JP2014199724A - Undervoltage tripper for circuit breaker and overvoltage/undervoltage tripper - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an undervoltage tripper capable of miniaturizing it and reducing costs, while stabilizing voltage sensitivity and ensuring delay-time characteristics.SOLUTION: An undervoltage tripper for a circuit breaker comprises: a low voltage detection part; a delay-time output part; a switch circuit interrupting an excitation magnetization current supplied to a coil based on an excitation magnetization interruption signals; and an interruption mechanism for interrupting power supply to a load apparatus based on the interruption of the excitation magnetization current for the coil. In the undervoltage tripper for the circuit breaker, the low voltage detection part 19 has a first comparator 21 for outputting a low voltage detection signal Vd by comparing a comparison voltage Vx based on a commercial power supply voltage with a first threshold voltage Vt1, and the delay-time output part 20 has a charge circuit Tr1 for charging a capacitor C2 when the low voltage detection signal Vd is input; a discharge circuit Tr2 for discharging a capacitor C2 when the low voltage detection signal Vd is not output; and a second comparator 24 for outputting an excitation magnetization current interruption signal S2 by comparing a charge potential of the capacitor C2 with a second threshold voltage Vt2.

Description

  The present invention relates to an undervoltage trip device used as an auxiliary device for a circuit breaker of a commercial power source.

  2. Description of the Related Art Conventionally, an undervoltage trip device for a circuit breaker operates to cut off power supply to a load device to which commercial power is supplied when the power voltage of the commercial power falls below a predetermined voltage.

  FIG. 10 shows a conventional example of an undervoltage trip device. The commercial power supply AC is full-wave rectified by the rectifier circuit 1, and an exciting current Ic based on the full-wave rectified voltage Vrec is supplied to the coil 3 wound around the fixed plunger 2. The commercial power supply AC is supplied to the rectifier circuit 1 via a sensitivity adjustment device 4 composed of a capacitor or a resistor, and a large-capacity capacitor is connected between both terminals of the coil 3 as a time delay setting device 5. .

  When the coil 3 is energized, the movable plunger 6 is attracted to the fixed plunger 2, and the movable plunger 6 is urged by a spring 7 in a direction away from the fixed plunger 2. Then, when the movable plunger 6 is pulled away from the fixed plunger 2 by the urging force of the spring 7, the shut-off device 8 is activated to cut off the supply of the power source VL to the load device.

  As shown in FIG. 11, in the undervoltage trip device configured as described above, when the commercial power supply AC is supplied at a substantially normal voltage and the exciting current Ic exceeding the threshold value It flows through the coil 3. The movable plunger 6 continues to be attracted to the fixed plunger 2 against the urging force of the spring 7. In this state, power is supplied to the load device.

  On the other hand, when the voltage of the commercial power supply AC decreases and the exciting current Ic falls below the threshold value It, the movable plunger 6 is pulled away from the fixed plunger 2 by the urging force of the spring 7, and as a result, the operation of the shut-off device 8 causes a load. The power supply to the device is cut off.

  The sensitivity adjusting device 4 is provided for adjusting the voltage of the commercial power supply AC that causes the movable plunger 6 to be separated from the fixed plunger 2. Further, the time delay setting device 5 operates the shut-off device 8 when the movable plunger 6 is separated from the fixed plunger 2 after a predetermined time td has elapsed with the excitation current Ic output from the rectifying circuit 1 being below the threshold value It. Thus, the operations of the movable plunger 6 and the shutoff device 8 are stabilized.

  Patent Documents 1 and 2 disclose a configuration similar to the undervoltage tripping device as described above. Patent Document 3 discloses an undervoltage trip device that allows an exciting current to flow through an exciting coil only when an abnormality occurs.

JP 2003-308775 A JP 2005-135690 A JP 61-124222 A

  In the undervoltage trip device as described above, the commercial power supply voltage when the movable plunger 6 is separated from the fixed plunger 2 depends on the magnetic characteristics of the fixed plunger 2 and the movable plunger 6, the shape of the attracting surface, and the like.

  For this reason, since the required precision is required for mechanical processing such as annealing of the magnetic body for forming the fixed plunger 2 and the movable plunger 6, polishing of the suction surface, and management of the gap of the suction surface, the processing cost is high. To rise.

  In addition, the operation of adjusting the sensitivity of the commercial power supply voltage with respect to the voltage change by the sensitivity adjustment device 4 is complicated, and in order to ensure sufficient time delay characteristics with the time delay setting device 5, a large capacity capacitor is required. Therefore, the size of the apparatus increases and the cost also increases.

  The present invention has been made in view of such circumstances, and an object thereof is to provide an undervoltage trip device capable of reducing the size and reducing the cost while ensuring the stability of the voltage sensitivity and the time delay characteristic. There is to do.

  An undervoltage trip device that solves the above problem includes a low voltage detection unit that compares a commercial power supply voltage with a preset first threshold voltage and outputs a low voltage detection signal; and the low voltage detection When the signal continues for a preset time or more, a time delay output unit that outputs an excitation current cut-off signal, a switch circuit that cuts off the excitation current supplied to the coil based on the excitation current cut-off signal, and the coil In the circuit breaker undervoltage trip device having a shut-off mechanism for shutting off the power supply to the load device based on the cut-off of the excitation current of the low-voltage detector, the low voltage detector is based on a change in the commercial power supply voltage. A first comparator that compares the changing comparison voltage with the first threshold voltage, and the delay output unit is a charging circuit that charges a capacitor when the low voltage detection signal is input; The low voltage When the output signal is not output, the discharge circuit for discharging the charge of the capacitor is compared with the charge potential of the capacitor and a preset second threshold voltage to output the excitation current cutoff signal And a second comparator.

  In the above configuration, the low voltage detection unit calculates an effective value by integrating the commercial power supply voltage, compares the effective value with the first threshold voltage, and outputs a low voltage detection signal. It is preferable to do.

  Further, in the above configuration, the low voltage detection unit integrates the commercial power supply voltage to calculate an average value, compares the average value with the first threshold voltage, and outputs a low voltage detection signal. It is preferable to do.

In the above configuration, it is preferable that the switch circuit includes a transistor that is turned off based on the input of the excitation current cutoff signal to cut off the excitation current.
An overvoltage / undervoltage trip device that solves the above problem generates a low voltage detection signal by comparing a commercial power supply voltage with a preset first threshold voltage, and the low voltage detection signal Compared with the commercial power supply voltage and the preset third threshold voltage, the low voltage detector with a time delay setting that outputs the excitation current cutoff signal when it continues for a preset time or more. A detection signal is generated, and when the overvoltage detection signal continues for a preset time or longer, an overvoltage detection unit with a time delay setting that outputs an excitation current cutoff signal and a coil based on the excitation current cutoff signal are generated. Overvoltage / undervoltage tripping of circuit breakers with a switch circuit that cuts off the excitation current to be supplied and a cut-off mechanism that cuts off the power supply to the load equipment based on the interruption of the excitation current to the coil In the apparatus, the low voltage detector with a time delay setting includes a first comparator that compares a comparison voltage that changes based on a change in the commercial power supply voltage and the first threshold value. A low voltage detection unit; a charging circuit that charges a capacitor when the low voltage detection signal is input; a discharge circuit that discharges the charge of the capacitor when the low voltage detection signal is not output; and And a time delay output unit including a second comparator that compares the charging potential with a preset second threshold voltage and outputs the excitation current cutoff signal.

  Further, in the above configuration, the first threshold voltage is set to a voltage higher than the comparison voltage when the cutoff mechanism stops operating due to a decrease in the excitation current, and an overvoltage detection unit with a time delay setting And it is preferable to set to a voltage higher than the commercial power supply voltage at which the low voltage detector with time delay setting becomes inoperable.

  ADVANTAGE OF THE INVENTION According to this invention, size reduction and cost reduction can be aimed at, stabilizing the voltage sensitivity of an undervoltage trip device, and ensuring a time delay characteristic.

It is a block diagram which shows the undervoltage trip apparatus of one Embodiment. It is a circuit diagram which shows a low voltage detection part and a time delay output part. It is a timing waveform diagram which shows operation | movement of a low voltage detection part and a time delay output part. It is a circuit diagram which shows a switch circuit. It is a block diagram showing an overvoltage / undervoltage trip device. It is a timing waveform diagram showing the operation of the overvoltage / undervoltage trip device. It is a circuit diagram which shows the overvoltage detection part with a time delay time setting. It is explanatory drawing which shows the setting of a threshold voltage. It is a circuit diagram which shows another example of a switch circuit. It is a circuit diagram which shows a prior art example. It is a timing waveform diagram which shows operation | movement of a prior art example.

(First embodiment)
Hereinafter, a first embodiment of an undervoltage trip device will be described with reference to FIGS.
In the undervoltage trip device shown in FIG. 1, the commercial power supply AC is full-wave rectified by the rectifier circuit 11, and the full-wave rectified voltage Vrec is output.

  The full-wave rectified voltage Vrec is supplied to one end of the coil 12 wound around the fixed plunger 14, and the other end of the coil 12 is connected to the switch circuit 13. Further, a capacitor C1 is connected in parallel between both terminals of the coil 12, and the exciting current Ic supplied to the coil 12 is slightly smoothed based on the full-wave rectified voltage Vrec.

  A movable plunger 15 that can be attracted based on the supply of the excitation current Ic is disposed in the vicinity of the fixed plunger 14, and the movable plunger 15 is urged by a spring 16 in a direction away from the fixed plunger 14. When the movable plunger 15 is pulled away from the fixed plunger 14 by the urging force of the spring 16, the shut-off device 17 is activated and the supply of power to the load device is shut off. The switch circuit 13, the fixed plunger 14, the movable plunger 15, and the shut-off device 17 constitute a shut-off mechanism.

  The full-wave rectified voltage Vrec is supplied to the power supply circuit 18, and the power supply circuit 18 generates a DC power supply voltage Vc based on the full-wave rectified voltage Vrec and supplies it to the low voltage detection unit 19 and the time delay output unit 20.

  As shown in FIG. 3, the low voltage detection unit 19 operates based on the supply of the DC power supply voltage Vc. When the full-wave rectified voltage Vrec becomes lower than the threshold voltage Vt1, the low voltage detection unit 19 outputs an H level low voltage detection signal Vd to the time delay output unit 20.

  The time delay output unit 20 generates a time delay signal S1 obtained by integrating the low voltage detection signal Vd. When the time delay signal S1 becomes higher than a preset threshold voltage Vt2, an excitation current cutoff signal is sent to the switch circuit 13. S2 is output. The excitation current cutoff signal S2 is a signal that switches from the H level to the L level when the delay signal S1 becomes higher than the threshold voltage Vt2.

  The switch circuit 13 operates to cut off the excitation current Ic based on the switching of the excitation current cut-off signal S2 from the H level to the L level. When the excitation current Ic is interrupted, the supply of the power source VL to the load device is interrupted by the interrupt mechanism.

  FIG. 4 shows an example of the switch circuit 13. The exciting current cut-off signal S2 is input to the base of the npn transistor Tr3 via the diode D, the collector of the transistor Tr3 is connected to the other end of the capacitor C1 and the coil 12, and the emitter is connected to the ground Vg. .

  Therefore, if the exciting current cut-off signal S2 is at the H level, the transistor Tr3 is turned on and the exciting current Ic is supplied to the coil 12. If the exciting current cut-off signal S2 becomes the L level, the transistor Tr3 is turned off and the exciting current Ic is turned on. Is cut off.

  Next, specific configurations of the low voltage detection unit 19 and the delay output unit 20 will be described with reference to FIG. In the low voltage detector 19, the full-wave rectified voltage Vrec is divided by resistors R1 and R2 connected in series with the ground Vg to generate a comparison voltage Vx, and the comparison voltage Vx and the threshold voltage are generated. The comparator 21 compares Vt1. When the comparison voltage Vx becomes lower than the threshold voltage Vt1, an H-level low voltage detection signal Vd is output from the comparator 21.

  The low voltage detection signal Vd output from the comparator 21 is input to the base of the npn transistor Tr1 of the time delay output unit 20, and is inverted by the inverter circuit 22 and input to the base of the npn transistor Tr2.

  A constant current is supplied from the DC power supply voltage Vc through the constant current source circuit 23 to the collector of the transistor Tr1. The emitter of the transistor Tr1 is connected to the ground Vg via the capacitor C2.

  The emitter of the transistor Tr1 is connected to the collector of the transistor Tr2 and to the negative input terminal of the comparator 24. The emitter of the transistor Tr2 is connected to the ground Vg.

  In the time delay output unit 20 configured as described above, when the low voltage detection signal Vd is at the L level, the transistor Tr1 is turned off and the transistor Tr2 is turned on. Then, the electric charge stored in the capacitor C2 is discharged, and the time delay signal S1 is maintained at the L level.

  On the other hand, when the low voltage detection signal Vd becomes H level, the transistor Tr1 is turned on and the transistor Tr2 is turned off. Then, electric charge is stored in the capacitor C2 due to the collector current of the transistor Tr1, and the potential of the delayed signal S1 rises up to a voltage lower than the DC power supply voltage Vc by the voltage drop between the collector and emitter of the transistor Tr1.

  With such a configuration, the transistor Tr1 operates as a charging circuit that charges the capacitor C2, and the transistor Tr2 operates as a discharging circuit that discharges the charging of the capacitor C2.

  The comparator 24 compares the time delay signal S1 with the threshold voltage Vt2. When the time delay signal S1 becomes higher than the threshold voltage Vt2, the comparator 24 outputs an L level excitation current cutoff signal S2 to the switch circuit 13.

The switch circuit 13 cuts off the connection between the other terminal of the coil 12 and the ground Vg on the basis of the L level excitation current cut-off signal S2 to cut off the excitation current Ic.
Next, the operation of the undervoltage tripping device configured as described above will be described with reference to FIG.

  When the commercial power supply AC is supplied at a normal voltage level, the peak value of the full-wave rectified voltage Vrec exceeds a preset threshold voltage Vt1, and thus the low voltage detection signal output from the low voltage detection unit 19 Vd becomes a pulse-like signal.

  In this state, the transistors Tr1 and Tr2 of the time delay output unit 20 alternately turn on and off, so that the voltage level of the time delay signal S1 does not exceed the threshold voltage Vt2. Then, the exciting current cutoff signal S2 is maintained at the H level, and the exciting current Ic is continuously supplied to the coil 12 by the operation of the switch circuit 13. Therefore, the movable plunger 15 is maintained in the state of being attracted to the fixed plunger 14, and the shut-off device 17 does not operate.

  When the voltage of the commercial power supply AC decreases and the peak value of the full-wave rectified voltage Vrec falls below the threshold voltage Vt1, the low voltage detection signal Vd output from the low voltage detector 19 is maintained at the H level.

  In this state, the transistor Tr1 of the time delay output unit 20 is maintained in the on state and the transistor Tr2 is maintained in the off state, so that charge is stored in the capacitor C2, and the voltage level of the time delay signal S1 increases. Soon, it exceeds the threshold voltage Vt2. Then, the excitation current cut-off signal S2 output from the time delay output unit 20 becomes L level, and the excitation current Ic to the coil 12 is cut off by the operation of the switch circuit 13. As a result, the movable plunger 15 is separated from the fixed plunger 14, and the shut-off device 17 is activated to cut off the supply of the power source VL to the load device.

According to the present embodiment, the following effects can be obtained.
(1) When the voltage level of the commercial power supply AC drops below a predetermined level for a predetermined time or longer, the movable plunger 15 can be pulled away from the fixed plunger 14 to operate the shut-off device 17. Therefore, it is possible to prevent problems caused by operating the load device in a state where the voltage level of the commercial power supply AC is insufficient.
(2) The voltage sensitivity for detecting whether or not the voltage level of the commercial power supply AC is insufficient can be set by the threshold voltage Vt1 input to the comparator 21 by the low voltage detector 19. Therefore, stable voltage sensitivity can be easily set.
(3) The time delay from when the voltage level of the commercial power supply AC drops to an undervoltage until the excitation current cut-off signal S2 for cutting off the excitation current Ic is output is the same as that of the transistor Tr1 of the time delay output unit 20 It can be set by a constant of a time constant circuit constituted by the capacitor C2 and a threshold voltage Vt2. Therefore, since the time delay can be set without using a large-capacity capacitor, the undervoltage trip device can be downsized and the cost can be reduced.
(Second embodiment)
5 to 8 show a second embodiment. This embodiment is an overvoltage that cuts off the supply of the power supply voltage to the load device when the commercial power supply AC becomes an undervoltage similar to the first embodiment and when the commercial power supply AC becomes an overvoltage that is equal to or higher than a preset voltage. -Indicates an undervoltage trip device.

  In the overvoltage / undervoltage trip device shown in FIG. 5, a single-phase two-wire commercial power supply AC is supplied to the power supply circuit 32 and the voltage signal generator 33 via the switching circuit 31. The power supply circuit 32 generates a required DC power supply voltage Vc based on the supply of the commercial power supply AC, and supplies the DC power supply voltage Vc to the overvoltage detection unit 34 with time delay setting and the low voltage detection unit 35 with time delay setting. Supply.

  As shown in FIG. 6, the voltage signal generator 33 generates a full-wave rectified voltage Vrec obtained by full-wave rectification of the commercial power supply AC, and the overvoltage detector 34 with time delay setting and the low voltage detection with time delay setting. To the unit 35.

  The commercial power supply AC is supplied to one end of the coil 36, and the other end of the coil 36 is connected to the ground Vg via the switch circuit 37. If the switch circuit 37 is in a conducting state, the exciting current Ic is supplied to the coil 36.

  The coil 36 is wound around the fixed plunger as in the first embodiment, the movable plunger is attracted based on the supply of the excitation current Ic, and the movable plunger is pulled away from the fixed plunger based on the interruption of the excitation current Ic. The point that the shut-off device operates is the same as in the first embodiment.

  The low voltage detector 35 with time delay setting has the same configuration as the low voltage detector 19 and the time delay output unit 20 of the first embodiment shown in FIG. S2 is output.

  When the full-wave rectified voltage Vrec becomes lower than the threshold voltage Vt1, the time delay signal S1 rises. When the time delay signal S1 exceeds the threshold voltage Vt2, the excitation current cutoff signal S2 becomes L level. As a result, the switch circuit 37 is turned off and the exciting current Ic is cut off.

  As shown in FIG. 7, the overvoltage detection unit 34 with time delay setting is composed of an overvoltage detection unit 38 and a time delay output unit 39. The time delay output unit 39 excludes the charging characteristics of the transistor Tr1 and the capacitor C2. The same as in the first embodiment.

  The overvoltage detection unit 38 is the same as the low voltage detection unit 19 of the first embodiment except that the threshold voltage Vt3 is input to the negative side input terminal of the comparator 21 and the comparison voltage is input to the positive side input terminal. The configuration is similar.

  In such an overvoltage detection unit 38, when the peak value of the full-wave rectified voltage Vrec becomes higher than the threshold voltage Vt3, the overvoltage detection signal Vd2 intermittently becomes H level, and the time delay signal S3 of the time delay output unit 39 The voltage level increases. When the time delay signal S3 exceeds the threshold voltage Vt4, the excitation current cut-off signal S4 becomes L level, and the supply of the excitation current Ic to the coil 36 is cut off.

When the exciting current Ic is interrupted, the power supply to the load device is interrupted by the operation of the interrupting mechanism, as in the first embodiment.
When the excitation current Ic is interrupted, the switching circuit 31 is rendered non-conductive due to a change in magnetic force generated by the coil 36, and the supply of the commercial power supply AC to the power supply circuit 32 and the voltage signal generator 33 is also interrupted.

  The excitation current cut-off signals S2 and S4 are output to the switch circuit 37 via an interface circuit, and the interface circuit has a function of supplying an L level input signal to the switch circuit 37 with priority.

  As shown in FIG. 8, in the overvoltage / undervoltage tripping apparatus as described above, the threshold voltage Vt1 set by the low voltage detection unit 35 with time delay setting is reduced by the decrease in the excitation current Ic of the coil 36. The voltage is set higher than the voltage Vf1 input to the comparator 21 when the movable plunger cannot be attracted by the fixed plunger. At the same time, due to a drop in the supply voltage from the power supply circuit 32 due to a drop in the commercial power supply voltage, the overvoltage detection unit 34 with time delay setting and the low voltage detection unit 35 with time delay setting become voltages higher than the voltage Vf2 at which the operation becomes impossible. Is set.

According to the present embodiment, the following effects can be obtained.
(1) When the voltage level of the commercial power supply AC drops below a predetermined level for a predetermined time or more and rises above a predetermined level, the movable plunger can be separated from the fixed plunger to operate the shut-off mechanism. Therefore, it is possible to prevent problems caused by operating the load device when the voltage level of the commercial power source AC is insufficient and operating the load device when the voltage level of the commercial power source AC is overvoltage. Can do.
(2) Threshold voltage input to the comparator 21 by the low voltage detection unit 19 or the overvoltage detection unit 38 as a voltage sensitivity for detecting whether or not the voltage level of the commercial power supply AC is insufficient or overvoltage. It can be set by Vt1 and Vt3. Therefore, stable voltage sensitivity can be easily set.
(3) The time delay from when the voltage level of the commercial power supply AC drops to an undervoltage until the excitation current cut-off signal S2 for cutting off the excitation current Ic is output is the same as that of the transistor Tr1 of the time delay output unit 20 It can be set by a time constant circuit composed of the capacitor C2. Similarly, the time delay from when the voltage level of the commercial power supply AC rises to an overvoltage until the excitation current cut-off signal S4 for cutting off the excitation current Ic is output is determined by the transistor Tr1 and the capacitor of the time delay output unit 39. It can be set by a time constant circuit composed of C2. Accordingly, since the time delay can be set without using a large-capacitance capacitor, the overvoltage / undervoltage trip device can be reduced in size and the cost can be reduced.

In addition, you may change the said embodiment as follows.
The low voltage detector 19 of the first embodiment and the low voltage detector 35 with time delay setting of the second embodiment calculate the effective value by integrating the commercial power supply voltage, and the effective value and threshold value The voltages Vt1 and Vt3 may be compared.
The low voltage detector 19 of the first embodiment and the low voltage detector 35 with time delay setting of the second embodiment calculate the average value by integrating the commercial power supply voltage, and the average value and the threshold value Vt1 and Vt3 may be compared.
As shown in FIG. 9, in the switch circuits of the first and second embodiments, a pnp transistor Tr4 is used instead of the npn transistor, and the excitation current cutoff signal S2 is connected to the base of the transistor Tr4 via the inverter circuit 40. Alternatively, the same S4 may be input. With this configuration, when the excitation current cutoff signals S2 and S4 are at the H level and the excitation current Ic flows through the coil 12, the base voltage of the transistor Tr4 is substantially at the ground Vg level. Therefore, even if the full-wave rectified voltage Vrec is reduced due to noise, the transistor Tr4 is maintained in the on state, and the exciting current Ic can be stably supplied to the coil 12.

  DESCRIPTION OF SYMBOLS 13 ... Switch circuit, 14 ... Shut-off mechanism (fixed plunger), 15 ... Shut-off mechanism (movable plunger), 17 ... Shut-off mechanism (shut-off device), 19 ... Low voltage detection part, 20 ... Time delay output part, 21 ... First 24, second comparator, AC ... commercial power, Vt1 ... first threshold voltage, Vt2 ... second threshold voltage, Vt3 ... third threshold voltage, Vd ... low Voltage detection signal, Ic ... excitation current, S1 ... delay signal, S2 ... excitation current cutoff signal, C2 ... capacitor, Tr1 ... charge circuit (transistor), Tr2 ... discharge circuit (transistor), Vx ... comparison voltage.

Claims (6)

A low voltage detector that compares the commercial power supply voltage with a preset first threshold voltage and outputs a low voltage detection signal;
When the low voltage detection signal continues for a preset time or longer, a time delay output unit that outputs an excitation current cutoff signal;
A switch circuit that cuts off the excitation current supplied to the coil based on the excitation current cut-off signal;
In an undervoltage trip device for a circuit breaker provided with a shut-off mechanism for shutting off power supply to a load device based on shut-off of an exciting current to the coil
The low voltage detection unit includes a first comparator that compares a comparison voltage that changes based on a change in a commercial power supply voltage and the first threshold voltage,
The time delay output unit is
A charging circuit that charges a capacitor when the low voltage detection signal is input;
A discharge circuit for discharging the charge of the capacitor when the low voltage detection signal is not output;
A circuit breaker undervoltage comprising a second comparator that compares the charging potential of the capacitor with a preset second threshold voltage and outputs the excitation current cutoff signal. Tripping device. The undervoltage trip device according to claim 1,
The low voltage detection unit integrates the commercial power supply voltage to calculate an effective value, compares the effective value with the first threshold voltage, and outputs a low voltage detection signal. Undervoltage trip device for circuit breakers. The undervoltage trip device according to claim 1,
The low voltage detection unit integrates the commercial power supply voltage to calculate an average value, compares the average value with the first threshold voltage, and outputs a low voltage detection signal. Undervoltage trip device for circuit breakers. The undervoltage trip device according to any one of claims 1 to 3,
2. The circuit breaker undervoltage trip device according to claim 1, wherein the switch circuit includes a transistor that is turned off based on an input of the excitation current cutoff signal to cut off the excitation current. A commercial power supply voltage and a preset first threshold voltage are compared to generate a low voltage detection signal, and when the low voltage detection signal continues for a preset time or more, an excitation current cutoff signal Low voltage detector with time delay setting
The commercial power supply voltage is compared with a preset third threshold voltage to generate an overvoltage detection signal, and when the overvoltage detection signal continues for a preset time, an excitation current cutoff signal is output An overvoltage detector with a time delay setting,
A switch circuit that cuts off the excitation current supplied to the coil based on the excitation current cut-off signal;
In an overvoltage / undervoltage trip device for a circuit breaker provided with a shut-off mechanism for shutting off power supply to a load device based on shut-off of an excitation current to the coil,
The low voltage detector with a time delay setting is
A low voltage detector comprising a comparison voltage that changes based on a change in the commercial power supply voltage and a first comparator that compares the first threshold;
A charging circuit that charges a capacitor when the low voltage detection signal is input;
A discharge circuit for discharging the charge of the capacitor when the low voltage detection signal is not output;
A time delay output unit including a second comparator that compares the charging potential of the capacitor with a preset second threshold voltage and outputs the excitation current cut-off signal. Overvoltage / undervoltage trip device for circuit breakers. In the overvoltage / undervoltage trip device according to claim 5,
The first threshold voltage is set to a voltage higher than the comparison voltage when the cutoff mechanism stops operating due to a decrease in the excitation current, and the third threshold voltage is set with a time delay time setting. An overvoltage / undervoltage tripping device for a circuit breaker, wherein the overvoltage detection unit and the low voltage detection unit with time delay setting are set to a voltage lower than the comparison voltage when the operation becomes impossible.