SU1358032A1 - Arrangement for protection against current leaks in three-phase electric mains - Google Patents

Abstract

This invention relates to current leakage protection devices in underground three-phase electrical networks with insulated neutral, and is intended to protect against electric shock. The purpose of the invention is to improve the reliability of the device and the accuracy of compensation of capacitive leakage currents. In the case of reducing the insulation resistance of the network to a hazardous value according to the safety conditions, the operating current 1 exceeds the amplitude value of its SP

Description

pulses of the reference current I,; -, the first amplifier 4 will be constantly open, and the actuating element 7 is turned off, which leads to the disconnection of the network by an automatic switch. When the capacitance of the network 34 changes, the equivalent capacitance changes into the oscillating circuit connected to generator 12 of the frequency. In connection with this, the natural frequency of this circuit changes. As the natural frequency approaches the frequency of the master oscillator 12, the voltage at the output of the oscillating circuit increases. The current proportional to the voltage on the circuit passes through the base-emitter junction of the transistor 31, to the base-junction collector of which the inputs of the emitter followers 26, 27 are connected. The current from the additional power source 28 passes through the input of the second

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The invention relates to devices for protection against current leakage in underground three-phase electrical networks with insulated neutral and is intended to protect against electric shock.

The purpose of the invention is to improve the reliability of the device and the accuracy of compensation of capacitive leakage currents,

The drawing shows the principal electrical circuit of the proposed device.

The leakage protection device consists of insulating and compensating capacitive current monitoring units, including a compensating one, a choke 1 connected through a three-phase choke 2 and a coupling capacitor 3 between the phases of the protected network and the ground, the first amplifier 4, which is bypassed the semiconductor device 5, the filter 6 constant: current component, the actuator 7 connected through the specified filter to the load circuit of the first amplifier, the operating current source 8 connected

the amplifier 13 and the emitter-collector junction of the emitter follower 26 opened by this current. By selecting the ratios of the resistors 30 and 37, the opening of the second 27 and subsequent emitter repeaters is controlled. The current through the input of the second amplifier 13 increases in connection with a decrease in the resistance in the auxiliary source 28, as the resistors 29 and 30 are connected in parallel with each other. By selecting the ratios of these resistors and voltages at which subsequent emitter followers are connected, by the number of emitter repeaters, one can bring the characteristic of the network capacity measuring unit (current at the input of the second transistor amplifier depending on the network capacity) to the desired control current of the compensating throttle. silt

through the KS filter 9 between the input of the first amplifier 4 and separation capacitor 3, the reference current source 10 (plus the specified source is located on the ground), the network capacity measuring unit 11 with the high frequency generator 12, the second amplifier 13, the input of which is connected to the measuring unit 11 network capacity

and the output - with the winding 14 of the control compensating throttle 1.

The load circuit of the amplifier 15 of the increased frequency generator 12 includes three parallel circuits, two of which consist of diodes 16 and 17 connected in series, resistors 18 and 19 and oscillating circuits 20 and 21, one third of diode 22, resistor 23 and emitter-base transition of the transistor 24, to the collector circuit of which resistor 25 is connected, the input of the second amplifier is connected through several emitter repeaters 26 and 27 connected in parallel to each other, to an additional power supply 28, to the minus of which through resistors 29 and 30 These emitters are specified

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of the switches 26 and 27, and the emitter followers 26 and 27 are connected to the plus of the power supply 28 via the base-collector junction of the transistor 31. The input of the specified transistor 31 is bridged by the oppositely connected diode 32 and connected to the oscillating circuit, the capacitive circuit of which through the filter 33 also The measured capacitance of the network 34 is included, and an additional source 35 of constant voltage is included in the compensating throttle circuit. A resistor 36 is included to create an initial operating current with resistance-and insulation equal to ha 5 between the zero point of a three-phase throttle 2 and ground.

The device works as follows.

With an infinitely large network isolation resistance, the operational current Ion flows through the circuit: RC filter resistors 9, parallel-connected base-emitter junction of transistor 4 and base-collector junction of transistor 5, ground, resistor 36, compensating droplet winding 1. From plus ( ground) of the source 10 of the reference current through the base-emitter junction of the transistor 5, the emitter-collector junction of the transistor 24, the resistor 25 and the minus of the source 10 of the reference current pass rectangular pulses of the reference current.

The formation of rectangular pulses occurs due to the operation of the amplifier 15 of the increased frequency generator 12 in the key mode, which is obtained when the secondary winding of the oscillating circuit 21 of the increased frequency generator 12 is connected to the emitter-basic transition of the amplifier 15 of the specified generator 12. Then, when the amplifier 15 is open the transistor 24 is opened by the current along the circuit: plus the power source of the generator 12 (ground), the base-emitter junction of the transistor 24, the resistor 23, the diode 22, the emitter-collector junction of the amplifier 15, minus and source of power generator 12. In the closed state of the amplifier 15, high frequency oscillator transistor 24 is closed. In the closed state of the transistor 24, the operational current passes through the base-emitter junction of the first amplifier 4. When open580324

In the transistor 24 state state, the operational current passes through the base-collector junction of transistor 4 and i the first amplifier is closed. Thus, the first amplifier 4 operates in the key mode with an increased switching frequency corresponding to the switching frequency of the amplifier 15 (High frequency not 12. When the transistor amplifier 4 is operated in the key mode, the actuator 7 is powered from the source plus via a constant filter 6

-15 current component, emitter-collector junction of the first amplifier 4, minus the source (ground). As a result, the actuator 7 is triggered, it allows to supply voltage to

2Q electrical network. In the case of reducing the insulation resistance of the network to a hazardous value according to safety conditions, the operational current 1 exceeds the amplitude value of the pulses of the standard current Ij, the first amplifier 4 is constantly open, and the actuator 7 is turned off, which leads to a circuit breaker. I

30 Connecting a constant voltage source 35 only to the compensating drossel circuit excludes surge current when the supply voltage is applied to the network, but in this case

35 there is a delay in the charging of the actuating element 7 due to the slow rise of the operational current, since the first amplifier 4 starts to operate in the switching mode

40 only with a certain amount of operating current sufficient to clearly open the transistor amplifier. By connecting an additional constant voltage source 35 to the compensating drossel circuit and selecting the relationships between the voltages of the operational current sources, it is possible to ensure, on the one hand, that the operational current of 10p does not exceed the amplitude of the reference current pulses I

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At the same time, the rapid increase of the operating current at the time of connecting the device to voltage, which is necessary for achieving the charging speed of the actuating element 7. The indicated connection of operating current sources and the increased switching frequency of the first amplifier provide

The response speed of the actuating element 7 is not more than 30 ms, which allows an operation delay of an intermediate relay not exceeding 100 ms, (for example, using an RC filter) with contacts designed for high voltages and currents, allowing an impact on the disconnecting coil of powerful circuit breaker (not shown).

When the capacitance of the network 34 changes, the equivalent capacitance changes into the oscillating circuit connected to the high frequency generator 12. In connection with this, the natural frequency of this circuit changes. As the natural frequency approaches the frequency of the master oscillator 12, the voltage at the output of the oscillating circuit increases. A current proportional to the voltage on the circuit passes through the base-emitter junction of transistor 31, to the base-junction collector of which the emitter followers 26 and 27 are connected. The current from the additional power source 28 passes through the input of the second amplifier 13 and opened by this current emitter-collector junction emitter follower 26. The choice of the ratios of the resistors 30 and 37 is governed by the opening of the second 27 and subsequent emitter followers. The current through, the input of the second effort. tel 13 increases in association with; decreasing the resistance in the auxiliary source 28, as the resistors 29 and 30 are connected in parallel with each other. By selecting the ratios of the indicated resistors and voltages at which subsequent emitter followers are connected, by the number of emitter followers, one can bring the capacitance measuring unit’s characteristics as close as desired, I current network at the input of the second transistor amplifier, depending on the network capacity to the required current characteristic control compensating throttle. This allows not only to reduce the current passing through the person when he accidentally touches the network phase, in the whole range of network capacity changes, but also makes it possible in serial production to ensure the operability of these devices with a significant 0

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nominal changes in ambient temperature from -40 to + 5 ° C and variations in the parameters of the elements. Reducing the short-term currents over the entire range of changes in network capacity also increases the allowable range of changes in network capacity. At present, with a network capacity greater than 1 microfarad per phase, it is necessary to apply. in the mine area network, instead of one transformer substation, there are two, fed separately, parts of the cable network. The use of one transformer substation and one network instead of two allows for a great economic effect.

Claims (1)

Invention Formula A device for protection against leakage of current in a three-phase electric network, containing a circuit of series-connected compensating throttle, three-phase throttle and a coupling capacitor, the terminals of which are intended to be connected between the protected network and the earth amplifier, whose input is bounded by a semiconductor element, an actuator, connected via a DC filter to the load circuit of the first amplifier, operating current sources, reference current and power supply, a high-voltage generator ennoy frequency vklyuchayush lish an amplifier and a first oscillation circuit LC-type, included in the load circuit of the amplifier measuring unit network capacity with terminals for connecting (, To the network, turn on the 1st oscillator circuit of the LC type, the circuit of which serves to turn on the measured network capacitance, the output of which is connected to the transformer input, the second amplifier, whose input is connected to the output of the network capacity measuring unit, and the output is wired control compensating throttle, characterized in that, in order to increase the reliability of the device and the accuracy of compensation of capacitive leakage currents, the newly introduced series-connected first plugs are included in the specified first oscillatory circuit stor and diode, and the second oscillating circuit and the emitter-base transition of the newly introduced additional I1358032o the transistor connected to the circuit is switched by an oppositely connected diode ground current, included each through. and connected to the output of the aforementioned newly introduced serially co-transformer, and to the output transients, respectively, the second and stor, the input of the emitter third diode and a parallel-repeater resistor, the output of which is connected to the first amplifier , during the tour, and in the capacity measurement unit of this power source is connected to the network, at least the power input of the capacitance measurement unit of the emitter follower is reintroduced, the JQ of the network is connected, and the compensating parallel in parallel a and choke used included additional transistor whose input zashunti- Tocnik constant voltage.