RU2738209C1 - Lightning protection cable (versions) - Google Patents

Abstract

FIELD: manufacturing technology.SUBSTANCE: lightning protection cable comprises a high-strength galvanized steel wire with a tensile strength not less than 1670 N/mm2, with nominal diameters of 0.85÷4.60 mm, and circular plastic deformation of cable with reduction of cross-section area of article to 5.0÷14 %. Providing high resistance of lightning protection cable to successive effects of lightning strikes with charge of up to 150 C, eolian vibration and dancing is achieved by increasing their structural density and reducing contact stresses. In the lightning protection cable there used are various designs of the cable, both with the contact in plane of the wires in the layers, and between the adjacent layers, as well as the technology of making the lightning protection cable, which differs from the technology of making the cable with point contact of wires in the cable.EFFECT: invention provides a lightning protection cable (versions) in a different design, resistant to the effect of lightning current with a portable charge of up to 150 C, where no break occurs, and disengagement of separate wires relative to each other, in compliance with all technical requirements affecting reliability of overhead transmission line.4 cl

Description

The invention relates to the field of electrical engineering, namely to the structures of a lightning protection cable, made by a lay of galvanized steel wires, with a temporary tensile strength of at least 1670 n / mm ² , and can be used for suspension on overhead power lines (OHL) to protect OHL from straight lines lightning strikes with a transferred charge power of up to 150 CL.

Known ropes used on overhead power lines (PTL) as lightning protection cables - steel ropes in accordance with GOST 3062, GOST 3063 and GOST 3064, point contact ropes (TC). In addition to power lines, these ropes are used for towing devices for masts, ship hoisting, on aerial ropeways, i.e. where, during operation, alternating bends and pulsating loads are insignificant or completely absent. This is due to the low structural density, as well as high contact stresses inside the rope during the operation of ropes of the TK type. In a loaded rope, at a point contact, large contact crushing stresses arise, which contribute to the wear of the wires, followed by their breakage. Therefore, ropes of the TK type are currently in limited use. In addition, from the point of view of manufacturing technology, they are not economical due to the large number of lay operations.

Known lightning protection cable for overhead power lines, (see the description of the utility model to the patent of the Russian Federation 114553, IPC Н01В 5/08. Publ. 03/27/2012. Bull. No. 9).

The lightning protection wire is made of wire in accordance with GOST 7372-79 with a zinc coating according to the "coolant" group (coolant is a zinc coating for particularly harsh operating conditions). The lightning protection cable is made of plastically compressed strands, The design of the lightning protection cable is 3 × 7 (1 + 6). The lightning protection cable is manufactured on a wire-rope machine in two technological steps. The first operation is the production of plastically compressed 1 + 6 strands. The second operation is the manufacture of a ground wire of the 3 × 7 (1 + 6) structure.

This three-strand design of the lightning protection cable does not lead to a significant effect of increasing the resistance to the effects of a lightning strike, short-circuit current, aeolian vibration, rope dance. The increased outer surface of the cable, in relation to single-strand lightning protection cables, contributes to increased ice formation on the surface of the cable. It should be noted that the use of a three-strand rope as a lightning protection cable will lead to a decrease in the modulus of normal elasticity by 15-20%, which will lead to an inevitable increased sagging of the cable during its operation.

Known lightning protection cable, (see the description of the utility model to the patent of the Russian Federation 93178, IPC Н01В 5/08; IPC Н01В 7/00. Publ. 20.04.2010. Bull. No. 11).

Made in two versions:

according to the first option, containing a central wire and one or more strands of wires twisted around it, the central wire and strands around it are made of steel-clad aluminum wires, and the thickness of the aluminum layer on the steel-clad aluminum wire is 7-35% of the diameter of the wire;

according to the second option, containing a central wire and one or more strands of wires twisted around it, the central wire is made of steel-clad aluminum wire, and the strands around it are made of steel-clad aluminum wire and wire made of aluminum alloy based on Al-Mg-Si, the thickness of the aluminum layer on the aluminum-clad steel wire is 7-35% of the wire diameter.

The main disadvantage of this utility model should be attributed to its low resistance to lightning strikes, in which the destruction and local melting of the used coatings occur under real conditions of unsteady instantaneous warm and electric impact of a charge of enormous power and the removal of thermal energy from the affected area occurs mainly due to the contact area steel wires between each other in layers. The efficiency of heat removal from the lightning impact zone and the resistance of the ground wire structure to its strikes under the conditions of this thermal problem depend only on the size of the contact area of the steel wires with each other and the density of this contact. It should also be noted the reduced strength of the structure, the increased cost (when using thick coatings of Al and Al-Mg-Si) and the technological complexity of manufacturing the above-mentioned known lightning protection cables.

Known lightning protection cable for overhead power lines (see description of the patent for a useful model RU 113061 U1. Publ. 27.01.2012. Bull. No. 3)

The design of the proposed ground wire, analogous to the construction of ropes with point tangencies, the number of wires (by one) in the upper layer is reduced in relation to GOST 3063-80, respectively, all the disadvantages previously prescribed for ropes with point tangency in the proposed solution are not eliminated Additional technological operation - plastic deformation separately for each layer, does not fully remove stress concentrators between layers, which will have an extremely negative effect on the resistance to lightning strikes, short-circuit currents and breaking load of the cable as a whole.

The aim of the claimed invention is to create a lightning protection cable (options) in various designs, resistant to lightning current with a portable charge of up to 150 C, in which there is no rupture, and the separation of individual wires relative to each other, while fulfilling all technical requirements affecting reliability overhead power line.

Achieving the technical result of the claimed invention, ensuring the high resistance of the lightning protection cable to the successive impact of lightning strikes with a charge of up to 150 C, aeolian vibration and dance, is achieved by increasing their constructive density and reducing contact stresses, due to circular plastic compression of the cable with linear contact of the wires in each layer and between layers of rope. Between the wires in the cable during circular plastic crimping, the linear contact of the wires is replaced by the contact along the plane, which reduces contact stresses, wear of the wires during their mutual sliding during bending of the cable.

Reducing the contact stresses, in relation to the cable with a point contact with the wires, to the minimum values, is possible only when touching the plane between the wires and between the layers of the lightning protection cable. Tangency on the plane of the wires is carried out at the same lay step, different lay angles for each layer, with an appropriate selection of wire diameters, lay all the wires simultaneously in one technological operation, regardless of the number of rope layers. The lightning protection cable contains high-strength galvanized steel wires with a ultimate tensile strength of at least 1670 n / mm ² , with nominal diameters of 0.85 ÷ 4.60 mm, and circular plastic deformation of the cable with a degree of compression of the cross-sectional area of the product up to 5.0 ÷ 14 %.

The lightning protection cable differs from the previously known ropes used as protection of the overhead power transmission line against lightning strikes in the fact that various cable designs are used, both with touching the plane of the wires in the layers, and between adjacent layers, as well as the technology of manufacturing the lightning protection cable, which differs from the technology making a rope with a point contact of the wires in the rope.

A lightning protection two-layer cable with contact along the plane of the wires is twisted with the same number of wires in each layer and different wire diameters in layers around the central wire. The circular plastic deformation of the cable along the outer surface of the wires is made with the degree of compression of the cable cross-sectional area 5.0-5-14%. The number of wires in the rope can vary from 11 to 21.

A lightning protection two-layer cable with contact along the plane of the wires is twisted with a different, but multiple number of wires in layers around the central wire. The first layer is made of wires of the same diameter, the second layer consists of an even number of wires of two different diameters, alternating with each other. The circular plastic deformation of the cable along the outer surface of the wires is made with a degree of compression of the cable cross-sectional area of 5.0 ÷ 14%. The number of wires in the rope can vary from 16 to 31.

A lightning protection two-layer cable with contact along the plane of the wires is twisted around the central wire, between the wires of the first and second layers, filling wires of a smaller diameter are used than wires in the first and second layers that are close in diameter. The circular plastic deformation of the cable along the outer surface of the wires is made with a degree of compression of the cable cross-sectional area of 5.0 ÷ 14%. The number of wires in the rope can vary from 21 to 41.

A three-layer lightning protection cable touching the plane of the wires is twisted around the central wire, the first layer is made of wires of the same diameter, the second layer consists of wires of different diameters, while in the second layer wires of larger and smaller diameters alternate through one of them, the third layer is made of wires of the same diameter. The circular plastic deformation of the cable along the outer surface of the wires is made with a degree of compression of the cable cross-sectional area of 5.0 ÷ 14%. The number of wires in the rope can vary from 26 to 51.

The technology for manufacturing a lightning protection cable is as follows, a cable with the same lay pitch and tangency along the plane of the wires is twisted on rope equipment, followed by circular plastic deformation along the outer surfaces of the cable wires in one technological operation. The degree of compression of the cross-sectional area of the cable is 5 ÷ 14%, as a result of which the outer and wires of the inner layers are plastically deformed. The contact area between the wires in the layers and between the layers has been increased, and accordingly the constructive density of the cable as a whole has been increased.

The claimed invention, which uses different from the previously known varieties of ropes used as a lightning protection cable to protect an overhead power line, the developed versions of a lightning protection cable touching along the plane of the wires, with an increased contact area between the wires in the layers and between the layers of the cable, makes it possible to increase the resistance lightning protection cable to the successive impact of lightning strikes with a charge of up to 150 C and aeolian vibration, without reducing the tension of the cable, breaking the wires during discharge and disconnecting individual wires relative to each other, subject to all technical requirements affecting the reliability of overhead power transmission lines.

Claims (4)

1. Lightning protection two-layer cable containing galvanized steel wires, touching the plane of the wires in each layer and between the layers of the cable, with their nominal diameters of 0.85 ÷ 4.60 mm, characterized in that the lightning protection two-layer cable is twisted with different wire diameters along layers, the same number of wires in each layer, around the central wire, the number of wires in the cable, depending on the nominal diameter from 11 to 21, with the degree of compression of the cross-sectional area of the cable 5.0 ÷ 14%. 2. Lightning protection two-layer cable containing galvanized steel wires, touching the plane of the wires in each layer and between the layers of the cable, with their nominal diameters of 0.85 ÷ 4.60 mm, characterized in that the lightning protection two-layer cable is twisted with different, but multiple the number of wires in layers around the central wire, the first layer is made of wires of the same diameter, the second layer consists of an even number of wires of two different diameters, alternating with each other, the number of wires in the cable is from 16 to 31, with the degree of compression of the cable cross-sectional area 5.0 ÷ 14%. 3. Lightning protection two-layer cable containing galvanized steel wires, touching the plane of the wires in each layer and between the layers of the cable, with their nominal diameters 0.85 ÷ 4.60 mm, characterized in that the lightning protection two-layer cable is twisted around the central wire, for ensuring a linear contact between the wires of the first and second layers, additionally using filling wires of a smaller diameter than the main wires of similar diameters in layers, the number of wires in the cable from 21 to 41, with the degree of compression of the cable cross-sectional area 5.0 ÷ 14%. 4. Three-layer lightning protection cable containing galvanized steel wires, touching the plane of the wires in each layer and between the layers of the cable, with their nominal diameters of 0.85 ÷ 4.60 mm, characterized in that the three-layer lightning protection cable, in which around the central wire the first layer of wires of the same diameter is located, the second layer of wires of different diameters, alternating with each other, the third layer of wires of the same diameter, the number of wires in the cable is from 26 to 51, with the degree of reduction of the cable cross-sectional area 5.0 ÷ 14%.