HRP20000614A2 - Tube for wire conduits - Google Patents

Abstract

The thermoplastic conduit has a cable channel of circular cross section with an internal wall with ribs running in the direction of the channel axis with the formation of reversal points. The rib spacing between cable bracket points in the area of the reversal points is so chosen that the communication cable with the smallest diameter is supported on at least two ribs close to reversal points.

Description

The invention relates to a pipe for conducting wire lines made of thermoplastic synthetic material for receiving communication cables, especially glass fiber cables, with a round channel for guiding or conducting the cable and the inner wall of the channel with sliding ribs in the section, which ribs in the direction of the longitudinal axis of the channel along the creation of turning points show alternating directions. The alternating direction means that the flow of the sliding ribs, viewed in the projection on the longitudinal axis of the channel itself for the cable routing, is different, for example once from left to right, once from right to left. In doing so, the arrangement can be made in such a way that the sliding ribs in the direction of the longitudinal axis of the cable in the sections have a different slope. After all, the sliding ribs can flow parallel to each other in a spiral, i.e. winding or snake-like manner.

Such pipes are known for conducting wire lines, in which the sliding ribs that flow in alternating directions are used so that disturbing twisting forces cannot act on the conducting cable or cable bundle that needs to be inserted or retracted. The forces resulting from the mutual action of a single cable for transmission of news with sliding ribs do not allow annoying twisting and sometimes completely neutralize each other. In individual cases, the sliding ribs can form areas of sliding with helically shaped sections of the sliding ribs, which show the opposite flowing direction of the turns. Sliding ribs can also run serpentine and usually have a triangular or arched cross-section. DE 40 16 726/.

The wire lines that are pulled, pushed or blown into such a pipe for conducting lie along the length of the cable, as a rule, on several sliding ribs, because these flow in a serpentine or winding manner with the opposite direction of rotation. Areas in front of the pivot points of the sliding ribs can become problematic. Because it is not excluded that wire lines with a relatively small diameter of the cable in such areas of turning /turning/ fall into the valley of the ribs between two adjacent sliding ribs. This makes pulling in or blowing in or blowing out the respective wire line due to the increased frictional force and reduced sliding much more difficult. This also applies to the case that with already inserted wire lines, at some later time, these wire lines must be drawn in for a certain length, that is, pushed in or even inflated. Similar problems can arise with cables with larger diameters. In principle, it depends on the design and arrangement of the sliding ribs, especially on the spacing of the sliding ribs. This is where invention will bring a solution.

The solution is based on the task of creating a pipe for conducting wire lines of the aforementioned form of performance

in which it is ensured that the wire lines that need to be inserted, drawn in or blown in the areas of the pivot points of the sliding ribs always rest on the sliding ribs and thus the frictional resistance when inserting the wire lines or when re-inserting the cable remains significantly reduced, regardless of the diameter of the conduit pipe wire lines.

This task is solved by the invention in the pipe for conducting wire lines in the embodiment as stated at the beginning by the fact that the distances of the sliding ribs between the points of contact of the pipe in the area of rotation are chosen in such a way that each wire line with the smallest diameter in the area of rotation and, accordingly, the points of rotation sliding areas in the most unfavorable case lies on at least two adjacent ones. sliding ribs. - Within the scope of the invention, the pipe contact points also mean contact lines or surfaces.

These measures of the invention have the consequence that the intrusion of the wire lines with the smallest diameter into the recess of two adjacent sliding ribs in the area of the turning points and thus the place of rotation of the sliding areas is avoided, what is more, the contact of the lines on the sliding ribs is always ensured. Therefore, there remains a significant reduction of frictional forces during the insertion or retraction of the respective wire line, as well as the re-insertion of the wire lines in the case of a pipe that already has wire lines.

Perfect gliding is always guaranteed even for wire lines with a small or the smallest wire diameter. Disturbing twists are still prevented.

Further measures according to the invention are listed below. Thus, the invention foresees that the sliding ribs in adjustment show for different diameters of the wire lines different heights of the sliding ribs and different distances of the sliding ribs between the contact points of the cable and that the distances of the sliding ribs between the contact points in the area of rotation are chosen in such a way that the wire lines of different diameters in the area turns rest on at least two sliding ribs. According to this way of implementing the invention, it is taken into account that, in particular, communication cables with a larger diameter than the wire line of the smallest diameter in the area of the turning point of the sliding ribs in the most unfavorable case also rest on the two sliding ribs, and therefore they cannot fall into the recess between the ribs. when greater spacing of the sliding ribs and the height of the ribs are realized. Therefore, it is always ensured, even with wire lines with larger or different cable diameters, that the frictional resistance that such a cable suffers when it is inserted or re-inserted into the pipe for conducting wire lines remains significantly reduced at the point of rotation and therefore also in the areas of rotation.

If it is a pipe for conducting wire lines with sliding ribs that flow in one direction and in parallel, so it is about sliding ribs without changing direction, the invention foresees that the sliding ribs in adjusting different diameters of wire lines have different heights and different distances between the sliding ribs between the points of contact of the cables and that the distances of the sliding ribs between the points of contact are chosen in such a way that these cables - depending on the respective diameter of the cable - lie on the sliding ribs provided for that diameter. Within this idea, these wire lines are classified into their own sliding ribs depending on their diameter. At the same time, cuts are not excluded, so that cables of different diameters then rest on identically the same sliding ribs, when it is a matter of an insignificant or relatively small difference in the diameter of the cable-wire lines.

Sliding ribs with larger sliding rib heights also indicate a larger width of ribs in the area of sliding rib renewal, so that ultimately sliding ribs of different rib widths and heights are realized.

Towards the end, the invention foresees that the sliding ribs of different heights, of different widths in the region of the base of the ribs and with different distances between the contact points form the guide cross-section of the conducting channel, which is symmetrically distributed over the inner diameter of the channel for guiding the wire bundles, therefore it repeats regularly, so that the adjustment a pipe for conducting wire lines is not necessary, in fact, in each position of the pipe for conducting wire lines, the above-defined guide section of the channel is available. As a result, according to the invention, a system of multiple ribs is realized for points in the area of rotation and therefore the area of rotation, which exists in the inner diameter of the cable channel.

In the following, the invention is explained on the basis of one example in the drawing. It shows like this:

Drawing 1 in a cut-off tube for conducting wire lines shown in perspective,

Drawing 2 object according to drawing 1 in a vertical section with indicated cables of different diameters,

Drawing 3 unwrapping the object according to drawing 2, in sections,

Drawing 4 Section through the object according to drawing 3 in the area between the turning points of the sliding ribs that flow in a serpentine manner,

Drawing 5 partial section through the object according to figure 3 in one area of rotation, with the points of contact of the cable in the most unfavorable case at the smallest diameter of the cable,

Drawing 6 Object according to drawing 5 with a larger cable diameter,

Drawing 7 object according to drawing 6 with an even larger cable diameter,

Drawing 8 object according to drawing 7 with an even larger cable diameter.

The drawings show a pipe for conducting wire bundles 1 made of thermoplastic synthetic material for receiving communication cables 2, especially cables made of glass fibers, i.e. conductors of light waves. This pipe for conducting bundles of wires 1 has a round guide channel 3 in diameter or cross-section, an inner wall with sliding ribs 4 lying parallel to each other, which, taken on the longitudinal axis of the channel and in the direction of the axis-joint of the channel L, with the creation of pivot points 5 show alternating directions. These pivot points 5 of the sliding ribs define the areas of rotation 6 between the sliding ribs 4. According to the embodiment, the sliding ribs 4 run serpentine in the direction of the longitudinal axis of the cable L and have a triangular cross-section. In this regard, reference is made to drawings 1 to 3.

According to drawing 4, bundles of wires 2 lie tucked between the area of the turning points, i.e. the area of turning/returning/ 6 along the length of the channel for guiding the wire lines 3 on different sliding ribs 4, where in the shown section of the guiding channel 3 they lie only on one sliding rib 4 and regardless of the respective cable diameter.

In the embodiment according to drawing 5, it was taken into account that the distances A between the sliding ribs between the contact point P in the area of the turning points 5 are chosen in such a way that the respective wire lines 2 of the smallest diameter in the area of turning 5 and therefore the area 6 are located at least two adjacent sliding ribs and therefore cannot fall into the depression of the ribs between two sliding ribs 4. According to drawings 5 to 8 show sliding ribs for adaptation to different cable diameters of wire lines 2 different heights of sliding ribs H and different distances A between the contact points P, at where the distances of the sliding ribs A are chosen in the area of rotation or the pivot points 5 of the sliding ribs 4 so that the cables 2 in the area of the pivot points 5 and therefore in the areas of rotation 6 lie on at least two sliding ribs, regardless of the size or diameter of the cable. The sliding ribs 4 have different widths of the sliding ribs B in the area of the base of the sliding ribs, namely a larger width of the sliding rib B at a higher height H of the sliding rib.

The sliding ribs 4 with different heights of the sliding ribs H and different width of the sliding ribs B in the area of the base of the sliding ribs and different distances of the ribs A between the contact points of the cable P, create a cross-section of the guiding channel for guiding the wire lines 3, which is symmetrically arranged around the inner circumference of the leading channel 3. This explains drawing 2 quite clearly.

Drawings 5 to 8 show the geometry of the sliding ribs with the contact points of the cable P in the area of the turning points 5 and in the areas of turning 6, and always in the most unfavorable case.

Claims (5)

1. A pipe for conducting wire lines made of thermoplastic synthetic mass for receiving communication cables, especially glass fiber cables with one, in cross-section, a round channel for conducting wires/cables/ and an inner wall of the channel with sliding ribs, which in the direction of the longitudinal axis of the channel - along the formation of turning points show alternating directions, indicated by the fact that the distances of the sliding ribs /A/ between the contact points of the cable /P/ in the area of the turning points /5/ are chosen in such a way that the cable /2/ with the smallest diameter in the area of turning /5/ lies on at least two sliding ribs /4/. 2. Pipe for conducting wire lines according to claim 1, characterized by the fact that the sliding ribs /4/ in order to adapt to different diameters of communication cables /2/ have different heights H of the sliding ribs, as well as different distances between the ribs /A/ between the contact points /P/ and that the distances of the sliding ribs /A/ between the contact points /P/ in the area of the turning points /5/ are chosen so that the wire line /2/ in the area of the turning points /5/ rests on at least two sliding ribs /4/. 3. Pipe for conducting wire lines made of thermoplastic synthetic mass for receiving communication cables, especially glass fiber cables, with one, in cross-section, round channel for conducting wires and the inner wall of the channel with sliding ribs, which run parallel to each other in the longitudinal direction of the pipe, characterized by the fact that the sliding ribs /4/ in order to adapt to the different cable diameters of the news wires /2/ have different heights of the sliding ribs /H/ and different distances of the sliding ribs /A/ between the contact points /P/ of the cable, so that the wire bundle of the respective diameter of the cable rests on certain sliding ribs. 4. Pipe for conducting wire bundles according to claims 1 to 3, characterized in that the sliding ribs /4/ show a different width of the sliding rib /B/ in the area of the base of the rib. 5. A pipe for conducting wire bundles according to one of claims 1 to 4, characterized in that the sliding ribs /4/ of different height /H/, different widths of the sliding ribs /B/ in the area of the base of the ribs and different spacing of the sliding ribs /A/ between points of contact of the cable /P/ create a leading cross-section of the cable for conducting wire bundles /3/, which in a symmetrical arrangement is distributed over the inner circumference of the channel for conducting wire bundles.