NO304810B1 - The conduits ÷ ring - Google Patents

Description

This invention generally relates to communication cable systems, more specifically a cable routing as stated in the introduction to the subsequent claim 1.

The continued dynamic growth in the communications industry has led to an ever-increasing need for additional and different types of communications cables. For example is the original installation of telephone cables in a certain area soon overloaded, as further cable installations must be able to satisfy the increasing communication requirements in this area. Furthermore, although the majority of today's telecommunications, video and data transmissions take place over twisted-pair telephone cables and coaxial cables, optical fiber cables are clearly becoming the transmission media of the future for the communications industry. Consequently, it is of crucial importance that existing installations of non-optical fiber cable assemblies include assemblies that not only provide for additional, future cable installations, but also for the ability to install optical fiber transmission cables in the future without the need for grounding and replacement of the original installations.

There are known systems which have sought to provide this extended cable option. For example US Patent No. 3,862,349 discloses an underground telephone cable assembly installation in which the telephone cable is arranged in a flexible outer casing having an outside diameter sufficiently larger than the telephone cable outer casing occupies to allow for the future placement of at least one additional cable, wherein a pulling wire is also laid next to the existing cable with a view to this future location. US patent no. 3 383 456 shows a flexible pipeline with the electrical conductors arranged in or near the pipeline wall, so that additional conductors can later be pulled through the pipeline if necessary without this having to be removed.

Although these known systems generally provide extended cable capability, they are not entirely satisfactory and they are burdened with a number of disadvantages. For example it can be mentioned that in addition to the fact that the existing cable or the existing conductors are located inside the pipeline and will thus come into conflict with the later placement of additional cables in the pipeline, as well as increasing the tensile strength for the future cable installation, the entire the construction and design of the known systems deficient in many material respects.

As further examples of prior art in the area, Norwegian generally available patent application no. 2745/70, Swedish patent no. 186,596 and Swedish explanatory document no. 435,004 should be mentioned, all of which show a cable route that is connected to a parallel running, possibly electrically conductive cable which is intended to act as a carrier cable for the cable routing and is therefore permanently connected to it throughout its length.

In addition to seeking to eliminate the above-mentioned disadvantages of the state of the art, the problem the present invention primarily aims to solve is to arrive at a construction that enables easy release of at least parts of the original cable from the cable routing . This is achieved according to the invention by equipping a cable routing of the type indicated at the outset, with the new and distinctive features indicated in the characterizing part of the subsequent claim 1, with advantageous embodiments as indicated in the other subsequent claims.

The invention thus involves a new and improved pipeline/communication cable unit which enables subsequent additions or upgrades to the existing cable installation with a minimum of installation costs and a minimum of inconvenience for the customer.

Special and further features of the invention, as well as further purposes and advantages thereof, will be easily understood by experts in the field from the following detailed description, in conjunction with the accompanying drawings. Figure 1 is a partial perspective view of a section of the combination of conduit and original communication cable in accordance with the present invention, which shows with dashed lines an optical fiber cable which will later be pulled through the conduit, Figure 2 is a cross section of the conduit and the original communication cable, which shows a method of attaching the original communication cable to the guide, Figure 3 is a cross-section of the guide and the original communication cable, which shows another method of attaching the original communication cable to the guide, Figure 4 is a cross-section of the guide and the original communication cable, showing a third method of attaching the original communication cable to the guide, Figure 5 is a schematic diagram of the guide and cable communication showing the ends of the cable detached or detached from the guide surface.

The drawings are not necessarily to scale, and certain parts may be exaggerated to emphasize certain details of the invention.

In the following description (and in the drawings) like parts are indicated with the same respective reference numbers.

Referring initially to figure 1, a cable guide 12 with an outer wall 14 and an inner wall 16 is shown here. The cable guide 12 is of the type conventionally known in the industry and is generally designed by extruding polymer material, such as a polyethylene or polyvinyl chloride, to form an elongated, flexible conduit to act as a protective underground sheath for a communications transmission cable. Such a guide is currently sold by Integral Corporation of Dallas, Texas, to which this invention is assigned, under the trademark

CABLECON.

In accordance with conventional solutions, the cable routing is buried in the ground, as the special transmission cable has normally either already been pre-introduced into the routing or introduced into the routing after the routing has been buried.

In accordance with the present invention, and again with reference to figure 1, the transmission cable 10 is attached to and parallel to the outer wall 14 of the guide 12. This unit is then installed underground, and the cable 10 forms the original communication link at the time of installation. The cable 10 will therefore be referred to in the following as the "original cable", and in today's applications it will normally be a cable of the pair-twisted or coaxial type. The guide 12, which is completely empty, acts as a path for the future insertion of a cable 20. The cable 20 will therefore be referred to in the following as the "later installed cable", and in this example it will be an optical fiber cable.

To facilitate the future installation of the later installed cable, a string or pulling element 18 (Figures 2 - 4) is also pre-installed in the guide 12, parallel to the length of the guide, for use in pulling the cable 20 through the empty guide. Moreover, it is desirable that the inner wall 16 of the guide is lubricated in advance or made of pre-lubricated material to facilitate this cable pulling through.

In accordance with a main feature of the present invention, the original cable 10 is releasably connected to the guide wall 14, so that the cable, if necessary, can be separated or detached from the guide 12 at its connecting end 10a, as shown in Figure 5. Consequently, three different methods or embodiments for making this dissolvable compound shown in figures 2, 3 and 4, respectively, and shall now be described.

The lead cable 10 shown in Figure 2 is releasably attached, and held in parallel near the guide 12 by means of a breakable polymer jacket 24 which is formed along the length of the cable guide assembly (as shown in Figure 1). This sheath, which preferably has a thickness of not less than 0.762 mm, can be co-extruded simultaneously with the extrusion of the guide 12, the original cable 10 being placed between the outer wall 14 and the sheath 24 during the co-extrusion process.

Alternatively, and with reference to figure 3, a breakable step 26 can be formed between and along the length of the cable 10 and the guide surface 14, the step 26 retaining the original cable 10 to the guide 12 until it is broken open to release the ends 10a from the outer wall of the guide .

In the embodiment shown in Figure 4, a pair of resilient gripping projections 28 with retaining fingers 28a can be formed in one piece and simultaneously with the extrusion of the guide 12, these extensions retaining the cable 10 parallel and close to the guide wall 14. In this example, the original cable 10 will be releasably connected to the guide after the extrusion process is completed.

The releasable connection of the original cable 10 to the guide 12 makes it possible to detach the cable, as shown in Figure 5, to change the direction of flow of the cable and the guide at the joint ends, e.g. In the example shown in Figures 1 - 3, the attachment will be carried out by selectively breaking up the cover 24 or the step 26; in the example shown in Figure 4, the cable 10 is selectively pulled free from the gripping unit 28's springy grip.

Although preferred embodiments of the present invention have been shown and described herein, further modifications and improvements may be made by those skilled in the art without departing from the spirit and scope of the invention, which shall be limited only by the accompanying claims.

Claims (6)

1. Cable conduit (12) with outer and inner walls (14, 16), adapted to receive a length of a later installed cable (20) to be pulled through the conduit, comprising an original cable (10) extending parallel and being connected to the outer wall of the guide (12), characterized by fasteners (24, 26, 28) which detachably connect the original cable (10) to the outer wall (14) of the cable guide (12). 2. Cable routing according to claim 1, characterized in that the fastening means are a breakable sheath (24). 3. Cable routing according to claim 2, characterized in that the breakable sheath (24) comprises a polymer with a thickness of no more than approx. 0.762 mm. 4. Cable routing according to one of the preceding claims, characterized in that the cable routing (12) and the jacket (24) are both made of a polymer and that the cable routing and the jacket are co-extruded at the same time as the original cable (20) was placed between the outer wall (14) and the jacket (24) during the coextrusion process. 5. Cable routing according to claim 1, characterized in that the fastening means are a breakable step (26). 6. Cable routing according to claim 1, characterized in that the fastening means is a gripping unit (28) consisting of springy protrusions (28a).