RU196705U1 - Optical coupler - Google Patents

Abstract

The invention relates to couplings for connecting fiber optic cables of communication lines. The technical result of the utility model is to reduce the complexity of installation work. The technical result is obtained by an optical coupler characterized by a hollow body with a removable headband having at least one cable entry pipe into the sleeve from the outside. At least one window is made in the headband, in which the hollow body of the removable terminal module is installed, having a mounting flange to the head end. The housing of the module is made with oppositely oriented nozzles with through sockets for installing adapters of optical connectors and cable plugs in them, with one nozzle located in the cavity of the coupling housing and in communication with it, and the other nozzle located in the sealed cavity of the casing formed by the module elements. The casing is located on the outer side of the headband and the cavity of the casing is configured to accommodate the plugs of the optical connectors of the subscriber cables and adapters connected to the plugs. 3 s.p. f-ly, 25 ill.

Description

This utility model relates to connecting and branching couplings intended for splicing the construction lengths of optical communication cables, branching cables to subscribers and storing intergrowths of optical fibers in sealed cases of couplings.

Known methods and systems for distributing fiber-optic communication services in a local service area (WO 2009/155487, 12/23/2009), in which a fiber-optic distribution terminal is disclosed, comprising a housing, several hardened adapters in the housing, each adapter having several ports. Access to these ports is possible both outside the enclosure, and inside the enclosure.

Known fiber optic distribution terminal, which contains a hollow flattened housing with side walls and a bottom. Through-holes are made in the bottom of the case for placement of landing sites for hardened adapters. Each hardened adapter contains a port that can be accessed from outside the chassis, as well as a port that can be accessed from inside the chassis. The terminal has the number of screw connections of the cover with the terminal housing, which complicates installation work (KZ 1298 U, 07/15/2015).

A multiport optical fiber connection terminal with a compact housing is also known, which has a configuration that allows easy accessibility and cable interconnections, while providing several installation options including storage space inside the terminal. The terminal may include cable connectors that are configured to provide weather protection for installing pre-terminated fiber optic cables with terminal ports (US 9039293 B2, 05.26.2015).

Known fiber terminal units (FDTs) for providing selective connections between optical fibers of distribution cables and optical fibers of drop cables, for example, in several residential units. FDT assemblies include a mounting plate that allows you to conveniently and securely install FDT on a vertical surface such as a wall. The mounting plate is so designed that the FDT base must be removed before removing the mounting plate, and the FDT cover is designed so that neither the base nor the mounting plate can be removed without first removing the cover. The cover may be selectively attached to the base and / or mounting plate with a fastener; therefore, only specialists who can remove the lock can remove the cover, base and / or mounting plate of the FDT assembly (US 7664360 B2, 02.16.2010.)

A multi-layer module is known which includes a layer for storing a multi-fiber cable having an opening for inputting a cable and a structure for winding a cable. Also included is a splicing storage layer that is separate from the storage level of the multifiber cable, wherein the splicing storage layer has a receiving hole for splicing the layer, a layer and a sagging storage area communicating with the multifiber cable storage. The multilayer module includes a pigtail storage layer that is separate from both the multi-fiber cable storage layer and the connector storage layer, wherein the pigtail storage layer has a pigtail connector region and a pigtail storage region, the pigtail storage region has an opening for receiving the pigtail storage layer, communicating with the compound storage layer (EP 2383594 A1, 02/02/2011).

A close solution to the solution presented in this description is a well-known fiber-optic distribution terminal containing a hollow body with a horizontal cross section, similar in shape to a semicircle, the inner and outer side surfaces of which are made in the form of wave-like surfaces that envelope the area of the reinforced guide adapters, one ends of which placed on landing sites in the body cavity, and the other ends are placed on landing sites made on a common ledge n the outer surface of the bottom of the housing, a removable cover with a sealing element installed between the seats of the cover and the housing, fastening elements of the cover with the housing, a cassette for placing and fixing the coils and splices of optical fibers installed in the hollow housing, characterized in that the outer surface of the removable cover is made domed with the formation of a cavity in the housing, which is divided into the input area of the main cable, the area of the removal of optical fiber from the main cable, the switching area of the splitter, the storage area plittera, cable reserves the storage area, the connection area subscribers splitter. Clips-clothespins are made removable and replaceable (RU 184781 U1, 08/08/2018).

The fiber optic distribution terminal disclosed in patent RU 184781 U1 has a housing with a removable cover, the outer surface of the cover is dome-shaped, while the formed cavity of the housing of the fiber-optic distribution terminal is divided into a cable entry area and an area for removing fiber from the main cable, switching area, storage and connection of subscribers splitter, and cable storage area. The housing of the distribution terminal is connected to the cover with removable and replaceable clip-clips, which make it easy to remove the cover without using a tool. The disadvantage of this distribution terminal is the installation of single cable entry nodes at a distance from each other, which leads to an increase in the size of the distribution terminal.

Another close solution to the solution presented in this description is the known cable termination device with several sealing modules, disclosed in patent RU 2632929 C2, which, in accordance with the claims, is a sheath containing a housing, at the end of which there is an opening for the sealing block, made with the possibility of its insertion into the hole and including a sealing device with many cable ports, providing peripheral sealing between the housing m and a sealing block, while the sealing block also includes a driving device configured to compress the sealing device in the opening of the sealing block and containing internal and external compression elements between which the sealing device is located, and a spring that compresses the sealing device between the inner and external compressing elements upon activation of the driving device, the shell being characterized in that the sealing device comprises o sealing modules, each of which forms a part of the sealing device activated by compression, and the sealing modules are arranged to individually install them between the internal and external compressing elements and to extract them from the space between these elements, each sealing module has a total axial length, formed between the first and second axial ends in the direction along the central axis of the sealing module, and includes the volume of the sealant, at least not partially located between the first and second retaining structures, which form the first and second axial ends of the sealing modules, each of which has at least one cable port extending in the axial direction through the volume of the sealant, including cable seal surfaces located around the cable ports, wherein each volume of sealant includes open external sealing surfaces surrounding the perimeter of the sealing modules, the sealing device comprising at least three sealing modules, and parts of the external sealing surface form a perimeter seal between the housing and the sealing block.

The second variant of the casing according to patent RU 2632929 C2, disclosed in the claims, comprises a casing with an opening in the casing extending along the central axis and a sealing block inserted in the direction along the central axis into the casing opening and including a sealant ring located around the central axis holes when the sealing block is inserted into the hole, while there is a drive unit with internal and external axial compressive elements, between which the sealant ring is clamped in the axial direction, forming an external radial seal with an inner surface of the housing opening and an internal radial seal with an external axially elongated portion of the internal compressing member, the drive device including a drive mounted externally comprising a drive shaft coupled to an external axially elongated portion of the internal compressing member (RU 2632929 C2, 10/11/2017). This invention made it possible to seal the cable entry points of the telecommunication systems housings by introducing a sealing block into the housing opening. The sealing unit comprises a sealing device with a plurality of cable ports. The sealing device also has a peripheral seal between the housing and the sealing unit. The sealing block comprises a driving device for compressing the sealing device in the opening of the sealing block. The sealing device contains several sealing modules, each of which is only a part of the sealing device activated by compression. The invention provides the possibility of multiple use of telecommunication buildings.

The disadvantage of the device according to patent RU 2632929 C2 is that the switching of the connected cables is inside the device’s case, which requires opening the case during installation. As a result, the complexity of installation work increases significantly when additional consumers are connected to the device.

Optical sleeves are also known, each of which contains a hollow body that is tightly and detachably connected to the body of the ogolovnik (cover), on which are located outside the pipes for the input of distribution cables into the sleeve (RU 2552119 C2, 06/10/2015; RU 2683815 C1, 04/02/2019 ; JP 2002139634 A, 05.17.2002). Moreover, in the indicated sources the branch pipe branch pipes can be round and oval, as well as pipes of a smaller diameter may be located on the branch pipe of a larger diameter.

A close solution to the solution presented in this description is the optical coupling presented in the description of patent RU 2683815 C1, 04/02/2019, G02B 6/44. This source discloses a design that has common features with the design presented in this description. Common features of the two structures are such signs that they relate to optical couplings and each of them contains a hollow body, as well as a detachable headband that is detachably connected to the body, on which there are nozzles for input of distribution cables into the sleeve.

As practice has shown, for introducing new subscriber cable entries into the coupling, a significant number of operations are required to connect these subscribers, and it is impossible to connect the specified subscriber cables without opening the coupling, and opening the coupling is associated with significant installation costs.

The technical result of the utility model is to reduce the complexity of installation work.

The technical result is obtained by an optical coupler characterized by a hollow body with a removable headband having at least one cable entry pipe into the sleeve outside, at least one window is made in the headband, in which a hollow body of a removable terminal module having a mounting flange is mounted to the gunner, while the module case is made with oppositely oriented nozzles with through sockets for installing adapters of optical connectors and cable plugs in them, one nozzle is located in the cavity rpusa coupling and communicates with it, the other nozzle located in the sealed unit formed by elements of the cavity casing which is disposed on the outer side of the end cap, wherein the housing cavity configured to house the forks of optical connectors, all subscriber cables and adapters to be connected with plugs.

The cavity of the casing is formed by two covers of the module housing and this cavity is hermetically connected with the cavity of the coupling, while in the covers there are grooves that form passages for subscriber cables in the working closed position.

The cavity of the terminal module housing is formed by the module housing and at least one module housing cover, while the housing cavity is hermetically connected to the coupling cavity, and grooves are made in the housing and module cover, forming passages for subscriber cables in the working closed position.

The head-end window has a rectangular shape in which a rectangular nozzle of the module housing is located.

 In the presented description and the drawings, one example of the implementation of an optical coupler having an end cap, enclosed by the housing, on which the optical elements of the coupler are fixed, is shown. Such couplings for external use operate in severe atmospheric conditions, they are fixed mainly on poles or on other load-bearing elements of building structures.

In FIG. 1 shows a general view of an optical coupler with terminal modules for introducing cables into the sleeve body.

In FIG. 2 - optical clutch disassembled.

In FIG. 3 - disassembled coupling sleeve and terminal modules.

In FIG. 4 - ogolovnik couplings and terminal modules assembly with the image of the plug in one of the holes of the ogolovnik.

In FIG. 5 is a view of the terminal module, the headband and the plug in the disassembled position.

In FIG. 6 is a view of the terminal modules of the coupling, which are closed by the covers of the cases of the terminal modules with subscriber cables inserted into the modules.

In FIG. 7 is a view of the end of the coupling with terminal modules from the inside of the end of the head with connected plugs and cables.

In FIG. 8 - terminal module of the coupling with the base of the module housing and one rotatable module cover.

In FIG. 9 is a view of a terminal module of a coupling with two rotatable module covers open.

In FIG. 10 is a rear view of the terminal module with the covers closed.

In FIG. 11 is a view of the terminal module with the covers closed.

In FIG. 12 - module housing with optical adapters installed in its nozzle.

In FIG. 13 is a view of the sleeve end of the clutch with the lower terminal module installed in it with two covers open and the upper module installed in the head end of the front module with one cover of the upper module open, as well as with optical connectors and cables installed in the body of each module.

In FIG. 14 — place A in FIG. 13 in an enlarged view.

In FIG. 15 - the terminal module in disassembled form, in the position of connection of its elements with optical connectors assembly and with cables.

In FIG. 16 is a view of a terminal module with connected optical connectors assembly with cables and open covers of the module case.

In FIG. 17 is a view of a terminal module with connected optical subscriber cables and closed housing covers.

In FIG. 18 is a front view of the terminal module with the covers closed, with subscriber cables connected and with forks located inside the coupling housing connected to the optical coupling cables.

In FIG. 19 is a view of the terminal module assembly with a multi-port optical connector adapter.

In FIG. 20 - the first execution of the module housing (covers removed).

In FIG. 21 - second execution of the module housing (cover removed).

In FIG. 22 is a rear view of an embodiment of an inner surface of branch pipes of a module case.

In FIG. 23 is a front view of an embodiment of an inner surface of branch pipes of a module case.

In FIG. 24 - windows ogolovnogo from its outer side with a cutout of one window.

In FIG. 25 - window headband on its inner side with a single window cutout.

The optical coupling contains a hollow body 1 (Fig. 1), detachably connected by a clamp 2 with a headband 3. The clamp is made of two halves and has a hinged latch. At least one terminal module 4 (Fig. 4) is installed in the head end for inputting subscriber optical cables newly connected to the coupling.

On the ogolovnik (Fig. 1) there are round nozzles for input into the coupling of the optical distribution cables of the communication lines: an oval nozzle 5 and a round nozzle 6, while at the end of the oval nozzle there are three round nozzles 7 of smaller diameter. The sealing of the input cables (not shown) in the nozzles of the sleeve of the coupling is carried out by heat-shrinkable tubes (tubes not shown).

A pair of protrusions 8 is made on the headband 3 for connecting the headband 3 of the coupling with the fastening elements of the coupling to a support (not shown). By means of protrusions 8, the sleeve is mounted on a support, for example, on a pole of a power line so that the body 1 of the sleeve is located at the top and the headband is under the body. Preferably, the sleeve is mounted on a support in an upright working position. This arrangement of the coupling in its working position facilitates the installation of the housing 1 on the headband and removal of the body from the headband. In this case, the clutch housing protects its connection with the headband and at the same time protects the input of optical cables into the clutch from atmospheric precipitation.

In order to ensure the compactness of the coupling and the convenience of working with it, the terminal modules 4 are located on the body of the headband 3 as shown in FIG. 1 - on opposite sides of the nozzles 6 and 7 of the head end, the length of each protruding outward from the head end of the module 4 is selected so that it does not exceed the length of each of the nozzles 6 and 7 made on the head end, which are designed to accommodate the input and output optical cables.

Between the flanges of the housing 1 and the headband 3 (Fig. 2) there is an elastic sealing gasket 9 (Fig. 2) of the coupling housing for sealing the junction of the housing and the headband, between the flange of the housing of the terminal module 4 and the flange of the headband 3 there is an elastic sealing gasket 10 of the module housing. In this example, the coupling, on opposite sides of the round and oval nozzles 6 and 7, are located in the wall of the headband two through windows 11 (Fig. 2, 3) for the installation of two terminal modules 4. Each window 11 is preferably rectangular in shape corresponding to the shape of the terminal module housing. A hollow case of a removable terminal module 4 is installed in each window 11. The module case has many elements that form its complex three-dimensional shape. It is a separate removable part.

Inside the mentioned housing 1 of the coupling are located the bracket 12 (Fig. 2) of the mounting block of cassettes, elements 13 for mounting cables, while the bracket 12 has a plate for mounting cables, as well as closed on top of the cover 14 block of cassettes 15, designed to store splices and stock optical fibers. The cassettes are fastened together in a block with plastic loops 16 of the cassette.

On the protruding part of the housing 17 of the terminal module facing the gunner 3, latches 18 of the module (Fig. 11) are made to fix the housing 17 of the module in the window 11 of the gunner 3 and to connect the housing to the gunner. Said gasket 10 is adjacent to the flange 19 (Fig. 3) of the rear of the housing 17. The flange 19 and the gasket 10 ensure a tight fit of the module housing 17 to the flange of the headband. If module 4 is not installed in the window 11 of the head end, then the window is hermetically closed by a plug 20 (Fig. 4). If the subscriber cables 21 (Fig. 10) are not connected to the terminal module, then the inputs to the module 4 are closed with plugs (plugs are not shown). In the case of connecting subscriber cables 21 to module 4, these cables are located in the passages that are formed by the grooves 28 in the covers 22 of the module (Fig. 6).

The housing 17 of the module 4 (Fig. 9) has two rotary covers 22. In the closed position, the covers form a hollow casing of the terminal module with a sealed cavity for accommodating plugs 23 of the optical connectors of the user cables connected to the adapters that are located in the sockets of the body pipes described below module. The plugs 23 of the subscriber cables 21 (Fig. 16) are connected to the optical cables 24 of the coupling.

The elastic gaskets 25 are located in the grooves of the first embodiment of the module housing 26 (Fig. 8), and they are also located in the grooves of the second embodiment of the module housing 17 (Fig. 9). The order of the buildings is indicated conditionally.

For tightness of the cavity of the module housing 26 (Fig. 8), an elastic u-shaped gasket 27 is located in the u-shaped groove of the module 26 housing 4. For the subscriber cables 21 to be sealed in tightly into the module housing 26, grooves 28 are made in its cover 22, which are also made the base 29 of the housing 26 as shown in FIG. 8. Gaskets 25 and 27 intersect grooves 28 and are in grooves in a compressed state when cover 22 is closed.

The housing 26 of the module (Fig. 8, 21) has a stepped shape. In this embodiment of the housing 26, its upper pivoting cover 22 is connected to the housing through an elastic cover gasket 25. In this embodiment, the upper cover 22 in the working position is docked with the base 29 of the housing 26, performing the functions of the lower cover. This base 29 is integral with housing 26 and is a continuation of this housing. This embodiment of the housing 26 has only one rotatable top cover 22 with a stepped gasket 25 located in its groove. Since the base 29 of the housing 26 is a continuation of the housing 26, the base 29 is in a fixed position at the moment when the cover 22 is turned towards the base and dock with him.

The gaskets 25 of the two covers 22 of the housing 17 (Fig. 9) in the working position are in contact with each other and with the surface 30 of the housing 17 of the module. On the side of the housing 17, on the opposite side from the latches 18, the through slots 31 are separated in the housing 17 by partitions for installing optical connectors and optical connector adapters 38 (FIG. 12). Each cover 22 of the housing 17 from the inner side around the perimeter has a recess in which is placed an elastic gasket 25 (Fig. 9). By hinge 32 (Fig. 12), each cover 22 is connected to any embodiment of the module housing.

Each cover 22 has an emphasis 33 (Fig. 9) for fixing it in the closed operating position. On the inner surface of the covers 22, ribs 34 are made to limit the longitudinal movement of the plugs 23 of the subscriber cables 21 in the closed position of the covers 22 of the housing 17.

Each lid has a lid lock 35 (FIG. 10). The lid lock limiter 36 (Fig. 9) is located on its side opposite to the lock 35. The housing 17 and the housing 26 have guides 37 (Figs. 20, 21) that also perform the functions of stiffening ribs of the housing.

Each hinge 32 of the connection of each cover 22 with the housing 17 has ears with holes in them, in which the removable hinge axis 39 is located (Fig. 15).

The above-mentioned adapter 38 (Fig. 12, 14) of the optical connector is a detachable part separate from the module, it is connected to the module as shown in the drawing for easy installation. In one embodiment of the terminal module, a multi-port adapter 40 of the optical connector is installed in its housing 17 (Fig. 19).

The housing 17 and the housing 26 of the modules are made with oppositely oriented nozzles 41 and 42 (Fig. 8, 9). In these pipes, said through sockets 31 are made for installing optical connector adapters in them.

One pipe 41 in the working position of the coupling is located in the cavity 43 of the housing 1 of the coupling (Fig. 4, 7) in the area of its headband 3 on its inner side. This pipe 41 is in communication with the cavity 43 of the coupling (Fig. 4), formed by the housing 1 and the headband 3.

Another pipe 42 (Fig. 6, 8) is located on the opposite outer side of the gunner 3 and on this pipe one cover 22 of the housing 26 or two covers 22 of the housing 17 are pivotally mounted, which form a hollow casing 44 (Fig. 17) in a closed position with a tight cavity 45 formed by covers 22 when they are closed. The cavity 45 of the casing 44 is formed by two recesses of the covers on their inner sides. Each cover in its cross section has a trough-like shape.

Located in the cavity 45 of the casing 44, the pipe 42 (Fig. 16, 17) is used for placement in its sockets 31 of the plugs of the optical connectors of the subscriber cables connected to the adapters 38 located in the sockets of the pipes 41 and 42. The pipes 41 and 42 are integral with the case 17 module, while the nozzles are oppositely oriented with respect to each other and are located along the module. Their through sockets 31 for installing optical connector adapters in them are also located along the module.

The cavity 45 of the casing 44 (Fig. 17) is configured to accommodate the subscriber cables 21 and plugs 23 of the optical connectors that are connected through adapters 38 located in the sockets 31 of the pipes 41 and 42 to the cables 24 located in the coupling (Fig. 17) . 16, 17).

An emphasis 46 is made in each slot 31 of the module housing 17 of the module (FIG. 20) and the module housing 26. The aforementioned ears 47 are made in the upper and lower parts of the housing 17 on the pipe 42 with holes in them under the axis 39 of the hinges 32. The ears 47 of the other case 26 (Fig. 21) are made on one upper part of the body of the pipe 42.

On the inner upper surface 48 of each housing of the module 4 (Fig. 22, 23) there is an upper stop 49, and on the side surface 50 of the housing there is a stop 51. Each adapter 38 has a spring clip 52 (Fig. 22) of the adapter for fixing it in the working position in the socket 31 of the housing. Access to each latch is through a groove 53 made in the upper wall of the pipe 42. On the upper part of each adapter 38 there is a stop 54 that interacts with the upper stop 49 of the housing 17 in the operating position of the module.

In ogolovnik 3 (Fig. 24), each window 11 is edged with a closed protrusion 55, inside which a stop 56 is made around the perimeter of the window. A flange 57 is formed around each window 11. The opening of the window 11 is formed by the edge 58 (Fig. 25), while the ogolovin 3 has flange 59.

All the cables mentioned in the description are made optical, with bundles of optical fibers covered by insulation. All of the aforementioned plugs and optical connectors are designed to connect optical cables and in the working position of the coupling are connected to the corresponding elements of the coupling.

An optical clutch is manufactured commercially by industrial means, and at the same time, one window 11 or two windows (Fig. 2) are made in the wall of the clutch head, which are sealed with plugs 20 (Fig. 4).

In another manufacturing variant, the windows are not made in the head end, however, the sections of the head end where modules 4 are supposed to be installed are made by scoring, the big bars of which indicate the location of the window 11. During the installation of the coupling on the communication line object, if necessary, this place is cut out with a tool as indicated scored lines and get a window 11 in the wall of the head end in the design place. After the operations, a terminal module 4 is inserted into the window 11.

In the third embodiment of the manufacture of the coupling, the terminal modules 4 are installed in the windows 11 of the headband 3 simultaneously during the installation of the coupling in the conditions of its production.

The installation of the coupling and bringing it into working position is performed at the construction site of the communication line. When mounting, cut off in the transverse direction at the calculated places the caps of the nozzles 6 and 7 of the headband 3, put heat-shrinkable tubes onto the cables (tubes and cables not shown), cut the cables according to the established technology and fix the cables to the fasteners 13 of the coupling (Fig. 2). Next, the optical fibers of the distribution and internal connecting cables 24 are welded (Fig. 7) and the stock and fiber splices are placed in the cassettes 15 (Fig. 2). Then, in a known manner, heat-shrink tubes are heated and seated on the cables and pipes 5, 6 and 7 of the headband 3 (Fig. 1). Clamp 2 is closed and the clutch housing 1 and the headband 3 are fixed in the connected operating position. Next, the clutch is fixed on a support in an inaccessible place or on a pole of a power line with the headband down in the working position of the coupling. At the same time, coils of the cable reserve are located next to the coupling on the support, allowing, if necessary, to remove the coupling from the support and lower it to the ground for repair or replacement, or for installation work to connect additional subscriber cables 21 to the communication line.

If it is necessary to connect subscriber users to the optical communication line through the optical coupling, when it is mounted at the top of the power line support, one or two plugs 20 (Fig. 4) are removed from the windows 11 and terminal modules 4 are installed in the windows. Each module 4 is installed in the window 11 of the headband 3, the clutch is produced on a clutch mounted in the working position, in the cavity 43 of which there are pre-positioned forks 23 of the optical connectors in it (Fig. 14). In this case, the plugs 23 are connected to the cables 24 of the coupling, which are also located in the cavity 43 of the coupling (Fig. 4).

To connect a subscriber’s user to an optical communication line through an optical coupling, a plug (not shown) is removed from the closed grooves 28 (FIG. 10), the covers 22 of module 4 are opened (FIG. 14), and the plug 23 of the subscriber cable 21 is inserted into the corresponding socket 31 of the pipe 42. In this case, the subscriber optical cable 21 is connected to the optical adapter 38 located in the socket 31 of the pipe 42. Since the adapter 38 is optically connected to the plug 23 of the optical cable 24, the subscriber cable 21 is optically connected to the optical cable 24 located m in the coupling cavity without opening it and removal of the end cap 3 with the clutch housing.

 It is possible to connect subscriber cables 21 to such a coupling, which is made without its preparation for connecting subscriber cables to it. In this case, to connect the subscriber cable 21 perform the following steps. The lever of the clamp 2 (Fig. 1) is put into an inoperative position and the lever 12 is removed from the housing 1 with the cassette block 15 fixed on it. Windows 11 are made in the headband 3 (Fig. 5) and modules 4 are installed in them. Slots 31 (Fig. 1) . 9) install adapters 38 (Fig. 13). When installing the modules 4 in the holes of the headband, the elastic gaskets 10 are compressed, the latches 18 are latched and the modules are securely and tightly fixed in the working position on the headband.

When mounting the connecting cables 24 (Fig. 7), terminated with plugs 23, lay out and fasten to the bracket 12 (Fig. 2), then connect the cables 24 to the adapters 38 on the inside of the headband (Fig. 7). After connecting the plugs 23 of the cables 24 to the adapters 38 of the module, install the gasket 9 on the headband 3 of the coupling and connect the headband to the body with a clamp 2 of the coupling. Then, external subscriber cables 21 (Fig. 15) are connected through plugs 23 to the adapter 38 of the module from the outside of the coupling. After connecting the cables 21 to the adapters 38, close and close the covers 22 of the module 4, snap the locks 35 (Fig. 10), while the gaskets 25 of the covers 22, the cables 21 are crimped along the perimeter in the grooves 28 of the covers 22 and the cables 21 are sealed in the passage of the terminal module 4 (Fig. 16).

During the operation of the coupling, if it becomes necessary to connect new subscriber users to the optical communication line, the covers 22 of one or each terminal module are transferred from the operating closed position to the open mounting position (Fig. 12), then optical adapters 38 are installed in the sockets 31 (Fig. . 11-13). The number of adapters installed may not coincide with the number of sockets and some of the sockets may remain free for other connections. On the outside of the case, optical connectors are connected to the plugs 23 (Fig. 13) and connected to the corresponding adapters 38, which are connected to the plugs 23 of the optical connectors of the subscriber optical cables 21.

Then, the covers 22 are moved to the working position, closing them together, while the protective sheaths of the subscriber optical cables 21 are clamped by elastic spacers 25 in the passages between the covers, after which the latches of the covers 22 are latched (Fig. 2).

 If the number of subscriber cables connected with the terminal module is less than the number of passages in the covers, then blank cylindrical plugs (not shown) are introduced into the free passages of the modules formed by the grooves 28 of the covers 22, the diameter of which corresponds to the diameter of the sheaths of the subscriber optical cables.

If necessary, access to the cassettes 15 of the coupling, open the clamp 21 with the lever latch, release the headband 3 of the coupling, remove the headband and cassettes 15 mounted on its bracket 12, remove the loop 16, release the necessary cartridge 15 and, with the module covers open 22, carry out all necessary known installation work to connect those elements of the coupling with the elements of the module elements that must be connected. At the same time, all optical connectors of the coupling and all elements of the coupling are opened simultaneously with one or two covers 22 of the module housing open, and access to all cassettes 15 of the coupling is also opened, which significantly reduces the complexity of installation and dismantling work on communication lines.

The installation of module 4 in the window 11 of the coupling is as follows. The gasket 10 is put on the branch pipe 41 (Fig. 3) of the module and, by moving the module 4 towards the headband 3, the module branch pipe 42 is inserted into the window 11 of the headband until the flange 19 (Fig. 3) of the rear part of the module 4 body is in the wall of the headband 3. In this case, the elastic the gasket is compressed, the elastic latches enter the window 11 and, interacting with the edge 58 (Fig. 25) are latched from the inside of the headband. In this case, the flange 57 is pressed against the flange 19 of the module, and the gasket abuts against the stop 56 located around the window 11.

 The installation of adapters 38 (Fig. 22) in the sockets 31 of the housing 17 of the module is as follows. First, the left one in FIG. 22 adapter 38 until the contact of the stop 54 of the adapter with the upper stop 49 of the housing 17. In this case, the spring clip 52 is compressed, passes under the stop 49, latches and abuts against the stop 49 of the housing 17 from the inside of the headband facing the housing 1 of the clutch. During installation, the right adapter 38 shown in FIG. 22 into the socket 31, which then connects the plug 23 (Fig. 14) of the subscriber cable 21. After jamming the cable 21 in the passage between the grooves 28 of the covers 22, the right adapter 38 is fixed in the socket 31 in the working position.

The clutch works as follows. Through the input optical cable (not shown) located in the nozzle pipe 6 (Fig. 1), the optical signals moving along the input cable at a speed close to the speed of light enter the optical fibers of the cassettes 15 (Fig. 2), from where they are given through the optical cables 24 (Fig. 7), through the plugs 23 and adapters 38 (Fig. 14) come out of the coupling. Then, via subscriber cables 21, the optical signals arrive at the subscriber of the communication line.

The design of the coupling allows you to use the outer part of the head end on its external side to install terminal modules in it with passages in them for subscriber cables and simplify the operations of connecting subscribers to the coupling without opening the coupling.

A clutch with windows in its headband for installing terminal modules in them, in the cavity of each of which are plugs of optical connectors, significantly simplifies installation and dismantling works and reduces their laboriousness.

The covers of each terminal module can be pivotally or otherwise fixed on the module case. A different number of optical connectors can be installed in the module case, each of which can be either single or multi-adapter.

The coupling in combination with the terminal modules installed in its head end can be implemented in several versions: with two rotary covers of each terminal module or with one rotary cover relative to the module case, as well as with single optical connectors installed in the module case, or with a multi-adapter optical connector installed in the module housing, or in various other possible combinations.

The design of the terminal module, part of which is sealed in the sleeve of the coupling, with the adapters of optical connectors installed in it, allows connecting subscriber cables terminated by connectors to the fibers of optical cables mounted in the coupling without opening the coupling housing, which simplifies the process of connection and maintenance and reduces the complexity of mounting works.

Also, the design of the terminal module provides for the placement in one of its case of one multiport adapter instead of many adapters of individual single-port modules, which can significantly simplify and reduce the complexity of installation work. The use of such a terminal module in the design of the optical coupling positively solves the issue of its compactness. If one or more modules are installed in the sleeve of the coupling, the size of the coupling does not increase.

Claims (4)

1. An optical coupler characterized by a hollow body with a removable headband having at least one cable entry pipe into the sleeve outside, at least one window is made in the headband in which a hollow body of a removable terminal module having a mounting flange is mounted while the module body is made with oppositely oriented nozzles with through sockets for installing adapters of optical connectors and cable plugs in them, one nozzle is located in the cavity of the coupling housing and communicated with it, d ugoy nozzle arranged in a sealed unit formed by elements of the cavity casing which is disposed on the outer side of the end cap, the cavity housing configured to house the forks of optical connectors, all subscriber cables and adapters to be connected with plugs. 2. The optical coupling according to claim 1, characterized in that the cavity of the casing is formed by two covers of the module housing and this cavity is hermetically connected to the cavity of the coupling, while the covers have grooves that form passages for the subscriber cables in the working closed position. 3. The optical coupling according to claim 1, characterized in that the cavity of the terminal module housing is formed by the module housing and at least one module housing cover, wherein the housing cavity is hermetically connected to the coupling cavity, and grooves are made in the housing and the module cover, forming passages under subscriber cables in a working closed position. 4. The optical clutch according to claim 1, characterized in that the headband window has a rectangular shape in which a rectangular pipe is located in the module housing.

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