RU185477U1 - POWER CABLE, FIRE RESISTANT FOR SHOCK LOADS - Google Patents

Abstract

The utility model relates to cable technology, namely, to designs of power cables with insulation from a halogen-free polyolefin composition, or from a halogen-free cross-linked polyolefin composition, or from cross-linked polyethylene, an inner and outer sheath of a halogen-free polyolefin composition, designed for the transmission and distribution of electrical energy in stationary electrical installations with an alternating voltage of 0.66, 1.0, 3.0 kV with a frequency of 50 Hz at an ambient temperature of min mustache 65 ° C to plus 60 ° C and relative humidity up to 98% at a temperature of plus 35 ° C.

The technical problem of the utility model is the development of the design of a fire-resistant power cable, designed for a voltage of 0.66, 1.0, and 3.0 kV and maintaining operability not only when exposed to a flame, but also with a mechanical shock for at least 60 minutes.

The technical result consists in increasing the fire resistance of the cable under shock loads.

The technical result is achieved by the fact that the power flame-retardant cable under shock loads, containing at least one copper conductive core, insulation, inner and outer sheath of polymer compositions not containing halogens, not containing halogens with a tensile strength at break of 25 ° C of at least 15 MPa , at 80 ° С not less than 5 MPa, the maximum average value of the heat release rate is not more than 150 kW / m ² , the smoke emission intensity is not more than 0.20 m ² / s. 9. s.p. f-ly; 1 ill.

Description

The utility model relates to cable technology, namely, to designs of power cables with insulation from a halogen-free polyolefin composition or from a halogen-free cross-linked polyolefin composition or from cross-linked polyethylene, an inner and outer sheath of a halogen-free polyolefin composition intended for transmission and distribution of electrical energy in stationary electrical installations at an alternating voltage of 0.66, 1.0, 3.0 kV with a frequency of 50 Hz at an ambient temperature of min from 65 ° C to plus 60 ° C and relative humidity of 98% at a temperature of 35 ° C.

Fire-resistant power cables for voltage of 0.66 and 1 kV are known according to the patent of the Russian Federation for utility model No. 174055 (dated May 19, 2017 publ. September 28, 2017) and the patent of the Russian Federation for utility model No. 139485 (from 08/09/2013 publ. 04/20/2014) ,

The disadvantage of the cables according to patent No. 174055 and patent No. 139485 is that the cables are not fire resistant under shock loads, i.e. they do not provide sufficient protection against mechanical stress during a fire, which can be extremely intense and to which the power cable may be exposed during rescue operations following a fire. The fire test under shock loads is regulated by GOST IEC 60331-1-2013.

The technical problem of the utility model is the development of the design of a fire-resistant power cable, designed for a voltage of 0.66, 1.0, and 3.0 kV and maintaining operability not only when exposed to a flame, but also with a mechanical shock for at least 60 minutes.

The technical result consists in increasing the fire resistance of the cable under shock loads.

The technical result is achieved by the fact that the power flame-retardant cable under impact loads, containing at least one copper conductive core, insulation, an inner and outer sheath of halogen-free polymer compositions, the outer sheath is made of a halogen-free polyolefin composition with tensile strength at 25 ° С not less than 15 MPa, at 80 ° С not less than 5 MPa, with a maximum average heat release rate of not more than 150 kW / m ² , smoke emission intensity of not more than 0.20 m ² / s.

The cable may further comprise, on top of the conductive wires, a winding of at least one mica tape.

The cable insulation can be made of a halogen-free polyolefin composition with a maximum average heat release rate of not more than 160 kW / m ² , smoke emission intensity of not more than 0.25 m ² / s.

The cable insulation can be made of a silanol-crosslinkable polyolefin composition that does not contain halogens with a maximum average heat release rate of not more than 150 kW / m ² , smoke emission intensity of not more than 0.20 m ² / s.

Cable insulation can be made of silane-crosslinkable polyethylene.

The inner sheath of the cable is made of a halogen-free polymer composition with a tensile strength at 25 ° C of at least 12 MPa, Shore D hardness of at least 54 units, processing temperature of at least 170 ° C, and a maximum average heat release rate of not more than 120 kW / m ² , smoke emission not more than 0.15 m ² / s.

To achieve the stated requirements, the insulation can be made of a halogen-free polyolefin composition of the HZ02DE grade or a halogen-free silanol crosslinkable polyolefin composition of the HZ01CX brand, the inner shell can be made of a halogen-free polymer composition of the HZ01BED brand, the outer shell can be made of a halogen-free polymer composition of the brand HZ03EP / 8000.

Also, the cable may contain a shield made of copper tapes or copper wires over the insulation of single-core cables or over the inner sheath of multicore cables.

Also, the cable may contain, on top of the inner sheath of unshielded cables or on top of the separation layer of shielded cables, armor in the form of a winding of metal tapes superimposed overlapping, or in the form of spirally superimposed metal wires, over which a polymer tape is imposed by a winding.

Also, the cable must necessarily contain a separation layer of a halogen-free polyolefin composition between the shield and the armor.

Utility Model Implementation

The utility model is illustrated in the drawing.

In FIG. 1 shows a sectional view of a power cable.

The power cable contains three conductive conductors 1, on top of each of which a thermal barrier 2 of mica tapes is sequentially located, insulation 3 from a halogen-free polyolefin composition or a halogen-free cross-linked polyolefin composition or cross-linked polyethylene. The cores are twisted into a common core, around a central filling 4. On top of the core, the cable contains an inner sheath 5 of a halogen-free polyolefin composition, a metal shield 6 in the form of a spirally applied copper tape, a separation layer 7 of a halogen-free polyolefin composition, 8 armor in the form of a winding of metal tapes superimposed overlapping or in the form of spirally imposed metal wires, over which a polymer tape 9, an outer sheath 10 is imposed by a winding.

As a conductive core 1, a copper wire rod is used.

A mica tape is used as a thermal barrier.

As the insulation material of the 3 cables, a HZ02DE halogen-free polyolefin composition manufactured by Cabopol or a HZ01CX halogen-free cross-linked polyolefin composition manufactured by Cabopol or a crosslinked polyethylene composition is used.

As the material of the central filling 4 is used polyvinyl chloride plastic compound of reduced fire hazard.

As the material of the inner shell 5, the separation layer 7, a halogen-free polyolefin composition of the brand HZ01BED manufactured by Cabopol is used.

As screen 6, a copper tape is used.

As the material of the wires or tapes of the armor 8, galvanized steel, aluminum or an aluminum alloy is used.

As a bonding layer for armor 8, a polymer tape 9 is used.

As the material of the outer shell 10, a HZ03EP / 8000 halogen-free polyolefin composition manufactured by Cabopol is used.

The materials used for the manufacture of the proposed cable are manufactured industrially and are widely used in the manufacture of power cables.

Conducting cores 1 are made of wire, traditional for electric cables, twisting into the core with the addition of sealing elements in it is carried out using conventional twisting equipment.

The imposition of insulation 3, the inner shell 5, the separation layer 7, the outer shell 10, the manufacture of the central filling 4 is carried out on extrusion equipment.

Silanol crosslinking of insulation 3 from a crosslinked polyolefin composition free of halogens or crosslinked polyethylene is carried out in the crosslinking chamber.

The overlay of armor 8, consisting of helically imposed metal wires, as well as the twisting of the isolated cores into the core, is carried out on the well-known twisting equipment traditionally used in the cable industry.

The winding with mica tape 2, copper tape 6, fastening polymer tape 9 for the armor 8, the imposition of the armor 8, consisting of metal tapes, is carried out on winding machines used in the cable industry.

The proposed power cable was tested for non-proliferation of combustion during group laying according to GOST R IEC 60332-3-22, for determining the optical density of smoke during combustion and smoldering in accordance with GOST R IEC 61034-2-2005 and for maintaining operability under conditions of flame exposure on equipment according to GOST R IEC 60331-11 when applying the rated operating voltage. The test results are positive.

The results of fire tests with simultaneous mechanical shock according to GOST IEC 60331-1-2013 are presented in table 1.

The inventive fire-resistant power cable is designed for alternating voltage of 0.66, 1 and 3 kV with a frequency of 50 Hz, operation at ambient temperature from minus 65 ° C to plus 60 ° C and relative humidity up to 98% at a temperature of plus 35 ° C and retains performance when exposed to flame with simultaneous mechanical shock for a period of not less than 60 minutes

Claims (10)

1. Power cable, fire resistant under shock loads, containing at least one copper conductive core, insulation, inner and outer sheath of polymer compositions that do not contain halogens, characterized in that the outer sheath is made of a polyolefin composition that does not contain halogens, with strength at a gap at 25 ° C of at least 15 MPa, at 80 ° C of at least 5 MPa, a maximum average heat release rate of not more than 150 kW / m ² , smoke emission intensity of not more than 0.20 m ² / s. 2. The cable according to claim 1, characterized in that it contains a winding of at least one mica tape on top of the conductive wires. 3. The cable according to claim 1, characterized in that the insulation is made of a halogen-free polyolefin composition with a maximum average heat release rate of not more than 160 kW / m ² , smoke emission intensity of not more than 0.25 m ² / s. 4. The cable according to claim 1, characterized in that the insulation is made of a silanol-crosslinkable polyolefin composition that does not contain halogens, with a maximum average heat release rate of not more than 150 kW / m ² , smoke emission intensity of not more than 0.20 m ² / s. 5. The cable according to claim 1, characterized in that the insulation is made of silanol-crosslinkable polyethylene. 6. The cable according to claim 1, characterized in that the inner shell is made of a halogen-free polymer composition with a tensile strength at 25 ° C of at least 12 MPa, Shore D hardness of at least 54 units, and processing temperature of at least 170 ° C, with a maximum average value of the heat release rate of not more than 120 kW / m ² , smoke emission intensity of not more than 0.15 m ² / s. 7. The cable according to claim 1, characterized in that it comprises a screen made of copper strips or copper wires over the insulation of single-core cables or over the inner sheath of multi-core cables. 8. The cable according to claim 7, characterized in that it contains a separating layer of a halogen-free polyolefin composition between the screen and the armor imposed on top of it in the form of a winding of metal tapes superimposed overlapping, or in the form of spirally imposed metal wires, over which is imposed by a winding polymer tape. 9. The cable according to claim 1, characterized in that it contains armor over the inner sheath of unshielded cables in the form of a winding of metal tapes superimposed overlapping, or in the form of spirally superimposed metal wires, over which a polymer tape is imposed by a winding. 10. The cable according to claim 1, characterized in that the insulation is made of a halogen-free polyolefin composition of the HZ02DE grade or a halogen-free silanol crosslinkable polyolefin composition of the HZ01CX brand, the inner sheath is made of a halogen-free polymer composition of the HZ01BED brand, the outer shell is made of a halogen-free polyolefin composition of the brand HZ03EP / 8000.

Images