RU52514U1 - FLOATING COMMUNICATION WIRE - Google Patents

Abstract

The utility model relates to the field of electrical engineering, namely to the design of special floating cargo wires, communication cables, designed for underwater operation in towing conditions with repeated bends and the effect of hydrostatic pressure.

The wire contains a core twisted from insulated conductive cores, a belt insulation, a reinforcing load-bearing element and a sheath. The core is made of an even number of conductive copper wires insulated with polyethylene twisted in pairs and / or four, the shell is made of a waterproof polymer material with a density of not more than 0.70 g / cm ³ , for example, of porous polyethylene, and a reinforcing load-bearing element is applied to the waist insulation in the form of coils of synthetic filaments or strands of filaments with a specific tensile strength of at least 1.8 N / tex, for example, of aramid filaments.

In the wire, the electrical parameters of the communication circuits (the level of signal attenuation, noise immunity between the circuits) are improved, the operational reliability of the wire is increased during rewinding under tension.

Description

The utility model relates to the field of electrical engineering, namely to the design of special floating cargo wires, communication cables, designed for underwater operation in towing conditions with repeated bends and the effect of hydrostatic pressure.

Known flexible floating cable type KGPVP, which contains a load-bearing element made of technical threads SVM, located in the center of the cable, several conductive steel-copper cores, insulated with polyethylene and twisted over the load-bearing element, a sheath of solid polyethylene (Specifications. TU 16-505.987-77 "Cables flexible floating ").

The specified cable (wire) has the following disadvantages:

- high resistance of conductive conductors to direct current and low frequency of transmitted signals (200 kHz), which is associated with the characteristics of steel-copper wires of the core;

- the centrally located load-bearing element during repeated cable rewinding through the rollers under tension during operation, deforms and further destroys the conductive conductors;

- insufficient buoyancy of the cable (± 20 g / m), since the sheath is made of solid polyethylene with a density of 0.92 g / cm ³ ;

- low operational reliability of the cable, since its buoyancy is ensured by air gaps between the core elements and when the outer shell is damaged, the cable is filled with water, i.e. loses buoyancy;

- there is no possibility of using a cable to transmit optical information signals.

The proposed utility model is based on the task of creating such a floating communication wire in which due to the introduction of new materials and structural elements, their new relative positions, the electrical parameters of the communication circuits (transmission frequency range, signal attenuation level, noise immunity between the circuits) would be improved operational reliability of the wire during rewinding under tension, as well as in case of emergency damage to the outer shell.

The problem is solved in that in a floating communication wire including a core twisted from insulated conductive cores, a belt insulation, a reinforcing load-carrying element and a sheath, in accordance with a utility model, the core is made of an even number of polyethylene insulated conductive copper cores twisted in pairs and / or four, the shell is made of a waterproof polymer material with a density of not more than 0.70 g / cm ³ , and a reinforcing load-bearing element is superimposed on the waist insulation (over the core) in the form threads of synthetic yarns or strands of threads with a specific strength at break of at least 1.8 N / tex.

The advantage of the proposed floating communication wire is as follows:

- the implementation of conductive conductors of copper wires reduces the attenuation of communication signals and extends the range of transmission frequencies;

- limiting the maximum density of the sheath material is due to the fact that at a density of more than 0.70 g / cm ^{3 the} necessary buoyancy of the wire is not provided;

- the implementation of the load-bearing element in the form of coils of high-strength lightweight synthetic threads, laid on top of the belt insulation of the core allows you to unload conductive

cores from crushing deformations, i.e. significantly increase the operational reliability of the wire.

Insulated cores can be twisted into pairs, and pairs twisted together with a pitch of no more than 23 mm, and the directions of twisting of the cores in a pair and pairs are mutually opposite, which significantly increases the noise immunity of the transmission circuits due to the small twisting pitch.

The cores can also be twisted into four, and the diameter for insulation of two mutually opposite cores refers to the diameter for insulation of two other cores as 2.2: 1.5, which allows you to get two circuits in one core that differ from each other in electrical transmission parameters - wave resistance, electric capacitance, attenuation coefficient, which in some cases is required by operating conditions.

Pairs of insulated cores can be twisted together with an additional optical module containing 3-5 optical single-mode fibers with a pitch of not more than 110 mm. The introduction of an additional optical module with several optical single-mode fibers into the core allows the use of a floating wire in modern information transfer systems.

The sheath of the floating wire can be made of a polymeric material based on porous polyethylene, which provides the required supply of positive buoyancy of the wire, including during emergency damage to the sheath during operation.

The belt insulation under the load-bearing element can be made in the form of an extruded polyethylene sheath and / or in the form of a winding with synthetic tapes that fasten the core from conductive veins and create a reliable base (pillow) for the reinforcing load-bearing element.

Synthetic threads for the reinforcing load-bearing element can be made of aramid fiber, which provide

the best combination of "tensile strength - weight" of the load-bearing element. A minimum weight is required to ensure the buoyancy of the wire.

The proposed wire is schematically shown in cross section in the drawings (Fig.1-3). In Fig. 1, a wire is given with two pairs of insulated cores twisted into a core. Figure 2 is given a wire twisted into a four of insulated cores of different diameters. Figure 3 shows a wire in which pairs of insulated cores are twisted in with an additional optical module. In figures 1 - conductive core, 2 - insulation made of polyethylene, 3 - belt insulation, 4 - reinforcing load-bearing element, 5 - sheath, 6 - optical module.

The floating communication wire contains a core twisted of insulated conductive conductors 1, a belt insulation 3, a reinforcing load-carrying element 4 and a sheath 5. The core is made of an even number of 2 insulated conductive copper conductors 1 twisted in pairs and / or four, the sheath 5 is made of waterproof polymeric material with a density not exceeding 0.70 g / cm ³ and a reinforcing load-carrying member 4 is superposed on the insulation waist 3 in the form of coils of filament tows or yarns having a specific strength at break of not m it 1.8 N / tex.

Example. The floating communication wire has four conductive conductors with a cross section of 0.35 mm ² twisted from copper wires. Veins 1 are covered with insulation 2 of polyethylene and twisted in two pairs. The core is twisted of two pairs together with the optical module 6 in increments of 100 mm. The optical module 6 contains 3 optical single-mode fibers placed in a polymer shell with a hydrophobic filler. The core is covered with belt insulation 3 in the form of a shell made of polyethylene superimposed on an extrusion line. On top of the shell 3, two coils of a reinforcing load-bearing element 4 of aramid yarns with a specific strength of 1.8 n / tex are superimposed. Outer shell

5 is made of porous polyethylene with a density of 0.6 g / cm ³ and superimposed on an extrusion line.

Claims (7)

1. A floating communication wire containing a core twisted from insulated conductive cores, a belt insulation, a reinforcing load-carrying element and a sheath, characterized in that the core is made of an even number of polyethylene insulated conductive copper conductors twisted in pairs and / or four, the sheath is made of waterproof polymer material with a density of not more than 0.70 g / cm ³ , and a reinforcing load-bearing element is superimposed on the belt insulation in the form of coils of synthetic threads or strands of threads with specific strength at a break of at least 1.8 N / tex. 2. The floating communication wire according to claim 1, characterized in that the insulated conductors are twisted into pairs, and the pairs are twisted together with a pitch of no more than 23 mm, and the directions of twisting of the wires into pairs and pairs are mutually opposite. 3. The floating communication wire according to claim 1, characterized in that the insulated conductors are twisted into four, and the diameter for insulation of two mutually opposite conductors refers to the diameter for insulation of two other conductors as 2.2: 1.5. 4. The floating communication wire according to claim 1, characterized in that the insulated conductors are twisted into pairs, and the pairs are twisted together with an additional optical module, including from 3 to 5 optical single-mode fibers, with a pitch of not more than 110 mm. 5. The floating communication wire according to claim 1, characterized in that the sheath is made of a polymeric material based on porous polyethylene. 6. The floating communication wire according to claim 1, characterized in that the belt insulation is made in the form of an extruded sheath of polyethylene and / or in the form of a winding with synthetic tapes. 7. The floating communication wire according to claim 1, characterized in that the synthetic threads for the reinforcing load-bearing element are made of aramid fiber.