RU158909U1 - CABLE INPUT FOR OPTICAL CLUTCH - Google Patents

Abstract

1. A cable entry for an optical coupling, comprising an elongated cylindrical body made of elastic tensile material with counter-directed annular ledges located on its outer surface for elastic engagement with opposite ends of the coupling finger, the ledges are located along the length of the housing at a distance less than the length of the coupling finger in inoperative position of the housing, the latter has a surface of an annular ledge for engagement with the inner end of the coupling finger and a working surface of another ledge for its engagement with a mating surface of the outer end of the finger of the coupling, characterized in that the inner surface of the housing in the area located between the annular ledges is made stepwise with a plurality of steps of a conical shape, and each step is resiliently engaged with the sheath of the optical cable placed in the cable entry, at the same time, the passage hole of each step is selected smaller than the cable diameter. 2. The cable entry according to claim 1, characterized in that the surface of the annular ledge for coupling with the inner end of the coupling finger is perpendicular to the outer surface of the housing, and the working surface of the other ledge for coupling with the counter surface of the outer end of the coupling finger is beveled.

Description

This utility model relates to optical communication line couplings and their elements intended for inputting an optical cable into the coupling and its reliable sealing.

Known optical blind coupling for an optical cable company Vilun with cable entries that are installed in the channels of the fingers of the coupling (Yandex,).

Also known is a cable entry in the design of a large-capacity GJS-R optical blind coupling for a fiber-optic cable, used to protect the places of welding of the optical cable in places of increased loads and possible external influences. These couplings are operated in difficult working conditions on supports, suspensions, in communication sewer shafts, on vertical surfaces under a wide temperature range, under the influence of aggressive media, ultraviolet radiation, high humidity, and possible earthquakes. Fixing the cable of the specified coupling provides resistance to external pulling of the cable, its twisting, as well as when exposed to shock loads. The coupling is assembled in a “hot” way using heat-shrinkable materials, which significantly complicates the technology of coupling assembly, especially when opening the coupling and re-sealing the cable-to-coupling connection (Yandex, Optical coupling GJS-R144 Core, Insteil-ltd.com.).

A cable entry for an optical coupling is known from practice, comprising a housing made of an elastic material in the form of an elongated cylindrical element with counter-directed ledges located on the outer surface, spaced apart from each other along the length of the element and designed to engage the coupling finger (www., Outside Plant , HT001, Issue, 10/09/2012, page 3 of 4, fig. 1, 5 - attached).

Also known from the patent documentation is a cable entry of an optical communication line coupling, which comprises an optical cable entry shank fixed to the base of the coupling in the coupling casing (RU 115081 U, G02B 5/48, 04/20/2012).

Another cable entry is known, comprising a cylindrical body made in the form of a sleeve with an external thread at one end and an internal one at the other end, a pressing element, a fixing element in the form of a sleeve with a conical outer surface on one side, an external seal, characterized in that the end surface the housing is provided with a groove for the outer seal, the cable entry is additionally equipped with a cylindrical grip with a thread on the outer surface, a protrusion and a thrust shoulder (RU 119181 U1, H02G 15/013, 08/10/2012).

A compressible module for cable glands or pipe transition devices is known, in which at least one compressible module is inserted surrounding each cable or each pipe, cable glands or pipe transition devices located directly in the wall opening or in the frame opening. Compression is carried out by the specified at least one module or at least one compressible device in the specified hole, and the compressible module contains at least one compressible layer for fitting to the diameter of the cable or pipe located at the base of the module, its cross section has a shape other than a rectangular shape (RU 105704 U1, F16L 5/02, 06/20/2011).

A cable entry is also known, having layers of different thicknesses, two or more compressible bases covering each cable, wire or pipe, and placed either directly in the hole in the wall or in another structural partition forming this wall, or in another partition or frame, and the specified two or more bases and at least one compression device in the hole or frame, a barrier is formed, and each base contains peelable sheets for fitting to the diameter of the cable, wire or pipe. At least one peelable sheet has a thickness in the range of about 1 / 20-1 / 4 of the dimensions of the compressible module in the corresponding direction (WO 2010089285 A, H02G 3/22, 08/12/2010).

Known compressible module for cable entries or pipe entries, which are placed either directly in the hole in the wall or other structural partition that forms this wall, or in another partition or frame, with the specified one or more modules and at least one compressing unit in a barrier is formed in the hole or frame, and the compressible module has an axial groove for accommodating the cable or pipe, wherein the compressible module contains at least two modular sections in the form of submodules in the direction of the cable or pipe, Commercially different physical properties, wherein the outer sealing is submodule submodule (US 8,806,713 B2, F16L 5/02, 19.08.2014).

A close analogue to the claimed technical solution is a cable entry containing a cable in a polymer sheath, a cylindrical seal in a pressed state and a cylindrical body with a flange. The casing is made of ductile metal, the cylindrical part of the casing is thin-walled, the seal is preloaded by plastic deformation of the outer surface of the thin-walled casing, with at least two annular grooves having an isosceles trapezoidal shape in longitudinal section. The total length of the small bases of the trapezoid does not exceed half the length of the thin-walled part of the casing, one end of the seal rests against the flange of the inner hole in the flange of the casing, its second end is free, and the length of the seal exceeds the length of the thin-walled part of the casing by at least the size of the outer diameter of the cable (RU 2138089 C1 , H01B 17/26, 09/20/1999).

The closest cable entry for the optical coupling to the cable entry described herein is a cable entry for the optical coupling, comprising a housing made of elastic tensile material in the form of an elongated cylindrical element with counter-directed ledges located on the outer surface, spaced apart from each other in length element, and intended for engagement with the clutch finger (www. Prusmiangrup.com, Outside Plant, HT001, Issue, 09.10.2012, page 3 of 4, fig. 1, 5).

This cable entry provides the fixation of the fiber optic cable in the finger of the optical sleeve in its working position and the connection of the cable to the cable entry, however, this connection does not fully meet the increased requirements for such a connection, operating in severe conditions of a wide range of changes in ambient temperature, precipitation and aggressive environments experiencing significant bending loads, which can lead to depressurization of the cable-cable entry and cable entry - the coupling body and can lead to aniyu aggressive environment or moisture inside the sleeve, and other negative consequences.

The technical result of the utility model presented in this description is to increase the reliability of the elastic tight connection of the cable with the cable entry and cable entry with the sleeve.

The result was obtained by a cable entry for an optical coupling, containing an elongated cylindrical body made of elastic tensile material with counter-directed annular ledges located on its outer surface for their elastic engagement with opposite ends of the coupling finger, the ledges are located along the length of the housing shorter than the length of the coupling finger in the idle position of the housing, the latter has a surface of an annular ledge for coupling with the inner end of the finger of the coupling and the working surface of another UPA for its adhesion with the counter surface of the outer end of the finger of the coupling, the inner surface of the housing in the area located between the annular ledges, made stepped with many steps of a conical shape and each step is located with the possibility of elastic adhesion to the sheath of the optical cable placed in the cable entry, with this passage hole of each stage is selected less than the diameter of the cable. The surface of the annular ledge for engagement with the inner end of the coupling finger is perpendicular to the outer surface of the housing, and the working surface of the other ledge for its engagement with the counter surface of the outer end of the coupling finger is beveled.

In FIG. 1 shows an optical sleeve with a cable entry.

In FIG. 2 - optical coupling with cable entry (without casing).

In FIG. 3 is a view A in FIG. 2.

In FIG. 4 - place B in FIG. 2.

In FIG. 5 - cable entry, front view.

In FIG. 6 - cable entry in longitudinal section.

The cable entry for the optical coupling includes a housing 1 (Fig. 1, 6) made of elastic tensile material in the form of an elongated cylindrical element. Outside on the casing 1 there are opposed annular upper and lower ledges 2 and 3, respectively, spaced from each other at a distance less than the length of the pin of the coupling, in the passage channel of which it is installed. The ledges are designed to engage with the inner and outer ends of the finger of the coupling due to the compression force arising from the extension of the input housing when it is installed in the finger channel due to the different lengths of the finger and the cable entry section between the ledges.

The inner surface of the housing 1 (Fig. 6) is made stepped with many ring steps 4 (combs) located along the length of the housing. Each step 4 is formed by an upwardly tapered conical part 5 of the wall 6 of the housing and an annular platform located above this part 7. The lower annular ledge 3 has a beveled down surface 8 for its engagement with the counter end surface of the coupling finger. Each step has a round bore.

The cable entry housing 1 has a working part 9 with a bulge 10 at the upper end 11 and an annular girdle 12 at the upper end 11, as well as recesses 14, which are ring-shaped on the outer surface 13. The cable entry housing 1 also has a tail portion 15 with less deep on its outer the surface 16 of the annular recesses 17. The end 18 of the tail is made conical. The cable entry housing 1 has a central channel 19 for accommodating and fixing cable 20 therein (FIGS. 1, 4).

The cable entry housing is installed in the channel 21 (Fig. 2) of the finger 22 of the headband 23 of the coupling. Golovinit 23 clamp 24 is detachably connected to the casing 27 of the coupling. In the case of the coupling screw clamps 25 are placed for fixing the power elements of the cables and cassettes 26 for laying splice optical fibers. The finger 22 has an outer end 28 (Fig. 4) and an inner end 29. The outer end 28 has a beveled surface 30 formed by the chamfer of the end 28.

Cable entry works as follows. The tail end of the cable entry housing 1 is introduced from the inside of the headband 23 into the channel 21 (Fig. 2) of the coupling finger 22 until the upper ledge 2 abuts against the inner end of the finger 22. They are caught by the tail portion 15 of the housing 1 and stretched

stretch the wall in the longitudinal direction of the housing 1 and pull it until the ledge 3 of the housing 1 comes out of the channel 21 of the finger 22. Release the tail part 15 of the housing 1 and at the same time, with its sloping surface 8 (Fig. 6), it engages in tight and tight engagement and connection with the outer end 28 of the finger 22 (Fig. 4). The joint is sealed due to the elasticity and extensibility of the body 1 and its beveled surface 8 is constantly pressed against the beveled surface 30 of the end face 28. These beveled surfaces significantly increase the density and tightness of the fixation of the body 1 in the channel 21 of the finger 22. The beveled surface 30 of the outer end 28 of the finger 22 couplings protects this surface from scratches that may appear when mounting the couplings in difficult conditions.

After the operations, cable 20 is inserted into the channel 19 (Fig. 2, 4) of the housing 1, which is pulled tightly from the bottom up through the channel 19 of the housing 1 until the cable exits the housing 1. Cable power elements, metal cable or aramid threads (not shown ) are fixed with screw clamps 25 (Fig. 2). The tightness of the junction of the cable sheath 20 in the passage channel 19 of the cable entry case 1 is ensured by the fact that the passage hole of each step 4 is chosen smaller than the diameter of the cable 20. During the movement of the cable in the channel 19 of the case, the cable contacts each step 4, slides along it and centers itself in the channel 19 so that it is located on the axial line of the channel 19 in a locked in working reliable position. In this case, the transverse fixation of the cable in its working position is carried out due to the elasticity of each step 4 of the cable entry. All steps 4 constantly pressurize the cable to the longitudinal axis of channel 19. In fact, the cable is clamped in the working position by the steps 4 of the cable entry, which ensures reliable connection of the cable 22 with the cable entry. After the operations of installing the required number of cable entries into the fingers of the sleeve of the coupling, inputting the cables and fixing the power elements of the cables with screw clamps, they carry out installation work on the splicing of the optical fibers of the cables. It is significant that during installation of the cable entry housing 1 in the finger channel 21 (Fig. 4), the beveled elastic surface 8 is tightly engaged with the mating mating face surface 30 of the end face 28 of the finger 22 and these surfaces increase the reliability of sealing the connection of the housing 1 with the finger 22 . In the process of installing the cable 20 in the housing 1, the cable surface repeatedly enters into interaction with a plurality of elastic steps 4 of the housing 1, which in the indicated multiplicity increases the density and reliability of the tight connection of the cable 20 with the housing 1. V s In the event of the appearance of bending loads on the cable 20, the flexible and elastic tail portion 15 of the body bends within specified limits and extinguishes the loads bending the cable, which eliminates dangerous cable bends. If necessary, the cable entry housing 1 can be replaced by another housing having other, smaller or larger diameters of the passage openings of the steps 4. This allows cables having different diameters to be fixed in the cable entry housing.

This cable entry can significantly increase the tightness of the connection, its reliability and the life of the optical coupling due to the exclusion of moisture inside the coupling.

Claims (2)

1. A cable entry for an optical coupling, comprising an elongated cylindrical body made of elastic tensile material with counter-directed annular ledges located on its outer surface for elastic engagement with opposite ends of the coupling finger, the ledges are located along the length of the housing at a distance less than the length of the coupling finger in inoperative position of the housing, the latter has a surface of an annular ledge for engagement with the inner end of the coupling finger and a working surface of another ledge for its engagement with a mating surface of the outer end of the finger of the coupling, characterized in that the inner surface of the housing in the area located between the annular ledges is made stepwise with a plurality of steps of a conical shape, and each step is resiliently engaged with the sheath of the optical cable placed in the cable entry, in this case, the passage opening of each step is selected smaller than the cable diameter. 2. The cable entry according to claim 1, characterized in that the surface of the annular ledge for coupling with the inner end of the coupling finger is perpendicular to the outer surface of the housing, and the working surface of the other ledge for coupling with the counter surface of the outer end of the coupling finger is beveled.

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