RU71471U1 - CARRYING CABLE FOR UNDERWATER WORKS - Google Patents

Abstract

The utility model relates to the field of electrical engineering, namely, to the designs of special load-carrying cables for underwater operations, designed to transmit communication signals and electrical power in underwater conditions under the influence of tensile forces and hydrostatic pressure.

The cable contains at least two insulated conductive conductors for electrical power transmission, one shielded pair of insulated conductors for communication signals, twisted in the core, filling elements, a fastening element, an inner sheath, a load-bearing element in the form of two mutually opposite windings of high-strength strands of strands and a protective sheath of elastic polymer material. The core is made of two insulated conductive cores located in the recesses between two filler elements twisted together, made in the form of cordels having a diameter larger than the mentioned insulated cores. The cores for the transmission of electrical power are placed between the bundles of threads of the first coil of the load-bearing element in diametrically opposite places.

The cable allows you to expand the transmission range of communication signals, reduce the mass-dimensional characteristics of the cable, increase its operational reliability.

Description

The utility model relates to the field of electrical engineering, namely, to the designs of special load-carrying cables for underwater operations, designed to transmit communication signals and electrical power in underwater conditions under the influence of tensile forces and hydrostatic pressure.

An analogue is the KGR-7-1,2M load-carrying cable for underwater operations, which contains a central load-carrying cable made of steel galvanized wires in rubber insulation, 5 steel-copper power cores insulated with polyethylene, 2 telephone copper cores twisted in pair and shielded with copper braid wires. The fastening element is made of heat-resistant film, and the protective sheath is made of rubber. (Technical conditions of KLGI. 685621.027 TU "Cable carrying KGR-7-1,2M"). The cable is protected by the patent of Ukraine No. 62870 A dated 10.28.2003, MKl Н01В 7/00.

The main disadvantages of this cable include:

- a symmetrical pair of cores is intended only for telephone communication in the tonal frequency range (several kilohertz);

- the core of the cable (conductive cores) is not reliably protected from mechanical damage that occurs during operation, since the steel cable is located in the center of the cable, and only the rubber sheath surrounds the cores;

- the rubber shell has a significant density and low abrasion resistance;

- the cable has a large mass and dimensions, due to the implementation of the load-bearing element of steel, and the protective sheath of rubber.

The prototype is a cable carrying for underwater work, containing at least two insulated conductive cores for the transmission of electrical power and one shielded twisted pair

insulated conductors for transmitting communication signals twisted into a core, a fastening element, a load-carrying element and a protective sheath, characterized in that the core is made of a central shielded pair, twisted polyethylene insulated copper conductors, over which a twisted of copper-insulated copper conductors and filling elements is laid, moreover, there is a dividing element between the shielded pair and the midwire of veins; the load-bearing element is superimposed on the core in the form of two mutually opposite windings of aramid harnesses x threads, and the protective sheath is made of elastic polymeric material. (Russian patent for utility model No. 55200 dated July 28, 2005)

However, said cable has a relatively large outer diameter and attenuation coefficient of the shielded pair.

The objective of this utility model is to create such a cable design in which, due to the introduction of new structural elements, their new relative positioning and normalization of the geometric dimensions of the elements, the mass-dimensional and electrical characteristics of the cable would be improved.

This object is achieved in that in a cable carrying for underwater work, including at least two insulated conductive conductors for transmitting electrical power, one shielded pair of insulated conductors for transmitting communication signals, twisted in the core, filling elements, a fastening element, an inner sheath, a carrying element in the form of two mutually opposite tufts of tows of high-strength threads and a protective sheath made of elastic polymer material, according to a utility model, the core is made of two insulated conductive conductors located in the recesses between two filler elements twisted together, made in the form of cordels having a diameter larger than the mentioned insulated conductors, and the conductors for electrical power transmission are placed between the bundles of threads of the first coil of the load-bearing element in diametrically opposite places.

The advantage of the proposed cable carrying for underwater work is as follows:

- the cable has the best electrical characteristics, since the conductors of a symmetrical pair for transmitting communication signals are spaced from each other by

greater distance than the prototype, which reduces the working capacity and the attenuation coefficient of the pair;

- the implementation of the core of two isolated conductive cores for transmitting communication signals located in the recesses between two twisted together filling elements in the form of cordels, as well as the placement of cores for the transmission of electrical power in the first winding of bundles of threads of the load-bearing element instead of the core of the prototype made central shielded pair, on top of which a layer of copper core insulated with polyethylene and filling elements is laid (in the amount of four cordels and polyethylene filling with a central symmetrical pair), allows to reduce the weight and size characteristics of the cable, reduce its diameter by 15-20%, and increase the resistance to rewinding, which will increase the operational reliability of the cable;

- the execution of the load-bearing element in the form of tows of high-strength threads, laid on top of the conductive elements (instead of the central cable of the analog) allows you to protect the veins from possible external mechanical damage, acting as an armor cover;

- the implementation of the separating element in the form of a winding tape between the core (a symmetrical pair and twisted corners) and a shield in the form of a braid increases the operational reliability of the cable, in particular, increasing its flexibility due to the low coefficient of sliding friction.

Cordels can be made 1.3-1.5 times larger in diameter than insulated conductors for transmitting communication signals.

In the cable, the filling elements can be made in the form of corps of polyethylene with reinforcing synthetic thread, which increases the cable resistance to crushing and additionally protects the wires of the symmetrical pair from possible tensile loads.

The proposed utility model is schematically shown in the figure, where 1 is a conductive core; 2 - core insulation; 3 - filling elements in the form of cordels; 4 - reinforcing synthetic thread, 5 - fastening element; 6 - screen; 7 - fastening element; 8 - inner shell; 9 - a load-bearing element of two types of high-strength threads; 10 - insulated conductors in the first coil of a load-bearing element; 11 - a protective polymer shell.

A load-carrying cable for underwater operations, including at least two insulated conductive cores 10 for transmitting electrical power,

one shielded pair of insulated conductors 1 for transmitting communication signals, twisted in the core, filling elements 3, a fastening element 5, 7, an inner shell 8, a load-bearing element 9 in the form of two mutually opposed strands of high-strength strands of strands and a protective shell 11 of elastic polymer material. The core is made of two insulated conductive conductors 1 located in the recesses between two filler elements 3 twisted together, made in the form of cordels having a diameter larger than the mentioned insulated conductors 1, and the conductors 10 for transmitting electrical power are placed between bundles of threads of the first layer load-bearing element 9 in diametrically opposite places.

Example. The load-carrying cable for underwater operations (Fig.) Contains a core that has a symmetrical pair in the form of two copper insulated conductors 1 with a cross section of 2 × 0.35 mm ² located in the recesses between two twisted together corbels 3. The corbels 3 are extruded from polyethylene with reinforcing synthetic thread 4 and each has a diameter of 1.3 times that of the insulated core 1. Screen 6 is made in the form of a braid of copper wires with a density of 90%. Under the screen 6 and on top of it is attached a fastening element 5, 7, made in the form of a winding of polyethylene terephthalate tape with overlapping. The core is coated with an inner shell 8 extruded by extrusion. The load-bearing element 9 is superimposed on the core in the form of two mutually opposite windings of aramid strands, and between the bundles of threads of the first winding of the load-bearing element 9, two insulated copper conductors 10 with a cross-section of 0.35 mm ² are diametrically opposed to transmit electrical power. The protective shell 11 is made of abrasion resistant thermoplastic polyurethane.

Claims (3)

1. A load-carrying cable for underwater operations, including at least two insulated conductive cores for transmitting electrical power, one shielded pair of insulated cores for transmitting communication signals, twisted in the core, filling elements, a fastening element, an inner sheath, a load-carrying element in the form of two mutually opposite coils of high-tensile strands of tows and a protective sheath made of an elastic polymer material, characterized in that the core is made of two insulated conductive wires, arranged decomposition in the recesses between the twisted together elements filling, constructed as Cordeel having a diameter greater than said insulated conductors, and the conductors for transmitting electrical power are placed between the filament bundles of the first helix load-bearing element in diametrically opposite positions. 2. The cable according to claim 1, characterized in that the cordes are made with a diameter greater than 1.3-1.5 times that of the isolated conductors for transmitting communication signals. 3. The cable according to claim 1, characterized in that the corps are made of polyethylene with reinforcing synthetic thread.