RU167142U1 - POWER CABLE, NOT DISTRIBUTING COMBUSTION, WITH SECTOR CONDUCTORS AND INSULATION FROM CROSSED POLYETHYLENE - Google Patents

Abstract

1. A flame retardant power cable containing three sector multi-wire, sealed conductive cores and the following layers sequentially arranged on each of them, namely, an extruded first screen of an electrically conductive cross-linked polymer composition of polyethylene, insulation of cross-linked polyethylene is applied over the screen of the conductive core, a second extruded screen of an electrically conductive cross-linked polymer composition is superimposed on top of the insulation, said conductive wires with the indicated layers are steeper s to the core, then a layer of tapes of electrically conductive material, a metal screen, a separation layer, an inner shell of a halogen-free polymer composition and an outer shell of a halogen-free polymer composition, wherein the outer shell is made of a halogen-free polymer composition with a tensile strength of at least 13 MPa, an elongation of at least 160% and an oxygen index of at least 33% .2. A cable according to claim 1, characterized in that the layer of electrically conductive tapes is made of either electrically conductive paper, or of electrically conductive polymer tapes, or of a non-woven fabric. A cable according to claim 1, characterized in that the metal screen is made of copper wires, and a spiral copper tape is laid over the screen's copper wires. The cable according to claim 1, characterized in that the separation layer is made of at least one glass tape. A cable according to claim 1, characterized in that an additional thermal barrier is additionally applied over the inner sheath from copper or aluminum tape or two glass strips, superimposed overlapping.

Description

Technical field

The utility model relates to cable technology, namely, to the construction of three-core power cables with insulation made of cross-linked polyethylene, not spreading combustion, intended for the transmission and distribution of electrical energy in stationary installations for a rated alternating voltage of 3.6 / 6, 6/10, 8 , 7/15, 12/20, 18/30, 20/35 kV with a nominal frequency of 50 Hz for networks with earthed and insulated neutral.

State of the art

Power cables for voltage of 6, 10, 20 and 35 kV with a frequency of 50 Hz are known, having three conductive cores and sequentially arranged on each of them imposed 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 compositions, winding with a tape of electrically conductive material, a metal screen, shielded cores are twisted into a common core around a central filling, interfacial filling and extruded outer sheath made of PVC compound (cable grade PvVng (A) -LS in accordance with TU 16.K71-335-2004 “Power cables with insulation of cross-linked polyethylene for voltage of 10, 20, 35 kV.” Information and technical reference book Cable products. Volume 1. Power cables, wires and cords - Part 1: M.: VNIIKP OJSC, 2006, p. 138).

However, such cables do not meet the requirements of GOST R IEC 61034-2 for smoke emission during combustion and decay, as well as the requirements for corrosion activity of smoke and gas products during combustion and decay (absence of halogens).

The closest analogue (prototype) is a power cable, containing three conductive cores and sequentially located on each of them, extruded 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 with a tape of electrically conductive material , metal screen, shielded cores twisted into a common core around a central filling, interfacial filling and extruded outward characterized in that the central filling is made of an extruded halogen-free polyolefin composition with an oxygen index of at least 30, the interfacial filling is made of a halogen-free polyolefin composition with an oxygen index of at least 40 and the outer shell is made of a polyolefin composition halogen-free with an oxygen index of at least 30 (RU 86035 U1, published 08/20/2009).

Signs of a known cable that coincide with the features of the claimed utility model consist of a cable with three metal conductors, each of which has a first conductive layer, insulation, a second conductive layer, a layer of conductive tapes, a metal shield, insulated shielded conductors twisted into a core and there is an outer shell of a halogen-free polymer composition.

The reason that prevents obtaining a technical result in a known cable, which is provided by the claimed utility model, is the implementation of conductive conductors of a sector shape, a layer of tapes of an electrically conductive material and a metal screen are superimposed not on each vein, but on the stranding of the strands, in addition, on the stranding of the strands a separation layer, an inner shell of a halogen-free polymer composition, a thermal barrier or armor, and an outer shell of a halogen-free polyolefin composition new, with an oxygen index of at least 33% and physico-mechanical characteristics that ensure cable reliability during operation.

Utility Model Disclosure

The problem to which the claimed utility model is directed is to expand the arsenal of cables with cross-linked polyethylene insulation, to reduce the cost of the cable with improved indicators of non-proliferation of combustion when laying in bundles, with low smoke emission during combustion and decay, of a cable that does not emit halogens in fire conditions and having a sufficiently high mechanical strength indicators.

The technical result, which leads to the solution of this problem, is to obtain a three-core cable with sector-sealed conductive conductors, with cross-linked polyethylene insulation, having a lower cost compared to analogs having round conductors, with improved fire safety indicators combined with high mechanical strength indicators.

The specified technical result is achieved by the fact that the power cable, which does not propagate combustion, contains three sector multi-wire sealed conductive cores and the following layers sequentially located on each of them, namely, an extruded first screen of an electrically conductive cross-linked polymer composition of polyethylene, laid on top of the screen over the conductive core cross-linked polyethylene insulation, a second extruded screen of an electrically conductive cross-linked polymer composition is superimposed on top of the insulation, indicated conducting conductors with the listed layers are twisted into a core; then a layer of tapes of electrically conductive paper, either of electrically conductive polymer tapes, or of a nonwoven fabric is superimposed on the core by winding; a metal screen made of copper wires, and spirally copper tape is applied over the copper wires of the screen; a separation layer made of at least one glass tape; the inner shell is made of a halogen-free polymer composition, then either a thermal barrier made of copper or aluminum tape or two glass tapes overlapping, or armor made of two galvanized steel tapes or round steel galvanized wires or wires of aluminum or aluminum alloy and an outer shell of a halogen-free polymer composition with a tensile strength of at least 13 MPa, elongation of at least 160%, and an oxygen index of at least 33%.

Since the technical result that is achieved in solving this problem is to manufacture a multi-wire conductive conductor, sealed, sector-shaped and to use a material for the outer shell with the indicated characteristics, which has lower combustibility, optical density of smoke during combustion and decay, corrosion activity gases and increased strength characteristics, cable modifications with structural elements such as thermal barrier or armor to achieve technical Cesky result is not affected. Therefore, in some special cases, on top of the inner sheath, either a thermal barrier made of copper or aluminum tape or two glass tape, overlapped (to increase the fire resistance of the cable), or armor made of two steel galvanized tapes or round steel galvanized wires or aluminum or aluminum alloy wires (for protection against mechanical damage). Also, the power cable under consideration in special cases can be made in a sealed version, which also does not affect the achievement of the technical task and obtaining the technical result.

The achievement of the technical result to reduce the cost is due to the manufacture of cable with sector cores, because cables with sector conductors have a diameter of 20–25% less than cables with round conductors of equivalent cross-section, and, accordingly, lower consumption of materials for insulation and sheath, and losses in the metal shield approach zero. Sealing a stranded core also provides material savings. Thus, the weight and overall characteristics of the cable are reduced to 40%, the maximum length of the winding on the drum is increased, cable cutting and manufacturing is simplified due to the lack of filling between the cores, and the risk of damage to the insulation during stripping is reduced. All these factors ultimately lead to a significant reduction in cost.

Improved performance of the cable for non-distribution of combustion when laying in beams, with low smoke emission during combustion and decay, not emitting halogens in a fire, provides the manufacture of a cable with an outer sheath from a polymer composition that does not contain halogens with an oxygen index of at least 33%.

High mechanical strength indicators are due to the use of a halogen-free polymer composition in the outer sheath of the cable with a tensile strength of at least 13 MPa and a relative elongation of at least 160%.

Tests of cable samples showed compliance of their characteristics with technical fire safety requirements GOST 31565-2012 “Cable products. Fire Safety Requirements ”, namely, on non-proliferation of combustion during group installation, smoke generation and the value of the equivalent toxicity index of combustion products for cable products with the HF index. And the strength characteristics of the outer shell determine the service life of the cables - at least 30 years.

Utility Model Implementation

The cable contains three multi-wire sealed sector conductive conductors. An extruded screen of an electrically conductive cross-linked polymer composition of polyethylene is laid over each core. On top of the first electrically conductive screen for each conductive core insulation is made of cross-linked polyethylene. A second extruded screen of an electrically conductive crosslinked polymer composition is superimposed on top of said insulation.

Insulated and shielded sector conductive conductors are twisted into a core. On top of the core is a layer of electrically conductive tape, which is an electrically conductive paper or an electrically conductive polymer tape or non-woven fabric. On top of the conductive tape of each core, there is a metal screen made of copper wires, on top of which a copper tape made in the form of a winding, or a skein of copper wires are helically imposed. Then a separation layer is applied, made of at least one glass tape and the inner shell. Over the inner sheath of the cable, either a thermal barrier made of copper or aluminum tape or two glass tape overlapping, or armor made of two steel galvanized tapes or round steel galvanized wires or wires of aluminum or aluminum alloy, and an outer sheath, can be applied made of a polymer composition that does not contain halogens with an oxygen index of at least 33%, while the corrosion activity of the gases of the material of the outer shell is quite low smoother, ie, the amount of hydrohalic acids is not more than 0.5 mg / g, the pH is not less than 4.3, and the maximum optical density of the smoke during combustion is not more than 100 in the inner shell and not more than 180 in the outer shell.

The twisting of sector veins and the twisting of veins into the core, the imposition of all subsequent layers is performed on standard equipment. In this case, the condition for the non-proliferation of combustion when laying in bundles with low smoke emission during combustion and decay is satisfied, because These conditions are provided primarily by the material of the outer sheath, while reducing the cost of the cable as a whole.

The manufacture of the cable consists in alternately applying the above layers in the appropriate order. In this case, the first screen is applied to each core by extrusion, and its (screen) purpose is to evenly distribute the electric field at the boundary of the conductive core and the insulation layer. Then, insulation is applied to each core, which serves as the main electrical insulating element and is designed to withstand the effects of an electric field. Then impose a second electrically conductive screen, which serves to evenly distribute the tension between the insulation and the metal screen. Then sector veins are twisted into a core, and a layer of an electrically conductive tape is applied over the core, which serves to align the electric field in the cable. Then impose a metal screen, the main purpose of which is protection against electromagnetic interference, as well as the removal of short circuit currents. Then impose a separation layer and the inner shell. In special cases, a thermal barrier can be applied to increase fire resistance or armor, which serves to protect against significant tensile forces. After that impose the outer shell.

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

Claims (8)

1. A flame retardant power cable containing three sector multi-wire, sealed conductive cores and the following layers sequentially arranged on each of them, namely, an extruded first screen of an electrically conductive cross-linked polymer composition of polyethylene, insulation of cross-linked polyethylene is applied over the screen of the conductive core, a second extruded screen of an electrically conductive cross-linked polymer composition is superimposed on top of the insulation, said conductive wires with the indicated layers are steeper s in the core, then a layer of tapes of electrically conductive material, a metal screen, a separation layer, an inner shell of a halogen-free polymer composition and an outer shell of a halogen-free polymer composition, wherein the outer shell is made of a halogen-free polymer composition with a tensile strength of at least 13 MPa, an elongation of at least 160% and an oxygen index of at least 33%. 2. The cable according to claim 1, characterized in that the layer of electrically conductive tapes is made either of electrically conductive paper, or of electrically conductive polymer tapes, or of a non-woven fabric. 3. The cable according to claim 1, characterized in that the metal screen is made of copper wires, and spirally copper tape is applied over the copper wires of the screen. 4. The cable according to claim 1, characterized in that the separation layer is made of at least one glass tape. 5. The cable according to claim 1, characterized in that on top of the inner shell there is additionally a thermal barrier made of copper or aluminum tape or two glass tape, superimposed overlapping. 6. The cable according to claim 1, characterized in that the armor of two galvanized steel tapes is additionally imposed on top of the inner shell. 7. The cable according to claim 1, characterized in that the armor is made of round galvanized steel wires or wires of aluminum or aluminum alloy over the inner sheath. 8. The cable according to claim 1, characterized in that it is made in a sealed version.