RU2813507C1 - Method for increasing efficiency of operational electrical network with isolated neutral - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: method of increasing the electrical safety of a reinforced concrete support of an overhead power line with an insulated neutral, which consists in applying a carbon-containing weather-resistant coating to the surface of the reinforced concrete support and attaching a current-limiting element to its crossarm. In this case, bitumen electrical insulating mastic is used as a carbon-containing weather-resistant coating, which is applied to the surface of a reinforced concrete rack, potentially open to contact with uninsulated wires of an overhead power line that have become detached from the insulators, as well as to the surface of a reinforced concrete rack in direct contact with an ungrounded electrically insulated metal traverse and holding its electrically insulated fastening clamp, while the connection of the electrically insulated terminals of the current-limiting element to the grounded electrically insulated traverse and to the upper electrically insulated grounding outlet of the reinforced concrete rack is performed using an electrically insulated bolted connection, and the electrical insulation of the terminals and bolted connections is carried out with bitumen electrical insulating mastic.

EFFECT: improved electrical safety and operational reliability of an overhead electrical network with an insulated neutral when single-phase insulation damage occurs in it.

1 cl, 1 dwg

Description

The invention relates to electrical networks and is intended to improve the efficiency of their functioning in the event of single-phase insulation damage.

There is a known method of shielding the electromagnetic field of an overhead power line (OHPL) in distribution networks with an insulated neutral, which consists in the fact that shielding is carried out with an insulated conductor twisted into a spiral, which is suspended on dielectric suspensions by the outer phase wires of the overhead power line in compliance with the standard dimensions to the ground surface, connected the ends of the shielding insulated conductor with grounded traverses of reinforced concrete supports by means of current-limiting elements are applied to the surface of the reinforced concrete support with a weather-resistant shungite coating (patent No. 2457594 of the Russian Federation, IPC N02NZ/14, published 2012).

The disadvantage of this known method is that it does not provide protection for people and animals from electrical shocks caused by the action of step voltage or touch voltage that occurs around a reinforced concrete support when a single-phase ground fault current flows through its grounding device, in which the voltage in the electrically connected network is intact phases relative to ground increases by √3, which entails accelerated aging of the insulation and often leads to the occurrence of more dangerous double ground faults, causing not only disconnection of consumers, but also causing premature failure of expensive electrical network equipment.

The technical objective of the proposed invention is to increase the efficiency of the operation of an overhead electrical network with an isolated neutral when single-phase ground faults occur in it by preventing the flow of single-phase ground fault current through the grounding device of each of the reinforced concrete supports.

The technical problem is solved due to the fact that in the known method of increasing the electrical safety of a reinforced concrete support of an overhead power line with an insulated neutral, which consists of applying a carbon-containing weather-resistant coating to the surface of the reinforced concrete support and attaching a current-limiting element to its traverse, according to the proposed invention, bitumen electrical insulating material is used as a carbon-containing weather-resistant coating mastic, which is applied by any of the known methods to the surface of a reinforced concrete rack, potentially open to contact with uninsulated wires of an overhead power line that have become detached from the insulators, as well as to the surface of a reinforced concrete rack in direct contact with an ungrounded electrically insulated metal traverse and an electrically insulated fastening clamp holding it, when In this case, the connection of the electrically insulated terminals of the current-limiting element to the grounded electrically insulated traverse and to the upper electrically insulated grounding outlet of the reinforced concrete rack is performed using an electrically insulated bolted connection, and the electrical insulation of the terminals and bolted connections is carried out with bitumen electrical insulating mastic by any of the known methods.

The technical result consists in increasing the electrical safety and reliability of the operation of an overhead electrical network with an insulated neutral when single-phase insulation damage occurs in it, because preventing the flow of single-phase fault current to the ground through the grounding devices of reinforced concrete supports eliminates the appearance of step voltage and touch voltage, which are extremely dangerous for people and animals, and also does not allow overvoltages to occur in the electrically connected network, disabling expensive electrical equipment and disrupting the reliability of power supply to consumers.

The essence of the proposed invention is illustrated by a drawing that shows a schematic diagram of increasing the efficiency of an overhead electrical network with an isolated neutral.

The overhead power line support contains a reinforced concrete rack 1, electrically insulated from contact with bare wires 2 and with an ungrounded metal cross-arm 3 and a fastening clamp 4 holding it, in turn electrically insulated from contact with the reinforced concrete rack 1 and with bare wires 2; pin insulator 5; wire fastening 6 of bare wire 2 to pin insulator 5; electrically insulated from contact with bare wires 2, the upper grounding outlet 7 of the reinforced concrete rack 1; electrically insulated from contact with bare wires 2 lower grounding outlet 8 of reinforced concrete rack 1; current-limiting element 9, terminal 9.1 of which, electrically insulated from contact with bare wires 2 by means of an electrically insulated bolted connection 9.1.1, is galvanically connected to a grounded metal cross-beam 3 electrically insulated from contact with bare wires 2, and terminal 9.2, electrically insulated from contact with bare wires 2 by electrically insulated bolted connection 9.2.1, galvanically connected to the electrically insulated upper grounding outlet 7 of the reinforced concrete rack 1. Bituminous electrical insulating mastic 10, applied to the surface of elements 1, 3, 4, 7, 9.1, 9.1.1, 9.2 and 9.2.1 by any of the known methods (brush, spatula, roller). Also shown in the figure is the electrical breakdown 11 of pin insulator 5; contacting 12 of bare wire 2 with electrically insulated elements 1, 3, 4, 7, 9.1, 9.1.1, 9.2 and 9.2.1 of the overhead power line support; electric spark discharge 13 of lightning on electrically insulated elements 1, 3, 4, 7, 9.1, 9.1.1, 9.2 and 9.2.1 of overhead power line supports; potential curve 14 of current flow to ground; potentially dangerous zone 15 of step voltage or touch voltage.

Let us consider the operating principle of the proposed method using the example of a 10 kV overhead power line (the principle is similar for overhead power lines of voltage class 6 and 35 kV).

In the event of the appearance of an ultra-high potential (11.5 kV or more) on the electrically insulated metal cross-arm 3, caused by atmospheric overvoltage, a huge current (5 kA and above) of the electric spark discharge 13 of lightning will easily overcome the high-resistance (at least 5000 MOhm) resistance of the current-limiting element 9 and through a slight transition resistance (no more than 0.05 Ohm) of bolted connections 9.1.1 and 9.2.1 of its terminals 9.1 and 9.2, respectively connected to the ungrounded metal cross-beam 3 and the upper grounding outlet 7 of the reinforced concrete rack 1, through the lower grounding outlet 8 of the reinforced concrete rack 1, having a small transition resistance (no more than 10 Ohms), flows quickly (from 20 to 100 μs) along the potential curve 14 to the ground. In this case, around the overhead power line support, as a result of the electric spark discharge 13 of lightning, a potentially dangerous zone of action of step voltage and touch voltage will be briefly formed, and insulation overvoltage will not occur in the electrically connected network. The impact of the electric spark discharge 13 of lightning on the following electrically insulated elements of the overhead transmission line support: 1, 3, 4, 7, 9.1 and 9.2 can lead to local breakdowns of the electrical insulating bitumen mastic 10 applied to their surfaces. However, as a result of the accompanying thermal effect of lightning, the electrical insulating bitumen mastic 10 will take on a viscous-fluid state, which will allow it to restore the integrity of its coating and, accordingly, the lost electrical insulating function.

In the event of an electrical breakdown 11 of the pin insulator 5 (due to the effect of an electric spark discharge 13 of lightning or unacceptable mechanical load from the bare wire 2, as well as due to other reasons), providing a galvanic connection of the bare wire 2 with an electrically insulated from the reinforced concrete rack 1, an ungrounded metal traverse 3, on the latter a potential is formed relative to the ground. At the same time, the presence in the circuit between the ungrounded metal cross-beam 3 and the upper grounding outlet 7 of the reinforced concrete rack 1 of a high-resistance (at least 5000 MOhm) resistance of the current-limiting element 9 will not allow single-phase capacitive current to flow to the ground through the upper 7 and lower 8 grounding outlets of the reinforced concrete rack 1.

When the bare wire 2 is detached from the pin insulator 5, due to a break in the wire fastening 6, contact 12 of the bare wire 2 occurs with the following elements of the overhead power line support: reinforced concrete rack 1, grounded metal crossbeam 3, mounting clamp 4, upper grounding outlet 7, terminals 9.1 and 9.2 current-limiting element 9. In this case, bitumen electrical insulating mastic applied to the surface of the listed elements will not allow single-phase capacitive current to flow to the ground through the upper 7 and lower 8 grounding outlets of the reinforced concrete rack 1. At the same time, a potentially dangerous zone 15 of step voltage action will not form around the overhead power line support and touch voltage, and insulation overvoltage will not occur in the electrically connected network.

Claims (1)

A method of increasing the electrical safety of a reinforced concrete support of an overhead power line with an insulated neutral, which consists of applying a carbon-containing weather-resistant coating to the surface of the reinforced concrete support and attaching a current-limiting element to its crossarm, characterized in that bitumen electrical insulating mastic is used as a carbon-containing weather-resistant coating, which is applied by any of the known methods on the surface of a reinforced concrete rack, potentially open for contact with non-insulated overhead power line wires that have become detached from the insulators, as well as on the surface of a reinforced concrete rack in direct contact with an ungrounded electrically insulated metal cross-arm and an electrically insulated fastening clamp holding it, while connecting the electrically insulated leads of the current-limiting element to the ungrounded the electrically insulated traverse and to the upper electrically insulated grounding outlet of the reinforced concrete rack are performed using an electrically insulated bolted connection, and the electrical insulation of the terminals and bolted connections is carried out with bitumen electrical insulating mastic by any of the known methods.