DE1173567B - Synchronous switch with electronic control - Google Patents

Description

Synchronous switch with electronic control To control synchronous switches, electronic systems arranged at ground potential have been used, for example, according to the work, with the electronics being fed via suitable current transformers. Such a structure has the advantage that the electrical energy for the electronic system can be provided in a simple manner, but on the other hand the correct transmission of high short-circuit currents and the transmission of commands from the earth potential to the high-voltage side cause almost insurmountable difficulties. It is also known to arrange the electronic control system, including the auxiliary power source used to power it, on the high-voltage side; control systems of this type have the problem of generating sufficient energy to trip the switch.

The invention relates to a synchronous switch with electronic Control in which the switching movement is activated by mechanical release of an energy store is initiated by means of a control force. It consists in the fact that when it is generated the control power through the electronic control system, including the to its supply serving auxiliary power source arranged on the high-voltage side is, between the organ influenced by the control force and the organ for release of the energy store is a mechanical amplifier with a rotating mass.

In Fig. 1 is the switching chamber of a synchronous switch in section shown; F i g. 2 shows an arrangement for generating the control energy at high voltage potential, while F i g. 3 to 5 to explain the electronic control for off and Fast reclosing are used.

In Fig. 1 means 1 an insulating tube, which at the same time essentially represents the switching chamber, 2 the fixed nozzle-shaped contact, 3 the movable contact, to which the current is fed via the contact rollers 4 and the contact lamellas 5. 6 is the switch-off spring, 7 the switch-on piston, which slides in the cylinder 8. 9 is a toroidal low-pressure chamber which, in the switched-on position of the switch, is in communication with the cylinder 8 via the holes 10; 11 is a valve disk, which is moved with the help of levers 12, 13 in a manner to be described. The space below the valve disk 11 is connected to a pressurized gas reservoir via the opening 33. In the switched-on position shown, the lower end of the piston rod 14 is supported on the rolling pawl 15, which is held in the position shown by the spring 16. 17 and 18 are levers, 19 a rotating gear with a relatively large mass, which is set in rapid rotation via the ratchet 20, the insulating rod 21 and the compressed air drive 22 when the valve 23 is opened. 24 is an air-gap converter (1 converter) which is excited by the current il to be switched off. 25 and 26 are toroidal cores, e.g. B. made of nickel-iron, of which the first is also excited by the current il, but the second is excited by the secondary current i2 of the air-gap converter 24. 27 is a contact which is closed via the pin 28 as soon as the piston rod 14 moves in the disconnection direction. 30 is the electronic control system, an exemplary embodiment of which is illustrated with reference to FIGS. 2 to 5 will be described in detail. 31, 32 are release magnets which, when energized, strike the levers 18 or 13 and bring them into engagement with the rotating gear 19. To establish the connection between the rotating mass 19 and the levers 13 and 18, instead of tooth engagement, a clamping lock in the manner of a freewheel can also be used.

The mode of operation of the arrangement is - without first being detailed on the function of the electronic control system 30 received will -following: If it is to be switched off, either manually or the valve 23 is opened by the overcurrent protection, whereupon by the compressed air drive 22 the gear 19 is set in rotation. The electronic control system does now that, for example, 2 ms before the zero crossing of the current il the tripping magnet 31 responds and thus brings the lever 18 into engagement with the gear 1.9. this has the consequence that the lever 17 rotates clockwise and thus counterclockwise the spring 16 moves the pawl 15 to the right, whereupon the switch under the Action of the spring 6 moves into the switch-off position.

If for any reason the arc is not extinguished be, the release magnet 32 is immediately excited by the electronic control unit 30. As a result, the lever 13 is now in engagement with the rotating gear 19 is coming. It is then lifted over the lever 12 of the valve plate 11, so that compressed gas gets behind the piston 7, which the quick reclosing against the spring 6 causes. The spring 16 returns the pawl 15 to the position shown brought and the switch locked in the on position.

As an auxiliary power source for the switch's electronic control system you can use a generator, the rotor of which is also the rotating mass of the mechanical amplifier forms. Such an arrangement is shown in FIG. 2. Here 19 means that in FIG. 1 gear already shown, which is now a relatively can have a low mass, since it is connected to the rotor 41 of the direct current generator 42 is coupled, which generates a DC voltage U on the brushes 43 and 44. The generator 42 directly charges the capacitor 45, the voltage of which is at the terminals O and -E can be tapped. So that the trigger circuit is first connected to voltage, when the generator 42 has run up, a switch 46 is provided, which over the insulating rod 21 (see FIG. 1) and the cam 48 is closed shortly before the insulating rod 21 has covered its full path. The switch 46 prevents also the disconnection when the insulating rod 21 has returned to its original position is. This is important when the return of the insulating rod 21 at the same time the extinguishing gas flow is blocked.

In Fig. 3 shows the course of the current i1 to be interrupted and the secondary current i "generated by the 1-converter 24 (see FIG. 1) as a function of time. Calculation and experiment show that the slope of i. In the vicinity of the Current zero crossing is approximately inversely proportional to the half-wave duration tfl; it is therefore large for the short half-wave of tj = 6 ms and small for the long half-wave of tH = 14 ms.The steepness of i is thus a direct measure of the half-wave duration tj.

With reference to FIG. 4 the electronic synchronous switch-off is closer explained. It denotes S1 and S, which are also shown in FIG. 1 clamps shown. Of the Current i2 flowing via resistor 51 is converted into full-wave rectifier 52 rectified. In parallel there is a Zener diode 53, which controls the voltage at the output of the rectifier is limited to 8 V, for example, to the following semiconductor elements to protect against overload. 54 is also a zener diode with a zener voltage of for example 5 V, which is connected in series with the resistor 55. So long the voltage at the zener diode 53 is higher than the zener voltage of the diode 54, A control current flows through the transistor 56, which makes this transistor conductive. This has the consequence that the capacitor 57 is short-circuited via the resistor 58 is.

If the current i., Is so small that the voltage at the Zener diode 53 falls below the Zener voltage of the diode 54. so no more control current flows through the transistor 56, whereby the latter blocks. From this moment on, the capacitor 57 is charged essentially via the diode 59 and the resistors 60 and 61 connected therewith. After a certain time, which is given by the steepness of the current zero crossing of i_, the voltage at the Zener diode 53 increases again above the Zener voltage of the diode 54. As already explained, this has the consequence that the transistor 56 becomes conductive again and capacitor 57 discharges through resistor 58. This creates a voltage drop across the resistor 58, which generates a current through the adjustable resistor 62 and the resistor 63 connected in series with it. The transistors 64 and 65 together with the resistors 66 to 71 form a trigger circuit known per se. As a result of the voltage drop across resistor 63, the trigger circuit comes to a standstill, in that transistor 64 turns off and transistor 65 turns on. The latter has the consequence that the capacitor 73 is discharged via the transistor 65 and the tripping magnet 31 (see also FIG. 1), whereby tripping takes place in the manner already described. The capacitor 72 prevents the trigger circuit from tilting back before the capacitor 73 is discharged. The diode 74 initially serves to charge the capacitor 73. At the same time, it protects the transistor circuit from overvoltages which could arise in the tripping magnet 31 when the tripping current is interrupted. The Zener diode 75 serves to stabilize the supply voltage for the measuring elements of the transistor circuit. The described mode of operation applies when the half-wave duration tj is not shorter than, for example, 6 ms. With an even shorter half-wave duration tj, the charging current of the capacitor 57 only flows for such a short time that the voltage reached up to its discharge is no longer sufficient to flip the trigger. There is therefore no tripping for half-wave durations below tj, = 6 ms.

To even with small switch currents and in the de-energized state, whereby the synchronous control no longer works, being able to switch it off is still the Zener diode 76 is provided. As a result of i. Being too small, the capacitor becomes 57 continuously charged until the Zener diode 76 responds, whereupon the transistor 65 becomes conductive and 'the triggering takes place in the manner already described.

With reference to FIG. 5, the reclosing is still unsuccessful Synchronous interruption or when a handling fault occurs. The clamps S3 and S4 correspond to those in FIG. 1. The toroidal core 25 (see FIG. 1) is at the zero crossing of the current il and through the toroidal core 26 at the zero crossing of the Current i, one voltage pulse each generated, but only in the circuit according to FIG. 5 are initiated when the switch 27 (see F i g. 1) is closed via the pin 28 during the switch-off movement. The voltage pulses are rectified by the rectifier 81. Transistors 82 and 83 together with resistors 84 to 90 again form a trigger circuit known per se. If there are no pulses at terminals S3 and S4, transistor 82 is conductive, while transistor 83 blocks. If, on the other hand, an impulse occurs via the resistance 91 of the trigger circuit is pressed, this causes the transistor to be blocked 82, while on the other hand the transistor 83 becomes conductive. This did the discharge of the capacitor 92 via the tripping magnet 32 (see FIG. 1), whereby the Reclosing has been initiated. The diode 93 is in turn used to charge the Capacitor 92 and as protection of the trigger circuit, while the capacitor 94 has the effect that tilting back is only possible after the capacitor 92 has been discharged.

Provided that it is switched on again only if it did not take place Arc quenching in the zero crossing of the current il would be required, it would suffice only to provide the toroidal core 25 (see FIG. 1). However, it can be the case with handling problems it can happen that the current suddenly passes without first crossing zero increases again. Without exception, this results in a zero crossing of the current 'z, wherein a voltage pulse is generated by the toroidal core 26, the instant Reclosing causes.

In Fig. 6 shows a further possibility for feeding the electronic control system by means of an auxiliary power source at high voltage potential. A conductor carrying the current il is designated by 100, in the course of which a current transformer 101 is located. The current converter 101 charges a capacitor 103 via a rectifier bridge circuit 102. The current transformer 101 is advantageously designed so that it is already saturated with currents below the nominal current, whereby the voltage time area given by the product of its saturation flux and its number of turns should be sufficient, the capacitor 103 at nominal current within a quarter wave of the main current il to the desired voltage to charge. Since the current transformer 101 sends a new current impulse to the capacitor 103 each time the main current crosses zero, a zener diode 104 is provided in parallel to the capacitor 103 to limit the capacitor voltage and takes over the current flow after reaching its zener voltage. A switch is denoted by 105, which is closed asynchronously to the main current when a trip command is issued, whereby the capacitor 103 is connected to the terminals O or -E, -A of the electronic device 30 (FIG. 1).

Claims (10)

Claims: 1. Synchronous switch with electronic control, in which the switching movement is achieved by mechanically releasing an energy storage device a control force is initiated, d a d u r c h marked that upon generation the control power through the electronic control system, including the to its supply serving auxiliary power source arranged on the high-voltage side is, between the organ influenced by the control force and the organ for release of the energy store is a mechanical amplifier with a rotating mass. 2. Synchronous switch according to claim 1, characterized in that the rotating Mass of the mechanical amplifier in rotation at the same time as the switch-off command is moved. 3. Synchronous switch according to claim 1, characterized in that the connection between the rotating mass and the organ for releasing the energy store is produced by tooth engagement. 4. Synchronous switch according to claim 1, characterized characterized in that the connection between the rotating mass and the organ for releasing the energy store by means of a locking mechanism in the manner of a freewheel will be produced. 5. Synchronous switch according to claim 2, characterized in that the rotating mass via an isolating transmission element through one to earth potential lying drive, in particular compressed gas drive, is set in rotation. 6. Synchronous switch according to claim 2, characterized in that the rotating mass is the rotor of a Generators forms, as the auxiliary power source lying on high voltage potential is used for the electronic control system of the switch. 7. Synchronous switch after Claim 1, with electronic control for synchronous disconnection, characterized characterized in that the secondary current is excited by one of the current to be interrupted 1 converter is rectified and controls a transistor in such a way that a measuring capacitor during the time when the rectified voltage is less than a predetermined one Value, is charged and discharged again when this specified voltage is exceeded becomes, whereby a known trigger flips and a previously charged capacitor discharges through the trip coil of the switch. B. Synchronous switch according to claim 7, characterized in that at a half-wave duration of the to be interrupted Current (tH), which is less than about twice the pre-release time, the measuring capacitor is only charged to a voltage that is below the breakover voltage of the trigger lies, so that in this case the switch-off does not take place. 9. Synchronous switch after Claim 7, characterized in that with a main stream (i1), which is below the synchronous control limit is (asynchronous switch-off), the measuring capacitor is on a higher voltage is charged than with synchronous control, which causes the Triggers and thus the supply of the trip coil. 10. Synchronous switch according to claim 1, with electronic control for quick reclosing, characterized in that both with the current to be interrupted and with the secondary current of an air-gap converter excited by the main current, one toroidal core each chained whose secondary coils are connected in series (via a switch), where either at the zero crossing of the main current (il) or the secondary current of the Air-gap converter (i ...) rectified voltage pulses and one Trigger circuit are supplied, which when at least one of these pulses occurs tilts, whereupon a previously charged capacitor discharges via the trip coil and thereby initiates reclosing.