RU152619U1 - POWER CABLE WITH TWO-LAYER METAL SCREEN - Google Patents

Abstract

1. Power cable for medium (from 6 kV) and high voltage (up to 330 kV), containing at least one copper or aluminum conductive core, containing a screen of an electrically conductive cross-linked polymer composition superimposed by extrusion on the conductive core, cross-linked polyethylene insulation, the second extruded a screen made of an electrically conductive cross-linked polyethylene composition, a metal screen wrapped in a spiral-wound metal tape, a separation layer and an outer shell, characterized in that the screen is made of metal wires The lock is made in two layers with a layer of electrically conductive tapes superimposed between the layers of the metal wire. 2. The power cable according to claim 1, characterized in that the metal shield is made of either copper or aluminum (or aluminum alloy) wires with a winding of either copper or aluminum (or aluminum alloy) tape, respectively. 3. The power cable according to claim 1, characterized in that a layer of electrically conductive water-blocking tapes is applied over the first layer of the screen from a metal wire. Power cable 1 and 3, characterized in that a fastening polypropylene tape is applied over the electrically conductive or electrically conductive water blocking tapes of the metal screen. The power cable according to claim 1, characterized in that a distribution fiber-optic temperature sensor is built into the screen of metal wires. The power cable according to claim 1, characterized in that between the separation layer and the outer sheath there is either an inner sheath, or an inner sheath and armor of aluminum or aluminum alloy wires, or an inner sheath and laminated

Description

The utility model relates to cable technology, namely, to the construction of power cables with cross-linked polyethylene insulation, used for transmission and distribution of electric energy in stationary installations for medium and high rated alternating voltage from 6 to 330 kV.

Known single-phase power cables containing an aluminum or copper conductive core and sequentially arranged on it by extrusion, a first screen of an electrically conductive cross-linked polymer composition, insulation of a cross-linked polyethylene composition, a second screen of an electrically conductive cross-linked polymer composition, winding tapes of an electrically conductive material, a metal screen of copper wires bonded spirally imposed with a gap of copper tape, extruded inner sheath and extruded outer the sheath (patents RU No. 92567 and RU No. 91218, M. class. H01B 9/00, published on March 20, 2010 and September 23, 2009) or power cables are known that contain armor covers in addition to these features (patent RU No. 106030 M Cl. H01B 9/00 published 06/27/2011).

Common features for known cables and the claimed cable are the type of insulation (cross-linked polyethylene), the materials of the outer and inner shells (PVC plastic that does not spread combustion, or a halogen-free polymer composition, or high-density polyethylene), the presence of two screens of an electrically conductive cross-linked polymer composition , a metal screen fastened spirally imposed with a gap of metal tape, a separation layer, an inner shell, superimposed on top of the inner layer of an armored aluminum cover mini wires or aluminum alloy and outer sheath.

The reason that prevents obtaining a technical result in a known technical solution, which is provided by the claimed utility model, is that the known cable does not satisfy the safety and reliability conditions of the medium and high voltage cable when significant short-circuit currents pass through the cable.

The problem the utility model aims to solve is to expand the arsenal of power cables with polyethylene insulation, operating in a wide voltage range from 6 kV to 330 kV, not inferior to the known cables in basic characteristics, but more high-quality and highly reliable in operation with significant currents short circuit.

A technical result is achieved in the claimed utility model by the fact that the metal screen of the power cable made of copper or aluminum (aluminum alloy) wires is laid in two layers with a layer between the layers of the metal wire and a layer of conductive tapes or water-blocking conductive tapes and a fastening polypropylene tape, which significantly increases cable service life and increases the reliability of the cable in case of high short circuit currents.

This problem is solved due to the fact that the power cable for medium (from 6 kV) and high voltage (up to 330 kV), containing at least one copper or aluminum conductive core, contains a screen of an electrically conductive cross-linked polymer composition imposed by extrusion on the conductive core, insulation made of cross-linked polyethylene, a second extruded screen of an electrically conductive cross-linked polyethylene composition, a metal screen, either of copper or aluminum (or aluminum alloy) wires with a winding of either copper or aluminum (or aluminum alloy) tape, respectively, the separation layer and the outer shell. In this case, the screen of metal wires is made in two layers with a layer between the layers of the metal wire of a layer of conductive or electrically conductive water blocking tapes with a fastening polypropylene tape. A distribution fiber optic temperature sensor can be integrated into the screen of metal wires. In addition, between the separation layer and the outer shell, either the inner shell or the inner shell and armor of aluminum or aluminum alloy wires, or the inner shell and the laminated aluminum-polymer tape can be located. A winding in a conductive core of an electrically conductive tape may be superimposed on a conductive core. The inner sheath is made of polyethylene, or non-combustible PVC compound, or of a halogen-free polymer composition, and the outer sheath of the cable is either high density polyethylene, non-combustible PVC compound, or non-combustion PVC compound with low smoke and gas emission. A layer of electrically conductive paper or electrically conductive polymer tape or a layer of electrically conductive water-blocking tape can be applied over the second screen, and conductive cores can be made with longitudinal sealing from water-blocking tapes, bundles and threads laid in the gaps between the wires when twisting the core.

A new feature of the claimed technical solution of the utility model is the manufacture of a metal screen of the claimed power cable from metal wires, laid in two layers with a layer between the layers of metal wires of a layer of electrically conductive or electrically conductive water blocking tapes with a possible application of a polypropylene fastening tape over these tapes.

In power cables for medium and high voltage, a voltage level of several tens and hundreds of kV makes it necessary to use a metal shield. The main purpose of the metal screen is to eliminate the electric field on the surface of the cable. The screen forms the second electrode of the capacitor formed by the cable (the first is the conductive core of the cable). The second purpose of the metal screen is to provide lateral sealing in the cable to protect its elements, including its insulation, from moisture, because simultaneous exposure to moisture and a strong electric field leads to the appearance of local breakdowns (dendrites), which after some time can lead to the destruction of the insulating material).

During normal operation of the cable, current flows through its conductive core, limited by the load resistance. If a conductive core and a metal screen come into contact during insulation breakdown (for example, due to overvoltage in the network) or a short circuit occurs on the load, the load resistance becomes zero, a significant current flows through the metal screen, limited only by the resistance of the conductive core and the screen, which much less load resistance, the core is quickly heated to a significant temperature, which leads to destruction of the insulation and its combustion. To pass this significant current through a metal screen, it is necessary to increase the cross section of the screen. The cross section of the metal screen provides an allowable short circuit current, to increase the permissible short circuit current, it is necessary to increase the cross-sectional area of the screen, because as the cross section increases, the screen resistance decreases.

The cross section of the copper screen is determined depending on the magnitude of the short-circuit currents and the time of their operation, i.e. if the power systems require an increased level of short circuit currents, and the standard screen cannot provide this (insulation is destroyed and the cable is destroyed), it is necessary to significantly increase the cross-sectional area of the screen. In order to get out of the situation when it is necessary to impose a large section of a metal wire screen, and the nominal section of the cable does not allow this, then it is necessary to impose a metal screen in two layers. To obtain the claimed cross-section of the screen, the required number of wires is calculated taking into account restrictions on the diameter of the wire, the capabilities of the equipment in the production, the compactness condition and the reduction of the airspace. To calculate the number of wires required to provide the required cross-sectional area of the screen, we use the formula:

n × d> L _okr , where

L _okr - the length of the circle on which the wire is wound;

n is the number of wires (pcs.);

d - diameter (nominal section) of the wire

if n × d is obtained more than it enters the surface to be coated, a second layer is made with the calculation of the distance through which the wires are superimposed, but not less than 8 mm:

A layer of electrically conductive or electrically conductive water blocking tapes (for cables with the index “r” and “2r”) is applied between the layers of metal wire to distribute the electric field between the layers, to fasten each layer of the wire so that the wires of the upper layer do not fall into the gaps between the turns, in order to maintain a regulated distance between the wires (8 mm) and in order to further protect the metal screen from moisture, if it is an electrically conductive water blocking tape.

On top of the electrically conductive and electrically conductive water-blocking tapes, the attachment of a fastening polypropylene tape is allowed.

In FIG. 1 shows a section of the claimed design of the power cable for high voltage.

On a multi-wire round or sector conductive core 1 by a winding, a layer of an electrically conductive polymer tape 2 is applied; then, by extrusion, a first screen 3 of an electrically conductive cross-linked polyethylene composition is applied, which serves to uniformly distribute the electric field strength at the interface between the conductive core and the insulation layer.

On top of the first screen by extrusion, insulation 4 from the composition of cross-linked polyethylene is applied, which serves as the main electrical insulating element and withstands the effects of an electric field.

On top of the insulation by extrusion, a second screen 5 of an electrically conductive cross-linked polyethylene composition is applied, which serves to evenly distribute the tension between the insulation and the metal screen.

A layer 6 of electrically conductive paper and an electrically conductive polymer tape or a water blocking tape can be applied by winding on top of the second screen for insulation 5, which serves as protection against mechanical damage to the second electrically conductive screen, and also serves to level the electric field in the cable.

A double-layer metal shield is superimposed on top of the winding from an electrically conductive tape: 7a is the first layer, 7b is the second layer, 7c is the electrically conductive (electrically conductive water blocking) layer, the main purpose of the metal double-layer screen is to uniformly spread the zero potential across the cable insulation surface and to transmit significant short-circuit currents. The metal screen is made of metal wires (copper, aluminum or aluminum alloy) twisted in one direction, over which a metal tape (copper, aluminum or aluminum alloy) is applied in the opposite direction by winding with electrical contact.

On top of the metal screen by the method of winding, a separation layer 8 is applied, which is necessary to prevent leakage of the sheath material between the screen wires during the manufacturing process.

On top of the separation layer can be applied laminated alumina tape 9.

Then, an inner shell 10 of PVC, flame retardant, non-halogen polymer composition or polyethylene is applied. The cable can also be armored, in this case, an armor 11 made of aluminum wires or aluminum alloy wires is superimposed on top of the inner shell, which in this case serves as a pillow for armor.

On top of the separation layer, or on top of the inner shell or the armor applied by extrusion, the outer shell 12 is made of high density polyethylene, or a composition made of low-flammable PVC compound, or non-flammable PVC compound, or a halogen-free composition.

The electric cable can be made in the execution of "g" and contain on top of the second electrically conductive screen a layer of electrically conductive water blocking tape, and as a separation layer contain a water block tape, which allows you to protect the cable from moisture. The electric cable can be made in the execution of "gzh" and in addition to the design in the execution of "g" contain a sealed conductive core by introducing water-blocking threads in the twisting process.

The cable can be made in the execution of “2g” and “2gh” and, in addition to the design in the execution of “g” or “gzh”, contain a winding over the dividing layer with an overlap of laminated alumina-polymer tape.

Thus, the task in the claimed utility model is solved due to the fact that the metal screen of the power cable from copper or aluminum (aluminum alloy) wires is superimposed in two layers with a layer between the layers of the metal wire layer of conductive tapes or water-blocking conductive tapes, which is typical for any variant of the proposed design of the claimed utility model.

Designs of the claimed utility model have been successfully tested in production conditions.

Claims (11)

1. Power cable for medium (from 6 kV) and high voltage (up to 330 kV), containing at least one copper or aluminum conductive core, containing a screen of an electrically conductive cross-linked polymer composition superimposed by extrusion on the conductive core, cross-linked polyethylene insulation, the second extruded a screen made of an electrically conductive cross-linked polyethylene composition, a metal screen wrapped in a spiral-wound metal tape, a separation layer and an outer shell, characterized in that the screen is made of metal wires The lock is made in two layers with a layer of electrically conductive tapes superimposed between the layers of the metal wire. 2. The power cable according to claim 1, characterized in that the metal shield is made of either copper or aluminum (or aluminum alloy) wires with a winding or copper or aluminum (or aluminum alloy) tape, respectively. 3. The power cable according to claim 1, characterized in that a layer of electrically conductive water blocking tapes is applied over the first layer of the screen from a metal wire. 4. Power cable for PP. 1 and 3, characterized in that a fastening polypropylene tape is applied over the electrically conductive or electrically conductive water blocking tapes of the metal screen. 5. The power cable according to claim 1, characterized in that a fiber optic temperature distribution sensor is integrated into the screen of metal wires. 6. The power cable according to claim 1, characterized in that between the separation layer and the outer sheath there is either an inner sheath, or an inner sheath and armor made of aluminum or aluminum alloy wires, or an inner sheath and a laminated aluminum-polymer tape. 7. The power cable according to claim 1, characterized in that a winding is applied to the conductive core along the conductive core of the conductive tape. 8. The power cable according to claim 1, characterized in that the inner sheath is made of polyethylene, or of PVC compound that does not spread combustion, or of a halogen-free polymer composition. 9. The power cable according to claim 1, characterized in that the outer sheath of the cable is made either of high density polyethylene, or of a PVC compound that does not spread combustion, or of a PVC compound that does not spread combustion with low smoke and gas emission. 10. Power cable for PP. 1-9, characterized in that a layer of electrically conductive paper or an electrically conductive polymer tape or a layer of an electrically conductive water blocking tape is applied over the second screen. 11. Power cable for PP. 1-10, characterized in that it is made with longitudinal sealing of the conductive core of water-blocking tapes, bundles and threads laid in the gaps between the wires when twisting the core.

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