SU1689895A1 - Device for transformer testing under short circuit - Google Patents

Abstract

The invention relates to electrical equipment, namely, devices for testing transformers in the short circuit mode. The purpose of the invention is to reduce the emergency hazard when tested by short-circuit currents. The device contains a three-phase (TF) power source 1, TF

Description

The invention relates to electrical engineering and can be used for electrodynamic testing of high-voltage power transformers (autotransformers) and their full-size models under network stand conditions and with the help of synchronous shock generators.

The purpose of the invention is to reduce the emergency hazard during short-circuit current testing,

Fig. 1 is a schematic diagram of the device; Fig. 2 shows the operation schedule of the switching equipment of the device.

The device contains a three-phase power source 1 (phases A, B and C), a three-phase safety switch 2 consisting of phases 3-5, a test transformer 6 with primary 7-9 and secondary 10-12 windings, three phases of bidirectional high-voltage thyristor valves 13 -15, transformer 16 under test with primary 17-19 and secondary 20-22 windings, voltage sensor 23, current sensors 24-26, control and protection system 27, the input of the first phase 5 of the safety switch 2 connected to the corresponding phase of the power supply source 1 , the output of the first phase 5 is connected to the input of the second Phase 4 of the safety switch 2, and the output of this phase — with the input terminals of all three primary windings 7–9 of the test transformer 6, all three output terminals of the secondary windings 10–12 are connected to the input terminal of the first phase of the bi-directional high-voltage transformer 13 and the output terminal of the third phase 3 of the protective switch 2, the input output of the primary winding 17 of the test phase of the test transformer 16 is connected to the output output of the first phase of the bi-directional high-voltage, thyristor valve 13 and the input output of the third The basics 3 of the safety switch 2, the input pins of the two other phases of the bi-directional high-voltage thyristor valves 14 and 15 are connected to the output pins of the secondary windings 11 and 12 of the test transformer 6, and the output pins of these phases of the bi-directional high-voltage thyristor valves 14 and 15 with the corresponding conclusions of the primary windings 18 and 19 untested phases of the tested transformer 16, the secondary windings 2022 of the tested transformer are shorted and grounded, the input terminal of the voltage sensor 23 is connected to the input of the first phase 5 of the safety switch 2, and the output of the voltage sensor 23 is connected to the input of the system 27

control and protection, the outputs of three current sensors included in the circuit of the connection from the side of the second 4 and third 3 phases of the protective switch 2 and the output of the first phase of the bi-directional high-voltage thyristor valve 13 are connected to the input of the control system 27 and the protection 27, the outputs of the control system 27 and protection - with control inputs of all three phases 3-5 of the safety switch 2 and all three phases bidirectional

high voltage thyristor valves 13-15. The device works as follows.

From the control and protection system 27 (FIG. 2) include the first 5 and second 4 phases

a safety switch 2, thereby applying voltage to all three phases of the test transformer, to three phases of bi-directional high-voltage thyristor valves and the output of the third phase 3 of the safety switch 2. Then, after the time required to charge own energy accumulators of high-voltage thyristor valves (usually within 30 -60 c), the third phase 3 of the safety switch 2 is turned on,

0.005-0.01 seconds before the actual closing of the contacts of the third phase 3 of the safety switch 2 is turned on with a certain angle relative to the zero value of the supply voltage, the first phase of the bi-directional high-voltage thyristor valve 13, the voltage is applied to the test phase 17 of the test transformer 16 and the flow of shock current is ensured short circuit and shunting first

the phases of the high-voltage thyristor valve 13 through 0.005-0.01 s using the third phase 3 of the protective switch 2. At the near moment of passing the short-circuit test current to zero, the first phase of the high-voltage thyristor valve 13 is disconnected from the control and protection system 27,

After the time set for the short circuit test, all three phases 3-5 of the circuit breaker 2 are disconnected. Test transformer 16 is considered to have passed the short circuit test if, during the tests, its parameters did not exceed the permissible limits. When testing, various emergency modes are possible due to malfunctions of the control and protection system 27, damage to the test transformer 16, test equipment, the occurrence of overlaps and short circuits in the power test circuit. Moreover, spontaneous switching of bidirectional high-voltage thyristor valves is possible after supplying voltage to them as a result of the failure of the control system, protection and automation of the valves themselves.

In these emergency conditions, unnormalized short-circuit currents occur in the test phase of the test transformer 15 and in the test equipment. The control and protection system 27 compares a signal proportional to an unsustainable current from current sensors 24-26 and setpoints. In the event of a deviation of current values in the tested transformer, the two phases of bidirectional thyristor valves 14 and 15 are automatically switched on, as a result The test circuit additionally introduces two unstable phases 18 and 19 of the transformer 16 under test. This leads to a significant reduction in current. ka in the test winding 17,

As a result, in the proposed device, the duration of the emergency unnormalized mode is reduced to a limit of no more than 0.01-0.02 s, which eliminates equipment destruction and increases emergency safety, which is especially important when tested by short-circuit currents in a 500 kV network. .

Claims (1)

Claims Device for testing short-circuit transformers containing a three-phase power source, a three-phase protective switch, a test transformer with input and output windings, a synchronous short-circuiter and a three-phase transformer with input and output windings, secondary winding which is shorted, characterized in that, in order to reduce the emergency hazard when tested by short-circuit currents, it is equipped with a control and protection system, a voltage sensor, three current sensors with output terminals, a three-phase safety switch has input, output and control terminals in each phase, and the synchronous short-circuitor consists of three phases of bidirectional high-voltage thyristor circuits with input and output outputs and a control output, the primary and secondary windings of the test o and the transformer under test are connected by a star and their Since the ground is grounded, the first phase of the safety switch is connected to one of the phases of the three-phase power source, the output of the first phase of the safety switch is connected to the input of the second phase of the safety switch 5 switch, and the output of the second phase of the protective switch is connected via a current sensor with the input terminals of the primary windings of the three phases of the test transformer, three output terminals of the secondary windings Test transformer 0 is connected to the input pins of three phases of bidirectional high-voltage thyristor valves and through a current sensor to the output TERMS of the third phase of the protective switch, 5, the output terminal of the first phase of the thyristor valve is connected to the input terminal of one phase of the transformer under test and to the input the conclusion of the third phase 0 of the safety switch, the output terminals of the two other phases of the bidirectional high-voltage thyristor valves are connected in phase with the input terminals of the two other phases of the primary winding of the tested transformer, and the input voltage sensor is connected to the input of the first Phase of the safety switch, and the output of the voltage sensor is connected to the control system input and protection, the current sensor outputs are connected to 0 inputs of the control system and protection, and outputs of the control system and protection are connected to the control terminals of the three phases of the safety switch and to the control terminals of the thyristor gates. 5 "m I