DE722417C - Arrangement for switching off inductive circuits - Google Patents

Description

Arrangement for switching off inductive circuits It is known and sometimes advantageous to switch off inductive circuits instead of switching them off directly by opening a contact, in that they are short-circuited within themselves or via a resistor. Since no external voltage is active in the circuit after the short-circuit, the current follows the equation whereby is the time constant of the circuit.

The known arrangements have relatively long decay times on what is undesirable when it is z. B. is a circuit in which .the inductance is formed by the winding of a relay with holding magnets. In these cases, the tripping time for the relay is too long.

This disadvantage is eliminated according to the invention in that in the inductive circuit to be switched off a resistor is arranged, whose Resistance value increases with decreasing terminal voltage (current-dependent resistance). This resistance can consist, for example, in a rectifier element, which in the forward direction, is switched. Of course, several series-connected Rectifier elements are used.

Although it is known in telephone systems, in parallel with the relay, when you call z. B. closes the motor circuit of a selector, a current-dependent Resistance, in particular a dry rectifier, to be provided. however acts In contrast to the invention, it is a question of sensitivity and operational reliability of the relay and decrease the eavesdropping caused by this relay. Not on the other hand, should, as in the case of the invention, in an arrangement for switching off inductive devices In circuits, the switching time can be shortened by short-circuiting the inductance.

In the following, the invention is described in more detail with reference to the drawing. Fig. i shows an inductive circuit where i is the inductance L, e.g. B. the winding of a relay with holding magnets, means. 2 the damping resistor 12, 3 the switch, which brings about the shutdown, and 4. a series resistor which is not of interest here. Fig. 2 shows the voltage characteristic of the damping resistor 2. The original Magnetizing current of the relay should be labeled Yes according to Fig. 3.

In point i of the diagram according to FIG. 3, the circuit may continue be short-circuited by switch 3. A variable equalizing current then flows, that in point 3, if the damping resistor 2 according to the invention is missing, your value Reached zero. With current JH, the holding magnet releases according to its counter-pulling force off (point 2). The time constant is T and the solenoid release time is t.

If, on the other hand, the current-dependent resistor 2 according to the invention is present in the discharge circuit as a damping width, the compensating current follows curve b according to FIG. 3. The holding magnet now triggers at point 2 with the time constant T ' and tripping time l'.

If, for example, two current-dependent resistors are connected in series, the current curve is according to curve c (FIG. 3). For the received times Minn are written T> T '> T ".....

t> t '> t ".. ... holding magnets can be used, for example, for distance protection devices and here in particular for impedance formation. For example, a distance protection circuit has already been proposed, which is basically shown in FIG It is a distance relay of this type, in which a holding magnet with high holding force but little remote action is provided with separate windings through which direct and alternating current flows, the direct current winding having a rectified current proportional to the mains voltage Ui and the AC winding the phase current of the network U. is supplied. This causes a differential formation of the ampere turns when the instantaneous value of the phase current is negative owns . Since: the impedance element is connected to the alternating voltage. network connected, whereby the structures S and @ with their symbolic symbols represent the one already proposed for the impedance relay. Represent phase multiphase transformation via rectifier. Further details of the distance protection, such as B. the excitation member, the directional members, etc., are omitted in the embodiment for the sake of simplicity, since they are not necessary for understanding the invention. In FIG. 4, the current-dependent resistors io and ii according to the invention are also shown in the diagonal of the bridge circuit, which is designed as a differential circuit. These resistances reduce the time constant of the diagonal current (s), as discussed above, and allow the impedance element to be triggered more quickly, especially when measuring small impedance values.

The arrangement according to the invention has the following effect in this case the end. The windings of the relay are driven by two currents in opposite directions flowed through, which can differ in size from each other. The one is stream initially much larger than the other and decreases in the response decision of the relay away. It is then desirable that this decrease in current occur very quickly so that the current quickly assumes its final value. The two opposing sides stand out Currents in the winding, then the relay armature drops. This is achieved by the -invention provided damping resistance guaranteed.

Claims (3)

PATENT CLAIMS: i. Arrangement for switching off inductive circuits, especially those in which the inductance is caused by the winding of a relay with holding magnets is formed by the following directly or via a resistor Short-circuiting the circuit, characterized in that in the short-circuit a current-dependent damping resistor (2) is provided. 2. Arrangement according to claim i, characterized in that the damping resistance consists of one or more in Series connected rectifier elements consists. 3. Arrangement according to claim i and 2, characterized by the application in relays with holding magnets of mains protection arrangements, especially with impedance relays of distance protection arrangements.