DE3813428C1 - Circuit arrangement for overvoltage testing - Google Patents

Abstract

To test the overvoltage of a load (6), a circuit arrangement should inexpensively generate overvoltage pulses, the peak value and variation in time of which are variable. For this purpose, a first AC converter (1) applies to the load (6) its rated voltage and a connectable second AC converter (2) connects the load to an adjustable voltage which is higher than the rated voltage. The higher voltage can be adjusted, particularly by phase-angle control and is phase-shifted compared with the rated voltage applied to the load (6). <IMAGE>

Description

The invention relates to a circuit arrangement for overvoltage testing a consumer. Such an overvoltage test is e.g. B. in DIN VDE 0160 - Section 7.3.1, valid from January 1st, 1988.

To do this, voltage pulses are required that differ from the peak value of the nominal voltage of the consumer in about 0.1 ms to 2.3 times the apex value of the nominal voltage and after 1.3 ms at the earliest Peak value minus 0.65 times the peak value of the nominal voltage are falling.

Such voltage pulses can be generated in accordance with the aforementioned DIN VDE 0160 - Section 7.3.1, Figure 13, for example in that the nominal voltage, with which the consumer has an impedance of one or three phase AC network is powered by a thyristor-controlled Discharge of a capacitor in an additional to the consumer closed test device a voltage peak is superimposed. Such Circuitry for overvoltage generation, however, is technically based manoeuvrable and can only do one by the capacitor discharge process bring about the given pulse form, which always remains constant over time.

The invention has for its object a circuit arrangement of Specify generic type that surge with little effort  generates impulses in their peak value and in their chronological course are variable.

This object is characterized according to the invention by the in claim 1 features resolved.

Due to the higher voltage adjustable via the second AC power controller Overvoltage pulses can be easily created in their time consequence, in the course of time and in the amount of the test specified conditions are easily adaptable.

Advantageous refinements of the circuit arrangement according to the invention are characterized in claims 2 to 8.

The invention is intended below with reference to the drawing for an embodiment example will be explained. It shows

Fig. 1 shows the principle circuit diagram of a circuit arrangement for surge testing according to the invention,

Fig. 2 shows the time course and the derivation with the circuit arrangement according to Fig. 1 generated voltage pulses and

Fig. 3 is a circuit diagram for the control of the two AC power controller shown in Fig. 1.

According to FIG. 1, a consumer 6 as a test object is to be subjected to a test with one or more overvoltage pulses. For this purpose, it is connected to connections x 1 , x 2 of a circuit arrangement which provides overvoltage pulses in the required form.

Via the connections x 1 , x 2 , its nominal voltage is applied to the consumer 6 by means of a first alternating current regulator 1 , so that the consumer 6 operates under normal operating conditions.

A switchable second AC power controller 2 also applies an adjustable voltage to the consumer 6 via the connections x 1 , x 2 , which is higher than the nominal voltage. This superimposed alternating voltage is preferably phase-cut and phase-shifted (in order, for example, to meet the required pulse shape in overvoltage tests according to the aforementioned DIN VDE 0160). The height of the superimposed voltage is connected upstream via a second AC power controller 2, set in the Übersetzungsver ratio adjustable transformer. 4

The phase control is carried out by the AC power controller 2 in the desired position every half cycle. The phase shift takes place by appropriate selection of the input AC voltage of the second AC power controller 2 . A 30 ° phase shift with respect to the nominal voltage made available via the first alternating current regulator 1 is e.g. B. with a single available AC voltage network with three phases L 1 , L 2 , L 3 and a common zero point N can be easily achieved by appropriate selection of chained voltages and phase voltages: B. a three-phase 380 V network with zero point available, so in the case of a nominal voltage of the consumer 6 of 220 V, this voltage as phase voltage L ₁ N between phase L 1 and the zero point N of the three-phase network over the first AC power controller 1 provided. The chained voltage L ₁ L ₂ between phases L ₁ and L _{2 of} the three-phase network has a phase shift of 30 °. This interlinked voltage L ₁ L ₂ can therefore only be transformed up to the required level of the test voltage pulse via the transformer 4 (e.g. so that the level of the superimposed voltages together reaches 2.3 times the peak value Û _{N of} the nominal voltage) and via one Phase angle through the alternating current regulator 2 of the nominal voltage at the connections x 1 , x 2 so that the test voltage pulse has the desired shape. The commutation of the current on the AC power controller 2 with the phase-shifted higher voltage begins at the time of ignition of its controlled semiconductors and ends at the time when the voltage has dropped below the instantaneous value of the nominal voltage.

In the event that the nominal voltage of the consumer 6 z. B. is 380 V, supplies a three-phase 380 V network with zero to the first alternator 1 the nominal voltage - as indicated in Fig. 1 - as a chained voltage L ₁ L ₂ between phases L ₁ , L _{2 of} the three-phase network. Then the phase voltage NL ₂ between the zero point N and the phase L _{2 of} the three-phase network with a phase shift of 30 ° is provided for the second AC power controller 2, taking into account the polarity and transformed via the transformer 4 to a desired higher voltage NL ' ₂ . Is determined by the AC power controller 2 (preferably) with phases broached this higher voltage is superimposed on the AC power controller 1 to the terminals x 1, x 2 supplied rated voltage and demVerbraucher 6 fed as a test voltage.

The required initial steepness of the voltage to be superimposed on the nominal voltage can, as shown in FIG. 1, be ensured by an additional capacitor 7 connected upstream of the second AC current regulator 2 .

The time profile of the voltages u of a three-phase network L ₁ , L ₂ , L ₃ with the zero point N , which, as described, provides the input voltages for the two AC controllers 1 and 2 , is shown in FIG. 2. Also, there is the resulting x 1 at the terminals, x 2 voltage applied inter _alia at appropriate superimposition of two of these voltages with a phase shift by an angle of 30 ° and a phase angle of the superimposed high transformed via the transformer 4 Voltage L ₁ L ' ₂ or NL ' _{2 shown} for the case of the nominal voltages of 220 V or 380 V.

A control electronics 3 indicated in FIG. 1 and shown in more detail in FIG. 3 ensures that the ignition of the semiconductors of the two alternating current actuators 1 and 2 causes the test voltage u _a shown in FIG. 2 at the connections x 1 , x 2 lies and the corresponding pulse current i flows through the consumer 6 . The control electronics 3 is set via an operating element 5 so that a desired phase angle ϕ occurs at the superimposed higher voltage and that 6 overvoltage pulses are supplied cyclically or as positive or negative individual pulses by the superimposition of the higher voltage.

According to FIG. 3, the control of the semiconductor switch of the first AC power controller 1 takes place by means of an ignition pulse stage 312, which is supplied with a control DC voltage, via a first ignition pulse transmitter 313 . The synchronization of the ignition pulses emitted by the ignition pulse stage 312 with the AC voltage applied to the first AC power controller 1 takes place by means of a first synchronization stage 311 .

The control of the semiconductor switch of the second alternating current controller 2 with a phase gating ϕ serves a phase gating control 323 , which is synchronized via a second synchronization stage 321 with the alternating voltage specified for the second alternating current actuator 2 . The phase control controller 323 is connected via a first AND gate 324 and a second ignition pulse transmitter 325 to the control connections of the semiconductor switches of the second AC controller 2 .

The phase shift in the phase control 323 is set via a potentiometer R 1 of the operating element 5 .

The control element 5 additionally has a switch S 1 , the actuation of which releases the overvoltage pulses (that is, the commissioning of the second AC power controller 2 ) is initiated. The switch S 1 starts a counter 327 , the outputs of which are connected to the inputs of a second AND gate 328 . The AND gate 328 is connected from the output side to a pulse time stage 329 , each of which acts on the second input of the first AND gate 324 for a time determined by it and thus causes the switching of the ignition pulses from the phase control 323 to the second AC power controller 2 .

In order to be able to deliver the overvoltage pulse either cyclically or as a positive or negative individual pulse by appropriately igniting the second AC power controller 2 to the consumer to be tested, the operating element 5 has a changeover switch S 2 with which the three operating modes previously mentioned can be set.

In the (lower) switching position shown, a positive single pulse is given, while in the middle position of the changeover switch S 2 a ne negative single pulse is given to the consumer by correspondingly firing the second AC power controller 2 once. In these two positions of the changeover switch S 2 , on the one hand the output pulse of the second AND gate 328 and on the other hand a positive (lower position from the changeover switch S 2 ) or negative (middle position of the changeover switch S 2 ) pulse emitted by a comparator 322 third AND gate 326 , which is connected on the output side to the clock input of counter 327 .

The comparator 322 is also acted upon on the input side by the second synchronizing element 321 .

In the upper position of the changeover switch S 2 , on the one hand, a positive DC voltage is continuously applied via an input resistor R 2 and, on the other hand, synchronized pulses emitted by the comparator 322 to the third AND gate 326 , which causes the counter 327 , the second AND gate 328 and the pulse time stage 329 cyclically fulfills the AND condition of the first AND gate 324 . Correspondingly, the second AC power controller 2 is ignited cyclically and the consumer is repeatedly occupied with overvoltage pulses.

Claims (8)

1. Circuit arrangement for overvoltage testing of a consumer, characterized in that a first AC actuator ( 1 ) loads the consumer ( 6 ) with its nominal voltage and a switchable second AC actuator ( 2 ) to the consumer ( 6 ) an adjustable, higher than the nominal voltage Tension. 2. Circuit arrangement according to claim 1, characterized, that the higher voltage is adjustable by phase control. 3. A circuit arrangement according to claim 1 or 2, characterized in that the higher voltage is out of phase with the nominal voltage applied to the consumer ( 6 ). 4. Circuit arrangement according to one of claims 1 to 3, characterized in that the higher voltage is cyclically continuously or as a single pulse which is superimposed on the consumer ( 6 ) at the nominal voltage. 5. Circuit arrangement according to one of claims 1 to 4, characterized in that the higher voltage is obtained via a transformer ( 4 ) from the same network as the nominal voltage. 6. Circuit arrangement according to one of claims 1 to 5, characterized, that the nominal voltage from one phase voltage of a three-phase Network and the higher voltage from the chained voltage of two Phases of this network is won. 7. Circuit arrangement according to one of claims 1 to 5, characterized, that if the rated voltage is the chained voltage of a three phase network is specified, the higher voltage through the high transform one of the phase voltages of this network is formed. 8. Circuit arrangement according to one of claims 1 to 7, characterized in that an additional, the voltage steepness when switching on the second AC power controller ( 2 ) determining capacitor ( 7 ) is connected upstream of the second AC power controller ( 2 ).