RU2228568C2 - Y-splice box for branching low-frequency conductors from combined copper-optical communication cable passing transit optical fibers and high-frequency copper conductors - Google Patents

Abstract

FIELD: subsurface laying of combined copper-optical communication cables. SUBSTANCE: proposed Y-splice box designed for branching low-frequency conductors of combined cable at its nonsplit factory length by means of additional low-frequency copper- conductor communication cable has split paronite body accommodating splices of low-frequency copper conductors in polyethylene insulating sleeves; connectors installed in body on aluminum- polyethylene sheath of branching-off cable with low-frequency conductors and on aluminum- polyethylene sheath of input and output sections of combined communication cable which are joined together by means of at least one copper wire or sheet aluminum buses, best of 2.5 mm in thickness; within box aluminum foil is wound on splices of conductors, optical fibers, copper conductors, and sections of aluminum-polyethylene sheaths of cables carrying connectors. EFFECT: enlarged functional capabilities and enhanced mechanical strength of box in subsurface cable laying. 3 cl, 13 dwg

Description

The invention relates to underground laying of a combined copper-optical communication cable and is designed to branch at least part of the low-frequency conductive wires from the combined cable on its uncut construction length using an additional low-frequency communication cable with copper conductors to ensure the transit of optical fibers and high-frequency conductive veins of the combined cable.

Designs of combined communication cables for both air laying (suspension on supports) and underground laying have been developed and are produced with the aim of obtaining the economic effect of replacing three cables: a fiber-optic cable, a high-frequency communication cable with copper conductors with a diameter of 1.05 mm and a low-frequency communication cable with copper conductors with a diameter of 0.7 mm.

The connection of the construction lengths of the combined cables, manufactured in lengths of 1200 m, is carried out in couplings with the connection of both insulated copper conductors and with the splice of optical fibers (OB) of the optical segment of the combined cable.

A device for splicing combined aerial cables with copper conductive cores and optical fibers [1] containing a housing in which splices of optical fibers and splices of conductive conductors are located.

The disadvantage of this device is the inability to branch conductive conductors and insufficient mechanical strength when laying the coupling in the ground.

Known coupler for conductive cables [2], providing a separation of conductive conductors into two channels.

Known branch couplings for fiber optic cable [3], [4], designed for branching part of the optical fibers and the transit passage of the remaining optical fibers, comprising a housing in which splices of optical fibers and means for attaching optical fibers to the housing are located.

However, when operating existing lines, it is often necessary to make branches in some place of the building length (for example, in the middle of 1200 m) of the combined cable and, most often, it is necessary to branch only with a low-frequency cable for communication with copper conductors without cutting the optical segment (optical fibers ) and without opening the high-frequency conductors (fours) of the combined cable.

The objective of the invention is to expand the functionality of the device by providing the possibility of branches of low-frequency conductive wires from a combined (copper-optical) communication cable with the transit of optical fibers and conductive high-frequency copper conductors, as well as increasing the mechanical strength of the coupling during its underground laying.

The specified technical result is achieved by the fact that the branching sleeve for the combined communication cable with the branching of at least part of the low-frequency conductive copper conductors and the transit passage of optical fibers and high-frequency conductive copper conductors contains lead made of lead with a soldered longitudinal seam and splices of low-frequency conductive located in the housing copper conductors in insulated polyethylene sleeves, while the aluminum sheath of the branch cable from the conductors low-frequency conductors and the aluminum sheath of the combined communication cable in the areas located at the ends of the housing are tinned, while the tinned sections of the aluminum cable sheaths are soldered to the ends of the housing to ensure electrical contact between the aluminum sheath of the combined cable and the aluminum sheath of the branch cable, with the restoration of the polyethylene cable sheaths located on top of their aluminum shells, made by winding the body and adjacent aluminum shells cable check with mastic tape with their overlap and several layers of PVC tape.

When using cables without armor cover, the case and adjacent cable sections are located in a heat-shrinkable sleeve, on which a protective coating of a moisture-curing bandage is made.

In the particular case of the coupling, the protective coating of the moisture-curing bandage is made with 50% overlap of the bandage in two layers.

When using cables with armored covers, the electrical contact between the armored covers of the cables is made in the form of a copper insulated wire located on the outside of the casing, soldered to the tinned sections of steel tapes of the armored covers of cables, and the soldering places are sealed by wrapping them with mastic tape and PVC tape with access to the outer polyethylene sheath of the cables, and the housing and adjacent cable sections are located in a cast-iron sleeve with a gap filled with self-curing polyurethane sealant.

According to the second embodiment, the technical result is achieved in that the branching sleeve for the combined communication cable with branching at least part of the low-frequency conductive copper conductors and the transit passage of optical fibers and high-frequency conductive copper conductors contains made of insulating material, for example paronite, a detachable housing and located in the case, splices of low-frequency conductive copper cores in insulated polyethylene sleeves, while in the case on aluminum the polyethylene sheath of the branch cable with conductive low-frequency conductors and the aluminum-polyethylene sheath of the input and output sections of the combined communication cable have connectors connected to each other by at least one copper wire or busbars made of aluminum sheet, preferably 2.5 mm thick, and in the case over the splices of conductive wires , optical fibers, conductive copper conductors and sections of aluminum-polyethylene cable sheaths with connectors made of aluminum foil ice, and the case and adjacent cable sections are located in a heat-shrinkable sleeve, which is made of a moisture-curing bandage protective coating, or in a cast-iron sleeve with a gap filled with self-curing polyurethane sealant.

The moisture-curing bandage protective coating is preferably made with a 50% overlap of the bandage in two layers.

The invention is illustrated in FIG. 1-13.

Figures 1 and 7 show the cuts, respectively, of a combined cable with an aluminum sheath and an outer polyethylene hose (sheath) and a combined armored cable with an aluminum sheath.

Figures 2 and 8 show the connection of the low-frequency cores of the main combined cable with the pairs of the branch cable and shows the transit passage of uncut high-frequency copper cores and optical fibers in the modular tubes of the optical segment of the combined cable.

Figure 3 and 9 shows the restoration of the electrical contact of the connected ends of the aluminum shell by hot soldering of a longitudinally split lead body and the longitudinal sealing of the sections of the outer polyethylene sheath (hose).

Figures 4, 10 and 11 show the restoration of an insulating cover with a lead casing by winding it and wrapping bare sections of an aluminum shell with mastic MG 14-16 and PVC insulating tape.

In FIG. Figure 5 shows the installation of an “unseated” heat-shrink sleeve type XAGA SLVP with a branch clamp type BOCL.

In FIG. Figure 6 shows the protection of the mounted housing by wrapping it with a moisture-curing bandage, for example, Armoplast.

In FIG. 12 shows a sleeve in which screen integrity has been restored using aluminum screen shields and connectors.

In FIG. 13 shows an insulated coupling sleeve of an armored combination cable mounted in a cast-iron protective sleeve.

Mortise coupler with one input and two outputs (in two directions) is mounted on a combination cable, the designs of which can be different, and this cable is the main cable 1, from which at least part of the low-frequency conductive conductors is tapped using a branch cable 2 with low-frequency conductive wires. Both cables 1 and 2 have an external polyethylene hose 3, under which, depending on the type of combination cable, there is a screen made of aluminum tape (aluminum-polyethylene sheath), aluminum sheath 4 or armored sheath 5 of the cable.

Before mounting the junction box, the main cable 1 is cut up with the core 6 of the cable opened and at least part of the low-frequency conductive cores 7 are prepared for their splicing with the cores 8 of the branch cable 2.

A junction box made on the main armored combined cable 1 with an aluminum sheath 4 and a standard core including optical fibers, high-frequency fours with copper conductors with a diameter of 1.05 mm, low-frequency pairs of 7 copper conductors with a diameter of 0.7 mm, contains: in transit passing in the clutch (without cutting) optical fibers and high-frequency fours 6 copper conductors with a diameter of 1.05 mm, branch cable 2, insulated copper conductors 8 of which are connected, for example, by twisting with cut copper conductors low frequency pairs of the main cable and are insulated with polyethylene sleeves 9 (intergrowths of copper cores), while the aluminum sheath 4 is restored using a longitudinally split lead body 10 with a longitudinally sealed seam 11, which is soldered at its ends 12 to the exposed and pre-tinned ends of the aluminum shells 4 of the main 1 and branch 2 cables. An insulated coating 13 is made on the sealed case 10 by wrapping its outer surface with a mastic tape MG 14-16 and then with a PVC tape. The electrical contact between the armored covers of cable 1 at its input and output and branch cable 2 is restored by sequential soldering to pre-tinned steel tapes of the armored cover 5 of cable 1 (cable 1 is soldered in areas located next to each end of housing 10) and 2 copper insulated wires 14 with a cross section of 4 mm ² , and the solder points are insulated (sealed) with adhesive insulating tapes MG 14-16 and PVC tape 13 with a call to the outer polyethylene sheath of the cables. In order to protect against mechanical damage, the lead casing 10 mounted and insulated with tapes 13 is mounted in a protective cast iron casing 16, while the space between the outer surface of the lead casing 10 and the inner surface of the protective casing 16 is filled with self-hardening polyurethane sealant 17.

When the junction box is made on a combination cable 1 without armor, i.e. on a cable with an aluminum sheath 4 and an outer polyethylene hose 3, then in this case, along with the transit of passing high-frequency fours of copper conductors 6, the optical fibers in the modules of the optical segment 6 and intergrowths of low-frequency copper conductors 9 with the conductors of the branch cable 2, contains soldered on the tinned ends of the aluminum sheath, a lead case 10 with an insulating cover 13 of MG 14-16 tapes and PVC tapes located on the case 10 and adjacent cable sections 1 and 2 of a heat-shrink sleeve 18, for example, of the XAGA SLVP type, unless pheno- clamp 19, for example, type BOCL, mounted in a heat-shrinkable cuff 18 outlet between the outer shell composite cable 1 and cable 2 branching, the protective coating vlagootverdevayuschim bandage 20, for example Armoplast formed on a heat-shrinkable cuff 18.

In another embodiment of the invention, when the coupling is made on a combination cable 1 without armor and without an aluminum sheath, but only with an aluminum-polyethylene sheath 21, the electrical integrity of the screen (i.e., aluminum-polyethylene sheaths) is restored by installing screen connectors 22 on the aluminum-sheaths of the cable sheaths to which the shield wires 23 are attached using at least one bus 24 connecting the aluminum-polyethylene sheaths of the combined cable 1 at the input and output, and at least one jumper 25 connecting aluminum-polyethylene sheaths of cables 1 and 2 at the output. The tire and bridge are made of sheet aluminum, preferably 2.5 mm thick. The protective properties of the screen in the coupling were restored using aluminum foil by wrapping the splice with foil of any thickness, but with a total thickness of the restored screen of at least 0.2 mm with overlapping screen connectors of 20 mm on both sides of the splice (not shown in the figures). A longitudinally split case made of paronite, for example, with cut petals at the edges of the case, is installed on top of the restored screen for a dense and smooth transition from splice to cable sheaths (not shown in the figures). A heat-shrinkable sleeve 18 is located on the housing. To give the coupling higher mechanical strength, a protective coating on the sleeve 18 is made with a moisture-curing bandage 20, for example, Armoplast or Armorkast.

Sources of information

1. US 5727100, cl. G 02 B 6/26, publ. 10.03. 1998.

2. WO 99/21259, cl. H 02 G 15/184, publ. 04/29/1999.

3. US 5121458, CL G 02 B6 / 26 publ. 06/09/1992.

4. US 5121458, CL G 02 B 6/36, publ. 06/09/1992.

Claims (3)

1. A junction box for a combined communication cable with branches at least part of the low-frequency conductive copper conductors and the transit passage of optical fibers and high-frequency conductive copper conductors, comprising a detachable housing made of insulating material and splices of low-frequency conductive copper conductors located in the housing in insulated polyethylene sleeves while in the case on an aluminum-polyethylene sheath, which is simultaneously a screen of a branch cable with a current conductive low-frequency conductors, and the aluminum-polyethylene sheath of the input and output sections of the combined communication cable, screen connectors are installed, connected to each other by at least one copper wire or sheet aluminum busbars and a jumper preferably 2.5 mm thick, and in the case on top of the conductive core splice, optical fibers, conductive copper conductors and sections of aluminum-polyethylene cable sheaths with shield connectors, winding was performed using aluminum foil, restoring The shield, the housing and the adjacent cable sections are located in a heat-shrinkable sleeve, on which a protective coating of a moisture-curing bandage is made, or in a cast-iron sleeve with a gap filled with self-curing polyurethane sealant. 2. The branch coupling according to claim 1, characterized in that the thickness of the winding of aluminum foil is at least 0.2 mm 3. A branch coupling according to claim 1 or 2, characterized in that the split housing is made of paronite.

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