DE3839109A1 - Optical cable having a plurality of chamber elements (slotted core elements) - Google Patents

Abstract

The side walls of neighbouring chamber elements abut against each other only in the interior region (e.g. at CR11, CR21). In the outer region (e.g. at CB11, CB21) the chamber walls separate from each other and in each case form an additional chamber (AC1-AC5). <IMAGE>

Description

The invention relates to an optical cable with several rings arranged in a shape, with their side walls abutting Chamber elements for the reception of optical fibers.

An optical cable of this type is from DE-OS 30 00 674 known, the individual chamber elements in cross section Have the shape of a ring section, so that the side walls run continuously only in the radial direction. This has to Consequence that the cross section of the entire cable core is complete is filled with such chamber elements and gaps are not can arise.

In some cases it is useful to sit next to the chambers of the chamber elements even additional chambers available len, be it to accommodate additional optical fibers and / or to provide tensile elements or one or more Provide channels for gas pressure monitoring of a cable len.

The present invention is based on the object To point out the way in which the creation of this additional came is made possible in a simple manner. According to the invention is this with an optical cable of the type mentioned achieved in that the side walls of adjacent Kammerele elements only meet in the interior and that in the exterior rich the chamber walls move away from each other and each form an additional chamber.

Since the side walls of adjacent chamber elements only in Touch inside while they are outside Removing others is created in the exterior without additional effort pass another chamber between two neighboring ones Chamber elements. The strength and rigidity of from the  Cable elements composed of cable elements is through this Measures are not affected and it is even in some ways Circumference, since only partial contact surfaces between the chambers elements, a simplified bundling of the Kammerele ment possible. Each of these chamber elements is practical a tube open to the outside (slotted), which in the extru sionsverfahren can be produced. After loading with the optical fibers or optical fiber bundles or Fiber optic ribbon cables become these chamber elements summarized in a forest, for example on one central tensile core roped. The individual Kammerele elements practically offer the advantageous properties a hollow core construction with the possibility of adjustment a disposable excess fiber length, the easier division and branching by removing individual chamber elements from the association of the cable core and the simplified possibility speed of the removal of optical fibers or optical fibers bundle from the individual chambers without the need for Severing the shell.

Further developments of the invention are in the dependent claims again given.

The invention and its developments are as follows explained in more detail with reference to drawings. It shows

Fig. 1 in greatly enlarged cross section of a constructed according to the invention, optical cable,

Fig. 2 in cross section a chamber member with a sealed by a film chamber opening,

Fig. 3 is a chamber element in cross-section with a closed by tabs chamber opening,

Fig. 4 is a chamber element in cross section with introduced filling mass, and

Fig. 5 shows a chamber element in cross section with an all around on brought wrapping.

The optical cable OC of FIG. 1 has an outer jacket MA on which a separation layer z. B. in the form of a hot melt adhesive covering SK follows. The actual cable core in the present example consists of five chamber elements CA 1 to CA 5 , which are arranged symmetrically around a tensile core element TE (e.g. a steel cable or an aramid cable). Each of the chamber elements CA 1 to CA 5 has an opening (recess) ON 1 to ON 5 , which is of rectangular design here, which is arranged essentially radially and is initially open to the outside in order to offer the possibility that (here not insert) optical fibers. The side walls of the individual chamber elements CA 1 to CA 5 are designed in their outer shape so that only the inner Teilbe rich result in an approximately radial course. These partial areas are designated CR 11 and CR 12 in the chamber element CA 1 and CR 21 and CR 22 in the chamber element CA 2 . If the individual chamber elements are brought together, e.g. B. by roping on the tensile core element TE , then the individual chamber elements CA 1 to CA 5 meet only in partial areas, inside, against each other, namely where the walls run in the radial direction. For example, if the chamber element CA 1 is guided so far inwards that it rests on the tensile element TE , there will be contact between its inner wall part CR 11 and the inner wall part CR 21 of the neighboring chamber element CA 2 . In the interior, which is marked by the contact of the adjacent chamber elements CA 1 to Ca 5 , the usual structure thus results from individual adjoining chamber elements. In contrast, the course of the chamber wall in the outer region is no longer radial, but instead is kinked. These outside areas are referred to in the chamber CA CB 1 and CB 11 12, wherein said chamber member 2 CA with CB and CB 21 22nd This creates gusset-shaped (approximately V-shaped cross-section) additional chambers between the individual chamber elements CA 1 to CA 5 , which are designated AC 1 to AC 5 . In these additional chambers AC 1 to AC 5 , additional elements can be accommodated, such as. B. indicated in the chamber AC 4 , where an additional optical fiber LW 4 was inserted. Instead of or in addition to such an optical waveguide or in a mixed form around the cable core can also tensile elements such. B. in the form of steel wires or aramid yarns are introduced into the additional chambers. It is also possible to use one or more of these chambers or all of the chambers for the longitudinal conduction of pressurized gas, which is particularly important in the case of pressurized gas chamber cables. In all cases, practically no additional effort is required to create the additional chambers AC 1 to AC 5 , and the strength of the construction of the cable core is not impaired by the shape of the chamber elements CA 1 to CA 5 according to the invention.

The cross-sectional shape of the chamber openings ON 1 to ON 5 can be adapted to the corresponding circumstances. For example, an approximately rectangular cross-sectional shape is preferable for the insertion of ribbon-shaped optical waveguides. In contrast, a round cross-section for the openings ON 1 to ON 5 may be more expedient when inserting individual optical fibers or optical fiber bundles. From the design of the chamber elements according to the invention, acute-angle gussets in the outer region are avoided in any case, as are otherwise inevitable with completely dig sector-shaped chamber elements. The like acute-angled, outwardly widening Kammeröff openings can hardly be used in their outer areas anyway, because the acute-angled partial areas do not provide enough space to accommodate the optical fibers there in a sufficiently flexible and flexible manner.

In FIG. 2 it is shown how the opening is sealed on the outside of a ONA Kammerele mantes CAA by a sheet FO. After inserting the ribbon-shaped optical waveguide bundle LWB into the opening ONA , the film FO is brought up in a suitable manner, in particular glued on. When using a film coated with hot melt adhesive, it only needs to be pressed onto the upper edge of the chamber element CAA with a heated wheel.

In the embodiment according to FIG. 3, the chamber opening ONB of the chamber element CAB is closed by two flexible noses NA 1 and NA 2 which are molded on during extrusion of the chamber element CAB . For inserting the ribbon-shaped optical waveguide LWB , the tabs NA 1 and NA 2 are pressed apart, thereby creating enough space to insert the ribbon LWB . After their introduction, the nose-shaped projections NA 1 and NA 2 snap back into their original position and secure the optical fibers LWB against falling out.

In Fig. 4 a filling must FM from a still sufficiently soft filling material (z. B. thixotropic Mas sen with oil addition) is provided in the chamber element CAC to secure the ribbon-shaped optical waveguide LWB .

In the embodiment according to FIG. 5, a winding BW is applied around the chamber element CAD and thereby the opening OND of the chamber element CAD is closed to the outside. The BW winding can consist of a film-like ribbon made of plastic material.

In all embodiments, as shown in Fig. 2 with 5 , each of the chamber elements CAA to CAD is practically equipped with the properties of a hollow vein, ie these elements can be individually manufactured, filled, drummed up and kept ready and only need for final manufacture of the chamber cable can be brought together to form the overall arrangement shown in FIG. 1.

Claims (12)

1. Optical cable with a plurality of annularly arranged, with their side walls abutting chamber elements (CA 1 - CA 5 ) for receiving optical fibers, characterized in that the side walls of adjacent chamber elements only in the interior area (z. B. CR 11 , CR 21 ) abut and that in the outer area (e.g. with CB 11 , CB 21 ) the chamber walls move away from each other and each form an additional chamber (AC 1 - AC 5 ). 2. Optical cable according to claim 1, characterized in that the side walls in the inner region (z. B. CR 11 , CR 21 ) extend in the radial direction. 3. Optical cable according to one of the preceding claims, characterized in that at least one of the additional chambers (AC 1 - AC 5 ) light waveguide (z. B. LW 4 ) and / or tensile elements. 4. Optical cable according to one of claims 1-3, characterized in that at least one of the additional chambers (AC 1 - AC 5 ) serves as a compressed gas duct. 5. Optical cable according to one of the preceding claims, characterized in that the additional chambers (AC 1 - AC 5 ) have an approximately V-shaped cross section. 6. Optical cable according to one of the preceding claims, characterized in that the chamber elements (CA 1 - CA 5 ) approximately rectangular openings (ON 1 - ON 5 ) for receiving the optical fibers. 7. Optical cable according to one of the preceding claims, characterized in that the inner ends of the chamber elements (CA 1 - CA 5 ) rest on a tensile element (TE) . 8. Optical cable according to one of the preceding claims, characterized, that the openings of the chamber elements are closed to the outside are. 9. Optical cable according to one of the preceding claims, characterized in that the openings (ONA) of the chamber elements (CAA) with a film (FO) are closed ( Fig. 2). 10. Optical cable according to claim 8, characterized in that the openings (ONB) of the chamber elements (CAB) by means of nose-like projections (NA 1 , NA 2 ) are at least partially closed ( Fig. 3). 11. Optical cable according to claim 8, characterized in that the openings (ONC) of the chamber elements (CAC) are closed by means of a soft filling compound (FM) ( Fig. 4). 12. Optical cable according to claim 8, characterized in that the openings (OND) of the chamber elements (CAD) are closed by means of an all-round winding (BW) ( Fig. 5).