DE4017772A1 - Non-interrupting switching of optical communications path - by breaking optical fibre and switching to adjacent input end of outgoing optical fibre - Google Patents

Abstract

The switching device uses a switching optical fibre (13) next to the end of the outgoing optical fibre (12), within the light cone (31) obtained in the switching gaps (33) from the light output face of the incoming optical fibre (11). The width of the switching gap is sufficient to provide a light fleck dia. equal to the dia. of the outgoing and switchinq ootical fibres (1213). The switchino is effected - KK :KK : KKK : : KKK : '. Kw to the axis of the incoming optical fibre (11). TAGEElimates need for T splice.

Description

The invention relates to a method for interruption free switching of an operating optical post straightening transmission line.

In the case of optical communication links, some use cases the need to be in operation sensitive route, for example due to intended dimensions took to replace with a new cable route. With electri cables are made using a method so-called T-splice used. This option is for optical communication links not applicable. If couplers have not been installed in the route from the start, are currently no procedures for uninterrupted switching known.

The invention is based on the object Procedure specifying these requirements in the above Senses fulfilled.

The solution of the problem according to the invention is that the optical fiber is broken in operation in such a way that the broken ends of the fibers are still sufficiently centric and at a distance that is opposite to the diameter of the optical Neglecting fiber is staying positioned to each other, where the breakage of the fiber is defined by a notch and tension or slight bend is made that the ends of the fibers axially guided so far apart that in the A cylindrical lens or a laser is inserted between the areas can then be the one required for the switching process Switching fiber is introduced into the resulting light cone in such a way that the outgoing fiber and the switch fiber in the switch distance to the incoming fiber, which must be so large that the light spot diameter is at least as large as the diameter  knife of the fibers must be so that the switching process through Rotation or displacement of the switching fiber in the axis line of the incoming fiber is accomplished. Through this procedure it is possible for the first time to use an optical Communication link without using T-splices switch.

An advantageous embodiment for carrying out the inventions The inventive method is that the device one splice to be used and one to be used as a tool using pivoting part. So there is a optimal use of the parts required for switching and Tools. That for splicing the new messaging stretch used splice part is also used as a tool used.

Another advantageous embodiment of the invention exists in that the splice along a V-groove and across in the middle has a rectangular groove. This embodiment of the front direction takes into account the tool function.

For ergonomic reasons, it is advantageous that the pivoted part the extended imaginary line of the V-groove for the outgoing fiber and that of the V-groove for switching fiber meet at the fulcrum.

An embodiment of the invention is based on the drawing and the description below. In the schematic Drawing shows:

Fig. 1 is a view of the position of the fiber ends during Umspleißen,

Fig. 2-6 the Umspleißvorgang and

Fig. 7 the Umspleiß basic part.

Fig. 1 shows the incoming fiber 11 at the distance of Umschaltent distance 33 from the outgoing fiber 12 and the Umschaltfaser 13th At this distance of the fibers from one another, the light spot diameter 34 of the resulting light cone 31 is at least as large as the diameter of the fibers used.

Figs. 2 to 6 show the Umspleißvorgang. The optical fiber 10 is broken by notching 40 during operation in such a way ( FIG. 2) that the broken ends of the fibers 11 , 12 still remain sufficiently centrally and positioned at a small distance from one another. The incoming and outgoing fibers 11 , 12 are moved apart axially. In the resulting intermediate area 32 , a cylindrical lens or a laser can be inserted. The switching fiber 13 is arranged next to the outgoing fiber 12 ( Fig. 3). The outgoing fiber 12 is retracted with the switching fiber 13 in the switching distance 33 from the incoming fiber 11 ( FIG. 4). The outgoing fiber 12 is rotated out of the axis line 30 of the resulting light cone 31 in the pivoting direction 58 in such a way that the switchover fiber 13 follows to the same extent until it is then also aligned with the incoming fiber 11 in the axis line 30 (FIGS . 4-6 ). Finally, the ends of the fibers 11 and 13 , which form the new optical communication link, are brought together axially. The sequence of mutually independent steps is interchangeable, such as creating the switching fiber 13 and axially moving apart the ends of the incoming and outgoing fiber 11 , 12 that are in operation.

Fig. 7 shows the changeover device 50. This consists of a splice part 51 and a pivotably mounted part 52 . The splice part 51 is provided lengthways with a V-groove 53 for the optical fiber 10 . Perpendicular to this there is a rectangular groove 54 for the introduction of a cylindrical lens or a laser. The part 52 which is pivotably mounted in the pivot point 58 in the pivot point 57 has a V-groove for the outgoing fiber 55 and one for the changeover fiber 56 .

Claims (4)

1. A method for the uninterrupted switching of an optical communication link in operation, characterized in that
that the optical fiber ( 10 ) is broken in operation in such a way
that the broken ends of the fibers ( 11 , 12 ) still remain sufficiently centric and at a distance from one another that can be neglected compared to the diameter of the optical fiber ( 10 ), the breakage of the fiber ( 10 ) being defined by a notch ( 40 ) and pull or slight bend is made
that the ends of the fibers ( 11 , 12 ) are axially guided so far apart that a cylindrical lens ( 20 ) or a laser can be introduced into the intermediate region ( 32 ), then the switching fiber ( 13 ) required for the switching process into the resulting light cone ( 31 ) is introduced in such a way
that the outgoing fiber ( 12 ) and the switching fiber ( 13 ) are in the switching distance ( 33 ) to the incoming fiber ( 11 ), which must be so large that the light spot diameter ( 34 ) is at least as large as the diameter of the fibers ( 10 or 13 ) must be so that the switching process is accomplished by rotating or shifting the switching fiber ( 13 ) in the axis line ( 30 ) of the incoming fiber ( 11 ). 2. Device for performing the method according to claim 1, characterized in that the device ( 50 ) consists of a splicing part to be used ( 51 ) and a pivotable part ( 52 ) to be used as a tool. 3. Apparatus according to claim 2, characterized in that the splice part ( 51 ) has a V-groove ( 53 ) and a rectangular groove ( 54 ) transversely to it in the central part. 4. Apparatus according to claim 2 or 3, characterized in that in the pivotally mounted part ( 52 ) the extended imaginary line of the V-groove for the outgoing fiber ( 55 ) and that of the V-groove for the switching fiber ( 56 ) at the pivot point ( 57 ) meet.