SU779941A1 - High-voltage power-diode testing device - Google Patents

Description

the input of an optoelectronic converter, the output of which is connected to the input of a pulse counter connected to the first inputs of the code comparator, the second inputs of which are connected to the pulse setter, and the output of koMnapaTopa connected to the second ignition pulse modulator.

FIG. 1 is a functional diagram of a device for testing high voltage valves; in fig. 2 shows the optical shutter design of the transducer code.

The device contains a source of pulsed current 1, the positive pole of which is connected to the upper arm of voltage divider 2 and through a ballast resistor 3, a parallel chain, from the additional ballast 4 and vacuum switch 5, the discharge inductance b is connected to the test discharge 7. The cathode The bottom 7 is connected to the negative pole of the current source 1 and connected to the common point of the test device. The middle point of the voltage divider 2 is connected to the first input of the comparison circuit 8, the second input of which It is connected to the output of the voltage source 9, and the output of the comparison circuit 8 is connected to the ignition pulse modulator 10 of the test discharger 7 and to the first input of the command pulse extraction unit 11, the second input of which is connected to the first output of the pulse switching system 12, the first input of the block 11 is connected to the control input of the induction dynamic drive 13, and the second output is connected to a pulsed optical radiation source 14. The second output of the control system 12 is connected to the control loop input of the test The current / source / 1, The source of the high-voltage pulsed voltage 15 is connected to the negative pole through the auxiliary controlled discharge voltage 16 and the ballast resistance 17 to the test y discharge floor 7. The positive pole of the voltage source 15 is connected to the common point of the device. Synchronizer output. 18 is connected to the input of the pulse control system 12, the third input of which is connected to the input of controlling the operation of the high voltage circuit (source) 15.

The optical radiation source 14 is connected via the first flexible light guide 19 to the converter input neP € solution-code 20, the output of the converter is connected by the second light guide 21 to the input of the optoelectronic converter 22, the output of which is connected to the input of the pulse number counter 23 The counter outputs are connected to the first inputs of the code comparator 24 , the second inputs of which are connected to the outputs of the setting unit for the number of pulses 25, and the output is connected to the input of the ignition pulse modulator 26 of the auxiliary arrester 16.

The device works as follows.

The synchronizer 18 generates a primary series of sync pulses of a predetermined following frequency, which enter the pulse control system 12, at the second output of which, a start command generates a packet of sync pulses of a predetermined duration that provide the input current of the pulse source 1. From the output of the voltage divider 2, information about the magnitude of the charging voltage of the output capacitive filler source 1 is fed to the first input of the comparison circuit 8, the second in the course of which is connected to the source of the reference voltage 9. At the moment when the charge voltage of the capacitive storage device reaches a predetermined level determined by the reference signal, the comparison circuit 8 generates a pulse signal which is fed to the control input of the ignition pulse modulator 10 of the test discharge 7 The discharge of the output capacitive accumulator of the source 1 occurs through the ballast resistor 3, the closed contacts of the vacuum switch 5, inductance 6, the tested discharger 7. At the second output of the control system 12 is formed by a single pulse applied to the input charge control the high voltage pulse source 15 and the voltage going preconditioning source 15 to the control of high voltage surge arrestor 7 test.

The test of the discharger 7 is monitored for the speed of restoring the electrical strength after the auxiliary power-controlled discharge accumulator 16 is discharged. The discharge of the output capacitive energy storage of the source 15 occurs through the output accumulator of the source 1, ballast / resistance 3, additional ballast resistance 4, discharge inductance b , the ballast resistance 17 and the auxiliary discharge 16. The moment of application of the test voltage is determined by two conditions: the length of the specified packet of pulses and the required duration of the time delay application of the test voltage.

The command pulse extraction unit 11 fixes the last pulse of a given burst of sync pulses. This impulse arrives at the control input of the 13 Vi drive through the control system 12 at the input of the pulsed radiation source 14, the radiation source 14 generates a light pulse for the required duration, and the drive 13 opens the Biv vacuum switch the test current discharge circuit introduces an additional ballast resistance 4. Application time delay the test voltage is provided by comparing the setting codes of the number of pulses 25 and the pulse counter 23 on the code comparator 24. If two numbers of pulses are equal, The comparator 24 outputs a pulse to the auxiliary ignition pulse modulator 26 of the auxiliary glitter 16. At the counter 23, the code is received from the optoelectronic converter 22, which converts the number-pulse code generated from the light flux of the optical source 14, the 1-code 20 is moved using the converter modulating optical shutter 27 of which is made in the form of a diaphragm 28 with transverse slots, the diaphragm being rigidly attached to the movable contact of the vacuum switch 5, the ends of the flexible light guides 19 and 21.

Thus, the device described provides the testing of high-power ignitron gaps in the frequency mode at full load current and from a low-voltage power source. The control of the recovery time of the tested arresters by a high voltage can be carried out after passing through the discharge of a burst of pulses of almost any duration that is predetermined to the command pulse extraction unit. Reliability and timeliness of the tested arresters for high voltage is provided by the light channel of communication with flexible optical fibers and the source of optical radiation, which increases the noise immunity of signals when an inductive-dynamic actuator is triggered. Using a moving-code transducer with a mobile diaphragm shaped by cross-sectional diameters, allows you to test on the device ignitron gaps with different recovery times of electrical strength using to separate current and voltage circuits one vacuum switch.

Claims (2)

1. USSR author's certificate number 480138, cl. H 01 J 13/48, 1975. 0 2.JEEE. Trausactions on power apparatus aud s: stems, 1976, Pas-95, Number 4.5, 1311-1317 (prototype). one