RU201420U1 - Power cable - Google Patents

Abstract

(57) The utility model relates to power cables for a voltage of 6–20 kV. The cable contains three conductive cores 1, on top of each of which the first electrically conductive layer 2 is sequentially applied, insulation consisting of glass-mica tapes 3 and a cross-linked polyethylene composition 4, a second electrically conductive layer 5, a separating layer 6, a metal shield 7, while the shielded conductors are twisted into a core over which the inner sheath 10 and the outer sheath 13 are sequentially superimposed. Technical result: ensuring high fire-safe and operational characteristics of the power cable, including functioning in case of fire under conditions of exposure to an open flame. 19 p.p. f-ly, 1 dwg

Description

The technical field to which the utility model belongs

The utility model relates to the field of electrical engineering, namely to the structures of power cables for transmission and distribution of electrical energy in stationary electrical installations for voltages from 6 to 20 kV inclusive.

State of the art

As the closest analogue, a well-known power cable was selected containing three round copper conductive cores, on top of each of which a first electrically conductive layer is sequentially applied by winding of at least one electrically conductive tape, at least four glass-mica tapes, each with overlapping winding, extruded insulation made of a cross-linked polyethylene composition, a second polymeric electrically conductive layer, wrapping with a tape made of an electrically conductive material, a metal shield made of copper wires fastened with a helically applied copper tape or a frame of copper wires, while the shielded cores are twisted into a common core around the central filling, and over a common core interphase filling and an extruded outer shell are successively applied (RF utility model No. 102424). This well-known cable is intended for the transmission and distribution of electrical energy in networks with a nominal voltage of 6 and 10 kV with a nominal frequency of 50 Hz, including at nuclear facilities in networks that must maintain their operability when exposed to an open flame, for example, in the case of the occurrence of a fire. The disadvantage of the design of this known cable is that the level of dielectric losses arising in the cable insulation system is increased in comparison with traditional cables according to GOST R 55025, due to the use of a large number of glass-mica tapes, which may, among other things, lead to a reduction in the service life of the known cable. Also, the disadvantage of the known cable design, which retains its operability under conditions of exposure to a flame with a temperature of at least 750 ° C on equipment in accordance with GOST R IEC 60331-11, which does not provide for testing simultaneously with mechanical shock, is the low electric strength of the cable under conditions of exposure to an open flame with a temperature of at least 1000 ° С simultaneously with mechanical shocks when the rated load current flows. The specified set of influences most fully reflects the real conditions of the fire and is the main criterion for the fire resistance of the cable for circuits, which are required to function in case of fire.

The essence of the utility model

The problem to be solved by the utility model is to develop a three-core power cable capable of operating in an open flame with a temperature of at least 1000 ° C simultaneously with mechanical shocks when applying the rated operating voltage and flowing the rated load current, while having increased technical and operational characteristics in comparison with the known analogue.

This utility model ensures the achievement of the following technical result: ensuring high fireproof and operational characteristics of the power cable, including the operation of the cable under conditions of exposure to flame simultaneously with mechanical shock for at least 120 minutes.

The technical result is achieved by the fact that the power cable contains three conductive cores, on top of each of which the first electrically conductive layer, insulation, the second electrically conductive layer, a separating layer, a metal screen, the said shielded conductors are twisted into a core over which an inner sheath and an outer sheath are sequentially applied , wherein said insulation of each core contains two layers, one of which is made of at least two glass-mica-containing tapes with an areal density of mica paper of at least 120 g / m ² for each tape, with the tapes being wrapped with each overlapping winding, and the other layer is a cross-linked polyethylene composition with a thickness of at least 2.15 mm.

The specified technical result is also achieved by the fact that the dielectric strength of each glass-mica tape is not less than 1.4 kV.

The specified technical result is also achieved by the fact that glass-mica-containing tapes can be composed of two successively superimposed layers of mica papers with a total density of the indicated layers of at least 300 g / m ² .

The specified technical result is also achieved by the fact that glass mica tapes contain an organosilicon binder in an amount of at least 25 g / m ² .

The specified technical result is also achieved by the fact that the metal shield is made of copper wires fastened with a copper tape or frame of copper wires or a bonding polymer tape, or copper tapes.

The specified technical result is also achieved in that the first electrically conductive layer is made of at least one tape of electrically conductive paper or electrically conductive glass tape or electrically conductive polymer or synthetic tape.

The specified technical result is also achieved by the fact that the second electrically conductive layer is made of a cross-linked polymer composition. In this case, the second electrically conductive layer can have adhesion to the insulation, characterized by the magnitude of the peel force from the insulation in the range from 0.35 N to 20 N, per 10 mm of the width of the electrically conductive screen.

The specified technical result is also achieved in that the separating layer is made of at least one electrically conductive tape or electrically conductive glass tape.

The specified technical result is also achieved by the fact that the shielded cores are twisted around a central filling made of polymer or fibrous material.

The specified technical result is also achieved by the fact that a fastening tape with a gap is additionally applied over the screened cores twisted into a core.

The specified technical result is also achieved by the fact that a cushion under the armor made of polymeric material is additionally applied over the inner shell.

This technical result is also achieved by the fact that over the inner shell or over the cushion under the armor there is an armor in the form of a winding of metal strips or in the form of spirally applied metal wires.

The specified technical result is also achieved by the fact that the inner shell is made of polyvinyl chloride plastic compound of reduced fire hazard with low smoke and gas emission or from a polymer composition that does not contain halogens.

The specified technical result is also achieved by the fact that the cushion under the armor is made of polyvinyl chloride plastic compound of reduced fire hazard with low smoke and gas emission or from a polymer composition that does not contain halogens.

The specified technical result is also achieved by the fact that the outer shell is made of polyvinyl chloride plastic compound of reduced fire hazard with low smoke and gas emission or from a polymer composition that does not contain halogens.

A distinctive feature of this utility model is the provision of high fireproof and operational characteristics of the power cable, including the operation of the cable under conditions of exposure to flame simultaneously with mechanical shocks for at least 120 minutes.

List of drawing figures

Figure 1 shows a cross-section of the cable.

Implementation of the utility model

The modern set of fire safety requirements for cable lines, including those intended for nuclear facilities, provides for their operation in emergency operation modes, which is due to the need for equipment to ensure the safety of the facility in the event of a fire.

One of the main requirements for electrical cables that ensure the safety of the facility and the operation of equipment in case of fire is to maintain their performance under conditions of exposure to an open flame.

In the event of a fire and the further spread of the flame, such cables must function for a specified period of time required to take and implement the required set of measures. At the same time, the conditions that most fully simulate the processes during real fires are the conditions reproduced on the equipment according to GOST IEC 60331-1, in which exposure to an open flame with a temperature of at least 1000 ° C is simultaneously accompanied by mechanical shock effects that simulate shock loads on the laid cable products, when the rated operating voltage is applied and the rated load current flows.

The technical solutions existing in the world practice for medium voltage fire-resistant cables do not fully ensure the functioning of cables in conditions of such impacts. At the same time, one of the main technical solutions for these cables is the use of glass-mica-containing tapes as part of the insulating system, which, depending on the properties of the tapes, their number and location, along with an increase in fire safety characteristics, can lead to a deterioration in the operational properties of the cable in normal modes. exploitation.

The present utility model is based on an optimal combination of glass-mica-containing tapes and polymer insulation, which together form a two-layer insulating system that ensures the reliability of power supply in normal operation during the specified service life by reducing the level of dielectric losses, as well as maintaining functioning under conditions of exposure to flame.

An important indicator for the applicability of a particular type of glass-mica tape is the surface density of mica paper, which provides the required electrical strength when exposed to a flame with a temperature of at least 1000 ° C simultaneously with mechanical shocks when testing a sample both in a straightened state and bent to the minimum permissible bending radius, at equipment in accordance with GOST IEC 60331-1 with the application of the rated operating voltage and the flow of the rated load current. At the same time, this technical solution makes it possible to ensure not only the preservation of the operability of the three-core cable as a whole, but also the functioning of each shielded core during their tests both with the outer covers of the cable removed and each shielded core separately under the conditions indicated above.

The power cable contains three conductive cores 1, on top of each of which the first electrically conductive layer 2 is sequentially applied, insulation consisting of a layer of at least two glass mica tapes 3 with an areal density of mica paper of at least 120 g / m ² for each tape and a layer of a cross-linked polyethylene composition 4 with a thickness of at least 2.15 mm, a second electrically conductive layer 5, a separating layer 6, a metal shield 7, while the shielded cores are twisted into a core over which the inner sheath 10 and the outer sheath 13 are sequentially applied.

The inner sheath can be applied with interphase filling to provide a nearly round cable. For this purpose, the inner casing can also be made of chalk-filled uncured rubber compound.

Glass-mica tapes 3 are superimposed by winding with overlapping, for example, not less than 30% each, and have a dielectric strength, determined in accordance with GOST 6433.3, for each tape not less than 1.4 kV.

To increase the level of breakdown voltage, glass-mica tapes can have two successively superimposed layers of mica papers with a total density of the indicated layers of at least 300 g / m ² and have an electrical strength of at least 4.2 kV.

Glass mica tapes may contain an organosilicon binder in an amount of at least 25 g / m ² .

The first electrically conductive layer 2 can be made of at least one tape of electrically conductive paper or electrically conductive glass tape or an electrically conductive polymer or synthetic tape.

The second electrically conductive layer 5 can be made of a crosslinked polymer composition. In this case, to facilitate the installation of the cable, the second electrically conductive layer can have an adhesion to the insulation characterized by a pull-off force in the range of 0.35 N to 20 N per 10 mm of the width of the electrically conductive screen.

The separating layer 6 can be made of at least one electrically conductive tape or an electrically conductive glass tape.

The metal shield can be made of copper wires, held together by copper tape or a frame of copper wires or bonding polymer tape, or copper tapes.

The shielded conductors can be twisted around a central filling 8 made of polymer or fibrous material.

To increase the stability of the core during the manufacture of the cable, a fastening, for example, polymer tape 9 with a winding with a gap can be additionally applied over the twisted conductive cores.

To protect against external mechanical influences during installation and during operation, armor 12 can be placed over the inner shell in the form of a winding made of metal strips or in the form of spirally applied metal wires. In this case, on top of the inner shell under the armor, an additional cushion under the armor 11 made of polymer material can be applied.

To ensure the resistance of the cable to non-propagation of combustion during group laying during tests in accordance with GOST IEC 60332-3-22, the requirement for smoke generation during tests in accordance with GOST IEC 61034-2, the inner sheath, cushion for armor and the outer sheath of the cable can be made of PVC compound with reduced fire hazard with low smoke and gas emission, with reduced emission of hydrogen chloride, determined during tests according to GOST IEC 60754-1. In addition to the specified properties to reduce the corrosiveness indicators of smoke and gas products, determined during tests in accordance with GOST IEC 60754-1 and GOST IEC 60754-2, the inner sheath, cushion under the armor and the outer sheath of the cable can be made of a polymer composition, not containing halogens.

The following is information confirming the possibility of implementing the utility model.

The conductive core 1, which can be either single-wire or multi-wire, is made of copper rod or wire, traditional for electrical cables.

The tapes for the electrically conductive layer 2, the glass-mica tapes 3, the separating layer 6, the metal screen 7 and the fastening tape 9 are applied using standard twisting equipment.

Armor 12 is applied on armored vehicles traditionally used in the cable industry.

Used for the manufacture of the cable polymer materials for insulation 4, electrically conductive screen 5, inner sheath 10, cushion for armor 11 and outer sheath 13 are produced industrially.

In the manufacture of cables for the application of polymeric materials, traditional extrusion equipment used in the cable industry is used.

Claims (20)

1. Power cable containing three conductive cores, on top of each of which a first electrically conductive layer, insulation, a second electrically conductive layer, a separating layer, a metal screen, shielded conductors are twisted into a core, on top of which an inner sheath and an outer sheath are sequentially applied, while said insulation of each core contains at least two layers, one of which is made of at least two glass-mica-containing tapes with an areal density of mica paper of at least 120 g / m ² for each tape, with the tapes being wrapped with each overlap and the other layer is a cross-linked polyethylene composition with a thickness of at least 2.15 mm. 2. A cable according to claim 1, characterized in that the dielectric strength of each glass-mica tape is not less than 1.4 kV. 3. A cable according to claim 1, characterized in that the glass-mica-containing tapes may include two successively superimposed layers of mica papers with a total density of the indicated layers of at least 300 g / m ² . 4. Cable according to claim 1, characterized in that the glass-mica tapes contain an organosilicon binder in an amount of at least 25 g / m ² . 5. A cable according to claim 1, characterized in that the first electrically conductive layer is made of at least one tape of electrically conductive paper, or electrically conductive glass tape, or electrically conductive polymer or synthetic tape. 6. A cable according to claim 1, characterized in that the second electrically conductive layer is made of a cross-linked polymer composition . 7. A cable according to claim 6, characterized in that the second electrically conductive layer has adhesion to insulation characterized by a pull-off force in the range from 0.35 N to 20 N per 10 mm of the conductive screen width. 8. Cable according to claim. 1, characterized in that the separating layer is made of at least one electrically conductive tape or electrically conductive glass tape. 9. A cable according to claim 1, characterized in that the metal shield is made of copper wires fastened with a copper tape, or a frame of copper wires, or a bonding polymer tape, or of copper tapes. 10. A cable according to claim 1, characterized in that the shielded cores are twisted around a central filling made of polymer or fibrous material. 11. A cable according to claim 1, characterized in that a fastening tape with a gap is additionally applied over the shielded cores twisted into a core. 12. The cable according to claim 1, characterized in that a cushion under the armor made of polymer material is additionally applied over the inner shell. 13. A cable according to claim 1, characterized in that armor is located on top of the inner sheath in the form of a winding of metal strips or in the form of spirally applied metal wires. 14. A cable according to claim 12, characterized in that armor is located over the cushion under the armor in the form of a winding of metal strips or in the form of spirally applied metal wires. 15. Cable according to claim. 1, characterized in that the inner sheath is made of polyvinyl chloride plastic compound of low fire hazard with low smoke and gas emission. 16. A cable according to claim 1, characterized in that the inner sheath is made of a halogen-free polymer composition. 17. Cable according to claim 12, characterized in that the inner sheath is made of polyvinyl chloride plastic compound of low fire hazard with low smoke and gas emission. 18. Cable according to claim 12, characterized in that the inner sheath is made of a halogen-free polymer composition. 19. Cable according to any one of paragraphs. 1-18, characterized in that the outer casing is made of polyvinyl chloride plastic compound of reduced fire hazard with low smoke and gas emission. 20. Cable according to any one of paragraphs. 1, 14, 16, 18, characterized in that the outer shell is made of a halogen-free polymer composition.

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