RU189589U1 - Insulated cable - Google Patents

Abstract

The inventive cable is used as a carrying cable, designed primarily for railway contact network, as well as for electrified vehicles. chemical de-icing agents used in artificial structures, roads and pavements, the introduction of additional longitudinal sealing moisture penetration inside the conductor, which does not allow the conductor to oxidize and prevents the shell from being destroyed during negative and positive temperature drops.

Description

The claimed technical solution relates to the field of contact networks, namely to the supporting cables of the contact suspension for the transmission of electric energy in electrical networks of electrified transport, mainly railway.

The tasks facing the developers of carrying cables of the contact network - the creation of products with high technical resource.

The technical solution of the carrying cable of the railway contact network is known (see the description of the patent for the invention (19) RU (11) 2 509666 (13) C1 (54) CABLE CABLE OF THE CONTACT RAILWAY NETWORK)), which consists of a central copper wire, turns of the first winding seven copper wires of the same diameter, turns of the second winding with alternation of seven copper wires of the same diameter and seven copper wires of a different diameter and turns of the third winding of fourteen copper wires of the same diameter. In this case, the first, second and third windings are made with the same stripe pitch, in the same direction and with linear contact of the wires of the first, second and third windings, the third winding wires are laid with gaps 2.5-3% of their nominal diameter and plastically deformed with the degree of compression of the cross-sectional area of the cable 10-10,5%. The technical result for which this technical solution is developed is an increase by 20-22% of the breaking load in relation to the cables used, as well as the complete elimination of the steel core with an increase in the calculated cross section of the supporting cable by 16-17%, which will contribute to an increase in electrical conductivity. Its disadvantage is that when using a cable in artificial structures (under ramps, bridges, in tunnels, etc.), salt and chemically active anti-icing agents are used on the cable, which are used to treat the surfaces of artificial structures, roads and pavements, which in combination with electromagnetic fields and heating during the passage of current cause active cable corrosion and accelerated its destruction.

Closest to the claimed cable is insulated for the contact network of electrified transport (see. Description (19) RU (11) 177556 (13) U1 (51) IPC B60M 1/22 (2006.01)), made round in cross section containing a central the wire, then - the inner curl of 6 and the outer one - of 12 wires from an alloy of low-alloyed copper, additionally has a protective sheath of light-stabilized silane-expanded polyethylene with a thickness of at least 1.6 mm.

The disadvantage of this cable is that the protective shell abrades at the points of contact with artificial structures and does not protect the conductive core from the effects of salt and chemically active anti-icing reagents, and under conditions of high humidity, moisture enters this shell, as a result of which the conductance of the conductive cores decreases and Accelerated corrosion of the conductor.

The technical result from the use of the proposed solution of the cable carrying an insulated (hereinafter referred to as the cable) is an increase in moisture resistance and, due to this, its service life, as well as an increase in ease of installation due to:

- performance of the protective sheath of polyurethane - light-stabilized polymer composition with increased resistance to salt and chemically active anti-icing agents and abrasion, as well as with increased resistance to the effects of high and low temperatures, which remains flexible at high and low temperatures, which allows to mount the wires at various, including sub-zero temperatures;

- adding an additional longitudinal sealing under the casing, preventing the penetration of moisture inside the conductor, which does not allow the conductor to oxidize and prevents the casing from swelling (breaking) at negative temperatures.

Longitudinal sealing can be performed either by adding water-swelling filaments laid longitudinally between conductive wires, or due to the longitudinal compounding of the interwire space of the conductor before the protective sheath is applied, which additionally protects the wires from oxidation.

In this case, the wires of the conductive core can be made either of copper alloy (bronze) with enhanced mechanical characteristics, which provides an increased tensile strength of the cable to a gap, or of copper, which provides a higher conductivity of the cable.

The claimed utility model is illustrated by drawings of the cable in the section, where

- Fig.1 - cable with sealing by swelling filaments;

- Figure 2, a cable with sealing compound.

The cable with water-swellable yarns Figure 1, consists of one central wire (1), an internal sheet of 6 wires (2) and an external sheet of 12 wires (3), a longitudinal sealing element - water-swelling threads (5), preventing the longitudinal penetration of moisture inside the conductor. A layer of polyurethane (4) is applied over the longitudinally sealed conductor.

Figure 2 - cable with compounded conductive core, which consists of one central wire (1), internal sheet of 6 wires (2) and external plate of 12 wires (3), longitudinal sealing element - compound (6), filling the wire gap and covering the outer curl. A layer of polyurethane (4) is applied over the conductive core sealed with a compound.

Description of the proposed technical solution.

The cable carrying an electrified transport insulated for a contact network has a conductor core round in cross section with longitudinal sealing, made of central wire (1), internal sheet (2) of 6 and external sheet (3) of 12 wires and protective polyurethane sheath (4) .

Conducting wires can be made of copper or bronze.

Longitudinal sealing, which prevents the penetration of moisture into the conductor, can be performed either by adding water-swelling filaments (5) longitudinally laid between the conductive wires, or by longitudinal compounding of the inter-wire space (6) of the conductive sheath.

In this case, the wires of the conductive core can be made either of copper alloy (bronze) with enhanced mechanical characteristics, which provides an increased tensile strength of the cable to a gap, or of copper, which provides a higher conductivity of the cable.

As a result of a search on patent and scientific and technical information sources, no solutions were found containing the entire set of essential features of the independent claim of the utility model, which allows to conclude that the claimed utility model complies with the novelty patentability criterion.

Industrial applicability of the claimed utility model is confirmed by the information below.

Insulated cable is manufactured by methods known in the cable industry. Its production is possible in all cable companies where there is equipment used in the production of conductive wires, ropes and cables.

Longitudinal sealing with compounding interwire space is performed by means of an extruder.

The imposition of a light-stabilized shell of polyurethane produced on the extrusion line.

The carrier cable in a protective sheath, having a thickness of 1.4 - 2.2 mm, after being in water at a temperature of (20 ± 10) выдержC, withstands the test of an alternating voltage of 4 kV at a frequency of 50 Hz for at least 15 minutes on the construction length. The supporting cable in the protective sheath meets all the requirements of water resistance.

Claims (5)

1. A cable carrying an electrified transport insulated for a contact network, having a conductor core round in cross section, made of a central wire, an internal sheet of 6 and an external sheet of 12 wires, and also a protective sheath, characterized in that the cable additionally has a longitudinal sealing, prevents the penetration of moisture into the conductor, and the protective sheath is made of polyurethane. 2. The cable according to claim 1, characterized in that the conductive wires are made of copper. 3. Cable according to claim 1, characterized in that the conductive wires are made of bronze. 4. The cable according to claim 1, characterized in that the longitudinal sealing, which prevents the penetration of moisture into the conductor, is made of water-swollen yarns laid longitudinally. 5. The cable according to claim 1, characterized in that the longitudinal sealing, which prevents the penetration of moisture into the conductor, is made by compounding the interwire space of the conductor.

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