KR860002721Y1 - Leakage breaker - Google Patents

Abstract

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Description

Earth leakage breaker

1 is a circuit diagram showing a conventional earth leakage breaker.

2 is a detailed circuit diagram of the control circuit shown in FIG.

3 is a characteristic diagram of the hysteresis circuit shown in FIG.

4 is a circuit diagram showing a first embodiment of an earth leakage breaker according to the present invention.

FIG. 5 is a diagram for explaining the operation of the first embodiment shown in FIG.

6 is a view for explaining the effect of the first embodiment shown in FIG.

7 and 8 are circuit diagrams showing second and third embodiments according to the present invention.

* Explanation of symbols for main parts of the drawings

1: power supply 2: main circuit contact

3: load 4: auxiliary transformer

5: single-phase full-wave rectifier 6: smoothing capacitor

7: trip coil 8: thyristor

9: image transformer 10, 12, 17, 19, 20, 21: resistance

11: control circuit 11a ₁ : resistance

11a ₂ : first constant voltage diode 11a ₃ : 2nd constant voltage diode

11e ₁ -11e ₄ : Resistance 11e ₅ : Capacitor

11e ₆ : Comparator 13: Capacitor

14 nonlinear surge absorber 15 double variable resistor

16: diode 18: double tap changer

The present invention relates to an improvement of an earth leakage breaker.

In the circuit configuration of the conventional earth leakage breaker, as shown in FIG. 1, the load 3 is connected to the power supply 1 via the main circuit contact 2, and comprises the main circuit. The auxiliary transformer 4, in which the primary side end 4a is connected in parallel to the main circuit, connects the secondary side end 4b to the input terminal of the single-phase full-wave rectifier 5, and the single-wave full-wave rectifier 5 The output capacitors P ₁ and N _{1 are} connected to a smoothing capacitor 6 and a series circuit of a trip coil and a thyristor 8 connected in parallel thereto.

On the other hand, the image current transformer 9 having the main circuit as the primary side connects the secondary end to the input terminals A and B of the control circuit 11 by connecting the resistor 10 in parallel between the lines. Doing. The input power supply terminals P ₂ and N ₁ of the control circuit 11 are connected to the output terminals P ₁ and N _{1 of} the single-phase full-wave rectifier 5 via a resistor 12 in series. The control power is being obtained.

The control circuit 11 generates a short-circuit detection current on the secondary side of the image transformer 9 when a short-circuit accident occurs on the load side 3 of the main circuit, which is a current signal of an AC sine wave, which is applied by a resistor 10 to the voltage. When the signal is converted into a signal and the capacitor 13 connected to one power terminal N ₂ and the hold terminal H is charged by input of the voltage signal, and the voltage of both ends thereof exceeds the set value, the thyristor at the output terminal S The thyristor 8 is fired by flowing a gate current through the gate of (8), the trip coil 7 is excited, the catch is opened, and the main contact 2 is opened.

Moreover, the earth leakage circuit breaker operates a thermal relay (not shown) to open the main circuit contact point (2) in case of an overcurrent accident, and an electromagnet (not shown) operates to open the main circuit contact point (2) for an instantaneous operation such as disconnection. . Further, reference numeral 14 denotes a nonlinear surge absorbing element connected in parallel to the primary end 4a of the auxiliary transformer 4, which absorbs and clips power supply noise.

Next, the detailed configuration and operation of the above-described control circuit 11 will be described with reference to FIG.

An input terminal of the stabilized power supply circuit 11a for outputting a reference voltage is connected to the + side power supply terminal P ₂ of the control circuit 11, and resistors 11b ₁ and 11b ₂ are connected to the output terminal of the stabilized power supply circuit 11a. ) Is connected to one power supply terminal (N ₂ ) to form a closed circuit. The input terminal A to which the secondary side of the image current transformer 9 of the control circuit 11 is connected is connected to the + side end of the comparator 11c, and the negative end of the comparator 11c is connected to the resistor 11b ₁ . (11 ₂ ) is in contact with the connection end. The input terminal B of the control circuit 11 is connected to one power supply terminal N ₂ together with one end of the series circuit of the resistors 11b ₁ and 11b ₂ .

The output terminal of the comparator 11c is connected to the hold terminal H to which the capacitor 13 is connected via the resistor 11d.

In addition, (11e) has a hydroxyl hysteresis characteristic to the input voltage is output to the output signal from (V _H) as shown in FIG. 3, and force the output signal until it falls to _{V L (V H> V L} ) In the hysteresis circuit 11e, the cathode of the thyristor 11f is connected as an input, and the anode of the thyristor 11f is connected with the hold terminal H and the cathode of the zener diode 11g. The anode of the zener diode 11g is connected to the gate of the thyristor 11f. The output terminal of the hysteresis circuit 11e is introduced into the terminal S of the control circuit 11 via a resistor 11h and connected to the gate of the thyristor 8.

In the operation of the control circuit 11 described above, the current signal of the AC sine wave caused by the short circuit accident occurring on the secondary side of the image current transformer 9 when a short circuit accident occurs on the load 3 side is caused by a voltage signal. Convert to When the voltage between both ends of the resistor 10 is equal to the positive side of the AC sine wave, the output voltage of the stabilizing power supply circuit 11a of the control circuit 11 is equal to or greater than the voltage divided by the resistors 11b ₁ and 11b ₂ . When a signal of logic level " 1 " is generated at the output of the comparator 11c, the capacitor 13 connected to the control circuit 11 is charged through a resistor in accordance with the signal. Next, when the voltage across the resistor 10 is equal to or less than the voltage obtained by dividing the stabilization power supply circuit output 11a of the control circuit 11 by the resistors 11b ₁ and 11b ₂ , the comparator 11c becomes a logic level ". 0 "is output, and the electric charge of the capacitor | condenser 13 discharges through resistance 11d and the comparator 11c.

In addition, when the voltage at both ends of the resistor 10 is equal to or greater than the voltage obtained by dividing the output voltage of the stabilized power supply circuit 11a by the resistors 11b ₁ and 11b ₂ , the logic level “1” is applied to the output of the comparator 11c. An output signal is generated, and the capacitor 13 is charged again through the resistor 11d in accordance with the signal. When the cycle is repeated and the voltage across the capacitor 13 gradually rises and the zener voltage of the zener diode 11g becomes abnormal, the gate signal is supplied to the thyristor 11f, and the thyristor 11f is turned on. Therefore, the capacitor | condenser 13 discharges through the thyristor 11f, and becomes the input signal VS of the hysteresis circuit 11e. The hysteresis circuit 11e sends a gate signal to the thyristor 8 via the resistor 11h by the input signal VS. Further, the hysteresis circuit 11e has the characteristics shown in FIG. 3 as described above, and the voltage at both ends of the capacitor 13 initially rises to (V _H ), and then becomes somewhat low, for example, (V Even if it is as low as _L ), the hysteresis circuit 11e sends a gate signal to the thyristor 8 through the resistor 11h. Accordingly, the thyristor 8 is surely turned on to excite the trip coil 7, and the catch is released to open the main circuit contact 2.

In the earth leakage breaker configured as described above, the time until the earth leakage accident occurs and the main circuit contact 2 opens, that is, the time delay can be adjusted by varying the capacity of the capacitor 13. When the capacitance of (13) is increased, the control circuit 11 is located in the path where the capacitor 13 discharges, and the control circuit 11 is usually formed of a single chip IC, and the thyristors 11f provided inside the single chip IC are provided. The allowable current value for electricity is tens of microamps, which is extremely small. Since the thyristor 11f is installed inside the control circuit 11, which is a one-chip IC, the current capacity cannot be increased, and since the thyristor 11f is destroyed according to the capacity, the capacitance can only be increased to about 0.05 microfarad (μF). There was little effect of time delay and only the effect of absorbing noise. Since the control circuit 11 using the thyristor 11f has to be provided with a separate circuit using an IC that is devoted to the demonstration effect, the number of parts for peripheral circuits also increases and the cost increases. In the case of a high speed leakage circuit breaker, since the circuit configuration is completely different from that of the demonstration type, there is a drawback that the standardization of the high speed type and the demonstration type is also significantly impaired.

The present invention has been made in view of the above circumstances, and it is possible to obtain a high speed operation type and a demonstration operation type without newly installing a control circuit IC for demonstration, and to provide an earth leakage breaker that facilitates standardization of products. It is purpose.

The earth leakage circuit breaker according to the present invention has a resistance connected between the secondary side lines of the video current transformer for determining the input voltage of the control circuit as the first resistor, and the hold voltage (H) of the control circuit The parallel circuit between the capacitor and the second resistor is connected in series, so that the first and second resistors can be simultaneously changed.

One embodiment of the present invention has been described with reference to the drawings. FIG. 4 is a circuit diagram showing an embodiment of the earth leakage breaker according to the present invention, and the power source 1 is the main circuit contact 2 of the earth leakage breaker. It is connected to the load 3 through the main circuit. The auxiliary transformer 4, in which the primary side stage 4a is connected in parallel to the main circuit, connects the secondary side stage 4b to the input terminal of the single phase full-wave rectifier 5, and the output stage P ₁ of the single phase full-wave rectifier. ) And (N ₁ ) are connected to the smoothing capacitor 6 and the series circuit of the trip coil and thyristor 8 connected in parallel with this.

On the other hand, between the secondary side lines of the image current transformer 9 having the main circuit as the primary side, the first variable resistor 15a of the double variable resistor 15 is connected in parallel to the input terminal of the control circuit ( It is connected to A) and (B).

The power supply terminals P ₂ and N ₂ of the control circuit 11 are connected to the output panels P ₁ and N _{1 of} the single-phase full-wave rectifier 5 via a resistor 12 in series. The control power is being obtained.

An anode of the diode 16 is connected to the hold terminal H of the control circuit, and a capacitor 14 connected in series with the diode 16 is connected to the cathode of the diode 16 of the series circuit. The second variable resistor 15b of the double variable resistor 15 is connected in parallel between the cathode and the capacitor 13 and connected to one power supply terminal N ₂ of the control circuit 11.

Further, since the detailed circuit diagram of the control circuit is the same as the conventional example shown in FIG. 2, the description thereof is omitted.

The power circuit breaker has a thermal relay and an electromagnet (not shown). The thermal relay operates in the event of an overcurrent accident to open the main circuit contact 2, and the electromagnet operates against momentary operation such as a short circuit. The main circuit contact 2 is open.

Next, the operation of the earth leakage breaker described above will be described with reference to FIG.

When an electric leakage accident occurs on the load 3 side of the main circuit, the electric current detecting current is detected by the image current machine 9 and converted into a voltage signal by the first variable resistor 15a. The control circuit 11 determines whether or not there is an error in accordance with the magnitude of the voltage signal. The configuration of this control circuit 11 is further described with reference to FIG.

The stabilizing power supply circuit 11a connects the cathodes of the first constant voltage diode 11a ₂ and the second constant voltage diode 11a _{3 to} both ends of the resistor 11a ₁ , and the anodes are connected together to control the circuit 11. Negative electrode terminal N ₂ ). The cathode of the first constant voltage diode 11a ₂ is connected to the input terminal of the comparator 11c via the terminal P ₃ of the control circuit 11 and the resistor 11b ₁ , and through the resistor 11e ₁ . It is connected to the negative input terminal of the comparator 11e _{5 in the} sheath circuit 11e. The hysteresis circuit 11e connects the middle points of the resistors 11e ₁ and 11e ₂ in series to the negative input terminal of the comparator 11e ₆ , and connects the resistors 11e ₃ and 11e ₄ in series. This intermediate point is connected to the + input terminal of the comparator 11e ₆ .

One end of the condenser 11e ₅ is connected to the + input terminal of the comparator 11e ₆ , and _one end of the resistor 11e ₁ is connected to a terminal P ₃ of the control circuit 11 and a thyristor (one end of the resistor 11e ₃ ). It connects to the cathode of 11f) and the anode of the zener diode 11g. The output of the comparator 11e ₆ is connected to the resistor 11h, and both of the resistors 11e ₂ (11e ₄ ) and one end of the capacitor 11e ₅ are connected to the negative terminal N ₂ of the control circuit 11. In addition to the stabilizing power supply 11a and the hysteresis circuit 11e, the control circuit 11 includes resistors 11b ₁ , 11b ₂ , 11d and 11h, a comparator 11c, a thyristor 11f, a zener diode ( 11g), the + input terminal of the comparator 11e is connected to the secondary input terminal of the image transformer 9 and the output of the comparator 11c is connected to the anode of the diode 16 at the hold terminal H via the resistor 11d. do. The resistors 11b ₁ and 11b ₂ are connected in series, and _one end of the 11b ₁ is connected to the resistor 11a ₁ of the stabilized power supply circuit 11a, and the midpoint is connected to the -input terminal of the comparator 11c. One end of (11b ₂ ) is connected to the negative electrode terminal N ₂ . The negative terminal N ₂ is connected to the input terminal B and one end of the capacitor 13. The resistor 11h is connected to the gate of the thyristor 8 at the output terminal S, the thyristor 11f and the zener diode 11g are connected in parallel with each other in reverse polarity, and the anode of the thyristor 11f is connected to the terminal H. .

Referring now to the operation of the control circuit 11, the control power supplied via the resistor 12 is stabilized by the first constant voltage diode 11a ₂ and supplied as the power of the comparators 11c and 11e ₆ . do. The output of the first constant voltage diode 11a ₂ is applied to the second constant voltage diode 11a ₃ via the resistor 11a ₁ , and again obtains a stable stabilizing power supply to obtain a -input short-circuit resistor of the comparator 11c. The divided voltage values by (11b ₁ ) and (11b ₂ ) are applied, and the divided voltage values by resistors 11e ₁ and 11e ₂ are applied to the input terminals of the comparator 11e ₆ .

Definition of Image Current Transformer 9 for Earth Leakage Detection A half-wave leakage signal is applied to the + input terminal of the comparator 11c. When this value is larger than the value of the input terminal, the capacitor 13 is interposed through the resistor 11d and the diode 16. ). In the negative half-wave section, the ground fault signal is discharged by the resistor 15b. When the capacitor 13 reaches about 2.5V after such charging and discharging continues, the thyristor 11f is turned on by supplying a gate signal to the thyristor 11f via the zener diode 11g. As a result, the output of the comparator 11c charges the capacitor 11e ₅ via the resistor 11d, the thyristor 11f, and the resistor 11e ₃ . The charging voltage of the capacitor 11e ₅ is applied to the + input terminal of the comparator 11e ₆ . When the voltage of the + input terminal is greater than the value of the-input terminal of the comparator, a logic level "1" is output to the output of the comparator 11e ₆ , and a gate signal is supplied to the thyristor 8 through the resistor 11h. By turning on, the trip coil 7 is excited to open the earth leakage breaker 2 inserted into the main circuit. When the voltage of the capacitor 13 drops below a certain value, the charge of the capacitor 11e ₅ passes through the diode 16 again through the forward conduction path of the zener diode 11g for the electrostatic voltage of the resistor 11e ₁ . Charge (13). Therefore, the charge of the capacitor 11e ₅ is rapidly discharged. The voltage at the + input terminal of the comparator 11e ₆ is lower than the voltage at the + input terminal, and the output of the comparator 11e ₄ is at a logic level " 0 ". Since the resistance values of the resistors 11d and 11e ₄ are largely about 750 K? To 1 M ?, the amount of discharge through the resistors 11d and 11e ₄ is not small. For this reason, the output voltage of the capacitor 13 hisi hysteresis circuit (11e) by a voltage level, as shown in FIG. 3, the input voltage level of the V _H of being held, hold until the input voltage V _L level Since the state continues and the hold is released below the V _L level, a spherical hysteresis characteristic as shown in FIG. 3 can be obtained. When a certain voltage, that is, the input operating voltage of the control circuit 11 is about 5 mV or more, current flows from the horn terminal H of the control circuit 11 and charges the capacitor 13 through the diode 16. When the voltage across the first variable resistor 15a, that is, the input operating voltage of the control circuit 11 is about 5 mV or less, the charge charged in the condensation 13 does not flow from the diode 16 to the control circuit 11. Discharge is performed through the second variable resistor 15b.

When the voltage between both ends of the first variable resistor 15a, that is, the input operating voltage of the control circuit 11 is about 5 mV or more, current flows through the diode 16 at the hold terminal H of the control circuit 11. Then the capacitor 13 is charged again. If the hold terminal H of the control circuit 11 reaches a predetermined voltage, for example 2.5V, after a certain time has elapsed by the cycle of charging and discharging the capacitor 13 repeatedly, the control circuit 11 A gate signal is sent to the thyristor 8 at the output terminal S of the N, and the thyristor 8 is turned on to excite the trip coil 7 to release the catch to open the circuit contact 2.

Next, the operation by the operation of the double variable resistor 15 will be described.

When the first variable resistor 15a of the double variable resistor 15 is rotated in the direction of increasing the resistance value, the operation sensitivity current decreases. At this time, since the second variable resistor 15b also rotates in the direction of increasing resistance as with the first variable resistor 15a, the discharge time of the electrons in the capacitor 13 is shortened, making it difficult to discharge the capacitor 13 The demonstration time related to the charging and discharging of the i) becomes short. The state corresponds to the curve 1 showing the sensitivity current I (mA) on the horizontal axis of FIG. 5 and the demonstration time T (m sec) on the vertical axis. On the contrary, when the first variable resistor 15a and the second variable resistor 15b of the double variable resistor 15 are rotated in the direction of decreasing the resistance value, the sensitivity current I (mA) and the time demonstration time T (m sec) are reduced. It changes, and moves in the direction of (2), (3) in the figure to increase the operating sensitivity current, so that the operation time also becomes slow.

According to the first embodiment and the earth leakage breaker described above, the sensitivity current and the demonstration time can be arbitrarily set without separately installing a dedicated IC for giving a demonstration action. It can be used and standardization is extremely easy.

In this embodiment, the demonstration operation is performed by installing the diode 16 and the second variable resistor 15b at a portion not related to the input of the control circuit 11, so that a new capacitor is used to absorb the noise. Even when it is necessary to connect, it is easy to connect because it is independent of the input, and its effect is great.

As shown in FIG. 6, in the power system, the power source 1 is connected to the main earth leakage breaker A, and is connected in parallel with the branch earth leakage breaker B as a load of the main earth leakage breaker A. FIG. In the case of connecting the branch circuit breaker C and connecting the loads 3a and 3b to the branch circuit breakers B and C, in the case of connecting the main circuit breaker A to the branch circuit breakers B and C, If the demonstration time is later than that, i.e., the branch circuit breakers (B) and (C) are operated at high speed, the protection cooperation of the power system can be achieved.

In the above power system, when a large current is energized, the absorption capacity of the noise can be increased for the unbalanced current and for the noise, so that the capacity of the capacitor 13 in each leakage circuit breaker unit can be increased, thereby preventing malfunction.

Next, a second embodiment of the present invention will be described with reference to FIG. Since the detailed circuit of the control circuit 11 in FIG. 7 is the same as FIG. 2, the description is abbreviate | omitted and the same code | symbol is attached | subjected to the same part as FIG. 4, and the description is abbreviate | omitted. The second embodiment differs from the first embodiment in that resistors 17a, 17b, 17b <17a are connected in series between the secondary side lines of the video current transformer 9, and the resistors 17a, The value of the resistor 17 connected between the input terminals A and B of the control circuit I1 by providing the first tap-changer 18a of the double tap-changer 18 at the connection point between 17b. It was possible to switch.

In addition, the capacitor 16 is connected in series with the diode 16 connected to the hold terminal H of the control circuit 11 and the one-side power supply terminal N ₂ of the control circuit 11. Resistors 19a, 19b, and 19b <19a are connected in series to the connection point between the diode 16 and the capacitor 13, and the double tap is connected to the connection point between the resistors 19a and 19b. The second tap changer 18b of the switch 18 is connected, and the value of the resistor 19 connected in parallel to the capacitor 13 can be switched.

Next, the operation of the second embodiment will be described. That is, when a short circuit fault occurs on the load 3 side when the double tap-changer 18 is in the state as shown in FIG. 7, the secondary current of the video current transformer 9 receives an alternating current signal of an AC sine wave due to a short circuit. Flows and is converted into a voltage signal by the resistor 17a. By the magnitude of the voltage signal, the control circuit 11 determines whether or not a short circuit is compared with the reference voltage as described in detail in FIG. In this case, since the resistor 17a having a large resistance value is connected between the secondary side lines of the video current transformer 9, the voltage at both ends of the resistor 17a, i.e., the input voltage of the control circuit 11, at the positive side of the AC sine wave. If this is about 5 mV or more, current flows from the hold terminal H of the control circuit 11 at that time, and thus the capacitor 13 is charged through the diode 16. Next, when the voltage at both ends of the secondary resistor 17a of the video current transformer 9 becomes less than or equal to the reference voltage of the control circuit 11, no current flows from the hold terminal H of the control circuit 11, while the capacitor The charge of (13) is not discharged in the control circuit 11 by the diode 16, but only through the resistor 19a.

Next, when the positive half wave of the AC sine wave flows to the secondary side of the video current transformer 9 again, the voltage at both ends of the resistor 17a becomes larger than the reference voltage of the control circuit 11, and the capacitor 13 is discharged. If the above-mentioned cycle is repeated and the voltage at both ends of the condenser 13 is more than a predetermined value, the control circuit 11 causes the gate current to flow through the gate of the thyristor 8 at the output terminal S, and the thyristor 8 is fired. The trip coil 7 is excited to open the main circuit contact 2.

Next, when the double tap-changer 18 is switched, the first tap-changer 18a causes the resistance 17b to enter between the secondary side lines of the image current transformer 9, and simultaneously with the second tap-changer 18a. The resistor 19b enters the condenser 13 in parallel by the switch 18b. In that case, the input voltage of the control circuit 11 becomes smaller than that of the resistor 17a, and the discharge amount of the capacitor 13 charge becomes larger than that of the resistor 19. Therefore, the time required until the voltage between both ends of the capacitor 13 reaches a predetermined value is increased, thereby realizing an earth leakage breaker with a long demonstration time.

As described above, as the double tap changer 18 is switched, the resistors 19a and 19b are switched, the input voltage of the control circuit 11 is varied, and is connected to the control circuit 11. Since the charging time of (13) is variable, an earth leakage breaker can be realized without using a new IC chip of the demonstration type control circuit 11, that is, a combination of a small number of parts and a low cost high speed type and a demonstration type. Furthermore, the second embodiment has the same effect as the first embodiment in addition to the above-described effects.

Next, a third embodiment of the present invention will be described with reference to FIG. 8, and since the detailed circuit of the control circuit 11 is the same as that of FIG. 2, the description thereof will be omitted. The description is omitted. The third embodiment differs from the first and second embodiments in that the resistor 20 is connected between the secondary side lines of the video current transformer 9, and the hold terminal H and the one-side power supply terminal N of the control circuit are connected. _The capacitor 13 and the resistor 21 connected to ₂ ) are connected in parallel, and the resistance values of the resistors 20 and 21 can be exchanged arbitrarily.

In the third embodiment, resistors 20 and 21 having relatively low resistance values are used in the case of the demonstration type leakage circuit breaker, and resistors 20 and 21 are used in the case of the high speed leakage circuit breaker. 21) Use a relatively high resistance.

The application effect of the third embodiment described above is the same as that of the first and second embodiments, and thus description thereof is omitted.

The present invention described above is not limited only to the above embodiment, but can be modified in various ways.

According to the present invention described above, a high speed operation type and a demonstration operation type can be obtained without providing a new control circuit IC for demonstration, and an earth leakage breaker can be provided that facilitates standardization of products.

Claims (1)

The power supply 1 is connected to one of the main circuit conductors provided with the main circuit contact 2, the load 3 is connected to the other side, and an image current transformer 9 having the main circuit conductor as the primary side is provided. A first resistor 15a is connected between the lines of the secondary side of the video current transformer, and when a short circuit fault occurs in the load, a ground fault detection current flows to the secondary side of the current transformer to transmit the current signal to the first side. When the resistance is converted into a voltage signal, and this exceeds the preset reference voltage, the DC current is charged to the capacitor. When the voltage across the capacitor exceeds the predetermined value, the trip coil is excited to open the main circuit contact point. In the earth leakage breaker having the control unit 11, The anode of the diode 16 is connected to the positive terminal on which the capacitor 13 is connected to the control unit, and the cathode of the diode is connected to one end of a parallel circuit of the capacitor and the second resistor 15b, and the other end thereof is connected. A ground fault circuit breaker, characterized in that the resistance of the first (15a) and the second (15b) can be simultaneously varied by connecting a negative electrode to which a capacitor (13) is connected to a terminal.