RU143786U1 - COMPACT DEVICE FOR BRANCHING FIBERS OF OPTICAL CABLE - Google Patents

Abstract

The utility model relates to devices for branching an optical multi-fiber cable for diluting its 250µ optical fibers loosely laid in a module through furcation tubes with a standard diameter of 0.9 mm or through single-fiber cables containing furcation tubes. A compact branching device, consisting of a tubular body that secures the cable and furcation tubes, is characterized in that its body is made in the form of a sleeve that tightly covers on one side a multi-fiber cable or part thereof, and on the other hand tightly covers a bundle of furcation tubes fastened together between each other in the area of entry into the sleeve, and the fibers removed from the cable pass freely inside the sleeve to the inputs into the furcation tubes, and the area of the fiber dilution inside the sleeve has this size along the sleeve To the fibers during extrusion of the tube furkatsionnoy any excess fiber optic cable in the left module without remaining in the dilution due to fiber bending stiffness as well, in any case, excluded unacceptable bending of the fiber.

Description

The technical field to which the utility model relates.

The invention relates to mechanical structures for providing tensile strength and external protection of fibers, namely, devices for branching optical multi-fiber cables for connecting single-fiber optical connectors.

State of the art

When connected to the connectors of a cross or transmit-receive equipment, the fibers of multi-fiber optical cables with a diameter of 250 microns are welded to the fibers of pigtails or cross-cables that have connectors at the opposite end, or the multi-fiber optical cables themselves have connectors directly into which their optical 250 micron fibers are inserted. If single-fiber connectors are connected directly to the fibers of a multi-fiber cable, then it is necessary to separate its 250-micron fibers one at a time, for which a branching device is installed at its end to flexible protective tubes or to single-fiber cables containing tubes, and then connectors are installed on cables or tubes . Flexible protective tubes for freely laying telecommunication optical fibers with a diameter of 250 µ in them are known in the art as furcation tubes. To protect 250µ fibers, furcation tubes with an external diameter of 0.9 mm are usually used as separate tubes or as part of single-fiber cables. A cable branched by furcation tubes or single-fiber cables, including them and a branching device, is called a cable assembly.

A device for branching a ribbon optical fiber cable for diluting 250 μ fibers one at a time, consisting of a plastic housing, an insert block with furcation tubes with diameters of 900 μ fixed therein, a lid and gaskets (US Pat. No. 7,461,981 dated December 12, 2008, Corning Cable Systems LLC). The tube holding unit is inserted into the housing into which the tape optical module is inserted on the other hand. The fibers of the module are separated and injected one by one into the furcation tubes. Both the tape module and the plug-in unit are fixed by means of gaskets when closing the lid. In this device, each fiber has freedom in the area from the place of clamping of the tape module to the bushings in the furcation tubes at the end of the plug-in unit. This branching device is applicable only to cables with tape fiber optic modules or to individual tape modules.

Another known device is similar to the previous one with the difference that a cable of a multi-fiber cable module is clamped at one end of the device, in which 250µ of fiber are laid freely (US Pat. No. 7,461,981 of December 12, 2008, Corning Cable Systems LLC; US Pat. No. 8,401,353 of 03/19/2013, Draka Comteq BV). When pulling the fiber into the furcation tube, the fiber is pulled in a free area in the device body and pulled out of the cable module. When pushing the fiber into the device from the furcation tube, the fiber is first uncontrollably laid in a free area before it begins to be pushed into the cable module, thereby forming a bend loop. The ejection of fiber from the furcation tube occurs, for example, if the tube is part of a single-ended cable terminated by a connector, which is shortened by cooling. The main disadvantage of this device is that with a large elongation and subsequent shortening of the furcation tube, for example, when the ambient temperature changes over a wide range, fiber bending may occur in the free area in the area of fiber dilution along the furcation tubes, leading to unacceptable attenuation of the optical signal in him. The disadvantages of this solution include the fact that the casing of the device is relatively large and is not designed to enter several optical cable modules with free laying of fibers.

A branching device is known in which each of 250 µ fibers is laid in an intermediate thin tube for conducting it from a multi-fiber cable module into a furcation tube, the diameter of the intermediate tube allowing it to enter the furcation tube (US Patent No. 5,970,195 of 10/19/1999, The United States of America as represented by the Secretary of the Navy). The intermediate tube limits the lateral movements of the fibers and does not allow transcendental bending when squeezing the fiber from the furcation tube and moving its excess into the cable module. The disadvantage of this solution is the presence of thin tubes that complicate the assembly. The outer diameter of the intermediate tubes should be less than the inner diameter of the furcation tubes, which is approximately 0.5 mm for a standard furcation tube with a diameter of 0.9 mm, and the intermediate tube must have a certain stiffness to limit the bending of the fibers.

A compact fiber branching device for an optical multi-fiber cable is known for diluting its 250 micron fibers freely laid in an optical cable module into separate furcation tubes with a standard diameter of 0.9 mm (US Patent No. 7,955,004 dated 07/07/2011, FiberSource, Inc.) . The body of the device is made in the form of a tube. An optical module and rigid cable power elements are inserted into the tube from one end, and flexible power elements are laid on the outer surface of the tube. Furcation tubes of single-fiber cables are introduced from the other end into the tube, the flexible force elements of which - glass fibers or aramid threads - are also laid on the outer surface of the tube. Flexible power elements of all cables are fixed on the tube by wrapping a plastic cord on which glue is applied, and then a heat-shrinkable tube is enclosed on it, covering both multi-fiber and single-fiber cables. The fiber dilution region inside the tube between the exit from the multi-fiber module and the entrances to the furcation tubes, where the fibers are in a free state, is dimensioned so that when the fibers are extruded from the furcation tubes when they are shortened, excess fiber is laid in the dilution region by bending. The disadvantage of this device is that with a large elongation and then shortening of the furcation tube in a free area in the breeding area, fiber bending may occur, leading to unacceptable attenuation of the optical signal in it. This technical solution is the closest among the known to the proposed utility model for a combination of features.

Utility Model Disclosure

The task was to develop a compact branching device for an optical multi-fiber cable for diluting its 250-micron optical fibers along furcation tubes or through single-fiber cables containing furcation tubes. The basic design of the device should be applicable to cables with one or more optical modules with free installation and the device should allow the cable assembly based on it to operate in such a wide temperature range that it would be possible to use it in outdoor conditions. The compactness of the device is needed, for example, for branching and subsequent termination with connectors of the inner end of the bay with a tight in-line winding of a winding cable, which is installed on the coil of the winding machine during installation, and the inner end with a branching device, single-fiber cables and connectors are temporarily placed in a compact container in the spindle coils of a winding machine.

The technical result of the utility model consists in the fact that a compact, universal, simple and technologically advanced in production design of a multi-fiber cable branching device for diluting its 250µ fibers along single-fiber cables or furcation tubes was found, which provides acceptable attenuation of the optical signal in the fibers in the dilution area under outdoor conditions application of cable assembly containing the device.

The technical result is achieved in that a compact device for branching the fibers of an optical multi-fiber cable for breeding its 250 micron fibers, freely laid in at least one optical cable module, made in the form of a protective tube, along separate furcation tubes with a standard diameter of 0.9 mm and with loose fiber laying, consisting of a tubular body into which at least one optical module of a multi-fiber cable and furcation tubes are inserted, the body fixes the cable and tubes, and inside the housing there is a fiber dilution zone, located from the exit of the fibers from at least one module of the multi-fiber cable and before they enter the furcation tubes, characterized in that its tubular body is made in the form of a sleeve that tightly covers the multi-fiber cable on one side or its part containing at least one optical module, and on the other hand tightly covers a bunch of furcation tubes fastened together in the area of entry into the sleeve, and the fibers removed from at least one of the optical module of a multifiber cable, pass freely inside the sleeve to the bushings, and the fiber dilution area inside the sleeve is sized along the sleeve so that unacceptable fiber bends are excluded, and so that when the fiber is extruded from any furcation tube into the fiber dilution area, the optical module of the cable, not remaining in the breeding area due to the stiffness of the fiber in bending, and unacceptable bending of the fiber was also excluded.

As the body of the device, a sleeve in the form of a tube is used, which tightly covers the cable or its part, and a bunch of furcation tubes, and this is one of the most compact solutions. After exiting the cable module, the fiber must deviate by a certain angle in order to enter, for example, the furcation tube extreme in the bundle. If the dilution area is too small in longitudinal size, then this angle may be too large, and this may lead to an unacceptably small bending radius of the fiber at this location. If the longitudinal size of the dilution region is large enough, the fiber may remain in the dilution region as excess when it is extruded from the furcation tube, and this will lead to its arcuate bending. For a specific cable design and a certain number of fibers, routed through furcation tubes, definitely located at the input to the sleeve, the optimal longitudinal dimension of the dilution region can be determined, large enough so that there are no unacceptable bends when breeding, and small enough so that the fibers when stressed from furcation tubes went into the module or modules of the cable so that the stiffness of the fibers did not allow them to noticeably change their bends in the breeding area. This, for example, allows the assembly of multi-fiber and single-fiber cables to be applied based on a useful model of a branching device in a wide temperature range. It should be noted that a decrease in the length of the furcation tube, for example, due to the temperature compression of the sheath of the single-fiber cable, which it is part of, leads to a longitudinal compression stress in the fiber, significantly greater than the longitudinal stress of the fiber laid in excess in the multi-fiber cable module, moreover, the change in the length of the furcation tube is much smaller than the length of the excess fiber in the optical module of the cable, and therefore, for example, when the tube and module are close and approximately coaxial, the excess fiber from t ubki seamlessly goes into the module. These features are used in the utility model, in particular, to determine the optimal size of the breeding area.

In one embodiment of the utility model, the furcation tubes in the input region of the sleeve are fastened together with glue. Preliminary gluing of furcation tubes into a bundle at the insertion point into the sleeve is the simplest and most technologically advanced way of fastening them together before fixing in the sleeve. In this case, the furcation tubes in the input region of the sleeve can touch each other, forming the most compact stacking in the bundle, which is important to reduce the deflection angles of the fibers in the fiber dilution region. This, in particular, allows minimizing the bending of the fibers extending into the furcation tubes extreme in the bundle.

In yet another possible implementation of the utility model, the sleeve is made of metal and molded so that at one end at a certain length its inner surface coincides in shape and size with the outer surface of the cable sheath, and at the other end at a certain length it matches the surface enveloping the bundle Furcation tubes fastened together. The sleeve can be made by molding a piece of stainless steel tubing.

In yet another possible implementation of the utility model, the furcation tubes are fastened together in a bundle so that their ends inside the sleeve are in the same plane perpendicular to the axis of the sleeve with a deviation of no more than 0.5 mm from the plane. It is easier to fasten furcational tubes in the input region of the sleeve and insert fibers into them if their ends are aligned with each other.

In yet another possible implementation of the utility model, the cross-section of the sleeve by the plane in which the ends of the furcation tubes are aligned is of a shape and size that minimize the maximum fiber bend across all fibers in the region of their dilution. For example, for a cable with one module, it is optimal if the furcation tubes are assembled in a bundle whose end face is similar in shape to a circle, inside which the rings of the ends of the furcation tubes are most compactly located, and whose center in the sleeve is opposite the center of the optical cable module. The greatest bending is experienced by fibers extending to the furthest tube inlets that are farthest from the center, and the bending radius depends on the distance from the center, but for a compact beam with an end face in shape close to a circle, this removal is minimal. At the same time, it is important that the furcation tubes are most compactly assembled in the bundle in the region of entry into the sleeve. For a cable with two modules, it is optimal to fasten the tubes into two groups, the centers of the ends of which are located in the sleeve in front of the centers of the modules. The fibers from the first module are distributed along the furcation tubes of the first group, and the fibers from the second module are distributed along the furcation tubes of the second group.

In yet another possible implementation of the utility model, a multi-fiber cable inserted into a sleeve is fixed by a heat-shrinkable tube with hot-melt adhesive applied to the inner surface, cased on the sleeve with the capture of a portion of the cable.

In yet another possible implementation of the utility model, a bundle of furcation tubes fastened together, inserted into a sleeve, is fixed by a heat-shrinkable tube with hot-melt adhesive applied to the inner surface, cased on the sleeve with capture of a section of the furcation tube bundle. The same heat-shrinkable tube can fix both the cable and the bundle of furcation tubes.

In yet another possible implementation of the utility model, a bundle of furcation tubes fastened together, inserted into the sleeve, is fixed by gluing to the inner surface of the sleeve. This fixation may be additional to fixation with a heat-shrinkable tube and hot-melt adhesive.

In yet another possible implementation of the utility model, furcation tubes are single-fiber cable tubes, the power elements and shells of which are fixed in the device. You can attach the power elements, for example, by laying the power elements on the device’s case and casing around the case an additional heat-shrinkable tube that captures the sheaths of single-fiber cables and has a layer of hot-melt adhesive on the inner surface.

Brief Description of the Drawings

FIG. 1 - A compact branching device for 250 micron optical fibers of a single-module circular cross-section optical cable along eight furcation tubes with a diameter of 0.9 mm. A cutout on the side of the housing is missing from the real device and is shown in the drawing of the device to demonstrate the fiber dilution area. The drawing further shows a cable cross-section (view A-A, shown on an enlarged scale) and a cross-section of the device in the input region of the furcation tube bundle (view BB, shown on an enlarged scale).

FIG. 2 - A compact branching device for 250 micron optical fibers of a two-module optical cable with a cross section close to rectangular along eight furcation tubes with a diameter of 0.9 mm. A cutout on the side of the housing is missing from the real device and is shown in the drawing of the device to demonstrate the fiber dilution area. The drawing additionally shows the cross section of the cable (view A-A, shown on an enlarged scale) and the cross section of the device in the area of the fiber exit from the cable modules (view BB, shown on an enlarged scale).

FIG. 3 - A compact branching device for 250 micron optical fibers of a single-module circular cross-section optical cable along eight furcation tubes with a diameter of 0.9 mm, which is partially inserted into the sleeve of the device. A cutout on the side of the housing is missing from the real device and is shown in the drawing of the device to demonstrate the fiber dilution area. The drawing additionally shows the cross section of the cable (view Α-A, shown on an enlarged scale).

FIG. 4 - A compact device for branching 250-micron optical fibers of a two-module optical cable with a cross section close to rectangular along eight single-fiber cables containing furcation tubes with a diameter of 0.9 mm; additionally shows a view of the device before sitting additional heat-shrinkable tube, which is shown in section.

In the figures:

1 - a branching device of 250 micron optical fibers of a single-module optical cable with free laying of circular fibers along eight furcation tubes with a diameter of 0.9 mm;

2 - optical fiber 250µ;

3 - single-module optical cable with free laying of circular fibers with four rigid power elements;

4 - furcation tube;

5 - rigid power elements;

5 - cable sheath;

7 - optical cable module;

8 - hydrophobic gel;

9 - sleeve branching device of circular cross section;

10 - a bundle of eight furcation tubes laid in a block with a cross section close to round;

11 - end of a bunch of furcation tubes laid in a block with a cross-section close to round;

12 - glue for gluing a bunch of furcation tubes;

13 - glue for gluing a bunch of furcation tubes to the inner surface of the sleeve;

14 - the region of dilution of the fibers from the optical module along the furcation tubes;

15 - hot glue;

16 - heat shrinkable tube;

17 - single-fiber optical connector;

18 is a device for branching 250-micron optical fibers of a two-module optical cable with free laying of cross-sectional fibers close to rectangular along eight furcation tubes with a diameter of 0.9 mm;

19 - a two-module optical cable with free laying of fibers with a cross section close to rectangular with one rigid power element;

20 - the first optical module cable;

21 - a second optical cable module;

22 - hard power element;

23 - sleeve device branching with a cross-section close to rectangular;

24 - a bundle of eight furcation tubes laid in a block with a cross section close to rectangular;

25 - end of a bunch of furcation tubes laid in a block with a cross section close to rectangular;

26 - the first four block furcation tubes;

27 - the second four block of furcation tubes;

28 - a branching device for 250 micron optical fibers of a single-module optical cable with free laying of circular fibers with flexible power elements along eight furcation tubes with a diameter of 0.9 mm;

29 - single-module optical cable with free laying of circular fibers with flexible power elements;

30 - flexible power elements in the form of aramid threads;

31 - cable sheath;

32 - glue for bonding the flexible power elements of the cable to each other;

33 - glue for gluing flexible power elements of the cable to the inner surface of the sleeve;

34 - a device for branching 250-micron optical fibers of a two-module optical cable with free laying of cross-sectional fibers close to rectangular along eight single-fiber cables until the additional heat-shrinkable tube shrinks;

35 - a device for branching 250-micron optical fibers of a two-module optical cable with free laying of cross-sectional fibers close to rectangular in eight single-fiber cables;

36 - single-fiber cable;

37 - polyvinyl chloride sheath of a single-fiber cable with a diameter of 2 mm;

38 - power elements of a single fiber cable in the form of aramid threads;

39 - glue for bonding the sheaths of single-fiber cables;

40 - additional heat-shrinkable tube;

41 - hot air gun;

A-A - view from the side of the section of the plane AA;

BB - view from the side of the section of the plane BB;

a is the size of the area of breeding fibers along the sleeve;

b is the longitudinal dimension of the sleeve;

d is the diameter of a compact branching device of 250µ optical fibers of a single-module circular cross-section optical cable along eight furcation tubes with a diameter of 0.9 mm in the input region of the bundle of furcation tubes;

h is the cross-sectional height of a compact branching device 250µ of optical fibers of a two-module optical cable with a cross section close to rectangular along eight furcation tubes with a diameter of 0.9 mm in the region of exit of the fibers from the cable modules;

w is the cross-sectional width of a compact branching device 250µ of optical fibers of a two-module optical cable with a cross section close to rectangular along eight furcation tubes with a diameter of 0.9 mm in the region of exit of the fibers from the cable modules.

Utility Model Implementation

One of the implementations of the utility model, but this implementation is not limited, is a compact device 1 for branching eight 250-micron optical fibers 2 of a single-module optical cable 3 with free laying of fibers along eight furcation tubes 4 with a diameter of 0.9 mm. Cable 3 has a round cross section with a diameter of 4 mm, contains 4 rigid power elements in the form of fiberglass 5, fused into the sheath 6 and one optical module 7 with 8 optical fibers 2 of the G.657A1 standard, for which a bend with a radius greater than 10 is permissible mm The optical module 7 is filled with a hydrophobic gel 8. The sleeve 9 of the device has a length b of 30 mm. The sleeve 9 is molded from a tube with a wall thickness of 0.25 mm made of stainless steel and has a cylindrical shape at one end with a length of 10 mm and an internal diameter of 4 mm, at the other end a cylindrical shape with a length of 10 mm and an internal diameter 3 mm, and in the middle transition section has the shape of a truncated cone. On the one hand, the cut cable 3 is tightly inserted into the sleeve 9 by 10 mm so that the module 7 extends beyond the cable sheath 6 by 5 mm. On the other hand, a compact bundle 10 of 8 furcation tubes aligned with the end face 11 of the bundle and glued together with glue 12 at a distance of 15 mm from the end face 11, forming a shape close to the cylinder, is inserted 10 mm into the sleeve 9 by 10 mm. The bundle 10 is glued to the inner surface of the sleeve 9 by glue 13. The fibers 2, leaving the optical module 7 without intersecting, are bred along the furcation tubes 4. The dilution region 14 has a longitudinal size of 5 mm. This size is large enough and allows you to not form invalid bends of the fibers 2 during breeding. On a sleeve 9, with a cable capture of 3 by 30 mm and a bundle of furcation tubes 10 by 5 mm, a heat-shrinkable tube 16 is seated and glued with hot-melt adhesive 15. Furcation tubes 4 have a length of 40 cm. Optical connectors 17 are installed at the ends of the tubes 4. When extending the furcation tubes 4, for example, from heating, the lack of fiber length is pulled from the optical module 7. When the length of the furcation tubes 4 is reduced, for example, from cooling, the excess fiber is squeezed out of the tubes 4 and pressed through the dilution region 14 into the optical module 7. The longitudinal size of the fiber ti dilution 14 is small enough and does not allow the formation of fiber loops due to resistance in the optical input module 7. The diameter of the device 1 in the entry area of the cable 3 into the sleeve 9 the cable diameter 3 to a value smaller than 1.5 mm. The diameter d of the device 1 in the input region of the bundle of furcation tubes 10 into the sleeve 9 is less than 4.5 mm. Such dimensions make it possible to consider the device 1 compact. Another implementation of the utility model, but not limited to this, is a compact device 18 for branching eight 250-micron optical fibers 2 of a two-module optical cable 19 with free laying of fibers along eight furcation tubes 4 with a diameter of 0.9 mm. Cable 19 has a cross section close to a rectangle with dimensions of 2 mm by 4 mm, contains two optical modules 20 and 21 with a diameter of 1.1 mm, each of which contains 4 fibers 2 of the G.657A1 standard, and one rigid power element in the form of a 22 bar fiberglass a diameter of 1 mm, which is located between the modules 20 and 21. The optical modules 20 and 21 are filled with a hydrophobic gel 8. The sleeve 23 of the device 18 has a length b of 30 mm. The sleeve 23 is molded from a tube with a wall thickness of 0.25 mm, made of stainless steel, and has a cross-sectional shape close to a rectangle with internal dimensions of 2 mm by 4 mm from one end to a length of 10 mm, from the other end to a length of 10 mm - a cross-sectional shape close to a rectangle with internal dimensions of 1.8 mm by 3.6 mm, and in the transition section in the middle of the sleeve 23, the rectangular cross-section with the first dimensions smoothly passes into a rectangular cross-section with the second dimensions. On the one hand, a cut-off cable 19 is tightly inserted into the sleeve 23 by 10 mm so that the modules 20 and 21 extend beyond the edge of the cable sheath 6 by 5 mm, and the fiberglass 22 is cut close to the edge of the sheath. On the other hand, a compact bundle 24 of 8 8 furcation tubes 4, aligned at the end face 25 of the bundle and glued together with adhesive 12 in the region of 15 mm from the end face 25, is inserted into the sleeve 23 by 10 mm, and the bundle 24 in the input region forms a block: two into four tubes with a cross section close to a rectangle. Fibers 2 from the first module 20, without intersecting with each other and not intersecting with fibers 2 from the second module 21, are routed into tubes 4 of the first four 26 of the bundle 24 of furcation tubes. Fibers 2 from the second module 21, without intersecting with each other and not intersecting with the fibers 2 from the first module 20, are routed into tubes 4 of the second four 27 of the bundle 24 of furcation tubes. The cross section of a bundle of 24 furcation tubes, having a shape close to a rectangle and dimensions of 1.8 mm by 3.6 mm, is optimal for minimizing fiber bends when they are routed from optical modules 20 and 21 of cable 19 through furcation tubes 4 for this cable. The cross section of the sleeve 23 at the end face 25 of the bundle 24 of furcation tubes has a similar shape and internal dimensions. Otherwise, this device is similar to the first device 1 described in this section. The cross-sectional dimensions of the device 18 in the exit region of the fibers 2 from the modules 20 and 21 of the cable 19 are as follows: h is less than 5.5 mm and w is less than 3.5 mm. Such dimensions make it possible to consider the device 18 compact. Another implementation of the utility model, but this implementation is not limited, is a compact device 28 for branching eight 250-micron optical fibers of a single-module optical cable 29 with free laying of fibers along eight furcation tubes 4 with a diameter of 0.9 mm. The cable has a circular cross section with a diameter of 5 mm, contains flexible power elements in the form of aramid filaments 30 located around one optical module 7 with 8 optical fibers 2 of the G.657A1 standard. The optical module 7 is filled with a hydrophobic gel 8. The thickness of the sheath 31 of the cable 29 is 0.5 mm. The sleeve is identical to the sleeve 9 of the first device described in this section. The end of the cable 29 is cut so that the aramid filaments 30 are 10 mm free of the sheath 31 and glued around the optical module 7 with glue 32 so that they form a cylinder with a diameter of 4 mm. The optical module 7 extends beyond the edge of the cylinder from glued aramid filaments 30 to 5 mm. This part of the cable without a sheath is inserted into the sleeve 9 so that the sheath of the cable 31 is in contact with the edge of the sleeve 9, while a cylinder of glued aramid threads is glued to the inner surface of the sleeve 9 with glue 33. Otherwise, this device is similar to the first device 1 described in this section .

Another implementation of the utility model, but this implementation is not limited to, is a compact device 35 for branching eight 250-micron optical fibers of a two-module optical cable 19 with free stacking of fibers 2 over eight single-fiber cables 36. Each single-fiber cable 36 has a sheath 37 made in the form PVC tubes with a diameter of 2 mm, in which a furcation tube 4 with a diameter of 0.9 mm and power elements in the form of aramid filaments 38 are freely placed. Multi-fiber cable 19, sleeve 9, fastening m ogovolokonnogo cable 19 and the pipes 4 furkatsionnyh monofilament cables 36 in the sleeve 9 with an adhesive 13 and the heat shrinkable tube 16 and the fiber 2 dilution cable 19 to furkatsionnym tubes 4 identical to apparatus 18 described in the second section. In this case, the sheaths 37 of single-fiber cables are cut so that their edge is located in the region from 5 mm to 10 mm from the edge of the sleeve 9, and the aramid threads 38 are cut so that they overlap the sleeve 9. To reduce the bends of the furcation tubes 4 emerging from the sleeve 9 when branching the bundle of them through single-fiber cables 36, the ends of the cable sheaths are offset with each other. The sheaths 37 of single-fiber cables in the dilution area are glued with glue 39, and a heat-shrinkable tube 40 is put on the device with a layer of hot-melt adhesive 15 on the inner surface to capture the sheaths 37, and aramid threads 38 of the single-fiber cables 36 pass through the tube 40. The device 34 is the device 35 until it is fixed power elements 38 and cable sheaths 37 by shrinking the heat-shrinkable tube 40 using a hot air gun 41. After shrinking, the heat-shrinkable tube 40 and hot-melt adhesive 15 fix the power elements 38 of the single-fiber cables to the surface of the device State 18 and their cable sheaths 37 at the breeding site. At the ends of the single-fiber cables 36, optical connectors 17 are installed.

Claims (10)

1. A compact device for branching fibers of an optical multi-fiber cable for breeding its 250-micron fibers, freely laid in at least one optical cable module, made in the form of a protective tube, along separate furcation tubes with a standard diameter of 0.9 mm and with free fiber laying, consisting of a tubular body into which at least one optical module of a multi-fiber cable and furcation tubes are inserted, the body fixes the cable and tubes, and there is a dilution zone inside the body fibers, located from the exit of the fibers from at least one module of the multi-fiber cable and before they are inserted into the furcation tubes, characterized in that its tubular body is made in the form of a sleeve that tightly covers on one side the multi-fiber cable or its part containing at least one optical module, and on the other hand tightly encloses a bundle of furcation tubes fastened together in the area of entry into the sleeve, the fibers removed from at least one optical module of a multi-fiber abel, pass freely inside the sleeve before entering the furcation tubes, and the area of fiber expansion inside the sleeve is sized along the sleeve so that unacceptable bending of the fiber is excluded, and so that when extruding fiber from any furcation tube into the area of fiber expansion, excess fiber goes into the optical module of the cable without remaining in the breeding area due to the bending stiffness of the fiber, and unacceptable fiber bends are also excluded. 2. A compact device for branching fibers of an optical multi-fiber cable according to claim 1, characterized in that the furcation tubes in the input region of the sleeve are fastened together by glue. 3. The compact device for branching the fibers of an optical multi-fiber cable according to claim 1, characterized in that the sleeve is made of metal and molded so that at one end at a certain length its inner surface coincides in shape and size with the outer surface of the cable sheath, and on the other end at a certain length - with a surface enveloping the bundle of furcation tubes fastened together. 4. A compact device for branching fibers of an optical multi-fiber cable according to claim 3, characterized in that the metal sleeve is made of stainless steel. 5. The compact device for branching the fibers of an optical multi-fiber cable according to claim 1, characterized in that the furcation tubes are fastened together in such a way that their ends inside the sleeve are in one plane perpendicular to the axis of the sleeve with a deviation of no more than 0, 5 mm. 6. The compact device for branching the fibers of an optical multi-fiber cable according to claim 5, characterized in that the cross-section of the sleeve by the plane in which the ends of the furcation tubes are located has a shape and dimensions that minimize the maximum fiber bend across all fibers in the region of their dilution. 7. The compact device for branching the fibers of an optical multi-fiber cable according to claim 1, characterized in that the multi-fiber cable inserted into the sleeve is fixed by a heat-shrinkable tube with a hot-melt adhesive applied to the inner surface, cased on the sleeve with the capture of the cable section. 8. The compact device for branching the fibers of an optical multi-fiber cable according to claim 1, characterized in that the bundle of fastened furcation tubes inserted into the sleeve is fixed by a heat-shrinkable tube with hot-melt adhesive deposited on the inner surface, cased on the sleeve with the capture of a section of the bundle of furcation tubes. 9. The compact device for branching the fibers of an optical multi-fiber cable according to claim 1, characterized in that the bundle of fastened furcation tubes inserted into the sleeve is fixed by gluing to the inner surface of the sleeve. 10. The compact device for branching the fibers of an optical multi-fiber cable according to claim 1, characterized in that the furcation tubes are tubes of single-fiber cables, the power elements and shells of which are fixed in the device.