JP2003197048A - Dislocated superconductive tape unit and superconductive application apparatus using it - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a dislocated superconductive tape unit capable of maintaining a dislocated standing structure even when bending distortion is applied by a wire winding process or the like, reducing an alternating current loss in energization of an alternating current, and suppressing drift, and a superconductive application apparatus using the dislocated superconductive tape unit. <P>SOLUTION: The dislocated superconductive tape unit 15 is composed by arranging laminated bodies 18a and 18a of a plurality of tape-like superconductors 18 in parallel and stranding the plurality of tape-like superconductors 18 composing the laminated bodies 18a and 18a in a dislocated state. A tape 30 for maintaining the dislocated stranding structure is wound with play around the dislocated superconductive tape unit, and one portion of the tape 30 for maintaining the dislocated stranding structure is interposed between the laminated bodies of the plurality of the tape-like superconductors. The superconductive application apparatus uses the dislocated superconductive tape unit 15. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a dislocation superconducting tape unit in which a plurality of tape-shaped superconducting conductors are twisted together and a superconducting application device using the transposition superconducting tape unit. In particular, the present invention relates to a dislocation superconducting tape unit capable of maintaining a dislocation twist structure and suppressing a drift when an alternating current is applied, and a superconducting applied device using the same.

[0002]

2. Description of the Related Art In a superconducting application device such as a superconducting cable, a superconducting transformer, a superconducting magnet, a superconducting fault current limiter or the like, a dislocation superconducting tape unit in which a plurality of tape-shaped superconducting conductors are dislocated and twisted is used. FIG. 12 is a perspective view showing an example of a superconducting cable provided with a conventional dislocation superconducting tape unit, and FIG. 13 is an explanatory view of a dislocation superconducting tape unit provided in the superconducting cable of FIG. ) Is a perspective view and (b) is a sectional view. Figure 1
The superconducting cable 110 of No. 2 has a structure that suppresses uneven flow when an alternating current is applied, and has a dislocation superconducting tape unit 1 around a pipe-shaped former 117.
15 is spirally wound to superpose a plurality of superconductor layers 124, and an interlayer insulating layer 125 made of an insulating tape or the like is interposed between the superconductor layers 124. This dislocation superconducting tape unit 115 is shown in FIG.
As shown in (a), a plurality of tape-shaped superconducting conductors (superconducting tapes) 118 (five in the drawing) are long strands formed by twisting dislocations. In this dislocation superconducting tape unit 115, when a plurality of tape-shaped superconducting conductors 118 are gathered and twisted together, each tape-shaped superconducting conductor 118 is sequentially displaced in its longitudinal direction and displaced. By twisting, the impedance of each superconducting element wire 119 described later is made uniform.

The surface of the former 117 is
7 and the dislocation superconducting tape unit 115 are insulated in order to suppress the current flow. Further, the inside of the former 117 serves as a flow path of a cooling medium, and the tape-shaped superconducting conductor 118 is cooled. In the tape-shaped superconducting conductor 118, as shown in FIG. 13B, the surface of the tape-shaped superconducting element wire 119 obtained by flattening the superconducting multi-core element wire (superconducting element wire) is subjected to sulfurization treatment. High resistance film 12
0 is formed. The superconducting multifilamentary wire is provided with a core portion made of a superconductor such as a superconducting filament or a core portion having a material which becomes a superconductor by heat treatment inside a base made of a sheath material formed of Ag or the like. It is a thing. As the superconductor of the core portion or the material which becomes the superconductor by heat treatment, Bi is
₂ Sr ₂ Ca ₁ Cu ₂ O _x (Bi2212 phase), Bi ₂ Sr ₂
A material having a composition such as Ca ₂ Cu ₃ O _y (Bi2223 phase) is used. A semiconductor layer, an insulating layer, a protective layer, a heat insulating layer, an anticorrosive layer, and the like (not shown) are formed and used on the outside of the superconducting cable 110 having the above-described configuration, if necessary.

[0004]

In the conventional dislocation superconducting tape unit 115, since the tape-shaped superconducting conductor 118 has a high rigidity and the dislocation twist structure is easily disturbed, the dislocation superconducting tape unit 115 is arranged at regular intervals. As shown by the chain double-dashed line in FIG. 13, the adhesive tape 127 was wound and attached in a ring shape. This adhesive tape 127
Is an adhesive layer formed on the entire surface on the side in contact with the dislocation superconducting tape unit 115.

However, the adhesive tape 12 as described above
Dislocation superconducting tape unit 115 to which 7 is attached
Since each superconducting conductor 118 is fixed to the adhesive tape 127, in other words, since a plurality of superconducting conductors 118 are integrated, the dislocation superconducting tape unit 115 has a bending strain. When applied, the plurality of integrated superconducting conductors 118 are distorted, and in particular, the tape-shaped superconducting conductor 118 located at the uppermost portion (outermost portion) of the dislocation superconducting tape unit 115.
A large bending strain may be added to.

When the dislocation superconducting tape unit 115 is applied to a superconducting application device such as a superconducting cable, a step of winding the dislocation superconducting tape unit 115 around the former 117 or a superconducting tape in which the dislocation superconducting tape unit 115 is wound around the former 117. Although a certain strain is applied to the dislocation superconducting tape unit 115 in a process such as winding the cable 110 on a drum, in the dislocation superconducting tape unit 115 to which the adhesive tape 127 as described above is attached, Bending strain may be applied more than the permissible value of the tape-shaped superconducting conductor 118. When the superconducting conductor 118 is greatly distorted in this way, the dislocation twist structure is disturbed, the AC loss increases when an AC current is applied, and a drift occurs. Will end up.

The present invention has been made in view of the above circumstances, and can maintain the dislocation twist structure even when bending strain is applied by winding processing or the like, reduce the AC loss when an AC current is applied, and cause a drift It is an object of the present invention to provide a dislocation superconducting tape unit that can suppress the occurrence of heat. Further, the present invention is a superconducting cable using a dislocation superconducting tape unit that can maintain a dislocation twist structure even when bending strain is applied by winding processing or the like, can reduce AC loss when an AC current is applied, and can suppress drift. Another purpose is to provide superconducting applied equipment such as superconducting transformers, superconducting magnets, and superconducting fault current limiters.

[0008]

DISCLOSURE OF THE INVENTION The present invention is a dislocation in which a plurality of tape-shaped superconducting conductor laminates are arranged in parallel, and the plurality of tape-like superconducting conductors constituting these laminates are dislocated and twisted together. A superconducting tape unit, wherein a dislocation twist structure retaining tape is wound around the dislocation superconducting tape unit with play, and a part of the dislocation twist structure retaining tape is formed of the plurality of tape-shaped superconducting conductors. A dislocation superconducting tape unit, which is characterized in that it is interposed between the laminated bodies, is a means for solving the above problems.

In the dislocation superconducting tape unit of the present invention, the above dislocation twist structure holding tape may have adhesive parts formed on both ends of one surface. The non-adhesive portion located between the adhesive portions of the dislocation twist structure holding tape is
The tape-shaped superconducting conductor is interposed between the plurality of tape-shaped superconducting laminated bodies, and one end of the dislocation twist structure holding tape passes around the one laminated body and the adhesive portion is the non-adhesive portion. The other end of the tape is passed through the periphery of the one laminated body and the periphery of the other laminated body in sequence, and the adhesive portion is formed on the surface opposite to the adhesive portion forming surface of the dislocation twist structure holding tape. May be attached.

In the dislocation superconducting tape unit of the present invention, the dislocation twist structure holding tape may have an adhesive portion formed on one end of one surface.
The other end of the dislocation twist structure holding tape is interposed between the laminated bodies of the plurality of tape-shaped superconducting conductors or is led out to the outside through the laminated bodies, and The end portion may pass through the periphery of the one laminated body and the periphery of the other laminated body one by one, and the adhesive portion may be attached to the surface opposite to the adhesive portion forming surface of the dislocation twist structure retaining tape. .

Further, the present invention is a dislocation superconducting tape unit in which a plurality of tape-shaped superconducting conductor laminates are arranged in parallel, and a plurality of tape-like superconducting conductors constituting these laminates are transposed and twisted together. A dislocation twist structure retaining tape is wound around the dislocation superconducting tape unit with play, and another dislocation twist structure retaining tape is provided between the laminated body of the plurality of tape-shaped superconducting conductors. A dislocation superconducting tape unit characterized in that a tape is interposed is used as a means for solving the above problems.

In the dislocation superconducting tape unit of the present invention, the other dislocation twist structure holding tape may be arranged vertically between the laminated body of the plurality of tape-shaped superconducting conductors.

In the present invention, the tape-shaped superconducting conductor may be one in which the surface of the tape-shaped superconducting element wire is subjected to sulfurization treatment to form a high resistance film.
In the present invention, the tape-shaped superconducting element wire is formed by flattening a superconducting element wire provided inside a base made of a sheath material having a core portion made of a superconductor or a core portion having a material which becomes a superconductor by heat treatment. It is preferable that the high resistance film has a higher electrical resistivity than the sheath material forming the matrix.

Of the superconductor or core portion forming the core portion
As a material that becomes a superconductor by heat treatment,
The superconducting material, which has mechanically brittle properties, can be mentioned.
For example, Bi₂Sr₂Ca₁Cu₂O_x (Bi2212
Phase), Bi₂Sr₂Ca₂Cu₃O _y(Bi2223 phase),
Bi_1.6Pb_0.4Sr₂Ca₂Cu₃O_x, Tl₂Ba₂Ca₂
Cu₃O_y, Y₁Ba₂Cu₃O_7-xThe composition indicated by
High temperature superconducting materials such as oxide superconducting materials and Nb₃
Sn, Nb₃Superconducting material having composition indicated by Al, etc.
One or more selected from
, Bi system 2223 phase or Bi system 2212 phase Bi system
It is preferable to use an oxide superconducting material.

The sheath material is preferably made of a noble metal such as Ag, Pt, Au or an alloy thereof. The resistance-increasing film is preferably made of a sulfide of the sheath material, more preferably silver sulfide.

As the material for the dislocation twist structure holding tape wound around the dislocation superconducting tape unit with play, polyimide tape such as Kapton (trade name) manufactured by du Pont, polypropylene tape, polyester tape, etc. It is preferable to use one selected from the above. As the material of the other dislocation twist structure holding tape interposed between the laminated body of the plurality of tape-shaped superconducting conductors, polyimide tape such as Kapton (trade name) manufactured by du Pont, polypropylene tape, polyester It is preferable to use one selected from tape, plastic tape, paper tape and the like. In addition, as the material of the tape for retaining the dislocation twist structure, a material selected from austenitic stainless steel such as SUS304 and SUS316, Cu alloy tape, etc. may be used for the purpose of reinforcing the stability of the superconducting property. Cu that doubles as
You may use what was selected from a tape, Ag tape, Al tape, etc. In the dislocation superconducting tape unit of the present invention, it is preferable that the tape-shaped superconducting conductor has a rectangular cross section. Further, it is preferable that the cross-sectional shape of the other tape for holding dislocation twist structure is rectangular.

Further, the present invention provides a superconducting applied device characterized by using the dislocation superconducting tape unit of the present invention having any one of the above-mentioned constitutions as a means for solving the above problems. Further, the present invention provides a superconducting cable in which the transposed superconducting tape unit of the present invention having any one of the above configurations is wound around a tubular body, as a means for solving the above problems. The tubular body is preferably made of stainless steel.

[0018]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of a dislocation superconducting tape unit according to the present invention and a superconducting applied device using the same will be described below with reference to the drawings. (First Embodiment of Dislocation Superconducting Tape Unit) FIG.
[FIG. 3] is a view showing a first embodiment of a dislocation superconducting tape unit of the present invention, (a) is a perspective view, and (b) is a sectional view. The dislocation superconducting tape unit 15 of this embodiment is
As shown in FIG. 1A, a plurality of (12 in the drawing) tape-shaped superconducting conductors (superconducting tapes) 18 are dislocation-twisted together, and a dislocation twist structure holding tape 30 is played around the dislocation superconducting tape unit. It has been wrapped around. The dislocation twist structure holding tape 30 is provided at each position between the dislocation twist crossover portions P of the dislocation superconducting tape unit 15. More specifically, a laminated body in which tape-shaped superconducting conductors (superconducting tapes) 18 are vertically laminated (in the drawing, a laminated body in which six superconducting conductors 18 are laminated)
18a, 18a are arranged side by side on the left and right,
a and 18a, a plurality of tape-shaped superconducting conductors 1
8 is a dislocation superconducting tape unit 15 formed by twisting dislocations, and a part of the dislocation twist structure holding tape 30 wound around the dislocation superconducting tape unit 15 with play is a plurality of tape-shaped superconducting tapes. Conductor 18
It is interposed between the laminated bodies 18a, 18a. The plurality of tape-shaped superconducting conductors 18 constituting the dislocation superconducting tape unit 15 are twisted so that each tape-shaped superconducting conductor 18 is sequentially displaced in the longitudinal direction when being twisted. Is.

The tape-shaped superconducting conductor 18 is shown in FIG.
As shown in (b), the surface of the tape-shaped superconducting element wire 19 is subjected to sulfurization treatment to form the high resistance film 20. The cross-sectional shape of this superconducting conductor 18 is preferably rectangular. The specific dimensions of the superconducting conductor 18 are about 1.0 mm to 5.0 mm in width and 0.1 mm in thickness.
The range is about 1.0 mm. The resistance-enhancing film 20 is made of a sulfide of a sheath material described later, and is preferably made of silver sulfide. The electric resistance of the high resistance film 20 is higher than that of the sheath material forming the matrix 29, which will be described later, so that the surface of the tape-shaped superconducting conductor 18 can be made high in resistance and adjacent to each other. A tape-shaped sheath material 29 for the superconducting conductor 18
This is preferable in that the eddy current does not conduct to each other and the eddy current can be retained inside each of the tape-shaped superconducting conductors 18. For example, the base 29 has a low electrical resistivity of Ag (7
When the electrical resistivity at 7K is 0.3 μΩcm or the like, the high resistance film 20 around the base 29 has a high electrical resistivity of silver sulfide (at 77K, about 10 ³ times the electrical resistivity of Ag). It has the above electrical resistivity) and the like.

The tape-shaped superconducting element wire 19 is formed by flattening a superconducting multi-core element wire (superconducting element wire) 25 as shown in FIG. The cross-sectional shape of this superconducting element wire 19 is preferably rectangular. This superconducting element 1
9 has a width of about 1.0 mm to 5.0 mm and a thickness of 0.1 mm
The range is about 1.0 mm. The superconducting multifilamentary wire 25 is provided inside a base 29 made of a sheath material in which a core portion 28 made of a plurality of superconductors 27 such as superconducting filaments or a core portion 28 having a material 27 to be a superconductor by heat treatment is formed. It will be.

As the superconductor 27 of the core portion 28 or the material 27 that becomes a superconductor by heat treatment, a superconducting material having a mechanically fragile property can be used.
For example, Bi ₂ Sr ₂ Ca ₁ Cu ₂ O _x (Bi2212
Phase), Bi ₂ Sr ₂ Ca ₂ Cu ₃ O _y (Bi 2223 phase),
Bi _1.6 Pb _0.4 Sr ₂ Ca ₂ Cu ₃ O _x , Tl ₂ Ba ₂ Ca ₂
A high temperature superconducting material such as an oxide superconducting material having a composition represented by Cu ₃ O _y , Y ₁ Ba ₂ Cu ₃ O _7-x , or Nb ₃
One or more selected from superconducting materials having a composition represented by Sn, Nb ₃ Al, etc. are used, and in particular, Bi-based 2223 phase or Bi-based 2212 phase Bi-based oxide superconducting material is used. As the sheath material forming the base 29, a material made of a noble metal such as Ag, Pt, Au or an alloy thereof is used.

As the material of the dislocation twist structure holding tape 30, a polyimide tape such as Kapton (trade name) manufactured by du Pont, polypropylene tape, polyester tape or the like can be used. The specific dimensions of the dislocation twist structure holding tape 30 are in the range of about 5 mm to 15 mm in width and about 0.025 mm to 0.05 mm in thickness. As shown in FIG. 3, this dislocation twist structure holding tape 30 has adhesive portions 32a and 32b made of an adhesive or the like formed on both ends of one surface thereof.
A non-adhesive portion 33 is formed between 2a and 32b. The length L of one adhesive portion 32a of the adhesive portions 30a and 30b
₁ is, for example, in the range of ₁ mm to 7 mm, preferably in the range of 4 mm to 5 mm, and the length L ₂ of the other adhesive portion 32b is in the range of, for example, 7 mm to 12 mm, and preferably The range is about 9 mm to 10 mm.

Such a dislocation twist structure holding tape 30
Is a laminated body 18a, 1 of the tape-shaped superconducting conductor 18 having a plurality of non-adhesive portions 33 located between the adhesive portions 32a, 32b.
It is interposed between 8a. Further, one end 30a of the dislocation twist structure holding tape 30 has one laminated body 18
The adhesive portion 32a is adhered to the non-adhesive portion 33 through the periphery of a, and the other end portion 30b sequentially passes around the periphery of one laminated body 18a and the periphery of the other laminated body 18a to retain the dislocation twist structure. The adhesive portion 3 is provided on the surface of the tape 30 opposite to the adhesive portion forming surface.
0b is attached. As described above, the dislocation twist structure holding tape 30 has the adhesive portions 32a and 32b partially formed on only one surface thereof, and these adhesive portions 32a and 32b are provided.
Is affixed to the non-adhesive portion 33 of the dislocation twist structure holding tape 30 or the surface of the tape 30 opposite to the adhesive portion forming surface, and is not affixed to the tape-shaped superconducting conductor 18, so that each tape-shaped superconducting The conductors 18 are not fixed to the dislocation twist structure holding tape 30, and although the plurality of tape-shaped superconducting conductors 18 are bundled, the plurality of tape-shaped superconducting conductors 18 are separated from each other without being integrated. Has become.

Next, an example of a method of manufacturing the dislocation superconducting tape unit 15 shown in FIG. 1 will be described in the order of steps. [Raw powder processing step] raw material powder of the oxide superconductor material, for example, _{Bi 2 O 3, PbO, SrCO} 3, CaCO 3, Cu
O is mixed such that the mixing ratio of Bi: Pb: Sr: Ca: Cu is 1.8: 0.4: 2.2: 3.0, and the mixture is mixed in the range of 780 ° C to 820 ° C. The heat treatment (calcination) performed under temperature conditions and the pulverization after the calcination are repeated multiple times. Here, the raw material powder to be mixed is
In addition to the above, any oxide or carbonate of each element of Bi, Pb, Sr, Ca and Cu may be used. [Filling Step] The crushed raw material powder is formed into a cylindrical body by, for example, CIP (cold isostatic pressing) molding, and then the cylindrical body is filled and sealed in a first pipe made of a sheath material such as Ag. Sheath material composite (Ag sheath composite)
To form.

[Wire Drawing (Pulling Out) Process of Single Core Wire] The sheath material composite (Ag sheath composite) is drawn into a predetermined wire diameter with a die or the like to obtain a superconducting single core wire (single wire). Form a core line). [Multi-core process] After arranging a predetermined number (for example, 19) of the above-mentioned single-core wires inside the second pipe made of a sheath material such as Ag and enclosing it, a predetermined wire diameter is obtained by a die or the like. The wire drawing process is performed until a superconducting multi-core element wire (superconducting element wire) 25 as shown in FIG. 2 is formed.

[Repeating Step of Rolling Heat Treatment of Superconducting Wire] The superconducting multifilamentary wire 25 is subjected to rolling processing such as roll rolling.
It is rolled to a predetermined thickness and flattened. As an apparatus used for the rolling process here, for example, a double rolling machine provided with a pair of upper and lower rolls, and a superconducting multi-core wire 25 between the rolls.
A rolling device (not shown) composed of a conveyer including a feeding drum that feeds out the superconducting multicore wire 25 rolled between the rolls and a winding drum that winds up the superconducting multicore element wire 25 is preferably used. In order to roll the superconducting multifilamentary wire 25 using such a rolling device, the superconducting multifilamentary wire 25 is fed from the delivery drum between the rolls and rolled, and the rolled superconducting multifilamentary wire 25 is rolled. It is performed by winding with a winding drum. Then, the flattened superconducting multi-core wire 25 is housed inside an electric furnace or the like in a wound state on a heat treatment drum, the temperature condition is set to a range of 820 ° C to 850 ° C, and the treatment time is set to 10 hours. The heat treatment is performed in the range of up to 200 hours. Further, the rolling process (or pressing process) and the heat treatment are repeated a plurality of times to form a tape-shaped superconducting element wire 19 having a predetermined thickness.

[Sulfurization Step of Superconducting Element Wire] The surface of the tape-shaped superconducting element wire 19 is subjected to sulfurization treatment to obtain a high resistance film 2
By forming 0, a tape-shaped superconducting conductor (superconducting tape) 18 as shown in FIG. 1 is formed. Examples of the apparatus used for the sulfurization treatment include a reaction vessel that can be evacuated and is filled with sulfur vapor, a delivery drum that delivers the tape-shaped superconducting element wire 19 into the reaction vessel, and the above reaction. A sulfidation treatment device including a winding drum that winds the tape-shaped superconducting element wire 19 that has been subjected to sulfidation treatment in the container is preferably used. The reaction container is formed with an introduction hole for introducing the tape-shaped superconducting element wire 19 into the inside and a lead-out hole for leading out the introduced tape-shaped superconducting element wire 19. At the peripheral portion of the hole, a sealing mechanism is provided to close the gap between the holes while allowing the tape-shaped superconducting element wire 19 to pass therethrough to make the inside of the reaction vessel airtight. The reaction container is equipped with a heater (not shown) so that the reaction container can be heated.

In order to perform the sulfurating treatment on the surface of the tape-shaped superconducting element wire 19 by using such a sulfurizing treatment apparatus, the inside of the reaction vessel is evacuated and then sulfur in a predetermined temperature range is placed in the reaction vessel. The steam is supplied, and then the tape-shaped superconducting element wire 19 is sent out from the delivery drum into the reaction vessel filled with the sulfur vapor, and the tape-shaped superconducting element wire 19 that has been subjected to sulfurization is wound up. When wound on a drum, a tape-shaped superconducting conductor (superconducting tape) 18 having a high resistance film 20 on its surface is obtained. Examples of the sulfur vapor supplied into the above reaction vessel include sulfur dichloride, disulfur dichloride, sulfur dioxide and the like.
The temperature of the sulfur vapor supplied into the reaction vessel,
It is set within the range of about 50 ° C to 170 ° C. The temperature inside the reaction vessel is such that the supplied sulfur vapor does not liquefy. The sulfurization time is 60 to 3
It is about 0000 seconds. The sulfiding time here can be changed by the linear velocity of the tape-shaped superconducting element wire 19 fed into the reaction vessel.

[Dislocation Twisting Step] A plurality of the tape-shaped superconducting conductors 18 (12 in the present embodiment) are dislocated and twisted at a predetermined dislocation pitch using a dislocation twisting machine. Laminated bodies 18a, 18a of a plurality of tape-shaped superconducting conductors 18 at positions between the transition parts P, P
As shown in FIG. 4, the dislocation twist structure holding tape 30
The non-adhesive part 33 is interposed. Further, one end portion 30a of the dislocation twist structure holding tape 30 is attached to the one laminated body 1
The adhesive portion 32a is attached to the non-adhesive portion 33 through the periphery of 8a to form an annular shape. Further, the other end 30b is passed through the periphery of the annular portion of the tape 30 surrounding the one laminated body 18a and the periphery of the other laminated body 18a in order to make the dislocation twist structure holding tape 30 annular. The adhesive portion 30b is attached to the surface of the part (the surface opposite to the surface on which the adhesive portion is formed).
When winding the dislocation twist structure holding tape 30 here,
It is preferable that the adhesive portions 32a and 32b do not come into direct contact with the tape-shaped superconducting conductor 18. In this way, the dislocation superconducting tape unit 15 as shown in FIG. 1 is obtained. Here, the length of the dislocation crossover portion P is 2
It is set within a range of about 0 mm to 500 mm.

Dislocation superconducting tape unit 1 of this embodiment
5, the dislocation twist structure holding tape 30 is wound around the dislocation superconducting tape unit with play, and a part of the dislocation twist structure holding tape 30 is formed by laminating a plurality of tape-shaped superconducting conductors 18. Since it is interposed between the bodies 18a, 18a, the dislocation superconducting tape unit 1
Even when stress such as bending strain is applied when winding 5 is processed, the plurality of tape-shaped superconducting conductors 18 are not integrated, and the stressed tape-shaped superconducting conductor 18 has a dislocation twist structure. It can be deformed and moved so as to relieve stress without breaking. A part of the dislocation twist structure holding tape 30 is a laminated body 1 of a plurality of tape-shaped superconducting conductors 18.
Since it is interposed between 8a and 18a, it is possible to prevent lateral displacement (lateral direction) of the tape-shaped superconducting conductors 18 ... Therefore, the dislocation superconducting tape unit 15 of the present embodiment can maintain the dislocation twist structure even if bending strain is applied by winding processing or the like, reduce the AC loss when an AC current is applied, and suppress the drift. As described above, the dislocation superconducting tape unit 15 of the present embodiment can maintain the dislocation twist structure even when bending strain is applied by winding processing or the like, and therefore, compared with the conventional dislocation superconducting tape unit to which the adhesive tape is attached. The flexibility can be improved.

(Second Embodiment of Dislocation Superconducting Tape Unit) FIG. 5 is a sectional view showing a second embodiment of the dislocation superconducting tape unit of the present invention. The dislocation superconducting tape unit 45 of the second embodiment is different from the dislocation superconducting tape unit 15 of the first embodiment shown in FIG. 1 in that a dislocation twist structure as shown in FIG. 6 is provided around the dislocation superconducting tape unit. This is that the holding tape 40 is wound with play. The dislocation twist structure holding tape 40 is provided at each position between the dislocation twist crossing portions of the dislocation superconducting tape unit.

As shown in FIG. 6, the tape 40 for holding the dislocation twist structure has an adhesive portion 42a made of an adhesive or the like formed on one end 40a of one surface, and the remaining portion of the one surface. A non-adhesive portion 43 is formed on the portion. The other end 40b of the tape 40 for holding the dislocation twist structure is led out to the outside through the space between the plurality of tape-shaped superconducting conductor laminates 18a, 18a, and one end 42a of the one laminate 18a. The adhesive portion 42a is attached to the surface opposite to the adhesive portion forming surface of the dislocation twist structure retaining tape 40 by sequentially passing around the periphery of the laminated body 18a and the periphery of the other laminated body 18a. As described above, the dislocation twist structure holding tape 40 has the adhesive portion 42a partially formed on only one surface thereof.
Is affixed to the surface of the dislocation twist structure holding tape 40 opposite to the surface on which the adhesive portion is formed, and is not affixed to the tape-shaped superconducting conductor 18. Therefore, each tape-shaped superconducting conductor 18 retains the dislocation twist structure. Although the plurality of tape-shaped superconducting conductors 18 are not fixed to the tape 40 and are bundled, the plurality of tape-shaped superconducting conductors 18 are separated from each other without being integrated.

Dislocation superconducting tape unit 4 of this embodiment
5, the dislocation twist structure holding tape 40 is wound around the dislocation superconducting tape unit with play, and a part of the dislocation twist structure holding tape 40 is formed by laminating a plurality of tape-shaped superconducting conductors 18. Since it is interposed between the bodies 18a, 18a, the dislocation superconducting tape unit 4
Even when stress such as bending strain is applied when winding 5 is processed, the plurality of tape-shaped superconducting conductors 18 are not integrated, and the stressed tape-shaped superconducting conductor 18 has a dislocation twist structure. It can be deformed and moved so as to relieve stress without breaking. Further, a part of the dislocation twist structure holding tape 40 is a laminated body 1 of a plurality of tape-shaped superconducting conductors 18.
Since it is interposed between 8a and 18a, it is possible to prevent lateral displacement of these tape-shaped superconducting conductors 18 (lateral direction). Therefore, the dislocation superconducting tape unit 45 of the present embodiment can maintain the dislocation twist structure even if bending strain is applied due to winding processing or the like, can reduce the AC loss when an AC current is applied, and can suppress the drift. As described above, the dislocation superconducting tape unit 45 of the present embodiment can maintain the dislocation twist structure even when bending strain is applied by winding processing or the like, and therefore, compared with the conventional dislocation superconducting tape unit to which the adhesive tape is attached. The flexibility can be improved.

(Third Embodiment of Dislocation Superconducting Tape Unit) FIG. 7 is a perspective view showing a third embodiment of the dislocation superconducting tape unit of the present invention. The dislocation superconducting tape unit 55 of the third embodiment differs from the dislocation superconducting tape unit 15 of the first embodiment shown in FIG. 1 in that a dislocation twist structure is provided around the dislocation superconducting tape unit as shown in FIG. A holding tape 50 is wound around with play, and a plurality of tape-shaped superconducting conductors 18 are provided.
Another dislocation twist structure holding tape 60 is interposed between the laminated bodies 18a, 18a.

The dislocation twist structure holding tape 50 is made of the same material as the dislocation twist structure holding tape 30 used in the first embodiment. Although not shown, the dislocation twist structure holding tape 50 has adhesive portions partially formed of an adhesive or the like on both ends of one surface, and a non-adhesive portion 53 is formed between the adhesive portions. Has been done. The dislocation twist structure holding tape 50 is spirally wound around the dislocation superconducting tape unit, and the one end portion (one winding end portion) of the dislocation twist structure holding tape 50 is previously wound. An adhesive portion is attached to the surface (front surface) opposite to the adhesive portion forming surface, and the other end portion (the other winding end portion) is the adhesive portion formation of the dislocation twist structure holding tape 50 previously wound. An adhesive portion is attached to the surface (front surface) opposite to the surface. In this way, the dislocation twist structure holding tape 50 has the adhesive portions partially formed on only one surface thereof, and these adhesive portions are on the surface opposite to the adhesive portion forming surface of the dislocation twist structure holding tape 50 ( The tape-shaped superconducting conductors 18 are not fixed to the dislocation twist structure holding tape 50 because they are adhered to the surface) and not to the tape-shaped superconducting conductors 18. Although 18 are bundled, a plurality of tape-shaped superconducting conductors 18 are separated without being integrated.

Another dislocation twist structure holding tape 60 is vertically arranged between the laminated bodies 18a, 18a arranged in parallel on the left and right. As the material of the dislocation twist structure holding tape 60, polyimide tape such as Kapton (trade name) manufactured by du Pont, polypropylene tape, polyester tape,
It is preferable to use one selected from plastic tape, paper tape and the like. Further, as the material of the dislocation twist structure holding tape 60, one selected from austenitic stainless steel such as SUS304 and SUS316, which also serves as reinforcement (also serves to improve mechanical strength), Cu alloy tape, etc. Alternatively, a Cu tape, an Ag tape, an Al tape, or the like may be used in order to stabilize the superconducting property. The cross-sectional shape of the dislocation twist structure holding tape 60 is preferably the same rectangular shape as the cross-sectional shape of the superconducting conductor 18. The specific dimensions of this reinforcing material 16 are 1.0 mm to 5.0 mm in width.
The thickness is about 0.1 mm to 1.0 mm. No adhesive portion is formed on the dislocation twist structure holding tape 60.

Next, in the method of manufacturing the dislocation superconducting tape unit 55 shown in FIG. 7, a plurality of tape-shaped superconducting conductors 1 are used.
After disposing the dislocation twist structure holding tape 60 vertically between the laminated bodies 18a, 18a of No. 8, the tape-shaped superconducting conductor 1
A plurality of 8 (12 in the present embodiment) are twisted with a dislocation at a predetermined dislocation pitch to obtain a dislocation superconducting tape unit,
A dislocation superconducting tape unit 55 is obtained by spirally winding the dislocation twist structure holding tape 50 around the dislocation superconducting tape unit. When the material of the dislocation twist structure holding tape 60 used here is the above metal material or alloy, it can be formed as follows. A linear body made of the above metal material or alloy (tape 60 for retaining dislocation twist structure before being formed into a tape) is rolled to a predetermined thickness by a rolling process such as roll rolling to be flattened. As an apparatus used for the rolling process here, for example, a double rolling mill provided with a pair of upper and lower rolls, a feeding drum for feeding the linear body between the rolls, and the linear body rolled between the rolls. A rolling device (not shown) including a transporting machine including a winding drum that winds the dislocation twist structure holding tape 60 obtained as described above is preferably used. In order to roll the linear body using such a rolling device, the linear body is fed from the delivery drum between the rolls and rolled, and the dislocation twist structure holding tape 60 obtained by rolling is wound. It is done by winding on a take-up drum.
Further, the rolling process (or pressing process) is repeated a plurality of times to form the dislocation twist structure holding tape 60 having a predetermined thickness.

Dislocation superconducting tape unit 5 of this embodiment
5, the dislocation twist structure holding tape 50 is wound around the dislocation superconducting tape unit with play, and the laminated body 1 of a plurality of tape-shaped superconducting conductors 18 is formed.
Another dislocation twist structure holding tape 60 between 8a and 18a
Are vertically arranged, the plurality of tape-shaped superconducting conductors 18 are not integrated even if stress such as bending strain is applied when winding the dislocation superconducting tape unit 55.
The tape-shaped superconducting conductor 18 to which the stress is applied can be deformed and moved so as to relieve the stress without breaking the dislocation twist structure. Therefore, the dislocation superconducting tape unit 55 of the present embodiment can maintain the dislocation twist structure even if bending strain is applied due to winding processing or the like, can reduce the AC loss when the AC current is applied, and suppress the drift. As described above, the dislocation superconducting tape unit 55 of the present embodiment can maintain the dislocation twist structure even when bending strain is applied by winding processing or the like, and therefore, compared with the conventional dislocation superconducting tape unit to which the adhesive tape is attached. The flexibility can be improved.

Further, the dislocation twist structure holding tape 60 is a laminated body 18a, 18 of a plurality of tape-shaped superconducting conductors 18.
Since it is interposed between a, the tape-shaped superconducting conductor 1
It is possible to prevent the position shift of 8 ... in the left-right direction (lateral direction).
Further, by selecting the material of the dislocation twist structure holding tape 60 interposed between the laminated bodies 18a, 18a, the dislocation superconducting tape unit can be given various characteristics. Further, in the dislocation superconducting tape unit 55 of the present embodiment, the dislocation twist structure holding tape 60 is arranged in the central portion, and the dislocation twist structure holding tape 50 is spirally wound around the dislocation superconducting tape unit. Therefore, as compared with the dislocation superconducting tape units 15 and 45 of the first and second embodiments, the dislocation twisting process can be simplified and the linear velocity can be improved, and the manufacturing efficiency can be improved.

In the present embodiment, the number of tape-shaped superconducting conductors 18 used in the dislocation superconducting tape unit is one.
Although the case where the number is two has been described, it is possible to provide a dislocation superconducting tape unit having desired superconducting properties by selecting the number of tape-shaped superconducting conductors 18 according to the required superconducting properties.

(Embodiment of Superconducting Cable) FIG. 8 is a perspective view showing an embodiment of a superconducting cable using the transposed superconducting tape unit according to the embodiment of the present invention. This superconducting cable 70 has a structure that suppresses uneven flow when an alternating current is applied, and the dislocation superconducting tape unit 15 of the first embodiment is spirally wound around a pipe-shaped former (tubular body) 77. A plurality of superconductor layers 84 are laminated, and an interlayer insulating layer 85 made of an insulating tape or the like is interposed between the superconductor layers 84, 84. The winding direction of the dislocation superconducting tape unit 15 is
The direction is S winding (right winding) or Z winding (left winding).

The former 77 is made of stainless steel or the like. The surface of such a former 77 is
Insulation is applied to suppress the energization between the former 77 and the dislocation superconducting tape unit 15. The inside of the former 77 serves as a flow path for a cooling medium such as liquid nitrogen, and cools the plurality of tape-shaped superconducting conductors 18 that form the dislocation superconducting tape unit 15.

As a method of manufacturing the superconducting cable 70 having such a structure, for example, the former 7 having a plurality of sets of the above-mentioned dislocation superconducting tape units 15 whose surface is insulated.
When a plurality of superconducting layers 84 are formed by winding Z or S windings around 7 at a predetermined spiral pitch, the inter-layer insulating layer 85 is interposed between the adjacent superconducting layers 84, 84. , A superconducting cable 70 as shown in FIG. 8 is obtained. The spiral pitch here is within a range of about 100 to 2000 mm. Outside the superconducting cable 70 having such a configuration, a semiconductor layer, an insulating layer, a protective layer, a heat insulating layer, an anticorrosive layer, etc. (not shown) are formed and used as necessary.

The superconducting cable 70 of the present embodiment can maintain the dislocation twist structure even when bending strain is applied by winding processing or the like, can reduce the AC loss when an AC current is applied, and can suppress the drift of the superconducting tape. Since the unit 15 is used, this dislocation superconducting tape unit 15
Since it is possible to prevent the dislocation twist structure from being disturbed when being wound around the former 77, it is possible to obtain excellent characteristics.

(Embodiment of Superconducting Magnet) FIG.
It is a perspective view showing one embodiment of a superconducting magnet using a dislocation superconducting tape unit of an embodiment of the present invention. The superconducting magnet 90 of the present embodiment includes a winding drum 91 and a collar plate 9.
The dislocation superconducting tape unit 15 according to the first embodiment is wound around a winding frame 93 including 2, 92. The unend portion 95a of the dislocation superconducting tape unit 15 is pulled out of the collar plate 92 through a cutout-shaped passage hole 92a formed in the outer peripheral edge portion of the collar plate 92, and passes through this passage hole 92a. The front portion 95b of the drawn-out portion of the dislocation superconducting tape unit 15 is covered with a reinforcing plate 97 fixed to the outer peripheral edge of the collar plate 92. The dislocation superconducting tape unit 15 at the portion penetrating the collar plate 92 is bonded to the collar plate 9 by an adhesive portion 98 such as an epoxy resin adhesive.
It is fixed at 2.

The superconducting magnet 90 of the present embodiment can maintain the dislocation twist structure even when bending strain is applied by winding processing or the like, can reduce the AC loss when an AC current is applied, and can suppress the drift of the dislocation superconducting tape. Since the unit 15 is used, this dislocation superconducting tape unit 1
Since the dislocation twist structure can be prevented from being disturbed when 5 is wound around the winding frame 93, excellent properties can be obtained.

(Embodiment of Superconducting Transformer) FIG. 10 is a perspective view showing an embodiment of a superconducting transformer using the transposed superconducting tape unit according to the embodiment of the present invention. Figure 11
FIG. 11 is a sectional view taken along line XI-XI in FIG. 10. The superconducting transformer 100 of the present embodiment has a bobbin 102 having a cylindrical winding drum 102a, and a first embodiment in which multiple layers are wound from one end side to the other end side in the axial direction of the winding barrel 102a of the bobbin 102. The dislocation superconducting tape unit 15 and the spacer 105 that separates the layers of the dislocation superconducting tape unit 15 from each other. The bobbin 102 is a winding drum 102.
a and flanges 102b and 102 provided at both ends thereof
The bobbin 102 has a winding drum 10
Dislocation superconducting tape units 15 are wound in multiple layers around the outer periphery of 2a. The spacer 105 is provided to separate the layers of the dislocation superconducting tape unit 15 from each other so that the dislocation superconducting tape unit 15 can be efficiently cooled by the refrigerant, and its longitudinal direction is along the bobbin axis direction. Thus, a plurality of bobbins 102 are provided at intervals in the circumferential direction.

The spacing between the layers of the dislocation superconducting tape unit 15 and the spacing between the dislocation superconducting tape unit 15 and the flanges 102b and 102c are cooling channels 104 which serve as coolant flow paths. Superconducting transformer 10
When 0 is used, in order to maintain the superconducting state of the dislocation superconducting tape unit 15, this superconducting transformer 100 is immersed in a coolant such as liquid helium and cooled. In the superconducting transformer 100, the spacer 105 that separates the dislocation superconducting tape units 15 is provided between the layers of the dislocation superconducting tape unit 15, so that an alternating current is passed through the plurality of tape-shaped superconducting conductors 18 that constitute the dislocation superconducting tape unit 15. Even when the transposition superconducting tape unit 15 generates heat due to the AC loss generated at this time, the refrigerant can be circulated through the cooling channel 104 between the layers to maintain the superconducting state of the transposition superconducting tape unit 1.

The superconducting transformer 100 of the present embodiment can maintain the dislocation twist structure even when bending strain is applied by winding processing or the like, can reduce the AC loss when an AC current is applied, and can suppress the drift. Since the tape unit 15 is used, this dislocation superconducting tape unit 15
Since it is possible to prevent the dislocation twisted structure from being disturbed when it is wound on the bobbin 102, it is possible to obtain excellent properties.

In the superconducting cable, the superconducting transformer, and the superconducting magnet of the above-described embodiment, the transposition superconducting tape unit 15 of the above-described first embodiment is used as the transposition superconducting tape unit. Dislocation superconducting tape unit 45 of the second embodiment or dislocation superconducting tape unit 5 of the third embodiment.
5 may be used, or two or more of the first to third dislocation superconducting tape units 15, 45, 55 may be used in combination. Further, in the above-mentioned embodiment, the case where the transposition superconducting tape unit of the embodiment of the present invention is used for a superconducting cable, a superconducting transformer, and a superconducting magnet has been described. It can be used for the winding part of superconducting applied equipment such as a container. A superconducting application device in which the dislocation superconducting tape unit of the present invention is used in the winding portion can have excellent characteristics.

[0051]

As described above, in the dislocation superconducting tape unit of the present invention, the dislocation twist structure retaining tape is wound around the dislocation superconducting tape unit with play to retain the dislocation twist structure. Since a part of the tape is interposed between the laminated body of the plurality of tape-shaped superconducting conductors, the dislocation twist structure can be maintained even when bending strain is applied due to winding processing, etc. AC loss can be reduced and uneven flow can be suppressed. As described above, the dislocation superconducting tape unit 15 of the present embodiment can maintain the dislocation twist structure even when bending strain is applied by winding processing or the like, and therefore, compared with the conventional dislocation superconducting tape unit to which the adhesive tape is attached. The flexibility can be improved. Further, according to the superconducting applied device of the present invention, even when bending strain is applied by winding processing or the like, the dislocation twist structure can be maintained, the AC loss at the time of passing an alternating current can be reduced, and the drift can be suppressed. Since the dislocation superconducting tape unit is used, it is possible to prevent the dislocation twist structure from being disturbed even when bending strain is applied when performing winding processing or the like on this dislocation superconducting tape unit, so it has excellent characteristics. Can be one.

[Brief description of drawings]

FIG. 1 is a diagram for explaining a first embodiment of a dislocation superconducting tape unit of the present invention, in which (a) is a perspective view,
(B) is a sectional view.

FIG. 2 is an explanatory diagram of a superconducting element wire used in a tape-shaped superconducting element wire that constitutes the dislocation superconducting tape unit of FIG.

FIG. 3 is a plan view showing a dislocation twist structure holding tape used in the dislocation superconducting tape unit of the first embodiment.

FIG. 4 is a diagram showing a method for winding the dislocation twist structure holding tape of FIG. 3 around a dislocation superconducting tape unit.

FIG. 5 is a cross-sectional view showing a second embodiment of a dislocation superconducting tape unit of the present invention.

FIG. 6 is a plan view showing a dislocation twist structure holding tape used in a dislocation superconducting tape unit of a second embodiment.

FIG. 7 is a perspective view showing a third embodiment of a dislocation superconducting tape unit of the present invention.

FIG. 8 is a perspective view showing an embodiment of the superconducting cable of the present invention.

FIG. 9 is a perspective view showing an embodiment of a superconducting magnet using the dislocation superconducting tape unit according to the embodiment of the present invention.

FIG. 10 is a perspective view showing an embodiment of a superconducting transformer using the transposed superconducting tape unit according to the embodiment of the present invention.

11 is a sectional view taken along line XI-XI of FIG.

FIG. 12 is a perspective view showing an example of a conventional superconducting cable provided with a transposed superconducting tape unit.

13A and 13B are explanatory views of a transposed superconducting tape unit included in the superconducting cable of FIG. 12, where FIG. 13A is a perspective view and FIG.

[Explanation of symbols]

15, 45, 55 ... Dislocation superconducting tape unit, 18.
..Tape-shaped superconducting conductor (superconducting tape), 19 ... Tape-shaped superconducting element wire, 20 ... High resistance film, 25 ... Superconducting multi-core element wire (superconducting element wire), 27 ... -Superconductor or a material to be a superconductor, 28 ... core portion, 29 ... matrix (sheath material), 30, 40, 50, 60 ... dislocation twist structure holding tape, 30a, 30b, 40a, 40b ... end,
32a, 32b, 42a ... Adhesive parts, 33, 43, 53 ...
..Non-adhesive portion, 70 ... superconducting cable, 77 ... former (tube), 90 ... superconducting magnet (applied superconducting device), 100 ... superconducting transformer.

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Tomoshi Suzuki             1-5-1 Kiba Stock Exchange, Koto-ku, Tokyo             Inside Fujikura (72) Inventor Kaoru Takeda             1-5-1 Kiba Stock Exchange, Koto-ku, Tokyo             Inside Fujikura (72) Inventor Shigeo Nagaya             20 Kitakanzan, Otakamachi, Midori-ku, Nagoya-shi, Aichi             No. 1 Chubu Electric Power Co., Inc. (72) Inventor Naoji Kashima             20 Kitakanzan, Otakamachi, Midori-ku, Nagoya-shi, Aichi             No. 1 Chubu Electric Power Co., Inc. F-term (reference) 5G321 BA01 BA03 CA18 CA46 CA48

Claims (7)

[Claims] 1. A dislocation superconducting tape unit in which a plurality of tape-shaped superconducting conductor laminated bodies are arranged in parallel with each other, and a plurality of tape-shaped superconducting conductors constituting these laminated bodies are transposed and twisted together. A dislocation twist structure holding tape is wound around the dislocation superconducting tape unit with play, and a part of the dislocation twist structure holding tape is interposed between the laminated body of the plurality of tape-shaped superconducting conductors. Dislocation superconducting tape unit characterized in that 2. The dislocation twist structure holding tape has adhesive parts formed on both ends of one surface, and the non-adhesive parts located between the adhesive parts of the dislocation twist structure holding tape are It is interposed between a laminate of a plurality of tape-shaped superconducting conductors, and one end portion of the dislocation twist structure holding tape passes around the one laminate and the adhesive portion is the non-adhesive portion. The other end of the tape is passed through the periphery of the one laminated body and the periphery of the other laminated body in order, and the adhesive portion is formed on the surface opposite to the adhesive portion forming surface of the dislocation twist structure holding tape. The dislocation superconducting tape unit according to claim 1, which is attached. 3. The dislocation twist structure retaining tape has an adhesive portion formed on one end of one surface thereof, and the other end of the dislocation twist structure retaining tape comprises the plurality of tapes. Of the superconducting conductors in the shape of a strip, or is led out to the outside through the gap between the laminates, and the one end is surrounded by the periphery of the one laminate and the periphery of the other laminate. 2. The dislocation superconducting tape unit according to claim 1, wherein the adhesive section is adhered to a surface of the tape for holding the dislocation twist structure that is opposite to the surface on which the adhesive section is formed. 4. A dislocation superconducting tape unit comprising a plurality of tape-shaped superconducting conductor laminated bodies arranged in parallel, and a plurality of tape-shaped superconducting conductors constituting these laminated bodies being dislocation twisted together. A dislocation twist structure holding tape is wound around the dislocation superconducting tape unit with play, and another dislocation twist structure holding tape is interposed between a stack of the plurality of tape-shaped superconducting conductors. Dislocation superconducting tape unit characterized in that 5. The other dislocation twist structure holding tape,
The dislocation superconducting tape unit according to claim 4, wherein the dislocation superconducting tape unit is arranged vertically between the laminated body of the plurality of tape-shaped superconducting conductors. 6. A superconducting application device comprising the dislocation superconducting tape unit according to any one of claims 1 to 5. 7. A superconducting cable, characterized in that the dislocation superconducting tape unit according to any one of claims 1 to 5 is wound around a tubular body.