DE1256322B - Synthetic test circuit for testing high-voltage high-performance switches - Google Patents

Description

Synthetic test circuit for testing high-voltage high-performance switches They are synthetic test circuits (cf. the article by Slamecka in the "ETZ-A", 1963, pp. 581 to 586, Figures 9 and 12) based on the principle of controlled stress superposition known. In these known synthetic test circuits, the High current circuit after the zero crossing of the high current the returning voltage, and the high voltage source only becomes effective after the zero crossing, whereby without a tension-free break, the required further course of the recurring tension is achieved.

The high voltage source is switched via a switching device as soon as the the recurring voltage generated by the high-current circuit reaches a certain value has, a choke coil and an ohmic damping resistor to the test Switch or to the auxiliary switch in series with the switch to be tested placed.

According to the invention, the ohmic damping resistance is parallel to the choke coil switched.

Compared to the known arrangement, this is how experiments are achieved have shown, in a simple manner, an even smoother course of the first voltage rise the recurring voltage, d. i.e. when the high voltage source is switched on no change in the steepness of the recurring voltage at the switch to be tested a. An ohmic resistor in parallel with the choke coil in the high-voltage circuit represents a new type of damping method in the high-voltage circuit, namely this resistance on the one hand effective as parallel damping, on the other hand it provides for bridging the choke coil for aperiodic charging of the capacitor, which is parallel to the auxiliary switch or the switch to be tested. There is an aperiodic increase in voltage first its greatest steepness, but a parallel damped transient process first reaches its lowest steepness, there is still a steepness of the at the beginning Settling voltage of the high-voltage circuit with an approximately straight course. As already mentioned, this novel damping method achieves that the curve of the settling voltage is improved, i.e. when the high voltage circuit supplied transient voltage becomes effective, it has a large initial steepness, thus the total settling voltage, which is the result of the settling voltage of the high-current circuit and that of the high voltage circuit is formed smoothly.

The dimensioning of the damping resistance parallel to the choke coil depends on the desired damping or the desired over- vibration factor the settling voltage supplied by the high-voltage circuit. As already mentioned. is parallel in the known circuits with controlled voltage superimposition to the switch to which the high voltage source via the choke coil and the Switching device is connected a capacitor in series with an ohmic Resistance. It is expedient to use this ohmic circuit in the circuit according to the invention Make resistance as small as possible, so that the overshoot factor of the recurring Voltage essentially only through the ohmic one lying parallel to the choke coil Damping resistance and the ohmic, possibly in series with the choke coil Resistance is determined. It is advantageous not to have an ohmic resistor in series to switch with the capacitor and put an ohmic resistor in one of the Lay connecting lines between switch and capacitor and the high voltage source to be connected to the capacitor via the choke coil and the switching device.

This ohmic resistance makes the capacitor when the switch failed during the test, protected from excessive discharge current. The cushioning the voltage curve at the switch is not influenced by this resistance.

Two exemplary embodiments of the invention are shown in the drawing.

In Fig. 1 is the high voltage source via a choke coil and a controlled spark gap after the zero crossing of the high current to the auxiliary switch connected. With 1 is the switch to be tested, with 2 the one in series with it Designated auxiliary switch. This series connection is parallel to the secondary winding a transformer 3.

The primary winding of this transformer is via a choke coil 4 and a switch s with the generator 6 connected. In the high current circuit lies in a manner known per se in parallel with the secondary winding of the transformer an ohmic resistor 8 and the series connection of a capacitor 9 and a Ohmic resistance 7. The generator and the transformer 3 form the high-current source. which the required breaking current for the switch to be tested 1 at an opposite the rated voltage of the switch delivers a lower voltage. The high voltage circuit consists of the charged capacitor 10, which forms the high voltage source, the Capacitor 13, which is parallel to the auxiliary switch 2 of the inductor 15, to the according to the invention an ohmic damping resistor 21 is connected in parallel, and of the controlled spark gap 16. In addition, in the exemplary embodiment, FIG Series with the capacitor 10 is an ohmic resistor 22 of a small ohmic value, the serves as a protective resistor for the capacitor 10 when the inductor 15 earth fault receives. In one of the connecting lines between capacitor 13 and auxiliary switch 2, a protective resistor 23 is switched on, in the exemplary embodiment between the common connection point of switches 1 and 2 and the lower terminal of the capacitor 13 But it could also be placed between the upper terminal of auxiliary switch 2 and the place the upper terminal of the capacitor 13. This protective resistance is small compared to that used in the known circuit which is improved by the invention ohmic resistance in series with the capacitor 13. The spark gap 16 has an ignition electrode 17. It is in a manner known per se via a control unit 8 connected to a resistor 20 in series with the spark gap 19 in parallel to the series connection of switch 1 to be tested and auxiliary switch 2.

Switches 1 and 2 are closed for testing. Then will the switch 5 is closed.

Then the two switches 1 and 2 receive the switch-off command. she are traversed by a current that is supplied by the high current source, but its driving voltage is lower than the nominal voltage of the switch. At the first or one of the following zero crossings of the high current, the contacts have the switch has reached the extinguishing distance, this being ensured in a manner known per se must be that up to this point in time the arcs burn in both switches.

It now occurs after the zero crossing of the high current on both of them Switches 1 and 2 on the recurring voltage of the high current circuit.

It is divided between switches 1 and 2 in proportion to the capacity of the capacitor 13 to the self-capacitance of the switch 1. One becomes the capacity of the capacitor 13 in a known manner substantially, e.g. make a hundred times larger than the self-capacitance of the switch 1, so that the recurring voltage that is supplied by the high-current circuit, is practically completely on switch 1.

By appropriate choice of the voltage of the high-current circuit, i. H. the secondary winding of the transformer 3, the frequency and damping of the high-current circuit, it is achieved that the recurring voltage at switch 1, from the high current circuit is supplied, has the required initial course, as determined by test specifications or conditions imposed by the consumer.

The frequency of the high current circuit is essentially determined by the inductance of the choke coil 4 including the leakage inductance of the transformer 3 and the generator 6 and the capacitance of the capacitor 9, while the attenuation is essentially determined by the ohmic resistors 7 and 8.

As soon as this recurring voltage supplied by the high current circuit has reached a certain value, i.e. after the high current has passed zero, for example, shortly before reaching its first maximum, the spark gap strikes 19 through, and there is a pulse-like voltage across resistor 20. This voltage pulse is via the control unit 18, for. B. a capacitor or a valve, the ignition electrode 17 supplied so that the spark gap 16 breaks down.

The charged capacitor 10 is thereby connected via the parallel connection of choke coil 15 and ohmic damping resistor 21 and the ohmic resistance 22 connected to the capacitor 13. The charge on the capacitor 10 is thereby so taken that the return voltage resulting from the high current circuit and those occurring at the capacitor 13 in cooperation with the elements 10, 22, 15, 21 Add the recurring voltage to the desired curve. As experiments have shown becomes through the parallel connection of the ohmic damping resistor 21 to the choke coil 15 achieves that when the high voltage source is switched on, there is no change in the slope the recurring voltage at the switch occurs, so that a simple way smooth initial course of the recurring voltage is achieved.

The resistor 23 protects the capacitor 13 when the switch 2 breaks down during the test, since it causes the discharge current of the capacitor 13 is limited.

In the embodiment of FIG. 1 the high voltage circuit is in parallel connected to the auxiliary switch. You can also use the high voltage circuit in in a manner known per se parallel to the switch to be tested, as shown in FIG is shown. As far as the parts with those of the F i g. 1 match are the the same reference numerals are chosen.

A capacitor 13 is parallel to the auxiliary switch 2 The switch to be tested has a capacitor 24. None of the capacitors as usual, an ohmic resistor connected in series, but between the connection point of switches 1 and 2 and the connection point of the Kc: '. capacitors 13 and 24 is a resistor 23. The capacitor 24 is connected to the choke coil 15, a controlled spark gap 16 with the ignition electrode 17 and the ohmic resistor 22 the charged capacitor 10 is connected. Is parallel to the choke coil 15 according to the invention an Obmsch damping resistor 21. The resistor 23 protects in the circuit according to the embodiment, the capacitor 24 from a too high Discharge current when the switch 1 to be tested or the capacitor 13 fails in the event of failure of the auxiliary switch 2.

The series connection of spark gap 19 and ohmic resistor In contrast to the arrangement according to FIG. 1 connected so that the upper Electrode is connected to the upper terminal of switch 2.

To test, the two switches that are closed after Closing the switch 5 received the switch-off command. After reaching the extinguishing distance delivers after the zero crossing of the current in a manner known per se, the High current circuit the recurring voltage. In the area of the maximum of this voltage the spark gap 19 breaks through, and a voltage pulse is generated as a result the ignition electrode 17 given so that the spark gap 16 breaks through and now the high-voltage circuit in cooperation with the high-current circuit the desired supplies further course of the returning voltage at switch 1.

Because the damping resistor 21 is parallel to the choke coil 15 lies. there is practically no change in the slope in the first increase in the recurring Voltage at switch 1 on.

Claims (4)

Claims: 1. Synthetic test circuit for testing high-voltage high-performance switches with an auxiliary switch in series with the switch to be tested and with a controlled one Voltage superimposition, whereby after the zero crossing of the high current initially the High-current circuit supplies the required recurring voltage and only after Zero crossing of the high current the high voltage source via a switching input direction, a choke coil and an ohmic damping resistor to one of the two switches is connected, so that this damping resistance (21) is connected in parallel to the choke coil (15). 2. Arrangement according to claim 1, characterized in that parallel to the switch to be tested (1) or to the auxiliary switch (2), which is connected via a choke coil (15) and a switching device (16) connected to the high voltage source (10) is, only one capacitor (24 or 13) is connected. 3. Arrangement according to claim 2, characterized in that in the Connection line from capacitor (24 or 13) and switch (1, 2) is an ohmic one Resistor (23) is turned on and parallel to the capacitor (24 or 13) the High voltage source (10) via a choke coil (15) and a switching device (16) is connected. 4. Arrangement according to claim 3, characterized in that the resistor (23) between the common connection point of auxiliary switch (2) and to be tested Switch (1) and one terminal of the switch that is parallel to the switch to be tested Capacitor (24) or a terminal of the capacitor lying parallel to the auxiliary switch (13) is connected.