DE19548502A1 - Fixing and positioning apparatus for sheathed optical fibre - Google Patents

Abstract

The optical fibre has an oblique end face and the sheath (7) has an oblique region (2) near the end of the optical fibre on the side with the end face of the optical fibre. The fixing and positioning apparatus includes a hollow cylindrical body (3) into which the sheath is coaxially introduced. The hollow body has a stop (4) at one end which is terminated by a coaxial bore hole (5). The stop has a wedge shape. The bore hole is designed so that when the sheath is introduced the slanted area of the end face of the sheath contacts the stop.

Description

The invention relates to a device for fixing and Position an optical fiber end in a sleeve is summarized, the optical fiber end being a beveled Has end face and the end face of the sleeve at least is chamfered in areas near the end of the optical fiber, wherein a hollow cylindrical body is provided, in which the Sleeve of the device can be introduced coaxially. Continue The invention relates to a use of the device.

In optical transmission systems, it is known to have optical fiber ends to couple to optoelectronic elements. Here it is often necessary that the optical fiber end in relation on the active surface of the optoelectronic transmission or Receiving elements is adjusted. Because back reflections from Light in the optoelectronic element can be avoided should, especially when coupling an optical fiber to a laser, it is known to face the face of the Chamfer fiber end. By the inclination of the End face is the reflection of those emerging from the laser Light on the face of the optical fiber back into the Lasers no longer possible.

It is also known optical fiber ends in sleeves, too Plug or connector pins called to grasp. This Sleeves are made of either ceramic or metal, are worked very precisely and ensure the coaxial Position of the optical fiber end to its cylinder axis.

The object of the invention is a device for fixing and positioning one contained in a sleeve Optical fiber end specifying both an axial and also a radial positioning of an optical fiber end  allowed with a beveled face. Next one should Use of such a device can be specified.

The task is done in relation to the device with a Device with the following features solved:

An optical fiber end contained in a sleeve has one beveled face; the sleeve faces on the side with the end face of the optical fiber on one end face, at least in the area near the end of the optical fiber is beveled; it is a hollow cylindrical body provided, into which the sleeve can be introduced coaxially; of the hollow cylindrical body is at one end with a stop closed with a coaxial bore; the stop is to the inside of the hollow cylindrical body coaxially to The bore is conical and the bore is such designed that when the sleeve is inserted, the beveled Area of the end face of the sleeve touches the stop.

Advantageous further developments are in subclaims 2 to 6 specified. In terms of use, the task solved by a use according to claim 7.

Advantageous further developments are in claims 8 and 9 indicated.

The arrangement according to the invention makes it possible Optical fiber end with a bevelled end face too to be positioned in the axial direction. It serves the conical stop as a stop for the beveled area of the end face of the sleeve in which the Optical fiber end is captured. A lateral guide in the hollow cylindrical body is achieved in that the hollow cylindrical body or the sleeve in which the Optical fiber is contained in its outer diameter or coordinated with each other in their clear width  are. A very precise opening in the hollow cylindrical body can be achieved in that the hollow cylindrical Body has a ceramic tube on the inside or is made entirely of ceramic.

It is particularly important that the stop is made of a hard Material is made to withstand wear and tear counteract multiple introduction of fibers. The Arrangement is particularly suitable for that multiple exchanges of fibers for all fibers an accurate Adjustment and positioning is achieved. A wear and tear the conical stop is also avoided that the angle between the mantle of the conical Stop and the cone axis the acute angle between the inclined area and the axis of the sleeve corresponds.

The device according to the invention can be particularly advantageous for positioning optical fiber ends relative to optoelectronic transmitting or receiving elements used will. The hollow cylindrical body is part of one Housing in which the optoelectronic component is added is. The optoelectronic component is opposite to the Hole firmly positioned. Housing, hollow cylindrical body and stop can be in one piece as well as several interconnected parts from be executed. Through the Introduction of a mounted optical fiber in the hollow cylindrical body is then ensured that this exactly compared to the optoelectronic component is positioned.

In order to achieve the most accurate positioning possible, hitting the sleeve as close as possible to the Fiber. This can be achieved in that the clear width of the hole only slightly larger than that Diameter of the fiber is.  

It is known in the prior art that the end face of Grinding optical fibers spherically. This can also be done in Combined with a sloping face. The The arrangement according to the invention is also suitable for this purpose Align the processed fiber axially. It can also inclined area of the end face of the sleeve slightly convex be ground.

With the invention, a highly precise positioning in Longitudinal direction reached. This must, for example, at the Connection of an optical fiber to a laser very precisely be because the light emitted by the laser hits the face the optical fiber must be focused to a high To achieve coupling efficiency. One problem is that the face of the sleeve contains several tolerances, such as Changes in the rounding radius of a spherical end face, Tolerances in the helix angle, tolerances in the diameter of the inclined area. The influence of the tolerances is determined by the invention minimized.

An embodiment of the invention is based on the Drawings explained. Show it:

Fig. 1 is a schematic representation of a device according to the invention and

Fig. 2 shows an arrangement for using a device according to the invention.

In Fig. 1, an apparatus according to the invention is shown. A sleeve 7 , in which an optical fiber end is held, can be seen. The end of the optical fiber has a bevelled end face. The sleeve 7 has a pin 1 at one end with the end face of the optical fiber end, of smaller diameter than the sleeve 7 . The end face of the sleeve 7 thus has a step, the pin 1 ending in a chamfered area 2 . The chamfered area 2 is coplanar with the chamfered end face of the optical fiber end. The end face is inclined at an angle α with respect to the axis of the optical fiber end or the sleeve. It is also possible, for example, for the beveled region 2 and the end face of the optical fiber to be spherical in addition to the inclination, that is to say they are curved outwards.

Another possible implementation is that the entire face of the sleeve is inclined, so none has additional level. It can also be slightly crowned be executed.

The sleeve 7 can be metallic or ceramic, for example. The optical fiber end can be inserted with the sleeve 7 into a hollow cylindrical body 3 coaxial to the axis of this hollow cylindrical body. The hollow cylindrical body 3 can have a tube, for example a ceramic tube 11 , on the inside. Such a tube can be produced with a very precise inner diameter, such that a high-precision guidance of the sleeve 7 in the cylindrical body 3 is achieved. The hollow cylindrical body 3 has a stop 4 at one end. This stop 4 can be part of the cylindrical body 3 or a separate part. It has a bore 5 which runs coaxially to the axis of the hollow cylindrical body 3 . The stop 4 is designed conically towards the interior 6 of the hollow cylindrical body 3 , the cone axis coinciding with the axis of the bore 5 . It is particularly advantageous if the angle between the cone shell and the cone axis β corresponds to the angle α between the end face and the axis of the optical fiber end.

The arrangement shown in FIG. 1 makes it possible to adjust a beveled and possibly spherically ground optical fiber at a certain distance from a certain point on the axis of the hollow cylindrical body. The inclined region 2 of the end face of the sleeve 7 abuts against the conical surface of the stop 4 . The diameter of the bore 5 is therefore smaller than the diameter of the pin. The clear width of the bore 5 should be larger than the diameter of the optical fiber so as not to damage the end face of the fiber. In order to achieve a high level of accuracy, it makes sense to provide the point of contact between the stop and the inclined area as close as possible to the fiber.

FIG. 2 shows a use of the arrangement shown in FIG. 1. The hollow cylindrical body 3 is part of a metallic housing 8 , which additionally has a receptacle for an optoelectronic transmitting or receiving element and an additional optical element. In this case the optical element is a spherical lens 10 which is fixed with respect to the axis of the hollow cylindrical body. A lens holder is provided in which the optoelectronic transmitting or receiving element, for example a laser 9 , is fixed. Due to the precise fixing of the hollow cylindrical body 3 to the optoelectronic element 9 and ball lens 10 , an exact positioning of the optical fiber end, which can be inserted into the cylindrical body, is ensured in the axial and radial direction relative to the laser 9 .

Claims (9)

1. Device for fixing and positioning an optical fiber end, which is set in a sleeve, the optical fiber end having a beveled end face and the sleeve ( 7 ) on the side with the end face of the optical fiber end has an end face which has a beveled area at least near the optical fiber end ( 2 ), wherein a hollow cylindrical body ( 3 ) is provided, into which the sleeve ( 7 ) can be introduced coaxially, characterized in that the hollow cylindrical body ( 3 ) has at one end a stop ( 4 ) with a coaxial bore ( 5 ) is closed, that the stop ( 4 ) towards the inside ( 6 ) of the hollow cylindrical body ( 3 ) is conically shaped coaxially to the bore, and that the bore ( 5 ) is designed such that when the sleeve is inserted, the chamfered area ( 7 ) the end face of the sleeve ( 7 ) touches the stop ( 4 ). 2. Apparatus according to claim 1, characterized in that it is suitable for use with an optical waveguide contained in a sleeve if the beveled end face of the optical fiber end and the beveled region ( 2 ) of the end face of the sleeve ( 7 ) are substantially coplanar or if the beveled end face of the optical fiber end and the beveled region ( 2 ) of the end face of the sleeve ( 7 ) form a slightly convex surface. 3. Apparatus according to claim 1, characterized in that the hollow cylindrical body ( 3 ) and the stop ( 4 ) are formed as one part. 4. Device according to one of claims 1 or 2, characterized in that the angle between the jacket of the conical stop ( 4 ) and the cone axis corresponds to the acute angle between the inclined region ( 2 ) and the axis of the sleeve ( 7 ). 5. Device according to one of claims 1 to 4, characterized in that the hollow cylindrical body ( 3 ) on the optical fiber end ( 1 ) facing inside ( 6 ) is made of metal. 6. Device according to one of claims 1 to 5, characterized in that the stop ( 4 ) is made of metal. 7. Use of an arrangement according to one of claims 1 to 6, characterized in that the optical fiber end ( 1 ) is positioned in the axial and radial direction relative to an optoelectronic transmitting or receiving element. 8. Use according to claim 7, characterized in that the hollow cylindrical body ( 3 ) with the stop ( 4 ) is part of a housing ( 8 ) which on the central axis of the hollow cylindrical body ( 3 ) behind the bore ( 5 ) the optically active Surface of an optoelectronic transmitting or receiving element ( 9 ) is arranged. 9. Use according to claim 8, characterized in that between the bore ( 5 ) and the optoelectronic transmitting or receiving element ( 9 ) a further optical element, in particular a lens ( 10 ) is arranged.