RU126502U1 - OPTOELECTRIC CABLE - Google Patents

Abstract

1. Optoelectric cable containing placed in its outer insulating sheath, at least one conductive core coated with an insulating material, and at least one fiber optic core containing at least one optical fiber, characterized in that at least one reinforcing element, made in the form of twisted wire ropes, is introduced, while the fiber optic core is made in the form of an optical fiber placed in a protective sheath filled with a hydrophobic, and the reinforcing element is not directly adjacent to a conductive core containing a conductor coated with an insulating material, and to a fiber optic core. 2. The optoelectric cable according to claim 1, characterized in that it comprises one conductive core coated with an insulating material, one fiber optic core and one reinforcing element. The optoelectric cable according to claim 1, characterized in that it comprises one conductive core coated with an insulating material, one fiber optic core and two reinforcing elements. The optoelectric cable according to claim 1, characterized in that the reinforcing element contained therein is made in the form of seven groups of wire wires adjacent to each other and twisted together, each of which contains six strands of wire wires adjacent to each other. The optoelectric cable according to claim 1, characterized in that the reinforcing element contained in it is made in the form of six adjacent to each other and twisted together groups of wire ropes, each of which contains six adjacent strands of wire ropes, and between six adjacent

Description

The utility model relates to cable technology and can be used to create optoelectric cables (OEC) for communication and information transmission systems, in particular, for video surveillance and security systems, when, along with the transmission of a large amount of video information, there is a need to transmit power supply cables for one cable nodes and elements of video systems.

Known cable containing a steel tube, located inside it, at least one optical fiber with a protective polymer coating and a hydrophobic filler, moreover, the tube is made in the form of coils of preformed steel wires, or strands with a multiplicity of coils of no more than 10, and the cable is equipped with an external polymer sheath [RU 56007, U1, G02B 6/44, H01B 7/00, 08/27/2006].

The disadvantage of this design is the relatively narrow functionality, since such a cable contains an optical fiber that allows you to transmit an optical signal through a cable, for example, in video surveillance and security systems, but the absence of an electrical conductor does not allow you to simultaneously transmit cable power to nodes and elements of video systems.

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

The disadvantage of the closest technical solution is the relatively low resistance to the effects of possible significant mechanical and temperature influences that arise both during its manufacture and during operation, for example, in immersion systems. This is due, in particular, to the fact that one or more flexible steel armored small-sized optical fiber cables are used, made in the form of 6 twisted preformed wire ropes or strands of wires forming a free channel in the center in which one or more optical fibers are located. Optical fibers and wire rope have significant differences in temperature coefficients, which, with significant temperature changes, can lead to damage to optical fibers or deterioration of their characteristics. In addition, when trying to increase the mechanical strength of the cable through the use of stiffer wire ropes, their significant mechanical effect on the optical fibers is possible, and when using soft wire ropes, an unacceptable mechanical effect on the optical fibers in the places of cable bending is possible.

The purpose of the technical improvement of the known technical solution is to increase the resistance of the cable to mechanical and thermal influences.

The required technical result is to improve the design of the cable to provide greater resistance to mechanical and thermal influences.

The required technical result is achieved in that a cable containing at least one conductive core coated with an insulating material and at least one fiber optic core containing at least one optical cable, placed in the outer insulating sheath of the cable fiber, at least one reinforcing element is introduced, made in the form of twisted wire ropes, while the fiber optic core is made in the form of an optical fiber placed in a protective sheath filled with a hydrophobic, and yayuschy member directly adjacent to the current-carrying conductor comprising a conductor coated with an insulating material, and a fiber-optical core.

In addition, the required technical result is achieved in that the cable contains one conductive core coated with an insulating material, one fiber optic core and one reinforcing element.

In addition, the required technical result is achieved in that the cable contains one conductive core coated with an insulating material, one fiber optic core and two reinforcing elements.

In addition, the required technical result is achieved in that the reinforcing element is made in the form of seven adjacent to each other and twisted together groups of wire ropes, each of which contains six adjacent strands of wire ropes.

In addition, the desired technical result is achieved in that the reinforcing element is made in the form of six adjacent to each other and twisted together groups of wire ropes, each of which contains six adjacent strands of wire ropes, and, between six adjacent to each other and twisted together groups of wire wires placed at least one optical fiber.

In addition, the required technical result is achieved in that the cable contains two conductive cores coated with an insulating material, and one reinforcing element made in the form of six adjacent to each other and twisted together wire rope groups, each of which contains six adjacent to each other strands of wire ropes to each other, and between six adjacent to each other and twisted together groups of wire ropes is at least one optical fiber.

In addition, the required technical result is achieved in that the cable contains two conductive wires coated with an insulating material, and two reinforcing elements made in the form of six adjacent to each other and twisted together wire rope groups, each of which contains six adjacent to each other strands of wire ropes, moreover, between six adjacent to each other and twisted together groups of wire ropes is at least one optical fiber.

In addition, the required technical result is achieved by the fact that, on top of the outer insulating sheath of the cable, an armored sheath is made.

In addition, the required technical result is achieved in that the reinforcing element is placed in the insulating shell of the reinforcing element.

In addition, the required technical result is achieved in that the space inside the outer insulating sheath of the cable between at least one conductive core, at least one fiber optic core and at least one reinforcing element is filled with a hydrophobic.

The drawing shows:

figure 1 - optoelectric cable, a variant with one conductive core, one fiber-optic core and one reinforcing element;

figure 2 - optoelectric cable, an option with two conductive cores and one reinforcing element containing optical fibers;

figure 3 - optoelectric cable, an option with two conductive cores and one reinforcing element containing optical fibers, the insulating shell of the reinforcing element.

figure 4 - optoelectric cable, an option with two conductive cores and two reinforcing elements containing optical fibers;

figure 5 - optoelectric cable, a variant of the cable with an armored sheath, with two conductive cores and one reinforcing element containing optical fibers;

figure 4 - optoelectric cable, a variant of the cable with an armored sheath, with two conductive cores and two reinforcing elements containing optical fibers.

The drawing shows: a reinforcing element 1, a fiber optic core 2 containing an optical fiber 3 placed in a hydrophobic protective sheath 4 of a fiber optic core, a conductive core 5 containing a conductor 6 coated with an insulating material 7, an insulating sheath 8 of the reinforcing element, an outer insulating sheath 9 of the optoelectric cable, an armored sheath 10 made on top of the outer insulating sheath 9 of the optoelectric cable.

Moreover, the optoelectric cable contains at least one conductive core 5, containing a conductor 6, covered with an insulating material 7, at least one fiber optic core 2, containing at least one optical fiber 3 and at least , one reinforcing element 1, made in the form of twisted wire ropes.

In the optoelectric cable, the fiber-optic core 2 is made in the form of an optical fiber 3, placed in a protective sheath 4 filled with a hydrophobic, and the reinforcing element 1 is directly adjacent to the conductive core 5 containing the conductor 6 coated with an insulating material 7, and to the fiber-optic core 2.

Preferred options for the optoelectric cable suggests that it contains one conductive core 5, one fiber optic core 2 and one reinforcing element 1.

In addition, the optoelectric cable may contain one conductive core 2, one fiber optic core 2 and two reinforcing elements 1.

The reinforcing element 1 can be made in the form of seven adjacent to each other and twisted together groups of wire ropes, each of which contains six adjacent strands of wire ropes. A combined embodiment of the reinforcing element 1 is also possible when it is made in the form of six adjacent to each other and twisted together wire rope groups, each of which contains six adjacent strands of wire rope, and, between six adjacent and twisted between themselves groups of wire wires placed at least one optical fiber 3.

The optoelectric cable may contain two conductive cores 2 and one reinforcing element 1, made in the form of six adjacent to each other and twisted together groups of wire ropes, each of which contains six adjacent strands of wire ropes, and, between six adjacent to each other each other and twisted together groups of wire wires placed at least one optical fiber 3.

In addition to the above preferred embodiments of the optoelectric cable, it can contain two conductive cores 5 and two reinforcing elements 1, made in the form of six adjacent to each other and twisted together groups of wire ropes, each of which contains six adjacent strands of wire ropes, and , between six adjacent to each other and twisted together a group of wire ropes placed at least one optical fiber 3.

It is also possible that the optoelectric cable is constructed when an armored sheath 10 is made over its outer insulating sheath 9, the reinforcing element 1 is placed in the insulating sheath 8, and the space inside the outer insulating sheath 9 is filled with a hydrophobic.

All nodes and elements of the proposed optoelectric cable are standard elements of electrical and communication technology and do not raise doubts about the possibility of their implementation ..

An optoelectric cable is used as follows.

The cable has high tensile, crushing, flexibility and temperature differences, therefore, it can be used under various laying conditions, for example, when installing video surveillance and security systems.

In the embodiment of FIG. 1, the reinforcing element 1 is adjacent to the conductive core 5 and the fiber optic core 2, but direct contact with the conductor and the optical fiber is excluded. Therefore, significant differences in the temperature coefficients of the optical fiber and the conductor relative to the wire rope with significant temperature changes reduces the possibility of damage to the optical fibers or deterioration of their characteristics. In addition, while increasing the mechanical strength of the proposed optoelectric cable due to the use of stiffer wire ropes in the reinforcing element, the proposed cable design reduces the mechanical effect on optical fibers, as well as the use of soft wire ropes in places of bending of the cable.

The embodiment of FIG. 2 allows the use of two conductive conductors, which is important for the respective use cases of the optoelectric cable, in particular in video surveillance and security systems. The embodiment of figure 3 allows to reduce the mutual influence of the reinforcing element on the conductive wires through the use of an insulating sheath at the reinforcing element. When using the variant of figure 4, it becomes possible, when using two conductive cores, to strengthen the optoelectronic cable through the use of two reinforcing elements while increasing the number of optical fibers used. The options of figure 5 and figure 6. They can significantly improve the strength characteristics of the optoelectric cable through the use of an armored sheath.

Thus, due to the proposed design of the optoelectric cable, the desired result is achieved, which consists in increasing the resistance of the cable to mechanical and thermal influences, since in the main version of the cable direct contact of the conductor with the optical fiber is excluded. Therefore, significant differences in the temperature coefficients of the optical fiber and the conductor relative to the wire rope with significant temperature changes reduces the possibility of damage to the optical fibers or deterioration of their characteristics. In addition, if it is necessary to increase the mechanical strength of the proposed optoelectric cable, for example, due to the use of stiffer cable wires in the reinforcing element, the proposed cable design reduces the mechanical effect on optical fibers at the points of cable bending, as if it is necessary to use soft cable wires.

Claims (10)

1. Optoelectric cable containing placed in its outer insulating sheath, at least one conductive core coated with an insulating material, and at least one fiber optic core containing at least one optical fiber, characterized in that at least one reinforcing element, made in the form of twisted wire ropes, is introduced, while the fiber optic core is made in the form of an optical fiber placed in a protective sheath filled with a hydrophobic, and the reinforcing element is not directly adjacent to a conductive core containing a conductor coated with an insulating material, and to a fiber optic core. 2. The optoelectric cable according to claim 1, characterized in that it contains one conductive core coated with an insulating material, one fiber optic core and one reinforcing element. 3. The optoelectric cable according to claim 1, characterized in that it contains one conductive core coated with an insulating material, one fiber optic core and two reinforcing elements. 4. The optoelectric cable according to claim 1, characterized in that the reinforcing element contained in it is made in the form of seven adjacent to each other and twisted together groups of wire ropes, each of which contains six adjacent strands of wire ropes. 5. The optoelectric cable according to claim 1, characterized in that the reinforcing element contained therein is made in the form of six adjacent to each other and twisted together groups of wire ropes, each of which contains six adjacent strands of wire ropes, and between six At least one optical fiber is placed adjacent to each other and twisted together by wire rope groups. 6. The optoelectric cable according to claim 1, characterized in that it contains two conductive cores coated with an insulating material, and one reinforcing element made in the form of six adjacent to each other and twisted together groups of wire ropes, each of which contains six adjacent strands of wire ropes to each other, and between six adjacent to each other and twisted together groups of wire ropes is at least one optical fiber. 7. The optoelectric cable according to claim 1, characterized in that it contains two conductive conductors coated with an insulating material, and two reinforcing elements made in the form of six adjacent to each other and twisted together wire rope groups, each of which contains six adjacent strands of wire ropes to each other, and between six adjacent to each other and twisted together groups of wire ropes is at least one optical fiber. 8. The optoelectric cable according to claim 1, characterized in that an armored sheath is made over its outer insulating sheath. 9. The optoelectric cable according to claim 1, characterized in that the reinforcing element contained therein is placed in the insulating sheath of the reinforcing element. 10. The optoelectric cable according to claim 1, characterized in that the space inside the outer insulating sheath of the cable between at least one conductive core, at least one fiber optic core and at least one reinforcing element is filled with a hydrophobic.

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