RU116248U1 - DISTRIBUTION DEVICE FOR OPTICAL CABLES - Google Patents

Abstract

1. A distribution device for optical cables, characterized in that it contains a housing with rear, side, bottom and top walls, a housing cover, at least two inputs for optical cables located in them are made in the housing walls, in the housing between the rear with a wall and a lid there is a hinged swivel shelf, on one side of the shelf facing the rear wall of the case, in the operating position of the shelf there are means for fixing the splices of optical fibers, and on the side of the shelf facing the cabinet lid, in the operating position of the shelf there is a panel having the means for attaching adapters for connecting optical connectors to it, while openings are made in the shelf for passing optical fibers through them from one side of the shelf to its other side. ! 2. The device according to claim 1, characterized in that the hinged revolving shelf is removable. ! 3. The device according to claim 1, characterized in that at least one of said sides of the shelf is provided with means for attaching at least one optical splitter.

Description

This technical solution relates to devices for terminating, distributing and connecting subscriber distribution optical cables and subscriber optical connecting cords to the fibers of the linear optical cable directly to each other or through a passive optical splitter. The utility model is intended for use in engineering network devices designed for laying and repairing fiber-optic communication lines.

The prior art optical cable distribution devices US5100221 A, 1992-03-31; US2006005282, 2006-02-15; RU2138067 C1, 09.20.1999; RU2059258 C1, 04/27/1996; RU2071074 C1, 12/27/1996; W0200608893, 2006-08-24

A distribution box for fiber optic cables is also known, in which the modular principle of placing elements of a fiber optic communication line is applied, the box consisting of many devices for splicing fibers and a base plate for making connections fixed at different places, but in close proximity to each other away from each other on one support, like sliding sections that are pivotally mounted on the housing of the junction box, and due to rotation on the hinge, the support plate, being outside case, may be inoperative, and it can carry out installation and commissioning, and the splicing devices themselves can be opened to receive from the main cable individual optical fibers that spliced with intermediate optical fibers leading to the support panel for connection to which, through optical connectors, for example, flexible fiber-optic connectors - pigtails, connect optical fibers coming from devices and consumers (EP 0538164, 1993-04-21).

The known box is hardly applicable for limited space in those cases where it is necessary to pivot the entire support with several devices for splicing fibers and a support panel for making connections. In addition, in order to gain access to a single fiber or connection, it is necessary to displace all the optical fibers located in the cable box and move one or more fiber splicing devices, and this will require more time for installation and commissioning work and errors may be made.

A more rational solution to the problem of spatial placement is described in the patent (US5740299, 1998-04-14), according to which instead of devices for splicing fibers and optical connectors that rotate on a hinged joint on a single support, separate cassettes rotate on the hinge, while the hinge is fixed on structural elements interconnected in the form of an ordered longline assembly intended for cable laying, while the incoming and outgoing network or station cables or cables coming from the optical x devices pass through the structural members for wiring to the individual cassettes, in which their optical fibers are spliced and placed in which excess lengths of the fibers. In the decision of US Pat. No. 5,740,299, there are no connectors in the cassettes, such as flexible fiber optic pigtail connectors. As a result, the connection must be made by splicing inside each cassette that rotates on the hinge, while the incoming and outgoing optical fibers enter the cassette through the same channels in the structural elements for laying the cable and through the attached flexible cable channel designed to protect the optical fiber from damage that may result from excessive bending. Accordingly, this requires considerable time and effort, given that the assembly involves compact placement in space, as well as the fact that the installation and change of network or station connections with consumers or devices or between them must be carried out in a relatively small space.

A modular cable box or device for distributing fiber-optic communication lines is known, comprising a structure open in the form of an open box, in which there are support frames for mounting a plurality of optical telecommunication modules on them, a section for laying optical fiber cables in optical cables is made on each support frame telecommunication modules, the box has distribution blocks, elements for laying the cable, each of which is made in the form of a plate and has corresponding fasteners means for fiber optic cables (brackets, hooks and other protruding means for fastening), a corresponding cable channel or guides are made in the area for laying the cable, the support frame has many plates, each of which is vertically mounted by a hinge pivotally mounted on the support frame in such a way that there is access to each plate when they, turning, from the working position go into the inoperative position, and under the working position of the plate is meant such a floor A reduction in which it is to some extent inside the support frame, and a non-working position means a position in which free access to a single plate is provided, for example, in order to install devices or carry out any work, while the plate has grooves, holes or staples necessary to perform structural or other functional tasks, and the rotary axis preferably passes through the end of the plate close to the access point to the support frame, so that when turning the plate, when it goes into an idle state, easy access to the section with an excess of cable length is provided, while the rotary axis of each plate is created using any suitable means, such as loops, a pin attached with screws, such as a crosshead finger, manipulators with a rotary degree of mobility or equivalent assemblies moreover, each plate has a mounting section, designed to be installed on it with the ability to disconnect and securely fasten at least one optical telecommunication module barrel (RU 2371743 C2, 03/27/2009). This box provides many entry and exit points for fiber optic cables and access to an excess of cable length, for example, to a section for mounting an optical module for connections or to a structural element for laying a cable, while the plate is used to lay fiber optic cables on it, coming from one of the many optical telecommunication modules in the immediate vicinity of the rotary axis of the plate with a minimum radius of bending of the cable. The advantage of this arrangement is that when the plate is rotated when it is in the working or inoperative state, the fiber optic cables are subjected to minimal tensile force, and their bending radius can be easily controlled, keeping its value above the minimum acceptable. Said fastening means are preferably cable brackets, but such means as hooks or rails are also suitable.

As mentioned above, optical modules are designed to establish connections between different signal-transmitting optical fibers of the network, and the connections made inside each optical module must be accessed from the outside of the module. Thus, each optical module has many connectors, for example the so-called flexible fiber optic connectors, which are designed to connect the ends of the fiber optic cables (pigtails) and can have at least one entry point so that the fiber optic cables included in the module. The connectors can be used to connect consumers or to make the device with an optical module, and the entry point can be used to connect a network or station cable to the splicing section or other splicing means inside the module that connect it from the inside to the connectors.

Inside the optical module, each connector has an optical fiber leading in the optical module to the splicing sites. To accommodate the aforementioned optical fiber of each module, the optical modules preferably have a portion for accommodating excess cable length and a splice plate for splicing the optical fibers. The splice plate can accommodate some fiber to be placed in addition to fiber splicers. In this regard, the advantage is that the splice plate in the optical module is pivotally mounted and can be moved to provide easy access to the section to accommodate the excess cable length, and also to facilitate installation by separating the main section to accommodate the cable from the section for splicing.

Despite the fact that the foregoing concerned a modular cable box having plates for mounting optical modules, plates are also considered on which at least one optical device is mounted. Here, the optical devices may be passive optical devices, such as signal splitters, or active optical devices, such as signal amplifiers. The described arrangement of the plates simplifies the process of connecting such devices and, in accordance with the requirements, makes it easy to include them in a modular cable box. Thus, the known distributor for optical networks has greater maneuverability in operation and is easy to use if it has at least one modular cable box in one of the above combinations and at least one optical telecommunication module in order to provide Networks The flexible connection of optical fibers with consumers and devices or between them to provide telecommunication and information services.

The essential features of patent RU 2371743 C2 is that the modular cable box contains a support frame for accommodating a plurality of optical telecommunication modules, the support frame has a portion for laying fiber optic cables coming from and to the telecommunication modules, the support frame has many plates, each of which is fixed with the possibility of rotation in order to provide separate access to the plates, the support frame has a mounting section made with the possibility of installing and removing at least one of the many mentioned optical telecommunication modules, as well as a section with fastening means for accommodating the excess length of the fiber optic cable, the plates being L-shaped and the pivot axis extending perpendicular to the plane of the plate through one of the L-shaped sides, said mounting portion is on the other L-shaped side.

A disadvantage of the known technical solution according to patent RU 2371743 C2 is that the device in its working position occupies a large space and therefore it does not meet the requirements of compactness and ease of installation.

A modular cross-sectional block of an optical communication line is known, characterized in that it is mounted in a three-dimensional protective structure such as a cabinet with a back wall on which a three-dimensional bracket with side step-shaped supports is fixed, a folding shelf with means for attaching to it is pivotally connected to each step of the support removable cassette for fixing and storing optical fibers of the communication cable and their splices in it, each shelf has a bar connected to it with slots for installing removable optical adapters in them connectors, the unit is removable, and all shelves in their working position have a fixed connection with the rear wall (RU 101210, 2011-01-10). This technical solution also does not fully satisfy the specified requirements for the operation of the described unit.

The technical result of the technical solution presented in this description is to increase the compactness of the device and ensure ease of use.

The specified technical result was obtained by a distribution device for optical cables, characterized in that it contains a housing with rear, side, lower and upper walls, a housing cover, at least two entries for optical cables located in them are made in the housing walls, in the housing between the back wall and the lid there is a hinged rotary shelf, on one side of the shelf facing the rear wall of the housing, in the working position of the shelf, there are means for fixing the splice of optical fibers, and on the side not the shelf facing the lid, in the operating position of the shelf, there is a panel having means for attaching adapters for connecting optical connectors to it, while the shelf has openings for passing optical fibers through them from one side of the shelf to its other side. The folding swivel shelf is removable. At least one of the indicated sides of the shelf is provided with means for attaching at least one optical splitter.

Figure 1 shows a front view of the switchgear for optical cables in a spatial image (the shelf of the device is in a vertical operating position, the cover of the device is removed);

Figure 2 shows the cover of the device;

Figure 3 - device in a spatial image in a front view (the shelf of the device is in a horizontal working position, the cover is removed);

Figure 4 shows a front view of the housing of the switchgear in a spatial image (the shelf and the cover of the device are removed);

Figure 5 shows a shelf with a cassette mounted on it;

Figure 6 - the reverse side of the shelf with a bracket for installing adapters and a splitter.

Switchgear for optical cables (figure 1) contains a housing 1, in the cavity 2 of which is located a folding removable rotary shelf 3 with clips 4 (figure 3), which serve to fix the shelf in the opening of the housing 1 in its working (vertical) position. In the cavity 2 on the rear wall of the housing 1 is fixed plate 5 (figure 4) with clamps 6 mounted on it. The plate has a comb 7.

The shelf 3 is pivotally connected to the housing via articulated or other joints located between the side walls 8 of the housing. The design of these connections allows you to install the shelf in the housing and remove it from the housing in a specific position of the shelf.

In each side wall 8 there are holes designed for docking the housing 1 with cable ducts and output from the housing 1 optical connecting cords. The overlay 5 and comb 7 are fixedly mounted on the rear wall 9 of the housing with bolts or resistance welding. Each clip 6 is fixed to the cover 5 by a screw 10 with the possibility of pressing the clip to the cover and the possibility of its removal from the cover. Openings 13 are made in the upper wall 11 of the housing and in the lower wall 12 of the housing, in which elastic sealing plugs (cable entries) are located for the cables (not shown) located in them. At least one cassette 15 is mounted on the inner side of the shelf 3 facing the rear wall of the casing (in the vertical position of the shelf) with screws 14 (Fig. 3), which has means for laying optical fibers in it and fixing their splices. The shelf 3 is located in such a way that in its working position between its inner surface 16 on one of its sides and the inner surface of the rear wall 9 of the housing, a space is formed in which at least one cartridge 15 is located. It is provided that the space between the inner surface 16 and the rear wall 9 of the casing is designed in such a way that several cassettes 15 fastened to each other can be located in it, arranged in tier on each other in the horizontal not working position of the shelf 3, as shown about figure 3.

Comb 7 (FIG. 4) has a plurality of T-shaped protrusions 17 arranged in a row, the number of which corresponds to the number of cable entries. Cable entries or sealing plugs are shown at 18. The cover 19 of the device is removable, which does not exclude another embodiment of the connection between the cover and the housing.

It is essential that on one side of the shelf (Fig. 3) facing the rear wall 9 of the housing in the operating position of the shelf there is at least one means for accommodating the optical fibers and their splices, and cassettes 15 belong to such means. the opposite side of the shelf (figure 1), facing the lid 19 of the housing in the working position of the shelf, when the lid is closed, there is a panel 20 with holes 21 for adapters 22 installed in them for connecting optical connectors 23 (pigtails).

In the side walls 8 of the housing, the aforementioned holes 24 are made (FIG. 1) for withdrawing subscriber optical cords from the housing. Each connector 23 (pigtail) is a piece of optical fiber terminated on one side by an optical connector.

The cover 19 (Fig. 2) has at least one lock 25. At least one splitter 26 (Figs. 1, 6) is fixed in the housing for branching the input fiber 27 into a plurality of output fibers 28. In the shelf 3, there are openings 29 for the optical fibers placed in them, emanating from the optical connectors. The openings 29 are intended for the passage of fibers 28 from one side of the shelf to its other side.

The device operates as follows. Remove the lid 19 and the shelf 3 from the housing 1 and attach the housing to the wall by connecting in a known manner the rear wall 9 of the housing with the wall. Connect to the ground terminal of the housing 1 wire connected to the protective earth bus. Through the inlets - sealing plugs 18 - optical cables are inserted into the cavity 2 of the housing 1 (Fig. 1) to the length required for installation work and the optical cables inserted into the housing 1 are cut in accordance with the technological instructions for working with optical cables. The optical cable sheath is mounted on the corresponding T-shaped protrusion 17 (Fig. 4) with a screed (not shown) so that the end of the edge of the optical cable sheath protrudes 3 ... 5 mm beyond the screed. Next, the power elements of the cables are fixed (fiberglass pressed rods pressed into the shell) on the lining 5 with clamps 6.

Install the removable shelf 3 in the cavity 2 of the housing 1 and fix the bundles of optical fibers on the side of the shelf 3, on which the cassettes 15 are located (figure 3). Optical adapters 22 are installed in the openings 21 of the panel 20, to which optical connectors 23 are then connected. The free ends of the optical connectors 23 through the openings 29 (Fig. 6) are transferred to the side of the shelf on which the optical cartridges 15 are located (Fig. 3). To the cable fibers by welding or mechanical connectors connect the free ends of the optical connectors 23. Splices and excess lengths of the optical fibers are laid in cassettes 15 in accordance with the technological instruction. Next, the shelf 3 is transferred to the vertical operating position shown in figure 1, and fix it in the housing by the latches 4 in this position. An adhesive tape or screeds attach an optical splitter 26 (Fig. 1) to the shelf from the side of the panel 20 and connect its leads to the optical adapters 22 in accordance with the wiring diagram. If the design of the communication network provides for the connection of subscribers using optical cords terminated with optical connectors 23, then they are led into the housing through openings 24 in the side walls 8 of the housing and connected to the optical adapters 22. Install cover 19 on the housing 1 and lock it with a lock 25.

The layout of the described technical solution allowed to significantly increase the compactness of the device and, accordingly, provided an increase in the convenience of installation work.

Claims (3)

1. Switchgear for optical cables, characterized in that it comprises a housing with rear, side, lower and upper walls, a housing cover, at least two entries for optical cables located in them are made in the housing walls, in the housing between the rear with a wall and a lid there is a hinged rotary shelf, on one side of the shelf facing the rear wall of the case, in the working position of the shelf there are means for fixing the splice of optical fibers, and on the side of the shelf facing the cabinet lid, what position the shelf panel is located, having means for securing thereto the optical connector adapter connection, with openings formed in the flange for passing therethrough the optical fiber from one side of the shelf on its other side. 2. The device according to claim 1, characterized in that the folding swivel shelf is removable. 3. The device according to claim 1, characterized in that, at least on one of the indicated sides of the shelf, means are provided for attaching at least one optical splitter.