DE440391C - Quick switch provided with polarized holding magnet - Google Patents

Description

High-speed switches are generally used to protect DC machines or Rectifier systems when high overcurrents occur. It is known that the quick switch for the purpose of quick release to be provided with a polarized holding magnet. The holding magnet carries two coils, a shunt coil, the normal current attracted the armature

ίο and thus also those on the anchor Keeps switch contacts closed, and one in the main circuit (often just off a single turn) current coil. These coils are connected to each other in such a way that that the magnet armature in an undesirable current state through the current coil is demagnetized and the quick switch triggers. It is also still known to switch the coils to each other so that the

ao The direction of current in the coils is either opposite to one another when the current is flowing normally or rectified, depending on whether the high-speed switch is to respond in the case of an overcurrent in the same current direction or in the other case with a current flowing in the opposite direction to the normal current. Such Quick switches provided with polarized holding magnets therefore have the peculiarity that they only work in one direction of the main current determined by the switching of the coils, d. H. with a certain direction of energy ·, switch off. Diesi is said to be based on the Fig. Ι and 2 are explained.

In Fig. Ι a high-speed switch is shown, which trips when the overcurrent flows normally.

If the normal operating current flows in the direction of the solid arrows, the Direction of current in the shunt coil 12 located on the holding magnets 11 an arrow end © shown, the opposite current direction in the main circuit coil 13, on the other hand, by an arrowhead O. With normal current, the shunt ampere turns predominate 12 and hold the armature 15 carrying the switching contacts 14 attracted, in the event of an overcurrent, however, the armature 15 is demagnetized by the main circuit coil 13, so that the switch triggers as a result of the spring force 16.

In Fig. 2 the mode of operation is shown graphically and the main (H) and secondary (N) final ampere turns plotted as a function of time (i). When the current is normal, the difference between the ampere turns acts as the stop ampere turns on the armature 15. If, on the other hand, overcurrent occurs at point A , the main current ampere turns are amplified and the switch triggers when the main current ampere turns H have reached the value of the shunt ampere turns JV at time B. the end.

If, however, a reverse current occurs with this arrangement (dashed lines in Figs. 1 and 2) shown), the current direction of the main circuit is reversed, and the main

Current amp turns H amplify the shunt amp turns so that the switch cannot trip. An example of a high-speed switch is given in Fig. 3, which keeps the high-speed switch switched on when the current is flowing normally and triggers it in the event of reverse overcurrent. The direction of the current in the shunt coil 0 12 and the main circuit coil 13 © is rectified when the current is flowing normally, as shown by the arrowheads in Fig. 3. When Rücküb he current occurs, the direction of current in the main circuit coil 13 is reversed (shown in dashed lines) and the armature 15 is demagnetized so that the high-speed switch is triggered. As can be seen from Fig. 4, when the current is flowing normally, the main current and shunt ampere turns add up, so that the high-speed switch cannot trip when the overcurrent flows normally (shown in dashed lines). If back overcurrent occurs at time C , the direction of the current in the main circuit coil is reversed and the main current ampere turns increase. When they have reached the size of the shunt ampere turns at time D, they cancel them and the quick switch trips. According to Fig. 1, the switch cannot trigger with reverse current, according to Fig. 3 not with forward current. Under certain circumstances, however, it is desirable that the switch in the case of Fig. 1 also correspond to reverse current or in the case of Fig. 3 to correspond to forward current. that triggers strength.

According to the invention this is achieved in that with a quick switch with polarized holding magnet, the relative current directions in the coils for forward like automatically maintained in the event of reverse current in the sense of triggering. Depending on the current directions present in the coils with normal current can therefore use the quick switch z. B. with reverse overcurrent fast in a known manner, but through when a forward overcurrent occurs automatic switching of the ampere turns counteracting the tripping with trigger reduced speed. It is also possible to change the coils from the start to switch in such a way that the high-speed switch is better known per se in the event of a forward overcurrent Way quickly, in the case of reverse overcurrent or reverse current, however, by switching the counteracting ampere turns off at a reduced speed. For example, the triggering of the Quick switch by reversing the direction of the current in the shunt coil, the shunt coil being self-actuated by reversing the direction of the main current is switched. The switching of the shunt coil can now either through a special current direction relay can be made, which is influenced by the main current, or by the fact that the magnetic Effects of the holding magnet itself can be used for switching. For example, the magnetic effect of the Holding magnets used as a result of the reversal of the current direction in the main circuit coil, in such a way that an auxiliary armature with quick release auxiliary poles of the holding magnet bridged, but when the current is reversed, the shunt coil switches over. The changeover contacts can be used directly closed by the automatic changeover switches or indirectly by these via a contactor or be opened.

In the event of a short circuit, the main ampere turns grow very quickly. The shunt amp turns but can only after a certain time (due to the speed of switching and the self-induction is conditional) reach their full height, so that there is a possibility that they will be required to trigger the switch do not reach the opposite value of the main current ampere turns in time or not at all. In this case it is beneficial to track the rise in shunt ampere turns after switching to accelerate. This can be achieved in a number of ways. Either the shunt coil is connected to resistors of voltage that is bridged by the changeover contacts after switching, so that the shunt coil is now only at full voltage, or it can also to the shunt ampere turns acting before the switchover, a larger number of turns after the switchover be switched on.

But because the voltage drops very quickly in the event of a short circuit, it is advantageous to use the shunt coil to excite foreign by an almost constant voltage.

In Figs. 5 to 15 embodiments according to the invention are shown.

FIG. 5 shows a normal high-speed switch in which the shunt coil 12 is switched by a polarized relay 17. The current winding of the polarized relay is formed by the continuous conductor 18. The voltage windings 19 are connected to an auxiliary voltage P, N. The contacts and 22 attached to the armature 20 of the polarized relay are also connected to P and N. When the current is flowing normally, these contacts come into contact with the fixed contacts 23, 24;

against with the other fixed contacts 25 and 26, in that the armature is rotated to the right against a spring. The fixed contacts 23, 24, 25, 26 are crossed with one another, so that at normal current the voltage coil 12 is connected to the PoIiV with its terminal 27 and to the ToIP of the auxiliary voltage with its other terminal 28. If a current directed against the normal current occurs in the current winding 18, the armature 20 is attracted and the terminal 28 is placed on the pole N and the terminal 27 is placed on the pole P and thus the shunt coil 12 of the high-speed switch is switched, that is, the polarity is reversed.

Furthermore, according to the invention, the holding magnet of the quick switch can also be used itself, which is also a polarized relay, to switch the shunt coil 12 use.

In Fig. 6 and 7 such an arrangement is shown for example. The holding magnet 11 has two auxiliary poles 29 and 30, which are bridged by an auxiliary anchor 31 can be. The auxiliary anchor 31 is supported by a spring 32 around a fixed pivot point 33 rotatable. The contacts 21 and 22 can again be attached to the auxiliary anchor according to the direction of the current with their mating contacts 23, 24, 25, 26 in contact can come. Through these contacts, as shown in Fig. 5, the switching

• management of the shunt coil.

In Fig. 8 are the magnetic lines of force as shown in the coils 12 and 13 when the current direction is rectified get lost. The middle auxiliary poles and the auxiliary armature are demagnetized 31 by the spring 32 from the auxiliary poles 29, 30 removed when the lines of force of the main circuit amp turns are opposite in this are equal to the lines of force of the shunt ampere turns, i.e. when the magnetic field in the auxiliary poles is equal Is zero. Before switching on again, the original circuit of the By appropriate means.

In Fig. 9 the course of the magnetic lines of force is in opposite directions Current directions in the main 13 and the shunt coil 12 are drawn. In this State, the main armature is demagnetized, while the auxiliary armature 31 at the auxiliary poles 29 and 30 held so that switching or reversing the polarity of the shunt coil cannot take place.

The switching of the shunt coil 12 can not only be done directly by the polarized Relay 17 or the holding magnet n take place, but also indirectly, for. B. over a Contactor 34 as shown in Fig. 10. It is not shown by the polarized relay only the contact 36 is actuated.

The mode of operation of the high-speed switch according to the invention is described below with reference to FIGS. 11 and 12.

Are the current directions in the shunt and main circuit coil with normal flowing When the current is rectified, the high-speed switch triggers when the direction of current is reversed in the main circuit coil 13, that is to say at Back overflow, in a manner known per se as shown in Fig. 4 quickly.

If, however, a normally flowing overcurrent occurs, for example at points £ in Fig. 11, the armature 20 or 31 of the relay respond and switch the shunt coil 12 so that the current directions of the coils are opposite. At point F , the ampere turns cancel each other out and the quick switch trips.

A high-speed switch in which the directions of the current in its coils are rectified switches off when reverse overcurrent occurs, but not with nominal reverse current, because the main current ampere turns do not have the value of the shunt ampere turns as shown by the dot-dash line in Fig. 4.

According to the invention, however, disconnection at nominal reverse current is achieved in that the switch triggers quickly in a manner known per se (Fig. 1 and 2) when the current is flowing normally, but at reduced speed with reverse current and reverse overcurrent. This is achieved by the fact that, as shown in Fig. 12, the current directions in the coils are oppositely directed when the current is flowing normally, but with reverse current (point G) the current direction in the main current coil is reversed and the armatures 20 and 31 of the relays are reversed change the direction of the current in the shunt coil (point H) so that the ampere turns cancel each other out at one point (point K) and the switch trips.

When short circuits occur, the main current amp turns grow very quickly at. There is therefore a possibility that the increase in shunt ampere turns takes place too slowly in the reverse current direction and these do not reach the value of the main current ampere turns (see dash-dotted curve in Fig. 11 and 12). In this case it is advantageous to use the Accelerate rise in shunt ampere turns after switching.

Some examples of how this can be achieved are given in Figs. 13 to 15.

In Fig. 13, a changeover switch 35 is moved by a contactor 34 controlled by the relays. If the contact 36 controlling the contactor 34 is open when the relay is not addressed, the changeover switch 35 is also open. The shunt coil 12 is connected to a throttled voltage of the auxiliary source P ₁ N via resistors 37. If the relay and the contactor 34 are activated, the changeover switch 35 is closed, the current direction in the shunt coil 12 is switched and the resistors 37 are bridged by the contacts, so that the shunt coil 12 is at the full auxiliary voltage and the increase in shunt ampere turns is accelerated when switching.

The increase in shunt ampere turns can also be seen as shown in Figs. 14 and 15 accelerate by the fact that (apart from the main current winding) two (38, 39) or more Shunt windings are applied to the holding magnet 11 and not addressed Contactor 34 the shunt coil 38 according to Fig. 14 via a changeover switch 40, but according to Fig. 15 it is directly connected to voltage, so that it is driven by a current in the direction of arrow is flowed through. If the contactor 34 responds, then after Fig. 14, the shunt coil 38 is switched off and the switch 40, the shunt coil 39 switched on with a larger number of ampere-turns with the opposite current direction.

According to Fig. 15, the shunt coil 38 remains on and through the changeover switch 41 the shunt coil 39 is switched on with the opposite current direction, so that the difference in the two ampere-turns will accelerate the increase in shunt ampere-turns.

Claims (14)

Patent claims: i. Equipped with polarized holding magnets High-speed switch, characterized in that the direction of current in its coils is for forward and reverse current is maintained automatically in the sense of triggering. 2. Quick switch according to claim 1, characterized in that it is at back overcurrent fast in a known manner, but by automatic switching when a forward overcurrent occurs which triggers the counteracting ampere turns at a reduced speed. 3. Quick switch according to claim 1, characterized in that it is at forward overcurrent fast in a known manner, but with reverse current or reverse current by switching the counteracting ampere turns triggers at reduced speed. 4. Quick switch according to claim 1 to 3, characterized in that the triggering the quick switch takes place by automatic switching of the shunt coil. 5. Quick switch according to claim r to 4, characterized in that the shunt coil is switched automatically by the direction of the main current. 6. Quick switch according to claim 1 to 5, characterized in that a special one Converter relay switches the shunt coil. 7. Quick switch according to claim 1 to 6, characterized in that for switching The shunt coil uses the magnetic effects of the polarized holding magnet itself. 8. Quick switch according to claim 1 to 7, characterized in that an auxiliary armature Auxiliary poles of the holding magnet are bridged in the event of rapid tripping, in the event of current reversal on the other hand, the shunt coil switches over. 9. Quick switch according to claim 1 to 8, characterized in that the changeover contacts operated directly or indirectly, for example via a contactor will. 10. Quick switch according to claim 1 bis'9, characterized in that with the switching of the shunt coil simultaneously the increase in the shunt ampere turns is accelerated. 11. Quick switch according to claim 1 to 10, characterized in that the shunt coil only after switching is due to the full voltage. 12. Quick switch according to claim 1 to 11, characterized in that the Shunt coil is connected to voltage via resistors, which is bridged by the changeover contacts after switching will. 13. Quick switch according to claim 1 to 12, characterized in that according to a greater number of shunt turns is effective after switching than before switching. 14. Quick switch according to claim 1 to 13, characterized in that the Shunt coil is externally excited. For this ι sheet of drawings, ■ -