RU1817045C - Device for burning-through defect isolation of power cables - Google Patents

Abstract

Usage: refers to the electric power industry and can be used to locate damage to defective insulation of power cables. The inventive device allows to reduce the burning time and increase the reliability of the device due to its simplification. The device -, --- The device for burning defective insulation of power cables contains sources of low 15 (burning current) and high voltage regulated by three-phase selsyn 28 wives 18, combined in a parallel branch and connected to the core of cable 19 with defective insulation. New in the device is the presence in the circuit of a low-voltage source of protection against impulse overvoltages arising from the burning of an electric arc made in the form of a throttle 12 with an unsaturated magnetic system of an inductor, a parallel-connected diode 13 and a limited resistor 14, as well as a phase sequence unit 7. controlling the correct rotation of the phase voltage vectors, linear reactors 2, 3, 4, 5, limiting the magnitude of the current during burning and voltage fluctuations on the buses of the power supply source ABC. 1 ill. (L C

Description

The device relates to the electric power industry and can be used to determine the location of damage to defective insulation of power cables.

The purpose of the invention is to increase the reliability of the device by simplifying it and shortening the burning time.

The inventive device differs from the prototype by the presence of new elements: a phase sequence unit, linear reactors, a buffer diode, a limiting resistor, an inductor with an unsaturated magnetic system, and a control unit using three-phase selsyn as the regulator and their links to the rest of the circuit elements.

The drawing shows a diagram of a device for burning defective cable insulation.

The device for burning defective cable insulation comprises a contactor 1 connected between the phase poles of the three-phase ABC network and the first terminals of the first 2, second 3, third 4, and fourth 5 linear reactors. The coil 6 of the contactor 1 is connected to the output of the phase rotation control unit 7. The input of the phase rotation unit 7 is connected to the poles of the ABC network, one of the poles of the input of the unit 7 being connected to the phase pole B via the control contact 8.

The second terminals of the reactors 2, 3, 4 are connected to the input of the three-phase rectifier 9. The second terminal of the reactor 5 is connected to the input of the thyristor controller 10, The input of the control unit 11 is also connected to the second terminals of the reactors 2, 3, 4. The first output of block 11 is connected control input rectifier 9 (a, b, c). A control input (c) of the thyristor controller 10 is connected to the second output of the control unit 11. The output of the rectifier 9 is connected to the connection point of the first output of the interconnector 12 with the anode of the buffer diode 13. The second output of the interconnector 12 is connected to the first output of the limiting resistor 14 and the cathode of the diodes low-voltage rectifier 15. The cathode of the diode 13 and the second output of the resistor 14 are combined and connected to the zero wire 0. The output of the thyristor controller 10 is connected to the input of the test transformer 17. The output of the transformer 17 is connected to the cathodes of the diode a high-voltage rectifier 18. Anodes straightening tifiers diodes 15 and 18 are connected to a terminal 19 for connecting the test cable lived 1 (3.

The phase sequence control unit 7 comprises a diode 20 connected by a cathode to the pole A of the network. A chain of the first 21, second 22 and third is connected to the anode of diode 20

23 resistors connecting the anode diode 20 to the control key 8. A thyristor cathode 24 is connected to the connection point of the resistors 21 and 22. The thyristor control electrode.

24 is connected to the connection point of the resistors 22 and 23. The anode of the thyristor 24 through the relay coil 25 is connected to the pole of the network C. A capacitor 26 is connected in parallel with the relay coil 25. Between the wire for connecting

the pole C of the network and the output of block 7 includes a make contact 27 of the relay 25.

The primary winding of the step-down transformer 28 of the control unit 11 is connected to the ABC network by linear outputs

5 reactors 2, 3, 4 and rectifier input 9, the stator winding of a three-phase selsyn 29 is connected to the secondary winding of a step-down transformer 28, and the rotor winding of a three-phase selsyn 29 is connected

0 primary windings of control transformers 30, 31, 32, the terminals of which are connected to a star, secondary windings of control transformers of phases a, b, c are connected to the corresponding phases ABC of anode input

5 thyristors rectified 9, other branches of the secondary windings of control transformers 30, 31, 32 through diodes 33, 34, 35, 36, 37 and control resistors 38, 39, 40, 41, 42 are connected to the control

The thyristor electrodes of the corresponding phases ABC rectifier 9 and thyristor controller 10, the cathodes of the diodes 33, 34, 35, 36, 37 are connected to the outputs of the secondary windings of the control transformers, and the anodes of the diodes 33, 34, 35, 36, 37 are connected to the movable contacts of adjusting resistors.

Breakdown of defective insulation can occur as during operation when a quantity is applied to the cable

0 of the rated voltage of the electrical installation of industrial frequency, as well as during preventive Tests by alternately applying to the current-carrying conductors an increased straightened cable 5.

The assessment of the cable insulation condition is determined by the value of the test rectified voltage. The cable is considered to have passed the test if there was no breakdown, there were no slipping discharges and current surges or its buildup after it reached a steady state value.

If during the cable tests the current surges were canceled (operation of the test setup automation), the tests are stopped and they begin to look for the place of damage.

After identifying a core with defective insulation, the operator puts the device into cable piercing mode and the circuit operates as follows. One of the cable cores, having a defective insulation, is connected to terminal 19 of the device. The other two and the cable sheath are connected to the grounded neutral wire of the 380/220 V power supply system. The device is powered from the 0.38 kV bus of the transformer substation using a four-wire power cable. To turn on the device, contact 8. closes. If the device is connected to the phase poles of the ABC network with a direct phase rotation, in block 7 a relay 25 is turned on, which supplies voltage to coil 6 through its contact 27. Capacitor 1 connects the device to the network.

Keeping the phase sequence control unit 7 in the device eliminates the possibility of short circuits when the device is connected to the phase poles of a network with reverse phase rotation.

After the contactor 1 is turned on, the mains voltage is supplied to the low-voltage direct current source 9 and the primary processing of the high-voltage test transformer 17 through the thyristor voltage regulator 10. The single-phase three-phase rectifier 9 and the thyristor regulator 10 are controlled by a three-phase syncron. included in the control unit 11. When the selsyn rotor is rotated, the opening angles of the thyristors of the low-voltage rectifier 9 and the voltage regulator 10 are proportionally opened. tviem high voltage applied to the conductor with the defective insulation, electric breakdown occurs, and there is an electric arc. The high voltage inhibiting diodes 15 acting on the transient resistance of the cable damage point and thereby eliminates the effect of the voltage of the low voltage direct current source 9. Under the influence of an electric arc, a decrease in the transient resistance at the burning place and a voltage drop across it occurs. As the transition resistance decreases, the voltage drop redistributes between the arc resistance and the internal resistance of the high-voltage source 18. When the value of the voltage drop across the arc is less than or equal to the voltage of the low-voltage direct current source 15, a burning current starts almost instantly from it. determined by the opening angle of the thyristors of the controlled rectifier 9. When the arc breaks or is unstable during the burning of defective insulation, an automatic instantaneous switching of power to the high-voltage source 18, the arc ignites again and the burning cycle may

repeated repeatedly. In order to sustainably burn the arc and accelerate the process of experiencing defective insulation and other cable elements, as well as obtain a small value of the transition resistance, the operator can increase the intensity of arc burning by increasing the opening angle of the thyristors. When the arc breaks, pulsed overvoltages occur, which apply to all

0 circuit elements. The cathodes of the rectifier diodes of the low voltage source 15 and high voltage source 18 are connected to the cable. These diodes block negative impulse overvoltage waves, but positive impulses freely pass through them. In the high-voltage circuit, the positive pulse waves are closed to the secondary winding, which has a significant inductance of the test transformer 17, level

0 isolation of which is higher than the level of arising surge surges. In the source of low-voltage source 9, thyristors with a low breakdown voltage are used and positive waves of pulsed overvoltage 5 are already dangerous

not only for thyristors and linear reactions. torus, but also for a low voltage network.

To protect the low voltage source 9 from

surge voltage to the device

0, an inductor 12 is introduced, made in the form of a throttle with an unsaturated magnetic system, in parallel with which a chain of a buffer diode 13 and a Limiting resistor 14 is turned on. The transfer of transient conditions during the arc burning in the inductor 12 induces a self-induction EMF due to which in a closed circuit, consisting of an inductance 12 of a buffer diode 13 and

0 of the limiting resistor 14, a circulation current arises in the opposite direction to the current from the positive half-waves and compensates for it; The presence of 12 throttle in the circuit low. voltage source smooths ripple

5 of the rectified current and has a positive effect on the stable burning of the arc. Linear current-limiting reactors 2, 3, 4, 5 limit the amount of current consumed from the network in both normal and

0 and in the event of short circuits in the device, and also reduces the level of voltage fluctuations on the substation buses when burning defective cable insulation. Fabricated and mounted on

5 mobile small-sized high-voltage measuring and testing laboratory, a sample of the proposed device was operated in existing electrical networks and confirmed the correctness of circuit solutions and design

nodes and blocks, and allows several times (2-3) to reduce the time for finding damages in cables in comparison with the time spent searching using existing laboratories, as domestic (station of movement electrotechnical testing and measuring - SPEII, TU 204 RSFSR - 973-82, manufacturer - Workshop of the Penza city power network; IPC - 10 NPO Analon of Vinnitsa), as well as foreign ones (Seba-Dinatronik, Germany), as well as improve the reliability of power supply to consumers.

The use of large values of the burning currents Csl of this cable section) allows for a short period of time to melt the cable sheath over the entire diameter, weld two or three cable cores in one piece and obtain a low transition resistance at the defect site. . V: : V

The experience of operating cable networks shows that in 98% of cases of repairing damaged cables it is necessary to insert and install two couplings. The use of large values of the burning current is expedient and justifies itself, since the occurrence of metallic phase faults on the cable sheath is practically eliminated, which is inherent in existing laboratories .-:; - l: -. :: ;;

In the proposed device there is no power burn transformer; which led to a sharp decrease in installation weight. The proposed implementation of the control unit allows you to smoothly steplessly control over a wide range of the current and voltage of the high-voltage source

ka. : ...; .. ;; ,. v -V .-: 1: -. . .-. .. Thus, due to the simplification of the circuit design by abandoning the automatic control system, the reliability of the device is increased, which ultimately leads to a reduction in the total time to find the damage and accelerate the operational recovery of the disturbed power supply of consumers .-. ... - .-. U., -, -. . :. . . - -: Formula and Device for burning defective insulation of power cables, comprising a contactor installed by power contacts between the poles of a three-phase power source and inputs of a three-phase power source and inputs of a three-phase controlled a rectifier and thyristor voltage regulator, the output of a three-phase controlled rectifier through an inductor and low voltage rectifier diodes, and the output of a thyristor voltage regulator

through the test transformer and diodes of the high-voltage rectifier are connected to the terminal for connecting the conductors of the test cable, the control unit, the input of which through the contactor is connected to the phase conductors of the network, and the first and second outputs are connected to the control inputs of the three-phase controlled rectifier and thyristor voltage regulator However, in order to increase the reliability, simplify and increase the burning intensity, a phase sequence control unit, a buffer DIBD; a limiting resistor, l the frost reactors / inductor is made in the form of a throttle with an unsaturated magnetic system, a series circuit of a buffer diode and a limiting resistor is connected parallel to the inductor opposite to the polarity of the diodes of the low voltage rectifier, the cathode connection point of the buffer diode with a limiting resistor is connected to the terminal for connecting the ground pole the input of the phase sequence control unit is connected to the poles of the network, and the contactor coil is connected to its output ;; linear reactors are connected between the linear poles of the contactor and the inputs of a three-phase controlled rectifier and thyristor voltage regulator,;:; .

2. The device according to claim 1, with the fact that the control unit is made in the form of a three-phase sync, the winding of which is connected to the phases of the network after linear reactors, through a step-down transformer, and connected to the secondary sync windings primary transformers connected to a star in one of the circuits of each secondary winding are connected in series with dibd and regulation resistors, the outputs of which are connected to the corresponding thyristors of the phases of the controlled three-phase rectifier and thyristor regulator for example

3. The device according to claim 1, it is stipulated that the phase sequence control unit consists of three circuits connected to the phases of the power source, the diode and resistors are connected in series in the first circuit, and the second in series circuit i is a chain of two series-connected resistors, to the common point of connection of which the thyristor control electrode circuit is connected, the relay coil is connected to the third circuit, a capacitor is connected in parallel, the thyristor cathode is connected to the common point and its anode is connected to the common neutral.