DE3718183A1 - DIFFERENTIAL CURRENT SWITCH - Google Patents

Abstract

The residual current device is provided with a summing current transformer whose secondary circuit contains a rectangular waveform generator, a measurement resistor and an electronic evaluation device. According to the invention, the secondary voltage (U1) and a control voltage (U2) are specified as input signals to the coupling switch (19). The coupling switch (19) contains one sensor (30, 30') and a tripping lock (40) for the tripping device (11), for each of these input signals (U1, U2). This residual current device is insensitive to brief, random surge currents and surge voltages (voltage spikes) which are produced, for example, by a lightning strike, even with a relatively low current intensity. <IMAGE>

Description

The invention relates to a differential current protection scarf ter according to the principle of a transducer circuit with a sum current transformer, whose secondary winding with a complex Measuring resistor and a rectangular generator connected in series is. The secondary circuit also contains an electronic off evaluation whose output ver with the trigger of a switch is bound.

Transductor circuits with a summation current transformer, which as controllable throttle acts are known (Hartel / Dietz, Trans duct circuits, Springer-Verlag 1966, page 62 ff). Here the secondary side of a transducer circuit is replaced by a applied, high-frequency AC voltage close to the satti limit alternating magnetized.

A series resistor is connected in series with the secondary winding stood arranged on the signals for an electronic off evaluation can be tapped. If by the primary If a total current flows, its ma overlap magnetic voltage and that of the alternating current in Total current transformer, leading to periodically increased ampere turns pay leads. This will exceed the saturation limit and the inductive resistance of the secondary winding becomes smaller. As a result, the voltage amplitude across the measuring resistor greater. In the evaluation, the voltage across the measuring resistor compared with an adjustable threshold voltage and at If this threshold voltage is exceeded, the trigger of a scarf ters activated, which then the line to be monitored under breaks.  

Residual current circuit breakers require one in the secondary winding induced voltage that is so great that the span voltage amplitude at the measuring resistor increased significantly and thus si cher is triggered. Therefore, the total current in the A corresponding magnetic field is generated in primary windings, a given number of turns for a given current which requires primary windings. With a complex, predominantly capacitive measuring resistor in the secondary circuit of the Sum current transformer is only required one at a time Winding of the primary windings (E-OS 01 67 079).

The evaluation can preferably be a first stage from a Rectifier and an integrator and a downstream second stage from a threshold switch included, zwi those of the coupling switch that can be switched against reference potential is connected as a sensor and lock. The coupling switch is controlled by a potential that is between the rectangle generator and the measuring components of the secondary circuit will. It contains a timer, a galvanic door and a blocking for the evaluation circuit, which the voltage at the measuring resistor is given as an input signal is.

The Pro occurs with sensitive residual current circuit breakers Blem up that even with temporary surge currents or Surge voltages, for example due to lightning or when Switching of consumers on long supply lines can occur the trigger of the associated switch.

The invention is based on the object of this known Switch to improve that short-term surge fault currents are not to trigger the switch, in particular a ge Precise setting of the trigger value regardless of the current direction of a fault current may be possible. Furthermore, the Triggering of the switch by surge currents and surge voltages  less bumps are avoided.

This object is achieved in that a Kop Pel switch is provided, the secondary voltage and a Control voltage are specified as input signals and for these input signals each have a sensor for surge currents or Surge voltages and a trigger controlled by the sensors lock for the trigger of the switch contains. The belt scarf ter blocks in the event of an interfered surge fault current with a larger one Amperage and short duration during an adjustable short Time the triggering of the switching device. The differential current Circuit breaker is therefore insensitive to short impact errors currents. In this embodiment, the differential current switch is obtained depending on the phase position of the surge current i gnals for alternating magnetization of the rectangular generator Raising current-related signal increase either at the secondary winding or on the measuring resistor or on the measuring components. That is why an interference suppressor is used, these two signals processed separately, even for relatively small ones Surge currents effective. The invention is based on the knowledge that that a decrease in alternating magnetization at the second därwick a corresponding increase in the voltage on the Measurement components and vice versa. This increase in Secondary voltage or the measuring voltage is in the coupling switch processes and leads to blocking of the trigger via a adjustable time.

The trigger lock, preferably one for the two sensors common electronic release lock, can both in the sec därkreis the sum current transformer as well as on the electronics analysis take effect. For example, you can Interrupt measuring circuit or a blocking potential at the Create measuring circuit. Furthermore, it can affect the alternating magnetism the secondary winding of the rectangular generator, for example by blocking the rectangular generator.  

In a special embodiment of the residual current protection switch can trigger the electronic evaluation lock can be blocked by, for example, the input span voltage or the supply voltage of the evaluation is interrupted becomes. A particularly simple embodiment consists in that the trip lock the input voltage of a threshold switches in the evaluation below the threshold and so that a signal blocks the trigger of the switch.

To further explain the invention, reference is made to the drawing Reference is made to an embodiment of a difference current switch according to the invention schematically illustrated is.

The residual current circuit breaker shown monitors an outer conductor L and a center conductor Mp , which each form a single primary conductor 3 or 4 of a summation current transformer 2 . The secondary circuit of the summation current transformer contains a series circuit of a rectangular generator 5 with a block capacitor 6 which , after reaching its stationary voltage, only passes alternating currents and blocks DC components, and the secondary winding 7 of this summation current transformer. With the secondary winding 7 connected in series are also measuring components with a predominantly ohmic damping resistance 8 of, for example, 1 kΩ and an attenuator 81 with a capacitive resistance of, for example, 1 / ω × C = 3 k Ω and an ohmic damping resistance of, for example, 10 k Ω Damping of vibrations between the inductance of the secondary winding 7 with the capacity of a complex, mainly capacitive measuring resistor 9 . The voltage at the measuring resistor 9 was an electronic evaluation 10 as input signal, the unspecified output to the trigger 11 of the switch 12 of a switch 14 is connected. The evaluation 10 essentially contains a series circuit comprising a rectifier and integrator 101 with a capacitor and a threshold switch 102 and an evaluator 103 .

The evaluation 10 is assigned a coupling switch 19 , which also serves as a sensor and a lock for the evaluation 10 and which in the case of a briefly interspersed fault current in the form of a surge current or a surge voltage via its output 46, the signal processing between the secondary winding 7 and the trigger 11 blocks. It can preferably block the evaluation circuit 10 for a time that can be set in the coupling switch 19 , for example by discharging the capacitor in the integrating element 101 and thus by lowering the input voltage of the threshold value switch 102 .

The coupling switch 19 can contain an optocoupler, which acts in its control circuit as a sensor 30 for the surge currents.

For this purpose, the secondary voltage U _{1 of} the sensor 30 is fed to a timing circuit which contains an input rectifier 191 and a timing element which consists of an RC element 193 and a current limiting resistor 194 and which is connected upstream of an op-coupler 195 , the output signal of which has a trip lock 40 operated.

The optocoupler 195 has the advantage that there is complete electrical isolation between the control and working sides, so that even high surge currents on the secondary side cannot lead to voltage fluctuations. An optocoupler is therefore suitable as a sensor for very high and very steep surge currents.

Another timing circuit 30 'leads to the measuring voltage U ₂ . The measuring voltage used is at least the voltage across the measuring resistor 9 , preferably the entire voltage across the measuring components, namely the total voltage across the damping resistor 8 , the attenuator 81 and the measuring resistor 9 . It contains the same elements that are designated in the figure with 191 ', 193', 194 ' and 195' . The two load circuits of the phototransistors of the optocouplers 195 and 195 'which are not shown in the figure are connected via a relatively small limitation resistor 197 of, for example, 20 ohms to the input terminal 198 of a positive supply voltage.

The trip lock 40 contains as a time control an RC element from a capacitor 42 and a discharge resistor 43 of, for example, 1 kOhm, which are arranged in the control circuit of a transistor 44 , the load current of which was a limiting resistor 45, the evaluation 10 blocks the capacitor 41 during the discharge time of the capacitor 41 . The capacitance of the capacitor 42 and the size of the discharge resistor 43 are selected so that the discharge time of the capacitor 42 , which determines the time at which the evaluation 10 is blocked, is approximately 1 to 5 ms. In the event of the control of one of the optocouplers 195 or 195 ', the capacitor 42 is relatively quickly over the relatively small limitation resistor 197 , for example within a few microseconds, charged and then discharged via the control path of the transistor 43 in at least a few milliseconds. The load current of the transistor 44 through the limiting resistor 45 discharges the capacitance in the integrator 101 of the evaluation 10 and thus temporarily lowers the input voltage at the threshold switch 102 , so that the evaluation 10 is blocked during this time.

In the diagram of Fig. 2 is the secondary voltage U _1, consisting essentially of the deformed by the electrical components in the secondary circuit square wave voltage U _1, t dependence plotted on the time. At time t ₁ , for example, a surge current should occur in the primary circuit of the summation current transformer 2 , which induces a voltage pulse U ₁ 'in the secondary winding 7 , which counter-directional value of the square-wave voltage U _{1 of} the square-wave generator 5 is opposite. Since this voltage pulse U ₁ 'does not exceed the square-wave voltage U ₁ , the optocoupler 195 in the sensor 30 is not controlled with this pulse.

In contrast, the counter voltage in the secondary circuit is reduced by this voltage pulse U ₁ '. Due to the correspondingly increased secondary current in accordance with the 3 also Spannungsim U pulse ₂ 'of the control voltage U ₂ to the measuring components increases FIG.. This voltage pulse U ₂ 'goes beyond the maximum voltage U ₂ generated by the square wave generator 5 and is effective for controlling the sensor 30 '. By this voltage pulse U ₂ 'is via the rectifier 191 ' and the RC element 193 ', the resistor and capacitor together with the limiting resistor 194 ' are chosen so that the discharge time is, for example, about 100 ms, the optocoupler 195 'is controlled. The discharge time of, for example, 100 ms determines the length of time that must elapse before a subsequent surge current signal can cause the optocouplers to switch again. This ensures that the residual current circuit breaker is triggered by continuous surge currents. The capacitor 42 of the trip lock 40 is charged via the limiting resistor 197 . It discharges via transistor 44 and the output signal at output 46 blocks evaluation circuit 10 .

As shown in FIG. 4 at time t ₁ in the secondary winding 7 of the converter 2 by a surge voltage, a voltage pulse U ₁ '' having the same direction as the instantaneous value of the square-wave voltage U ₁ induced, so this voltage pulse is increased during the time t ₁ to t ₂ of for example, about 50 to 100 microseconds the rectangle voltage and this signal actuates the trip lock 40 via the optocoupler 195 of the sensor 30 , whereby the capacitor 42 is discharged and the evaluation 10 is also blocked. Dage gene does not lead to an actuation of the sensor 30 ' during this time the voltage pulse U ₂ ''according to FIG. 5. Thus, the surge voltage is the evaluation 10 either by the secondary voltage U ₁ or by the control voltage U ₂ blocked to change the magnetization in the secondary circuit of the summation current converter 2 depending on the phase position.

Claims (3)

1. Residual current circuit breaker according to the principle of a transducer gate circuit with a summation current transformer, the secondary winding of which is connected in series with a complex measuring resistor and a rectangular generator, and whose secondary circuit contains an electronic evaluation, the output of which is connected to the trigger of a switch, characterized by that the secondary voltage (U ₁₎ and a control voltage (U ₂₎ a coupling switch (19) are given as a output signals, the voltages in each case a sensor (30 ', 30) for surge currents or surge clamping for those input signals and a controllable from the sensors Trigger lock ( 40 ) for the trigger ( 11 ) contains. 2. Residual current circuit breaker according to claim 1, characterized in that the output signal of the trip lock ( 40 ) for blocking the evaluation ( 10 ) is provided. 3. Residual current circuit breaker according to claim 1 or 2 with measuring components in the secondary circuit, characterized in that the voltage at the measuring resistor ( 9 ) and at least some of the measuring components ( 8 , 81 ) of the secondary circuit is provided as the control voltage ( U ₂ ).