DE3900370C1 - Synthetic circuit for testing the breaking power of high-voltage circuit breakers - Google Patents

Abstract

Synthetic test circuits are used for testing high-voltage circuit breakers under conditions which are intended to correspond to the loads encountered in practice. To match the test conditions to the higher voltages of current power supply systems, the known Weil circuit, which is composed of a high-current circuit and a high-voltage circuit, was supplemented by a further high-voltage circuit, in such a manner that these voltages are added together. According to the invention, an addition of this second high-voltage circuit (II) with simple technical means and at a time which could be determined accurately, was achieved by the fact that the auxiliary breaker (HS2) adding this second high-voltage circuit is acted upon by a charging current (IE) with the opposite direction to the additional current (IZ) of the second high-voltage circuit (II) by means of an RC section (RE, CE) branching off from the first high-voltage circuit (I), in such a manner that the quenching of the arc of the auxiliary breaker (HS2) is forced by an artificial zero crossing. <IMAGE>

Description

The invention relates to a synthetic circuit for testing the switch-off performance of high voltage circuit breakers at the test switch by means of a high current circuit and a first and a second high chip circuit with an opening current and after an interruption Current with two, capacities drawn, voltages of the two high voltage circles is applied so that the desired shape of the one Vibration test voltage results in that a first with the test switch in Row of auxiliary switches interrupts the high current circuit, the first high voltage circuit the test switch first with a the high current superimposed oscillating current and after the arc has extinguished the test switch with the first voltage applied to the second opposite voltage from the second high voltage circuit then over is stored when the arc switches on the second high-voltage circuit tendency, second auxiliary also in series with the test switch switch is extinguished.

It is for checking the breaking capacity of high voltage circuit breakers usual, because of the short available only to a limited extent an indirect test with the help of perform synthetic circuits. These usually consist of a high current source and a high voltage source. The switch to be tested is initially charged with the breaking current and immediately after the Interruption of this current claimed for dielectric strength. By a  Such synthetic test circuit will artificially the conditions represents how they occur when switching off line networks. Even there a strong recurring voltage occurs after the interruption of the current which a switch has to endure without causing the Arc comes.

F. Weil succeeded in the first realistic replica of a switch load using a synthetic test circuit with a proposal known to the person skilled in the art as a Weil circuit (e.g. described in AEG-Mitteilungen 9/10, 1953, pages 281f.). This circuit consists essentially of a synchronous generator that feeds a high-current circuit via a high-current transformer, and a high-voltage circuit that supplies the oscillating voltage for the switch test and that consists of a high-voltage oscillating circuit with a capacitor battery charged before the test and a choke coil. In addition, it contains an RC element that determines the transient voltage according to frequency and damping. The high-voltage circuit is closed by a switching spark gap, excited by the short-circuit current of the high-current circuit itself, via the arc of the test switch to the resonant circuit, the high-voltage circuit being switched on shortly before the short-circuit current passes zero and thereby generating an oscillating current half-wave which is added to the short-circuit current in the test switch and this in the last Replaces part of its existence. In the Weil circuit, current and voltage come from the same source at the crucial moment, namely the high-voltage resonant circuit. The frequency and damping of the transient process can be regulated by the capacitors and resistors and adapted to the different network conditions.

The further expansion of the power supply networks with higher voltages made it required that the existing test facilities be adapted to these conditions were. For this purpose, proposals have been developed that provide for a insert another high-voltage circuit in the synthetic test circuit, through which the test voltage could be increased further.

DE 24 43 407 C2 is a synthetic circuit at the beginning known type known. This circuit uses a second high voltage nungskreis in the test circle that by means of another Spark gap the additional current of the second high-voltage circuit from one  additional auxiliary switch associated with this second high-voltage circuit into a is commutated to this parallel capacitance. This takes place a forced zero crossing of the current takes place in the second auxiliary switch, which is interrupted. In this way, the test switch with a applied to the second voltage opposite to the first voltage, whereby there is an addition of the voltages of the two high-voltage circuits and a correspondingly higher test voltage is applied to the test switch can be.

However, for such a configuration of the synthetic circuit compared to the Weil circuit, another spark gap with a timing control channel required to ignite this spark gap. This doesn't just mean a considerable additional effort for the circuit but also represents a certain uncertainty in the course of the test because the timely ignition the spark gap is problematic.

The invention has for its object to provide a synthetic circuit to make available a second high-voltage circuit, in which the second High voltage circuit with simple technical means all in one determining time is safely switched on.

The object is achieved with a synthetic circuit solved with the features specified in claim 1.

The advantage of the invention is that the time of the voltage superimposition of the voltages of the two high-voltage circuits can be precisely determined by appropriate dimensioning of the elements of the second high-voltage circuit and the RC element of the first high-voltage circuit. This choice is to be made so that the current of the second high-voltage circuit is adapted to the charging current of the RC element according to size and steepness so that the zero crossing takes place at the time required for the voltage superimposition. A separate time control channel and the spark gap are omitted, which simplifies and accelerates the test procedure and considerably reduces the expenditure on equipment.

Appropriate refinements and developments of the invention are the See subclaims.

An embodiment of the invention is based on the drawing explained. It shows

Fig. 1 shows a basic circuit and

FIG. 2 shows the current and voltage profiles belonging to FIG. 1.

The basic circuit shown in Fig. 1 first of all has all the components of the classic Weil circuit: A synchronous generator G feeds via a top switch S _D and a high current transformer Tr ₁ , a high current circuit which has a limiting choke L _B , a first auxiliary switch HS ₁ and contains the test switch PS . The voltage circuit of the Weil circuit corresponds here to the first voltage circuit I. It contains the elements of the high-voltage resonant circuit, with a vibration inductor L , a spark gap F ₁ and a first capacitor C _S lying parallel to the test switch. The damping resistor R _E and the second capacitor C _E are parallel to this and also parallel to the test switch. The spark gap F ₁ is equipped with a control device, not shown, which detects the short-circuit current of the high-current circuit as described above.

As a further development of the Weil circuit, a second high-voltage circuit II is inserted. For this purpose, a second auxiliary switch HS ₂ is in series with the test switch S and the other elements in series in such a way that it comes to lie between the earth potential and the test switch PS . The earth potential side of the second auxiliary switch HS _{2 is} connected to the vibration inductance L , the spark gap F ₁ and the first capacitor C _S and the damping resistor R _E with the second capacitor C _E are between the test switch PS and the second auxiliary switch HS ₂ to the High current circuit connected. At this point, the second high-voltage circuit II is also connected to the high-current circuit. This consists of a third capacitor C _Z , which is connected in parallel to the second auxiliary switch HS ₂ , these two elements being connected on their voltage side to a high-voltage transformer Tr ₂ via a resistor R _S and an inductor L _S. This high-voltage transformer Tr ₂ is fed on the primary side of the high current transformer Tr _1, wherein the high-voltage transformer Tr is connected poled ₂ opposite to the high-current transformer Tr. ₁ The further inductances L ₁ and the further capacitances C ₁ are inserted into the first high-voltage circuit I here. In the case of testing under short-circuit conditions, they simulate the short-circuited line at the end.

The course of a switching test now proceeds as follows with the current and voltage curves shown in FIG. 2: Before the test begins, the two auxiliary switches HS ₁ and HS ₂ and the test switch PS are closed. The first capacitor C _S is charged via a connection, not shown, and the synchronous generator G is excited to the desired voltage. The start of the test is initiated by closing the top switch S _D , whereupon the short-circuit current I _K begins to flow in the high-current circuit. At the desired point in time, after a possibly a few current half-waves, the test switch PS and the auxiliary switches HS ₁ and HS _{2 are} opened approximately simultaneously. A few 100 microseconds before the next current zero crossing of the short-circuit current I _K , the spark gap F ₁ is now ignited by the control device, as a result of which the first capacitor C _S oscillates via the inductance L , the test switch PS and the auxiliary switch HS ₂ , in such a way that the oscillation current I _S and the short-circuit current I _K are superimposed in the switching path of the test switch PS . At time t ₁ , the short-circuit current I _{K reaches} its zero crossing and the first auxiliary switch HS ₁ clears. Via the test switch PS and the auxiliary switch HS ₂ , the oscillating current I _{S introduced} at time t ₀ flows out of the conventional Weil circuit, which corresponds to the first high-voltage circuit I, up to its zero crossing at time t ₂ . At this point in time t ₂ , the test switch PS clears and the voltage UW ₁ coming from the first high-voltage circuit I builds up on it. At the time t ₁ , after the short-circuit current I _{K has passed} zero and has been interrupted by the auxiliary switch HS ₁ , the high-voltage transformer Tr _{2 is} excited. This creates the voltage UTR ₂ on its secondary side, which drives the additional current I _Z. When the voltage UW ₁ builds up in the first high-voltage circuit I, the second capacitor C _E draws a charging current which is superimposed on the additional current I _Z which comes from the second high-voltage circuit II. Since the charging current I _E the additional current I _Z is opposite, both streams complement briefly to zero, thereby forcing the deletion of the second auxiliary scarf ters HS. ₂ The extinction takes place at time t ₂ , the dimensions and steepness of these currents being determined by the dimensioning of the components of the second high-voltage circuit II and of the second capacitor C _E and of the damping resistor R _E such that the voltage UW coming from the first high-voltage circuit I ₁ and the voltage UW ₂ coming from the second high voltage circuit II give the desired test voltage UW . The voltage UW ₂ arises from the fact that by deleting the second auxiliary switch HS _2, the energy in the transformer Tr ₂ , which was previously absorbed by the third capacitor C _Z and in part also by the second capacitor C _E , is also added to the test switch PS pending.

Claims (4)

1.Synthetic circuit for testing the breaking capacity of high-voltage circuit breakers in which the test switch is first subjected to a breaking current by means of a high-current circuit and a first and a second high-voltage circuit and, after this current has been interrupted, with two capacitances drawn from the two high-voltage circuits that the desired shape of the transient test voltage results from the fact that a first auxiliary switch in series with the test switch interrupts the high-current circuit, the first high-voltage circuit first providing the test switch with a high-current oscillating current and after the arc of the test switch has been extinguished with the first voltage acted upon, which overlaps with the second opposite voltage from the second high-voltage circuit when the arc of a second, also connected to the test switch in series with the test switch n auxiliary switch is extinguished, characterized in that the luminous flux of the second auxiliary switch is extinguished in that the RC element (R _E , C _E ) determining the voltage form of the first high-voltage circuit ( _I ) together with the second high-voltage circuit (II ) is connected to the voltage side of the second auxiliary switch (HS ₂ ) and the RC element (R _E , C _E ) and the second high-voltage circuit ( II) are dimensioned such that the charging current (I _E ) of the RC element (R _E , C _E ) at the time required for the voltage superimposition, briefly supplemented with the current (I _Z ) of the second high-voltage circuit (II) to zero. 2. Synthetic circuit according to claim 1, characterized in that the high current circuit and the first high voltage circuit (I) are constructed as a Weil circuit, the second auxiliary switch (HS ₂ ) of the second high voltage circuit (II) between the capacitors (C _E , C _S ) of the high-voltage resonant circuit (L, F ₁ , C _S , R _E , C _E ) of the first high-voltage circuit (I) is arranged. 3. Synthetic circuit according to claim 1 or 2, characterized in that the second high-voltage circuit (II) from a high-voltage transformer (Tr ₂ ) is fed, the primary side of a high-current circuit supplying the high-current transformer (T 1 ) that the high-voltage transformer (Tr ₂ ) to the high current transformer (T 1 ) is connected with opposite polarity and that to the second auxiliary switch (HS ₂ ) an inductor (L _S ) and a resistor (R _S ) are connected in series and a capacitor (C _Z ) connected in parallel is, the second auxiliary switch (HS ₂ ) and the capacitor (C _Z ) with one side are at ground potential. 4. Synthetic test circuit according to one of claims 1 to 3, characterized in that one or both high-voltage circuits are equipped with inductors (L 1 ) and capacitors (C 1 ) which correspond to the inductors and capacitors of power supply networks.