RU118015U1 - MULTILAYER PIPE - Google Patents

Abstract

1. A multilayer pipe obtained by extrusion and / or pultrusion and / or molding, including at least one polymer layer and at least one reinforcing layer, including two or more metal layers. ! 2. The multilayer pipe of claim 1, comprising an inner polymer layer and an outer reinforcing layer surrounding the inner polymer layer. ! 3. The multilayer pipe of claim 1, comprising an inner reinforcing layer and an outer polymeric layer surrounding the inner reinforcing layer. ! 4. A multilayer pipe according to claim 1, comprising at least one inner polymer layer, a reinforcing layer surrounding at least one inner polymer layer, and at least one outer polymer layer surrounding the reinforcing layer. ! 5. Multilayer pipe according to claims 1-4, in which the reinforcing layer is formed from at least two metal layers of different alloys of the same metal selected from the group including: aluminum, iron, copper. ! 6. The multilayer pipe according to claim 5, in which the metal layers of the reinforcing layer are formed by methods selected from the group including: multilayer extrusion, plasma deposition of metal layers, electro-vacuum deposition of layers, chemical deposition of metal layers, electrochemical deposition of metal layers or another method of forming a multilayer metal layer. ! 7. Multilayer pipe according to claims 1-4, in which the reinforcing layer is formed in the form of a smooth or corrugated pipe from a multilayer metal strip, including at least two metal layers of different alloys of the same metal selected from the group including: aluminum, iron, copper. ! 8. Me

Description

FIELD OF TECHNOLOGY

The utility model relates to pipeline technology, in particular, to multilayer pipes made of metal and polymers made by extrusion, pultrusion or molding for transportation of liquid and gaseous media, for heating systems, hot and cold water supply, gas supply, floor heating systems, panel heating and air conditioning , snow melting and anti-icing systems, systems for using geothermal and low-grade heat, technological heat exchange systems, compressed air supply systems, techno logical pipelines, fire water supply systems. Other applications include the transport of gases, liquids, and suspensions.

BACKGROUND

Multilayer metal-polymer pipes are well known and are described in large numbers in the literature. Due to their advantages, multilayer metal-polymer pipes have deservedly found wide application in various fields.

Multilayer pipes are known in which they consist of a metal layer surrounded by a polymer layer (RU 2415333 C2, 08.08.2006, F16L 59/00, B32B 27/32, B32B 27/06). Multilayer pipes are used, for example, in cases where increased mechanical strength, long-term strength at elevated temperatures are required, or a reinforcing layer and a barrier layer providing oxygen impermeability are required.

Recently, multilayer metal-polymer pipes including barrier layers based on aluminum, which is also a reinforcing layer (RU 88311 U1, dated 05.08.2009, B32B 15/08, B29C 47/04, B82B 3/00), have been very popular. When installing domestic heating systems, water supply, gas supply, the metal layer provides special and important advantages: in particular, when bending pipes, they retain a new configuration, as opposed to plastic pipes without a metal reinforcing barrier layer, which tend to return to their original shape.

Usually, a metal layer in a metal-polymer pipe is obtained by forming a pipe from a metal tape, followed by welding of its edges. The most common methods for welding the edges of a metal strip are: lap welding with ultrasound, TIG welding, laser welding.

In many ways, the possibility of welding determines the choice of alloy for the metal layer of the metal-polymer pipe, and at the same time, orientation on the weldability of the alloy significantly reduces the possibility of optimizing the physical parameters and the cost of the metal-polymer pipe. For example, it is well known that by introducing alloying additives into aluminum, it is possible to obtain an aluminum strip with a wide range of physical characteristics, such as strength, flexibility, and ductility. At the same time, the presence of dopants can reduce the cost of the alloy. But when the aluminum content in the alloy is less than 96..97%, the alloy loses its weldability. Basically, in the production of a metal-polymer pipe, a compromise between the physical parameters of the pipe and its cost should be achieved by varying the thickness of the metal layer - or increase the strength of the pipe by increasing the thickness of the metal layer to the detriment of cost, or vice versa to reduce the cost to the detriment of strength.

The objective of this utility model is to optimize the technical and economic parameters of multilayer metal-polymer pipes.

DISCLOSURE OF A USEFUL MODEL

The problem is solved in that the multilayer pipe obtained by extrusion and / or pultrusion and / or molding, includes at least one polymer layer, and at least one reinforcing layer comprising two or more metal layers.

Moreover, the multilayer pipe may include an inner polymer layer, and an outer reinforcing layer surrounding the inner polymer layer.

Moreover, the multilayer pipe may include an inner reinforcing layer, and an outer polymer layer surrounding the inner reinforcing layer.

Moreover, the multilayer pipe may include at least one inner polymer layer, a reinforcing layer surrounding at least one inner polymer layer, and at least one outer polymer layer surrounding the reinforcing layer.

The reinforcing layer of a multilayer pipe may be formed of at least two metal layers of different alloys of the same metal selected from the group including: aluminum, iron, copper; or a reinforcing layer of a multilayer pipe may be formed of at least two metal layers of alloys of various metals selected from the group including: aluminum, iron, copper; moreover, the metal layers of the reinforcing layer can be formed by methods selected from the group including: multilayer extrusion, plasma deposition of metal layers, electro-vacuum deposition of layers, chemical deposition of metal layers, electrochemical deposition of metal layers, or another method of forming a multilayer metal layer.

The reinforcing layer of the multilayer pipe may be formed in the form of a smooth or corrugated pipe from a multilayer metal tape comprising at least two metal layers of different alloys of the same metal selected from the group including: aluminum, iron, copper; or a reinforcing layer of a multilayer pipe is formed in the form of a smooth or corrugated pipe from a multilayer metal tape comprising at least two metal layers of alloys of various metals selected from the group consisting of: aluminum, iron, copper; moreover, the layers of a multilayer metal strip are formed by methods selected from the group including: metallurgical, multilayer casting of metals, plasma deposition of a metal layer, electro-vacuum deposition, chemical deposition of metal, electrochemical deposition of metal, bonding, soldering, welding, explosion welding, rolling, or other A method of forming a multilayer metal tape.

An example of the implementation of a multilayer metal tape can be a tape consisting of three layers of various aluminum alloys; the two outer layers to ensure good weldability and / or adhesion are made of a high aluminum alloy, and the inner layer is alloyed with additives to achieve the desired physical performance and cost ratios - thus thin outer layers of an expensive alloy with a high base metal content ensure the weldability of the edges of the tape when forming a pipe from it, and the inner layer forms the physical and mechanical properties of the tape through the use of alloy hydrogenated by well-known additives. This approach significantly expands the range of mechanical and physical characteristics of aluminum tape, and therefore, the multilayer pipe itself. An additional advantage of this approach is that an alloy of recycled metal can be used as the inner layer.

The surfaces of the reinforcing layer of a multilayer pipe may not be processed by physical surface modification, chemical surface modification, nanoscale surface modification; or at least one surface of the reinforcing layer of the multilayer pipe is treated by physical surface modification, wherein the surface modification is selected from the group including treatment with high voltage atmospheric pressure barrier discharges, plasma treatment, ultrasonic treatment, electrovacuum spraying, abrasive treatment, ablation and cleaning, or processed by chemical surface modification, the surface modification being selected from the group including solvent cleaning, ku chemicals, chemical modifiers, processing for introduction of surface functional groups, deposition of surface layers by plasma deposition of a polymeric layer containing functional groups, deposition of a glassy layer, or other surface coating techniques to improve its wetting characteristics; or at least on one surface of the reinforcing layer of the multilayer pipe by nano-sized surface modification, a nano-sized relief and / or nano-submicrodimensional relief and / or nano-microdimensional relief and / or periodic nanoscale relief are formed, wherein the surface nanoscale modification is selected from the group including: treatment with high-voltage atmospheric pressure barrier discharges, plasma treatment, ultrasonic treatment, electro-vacuum deposition of metals, chemical etching, electro chemical etching and other technologies of nanoscale surface modification to increase the adhesive strength between the layers of metal and polymer.

Additionally, the reinforcing layer acts as an oxygen barrier.

All the polymer layers of the multilayer pipe can be made of one polymer, or the polymer layers of the multilayer pipe can be made of different polymers.

Moreover, the polymer layers of the multilayer pipe can be made of polymers selected from classes including carbochain polymers, heterochain polymers, high molecular weight compounds with conjugated

Moreover, the polymer layers of the multilayer pipe can be made of polyolefins.

Moreover, the polymer layers of the multilayer pipe can be made of polymer compositions.

Moreover, the polymer layers of the multilayer pipe can be made of polymer compounds.

Moreover, the polymer layers of the multilayer pipe can be made of polymers selected from the group including: polyethylene, marketed by polyethylene of various densities, such as low-pressure polyethylene - HDPE, high-pressure polyethylene - LDPE, linear LLDPE polyethylene; including crosslinked polyethylene, which is currently on the market with crosslinked polyethylene with various types of crosslinking: peroxide, designated - PEX; silane, designated - PEX-b; radiation, designated - PEX-s, and nitrogen (PEX-d); including polyethylene of increased heat resistance, referred to as PE-RT (Polyethylene of Raised Temperature resistance), which is marketed by polyethylene of high temperature resistance of various types: type I, type II, type III, and the most common brands Dowlex 2344, Dowlex 2388 - manufacturer Dow Chemical ; DX800 - manufacturer of SK Corporation; XP9000 - manufacturer Daelim; SP980, SP988 - manufacturer of LG Chem; ELTEX TUB220-RT - manufacturer of INEOS; including polyethylene copolymers, ethylene-octene copolymer, ethylene-octene-1 copolymer, polypropylene, polypropylene copolymers, combinations of polyethylene or copolymers of polyethylene with polypropylene or polypropylene copolymers.

Moreover, the polymer layers of the multilayer pipe can be made of polymers selected from the group consisting of polyester resins, epoxy resins, vinyl ether resins, full-methane resins; and reinforced with fibers selected from the group consisting of fiberglass, basalt fiber, carbon fiber.

The polymer layers of the multilayer pipe may not contain stabilizing additives.

To improve the physical properties of the multilayer pipe, and expand the scope of its application, at least one polymer layer may contain an effective amount of at least one stabilizing additive selected from the group including: thermostabilizer, antioxidant, radical scavenger, aging inhibitor, light stabilizer, UV stabilizer, flame retardant. For example, the use of light stabilizers and a UV stabilizer allow the use of a multilayer pipe as a gas pipe; the use of flame retardants improves the fire resistance of a multilayer pipe, which makes it possible to use it as a pipe for fire water supply.

The polymer layers of the multilayer pipe may not contain antibacterial additives, ions of antibacterial metals, nanoparticles of antibacterial metals.

In order to reduce siltation of the inner surface of the polymer pipe, improve the quality of transported water, and reduce bacterial contamination of the pipe surfaces, the polymer layers of the multilayer pipe may contain an effective amount of at least one antibacterial additive, which is a concentrate of the antibacterial additives in the polymer carrier. Currently, a number of companies produce concentrates of antibacterial additives in a polymer carrier. An example of a concentrate of antibacterial additives in a polymer carrier is CESA-antimicro, manufactured by Clariant.

In order to reduce siltation of the inner surface of the polymer pipe, improve the quality of the transported water, and reduce bacterial contamination of the pipe surfaces, at least one polymer layer of the multilayer pipe may contain antibacterial metal ions selected from the group consisting of silver, gold, platinum, palladium, iridium, tin, copper, antimony, bismuth, zinc, or at least one polymer layer of a multilayer pipe may contain nanoparticles obtained from antibacterial metals selected from the group, including bubbling silver, gold, platinum, palladium, iridium, tin, copper, antimony, bismuth, zinc.

The polymer layers of the multilayer pipe may not contain heat-conducting additives, dispersed heat-conducting fillers, heat-conducting nanofillers.

In order to obtain the property of increased thermal conductivity of the multilayer pipe, at least one polymer layer of the multilayer pipe may contain heat-conducting additives, which are present in an amount of from 0.05 to 45 wt.%. An example of concentrates of thermally conductive additives are additives; Nemcon ™ H PE from Ovation Polymers, CoolPoly E8103 from Cool Polymers Inc .. A number of other companies specializing in the manufacture of additives for polymers produce similar heat-conducting additives for polyolefins. Currently, there are concentrates of heat-conducting additives on the market with a wide range of thermal conductivity from 3 to 100 W / m.K.

In order to obtain the property of increased thermal conductivity of the multilayer pipe, at least one polymer layer of the multilayer pipe may contain an effective amount of at least one heat-conducting dispersed filler in an amount of from 0.05 to 45 wt.%, Which is selected from the group comprising boron nitride, nitride aluminum, aluminum oxide, aluminum hydroxide, aluminum powder, aluminum fibers, aluminum flakes, iron powder, iron fibers, iron flakes, copper powder, copper fibers, copper flakes, technical th carbon, graphite, graphite fibers, metallized glass fibers; or at least one polymer layer of the multilayer pipe may contain an effective amount of at least one heat-conducting nanofiller in an amount of not more than 15 wt.%., which is obtained from the group including: boron nitride, aluminum nitride, aluminum oxide, aluminum hydroxide, aluminum, iron, copper, graphite, layered clays, layered silicates, ceramics.

The polymer layers of the multilayer pipe may not contain fiber, or at least one polymer layer of the multilayer pipe may contain fiber from fibers selected from the group consisting of fiberglass, basalt fiber, carbon fiber.

The polymer layers of the multilayer pipe may not contain nanoparticles, or at least one polymer layer of the multilayer pipe may contain nanoparticles selected from the group including fullerene, astralen, graphene, carbon nanotubes, nanotubes obtained from synthetic polymers.

The polymer layers of the multilayer pipe may not contain mineral particulate fillers, or at least one polymer layer of the multilayer pipe may contain mineral particulate fillers in an amount of 1 to 30 wt.%, And is selected from the group consisting of talc, mica, calcium carbonate, kaolin, clay, magnesium hydroxide, calcium silicate, carbon black, graphite, iron powder, silicon dioxide, diatomite, titanium oxide, iron oxide, pumice, antimony oxide, dolomite, dawsonite, zeolite filler, vermiculite, montmorillonite and hydrate Alumina.

The polymer layers of the multilayer pipe may not contain mineral nanoscale fillers, or at least one polymer layer of the multilayer pipe may contain mineral nanoscale fillers that are obtained from intercalated clays, expanded clays, layered clays, layered silicates, calcium carbonate, calcium phosphate, silicon carbide and silica.

The multilayer pipe according to the present utility model may not contain polymer layers of foamed polymers.

A multilayer pipe according to the present utility model may comprise at least one polymer layer, which is made of foamed polymer. Various types of foamed polymers (sometimes called gas-filled polymers) are available on the market that can be used according to this utility model; these are foamed polymers based on thermoplastic polymers with a linear structure - polyolefins (polyethylene, polystyrene, polyvinyl chloride, polypropylene, etc.) and thermosetting polymers based on polymers with a spatial structure (phenol-formaldehyde, urea-formaldehyde, unsaturated polyesters, epoxy, vinyl ether, polyurethane, etc.), the most common ennymi foamed polymers are: polystyrene, penopolivinilhlorid, polyurethane, foam rubber, penofenoplast, expanded polypropylene, penopoliepoksid, penokarbamid, Penoizol, foamed polyethylene, foamed ethylene propylene rubber.

The multilayer pipe according to the present utility model may not contain polymer layers from intumescent fire retardant compositions.

A multilayer pipe according to the present utility model may contain at least one polymer layer, which consists of intumescent fire retardant compositions based on intercalated graphite and / or intercalated clays.

Layers of a multilayer pipe according to the present utility model can be connected directly to each other, or at least one pair of adjacent layers of the polymer pipe can be connected by an adhesive layer.

The adhesive layer of the present utility model may be an adhesive layer.

The adhesive layer according to the present utility model may be a mixture of a polyolefin polymer with an adhesive, wherein the polyolefin polymer is present in an amount of not more than 90% by weight.

The adhesive layer of the present utility model may be a functional polyolefin polymer containing side polar functional groups.

The adhesive layer according to the present utility model may be a mixture of a polyolefin polymer and a functional polyolefin polymer containing lateral polar functional groups, wherein the polyolefin polymer is present in an amount of not more than 90 wt.%.

The adhesive layer of the present utility model may be a mixture of a polyolefin polymer and an inorganic particulate filler containing side polar functional groups.

Adding additives, fillers, nanofillers to the polymer layers of a multilayer pipe before extrusion, molding, pultrusion of polymers by mixing the polymer with filler (additives, nanofillers) in a mixer, or preparing the mixture by granulation in a twin-screw extruder, or by directly feeding polymer components to the extruder layer using vacuum or gravimetric loaders, or other technically feasible method.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 shows a schematic diagram of a multilayer pipe with a three-layer metal reinforcing layer.

EXAMPLE OF IMPLEMENTATION OF A USEFUL MODEL

As shown in FIG. 1, a multilayer pipe consists of an inner polymer layer 1, an inner adhesive layer 2, an outer polymer layer 3, an outer adhesive layer 4, and a three-layer reinforcing layer 5 consisting of two outer metal layers 6 located between the inner and outer adhesive layers , and the inner metal layer 7.

The polymer pipe is obtained by extrusion and / or molding and / or pultrusion.

In order to expand the functional properties of the multilayer pipe, and improve the technical characteristics of the multilayer pipe, the polymer layers can contain stabilizing, antibacterial, heat-conducting additives, various fillers and nanofillers that are added to the polymers before extrusion, molding, pultrusion by mixing in a mixer, or preparing the mixture by re-granulation in a twin-screw extruder, or by directly feeding the components of the polymer layer into the extruder using vacuum or gravimetric charges ikov, or in another technically feasible way.

The use of a multilayer metal layer in a multilayer pipe as a reinforcing layer allows optimizing the technical and cost performance of a multilayer pipe.

The device operates as follows:

A multilayer pipe obtained by extrusion and / or pultrusion and / or molding methods includes at least one polymer layer and at least one reinforcing layer comprising two or more metal layers. Due to the use of two or more layers of metal in the reinforcing layer in various combinations of alloys of one metal, or alloys of different metals, a compromise is achieved between the properties of the reinforcing layer.

For example, the outer or outer layers of the reinforcing layer are made in the form of a thin layer of an expensive alloy with a high content of the base metal to ensure weldability and / or better adhesion, and the required mechanical characteristics are provided by an inexpensive inner alloy with alloying additives.

Thus, the device allows you to optimize the technical and cost parameters of a multilayer pipe depending on its purpose, for example: to reduce the cost of the multilayer pipe while maintaining its physical parameters, to improve the physical parameters of the multilayer pipe while maintaining its value, or to find a compromise between the cost and the required physical characteristics of the multilayer pipes.

The proposed device is industrially applicable using existing technical means. (It is planned to start mass production in the 4th quarter of 2011)

It will be apparent to one skilled in the art that various modifications and changes are possible in the present utility model. Accordingly, it is assumed that this utility model covers possible modifications and changes, as well as their equivalents, without departing from the essence and scope of the utility model disclosed in the attached utility model formula.

Claims (46)

1. A multilayer pipe obtained by extrusion and / or pultrusion and / or molding, comprising at least one polymer layer and at least one reinforcing layer comprising two or more metal layers. 2. The multilayer pipe according to claim 1, comprising an inner polymer layer and an outer reinforcing layer surrounding the inner polymer layer. 3. The multilayer pipe according to claim 1, comprising an inner reinforcing layer and an outer polymer layer surrounding the inner reinforcing layer. 4. The multilayer pipe according to claim 1, comprising at least one inner polymer layer, a reinforcing layer surrounding at least one inner polymer layer, and at least one outer polymer layer surrounding the reinforcing layer. 5. A multilayer pipe according to claims 1 to 4, in which the reinforcing layer is formed of at least two metal layers of different alloys of the same metal selected from the group including: aluminum, iron, copper. 6. The multilayer pipe according to claim 5, in which the metal layers of the reinforcing layer are formed by methods selected from the group including: multilayer extrusion, plasma deposition of metal layers, electro-vacuum deposition of layers, chemical deposition of metal layers, electrochemical deposition of metal layers or another method of forming a multilayer metal layer. 7. A multilayer pipe according to claims 1 to 4, in which the reinforcing layer is formed in the form of a smooth or corrugated pipe from a multilayer metal tape comprising at least two metal layers of different alloys of the same metal selected from the group consisting of: aluminum, iron, copper. 8. The multilayer pipe according to claim 7, in which the layers of the multilayer metal tape are formed by methods selected from the group including: metallurgical, multilayer metal casting, plasma deposition of the metal layer, electro-vacuum deposition, chemical metal deposition, electrochemical metal deposition, bonding, soldering, welding, explosion welding, rolling or another method of forming a multilayer metal strip. 9. A multilayer pipe according to claims 1 to 4, in which the surface of the reinforcing layer is not processed by physical surface modification, chemical surface modification, nanoscale surface modification. 10. A multilayer pipe according to claims 1 to 4, in which at least one surface of the reinforcing layer is treated by physical surface modification, the surface modification being selected from the group including treatment with high-voltage atmospheric pressure barrier discharges, plasma treatment, ultrasonic treatment, electric vacuum spraying , abrasive treatment, ablation and cleaning, or processed by chemical surface modification, while the surface modification is selected from the group including cleaning Oritel, cleaning chemicals, chemical modifiers, processing for introduction of surface functional groups, deposition of surface layers by plasma deposition of a polymeric layer containing functional groups, deposition of the vitreous layer and the other surface coating techniques to improve its wetting characteristics. 11. A multilayer pipe according to claims 1 to 4, in which at least one surface of the reinforcing layer by nanoscale surface modification is formed nanoscale relief, and / or nanosubmicro-sized relief, and / or nanomicro-sized relief, and / or periodic nanoscale relief, surface nanoscale modification is selected from the group including: treatment with high-voltage atmospheric pressure barrier discharges, plasma treatment, ultrasonic treatment, electro-vacuum deposition of metals, chemical herbs pouring, electrochemical etching and other technologies of nanoscale surface modification to increase the adhesive strength between the layers of metal and polymer. 12. A multilayer pipe according to claims 1 to 4, in which at least one polymer layer is made of polymers selected from classes including carbochain polymers, heterochain polymers, high molecular weight compounds with a conjugated bond system. 13. The polymer pipe according to claims 1 to 4, in which at least one polymer layer is made of polyolefins. 14. A multilayer pipe according to claims 1 to 4, in which at least one polymer layer is made of polymer compositions. 15. A multilayer pipe according to claims 1 to 4, in which at least one polymer layer is made of polymer compounds. 16. A multilayer pipe according to claims 1 to 4, in which at least one polymer layer is made of polymers selected from the group consisting of polyethylene, crosslinked polyethylene, high temperature resistant polyethylene, polyethylene copolymers, ethylene-octene copolymer, ethylene- copolymer octene-1, polypropylene, copolymers of polypropylene, combinations of polyethylene or copolymers of polyethylene with polypropylene or copolymers of polypropylene. 17. The multilayer pipe according to claims 1 to 4, in which at least one polymer layer is made of polymers selected from the group consisting of polyester resins, epoxy resins, vinyl ether resins, polyurethane resins; and reinforced with fibers selected from the group consisting of fiberglass, basalt fiber, carbon fiber. 18. A multilayer pipe according to claims 1 to 4, in which the polymer layers do not contain stabilizing additives. 19. A multilayer pipe according to claims 1 to 4, in which at least one polymer layer contains an effective amount of at least one stabilizing additive selected from the group including: a thermal stabilizer, an antioxidant, a radical acceptor, an aging inhibitor, a light stabilizer, UV- stabilizer, flame retardant. 20. A multilayer pipe according to claims 1 to 4, in which the polymer layers do not contain antibacterial additives, ions of antibacterial metals, nanoparticles of antibacterial metals. 21. The multilayer pipe according to claims 1 to 4, in which at least one polymer layer contains at least one antibacterial additive, which is a concentrate of antibacterial additives in the polymer carrier. 22. The multilayer pipe according to claims 1 to 4, in which at least one polymer layer contains antibacterial metal ions selected from the group comprising silver, gold, platinum, palladium, iridium, tin, copper, antimony, bismuth, zinc. 23. The multilayer pipe according to claims 1 to 4, in which at least one polymer layer contains nanoparticles obtained from antibacterial metals selected from the group comprising silver, gold, platinum, palladium, iridium, tin, copper, antimony, bismuth zinc. 24. The multilayer pipe according to claims 1 to 4, in which the polymer layers do not contain heat-conducting additives, dispersed heat-conducting fillers, heat-conducting nanofillers. 25. The multilayer pipe according to claims 1 to 4, in which at least one polymer layer contains heat-conducting additives, which are present in an amount of from 0.05 to 45 wt.%. 26. A multilayer pipe according to claims 1 to 4, in which at least one polymer layer contains at least one heat-conducting dispersed filler in an amount of from 0.05 to 45 wt.%, Which is selected from the group comprising boron nitride, aluminum nitride , aluminum oxide, aluminum hydroxide, aluminum powder, aluminum fibers, aluminum flakes, iron powder, iron fibers, iron flakes, copper powder, copper fibers, copper flakes, carbon black, graphite, graphite fibers, metallized glass fibers. 27. A multilayer pipe according to claims 1 to 4, in which at least one polymer layer contains at least one heat-conducting nanofiller in an amount of not more than 15 wt.%, Which is obtained from the group comprising: boron nitride, aluminum nitride, aluminum oxide, aluminum hydroxide, aluminum, iron, copper, graphite, layered clays, layered silicates, ceramics. 28. A multilayer pipe according to claims 1 to 4, in which the polymer layers do not contain fiber. 29. A multilayer pipe according to claims 1 to 4, in which at least one polymer layer contains a fiber of fibers selected from the group including fiberglass, basalt fiber, carbon fiber. 30. A multilayer pipe according to claims 1 to 4, in which the polymer layers do not contain nanoparticles. 31. A multilayer pipe according to claims 1 to 4, in which at least one polymer layer contains nanoparticles selected from the group consisting of: fullerene, astralen, graphene, carbon nanotubes, nanotubes obtained from synthetic polymers. 32. A multilayer pipe according to claims 1 to 4, in which the polymer layers do not contain mineral particulate fillers. 33. A multilayer pipe according to claims 1 to 4, in which at least one polymer layer contains mineral dispersed fillers in an amount of from 1 to 30 wt.% And is selected from the group consisting of talc, mica, calcium carbonate, kaolin, clay , magnesium hydroxide, calcium silicate, carbon black, graphite, iron powder, silicon dioxide, diatomite, titanium oxide, iron oxide, pumice, antimony oxide, dolomite, dausonite, zeolite filler, vermiculite, montmorillonite and hydrated alumina. 34. A multilayer pipe according to claims 1 to 4, in which the polymer layers do not contain mineral nanoscale fillers. 35. A multilayer pipe according to claims 1 to 4, in which at least one polymer layer contains mineral nanoscale fillers, which are obtained from intercalated clays, expanded clays, layered clays, layered silicates, calcium carbonate, calcium phosphate, silicon carbide and silica. 36. A multilayer pipe according to claims 1 to 4, which does not contain polymer layers of foamed polymers. 37. The multilayer pipe according to claims 1 to 4, in which at least one polymer layer is made of foamed polymer. 38. A multilayer pipe according to claims 1 to 4, which does not contain polymer layers of intumescent fire retardant compositions. 39. A multilayer pipe according to claims 1 to 4, in which at least one polymer layer consists of intumescent fire retardant compositions based on intercalated graphite and / or intercalated clay. 40. A multilayer pipe according to claims 1 to 4, in which the layers are connected directly to each other. 41. A multilayer pipe according to claims 1 to 4, in which at least one pair of adjacent layers is connected by an adhesive layer. 42. The multilayer pipe of claim 41, wherein the adhesive layer is an adhesive layer. 43. The multilayer pipe according to paragraph 41, in which the adhesive layer is a mixture of a polyolefin polymer with an adhesive, and the polyolefin polymer is present in an amount of not more than 90 wt.%. 44. The multilayer pipe according to paragraph 41, in which the adhesive layer is a functional polyolefin polymer containing lateral polar functional groups. 45. The multilayer pipe according to paragraph 41, in which the adhesive layer is a mixture of a polyolefin polymer and a functional polyolefin polymer containing lateral polar functional groups, and the polyolefin polymer is present in an amount of not more than 90 wt.%. 46. The multilayer pipe according to paragraph 41, in which the adhesive layer is a mixture of a polyolefin polymer and a filler containing lateral polar functional groups.