RU227387U1 - Protected wire for overhead power lines - Google Patents

Abstract

The utility model relates to the designs of protected wires for overhead power lines. The technical result consists in increasing the reliability of operation of the wire by increasing its mechanical and electrical strength, as well as resistance to electrical breakdown during whipping. The technical result is achieved due to the fact that the wire contains a conductive core 1, twisted from aluminum alloy wires, on top of which an electrically conductive layer 2 and two-layer protective insulation are applied. The inner insulating layer 3 is made of a cross-linked composition based on polyethylene, not containing soot, and has a thickness of at least 20% greater than the thickness of the outer insulating layer 4, which is made of a tracking-resistant polymer composition based on carbon black in an amount of at least 2.0%. polyethylene. 3 salary f-ly, 1 ill.

Description

Field of technology to which the utility model relates

The utility model relates to the field of electrical engineering, namely to the designs of protected wires for overhead power lines.

State of the art

As the closest analogue, the well-known protected wire of the SIP-3 brand was chosen, containing one round conductive core, on top of which is applied extruded polymer protective insulation made of light-stabilized cross-linked polyethylene with a soot content of at least 2.5% (GOST 31946-2012).

This well-known protected wire for overhead power lines with a rated voltage of 20 kV is intended for the transmission and distribution of electrical energy in networks with a rated voltage of 10, 15 and 20 kV with a nominal frequency of 50 Hz, a protected wire for overhead power lines with a rated voltage of 35 kV - for networks for a voltage of 35 kV with a nominal frequency of 50 Hz. In this case, the conductor must be twisted from round wires made of aluminum alloy, have a round shape and be compacted. The nominal thickness of the protective insulation of protected wires for a rated voltage of 20 kV should be 2.3 mm, for a rated voltage of 35 kV - 3.5 mm.

Essence of a utility model

The problem that the utility model is aimed at solving is the development of a protected wire with increased reliability of operation of overhead power lines.

This utility model ensures the achievement of the following technical result: increasing mechanical and electrical strength, as well as resistance to short circuits in the event of accidental contact of a wire with a conductive conductor made of aluminum alloy with a grounded element or in contact of wires of different phases of overhead power lines with a rated voltage of up to 35 kV and a nominal frequency of 50 Hz, with optimal material consumption of the wire design.

The technical result is achieved in that the wire protected for overhead power lines contains one current-carrying core twisted from aluminum alloy wires, on top of which an electrically conductive layer and protective insulation are applied, said insulation is made of two layers and contains inner and outer layers, while the inner insulation layer is made made of a cross-linked polyethylene-based composition that does not contain soot, and has a thickness of at least 20% greater than the thickness of the outer insulating layer, which is made of a polyethylene-based composition with a soot content of at least 2.0%.

The specified technical result is also achieved by the fact that the current-carrying core is made unsealed.

The specified technical result is also achieved by the fact that the conductor is made with sealing of the interwire space.

The specified technical result is also achieved by the fact that the electrically conductive layer is made in the form of a winding with an overlap of electrically conductive tapes or extrusion from a cross-linked electrically conductive polymer composition.

This technical result is also achieved by the fact that the outer insulating layer is made of a soot-containing tracking-resistant polymer composition.

A distinctive feature of this useful model is the increase in the reliability of operation of protected wires for overhead power lines due to the use of an electrically conductive layer and multi-layer protective insulation, which provides increased electrical strength and resistance to electrical breakdown in the event of contact of the wire with a grounded element or in contact of wires of different air phases power lines.

List of drawing figures

In fig. Figure 1 shows a cross-section of a wire protected for overhead power lines.

Implementation of a utility model

The development of medium voltage distribution networks made by overhead power lines (OPL) using protected wires has a number of undeniable advantages compared to traditional OPL using bare wires.

At the same time, the requirements of operating organizations and consumers for the reliability and uninterrupted power supply are growing.

The protective insulation of currently used protected wires reduces the likelihood of a short circuit when a wire accidentally touches a grounded element or when wires of different phases of overhead power lines come into contact. Such contacts or clashes are in most cases short-term in nature.

However, in the event of prolonged overlap or contact of the wire with grounded elements during operation, in addition to the fact that the wires are heated to a temperature exceeding the ambient temperature due to the flow of a long-term permissible load current or operation in overload or emergency mode, existing designs of protected wires do not provide reliable safe operation.

In addition, the use of compacted conductor in existing wire designs can have a negative impact in terms of wire vibration.

The protective insulation currently used has insufficient tracking resistance.

This utility model is based on the use of an optimal design of a protected wire, which ensures increased reliability of operation of protected wires with a conductor made of aluminum alloy for overhead power lines through the use of a multilayer structure consisting of an electrically conductive layer applied over the conductor and two-layer protective insulation.

The protected wire contains one current-carrying core 1, twisted from aluminum alloy wires, on top of which is applied an electrically conductive layer 2 and a two-layer protective insulation, including an inner 3 and outer 4 layers.

The inner insulating layer 3 is made of a cross-linked polyethylene-based composition that does not contain soot, and has a thickness of at least 20% greater than the thickness of the outer insulating layer 4, which is made of a polyethylene-based composition with a soot content of at least 2.0%.

Considering that whiplash during operation may not be of a short-term nature, and also that the wires are heated to a temperature exceeding the ambient temperature due to the flow of a long-term permissible load current or operation in overload or emergency mode, the design of the protected wire must ensure reliable safe exploitation.

The specified choice of insulating layer thicknesses was experimentally established based on the best balance between the performance properties of a wire with a conductive core twisted from aluminum alloy wires and its material consumption. Dividing the insulation into two layers makes it possible to ensure a high level of electrical strength due to the use of a cross-linked composition based on polyethylene that does not contain soot for the internal insulating layer, while maintaining resistance to a complex of external influencing factors during operation, including resistance to solar radiation, due to the use of external insulating layer.

In this utility model, the main insulating element is the internal insulating layer. The parameters of the outer insulating layer are selected based on the thickness of the inner insulating layer.

To increase resistance to vibration, the conductor can be made unsealed.

To equalize the electric field around the conductive core, the electrically conductive layer 2 can be made either in the form of a winding with an overlap of electrically conductive tapes, or applied by extrusion from a cross-linkable electrically conductive polymer composition.

To ensure longitudinal sealing of the internal space and prevent the spread of water along the length of the wire, sealing the internal space 5 of the conductive core can be performed either with an electrically conductive sealant or with electrically conductive tapes or threads.

To ensure protection of the wire to a complex of external influencing factors during operation, including resistance to solar radiation, the outer insulating layer 4 is made of a polyethylene-based composition with a soot content of at least 2.0%. In this case, a composition based on polyethylene that can be cross-linked during the production process or a thermoplastic composition based on high-density polyethylene can be used for the outer insulating layer.

The following is information confirming the possibility of implementing the utility model.

The stranded conductor 1, which can be either compacted or undensified, is made of stranded aluminum alloy wire rods.

The application of tapes for the electrically conductive layer 2, made by winding, is carried out using standard torsion equipment.

Sealing of the interwire space 5 can be carried out simultaneously with the operation of twisting the wires in the traditional way.

The polymer materials used for the manufacture of the wire for the electrically conductive layer 2, made by extrusion, and the insulating layers 3 and 4 are produced industrially.

An example of the implementation of a utility model.

The wire protected for overhead power lines contains one conductive core twisted from wires made of aluminum alloy grade ABE in accordance with GOST 20967. An electrically conductive layer and protective double-layer insulation are applied on top of the conductive core. The inner insulating layer is made with a thickness of 1.2 mm from a cross-linked composition based on polyethylene, which does not contain soot. The outer insulating layer has a thickness of 0.9 mm and is made of a polyethylene-based composition with a soot content of at least 2.0%.

When producing wires for applying polymer materials, traditional extrusion equipment used in the cable industry is used.

Claims (4)

1. A wire protected for overhead power lines for medium voltage, containing one conductive core twisted from aluminum alloy wires, on top of which an electrically conductive layer and protective insulation are applied, said insulation is made of two layers and contains inner and outer layers, while the inner insulating layer is made from a cross-linked polyethylene-based composition that does not contain soot, and has a thickness of at least 20% greater than the thickness of the outer insulating layer, which is made of a tracking-resistant polymer composition based on polyethylene containing soot in an amount of at least 2.0%. 2. The wire according to claim 1, characterized in that the conductor is made unsealed. 3. The wire according to claim 1, characterized in that the conductor is made with sealing of the interwire space. 4. The wire according to claim 1, characterized in that the electrically conductive layer is made in the form of a winding with an overlap of electrically conductive tapes or extrusion from a cross-linked electrically conductive polymer composition.