RU171278U1 - POWER CABLE COLD RESISTANT - Google Patents

Abstract

The utility model relates to cable technology, namely to the construction of cables with rubber insulation, intended for the transmission and distribution of electrical energy in stationary installations for alternating voltage of 6, 10, 15, 20, 30, 35 kV with a nominal frequency of 50 Hz for networks with grounded and insulated neutral. Power cable containing sequentially superimposed layers on top of the conductive core, namely the first conductive screen, insulation, the second conductive screen, a layer of conductive tape, a metal screen, and Also containing an outer sheath, said insulation being made of ethylene propylene rubber with a reinforcing hydrophobic filler, and said first and second electrically conductive screens are made of ethylene propylene rubber containing soot, characterized in that the outer sheath is made of cold-resistant materials that provide cable resistance to reduced ambient temperature.

Description

The utility model relates to cable technology, namely to the construction of cables with rubber insulation, intended for the transmission and distribution of electrical energy in stationary installations for alternating voltage of 6, 10, 15, 20, 30, 35 kV with a nominal frequency of 50 Hz for networks with grounded and isolated by neutral.

State of the art

A power cable for voltage of 10 and 20 kV with copper or aluminum conductive cores is known, an electrically conductive screen of an electrically conductive cross-linked polyethylene composition is applied to each core by extrusion, an insulation of a cross-linked polyethylene composition is applied to the screen by extrusion, and a second screen of an electrically conductive cross-linked composition is applied over the insulation an electrically conductive extruded screen a layer of electrically conductive tapes is applied to each core, a metal screen of superimposed wires is laid on top of the conductive tapes Ohm of copper wires fastened with copper tape, extruded is applied on a core twisted of three shielded cores, filling the space between the cores of a highly filled polymer composition, depending on the design and purpose of the cable, an inner sheath of an extruded polymer composition, an armor of a steel tape and a sheath of extruded polymer composition (IEC 60502-2: 2005 “Power cables with extruded insulation and fittings for them with a rated voltage of 6 kV (Um = 7.2 kV) to 30 kV (Um = 36 kV ) ". Part 2. Cables for rated voltage from 6 kV (Um = 7.2 kV) to 30 kV (Um = 36 kV)).

Signs of a known cable that match the features of the claimed utility model consist in the execution of a cable for voltage of 10 and 20 kV, with metal conductors, on each of which a first conductive layer, insulation, a second conductive layer, a layer of conductive tapes, a metal screen are applied inner shell and outer shell.

The reason that prevents obtaining a technical result in a known cable, which is provided by the claimed utility model, is the insulation of conductive conductors from cross-linked polyethylene.

The closest analogue (prototype) is a power cable, in which layers are sequentially laid on top of each conductive core, namely the first conductive screen, insulation, a second conductive screen, a layer of conductive tape and a metal screen, these conductive wires with these layers are twisted into a core or directly, or around a bundle extruded from a polymer material, either a release layer, an inner shell, and the outer shell, or the separation layer, the inner shell, the armor and the outer shell, or the inner shell and the outer shell, or the inner shell, the armor and the outer shell, wherein said insulation is made of ethylene propylene rubber with reinforcing hydrophobic filler, said first and second electrically conductive screens made of ethylene-propylene rubber containing soot, and the said armor is made of either galvanized steel tapes or galvanized steel wires (Patent RU No. 152230 U1, IPC Н01В 3 / 00, published on 05/10/2015).

The signs of the known cable, which coincides with the features of the claimed utility model, consist in the execution of a cable for voltage of 6, 10, 15, 20, 30, 35 kV, with conductive conductors insulated with rubber based on ethylene propylene diene rubber containing a reinforcing hydrophobic filler, in the design of conductive screens from ethylene-propylene rubber containing soot containing a layer of electrically conductive tape and a metal screen, in the execution of the inner and outer shells of polymeric materials.

The reason that prevents obtaining a technical result in a known technical solution, which is provided by the utility model, is that the inner and outer shells are made of materials that ensure the cable is resistant to low ambient temperature to minus 50 ° C.

Utility Model Disclosure

The problem the utility model aims to solve is to make a power cable with increased throughput, namely with the ability to work in nominal mode with a core temperature of up to 105 ° C, to make a power cable with insulation of increased flexibility (compared to cables with insulation from cross-linked polyethylene), as well as in the performance of a power cable that is resistant to low ambient temperature from minus 40 ° C to minus 65 ° C.

The technical result is achieved by the fact that the insulation of the conductive conductors is made of rubber based on ethylene propylene diene rubber containing a reinforcing hydrophobic filler, the electrically conductive screens are made of ethylene propylene rubber containing soot, and the materials of the outer shell are made of cold-resistant materials ensuring the cable is resistant to low ambient temperature in the range from minus 40 ° С to minus 65 ° С.

The use of insulation from ethylene-propylene rubber (rubber based on ethylene-propylene rubber containing a reinforcing hydrophobic filler) with high electrical and thermal resistance, as well as the use of the first and second electrically conductive layers of ethylene-propylene rubber (rubber based on ethylene-propylene rubber) with the content of highly conductive carbon blacks, can withstand current the load is 15-20% more with respect to the cable with XLPE insulation. Due to the high thermomechanical characteristics of this rubber, bending of the cable causes insignificant mechanical stresses of the insulation layers, which significantly reduces the likelihood of an uneven distribution of electrical tension in the insulation thickness.

The use of sheaths made of cold-resistant materials allows the cable to be used in areas with a temperate and cold climate, provides resistance to the effects of low ambient temperatures from minus 40 ° С to minus 65 ° С, in contrast to the materials of the sheaths used in the prototype cable, which provide resistance cable to the effects of low ambient temperature to minus 50 ° C, depending on the type of sheath, with the possibility of laying it at temperatures up to minus 40 ° C.

The technical result is achieved in that the power cable containing sequentially superimposed layers on top of the conductive core, namely, the first electrically conductive screen, the insulation, the second electrically conductive screen, the layer of the electrically conductive tape, the metal screen, and also containing the inner and outer shells, wherein said insulation is made from ethylene-propylene rubber with a reinforcing hydrophobic filler, and the aforementioned first and second electrically conductive screens are made of ethylene-propylene rubber containing soot, characterized in that the outer sheath is made of cold-resistant materials that provide cable resistance to low ambient temperatures.

New features of the claimed technical solution of the utility model are that they are used together in the cable: insulation of conductive conductors from rubber based on ethylene propylene diene rubber containing reinforcing hydrophobic filler, first and second conductive screens made of ethylene propylene rubber containing soot, and an outer sheath of cold resistant materials.

Special cases of cable execution, depending on additional requirements for operating conditions, in addition to the main one for resistance to low temperature, is the use of the following materials as outer shells:

- Halogen-free composition in cold-resistant design - with additional requirements for non-proliferation of combustion and the absence of volatile products, when burning cable, toxic, corrosive hydrogen chloride and other halogen-containing compounds.

- low flammability PVC compound in cold-resistant design - with additional requirements for non-proliferation of combustion;

- PVC compound in frost-resistant design - without additional requirements for operating conditions;

- Rubber that does not spread combustion in a frost-resistant design, - with additional requirements for increased cable flexibility and non-proliferation of combustion;

- Rubber in a frost-resistant design - with additional requirements for increased cable flexibility;

- Halogen-free rubber in frost-resistant design - with additional requirements for increased cable flexibility and the absence of volatile products, cable burning, toxic, corrosive hydrogen chloride and other halogen-containing compounds.

As an inner shell of materials:

- Rubber - with additional requirements for increased cable flexibility;

- low flammability PVC compound - with additional requirements for non-proliferation of combustion;

- finely filled unvulcanized rubber compound, highly filled polyvinyl chloride plasticate - without additional requirements for operating conditions;

- Halogen-free composition - with additional requirements for non-proliferation of combustion and the absence of volatile products, when burning cable, toxic, corrosive hydrogen chloride and other halogen-containing compounds.

Utility Model Implementation

The power cable contains one or more conductive cores intended for the passage of electric current.

The first electrically conductive screen, which is made of conductive rubber based on ethylene-propylene rubber containing highly conductive soot, is laid over the core by extrusion, the purpose of the first screen is to uniformly distribute the electric field strength at the interface between the conductive core and the insulation layer.

An insulation made of rubber based on ethylene-propylene rubber containing reinforcing hydrophobic filler, which serves as the main insulating element and withstands the effects of an electric field, is applied over the first electrically conductive screen by extrusion.

On top of the specified insulation by extrusion impose a second conductive screen, which is made of the same material as the first conductive screen. The second electrically conductive screen serves to evenly distribute the tension between the insulation and the metal screen.

A layer of an electrically conductive tape, which is an electrically conductive paper, or an electrically conductive polymer tape, or an electrically conductive water blocking tape serving to level the electric field in the cable, is applied by winding method over the second electrically conductive screen.

On top of the conductive tape on the shielding machines, a metal screen is applied, made either in the form of a plurality of copper wires, on top of which either a copper tape made in the form of a winding, or a pile of copper wires made in the form of a winding, or in the form of a plurality of aluminum or aluminum wires alloy wrapped in tape made of aluminum or aluminum alloy. The main purpose of the screen is protection against electromagnetic interference, as well as the removal of short circuit currents.

Insulated and shielded conductive conductors of a multicore cable are twisted into a core on twisting machines. Between twisted veins, there may be a bundle made of pressed polyvinyl chloride plastic compound, or of an unvulcanized rubber mixture, or of flame retardant rubber, or of water blocking tapes.

Since the technical result that is achieved when solving this problem is to use insulation materials with high electrical and thermal resistance in the cable, modifications of the cable with structural elements such as a separation layer, inner sheath, thermal barrier and armor to achieve technical do not affect the result and are special cases of execution when using a cable.

The cable may include a winding separation layer made of crepe or cable paper tape, or polypropylene tape, or non-woven fabric tape, or rubberized fabric, or fire retardant tape, or from a water blocking tape.

On top of the separation layer (or core of twisted veins), an inner shell is located, which is made of rubber, or of low fire hazard PVC compound, or of a finely filled unvulcanized rubber compound, or of a highly filled polyvinyl chloride compound, or of a halogen-free composition, or of a halogen-free composition cold resistant design.

A thermal barrier of copper or aluminum tape or fire retardant tapes can be applied over the inner shell by winding.

The cable may contain armor located on top of the inner sheath, while the armor is made of galvanized steel tapes, or galvanized steel wires, or aluminum or aluminum alloy wires, which serves to protect against significant tensile forces.

On top of the inner shell (or on top of the armor), an outer shell is applied by extrusion, made of a halogen-free composition in a cold-resistant version, or of low-flammable PVC compound in a cold-resistant version, or of a PVC compound in a frost-resistant version, or of non-flame-retardant rubber in a frost-resistant version, either from rubber in a frost-resistant design, or from rubber that does not contain halogens in a frost-resistant design.

The cable design has been successfully tested in the production environment.

Claims (22)

1. A power cable containing sequentially superimposed layers on top of the conductive core, namely, a first conductive shield, insulation, a second conductive shield, a layer of conductive tape, a metal shield, as well as an outer sheath, wherein said insulation is made of ethylene propylene rubber with reinforcing hydrophobic filler, and the aforementioned first and second electrically conductive screens are made of ethylene propylene rubber containing carbon black, characterized in that the outer shell is made of x malt-resistant materials that provide cable resistance to low ambient temperatures. 2. The cable according to claim 1, characterized in that the outer sheath is made of a halogen-free composition in a cold-resistant design, which ensures the resistance of the cable to low ambient temperatures to minus 65 ° C. 3. The cable according to claim 1, characterized in that the outer sheath is made of a halogen-free composition in a cold-resistant design, which ensures the cable is resistant to low ambient temperature to minus 60 ° C. 4. The cable according to claim 1, characterized in that the outer sheath is made of low-flammability PVC compound in a cold-resistant design, which ensures the cable is resistant to low ambient temperatures up to minus 60 ° C. 5. The cable according to claim 1, characterized in that the outer sheath is made of PVC compound in a frost-resistant design, which ensures the cable is resistant to low ambient temperature to minus 60 ° C. 6. The cable according to claim 1, characterized in that the outer sheath is made of rubber that does not spread combustion in a frost-resistant design, which ensures the cable is resistant to low ambient temperature to minus 60 ° C. 7. The cable according to claim 1, characterized in that the outer sheath is made of rubber in a frost-resistant design, which ensures the cable is resistant to low ambient temperature to minus 60 ° C. 8. The cable according to claim 1, characterized in that the outer sheath is made of halogen-free rubber in a frost-resistant design, which ensures the cable is resistant to low ambient temperature to minus 60 ° C. 9. The cable according to claim 1, in which the isolated conductors are twisted to form a core. 10. Cable according to claims 1 and 9, characterized in that on top of the twisted cores, a separation layer is applied. 11. The cable according to claim 1, characterized in that a separation layer is applied over the metal screen. 12. The cable according to claim 1, characterized in that it contains an inner sheath. 13. Cable according to claims 1 and 12, characterized in that the inner shell is made of rubber. 14. Cable according to claims 1 and 12, characterized in that the inner shell is made of polyvinyl chloride plastic compound of reduced fire hazard. 15. Cable according to claims 1 and 12, in which the inner shell is made of a finely filled unvulcanized rubber compound. 16. Cable according to claims 1 and 12, in which the inner shell is made of highly filled polyvinyl chloride plastic compound. 17. Cable according to claims 1 and 12, characterized in that the inner shell is made of a halogen-free composition. 18. Cable according to claims 1 and 12, characterized in that the inner shell is made of a halogen-free composition in a cold-resistant design. 19. Cable according to claims 1 and 12, characterized in that a thermal barrier is applied over the inner shell. 20. Cable according to claims 1 and 12, characterized in that on top of the inner shell imposed armor. 21. The cable according to claim 1, in which a cushion under the armor is applied over the inner shell. 22. The cable according to claim 17, characterized in that armor is imposed over the pillow under the armor.