RU2759825C1 - Power sealed cable (options) - Google Patents

Abstract

FIELD: power cables.

SUBSTANCE: invention relates to power cables for alternating voltage 6-35 kV with a frequency of 50 Hz, single-core (first option) and three-core (second and third options), which are designed for the transmission and distribution of electrical energy in stationary electrical installations located in hazardous areas. In cables in a conductive core, which is made of copper wires twisted together, the interwire space is filled with a sealant based on butyl rubber and polybutene; in the construction of three-core cables, a profile sectional element is used, pre-made from a semiconducting compound on a polyolefin base, installed in the center of the cable, in sections of which, with total twisting, prepared insulated conductive conductors are laid, also in the construction of three-core cables, the interphase free space between the profile sectional element, the current-carrying conductors and the next layer in the cable is hermetically filled with a semiconducting compound based on a polyolefin base.

EFFECT: longitudinal propagation of explosive gas atmosphere along the cable is prevented in the cables.

36 cl, 5 dwg, 5 ex

Description

The technical solution claimed as an invention relates to the field of electrical engineering, namely to the structures of power cables for alternating voltage 6-35 kV with a frequency of 50 Hz, intended for the transmission and distribution of electrical energy in stationary electrical installations located in hazardous areas.

There are three different versions of the power cable, which meet the criterion of "unity of invention", tk. they describe objects of the same kind, intended for the same purposes and aimed at one technical result.

The developers of all three design options, differing from each other in the number of current-carrying conductors and the design of the crane, which performs the function of equalizing the electric field in the cable and the protective function during operating and emergency modes, was faced with the task of creating power cables with increased longitudinal tightness that meets the requirements for longitudinal tightness in accordance with with GOST 58342-2019.

Let's define the terms used in the description.

"Explosive zone" (see GOST R IEC 60079-0-2011. Explosive atmospheres. Part 0. Equipment. General requirements) - a part of an enclosed or open space in which an explosive atmosphere is present or may form in an amount that requires special protection measures when design, manufacture, installation and operation of equipment.

"Explosive atmosphere" (see GOST R IEC 60079-0-2011. Explosive atmospheres. Part 0. Equipment. General requirements) - a mixture with air, under atmospheric conditions, combustible substances in the form of gas, vapor, fog, dust, fibers or volatile particles, in which self-sustaining flame propagation occurs after ignition.

POWER SEALED CABLE (FIRST OPTION)

As a result of a patent information search, a technical solution was revealed (see RU 57958 U1, 01/17/2006) A SEALED, FIRE-RESISTANT CABLE, including: one or more conductive conductors with rubber insulation with an additional fire-resistant barrier in the form of a winding overlapped with one or two mica tapes sealed with a vulcanizing dielectric compound that fills all the voids under and between the tapes, as well as the overlap of the tapes; fillers for inter-wire, under-insulating and inter-core voids; rubber sheath; the overall cable shield is provided by introducing a thermal barrier with mica tapes in addition to the working electrical insulation. The known cable retains the ability to transmit electrical energy when exposed to a flame during a fire. Tightness can be ensured by filling all voids in the cable with special sealing compounds that have high adhesion to the structural elements of the cable.

The disadvantage of the known device is that in it the sealing is made between the structural elements of the cable, and the problem of sealing the space between the wires in the conductive cores has not been solved.

The technical result from the use of the proposed cable solution is the creation of a single-core cable, in which the longitudinal propagation of an explosive gas environment, suitable for use in explosive zones, is prevented.

The result is achieved due to the fact that there are no voids inside the cable through which explosive gases can spread, this is achieved using the following technical solutions:

- in the conductive core, which is made of copper wires twisted together, the inter-wire space is filled with a sealant based on butyl rubber and polybutene;

- the inner sheath is extruded with compression directly over the wire screen without the imposition of a separating layer, while the free space between the screen wires is filled with the material of the inner sheath made of a halogen-free composition or low fire hazard PVC compound.

The cable structure according to the first embodiment is shown in Fig. 1, where:

1 - conductive core;

2 - a semiconducting screen along a current-carrying conductor;

3 - insulation;

4 - semiconducting screen for insulation;

14 - damping layer;

10 - copper wire shield;

11 - inner sheath filling the gaps between the shield wires;

9 - outer shell.

CABLE DESCRIPTION

Power cable for voltage 6-35 kV inclusive, single-core, with a round conductive copper conductor, contains:

- a conductive core 1 made of copper wires, twisted together, in which a sealant based on butyl rubber and polybutene is applied over each inner layer, as a result of which the entire inter-wire space is filled with a sealant;

- three-layer insulation of conductive conductors made of a semiconducting screen along conductor 2, an insulation layer 3, a semiconducting screen on insulation 4, where the layers are applied by extrusion, while the second layer of three-layer insulation of a conductive conductor is made either from cross-linked polyethylene or from a compound based on polypropylene , or ethylene-propylene rubber;

- a damping layer 14 made of a semiconducting tape;

- copper wire shield 10;

- the inner sheath 11, extruded with compression directly over the wire screen without imposing a separating layer, while the free space between the wires of the screen is filled with the material of the inner sheath;

- the outer shell 9, which is made of polyvinyl chloride plastic compound of reduced fire hazard, or from a polymer composition that does not contain halogens.

The cable can be made on cable production equipment, which includes extrusion equipment.

Example 1

Power cable, designed for operation in hazardous areas, for voltage 35 kV with a round copper conductive core 1 with a cross section of 300 mm ² , made with an overlay of sealant wires based on butyl rubber and polybutene along each inner layer of wires, on top of which a semiconducting layer of polymer material is applied in layers. core 2, XLPE insulation 3, a semiconductive layer on the insulation made of polymeric material 4. A semiconductive tape 14 is placed on top of the winding, which performs a damping role. A copper wire screen is applied to the semiconducting tape with a copper tape spirally applied over it with a gap of 10, an inner sheath 11 is applied over the screen with a compression made of polyvinyl chloride plastic compound of reduced fire hazard. An outer shell 9 made of polyvinyl chloride plastic with reduced fire hazard is applied on top.

POWER SEALED CABLE (SECOND OPTION)

The sealed power cable (hereinafter referred to as the cable) is a three-core cable with a screen located over the twisted conductive cores.

When determining the "state of the art" for a given cable, we analyzed the features that affect the tightness of both conductive cores and the entire internal space of the cable.

As a result of the search, a technical solution was identified (see RU 57958 U1, 01/17/2006) SEALED, FIRE-RESISTANT CABLE, including: one or more conductive conductors with rubber insulation with an additional fire barrier in the form of a winding overlapped with one or two mica tapes, sealed with vulcanizing a dielectric compound that fills all the voids under and between the tapes, as well as the overlap areas of the tapes; fillers for inter-wire, under-insulating and inter-core voids; rubber sheath; the overall cable shield is provided by introducing a thermal barrier with mica tapes in addition to the working electrical insulation. The known cable retains the ability to transmit electrical energy when exposed to a flame during a fire. Tightness can be ensured by filling all voids in the cable with special sealing compounds that have high adhesion to the structural elements of the cable.

The disadvantage of the known device is that it is sealed between the structural elements of the cable, and the problem of sealing the space between the wires in the conductive cores has not been solved.

One of the known technical solutions for use in cables aimed at increasing the sealing is described in the patent (see ELECTRICAL CABLE, (19) RU, (11) 13847, (13) U1, (51) IPC H01B13 / 32).

This power cable contains insulated conductors twisted into a core, inner and outer sheaths. It is equipped with a central profile sectional element, in the sections of which conductive conductors covered with insulation are laid, while the central profile sectional element and insulation of conductive cores, the inner and outer shells are made of polymer materials.

The disadvantage of this cable is that it is not completely sealed.

The closest to the claimed is the POWER CABLE (OPTIONS) (19) RU (11) 89 755 (13) U1, (51) IPC H01B 9/00 (2006.01), where the power cable according to the first option contains conductive conductors covered with insulation, twisted into core, inner and outer sheaths.

The cable is equipped with a central profile sectional element, in the section of which conductive conductors covered with insulation are laid, while the central profile sectional element and insulation of conductive cores, the inner and outer sheaths are made of polymer materials, where the inner sheath can be made of a mixture of chalk-filled rubber, may additionally contain a shield of copper foil or copper tape over the inner sheath, while instead of a metal shield, the cable may contain armor of galvanized steel wires or two steel strips over the inner sheath.

The second version of the power cable contains conductive conductors covered with insulation, twisted into a core, inner and outer sheaths, equipped with a central profile sectional element, in the section of which conductive conductors covered with insulation are laid, while the central profile sectional element and conductive conductor insulation are made of polyvinyl chloride plastic compound of low fire hazard with an oxygen index of at least 30, the inner sheath is of low fire hazard PVC compound with an oxygen index of at least 28, and the outer sheath is of low fire hazard PVC compound with an oxygen index of at least 35. Additionally, the cable may contain a shield made of copper foil or copper tape, superimposed on top of the inner shell, also instead of a metal screen, it can contain armor of galvanized steel wires or two steel strips superimposed over the inner shell.

The third version of the power cable, containing insulated conductive cores twisted into a core, inner and outer sheaths, is equipped with a central profile sectional element, in the section of which conductive cores covered with insulation are laid, while the central profile sectional element and the insulation of conductive cores are made of a polymer composition, halogen-free, with an oxygen index of at least 30, the inner shell is made of a polymer composition that does not contain halogens, with an oxygen index of at least 40, and the outer shell is made of a polymer composition that does not contain halogens, with an oxygen index of at least 45. The power cable can additionally contain a shield of copper foil or copper tape applied over the inner sheath, and instead of a metal screen, it can contain armor made of galvanized steel wires or two steel strips, applied over the inner sheath.

The fourth version of the power cable, containing insulated conductive conductors twisted into a core, inner and outer sheaths, characterized in that it is equipped with a central profile sectional element, in the section of which conductive conductors covered with insulation are laid, while the insulation of conductive conductors is made of cross-linked polyethylene, the inner and outer shells are made of polyethylene, and the central sectional section is made of polyethylene or cross-linked polyethylene, or a block copolymer. The power cable can additionally contain a shield made of copper foil or copper tape, superimposed over the inner sheath. Also, instead of a metal shield, this cable may contain armor made of galvanized steel wires or two steel strips, superimposed over the inner sheath.

The disadvantage of this cable in all four versions is the lack of sealing of the conductive core. An explosive atmosphere will pass through the conductors - the cable will not meet the requirements specified in the regulatory documents for power cables for longitudinal tightness, which are mandatory for cables used in hazardous areas.

The designs of the inventive cable are shown in Fig. 2 and FIG. 3, where in FIG. 2 - a three-core cable with round conductors, FIG. 3 - three-core cable with sector conductors.

The following numbering of structural elements is used in cables:

1 - conductive core;

2 - semiconducting screen;

3 - insulation;

4 - semiconducting screen for insulation;

7 - profile sectional element;

8 - interphase filling;

10 - wire screen;

11 - inner sheath filling the screen wires

12 - a pillow for armor;

13 - armor;

9 - outer shell.

The technical result from the use of the proposed cable solution is the creation of a power cable suitable for use in hazardous areas.

The result is achieved due to the fact that there are no voids inside the cable through which explosive gases can spread, this is achieved using the following technical solutions:

- in the conductive core, which is made of copper wires twisted together, the space between the wires is filled with a sealant based on butyl rubber and polybutene;

- in the construction of the cable, a profiled sectional element is used, preliminarily made from a semiconducting compound on a polyolefin base, installed in the center of the cable, in the section of which prepared insulated conductive conductors are laid during general twisting;

- the interphase free space 8, available between the current-carrying conductors 1, the profile sectional element 7 and the copper wire screen 10, is hermetically filled with a semiconducting compound on a polyolefin basis;

- the inner sheath is extruded with compression directly over the wire screen without the imposition of a separating layer, while the free space between the screen wires is filled with the material of the inner sheath made of a halogen-free composition or low fire hazard PVC compound.

CABLE DESCRIPTION

Power cable for voltage 6-35 kV inclusive, three-core with conductive conductors of a round or sector shape, containing:

- conductive conductors 1, made of copper wires, twisted together, in which a sealant based on butyl rubber and polybutene is applied to each inner layer, as a result of which the entire inter-wire space is filled with a sealant;

- three-layer insulation of conductive conductors made of a semiconducting screen along conductor 2, an insulation layer 3, a semiconducting screen on insulation 4, where the layers are applied by extrusion, while the second layer of three-layer insulation of a conductive conductor is made either from cross-linked polyethylene or from a compound based on polypropylene , or ethylene-propylene rubber;

- profiled sectional element 7, pre-made from a semiconducting compound on a polyolefin base, the inner surfaces of which correspond to the shape and size of the conductive conductors inserted into them;

- interfacial filling 8, applied by extrusion, made of a halogen-free composition or polyvinyl chloride compound of reduced fire hazard;

- inner shell 11, which can be made either from polyvinyl chloride plastic compound of reduced fire hazard, or from a polymer composition that does not contain halogens;

- shield 10 in the form of copper wires;

- the outer shell 9, which is made of polyvinyl chloride plastic compound of reduced fire hazard, or from a polymer composition that does not contain halogens.

Also, the cable can contain armor 13 made of steel tape with a pillow under the armor 12.

The sequence of filling the cable from its center:

profile sectional element 7, in the sections of which prepared conductive conductors 1 are laid, covered with three-layer insulation (layers 2, 3, 4), followed by interphase filling 8, which occupies all the free space between the sections of the profile sectional element 7, insulated conductive conductors 1 and the inner sheath 11, then the inner sheath 11 is located, then follows the shield of copper wires 10, the space between which is filled with the inner sheath 11. Armor 13 made of steel tape can be installed in the cable structure. In this case, a pillow under the armor 12 is applied to the inner sheath 11. The outer sheath 9 is the outermost layer of the cable, which is applied by extrusion.

The inventive cable can be manufactured on equipment for cable production, which includes equipment for extrusion.

Example 2

Power cable, designed for operation in hazardous areas, for a voltage of 10 kV with round copper conductive conductors 1 with a cross section of 95 mm ² , made with the imposition of a sealant based on butyl rubber and polybutene on each inner layer, on top of each of these conductors a semiconducting polymer layer is applied material along the core 2, insulation made of ethylene-propylene rubber 3, a semi-conductive layer on insulation made of polymeric material 4. The insulated cores are twisted around a pre-fabricated profile sectional element 7 made of a semi-conductive compound on a polyolefin basis. An interfacial filling of a semiconducting compound on a polyolefin base 8 is applied to the twisted workpiece, while the shape of the profile sectional element allows the interfacial filling material to completely fill the internal voids, thereby ensuring the longitudinal tightness of the cable. A copper wire screen is applied over the interfacial filling with a copper tape spirally applied over it with a gap 10, an inner shell 11 filled with a polymer composition that does not contain halogens and a pillow for armor 12 made of the same material are applied over the screen. Above is applied armor 13 made of galvanized steel strips and an outer shell 9 made of a polymer composition that does not contain halogens.

Example 3

Power cable, designed for operation in hazardous areas, for a voltage of 20 kV with sector copper conductive conductors 1 with a section of 70 mm ² , made with the imposition of a sealant based on butyl rubber and polybutene on each inner layer, on top of each of which a semiconducting layer of polymer material is applied along conductor 2, insulation made of ethylene-propylene rubber 3, semi-conductive layer on insulation made of polymeric material 4. Insulated conductors are twisted around a pre-extruded sectional element 7 made of a polyolefin-based semiconducting compound. An intersectional filling of a semiconducting compound on a polyolefin base 8 is applied to the twisted workpiece, while the shape of the profile core allows the interfacial filling material to completely fill the internal voids, thereby ensuring longitudinal tightness. On top of the interfacial filling, a copper wire screen is applied with a copper tape spirally applied over it with a gap of 10, and an inner shell 11 is applied over the screen with a filling made of polyvinyl chloride plastic compound of reduced fire hazard. An outer shell 9 made of polyvinyl chloride plastic with reduced fire hazard is applied on top.

POWER SEALED CABLE (THIRD OPTION)

A sealed power cable (hereinafter referred to as a cable) is a three-core cable with a screen in the form of a combination of a conductor located in the center of the cable inside a profile sectional element, and copper foil windings superimposed on conductive insulated conductors.

Multilevel cable protection against longitudinal propagation of explosive gases through its cross-section consists of sealing the space between the wires of current-carrying conductors, creating a barrier impenetrable for explosive gases between twisted conductive conductors and structural elements of the cable screen.

When determining the "state of the art" for a given cable, we analyzed the features that ensure the tightness of both the conductive cores and the entire internal space of the cable.

As a result of the search, a technical solution was revealed (see RU 57958 U1, 01/17/2006) a sealed, fire-resistant cable, including: one or more conductive cores with rubber insulation with an additional fire-resistant barrier in the form of a winding overlapped with one or two mica tapes, sealed with vulcanizing a dielectric compound that fills all the voids under and between the tapes, as well as the overlap areas of the tapes; fillers for inter-wire, under-insulating and inter-core voids; rubber sheath; the overall cable shield is provided by introducing a thermal barrier with mica tapes in addition to the working electrical insulation. The known cable retains the ability to transmit electrical energy when exposed to a flame during a fire. Tightness can be ensured by filling all voids in the cable with special sealing compounds that have high adhesion to the structural elements of the cable.

The disadvantage of the known device is that the problem of sealing the connection of the wires in the conductive core has not been solved. It is sealed between the structural elements of the cable.

One of the known technical solutions for use in cables aimed at increasing the sealing is described in the patent (see ELECTRICAL CABLE, (19) RU, (11) 13847, (13) U1, (51) IPC H01B13 / 32).

This power cable contains insulated conductors twisted into a core, inner and outer sheaths. It is equipped with a central profile sectional element, in the sections of which conductive conductors covered with insulation are laid, while the central profile sectional element and insulation of conductive cores, the inner and outer shells are made of polymer materials.

The disadvantage of this cable is that it is not completely sealed.

The closest to the claimed is the POWER CABLE (OPTIONS) (19) RU (11) 89 755 (13) U1, (51) IPC H01B 9/00 (2006.01), where the power cable according to the first option contains conductive conductors covered with insulation, twisted into core, inner and outer sheaths.

The cable is equipped with a central profile sectional element, in the section of which conductive conductors covered with insulation are laid, while the central profile sectional element and insulation of conductive cores, the inner and outer sheaths are made of polymer materials, where the inner sheath can be made of a mixture of chalk-filled rubber, may additionally contain a shield of copper foil or copper tape over the inner sheath, while instead of a metal shield, the cable may contain armor of galvanized steel wires or two steel strips over the inner sheath.

The second version of the power cable contains conductive conductors covered with insulation, twisted into a core, inner and outer sheaths, equipped with a central profile sectional element, in the section of which conductive conductors covered with insulation are laid, while the central profile sectional element and conductive conductor insulation are made of polyvinyl chloride plastic compound of low fire hazard with an oxygen index of at least 30, the inner sheath is of low fire hazard PVC compound with an oxygen index of at least 28, and the outer sheath is of low fire hazard PVC compound with an oxygen index of at least 35. Additionally, the cable may contain a shield made of copper foil or copper tape, superimposed on top of the inner shell, also instead of a metal screen, it can contain armor of galvanized steel wires or two steel strips superimposed over the inner shell.

The third version of the power cable, containing insulated conductive cores twisted into a core, inner and outer sheaths, is equipped with a central profile sectional element, in the section of which conductive cores covered with insulation are laid, while the central profile sectional element and the insulation of conductive cores are made of a polymer composition, halogen-free, with an oxygen index of at least 30, the inner shell is made of a polymer composition that does not contain halogens, with an oxygen index of at least 40, and the outer shell is made of a polymer composition that does not contain halogens, with an oxygen index of at least 45. The power cable can additionally contain a shield of copper foil or copper tape applied over the inner sheath, and instead of a metal screen, it can contain armor made of galvanized steel wires or two steel strips, applied over the inner sheath.

The fourth version of the power cable, containing insulated conductive conductors twisted into a core, inner and outer sheaths, characterized in that it is equipped with a central profile sectional element, in the section of which conductive conductors covered with insulation are laid, while the insulation of conductive conductors is made of cross-linked polyethylene, the inner and outer shells are made of polyethylene, and the central sectional section is made of polyethylene or cross-linked polyethylene, or a block copolymer. The power cable can additionally contain a shield made of copper foil or copper tape, superimposed over the inner sheath. Also, instead of a metal shield, this cable may contain armor made of galvanized steel wires or two steel strips, superimposed over the inner sheath.

The disadvantage of this cable in all four versions is the lack of sealing of the conductive core. An explosive atmosphere will pass through the conductors - the cable will not meet the requirements specified in the regulatory documents for power cables for longitudinal tightness, which are mandatory for cables used in hazardous areas.

The designs of the inventive cable are shown in Fig. 4 and FIG. 5, where in FIG. 4 - a three-core cable with round conductors, FIG. 5 - three-core cable with sector cores.

The following numbering of structural elements is used in cables:

1 - conductive core,

2 - a semiconducting screen for a current-carrying conductor,

3 - insulation,

4 - semiconducting screen for insulation,

5 - copper foil tape wrapping,

6 - a conductor in a profile core, acting as a screen,

7 - profile sectional element,

8 - interfacial filling (applied by extrusion),

9 - outer shell (applied by extrusion).

The technical result of the proposed cable solution is the creation of a power cable suitable for use in hazardous areas.

The result is achieved due to the fact that there are no voids inside the cable through which explosive gases can spread, this is achieved using a combination of the following technical solutions:

- in the conductive core, which is made of copper wires twisted together, the space between the wires is filled with a sealant based on butyl rubber and polybutene;

- the design uses a pre-fabricated sectional element 7 made of a semiconducting compound on a polyolefin base, with a conductor 6 located in the center of this element (preferably copper), which, together with the copper foil of the winding of insulated conductors, acts as a screen.

Prepared insulated conductive conductors are laid in the section of the profile sectional element. The shape of the profile sectional element 7 almost completely repeats the shape of a conductive core with three-layer insulation;

- the interfacial free space 8, which is available between the current-carrying conductors 1, the profile sectional element 7 and the outer sheath 9, is hermetically filled with either a material made of a halogen-free composition or a low fire hazard PVC compound by extrusion under pressure;

- the role of the screen is performed by a set of elements consisting of a conductor 6 passing inside the profile sectional element 7 and copper windings 5 made along insulated conductive conductors located after the semiconducting screen along insulation 4.

CABLE DESCRIPTION

Power cable for voltage 6-35 kV inclusive, three-core with conductive conductors of a round or sector shape, containing:

- conductive cores 1, made of copper wires, twisted together, in which a sealant is applied over each inner strand, as a result of which the entire inter-wire space is filled with a sealant based on butyl rubber and polybutene;

- three-layer insulation of conductive conductors made of a semiconducting screen along conductor 2, an insulation layer 3, a semiconducting screen on insulation 4, where the layers are applied by extrusion, while the second layer of three-layer insulation of a conductive conductor is made either from cross-linked polyethylene or from a compound based on polypropylene , or ethylene-propylene rubber;

- windings 5 of copper foil, located after the semiconducting screen along the insulation 4;

- profiled sectional element 7, pre-made from a semiconducting compound on a polyolefin base, through the center of which passes - conductor 6, in conjunction with windings 5 performing the role of a screen. The inner surfaces of the profiled sectional element correspond to the shape and dimensions of the conductive conductors inserted into them;

- interfacial filling 8, applied by extrusion, made of a halogen-free composition or a polyvinyl chloride compound with a reduced fire hazard;

- outer shell 9 made of halogen-free composition or polyvinyl chloride plasticate of reduced fire hazard.

Sequence of filling the cable from its center

Conductor 6, located inside the profile sectional element 7, in the sections of which prepared conductive conductors 1 are laid, covered with three-layer insulation (layers 2, 3, 4), on top of which there is a winding 5 made of copper foil tapes, then interphase filling 8 follows, occupying all the free space between the sections of the profile sectional element 7, the insulated conductors 1 and the outer sheath 9, which is applied by extrusion.

The inventive cable can be manufactured on equipment for cable production, which includes equipment for extrusion.

Example 4

Power cable, designed for operation in hazardous areas, for a voltage of 10 kV with round copper conductive conductors 1 with a section of 120 mm ² , made with the imposition of a sealant based on butyl rubber and polybutene on each inner layer, on top of each of which a semiconducting layer 2 of polymer is applied in layers material on core 1, insulation 3 made of XLPE, semi-conductive layer 4 on insulation made of polymer material, winding with copper foil 5. Insulated and wound cores are twisted around a pre-pressed profile sectional element 7, made of a semiconducting compound on a polyolefin base, with a copper conductor 6 with a cross section of 25 mm2, acting as a screen in conjunction with a copper foil of a winding of insulated conductors 5. An interphase filling made of PVC o filling completely fill the internal voids, thereby ensuring longitudinal tightness. On top of the interfacial filling, an outer 9 made of polyvinylchloride plastic with a reduced fire hazard is applied.

Example 5

Power cable, designed for operation in hazardous areas, for a voltage of 6 kV with sector copper conductors 1 with a section of 185 mm2, made with the imposition of a sealant based on butyl rubber and polybutene on each inner layer, on top of each of which a semiconducting layer of polymer material is applied in layers core 2, XLPE insulation 3, a semi-conductive layer on the insulation made of polymeric material 4, winding with copper foil 5. Insulated and wound cores are twisted around a pre-extruded profile core 7 made of a polyolefin-based semiconducting compound with a copper conductor 6 with a cross section located inside 35 mm ² , acting as a screen in conjunction with a copper foil of the winding of insulated conductors 5. An interphase filling made of a polymer composition that does not contain halogens 8 is applied to the twisted workpiece, while the shape of the profile core allows the interfacial filling material to be completely filled. fill the internal voids, thereby ensuring longitudinal tightness. On top of the interfacial filling, an outer 9 made of a halogen-free polymer composition is applied.

Claims (36)

1. Power cable for a voltage of 6-35 kV inclusive, with a conductive conductor of a round shape, containing: one conductive conductor, three-layer insulation of a conductive conductor, a damping layer, a screen of metal wires, an inner and outer sheath, characterized in that the interwire space in the conductive the core, which is made of copper wires, twisted together, filled with a sealant based on butyl rubber and polybutene; a semi-conductive screen along a conductive core, insulation, a semi-conductive screen along the insulation are applied by extrusion; the cable shield is made of wires and is located over the damping layer, and the free space between the shield wires, as a result of the operation of applying the inner sheath with cable compression, is filled with the material of the inner sheath. 2. The cable according to claim 1, characterized in that the sealant in the conductive core is applied to each inner layer. 3. Cable according to claim 1, characterized in that the second layer of three-layer insulation of the conductive core is made of cross-linked polyethylene. 4. Cable according to claim 1, characterized in that the second layer of the three-layer conductive core is made of a polypropylene-based compound. 5. Cable according to claim 1, characterized in that the second layer of three-layer insulation of the conductive core is made of ethylene-propylene rubber. 6. The cable according to claim 1, characterized in that its inner sheath is made of polyvinyl chloride plastic compound of low fire hazard. 7. Cable according to claim 1, characterized in that its inner sheath is made of a halogen-free polymer composition. 8. Cable according to claim 1, characterized in that its outer sheath is made of polyvinylchloride plastic compound of low fire hazard. 9. Cable according to claim 1, characterized in that its outer sheath is made of a halogen-free polymer composition. 10. Cable according to claim 1, characterized in that the damping layer is made of a semiconducting tape. 11. Cable according to claim 1, characterized in that the shield wires are made of copper. 12. Power cable for a voltage of 6-35 kV inclusive, with conductive conductors of a round or sector shape, containing three conductive conductors covered with insulation, a profile sectional element, in the sections of which conductive conductors are laid, having three-layer insulation, a screen, an inner and outer sheath, which is different the fact that the profile sectional element is made of a semiconducting compound on a polyolefin basis; the space between the wires in the conductive core, which is made of copper wires twisted together, is filled with a sealant based on butyl rubber and polybutene; the interphase filling of the free space between the inner surface of the profile sectional element, the insulated conductive core and the inner sheath, made by the extrusion method has been added to the cable; the cable shield is made of copper wires and is located over the interphase filling, and the free space between the shield wires, as a result of the operation of applying the inner sheath with cable compression, is filled with the material of the inner sheath; the inner shell is made by extrusion. 13. A cable according to claim 12, characterized in that the sealant in the conductive core is applied to each inner layer. 14. Cable according to claim 12, characterized in that the three-layer insulation of the conductive cores consists of a first insulation layer made of a semiconducting material, a second layer of an insulating material, a third layer of a semiconducting material applied over the insulation. 15. Cable according to claim 12, characterized in that the second layer of three-layer insulation of the conductive core is made of cross-linked polyethylene. 16. Cable according to claim 12, characterized in that the second layer of the three-layer conductive core is made of a polypropylene-based compound. 17. Cable according to claim 12, characterized in that the second layer of three-layer insulation of the conductive core is made of ethylene-propylene rubber. 18. Cable according to claim 12, characterized in that the interfacial filling is made of a polyolefin-based semiconducting compound. 19. Cable according to claim 12, characterized in that the interphase filling is made of a semiconducting compound based on synthetic rubber. 20. Cable according to claim 12, characterized in that its inner sheath is made of polyvinylchloride plastic compound of low fire hazard. 21. Cable according to claim 12, characterized in that its inner sheath is made of a halogen-free polymer composition. 22. A cable according to claim 12, characterized in that its outer sheath is made of polyvinyl chloride plastic compound of low fire hazard. 23. Cable according to claim 12, characterized in that its outer sheath is made of a halogen-free polymer composition. 24. Cable according to claim 12, characterized in that the wires for the screen are made of copper. 25. A cable according to claim 12, characterized in that in front of the outer sheath there is a cushion for the armor and the armor. 26. Power cable for a voltage of 6-35 kV inclusive, with conductive conductors of a round or sector shape, containing three conductive conductors covered with insulation, a profile sectional element, in the sections of which conductive conductors are laid, having three-layer insulation, an inner sheath, an outer sheath, characterized by that the profiled sectional element is made of a polyolefin-based semiconducting compound with a conductor located inside; the space between the wires in the conductive core, which is made of copper wires twisted together, is filled with a sealant based on butyl rubber and polybutene; the interphase filling of the free space between the inner surface of the profile sectional element, the insulated conductive core and the inner sheath, made by the extrusion method has been added to the cable; the cable shield is made of a combination of a conductor inside a profile sectional element and windings in the form of copper foil strips superimposed over the insulation of current-carrying conductors, the outer sheath is made by extrusion. 27. A cable according to claim 26, characterized in that the sealant in the conductive core is applied to each internal strand. 28. The cable according to claim 26, characterized in that the three-layer insulation of the conductive cores consists of a first insulation layer made of a semiconducting material, a second layer of an insulating material, a third layer of a semiconducting material applied over the insulation. 29. Cable according to claim 26, characterized in that the second layer of three-layer insulation of the conductive core is made of cross-linked polyethylene. 30. Cable according to claim 26, characterized in that the second layer of three-layer insulation of the conductive core is made of a polypropylene-based compound. 31. Cable according to claim 26, characterized in that the second layer of three-layer insulation of the conductive core is made of ethylene-propylene rubber. 32. Cable according to claim 26, characterized in that the interphase filling is made of polyvinylchloride plastic compound of reduced fire hazard. 33. Cable according to claim 26, characterized in that the interfacial filling is made of a halogen-free polymer composition. 34. A cable according to claim 26, characterized in that in front of the outer sheath there is a cushion for the armor and the armor. 35. The cable according to claim 26, characterized in that its outer sheath is made of polyvinyl chloride plastic compound of reduced fire hazard. 36. Cable according to claim 26, characterized in that its outer sheath is made of a halogen-free polymer composition.

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