DE1128009B - DC high-speed switch - Google Patents

Description

DC high-speed switches High-speed switches are single-pole, for protection Circuit breakers with trip-free release developed by DC systems. you Switch-off delay is about a ten exponential less than the normal self-switch. The tripping of the DC circuit breakers known up to now is carried out by special ones controllable magnet systems.

DC high-speed switches with a holding magnet system are known. They are connected to the armature of the holding magnet with the help of the holding magnet Movable contact against the force of a strong return spring in the on position held. In the event of a trip, the main current or a Part of the main current, the magnetic weakening of the armature's holding flux takes place torn off by the return spring from the holding magnet and the moving contact from fixed mating contact separated. The triggering takes place depending on the slope the current rise and an adjustable value of the current. The readiness to release is limited to one current direction without additional devices.

There are also known impact-operated direct current high-speed switches. They have a magnet system that consists of a holding magnet and a release magnet. Both the holding magnet and the release magnet are excited by the main current. In the event of a trip, the anchor is removed from the holding magnet by the then predominant Force of the release magnet torn off towards the release magnet. The anchor hits it hits the moving contact and hits it. Triggering takes place in both directions of current with the same fixed, adjustable response value.

By polarizing the holding magnet, a shift in the response values can be achieved in the case of the quick-release switches operated by means of a flicker. The switch then triggers z. B. with increasing forward current later, so with higher current, earlier with increasing reverse current, so even with lower current values than with unpolarized holding magnets. However, a premature release in the current direction must always be paid for by a late trip in the other current direction.

The invention relates to direct current high-speed switches of the type defined at the outset with triggering devices responding in both directions of current. It consists in that two independently working, on the contact system and / or a switch mechanism acting together triggers are provided, one of which is current-dependent electromagnetically, the other, controlled by a voltage derived from this current, is electrodynamically effective and that both triggers their effect on the movable contact system can be adjusted so that, depending on the operating conditions for which the switch is to be used, one or the other release causes the switch to open when the switch opening is dependent on the current direction.

Through the combined use of a magnet system controlled by the main current and an electrodynamic trigger controlled by voltage values the protection tasks occurring in modern rectifier systems for Solve industrial and rail operations better and more safely than with the previously known Quick switches.

The invention is to be explained in more detail with reference to the drawing. 1 shows schematically an embodiment according to the invention, seen from the side, FIG. 2 shows a further embodiment with a special arrangement of the two tripping systems, FIG. 3 shows a comparative illustration of the forward currents of the switch according to the invention and a known switch, FIG Circuit of the excitation element for the electrodynamic trigger.

The quick switch shown in Fig. 1 contains a flap magnet system as a controllable magnet system. It consists of the holding magnet 1, the release magnet 2 and the impact armature 3. FIG. 2 shows a plan view of the two magazine circles.

Both magnetic circuits are excited directly by the main current I. For this purpose, the power supply rail 4 to the fixed contact 5 is passed through the window 6 of the holding magnet 1 . From the fixed contact 5 , the current I enters the movable contact lever 7 , which is connected to the excitation winding 9 of the tripping magnet 2 by a flexible band 8.

The contact lever 17 is rotatably mounted about the axis 10. The axis 10 is cushioned in the direction of impact of the drop anchor 3. The release lever 11 is rotatably seated on the same axis 10 and is connected to the lap via the pull rod 12. The lock is indicated by parts 13 to 17 . The contact lever return spring is designated by 18 . 24 and 25 are arcing horns which are located in an arcing chamber which is not shown.

The electrodynamic release consists of the pulse coil 19 and the impact ring 20, which is inductively closely coupled to the pulse coil in a known manner.

According to the exemplary embodiment in FIG. 1 , the impact ring 20 is connected to the contact lever 7 and the ratchet lever 17 via a linkage 23 that is as short as possible. According to the exemplary embodiment in FIG. 2, the electrodynamic trigger is arranged in the window 6 of the holding magnet 1 . The impact ring 20 here has a firing pin 21 which is passed through a bore 22 of the impact armature 3 so that it can act directly on the release lever 11 and the movable contact lever 7, as shown.

The electrodynamic trigger is controlled by the exciter 26 , which initiates the discharge of the capacitor 27 via the pulse coil 19 in the event of a trigger. The excitation element 26 itself is controlled by the voltage drop across the resistor 28 , which is proportional to the main current I.

4 shows the details of the excitation element 26. It consists of three stages: a preamplifier stage V, a monostable multivibrator M and an output stage T.

The voltage drop across the resistor 28 is fed to the preamplifier stage V, where it is amplified to such an extent that the triggering of the trigger stage M is guaranteed.

In normal operation, only the transistor T2 is in the conductive state. The transistor T i blocks as long as the voltage at its base has not reached the response threshold. If the control voltage supplied by the preamplifier exceeds this value, a small change in the emitter current of the transistor Ti causes an opposite, larger change in the emitter current of the second transistor T., so that the voltage drop across the common emitter series resistor Re becomes smaller. The base-emitter voltage of the first transistor rises for this reason, its emitter current is increased still further as a result, while the emitter current of the second transistor decreases even further, etc. The flip-over process is ended when the transistor T 1 blocks and the first transistor T, is conductive. At this moment the base voltage of the power transistor T , jumps so far into the negative that T, suddenly becomes conductive.

As a result, an ignition voltage pulse for the three-electrode spark gap 31 is generated in the ignition transformer 30 located in the collector line, and an ignitron can also be used in its place. When the spark gap 31 is ignited, the capacitor 27 discharges abruptly via the pulse coil 19 of the electrodynamic trigger, the impact ring 20 of which is repelled and the rapid switch 32 opens.

The time lost from the start of the excitation of the excitation member 26 to the discharge of the electrical energy of the capacitor is in the order of magnitude of 0.01 to 0.1 ms.

Compared to the previously known, only magnetically controlled direct current high-speed switches offers a quick switch according to the invention with two independently working Triggers significant benefits.

The well-known quick-action switches, which are operated by means of a flicker, achieve a switch-off delay, that is the time from the start of the trip command to the opening of the contact, of 3 to 6 ms. With an electrodynamic release with an electronic exciter, switch-off delays in the order of magnitude of 0.5 to 1 ms can be achieved.

One achieved through the use of an electrodynamic trigger instead of the usual polarization device with approximately the same technical Effort one, decoupling of the release properties in the forward and reverse flow direction. Early tripping in one current direction is no longer inevitable a late trip connected in the other current direction. The stress on the systems to be protected and the quick switch itself will be less, his Applicability more diverse.

In Fig. 3, the Durchlaßströrne of the known impact armature actuated quick switch and an inventive speed circuit breaker based on the same steepness of the rise in current program are summarized in a diagram. Column 1 and II show the forward currents of a previously known snap-action switch, column 11 with an additional polarization device. It can be clearly seen that a reduction in the forward flow in the reverse flow direction is associated with an increase in the forward flow in the forward flow direction.

In columns 111 to V, the forward currents of a switch according to the invention are plotted. In the example in column III, the electrodynamic release works only in the reverse flow direction, whereas the impact armature network system works in the forward flow direction. In the example according to column IV it is the other way round, and in the example according to column V the electrodynamic release responds in both directions of current. It should be emphasized as a particular advantage that the switch works with double safety in the current direction in which the electrodynamic release acts. Should the electrodynamic release fail for any reason, the magnetically controlled release will still respond, albeit with a somewhat higher release delay. The trip combination according to the invention not only achieves shorter delay times and a decoupling of the tripping properties in the forward and reverse flow areas, but also significantly improved operational reliability. This is all the more important because such column switches are used in systems in which the failure of a switch causes great damage.

The combination of the two triggers provides the necessary security and quick response. The proven release system with controlled Magnetic circuits So it enables an electrodynamic release with an electronic exciter to be used for quick switches.

Claims (2)

PATENT CLAIMS-1. DC high-speed switch with tripping in both current directions to transfer the movable contact system into the switch-off position, characterized by two independently working releases that act jointly on the contact system and / or a switching mechanism, one of which is current-dependent electromagnetic, the other by a voltage derived from this current controlled, is electrodynamically effective, and that the effect of both triggers on the movable contact system can be adjusted so that, depending on the operating conditions for which the switch is to be used, one or the other of the triggers causes the switch to open when the current-direction-dependent switch opening is desired. 2. DC high-speed switch according to address 1, characterized in that the electromagnetic release is carried out by a per se known flap armature magnet system with a holding and release magnet excited by the main current and a Sählaganker arranged between the two. 3. DC switch according to claim 1 and 2, characterized in that the electrodynamic trigger is controlled by an exciter which consists of a preamplifier controlled by the voltage drop across an Olun resistor, which in turn controls a known monostable trigger stage whose output pulse is generated when tilting is converted via a power transistor in a known manner into a current impulse for an ignition current converter to trigger a high-current capacitor discharge, which causes the electrodynamic trigger to be excited. 4. DC high- speed switch according to spoke 1 to 3, characterized in that both the magnetically controlled and the electrically controlled release act suddenly on the movable contact system. 5. DC high-speed switch according to claim 1 to 4, characterized in that the electrodynamic release is arranged in the window of the holding magnet in such a way that the movable part, designed as a firing pin, can act on the movable contact system through a bore in the impact armature of the magnetically controlled release. Documents considered: German Auslegeschrift No. 1079 176; Swiss patents No. 227 246, 109564.