RU207927U1 - THREE-PHASE POWER CABLE WITH METAL SHEATH - Google Patents

Abstract

The utility model relates to cable technology, namely to the structures of power cables with XLPE insulation, used for the transmission and distribution of electrical energy in stationary installations for a rated alternating voltage of 6, 10, 15, 20, 30, 35, 45, 66, 110 , 132, 150, 220, 275, 330 kV. The power cable contains three round metal conductive conductors, each of which is covered with a first layer of an electrically conductive cross-linked polyethylene composition, insulation from a cross-linked polyethylene composition, a second layer of an electrically conductive cross-linked polyethylene composition, while the conductive conductors covered with insulation and two electrically conductive layers are twisted into a core around the bundle made of polymeric material, and on top of the twisted cores there is an inner sheath and an outer sheath, and between the inner and outer sheaths there is a metal sheath made of aluminum, aluminum alloy or lead, made with a thickness of at least 1 mm. A thermal barrier or cushion for armor and armor can be applied over the metal shell. Conductors can be made of copper or aluminum. An additional layer of electrically conductive polymer tape can be applied along the conductive cores. When a metal screen is applied, it is made of copper wires wrapped with copper tape or a frame of copper wires or aluminum (or aluminum alloy) wires wrapped with an aluminum (or aluminum alloy) tape, or wrapped with aramid, or polymer thread, or polymer tape. A metal shield can be applied either to each conductive core, or to the twisting of the cores (common shield) over the inner sheath. An additional separating layer can be applied to the metal screen. The outer sheath of the cable is made of polyethylene, either from polyvinyl chloride, or from polyvinyl chloride of low flammability, or polyvinyl chloride of low flammability in a cold-resistant version, or from polyvinyl chloride of reduced fire hazard, or from polyvinyl chloride containing a reduced fire hazard with low smoke emission, or in a cold-resistant composition halogens, either from a halogen-free polymer composition in a cold-resistant design, or from a halogen-free flame-retardant polymer composition. The outer sheath of the cable can also be made in a reinforced or two-layer design. The cable can be made in a sealed version, with hermetically sealed conductor and overlaid over a metal screen, over an electrically conductive screen over insulation and over the inner sheath of a water-blocking tape. An electrically conductive layer is applied over the outer shell. The design of the claimed utility model has been successfully tested in production conditions.

Description

The utility model relates to cable technology, namely to the structures of power cables with XLPE insulation, used for the transmission and distribution of electrical energy in stationary installations for a rated alternating voltage of 6, 10, 15, 20, 30, 35, 45, 66, 110 , 132, 150, 220, 275, 330 kV.

A power cable is known, which is a close analogue (prototype) of the claimed design of a power cable, it is a power cable containing three metal conductive conductors, each of which is covered with a first layer of an electrically conductive cross-linked polyethylene composition, insulation from a cross-linked polyethylene composition, a second layer of an electrically conductive cross-linked polyethylene composition , a layer of an electrically conductive tape and a metal screen, while the conductive cores covered with these layers are twisted into a core around a bundle of polymer material, and a separating layer and an outer sheath are contained on top of the twisted cores, while the separating layer is made of PVC compound with an oxygen index not less than 28, and the outer shell is made of PVC compound with an oxygen index of at least 32 (patent RU No. 148879, M. class Н01В 7/295, published on 20.12.2014).

The features of the known cable, which coincide with the features of the claimed utility model, consist in the execution of a three-phase cable with copper or aluminum conductive conductors, a screen along the conductor of an electrically conductive cross-linked polymer composition, insulation from a cross-linked polyethylene composition, a screen on insulation from an electrically conductive cross-linked polymer composition, the presence of an internal and outer shell. The presence of a separating layer, a layer of electrically conductive tape, and a metal shield in special cases of execution.

Distinctive features of the proposed utility model and the known cable design is the presence of a metal sheath with a thickness of at least 1 mm between the inner and outer sheaths of the cable.

The problem to be solved by the utility model is to increase the reliability of the medium and high voltage power cable during operation under extreme conditions of increased electrical, mechanical and temperature loads.

The technical result is achieved by the fact that the power cable contains three round metal conductive conductors, each of which is covered with a first layer of an electrically conductive cross-linked polyethylene composition, insulation from a cross-linked polyethylene composition, a second layer of an electrically conductive cross-linked polyethylene composition, while conductive conductors are covered with insulation and two electrically conductive layers are twisted into a core around a bundle of polymer material, and on top of the twisted cores there is an inner sheath and an outer sheath, and between the inner and outer sheaths there is a metal sheath made of aluminum, aluminum alloy or lead, made with a thickness of at least 1 mm. A thermal barrier or cushion for armor and armor can be applied over the metal shell. Conductors can be made of copper or aluminum. An additional layer of electrically conductive polymer tape can be applied along the conductive cores. When a metal screen is applied, it is made of copper wires wrapped with copper tape or a frame of copper wires or aluminum (or aluminum alloy) wires wrapped with aluminum (or aluminum alloy) tape, or wrapped with aramid or polymer thread, or polymer tape ... The metal shield can be applied either to each conductive core, or to the twisting of the cores (common shield) over the inner sheath. An additional separating layer can be applied to the metal screen.

The outer sheath of the cable is made of polyethylene, either from polyvinyl chloride, or from polyvinyl chloride of low flammability, or polyvinyl chloride of low flammability in a cold-resistant version, or from polyvinyl chloride of reduced fire hazard, or from polyvinyl chloride containing a reduced fire hazard with low smoke emission, or in a cold-resistant composition halogens, either from a halogen-free polymer composition in a cold-resistant design, or from a halogen-free flame-retardant polymer composition. The outer sheath of the cable can also be made in a reinforced or two-layer design. The cable can be made in a sealed version, with hermetically sealed conductor and overlaid over a metal screen, over an electrically conductive screen over insulation and over the inner sheath of a water-blocking tape. An electrically conductive layer is applied over the outer shell.

Experience in the manufacture and operation of medium and high voltage power cables has shown that it is possible to provide additional protection for the power cable to increase the reliability of the cable during operation by making an additional cable sheath of metal (aluminum, aluminum alloy or lead). Metal sheaths are used mainly in paper-insulated cables, but it turned out that this is also advisable in cables with XLPE insulation. In this case, the metal sheath performs several protective functions at once in the power cable, i.e. it plays the role of a metal screen or an additional metal screen to protect external circuits from the influence of electromagnetic fields of currents passing through the cable and to ensure the symmetry of the electric field around the cable cores; it additionally protects the cable from external mechanical damage, i.e. serves as an armor. The aluminum or lead cable sheath protects the internal elements of the cable from destruction by moisture, acids, gases, etc. serve for additional sealing of the cable, while maintaining all the basic properties of the power cable for medium and high voltage. The thickness of the metal sheath is determined by the magnitude of the short-circuit currents, their duration and varies from 1 mm to 1.71 mm, depending on the operating conditions of the cable and its purpose. In the case when the values of the short-circuit currents are high enough and the thickness of the metal shell is not enough to protect against electromagnetic fields, a metal screen (copper or aluminum) is additionally applied to the layer of the winding made of electrically conductive material along the electrically conductive screen along the insulation, either along each conductive core, or a common shield over the inner shell, the choice of the location of the metal shield is due to the provision of maximum contact of the metal shield with the semiconducting shield over the insulation of current-carrying conductors. A separating electrically conductive layer with a thickness of at least 0.15 mm of electrically conductive crepe tape or electrically conductive cable paper or electrically conductive polymer tape or electrically conductive nonwoven tapes, electrically conductive water-blocking tape, or electrically conductive paper tape or electrically conductive synthetic tape, or electrically conductive water-blocking tape (in the case of a sealed cable) or winding of at least one fire-retardant tape in cables with the index "ng ()", "gng ()", "ng () - LS", ng () - HL, then an inner metal sheath is applied , then additional winding with cable paper or polymer tape or tapes made of non-woven fabric (for cable structures with individual screens of conductive conductors or without a screen) and an outer sheath. Because the presence of a metal inner sheath protects the internal structure of the cable well from external mechanical and corrosive influences, these cables are recommended for laying in the ground, regardless of the degree of corrosiveness of soils (with a lead sheath). And with an aluminum sheath in a sealed version for laying in the ground and in water (in non-navigable water bodies) - subject to measures that exclude mechanical damage to the cable. For additional protection of the cable from mechanical damage, armor can be additionally applied, therefore, these cables are intended for laying on difficult sections of cable routes, as well as on sections without limiting the level difference.

The manufacturing process for a medium and high voltage power cable with a metal inner sheath is as follows:

The power cable contains three conductive cores, copper or aluminum, twisted from many wires and sealed, round in shape, designed for the passage of electric current.

Each conductive core is wound with a layer of electrically conductive polymer tape - a fire barrier (in the case of manufacturing a fire-resistant cable), then the first layer of an electrically conductive cross-linked polyethylene composition is applied by extrusion (either on the fire barrier or directly on the conductive core), which serves for uniform distribution the strength of the electric field at the border of the conductive core and the insulation layer.

On top of the first layer of an electrically conductive cross-linked polyethylene composition, a layer of cross-linked polyethylene insulating composition is applied by extrusion, which serves as the main electrical insulating element and withstands the effect of an electric field.

A second layer of an electrically conductive cross-linked polyethylene composition is applied on top of the insulating layer by extrusion, which serves to evenly distribute the tension between the insulation and the metal screen (or metal sheath in the absence of a screen).

On top of the second layer of electrically conductive cross-linked polyethylene composition, a layer of electrically conductive paper tape or electrically conductive polymer tape, or non-woven fabric, or electrically conductive water-blocking tape is applied, which serves as protection against mechanical damage to the second electrically conductive screen, and also serves to equalize the electric field in the cable.

A metal screen (if any) is applied over the winding made of electrically conductive tape. The main purpose of the metal screen is the uniform spread of the zero potential over the surface of the cable insulation and the transmission of short-circuit currents. The metal screen is made of metal wires twisted in one direction, on top of which a metal tape (or of metal wires) is applied by winding to ensure electrical contact, while the wires and tape can be made of copper, or aluminum or aluminum alloy, and the winding can also be made of aramid threads or polymeric threads or polymeric tapes. A metal shield can be applied either along each conductor, or along the twisting of the conductors along the inner sheath of the cable.

Insulated and shielded conductors are twisted into a core around a bundle made of polymer material.

On top of the core made of twisted conductors by extrusion, an inner sheath is applied with filling of the interphase space (to give the cable an almost round shape) and a metal screen (if any).

On top of the metal screen by the winding method, it is allowed to apply a separating layer in the form of a winding, which is necessary to prevent the sheath material from flowing between the screen wires during the manufacturing process. On top of the separating layer, a metal inner shell with a thickness of at least 1 mm is applied. On top of the metal sheath, a winding is made of tapes of cable paper or polymer tape, or non-woven fabric, or glass tape. In the case of the manufacture of a flame-retardant cable, a thermal barrier made of polyvinyl chloride of low flammability or from a polymer composition that does not contain halogens is pressed over the metal sheath, and in the case of the manufacture of a cable with increased requirements for protection against mechanical damage, a pillow under the armor and tape is applied over the metal sheath , wire or combined armor.

Then the outer sheath is applied.

The power cable can be made in version "g" and contain a layer of electrically conductive water-blocking tape over the second electrically conductive screen and over the metal shield, and over the separating layer contain a water-blocking tape, which additionally protects the cable from moisture spread. The power cable can be made in the "gzh" version and, in addition to the structure in the "g" version, contain a sealed conductive core by introducing water-blocking threads during the twisting process.

The design of the claimed utility model has been successfully tested in production conditions.

Claims (18)

1. Power cable containing three round metal conductive conductors, each of which is covered with a first layer of an electrically conductive cross-linked polyethylene composition, insulation from a cross-linked polyethylene composition, a second layer of an electrically conductive cross-linked polyethylene composition, while conductive conductors are covered with insulation and two electrically conductive layers, are twisted into a core around a bundle of polymeric material, and on top of the twisted cores there is an inner sheath and an outer sheath, characterized in that between the inner and outer sheaths there is a metal sheath made with a thickness of at least 1 mm. 2. Cable according to claim 1, characterized in that the conductors are made of copper or aluminum. 3. A cable according to claim 1, characterized in that a layer of electrically conductive polymer tape is additionally applied along the current-carrying conductors. 4. The cable according to claim 1, characterized in that a layer of electrically conductive tape made of electrically conductive paper, or electrically conductive polymer tape, or non-woven electrically conductive fabric, or electrically conductive water-blocking tape is applied over the insulating layer. 5. A cable according to claim 3, characterized in that a metal screen made of copper wires, or aluminum wires, or aluminum alloy wires is applied over the winding of insulated conductive conductors. 6. The cable according to claim 5, characterized in that the metal screen is wrapped with copper tape or frame made of copper wires, or aluminum wires, or aluminum alloy wires, wrapped with an aluminum or aluminum alloy tape or aramid thread, or polymer thread, or polymer tape. 7. Cable according to claim 1 or 5, characterized in that the inner sheath is extruded over the stranding of conductive conductors with filling of the interphase space from materials compatible with the materials of the insulation and the outer sheath, and a winding of water-blocking electrically conductive tapes or polymer tapes is applied over the inner sheath , or fiberglass tapes. 8. Cable according to claim 5, characterized in that the metal shield is applied over the inner sheath. 9. Cable according to claim 8, characterized in that a separating layer made of electrically conductive crepe tape or electrically conductive cable paper, or electrically conductive polymer tape, or electrically conductive tapes of nonwoven fabric, or electrically conductive water-blocking tape, or electrically conductive glass tape is applied over the metal screen. 10. A cable according to claim 1, characterized in that the core is made of rubber, or polymer twisted tapes, or water-blocking tapes. 11. A cable according to claim 1, characterized in that the metal sheath is made of aluminum or aluminum alloy or lead. 12. The cable according to claim. 1, characterized in that over the metal sheath is made of tapes of cable paper or polymer tape, or non-woven fabric, or glass tape. 13. A cable according to claim 1, characterized in that a thermal barrier made of polyvinyl chloride of low flammability or from a polymer composition that does not contain halogens is extruded over the metal sheath. 14. The cable according to claim 1, characterized in that a cushion for the armor and tape, wire or combined armor are applied over the metal sheath. 15. The cable according to claim 1, characterized in that the outer sheath of the cable is made of polyethylene, either from polyvinyl chloride, or from polyvinyl chloride of low flammability, or polyvinyl chloride of low flammability in a cold-resistant version, or from polyvinyl chloride of low fire hazard, or from polyvinyl chloride with low fire hazard. smoke emission, or from polyvinyl chloride of reduced fire hazard with low smoke emission in a cold-resistant version, or from a polymer composition that does not contain halogens, or from a polymer composition that does not contain halogens in a cold-resistant version. 16. The cable according to claim 1, characterized in that the outer sheath of the cable is made in a reinforced or two-layer design. 17. Cable according to claim 1, characterized in that the conductive cores are made sealed. 18. A cable according to claim 1, characterized in that an electrically conductive layer is applied over the outer sheath.