DE4039533A1 - Optical fibre connector assembly - has pins for guiding fibre=optic cable fibres into connector fixed to base - Google Patents

Abstract

The assembly device guides optical fibres (7, 23) into a connector (3) after the coating of the fibres has been removed. The connector is fixed to a base (1) which has at least three guide pins (41, 42, 43; 51, 52, 53) for each optical fibre, which hold the optical cables (61, 91) such that the fibre ends are guided into openings in the connector. The fitting of the fibres into the connector is facilitated by conical tapering of the openings. Several parallel fibres may be guided using an additional clip. USE - For mechanical splice, welded or glued connection of single or multiple fibre-optic cables.

Description

The invention relates to a mounting device for insertion of fiber optic fibers in a connector. Permanent connections of optical fibers are made by Gluing, welding or mechanical couplings. Around to avoid mechanical contamination of the fiber ends, assembly arrangements are used. In the main patent ....... (File number P 40 31 451.0) is such an installation direction indicated, which is preferred for connections by means of a mechanical splice, a so-called finger splice, suitable is. A carrier body is with a holder for the Connection device and with two guide devices ver see that are used to hold optical fibers. By attachable guide bodies, the optical fibers are fixed. However, they can be moved axially and thereby into the connector be introduced. Protection clearances for the Fiber ends prevent contamination during insertion and introducing.

The connection device can also be simpler than in the main patent. It can also be used for multiple splices are provided.

The invention is set out in claim 1.

Advantageous embodiments of the invention are in the Unteran sayings described.

The simple structure of the assembly is particularly advantageous direction.  

Due to the staggered guide elements, the light can shaft line (core or ribbon cable) through their ver larger distance inserted more easily and also by bending the remaining guide element are clamped.

The mounting device is both for making splice joints bindings of individual fiber optic fibers as well as Suitable for multiple splicing. It only has to be the vertical distance be varied between the guide elements and a corre sponding appropriate connecting device can be provided.

It is particularly advantageous for multiple splice connections when hold-down devices fix the optical fibers. A swivel or folding hold-down device makes removal easier the connecting device.

The mounting device can be used for the production of me mechanical connections as well as for welded connections or Adhesive connections are used.

It is advantageous if an additional guide element for this ensures that only an axial displacement of the fiber optic cable and swiveling is no longer possible.

In addition, this mounting device also largely has the Advantages of the mounting device according to the main patent, whose most important advantage is the pollution-free introduction of the Coating freed fiber optic fibers in the connection facility is.

An embodiment of the invention is based on a Mon day device for a mechanical connection device purifies.

Show it:

Fig. 1 shows the main view of a mounting device,

Fig. 2 is a plan view of the mounting device,

Fig. 3 is a side view, in section,

Fig. 4 the insertion of the optical fiber and

Fig. 5 shows a variant of the mounting device for a flat cable.

Fig. 1 shows a mounting device with a carrier body 1, in the middle of a connecting means 3 is fixed by means of a holder 2. The carrier body 1 can have recesses for receiving the connecting device, which are just considered as a holder or part of the holder. Guide devices, each with three guide elements 41 , 42 , 43 and 51 , 52 , 53, are provided on both sides of the carrier body. In a guide device there is already a light waveguide 91 , (an optical waveguide consists of a core or several optical waveguide cores, which in turn each consist of a core and a jacket which is surrounded by the coating; an optical waveguide with an optical waveguide fiber is called Designated optical fiber, several optical fibers can be combined to form a ribbon cable, also called ribbon) here an optical fiber with an optical fiber 23 inserted. Protective spaces 11 and 24 are formed by transverse grooves in front of the insertion openings of the connecting device, into which ends the fibers protrude when inserted. The protective clearances can also extend as far as the insertion openings 26 , 20 of the connecting device.

The insertion of an optical fiber line is shown in Fig. 2. This figure also shows the arrangement of the guide elements. A first optical waveguide line 61 is inserted from above, preferably obliquely between the guide elements 42 and 43 , which are arranged near the protective clearance, from above such that the fiber end 8 projects into the protective clearance 11 . The optical waveguide is then pivoted until it abuts the first guide element 41 and can then be inserted into the connecting device 3 by axial displacement. The vertical distance 27 between the guide elements 42 and 43 corresponds to the diameter or the width of the Lichtwellenlei device. This is facilitated by conically enlarged insertion openings 20 , 26 of the connecting element.

In FIG. 2, a second secured by self-clamping fiber optic cable 91 is illustrated. For this purpose, the light wave line was placed over the guide element 51 - which now acts as a fixing pin. As a result, it is first possible to fix both light waveguides 61 and 91 in order to then introduce them into the connecting device, as shown in FIG. 4.

A hold-down device 25 , here designed as a resilient element, prevents the optical waveguide 91 from bending open during insertion. In the case of a single splice, it is only necessary for an inexperienced or unskilled technician; If several fiber optic cables are to be inserted simultaneously into a correspondingly designed connecting device, it is very advantageous.

The guide elements 42 , 43 and 52 , 53, which are close to the protective clearance, are bent apart upwards in a V-shape in order to facilitate the insertion of the optical waveguide. They are particularly easy to manufacture as round guide pins. Other shapes, for example rectangular, are also possible. Interchangeable guide units with different guide element spacing can also be provided. Of course, a fourth additional guide element 44 or 54 can also be provided in each guide device ( FIG. 4), through which only an axial displacement of the optical waveguides is possible. Since the diagonally inserted line must be lifted over the additional guide element, it should have a lower height than the other guide elements.

In Fig. 5, the guide device for receiving a light waveguide ribbon cable or several lines of light waveguide is formed. A hold-down 24 prevents the lines from bending open. Designed to be pivotable or foldable, it makes it easier to remove the connecting device with the spliced optical waveguides.

Claims (7)

1. Mounting device for introducing the optical fiber fibers ( 7 , 23 ) from optical fibers ( 61 , 91 ) freed from coating into a connecting device ( 3 ) with a carrier body ( 1 ) which has a holder ( 2 ) for the connecting device ( 13 ), with guide devices ( 41 , 42 , 43 ; 51 , 52 , 53 ) through which the optical fibers ( 61 , 91 ) for introducing their fiber ends ( 8 , 10 ) into the guide devices ( 41 , 42 , 43 ; 51 , 52 , 53 ) are positioned so as to be axially displaceable and each have a protective space ( 11 , 24 ) in front of the insertion openings ( 26 , 20 ) of the connecting device ( 3 ) into which the fiber ends ( 8 , 10 ) when inserting and moving the optical waveguide ( 61 , 91 ) protrude, characterized in that as the guide device ( 41 , 42 , 43 ; 51 , 52 , 53 ) at least three guide elements ( 41 , 42 , 43 ; 51 , 52 , 53 ) fastened to the carrier body ( 1 ) are provided, of which the first and the second guide element ( 41 , 42 ; 51 , 52 ) are arranged on a parallel to the axis of the connecting device ( 3 ), and that the third guide element ( 43 , 53 ) is arranged close to the first on the other side of the inserted optical waveguide ( 61 , 91 ). 2. Mounting device according to claim 1, characterized in that the third guide element ( 43 ; 53 ) each connec tion device ( 3 ) closest in the axial direction of the connec tion device and offset to the second guide element ( 42 ; 52 ) is arranged. 3. Mounting device according to claim 1 or 2, characterized in that the vertical distance ( 27 ) measured perpendicular to the axis of the connecting device ( 3 ) between each of the second and the third guide element ( 42 , 43 ; 52 , 53 ) the diameter of a plurality of optical fibers ( 61 , 91 ) or the width of an optical waveguide ribbon cable ( 28 ). 4. Mounting device according to one of the preceding claims, characterized in that the guide device ( 51 , 52 , 53 ) has a hold-down device ( 25 ) for the inserted optical waveguide ( 91 ), the light waveguide ribbon cable ( 28 ) or for a plurality of parallel optical waveguides. 5. Mounting device according to one of the preceding claims, characterized in that guide pins are provided as guide elements ( 41 , 42 , 43 ; 51 , 52 , 53 ). 6. Mounting device according to claim 5, characterized in that the guide elements ( 41 , 42 , 43 ; 51 , 52 , 53 ) are richly bent in the upper loading. 7. Mounting device according to one of the preceding claims, characterized in that an additional guide pin ( 44 ; 54 ) together with the third guide pin ( 43 ; 53 ) is arranged on a parallel to the axis of the connecting element ( 3 ).