RU159553U1 - ELECTRICAL OPTICAL CABLE FOR AIR TRANSMISSION LINES - Google Patents

Abstract

1. Electro-optical cable containing twisted two phase and one zero insulated electrical conductors, as well as a fiber-optic core made in the form of twisted preformed steel wires forming a channel in which optical fibers are located, according to a utility model, the fiber-optic core is twisted together with two phase and one zero insulated electrical conductors, and the channel in which the optical fibers are located is filled with a hydrophobic compound. 2. A cable according to claim 1, characterized in that the electro-optical cable is coated with a cross-linked polyethylene sheath. 3. A cable according to claim 1, characterized in that the preformed steel wires have a diameter of 1.1 ... 1.35 mm with a temporary tensile strength of at least 1770 kg / mm. 4. The cable according to claim 1, characterized in that the fiber optic core is coated with a cross-linked polyethylene sheath. The cable according to claim 4, characterized in that the space between the twisted preformed steel wires and the sheath of cross-linked polyethylene is filled with an adhesive layer of sealant up to 0.2 mm thick.

Description

The utility model relates to cable technology and can be used mainly for cables used for suspension on poles of power lines.

Known cable [US 2011/0011617, A1, H01B 7/08, 01/11/2008] made of twisted together aluminum insulated wires of large cross section, moreover, the neutral conductor is made of hardened aluminum, including reinforced steel wires, and light-stabilized cross-linked polyethylene is used as a protective insulating sheath in such cables.

The disadvantage of this technical solution is the relatively narrow functionality, since when performing the function of transmitting electrical energy, the information transfer function is not provided.

In addition, a cable is known [RU 74004, U1, H01B 9/00, 06/10/2008], containing conductive conductors laid parallel in one plane or twisted together, coated with plastic or rubber insulation and enclosed in corrosion-resistant tape armor, with this, in the spaces between the cores one or more optical modules are laid, each of which is a bunch of fiber optic fibers placed inside the polymer sheath.

The disadvantage of this cable is its relatively low reliability.

The closest in technical essence to the proposed one is an electro-optical cable [RU 109907, U1, H01B 11/22, 10.27.2011], containing conductive conductors laid parallel in one plane or twisted together, coated with plastic insulation, and longitudinally laid non-woven tapes canvases enclosed in a corrosion-resistant tape armor, in this case, one or more flexible steel armored small-sized fiber-optic cables made in the form of 6 twisted preformed wires are introduced into the space between the veins wire ropes or strands of wire forming a free channel in the center, in which one or more optical fibers are located.

The features of the closest technical solution include the fact that preformed steel wire ropes or strands of wires have a diameter of 0.5 to 0.9 mm, providing resistance to static crushing and shock loads that occur during manufacturing, as well as that, flexible optical cables have heat-resistant and resistant to aggressive chemical environments insulation covering the armor coating with a thickness of less than 0.3 mm.

The disadvantage of the closest technical solution is the lack of stability and reliability under the influence of significant mechanical and temperature loads that arise during operation, for example, overhead lines for the joint transmission of electrical energy and information via an electro-optical cable. This is because conductive wires and flexible steel armored small-sized fiber-optic cables have different characteristics in terms of flexibility, deformation resistance, thermal expansion coefficients, etc.

The objective of the utility model is to increase the durability and reliability of the electro-optical cable.

The technical result achieved by the implementation of the utility model is to increase the resistance and reliability of the electro-optical cable.

The problem is solved, and the required technical result is achieved by the fact that, in an electro-optical cable containing twisted two phase and one zero insulated electrical conductors, as well as a fiber-optic core made in the form of twisted preformed steel wires forming a channel in which the optical fiber, according to the utility model, the fiber optic core is twisted together with two phase and one zero insulated electrical conductors, moreover, the channel in which the optic cal fibers filled with hydrophobic compound.

In addition, the required technical result is achieved in that the electro-optical cable is covered with a sheath of cross-linked polyethylene.

In addition, the required technical result is achieved in that the preformed steel wires have a diameter of 1.1 ... 1.35 mm with a temporary tensile strength of at least 1770 kg / mm ² .

In addition, the required technical result is achieved in that the fiber optic core is coated with a cross-linked polyethylene sheath.

In addition, the required technical result is achieved in that the space between the twisted preformed steel wires and the sheath of cross-linked polyethylene is filled with an adhesive layer of sealant up to 0.2 mm thick.

The utility model is illustrated by drawings:

in FIG. 1 - section of an electro-optical cable;

in FIG. 2 is an example of a structural embodiment of a fiber optic core.

The electro-optical cable contains twisted two phase 1 and one zero 2 insulated electrical conductors, as well as fiber-optic core 3.

Fiber optic core 3 in an electro-optical cable is made in the form of twisted preformed steel wires 4, forming a channel in which optical fibers 5 are located.

A feature of the electro-optical cable is that the fiber-optic core 3 is twisted together with two phase 1 and one zero 2 insulated electrical conductors, moreover, the channel in which the optical fibers are located is filled with a hydrophobic compound 6. In the proposed electro-optical cable, the preformed steel wires 4 mainly have a diameter of 1.1 ... 1.35 mm with a temporary tensile strength of at least 1770 kg / mm ² , the fiber optic core 3 is covered with a sheath 7 made of cross-linked polyethylene, and the space between twisted preformed steel wires 4 and a sheath of cross-linked polyethylene 7 are filled with an adhesive layer 8 of sealant with a thickness of up to 0.2 mm.

The electro-optical cable is manufactured and used as follows.

The manufacture of an electro-optical cable (Fig. 1) includes the process of manufacturing a fiber-optic core 3 in the form of twisted preformed steel wires 4 (for example, with a diameter of 1.1-1.35 mm with a temporary burst resistance of at least 1770 kg / mm ² ) forming a channel in which optical fibers 5 (for example, quartz fibers with a varnish coating with a diameter of about 250 microns), the production process of two phase 1 and one zero 2 isolated electrical conductors and their joint twisting. On top of the twisted preformed steel wires 4 are coated with an adhesive layer of heat-resistant sealant with a thickness of not more than 0.2 mm, also resistant to chemically aggressive environments, for example, fluoroplastic).

Crosslinked polyethylene can be used as the insulation of the optical cable. The electro-optical cable itself can also be coated with cross-linked polyethylene, which acts as a protective sheath. The strands are twisted on cage or towing machines, at the same time, at least one element must be unscrewed - fiber-optic strands.

Samples of the proposed electro-optical cable with a cross section of 16 mm ² conductors were made and its successful tests were carried out with the suspension on power transmission towers in a state equivalent to practical installation work and operation with increased tensile forces.

Thus, due to the improvement of the known device, namely, the fiber optic core is twisted together with two phase and one zero insulated electrical conductors, moreover, the channel in which the optical fibers are filled with a hydrophobic compound, the resistance and reliability are significantly increased under the influence of significant mechanical and temperature loads, since these loads affect the twisted core system, in which the emerging loads are distributed evenly between in veins, which compensates and softens sudden load changes, and the hydrophobic compound produces additional compensation and mitigation of the load.

Claims (5)

1. Electro-optical cable containing twisted two phase and one zero insulated electrical conductors, as well as a fiber-optic core made in the form of twisted preformed steel wires forming a channel in which optical fibers are located, according to a utility model, the fiber-optic core is twisted together with two phase and one zero insulated electrical conductors, and the channel in which the optical fibers are located is filled with a hydrophobic compound. 2. The cable according to claim 1, characterized in that the electro-optical cable is coated with a sheath of cross-linked polyethylene. 3. The cable according to claim 1, characterized in that the preformed steel wires have a diameter of 1.1 ... 1.35 mm with a temporary tensile strength of at least 1770 kg / mm ² . 4. The cable according to claim 1, characterized in that the fiber optic core is coated with a cross-linked polyethylene sheath. 5. The cable according to claim 4, characterized in that the space between the twisted preformed steel wires and the sheath of cross-linked polyethylene is filled with an adhesive layer of sealant up to 0.2 mm thick.

Images