SK284612B6 - Pipe made of polymeric material - Google Patents

Abstract

Pipe made of polymeric material for setting cables, optical conductors, tubes and similar has an internal smooth periphery, which is divided into partial segments (11), which are separated by grooves (12). Dimensional proportion between the partial segments (11) and the grooves (12) is in scope from 1.5 : 1 until 5 : 1. Internal tube periphery is created from hard polymeric material.

Description

The invention relates to a pipe made of a thermoplastic material consisting of at least two layers of thermoplastics of different properties, the inner pipe as a support layer being sheathed on its outer circumference with a protective sheath forming a covering layer.

BACKGROUND OF THE INVENTION

Multi-layer pipes are widely known. For example, EP-A-174611 and WO-A-8 401988 disclose multi-layer thermoplastic pipes having a top layer of cross-linked polyethylene. European Patent Specification No. 0 337037 B1 discloses a multilayer pipe consisting of a support pipe of high density crosslinked polyethylene and an outer sheath of high density uncrosslinked polyethylene. On the one hand, the pipe utilizes the beneficial properties of cross-linked polyethylene in that the pipes of this material have a high chemical resistance and a high heat resistance, are resistant to abrasion and are insensitive to stress corrosion and notch effects. However, the drawback of such cross-linked polyethylene pipes is that they are difficult to weld or cannot be welded at all. This drawback is avoided in the prior art in that the high density crosslinked polyethylene is provided at least on the outside with a sheath of uncrosslinked, weldable polyethylene. Such multilayer tubes can be produced by coextrusion.

DE 44 18 006 A1 discloses a further multilayer plastic pipe with a polyolefin base pipe and a last layer of thermoplastic polyester. The two layers of this construction are cohesively bonded to each other by a suitable adhesive layer. Such pipes can also be laid as drinking water pipes in contaminated soils since the last layers prevent the penetration of interfering substances into the flowing fluid. A drawback of tubes with a last layer of thermoplastic polyester is that the latter layer must be glued to the base tube.

German patent DE 4 113415 A discloses a cable entry device with at least one thermoplastic cable entry pipe having a cross-section of a circular cable entry channel and having an inner wall with mutually parallel grooves and between the grooves with projecting ribs. The grooves are provided with a liquid glidant wetting the inner wall of the channel having a predetermined viscosity and a predetermined surface tension, the groove depth and groove width being adjusted such that the glidant is under the influence of surface tension and viscosity and under wetting forces in the grooves as a space for retaining the glidant.

Glidant grooves are provided with glidants selected from the group consisting of glycerol caprylate, caprate, layered silicate, medium chain fatty acid triglyceride, silicones and mixtures thereof. Such glidant grooves have a depth in the range of 0.1 to 1.0 mm and a maximum width in the range of 0.3 to 3.0 mm. The grooves for retaining the glidant and the ribs are helical or corrugated and / or are zigzag. The arrangement of very densely divided grooves in the inner part of the pipe should influence the increased reduction of the contact surface between the pipe and the cable, which should successfully influence the movement of the cable within the pipe guide. The depth of the grooves or their spacing and thus the so-called grooving is kept as small as possible in order to reduce the effective surface of the inner circumference of the pipe and thus also the resistance to sliding friction. Sliding means are provided in the trenches soaking the inner wall of the channel. The pipes thus formed have an extremely fine grooving on the inner surface with very pointed ribs between which the known grooves lie. Such pipes are also known from DE 3 830942, DE 3 529541 or DE 3 539304 and EP 0 329 128, CZ3524U and EP0 326 711.

Such tubes known in the art have triangular, circular or semicircular ribs on the inner surface, which are separated by grooves, but no tube has been described so far that the inner, smooth circumference of the tube is divided into sub-segments.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a wear-resistant thermoplastic pipe for trenchless laying, which can be joined by standard joining elements without the need to remove the protective layer, wherein the clearance is no longer affected compared to the standard pipe.

SUMMARY OF THE INVENTION

According to the invention, a polymer pipe for pulling cables, light conductors, pipes and the like, wherein the inner circumference of the pipe has a ribbed structure formed by grooves, consists in that the inner smooth pipe circumference is divided into sub-segments, the sub-segments forming sub-regions of smooth inner the pipe areas separated by the grooves between the sub segments and the dimensional ratio between the sub segments and the grooves is in the range of 1.5: 1 to 5: 1. The inner circumference of the pipe with the sub segments, separated by the grooves, forms a hard polymer layer. .

Thus, it is a pipe which is made of polymeric material for introducing, for example, cables, light fibers and pipes, the inner circumference of the pipe having a rib-like structure which is formed by grooves, its main inner smooth circumference being divided into sub-segments which form sub-areas of smooth the inner surface of the pipe, which are separated from each other by known grooves arranged between the sub-segments, while maintaining the dimensional ratios between the sub-segments and the grooves of 1.5: 1 to 5: 1. a partial area of the smooth inner surface of the pipe, still being in direct contact. The cables to be introduced therefore do not rest on triangular ribs, in particular as in DE 4 113415 A, but on sub-segments which form partial regions of the smooth inner surface of the pipe.

In contrast to the prior art solution, in particular unlike the German patent DE 4 113415 A, the dimensional ratio between the sub-segments and the grooves is 1.5: 1 to 5: 1. This is exactly in contrast to the prior art, in particular German Patent DE 4 113415 A discloses grooves width in the range 0.3 to 3.0 mm, the groove depth being in the range 0.1 to 1.0 mm.

The fact that the inner smooth circumference of the pipe is divided into three sub-segments which form the sub-regions of the smooth inner surface of the pipe and which are separated from each other by known grooves arranged between the sub-segments and that the dimensional ratio between the sub-segments and the grooves is 1 , 5: 1 to 5: 1, is neither known nor deductible from the prior art.

The fact that the inner circumference of the pipe with the segment segments separated by grooves is made of a layer of hard polymeric material is different from the solution, for example according to German patent DE 4 113415 A.

Thus, according to the invention, the sub-segments form the sub-sections of the smooth inner surface of the pipe, thus forming no spikes or rounded rib shapes. Thus, the blown cable remains on the respective partial section of the smooth inner surface of the pipe when blowing, always in a straight line contact. This achieves a minimum of friction and minimum cable shear, as is the case with pipes having a smooth inner surface as described in the prior art.

By arranging the grooves between these sub-segments of the smooth inner surface, on the other hand, infiltration of the blown compressed air under the cable is still guaranteed, thus creating an air cushion under the cable. Accordingly, according to the invention, the advantages of the grooved cable protection tubes are combined with the advantages of the cable protection tubes with a smooth inner surface.

The dimensional ratio of the partial sections and the grooves is preferably 1.5: 1 to 5: 1. Thus it is possible to blow the cables of different diameters into the protective tubes with the advantage of minimal trimming according to the invention at a large blown length.

In a preferred embodiment, the inner circumference of the pipe with the broken segments is interrupted by a hard polymer layer. In this multi-layered pipe wall cross-sectional construction, the inner pipe is produced by the coextrusion technique in the region of the high density polyethylene hard segments and grooves. By this measure, further reduction of the sliding friction is guaranteed and thus the cable is in contact with the blown cable with the smooth inner surface of the pipe, manufactured as a sub-segment with a relatively wide mounting range.

The inner surface of the protective tube results in an optimum combination of the positive features of the protective tube with a smooth inner surface and the characteristics of the protective tube with internal ribs. At the same time, the unavoidable sliding friction on the smooth inner surface of the pipe - made by the partial segments - minimizes the cable sheathing while forming under the air cushion cable through the air penetrating the grooves, thereby extending the injected length of such cable extremely.

The invention is illustrated, but not limited, by the following examples.

BRIEF DESCRIPTION OF THE DRAWINGS

In FIG. 1 is a cross-sectional view of the protective tube with the cables inserted.

In FIG. 2 are the dimensional ratios of the sub-segments and grooves in various embodiments.

DETAILED DESCRIPTION OF THE INVENTION

Fig. 1 shows a protective tube 1 with a single-layer wall cross-section. Partial segments 11 are arranged at regular intervals on the inner circumference and are each separated by grooves 12. Cables of different cross-section are inserted into the interior 13 of the protective tube 1. For example, cable 2 has a diameter d = 12 mm, while cable 3 has a diameter of 20 mm. The cable 2 remains on the other sub-segments 11 'and overlaps the groove 12'. When the compressed air is blown, the compressed air enters the groove 12 ', whereby the cable 2 is lifted into the interior 13 of the protective pipe 1 and carried on the air cushion. This process is further supported by the air running through the adjacent grooves 12 on the sides of the cable 2. This minimizes scraping of the cable sheath and the compressed air is optimally utilized to transport the cable 2 inside the protective tube 1.

For cable 2, the procedure is similar. The cable 3 rests with the entire circumference on the sub-segments 11 ', which is understandable due to its larger cross-sectional area. Compressed air from the grooves 12 'and the adjacent 12 cables 3 lifts - as described with cable 2 - to the interior 13 of the protective tube 1'. This movement is supported by a stream of air from the other grooves 12 running along the cable 3, thereby improving the floatability of the cable 3. Figure 2 shows the dimensional ratios of the sub-segment 11 and the groove 12 in various embodiments. In Figure 2a, the dimension ratio is 1.5: 1. This ratio is expediently used only where large diameter cables must be drawn into the protective tubes.

In Figure 2b, the ratio between the sub-segment 11a is the groove 12 2: 1. Also this dimensional ratio should be usefully used when pulling cables of larger diameters. In both cases, for smaller diameter cables, the carrier air could not generally act under the cable, as it should be in the optimum case, but would blow out on both sides of the cable sheath, while the desired float would only be insufficiently achieved.

Figure 2c shows the dimensional ratio 3.1a and Figure 2d shows the 5: 1 ratio.

With these ratios, smaller diameter cables can also be lifted optimally into the interior 13 of the protective tube 1, because, due to the selected dimensional ratios, the air flow from the grooves 12 is directly under the cable and thus the lifting effect is optimized.

The partial segments 11 with the grooves 12 separating these are variable in their direction. They may be oriented axially along the entire length of the protective tube 1, but they may also be in a spiral, arc or similar arrangement on the inner circumference of the protective tube 1.

Industrial usability

Protective tube for cables, tubes and similar appliances. A suitable treatment of the inner surface of the protective tube is achieved by combining a smooth surface with minimal friction with a grooved profile, allowing the supply of compressed air to float the stranded cable.

Claims (2)

A polymer pipe for wiring cables, light conductors, pipes and the like, wherein the inner circumference of the pipe has a ribbed structure formed by grooves, characterized in that the inner smooth circumference of the pipe is divided into sub-segments (11), the sub-segments ( 11) form sub-regions of the smooth inner surface of the pipe which are separated by grooves (12) between the sub-segments (11) and the dimensional ratio between the sub-segments (11) and the grooves (12) is in the range of 1.5: 1 to 5 : 1. A pipe according to claim 1, characterized in that the inner circumference of the pipe with the partial segments (11) separated by the grooves (12) is a hard polymer layer.