JPH05290947A - Connecting method for superconducting wire - Google Patents

Abstract

PURPOSE:To restrain the occurrence of Joule heat for stabilizing the superconducting state of a superconducting wire, and reduce the evaporation of a coolant at a cryostat. CONSTITUTION:The base material of an extra fine multiconductor filament is caused to melt, and the extra fine multiconductor filament is thereby exposed. The filament so exposed are covered with a good conductor and soldered. As the filament is covered with the good conductor, filament wires can be prevented from contacting each other and stabilized, thereby improving electrical contact. In addition, as there is no base material, Joule heat is not generated. When a plurality of superconducting wires 17 are connected to a conductor, a tape type oxide superconducting wire is soldered to an electrode on the conductor, and the extra fine multiconductor filament after covered with the good conductor is soldered to the tape type oxide superconducting wire.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for connecting superconducting wires.

[0002]

2. Description of the Related Art Conventionally, for example, in a superconducting motor,
The coil of the superconducting magnet is placed in a cryogenic state and a permanent current is passed through the coil to drive the coil.
In this case, the coil is housed in the system of the cryostat and is cooled to a cryogenic temperature by liquid helium.

FIG. 8 is a circuit diagram of a superconducting device. In the figure, 11 is a switch for exciting the superconducting magnet, 1
Reference numeral 2 denotes an exciting power source, which can turn on the switch 11 to supply current to the coil 13 of the superconducting magnet. Reference numeral 16 is a conductive wire made of copper, 17 is a superconducting wire, and 18 is a switch superconducting wire.

The conductive wire 16 and the superconducting wire 17 have contact points 21,
The switch superconducting wire 18 is connected between the contacts 21 and 22. The broken line portion of the switch superconducting wire 18 constitutes a thermal permanent current switch 23, and a part of the switch superconducting wire 18 is usually surrounded by a heat insulating material such as FRP. Switch 1
1, the excitation power source 12 and the conducting wire 16 are placed in the normal conducting state, while the contacts 21, 22 and the superconducting wire 17, the switch superconducting wire 18, the permanent current switch 23 and the superconducting magnet (including the coil 13). It is housed in the system of the cryostat 25 shown by the one-dot chain line, cooled to a cryogenic temperature by a refrigerant such as liquid helium, and placed in a superconducting state.

Then, the switch superconducting wire 18 is
For example, when heat is applied by heating with a heating element to raise the temperature above the critical temperature, the switch superconducting wire 18 momentarily enters the normal conducting state and can have a finite resistance.
When the heating is stopped and the switch superconducting wire 18 is cooled to a cryogenic temperature by the cryostat 25 and placed in a superconducting state, the resistance of the switch superconducting wire 18 becomes effectively zero. In this way, the permanent current switch 23
The switch superconducting wire 18 can be turned off by heating and turned on by cooling.

In the superconducting device having the above structure, when the switch 11 is turned on, an electric current is supplied from the exciting power source 12 to the coil 13 of the superconducting magnet. At this time, the switch superconducting wire 18 is heated and placed in the normal conducting state, and the permanent current switch 23 is turned off. Then, when the current supplied to the coil 13 reaches the set value, the heating of the switch superconducting wire 18 is stopped and the permanent current switch 23 is turned on. In this state, when the current from the exciting power source 12 is gradually reduced, the corresponding current flows through the switch superconducting wire 18, and when the switch 11 is turned off, the switch superconducting wire 18 and the superconducting wire 17 are turned on.
The persistent current continues to circulate in the closed loop circuit formed between the coil 13 and the coil 13.

In the superconducting device having the above structure, as described above, the contact wire 21 and the superconducting wire 1 are provided at the contacts 21 and 22.
7 and the switch superconducting wire 18 are connected. 9 is a plan view of a connection portion of a conventional superconducting wire, and FIG. 10 is AA of FIG.
FIG. In the figure, 16a is a conductor 16 (FIG. 8)
, 17 is a superconducting wire, and 18 is a superconducting wire for a switch. The superconducting wire 17 is a NbT constituting a superconductor.
The ultrafine multifilamentary filament wire 17a is embedded in a base material 17b made of copper. The switch superconducting wire 18 is formed by embedding a NbTi extra fine multifilamentary filament wire 18a forming a superconductor in a base material 18b made of a copper-nickel alloy. And the electrode 1
6a uses a copper plate. And the superconducting wire 1
7 and the switch superconducting wire 18 are soldered to the electrode 16a at the portion indicated by the region P ₁ .

The NbTi extra-fine multi-core filament wires 17a and 18a each have an ultra-fine multi-core structure so that the NbTi extra-fine multi-filament wires 17a and 18a can be rapidly cooled to the central portion when the state is changed to the normal conduction state. .. FIG. 11 is a plan view of another conventional connecting portion of a superconducting wire, and FIG. 12 is a sectional view taken along line BB of FIG.

In the figure, 16a is an electrode of the conducting wire 16 (FIG. 8), 17 is a superconducting wire, and 18 is a superconducting wire for a switch. Similar to FIGS. 9 and 10, the superconducting wire 17 is made of NbTi extra fine multifilament wire 17a as a superconductor.
Is used as the base material 17b (FIG. 10). The switch superconducting wire 18 is made of NbT as a superconductor.
A copper-nickel alloy is used as the base material 18b for the i-fine multicore filament wire 18a. And the electrode 16a
Uses a copper plate.

In this case, the superconducting wire 17 and the switch
Part of superconducting wire 18 is melted with nitric acid.
By exposing the core filament wires 17a and 18a, the NbT
i Superfine multifilamentary filament wires 17a and 18a are overlaid and
Area P at the edge₂Spot welding as shown in
The superconducting wire 17 and the switch superconducting wire 18 are in the region P. ₃
It is soldered to the electrode 16a as shown by.

[0011]

However, in the above-mentioned conventional superconducting wire connecting method, in the case of the one shown in FIGS. 9 and 10, the electrode 16a itself, the base material 17b of the superconducting wire 17 and the switch superconducting wire 18 are provided. Since Joule heat is generated in each of the base materials 18b, the base material 18b partially transitions to the normal conducting state. In that case, resistance is generated in the portion that has transitioned to the normal conduction state, and Joule heat is generated by the resistance, further raising the temperature. Therefore, the part in the normal conduction state spreads and becomes a quench state. Moreover, in the cryostat 25, the extra refrigerant evaporates by the amount of the Joule heat generated.

In particular, in the case of the switch superconducting wire 18, since a copper-nickel alloy having a high resistance is used as the base material 18b, a large amount of Joule heat is generated and it is easy to transfer to the normal conducting state. In the case of the one shown in FIGS. 11 and 12,
Even if the NbTi ultrafine multifilamentary wires 17a and 18a are made into an ultrafine multifilamentary structure, the superconducting wire 17 and the switch superconducting wire 18 are connected to the electrode 16 by spot welding the tip.
Since it is soldered to a, it becomes a substantially single filament wire, and the cooling effect is reduced. Therefore, the advantage that the NbTi ultrafine multifilamentary wires 17a and 18a are prevented from directly contacting each other is lost.

Furthermore, since the solder and the NbTi extra fine multifilamentary filament wires 17a and 18a are not compatible with each other, electrical contact failure will occur. The present invention solves the problems of the conventional superconducting wire connection method, suppresses the generation of Joule heat in connecting the superconducting wire and the switch superconducting wire to the electrodes, and stabilizes the superconducting state in the superconducting wire. It is an object of the present invention to provide a superconducting wire connecting method capable of reducing evaporation of a refrigerant in a cryostat.

[0014]

Therefore, in the superconducting wire connecting method of the present invention, when connecting a plurality of superconducting wires formed by embedding an ultrafine multifilamentary filament wire in a base material, The base material of the superconducting wire is melted to expose the ultrafine multicore filament wire. Then, the exposed ultrafine multicore filament wire is coated with a good conductor, and the ultrafine multicore filament wire after coating the good conductor is soldered.

Further, when connecting a plurality of superconducting wires with each other, the base material of each superconducting wire is melted to expose the ultrafine multifilamentary filament wire, and the exposed ultrafine multifilamentary filament wire is coated with a good conductor. On the other hand, a tape-shaped oxide superconducting wire is soldered on the electrode of the conducting wire, and an ultrafine multicore filament wire after coating a good conductor is soldered on the tape-shaped oxide superconducting wire.

[0016]

According to the present invention, when connecting a plurality of superconducting wires formed by embedding the ultrafine multifilamentary filament wire in the base material as described above, the base material of each superconducting wire is melted to make the ultrafine multifilament wire. Expose the core filament wire. Then, the exposed ultrafine multicore filament wire is coated with a good conductor, and the ultrafine multicore filament wire after coating the good conductor is soldered.

Since each ultra-fine multi-core filament wire is covered with a good conductor, direct contact between the ultra-fine multi-core filament wires can be prevented and stabilized. Also, since a good conductor is present between the ultrafine multicore filament wire and the solder, good electrical contact is achieved. Furthermore, since there is no base material between the ultra-fine multi-core filament wires, the generation of Joule heat can be suppressed.

Next, when connecting a plurality of superconducting wires to each other, the base material of each superconducting wire is melted to expose the ultrafine multifilamentary filament wire, and the exposed ultrafine multifilamentary filament wire is coated with a good conductor. On the other hand, a tape-shaped oxide superconducting wire is soldered on the electrode of the conducting wire, and an ultrafine multicore filament wire after coating a good conductor is soldered on the tape-shaped oxide superconducting wire.

Therefore, between the superconducting wires, the current flows exclusively through the tape-shaped oxide superconducting wires and does not flow through the electrodes of the conducting wires, so that the generation of Joule heat can be prevented.

[0020]

Embodiments of the present invention will now be described in detail with reference to the drawings. FIG. 1 is a first step diagram in a superconducting wire connecting method showing an embodiment of the present invention, FIG. 2 is a second step diagram in a superconducting wire connecting method showing an embodiment of the present invention, and FIG. 3 is a third step diagram in the method of connecting superconducting wires showing an embodiment, FIG. 4 is a fourth step diagram in the method of connecting superconducting wires showing an example of the present invention, and FIG. 5 is a superconducting wire showing an example of the present invention. 5 is a fifth step diagram in the connection method of FIG. 6, and FIG. 6 is a sixth step diagram in the connection method of the superconducting wires showing an embodiment of the present invention. 4A to 6A are plan views of respective steps, and FIG. 6B is a sectional view.

In the figure, reference numeral 17 designates contacts 21 and 22 (see FIG. 8).
(See) and the coil 13 is a superconducting wire. The superconducting wire 17 is formed by embedding a NbTi extra fine multifilamentary filament wire 17a forming a superconductor in a base material 17b made of copper (see FIG. 10). The switch superconducting wire 18 also has a structure similar to that of the superconducting wire 17. The switch superconducting wire 18 is also formed by embedding a NbTi extra fine multifilamentary filament wire 18a forming a superconductor in a base material 18b made of a copper-nickel alloy.

In the first step, the superconducting wire 17 and the switch superconducting wire 18 are placed with the NbTi ultrafine multifilamentary wires 17a, 18a embedded in the base materials 17b, 18b (FIG. 1). In the second step, the base materials 17b and 18b are dissolved by nitric acid to expose the NbTi extra fine multifilamentary wires 17a and 18a (FIG. 2).

In the third step, the exposed N
bTi extra-fine multi-core filament wires 17a, 18a, copper,
A good conductor such as silver or indium is coated by electroplating (Fig. 3). Reference numerals 17c and 18c are NbTi ultrafine multifilamentary filament wires coated with a good conductor such as copper, silver or indium. The copper, silver, indium, and the like have a large resistance in the superconducting state, and by coating the NbTi ultrafine multifilamentary filament wires 17a and 18a, the effect of the ultrafine multifilament can be maintained.

In this case, since the layer formed by electroplating is very thin, Joule heat is not generated. In the fourth step, the superconducting wire 17 and the switch superconducting wire 18 are arranged in parallel, and the tips of the NbTi ultrafine multifilamentary wires 17c and 18c are crimped by a copper pipe 25 (FIG. 4).

In the fifth step, the tape-shaped oxide superconducting wire 26 is soldered to the surface of the electrode 16a formed of a copper plate. Next, the crimped NbTi microfine multifilamentary wire 17c formed in the fourth step,
While twisting 18c, the tape-shaped oxide superconducting wire 2
6 and solder (Fig. 5). In the sixth step, the area P ₄ shown by the broken line is covered with the flat wire 27 and soldered (FIG. 6).

FIG. 7 is a diagram showing a method of manufacturing a tape-shaped oxide superconducting wire. In the figure, 30 is a silver pipe,
The tape-shaped oxide superconducting wire 26 is formed by filling the silver pipe 30 with bismuth oxide superconducting powder, subjecting it to drawing and rolling, and then sintering. Such a tape-shaped oxide superconducting wire 26 is used for the electrode 16
Since it is soldered to a (FIG. 6), the current flows exclusively through the tape-shaped oxide superconducting wire 26 between the superconducting wire 17 and the NbTi ultrafine multifilamentary filament wires 17c and 18c of the switch superconducting wire 18. Become. Therefore, no current flows through the electrode 16a and Joule heat is not generated.

Further, each NbT of the switch superconducting wire 18 is
i Base material 17b, 18 between the ultra-fine multi-core filament wire 18c
b (see FIG. 10), current flows through the electroplating layers of copper, silver, indium, etc. that coat the NbTi ultrafine multifilamentary wires 17a and 18a and the solder that connects them, so that Joule heat is generated. Occurrence can be suppressed.

In the above-mentioned embodiment, the contact for connecting the conductor 16 (see FIG. 8), the superconducting wire 17 and the switch superconducting wire 18 is explained. However, the superconducting wires 17 are connected in parallel, and the switch superconducting wire is connected. It can be used as a contact for connecting 18 in parallel. It should be noted that the present invention is not limited to the above-described embodiments, and various modifications can be made based on the spirit of the present invention, and these are not excluded from the scope of the present invention.

[0029]

As described in detail above, according to the present invention, when connecting a plurality of superconducting wires formed by embedding an ultrafine multifilament wire in a base material, the mother wire of each superconducting wire is connected. The material is melted to expose the ultra-fine multicore filament wire.
Then, the exposed ultrafine multicore filament wire is coated with a good conductor, and the ultrafine multicore filament wire after coating the good conductor is soldered.

Since each ultra-fine multi-core filament wire is covered with a good conductor, direct contact between the ultra-fine multi-core filament wires can be prevented and the superconducting state can be stabilized. Also, since a good conductor is present between the ultrafine multicore filament wire and the solder, good electrical contact is achieved. Further, since there is no base material between the ultra-fine multi-core filament wires, it is possible to suppress the generation of Joule heat and prevent the quenching state. Further, the amount of refrigerant used in the cryostat can be reduced.

Next, when a plurality of superconducting wires are connected to each other, the base material of each superconducting wire is melted to expose the ultrafine multicore filament wire, and the exposed ultrafine multicore filament wire is coated with a good conductor. On the other hand, a tape-shaped oxide superconducting wire is soldered on the electrode of the conducting wire, and an ultrafine multicore filament wire after coating a good conductor is soldered on the tape-shaped oxide superconducting wire.

Therefore, between the superconducting wires, the current flows exclusively through the tape-shaped oxide superconducting wires and does not flow through the electrodes of the conducting wires, so that it is possible to prevent the generation of Joule heat and prevent the quench state. be able to. Further, the amount of refrigerant used in the cryostat can be reduced.

[Brief description of drawings]

FIG. 1 is a first process diagram in a method of connecting superconducting wires showing an embodiment of the present invention.

FIG. 2 is a second process diagram in the method of connecting superconducting wires showing the embodiment of the present invention.

FIG. 3 is a third process diagram in the method of connecting superconducting wires showing the embodiment of the present invention.

FIG. 4 is a fourth step diagram in the method of connecting superconducting wires showing an example of the present invention.

FIG. 5 is a fifth step diagram in the method of connecting superconducting wires showing the embodiment of the present invention.

FIG. 6 is a sixth step diagram in the method of connecting superconducting wires showing the embodiment of the present invention.

FIG. 7 is a diagram showing a method for manufacturing a tape-shaped oxide superconducting wire.

FIG. 8 is a circuit diagram of a superconducting device.

FIG. 9 is a plan view of a connection portion of a conventional superconducting wire.

10 is a cross-sectional view taken along the line AA of FIG.

FIG. 11 is a plan view of another conventional superconducting wire connecting portion.

12 is a sectional view taken along line BB of FIG.

[Explanation of symbols]

16 Conductive wire 16a Electrode 17 Superconducting wire 17b, 18b Base material 18 Superconducting wire for switch 17a, 17c, 18a, 18c NbTi extra fine multifilamentary filament wire 26 Tape-shaped oxide superconducting wire

Claims (2)

[Claims] 1. A superconducting wire connecting method for connecting a plurality of superconducting wires formed by embedding an ultrafine multicore filament wire in a base material, comprising: (a) melting the base material of each superconducting wire Exposing the core filament wire, (b) coating the exposed ultrafine multicore filament wire with a good conductor, (c)
A method for connecting superconducting wires, characterized in that soldering is carried out between the ultrafine multifilamentary wires after coating the good conductor. 2. A superconducting wire connecting method for connecting a plurality of superconducting wires formed by embedding an ultrafine multifilamentary wire in a base material, comprising: (a) melting the base material of each superconducting wire Exposing the core filament wire, (b) coating the exposed ultrafine multicore filament wire with a good conductor, (c)
A tape-shaped oxide superconducting wire is soldered on an electrode of a conductor, and (d) a superconducting multifilament filament wire coated with a good conductor is soldered onto the tape-shaped oxide superconducting wire. Connection method.