RU168157U1 - Single-core power cable with halogen-free sheaths - Google Patents

Abstract

The utility model relates to power electric cables characterized by a material and arrangement of layers including halogen-free sheaths. These cables are designed for the transmission and distribution of electricity in stationary installations with a rated alternating voltage of 6, 10, 20 and 35 kV with a current frequency of 50 Hz, operated in conditions of increased fire hazard in accordance with the requirements for non-proliferation of combustion, excluding the release of hydrogen chloride during combustion. power with halogen-free shells, contains a conductive core, insulation of a conductive core, an inner shell made of a polymer composition that does not contain halogen, with an oxygen index of at least 47%, an outer shell made of a halogen-free polymer composition with an oxygen index of at least 33%, and a conductive core screen superimposed on the conductive core and comprising a layer of extruded electrically conductive cross-linked polymer composition on top of which said conductive core insulation is made of cross-linked polyethylene, an insulation screen overlaid on the conductive core insulation and made of extruded electrically conductive a cross-linked polymer composition, a protective winding made of an electrically conductive tape and overlaid on an insulation screen, a metal screen made of copper wires and located on top of the protective winding.

Description

The technical field to which the utility model relates.

The utility model relates to power electric cables characterized by a material and arrangement of layers including halogen-free sheaths. These cables are designed for the transmission and distribution of electricity in stationary installations with a rated alternating voltage of 6, 10, 20 and 35 kV with a current frequency of 50 Hz, operated in conditions of increased fire hazard in accordance with the requirements for non-proliferation of combustion, excluding the release of hydrogen chloride during combustion. Cables can be used, for example, in heat and hydroelectric power plants, in oil and gas enterprises, in chemical plants, in the construction of high-rise buildings, in subways, and in a number of other facilities that pay special attention to fire safety.

State of the art

A cable is known that includes a conductive core with combined insulation, as well as a protective sheath, while the core insulation is made in the form of an extruded continuous concentric layer of composite material, which subsequently turns into ceramic when exposed to high temperature, and the polymer insulation and protective sheath are made of non-halogen polymer compositions (Patent RU No. 58777 U1, IPC H01B 7/02, published November 27, 2006).

Signs of the known cable, which are common with the claimed technical solution, are that it contains a conductive core with insulation, as well as a protective sheath, while the protective sheath is made of a halogen-free polymer composition.

The reason that prevents obtaining the claimed technical result in a known cable is that the composite material from which the core insulation is made turns into ceramic when exposed to high temperature.

The closest known technical solutions (prototype) is a single-core power fire-resistant cable with combined insulation and halogen-free sheaths, which contains a conductive core coated with a combined insulation consisting of two sequentially applied layers of insulation, as well as an inner sheath and an outer sheath, this first layer of core insulation is made in the form of a winding directly from the conductive core of two mica tapes, over which a second layer is applied insulation made of a polymer material, said inner shell is made of a halogen-free polymer composition characterized by an oxygen index of at least 42%, and said outer shell is made of a halogen-free polymer composition, characterized by an oxygen index of at least 32%, strength a gap of at least 8 MPa, elongation at break of at least 125% (Patent RU No. 161729 U1, IPC H01B 7/295, published May 10, 2016, Bull. 13).

Signs of a known cable that are common with the claimed technical solution are that it contains a conductive core, insulation of a conductive core, an inner shell made of a halogen-free polymer composition with an oxygen index of at least 47%, and an outer shell made from a halogen-free polymer composition with an oxygen index of at least 33%.

The reason that prevents obtaining the claimed technical result in a known cable is the lack of layers providing the necessary electrical and mechanical parameters of the cable (uniform distribution of electric field strength around the cable, protection against short circuit currents, mechanical strength of the cable).

The technical problem is the need to expand the arsenal of cables that combine a low level of smoke emission during burning and smoldering of the cable, as well as the non-emission of halogens in a fire with high electrical and mechanical parameters of the cable (uniform distribution of electric field strength around the cable, protection against short circuit currents, mechanical strength).

Utility Model Disclosure

The technical result that mediates the solution of the indicated technical problem consists in the realization of the indicated purpose by combining three types of properties in the cable design:

1) in meeting 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);

2) in increasing the uniformity of the distribution of electric field strength at the boundary of the conductive core and the insulation layer, in aligning the electric field in the cable, in increasing the protection of the cable from short circuit currents;

3) to increase the security of the cable from mechanical damage.

The technical result is achieved in that a single-core power cable with halogen-free sheaths contains a conductive core, insulation of a conductive core, an inner sheath made of a halogen-free polymer composition with an oxygen index of at least 47%, an outer sheath made of polymer a halogen-free composition with an oxygen index of at least 33%, as well as a conductive core screen superimposed on a conductive core and including a layer of extruded electrically conductive crosslinked a dimensional composition over which said conductive core insulation is applied made of cross-linked polyethylene, an insulation screen superimposed on the conductive core insulation and made of extruded electrically conductive cross-linked polymer composition, a protective winding made of an electrically conductive tape and superimposed on top of the insulation screen, a metal screen made made of copper wires and located on top of the protective winding.

Distinctive features of the claimed technical solution are that the cable contains a screen of a conductive core superimposed on a conductive core and comprising a layer of extruded conductive cross-linked polymer composition over which said conductive core insulation made of cross-linked polyethylene is applied, an insulation screen applied over conductive insulation cores and made of extruded electrically conductive cross-linked polymer composition, a protective winding made of electro odyaschey tape and superimposed on top of the screen insulation and a metal screen, made of a copper wire and disposed over the protective winding.

Utility Model Implementation

Within the claimed patent rights, the following embodiments of the utility model are possible.

First option.

Power single-core cable with halogen-free sheaths contains a conductive core and a number of layers. The conductive core is round in cross section, multi-wire, preferably corresponding to flexibility class 2 according to GOST 22483-2012. On top of the conductive core, a conductive core screen is applied, made either as a single layer of an extruded electrically conductive cross-linked polymer composition, or two-layer, the first layer being made in the form of a synthetic electrically conductive tape superimposed on the core, over which a second layer of said extruded electrically conductive cross-linked polymer composition is applied. This screen is designed for uniform distribution of electric field strength at the boundary of the conductive core and the insulation layer. On top of this screen, a conductive core insulation made of cross-linked polyethylene is superimposed. Over the insulation of the conductive core, an insulation screen is made of an extruded electrically conductive cross-linked polymer composition. The insulation shield is designed to evenly distribute the electric field between the insulation and the metal shield. A protective winding is made over the insulation screen made of an electrically conductive tape, namely, tapes of an electrically conductive paper or an electrically conductive polymer tape, or an electrically conductive non-woven fabric. This protective winding is designed to protect against mechanical damage to the insulation shield, as well as to equalize the electric field in the cable. Over the protective winding is a metal screen made of copper wires, over which a copper tape or skein of copper wires are spirally applied. This metal screen protects against short circuit currents. Over the metal screen, a separation layer is applied, made in the form of a winding, consisting of at least one glass tape with an overlap of at least 30%. This separation layer is designed to prevent leakage of the material of the inner sheath between the wires. An inner shell made of a halogen-free polymer composition with an oxygen index of at least 47% is superimposed on top of the separation layer. The inner sheath serves to provide additional mechanical protection for the cable. A thermal barrier of copper or aluminum tape or two glass strips, superimposed with an overlap of at least 30%, is applied over the inner shell. This thermal barrier is designed to protect the cable. Over the thermal barrier, an outer shell is made of a halogen-free polymer composition with an oxygen index of at least 33%. The outer sheath is designed to protect the cable from the action of the external environment.

The inner and outer shells, as noted above, are made of halogen-free cable compositions characterized by an increased oxygen index. This increase is achieved by introducing flame retardants hydroxides into the starting polymer. Industrial application was obtained by aluminum hydroxides Al (OH) ₃ and magnesium Mg (OH) ₂ both synthetic and natural origin. The natural mineral of aluminum hydroxide is gibbsite, magnesium hydroxide is brucite. The mechanism of flame retardant action of hydroxides is to absorb a large amount of heat due to water with increasing temperature:

Heat absorption for Al (OH) ₃ is 1051 J / g, for Mg (OH) ₂ - 1316 J / g. The process of water loss for aluminum hydroxide begins at 200 ° C, and for Mg (OH) ₂ - at 340 ° C.

Since halogen-free polymers have an oxygen coefficient of the order of 20, in order to achieve the required higher values of this coefficient, about 150 wt. including filler - hydroxide per 100 wt. including polymer. In terms of volume fractions, the ratio will be as follows: the volume fraction of the polymer is 0.6, the volume fraction of the filler is 0.4, i.e. with a fairly uniform distribution of the filler, the continuous polymer phase will be maintained. At the same time, because of its high crystallinity, polyethylene cannot be used as a base polymer, since it cannot accept such a significant amount of filler. For this reason, the base polymer for industrial halogen-free compositions are ethylene copolymers: ethylene-vinyl acetate, ethylene-acrylate polymers, metallocene ethylene-octene copolymers and ethylene-propylene copolymers. In addition, since halogen-free compositions have a heterogeneous structure, their properties are a function of both composition and structure, i.e. depend on the nature of the surface of the filler. Thus, coating the surface of the filler with stearic acid gives an improvement in the mechanical and electrical insulating properties of the composition, the dispersion of the filler, and the shape of the size distribution curve of the filler particles.

The second version of the cable differs from the first in that it does not have a thermal barrier, while the outer sheath is superimposed on top of the inner sheath.

The third version of the cable differs from the first in that instead of a thermal barrier, an armor made of aluminum or aluminum alloy wires is superimposed on the inner shell, and the outer shell is superimposed on top of the armor.

The fourth version of the cable differs from the first in that it does not have a separation layer, while the inner sheath is superimposed on a metal screen.

The fifth version of the cable differs from the fourth version in that it does not have a thermal barrier, while the outer sheath is laid on top of the inner sheath.

The sixth version of the cable differs from the fourth version in that instead of a thermal barrier, an armor made of aluminum or aluminum alloy wires is applied to the inner shell, and the outer shell is applied over the armor.

The manufacture of the cable is as follows.

Conductors are made of wire, traditional for electric cables, the twisting of the cable elements is carried out on conventional twisting equipment. The application of extruded electrically conductive screens, insulation and their stitching is carried out on continuous vulcanization lines, and the application of the extruded inner shell and outer shell is carried out on extrusion equipment. The imposition of a metal screen and armor is carried out on the known twisting equipment, traditionally used in the cable industry.

The imposition of a winding from a tape of electrically conductive material, a separation layer made by a winding, a thermal barrier and armor consisting of metal tapes is carried out on winding machines used in the cable industry.

Samples of the proposed power cable were tested for smoke during combustion and smoldering in accordance with GOST R IEC 61034-2-2005 and for the corrosion activity of smoke and gas products during combustion and smoldering in accordance with GOST R IEC 60754-2-99.

Claims (8)

1. Power single-core cable with halogen-free sheaths that contains a conductive core, insulation of a conductive core, an inner sheath made of a halogen-free polymer composition with an oxygen index of at least 47%, and an outer sheath made of a polymer composition, halogen-free, with an oxygen index of at least 33%, characterized in that it contains a conductive core screen superimposed on a conductive core and comprising a layer of extruded electrically conductive crosslinked polymer a composition on top of which said conductive core insulation is made of cross-linked polyethylene, an insulation screen overlaid on a conductive core insulation and made of extruded electrically conductive cross-linked polymer composition, a protective winding made of an electrically conductive tape and overlaid on the insulation screen, as well as a metal screen made of copper wires and located on top of the protective winding. 2. The cable according to claim 1, in which the inner sheath is superimposed on top of a metal screen. 3. The cable according to claim 1, in which the outer sheath is superimposed on top of the inner sheath. 4. The cable according to claim 1, which contains a separation layer made in the form of a winding of glass tape and superimposed on a metal screen, and the inner sheath is superimposed on the specified separation layer. 5. The cable according to claim 1, in which the screen of the conductive core is made of two layers, wherein the first layer is made in the form of a synthetic conductive tape superimposed on the core, over which a second layer of extruded electrically conductive cross-linked polymer composition is applied. 6. The cable according to claim 1, which contains a thermal barrier overlaid on top of the inner shell and made of copper or aluminum tape or two glass tape, and on top of the specified thermal barrier, an outer sheath is applied. 7. The cable according to claim 1, which contains armor overlaid on top of the inner shell and made of aluminum or aluminum alloy wires, and an outer sheath is laid over said armor. 8. The cable according to claim 1, in which the metal shield is made of copper wires, over which a copper tape or skein of copper wires are spirally applied.