DE3428562A1 - Splicing carrier for optical fibre cables - Google Patents

Abstract

The splicing carrier (ST1) has devices for accommodating the optical fibre splices and devices for fixing excess lengths of at least one optical fibre conductor. Conductor entry fittings for the incoming (LW11) and the outgoing (LW12) optical fibre conductors are provided, the splicing carrier (ST1) being arranged such that it can be swivelled out. The splicing carrier (ST1) is constructed to be axially rotatable relative to the conductor entry fittings (AE), so that no torsion is produced upon swivelling out. <IMAGE>

Description

SDleiX carrier for light waveguide cables

The invention relates to a splice carrier for optical fiber cables, at least one of which is inserted into a socket or the like,. whereby the splice carrier Devices for receiving the fiber optic splices and devices to fix excess length at least one fiber optic wire contains and wire lead-ins are provided for the incoming and outgoing optical fiber cores, / wherein the splice carrier is arranged such that it can be swiveled out.

A splice carrier of this type is shown in FIG. 1 of DE-OS 31 33 586 known. When pulling out the splice support transversely to the longitudinal axis of the sleeve is included this arrangement of the splice carrier with its entry point for the associated Optical fiber cores in such a way that the core entry point is on that of the sleeve housing facing away from the splice carrier. This has the consequence that the splice carrier in the assembled state inwards, that is to say extends towards the sleeve. This stands with a given length of the fiber optic cores only a smaller space available as if the arrangement were reversed, that is, the vein entry point would lie on the side of the pulled out splice carrier facing the sleeve. If the splice carrier is in this cheaper because greater or better accessibility The resulting position would have to be twisted in the optical waveguide cores and there is also the possibility that the splice carrier is no longer of would be accessible from the right side.

The present invention is based on the object of one possibility to create how the splice support is pivoted out of the cable sleeve can without undesired mechanical stress (torsion) on the optical fiber cores entry. According to the invention, which relates to a splice carrier of the aforementioned Art relates, this object is achieved in that the splice carrier is relative to the wire entries is designed to be axially rotatable.

As a result of the rotatable design of the wire entries can Guide the individual splice carriers out of the cable sleeve into the splice position, whereby the rotary movements do not lead to any torsion of the optical waveguide cores, because a movement compensation can be carried out in the area of the insertion point.

Further developments of the invention are given in the subclaims.

The invention and its developments are explained below with reference to Drawings explained in more detail. It shows: Fig. 1 a section transverse to the longitudinal axis of a socket housing, FIG. 2 shows a section parallel to the longitudinal axis of the socket housing, 3 shows the view according to FIG. 2 rotated by 900, FIG. 4 shows details of the pivoting out the rotatably arranged splice carrier according to the invention, FIG. 5 in plan view the formation of a wire entry designed according to the invention, Fig. 6 shows a side view of the wire insertion according to FIG. 5 and FIG. 7 shows a longitudinal section Sleeve used in the area of the wire entry.

In Figure 1, a cylindrical sleeve housing MG is provided in which Inside a stack of splice carriers ST2 to STn is arranged. Any of these splice carriers consists for example of a metallic housing, preferably of a base plate and a cover, as well as splice connectors arranged inside. Like the side view According to Figure 2 shows, the various splice supports STS to STn are between two Mounting rails MS1 and MS2 arranged, with a retaining bolt HB, which all Splice carrier STI to STn penetrates, serves to secure the position. The socket housing MG has sealing bodies DK1 and DK2 at both of its ends, via which corresponding Optical fiber cables KA1 and KA2 introduced into the interior of the sleeve housing MG are. Inside the sleeve housing MG, the fiber optic cables KAI and KA2 intercepted by cable clamps and connected to each other with tensile strength, including the Cable clamps corresponding holders HK1 and HK2 are provided, which extend to the mounting rail MS2 reach, and be attached to this.

The following description is intended to simplify the representation assumed that only a single optical fiber is spliced in each splice carrier shall be.

In reality, there are usually several optical fibers in a splice carrier connected with each other. A fiber optic wire leads from the cables KAI and KA2 to the appropriate splice carrier. As can be seen above all from the representation Figure 1 and Figure 3 is a fiber optic cable from the cable tA2 (the is shown coming from the right) to the left Entrance of the top Splice carrier ST1 out and labeled LKW11. Accordingly, that of LtK12 fiber optic wire coming from the KAI cable to the left right input of the splice carrier ST1 out.

While in Figures 1 to 3 the fully spliced cable sleeve is shown Figure 4 shows details of the sequence of splicing and repair operations. It is assumed that the top splice carrier, namely ST1, has been removed from the package and is to be brought into a position in which a splicing process for the operator can be carried out in a particularly simple manner. This presupposes that the Splice carrier ST1 laterally as far as possible from the stack of other splice carriers can be removed to facilitate accessibility and, on the other hand, that the splice support ST1 is in a position in which the splice point on the right side and the fiber optic cables LKW11 and LW12 as tension-free as possible, that means above all to be torsion-free. From Figure 4 it can be seen that each according to the length of the fiber optic cables Lkw71 and LW12 (which are otherwise due to the small available space inside the socket housing is not arbitrary can be chosen large) the splice carrier ST1 on a wire length through this Moved specified circular path (indicated by dashed lines and denoted by K3). As As can be seen from FIG. 4, it changes when the splice support is pivoted out STI the angle X, which the fiber optic wires LWII and LW72 with the associated Including splice carrier ST1. In the present example, two intermediate positions are shown in dashed lines shown for the splice carrier ST7, their associated angles labeled CX1 and CC2 are. In the end position, the angle ob 3 shows a compared to the starting position Angular change of the order of 1800. If the entry point means one fixed wire harnessing works, then the splice support ST1 is swiveled out from the stack to the assembly position on the SG splicer practically only under one Correspondingly strong torsion of the LW11 and LW12 fiber optic cables is possible.

In Figures 5 to 7 details of a wire insertion are shown, in which a relative movement between the splice carrier ST1 (only partially drawn here) and the j respective fiber optic cable (referred to here as LW11) is possible. For this purpose, in the area of the wire entry point AE via the fiber optic wire Lkw71 pushed a sleeve LH, which has an axial opening OF, the diameter of which is chosen to be only slightly larger than the outer diameter of the optical waveguide core LW11.

It is useful if the sleeve LH is fixed (e.g. by gluing) is held on the outer shell of the optical fiber LW11 because then the relative movement takes place between the splice carrier ST1 and the sleeve LH.

The sleeve LH can also act as a kink protection with take over, which is appropriate in the area of the interception of the fiber optic core is provided. Otherwise it would have to have its own via the LW11 fiber optic cable Sheath can be pushed, which could be used as a kink protection.

In the present example, the sleeve LH also has a protruding one Nose IN, which is dimensioned so that it is just axially offset between two flaps LA7 and LA2 arranged against one another on the splice carrier STI fit. These tabs LA7 and LA2 become after inserting the fiber optic cable LW11 together with the sheathing EH closed. For example, they can consist of flexible metallic flaps, However, care must be taken that the sleeve LH and thus the fiber optic cable LW11 are still rotatably held in the lugs LA1 and LA2. This is the swivel movement Generation according to Figure 4 can be carried out without the LW11 and LW12 fiber optic cables twist during the assembly process comes.

The LW11 fiber optic cable is expediently designed as a hollow core, as the side view of Figure 6 shows, where in an outer shell LWH11 a single Optical fiber LWF11 is arranged. Under loose tubes are in this context also to understand those filled veins in which the actual optical waveguide fiber LW11 still has a certain mobility due to a very soft or flowable filling having.

Instead of the one shown in FIG. 7 for securing the axial position of the optical waveguide core LW11 provided lugs on the sleeve LH can of course also be groove-shaped Depressions can be provided on the outer edge of the sleeve LH.

It is also possible to apply both tabs and grooves at the same time. It can be useful especially with somewhat thicker LW11 fiber optic cables be without working without a sleeve according to Figures 5 to 5. In this case becomes the outer protective sheath of the LW11 fiber optic cable, for example the Sheath LWHlI according to Figure 6 held directly rotatable.

This can be done, for example, through a tab in which the fiber optic cable LW11 still has a certain amount of play and therefore accordingly when pivoting out Figure 4 can rotate freely and is not twisted. Another possibility the rotatable holder in the area of the entry point AE for the fiber optic cable Lkw11 consists in that clip-like brackets are provided on the splice support ST1 into which the optical fiber core is pressed via an entry slot can be, the clear width of this arrangement is selected to be greater than that outer diameter the fiber optic wire, so that again a rotatable bracket is created.

As can be seen from Figure 4, the arrangement of the splice supports becomes ST1 inside the sleeve housing and the arrangement of the entry points for the Optical fiber cores taken so that the splice carrier in the swiveled-out state STl the associated wire entry point AE rests on a side facing the sleeve. This ensures the maximum possible distance between the splice carrier and the stack or the sleeve reached, and a particularly easy work for the operator allows 7 Figures 11 claims - blank page -

Claims (10)

Claims 1. Splice carrier (e.g. ST7) for fiber optic cables (EA1, Kr2), of which at least one in a socket (MG) or the like. is used, wherein the splice carrier (ST1) has devices for receiving the optical waveguide splices and devices for fixing excess lengths of at least one optical waveguide core contains and wire entries for the incoming (LW11) and the and de fiber optic wire LW12) are provided, / with the splice support (ST1) being arranged so that it can be swiveled out, characterized in that the splice carrier (ST1) is relative to the lead inlets (AE) is designed to be axially rotatable. 2. Splice carrier 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 a sleeve (ui) is provided in the area of the wire entry (AE) and that the sleeve (LM) opposite the optical waveguide core and / or opposite the Splice carrier is rotatably mounted. 3. Splice carrier according to claim 2, d a d u r c h g e k e n n z e i c h n e t that the fiber optic cable (LW11) is fixed, in particular by an adhesive connection, is held in the sleeve (LH) and that the sleeve (LH) is rotatable on the splice carrier (ST1) is stored. 4. splice carrier according to claim 2 or 3, d a d u r c h g e k e n n shows that the sleeve (LH) has at least one protruding nose (LHN) on the outside and / or has at least one recess with which they ebb against axial displacement is held securely on the splice carrier (ST1). 5. Spleißträ.ger according to claim 4, d a d u r c h g e k e n n z e i c h n e t that the holder of the sleeve (LH) is secured by at least one tab (LA1, LA2) has been made. 6. Splice carrier according to claim 1, d a d u r c h g e k e n n z e i c This means that the fiber optic cable (LW11) can be rotated directly on the splice carrier (ST1) is held. 7. Splice carrier according to claim 6, d a d u r c h g e k e n n z e i c n e t that the fiber optic cable (LW11) is loosely attached to the splice carrier by means of tabs (ST1) is held. 8. splice carrier according to claim 6, d a d u r c h g e k e n n z e i c n e t that the fiber optic cable (LW11) latches but loosely in a snap clamp is held. 9. Splice carrier according to one of the preceding claims, d a d u r c h e k e k e n n n n e i c h n e t that there is a kink protection in the area of the wire entry (AE) is arranged on the fiber optic cable (LW11). 10. Splice carrier according to one of the preceding claims, d a d u r c h g e k e n n n z e i c h n e t that the assignment of the wire entry (AE) to the splice carrier (ST1) is made in such a way that in the swiveled-out state the wire is inserted (AE) lies on the mu ite. left Splice carrier according to one of the preceding claims, d a d u R e k e k e n n n e i n e t that as a fiber optic cable (LW11) a loose tube is used.