KR100803568B1 - Superconductivity electric power cable component for PSCAD/EMTDC - Google Patents

Abstract

The present invention relates to a superconducting power cable component for PSCAD (Power System Computer Aided Design) / EMTDC (Electro Magnetic Transient DC analysis program), which is connected to the superconducting cable and inputs the current flowing through the cable, the temperature of the cable, and the operation of the breaker. It is characterized in that the output of the corresponding superconducting power cable can be presented and solved according to the corresponding output formula.

The present invention for achieving the above object is an input unit for receiving the input signal of the line breaker and the input current of the superconducting power cable and the temperature of the superconducting power cable in the system in order to simulate the line applying the superconducting power cable, and the input signal According to the characteristics of the superconductor when the accident does not occur in the system according to the current value and temperature value flowing through the superconducting cable input to the input unit, and the operation state of the breaker The superconducting power cable component for PSCAD / EMTDC, which is operated by the output type of the superconducting power cable when an accident occurs (ground, short circuit, temperature rise due to freezer failure, etc.). Let that thing be about the technical gist.

Superconducting power cables, components, PSCAD / EMTDC, simulation,

Description

Superconductivity electric power cable component for PSCAD / EMTDC}

1 is a V-I characteristic graph of the superconducting power cable,

2 is a graph showing the change of the threshold current according to the change of the voltage and current characteristic equation characteristic coefficient,

3 is a graph of the critical current characteristic data according to the change of temperature;

4 is a magnetic field characteristic experiment data graph,

5 is a conceptual diagram illustrating a superconducting power cable component,

6 is an operation algorithm of a superconducting power cable component,

7 is a circuit diagram illustrating a simulation by applying a superconducting power cable component to a domestic 22.9 [kV] distribution line;

8 is a graph showing the fault current of the superconducting power cable at ground fault;

9 is a graph showing the resistance of the superconducting power cable at ground fault,

10 is a graph showing the power loss change of the superconducting power cable according to the threshold current value in the three-phase short circuit,

11 is a graph showing the change in the internal power loss of the superconducting power cable according to the impedance change of the line of the graph showing the simulation result of applying the superconducting power cable component to the 345/154 [kV] transmission line.

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

(IN): Inrush current from the system to the superconducting power cable

(K): temperature of superconducting power cable

(CB): line breaker

(OUT): resistance of superconducting power cable

The present invention relates to a superconducting power cable component for PSCAD (Power System Computer Aided Design) / EMTDC (Electro Magnetic Transient DC analysis program), which is connected to the superconducting cable and inputs the current flowing through the cable, the temperature of the cable, and whether the breaker is operated. It is characterized in that the output of the corresponding superconducting power cable can be presented and solved according to the corresponding output formula.

The superconducting power cable can increase the transmission capacity per unit area by three or four times compared with the existing power cable, which makes the power cable smaller and larger in capacity. In addition, there is almost no loss due to electrical resistance, which can also reduce the transmission cost.

  The development of such superconducting power cables has been actively promoted at home and abroad in recent years, and the necessity of researches on the application of actual system lines for practical use has emerged.

Various studies are required to apply superconducting power cable to real system line, among which superconducting power cable is applied in simulation program that can implement real power system. Power System Computer Aided Design / Electro Magnetic Transient DC analysis program PSCAD / EMTDC abbreviated as PSCAD / EMTDC is widely used by power system analysis researchers because of its excellent grid-connected analysis characteristics and familiar interface, but it does not have a component model of superconducting power cable. The problem is that you can't.

The present invention was created to solve the above-mentioned conventional problems, and superconducting power for PSCAD / EMTDC reflecting the characteristics (critical current, critical temperature, magnetic field, etc.) of the superconducting power cable for the application of the superconducting power cable in the simulation. It is an object of the present invention to provide a superconducting power cable component for PSCAD / EMTDC characterized by developing a cable component model and applying it to a power system using a superconducting power cable.

The present invention for achieving the above object is an input unit for receiving the input current of the line breaker and the input current of the superconducting power cable and the temperature of the superconducting power cable to the superconducting power cable in order to simulate the line applying the superconducting power cable, and the input signal According to the characteristics of the superconductor when the accident does not occur in the system according to the current value and temperature value flowing through the superconducting cable input to the input part and the breaker operating state The superconducting power cable component for PSCAD / EMTDC, which is operated by the output type of the superconducting power cable when an accident occurs (ground, short circuit, temperature rise due to freezer failure, etc.). It is about.

When described in detail in connection with the accompanying drawings the configuration and the operation of the embodiment of the present invention to achieve the object as described above and to perform the problem for eliminating the conventional drawbacks.

Figure 1 shows the superconducting cable voltage-current characteristic curve obtained through the experiment, through which the V-I characteristic equation (1) of the cable can be derived.

V = exp ^{(Ι / 557.72385)} * 2.14242E-6 + 1.43695E-4 (1)

By changing the constant value (557.72385) in (1) (named the constant value as the characteristic coefficient of the characteristic equation), the threshold current value Ιc can be changed accordingly. The threshold current and the characteristic coefficient of each graph can be changed. Equation (2) can be derived from the relation with.

V = exp ^{(Ι / -1.20531 + 0.20913 * Ιc)} * 2.14242E-6 + 1.43695E-4 (2)

The resistance formula of the superconducting power cable is shown in Equation (3).

R = V / I = (exp ^{(Ι / -1.20531 + 0.20913 * Ιc)} * 2.14242E-6 + 1.43695E-4) / I (3)

That is, it can be seen that the resistance of the superconducting power cable is determined according to the current flowing through the cable when the critical current is determined.

3 is a diagram of the critical current characteristics of the superconducting wire according to the temperature change, as shown in FIG. 3, it can be seen that the critical current (I _C ) value decreases as the temperature increases. You can change the value of I _C according to.

4 shows a decrease in the threshold current value when a magnetic field is applied to the superconducting wire, which can also be formulated to formulate a change value of I _C according to the change of the magnetic field in Equation (3). Finally, the changed equation will be described in detail with reference to FIG. 6.

5 shows a component of the superconducting power cable invented, the component operates in a computer language, and used the FORTRAN language in this embodiment.

The component model consists of three inputs (IN, K, CB) and one output (OUT).

Superconducting power cable components operate according to the current and temperature values flowing through the superconducting cable in the system and the breaker operating conditions. When there is no accident in the system, the superconducting power cable component operates with a resistance value of almost 0 according to the characteristics of the superconductor. It is operated by the output expression which shows the same transient as the actual superconducting power cable.

6 is a diagram illustrating an operation algorithm of the superconducting power cable component, which is operated according to an output expression for each case when an incoming current and temperature are normal, when a quench occurs, and when a breaker is operated. The output formula for each situation is expressed as the resistance characteristic function.

When the incoming current and the temperature are normal, as shown in FIG. 6, it operates as a F ₁ (t) function, and the operation equation is as follows.

F ₁ (t) = R ≒ 0

On the other hand, F ₂ (t), which is the resistance characteristic function when quench occurs, is as follows.

F ₂ (t) = R = V / I = (exp ^{(Ι / (-1.20531 + 0.20913 * (Ιc- (Ιc / 50 * (K-77))-0.27 * I / 2)))} * 2.14242E- 6 + 1.43695E-4) / I

In the above formula, K represents temperature and I represents inrush current.

In addition, F ₃ (t), which is a resistance characteristic function when the circuit breaker operates, is as follows.

F ₃ (t) = F ₂ (t)-((TIME-TC) ² * 0.05)

In the above formula, TIME represents simulation time and TC represents time constant.

FIG. 7 is a circuit diagram illustrating a simulation by applying a superconducting power cable component to a domestic 22.9 [kV] distribution line, and FIGS. 8, 9, and 10 are examples of waveforms of the simulation results.

8, 9 and 10, it can be seen at a glance the fault current of the superconducting power cable, the resistance of the superconducting power cable, the internal power loss of the superconducting power cable when a line accident occurs.

One of the factors to be considered when applying a superconducting power cable to an actual system is the refrigerator capacity, which is related to the power loss (Ploss = I ² R).

As the power loss increases, the capacity of the refrigerator increases accordingly, and simulation results using cable components show that proper calculation of the critical current value will be required.

FIG. 11 is a graph showing simulation results of applying a superconducting power cable component to another 345/154 [kV] transmission line. This is a result of changing the impedance value of a general cable line while keeping the length of the superconducting power cable constant. When the internal power loss change graph is shown.

As shown in FIG. 11, since the impedance changes according to an accident point of the line, it is possible to know the loss value of the superconducting power cable according to the accident occurrence point.

Furthermore, if the installation location of the superconducting power cable (distance from the power plant), the threshold current value, the fault current value, the length of the cable, the fault point, etc. are applied to the superconducting power cable EMTDC component, the superconducting power cable The change in the internal power loss can be easily seen.

The present invention is not limited to the above-described specific preferred embodiments, and those skilled in the art to which the present invention pertains may make various modifications without departing from the gist of the present invention as claimed in the claims. Of course, such changes will fall within the scope of the claims.

The effects of the present invention that can be expected by the configuration and action as described above are as follows.

By applying the superconducting power cable component of the present invention to simulation, it is possible to simulate a variety of accidents of the system, through which it is possible to predict possible problems in the design of the superconducting power cable, the actual line application.

Claims (2)

In constructing a superconducting power cable component for PSCAD / EMTDC (Power System Computer Aided Design / Electro Magnetic Transient DC analysis program), An input unit receiving an input current from the system to the superconducting power cable and the temperature of the superconducting power cable and an input signal of the line breaker, and an output unit transmitting an output signal according to the input signal input by the input unit, When there is no accident in the system according to the current value and temperature value flowing through the superconducting cable inputted to the input unit and the operation state of the breaker, the resistance operates according to the characteristics of the superconductor, and an accident has occurred. A superconducting power cable component for PSCAD / EMTDC, characterized in that during operation (ground, short circuit, temperature rise due to a freezer failure, etc.), it is operated by an output expression representing the same transient as the actual superconducting power cable. The method of claim 1, The output expression representing the same transient as the actual superconducting power cable is 0 when the incoming current and temperature are normal and the breaker is operated, and the resistance value is 0. When the quench occurs, it is determined according to the incoming current and the temperature into the superconducting cable. Superconducting power cable component for PSCAD / EMTDC, characterized in that the simulation can be interpreted according to the resistance value.

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