DE1161619B - Electrical AC synchronous switch or current limiter switch - Google Patents

Description

Electrical alternating current synchronous switch or current limiter switch Switches are already known in which the switch-off takes place by increasing the resistance. This is mostly done by lengthening and cooling the arc that occurs when the contacts are separated. In addition to the well-known automatic switches for direct and alternating currents up to about 1000 V, so-called alternating current magnetic blow switches up to a nominal voltage of 15 kV have recently been built. Here, the current to be interrupted comes almost in phase with the voltage due to the high resistance of the arc, whereby the extinction can easily be brought about in the current zero passage with a low recurring voltage. The disadvantage of this switch is that the Löschsystern must absorb a very high arc power and shift work, resulting measurements to large waste and high costs.

It is also already known, along with the elongated arc to switch on additional resistance in the circuit. But provided an arc duration occurs from two to three half-waves, this leads to very heavy resistance, which are also not very effective because only relatively low ohmic values are switched on can be.

It is also known by rotating a movable contact piece to draw an arc that initially burns horizontally. Only when the arc has reached a certain length and thereby as a result of its thermal effect Horn-like intermediate pieces are brought up, he begins to get under the influence of electrodynamic forces to expand faster. Experience has shown that it is delayed This significantly reduces the arc extinction. One could indeed with this arrangement in the usual way use an additional magnetic blowing coil, its circuit is closed by the arc itself. Experience has shown that the arrangement works but only flawless if the arc movement is already in the initial stage is accelerated, which can only be achieved by a permanently switched-on magnetic blown field is possible. However, this results in a substantial increase in the price and greater Joule losses in continuous operation.

Furthermore, switches have already been described in which the Contact pieces are separated by inserting an insulating part.

The invention relates to electrical alternating current synchronous switches or current limiter switches with arc quenching by increasing the resistance. It consists in the fact that the contact is separated by an insulating piece moved between the contacts, that at the same time a drive system is used which only actuates the movable insulating piece when the instantaneous value of the current is one third of the amplitude of the maximum surge short-circuit current assigned to the switch in the case of a synchronous switch fallen below or has not yet reached with a current limiter, and that furthermore the initially hairpin-shaped arc is driven into the open space of the extinguishing system by the electrodynamic forces generated by it and there closes the circuit of a magnetic blowing coil, through whose field it is moved further. With this arrangement, the arc is mechanically brought into a hairpin shape by the insulating piece moved between the contacts, which has the effect that the long sides of the arc are explosively driven apart and into the extinguishing system due to the opposite direction of current by the electrodynamic forces, without a additional magnetic field is required. As a result of this strong self-blowing of the arc, the magnetic blown field only needs to be excited after the arc has been expanded for the first time. Is z. If, for example, the thickness of the insulating plate is 0.5 cm and the contacts are separated at around 10,000 A, the result is a repulsive force of 4 kp over a length of 1 cm of the arc loop, without an additional blown field being required.

Such a switch can be designed as a synchronous switch, for example, in that the contact separation is brought about with the aid of a so-called pre-release shortly before the current zero crossing. As a result, the switching work can be reduced to less than 3 1 / o that of conventional magnetic blower switches. This type of synchronous actuation can only be carried out if the arc runs into the extinguishing system within a fraction of a millisecond after the contact has been separated. The switching work can be further reduced by means of metallic resistors arranged in the extinguishing system, the resistance value of which increases as the arc progresses.

But you can now also use such an electrical switch as a Use current limiter. It is only necessary to change the control so that that the contact separation begins immediately with the rise of the overcurrent. Here, too, a hairpin-shaped arc loop is created, which is now spreads even more intensely under the rising current and explodes into the Extinguishing system is driven into it. By extending the arc on the one hand and additional switching on of a resistor on the other hand, the overcurrent is limited and then practically goes through zero together with the driving voltage, so that here, too, the deletion comes about in a simple manner.

But you can now also use such an electrical switch as a Use current limiter. It is only necessary to change the control so that that the contact separation begins immediately with the increase in the overcurrent. Here, too, a hairpin-shaped arc loop is created, which is now spreads even more intensely and explosively under the rising current is driven into the extinguishing system. By extending the arc on the one hand and additional switching on of a resistor on the other hand, the overcurrent is limited and then practically goes through zero together with the driving voltage, so that here, too, the deletion comes about in a simple manner.

In Fig. 1 shows an exemplary embodiment of a switch according to the invention in section, while FIG. Figure 2 shows the moving mechanism. 1 and 2 denote the fixed connections which are attached to the insulators 3 and 4. 5 is the base plate, 6 and 7 are the resilient contact pieces lying on top of one another with bias, 8 is a movable insulating partition which can be moved up and down via the tension-compression spring 9 and the angle lever 10 , with the contacts 6, 7 open or closed again. To guide the partition 8 , insulating pieces 11 and 12 are provided. The connecting line 2 is surrounded by a magnet system 13 which, in addition to the central opening 14 (see FIG. 2), also has a circular cutout 15 with no 16 . A rotating coil 17 , the axis 18 of which is connected to the crank 19 , is arranged in the air gap formed in this way. The crank pin 20 engages in a slot 21 in the insulating plate 8 .

The extinguishing system 22 is designed symmetrically to the center line AA7 Only the parts visible in section on the left are listed below. 23 is a metallic busbar which is connected to the connection 1 via the bracket 24. 25 are insulating wedges which have resistors 26 on their surface. 27 is a further metallic busbar which is connected to one end 28 of the magnetic blowing coil 29 . The lamellar none of the blowing coil is designated by 30 . It bears the pole plates 31 on both sides. On the front and back of the wedges 25 , 1sole plates 32 are arranged, creating a fan-like arc extinguishing system.

The mode of operation of the arrangement as a magnetic bubble holder is as follows: To bring about an arbitrary disconnection, the angle lever 10 is rotated in the direction of the arrow and thus the spring 9 is compressed, whereupon the insulating piece 8 then shoots upwards at great speed, thereby separating the contacts 6 and 7. Starting from the contact 6 over the upper end of the insulating piece 8 and back to the contact 7, a hairpin-shaped arc is created, the vertical parts of which are driven into the blowing system 22 by the high dynamic forces on the left and right. From the moment that the arc touches the two busbars 23 and 27 , the current flows through the blower coil 29, so that the additional magnetic blown field becomes effective and drives the two arcs into the extinguishing system 22 at high speed. In the dotted position of the arc, the current flows from connection 1 via connection 24, rail 23, from there via the first partial arc to the switched-on part of the resistor on the lowest wedge 25 of the extinguishing system, etc. It can be seen that as the Arc not only increases in length and thus its own resistance increases, but that an ohmic resistance is also switched on. When the current crosses zero, the current is practically in phase with the voltage, so that the interruption can take place without difficulty.

If an overcurrent occurs, as long as the current increases, the crank 19 is pressed down by the rotating coil 17. If the current begins to fall, the moment on the moving coil 17 changes. The lever 19 moves in the counter-clockwise direction and thus moves the insulating piece 8 upwards. 1 to 2 milliseconds before the current crosses zero, the contacts 6 and 7 are separated by the insulating piece 8 , whereupon the arc extinction takes place in the manner already described. If, for whatever reason, the arc is not extinguished at the current zero crossing, the torque of the moving coil changes immediately after the current zero crossing. The insulating piece 8 is pulled downwards at great speed. The contacts 6 , 7 close again, and from this moment on the short-circuit current flows through the closed contact system and thus no longer generates any arcing work. Only shortly before the subsequent current zero passage is the Isollerstück 8 pushed up again and thus a second extinguishing process is initiated.

If, on the other hand, it is switched off manually and a so-called reversal fault occurs while the arc has already been extinguished, the insulating piece 8 is instantly torn down by the moving coil system, with the contacts 6, 7 closing again; d. H. but that the switch can never be significantly stressed by an envelope fault. Only when the now flowing short-circuit current approaches its zero value again, its synchronous interruption takes place with little switching work.

If the switch according to FIG. 1 act as a current limiter, it is only necessary to change the control of the insulating plate 8 in such a way that it is moved upwards when the short-circuit current starts and is held in this position. The moving coil system can be used for this purpose, for example. It is only necessary to offset the rotating coil by 90 ' with respect to the crank 19 , as a result of which its direction of rotation is reversed. Further, a locking of the plate would have to be provided in 8 of the off position in addition, so that no recirculation of the insulating plate occurs with decreasing current. 8

For current limiters, it can be useful to provide a suitable magnet system, which is excited by the onset of overcurrent directly or via a converter, instead of the moving coil system, the armature of which acts suddenly on the insulating piece 8. Even higher switching speeds can be achieved in a manner known per se by using an electrodynamic drive, via whose stationary coil a capacitor is discharged when an overcurrent begins, while its movable coil is in direct mechanical connection with the insulating piece 8 .

When operating the switch according to the invention as a synchronously controlled magnetic blower switch or as a current limiter, the extinguishing system is always only exposed to currents which are at most one third of the amplitude of the maximum surge short-circuit current assigned to the switch. As a result, the extinguishing system 22 can be made relatively small. In addition, contact erosion and the associated reduction in insulation strength is also significantly reduced. For larger nominal currents, a main contact can be provided in a manner known per se parallel to the contacts 6 and 7 , which is moved together with the insulating piece 8 ; the contacts 6, 7 then act essentially as tear-off contacts. The initially hairpin-shaped shape of the arc has the advantage that the arc is safely driven into the extinguishing system by the dynamic forces that are still considerable, even with a small current. If you want to achieve an approximately constant arc duration over the entire area, it can also be useful to provide a small pneumatic device, the piston of which is moved, for example, together with the insulating plate 8 and through which a double flow is generated in the direction of the two halves of the extinguishing system .

The additional resistors 26 (see FIG. 1) will generally be produced from metal strips. However, it may be useful to use wire-shaped resistors made of magnetizable material, e.g. B. iron wires to be used. This creates a concentration of the magnetic field generated by the blower coil 29 in the immediate vicinity of the arc base points, whereby the arc migration is favored. If the resistors are made of a material with a high positive temperature coefficient (e.g. chemically pure iron, tungsten), the increase in resistance by heating can also be used to reduce the current in a manner known per se.

Magnetic blow switches according to the invention have only about 1011 / o of the maximum Arc conduction and about 319 / o of the switching work of a magnetic blower switch so far Construction on. This leads to significantly smaller dimensions, less contact wear, and only moderate thermal stress on the blowing system. When used as a current limiter the result is a simple construction that also does not require a residual current switch.

Claims (2)

Claims: 1. An electrical AC synchronous switches or current limiting switch with arc extinguishing by resistance increase, d a d u rch g e kc is used to mark, that the contact separation effected by a moving between the contacts insulating piece, that at the same time, a drive system is used which only the movable insulating then actuated when the instantaneous value of the current falls below a third of the amplitude of the maximum surge short-circuit current assigned to the switch for a synchronous switch or has not yet reached it for a current limiter, and also that the initially hairpin arc caused by the electrodynamic forces generated by it in the The open space of the extinguishing system is driven into it and there closes the circuit of a magnetic blowing coil, through whose field it is moved on. 2. Switch according to spoke 1, characterized in that to increase the resistance, metallic resistors are additionally arranged along the transverse flanges of the extinguishing system, the resistance value of which increases as the arc progresses. 3. Switch according to claim 2, characterized in that the resistors are designed in the form of wires made of magnetizable material. 4. Switch according spoke 1, characterized in that an induction system with a moving coil, which is excited by the current to be switched off, is used as the drive system. Considered publications: German Patent Nos. 285 505, 523 821, 663263 ' 914 870, 943 894; German interpretation document No. 1028 660.