JPH07273376A - Superconductive current limiter - Google Patents

Abstract

PURPOSE:To prevent a superconductive magnetic shielding body from being quenched by lessening the magnetic flux generated in the superconductive magnetic shielding body by the current which flows through a transmission line at the normal transmission. CONSTITUTION:In a superconductive current limiter wherein a first coil 8 in which the transmission current is allowed to flow and a second coil 9 which works as to cancel a magnetic field generated by the first coil 8 are installed on an outer part of a superconductive magnetic shielding body, wires of the first coil 8 and second coil 9 are twisted. By this method, the superconductive magnetic shielding body is prevented from reaching a critical magnetic field by the normal transmission current.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a superconducting fault current limiter utilizing the magnetic shielding effect of a superconducting magnetic shield.

[0002]

2. Description of the Related Art Conventionally, development of a current limiting device for limiting a current in a transmission line system has been advanced. When the overcurrent flows, the current limiter functions as a resistance to suppress the overcurrent and reduce the load on the breaker and the transformer. Although there are various types of current limiting methods, in recent years, a method of limiting current using a so-called superconductor has been proposed as a current limiting device. This utilizes the magnetic shielding effect and magnetic flux switching effect of the superconductor. First, a conductive wire is wound around the superconducting magnetic shield in a coil shape to form a superconducting fault current limiter. Normally, when the coil is energized, it exhibits impedance due to its self-inductance, but in the above superconducting fault current limiter, when the superconducting magnetic shield is in the superconducting state, the magnetic flux is shielded by the magnetic shielding effect, so theoretically the self-inductance disappears. I will end up. That is, since the impedance is extremely small, the loss of normal transmission current is small. However, once an overcurrent occurs due to a short circuit, a lightning strike, etc., and a magnetic flux above a certain value occurs, the critical magnetic field is exceeded, so the superconducting magnetic shield is quenched (converted) from the superconducting state to the normal conducting state. Disappear. Then, the magnetic flux is linked to the superconducting magnetic shield (flux switching effect) as in the case of a normal coil, so that a large self-inductance is generated in the coil and the current can be limited.

[0003]

However, since this conventional superconducting magnetic shield has a small critical magnetic field, it cannot be applied to a fault current limiter such as a transmission line through which a large current flows.
That is, the normal current flowing through the power transmission line generates a considerably large magnetic field, which already exceeds the critical magnetic field of the superconducting magnetic shield. Then, the superconductor will be quenched to the normal conducting state, so the current limiter cannot eliminate the self-inductance of the coil, and impedance will be generated despite normal power transmission, resulting in power transmission loss. . Therefore, it was difficult to actually apply it to a fault current limiter. An object of the present invention is to provide a superconducting fault current limiter using a superconducting magnetic shield that reduces the magnetic flux generated on the superconductor during normal power transmission and prevents the superconducting magnetic shield from being quenched.

[0004]

Means for Solving the Problems In order to solve the above problems, the inventors of the present invention, in the invention of claim 1, permit the passage of a transmission current to the inner peripheral side or the outer peripheral side of a superconducting magnetic shield. In a superconducting fault current limiter in which a first coil and a second coil that acts to cancel the magnetic field of the first coil are arranged, a configuration in which the coil wires of the first coil and the second coil are twisted together did. Further, in the invention of claim 2, in the same superconducting fault current limiter, the coil wire of the first coil and the coil wire of the second coil are arranged alternately at predetermined intervals. Further, according to the invention of claim 3, in the same superconducting fault current limiter, the coil wires of the first coil and the second coil are randomly wound with respect to each other. According to the invention of claim 4, in the same superconducting fault current limiter, the second
The coil wire of the first coil is arranged in the coil wire of the coil through the insulating layer. According to the fifth aspect of the invention, the coil wires of the first and second coils are alternately wound every predetermined turn, and are arranged in a sandwiched state between the superconducting magnetic shields divided into a plurality of annular bodies. Further, in the invention of claim 6, the coil wires of the first and second coils are randomly wound around each other, and the coil wires are arranged in a sandwiched state between the superconducting magnetic shields divided into a plurality of annular bodies. Current limiter.

[0005]

According to the above configuration, in the invention of claim 1, since the first coil is wound around the superconducting magnetic shield, the magnetic flux is generated by the superconducting magnetic shield when the normal current is applied. It is shielded, does not generate self-inductance, and does not limit current. Then, the second coil, which is more closely matched with the first coil, works in the direction of canceling the magnetic field of the first coil, and as a result, the quenching current value can be set to be larger than that in the case of the first coil alone. .
On the other hand, when an overcurrent flows due to a short circuit, a lightning strike, or the like, the critical magnetic field is exceeded and the superconducting magnetic shield is quenched and the current is limited. The invention of claim 2 is similar to the operation of the invention of claim 1, but in the direction in which the first coil and the second coil alternately arranged at every predetermined turn cancel the magnetic field of the first coil. As a result, the quenching current value can be set to be larger than that in the case of the first coil alone. On the other hand, when an overcurrent flows due to a short circuit, a lightning strike, or the like, the critical magnetic field is exceeded and the superconducting magnetic shield is quenched and the current is limited. The invention of claim 3 is also the same as the invention of claim 1, but the second coil randomly arranged with the first coil works in a direction to cancel the magnetic field of the first coil, and as a result, the first coil The current value for quenching can be set to be larger than that in the case of using only the coil. On the other hand, when an overcurrent flows due to a short circuit, a lightning strike, or the like, the critical magnetic field is exceeded and the superconducting magnetic shield is quenched and the current is limited. The invention according to claim 4 is also the same as the invention according to claim 1, but the first coil is disposed in the hollow second coil and is completely covered, and the second coil is the first coil. The coil works in a direction to cancel the magnetic field, and as a result, the quenching current value can be set to be larger than that in the case of the first coil alone. On the other hand, when an overcurrent flows due to a short circuit, a lightning strike, or the like, the critical magnetic field is exceeded and the superconducting magnetic shield is quenched to limit the current.

The invention of claim 5 is the same as the invention of claim 1, but in the direction in which the second coil alternately arranged with the first coil for every predetermined turn cancels the magnetic field of the first coil. As a result, the quenching current value can be set to be larger than that in the case of the first coil alone. Further, since the coil is sandwiched between the annular superconducting magnetic shields, the leakage impedance is reduced. The invention of claim 6 is the same as the invention of claim 1, but the first coil and the second coil arranged at random.
Coil acts in a direction to cancel the magnetic field of the first coil,
As a result, the quenching current value can be set to a large value as compared with the case where only the first coil is used.
Further, since the coil is sandwiched between the annular superconducting magnetic shields, the leakage impedance is reduced.

[0007]

EXAMPLES A superconducting fault current limiter using the superconducting magnetic shield of the present invention will be described in detail below with reference to the drawings.

As shown in FIG. 3, the superconducting fault current limiter 1 is a tower 2
It is arranged on the power transmission line 4 between the circuit breaker 3 and the circuit breaker 3. Circuit breaker 3
A transformer 5 is further arranged on the primary side of the. (Embodiment 1) As shown in FIG. 1, a superconducting fault current limiter 1 has a cylindrical main body 7 made of a superconducting magnetic shield and a first coil 8.
And the second coil 9. The first coil 8 is wound around the outer periphery of the main body 7, the tip end thereof is connected to the power transmission line 4 side, and the base end thereof is connected to the circuit breaker 3 side. The second coil 9 is wound around the outer periphery of the main body 7 alternately with the first coil 8. The first coil 8 and the second coil 9 are wound in the same direction with the adjacent coil wires in close contact with each other. Both ends of the second coil 9 are joined via a resistor 10. Both coils 8 and 9 are arranged on the outer peripheral side of the main body 7, and magnetically influence each other with the first coil 8 during normal power transmission and overcurrent generation. The superconducting fault current limiter 1 is always kept in a cooled state by liquid nitrogen.

As shown in FIG. 2, the main body 7 has a second coil 9
When a normal power transmission current is flowing through the first coil 8 in the presence of, the superconducting state is established. That is, the magnetic flux a of the first coil 8 is shielded by the main body 7 as shown by the chain double-dashed line in the figure. Therefore, the self-inductance generated in the first coil 8 is theoretically 0, and the current is not limited. On the other hand, once an overcurrent flows due to a ground fault or a lightning strike, and exceeds the critical magnetic field of the superconducting magnetic shield (main body 7),
The shielding effect of the superconducting magnetic shield disappears. That is, the superconducting magnetic shield is quenched from the superconducting state to the normal conducting state. Then, since the magnetic flux a passes through the main body 7, self-inductance is generated in the first coil 8 and the current is limited.

The second coil 9 wound alternately with the first coil 8 is induced when a current flows through the first coil 8 to generate an induced current. This induced current forms a magnetic flux b in a direction that cancels the magnetic field generated by the first coil 8. As a result, the superconducting magnetic shield (main body 7) does not reach the critical magnetic field due to the normal transmission current, and does not quench from the superconducting state to the normal conducting state. Here, in the state where the second coil 9 is not wound, the first coil 8 is quenched from the superconducting state to the normal conducting state by the normal transmission current. That is, without the second coil 9, the magnetic field for the transmission current becomes too large and reaches the critical magnetic field of the superconducting magnetic shield (main body 7). However, as a result of the second coil 9 canceling its own magnetic field, it is possible to allow a relatively larger current to flow. The resistor 10 imposes a certain limit on the induced current flowing through the second coil 9.

With the above construction, the following effects are obtained in this embodiment. (1) The superconducting magnetic shield (main body 7) cannot be used for the superconducting fault current limiter 1 only with the first coil 8 because the superconducting magnetic shield (main body 7) easily reaches the critical magnetic field by the normal transmission current. However, since the magnetic field of the first coil 8 can be shielded by alternately winding the first coil 8 and the second coil 9 around the main body 7, the superconducting magnetic shield (main body 7). The shielding effect is enhanced and the leakage impedance can be reduced as compared with only That is, even if the power transmission current is normal, it is possible to prevent reaching the critical magnetic field by alternately disposing the second coil 9 and the first coil 8. (2) Since the first coil 8 is wound around the superconducting magnetic shield (main body 7) without any gap, there is no leakage impedance between the coil 8 and the main body 7 and waste of transmitted power is eliminated. (3) Since the second coil 9 is wound around the first coil 8 alternately, an induced current is generated in the second coil 9 by the first coil 8 to reduce the magnetic flux a of the first coil 8. It will be possible to cancel it. (4) The critical current value can be adjusted by changing the value of the resistor 10 arranged in the second coil 9.

Next, experimental data in this embodiment will be described. The main body has an outer diameter of 50 mmΦ, an inner diameter of 40 mmΦ, and a length of 50 m.
It is composed of a cylindrical superconducting magnetic shield of m. The superconducting magnetic shield is of bismuth type and has a normal atomic ratio of B
i: Sr: Ca: Cu = B: 2: 2: 1: 2
After preparing i ₂ O ₃ , SrCO ₃ , CaCO ₃ , and CuO powder, 4 wt% of Ag powder was added to obtain a raw material powder. The raw material powder was molded into a cylindrical shape and sintered, and the critical conditions were: critical temperature (Tc) 90K, critical magnetic field (Bc) 50 gauss, critical current (Ic) 3000A / c.
m ² . This body has 100 turns and a coil length of 4
When the first coil was wound once at 0 mm and an electric current was passed, it was quenched at 14.0 A.

The conditions of the main body and the first coil were set in the same manner as above, and the second coil was wound alternately with the first coil at 100 turns and a coil length of 40 mm. A 0.3 Ω resistor was connected to the end of the second coil. When a current was passed through the first coil under this condition, the first coil was quenched at 18.0A. Therefore, according to the present implementation data, about 1.3 times as much current could be passed as compared with the case where the second coil is not wound.

(Embodiment 2) As shown in FIG. 4, a superconducting fault current limiter 1 comprises a cylindrical main body 7 made of a superconducting magnetic shield, a first coil 8 and a second coil 9. The coils 8 and 9 are twisted together, and the coils 8 and 9 in the twisted state are wound around the outer circumference of the main body 7. The tip of the first coil 8 is connected to the power transmission line 4 side, and the base end is connected to the circuit breaker 3 side. Both ends of the second coil 9 are joined via a resistor 10. The coils 8 and 9 magnetically affect each other on the outer peripheral side of the main body 7 during normal power transmission and overcurrent generation. The superconducting fault current limiter 1 is always kept in a cooled state by liquid nitrogen.

Also in the second embodiment, as in the principle of the first embodiment, the magnetic field of the first coil 8 is canceled by the second coil 9, so that the following effects are produced. (1) The superconducting magnetic shield (main body 7) cannot be used for the superconducting fault current limiter 1 only with the first coil 8 because the superconducting magnetic shield (main body 7) easily reaches the critical magnetic field by the normal transmission current. However, since the magnetic field of the first coil 8 can be shielded by twisting the first coil 8 and the second coil 9 together around the main body 7, only the superconducting magnetic shield (main body 7) can be shielded. Compared with this, the shielding effect is enhanced and the leakage impedance can be reduced. That is, by winding the first coil 8 around the second coil 9, it is possible to prevent the first coil 8 from reaching the critical magnetic field under normal power transmission current. (2) Since the first coil 8 and the second coil 9 are twisted together and wound around the main body 7, the adhesion between the two coils 8 and 9 is improved, and the magnetic field of the first coil 8 is changed to the embodiment. Shielded to 1 or more. (3) Since both coils 8 and 9 are wound around the superconducting magnetic shield (main body 7) without any gap, there is no leakage impedance between the coil 8 and the main body 7, and the transmission power is not wasted. (4) The critical current value can be adjusted by changing the value of the resistor 10 arranged in the second coil 9.

(Embodiment 3) As shown in FIG. 5, the superconducting fault current limiter 1 comprises a cylindrical main body 7 made of a superconducting magnetic shield, a first coil 8 and a second coil 9. Both coils 8 and 9 are wound in the same direction, and are alternately superposed so that the other coil is wound on the outside of one coil, and in the third embodiment, four coils are formed.
The first coil 8 of the first stage is wound around the outer circumference of the main body 7 for 100 turns. Then, the second coil 9 is 100 in the second stage so as to surround the first coil 8 in the first stage.
It is wound around the turn. Then, the first coil 8 is wound again for 100 turns in the third stage, and the second coil is again wound in the fourth stage.
The coil 9 is wound 100 turns. The tip of the first coil 8 is connected to the power transmission line 4 side, and the base end is connected to the circuit breaker 3 side. Both ends of the second coil 9 are joined via a resistor (not shown). Both coils 8,
Both 9 are arranged on the outer peripheral side of the main body 7, and magnetically affect the first coil 8 during normal power transmission and overcurrent generation. The superconducting fault current limiter 1 is always kept in a cooled state by liquid nitrogen.

Also in the third embodiment, the magnetic field of the first coil 8 is canceled by the second coil 9 similarly to the principle of the first embodiment, so that the following effects are produced. (1) The superconducting magnetic shield (main body 7) cannot be used for the superconducting fault current limiter 1 only with the first coil 8 because the superconducting magnetic shield (main body 7) easily reaches the critical magnetic field by the normal transmission current. However, since the magnetic field of the first coil 8 can be shielded by alternately winding the first coil 8 and the second coil 9 around the main body 7, only the superconducting magnetic shield (main body 7) is used. Compared with this, the shielding effect is enhanced and the leakage impedance can be reduced. That is, since the first coil 8 and the second coil 9 are alternately arranged, it is possible to prevent the first coil 8 from reaching the critical magnetic field in the normal transmission current. (2) When the first coil 8 and the second coil 9 are alternately overlapped and wound around the main body 7, when the second coil 9 is simply wound around the outer circumference of the first coil 8. Compared with each other, the degree of adhesion between the coils 8 and 9 is improved, and the magnetic field of the first coil 8 is shielded more than the first embodiment. (3) Since the first coil 8 is wound around the superconducting magnetic shield (main body 7) without a gap, there is no leakage impedance between the coil 8 and the main body 7, and the transmitted power is not wasted. (4) The critical current value can be adjusted by changing the value of the resistor 10 arranged in the second coil 9.

(Embodiment 4) As shown in FIG. 6, a superconducting fault current limiter 1 comprises an annular main body 7 made of a superconducting magnetic shield, a first coil 8 and a second coil 9. . Both coils 8 and 9 are wound in the same direction, and the coil wires of both coils 8 and 9 are arranged alternately as in the first embodiment. The main body 7 is divided into a plurality of pieces, and both coils 8 and 9 are arranged in a sandwiched state between the divided main bodies 7. The outer surfaces of the coils 8 and 9 and the outer periphery of the main body 7 are substantially flush with each other,
The inner surfaces of the coils 8 and 9 and the inner circumference of the main body 7 are substantially flush with each other. As a result, the coils 8 and 9 do not protrude from the end face side of the main body 7. Both coils 8,
9 and the main body 7 are adhered with a low temperature resistant adhesive tape so as not to separate from each other.

The tip end of the first coil 8 is connected to the power transmission line 4 side, and the base end is connected to the circuit breaker 3 side. Second
Both ends of the coil 9 are joined via a resistor (not shown). Both coils 8 and 9 are arranged on the outer peripheral side of the main body 7, and magnetically influence each other with the first coil 8 during normal power transmission and overcurrent generation. The superconducting fault current limiter 1 is always kept in a cooled state by liquid nitrogen.

Also in the fourth embodiment, the magnetic field of the first coil 8 is canceled by the second coil 9 similarly to the principle of the first embodiment, so that the following effects are produced. (1) The superconducting magnetic shield (main body 7) cannot be used for the superconducting fault current limiter 1 only with the first coil 8 because the superconducting magnetic shield (main body 7) easily reaches the critical magnetic field by the normal transmission current. However, since the magnetic field of the first coil 8 can be shielded by alternately winding the first coil 8 and the second coil 9 around the main body 7, only the superconducting magnetic shield (main body 7) is used. Compared with this, the shielding effect is enhanced and the leakage impedance can be reduced. That is, since the first coil 8 and the second coil 9 are alternately arranged, it is possible to prevent the first coil 8 from reaching the critical magnetic field in the normal transmission current. (2) When the first coil 8 and the second coil 9 are alternately overlapped and wound around the main body 7, when the second coil 9 is simply wound around the outer circumference of the first coil 8. Compared with each other, the degree of adhesion between the coils 8 and 9 is improved, and the magnetic field of the first coil 8 is shielded more than the first embodiment. (3) Since the first coil 8 is arranged without protruding from the superconducting magnetic shield (main body 7), there is no leakage impedance between the coil 8 and the main body 7 and waste of transmitted power is eliminated. (4) The critical current value can be adjusted by changing the value of the resistance arranged in the second coil 9.

(Embodiment 5) As shown in FIG. 8, the first coil 8 may be arranged in a second coil 9 formed of a hollow coil wire. Both coils 8 and 9 are wound around the outer periphery of the main body 7 made of a superconducting magnetic shield. The outer surfaces of the coil wires of both coils 8 and 9 are insulated with enamel paint. The tip of the first coil 8 extending outward from the second coil 9 is connected to the power transmission line 4 side, and the base end extending outward from the second coil 9 is also a circuit breaker. It is connected to the 3 side. Both ends of the second coil 9 are joined via a resistor (not shown). Both coils 8 and 9 are arranged on the outer peripheral side of the main body 7, and magnetically influence each other with the first coil 8 during normal power transmission and overcurrent generation. The superconducting fault current limiter 1 is always kept in a cooled state by liquid nitrogen.

Also in the fifth embodiment, the magnetic field of the first coil 8 is canceled by the second coil 9 similarly to the principle of the first embodiment, so that the following effects are produced. (1) The superconducting magnetic shield (main body 7) cannot be used for the superconducting fault current limiter 1 only with the first coil 8 because the superconducting magnetic shield (main body 7) easily reaches the critical magnetic field by the normal transmission current. However, since the magnetic field of the first coil 8 can be shielded by disposing the first coil 8 in the second coil 9, the shielding effect is enhanced as compared with only the superconducting magnetic shield (main body 7). Leakage impedance can be reduced. That is, since the first coil 8 is disposed inside the second coil 9, it is possible to prevent the first coil 8 from reaching the critical magnetic field during normal power transmission current. (2) By disposing the first coil 8 in the second coil 9, it is possible to completely surround the first coil 8 and shield the magnetic field, so that the magnetic field is shielded very effectively. You can (3) It is possible to adjust the critical current value by changing the value of the resistance arranged in the second coil 9.

The embodiment of the present invention has been described above.
The present invention can be implemented by being modified into other aspects. When the first coil 8 and the second coil 9 are wound around the outer circumference or the inner circumference of the main body 7, both coils 8 and 9 may be randomly wound without being arranged in an orderly manner. Good. That is, even if both coils 8 and 9 are appropriately wound in the same direction, the second coil 9 prevents the first coil 8 from winding.
Since the magnetic field can be shielded, the shielding effect is enhanced and the leakage impedance can be reduced as compared with the superconducting magnetic shield (main body 7) alone.

In each of the above-mentioned embodiments, the first side is provided on the outer peripheral side of the main body 7.
Although the second coils 8 and 9 are arranged, both coils 8 and 9 may be provided on the inner circumference of the main body 7 as shown in FIG. This is because the magnetic shielding effect of the main body 7 is exerted on the first coil 8 even at the inner circumference of the main body 7, and the second coil 9 can cancel the magnetic field of the first coil 8. .

In the third embodiment, the number of turns is especially 1
It is not limited to 00 turns. Further, although both coils 8 and 9 are wound in four turns for each same number of turns, the number of turns need not be the same, and it is not necessary that the number of turns is four. In the third embodiment, the coils 8 and 9 are alternately wound by changing the stage every 100 turns, but may be alternately wound by every one turn. That is, you may wind so that both coils 8 and 9 may adjoin each stage. That is, it suffices that both coils 8 and 9 have a relationship in which they influence each other.

In the fourth embodiment, both coils 8 and 9 are alternately arranged between the main bodies 7, but they are not alternately arranged.
9 may be wound at random as described above. Further, the number of divided bodies and the arrangement interval of the annular main body 7 can be freely changed.

Although the main body 7 is hollow, it is of course possible to insert an iron core inside. Examples of the iron core include high resistance magnetic material, ferrite, and amorphous. Although the main body 7 has a cylindrical shape, it does not have to be a cylindrical shape, and may be a cylindrical body having a polygonal cross section. Further, it is also possible to form flange portions on both ends of the main body 7 or to form irregularities on the outer periphery of the main body. Also,
In the above embodiment, Bi: Sr: Ca: Cu = 2: 2: 1 :.
Although the bismuth-based superconducting shield of No. 2 was used, other blends may be used. Further, it is of course possible to use a superconducting shield other than bismuth based, for example, yttrium based.

In addition, the present invention can be implemented by freely changing it without departing from the spirit of the present invention.

[0029]

As described above, in the inventions of claims 1 to 5, the magnetic field of the first coil can be canceled by the second coil. Therefore, the excellent effect that the superconducting magnetic shield can be prevented from reaching the critical magnetic field in the normal transmission current and the practical use of the current limiting device utilizing the superconducting phenomenon can be achieved. In addition, in the inventions of claims 4 and 5, in addition to the first
The leakage impedance of the coil is reduced and the transmission current loss is reduced.

[Brief description of drawings]

FIG. 1 is a schematic perspective view illustrating a main part of a first embodiment to which a superconducting fault current limiter according to the present invention is applied.

FIG. 2 is a partially enlarged front view illustrating the flow of magnetic flux of a coil in the same Example 1.

FIG. 3 is a schematic diagram illustrating an arrangement position of a current limiting device in a power transmission and distribution facility in the same Example 1.

FIG. 4 is a schematic perspective view illustrating a main part of a superconducting fault current limiter of another embodiment 2.

FIG. 5 is a schematic side view illustrating a main part of a superconducting fault current limiter of another example 3.

FIG. 6 is a schematic side sectional view of a superconducting fault current limiter of another embodiment 4.

FIG. 7 is a schematic perspective view illustrating a main part of a superconducting fault current limiter according to another embodiment.

FIG. 8 is a schematic side sectional view for explaining a main part of a superconducting fault current limiter according to a fifth embodiment.

[Explanation of symbols]

1 ... Superconducting fault current limiter, 7 ... Superconducting magnetic shield main body, 8
... first coil, 9 ... second coil.

Claims (6)

[Claims] 1. A first coil that allows conduction of a transmission current and a second coil that acts so as to cancel the magnetic field of the first coil are arranged on the inner or outer circumference side of the superconducting magnetic shield. A superconducting fault current limiter, characterized in that in the provided superconducting fault current limiter, the coil wires of the first coil and the second coil are twisted together. 2. A superconducting magnetic shield is provided with a first coil which allows the passage of a transmission current and an second coil which acts so as to cancel the magnetic field of the first coil on the inner peripheral side or the outer peripheral side. A superconducting fault current limiter, characterized in that, in the provided superconducting fault current limiter, coil wires of a first coil and a second coil are alternately arranged every predetermined turn. 3. A superconducting magnetic shield is provided with a first coil which allows conduction of a transmission current and a second coil which acts so as to cancel a magnetic field of the first coil on the inner or outer circumference side. A superconducting fault current limiter, characterized in that in the provided superconducting fault current limiter, the coil wires of the first coil and the second coil are wound at random with respect to each other. 4. A first coil, which allows the passage of a transmission current, and a second coil, which acts to cancel the magnetic field of the first coil, are arranged on the inner circumference side or the outer circumference side of the superconducting magnetic shield. The superconducting fault current limiter provided, wherein the coil line of the first coil is disposed inside the coil line of the second coil formed in the hollow via an insulating layer. 5. A superconducting device, characterized in that the coil wires of the first and second coils are alternately wound every predetermined number of turns and are sandwiched between superconducting magnetic shields divided into a plurality of annular bodies. Current limiter. 6. A superconducting fault current limiter characterized in that coil wires of a first coil and a second coil are randomly wound around each other and are sandwiched between superconducting magnetic shields divided into a plurality of annular bodies. .