JP2019096849A - Permanent current switch - Google Patents

Abstract

To provide a permanent current switch in which switching from on to off is accelerated.SOLUTION: Permanent current switches S1, S2, S3 include non-inductive coils around which a superconducting tape 10 is wound. By winding the superconducting tape 10, a superconducting layer 16 (superconductor) is disposed in a spiral shape. Furthermore, a heater tape 20 provided as a part of or separately from the superconducting tape 10 is disposed in a spiral shape along the superconducting layer 16 between turns of the superconducting layer 16.SELECTED DRAWING: Figure 2A

Description

  The present invention relates to permanent current switches.

  In the permanent current switch (PCS; Persistent Current Switch) disclosed in Patent Document 1, a heater resistor is wound on the inner circumferential side of the winding portion of the superconducting wire.

JP, 2016-131231, A

  However, the permanent current switch of Patent Document 1 has room for improvement in the switching speed from on to off.

  An object of the present invention is to provide a permanent current switch whose switching from on to off is speeded up.

  The permanent current switch according to the first aspect is a permanent current switch including a non-induction coil in which a superconducting tape is wound, and the superconducting tape is wound so that the superconductor of the superconducting tape is spirally wound. The heater tape, which is disposed as a part of or separately from the superconducting tape, is disposed spirally along the superconductor between turns of the superconductor.

(Action effect)
In this aspect, the non-induction coil is configured by winding the superconducting tape, whereby the superconductor of the superconducting tape is disposed in a spiral shape. Furthermore, a heater tape is provided, and the heater tape is spirally disposed along the superconductor between turns of the superconductor. For this reason, the heating efficiency of the superconductor is better as compared with the aspect in which the heater tape is not disposed between the turns of the superconductor. Therefore, the switching of the superconducting switch to off can be speeded up.

  The heater tape may be provided as part of the superconducting tape or may be provided separately.

  In the permanent current switch according to the second aspect, in the first aspect, the winding size of the non-induction coil has an axial dimension equal to or less than 1.5 times a radial dimension.

(Action effect)
In this aspect, the winding portion of the superconducting tape has an axial dimension of not more than 1.5 times the radial dimension. For this reason, the heat transfer distance from the axial direction outer side of the winding part of a superconducting tape to the center part of a winding part is short. Therefore, the cooling efficiency at the time of cooling of the superconductor (that is, at the time of switching to ON) can be improved, and the switching to ON can be speeded up.

  In the permanent current switch according to the third aspect, in the first or second aspect, the heater tape is provided separately from the superconducting tape, and is co-wound with the superconducting tape.

  In the permanent current switch according to the fourth aspect, in the first or second aspect, the heater tape is provided as a part of the superconducting tape, and the superconducting tape is a base material as the heater tape; It comprises: an orientation intermediate layer formed on a substrate; and a superconducting layer as the superconductor formed on the orientation intermediate layer and insulated from the substrate.

(Action effect)
In this aspect, the permanent current switch can be manufactured without co-winding a heater tape provided separately from the superconducting tape.

  The permanent current switch according to the fifth aspect is any of the first to fourth aspects, wherein an aluminum tape is co-wound on the superconducting tape.

(Action effect)
If heater heating for switching off is performed while the permanent current switch is energized, heat generation due to heater heating and magnetic flux flow may be uneven due to the position of the superconducting tape, and heat generation may be concentrated. Thermal runaway may cause burnout.
Therefore, in this aspect, the aluminum tape is co-wound on the superconducting tape.
Since the aluminum tape of high thermal conductivity is arranged along the superconducting tape, non-uniformity in temperature rise due to the position of the superconducting tape can be suppressed, and as a result, burnout can be suppressed.

  In the permanent current switch according to the sixth aspect, in the third aspect, the heater tape is co-wound in a state of being disposed between the right-handed tape and the left-handed tape of the superconducting tape.

  In the permanent current switch according to the seventh aspect, in the third aspect, the heater tape is co-wound in a state where the right-turn tape and the left-turn tape are disposed outside the right-turn tape.

  In the permanent current switch according to the eighth aspect, in the third aspect, the heater tape is co-wound in a state where the heater tape is disposed between both the right-handed tape and the left-handed tape of the superconducting tape. .

(Action effect)
In this aspect, since the heater tape is co-wound in a state of being disposed between the right-handed tape and the left-handed tape of the superconducting tape both at the outer side and the outer side, co-wound in a state where only one of them is disposed. The heating efficiency of the superconductor is better than that of the above embodiment.

  A permanent current switch according to a ninth aspect is the inner heater tape according to the eighth aspect, which is the heater tape co-wound in a state of being disposed between the right-handed tape and the left-handed tape, and the right The wound tape and the outer heater tape, which is the heater tape co-wound in a state of being disposed outside the left-handed tape, are connected to another power source.

(Action effect)
In this aspect, since the inner heater tape and the outer heater tape are connected to different power supplies, even when an abnormality occurs in either one of the inner heater tape and the outer heater tape, the permanent current switch can be switched by the other heater tape. It can be switched to the off state.

  A permanent current switch according to a tenth aspect is the inner heater tape according to the eighth aspect, which is the heater tape co-wound in a state of being disposed between the right-handed tape and the left-handed tape, and the right The wound tape and the outer heater tape which is the heater tape co-wound in a state of being disposed outside the left-handed tape are connected to each other.

(Action effect)
In this aspect, since the inner heater tape and the outer heater tape are connected to each other, they can be heated by a single power source.

  According to the present invention, it is possible to obtain a permanent current switch in which switching from on to off is accelerated.

It is a typical sectional view of the superconducting tape of an embodiment. It is a typical sectional view of a permanent current switch of a 1st embodiment. It is the 2B-2B line sectional view of Drawing 2A. It is a perspective view which shows the arrangement | positioning relationship of the superconducting tape in 1st Embodiment, and a heater tape. It is sectional drawing which shows the permanent current switch of 1st Embodiment with a heat-transfer cooling plate. FIG. 6 is a schematic cross-sectional view of a case where two heater power supplies are used in the permanent current switch according to the first embodiment. It is a typical sectional view of a permanent current switch of a 2nd embodiment. FIG. 3B is a cross-sectional view taken along line 3B-3B of FIG. 3A. It is a perspective view which shows the arrangement | positioning relationship of the superconducting tape in 2nd Embodiment. It is a typical sectional view of a permanent current switch of a 3rd embodiment. FIG. 4B is a cross-sectional view taken along line 4B-4B of FIG. 4A. It is a perspective view which shows the arrangement | positioning relationship of the superconducting tape in 3rd Embodiment, a heater tape, and an aluminum tape.

First Embodiment
A first embodiment of the present invention will be described using FIGS. 1 to 2D.

(Outline)
The permanent current switch S1 of the first embodiment includes a non-induction coil around which the superconducting tape 10 is wound, and a heater tape 20 around which the superconducting tape 10 is co-wound. Then, in a state where the wound superconducting tape 10 and the heater tape 20 are accommodated in the insulating case 30, the shape is fixed by resin impregnation.

(Superconducting tape)
First, the superconducting tape 10 will be described.

  The superconducting tape 10 is a tape-shaped superconducting wire, and is, for example, a rare earth-based (hereinafter, “RE-based”) superconducting wire. The cross-sectional structure of the superconducting tape 10 is schematically shown in FIG. As shown in FIG. 1, the superconducting tape 10 has a laminated structure constituted by a tape-shaped base 12, an orientation intermediate layer 14, a superconducting layer 16, and a protective layer 18. On the tape-shaped substrate 12, an orientation intermediate layer 14, a superconducting layer 16, and a protective layer 18 are laminated in this order. The superconducting tape 10 is a high temperature superconducting wire whose critical temperature is about 35 K or more.

  The base 12 is preferably made of a high-strength metal material excellent in heat resistance, and is made of, for example, a nickel alloy such as Hastelloy (registered trademark). The thickness of the substrate 12 is, for example, 1 to 500 μm.

The alignment intermediate layer 14 is a layer having a function of suppressing the growth inhibition of the superconducting film and the deterioration of the superconducting characteristics due to the diffusion of the metal element of the base 12 into the superconductor. The orientation intermediate layer 14 is preferably formed using a material such as CeO ₂ , MgO, Y ₂ O ₃ , Al ₂ O ₃ or the like which is excellent in crystal orientation and has an expansion coefficient close to that of the superconducting layer 16. . The thickness of the alignment intermediate layer 14 is, for example, 0.06 to 6 μm. The alignment intermediate layer 14 is an insulator.

The superconducting layer 16 is preferably formed of a high critical temperature oxide superconductor by laser deposition or the like. As an oxide superconductor having a high critical temperature, REBa ₂ Cu ₃ O _y (RE represents one or more of rare earth elements), YBa ₂ Cu ₃ O _7-x , or GdBa ₂ Cu ₃ O _7-x etc. can be illustrated.

  The protective layer 18 is a layer of Ag or an Ag alloy, and has a function of protecting the superconducting layer 16 from moisture and the like. The thickness of the protective layer 18 is, for example, 1 to 30 μm.

  A polyimide film 19 as an “electrical insulating material” is formed around the laminated structure of the base 12, the alignment intermediate layer 14, the superconducting layer 16, and the protective layer 18 described above. The polyimide film 19 can be formed by electrodeposition coating.

(Heater tape)
Next, the heater tape 20 will be described.

  The heater tape 20 is a tape-like wire (tape wire). The material of the heater tape 20 is preferably a material that effectively generates Joule heat, and is made of stainless steel in the present embodiment. The width of the heater tape 20 is preferably substantially the same as the width of the superconducting tape 10.

(Production method)
The permanent current switch S1 is manufactured by winding the superconducting tape 10 to form a non-induction coil and simultaneously co-winding the heater tape 20 with the superconducting tape 10 and further performing shape fixation by resin impregnation in the insulating case 30. . The insulating case 30 is made of, for example, a heat insulating material such as GFRP (glass fiber reinforced plastic).

  Specifically, as shown in FIG. 2C, two superconducting tapes 10R and 10L are stacked, and their end portions are soldered to form a solder connection portion 10H. At this time, the two superconducting tapes 10R and 10L are connected to each other with the protective layers 18 facing each other. And while arrange | positioning the heater tape 20 (henceforth "the inner side heater tape 20U") between two superconducting tapes 10R and 10L, the heater tape 20 (henceforth "the outer side heater is also carried out outside the two superconducting tapes 10 Place the tape 20S. Then, the inner heater tape 20U and the outer heater tape 20S are connected by the heater connection portion 21 which is closest to the solder connection portion 10H. Furthermore, the two superconducting tapes 10R and 10L and the two heater tapes 20U and 20S are wound around the winding frame 32 of the insulating case 30 in a state of being superimposed. At this time, the solder connection portion 10H is on the winding start side (inner peripheral side of the non-induction coil). As described above, since the polyimide film 19 is formed around the superconducting tape 10, the layered structure of the superconducting tape 10 and the heater tape 20 are insulated. Then, the epoxy resin is injected into the insulating case 30 and cured to fix the shape.

(Structure of permanent current switch)
2A and 2B schematically show the structure of the permanent current switch S1. Although a structure having a small number of turns is illustrated for simplicity, the actual number of turns is, for example, 2 to 500.

  As shown in FIGS. 2A and 2B, the two superconducting tapes 10R and 10L and the two heater tapes 20U and 20S are all arranged spirally with the thickness direction being in the coil radial direction.

  One superconducting tape 10R of the two superconducting tapes 10R and 10L is in the state of being disposed on the outer side in the coil radial direction with respect to the other superconducting tape 10L. Therefore, hereinafter, this one superconducting tape 10R is referred to as an outer superconducting tape 10R, and the other superconducting tape 10 is referred to as an inner superconducting tape 10L.

  The outer circumferential side which is the winding end side of the two superconducting tapes 10R and 10L is drawn out of the insulating case 30. Then, current flows in the superconducting tape 10 in the direction of the current flow shown in FIG. 2A. Therefore, a clockwise current flows in the illustrated direction in the outer superconducting tape 10R, and a counterclockwise current flows in the inner superconducting tape 10L. Therefore, hereinafter, the outer superconducting tape 10R is referred to as a right-handed tape 10R, and the inner superconducting tape 10L is referred to as a left-handed tape 10L.

  The right-handed tape 10R and the left-handed tape 10L generate magnetic fields in opposite directions, so the coil formed by winding the two superconducting tapes 10R and 10L is a non-induction coil that does not generate a magnetic field.

  The heater tape 20 is disposed between all the turns of the superconducting tape 10 by the two heater tapes 20U and 20S. On the other hand, the heater tape 20 is not disposed outside the outermost turns of the superconducting tape 10 or inside the innermost turns of the superconducting tape 10 (that is, from the arrangement position of the heater tape 20, the induction tape is not Outer surface and inner surface are removed). The inner peripheral ends of the two heater tapes 20U and 20S are connected to each other by the heater connection portion 21, and the outer peripheral ends are connected to the heater power supply 80. The heater tape 20 is heated by Joule heat by supplying a current to the two heater tapes 20 by the heater power supply 80. The heating of the heater tape 20 heats the superconducting layer 16 of the superconducting tape 10 disposed along the heater tape 20, and the superconducting tape 10 is in the normal conduction state, whereby the permanent current switch S1 is turned off. .

  Further, as shown in FIG. 2D, the heat transfer cooling plate 40 is attached to the insulating case 30. The heat transfer cooling plate 40 is connected to a refrigerator (not shown) and cools the insulating case 30 (permanent current switch S1).

  The heat transfer cooling plate 40 has an enclosure 42 surrounding the insulating case 30, and a connection 44 connecting the enclosure 42 and the refrigerator. The surrounding portion 42 is configured to surround the periphery of the insulating case 30 (specifically, all around the coil radial direction outer side and the coil axial direction outer side), and is in close contact with the insulating case 30. By cooling the heat transfer cooling plate 40 with a refrigerator, the non-induction coil is cooled via the insulating case 30, and the superconducting tape 10 is brought into a superconducting state. As a result, the permanent current switch S1 is turned on.

<Function effect>
Next, the operation and effect of the present embodiment will be described.

  In the present embodiment, the non-induction coil is configured by winding the superconducting tape 10, whereby the superconducting layer 16 (superconductor) of the superconducting tape 10 is disposed in a spiral shape. Furthermore, a heater tape 20 is provided, and the heater tape 20 is spirally disposed along the superconducting layer 16 between turns of the superconducting layer 16. Therefore, the heating efficiency of the superconductor is better as compared with the embodiment in which the heater tape 20 is not disposed between the turns of the superconducting layer 16. Therefore, the switching of the permanent current switch S1 to the off state can be speeded up.

  Further, in the present embodiment, the axial dimension H of the wound portion of the superconducting tape 10 is equal to or less than 1.0 times the diameter dimension R (see FIG. 2D). The heat transfer distance from the axial direction outer side of the winding portion of the superconducting tape 10 to the central portion of the winding portion is shortened by setting the axial dimension H to 1.5 times or less or further 1.0 times or less of the diameter dimension R Can. Therefore, the cooling efficiency of the superconductor can be improved, and the switching to ON can be speeded up. The axial dimension H of the wound portion substantially corresponds to the width of the superconducting tape 10, and the radial dimension R of the wound portion means the distance from the inner circumferential surface to the outer circumferential surface of the wound portion (non-induction coil).

  Further, in the present embodiment, as shown in FIG. 2C etc., the heater tape 20 is co-wound in a state of being disposed between both the right-handed tape 10R and the left-handed tape 10L of the superconducting tape 10 Therefore, the heating efficiency of the superconductor is better as compared with the embodiment arranged in only one of them.

  Further, in the present embodiment, since the inner heater tape 20U and the outer heater tape 20S are connected to each other, heating can be performed by a single heater power supply 80.

<Supplementary explanation of the first embodiment>
In the above embodiment, the superconducting tape may be replaced with a RE-based superconducting tape to be a bismuth-based (Bi-based) superconducting tape. Moreover, the heater tape 20 is not limited to stainless steel.

Further, although the example using the superconducting tape 10 in which the polyimide film 19 is formed on the periphery to insulate the laminated structure of the superconducting tape 10 from the heater tape 20 has been described above, the laminated structure of the superconducting tape 10 An insulating tape (fluorine-coated polyimide tape) may be spirally wound around the periphery.
The superconducting layer 16 and the heater tape 20 may be insulated by forming an insulating layer with a polyimide film or a fluorine-coated polyimide tape not around the laminated structure of the superconducting tape 10, but around the heater tape 20.

  In the above-described embodiment, the inner heater tape 20U and the outer heater tape 20S are connected to each other, and an example in which heating is performed by a single heater power supply 80 has been described. However, the present invention is not limited thereto. For example, without connecting the inner heater tape 20U and the outer heater tape 20S, the respective heater tapes 20 may be connected to separate heater power supplies 80, 81 (see FIG. 2E). In this case, even if one heater tape 20 is broken, the permanent current switch S1 can be turned off by the other heater tape 20.

Second Embodiment
Next, a second embodiment of the present invention will be described using FIGS. 3A to 3C.

The difference from the first embodiment of the second embodiment is that the heater tape 20 separate from the superconducting tape 10 is not provided. Instead, in the second embodiment, the base material 12 constituting a part of the superconducting tape 10 is used as the heater tape 20.
Since the other configurations are substantially the same, the same reference numerals are given to the drawings and the description will be appropriately omitted.

  The superconducting tape 10 of the present embodiment is formed such that the base 12 and the superconducting layer 16 are in an insulating state. That is, although the alignment intermediate layer 14 interposed between the base 12 and the superconducting layer 16 is an insulating layer, there is a possibility that the base 12 and the superconducting layer 16 may short circuit due to silver (Ag) attached around the laminated structure. is there. The superconducting tape 10 of this embodiment needs to be manufactured so that this short circuit does not occur.

(Production method)
In the second embodiment, as shown in FIG. 3C, two superconducting tapes 10R and 10L are stacked, and their ends are soldered to form a solder connection portion 10H. At this time, the two superconducting tapes 10R and 10L are connected to each other with the protective layers 18 facing each other. Further, the base members 12 of the two superconducting tapes 10R and 10L are connected to each other by the heater connection portion 21 closest to the solder connection portion 10H. Then, in a state where the two superconducting tapes 10R and 10L are superimposed, the solder connection portion 10H is wound around the winding frame 32 as the winding start side. Here, in the present embodiment, it is not necessary to arrange the heater tape 20 provided separately.

  FIGS. 3A and 3B schematically show the structure of the permanent current switch S2 of this embodiment.

  As shown in FIGS. 3A and 3B, the superconducting tape 10 is wound from the inner periphery toward the outer periphery with the thickness direction (stacking direction) directed in the coil radial direction. Therefore, the superconducting layer 16 of the superconducting tape 10 is disposed in a spiral shape, and the base 12 is disposed along the superconducting layer 16 between the turns of the superconducting layer 16 disposed in a spiral shape. More specifically, the substrate 12 is disposed between all the turns of the superconducting layer 16.

  A heater power supply 80 is connected to the base 12 at the outer end of the two superconducting tapes 10. By supplying power from the heater power supply 80, a current flows through the base 12, and the Joule heat can heat the superconducting layer 16.

<Function effect>
Next, the operation and effect of the second embodiment will be described.

  Also in the present embodiment, the non-induction coil is configured by winding the superconducting tape 10, whereby the superconducting layer 16 (superconductor) of the superconducting tape 10 is disposed in a spiral shape. Furthermore, the base material 12 as the heater tape 20 is spirally disposed along the superconducting layer 16 between turns of the superconducting layer 16. Therefore, the heating efficiency of the superconductor is better as compared with the embodiment in which the heater tape 20 is not disposed between the turns of the superconducting layer 16. Therefore, the switching of the permanent current switch S1 to the off state can be speeded up.

  Further, in the present embodiment, the base material 12 constituting a part of the superconducting tape 10 is the heater tape 20. Therefore, the permanent current switch S2 can be manufactured without co-winding the heater tape 20 provided separately from the superconducting tape 10.

  Further, in the present embodiment, since the base material 12 constituting a part of the superconducting tape 10 is the heater tape 20, the heater tape 20 is disposed between all the turns of the superconducting layer 16. For this reason, the heating efficiency by the heater tape 20 is good, and the off switching is speeded up.

Third Embodiment
Next, a third embodiment of the present invention will be described using FIGS. 4A to 4C.

  The difference from the first embodiment of the third embodiment is that the permanent current switch S3 further includes an aluminum tape 50. Moreover, it is different also in the point which is not equipped with the outer side heater tape 20S.

  In the third embodiment, as shown in FIG. 4C, two superconducting tapes 10R and 10L are stacked, and their ends are soldered to form a solder connection portion 10H. Then, the heater tape 20 (inner heater tape 20U) is disposed between the two superconducting tapes 10R and 10L. On the other hand, an aluminum tape 50 is disposed on the outside of the two superconducting tapes 10.

  Then, the two superconducting tapes 10R and 10L, the heater tape 20, and the aluminum tape 50 are wound around the winding frame 32 of the insulating case 30 in a state of being superimposed. At this time, the solder connection portion 10H is on the winding start side (inner peripheral side of the non-induction coil). Then, the epoxy resin is injected into the insulating case 30 and cured to fix the shape.

  FIGS. 4A and 4B schematically show the structure of the permanent current switch S3 of the third embodiment.

  A heater power supply 80 is connected to the outer end and the inner end of the heater tape 20U. On the other hand, no power supply or the like is connected to the aluminum tape 50.

<Function effect>
Next, the operation and effect of the third embodiment will be described.

  Also in the present embodiment, the non-induction coil is configured by winding the superconducting tape 10, whereby the superconducting layer 16 (superconductor) of the superconducting tape 10 is disposed in a spiral shape. Furthermore, a heater tape 20U is provided, and the heater tape 20U is spirally disposed along the superconducting layer 16 between turns of the superconducting layer 16. Therefore, the heating efficiency of the superconductor is better as compared with the embodiment in which the heater tape 20 is not disposed between the turns of the superconducting layer 16. Therefore, the switching of the permanent current switch S1 to the off state can be speeded up.

By the way, if heater heating for switching off is performed while the permanent current switch is energized, heat generation due to heater heating and magnetic flux flow and heat generation due to normal conduction transition may become uneven depending on the position of the superconducting tape, Can cause thermal runaway and burnout.
Therefore, in the present embodiment, the aluminum tape 50 is co-wound on the superconducting tape 10. Since the aluminum tape 50 with high thermal conductivity is disposed along the superconducting tape 10, non-uniformity in temperature rise due to the position of the superconducting tape 10 is suppressed. As a result, burnout can be suppressed.

  In the third embodiment, the heater tape 20 (inner heater tape 20U) is disposed between the two superconducting tapes 10R and 10L while the aluminum tape 50 is disposed outside the two superconducting tapes 10. Although the example has been described, the arrangement relationship between the heater tape 20 and the aluminum tape 50 may be reversed. The superconducting tape 10 and the aluminum tape 50 may be co-wound in a mode in which the heater tape 20 is not co-wound with the base material 12 as in the second embodiment as the heater tape 20.

[Supplementary explanation]
In the above embodiment, the “inverted portion”, which is the portion where the winding direction is reversed in the non-induction coil, is the soldered portion (solder connection portion 10H), but by folding back one superconducting tape 10 You may form an inversion part.
In the above embodiment, an example is described in which the reversing part is on the winding start side (radially inner side of the non-induction coil), but the reversing part may be on the winding end side (radial direction outside of the non-induction coil).

  Further, although the example (example of conduction cooling) in which the permanent current switch S1 is cooled by the heat transfer cooling plate 40 (see FIG. 2D) connected to the refrigerator has been described in the above embodiment, the present invention is not limited thereto . For example, the insulating case 30 may be cooled by immersion in a refrigerant such as liquid nitrogen or liquid helium (immersion cooling).

S1 permanent current switch S2 permanent current switch S3 permanent current switch 10 superconducting tape 10H solder connection portion (inversion portion)
10R outer superconducting tape (right-handed tape)
10 L inner superconducting tape (left-handed tape)
12 base material 14 orientation intermediate layer 16 superconducting layer (superconductor)
18 Protective layer 19 Polyimide film (electrical insulating material)
Reference Signs List 20 heater tape 21 heater connection portion 20U inner heater tape 20S outer heater tape 30 insulating case 32 winding frame 40 heat transfer cooling plate 50 aluminum tape 80 heater power supply 81 heater power supply H winding dimension axial dimension R winding dimension

Claims (10)

A permanent current switch comprising a non-inductive coil wound with a superconducting tape, comprising:
By winding the superconducting tape, the superconductor of the superconducting tape is disposed in a spiral shape.
A heater tape provided as a part or a separate body of the superconducting tape is disposed in a spiral shape so as to be along the superconductor between turns of the superconductor.
Permanent current switch. In the winding portion of the non-inductive coil, the axial dimension is not more than 1.5 times the radial dimension,
The permanent current switch according to claim 1. The heater tape is provided separately from the superconducting tape, and is co-wound with the superconducting tape.
The permanent current switch according to claim 1 or 2. The heater tape is provided as part of the superconducting tape.
The superconducting tape is formed on the substrate as the heater tape, an alignment interlayer formed on the substrate, and the superconductor formed on the alignment interlayer and insulated from the substrate. And a superconducting layer of
The permanent current switch according to claim 1 or 2. An aluminum tape is co-wound on the superconducting tape,
The permanent current switch according to any one of claims 1 to 4. The heater tape is co-wound in a state of being disposed between the right-handed tape and the left-handed tape of the superconducting tape.
The permanent current switch according to claim 3. The heater tape is co-wound in a state of being disposed outside the right-handed tape and the left-handed tape of the superconducting tape.
The permanent current switch according to claim 3. The heater tape is co-wound in a state where the heater tape is disposed between both the right-handed tape and the left-handed tape of the superconducting tape.
The permanent current switch according to claim 3. An inner heater tape, which is the heater tape co-rolled in a state of being disposed between the right-handed tape and the left-handed tape, and co-wound in a state of being disposed outside the right-handed tape and the left-handed tape The external heater tape which is the heater tape which has been set is connected to a separate power supply,
A permanent current switch according to claim 8. An inner heater tape, which is the heater tape co-rolled in a state of being disposed between the right-handed tape and the left-handed tape, and co-wound in a state of being disposed outside the right-handed tape and the left-handed tape And the outer heater tape which is the heated heater tape are mutually connected,
A permanent current switch according to claim 8.