RU229361U1 - Power cable for voltage 6-35 kV - Google Patents

Abstract

The utility model relates to single-core power cables. The technical result consists in increasing the strength of the cable, ensuring the possibility of using it for laying in difficult mountainous conditions. The cable contains a conductive core, onto which a screen made of a polymer cross-linkable conductive composition, polymer insulation made of cross-linkable polyethylene and a screen made of a polymer cross-linkable conductive composition are successively applied, wherein a winding of conductive tapes and a metal screen made of copper wires fastened with a winding of copper tape are applied on top of the insulation, then a separating layer in the form of a winding of polymer water-blocking tapes and an aluminum-polymer tape are applied on top of the metal screen, then an extruded pad made of a polyethylene composition, on top of which an armor in the form of a winding of wires containing aluminum is applied, and on top of the armor - an outer sheath made of a high-density polyethylene composition. 9 c.p. phyl., 1 fig.

Description

The utility model relates to single-core power cables with a voltage of 6-35 kV, armored with metal wires, in a sheath made of a polyethylene composition.

The task that the technical solution is aimed at solving is to expand the range of single-core power cables capable of operating at voltages from 6 to 35 kV, with increased resistance to small-radius installation bends and increased resistance to crushing loads.

The prior art includes power cables with extruded insulation for a rated voltage of 6-35 kV inclusive, armored with metal wires, in a sheath made of polyethylene of the APvKaPu2gzh, PvKaPu2gzh, APvKaP2gzh, PvKaP2gzh brands, manufactured in accordance with the requirements of GOST R 55025-2012 (https://internet-law.ru/gosts/gost/53908/) and GOST 34834-2022 (https://internet-law.ru/gosts/gost/78477/) (for example, cables https://www.holdcable.com/products/pvkap2gzh/?ysclid=lusmwnej1k424387229). They contain one single-wire or multi-wire conductive core made of copper or aluminum with a cross-section from 10 mm ² to 1600 mm ² . To prevent longitudinal spread of water along the length of the cable, the wires in multi-wire conductive cores are twisted together with water-blocking threads.

A screen made of a polymer conductive composition, polymer insulation and a screen made of a polymer conductive composition are applied sequentially to each conductive core. The nominal thickness of the insulation is from 2.5 mm to 8.5 mm depending on the cross-section of the conductive core and the nominal voltage of the cable. Next, a winding of water-blocking conductive tapes and a metal screen of copper wires with a diameter of 0.7-3.0 mm, fastened with a winding of copper tape with a nominal thickness of at least 0.1 mm, are applied. A separating layer with a thickness of at least 0.15 mm in the form of a winding of water-blocking conductive tapes and a winding of aluminum-polymer tape with an aluminum layer thickness of at least 0.1 mm are applied over the metal screen. Then, an extruded polymer pad with a thickness of at least 1.0 mm is applied. Armor in the form of a winding of aluminum or aluminum alloy wires with a diameter of 1.6-3.15 mm, a winding of polymer tapes and an outer shell of polyethylene are applied over the cushion.

At the same time, GOST R 55025-2012 and GOST 34834-2022 “Power cables with extruded insulation for rated voltage of 6-35 kV inclusive” among others specify the following requirements for the characteristics of the outer polyethylene sheath:

Shore hardness not less than 55 HD;

tensile strength before aging is not less than 12.5 N/ ^mm2 ;

relative elongation before and after aging is not less than 300%.

The disadvantages of the above-mentioned cables, which prevent their installation in difficult mountainous terrain with possible rockfalls and mudflows in moving and rocky soils, are insufficient resistance to sheath defects under external mechanical influences and a large permissible bending radius of the cable.

The value of cable resistance to crushing forces is not regulated in these GOSTs.

According to GOST R 55025-2012 and GOST 34834-2022, the permissible bending radius of single-core cables during installation must be at least 15 times the outer diameter of the cables.

The prior art discloses an ARMOURED POWER CABLE (see (19) RU (11) 97857 (13) U1, (51) IPC H01B 7/18 (2006.01) H01B 9/02 (2006.01)), characterised by the following set of essential features: "A power cable comprising one conductive core and, sequentially located on it and applied by extrusion, a first screen made of an electrically conductive cross-linked polymer composition, insulation made of a cross-linked polyethylene composition, a second screen made of an electrically conductive cross-linked polymer composition, a winding with a tape made of an electrically conductive material, a metal screen, a separating layer and an extruded outer sheath made of polyethylene or polyvinyl chloride plastic compound, characterised in that the metal screen is made in the form of spirally or wave-like applied copper wires, fastened with a spirally applied skein of copper wires, on top of The separating layer is covered with an internal extruded shell and wire armor made of aluminum wires or aluminum alloy wires."

Its disadvantage is the low resistance of the outer sheath and the cable as a whole to the appearance of defects under external mechanical influences, which prevents its installation in difficult mountainous terrain with possible rockfalls and mudflows in moving and rocky soils.

An analogue is known from the prior art - a power cable (see patent (19) RU, (11) 216212, (13) U1, (51) IPC H01B 9/02 (2006.01)), characterized by the following essential features:

"A power cable for a voltage of 6 to 35 kV, containing a conductive core covered with an electrically conductive polymer screen over the core, insulation and an electrically conductive polymer screen over the insulation, on top of which a layer of electrically conductive material is applied, a metal screen and an outer polymer sheath, characterized in that the conductive core is made flexible, from strands twisted from copper wires, and the insulation is made from high-modulus ethylene-propylene rubber."

The disadvantage of this cable design is the low resistance of the outer sheath and the cable as a whole to the appearance of defects under external mechanical influences, which prevents their installation in difficult mountainous conditions with possible rockfalls and mudflows in moving and rocky soils.

Technical result: creation of a new single-core power cable for voltage from 6 to 35 kV, intended for installation in difficult mountainous terrain with possible rockfalls and mudflows in mobile and rocky soils.

Improved operational properties of the cable are created by using a polyethylene composition for the outer sheath with improved physical and mechanical properties compared to analogues, where the outer sheath is characterized by the following parameters:

Shore hardness of at least 60 H _D ; tensile strength before aging of at least 20 N/mm ² ; relative elongation after aging of at least 700%.

The use of such an outer sheath makes it possible to create a cable:

with a minimum bending radius reduced by 3-4% compared to the corresponding cables, the operating parameters of which are specified in GOST R 55025-2012 and GOST 34834-2022, which is at least 14.5 external diameters of cables, and this makes it possible to reduce the permissible bending radius of the cable during installation;

with increased resistance to crushing forces of up to 0.7 kN/cm, which virtually eliminates the possibility of damage to internal structural elements and the cable as a whole, while maintaining the integrity of the outer cable sheath.

The above-mentioned advantages of cables expand the scope of cable use, since these cables can be laid and stably operated in mountainous areas with possible rockfalls and mudflows in mobile and rocky soils.

The drawing shows the design of the utility model, where:

1 - conductive core;

2 - screen made of polymer conductive composition;

3 - polymer insulation made of cross-linked polyethylene;

4 - screen made of polymer conductive composition;

5 - winding of electrically conductive water-blocking tapes;

6 - a metal screen made of copper wires, fastened with a winding of copper tape;

7 - a separating layer in the form of a winding of electrically conductive water-blocking tapes;

8 - winding with aluminum-polymer tape;

9 - extruded polymer cushion;

10 - armor in the form of a winding of wires made of aluminum or aluminum alloy;

11- polymer tape winding;

12 - outer shell made of polyethylene composition.

DESCRIPTION OF THE UTILITY MODEL

Power cables for voltage of 6-35 kV contain one single-wire or multi-wire conductive core 1 made of either copper, or aluminum, or aluminum alloy.

The following are successively applied to the conductive core: screen 2 made of a polymer conductive composition, polymer insulation 3 and screen 4 made of a polymer conductive composition.

For additional cable sealing, wires can be twisted together with water-blocking threads into multi-wire conductive cores (not shown in the drawing).

A winding 5 of electrically conductive water-blocking tapes and a metal screen 6 of copper wires, fastened with a winding of copper tape, are applied over the screen made of polymer composition 4.

Next, a separating layer 7 in the form of a winding made of electrically conductive water-blocking tapes is applied over the metal screen 6.

Next, a winding 8 of aluminum-polymer tape is made, on top of which an extruded polymer pad 9 is applied, on top of which armor 10 is applied, made in the form of a winding of aluminum or aluminum alloy wires, on top of which a winding 11 of polymer tapes is applied.

The top layer of the cable is the outer sheath 12 made of a polyethylene composition with the following characteristics: Shore hardness of at least 60 H _D ; tensile strength before aging of at least 20 N/mm ² ; relative elongation after aging of at least 700%.

The radial thickness of the outer sheath can range from 3 mm to 6 mm depending on the cable cross-section.

The utility model with the above-described distinctive essential features has improved operational properties compared to analogues, namely, it has smaller-radius installation bends and increased resistance to external mechanical impacts during installation and operation.

The cable is characterized by a new set of essential features, which allows us to conclude that the utility model meets the patentability criterion of “novelty”.

As a result of creating a technical solution for the cable, a technical result was achieved - a new cable was created, expanding the range of cables intended primarily for use in mountainous areas.

Information confirming the possibility of cable implementation.

The conductor 1, which may be either single-wire or multi-wire, is made of copper or aluminum rod or wire, traditionally used for electrical cables.

A screen made of a polymer conductive composition 2, a polymer insulation made of cross-linked polyethylene 3 and a screen made of a polymer conductive composition 4 are created on inclined type extrusion lines.

The application of tapes for the conductive layer 4, windings of conductive water-blocking tapes 5, separating layer 7, windings of aluminum-polymer tapes 8, and polymer tapes 11 is performed on standard twisting equipment.

The application of an extruded polymer cushion under the armor 9 and an outer shell made of polyethylene composite 12 is performed on extrusion lines.

The application of a metal screen made of copper wires 6, fastened with a winding of copper tape and wire armor 10, is carried out on twisting machines traditionally used in the cable industry.

EXAMPLES OF CABLE EXECUTION

1. A cable with a diameter of 39.6 mm contains a copper insulated conductive core with a cross-section of 120 ^mm2 and has protection in the form of armor made of aluminum alloy wires with a diameter of 2.0 mm, laid on a pad of polyethylene with a thickness of 1.5 mm and an outer sheath with a thickness of 3.0 mm made of a polyethylene composition of the TUROLEN 153-73THL brand, made on the basis of high-density polyethylene.

2. A cable with a diameter of 47.4 mm contains a copper insulated conductive core with a cross-section of 240 ^mm2 , has protection in the form of armor made of aluminum alloy wires with a diameter of 2.5 mm, laid on a pad of polyethylene with a thickness of 1.5 mm and an outer sheath with a thickness of 3.2 mm made of a polyethylene composition of the TUROLEN 153-73THL brand, made on the basis of high-density polyethylene.

Claims (10)

1. An armoured power cable for a voltage of 6 to 35 kV, intended for installation in mountainous terrain, comprising a conductive core onto which a screen made of a cross-linkable polymer conductive composition, polymer insulation made of cross-linkable polyethylene and a screen made of a cross-linkable polymer conductive composition are successively applied, wherein a winding of conductive tapes and a metal screen of copper wires fastened with a winding of copper tape are applied on top of the insulation, then a separating layer in the form of a winding of polymer water-blocking tapes and an aluminum-polymer tape are applied on top of the metal screen, then an extruded pad made of a polyethylene composition, on top of which armour in the form of a winding of wires containing aluminum is applied, and on top of the armour - an outer sheath, characterized in that the outer sheath of the cable is made of a high-density polyethylene composition and is characterized by the following parameters: a Shore hardness of at least 60 H _D ; tensile strength before aging of at least 20 N/ ^mm2 , relative elongation after aging of at least 700%. 2. A cable according to item 1, characterized in that the radial thickness of the outer sheath is from 3 mm to 6 mm, depending on the size of the cable cross-section. 3. A cable according to item 1, characterized in that the conductive core is made single-wire. 4. A cable according to item 1, characterized in that the conductive core is made multi-wire. 5. A cable according to item 1, characterized in that the conductive core is made of copper. 6. A cable according to item 1, characterized in that the conductive core is made of aluminum. 7. A cable according to item 1, characterized in that the conductive core is made of an aluminum alloy. 8. A cable according to item 1, characterized in that the wires of the conductive core are twisted together with water-blocking threads into multi-wire conductive cores. 9. The cable according to item 1, characterized in that the composition of the armor wires is aluminum. 10. The cable according to item 1, characterized in that the composition of the armor wires is an aluminum alloy.