NL8102641A - ERROR POWER PROTECTION SWITCH. - Google Patents

Description

N / 30270-St / lb * *

Fault current protection switch.

The invention relates to a fault current protection switch consisting of a contact device, a switch lock with freewheel and operating device, a summing current transformer, an electronic energy accumulation circuit and a fault current switching device with a permanent magnet, which parts are provided with insulating material. terminals are housed.

Fault-current protection circuits have been used for decades, but can still be improved in several respects.

The three basic circuits possible for the construction of fault current circuit breakers have been indicated more than twenty years ago. The then recommended fault current circuit breaker with impulse or energy accumulation trip, as described in Austrian Patent 197,468, French Patent 1,202,203 and British Patent 841,181, has been installed in large numbers in Austria, among others, and has proven to be reliable. At the time, a glow lamp was used as a switching element in the energy-accumulation circuit, so that this solution was expensive (large number of turns of the secondary winding of the summation current transformer) and took up too much space. Although these switches had advantages in terms of reliability and characteristic, because the energy available for tripping was considerably higher than with the directly operating circuits without electric energy accumulation, the competition led to ever lower prices and smaller dimensions of the fault currents. -30 circuit breakers with the result that the impulse switch-off was only used for special switches (eg with neutral-circuit breakers). At the time, business arguments were also used in this competitive battle, such as the desirability of extremely short switch-off times, which of course leads to difficulties in energy accumulation circuits.

The studies of modern electropathology indicate 8102641 1 ** "* - 2 - however, that for the protection against direct and indirect contact the tripping time of the safety switch, provided it is less than 0.2 s, is of no particular significance Too short switch-off times 5 and unnecessarily high response sensitivities only lead to Unnecessary disconnections due to self-permissible diversion currents or when switching cables and when atmospheric overvoltages occur, especially in the case of air supply networks this often results in economic damage occurred, for example due to the failure of freezers.

More important is reliable operation of the safety switch and in this respect the development described above has led to unfavorable results. More and more sensitive tripping devices have been developed, whereby the manufacturing problems and environmental influences can hardly be controlled anymore.

When testing the current installations, it often appears that a few percent of the built-in fault current protection switches do not work properly. That is an unsustainable situation, which is of great concern.

A solution to this serious problem provides, on the one hand, the introduction of the zero point connection, which together with fault current circuit breakers enables a very high-quality and reliable protection measure in the form of the so-called zero protection circuit, and, on the other hand, provides in networks in which this zero point connection is not permitted, the application of a series circuit of two fault current protection switches.

Of course, the underlying switch must thereby selectively switch, which means that in the event of an error only the installation protected by this switch is switched off and the safety switch placed in front of it, which protects a number of installations, remains switched on. This requirement can be easily met by the energy accumulation circuit. This circuit also avoids the above-mentioned unnecessary trips due to atmospheric overvoltages and even allows the installation of surge arresters behind the fault current protection switches. When the f 8102641 * * - 3 - surge arrester trips, current flows briefly (within 10 ms) from the mains to earth / which would cause a fault current protection switch with direct shutdown without electrical energy accumulation circuit to speak -5.

The residual current circuit breaker of the type mentioned in the opening paragraph is now characterized according to the invention in that the summation current transformer has a core of a magnetic material with high permeability, the retentive inductance of which is less than 40% of the saturation inductance (measured statically) and of which the secondary winding has more than one hundred turns and is connected via an electronic energy accumulation circuit independent of the mains voltage to the fault current-switching device of the switch lock, the energy accumulation circuit consisting of a capacitor which is connected over an appropriate rectifying circuit depending on the fault current is charged by the summation current transformer and which, when a certain charging voltage is reached, discharges impulse through a voltage-dependent semiconductor element through the trip coil of the fault current disconnecting device and thereby trips the fault current protection switch chops.

Recently, semiconductor devices 25 have become available, which are inexpensive and small in size and therefore suitable for replacing the glow lamp as a switching element. With switching voltages of approx. Ten volts, they enable small secondary winding numbers of the summation transformer and at -30 randomly selectable switch-off characteristics of the circuit breaker. In order to also keep the capacitor small, it is advantageous to use a permanent magnet switch-off device, which switch-off device is less critically adjustable and that one can operate with 35 greater switch-off forces than is the case with the directly operating circuits without electric energy accumulation. . By choosing the number of turns of the secondary winding of the summation current transformer greater than one hundred turns 40, economically favorable core dimensions of these transients are 8102641

V- · V

- 4 - • Formator has obtained a form of the tripping characteristic of the safety switch that is favorable for contact protection. The excitation winding of the permanent magnetic switch-off member must have a number of turns 5, which for this switch-off member provides the most favorable form of the switch-off pulse for the discharge of the capacitor. According to the invention this can be most easily achieved with a so-called polarized permanent-magnetic switch-off member, the magnetic circuit of which has an air gap. As a result, the excitation winding can be manufactured on a winding machine and the manufacture can be largely automated.

A modern fault current protection switch must also control the tripping of pulsating DC currents. Hitherto, fault-current protection switches could only operate with alternating current. If the fault current has direct current components, the tripping sensitivity of the safety switch is adversely affected. However, as more and more electronic building elements 20 are used in household appliances, this DC problem must also be solved, whereby it appears that in the circuits used in practice for electrical household appliances in the event of a closure by a human body, the flowing fault current always remains in the form. of a pulsating DC current can occur.

Magnetic materials have recently been developed, in which despite a relatively high permeability the difference between the induction in the remanent state and in the saturation state is large. This means that statically measured the remanent induction is less than 40% of the saturation induction. By using this material it is possible to achieve that - although with a smaller tripping sensitivity - the fault current protection switch also functions in the case of fault currents in the form of pulsating direct currents. Since the induced voltage in the secondary winding is then smaller with the same effective value of the primary current than with a sinusoidal alternating current, the energy accumulation circuit can lead to a better switch-off behavior here. The energy content 8102641 - t - 5 - of the switch-off pulses, which is determined by the switching voltage of the semiconductor element, always remains the same and thus also the reliability of the switch-off.

The invention therefore provides a fault current protection switch with a mains voltage independent electronic energy accumulation circuit in the switch-off circuit, a summing current transformer with a core of a magnetic material of high permeability and with a large difference between the remanent and the saturation inductance, and a permanent magnetic switch-off member, which is preferably polarized.

Finally, according to the invention, the rectifier circuit preferably consists of a voltage multiplier circuit.

The drawing schematically shows exemplary embodiments of the fault current protection switch according to the invention.

Fig. 1 shows a first embodiment of the safety switch; and FIG. 2 shows an embodiment of the trip circuit of the safety switch.

The fault current protection switch of fig.

1 has a contact device 1, which is switched on or off via a switch lock 2 by means of an operating member 3 or an error current-switching member 8. can be turned off.

The excitation winding of the fault current trip member 8 is connected to a pulse capacitor 5 via a voltage-dependent switch member 7, which consists of a semiconductor element. This capacitor can be charged via a rectifier circuit 6 by the secondary winding of a summing current transformer 4 depending on the magnitude of a flowing fault current. The core 9 of the summation current transformer 4 is made of a magnetic material of high permeability, the material of which the remanent inductance is less than 40% of the saturation inductance.

Fig. 2 shows an example of a trip circuit, in which the pulse capacitor 5 is charged via the rectifier circuit 6, which is designed as a voltage doubling circuit, through the secondary winding of the 81 0 2 6 4 1 - 6 summing transformer 4. The purpose of the switch-off member here is a polarized switch-off member which has an air gap in the magnetic circuit between pole shoes 10 and an armature 11, so that when the armature has been removed, the winding 12 can be applied to the relevant pole shoe in a ready, wound condition. .

81 0 2 6 4 1

Claims (3)

1. Fault-current circuit-breaker consisting of a contact device, a key switch with freewheel and actuator, a summation current transformer, an electronic energy accumulation circuit and a fault-5-circuit breaker with a permanent magnet, which parts are housed in an insulating material housing and provided with terminals. characterized in that the summation current transformer has a core of a high permeability magnetic material 10, the remanent inductance of which is less than 40% of the saturation inductance (measured statically) and of which the secondary winding has more than one hundred turns and via one of the mains voltage independent electronic energy accumulation circuit is connected to the fault current switch-off means of the switch lock, the energy accumulation circuit consisting of a capacitor (5), which is connected over a suitable rectifier circuit (6) depending on the fault current through the summing current The transformer (4) is charged and which, when a certain charging voltage is reached, discharges impulse-wise through a voltage-dependent semiconductor element (7) through the trip coil of the fault current disconnect device (8) and thereby trips the fault current protection switch. Fault-current protection switch according to claim 1, characterized in that the fault-current release member (8) is designed as a polarized shut-off member and has an air gap in its magnetic circuit. Fault-current protection switch according to claim 1 or 2, characterized in that the rectifier circuit (6) consists of a voltage multiplier circuit. 81 02 6 4 1