RU2363062C1 - Optical communication cable - Google Patents

Abstract

FIELD: communication facilities.

SUBSTANCE: invention relates to the area of electric engineering; it can be used in makeups of optical cables while laying optical fibre communication lines. Known makeup of optical cable contains optical fibres in polymer ribbons, hydrophobic filler, module, main reinforcing element in this module, the first auxiliary load-bearing element in outer polymer sheath, waterproof ribbon and two cords tearing outer sheath, which are located close to module peaks and marked at surface of outer sheath as protrusions. Module is made of "Э"-shape for the purpose of easy opening of optical core, removal of optical fibres, significant risk reduction of moisture penetration to optical fibres, reduction of recovery time in case of optical cable damage and moisture penetration during optical cable repair. Middle peak divides module into two chambers and two edge peaks are connected with middle one; waterproof ribbon is located inside inner surface of outer sheath with edge overlapping over the second load-bearing element, which is located over middle peak of "Э"-shaped module and connection of two edge peaks at middle peak.

EFFECT: easy opening of optical core, removal of optical fibres, significant risk reduction of moisture penetration to optical fibres, reduction of recovery time in case of optical cable damage and protection from moisture penetration during optical cable repair.

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Description

The invention relates to the field of electrical engineering and can be used in the construction of optical communication cables in the construction of fiber-optic communication lines.

Known design of the optical cable (OK) for laying in pipes and collectors with a centrally located module (Book D.V. Iorgachev, O.V. Bondarenko, A.V. Dashchenko, A.V. Usov. Fiber optic cables. Odessa: Astroprint, 2000; 536 p., P. 155, Fig. 3.32). It contains a module tube, power elements in a polymer shell - a protective hose made of polyethylene, a water blocking tape over the module tube and a tape with optical fibers placed in the central module.

The disadvantages of this design are the inaccessibility to optical fibers (OV) when OK is damaged and its operation without damage and opening of all cable elements and, hence, a long time to repair cable damage.

The well-known design of OK ZAO Moskabel-Fujikura with a single-module optical core with a central module of a tubular type (Reference "Optical Communication Cables of Russian Production", A.S. Vorontsov, O.I. Gurin, S.Kh. Miftyakhetdinov, K.K. Nikolsky, S.E. Piterskikh, M .: Eco-Trends, 2003, 285 p., Fig. 4.10, p. 98).

The design contains optical fibers in a hydrophobic filler in a central polymer tube, corrugated steel armor, and steel wires in an outer polyethylene sheath.

The disadvantages of this design are the complexity of access to optical fibers in case of damage to the cable and during its operation, as well as a long time to repair cable damage.

The closest in technical essence is the design of the optical cable (International Wire and Cable Symposium. Proceedings of the 56 ^th IWCS, 2007, fig. 1, p. 225. Ken Osato, Yoshio Hashimoto, Naoki Okado. New design of optical fiber cable for easy mid-span access, p.225-229), containing optical fibers in polymer tapes, hydrophobic aggregate, C-shaped module, the main reinforcing element in this module, an additional power element in the outer polymer coating, a water blocking tape and two tearing cord cords, located symmetrically relative to each other. Closer to the tops of the C-shape of the module are two protrusions that change the circular shape of the cable, indicating the location of two cords breaking the outer shell. This optical cable design eliminates some of the disadvantages, i.e. gives access to damaged fiber.

The disadvantages of this design are the possibility of moisture penetration to all optical fibers due to the removal of the cover with a water-blocking tape of the C-shape of the module, if necessary, access to the optical fibers and also a sufficiently long time to repair the damage of the organic matter in the OK, although less than in analogs.

The objective to which this technical solution is directed is to create such a design of an optical communication cable that will not only easily open the optical core and get one of the optical fibers, but also significantly reduce the risk of moisture penetrating the optical fibers, and reduce the time to repair damage and to protect optical fibers as much as possible from moisture penetration during OK repair on OV.

To solve this problem, an optical communication cable containing optical fibers in polymer tapes, a hydrophobic filler, a module, the main reinforcing element in this module, an additional power element in the outer polymer coating, a water blocking tape and two tearing the outer sheath of the cord, located symmetrically relative to each other closer to the top of the module and marked on the outer surface of the outer polymer shell in the form of protrusions, in contrast to the prototype, the module is made in the form of an E-form of the module, where I vertex divides the module into two chambers, and the two extreme vertices are joined with the middle vertex, and the water blocking tape is located on the inner surface of the outer shell with overlapping edges above the second additional force element located above the middle vertex of the E-module and fixing its two extreme vertices on the middle top.

Figure 1 shows the design of the optical cable. It contains optical fibers 1 in polymer tapes 2, hydrophobic filler 3, E-form module 4, two cameras of a two-chamber E-form module 5, the main reinforcing element 6 in this E-form module, the first additional power element 7 in the outer polymer coating ( shell) 8, a water blocking tape 9, located along the entire length of the inner section of the outer shell 8, a second additional power element above the middle peak of the E-shape of the module 10, two tearing the outer shell of the cord 11, located symmetrically closer to each other to the tops of the E-form of the module, and two protrusions 12, indicating the location of two cords breaking the outer shell.

As a result, in case of OB failure in the cable, with the help of cords, the location of which is indicated by protrusions on the outer surface of the outer shell, the upper part of the cable is opened in the area determined by the measurements, and the upper part of this shell is removed, the water blocking tape is opened, the second additional power element is lifted, fixing two extreme peaks on the middle peak of the E-form of the module, and one of the chambers of the E-form of the module opens, in which the damaged fiber is located, a damaged tape with a damaged wave knom is performed in a tape replacement OB, is set in place and closes the open chamber module E-shape is lowered to place the second further power element locking the extreme vertices E-shaped module to the central top closed water blocking tape, and recovering the outer shell. This allows you to speed up the process of restoring the operational efficiency of the exhaust agent without disconnecting the line and without moisture entering the OK in one of the chambers of the module’s E-shape due to the presence of a water blocking tape in the inner surface of the cable’s outer coating, hydrophobic filler, and speed of restoration work.

Claims (1)

An optical communication cable containing optical fibers in polymer tapes, a hydrophobic filler, a module, the main reinforcing element in this module, the first additional power element in the outer polymer coating, a water blocking tape and two tearing outer sheaths of the cord, which are located symmetrically relative to each other closer to the tops module and marked on the outer surface of the outer shell in the form of protrusions, characterized in that the module is made in the form of an E-form of the module, where the middle vertex divides the module into two amers, wherein the two outer vertices are joined with average apex and water blocking tape is disposed on the inner surface of the outer shell with overlapping edges of the second auxiliary power element which is disposed above the middle vertex of the E-shaped unit and above the connection of the two extremes of its vertices on the middle vertex.