KR100352791B1 - Device for noninductively limiting fault-current with superconductor - Google Patents

Abstract

The present invention relates to a non-inductive superconducting fault current limiter by designing a superconductor in a symmetrical repeating annular structure so that no inductive capacity is generated and an accident current can be limited to an appropriate value instantaneously without any control device when an accident occurs. .

The superconducting fault current limiter according to the present invention is composed of a superconductor thin film designed in a symmetric repeating annular structure of a circle or a square in order to limit the fault current instantaneously without having an inductive capacity and a circuit breaker by supporting the thin film. It is installed in series with and characterized in that it can be used as part of the transmission line.

According to the present invention configured as described above, in the event of an accident, the instantaneous phase conduction phenomenon of the superconductor can quickly limit the accident current to an appropriate value or less, thereby stabilizing the power system and preventing various devices from being damaged. Designed as a repeating annular structure, it has no inductive capacity and can be used as part of a transmission line without affecting the existing power system network.

Description

Non-inductive superconductor fault current limiter {Device for noninductively limiting fault-current with superconductor}

The present invention relates to a non-inductive superconducting fault current limiter, and more particularly, by designing the superconductor in a symmetrical repeating annular structure, it does not have an inductive capacity, and when an accident occurs, the fault current is instantaneously or less without any control device. It relates to a non-inductive superconducting fault current limiter that can be limited.

In general, in the event of an accident such as a short circuit in any part of the power system, by operating the adjacent breaker at the site of the fault, the upper power line and the short circuited line are cut off, thereby reducing the power loss due to overcurrent leakage and reducing the surrounding power. It protects the equipment and prevents the entire system from going down, allowing the continuous supply of power to other healthy lines. Therefore, the breaking speed and current limiting ability of the breaker system are very important factors in the stability of the power system.

Conventionally, semiconductor switching is performed by detecting a current limiting device that suppresses overcurrent leakage and a current limiter which consists of a circuit breaker that increases the breaking speed by using a power semiconductor switching element such as a GTO, or a general impedance circuit. A circuit breaker system consisting of a current detector to control the device was installed to improve the performance of the breaker speed and stabilize the system.

However, the conventional circuit breaker system configured as described above detects an overcurrent in the current detector and controls the circuit breaker switching device, and then flows a current through a current limiting device connected in parallel with the circuit breaker to suppress leakage overcurrent. About five to six cycles of time have elapsed during this process, causing excessive current to flow through the power grid. Therefore, in order to stabilize the system, a circuit breaker having a large enough capacity to withstand such excessive currents and various power devices must be installed, and in some cases, there is a problem that the entire system can be down due to the breakdown of various devices.

The present invention has been made to solve the above problems, the object of the present invention is that the electrical resistance is "zero" for a certain current and the property that the electrical resistance is generated by the phase-conducting for overcurrent over a certain value In introducing superconductors into a power system, superconductors are designed as a non-inductive circuit with a symmetrical repeating annular structure and installed in series on a line, minimizing line impedance and instantaneously suppressing an accident current below an appropriate value when an accident occurs. It is to provide a non-inductive superconducting fault current limiter.

1A shows a circular symmetric repeating annular circuit of an inductive superconducting fault current limiter in accordance with the present invention;

1B is a diagram showing a rectangular symmetric repeating annular circuit of an inductive superconducting fault current limiter according to the present invention;

Figure 2a is a cross-sectional view of a single fault current limiter in accordance with the invention.

2b is a sectional view of a double layer fault current limiter in accordance with the invention;

3 is a structural diagram of a circuit breaker system incorporating an accident current limiter according to the present invention;

<Explanation of symbols for the main parts of the drawings>

10. Superconductor Thin Film 11. Input Terminal

12. Output terminal 20. Support board

25. Magnetic flux line 30. Superconductor accident current limiter

40. Breaker 45. Fault current detector

The present invention is configured as follows to achieve the above object. That is, the non-inductive superconducting fault current limiter 30 according to the present invention includes an input terminal 11 for inputting a current of a transmission line into the fault current limiter 30, and the fault current limiter 30. Output terminal 12 for outputting the current passing through the transmission line, connected to the transmission line through the input terminal 11 and the output terminal 12 is used as part of the transmission line and is made of a superconductor symmetrical And a superconductor thin film 10 which is designed as a plurality of series annular circuits (hereinafter referred to as symmetric repeating annular circuits) which are arranged inwardly, thereby limiting the flow of fault current without generating inductive capacitance, and supporting the superconductor thin film. It characterized in that it comprises a substrate (20).

Preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1A to 1B are views showing a symmetrically repeating annular structure of a superconductor thin film in the fault current limiter according to the present invention, and FIGS. 2A to 2B are cross-sectional views of a fault current limiter designed as a single layer or a double layer. 3 is a structural diagram of a circuit breaker system incorporating an accident current limiter 30 according to the present invention.

1A to 1B, in the fault current limiter 30 according to the present invention, the superconductor thin film 10 may have a circular or rectangular symmetric repeating annular structure, and the current of the line is input terminal. Input through (11) is passed through the superconductor thin film 10 formed of a symmetrical repeat annular structure and then output through the output terminal 12 is transmitted.

In general, superconductors have a property of zero electrical resistance and repulsion against a magnetic field. When a constant current flows, the electrical resistance becomes "zero", and when an overcurrent exceeding a threshold value flows (up to 1 ms), the phase conductor becomes superconducting. There is a property that the electrical resistance is generated.

The present invention is to suppress the fault current by using the superconductor properties of the present invention, which uses passive elements (R, L) and the like, and is fundamentally different from the conventional fault current limiter installed and operated in parallel with a breaker. will be.

On the other hand, in the transmission system, the line impedance should be as low as possible to reduce the line loss and improve the power factor, and the impedance of the fault current limiter should be high enough to limit the overcurrent in case of an accident. Incorporating the fault current limiter 30 into a circuit having a symmetrical repeating annular structure, it is possible to simultaneously achieve these two requirements, and the fault current limiter 30 is usually part of a transmission line. Simultaneously with use, in case of an accident, it is to play a role of limiting the accident current.

That is, the superconductor thin film 10 is configured as a symmetrical repeating annular circuit so that inductive capacitance does not occur and the electrical resistance of the superconductor becomes "zero" for a current below a threshold value, so that the fault current limiter is part of the transmission line. Even if it is used, the impedance of the line is not increased, and in case of an accident, the electrical resistance of the fault current limiter 30 is rapidly increased due to the superconductor's nature of the superconductor converting to a phase conductor instantaneously (within 1 ms) for overcurrent above a certain value. Therefore, the fault current can be limited below the appropriate value.

In addition, when the fault current limiter 30 is installed in series with the breaker 40 to use the superconductor thin film 10 as part of a transmission line, when a short circuit accident occurs regardless of the overcurrent detection of the current detector 45. Immediately, the fault current can be limited below the appropriate value.

In the above design of the superconductor in a symmetric repeating annular structure is introduced to increase the length of the superconductor thin film 10 with respect to the volume of the constant support substrate 20 so as to prevent the inductive capacitance from occurring while improving the capability of suppressing the fault current. It is.

The principle that the superconductor thin film circuit 10 becomes inductive by the annular structure is as follows.

The circuit of the symmetric repetitive annular structure is configured to be connected continuously from the input terminal 11 to the output terminal 12, but in electrical terms it is composed of a plurality of circular or square circuits, the current through each circuit Can be treated as circulating clockwise or counterclockwise. This flow of current is arranged by repeating the counterclockwise and clockwise flows from the outermost to the innermost. The magnetic flux caused by the counterclockwise current cancels the magnetic flux caused by the inner clockwise current and is applied to the clockwise current. The magnetic flux caused by this cancels the magnetic flux caused by the counterclockwise current just inside, so that the circuit of the annular structure does not generate the inductive capacity.

In addition, as shown in Figures 2a to 2b, the superconductor thin film 10 is designed in a single layer structure on the support substrate 20, or using the support substrate 20 more efficiently and the superconductor circuit 10 ) May be designed as a double layer circuit having the same symmetric repeating annular structure on the top or bottom of the support substrate 20 to increase the current suppression capacity.

In addition, by providing a plurality of the support substrate 20 to design a superconductor thin film 10 circuit of a multi-layer array it is possible to further increase the capacity to suppress the accident current.

On the other hand, the superconductor thin film 10 is converted to a phase conductor at the time of an accident to limit the fault current to an acceptable value or less, the point where the fault current limiter is installed in the system and the capacity or desired current limit value of the peripheral power equipment. The thickness, width, and length of the thin film 10 may be changed in order to set the electrical resistance of the fault current limiter to an appropriate value in consideration of the above.

In FIG. 2A to FIG. 2B, the solid line indicates the direction and path of the magnetic flux line 25, and shows that the magnetic flux caused by the current in the inner circuit and the magnetic flux caused by the current in the outer circuit cancel each other. It can be seen that the circular or rectangular symmetric repeating annular circuit does not generate inductance. In addition, the dot (*) and X (X) marks in the superconductor thin film 10 are for indicating the current flowing out of the ground and the current flowing into the ground, respectively.

In addition, in designing the superconductor thin film 10 as a circuit having a symmetric repeating annular structure, the shape may be designed as a circuit such as a circle, a square, or another polygon.

In addition, as shown in Figure 3, the superconducting fault current limiter 30 according to the present invention is installed in series at the front end of the circuit breaker 40, is usually used as part of the main power line in the event of an accident It acts as a current limiting device.

In the circuit breaker system provided with the fault current limiter according to the present invention, the fault current blocking step includes a fault current generation step in which an over current flows through a power transmission line due to a short circuit accident on the receiving end side, and the current detector 45. Detects the fault current and at the same time the fault current limiter 30 is the fault current detection and limiting step to limit the fault current to less than an appropriate value by the superconductor phase phase, and to control the detector 45 By the breaker switch control step of operating the breaker switch, and by the opening of the breaker switch, the sound power system and the line blocking step is completely cut off the accident line.

The present invention is not limited to the above embodiments, and various modifications can be made within the scope of the technical idea of the present invention.

According to the present invention of the above-described configuration, by the instantaneous (1ms) phase conduction phenomenon of the superconductor in the event of an accident, by limiting the fault current to an appropriate value or less than 80 times faster than the conventional circuit breaker system to stabilize the power system and It can be designed to prevent damage to various devices, and because it is designed as a symmetrical repeating ring structure, it has no inductive capacity, and thus can be used as part of a transmission line without affecting the existing power system network.

In addition, it is possible to install various power devices with a smaller capacity than the conventional one and to promote efficient operation of the system by preventing accidental currents to be below an appropriate value and preventing overcurrent from flowing through the surrounding power devices.

Claims (4)

In the fault current limiter 30 for limiting the fault current of the power system, An input terminal 11 for inputting a current of a transmission line to the accident current limiter 30; An output terminal 12 for outputting the current passing through the accident current limiter 30 to a transmission line, It is connected to a transmission line through the input terminal 11 and the output terminal 12 and used as part of the transmission line, and a plurality of symmetrical and repeated internally arranged to prevent the generation of inductive capacity and to limit the flow of accident current. A superconductor thin film 10 having a series annular circuit, A support substrate 20 for supporting the superconductor thin film; The superconductor thin film 10 is a non-inductive superconducting fault current limiter, characterized in that the two-layer arrangement on the upper and lower portions of the support substrate 20. delete delete delete