RU2670099C1 - Power cable - Google Patents

Abstract

FIELD: cable technology.

SUBSTANCE: invention relates to cable technology, namely to the construction of power cables with plastic insulation and sheath intended for transmission and distribution of electrical energy in stationary electrical installations at alternating voltage up to 1,000 V with frequency up to 100 Hz. Current-carrying wires 1 are made of aluminum alloy wires comprising the following components, mass. %: aluminum up to 99 %, iron 0.3–1.0 %, zinc up to 0.1 %, silicon to 0.15 %, gallium to 0.03 %, copper to 0.3 %, magnesium to 0.05 %.

EFFECT: improved operational and installation characteristics of the cable.

18 cl, 1 dwg, 1 tbl

Description

The invention relates to cable technology, namely, to designs of power cables with plastic insulation and a sheath, intended for the transmission and distribution of electrical energy in stationary electrical installations with alternating voltage up to 1000 V with a frequency of up to 100 Hz.

Power cables of the AVVG brand are known having conductive conductors made of aluminum, insulation and a sheath of polyvinyl chloride compositions (GOST 31996-2012 "Power cables with plastic insulation for a rated voltage of 0.66; 1 and 3 kV").

However, the problematic issue of using cables with aluminum conductors, for example, in the electrical wiring of residential and public buildings, is contact connections. Standard technical solutions in connectors and sockets, consisting in the use of steel screws instead of copper and brass, lead to deterioration (weakening) of the contact joint during operation. This is due to the difference in thermal expansion of the contacting elements and the creep of aluminum. Since aluminum and steel expand and contract at different speeds at different loads and temperatures, the contact area gradually decreases, which leads to an increase in the electrical resistance of the contact joint.

The second negative point when using cables and wires with aluminum conductors for electrical wiring in buildings is such a property of aluminum as creep, which is characterized by the rate of change in the size of the material over time under the influence of mechanical stress and temperature. The creep phenomenon is characteristic of many metals, however, their creep rate can vary significantly. The aluminum wire used as a conductive conductor (TJ) of cables and wires has a high creep rate, in contrast to aluminum-based alloys, including iron, zinc, silicon.

In addition, there are mechanical damage (kink) of the conductive aluminum conductors during installation (remounting) of wiring in buildings. The aluminum wire used has low resistance to multiple bends - the number of bends at an angle of 90 ° from the initial position of the sample in both directions when tested according to GOST 1579-93 is not more than 10.

The technical result consists in increasing the reliability of power cables by improving fire safety characteristics, increasing the stability of the transition resistance of contact joints and resistance to repeated bends, at least 10 bends at an angle of 90 ° from the initial position in both directions when tested according to GOST 1579-93.

The technical result is achieved in that in a power cable containing at least one conductive core with plastic insulation and an outer sheath, the conductive wires are made by drawing and then annealed from a wire rod made of aluminum alloy, including the following components%: aluminum up to 99%, iron 0.3-1.0%, zinc up to 0.1%, silicon up to 0.15%, gallium up to 0.03%, copper up to 0.3%, magnesium up to 0.05%.

The conductive core withstands at least 10 bends at an angle of 90 ° from the starting position on both sides when tested according to GOST 1579-93 and can be single-wire with a temporary resistance at a maximum load of 75-130 MPa and an elongation at break of 5% -20% or multiwire.

The cable may be provided with an inner sheath overlaid on top of the insulation or twisted into the core of insulated cores.

The insulation can be made of low fire hazard PVC compound with an oxygen index of at least 32 with a maximum specific optical density of smoke during combustion and decay (D _max ) of not more than 150 and with a mass fraction of hydrogen chloride released during combustion of not more than 120 mg / d, the outer shell can be made of low fire hazard PVC compound with an oxygen index of at least 35, with a maximum specific optical density of smoke during combustion and decay (D _max. ) of not more than 150 and with the mass fraction of hydrogen chloride released during combustion is not more than 100 mg / g, and the inner shell can be made of low fire hazard PVC compound with an oxygen index of at least 40, with a maximum specific optical density of smoke during combustion and decay (D _max. ) not more than 120 and with a mass fraction of hydrogen chloride released during combustion, not more than 50 mg / g.

The insulation can be made of low fire danger PVC compound of the brand Lowgran 1110 or Eligran 1110 or Bashgran 1110, the outer shell can be made of the low fire hazard PVC compound of the Lowgran 2110 or Eligran 2110 or Bashgran 2110 brand, the inner shell can be made of fireproof polyvinyl chloride Hazards of the Lousgran 3110 or Eligran 3110 or Bashgran 3110 brands.

The insulation, the outer shell and the inner shell can be made of low fire hazard PVC compounds belonging to the groups of moderately hazardous and / or low hazard toxic products of combustion and the use of which provides an equivalent toxicity index of the combustion products of the cable product of at least 121 g / m ³ , the insulation can be made of low fire hazard PVC compound of the brand Lowgran 1010 or Eligran 1010, the outer shell can be made made of low fire hazard PVC compound of the Grade 2010 or Eligran 2010 brand, the inner shell can be made of low fire hazard PVC compound of the Grace 3010 or Eligran 3010 brand.

The insulation can be made of a halogen-free polymer composition with an oxygen index of at least 28, the outer shell can be made of a halogen-free polymer composition with an oxygen index of at least 35, and the inner shell can be made of a polymer composition, not containing halogens with an oxygen index of at least 40, while the insulation can be made from a polymer composition of the brand Vintes 1110 or Promvulk 13633 or Lekron VHF-40 or from a crosslinkable polymer composition that does not contain halogens, aruzhnaya shell may be made from a polymer composition Vintes mark 2010 or 33622 or Promvulk Lekron VHF-38, while the inner shell may be made from a polymer composition Vintes mark 3020 or 23633 or Promvulk Lekron VHF-44.

The cable can be equipped with a shield made of copper tapes or copper wires connected by copper tape or pasme and laid on top of the inner shell and armor of two steel galvanized tapes, or from steel wires or aluminum wires

The invention is illustrated in the drawing.

The polyvinyl chloride compositions used for the manufacture of the proposed cable, both for general industrial cables and low fire danger PVC compounds, as well as halogen-free polymer compositions, are manufactured industrially and are widely used in the manufacture of cables.

Conducting cores 1 are made of aluminum alloy wires, including the following mass% components: aluminum up to 99%, iron 0.3-1.0%, zinc up to 0.1%, silicon up to 0.15%, gallium up to 0.03 %, copper up to 0.3%, magnesium up to 0.05%.

The wire from the specified alloy during the traditional drawing of wire rods for electric cables and subsequent annealing at temperatures of 240 - 400 ° C (in the case of holding no more than 1 hour) obtains the necessary properties to achieve the specified technical result. These operations can be carried out with separate processes or annealing during drawing in the case of the use of appropriate equipment, widely used in the cable industry.

Cable elements are twisted using conventional twisting equipment. Insulation 2, outer 3 and inner 4 shells are applied on extrusion equipment.

The overlay of the screen 5 of copper tapes or copper wires and armor 6 of steel wires or wires of aluminum or aluminum alloy is carried out on known equipment traditionally used in the cable industry.

The application of armor 6 made of galvanized steel strip is made on armor machines, traditionally used in the cable industry.

Samples of the proposed cables were tested for resistance to repeated bends at an angle of 90 ° from the initial position of the sample in both directions when tested according to GOST 1579-93, and the increase in the electrical resistance of the contact joint was determined during testing according to GOST 17441-84.

The test results are shown in the table.

Claims (18)

1. Power cable containing at least one conductive core with plastic insulation and an outer sheath, characterized in that the conductive wires are made of aluminum alloy wire, including the following components, mass. %: aluminum up to 99%, iron 0.3-1.0%, zinc up to 0.1%, silicon up to 0.15%, gallium up to 0.03%, copper up to 0.3%, magnesium up to 0.05 % 2. The cable according to claim 1, characterized in that the conductive core is made single-wire with a temporary resistance at a maximum load of 75-130 MPa, elongation at break of 5-20% and can withstand at least 10 bends at an angle of 90 ° from the initial position in both side. 3. The cable according to claim 1, characterized in that the conductive core is multi-wire and can withstand at least 10 bends at an angle of 90 ° from the initial position in both directions. 4. Cable according to any one of paragraphs. 1-3, characterized in that the insulation is made of low fire hazard PVC compound with an oxygen index of at least 32 with a maximum specific optical density of smoke during combustion and decay (D _max ) of not more than 150 and with a mass fraction of hydrogen chloride released during combustion, no more than 120 mg / g, the outer shell is made of a PVC compound with a reduced fire hazard oxygen index of not less than 35, with maximum specific optical density of smoke when burning and smoldering (d _max) of not more than 150 and aces share hydrogen chloride released during the combustion, no more than 100 mg / g. 5. The cable according to claim 4, characterized in that the insulation is made of low fire danger PVC compound of the brand Lowgran 1110, or Eligran 1110, or Bashgran 1110, the outer sheath of the low fire risk PVC compound of the brand Lowgran 2110, or Eligran 2110, or Bashgran 2110. 6. Cable according to any one of paragraphs. 1-3, characterized in that the insulation and the outer shell are made of low fire hazard PVC compounds belonging to the groups of moderately hazardous and / or low hazard toxic products of combustion and the use of which provides a value of an equivalent toxicity index of the combustion products of the cable product of at least 121 g / m ³ . 7. The cable according to claim 6, characterized in that the insulation is made of low fire hazard PVC of the brand Lowgran 1010 or Eligran 1010, the outer sheath of low fire danger PVC plastic of the Lowgran 2010 or Eligran 2010 brand. 8. The cable according to any one of paragraphs. 1-3, characterized in that the insulation is made of a halogen-free polymer composition with an oxygen index of at least 28, the outer shell is made of a halogen-free polymer composition with an oxygen index of at least 35. 9. The cable according to claim 8, characterized in that the insulation is made of a polymer composition of Vintes 1110 brand, or Promvulk 13633, or LekronVHF-40, or of a crosslinkable polymer composition that does not contain halogens, the outer shell of a polymer composition of Vintes 2010 brand, or Promvulk 33622, or LekronVHF-38. 10. Cable according to any one of paragraphs. 1-3, characterized in that it is provided with an inner shell, overlaid on top of insulation or twisted insulated cores. 11. The cable according to claim 4, characterized in that it is provided with an inner sheath overlaid on insulation or twisted insulated cores made of low fire hazard PVC compound with an oxygen index of at least 40, with a maximum specific optical density of smoke during combustion and decay (D _max ) no more than 120 and with a mass fraction of hydrogen chloride released during combustion, not more than 50 mg / g. 12. The cable according to claim 11, characterized in that the inner sheath is made of low fire hazard PVC compound of the brand Lowgran 3110, or Eligran 3110, or Bashgran 3110. 13. The cable according to claim 6, characterized in that it is provided with an inner sheath overlaid on insulation or twisted insulated cores made of low fire hazard PVC compound belonging to the groups of moderately hazardous or low-toxicity combustion products and the use of which provides an equivalent value the toxicity of the combustion products of the cable product is not less than 121 g / m ³ . 14. The cable according to claim 13, characterized in that the inner sheath is made of low fire hazard PVC compound of the brand Lowgran 3010 or Eligran 3010. 15. The cable according to claim 8, characterized in that it is provided with an inner sheath applied over insulation or twisted insulated cores made of a halogen-free polymer composition with an oxygen index of at least 40. 16. The cable according to p. 15, characterized in that the inner shell is made of a polymer composition of the brand Vintes 3020, or Promvulk 23633, or LekronVHF-44. 17. The cable according to claim 10, characterized in that it is provided on top of the inner sheath with a screen made of copper tapes or copper wires connected by a copper tape or sheaf and laid on top of the inner sheath. 18. The cable according to claim 10, characterized in that it is provided on top of the inner shell with armor from two steel galvanized tapes, or from steel wires, or wires of aluminum or aluminum alloy, superimposed on top of the inner shell.

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