JP2006254675A - Electric circuit current limiter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electric circuit current limiter capable of controlling the current value of an electric circuit in a short time through simple construction. <P>SOLUTION: A current limiting circuit 20 connected in series with an electric circuit L limits an output current so that it does not exceed a current limit value corresponding to a control signal input to a control terminal. A control circuit 40 determines a control signal output to the control terminal of the current limiting circuit 20 so that the detection current value M of the electric circuit L, detected through a current detection circuit 30, becomes equal to or lower than a set current value S1, and lowers the current limit value of the current limiting circuit 20. A set current value for normal operation or a set current value for abnormal operation can be set for the set current value S1. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a technique for limiting a current of an electric circuit, in particular, an electric circuit connecting between different AC power systems.

Power transmission system and distribution system for supplying AC power to each customer from the power generation facility, power distribution system for distributing the power received from the distribution system to the customer (hereinafter referred to as “AC power system”) A circuit breaker having an on / off function is provided in the electric circuit connecting between them for system switching, interruption of fault current, and the like.
The circuit breaker is turned on and off by opening and closing metal contacts. For this reason, when the electric circuit is interrupted at the time of failure, an arc is generated between the contacts, and it takes time to complete the interruption.
Therefore, a circuit breaker in which the switch element and the current limiting impedance element are connected in parallel to the circuit breaker, and a circuit breaker in which the switch element and the current limiting impedance element are connected in parallel to the series circuit of the circuit breaker and the commutation device have been proposed. Yes. (See Patent Document 1)
JP 2002-271975 A

The conventional circuit breaker switches on and off the electric circuit by opening and closing the mechanical contact of the circuit breaker. Therefore, when the electric circuit is interrupted while a current having a current value close to the interruption capacity is flowing in the electric circuit, Insulating gas, a current limiting impedance element, etc. for extinguishing the arc generated between the contacts of the circuit breaker are required. For this reason, the configuration is complicated, and it takes time until the fault current is reduced.
Moreover, since the conventional interruption | blocking apparatus has only the function to turn on and off an electric circuit, the usage aspect is limited.
Therefore, the present invention has been made in view of such a point, and the current value of the electric circuit can be controlled in a short time with a simple configuration and can be used in various usage modes. It aims at providing an electric circuit current limiting device.

(First invention)
A first invention of the present invention for solving the above-mentioned problems is an electric circuit current limiting device as described in claim 1.
The present invention provides a current control unit that can change a current limit value, a current detection unit that detects a current value of an alternating current in a circuit, and a first control that outputs a control signal that controls the current limit value of the current limit unit. Means.
The current limiting means has first and second output terminals connected in series to the electric circuit, and a control terminal to which a control signal is input, and between the first output terminal and the second output terminal. Is limited so that the current value of the current flowing through (output current) does not exceed the current limit value corresponding to the control signal input to the control terminal.
Then, the first control means adjusts a control signal output to the control terminal of the current limiting means so as to reduce the current limit value of the current limiting means so that the detected current value is equal to or less than the current set value.
The “electric circuit” used in this specification corresponds to an electric circuit that connects between different AC power systems such as a power transmission system, a power distribution system, and a power receiving / distributing system in a consumer.
The current limiting means is constituted by a current limiting element having first and second output terminals and a control terminal. The number of current limiting elements may be one or plural. When configured by a plurality of current limiting elements, a method of connecting in series or a method of connecting in parallel can be used. In the case where the current limiting means is configured by a plurality of current limiting elements, the first output terminal of the current limiting element connected to one end of the electric circuit and the current limiting element disposed on the other end of the electric circuit The second output terminal corresponds to the first output terminal and the second output terminal of the current limiting means, and the control terminal of each current limiting element corresponds to the control terminal of the current limiting means.
Preferably, the current limiting means preferably connects the current limiting element in reverse series or a series circuit in which a plurality of current limiting elements are directly connected in reverse series, and reverses the withstand voltage diode to the current limiting element. Configured by connecting in parallel. The diode may be connected in antiparallel to each current limiting element, or a series circuit in which a plurality of diodes are connected in series may be connected in antiparallel to the series circuit of current limiting elements. In this case, a common control signal can be output from the first control means to the control terminal of each current limiting element.
Typically, the limiting operation by the current limiting means is such that when the current value of the output current exceeds the current limiting value, the voltage between the first and second output terminals of the current limiting means corresponds to the increase in the current value. By increasing, it means an operation of limiting the current value of the current flowing between the first output terminal and the second output terminal so as not to exceed the current limit value.
As the current limiting element constituting the current limiting means, for example, a semiconductor element such as a gate insulating bipolar transistor (IGBT), a field effect transistor (FET), or a gate turn-off thyristor (GTO) can be used.
The control signal output from the first control means to the control terminal of the current limiting means may be a continuous control signal or a control signal that changes stepwise.
As the “current set value”, various set values can be set. For example, a normal current setting value or an abnormal current setting value can be set. In this case, control is performed so that the current value of the alternating current in the electric circuit does not exceed the normal current setting value or the abnormal current setting value.
(Second invention)
A second invention of the present invention is an electric circuit current limiting device as set forth in claim 2.
In the present invention, the first control means, when the abnormality occurrence condition is not satisfied, when the abnormality occurrence condition is satisfied so that the current detection value is equal to or lower than the normal current setting value, The control signal output to the control terminal of the current limiting means is adjusted so as to reduce the current limiting value of the current limiting means so that the detected current value is equal to or less than the current setting value for abnormal conditions.
Various conditions can be used as the “abnormal condition”. For example, the fact that a detection signal is output from an abnormality detection means such as a ground fault detector can be used as an abnormality occurrence condition. Alternatively, it can be used as an abnormality occurrence condition that the current detection value detected by the current detection means has reached the abnormality detection current set value and that the increase rate of the current detection value is equal to or greater than the set change rate.
As the current setting value for normal time, for example, a value for setting the current value of the electric circuit to be equal to or lower than the continuous allowable current value (normal current limit current value) of the electric circuit is set.
As the abnormal current setting value, for example, a value (abnormal current limit current value) for preventing damage to facilities connected to the electric circuit or the power system is set. “0” can also be set as the current setting value for abnormality.
(Third invention)
A third aspect of the present invention is a circuit current limiting device as set forth in claim 3.
In the present invention, a circuit breaker connected in series with the current limiting means is provided, and the circuit breaker breaking current value is used as the current setting value for abnormal conditions.
As the “breaker current value of the circuit breaker”, for example, the rated current value of the circuit breaker can be used.
Although the alternating current flowing through the electric circuit can be interrupted by the current limiting unit, a configuration in which a series circuit of a circuit breaker and a current limiting unit is connected to the electric circuit may be used. The present invention can be suitably used in such a case.
(Fourth invention)
A fourth aspect of the present invention is an electric circuit current limiting device as set forth in the fourth aspect.
The present invention includes switch means connected in parallel with the current limiting means, and second control means for outputting a control signal for controlling the conduction state or non-conduction state of the switch means.
The switch means has first and second output terminals connected in series to the electric circuit and a control terminal to which a control signal is input, and is turned on or off by the second control signal input to the control terminal. It becomes a state.
The second control means outputs a control signal for turning on the switching means when the current limiting means input condition is not satisfied, and the switch means when the current limiting means input condition is satisfied. A control signal for setting the non-conductive state is output to the control terminal of the switch means.
The switch means is constituted by a switch element. The number of switch elements constituting the switch means may be one or plural. When the current limiting means is constituted by a series circuit in which a plurality of current limiting elements are connected in series, the switching elements may be connected in parallel to the current limiting elements, or the switching elements may be connected in series. The circuit may be connected in parallel to a series circuit of current limiting elements. A mode in which a switching element is connected in parallel to each current limiting element constituting the current limiting means and a mode in which a switching element is connected in parallel to each of a plurality of series circuits in which a plurality of current limiting elements are connected in series are also current limiting. It is included in the concept of connecting the switch means in parallel with the means.
As the switch element, an element whose power loss in the conduction state is smaller than the power loss in the conduction state of the current limiting element constituting the current limiting means, for example, a semiconductor element such as a thyristor is used.
As the “current limiting means input condition”, it is possible to use an appropriate condition that enables the switch means to be in a non-conductive state at least when the current limiting operation by the current limiting means is executed. For example, the current detection value has reached the normal current setting value, the current detection value has reached the abnormality detection current setting value, the current detection value has reached a predetermined value, etc. are used as predetermined conditions. Can do.
(Fifth invention)
A fifth aspect of the present invention is a circuit current limiting device as set forth in the fifth aspect.
In the present invention, a circuit current limiting device is provided in a circuit that connects different AC power systems.
(Sixth invention)
A sixth aspect of the present invention is a circuit current limiting device as set forth in the sixth aspect.
In the present invention, the circuit current limiting device is disposed in at least one of the plurality of circuits that connect different AC power systems.
(Seventh invention)
A seventh aspect of the present invention is a circuit current limiting device as set forth in the seventh aspect.
In the present invention, the current limiting means is constituted by a gate insulating bipolar transistor.

Since the electric circuit current limiting device according to the first aspect can be configured by the current limiting means, the current detection means, and the control means, the configuration is simple.
Further, since the current value of the electric circuit can be limited by controlling the current limit value of the current limiting means, the current value of the electric circuit can be controlled in a short time.
Furthermore, since the current value of the electric circuit can be controlled to an arbitrary value by changing the current setting value, it can be used in various modes. For example, by setting the normal current setting value as the current setting value, it is possible to control the current value of the electric circuit in the normal condition so as not to exceed the limit current value of the electric circuit. Alternatively, by setting the current setting value for abnormal time as the current setting value, the current value of the electric circuit at the time of abnormality can be reduced in a short time.
In the electric circuit current limiting device according to the second aspect, the electric current value of the electric circuit is controlled so as to be equal to or less than the normal current setting value at the normal time, and to be equal to or smaller than the abnormal current setting value at the time of abnormality. That is, the control signal of the current limiting means is used so that the current value of the electric circuit does not exceed the continuous allowable current value of the electric circuit at normal times, and the equipment connected to the electric circuit and the power system is prevented at the time of abnormality. Is controlled.
Thereby, the electric circuit current limiting device provided with the function which restricts the electric current value of the electric circuit at the normal time, and the function which controls the electric current value of the electric circuit at the time of abnormality can be obtained.
If the electric circuit current limiting device according to claim 3 is used, the circuit breaker can be operated in a state where the current value of the electric circuit is reduced below the circuit breaker current value. The operation can be performed in a short time.
If the electric circuit current limiting device of Claim 4 is used, the power loss in a current limiting means can be reduced.
If the electric circuit current limiting apparatus of Claim 5 is used, the electric current value between different alternating current power systems can be controlled.
If the electric circuit current limiting device of Claim 6 is used, the electric current value between the some electric circuits which connect different alternating current power systems can be controlled.
If the electric circuit current limiting device of Claim 7 is used, the electric current value of an electric circuit can be controlled easily in a short time.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a schematic configuration diagram when a circuit current limiting device 10 according to the first embodiment of the present invention is disposed in a circuit L connecting different AC power systems A and B. A generator G is connected to the AC power system A.
In this specification, the term “AC power system” means a power transmission system or power distribution system for supplying AC power to each consumer from a power generation facility such as a generator, and AC power received from the power distribution system is a low voltage within the consumer. Includes all power receiving and distribution systems for distributing power to the circuit.
Moreover, although the electric circuit current limiting device of this invention is mainly arrange | positioned in the electric circuit which connects a different alternating current power system, it can also be arrange | positioned in the electric circuit in an alternating current power system.

The circuit current limiting device 10 according to the present embodiment includes a current limiting circuit 20, a current detection circuit 30, a control circuit 40, a current set value output circuit 50, and the like.
The current limiting circuit 20 has a current limiting function that limits the current value of the alternating current flowing through the electric circuit L so as not to exceed the current limiting value. This current limit value can be changed by a control signal.
FIG. 2 shows the configuration of one phase of the circuit current limiting device 10 of the present embodiment.
In addition, when the alternating current of the electric circuit L is multiphase, the electric circuit current limiting device shown in FIG. 2 is provided in each phase. At this time, when it is not necessary to individually limit the current value of the electric circuit for each phase, the current detection circuit 30, the control circuit 40, and the current set value output circuit 50 may be shared by each phase.
The current limiting circuit 20 is configured by a current limiting element. Current limiting elements constituting the current limiting circuit 20 include a gate insulated bipolar transistor (referred to as “IGBT”), a gate turn-off thyristor (referred to as “GTO thyristor”), and an electric field. A semiconductor element such as an effect transistor (Metal Oxide Semiconductor Field Effect Transistor) (referred to as “MOSFET”) can be used.
In the present embodiment, an IGBT which is a bipolar transistor in which a MOSFET is incorporated in a gate portion is used as a current limiting element. Since IGBT is publicly known, detailed description of the structure and the like is omitted here.

The current limiting circuit 20 shown in FIG. 2 corresponds to an alternating current by connecting two IGBTs 21 and 22 in anti-series and by connecting anti-voltage diodes 25 and 26 in anti-parallel to the IGBTs 21 and 22, respectively. I am letting.
That is, the IGBTs 21 and 22 shown in FIG. 2 have a collector terminal C that is a positive terminal, an emitter terminal E that is a negative terminal, and a gate terminal G that is a control terminal, and a direction from the collector terminal C to the emitter terminal E. A current can be passed in the (energization direction). The current value of the current flowing through the collector terminal C and the emitter terminal E is limited so as not to exceed the current limit value corresponding to the gate voltage input to the gate terminal G. One of the collector terminal C and the emitter terminal E forms a first output terminal of the IGBT, and the other forms a second output terminal of the IGBT.
The IGBTs 21 and 22 are connected in series (connected in reverse series) so that the energization direction is reversed by connecting the emitter terminals E to each other.
The collector terminal C of the IGBT 21 is connected to one output terminal 20 a of the current limiting circuit 20, and the collector terminal C of the IGBT 22 is connected to the other output terminal 20 b of the current limiting circuit 20.
The diodes 25 and 26 are connected in parallel (connected in reverse parallel) to the IGBTs 21 and 22 so that the energization direction is opposite to the energization direction of the IGBTs 21 and 22.
Furthermore, the gate terminals G of the IGBTs 21 and 22 are connected to the control terminals 20 c and 20 d of the current limiting circuit 20. A gate voltage (control signal) is input from the control circuit 40 to the control terminals 20c and 20d. When the current limiting circuit 20 shown in FIG. 2 is used, the same gate voltage (control signal) can be output from the control circuit 40 to the control terminals 20c and 20d (hence, the gate terminals G of the IGBTs 21 and 22).
In the current limiting circuit 20 shown in FIG. 2, when the polarity of the alternating current is positive on the output terminal 20 b side and negative on the output terminal 20 a side, a current flows in the x1 direction via the IGBT 22 and the diode 25. On the other hand, when the polarity of the alternating current is positive on the output terminal 20a side and negative on the output terminal 20b side, a current flows in the x2 direction via the IGBT 21 and the diode 26. Thus, since the alternating current having the opposite polarity to the energizing direction of the IGBTs 21 and 22 flows through the diodes 25 and 26, the withstand voltage characteristics of the IGBTs 21 and 22 are improved.

As a method of connecting the IGBTs 21 and 22 in anti-series, a method of connecting the collector terminals C of the IGBTs 21 and 22 can also be used.
Moreover, although the IGBT in which the output current flows in the direction from the collector terminal to the emitter terminal is used, the IGBT in which the output current flows in the direction from the emitter terminal to the collector terminal can also be used.

The current limiting circuit 20 shown in FIG. 2 uses one IGBT 21 and 22 for each direction of the alternating current. Here, the rated voltage or rated current of the IGBT may be lower than the rated voltage or rated current of the electric circuit L. In such a case, a method of connecting a plurality of IGBTs in series or a method of connecting them in parallel is used.
FIG. 3 shows the configuration of one phase of the circuit current limiting device of the second embodiment provided with a current limiting circuit using a plurality of IGBTs for each direction of the alternating current. In addition, when the alternating current of the electric circuit L is multiphase, the electric circuit current limiting device shown in FIG. 3 is provided in each phase.
In FIG. 3, the current detection circuit 30, the control circuit 40, and the current set value output circuit 50 have the same configuration as that of the first embodiment, and only the current limiting circuit 120 is different from the configuration of the first embodiment. Yes.

3 includes a series circuit (hereinafter referred to as “series circuit 121”) in which n (where n is an arbitrary positive integer) IGBTs 121a to 121n connected in series, and n IGBTs 122a to 122n. A series circuit connected in series (hereinafter referred to as “series circuit 122”) is connected in anti-series and diodes 125a to 125n and 126a to 126n are connected in reverse parallel to the IGBTs 121a to 121n and 122a to 122n, respectively. Corresponds to AC current. As the IGBTs 121a to 121n and 122a to 122n, the same IGBTs as the IGBTs 21 and 22 of the first embodiment are used.
That is, the series circuit 121 is formed by sequentially connecting the IGBTs 121a to 121n to the emitter terminal E which is the negative terminal of the adjacent IGBT and the collector terminal C which is the positive terminal. Further, the series circuit 122 is formed by sequentially connecting the IGBT 122a to the IGBT 122n to the collector terminal C which is a positive terminal of the adjacent IGBT and the emitter terminal E which is a negative terminal. And the collector terminal C which is the positive electrode terminal of IGBT121a arrange | positioned at the one side edge part of the series circuit 121 is connected to one output terminal 120a of the current limiting circuit 20, and is arrange | positioned at the other side edge part of the series circuit 121. The emitter terminal E, which is the negative terminal of the IGBT 121n, is connected to the emitter terminal E, which is the negative terminal of the IGBT 122a, arranged at one end of the series circuit 122, and is arranged at the other end of the series circuit 122. By connecting the collector terminal C, which is the positive terminal of the IGBT 122n, to the other output terminal 120b of the current limiting circuit 20, the series circuits 121 and 122 are connected in series so that the energization direction is reversed (connected in reverse series). )is doing.
Also, the diodes 125a to 125n and 126a to 126n are connected in parallel to the IGBTs 121a to 121n and the IGBTs 122a to 122n (connected in reverse parallel) so that the energization direction is opposite to the energization direction of the IGBTs 121a to 121n and IGBTs 122a to 122n. )is doing.
Furthermore, the gate terminals G of the IGBTs 121a to 121n and IGBTs 122a to 122n are connected to the control terminals 120c1 to 120cn and 120d1 to 120dn of the current limiting circuit 120. A gate voltage (control signal) is input from the control circuit 40 to the control terminals 120c1 to 120cn and 120d1 to 120dn. When the current limiting circuit 120 shown in FIG. 3 is used, the same gate voltage (control signal) is applied from the control circuit 40 to each control terminal (and hence the gate terminal G of each IGBT) as in the first embodiment. Can be output.
In the current limiting circuit 120 shown in FIG. 3, when the polarity of the alternating current is positive on the output terminal 120b side and negative on the output terminal 120a side, current flows in the x1 direction via the IGBTs 122a to 122n and the diodes 125a to 125n. . On the other hand, when the polarity of the alternating current is positive on the output terminal 120a side and negative on the output terminal 120b side, current flows in the x2 direction via the IGBTs 121a to 121n and the diodes 126a to 126n.

As a method of connecting the series circuits 121 and 122 in anti-series, a method of connecting the collector terminals C of the IGBTs 121a and 122n can also be used.
Moreover, although the IGBT in which the output current flows in the direction from the collector terminal to the emitter terminal is used, the IGBT in which the output current flows in the direction from the emitter terminal to the collector terminal can also be used.
In addition, the diodes 125a to 125n and 126a to 126 are connected in antiparallel to the IGBTs 121a to 121n and 122a to 122n, respectively, but a series circuit (hereinafter referred to as “series circuit 125”) and a diode in which the diodes 125a to 125n are connected in series. A series circuit in which 126a to 126n are connected in series (hereinafter referred to as a series circuit “126”) may be connected in antiparallel to the series circuits 121 and 122, respectively.
A parallel circuit in which a plurality of IGBTs are connected in parallel can also be used.

The second embodiment shown in FIG. 3 is an anti-parallel circuit of the current limiting element 21 and the withstand voltage diode 25 and the current limiting element 22 and the withstand voltage diode of the first embodiment shown in FIG. In place of the anti-parallel circuit 26, n anti-parallel circuits (an anti-parallel circuit of a current limiting element 121a and a withstand voltage diode 125a to a parallel circuit of a current limiting element 121n and a withstand voltage diode 125n, The only difference is that a circuit in which an antiparallel circuit of a current limiting element 122a and a withstand voltage diode 126a to an antiparallel circuit of a current limiting element 122n and a withstand voltage diode 126n is connected in series is used. The operations of the control circuit and the current limiting circuit are the same as those in the first embodiment. For this reason, for the sake of simplicity, the operation of the first embodiment shown in FIG. 2 will be described below.
First, the voltage-current characteristics of the IGBT are shown in FIG.
Note that the voltage-current characteristics when a plurality of IGBTs are connected in series or in parallel are the same as those in FIG. 4 except that the current values and voltage values are different.
The horizontal axis of FIG. 4 shows the output current of the IGBT (current flowing through the collector terminal C and the emitter terminal E) (A), and the vertical axis shows the voltage between the emitter and collector of the IGBT (between the emitter terminal E and the collector terminal C). (V) between the output terminals. Further, in FIG. 4, respectively to the gate terminal G of the _{IGBT [0V] (V GE =} 0V), [8V] (V GE = 8V), [10V] (V GE = 10V), [20V] (V GE A characteristic curve is shown when a gate voltage V _GE (voltage between the gate terminal G and the emitter terminal E) of = 20 V) is supplied.
As can be understood from FIG. 4, when the gate voltage [20V] (V _GE = 20V) is supplied to the gate terminal G of the IGBT, the output current of the IGBT flows in the range of [0A] to [1800A]. Does not flow over [1800A].
Further, when the gate voltage [10V] (V _GE = 10V) is supplied to the gate terminal G of the IGBT, the output current of the IGBT flows in the range of [0A] to [1500A], but not less than [1500A]. Not flowing.
Further, when the gate voltage [8V] (V _GE = 8V) is supplied to the gate terminal G of the IGBT, the output current of the IGBT flows in the range of [0A] to [300A], but not less than [300A]. Not flowing.
When a gate voltage [0V] (V _GE = 0V) is supplied to the gate terminal G of the IGBT, the output current of the IGBT is [0A].
Thus, in the IGBT, when the current value of the output current exceeds the current limit value corresponding to the gate voltage, the emitter-collector voltage (voltage between the output terminals) increases according to the current value, and the current value of the output current is Limiting operation is performed so as not to exceed the current limit value.

The current detection circuit 30 detects the current value of the alternating current flowing through the electric circuit L and outputs the current detection value M to the control circuit 40.
Based on the current detection value M detected by the current detection circuit 30 and the current setting value S1 of the current setting value output circuit 50, the control circuit 40 determines the current limiting circuit 20 (specifically, each IGBT 21 constituting the current limiting circuit 20). , 22 to determine the gate voltage (control signal) output to the gate terminal G).
As the current set value S1, a normal current set value or an abnormal current set value is set. As the current setting value for normal time, for example, a value corresponding to the continuous allowable current value of the electric circuit L in normal time is set. As the current setting value for abnormal time, for example, a value for preventing damage to equipment connected to the electric circuit or the AC power system is set at the time of abnormality.
Then, the control circuit 40 compares the current detection value M with the current setting value S1, and determines whether or not the current detection value M has reached the current setting value S1.
If the current detection value M does not exceed the current set value S1, the currently output gate voltage (control signal) is output as it is.
On the other hand, when the current detection value M exceeds the current setting value S1, the gate voltage (control signal) is determined so that the current detection value M is equal to or less than the current setting value S1. Output to. For example, a gate voltage smaller than the currently output gate voltage is determined and output so that the current limit value of the current limit circuit 20 is smaller than the current limit value corresponding to the currently output gate voltage. Even if the gate voltage is changed, if the current detection value M exceeds the current setting value S1, a smaller gate voltage is determined and output.
As described above, the control circuit 40 controls the current limit circuit so that the current detection value M of the electric circuit L detected by the current detection circuit 30 is equal to or less than the current set value S1 output from the current set value output circuit 50. The gate voltage output to the gate terminal 20 (control signal output to the control terminal) is adjusted to reduce the current limit value of the current limit circuit 20.
As the current set value output circuit 50, for example, a storage circuit accessible by the control circuit 40 is used. Of course, the current set value can also be input from the outside via a communication line or the like.

In the first embodiment (or the second embodiment), the electric circuit L corresponds to the “electric circuit” of the present invention, and the current limiting circuit 20 (or 120) corresponds to the “current limiting means” of the present invention. One of the output terminals 20a and 20b of the limiting circuit 20 (or the output terminals 120a and 120b of the current limiting circuit 120) is the "first output terminal of the current limiting means" of the present invention, and the other is the "current limiting means of the present invention. The control terminals 20c and 20d (or the control terminals 120c1 to 120cn and 120d1 to 120dn) correspond to the “control terminal of the current limiting means” of the present invention, and the current detection circuit 30 corresponds to the “second output terminal”. Corresponding to the “current detection means” of the invention, the control circuit 40 corresponds to the “first control means” of the invention.
The current setting value S1 corresponds to the “current setting value” of the present invention, and the IGBTs 21 and 22 (or IGBTs 121a to 121n and 122a to 122n) correspond to the “current limiting element” of the present invention.

Next, the operation of the first embodiment will be specifically described.
Here, as a factor which the electric current value of the electric circuit which connects a different alternating current power system increases, the case where the electric power supply-and-demand balance in each alternating current power system has collapsed, or the case where the fault electric current by a failure has flowed are considered.
If the current value of the circuit increases due to the imbalance between supply and demand of each AC power system, control is performed so that the current value of the circuit does not exceed the limit current value (for example, continuous permissible current value) at normal times. There is a need to. Here, as a method of controlling the current value of the electric circuit so as not to exceed the limit current value, a method of suppressing the current value of the electric circuit and diverting the current to the electric circuit having a margin can be used.
Also, if a fault current is flowing through the circuit, immediately reduce the current value of the circuit, substantially cut off the circuit (preferably, cut off the circuit at the zero current point), The impact needs to be minimized.

The operation when the current value of the electric circuit L is limited to the normal current setting value or less according to the first embodiment shown in FIG. 1 will be described with reference to FIG. 5 (see “Normal Current Control Curve”). ).
Note that FIG. 5 shows a change state (normal current control curve) of the circuit current (current value of the circuit L) when the present embodiment is used for current control in a normal state, and the present embodiment is in an abnormal state. It is the graph showing the change state (current control curve at the time of abnormality) of the circuit current at the time of using for current control in.
Now, a case where the current value of the electric circuit L in a normal state is limited to the continuous allowable current value 1500A of the electric circuit L will be described. In this case, the current set value output circuit 50 is set with a normal current set value 1500A as the current set value S1.
Further, as shown in FIG. 5, the control circuit 40 applies a gate voltage (control) corresponding to the current limit value 1800A to the control terminal of the current limit circuit 20 (the gate terminals G of the IGBTs 21 and 22 constituting the current limit circuit 20). Signal) V _GE = 20V is output.
In this state, when the current value of the electric circuit L increases and the current detection value M detected by the current detection circuit 30 reaches the current set value S1 = 1500A at the time point x1, the control circuit 40 determines the current value of the electric circuit L. The gate voltage (control signal) is determined so that the current becomes 1500 A or less.
In this case, the control circuit 40 determines the gate voltage V _GE = 10V corresponding to the current limit value 1500A from the voltage-current characteristic diagram of the IGBT shown in FIG.
When the current detection value M of the electric circuit L reaches the current set value S1 again in a state where the gate voltage V _GE = 10V is determined, a smaller gate voltage is determined.
As described above, normal current control is performed by adjusting the gate voltage (control signal) of the IGBT so that the current value of the electric circuit L does not exceed the normal current setting value S1.

Next, according to the first embodiment shown in FIG. 1, the operation in the case where the current value of the electric circuit L is limited to the current setting value for abnormal time or less (current limiting) at the time of abnormality is shown in FIG. (Refer to “Current control curve at the time of abnormality”).
Now, a case will be described in which it is determined that an abnormality has occurred when the current value of the electric circuit L reaches 1700A, and the current value of the electric circuit L is decreased to 300A. In this case, the current setting value output circuit 50 is set with the abnormality current setting value 300A as the current setting value S1.
Similarly to the above, it is assumed that the control circuit 40 outputs the gate voltage V _GE = 20V corresponding to the current limit value 1800A to the control terminal of the current limit circuit 20.
In this state, when a failure occurs and the current detection value M detected by the current detection circuit 30 reaches the current set value S1 = 1700A at the time point x2, the control circuit 40 determines that the current value of the electric circuit L is 300A or less. The gate voltage (control signal) is determined so that
In this case, the control circuit 40 determines the gate voltage V _GE = 8V corresponding to the current limit value 300A from the voltage-current characteristic diagram of the IGBT shown in FIG. Thereby, the current value of the electric circuit L is suppressed (current-limited) to the limiting current value 300A corresponding to the gate voltage V _GB = 8V.
In FIG. 5, after the current value of the electric circuit L is suppressed to 300 A, the gate voltage V _GE = 0 V is output from the control circuit 40 to the control terminal of the current limiting circuit 20. Thereby, the current value of the electric circuit L is suppressed (current-limited) to 0A.
As described above, current control of the electric circuit L at the time of abnormality is performed.
Note that the gate voltage V _GE = 0 V can be output from the control circuit 40 to the control terminal of the current limiting circuit 20 at the time point x2 by setting the current set value S1 to “0” A.

In the first and second embodiments, since a current limiting circuit configured by a semiconductor element such as an IGBT having a current limiting function is used, the operation of controlling the current value of the electric circuit L is fast. In particular, at the time of abnormality, the current value of the electric circuit L can be quickly reduced, so that damage to the equipment connected to the electric circuit and the power system can be reliably prevented.
Further, by changing the current set value, it can be used in various modes such as normal current control and abnormal current control.

In the first and second embodiments, after the gate voltage is lowered (after the current limit value is lowered), the control circuit 40 sets the gate voltage to a higher value (the current control signal). Processing for determining a control signal corresponding to a current limit value higher than the corresponding current limit value is not performed. The process for returning the gate voltage set by the current control (the process for increasing the gate voltage) is configured to be executed by the control circuit 40 when an operator performs a predetermined operation (for example, a reset operation). .
In the first and second embodiments, the gate voltage (control signal) is changed stepwise, but may be changed continuously.

In the first and second embodiments, either the normal current control or the abnormal current control is performed by the circuit current limiting device, but the normal current control and the abnormal current control are performed. You can also
A circuit for one phase of the circuit current control device according to the third embodiment configured to perform normal current control and abnormal current control will be described with reference to FIG.
Similarly to the first and second embodiments, the circuit current limiting device 210 according to the third embodiment is disposed in a circuit L that connects different power systems A and B.
The circuit current limiter 210 includes a current limit circuit 220, a current detection circuit 230, a control circuit 240, a first current set value output circuit 250, a second current set value output circuit 260, and the like. In FIG. 6, the circuit breaker 200 is provided in the electric circuit L.
This embodiment can be suitably used for an existing electric circuit in which a circuit breaker is provided.

The current limiting circuit 220 is composed of an IGBT, like the current limiting circuits 20 and 120. The current detection circuit 230 detects the current value of the electric circuit L and outputs the current detection value M to the control circuit 240.
The first current set value output circuit 250 and the second current set value output circuit 260 output the first current set value S5 and the second current set value S6, respectively. The first current setting value S5 is a normal current setting value, for example, a value corresponding to the continuous allowable current value of the electric circuit L in the normal time is set. The second current setting value S6 is an abnormal current setting value, and the current value of the electric circuit L when the abnormality occurs is set. In the present embodiment, the breaking current value (rated current value) of the circuit breaker 200 is used as the second current setting value S6.
The control circuit 240 normally outputs a gate voltage (to be output to the control terminal of the current limiting circuit 220) such that the current detection value M of the electric circuit L detected by the current detection circuit 230 is equal to or lower than the first current set value S5. Control signal). Further, when an abnormality occurs, a gate voltage (control signal) output to the control terminal of the current limiting circuit 220 so that the current detection value M of the electric circuit L detected by the current detection circuit 230 is equal to or less than the second current set value S6. ).
In the present embodiment, the control circuit 240 determines that no abnormality has occurred if the current detection value M is equal to or less than the abnormality detection current set value (determination that the current state is the normal state), and the current detection value M Exceeds the current setting value for abnormality detection, it is determined that an abnormality has occurred.

In the present embodiment, the current limiting circuit 220 corresponds to the “current limiting unit” of the present invention, the current detection circuit 230 corresponds to the “current detecting unit” of the present invention, and the control circuit 240 corresponds to the “first” of the present invention. Corresponds to “control means”.
The first current setting value S5 corresponds to the “normal current setting value” of the present invention, and the second current setting value S6 corresponds to the “abnormal current setting value” of the present invention.

The operation of the third embodiment shown in FIG. 6 will be described.
The control circuit 240 determines that no abnormality has occurred when the current detection value M is equal to or less than the abnormality detection current setting value (usually greater than the first current setting value S5).
In this state, when the current detection value M exceeds the first current setting value S5 (current setting value S1 in FIG. 5), the control circuit 240 causes the current detection value M to be equal to or less than the first current setting value S5. Thus, the gate voltage of the current limiting circuit 120 is determined. The operation in this case is similar to the above-described normal current control.

Next, the operation when an abnormality occurs will be described with reference to FIGS. 5 and 6 by taking as an example the case where the operation is applied to a power subordinate system.
Here, as the second current setting value S6, an abnormal current setting value = 300A corresponding to the breaking current value of the circuit breaker 200 is set, and the control circuit 240 indicates that the current detection value M of the electric circuit L is for abnormality detection. When the current set value is exceeded, the gate voltage (control) that is output to the control terminal of the current limiting circuit 220 so that the current value of the line L becomes equal to or less than the second current set value S6 corresponding to the cut-off current value of the circuit breaker 200. Signal).
Similarly to the above, it is assumed that the control circuit 240 outputs a gate voltage corresponding to the current limit value 1800A to the control terminal of the current limit circuit 220. That is, it is assumed that the gate voltage V _GE = 20V is supplied to the gate terminal G of the IGBT constituting the current limiting circuit 220.

In this state, a fault current flows in the electric circuit L, and when the current detection value M detected by the current detection circuit 230 exceeds the current detection value for abnormality detection = 1700A (current setting value S2 in FIG. 5) at time x2. The control circuit 240 uses a current limiting circuit so that the current detection value M of the electric circuit L is equal to or less than the second current setting value (current setting value for abnormality) S6 = 300 A (current setting value S3 in FIG. 5). The gate voltage output to the control terminal 220 is determined.
In this case, the gate voltage V _GE = 8V corresponding to the current limit value 300A is determined from the voltage-current characteristic diagram shown in FIG.
Of course, even if the gate voltage V _GE = 8V is determined, if the current detection value M of the electric circuit L does not become the second current set value S6 = 300 A or less, a smaller gate voltage is determined.
Then, after the current detection value M reaches the second current set value S6 = 300A, the control circuit 240 outputs a cutoff operation instruction signal to the circuit breaker 200, and the current detection value M (current instantaneous value) is “ At the time when “0” is reached, the gate voltage V _GB is set to 0 V, and this is maintained. Thereby, the electric current value (instantaneous value) of the electric circuit L is hold | maintained at "0" after the time of becoming "0".
Here, the circuit breaker 200 has a delay time from the output of the shutoff operation instruction signal until the shutoff operation is performed. During this delay time, the gate voltage of the current limiting circuit 220 is set to “0” by the control circuit 240. Set and maintained. For this reason, when the circuit breaker 200 performs the circuit breaking operation, the current value of the electric circuit L is suppressed to “0” (current limiting), and the circuit breaker 200 interrupts the electric circuit L in a short time. Note that the cutoff operation instruction signal may be output after the gate voltage is set to 0V.

In the third embodiment, the control circuit 240 is normally connected to the control terminal of the current limiting circuit 220 so that the current detection value M is equal to or lower than the first current setting value (normal current setting value) S5. The output gate voltage (control signal) is determined. Further, when the current detection value M exceeds the abnormality detection current setting value, the control circuit 240 determines that an abnormality has occurred, and the current detection value M is set to the second current setting value (current setting for abnormality). Value) The gate voltage (control signal) output to the control terminal of the current limiting circuit 220 is determined so as to be equal to or less than S6, and the circuit is cut off.
Thereby, the current control of the electric circuit L at the normal time and the current control (current limiting control) of the electric circuit L at the time of abnormality can be performed by one electric circuit current limiting device.

In the third embodiment, since the circuit breaker 200 is disposed in the electric circuit L, the breaking current value of the circuit breaker 200 is used as the second current setting value (abnormal current setting value). However, various values other than the breaking current value of the circuit breaker 200 can be used as the second current set value.
Further, the circuit breaker 200 can be omitted. In this case, the control circuit 240 determines the gate voltage (control signal) to be output to the control terminal of the current limiting circuit 220 so that, for example, the current detection value M becomes “0” when an abnormality occurs.

By the way, the IGBT has a large voltage drop during conduction. For this reason, when a current limiting circuit is configured by connecting a plurality of IGBTs in series or in parallel, the power loss of the current limiting circuit increases.
Therefore, a fourth embodiment that can reduce the power loss of the current limiting circuit will be described with reference to FIG.
Similarly to the first and second embodiments, the circuit current limiting device 310 according to the fourth embodiment is disposed in a circuit L that connects different power systems A and B.
The electric circuit current limiting device 310 includes a current limiting circuit 320, a current detection circuit 330, a first control circuit 340, a current set value output circuit 350, a switch circuit 360, a second control circuit 370, and the like. The switch circuit 360 is connected to the current limiting circuit 320 in parallel.
The current limiting circuit 320 is composed of an IGBT as in the first or second embodiment. The current detection circuit 330 detects the current value of the electric circuit L and outputs the current detection value M to the first control circuit 340.
The current set value output circuit 350 outputs a current set value S1. As the current set value S1, a normal current set value or an abnormal current set value can be set as in the first or second embodiment.
The first control circuit 340 outputs a gate voltage (control signal) output to the control terminal of the current limiting circuit 320 so that the current detection value M of the electric circuit L detected by the current detection circuit 330 is equal to or less than the current setting value S1. To decide. The control circuit 340 can have the same configuration as the control circuit 40 of the first or second embodiment or the control circuit 240 of the third embodiment.

The switch circuit 360 connected in parallel to the current limiting circuit 320 is turned on or off by a control signal output from the second control circuit 370.
The second control circuit 370 outputs, to the control terminal of the switch circuit 360, a control signal that makes the switch circuit 360 conductive when the current limiting circuit input condition is not satisfied. On the other hand, if the current limiting circuit input condition is satisfied, a control signal for turning off the switch circuit 360 is output to the control terminal of the switch circuit 360.
As conditions for turning on the current limiting circuit, various conditions that can make the switch circuit 360 non-conductive so as not to affect the current limiting operation of the current value of the electric circuit L by the current limiting circuit 320 can be used.
For example, when the normal current setting value is set as the current setting value S1, the current limit circuit is turned on when the current detection value M detected by the current detection circuit 330 has reached the normal current setting value. It can be used as a condition.
When the current setting value for abnormality is set as the current setting value S1, the current detection value M detected by the current detection circuit 330 exceeds the current detection value for abnormality detection, and the failure detection circuit The fact that a failure detection signal has been output or the like can be used as a current limiting circuit input condition. Note that the current detection value M detected by the current detection circuit 330 is used for abnormality detection so that the current limit circuit 320 can quickly suppress (current limit) the current value of the electric circuit L when an abnormality occurs. It is preferable to use a current limit circuit input condition that a current set value smaller than the current set value is exceeded.
In addition, when the normal current setting value and the abnormal current setting value are set as the current setting values, the current detection value M detected by the current detection circuit 330 exceeds the normal current setting value. This can be used as the current limiting circuit input condition.

A one-phase configuration of the present embodiment is shown in FIG.
As in the second embodiment, the current limiting circuit 320 includes a series circuit (hereinafter referred to as a series circuit “321”) in which n (n is an arbitrary positive integer) IGBTs 321a to 321n are connected in series. A series circuit in which n IGBTs 322a to 322n are connected in series (hereinafter referred to as a series circuit “322”) is connected in reverse series, and withstand voltage diodes 325a to 325n and 326a to 326n are IGBTs 321a to 321n, 322a to It is configured by connecting to 322n in antiparallel. The collector terminal C of the IGBT 321a is connected to one output terminal 320a of the current limiting circuit, the collector terminal C of the IGBT 322n is connected to the other output terminal 320b of the current limiting circuit 320, and the gates of the IGBTs 321a to 321n and 322a to 322n. The terminals are connected to the control terminals 320c1 to 320cn and 320d1 to 320dn of the current limiting circuit 320.

The switch circuit 360 includes a switch element having a first output terminal, a second output terminal, and a control terminal to which a control signal is input. The switch circuit 360 can be composed of a single switch element or a plurality of switch elements.
As the switch element, an element whose power loss during conduction is smaller than that of the current limit element constituting the current limit circuit 320 is used.
In this embodiment, a thyristor is used as the switch element. The voltage between the output terminals of the thyristor (voltage drop due to resistance between the anode terminal as the positive terminal and the cathode terminal as the negative terminal when the thyristor is on) is smaller than that of the IGBT as shown by the broken line in FIG. . For this reason, the power loss at the time of conduction of the thyristor is also small.
In the present embodiment, as shown in FIG. 8, the switch circuit 360 includes a series circuit in which n thyristors 361 a to 361 n are connected in series (hereinafter referred to as a series circuit “361”) and n thyristors 362 a to 362 a. It is constituted by a series circuit (hereinafter referred to as a series circuit “362”) in which 362n are connected in series. The series circuit 361 is connected in parallel to the series circuit 321 of the current limiting circuit 320 so that the energization direction is the same direction, and the series circuit 362 is parallel to the series circuit 322 of the current limiting circuit 320 and the energization direction. Are connected in parallel so that they are in the same direction. The gate terminals of the thyristors 361a to 361n and 362a to 362n are connected to the control terminals 320e1 to 320en and 320f1 to 320fn of the current limiting circuit 320. The second control circuit 370 outputs control signals to the control terminals 320e1 to 320en and 320f1 to 320fn, and thus to the gate terminals of the thyristors 361a to 361n and 362a to 362n.

In FIG. 8, only the circuit current limiting device for one phase is shown, but in the case of three phases, the circuit current limiting device shown in FIG. 8 is arranged in each phase.
In the circuit configuration shown in FIG. 8, when the thyristors 361a to 361n and 362a to 362n are turned on when a control signal is input to the gate terminal from the second control circuit 370, most of the current in the electric circuit L is thyristors 361a to 361a. It flows through 361n, 362a-362n and diodes 325a-325n, 326a-326n. That is, when the polarity of the alternating current is positive on the output terminal 320b side and negative on the output terminal 320a side, current flows in the y1 direction through the thyristors 362a to 362n and the diodes 325a to 325n. On the other hand, when the polarity of the alternating current is positive on the output terminal 320a side and negative on the output terminal 320b side, current flows in the y2 direction via the thyristors 361a to 361n and the diodes 326a to 326n.
Thereby, the power loss of IGBTs 321a to 321n and 322a to 322n, and hence the power loss of current limiting circuit 320 can be reduced.
When the input of the control signal from the second control circuit 370 to the gate terminals of the thyristors 361a to 361n and 362a to 362n is stopped, the thyristors 361a to 361n and 362a to 362n are not turned on when the reverse voltage is applied. It becomes a conductive state. In this case, as described above, current flows in the x1 direction or the x2 direction via the IGBTs 321a to 321n, 322a to 322n and the diodes 325a to 325n and 326a to 326n.
Further, the same control signal is output from the second control circuit 370 to the gate terminals of the thyristors 320e1 to 320en and 320f1 to 320fn, but the second control circuit 370 and the gate terminals of the thyristors 320e1 to 320en A separate control signal may be output to the gate terminals of the thyristors 320f1 to 320fn. When such a configuration is used, finer control can be performed.

In the fourth embodiment, when it is not necessary to control the current value of the electric circuit L by the current limiting circuit 320 (when the current limiting circuit input condition is not satisfied), the current limiting circuit 320 is connected in parallel with the current limiting circuit. By making the switch circuit (specifically, the switch element connected in parallel with the current limiting element) conductive, the power loss of the current limiting circuit can be reduced.
On the other hand, when it is necessary to control the current value of the electric circuit L by the current limiting circuit 320 (when the current limiting circuit injection condition is satisfied), the switch circuit (specifically, connected in parallel to the current limiting element). The current limiting operation by the current limiting circuit 320 can be executed by turning off the switching element).
Note that the first control circuit 340 and the second control circuit 370 may be configured by separate control circuits, or may be configured by the same control circuit.
In addition, when the switch circuit 360 is controlled to be in the conductive state by the second control circuit 370, the output of the gate voltage from the first control circuit 340 to the control terminal of the current limiting circuit 320 may be stopped. From the viewpoint of shortening the operation time of the current limiting circuit 320, the first control circuit 340 is operated to output the gate voltage from the first control circuit to the control terminal of the current limiting circuit. preferable.

In the above embodiments, different AC power systems are connected by connecting different AC power systems (for example, AC power system A and AC power system B) with one electric circuit, and an electric current limiting device is provided in this electric circuit. However, it is also possible to connect different AC power systems with a plurality of electric circuits and to arrange the electric circuit current limiting device in any one of the electric circuits.
For example, as shown in FIG. 9, two different AC power systems A and B are connected by a first electric circuit L1 and a second electric circuit L2, and an electric circuit current limiting device is disposed in the electric circuit L1.
As described above, when the current value of the electric circuit L1 exceeds the current setting value (for example, the normal current installation value), the electric circuit current control device limits the current so that the electric current value of the electric circuit L1 becomes equal to or less than the current setting value. The gate voltage (control signal) to be output to the control terminal of the circuit is determined. In this case, the current limited by the electric circuit L1 is bypassed to the other electric circuit L2.
Three or more electric circuits may be connected to the AC power system A and the AC power system B. In this case, the electric circuit current limiting device may be disposed in at least one electric circuit.

The present invention is not limited to the configuration described in the embodiment, and various changes, additions, and deletions are possible.
For example, the features of each embodiment described in the first to fourth embodiments may be used alone or in combination by an appropriate method.
Further, the current limiting element constituting the current limiting circuit is not limited to IGBT, MOSFET, and GTO, and various current limiting elements can be used.
Various connection modes can be used as a connection mode for connecting a withstand voltage diode or switch element to the current limiting element.
Moreover, in order to correspond to alternating current, the aspect which connected two current limiting elements in anti-series or the connection aspect which connected two series circuits which connected the several current limiting element in series was used in reverse series was used. Various connection modes other than these can be used. For example, a mode in which two current limiting elements are connected in anti-parallel, two series circuits in which a plurality of current limiting elements are connected in series, or two parallel circuits in which a plurality of current limiting elements are connected in parallel are anti-parallel A connection mode to connect to can be used. In this case, the aforementioned diode can be omitted.
Further, the switch elements constituting the switch circuit are not limited to thyristors, and various switch elements can be used.
Moreover, the current control method at the normal time and the current control method at the time of abnormality are not limited to the methods described in the embodiment, and various control methods can be used.
In addition, the configuration for controlling the current of the electric circuit in the normal state has been described, but the configuration for controlling the electric current of the electric circuit described in the embodiment is provided with a configuration for capturing the voltage of the electric circuit or a configuration for setting the voltage of the electric circuit. It can be configured as a power flow control device that controls the power flow of the electric circuit.
Moreover, the electric circuit current limiting device of the present invention can be disposed in a load in an AC power system.

The present invention can be configured as follows.
For example, “(Aspect 1) The circuit current limiting device according to any one of claims 1 to 7, wherein the current limiting means includes first and second output terminals and a control terminal. First and second current limiting means having at least one current limiting element capable of flowing current in one direction from the second output terminal are connected in anti-series, and the first and second An electric circuit current limiting device characterized in that it is configured by connecting a diode to the current limiting means in antiparallel. "
The first and second current limiting means can be configured by, for example, a series circuit in which a plurality of current limiting elements are connected in series or a parallel circuit in which the current limiting elements are connected in parallel.
In addition, the current limiting unit can be configured, for example, by connecting the first and second current limiting units in series (connected in reverse series) so that the energization direction is reverse.
The diodes may be connected in parallel to the individual current limiting elements. Such a configuration is also included in a configuration in which a diode is connected in parallel to the first and second current limiting means.
If the electric circuit current limiting device of aspect 1 is used, the withstand voltage characteristic of the current limiting element can be enhanced.
Alternatively, “(Aspect 2) is the electric circuit current limiting device according to any one of claims 1 to 7, wherein the current limiting means includes first and second output terminals and a control terminal, The first and second current limiting means having at least one current limiting element capable of flowing a current in one direction from the second output terminal are connected in antiparallel to each other. It can be configured as an electric circuit current limiting device.
In this case, the withstand voltage diode is preferably omitted.
If the electric circuit current limiting device of aspect 2 is used, the circuit configuration is simple.

It is a schematic block diagram of 1st Embodiment applied to the electric circuit which connects between different electric power systems. It is a figure which shows the structure for the one phase of 1st Embodiment. It is a figure which shows the structure for the one phase of 2nd Embodiment. It is a figure which shows the voltage-current characteristic of IGBT (gate insulation type bipolar transistor). It is a figure which shows the change state of the electric circuit current at the time of performing the current control at the time of normality, or the current control at the time of abnormality using 1st or 2nd embodiment. It is a schematic block diagram of 3rd Embodiment. It is a schematic block diagram of 4th Embodiment. It is a figure which shows the structure for the one phase of 4th Embodiment. It is a schematic explanatory drawing at the time of applying to one of the some electric circuit which connects a different alternating current power grid | system.

Explanation of symbols

10, 210, 310 Circuit current limiting device 20, 120, 220, 320 Current limiting circuit 21, 22, 121a-121n, 122a-122n, 321a-321n, 322a-322n IGBT (gate insulation type bipolar transistor) (current limiting element) )
25, 26, 125a to 125n, 126a to 126n, 325a to 325n, 326a to 326n Diode 30, 230, 330 Current detection circuit 40, 240, 340, 370 Control circuit 50, 250, 260, 350 Current set value output circuit 200 Circuit breaker 360 Switch circuit 361a-361n, 362a-362n Thyristor (switch element)

Claims (7)

An electric circuit current limiting device for limiting a current value of an alternating current flowing through an electric circuit,
A first output terminal and a second output terminal connected to the electric circuit; a control terminal to which a control signal is input; and a current value of a current flowing between the first output terminal and the second output terminal. Current limiting means for performing a limiting operation so as not to exceed a current limiting value corresponding to a control signal input to the control terminal;
Current detection means for detecting a current value of an alternating current flowing through the electric circuit;
First control means for outputting a control signal to a control terminal of the current limiting means;
The first control means compares the current detection value detected by the current detection means with a current set value, and connects the current limit value to a control terminal of the current limiting means so that the current detection value is equal to or less than the current set value. Adjusting the output control signal to reduce the current limiting value of the current limiting means;
An electric circuit current limiting device. The circuit current limiting device according to claim 1,
The first control means determines whether or not an abnormality occurrence condition is satisfied, and if the abnormality occurrence condition is not satisfied, the current detection value is set to be equal to or less than a normal current setting value. Adjusting the control signal output to the control terminal of the current limiting means to lower the current limit value of the current limiting means, and when the abnormality occurrence condition is satisfied, the current detection value is set as the current setting for abnormal Adjusting the control signal output to the control terminal of the current limiting means so that the current limiting value of the current limiting means is lowered so as to be equal to or less than the value,
An electric circuit current limiting device. The circuit current limiting device according to claim 1 or 2,
A circuit breaker is arranged in the electric circuit,
As the current setting value for abnormal time, the breaking current value of the breaker is used,
An electric circuit current limiting device. The circuit current limiting device according to any one of claims 1 to 3,
A first output terminal and a second output terminal connected to the electric circuit so as to be in parallel with the current limiting means, a control terminal to which a control signal is input, and conduction by a control signal input to the control terminal Switch means to be in a state or non-conductive state;
Second control means for outputting a control signal to a control terminal of the switch means;
The second control means determines whether or not a current limiting means input condition is satisfied, and if the current limiting means input condition is not satisfied, a control signal for setting the switch means to a conductive state, When the current limiting means input condition is satisfied, a control signal for turning off the switch means is output to the control terminal of the switch means.
An electric circuit current limiting device. The circuit current limiting device according to any one of claims 1 to 4,
The electric circuit is an electric circuit that connects different AC power systems,
An electric circuit current limiting device. The circuit current limiting device according to any one of claims 1 to 5,
The electric circuit is at least one of a plurality of electric circuits that connect different AC power systems.
An electric circuit current limiting device. The circuit current limiting device according to any one of claims 1 to 6,
The current limiting means is composed of a gate insulating bipolar transistor.
An electric circuit current limiting device.

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