RU201115U1 - Optical cable assembly - Google Patents

Abstract

The utility model relates to optical assemblies for multicore fiber optic cables. The technical result consists in providing the possibility of spatial separation of protected cores of a multicore fiber cable. This result is achieved by the fact that the device comprises a housing in the form of a heat shrink tube, in which a sleeve is installed, made in the form of an input sleeve, made with the possibility of enclosing and holding the input end of the multicore fiber optic cable, and an output sleeve connected to the output end of the input sleeve and made with the possibility of separate holding and withdrawal of the protected cores of a multicore fiber cable from the case. The input end of the heat-shrinkable tube is configured to enclose and hold the input multicore fiber-optic cable, in which each of the cores is made in the form of an optical fiber with a protective coating. The output end of the heat-shrinkable tube is configured to grip and hold the output sleeve, at the outlet of which the veins are placed in furcation tubes. 1 ill.

Description

The utility model relates to optical assemblies for multicore fiber optic cables.

Known fiber optic connector [RU 2598774, C2, G02B 6/38, 09/27/2016], containing a fiber optic tip, placed in the tip resiliently held by means of an elastic element, the main optical fiber fused with the tip optical fiber using an optical fiber fusion apparatus, and the fused section is reinforced with using a reinforcing sleeve to form a connection between the main fiber and the fiber of the tip.

Additionally, the fiber optic connector comprises a ferrule guide bush mounted between the ferrule and the resilient member. In a particular case, the guide sleeve of the tip, the optical fiber and the fused section can be connected in one piece by means of a reinforcing sleeve. In some cases, the tip includes a plug socket housing that accommodates the tip, tip guide sleeve and elastic element; a plug inserted into the housing of the plug socket, the plug securing the elastic element and the guide sleeve of the tip. In this case, the tip and the guide sleeve of the tip are made with the possibility of moving a distance within the limits specified by the elastic element. A protruding part is made at the end of the tip guide sleeve, and one end of the reinforcing sleeve is put on the protruding part so that the tip, the tip guide sleeve and the reinforcing sleeve are integrated into one piece.

This technical solution makes it possible to solve the problem of reliable fiber splicing under conditions of heat shrinkage, which takes place in the process of their fusion. However, it is designed to connect individual fibers and does not allow solving the problem of retention before installation of a multicore fiber-optic cable and its guaranteed preservation without damage.

It is also known a sleeve for holding optical fibers in a fiber optic connector [RU 2630201, C2, G02B 6/38, 09/06/2017], containing a housing structured in such a way that it has open recesses for holding bare, with a bare coating of end fragments of the first and second sets of optical fibers partitions provided for separating adjacent optical fibers and defining walls of adjacent open recesses so that each open recess accommodates the optical fiber in such a way that it does not protrude beyond the edge of the recess, the sleeve housing contains opposed to each other, held in a mating position, the first and the second portion, in order to hold the end portions of the first and second set of optical fibers, the end portions of the first set of optical fibers are staggered relative to the end portions of the second set of optical fibers on the opposite surfaces of the first and second housing portions, wherein, n A first and a second plurality of fiber holding recesses may be defined on the first and second surface of the housing perimeter, respectively.

The technical result of this technical solution is to create a fiber optic connector with a high density of fiber placement and low losses.

The disadvantage of this technical solution is the relatively low manufacturability and reliability of use in the field, since it has open recesses for holding the end fragments of the first and second set of optical fibers, which are bared with an exposed coating, and are provided for separating adjacent optical fibers. This makes it difficult to maintain the integrity of the optical fibers during installation.

The closest in technical essence to the proposed one is a tubular assembly [RU 2666960, C2, G02B 6/38, 09/19/2018] containing glass fiber, a heat-reduced heat-shrinkable tube surrounding at least a part of the glass fiber, and an adhesive that in an adhesive manner connects a heat-reduced heat-shrinkable tube with a glass fiber, the adhesive having an adhesive composition comprising a resin based on maleic anhydride-modified linear low density polyethylene and a maleic anhydride-grafted polypropylene copolymer.

The disadvantage of this technical solution is the relatively narrow functionality, since it is intended for fixing one optical fiber in a heat-shrinkable tube, as well as low manufacturability and reliability of use in the field, since it involves exposing the optical fiber. This makes it difficult to maintain the integrity of the optical fibers during installation.

The problem that is solved in the proposed technical solution is to create an optical assembly designed for spatial separation of the protected cores of a multicore fiber cable, the ends of which can be equipped with terminal connectors for installation. This achieves high reliability of the use of multicore fiber-optic cables during their transportation and installation in the field.

The required technical result is to expand the functionality of the known device by providing the possibility of spatial separation of the protected cores of a multicore fiber cable and increasing the reliability of using multicore fiber optic cables during their transportation and installation in the field, as well as expanding, on this basis, the arsenal of technical means used for installation of multicore fiber-optic cables in communication systems and information transmission.

The problem is solved, and the required technical result is achieved by the fact that, in a device containing a housing in the form of a heat-shrinkable tube (TU), a sleeve installed in the housing is introduced (fanout) made in the form of an input sleeve made with the possibility of covering and holding the input end of a multicore fiber optic cable, and an output bushing connected to the output end of the input bushing and made with the possibility of separate coverage, output from the body and holding of furcation tubes (FT) (from 2 to 16 pcs.), in which aramid threads and cores of a multicore fiber cable are placed, at the same time, the input end of the heat shrinkable tube is configured to enclose and hold the input multicore fiber-optic cable, in which each of the cores is made in the form of an optical fiber with a protective coating, and the output end of the heat shrinkable tube is configured to enclose and hold the output sleeve, at the exit from which the veins are placed in furcation tubes.

The drawing shows a cross-sectional view of an optical cable assembly together with a multicore optical fiber cable.

The optical cable assembly contains a body in the form of a heat shrink tube 1 and a sleeve 2 installed in the body, made in the form of an input sleeve 3, made with the possibility of enclosing and holding the input end of the multicore fiber optic cable 4, and an output sleeve 5 connected to the output end of the input sleeve 3 and made with the possibility of separate holding and output of the protected cores 6 of the multicore fiber cable 4, protected by aramid threads 7, from the housing, while the input end of the heat shrinkable tube 1 is configured to enclose and hold the input multicore fiber optic cable 4, in which each of the cores 6 is made in in the form of an optical fiber with a protective coating, and the output end of the heat-shrinkable tube 1 is configured to enclose and hold the output sleeve 5, at the output of which the cores 6 are placed in furcation tubes 8.

The cable optical assembly is used as follows.

Preliminarily, the end of the fiber-optic cable 4 is inserted through the input end of the heat-shrinkable tube 1 and the input sleeve 3 is put on the end of the fiber-optic cable 4. At its outlet, cores 6 (fibers with a protective buffer coating) are removed from the fiber-optic cable 4, inside with aramid threads 7, the veins 6 are taken out of the housing and placed in furcation tubes 8, fixed in the output sleeve 4, the aramid threads 7 are evenly distributed inside the housing, and then with the help of glue the input 3 and output 4 bushings of the coupling are connected.

Finally, the housing 1 in the form of a heat-shrink tube is heated and the final cable optical assembly is formed in the form of a sealed device, at the input of which a fiber-optic cable is fixed, and at the output - 6 optical fibers terminated with connectors of various types.

Thus, the device achieves the required technical result, which consists in expanding the functionality of the known device by providing the possibility of spatial separation of the protected cores of a multicore fiber cable and increasing the reliability of using multicore fiber optic cables during their transportation and installation in the field and expanding, on this basis, an arsenal of technical means used for the installation of multicore fiber-optic cables in communication and information transmission systems.

Claims (1)

An optical cable assembly comprising a housing in the form of a heat shrink tube, characterized in that a sleeve installed in the housing is introduced, made in the form of an input sleeve, made with the possibility of enclosing and holding the input end of a multicore fiber optic cable, and an output sleeve connected to the output end of the input sleeve, and made with the possibility of separate holding and output of the protected cores of the multicore fiber cable from the body, while the input end of the heat shrinkable tube is configured to enclose and hold the input multicore fiber optic cable, in which each of the cores is made in the form of an optical fiber with a protective coating, and the output end of the heat shrinkable the tube is configured to grip and hold the outlet sleeve, at the outlet of which the veins are placed in furcation tubes.

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