaments are each separated from each other by a first high resistance layer. Therefore, coupling loss between filaments can be reduced, and it can be used for pulse applications and alternating current applications.

Furthermore, in the present invention, a second high resistance layer is provided on the outer peripheral surface of the wire. Therefore, the coupling loss between the strands can be reduced, and the capacity can be increased. Also, NbaAl
Since it is a material that is resistant to distortion, it is possible to twist it together.

Furthermore, when the Nb3Al filament is formed by the jelly roll method, the critical current density can be increased, so that a large capacity conductor with a high current density can be obtained.

In compound superconductors such as Nb3Sn and Nb3Al, after the final conductor is formed and coiled, it is heat treated to form a superconducting layer (A15 type structure of Nb3Sn or Nb5AL). This heat treatment usually ranges from 700°C to 80°C.
The temperature reaches 0°C.

Therefore, due to the difference in thermal shrinkage between the conduit material made of CuNi, SUS, etc. and the Nb3Sn or Nb3Al wire, a large strain is applied during heat treatment. Since Nb3Al used in this invention is strong against strain as described above, even if a large strain is applied during such heat treatment, the effect is less than that of Nb3Sn. For this reason,
The superconducting conductor of the present invention is also useful as a cable-in-conduit in which wires are twisted together and inserted into a conduit.

[Example] FIG. 1 is a sectional view showing an Nb5AL filament according to an example of the present invention. Referring to Figure 1, center C
A first diffusion barrier layer 2 is provided around the u section 1 . Around the first diffusion barrier layer 2, an AI foil 3
A jelly roll layer formed by overlapping and winding Nb foil 4 is provided. A stabilized Cu layer 6 is provided around this jelly roll layer via a second diffusion barrier layer 5. This stabilized Cu layer 6 is formed to have a hexagonal cross section by wire drawing. A first high resistance layer 7 is provided around this stabilized Cu layer 6. In this example, the first barrier layer 2 and the second
Nb is used as the barrier layer 5, and a Cu-Ni alloy is used as the first high-resistance layer 7. A large number of Nb3Al filaments 8 constructed in this manner are arranged in a Cu pipe to form a billet, and the diameter of this billet is reduced to form a wire.

FIG. 2 is a cross-sectional view showing the wire thus formed. Referring to FIG. 2, an internally stabilized Cu1l is provided at the center of the strand 15.
A large number of Nb layers are surrounded by the third high-resistance layer 12.
A Nb3Al filament section 13 formed from a 3Al filament 8 is provided. A second high resistance layer 14 is provided around the Nb3Al filament portion 13. In this example, the second high resistance layer 14 and the third high resistance layer 12 are made of Cu like the first high resistance layer 7.
-Ni alloy is used.

FIG. 3 is an enlarged view showing the Nb3Al filament section shown in FIG. 2. Referring to FIG. 3, the Nb5A filaments 8 are separated from each other by a first high resistance layer 7 around them.

Further, as shown in FIG. 2, a second
A high resistance layer 14 is provided.

FIG. 4 is a sectional view showing a cable-in-conduit in which the wires shown in FIG. 2 are twisted together and inserted into a conduit. Referring to FIG. 4, in this cable-in-conduit, a large number of wires 15 having a second high resistance layer on the outer peripheral surface are twisted together and inserted into a conduit 16.

FIG. 5 is a sectional view showing another embodiment of the invention.

As shown in FIG. 5, the strands 15 may be twisted into rectangular strands.

FIG. 6 is a sectional view showing still another embodiment of the invention. As shown in FIG. 6, the strands of the strands 15 may be further twisted into rectangular strands.

According to this invention, a cable-in-conduit superconducting conductor as shown in FIG. 4 was created. The structure of this superconducting conductor is shown in Table 1.

Table 1 1. Conductor type Cable-in-conduit forced cooling type Outer diameter 22.5mm Conduit material CuNi seamless pipe void ratio (thickness 1.5') 35.0% 2. Cable (stranded wire) Operating current 10kA (12T, 4.2K) Critical current 24kA (12T, 4.2K) Twisted wire configuration 324 wires (3x3x3x12 wires twisted) 3. Critical current density of strands Wire diameter Number of filaments Copper ratio Filament diameter Outer diameter Inner diameter Nb layer thickness Al layer thickness 360A/ mm2 (12T, 4.2K) 0, 88mm 360 pieces 2.1 28μm 11μm 00nm 0nm This superconducting conductor with a cable-in-conduit structure was created as a wire material for a magnet for a fusion reactor.
This assumes an operating current of 2T and 10kA.

The filament type is 28 μm, and the wire diameter of the strand is 0.8
It is 8 μm. The filament was manufactured by the jelly roll method as shown in Figure 1, and the filament manufactured over 10,000 m was stranded into 3 x 3 x 3 x 12 wires.
It was inserted into a Cu-Ni conduit.

Assuming actual coil winding, the wire was bent with a bending radius of 1.5 m and heat treated at 800° C. for 5 days, and the Nb5A sample wire inside was taken out without damage and Ic was measured.

As a result, the Ic of the Φ element wire before twisting was 74A, while that of the wire taken out after heat treatment was 70.5A, which was about 5
% had decreased. This is a very low decrease compared to Nb3Sn, and it is clear that the superconducting conductor of the present invention is suitable as a wire material for a large capacity cable-in-conduit conductor.

Similarly, the electrical resistance of the heat-treated wires was measured in different magnetic fields. FIG. 7 shows this result.

A residual resistance ratio (RRR) value of 200 or more was obtained.

As a result of investigating the dependence of resistance on the magnetic field, it was found that the relationship is expressed by the following equation.

pm=0.8+〇, 6xB OT<B<27 (1) pm=1: 07+0.465xB 2T<B<87 (2) This result is a result of highly pure anaerobic skin tone and is in accordance with the present invention. It was confirmed that the superconducting conductor has high stability even if the filaments are separated by the high resistance layer, there is no diffusion of elements from the high resistance layer to the stabilizing material Cu.

[Brief explanation of drawings]

FIG. 1 is a sectional view showing an Nb5A filament according to an embodiment of the present invention. FIG. 2 is a sectional view showing an example of a wire according to the present invention. 3 is an enlarged view showing the Nb3Al filament portion of the wire shown in FIG. 2. FIG. FIG. 4 is a sectional view showing a cable-in conduit in which the wires shown in FIG. 2 are twisted and inserted into a conduit. Figure 5 is a sectional view showing another embodiment of the present invention. FIG. 6 is a sectional view showing still another embodiment of the invention. FIG. 7 shows N b , , A of an embodiment according to the present invention.
FIG. 3 is a diagram showing resistance and magnetic field dependence in a glued superconducting conductor. In the figure, 1 is the center Cu part, 2 is the first diffusion barrier layer, 3 is Al foil, 4 is Nb foil, 5 is the second diffusion barrier layer,
6 is a stabilized Cu layer, 7 is a first high resistance layer, 8 is Nb3A
1 filament, 11 is internally stabilized Cu, 12 is the third high resistance layer, 13 is the Nb5Al filament portion, 14 is the second high resistance layer, 15 is a wire, and 16 is a conduit.

Claims (4)

[Claims] (1) An Nb_3Al-based superconducting conductor constructed by twisting together wires each having a plurality of Nb_3Al-based filaments, the Nb_3Al-based filaments each having a first
A Nb_3Al-based superconducting conductor, which is separated by a high-resistance layer, and a second high-resistance layer is provided on the outer peripheral surface of the wire. (2) The high resistance layer is a Cu-M alloy (M is Ni, Mn,
Claim 1: at least one member selected from the group consisting of Fe, Cr, and Si.
Nb_3Al-based superconducting conductor described in . (3) The Nb_3Al-based superconducting conductor according to claim 1, wherein the wires are twisted together and inserted into a conduit to form a cable-in-conduit. (4) The Nb_3Al-based filament has a center portion formed from Cu, a first diffusion barrier layer formed from Nb or Ta provided around the center portion, and a surrounding area of the first diffusion barrier layer. a jelly roll layer provided around the jelly roll layer and formed by overlapping Nb foil and Al foil; a second diffusion barrier layer formed from Nb or Ta provided around the jelly roll layer; The Nb_3Al-based superconducting conductor according to claim 1, comprising: a stabilized copper layer provided around a diffusion barrier layer; and the first high resistance layer provided around the stabilized copper layer.