SU1584011A1 - Dc electric power transmission system grounding - Google Patents

Abstract

The invention relates to electrical engineering and is used in electrical systems. The purpose of the invention is to increase reliability by monitoring the state of the electrodes. A direct current flows through the wire 1 of the extension line. This current through the descents 2 flows into the grounding electrodes 3. The beginning of line 1 is connected to the zero point of the substation formed by converters 4 and 5. The working winding of saturation throttles 6, when there is a current in descent 2 having a coil on the throttles core, reduces the inductance and the current through the ballast resistance 7 increases. The total current of the ballasts 7, connected to the additional wire 8 of the line, is detected by a sensor connected to an industrial network with a grounded neutral. A decrease in the current of this sensor below the nominal value indicates damage to the individual electrodes 3, slopes 2, chokes 6, or ballasts 7. After fixing this, the operating personnel take measures to repair the damage. 1 hp f-ly, 3 ill.

Description

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FIG. one

The invention relates to electrical engineering and can be used in the power industry.

The purpose of the invention is to increase reliability by monitoring the state of the electrodes.

FIG. 1 and 2 show the working grounding diagrams; in fig. 3 shows the characteristics of the current of the ballast resistance from the current through the earth conductor.

The predominantly overhead line 1 of the working ground is connected via vertical slopes 2 to grounding conductors 3. The beginning of line 1 is connected to the zero point of the dc power substation formed by converters 4 and 5. The saturation choke 6 uses the descent wire as a control winding 2, and the working winding of the droplet 6 is connected in series with the ballast resistance 7, made in the form of a resistor or inductance coil. One output of this circuit is connected to the earthing switch 3, and the other, via ballast resistance 7, is connected to an additional 8 extension line. The end of the wire 8 is connected to a current sensor 9, made (Fig. 1) in the form of an ammeter or a current relay. The second terminal of the sensor 9 is designed to be connected to an industrial AC network with a grounded neutral.

The current sensor 9 (FIG. 2) may be made in the form of a current transformer or a magnetic amplifier. The second current sensor 10 is included in the wire of the remote line 1. The sensor outputs 9 and 10 are connected to threshold elements 11 and 12. The first one is directly, and the second is connected through circuit HE 13 to circuit I 14, which is connected to the output device 15 by a signal. For example, in the form of a signal lamp of the specified relay (Blinkerre), etc.

Working ground works as follows.

A direct current of one or another direction flows through the line 1 of the work ground. This current flows through the ground electrodes 3 placed in the ground. The current flow through the drops 2 causes the drossel 6 to magnetize. The inductance of the work winding drossel 6 decreases to the minimum value, and the current through ballast 7 increases dramatically. The characteristic of current I of the ballast circuit 7 as a function of current s through descent is shown in FIG. 3. The value of Icp may be fractions of an ampere. The total current of all the ballast circuits is equal to a certain value, which is detected by sensor 9. In the event of a failure

one of the electrodes 3 (corroded by corrosion) and descent 2 (break) or damage to the throttle 6, or ballast 7, the current through the corresponding ballast does not leak, or a very small amount (2-5%) of the current flows. Therefore, the total current measured by sensor 9 decreases, which is fixed,

In the circuit (Fig. 2), the threshold element 12 is disconnected; at the output of the circuit

0 NOT 13 a signal appears. If at the same time sufficient current flows through the ground wire, then the threshold element 11 is in the actuated position, and two signals arriving at the input of the AND circuit 14,

5 cause the inclusion of the alarm 15..

In the absence of damaged elements 2, 3 and 6 and the presence of current in the wire of line 1 through the sensor 9 a current of normal magnitude flows, which is fixed. AT

0 to the circuit (FIG. 2), wherein the threshold element is in the on state. At the output of the NOT 13 circuit, there is a zero signal, and the alarm 15 is turned off.

Thus, the invention allows

5 to fix the damage to the nodes of the remote distributed working ground of the power transmission, which allows the operating personnel to detect the damage in due time and take corrective measures and repair. For this reason, the work ground is always in good working condition. The elimination of ground damage increases safety, since

By breaking open individual electrodes, the resistance to spreading increases, which can lead to an increase in the touch voltage and the step voltage above human hazards. Besides,

Increased flow resistance increases energy loss. The proposed working ground excludes such modes.

Claims (2)

Invention Formula 5 1. Working grounding of DC power transmission, containing the main wire of the extension line, the slopes of which are connected to the grounding electrodes, characterized in that 0 increase reliability by providing monitoring of the state of the electrodes, it is equipped with an additional wire of the extension line, the first current sensor and circuits connected in series 5 ballast, made in the form of a resistor or inductance coil, and saturation droplets, with the first current sensor included in the main wire of the extension line, the circuit of successively included ballast, made in the form of a resistor or inductance coil, and saturation droplets are connected to an additional lead wire at each of the descents, with each descent located in the core opening of the saturation droplet. 2. Working ground according to claim 1, characterized in that it is additionally equipped with two threshold elements, NOT, AND circuits, a second current sensor and a signaling device, the second current sensor being included in the main wire of the remote line, the outputs of the first and second current sensors are connected to threshold elements, the outputs of which are connected to the inputs of the AND circuit - the first one through the NOT circuit, the second directly, and the output of the AND circuit is connected to a signaling device, FIG. g