DE3743108A1 - Cross-connection matrix for optical waveguides - Google Patents

Abstract

The optical waveguides (2) coming from a central exchange are optionally connected to the optical waveguides (3) leading to the subscribers on a plug panel (4) which is arranged at an easily accessible installation height, preferably horizontally. In this plug panel, a multiplicity of plug elements (6) for establishing optical coupling devices are inserted; the optical waveguides (3) leading to the subscribers are connected to these plug elements. The corresponding counter-plugs (7) are located at the ends of the optical waveguides (3) leading to the exchange. These conductors are supplied to the plug panel (4) from the top, hanging through a central cutout (8) in the plug panel and forming loops when the counter-plugs (7) are plugged together with the plug elements (6). The optical waveguides (2) are of such a length that they can be connected to any arbitrary plug element of the plug panel via their counter-plugs. <IMAGE>

Description

The invention relates to a distribution distributor for Optical fiber for optional connection of a zen central exchange coming with the fiber optic cables leading to the participants.

Optical fibers are increasingly used in transmission technology used instead of copper lines because they are the same early time and / or channel multiplex transmission of a lot number of different data on just one conductor allow. For example, Ge talks and data are transmitted at the same time; this is for example for the operation of the so-called screen phones of interest. Via the optical fiber further data such as Office communication, warehouse data inventory management or data transmitted from databases the. Also the transmission of the on a screen device or to commands and data entered on a keyboard to an ent distant receiver is possible via the optical fiber.

Patch distributor for the optional connection of a variety of Optical fibers are not yet known.

task The invention is therefore a distribution distributor for light waveguide for optional connection of a central Exchange coming with the to the Participants to create leading fiber optic cables that the Routing a variety of optical fibers at the narrowest Allows space and is easy to handle for the operating personnel.

The invention solves this problem by the characterizing Features of claim 1. Advantageous refinements of the distribution distributor according to the invention are in the Unteran sayings.

The invention is explained below with reference to an embodiment shown in the drawing. The drawing shows a distribution room 1 , in which the means for optionally connecting the coming from a central switching point optical fibers 2 with the leading to the participants fibers 3 are accommodated. It is maneuvered on a large-area connector panel 4 which, according to a preferred embodiment of the invention, is arranged horizontally or obliquely at the mounting height. The connector panel 4 is to be arranged in a suitable manner in the distribution room, for example, via angles fastened to the walls of the distribution room, which support the connector panel, via supporting columns on the floor or, as in the illustrated embodiment , attached to the ceiling of the distribution room Rods. These rods are partially covered by a jacket 5 in the illustrated embodiment, for example. The connector field 4 is provided with a plurality of connector elements 6 arranged at regular intervals. These plug elements form part of optical coupling devices, via which the optical fibers are to be connected to one another. The connector elements arranged in the connector field are connected in a suitable manner to the ends of the optical fibers 3 leading to the participants. The coming from the central switching center fiber optic cable 2 are provided at their ends with corresponding mating connectors 7 , which are to be connected optionally with the corresponding connector elements 6 of the connector panel. The connector field is provided with a preferably central recess 8 , through which the ends of the leading to the central switching office Lichtwellenlei ter 2 hang through. The optical fibers are made in excess length, the excess length being dimensioned such that each optical fiber can be contacted via its mating connector 7 with each plug element 6 of the connector field. The optical waveguides hanging down through the recess 8 of the connector field must be guided upwards again for their coupling with the connector elements of the connector field. They form loops and lie on a half of the connector panel 4 at a distance from this arranged deflection frame 9 , on which they can be fixed for strain relief if necessary. The supply of the optical fiber coming from the switching center via a recess 8 arranged in the center of the connector field has the advantage that all optical fibers coming from the switching center can be of equal length. Any deviations in length of the optical waveguide, which are given, for example, by the individual location within the line running to the switching center, are absorbed by the loops.

In the exemplary embodiment shown, the optical fibers 2 coming from the switching center are fed to the marshalling panel via an opening 10 in the ceiling of the distribution space and a cable grate 11 . The to the participants lead the optical fiber 3 are guided in a separate guide channel 12 to the level of the connector panel 4 , so that there is a free space for handling the optical fibers under half of the connector panel. A protective grating 13 is provided below the connector field, which at least partially surrounds the optical waveguide loops hanging through the recess 8 of the connector field 4 and forms mechanical protection for the optical waveguides. The protective grille can also be attached to the deflection frame 9 .

The connector panel 4 may be flat or form a convex surface, which increases the accessibility to the connector elements, in particular in the presence of a large number of optical fibers to be connected. The connector field can be circular as in the illustrated embodiment; however, it can also have the shape of a square, which can possibly lead to better utilization of the distribution space area. To expand the connector field as required, segments, rectangles or trapezoids with additional connector elements can be attached to the side. By retightening the corresponding optical waveguide, the plug-in capacity of the distribution distributor can also be subsequently increased.

In the illustrated embodiment, the leading to the part participants fiber optic 3 with the Steckerelemen th 6 of the connector panel 4 are connected and the leading to the switching center fiber optic 2 are provided with the associated mating connectors 7 and led to the patch panel with excess length. The arrangement can also be such that the optical waveguides leading to the switching center are guided to the plug elements of the connector field and that the optical waveguides leading to the participants have at their ends the mating connectors for the plug elements defined in the plug field.

A major advantage of the shunting distribution according to the invention lers lies in its easy accessibility and manageability speed in that for each pair of optical fibers to be connected only one, consist of plug element and mating connector de coupling device is to be provided; this reduces the Cost of installing an optical fiber patch cord divider significantly compared to an arrangement with two Coupling devices per pair of optical fibers, as in a separate connection line between two fixed instal gated connector fields would be required. In addition, through the use of a single coupling device for each Optical fiber pair the attenuation compared to an execution form significantly reduced with two coupling devices.

Claims (9)

1. Manifold for optical fibers for optional connection of the optical fibers coming from a central exchange with the optical fibers leading to the participants, characterized in that a large-area connector field ( 4 ) with a plurality of arranged at regular intervals, forming part of an optical coupling device Plug elements ( 6 ) are provided, to which either the optical fibers ( 3 ) coming from the exchange or leading to the subscribers are connected individually and that the optical fibers ( 2 ) combined in the other strand are connected at their ends provided with the corresponding mating plugs ( 7 ) and made so long that they can be coupled to any plug element ( 6 ) of the plug field ( 4 ) via these mating plugs. 2. patch distributor according to claim 1, characterized in
that one strand is led over a cable grate ( 11 ) running along the ceiling of the distributor space up to the vicinity of the connector panel ( 4 ) and hangs down from there,
that the connector panel ( 4 ) is arranged horizontally or obliquely at assembly height and is provided with a preferably central recess ( 8 ) through which the optical fibers ( 2 ) of the strand guided on the cable grate ( 11 ) hang from above,
that the optical fibers ( 2 ) forming loops over a below the connector panel ( 4 ) at a distance from this angeordne th deflection frame ( 9 ) and from the bottom of the connector panel ( 4 ) forth with their mating connectors ( 7 ) on the connector elements held in the connector panel ( 6 ) can be placed and that the connector elements ( 6 ) on the top of the connector panel ( 4 ) to the in a separate guide channel ( 12 ) up to the level of the connector panel ( 4 ) guided optical fiber ( 3 ) of the other strand are connected. 3. Manifold distributor according to claim 1 or 2, characterized in that the connector panel ( 4 ) is fastened to the distributor room ceiling via a linkage. 4. patch distributor according to one of claims 1 to 3, characterized in that the connector panel ( 4 ) is circular. 5. patch distributor according to one of claims 1 to 3, characterized in that the plug field is square. 6. distribution distributor according to one of claims 1 to 5, characterized in that the Connector field forms a flat surface. 7. distribution distributor according to one of claims 1 to 5, characterized in that the Connector field forms a convex surface. 8. patch distributor according to one of claims 1 to 8, characterized in that the Connector field by lateral positioning of segments or Rectangles or trapezoids on larger plug capacities is further. 9. patch panel according to one of claims 1 to 8, characterized in that below the connector panel ( 4 ) a protective grille ( 13 ) is provided which at least partially surrounds the through the recess ( 8 ) of the connector panel, the optical waveguide loops.