CZ20003657A3 - Thermoplastic tube for cable lines - Google Patents

Abstract

Cable routing tube (1) made of thermoplastic, for storing communication cables (2), in particular cables of glass fibers is provided with a conduit (3) cables (2) of circular cross-section. The inner wall of the channel (3) is provided with sliding ribs (4) having a longitudinal axis channel (3) alternating directions when creating inflection points (5). Spacing between cable contact area (2) on sliding ribs (4) are selected in the area of inflection sites (5) to be communicative the cable (2) with its smallest diameter abuts in the area inflection points (5) on at least two sliding ribs (4).

Description

Technical field

BACKGROUND OF THE INVENTION The invention relates to a cable guide tube made of thermoplastic material for receiving communication cables, in particular glass fiber cables, with a cable guide channel of circular cross-section and an inner channel wall with sliding ribs which have alternating directions in the longitudinal axis inflexion points. The term alternating directions means that the course of the sliding ribs, considered in projection into the longitudinal axis of the cable guide channel, varies, for example, from left to right, once from right to left. In this case, the arrangement of the sliding ribs can be designed such that the sliding ribs also have different pitches in different sections in the direction of the longitudinal axis of the channel. The sliding ribs may be helical or helical or serpentine and are parallel to each other.

BACKGROUND OF THE INVENTION

Cable routing tubes of this embodiment are known in which sliding ribs running in alternating direction serve to prevent communication cables or cable harnesses to be inserted or retracted into the cable routing tube from being subject to disturbing torsional forces. The forces due to the friction effect of the communication cable on the sliding ribs no longer cause the cables to twist and are sometimes absent at all. The sliding ribs can form sliding areas with their helical guided sections which have the opposite sense of winding. However, the sliding ribs may also be serpentine and generally have a triangular or arcuate cross section (see DE 40 16 726).

Communication cables which have already been retracted, inserted or blown into such a cable guide tube generally overlap with the plurality of sliding ribs over their entire length because the sliding ribs are arranged serpentine or helical with the opposite sense of winding. However, the inflection regions formed by the inflection points of the sliding ribs can be problematic, since it is not excluded that the communication cables, by their relatively small diameter in these inflection regions, fit into the groove between two adjacent sliding ribs. As a result, the insertion or retraction or blowing-in of the respective communication cable is considerably more difficult due to the higher frictional forces and the reduced sliding effect. This also applies if, in the case of a cable guide tube already fitted with a communication cable, the communication cable must later be inserted, retracted or blown, a certain distance away. Similar problems may arise for communication cables with larger diameters. This essentially depends on the design and arrangement of the sliding ribs, in particular their spacing. This is where the solution according to the invention starts.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a cable guide tube of the above-described embodiment, which guarantees that the communication cable to be inserted, retracted or inflated will still abut the sliding ribs in the region of the inflexion points of the sliding ribs. of the communication cable or when it is inserted again, it will be substantially reduced, irrespective of the diameter of the communication cable.

SUMMARY OF THE INVENTION

A cable guide tube, made of thermoplastic material, for receiving communication cables, in particular glass fiber cables, with a cable guide channel of circular cross-section and an inner wall of the channel with sliding ribs having a longitudinal «φ φ ··« · The axis of the channel alternating directions to form inflection points, according to the invention, which is based on the fact that the spacing between the cable contact points on the sliding ribs is selected in the area of the inflection points so that the communication cable the smallest diameter abuts at least two sliding ribs in the region of the inflection points.

In the context of the invention, the abutment points of the cable also include abutment lines or surfaces.

These measures according to the invention have the effect that even the smallest diameter of the communication cable fits into the groove between two adjacent sliding ribs in the region of the inflection points and, consequently, in the sliding areas where the direction of change in the sliding areas is prevented. the cables can rest on the sliding ribs. As a result, a considerable reduction of the frictional forces is maintained during insertion or retraction of the respective communication cable as well as at a later insertion or retraction of the cable which has already been laid into the cable guide tube. The fault-free sliding effect is maintained even for small and small diameter communication cables. Cable twisting is completely avoided.

Other preferred embodiments of the invention will be set forth below. According to an advantageous embodiment of the invention, the sliding ribs have different heights and spacings from each other at the cable contact points to accommodate different cable diameters, and that the spacing between the cable contact points in the region of the inflection points is selected such that in the region of the inflection points on at least two sliding ribs. According to this embodiment of the invention, it is thus ensured that, in particular, communication cables with larger diameters than communication cables with the smallest diameter abut in the region of the inflection points of the sliding ribs. in the worst case, also only on two sliding ribs, as a result of which they cannot fit into the groove between the sliding ribs even if the sliding ribs have greater spacing and height. As a result, even with communication cables with larger and different diameters, it is still guaranteed that the frictional resistance acting on such communication cable when it is inserted into the cable guide tube or later retracted remains in the inflection points and consequently in the inflection points. inflexion areas, greatly reduced.

If the cable guide tube is a pipe with sliding ribs extending in the longitudinal direction of the pipe and parallel to each other so that they are sliding ribs without changing direction, according to a further preferred embodiment of the invention the sliding ribs have different heights and spacings between The cable contact points on the sliding ribs are also different, and the spacing between the cable contact points on the sliding ribs is selected such that the communication cables, depending on their respective diameter, bear against the sliding ribs intended for the respective cable diameter. Consequently, even within this embodiment of the invention, the communication cables have their own sliding ribs depending on their diameters. This does not exclude situations in which the communication cables of different diameters can also touch the same sliding ribs when there is only a slight or relatively small difference in cable diameters.

Sliding ribs with higher heights preferably also have a larger width in the region of their base, so that the result is the possibility of creating sliding ribs of different width and height.

According to yet another advantageous embodiment, the sliding ribs of different heights, with different widths in the region of their base and with different spacings between the cable contact points form a cable cross section between the cable contact points, which is distributed symmetrically over the entire inner circumference of the channel The cable guide tube does not need to be straightened before inserting or retracting the cable guide, since the cable guide channel as defined above is available at any position of the cable guide. As a result, according to the invention, a system with a plurality of ribs is also available on the inner circumference of the cable guide channel even for inflection areas, i.e. for transition regions with a change in the direction of the sliding ribs winding.

BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a portion of a cable guide tube according to the present invention; FIG. 2 is a vertical cross-sectional view of the cable guide tube of FIG. Fig. 3 shows the sliding rib arrangement on the deployed cable guide tube of Fig. 2, Fig. 4 a cross section of the cable guide tube of Fig. 3 in the area between the inflection points of the serpentine sliding ribs; 3 in the region of the inflection points, namely with the contact points of the cable in the worst case at the smallest cable diameter, FIG. 6 of the embodiment according to FIG. 5 with a larger cable diameter; and FIG. 8 of the embodiment of FIG. 7 with an even larger cable diameter.

DETAILED DESCRIPTION OF THE INVENTION 9 9 9 9 9 9 99 9999

The figures show a cable guide tube 1, made of thermoplastic material, intended to accommodate a communication cable 2, in particular a glass fiber cable or a light guide. This cable guide tube 1 comprises a cable guide channel 3 with a circular cross-section, the inner wall of which has sliding ribs 4 running parallel to one another and having, in relation to the longitudinal axis L of the channel 3 and in the longitudinal axis L of the channel 3 points 5. The inflection points 5 of the sliding ribs 4 form inflection regions 6 between the sliding ribs 4. According to the illustrated embodiment, the sliding ribs 4 run serpentine in the direction of the longitudinal axis L of the channel 3. and have a triangular cross-section, see FIGS.

According to FIG. 4, the retracted communication cables 2 lie between the inflection regions 6 along the entire length of the cable guide channel 1 on different sliding ribs 4, but in the illustrated cross section of the channel 3 only one sliding rib 4, independently of the diameter of the communication cable 2.

In the embodiment according to FIG. 5, it is ensured that the distances A between the contact points P of the communication cable 2 are selected in the region of the inflection points 5 so that the corresponding communication cable 2 with the smallest diameter in the region of the inflection points 5 and consequently 5 to 8, the sliding ribs 4 have different heights H and different spacings A between the different cable diameters 2 to accommodate the different diameters of the communication cables 2. the contacting points P of the communication cables 2, the spacing A between the contacting points P in the region of the inflection points 5 of the sliding ribs 4 are selected such that the communication cables 2 in this region of the inflection points 5 and consequently in the inflection areas 6 at least two sliding ribs 4, independently of their diameter. The sliding • ribs 4 have different width B in the region of their base, namely a larger width B at their higher height H.

Sliding ribs 4 with different heights H and different width B in the region of their base and different spacings A between the contact points P of the communication cables 2 form the guide cross section of the channel 3, which is distributed symmetrically over the inner circumference of the channel 3.

Giant. 5 to 8 show the geometry of the sliding ribs 4 with abutment points P in the region of the inflection points 1 and in the inflection regions 6, respectively, in the most unfavorable case.

Claims (5)

PATENT CLAIMS A cable guide tube, made of thermoplastic material, for receiving communication cables, in particular glass fiber cables, with a cable guide channel of circular cross-section and an inner channel wall with sliding ribs having alternating directions in the direction of the longitudinal axis of the channel A method according to claim 1, characterized in that the spacings (A) between the cable contact points (P) on the sliding ribs (4) are selected in the region of the inflection points (5) such that the communication cable (2) bears with its smallest diameter. 5) on at least two sliding ribs (4). Cable guide tube according to claim 1, characterized in that the sliding ribs (4) have different heights (H) and different spacings (A) at the bearing points (P) to accommodate different diameters of the communication cables (2). and that the spacings (A) between the cable contact points (P) in the region of the inflection points (5) are selected such that the communication cables (2) with different diameters fit in the region of the inflection points (5) on at least two sliding ribs (2). ). 3. A cable guide tube made of thermoplastic material for receiving communication cables, in particular glass fiber cables, with a cable guide channel of circular cross-section and an inner channel wall with sliding ribs extending parallel to one another in the longitudinal direction of the pipe. that the sliding ribs (4) for adapting to different diameters of the communication cables (2) have different heights (H) and different spacings (A) between the cable contact points (P), these spacings (A) between the cable contact points (P) being They are selected in such a way that the communication cables (2), depending on their respective diameter, bear against the sliding ribs (4) intended for the respective cable diameter. 9 9 9 99 99 • * Cable guide tube according to one of Claims 1 to 3, characterized in that the sliding ribs (4) have different widths (B) in the region of their base. Cable guide tube according to one of Claims 1 to 4, characterized in that the sliding ribs (4) with different heights (H), with different widths (B) in the region of their base and with different spacings (A) between the bearing points The cable (P) forms a guiding cross-section between the cable contact points (P) of the cable guide channel (3), which is distributed symmetrically over the entire inner circumference of the cable guide channel (3).