JPH08294227A - Grounding current detector - Google Patents

Abstract

PURPOSE: To open a circuit breaker immediately if grounding exists when the circuit breaker is closed. CONSTITUTION: An alternating current from an AC line is rectified by a diode D3 and smoothed by a capacitor C3 . A starter circuit 6 is provided between a ground current judgment circuit 2 which decides the existence of grounding in accordance with the detected voltage of a zero-phase current transformer ZCT and the capacitor C3 . The starter circuit 6 has a transistor which is provided between the capacitor C3 and the power supply terminal Vcc of the ground current judgment circuit 2 and the transistor is held at an OFF-state until a voltage between both terminals of the capacitor C3 reaches the operation voltage of the ground current judgment circuit 2. Therefore, the charge in the capacitor C3 is not consumed until the capacitor C3 is sufficiently charged and hence the voltage between both terminals of the capacitor C3 can be made to rise quickly.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a ground fault current detecting device for detecting a ground fault in an electric line.

[0002]

2. Description of the Related Art As a ground fault current detecting device of this type, the inventors of the present invention have previously proposed a device shown in FIG. 4 (Japanese Patent Application No. 4-280340). This ground fault current detection device includes a zero-phase current transformer ZCT having an AC electric line Lp inserted therein, and converts an unbalanced current generated in the AC electric line Lp due to a ground fault current into a voltage by the zero-phase current transformer ZCT. The detection voltage output from the zero-phase current transformer ZCT due to the ground fault current is an alternating voltage, which is clamped by a clamp circuit composed of two diodes D1 and D2 connected in antiparallel, and the resistors R1 and R2 and the capacitor C1 are connected. , C2 attenuates the harmonic components. The detection voltage of the zero-phase current transformer ZCT is input to the ground fault current determination circuit 2 after passing through the waveform shaping circuit 1 including a clamp circuit and a low pass filter.

The power supply of the ground fault current judging circuit 2 is such that a series circuit of resistors R3 and R4, a diode D3 and a smoothing capacitor C3 is passed through the trip coil 3 of the circuit breaker 5 and the AC circuit L.
It is obtained by connecting between two lines of p and applying the voltage across the capacitor C3 between the power supply terminal Vcc and the ground terminal GND of the ground fault current determination circuit 2. In addition, AC line L
A series circuit of a trip coil 3, a thyristor 4 and a diode D5 is connected between two lines of p, and the thyristor 4 is controlled by a ground fault signal output from an output terminal OUT of the ground fault current determination circuit 2. . A noise preventing capacitor C5 is connected between the gate and the cathode of the thyristor 4. Further, a noise prevention element N is provided between the two wires of the AC electric circuit Lp.
R is connected.

The ground fault current determination circuit 2 compares the detected voltage of the zero-phase current transformer ZCT with a predetermined threshold value, charges or discharges the capacitor C4 according to the comparison result, and responds to the voltage across the capacitor C4. By generating a ground fault signal from the output terminal OUT, the comparison result is delayed. Therefore, when a ground fault occurs in the AC circuit Lp, the ground fault signal turns on the thyristor 4, and the trip coil 3 is energized to turn off the circuit breaker 5. The ground fault current determination circuit 2 is composed of an integrated circuit, and is externally provided with the capacitor C4 and a resistor R5 which determines a time constant for discharging the capacitor C4 after detecting the ground fault.

The ground fault current determination circuit 2 will be described in more detail. As shown in FIG. 5, the reference potentials L1 and L1 ', which are the potentials at the output terminals of the waveform shaping circuit 1, set by a reference potential generating circuit (not shown), respectively. A pair of comparison circuits 10 and 11 composed of a comparator for comparing with the above is provided, and the detection voltages of the zero-phase current transformer ZCT are compared by both comparison circuits 10 and 11. The comparator circuits 10 and 11 are configured to set the output to the L level while the potential of each output terminal of the waveform shaping circuit 1 (that is, the detection voltage of the zero-phase current transformer ZCT) exceeds the reference potentials L1 and L1 '. To be done. That is, the comparison circuit 10,
11 indicates that the absolute value of the detected voltage is compared with the reference potentials L1 and L1 ', and in general, L1.apprxeq.
It is set to L1 '. The reference potentials L1 and L1 'are
It is set lower than the clipping voltage by the diodes D1 and D2.

The ground fault current determination circuit 2 includes a capacitor C4
A charging / discharging circuit 12 for switching between a charging state and a discharging state is provided, and the voltage across the capacitor C4 is compared with three-stage threshold values Vth1 to Vth3 by decision circuits 13 to 15 composed of comparators. Charge / discharge circuit 1
2 is a bias current supply terminal or a charge / discharge control terminal C
D and a circuit such as a current mirror circuit (not shown) that forms a charging current and a discharging current according to the level of the bias current supplied to the bias current supply terminal CD. As a result, the charging current and the discharging current to the capacitor C4 by the charging / discharging circuit 12 are determined by the bias current supplied to the bias current supply terminal CD. The threshold values Vth1 to Vth3 are the power supply terminal V
4 resistors R connected between cc and ground terminal GND
11 to R14. Also, a series circuit of a diode D10 and a collector-emitter of a transistor Q2 is connected in parallel to the series circuit of the resistors R11 to R13, and the transistor Q2 is turned on while the output of the decision circuit 15 is at the H level, and the threshold value is set. By lowering Vth1 to Vth3, hysteresis is given to the comparison operation of the determination circuits 13 to 15. In this way, the resistors R11 to R14 and the transistor Q
2. The threshold circuit 16 is composed of the diode D10. The decision circuit 15 also controls the transistor Q3, and the series circuit of the collector-emitter of the transistor Q3 and the resistor R5 is connected in parallel to the capacitor C4. Therefore, the capacitor C4 is discharged through the resistor R5 while the output of the decision circuit 15 is at H level. Here, the transistor Q1 is turned on / off by the output of the determination circuit 15,
The collector of the transistor Q1 is connected to the power supply terminal Vcc and the emitter is connected to the output terminal OUT. When the output of the determination circuit 15 becomes H level and the transistor Q1 is turned on, a ground fault signal is output from the output terminal OUT. To be done.

By the way, as described above, the comparison circuit 1
0 and 11 are for comparing the magnitude of the detected voltage of the zero-phase current transformer ZCT, and the decision circuits 13 to 15 are for comparing the magnitude of the voltage across the capacitor C4. These comparison results are combined. If used, a ground fault signal will not be generated by a transient current change such as a lightning surge or a current change caused by a variation in the characteristics of the zero-phase current transformer, and when the ground fault occurs, the trip coil 3 is reliably It becomes possible to turn on the circuit breaker by energizing. In this way, the comparison circuits 10, 11,
In order to combine the comparison results of the judgment circuits 13 to 15,
The ground fault current determination circuit 2 includes a control circuit 1 including a logic circuit.
7 are provided.

The control circuit 17 controls the charge / discharge circuit 12,
The charge / discharge circuit 12 charges the capacitor C4 with a predetermined current when the output of the control circuit 17 is at the H level, and when the output of the control circuit 17 is at the L level, the capacitor C4 has a time constant larger than that at the time of charging.
Discharge 4. Further, the capacitor C4 also has a discharge path by the transistor Q3 and the resistor R5, and while the output of the judgment circuit 15 is at the H level and the ground fault signal is being output, the transistor Q3 is turned on, so that the charge / discharge circuit is The capacitor C4 is discharged with a smaller time constant than when only 12 is used.

Although the details have been described in the above application, the output of the control circuit 17 becomes H level and the charging / discharging circuit 12 charges the capacitor C4 under the following three conditions. The capacitor C4 is discharged. That is, the output of the comparison circuit 10 is S1 and the output of the comparison circuit 11 is S2.
, When the voltage across the capacitor C4 is VC4, (A) S1 = L ∧ VC4 <Vth1 (B) S1 = H ∧ S2 = L ∧ Vth1 '≤ VC4
<Vth2 (C) S1 = L ∧ S2 = H ∧ Vth2 '≤ VC4
If any one of <Vth3 is established, the capacitor C4 is charged and discharged under other conditions. Here, H means H level, L means L level, and ∧ means “and”. Also, V
th1 'and Vth2' are threshold values Vth1 and Vth, respectively.
It shows a voltage slightly lower than 2, and the decision circuits 13 and 1
In 4, the output is inverted to the H level and then the threshold is set to Vth1.
It has a hysteresis function of lowering to ', Vth2', and is configured to prevent output chattering. The threshold values Vth1 ′ and Vth2 ′ are the voltage across the capacitor C4 that drops in about half a cycle of the power supply frequency when the charging / discharging circuit 12 starts discharging when the voltage across the capacitor C4 reaches the threshold Vth1 and Vth2. Is set lower than.

However, if a ground fault does not occur in the AC circuit Lp, no detection voltage is generated from the zero-phase current transformer ZCT, so that the outputs of both comparison circuits 10 and 11 become H level as described above. Since the outputs of both comparator circuits 10 and 11 are both at the H level under none of the above three conditions, the output of the control circuit 17 is at the L level at this time and the charging / discharging circuit 12 discharges the capacitor C4. become.

Next, when a ground fault occurs in the AC electric line Lp, an alternating detection voltage as shown in FIG. 6A is output from the zero-phase current transformer ZCT, and this detection voltage is compared with the comparison circuits 10 and 1.
At 1, the reference potentials L1 and L1 'are compared. In normal operation, the detection voltage does not exceed the reference potentials L1 and L1 'at the same time. Therefore, the combinations of the outputs of the comparison circuits 10 and 11 are: (a) S1 = H level ∧ S2 = H level (b) S1 = L Level ∧ S2 = H level (c) S1 = H level ∧ S2 = L level, and (a) is a state in which no detection voltage is generated, so the AC line Lp is grounded and its state is When it continues, the above-mentioned change of state is repeated in the order of (a), (b), (a), (c), and (a).

Then, first, as shown in FIG. 6A, if the detected voltage exceeds the reference potential L1, the state becomes (B), and at this time, the voltage across the capacitor C4 is considered to be 0 V, so that When the condition (A) is satisfied, the capacitor C4 is charged with the charging current IA as shown in FIG. 6 (b). The charging current IA to the capacitor C4 is the same as the charging current IA during the period when the detection voltage exceeds the reference potential L1.
The voltage across 4 is set to be equal to or higher than the threshold value Vth1. Therefore, as shown in FIG. 6B, the voltage across the capacitor C4 is equal to the threshold value Vth during the charging of the capacitor C4.
Since it reaches 1 and the conditions (A) to (C) are not satisfied at that time, the capacitor C4 starts discharging at the discharge current ID. The discharge current ID is set smaller than the charge current IA.

If the state of the ground fault continues, the detected voltage exceeds the comparison potential L1 'during the discharge of the capacitor C4, so that the state (c) is established and the condition (B) is satisfied. The capacitor C4 is charged until the voltage across the capacitor reaches the threshold value Vth2 as shown in FIG. 6 (b). When the voltage across the capacitor C4 reaches the threshold value Vth2, the control circuit 17
When the output voltage of the capacitor C4 becomes L level again and the capacitor C4 is discharged, and the detected voltage of the zero-phase current transformer ZCT exceeds the reference potential L1 again while the capacitor C4 is discharging, this time (C)
Then, the capacitor C4 is charged until the voltage across the capacitor reaches the threshold value Vth3 as shown in FIG. 6 (b).

As described above, the voltage across the capacitor C4 reaches Vth3 after being charged three times.
At this time, the output of the determination circuit 15 is inverted to the H level, so that the ground fault signal is output from the output terminal OUT as shown in FIG. 6C. In addition, the output of the determination circuit 15 is H
At the level, the transistor Q2 turns on and the threshold value V
Th1 to Vth3 are sufficiently lowered, and the transistor Q3 is turned on to discharge the capacitor C4 with a discharge current IC larger than that obtained by the charge / discharge circuit 12 alone. In the charge / discharge circuit 12, the voltage of the capacitor C4 is the threshold value Vt.
When h3 drops below a certain percentage, capacitor C4 is rapidly discharged.

As described above, the ground fault current determination circuit 2
When a detection voltage is generated in the zero-phase current transformer ZCT due to a ground fault, the capacitor C4 is charged three times within a period within two cycles of the power supply frequency to delay the occurrence of the ground fault and generate a ground fault signal. To do. When the ground fault signal is generated as described above, the thyristor 4 is triggered, and the trip coil 3 is energized to turn off the circuit breaker 5 and shut off the AC circuit Lp.

In the above operation, a ground fault occurs and the zero-phase current transformer ZCT
This is the operation when the detection voltage output from the zero-phase current transformer ZCT continues for two cycles or more. However, when a transient detection output is generated from the zero-phase current transformer ZCT due to a lightning surge or the like, When a detection voltage with waveform distortion is generated at the time of starting a load such as a motor due to variation in characteristics, the detection voltage does not change as described above, and the comparison circuit 10,
Since the reference levels L1 and L1 'of 11 are not exceeded in the above order, the ground fault signal is not output.

[0017]

The ground-fault current detecting device described above is constructed for the purpose of preventing malfunction due to lightning surge and characteristics of the zero-phase current transformer ZCT, and this object is achieved. However, half-wave rectification of the alternating current supplied to the alternating current circuit Lp by the diode D3,
Since the power supply for the ground fault current determination circuit 2 is obtained by smoothing with the capacitor C3 and the capacitor C4 is charged three times with this power supply, the above malfunction is prevented, so that the following problems occur. .

That is, assuming that a ground fault has already occurred in the AC electric line Lp at the time when the circuit breaker 5 is turned on as shown in FIG. 7A, the state shown in FIG.
Although the detection voltage is generated from the zero-phase current transformer ZCT as shown in (b), the charging of the capacitor C4 is started as shown in FIG. 7 (c) because the voltage across the smoothing capacitor C3 is grounded. This is after reaching the operating voltage Vop of the current determination circuit 2 (FIG. 7D shows the voltage between the power supply terminal Vcc and the ground terminal GND of the ground fault current determination circuit 2). After that, when the capacitor C4 is charged three times by the above operation, a ground fault signal is generated. After the occurrence of the ground fault signal, the thyristor 4 will be
It turns on in synchronization with the on-side half cycle shown in (e) (FIG. 7 (f) shows the voltage between the output terminal OUT of the ground fault current determination circuit 2 and the ground terminal GND). Figure 7 at this point
The circuit breaker 5 is turned off as shown in (a), and the trigger signal to the thyristor 4 is held until the voltage across the capacitor C3 reaches the holding voltage Voh of the ground fault current determination circuit 2.

As described above, when the ground fault has already occurred when the circuit breaker 5 is turned on, the time required from the time when the circuit breaker 5 is turned on until the time when the circuit breaker 5 is turned off by the ground fault detection is as follows. The charging time of the capacitor C3, the time required for the ground fault detection process described above, the time from the occurrence of the ground fault signal to the turning on of the thyristor 4, the breaker 5 being turned off after the trip coil 3 is energized. It will be the total time to become.
As a result, there are cases where the time from when the AC circuit Lp in which the ground fault occurs to when the circuit breaker 5 is turned off exceeds 100 msec. The cause of such a time delay is
Most of the time required to charge the capacitor C3 is occupied.

As a method of shortening the charging time of the capacitor C3, it is conceivable to reduce the capacity of the capacitor C3. However, as shown in FIG. 8 (a), the circuit breaker 5 is turned on,
When the detected voltage is obtained from the zero-phase current transformer ZCT as shown in FIG. 8 (b), the capacitor C4 is provided as shown in FIG. 8 (c).
Even if the voltage across both ends of the capacitor rises to the voltage required to generate the ground fault signal (in FIG. 8 (c), the process of charging the capacitor C4 is simplified to charge only once.
(Actually, the above processing), within the time from the application of the ground fault signal to the thyristor 4 until the thyristor 4 is turned on,
As shown in FIG. 8 (d), the voltage across the capacitor C3 becomes lower than the holding voltage Voh, and the ground fault signal is maintained until the next half cycle of the thyristor 4 on side (see FIG. 8 (e)). And eventually the thyristor 4 could not be turned on (FIG. 8 (f) shows the voltage between the output terminal OUT of the ground fault current determination circuit 2 and the ground terminal GND). Although it occurs, there is a case where the circuit breaker 5 cannot be turned off as shown in FIG.

The present invention has been made in view of the above circumstances, and an object thereof is to be able to turn off a circuit breaker without delay if a ground fault occurs when the circuit breaker is turned on. Another object of the present invention is to provide a ground fault current detector.

[0022]

According to a first aspect of the present invention, there is provided a zero-phase current transformer for detecting an unbalanced current in an AC circuit, and a comparison circuit for comparing a detection voltage of the zero-phase current transformer with a reference potential. A charging / discharging circuit that charges the capacitor with a predetermined time constant when the detected voltage is equal to or higher than the reference potential and discharges the capacitor with a time constant that is larger than that during charging when the detected voltage is lower than the reference potential, and a voltage across the capacitor is predetermined A switching circuit that turns on the circuit breaker by energizing the trip coil when a ground fault signal is generated and connected in series with the trip circuit of the circuit breaker inserted in the AC circuit when the voltage reaches the voltage. In a ground fault current detection device including an element and a smoothing capacitor that supplies power to a ground fault current determination circuit including a comparison circuit, a charging / discharging circuit, and a determination circuit that are connected to an AC circuit via a rectifier circuit, For smoothing Startup including a switch element inserted between the capacitor and the ground fault current determination circuit, and a startup control unit that keeps the switch element off until the voltage across the smoothing capacitor reaches the operating voltage of the ground fault current determination circuit It is characterized in that a circuit is provided.

According to a second aspect of the present invention, in the first aspect of the present invention, the activation control unit causes the voltage across the smoothing capacitor to become a holding voltage lower than the operating voltage of the ground fault current determination circuit when the switch element is turned on. It is characterized in that it is provided with a hysteresis imparting section for maintaining the switch element in the ON state until the voltage falls. According to a third aspect of the invention, in the second aspect of the invention, the starting circuit includes a voltage detection circuit that is supplied with power when the switch element is turned on and determines whether or not the capacitor is charged / discharged by the charge / discharge circuit. Is characterized in that charging and discharging of the capacitor is prohibited when the voltage across the smoothing capacitor drops to a predetermined voltage higher than the holding voltage.

According to the invention of claim 4, in claim 1,
The switch element is a transistor, and the collector-emitter is inserted between the smoothing capacitor and the ground fault current detector, and the start control unit uses the voltage of the smoothing capacitor when turning on the transistor as the start voltage. A starting voltage setting unit for setting and a constant voltage setting unit for applying a constant control voltage to the base of the transistor so as to supply the constant voltage to the ground fault current detection device after the transistor is turned on are provided. It is characterized by being set higher than.

According to a fifth aspect of the present invention, in the fourth aspect, the starting voltage setting section and the constant voltage setting section each include a constant voltage element in which a base and a collector of an npn-type transistor are connected.

[0026]

According to the structure of the invention of claim 1, the switch element inserted between the smoothing capacitor and the ground fault current judging circuit and the voltage across the smoothing capacitor are the operation of the ground fault current judging circuit. By providing the start-up circuit that includes the start-up control unit that keeps the switch elements off until the voltage reaches the voltage, the charge of the smoothing capacitor is not consumed until the operating voltage of the ground fault current determination circuit is reached, and the smoothing capacitor is not consumed. It is possible to rapidly raise the voltage across the capacitor. As a result, even if a ground fault occurs when the circuit breaker is turned on, the time from when the circuit breaker is turned on until the ground fault signal is generated by the ground fault current determination circuit is significantly shorter and shorter than before. The circuit breaker can be turned off in time. That is, it is possible to provide a highly safe earth leakage circuit breaker.

According to the second aspect of the present invention, once the switch element is turned on, hysteresis is provided so that the switch element can be maintained in the on state even if the voltage across the smoothing capacitor is slightly lowered. Therefore, even if a voltage fluctuation due to a ripple component or the like occurs, it is possible to continue power supply to the ground fault current determination circuit and stably operate the ground fault current determination circuit.

According to the third aspect of the invention, the operation of the charge / discharge circuit of the ground fault current determination circuit is controlled by the voltage detection circuit, and the voltage detection circuit turns on the switch element by the voltage across the smoothing capacitor. Since the charging / discharging of the capacitor by the charging / discharging circuit is prohibited when the voltage drops to a predetermined voltage higher than the holding voltage to be maintained, the operation of the charging / discharging circuit is performed while the switch element is kept on and power is supplied to the ground fault current determination circuit. When the voltage drops, the charging / discharging of the capacitor is stopped prior to the stopping of other circuits, so that the malfunction due to the voltage fluctuation of the capacitor can be prevented.

According to the structure of the invention of claim 4, the starting voltage for turning on the switch element is set higher than the control voltage when the constant voltage is applied to the ground fault current detecting device.
When the switch element is turned on, the operating voltage of the ground fault current determination circuit can be reliably ensured. Claim 5
According to the configuration of the invention described above, a constant voltage element with a small leak current can be obtained by performing constant voltage using the constant voltage element in which the base-collector of an npn-type transistor is connected, and it is possible to obtain an accuracy even with a small current. The voltage can be set well.

[0030]

EXAMPLE This example has, as shown in FIG. 1, basically the same structure as that shown in the conventional example, and a starting circuit 6 is provided between a capacitor C3 and a ground fault current judging circuit 2. The only difference is the addition of. As shown in FIG. 2, the starting circuit 6 includes a power supply terminal T1 connected to the positive electrode of the capacitor C3.
And a ground terminal T2 connected to the negative electrode of the capacitor C3
And a constant voltage output terminal T3 connected to the power supply terminal Vcc of the ground fault current determination circuit 2. Further, a bandgap reference voltage generating circuit (not shown) for determining a charging current and a discharging current in the charging / discharging circuit 12 of the ground fault current determination circuit 2 described as the conventional example and a constant current transistor (illustrated in the drawing) biased by the bandgap reference voltage generating circuit. Is connected between the constant voltage output terminal T3 and the ground terminal T2, and the output terminal T4 of the voltage detection circuit 7 is the charging / discharging control terminal CD of the charging / discharging circuit 12 shown in FIG. Connected to.
When the voltage applied to the control terminal CN is equal to or lower than the predetermined voltage, the voltage detection circuit 7 causes the capacitor C4 by the charge / discharge circuit 12
The charging / discharging (see FIG. 5) is prohibited. The voltage detection circuit 7 may be incorporated in the integrated circuit that constitutes the ground fault current determination circuit 2. When the voltage detection circuit 7 is configured to use the bandgap reference voltage generation as described above, the bias current supplied to the charge / discharge control terminal CD can be set to a relatively accurate level, and accordingly the capacitor C4 It will be possible to bring the charge current and the discharge current for the to a relatively accurate level.

Between the power supply terminal T1 and the output terminal T3,
The collector-emitter of the transistor Q11 as a switching element is inserted, and power is supplied to the ground fault current determination circuit 2 from the constant voltage output terminal T3 while the transistor Q11 is on. A series circuit of a Zener diode ZD11 and a diode D11 is connected between the base of the transistor Q11 and the ground terminal T2. The control terminal CN of the voltage detection circuit 7 described above is a Zener diode Z.
It is connected to the connection point between D11 and diode D11.

The collector of the transistor Q11 has p
The emitter of an np-type multicollector transistor Q12 is connected. One of the three collectors provided in the transistor Q12 is connected to the base of the transistor Q11,
The other one is connected to the base of the transistor Q12, and the other one is connected to the base of another transistor Q13 via four diodes D12 to D15 connected in series. The base of the transistor Q12 is connected to the ground terminal T via the collector-emitter of the transistor Q13 and the resistor R21.
Connected to 2.

Between the power supply terminal T1 and the ground terminal T2,
Resistor R22, diode D16, Zener diode ZD1
2, a series circuit of diodes D17 and D18 is connected, and the base of the transistor Q13 is a Zener diode ZD12.
And diode D17. Further, a series circuit of two Zener diodes ZD13, ZD14 and a resistor R23 and a series circuit of a resistor R24 and a collector-emitter of the transistor Q14 are also connected between the power supply terminal T1 and the ground terminal T2. The base of the transistor Q14 is connected to the connection point between the Zener diode ZD14 and the resistor R23 to form the clamp circuit 8 (included in the starting circuit 6).

Here, the Zener diode ZD1
Zener voltages of 1 and ZD12 are equal (for example, 6.3).
V), and the Zener voltages of the Zener diodes ZD13 and ZD14 are set equal (for example, 5.7V). Here, regarding the Zener diodes ZD11 and ZD12,
If the base-collector of the npn-type transistor is connected and the collector-emitter is used as a Zener diode, malfunction does not occur even when the passing current is small. That is, the p ⁺ Zener generally used in the bipolar process has a large current leak at a high temperature, and thus a malfunction may occur if the passing current is small.
If a pnp type transistor with a small leak current is used, malfunction can be prevented. Each diode D11 to D
The forward drop voltage of 18 is the same (0.7 V), and the same applies to the transistors Q11 to Q14.

Now, the operation of the starting circuit will be described assuming that the voltage is set to the voltage described in the above parentheses. In the above circuit configuration, there are four circuits that conduct when the voltage between the power supply terminal T1 and the ground terminal T2 reaches a predetermined voltage and clamp the voltage between the power supply terminal T1 and the ground terminal T2 to that voltage. It is provided. Firstly, the base of diode D16, Zener diode ZD12 and transistor Q13-
A series circuit between the emitters, which is 7.
It conducts at 7V. Second, between the emitter and collector of the transistor Q12, the diodes D12 to D15 and the transistor Q.
13 is a series circuit between the base and the emitter and has a conducting voltage of 4.2V. Thirdly, there is a series circuit of the diodes D16 to D18 and the zener diode ZD12 and has a conducting voltage of 8.4V and the fourth. Zener diodes ZD13, ZD14
And a series circuit between the base and emitter of the transistor Q14, which is 12.1V.

Therefore, when the applied voltage between the power supply terminal T1 and the ground terminal T2 (that is, the voltage across the capacitor C3) is Vx, there are four states when the applied voltage Vx rises and four states when the applied voltage Vx falls. There are two states. That is, in the ascending process, (a) 0V ≦ Vx <7.7V (b) 7.7V ≦ Vx <8.4V (c) 8.4V ≦ Vx <12.1V (d) 12.1V ≦ Vx descending process Then, (e) 4.2 V ≤ Vx ≤ 8.4 V (f) Vx <4.2 V In the state of (a), the above-mentioned first series circuit (diode D16-Zener diode ZD12-transistor Q13).
Transistor Q12 is off, and transistor Q11 is kept off.

In the state of (b), the first series circuit is turned on and the transistor Q12 is turned on. At this time, through the emitter-collector of the transistor Q12, the transistor Q
A base current flows through 11, and the transistor Q11 is turned on. That is, when the voltage across the capacitor C3 becomes 7.7 V or higher, the constant-voltage power supply to the ground fault detection determination circuit 2 is started. Conversely, in the period lower than 7.7V, the ground fault detection determination circuit 2 is not supplied with power, and there is no power consumption in the ground fault detection determination circuit 2, so that the charging of the capacitor C3 proceeds quickly. . Further, a start-up voltage is applied to the control terminal CN of the voltage detection circuit 7 by the conduction of the Zener diode ZD11 and the diode D11, and the charge / discharge circuit 12 of the ground fault current determination circuit 2 can be operated through the voltage detection circuit 7. Further, when the transistor Q12 is turned on, current flows through the diodes D12 to D15 and the base-emitter of the transistor Q13 (that is, the second series circuit), and once the transistor Q12 is turned on, the applied voltage Vx is applied thereafter. Transistor Q12 is maintained in the ON state until the voltage becomes less than 4.2V. That is, the transistor Q
Hysteresis is given to the on / off of 12. By applying such hysteresis, the applied voltage Vx fluctuates (including fluctuation due to the ripple component of the power supply).
Even so, it can be operated stably.

In the state of (c), the above-mentioned third series circuit (diodes D16 to D18 and Zener diode Z).
D12) becomes conductive, and the constant-voltage power supply to the ground fault current determination circuit 2 is continued. In the state of (d), the applied voltage Vx is kept at 12.1 V due to conduction of the clamp circuit 8 and the resistance is
The current flows between the collector and the emitter of the transistor Q14 and the transistor 24, and the Zener diode ZD
13, the current flowing through ZD14 is suppressed. That is, even if a surge current flows between the power supply terminal T1 and the ground terminal T2, the current flows through the resistor 24 and the series circuit between the collector and the emitter of the transistor Q14, thereby protecting the Zener diodes ZD13 and ZD14. In addition, the temperature drift of the applied voltage Vx between the power supply terminal T1 and the ground terminal T2 is suppressed by limiting the current flowing through the Zener diodes ZD13 and ZD14.

On the other hand, when the applied voltage Vx drops,
When the voltage is less than 8.4V as in the state (e), no current flows in the above-mentioned third series circuit (diodes D16 to D18 and zener diode ZD12), but hysteresis is added as described above. By
When the applied voltage Vx is 4.2 V or higher, the on state of the transistor Q11 is maintained.

When the applied voltage Vx becomes less than 4.2 V as in the state (f), the transistor Q11 is turned off and the power supply to the ground fault current determination circuit 2 is stopped. As described above, the provision of the start-up circuit 6 enables the configuration shown in FIG.
As shown in (a), if the ground fault occurs when the circuit breaker 5 is turned on and the detection voltage as shown in FIG. 3 (b) is generated from the zero-phase current transformer ZCT, the ground fault occurs. The electric charge of the capacitor C3 that supplies power to the current determination circuit 2 is the operating voltage Vop of the ground fault current determination circuit 2 (7.7 in the above example).
Since it is not consumed by the ground fault current determination circuit 2 until the voltage reaches V), the voltage across the capacitor C3 rises rapidly as shown in FIG. Does not decrease, and the operating voltage Vop of the ground fault current determination circuit 2 is reached in a relatively short time. The voltage across the capacitor C3 is the operating voltage V of the ground fault current determination circuit 2.
When op is reached, a ground fault signal is generated after charging the capacitor C4 (see FIG. 5) three times as in the conventional example as shown in FIG. That is, after the generation of the ground fault signal, the thyristor 4 can be turned on in the half cycle of the thyristor 4 on the ON side (FIG. 3 (e)) (FIG. 3 (f) shows the output of the ground fault current determination circuit 2). The voltage between the terminal OUT and the ground terminal GND is shown). As described above, the time required for the voltage across the capacitor C3 to reach the operating voltage Vop of the ground fault current determination circuit 2 is significantly shortened as compared with the conventional configuration, and as a result, the ground fault signal is generated and the thyristor 4 is turned on. It is possible to operate the circuit breaker 5 quickly while using the capacitor C3 having a capacity that can be maintained until about the time.

In the above embodiment, the capacitor C4 is charged three times to generate a ground fault signal as in the conventional example. However, if malfunctions such as lightning surge do not pose a problem, only one charge is required. The technical idea of the present invention can also be applied to a device that generates a ground fault signal in.

[0042]

According to the first aspect of the present invention, the switch element inserted between the smoothing capacitor and the ground fault current judging circuit and the voltage across the smoothing capacitor become the operating voltage of the ground fault current judging circuit. By providing a start-up circuit with a start-up controller that keeps the switch elements off until reaching
The charge of the smoothing capacitor is not consumed until the operating voltage of the ground fault current determination circuit is reached, and the voltage across the smoothing capacitor can be rapidly raised. As a result, even if a ground fault occurs when the circuit breaker is turned on, the time from when the circuit breaker is turned on until the ground fault signal is generated by the ground fault current determination circuit is significantly shorter and shorter than before. It has the advantage that the circuit breaker can be turned off in time. That is, it is possible to provide a highly safe earth leakage circuit breaker.

According to the second aspect of the present invention, once the switch element is turned on, hysteresis is added so that the on state of the switch element can be maintained even if the voltage across the smoothing capacitor drops to some extent. There is an advantage that the power supply to the ground fault current determination circuit can be continued and the ground fault current determination circuit can be operated stably even if a voltage fluctuation occurs due to the above.

According to the third aspect of the present invention, the operation of the charge / discharge circuit of the ground fault current determination circuit is controlled by the voltage detection circuit, and the voltage detection circuit is configured such that the voltage across the smoothing capacitor is higher than the holding voltage for keeping the switch element on. The charging / discharging circuit prohibits the charging / discharging of the capacitor when the voltage drops to a high predetermined voltage.Therefore, stop the operation of the charging / discharging circuit while the switch element is kept on and the ground fault current judgment circuit is being supplied with power. When the voltage drops, the charging / discharging of the capacitor is stopped prior to the stop of the other circuits, so that the malfunction due to the voltage fluctuation of the capacitor can be prevented.

According to the invention of claim 4, the starting voltage for turning on the switching element is set higher than the control voltage for applying a constant voltage to the ground fault current detecting device, so that the switching element is turned on. At times, there is an advantage that the operating voltage of the ground fault current determination circuit can be reliably ensured. According to the invention of claim 5, a constant voltage element having a small leak current can be obtained by performing constant voltage using a constant voltage element in which a base-collector of an npn-type transistor is connected, and a small current can be accurately obtained. It has the effect that the voltage can be set.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing an embodiment.

FIG. 2 is a circuit diagram of a starting circuit used in the embodiment.

FIG. 3 is an operation explanatory diagram of the embodiment.

FIG. 4 is a circuit diagram showing a conventional example.

FIG. 5 is a circuit diagram of a ground fault current determination circuit used in a conventional example.

FIG. 6 is an operation explanatory diagram of a conventional example.

FIG. 7 is an operation explanatory view showing a problem of the conventional example.

FIG. 8 is an operation explanatory view showing a problem of the conventional example.

[Explanation of symbols]

 2 Ground fault current judgment circuit 3 Tripping coil 4 Thyristor 5 Circuit breaker 6 Start circuit 7 Voltage detection circuit 10 Comparison circuit 11 Comparison circuit 12 Charge / discharge circuit 13 Judger circuit 14 Judgment circuit 15 Judgment circuit C3 Capacitor C4 Capacitor D11 Diode D12 Diode D13 diode D14 diode D15 diode D16 diode D17 diode D18 diode Lp AC circuit Q11 transistor Q12 transistor Q13 transistor Q14 transistor R21 resistor R22 resistor R23 resistor R24 resistor ZD11 Zener diode ZD12 Zener diode ZD13 Zener diode ZD13

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[Procedure amendment]

[Submission date] April 24, 1995

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] Explanation of code

[Correction method] Change

[Correction content]

[EXPLANATION OF SYMBOLS] 2 grounding current determination circuit 3 releasing coil 4 Thyristor 5 breaker 6 starting circuit 7 voltage detecting circuit 10 comparison circuit 11 comparison circuit 12 charging and discharging circuit 13 determiner circuitry 14 determining circuit 15 determines the circuit C3 capacitor C4 Capacitor D11 Diode D12 Diode D13 Diode D14 Diode D15 Diode D16 Diode D17 Diode D18 Diode Lp AC Circuit Q11 Transistor Q12 Transistor Q13 Transistor Q14 Transistor R21 Zener R22 Resistor R22 Resistor ZD Zener ZD11 Zener D24 Zener ZD11

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Hitoshi Makinaga 1048 Kadoma, Kadoma City, Osaka Prefecture Matsushita Electric Works Co., Ltd. (72) Inventor Yasuo Nagai 5-20-1 Kamimizuhonmachi, Kodaira-shi, Tokyo Ceremony Company Hitachi, Ltd. Semiconductor Division (72) Inventor Yuji Tsukui 5-22-1 Kamisuihonmachi, Kodaira-shi, Tokyo Inside Hitachi Microcomputer System Co., Ltd.

Claims (5)

[Claims] 1. A zero-phase current transformer that detects an unbalanced current in an alternating current circuit, a comparison circuit that compares a detection voltage of the zero-phase current transformer with a reference potential, and a predetermined period when the detection voltage is equal to or higher than the reference potential. A charging / discharging circuit that charges the capacitor with a time constant of, and discharges the capacitor with a time constant larger than that during charging in a period less than the reference potential, and a judgment that a ground fault signal is generated when the voltage across the capacitor reaches a predetermined voltage. Circuit and a switching element connected in series to the trip coil of the circuit breaker inserted in the AC circuit, and a switching element that energizes the trip coil to turn off the circuit breaker when a ground fault signal occurs, and a rectifier circuit in the AC circuit. In a ground fault current detection device including a smoothing capacitor that supplies power to a ground fault current determination circuit that includes a comparison circuit, a charging / discharging circuit, and a determination circuit, a smoothing capacitor and a ground fault current determination circuit Between A ground fault, which is provided with a start-up circuit including an inserted switch element and a start-up control unit that keeps the switch element off until the voltage across the smoothing capacitor reaches the operating voltage of the ground fault current determination circuit. Current detection device. 2. The hysteresis that maintains the switch element in the on state until the voltage across the smoothing capacitor drops to a holding voltage lower than the operating voltage of the ground fault current determination circuit when the switch element is turned on. The ground fault current detection device according to claim 1, further comprising an application unit. 3. The start-up circuit is provided with a voltage detection circuit that is supplied with power when the switch element is turned on and determines whether or not the charge / discharge circuit charges or discharges the capacitor, and the voltage detection circuit detects the voltage across the smoothing capacitor. 3. The ground fault current detection device according to claim 2, wherein charging and discharging of the capacitor is prohibited when the voltage drops to a predetermined voltage higher than the holding voltage. 4. The switch element is a transistor, and a collector-emitter is inserted between a smoothing capacitor and a ground fault current detecting device, and a start control unit of the smoothing capacitor when turning on the transistor. A starting voltage setting unit that sets a voltage as a starting voltage, and a constant voltage setting unit that applies a constant control voltage to the base of the transistor so as to supply a constant voltage to the ground fault current detection device after the transistor is turned on, The ground fault current detection device according to claim 1, wherein the starting voltage is set higher than the control voltage. 5. The ground fault current detection device according to claim 4, wherein the starting voltage setting unit and the constant voltage setting unit each include a constant voltage element in which a base and a collector of an npn-type transistor are connected.