SU905884A1 - Device for synthetic testing of heavy-duty spark discharger - Google Patents

Description

The invention relates to electrical engineering and can be used to control and test powerful spark gaps.

A device for synthetic tests of valve arresters in atmospheric overvoltage at alternating voltage, containing a pulse generator, step-down transformer and control units, synchronization and ignition of the generator [1].

A disadvantage of the known device is that the secondary windings of the transformer are connected directly to the terminals of the tested arrester, so the insulation of the secondary windings must be sharply strengthened, which leads to a complication of the device and a decrease in reliability.

Closest to the proposed technical essence is a device for synthetic testing of valve arresters, containing a pulse generator connected to the spark gap through resistance, inductance and spark gaps separating the pulse generator from the industrial frequency source, as well as ignition and synchronization units (2J.

The disadvantage of this device is the complexity of the design and reduced reliability due to the fact that the source of the accompanying current of industrial frequency is connected directly to the tested arrester and is exposed to a high breakdown voltage pulse in this connection.

The purpose of the invention is to increase the reliability of the device.

This goal is achieved by the fact that in '- ^{3 is a} known device for synthesizing tests of a powerful spark gap, containing a series-connected ignition unit and a pulse voltage generator, ^υ whose first output is connected through a first measuring resistor to a common bus, to the first electrode of the tested spark gap, to one of the terminals of the voltage divider and to one of the terminals of the second measuring resistor, the other terminal of which is connected to one of the terminals of the source of the accompanying current, the other terminal of which 40 connected to one of the terminals of the operational switch, the second output of the pulse voltage generator is connected to one of the electrodes of the auxiliary spark gap, the other terminal of the voltage divider is connected to the second electrode of the tested powerful spark gap, a controlled three-electrode spark gap, a resistor and a capacitor are introduced, and the control electrode controlled three-electrode spark gap connected to another electrode of the auxiliary spark gap and through a parallel connected resistor and con a capacitor with a second electrode of a powerful spark gap and with one of the electrodes of a controlled three-electrode spark gap, the other electrode of which is connected to the other terminal of the operational switch.

The drawing shows a diagram of the described device.

The device comprises a pulse voltage generator 1 with an ignition unit 2, consisting of a charging circuit, capacitance, resistance, and inductance that determine the waveform of the pulse current, connected to the tested powerful spark gap 3 through an auxiliary spark gap 4 and a chain of connected parallel to the capacitor 5 and resistor 6; an accompanying current source 7 connected to the tested arrester 3 through an operating switch 8, a controlled three-electrode arrester 9 with a control electrode 10 electrically connected to a capacitor 5, a first measuring resistor 11 and a second measuring resistor 12 and a voltage divider 13.

The operation of the device is based on the fact that the pulse current flowing from the pulse voltage generator ...: Д; th through the test arrester charges an additional capacitor to a voltage sufficient to ignite the controlled arrester, the breakdown of which ensures the connection of the low voltage source to the tested arrester and the leakage accompanying current. Thus, a low voltage source, separate from the test power gap arrester managed three-electrode spark gap, is not exposed to pulsed voltage surge arrester perforation test that allows to simplify the structure of the apparatus due to the reduction ⁶ · sheniya insulation and improve device reliability.

The device operates as follows.

Before the start of the experiment, the operational switch 8 is turned on, and all capacities of the generator 1 of the pulse voltage are charged. When a command is issued to the ignition unit 2, the pulse voltage generator (GIN) 1 is activated, the auxiliary gap 4 breaks through and the voltage of the GIN 1 is applied to the tested spark gap 3, which breaks through. From GIN 1 through the auxiliary spark gap 4, the capacitor 5, the test arrester 3 and the first measuring resistor 11, a pulsed current flows. The capacitor 5 is charged by this current, and when the voltage across it reaches a value sufficient for the breakdown of the initiating gap between the control electrode 10 and the power electrode of the controlled spark gap 9, the initiating gap breaks through and ignites the spark gap 9, the breakdown of which leads to the connection of the source of accompanying current 7 to test arrester 3. Through the controlled arrester 9, the test arrester 3 and the second measuring resistor 12, an accompanying current flows, which is switched off by the operational switch 8.

This device allows you to prevent the ingress of high pulse voltage into the circuit of the source of the accompanying current, as a result of which there is no need for a high insulation class of the specified source, which simplifies the design of the device and makes it more reliable.

Claims (2)

1. Kaplan V.V. and others. Switching tests of high-voltage devices. Energy, 1969, p.122124, fig. 5-5. 2. Recommended IEC. Publication 99-1. Dischargers, Part 1. Valve dischargers for AC networks. Ed. 2, 1970, Appendix A 0 (prototype). F ten f 3 13 12 eleven