DE4236429C1 - Reflection-free end termination for optical fibres - terminates ends of inserted optical fibres in optical sump, with fibre path following corrugations of upper and lower parts of connector - Google Patents

Abstract

The end termination (1) is fitted to an optical fibre or fibre bundle, the ends (5) of each of the optical fibres (3) located within an optical sump (6,7), between parallel upper and lower parts. The optical fibres extend parallel to the latter, which each have a corrugated surface in the optical fibre reception zone transverse to the inserted optical fibres. Pref. the optical sump is provided by an immersion gel or an adhesive. The end faces of the inserted optical fibres lying at an acute angle to the optical fibre axis. ADVANTAGE - Simple assembly and fitting.

Description

The invention relates to a termination device for minde least an optical fiber according to the generic term of Pa claim 1 or claim 2.

For optical couplers with a higher splitting ratio there is often a swirl of up to four meters long optical fiber. An orderly filing and the ge This only allows targeted access to a desired fiber hardly possible. Not all light on the output side waveguide needed for a coupler, so must be ensured that no reflections occur.

From German published patent application DE 32 24 518 A1 an optical coupler with several optical fibers known a reflection-free terminated coupler end. The coupler end is conical for reflection-free termination pulled out and into a light-absorbing potting compound bedded. A suitable casting compound is, for example a filled two-component adhesive based on epoxy resin.

The object of the invention is a termination device for Provide fiber optic cables that facilitate assembly and reflections on non-connected optical fibers prevented.

This object is achieved by a patent claim 1 and Claim 2 specified termination device solved.

Advantageous further developments are in the subclaims specified.  

The invention is illustrated by means of exemplary embodiments explained.

Show it:

Fig. 1 a device formed as a capillary Abschlußein,

Fig. 2 is a block-shaped Abschlußein direction,

Fig. 3, 4 and 5 a variant of the terminal device,

Fig. 6 shows the basic structure of a Kopplermagazins,

Fig. 7 shows an advantageous variant of a coupler magazine, and

Fig. 8 shows the assembled coupler magazine.

In Fig. 1 designed as a capillary 2 closing device 1 is shown. In the interior of the capillary several light wave guide 3 are only provided with their coating and connected with the help of an adhesive 4 on the insertion side with the capillary 2 . The light waveguide ends 5 are broken off or cut off at an angle if possible in order to obtain the lowest possible reflections. They end in an optical sump 6 formed by an immersion gel. The immersion gel has approximately the same or a higher refractive index than the core glass of the optical waveguide. By a capillary 7 , here an adhesive, the immersion gel will hold ge in the interior.

By using a suitable adhesive 7 with a suitable refractive index, the immersion gel can be dispensed with. The adhesive then takes up the space of the immersion gel 6 as an optical sump. The same adhesive can be used for all adhesive points.

Due to the beveled light wave ends and a suitable neten glue or a suitable immersion gel Light coupled out and scattered. The optical thus formed Swamp has high attenuation values (<50 dB). Of the Optical termination is therefore also suitable for overlaying of analog signals.

If an optical waveguide 3 is now to be connected, it is cut off at the termination device and spliced at the desired point with the optical waveguide of an outgoing hollow artery. The remaining lightwave conductors remain in the termination device until they are needed.

In Fig. 2 a variant of the termination device is provided. It consists of a lower part 8 and an upper part 9 . Between both parts, the Lichtwel lenleiter 3 are introduced in parallel. The upper and lower parts are glued together and the optical fibers are glued in at the same time. The adhesive 7 again acts as an optical sump. In the insertion area, the lower part 8 and the upper part 9 each have a washboard-shaped design 10 . Through this, the optical fibers are bent out several times, whereby the attenuation is significantly increased.

Further possibilities for increasing the attenuation are provided by repeatedly deflecting the optical fibers with a small radius. For example, they can be wrapped around the capillary ( Fig. 1) or - like the cord of a telephone handset - wound helically. It is also possible to lay the fiber optic cables in loops with a very small diameter and to fix them so that they do not open by themselves. The fiber optic cables can be easily removed from the ring-shaped loops.

In Fig. 3 another variant of the Abschlußeinrich device is shown. The optical fibers 3 are in a metallic protective device 26 between two layers of porous with an immersion liquid soaked mate rials 27, for example rubber or plastic, placed. Due to the compressed legs of the protection device ( Fig. 4), the rubber layers are pressed together and fix the optical fiber by friction. Now the protective device is bent ( Fig. 5), the Lichtwellenlei ter break and at the break points 28 , the immersion liquid collects, which prevents reflections.

In Fig. 6 an example of a coupler magazine is Darge presents. In a cassette 11 , a coupler 12 is net angeord. Reserve lengths for splicing the Lichtwellenlei ter are accommodated in the cassette itself. The hollow wires 13 of the output optical waveguide 3 are fastened by Hal extensions 14 , 15 and led out. Your light waveguides are fixed in termination devices 1 and 8/9 . The input optical fiber 16 is provided with its own circuit device 1 only for reasons of better mechanical handling. It can also be fixed together with the output optical fibers in the termination device 8/9 .

Fig. 7 shows a coupler magazine which is formed from four cassettes 11 , 17 , 18 and 19 . Cassettes 17 through 19 contain couplers. Thus, a 1: 2 coupler 20 is arranged in the cassette 17 , and a 1:16 coupler 21 or 22 is arranged in the cassettes 18 and 19 , respectively. It is also possible to cascade several couplers in a cassette, e.g. E.g .: 15 couplers with a 1: 2 distribution including splicing. The couplers in the cassettes 17 , 18 and 19 are connected to one another by internal switching wires 23 .

In addition, circular, oval or eight-shaped reserve lengths 24 of the optical waveguide are placed in the cassettes, but for the sake of clarity they are only shown in detail. The hollow veins are grouped together and wound up. Their ends are guided in the cassette 11 and fixed there in Hal extensions. The optical fibers are in the circuit devices from 1 and 8/9 .

Only one access to the top cassette 11 is required during assembly. The internal connecting wires 23 are guided through the side through openings of the cassettes and therefore do not interfere. The connecting wires can be protected with a hose, which eliminates mechanical stress.

In Fig. 8 the fully assembled coupler magazine is Darge. The hollow cores 13 are opened up into bundles 25 . The fitter can remove the desired hollow wire with the already exposed optical fiber from the top cassette and does not need to access the other cassettes.

Couplers with a split ratio less than 16 can be in a coupler magazine consisting of 2 cassettes be brought. The lower one receives the couplers. The The upper cassette is used to store the fiber optic ends and the Ab closing device.

Claims (7)

1. termination device ( 1 , 8/9 ) for fixing at least one optical waveguide ( 3 ), characterized in that
that several optical fibers ( 3 ) are combined in it, the optical fiber ends ( 5 ) ending in an optical sump ( 6 , 7 ),
that it has a flat lower part ( 8 ) and a flat upper part ( 9 ) and
that between the lower part ( 8 ) and the upper part ( 9 ) the optical fibers ( 3 ) are arranged in parallel and that the lower part ( 8 ) and the upper part ( 9 ) in the insertion area of the optical fibers ( 3 ) transversely to the course of the optical fibers ( 3 ) washboard-shaped are trained. 2. termination device ( 1 , 8/9 ) for fixing at least one optical waveguide ( 3 ), characterized in that
that several optical fibers ( 3 ) are combined in it, the optical fiber ends ( 5 ) ending in an optical sump ( 6 , 7 ),
that the optical waveguides ( 3 ) are arranged in a plane parallel between two plates ( 27 ) soaked with an immersion liquid and made of porous material, which are pressed together by a metal protective device ( 26 ) which is bent over in such a way that the optical waveguides ( 3 ) are broken. 3. Termination device according to one of the preceding claims, characterized in that the optical waveguides ( 3 ) are rotated helically outside the insertion opening. 4. Closing device according to one of the preceding claims, characterized in that the optical waveguides ( 3 , 16 ) are fixed by gluing. 5. Closing device according to one of the preceding claims, characterized in that an immersion gel or an adhesive ( 7 ) is provided as the optical sump ( 6 ). 6. Termination device according to one of the preceding claims, characterized in that the ends of the optical fibers ( 3 ) are chamfered. 7. Termination device according to one of the preceding claims, characterized in that at least the output optical fibers ( 3 ) of a coupler ( 12 ) are combined.