DE2555232A1 - Connector for glass fibre conductors - has rotationally symmetric rubber body to force optical fibres together in extended axial channel - Google Patents

Abstract

The glass fibre conductor connector comprises a rotationally symmetric rubber elastic body (1) with a hollow channel (2) in the axial direction to retain the two light fibres. In one embodiment of the connector an external unit is provided which has an annular chamber filled with a liquid and a screw pressurising device. In another embodiment of the invention an annular member with a conical inner profile (7) is placed over the rubber elastic body and is compressed by a screwed nut (9) and bush (10) which when tightened together force the conical member (7) onto the rubber elastic body (1) to cause the optical light fibres together.

Description

Connector for connecting fiber optic light lines

The present invention relates to a connector for connection of fiber optic clearings. With the help of such a connector, fiber optic light lines are created optically and mechanically connected to each other.

In order to connect two fiber optic cables, u are first through controlled breaking of the fibers or by grinding and polishing the fiber ends End faces prepared that are as flat as possible and as perpendicular as possible z the direction are the axis of the fiber.

Then the fiber ends are butted against each other so that the case of an uninterrupted fiber is approximated as closely as possible. The optical Transmission losses caused by a gap between the end faces due to misalignment or caused by a finite angle between the two fiber axes, have been investigated theoretically and experimentally on fibers as well as on fiber models.

In the practical implementation of the described coupling print difficulties arise because of the required adjustment capability: so that the Transmission losses with single-mode fibers remain within a reasonable range (up to 10 °), the gap must be shorter than the axial offset smaller than a fraction of a micrometer and the angle between the fiber axes remain less than about 2 °. With multimode fibers the requirements for the adjustment are less strict. For 5% loss of performance the axial offset can be up to 10 µm and the fiber spacing up to 25 µm.

A number of methods and devices for connection already apply of fiber optic light lines. There are two processes involved in establishing a connection to distinguish: 1. The establishment of the optical connection by aligning the Fiber ends on me. paint fiber spacing, minimal misalignment and minimal angle between the fiber axes, or for minimal transmission loss, 2. the production the mechanical connection by fixing the fiber ends in the optimal position.

The various methods and devices differ in terms of how they are used the alignment and definition of the fibers. Used to align the fiber ends e.g. micromanipulators, eccentrically mounted, rotatable and axially displaceable Sleeves in bores, dowel pins made of glass for fibers with a liquid core, glass capillaries, hexagonal guides and circular or V-shaped wheels in various materials or elastomer cylinders under axial pressure. For fixing In the most favorable position, the fiber ends are fused and fixed with glue or held in place by screws or spring forces.

The known methods and devices have the disadvantage that either alignment is difficult or the connection devices are bulky compared to the dimensions of the glass fibers (typical outer diameter 100 µm) are.

The present invention is based on the object of a clear, economical and detachable connection between two Olas fiber light cables create a simple alignment and quick fixation of the fiber ends, If possible, without observing the transmitted signal made possible and through characterized by small dimensions and light weight.

The connection should continue to be available to be able to solve without damaging the fiber and furthermore the invention Plugs for single-mode and multimode fibers are suitable.

According to the invention this is achieved by a plug that has a rotationally symmetrical rubber-elastic body with a center in the axial direction running hollow channel for receiving the fiber ends to be connected and an in Height of the fiber connection point acting on the body in the radial direction Has printing part. The essential component of the connector according to the invention is the rotationally symmetrical or cylindrical body made of rubber-elastic material, in those prepared by known processes for the preparation of the compound Fiber modes are introduced from both sides until they are approximately in the middle of the cylinder bump into each other. Then there are rotationally symmetrical radial forces in the middle of the cylinder to engage, reducing the diameter of the channel and the axes of the fiberglass jackets are automatically brought into congruence, as well as the fiber ends are pinched. The axes of the fiber cores to be connected so practically coincide, so that only very small transmission losses for multimode fibers are to be expected due to misalignment. With the highest concentricity of core and jacket the connector according to the invention can even be used with single-mode fibers. With the connector according to the invention can even use glass fibers with different sheath diameters due to the rotationally symmetrical contract tone of the canal are brought to congruence.

In an embodiment of the invention, it can be used to generate the rotationally symmetrical attacking radial forces be useful if the printed part consists of an annular chamber arranged in the body and filled with liquid, in which can be screwed in a screw from the outside in a sealing manner. By screwing in the screw can put the liquid located in the annular chamber under pressure and on this Way the desired force distribution can be generated. In doing so, the pressure exertion causes due to the liquid an extremely even distribution of force.

According to the invention, it can also be useful to use the radial To generate forces when the body is conical at the level of the fiber connection point and there is surrounded by a correspondingly designed conical ring, which with the help a screw sleeve enclosing it is displaceable in the axial direction.

The screw sleeve expediently consists of a union nut, which can be screwed onto a pressure body acting axially on the conical ring. at In this embodiment according to the invention, the radial forces are generated by the conical ring generated, indenldleser is pushed in the axial direction on the conical body.

According to the invention, it can also be useful if the two Ends of the hollow channel are widened in a funnel shape, whereby the introduction of the Fiber ends in the hollow channel is facilitated.

The hollow channel in the rubber-elastic body can be drilled produce or by putting a suitable plastic around a wire with a matching Diameter is poured and the wire after polymerization from the material is pulled out. If the hollow channel is opened with a TmmersionsflUssigkeit, whose refractive index as closely as possible with that of the used Glass matches, filled, so the losses due to Fresnel reflection to decrease.

As can be seen from the above, the connector described is easy and cheap. The alignment required for the optical coupling Fiber ends and the fixing of the fiber ends take place easily at the same time Application of radial forces.

The connection can be restored by removing the radial forces separate. The connector can be used for single-mode and multimode Fibers and allows the connection of fibers of different sheath diameters and from Fibers with different refractive index profiles.

With the connector described, connections can be made quickly and just recreate and read again. The connection is unresponsive to it Shocks and vibrations and to reduce reflection losses Immersion liquids can be used.

On the basis of the exemplary embodiments shown in the accompanying drawings the invention is explained in more detail. The figures show: FIG. 1 an illustration of the inventive concept Connector in principle, Fig. 2 shows a cross section along the section line II-TT in Fig.l, Fig. 3 a possible embodiment of a connector according to the invention, Fig. 4 another possible embodiment of a plug according to the invention.

Fig. 1 and Fig. 2 show in principle how on a rotationally symmetrical rubber-elastic body 1 with a continuous hollow channel 2 two glass fibers 3 are stirred in with their ends butting against each other. They act on the outside rubber-elastic body 1 radial rotationally symmetrical forces K a, which a constriction effect of the hollow channel 2; so that they are offset from one another in the radial direction Fiber optic ends are aligned with each other and at the same time also thereby in are fixed in their position.

Fig. 3 again shows the rubber-elastic Kirper 1 with the hollow channel 2. The body 1 has an annular chamber 4 which is filled with a liquid 5 is. A screw 6 can be screwed into the annular chamber 4 through the elastic body 1, whereby the chamber volume is reduced and the liquid 4 is thus put under pressure will. The overpressure thus generated in turn causes a radial, rotationally symmetrical one Force acting on the hollow channel 2. In this embodiment it is important to that the screw 6 is sealed against the annular chamber, so that the liquid cannot escape from the annular chamber.

The embodiment shown in Fig. 4 of an inventive Connector in turn consists of a rubber elastic body 1. This body 1 is however, it is conical in the area of the connection point of the glass fibers to be introduced. A conical ring 7 is pushed onto the body 1 and is enclosed in a screw sleeve The screw sleeve 8 consists of a union nut that sits on a pressure body 10 is screwed on. By screwing on the union nut 9, the pressure body 10 is drawn in the direction of the conical ring and moves it onto the conical Part of the body 1. This compresses the rubber-elastic body 1, so that radial forces are generated which constrict the hollow channel 2. The cone ring 7 and the screw sleeve 8 are expediently made of brass.

Claims (5)

Claims: Connector for connecting fiber optic light lines, g e -k e n n z e i c h n e t d u r c h a rotationally symmetric rubber-elastic Body (1) with a hollow channel (2) running centrally in the axial direction for receiving the fiber ends to be connected and one level with the fiber connection point the body (1) acting in the radial direction pressure part (7, 8, 9, 10). 2. Connector according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the pressure part consists of an in the body (1) arranged, with liquid (5) filled annular chamber (4), into which a screw (6) can be screwed in a sealing manner from the outside is. 3. Connector according to claim 1, d a d u r c h g e k e n nz e i c h n e t that the body (1) is conical at the level of the fiber connection point and there is surrounded by a correspondingly designed Konusrlng (7), which with With the aid of a screw sleeve (8) enclosing it, it can be displaced in the axial direction is. 4. Connector according to claim 3, d a d u r c h g e k e n n -z e i c h n e t that the screw sleeve (8) consists of a union nut (9), which on a on the conical ring (7) axially acting pressure body (10) can be screwed. 5. Connector according to one or more of claims 1 to 4, d a -d u r c h e k e n n n z e i c h n e t that the two ends of the hollow channel (2) are funnel-shaped are widened.