NL7905943A - ERROR POWER PROTECTION SWITCH. - Google Patents

Description

N / 29110-St / lb \ "#

Facts & Guilleaume Fabrik elektroner Apparate AG in Schrems-Eugenia and Gottfried Biegelmeier in Vienna, both Austria.

Fault current protection switch.

The invention relates to a fault current protection switch.

Fault-current circuit-breakers originally served to protect AC-powered devices 5 and installations from isolation faults. In the state of the art at the time, for these devices, when an insulation fault occurred, only pure alternating current fault currents had to be taken into account, with a few exceptions, such as, for example, in the protection of installations in which cathodic corrosion protection was applied, or railway company, so in those cases that pure DC currents could flow through the residual current circuit breaker.

In recent years, the situation has changed to such an extent that the use of semiconductor components for electronic control devices is increasingly utilizing operating means which cause fault currents with direct current components 20 in the event of faults and which therefore cause the operation of the conventional fault current protective circuit breakers. can disturb.

As far as is known, this has not yet led to accidents, because the simultaneous occurrence of the necessary conditions is unlikely, but the fault current protection technology must nevertheless take into account the changing conditions in electrical installations and develop a fault current protection switch, which also when fault currents consisting of direct current occur.

30 If one examines the possibilities for interference with electronically controlled operating equipment, it appears that the possibly occurring fault currents usually take the form of pulsating half-wave currents. It is true that with single-phase rectification with smoothing capacitors 5 and with three-phase rectifying circuits in the event of a fault, a smoothed DC current can also occur, but a careful examination of the fault possibilities shows that this fault current consisting of a DC current always occurs suddenly, so that it does not slow down. calculating fault currents of the direct current type have to be taken into account. As a result, it remains possible to apply the long-proven principle of fault current protection using a summation current transformer in these cases as well.

The problem, therefore, is that a new fault current protection switch must be developed, which, even with pulsating direct currents and with suddenly occurring smoothed direct currents, trips independently of its direction. In this case, circuits must be used which operate independently of the mains voltage, because only then the required operational reliability and long service life of the safety switch are guaranteed.

With switches currently available on the market 25. in the above-mentioned cases, the switch-off is not certain, because the summing transformer is premagnetized by an error current having a DC current proportion. Thereby, the flux change caused by the alternating current portion of the fault current is reduced and can become so small that in the secondary winding of the summation transformer the induced voltage is insufficient to trigger the fault current trip of the switch. German patent 716,585 has already indicated attempts to increase the 790 5 9 43 - 3 response sensitivity of fault current circuit breakers, at least with pure alternating current magnetization, by switching a capacitor between the secondary winding of the summation current transformer and the excitation winding of the fault current tripping device. The vibration chain formed thereby is tuned to the operating frequency of the current circuit to be monitored.

Such a circuit is described in Austrian Patent Specification 318,052, in which, however, pulsating direct current fault currents are determined with the aid of a vibration circuit which is tuned to the frequency of the voltage applied in the secondary winding by the pulses in the primary windings. pulsating direct current flowing from the summing transformer is induced. However, the operation of this circuit is not satisfactory for the following reasons: while in the case of the circuit breaker according to German patent 716,585 the mains frequency is fixed and therefore the tuning of the vibration chain to this frequency is readily possible, secondary voltage upon energization of the summing current transformer with pulsating DC currents from a long range of different frequencies, as can be easily determined by Fourier series decomposition. However, the vibration circuit of the circuit 25 according to said Austrian Patent Specification 318,052 can only be tuned to a single frequency. Moreover, the optimum setting when responding to pulsating direct currents depends not only on the resonant state in the vibratory circuit at a given frequency, but also on the mechanical construction of the fault current trip device, in particular on the inertia of its armature. Namely, the action of the secondary current on the excitation winding should continue long enough, if possible, in each half-period to allow the lifting or pulling of the armature thereof depending on the operation of the tripping device. 790 5 9 43 4> to make.

German "Auslegeschrift" 2,336,260 / which describes a circuit breaker with a summation current transformer provided with a tertiary winding, is based on a completely different problem. Two opposing diodes and possibly an RC member are connected to this tertiary winding, whereby it is to be avoided that an undesired shutdown occurs, which is the result of short-term capacitive charging currents, which are as fault currents when switching power circuits, the capacity of which against earth is great can occur.

Finally, German "Auslegeschrift" 2,811,064 describes a fault current protection switch, which is also provided with a summing current transformer with tertiary winding, which is connected to a capacitor. Therefore, approximately at the mains frequency, the inductance text of the windings and of the tripping device must be approximately compensated. The tertiary winding then has a number of turns that is at least ten times the number of turns of the secondary winding. It is hereby achieved, though, that a small capacitance for the compensation capacitor can be used without the number of turns of the fault current tripping device having to be chosen too high, but on the other hand, the required relatively large number of turns. Many turns of the tertiary winding cause the voltage at the capacitor to be unnecessarily high. After all, fault currents can also occur as short-circuit earth fault currents and the high voltage peaks occurring in that case in the tertiary winding pose a danger to the capacitor.

In order to obtain a long life of the capacitor and thus the desired and long-term reliability of the operation of the safety switch 35, the voltages occurring on the capacitor must therefore be kept as small as possible. This is possible in 790 5 945 5 more, now that with the modern capacitor technology also large capacitance values with small dimensions and low capacitor prices can be realized. The optimum dimensioning for the tertiary winding will then have to be such that, if the transformation ratio is not too great compared to the secondary winding, sufficient compensation effect of the capacitor used is obtained. First, it must be considered that the capacitance of the capacitor connected to the tertiary winding and required for the compensation is inversely proportional to the square of the number of turns. Therefore, if the tertiary winding has a number of turns that is at least three times the number of turns of the secondary winding, then the required capacity already drops to about one tenth of the value required if the capacitor is connected directly to the secondary winding. winding would be connected. As discussed above, however, in view of the life of the capacitors, the operating voltage which occurs on the tertiary winding should not be chosen so high that the tenfold voltage value of the operating voltage of the secondary winding is achieved. This is therefore already favorable, because otherwise capacitors with a high nominal voltage must be chosen, which have larger dimensions and are more expensive. The number of turns of the secondary winding is determined by the adaptation to the excitation winding of the fault current trip device. It should be borne in mind here that, as has already been noted, the switch must also act independently of the direction of the current when a smoothed direct current occurs suddenly. This is best achieved by using a tripping device which has an excitation circuit without an air gap for the excitation flux. The excitation winding must be 35 or applied manually and therefore must have less than one hundred turns. Because of the modification already mentioned 790 5 9 43 i 6, the secondary winding must then be carried out with an even smaller number of turns, this winding being able to be carried out even with only a single piercing winding. Therefore, for the reasons discussed above, the tertiary winding must have a number of turns that is three to nine times the number of turns of the secondary winding.

The invention therefore relates to a fault current protection switch, with a switch lock operating the switch contacts 10, which is controlled by a switch-off device acting on a fault current, the excitation winding of which is on the secondary winding of a summing current transformer included with its primary windings in the current circuit to be protected. connected. In accordance with the foregoing, such a residual current circuit breaker according to the invention is now characterized in that the residual current trip device is provided with an excitation circuit without air gap and with an excitation winding having less than one hundred turns, while the summation current transformer has an added tertiary winding, which is connected in series with a compensating capacitor in order to increase the response sensitivity of the safety switch when a pulsating direct current containing fault currents occurs, the number of turns of the tertiary winding being three to nine times the number of turns of the secondary winding amounts.

According to an embodiment of the invention, it is thereby possible to design the secondary winding and the tertiary winding as an inductive voltage divider in the form of a tapering winding for the connection of the excitation winding of the fault current trip device.

The drawing shows embodiments of the residual current circuit breaker according to the invention 790 5 9 43 7.

Fig. 1 shows the schematic of a first embodiment of the safety switch; and Fig. 2 schematically shows part of another embodiment of the switch.

The fault current protection switch shown in Fig. 1 has a switch lock 1, which can open the switch contacts 4 if the installation to be protected is to be disconnected from the mains in the event of an error current occurring. The switch lock 1 can again be unlocked in a conventional manner by a switch-off member 2 which is responsive to such an error current. This tripping member 2 has a magnetic excitation circuit without air gap, the excitation flux being generated by an excitation winding 3. This excitation winding 3 is directly connected to the secondary winding 9 of a summing current transformer 7, the primary windings 8 of which are incorporated in the supply lines of the installation to be protected, so that the operating current flows through these windings 8. A tertiary winding 10, which is directly connected to a compensation capacitor 11, is provided on the summation current transformer 7. The fault current protection switch is still designed in the usual manner with a test current circuit 5. The said parts of the switch are housed in a housing, not shown, which is provided with connection terminals 6.

The number of turns of the excitation. winding 3 of the trip member 2 is less than 30 hundred, while the number of turns of the tertiary winding 10 of the summing current transformer 7 is three to nine times the number of turns of the secondary winding 9 of this transformer.

In the embodiment of the switch 35 shown in FIG. 2, the secondary winding 9 and the tertiary winding 10 of the summation current transformer are shown. Figure 8 of FIG. 1 is now designed as an inductive voltage divider in the form of a transformer winding 12, which has a tap between its ends. The energizing winding 3 of the tripping member 2 is connected to this tap and to the nearest end of the winding 12, while the compensation capacitor 11 is connected to both winding ends of the voltage divider.

790 5 9 43

Claims (2)

9. 1. Fault-current circuit-breaker with a switch-lock operating the switches contacts, which is controlled by a fault-current-tripping switch, the excitation winding of which is connected to the secondary winding of a summation current transformer included with its primary windings in the current circuit to be protected, with the characterized in that the fault current tripping device (2) is provided with a magnetic excitation circuit without air gap and with an excitation winding (3), which has less than one hundred windings, while the summing current transformer (7) has an added tertiary winding (10) which is connected in series with a compensating capacitor (11) in order to increase the response sensitivity of the protection switch when a pulsating direct current containing fault currents occurs, the number of turns of the tertiary winding (10) being three- up to nine times the number of turns of the secondary winding (9) of the summation current transformer 20. Fault current circuit breaker according to claim 1, characterized in that the secondary winding (9) and the tertiary winding (10) of the summation current transformer (7) are designed as an inductive voltage divider in the form of a winding (12) with tap-off for the connection of the excitation winding (3) of the fault current release (2) (fig. 2). 790 5 9 43