DE3006131A1 - Splicing coupling for light wave conductors - has inner core for winding on spare cable and clamping connectors - Google Patents

Abstract

The splicing coupling (1) has a cylindrical core (2) inside it, which is supported horizontally by spacer bars (3,4), keeping the core (2) in the centre of the coupling (1). Around this central core (2) the individual light conductor bundles (5,6) of the two joined cables (7,8) are wound, the length of these bundles (5,6) depending on the amount required to be left for stock. The left hand bundle of conductors (5) are wound around the core (2) anticlockwise and the right hand bundle (6) clockwise, until they meet at a central position where their connection takes place (9). These connections - either by plug connectors, welding or adhesive - are held by a suitable clamping arrangement parallel with and around the circumference of the core (2). The dia. of the core (2) is chosen so that it is never less than the min. bending radius of the light conductors. The coupling allows a large number of light conductors to be connected and housed with suitable spare lengths, in a small space.

Description

Splice closure with a receiving device

for stock lengths of fiber optic cables The invention relates to a receiving device arranged in a splice sleeve for optical fiber cables for the storage lengths and connection points of the spliced fiber optic cables two cables.

Optical fibers are generally made by gluing, welding, Terminals or connected to one another by means of plugs.

Usually the connection points of the optical waveguides are used housed in connection or splice sleeves, with the sleeves additionally Record stock lengths of fiber optic cables. The stock lengths allow the Optical fiber ends to be connected to one another, e.g. - to an outside of the sleeve Bring the splicer in place.

To accommodate the connection points and storage lengths of the optical waveguides up to now, for example, supply spools have been used. Such a supply reel is off DE-OS 27 35 106 known. The storage lengths of the individual light waveguide placed in loops, which are held in stands arranged one above the other. Such Log length fixtures take up a lot of space, especially when To accommodate stock lengths of cables with a lot of optical fibers in it are.

The invention is therefore based on the object of a very space-saving Holding device for the supply lines and connection points of a large number of fiber optic cables.

The object is achieved according to the invention in that the receiving device consists of a mandrel, that around the mandrel the optical waveguide bundle belonging to each cable is helically wound, the optical fiber bundle of the first Cable from one end of the mandrel to the center of the mandrel and the fiber optic bundle of the second cable in the opposite direction of winding to this from the opposite end of the mandrel is wound from the center of the mandrel, and that the connection points of the individual optical waveguides are supported on a belt line in the center of the mandrel.

Appropriate embodiments of the receiving device according to the invention can be found in the subclaims.

Based on the embodiments shown in the drawing now the invention is explained in more detail. They show: FIG. 1 the wound on a mandrel Optical fiber bundle within a splice closure, Figure 2 and 3 holders for the connection points of the optical waveguides, figure Lt one with a protective cover surrounded mandrel and Figure 5 and 6 mandrels, provided with guides for the windings the fiber optic bundle.

Figure 1 shows a splice closure 1 in which a cylindrical mandrel 2 is fastened in a horizontal position on webs 3 and 4. Around the mandrel 2 they are ever after the desired storage length exposed fiber optic bundles 5 and 6 of two Cable 7 and 8 wound helically. And that is the fiber optic bundle 5 from the left end of the mandrel to the center of the mandrel to the left and the fiber optic bundle 6 from the right end of the mandrel also wound to the right towards the center of the mandrel.

The connection points 9 between the optical fibers of the one Cable and those of the other cable, be it plugs or by welding or Glued splices> are in the center of the mandrel on a belt line held. Most of the connection points 9 can be accommodated on the mandrel, if they are arranged parallel to the mandrel axis, as in the present exemplary embodiment are.

Characterized in that the two fiber optic bundles with mutually opposite Winding sense are wrapped around the mandrel, a simultaneous orderly assembly and unwinding of both fiber optic bundles from the center of the mandrel is possible. Of the The mandrel diameter is chosen so that the smallest permissible bending radius of the optical waveguide is not fallen below. It depends on the length and the diameter of the mandrel how large an optical waveguide supply can be accommodated on this. E.g. a mandrel with a diameter of approx. 50 mm with three turns each the two fiber optic bundles take up a storage length of about 500 mm, Two embodiments for the attachment of the connection points 9 a.iaen die Figures 2 and 3.

rn Figure 2 did a section from the middle of the mandrel. 2 shown, on the several connection points 9 by means of a leaf spring-like retaining bracket 10 are clamped.

On the mandrel cutout shown in Figure 3 is a ring gear 11 inserted, in the gaps 12, the connection points 9 with a slight press fit are depressed. The hatches 12 can also be designed so that not only one, but several connection points can be clamped in each gap.

With regard to the mechanical sensitivity of the fiber optics accordingly soft materials, such as thermoplastic or rubber-like, can be used for the mandrel be used. When using hard materials, e.g. metal, ensure that there are no burrs to pay attention to all edges. As a protective cover for the one wrapped with the fiber optic cables Thorn, paper, plastic or metal foils can be used. A special protection a flexible foam or Filzmattc 13, which, as Figure 4 shows, around the mandrel via the optical waveguide and their connection points are placed and held together with one adhesive strip 1.

The mandrel 2 shown in Figure 5 contains grooves 15 for receiving the Fiber optic bundle. The grooves through the mandrel helically and end in the middle of the mandrel, where the connection points are to be arranged. You relieve the orderly winding and unwinding of the fiber optic bundles with, above all, one large number (# 10) fiber optic cables. Depending on the location of the connection points on the Dorn, some fiber optics are tight and some handlebars are wound. The grooves are in the LflSe * * r more spacious training, even the loosely wound fiber optic cables to record. A forfeiture of the optical waveguide can be so avoided will. However, it can also be achieved by removing the optical waveguides for different lengths of time ensure that all optical fibers are wound tightly.

Similar to through the grooves, is a helical path for the fiber optic bundles also by running parallel to each other on the mandrel Web 16 can be implemented (see FIG. 5).

The mandrel ends can still be sheathed with fastening devices for the Cable ends are provided so that they are secured against tensile stress.

Claims (9)

Claims 1. In a splice closure for fiber optic cables arranged receiving device for the supply lengths and connection points of the spliced fiber optic cable of two cables, characterized in that that the receiving device consists of a mandrel (2) that around the mandrel that to each Cable / 7,8) belonging fiber optic bundles (5, 6) wound in a helical shape is, wherein the optical fiber bundle (5) of the first cable (7) from a mandrel end out to the center of the mandrel and the fiber optic bundle (6) of the second cable (8) in opposite direction of winding from the opposite end of the mandrel to the center of the mandrel is wound, and that the connection points (9) of the individual optical waveguides are supported on a belt line in the center of the mandrel. 2. Recording device according to claim 1, characterized in that the mandrel (2) consists of a thermoplastic or rubber-like material. 3. Recording device according to claim 1, characterized in that the connection points (9) of the optical waveguides are arranged parallel to the mandrel axis are. Recording device according to claim 1 or 3, characterized in that that the connection points (9) of the optical waveguide with a leaf spring-like Retaining bracket (10) are clamped on the mandrel (2). 5. Recording device according to claim 1 or 3, characterized in that that the connection points (9) of the optical waveguide in the gaps (12) on one the mandrel (2) inserted ring gear (11) are clamped. 6. Recording device according to claim 1, characterized in that In the mandrel (2) helical grooves (15) are embedded for guiding each of the mandrel end fiber optic bundles (5, 6) wound helically towards the center of the mandrel. 7. Recording device according to claim 1, characterized in that on the mandrel (2) spiral webs (16) are attached, between which the fiber optic bundles (5, 6) are each guided helically from the end of the mandrel to the center of the mandrel. 8. Recording device according to claim 1, characterized in that the mandrel (2) wound with the fiber optic bundles (5, 6) with a protective covering (13) is provided. 9. Recording device according to claim 8, characterized in that the protective cover (13) for the mandrel (2) made of paper, a plastic or metal foil or consists of a foam or felt mat.