DE20022368U1 - pipe - Google Patents

Description

Pipe

The invention relates to a pipe for the transport of liquid or gaseous media, consisting of polymeric material, with at least one medium-carrying inner pipe, an outer pipe, wherein the inner pipe and/or the outer pipe preferably consist of a cross-linked polymeric material, a heat insulation layer made of a foamed polymeric material located between the inner pipe and the outer pipe and a barrier layer located on the inside and/or the outside and/or within the wall of the inner pipe.

A pipe of this type is known from DE 33 07 120.

This pipe consists of at least one medium-carrying inner pipe, an outer pipe and a heat insulation layer between the pipes made of in situ foamed plastic based on polyurethane or polyisocyanate. The inner pipe should consist of a cross-linked plastic and have a metallic layer on its inside and/or outside or within its wall, with the outer pipe also consisting of plastic, preferably a cross-linked plastic.

This pipe should be more cost-effective to produce and more corrosion-resistant to aggressive media while maintaining the flexibility and good thermal insulation known from the state of the art.

The metallic layer, which is applied in the form of a metal foil, in particular an aluminium foil with a wall thickness of 0.1 to 0.5 mm, is intended to prevent water vapour from diffusing through the wall of the inner tube into the foam layer, which could potentially lead to the destruction of the foam. To do this, it is necessary that the metallic layer is self-contained.

This metallic layer has a coating on both sides, which is intended to create a bond between the inner tube and the plastic layer positioned below the foam layer.

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This is intended to ensure that the metal foil does not tear or wrinkle when the pipe is bent.

A further metallic layer in the form of a one-sided coated aluminum foil is applied to the thermal insulation layer, which is intended to create an adhesive bond between the aluminum foil and the foam layer.

An extruded plastic tube, which is preferably made of a polyolefin, is then applied to this aluminum foil as an outer jacket.

However, with such a complicated pipe structure as described in DE 33 07 120, the necessary manufacturing costs are very high, so that an economical use of such a pipe is not possible.

A further disadvantage is that the metal foils to be applied, in addition to the complex coating with adhesives, which should be carried out on one or both sides, have a weak point at their contact edges.

Here, a sufficient overlap of the metal foil must be provided, which further increases the material and manufacturing costs, although it is still not guaranteed that the metal foil will wrinkle or tear when this pipe is laid in small bending radii.

Another disadvantage is that a plastic layer is extruded onto this first metal foil, which acts as an additional protective and supporting layer and which calls into question the economic viability of a pipe manufactured in this way.

In a preferred embodiment, the tube structure has been further complicated by inserting a further metal foil between the foam layer and the outer tube, which metal foil has at least one adhesive coating on one side.
Although this further reduces water vapor diffusion and oxygen permeation from the outside to the inside, the economic efficiency of such a pipe falls by the wayside.

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The use of such metal foils also leads to a disadvantageous reduction in the flexibility of the entire pipe, since both the linear installation and the realization of bending radii depend on the properties of the metal foil used.

Another pipe of this type is known from EP 0 538 538. In this pipe, the outer layer consists of a cross-linked polyethylene-butyl-acrylate copolymer, which has an increased permeability to water vapor and is therefore intended to prevent an accumulation of water vapor diffusing out of the medium-carrying inner pipe into the foam layer.

When using such a polyethylene-butyl-acrylate copolymer, the pipe is optimized with regard to water vapor diffusion from the medium-carrying inner pipe, but the mechanical properties of this pipe are negatively affected.

A disadvantage of this pipe is that the costs of using such optimized copolymers for the use of the pipe according to the invention are uneconomical.

A further disadvantage is that the oxygen permeation of such a pipe is not prevented or only insignificantly prevented, so that additional protective measures must be provided when using such a pipe.

In other pipes used in the known state of the art, the outer pipe consists of a non-crosslinked polymer material, in particular polyethylene or polypropylene.

With these pipes, special care must be taken when laying them underground in order not to damage the outer pipe, which serves as a protective layer.
In order to be able to be laid as flexibly as possible, these pipes are designed to be very thin in terms of the wall thickness of the protective layer, with the wall thicknesses in this range being between approx. 1 and 3 mm.

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In order not to damage this protective layer during installation on the construction site or when subjected to loads during use, such as settlement or traffic loads, it is imperative that these pipes are laid in a sand bed.

This has the disadvantage that when laying pipes underground, a certain amount of soil replacement must be carried out, as the excavated material must be deposited and sand must be transported and properly placed for laying such pipes.

This significantly increases the costs of laying such pipes, so that the economic viability of using such pipes must be questioned.

This is where the invention comes in, which has set itself the task of avoiding the disadvantages of the known prior art and of demonstrating a pipe which can be produced economically while optimally preventing water vapor diffusion and oxygen permeation, which is easier to handle due to its flexibility and can be laid underground without additional effort and which ensures optimal prevention of water vapor diffusion and oxygen permeation even with small bending radii.

According to the invention, this is achieved in that the barrier layer consists of a non-metallic material and that the outer tube consists of a cross-linked polymeric material.

The barrier layer made of a non-metallic material has the great advantage that the pipe according to the invention can be produced economically using an extrusion process without additional devices, such as for applying metal foils. A further advantage is seen in the fact that this barrier layer, which in an advantageous embodiment is a polymer material based on ethylene vinyl alcohol, prevents the diffusion processes from the inner pipe carrying the medium to be transported.

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Fluid to the environment and at the same time prevents the diffusion of oxygen or similar substances into the interior of the pipe according to the invention.
It has been found advantageous that when using ethylene vinyl alcohol for the barrier layer of the pipe according to the invention, a vinyl alcohol content of at least 10% is required in order to be able to realize the required diffusion properties.

This is also the case when the pipe according to the invention is laid in very tight bending radii, since the barrier layer made of the non-metallic material is firmly connected to the inner pipe, but at the same time is flexible. This barrier layer, which in another advantageous embodiment is an aliphatic polyketone, largely prevents the diffusion of oxygen into the fluid or gas to be transported in the medium-carrying inner pipe. This oxygen diffusion is known to lead to increased corrosion on metallic parts, such as fittings or pipelines. Surprisingly, it was found that the barrier layer made of the non-metallic material ensures optimal prevention of water vapor diffusion and oxygen permeation even with a wall thickness of 1/32 of the outer diameter of the inner pipe, so that the price-performance ratio of the pipe according to the invention is considerably better than that of the known prior art.

In order to be able to implement the optimal diffusion properties of the pipe according to the invention combined with the high corrosion resistance of the inner pipe used in a cost-effective manner during installation and assembly, the outer pipe preferably has a corrugated structure.

It has been found to be particularly advantageous here that with a ratio of the corrugation depth to the distance between two corrugation peaks of preferably 20 to 25 mm, on the one hand the stability and winding ability in the manufacturing process of the pipe according to the invention and, on the other hand, the flexibility in laying even with small bending radii are guaranteed at all times.

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Another advantage is that the corrugation depth of the outer pipe is preferably 2 to 4 mm, which on the one hand limits the manufacturing costs of such corrugated pipes, but on the other hand defines the required stability and flexibility.

It was further found that the wall thickness of the outer tube is preferably 1/50 of the outer diameter of the wave crests.

This value is an optimum of the requirements necessary for flexibility and stability and the possibilities that can be realized cost-effectively and economically in production.

A further additional advantage of the pipe according to the invention is the design of the outer pipe in a cross-linked polymer material, since this allows installation without additional expenditure for a sand bedding.

In a preferred embodiment, the cross-linked polymeric material is a cross-linked polyethylene, which is characterized by high point load capacity without a tendency to stress cracking.

A further advantage is that the wall thickness of the outer tube is 1.5% of the outer diameter of the outer tube, which means that the tube according to the invention is still flexible while being sufficiently robust.

Due to the geometric dependencies of the corrugated structure of the outer pipe found, it has also been possible to improve the stability of the entire pipe, especially when using larger thermal insulation layers, due to increased legal requirements, so that the flexibility of the pipe according to the invention is nevertheless maintained.

This corrugated structure of the outer pipe also enables the use of thermal insulation layers with lower densities, which have the same thermal conductivity and thus have the same insulating effect, so that the pipes according to the invention can be produced more cost-effectively.

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Due to its optimal chemical, mechanical and thermal properties, the pipe according to the invention can be manufactured and installed cost-effectively, whereby bending radii corresponding to twice the outer diameter of the corrugation crests of the outer pipe are permissible.

In a further embodiment of the pipe according to the invention, an empty pipe is inserted between the inner pipe and the outer pipe.

This empty pipe, which is sufficiently spaced from the inner pipe to prevent thermal effects, is suitable for accommodating cables for electrical and/or optical communication. Here, it has proven to be useful that the distance of the empty pipe from the inner pipe is greater than the distance from the outer pipe.

The pipe according to the invention will now be explained in more detail using the embodiment shown schematically in the following figure. It shows:

Figure 1: Sectional view of a pipe according to the invention

The tube 1, which is not shown to scale in section in Figure 1, has a multi-layered structure. The lumen 2 of the tube 1 surrounds the wall of the inner tube 3.

In this embodiment, a barrier layer 4 made of a non-metallic material is applied to the outside of the inner tube 3, which has a wall thickness of 0.1 mm, which corresponds to approximately 1/30 of the outer diameter of the inner tube 3.

In further embodiments not shown here, the barrier layer 4 can also be applied to the inside of the inner tube 3, wherein the barrier layer 4 can also be introduced into the wall of the inner tube 3.

Between the inner pipe 3 with the barrier layer 4, which is fully connected to it and over its entire length, and the outer pipe 6, the thermal insulation

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layer 5 is introduced, which consists of a foamed polymer material. This heat insulation layer 5 is firmly connected to the outer tube 6 and via the barrier layer 4 to the inner tube 3.

The outer tube 6 of the tube 1 according to the invention has a corrugated structure, with wave crests 62 and wave troughs 61 adjoining one another. The difference between the outer diameter of the wave crests 62 and the wave troughs 61 results in the wave depth, which is preferably 2 to 4 mm.

The arrangement of the wave crests 62 and wave troughs 61 is designed to alternate in this embodiment, but can also be irregularly alternating or spiral-shaped over the circumference of the tube 1.

In this embodiment, the wall thickness of the outer tube 6 is 1/100 of the outer diameter of the wave crests 62.

The invention further teaches that a monitoring element 7 is introduced into the space filled by the thermal insulation layer 5 between the inner pipe 3 and the outer pipe 6 of the pipe according to the invention, which monitoring element is intended to register leaks.

This monitoring element 7 can, for example, be an electrically conductive uninsulated cable running parallel to the longitudinal axis of the pipe 1, wherein such a monitoring element 7 can also be applied in a spiral shape to the barrier layer 4 located on the inner pipe 3.

- Protection claims -

Rehau, 02.05.2001
dr.schi-zkmi/e

Claims (12)

1. Pipe for the transport of liquid or gaseous media, consisting of polymer material, with at least one medium-carrying inner pipe, an outer pipe, a heat insulation layer made of a foamed polymer material located between the inner pipe and the outer pipe and a barrier layer located on the inside and/or outside and/or within the wall of the inner pipe, characterized in that the barrier layer ( 4 ) consists of a non-metallic material and that the outer pipe ( 6 ) consists of a cross-linked polymer material. 2. Pipe according to claim 1, characterized in that the barrier layer ( 4 ) is an ethylene vinyl alcohol with a vinyl alcohol content of at least 10 percent by weight. 3. Pipe according to one of the preceding claims, characterized in that the barrier layer ( 4 ) is an aliphatic polyketone. 4. Pipe according to one of the preceding claims, characterized in that the outer pipe ( 6 ) is corrugated. 5. Pipe according to one of the preceding claims, characterized in that in the outer pipe ( 6 ) the ratio of wave depth to the distance between two wave crests ( 62 ) is at least 5. 6. Pipe according to one of the preceding claims, characterized in that the corrugation depth of the outer pipe ( 6 ) is preferably 2 to 4 mm. 7. Pipe according to one of the preceding claims, characterized in that the wall thickness of the outer pipe ( 6 ) is preferably 1/50 of the outer diameter of the corrugation peaks ( 62 ). 8. Pipe according to one of the preceding claims, characterized in that the wall thickness of the outer pipe ( 6 ) is a maximum of 1.5% of the outer diameter of the outer pipe ( 6 ). 9. Pipe according to one of the preceding claims, characterized in that monitoring elements ( 7 ) are introduced between the inner pipe ( 3 ) and the outer pipe ( 6 ). 10. Pipe according to one of the preceding claims, characterized in that the monitoring elements ( 7 ) are electrically conductive, uninsulated cables. 11. Pipe according to one of the preceding claims, characterized in that between the inner pipe ( 3 ) and the outer pipe ( 6 ) there is at least one empty pipe ( 8 ) which is spaced from the inner pipe ( 3 ) and is suitable for receiving communication cables. 12. Pipe according to one of the preceding claims, characterized in that the distance of the empty pipe ( 8 ) from the inner pipe ( 3 ) is greater than the distance from the outer pipe ( 6 ).