JPS6227610B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a current cutoff method for a DC power supply circuit.

BACKGROUND ART Conventionally, the use of thyristors and disconnectors in DC feeding circuits has been considered, for example, in DC substations of electric railways. FIG. 1a shows a conventional system using thyristors and disconnectors. In the figure, 1 is a thyristor rectifier, and its DC output is supplied to the load from feeding circuits A and B, respectively. Each feeding circuit A, B has a commutation circuit and is composed of a thyristor shield breaker 2 that forcibly cuts, a diode 3 for reverse current, a CT 4 for current detection, and a control circuit 5 for the thyristor shield breaker 2. be done. On the other hand, Fig. 1b
1 shows a conventional method using a thyristor switch that does not have a commutation circuit and extinguishes at the current zero point. Supplied to loads not shown. Each feeding circuit A, B is composed of a thyristor switch 6, a reverse current diode 3, a current detection CT 4, and a control circuit 5 for the thyristor switch 6. This reverse current diode 3 is provided to supply the current regenerated from feeding circuit A to a load (not shown) in another feeding circuit B when a load (not shown) regenerates power. It will be done.

Next, the operation of the conventional system shown in FIG. 1 will be explained. First, for the system shown in Figure 1a, if an overcurrent occurs in feeding circuit A,
It is detected by the CT 4, a damping signal is generated from the control circuit 5, and the overcurrent is forcibly cut off by the commutation circuit of the thyristor circuit breaker 2. On the other hand, in the case of the system shown in Fig. 1b, when an overcurrent occurs in the feeding circuit A, this is detected by the CT4 and the gate signal of the thyristor rectifier 1 is stopped or the current is cut off by inverter operation. At the same time, the control circuit 5 stops the gate signal of the thyristor switch 6. As a result, a current zero point of the feeding circuit A is formed, and the thyristor switch 6 is turned off.

By the way, in the conventional system shown in FIG. 1a, if current is being supplied from the feeding circuit A shown in FIG. 1a to the load of the feeding circuit B through the reverse current diode 3, If an accident occurs in the connected thyristor or disconnector, in order to disconnect the feeding circuit B, the fault current from the thyristor rectifier and the reverse current diode 3 connected to the feeding circuit B must be connected. Since both the regenerative current flowing into the thyristor and the disconnector must be interrupted, the disconnection current (responsibility for disconnection current) increases, and the thyristor and disconnector 2
The number of commutation circuits has become enormous.

On the other hand, in the conventional system shown in FIG. 1b, the feeding circuits A and B may be thyristor switches 6, which eliminates the need for a commutation circuit as in the system shown in FIG. When current is being supplied from feeding circuit A to the load in feeding circuit B through reverse current diode 3, if an accident occurs in the thyristor switch connected to feeding circuit B, thyristor current transformer 1 is stopped. Even if current continues to flow through the reverse current diode 3 to the thyristor switch connected to the feeding circuit B, it becomes impossible to form a current zero point to naturally extinguish the thyristor switch. It becomes impossible to open. In addition, if there is a large inductance in the circuit to be opened, the current cut-off time due to the thyristor rectifier 1 becomes longer, and it takes several cycles of the commercial power supply to In some cases, it even extended to cycles.

As mentioned above, in the conventional system, the feeding circuit thyristor and the commutation circuit of the disconnector are large, and in a DC power supply circuit that requires a large number of feeding circuits such as a railway substation, the feeding circuit The size of the commutation circuit has become enormous, or it has become impossible to disconnect, or the disconnection time has become longer.

This invention is intended to eliminate the above-mentioned drawbacks of the conventional ones, and by organically combining the thyristor rectifier and the closing and breaking operations of the thyristor and disconnector, the thyristor and disconnector can be made into a small converter. The present invention is designed to allow only a current circuit to be used, and to shorten the time required for current flow and interruption.

An embodiment of the present invention will be described below with reference to FIGS. 2 and 3.
This will be explained based on the diagram. FIG. 2 shows an example of a current cutoff system equipped with a thyristor and a cutter. In Fig. 2, 1 is a thyristor rectifier, and its DC output is from feeding circuits A and B.
Each is supplied to a load (not shown). Further, the feeding circuits A and B are each connected to a feeding circuit of an adjacent substation (not shown) on the opposite side.
Each of the feeding circuits A and B is composed of a thyristor switch/breaker 2, a reverse current diode 3, a current detection CT 4, and a control circuit 5 for the thyristor switch/breaker. The control circuit 5 is configured to send a current switch/breaker signal to the thyristor rectifier 1 and the thyristor switch/breaker 2 based on the current detection signal from the CT 4. FIG. 3 is a detailed diagram of the control circuit 5 in FIG. 2.
In the figure, numeral 7 denotes a current setting circuit for setting the current that can be cut off by the thyristor or the disconnector 2. 8 is a comparison circuit which inputs the current setting value I _B from the current setting circuit 7 and the feeding circuit current I _O detected by the CT 4 and compares them, so that the feeding circuit current I _O becomes the current setting value I When it is equal to or less than _B , "1" is output, and the feeding circuit current I _O is the current set value I
It is configured to output "0" when it is larger than _B. Reference numeral 9 denotes a current setting circuit for setting the cut-off current of the feeding circuit. Reference numeral 10 denotes a comparison circuit which inputs the current setting value I _A from the current setting circuit 9 and the feeding circuit current I ₀ detected by the CT 4 and compares them, so that the feeding circuit current I ₀ is lower than the current setting value I _A It is configured to output "0" when it is small, and to output "1" when the feeding circuit current I ₀ is equal to or larger than the current setting value I _A . 11 is a disconnection signal circuit whose output is always "0",
When a shearing operation is performed by an external signal or the like, the output is set to "1". Note that the comparator circuit 10 and the shrinkage signal circuit 11
The output side of is connected to the input circuit of the OR circuit 12. The output of the OR circuit 12 is connected to the thyristor rectifier 1 and the input circuit of the self-holding circuit 13.
When the output of circuit 12 is "1", thyristor rectifier 1
performs a current on/off operation, and at the same time, the self-holding circuit 13 outputs "1", and the self-holding circuit 13 outputs "1" until a reset signal from the control circuit 14 of the thyristor switch 2 is input. On the other hand, the thyristor rectifier 1 is configured to continue the current cutting operation. Reference numeral 15 denotes an AND circuit, which receives the output signals of the comparator circuit 8 and the self-holding circuit 13 as its input, and its output side is connected to the input circuit of the control circuit 14, so that when the output of the AND circuit 15 becomes "1", The thyristor and disconnector 2 is configured to perform a disconnection and disconnection operation.

FIG. 4 shows operating waveforms of the embodiment of the present invention shown in FIGS. 2 and 3, and shows the case where a short-circuit accident occurs on the output side of the feeding circuit A at time _t0 . In the figure, I ₁ is the DC side current of the thyristor rectifier 1, and I ₂ is the current flowing from the adjacent substation (not shown in Figures 2 and 3) via the diode 3 of the feeding circuit B. , I ₀ is the above current I ₁ and current I ₂
This shows the current of the feeding circuit A. (8OUT) is comparison circuit 8, (10OUT) is comparison circuit 10, (12OUT) is OR circuit 12,
(13OUT) is self-holding circuit 13, (15OUT) is
The output signal waveforms of the AND circuit 15 are shown. (14R) shows the reset signal waveform sent from the control circuit 14 to the self-holding circuit 13.

Next, details of the operation of the present invention will be explained based on FIGS. 2, 3, and 4. First, when feeding circuit A is in a normal energized state, feeding circuit current I ₀
The relationship between I 0 and set current I _B is arbitrarily changed so that I ₀ ≦I _B or I ₀ >I _B . As a result, the output of the comparator circuit 8 is I ₀
It changes to "0" or "1" depending on the relationship between and I _B . However, since the relationship I ₀ <I _A holds true with the set current I _A , the output of the comparator circuit 10 becomes "0". Therefore, the external sheath disconnection signal circuit 1
The output of the OR circuit 12 maintains the state of "0" unless there is an on/off signal from 1. As a result, the thyristor rectifier 1 continues to operate normally, while the output of the self-holding circuit 13 remains at "0". Therefore, regardless of the output state of the comparator circuit 8, the output of the AND circuit 15 remains in the "0" state, and the control circuit 14 sends a control signal to the thyristor switch 2 so that it becomes energized. .

Next, a case where a short circuit accident occurs in the load circuit of the power circuit A at time _t0 will be explained. From time t ₀ to time t ₁ , the relationship is I ₀ < I _A and I ₀ < I _B , so the output of comparator circuit 8 is "1" and the output of comparator circuit 10 is "1".
The output of is "0". Therefore, as long as the output of the external shear disconnection signal circuit 11 is "0", the OR circuit 12
The output of becomes "0", and the self-holding circuit 13,
Since the output of the AND circuit 15 is "0", the thyristor rectifier 1 and the thyristor cutter 2 do not perform the current cutoff operation. Next, at time t ₁ I ₀ >
When I _B is reached, the output of the comparator circuit 8 changes from "1" to "0". On the other hand, since I ₀ <I _A , the outputs of the comparison circuit 10 and the OR circuit 12 continue to be "0". Therefore, neither the thyristor rectifier 1 nor the thyristor cutter 2 performs a current cutoff operation. Thereafter, when I ₀ =I _A at time t ₂ , the output of the comparison circuit 10 changes from "0" to "1". As a result, the output of the OR circuit 12 becomes "1", and the thyristor rectifier 1 performs the inverter operation after a slight control time delay and enters the current cutoff operation. On the other hand, since I ₀ > I _B , comparison circuit 8 and AND circuit 1
The output of 5 is "0", and the thyristor and disconnector 2
Do not perform chopping or cutting operations. Thyristor rectifier 1
The current I ₀ starts to attenuate due to the current fading action at the time
At t ₃ , I ₀ <I _A again. As a result, comparison circuit 1
0, the output of the OR circuit 12 becomes "0" again. However, since the control circuit 14 does not generate a reset signal, the output of the self-holding circuit 13 remains at "1" and the thyristor rectifier 1 continues to cut off the current. Next, when I ₀ =I _B at time t ₄ , the output of the comparator circuit 8 changes from "0" to "1". On the other hand, since the output of the self-holding circuit 13 is "1" at this time, the output of the AND circuit 15 changes from "0" to "1".
The control circuit 14 sends a disconnection signal to the thyristor and disconnector. As a result, after a slight control time delay, the thyristor circuit breaker 2 is turned off by the current magnitude I.
Cut off the current at _B. When the thyristor circuit breaker 2 completes current interruption, a circuit (not shown) sends a termination completion signal to the control circuit 14, and the control circuit 14 connects the thyristor rectifier 1 and the self-holding circuit 1.
A reset signal 14R is sent to 3. As a result, the thyristor rectifier 1 and the self-holding circuit 13 return to the state before the accident occurred. Also, when the output signal of the external sheath disconnection signal circuit 11 becomes "1", the OR circuit 12
The output of becomes "1", and in the same way as above, I ₀ > I
When in state _B , first thyristor rectifier 1
performs a current cutting operation, and when I ₀ ≦I _B , the thyristor and disconnector 2 performs a current cutting operation. Further, when I ₀ ≦I _B , the thyristor rectifier 1 and the thyristor switch/breaker 2 perform the cutting operation at the same time.

As is clear from the above explanation, the current breaking capacity of thyristor breakers and circuit breakers has conventionally been up to a current I _A with a capacity corresponding to the sum I ₀ of the fault current I ₁ and the regenerative current from the reverse current diode. What was needed was the current I _B
That's a good thing. Now, if the number of feeding circuits is n, the commutation capacity of all feeding circuits will be reduced by n(I _A - I _B ), and the effect will be greater in a DC feeding circuit with a large number of feeding circuits. growing.

Figure 5 shows a case where the present invention is applied to a main circuit configuration using a thyristor switch. In the configuration shown in the figure, the cathode side of the reverse current diode 3 of each feeding circuit A, The thyristor rectifier 1 is connected to the thyristor rectifier 1 through the thyristor disconnector 15.
Connected to the anode side of the output circuit. In such a configuration, the control circuit 5 sends a current disconnection signal to the thyristor rectifier 1 and the thyristor disconnector 15 at time _t2 in FIG. As a result, the current I ₂ from the adjacent substation shown in FIG. 4 is cut off at time t ₂ by the thyristor and disconnector 15, so that the regenerative current flowing from other feeding circuits through the reverse current diode I ₂ is suddenly cut off, so that the feeding circuit current I ₀ at time t ₄ is equal to the current I ₁ from the thyristor rectifier 1
Therefore, the current set value I _B can be made even lower.

The example shown in FIG. 2 has a configuration including a reverse current diode 3; however, this reverse current diode 3
Even without this, the present invention has the same effect as the above embodiment.

As described above, according to the present invention, in a DC power supply circuit having a thyristor rectifier current and a thyristor cutter or cutter in its DC output circuit, the thyristor rectifier performs current cutoff or current suppression operation, and the thyristor When the current in the thyristor or disconnector falls below a predetermined value, the thyristor or disconnector can be operated to quickly disconnect, thereby reducing the disconnection current in the thyristor or disconnector in the DC output circuit. It is small and the commutation circuit is small. Therefore, when there are many feeding circuits, such as in a railway substation, and each uses a thyristor or disconnector, the total installed capacity of the commutation circuits is greatly reduced.
The effects of the present invention are significant. In addition, when the inductance of the circuit to be interrupted is large, if the current is interrupted only by a thyristor rectifier, the current attenuates significantly at the beginning, but it takes a considerable amount of time for the current to become zero after that. However, according to the present invention, in addition to the current interruption operation of the thyristor rectifier, by using a thyristor breaker and a circuit breaker, the current is interrupted at the point where the current initially attenuates, and the current interruption time is reduced. It is also short.

[Brief explanation of the drawing]

Figures 1a and 1b are circuit diagrams when the conventional current cutoff method is applied, Figure 2 is a circuit diagram showing an outline of an embodiment of the present invention, and Figure 3 is the same as Figure 2. FIG. 4 is a detailed diagram of the control circuit example shown, FIG. 4 is an operational waveform diagram in an embodiment of the present invention, and FIG. 5 is a diagram showing another embodiment of the present invention. In the figure, 1...thyristor rectifier, 2...thyristor circuit breaker, 4...CT, 5...control circuit, 7...
Current setting circuit, 8... Comparison circuit, 9... Current setting circuit, 10... Comparison circuit, 12... OR circuit, 13... Self-holding circuit, 14... Control circuit, 15... AND circuit, and the same symbols in the figures are the same or equivalent. Show parts.

Claims (1)

[Claims] 1 having a thyristor rectifier and a thyristor switch or disconnector in the DC output circuit of the thyristor rectifier;
In a DC power supply circuit configured by connecting a set or a plurality of sets of feeding circuits, the current in the thyristor or disconnector is reduced to a predetermined value or less by causing the thyristor rectifier to cut off or suppress the current. 1. A current cutting method for a DC power supply circuit, characterized in that the thyristor or the disconnector is configured to carry out a current cutting operation when the thyristor or the disconnector becomes hot.