RU2288398C1 - Multilayer pipe and method of its manufacturing - Google Patents

Abstract

FIELD: rigid pipes.

SUBSTANCE: multilayer pipe comprises inner protecting layer made of durable material, intermediate layer, and outer protecting layer made of a composition material. The layers are interconnected. The pipe has fittings for connecting the pipe with adjacent pipes or valving members. The inner protecting layer and intermediate layer are interconnected through the flexible cords. The intermediate layer is made of a polymeric concrete reinforced with the longitudinal rods rigidly connected with the fittings to define reinforcing frames. The method comprises moulding the inner protecting layer, intermediate layer, and outer protecting layer with the use of a mandrel, laying the reinforcing members, and securing fittings for connecting with the adjacent pipes or valving members.

EFFECT: reduced labor consumptions and cost.

2 dwg

Description

The invention relates to rigid composite reinforced pipes made of several materials and intended for transportation of liquid products under high pressure or vacuum, as well as to the processes of their manufacture.

The prior art is known for the closest to the invention in terms of number of common features and the achieved result multilayer pipe containing interconnected inner protective layer made of wear-resistant material, an intermediate layer and an outer protective layer made of composite material, as well as endings for connection with adjacent pipes or pipe fittings (“A pipe made of composite materials for transporting gaseous and liquid products under high pressure and the method of its production copulating (variants) », RU, №2166145 C1, IPC 7 F 16 L 9/12, appl 02.11.1999, published on 27.04.2001, the closest analogue -.. prototype).

The inner protective layer is made in the form of three concentric layers of chemically and abrasion-resistant rubber, which are formed by rubber bands laid in each layer in a spiral overlap. To form concentric layers forming the inner protective layer, rubber tapes 130 mm wide and 1.0 mm thick were used. Tapes are spirally overlapped in each layer along the edges. The width of the lap is 8-12 thicknesses of the tape, and in the first layer, the lap is facing in the opposite direction to the direction of movement of the transported product.

The intermediate layer comprises two concentric layers of a low-density material not impregnated with a binder. As a low-density material used non-woven material. The said layers are formed by non-woven fabric ribbons with a width of 70 mm, which are laid in a spiral overlap at half the width of the tape. The non-woven material of the tapes has a porous loose structure with the possibility of penetration into it at certain softening temperatures and the pressing forces of the crude rubber of the inner protective layer. At the same time, the nonwoven material does not interfere with the penetration of a binder from the side of the third additional concentric layer that is part of the intermediate layer, and directly contacts the outer protective layer of composite material.

The outer protective layer, plays the role of a power cage in this pipe construction, contains fifteen concentric layers of composite material, each of which is formed by ribbons with a parallel arrangement of reinforcing elements in the form of fibers. The tapes are laid with overlapping edges in a spiral with an angle of inclination to the longitudinal axis of the pipe from 52 to 56 ° and impregnated with a binder.

The pipe ends are made of composite material simultaneously with the manufacture of the pipe body, placed on top of the outer layer, connected to it by a one-piece cured binder, have the form of flanges in the form of an annular thickening of the pipe ends with the shank and contact with the outer layer in the length from 0.27 to 0.29 m

However, the known pipe has a complex structure and is made of expensive materials. So, to ensure the necessary strength and reliability, its outer protective layer, which plays the role of a power cage in this pipe design, is made of fifteen concentric layers of spiral tapes made of composite material impregnated with a binder, which significantly increases the complexity and cost of its manufacture. Moreover, the connection of the inner protective layer made of rubber, based on the penetration of crude rubber into the pores of the nonwoven material of the intermediate layer, does not provide sufficient strength for such fastening and makes it unreliable when using a solid material with low adhesive properties as an inner protective layer of a multilayer pipe e.g. glass, porcelain, fluoroplastic or other material with similar properties.

The prior art method of manufacturing a multilayer pipe closest to the invention by the number of common features and the achieved result, comprising forming an inner protective layer made of a wear-resistant material, an intermediate layer and an outer protective layer made of a composite material, and also fastening the ends, are known for connection with adjacent pipes or pipe fittings ("A pipe made of composite materials for transporting gaseous and liquid products under high pressure and the method of its manufacture (options) ", RU, No. 2166145 C1, 7 IPC F 16 L 9/12, application. 02.11.1999, publ. 04/27/2001, the closest analogue is the prototype).

The inner protective layer of wear-resistant material is formed by winding onto a cylindrical mandrel coated with a release agent or a release film of three concentric layers of raw rubber tape with a winding pitch of 120 mm.

An intermediate layer is then formed. For this, two concentric layers of an intermediate layer of a tape of dry nonwoven material are wound on the inner protective layer. At a certain softening temperature and winding forces, the crude rubber of the inner protective layer penetrates into the pores of the loose structure of the two concentric layers of the nonwoven material and, with further vulcanization of the crude rubber, provides the connection of the inner protective layer with the intermediate layer of the pipe. After that, a third concentric layer of the intermediate layer of a tape of dry nonwoven material is wound with a winding pitch of 25 mm and a tension of 25-30 kg.

The outer protective layer of the pipe made of composite material - the power frame is formed from fifteen concentric spiral layers of roving impregnated with an epoxy binder with a parallel arrangement of reinforcing elements in the form of fibers. The tapes are laid at a winding angle of 52-56 ° to the longitudinal axis of the pipe with a tension of 25-30 kg and at a binder temperature of 55 + 5 ° C. In this case, the binder of the outer layer penetrates into the pores of the loose structure of the third concentric layer of the nonwoven layer of the intermediate layer and, upon further curing of the binder, provides the connection of the outer layer with the intermediate layer of the pipe.

Endings in the form of flanges or fittings are formed by spiral winding at the end sections of the outer layer of the tape from a composite material composed of glass rovings and impregnated with an epoxy binder.

The mandrel with the wound billet of the pipe is removed from the machine and placed in a thermal unit, where the binder is cured with the vulcanization of rubber and their penetration into the non-woven material of the concentric layers of tapes of the intermediate layer of the pipe for their layer-by-layer connection.

However, the known method of manufacturing a multilayer pipe is characterized by great complexity and requires the use of expensive materials. So, to ensure the necessary strength and reliability, the outer layer, which plays the role of a power cage in this pipe design, is formed from fifteen concentric layers of spiral strips of composite material impregnated with a binder, which significantly increases the complexity and cost of its manufacture.

Moreover, the connection of the inner protective layer made of rubber, based on the penetration of crude rubber into the pores of the nonwoven material of the intermediate layer, does not provide sufficient strength for such an attachment and makes it unreliable when it is used as a material of the inner protective layer of a solid material with low adhesive properties e.g. glass, porcelain, fluoroplastic or other material with similar properties.

The technical problem to which the group of inventions, united by a single inventive concept, is directed, is to create a multilayer pipe design and a method for its manufacture in which, through their improvement, the use of low-cost materials and the optimal sequence of operations, reliability and simplification of the pipe design and process are improved its manufacture.

The technical result of using the group of inventions is to reduce the complexity and cost of manufacturing a multilayer pipe while ensuring its high strength.

The stated technical problem is solved, and the expected technical result is achieved by the fact that in a multilayer pipe containing interconnected inner protective layer made of wear-resistant material, an intermediate layer and an outer protective layer made of composite material, as well as endings for connection with adjacent pipes or pipe fittings, according to the invention, the inner protective layer and the intermediate layer are fastened together by flexible bundles, while the intermediate layer is made of reinforced polymer concrete rods rigidly fastened with tips in reinforcing frames.

These signs are significant, since in aggregate they are sufficient to solve the technical problem and achieve the expected technical result, and each separately is necessary to identify and distinguish the claimed multilayer pipe from similar technical solutions known from the prior art.

This combination of common and distinctive essential features that characterize the claimed multilayer pipe is not known from the prior art, is new and sufficient in all cases to which the scope of legal protection applies.

The causal relationship of the distinctive features in their interaction with the known features in achieving the expected technical result due to the technical task is as follows.

Thus, the fastening of the inner protective layer with the intermediate layer between each other with flexible braids significantly increases the strength and reliability of this connection and the multilayer pipe as a whole.

Such a connection also makes it possible to use not only rubber as a material of the inner protective layer, but also a solid material with low adhesive properties, such as glass, porcelain, fluoroplastic, or other material with similar properties, which also increases the reliability and safety of the multilayer pipe during operation.

The implementation of the intermediate layer of polymer concrete, reinforced with longitudinal rods, rigidly fastened with tips in the reinforcing frames, ensures the formation in the intermediate layer of a technologically advanced, durable and reliable power frame made of inexpensive materials, such as reinforcing and structural steel.

In addition, the use of polymer concrete increases the strength of the pipe under the action of high overpressure both inside and outside the multilayer pipe, reduces the complexity and cost of its manufacture, and also increases the manufacturability through the use of inexpensive material based on polymers and cement.

The prior art, the applicant does not know the technical solutions that match the distinguishing features of the inventive multilayer pipe, which indicates that the proposed technical solution has an inventive step.

The stated technical problem is solved, and the expected technical result is also achieved by the fact that in the method of manufacturing a multilayer pipe, comprising forming with the mandrel an inner protective layer made of wear-resistant material, an intermediate layer and an outer protective layer made of composite material, as well as fixing the ends for connection with adjacent pipes or pipe fittings, according to the invention, when forming the inner protective layer, separate parts are attached to it these flexible strands, and then form an intermediate layer of reinforced polymer concrete, for which longitudinal rods are placed on the formed inner protective layer, which are rigidly fastened with tips in reinforcing frames, free parts of flexible strands are fastened with longitudinal rods of reinforcing frames, and the gaps between the longitudinal rods of reinforcing the frames are filled with polymer concrete, after which an outer protective layer is formed.

The above signs are significant, since in aggregate they are sufficient to solve the technical problem and achieve the expected technical result, and each separately is necessary to identify and distinguish the claimed method of manufacturing a multilayer pipe from similar technical solutions known from the prior art.

This set of common and distinctive essential features that characterize the claimed method of manufacturing a multilayer pipe is not known from the prior art, is new and sufficient in all cases to which the scope of legal protection applies.

The causal relationship of the distinctive features in their interaction with the known features in achieving the expected technical result due to the technical task is as follows.

So, due to the fact that during the formation of the inner protective layer, separate parts of flexible bundles are attached to it, a reliable and strong mechanical connection of the latter with the said layer is ensured.

Due to the fact that the formation of the intermediate layer is made of reinforced polymer concrete, the laboriousness and cost of manufacturing the pipe are significantly reduced, its processability is increased, and at the same time, its high strength and reliability during operation are achieved.

Due to the fact that during the formation of the intermediate layer longitudinal rods are laid on the formed inner layer, which are rigidly fastened with the tips in reinforcing frames, the formation of a technologically advanced, durable and reliable power frame from inexpensive materials, for example, reinforcing and structural steel, is ensured in the intermediate layer.

Due to the fact that during the formation of the intermediate layer, the free parts of the flexible bundles are fastened to the longitudinal rods of the reinforcing frames, a reliable and strong mechanical connection of the latter with the said layer is achieved.

Filling the gaps between the reinforcing carcass rods with polymer concrete after attaching the flexible harnesses to the longitudinal rods of the reinforcing carcasses creates an additional reliable and strong mechanical connection between the flexible harnesses and the cured polymer concrete.

An improved method for manufacturing a multilayer pipe allows, along with the polymer material - rubber, to use as the material of the inner protective layer a solid material with low adhesive properties, such as glass, porcelain, fluoroplastic, or other material with similar properties, which also increases the reliability and safety of the multilayer pipe when operation.

And the use of polymer concrete is technologically feasible and justified, as it provides increased pipe strength under the action of high overpressure, both inside and outside the multilayer pipe, reduced labor intensity and cost of its manufacture, as well as increased manufacturability through the use of inexpensive material based on polymers and cement.

The prior art, the applicant does not know the technical solutions that match the distinguishing features of the proposed method for manufacturing a multilayer pipe, which indicates that the proposed technical solution has an inventive step.

The above characteristics characterizing this group of inventions are not mandatory, but, according to the applicant, are the best and do not exclude the possibility of their equivalent performance.

In the future, a group of inventions related by a single inventive concept is illustrated by a detailed description of the construction of a multilayer pipe and a method of manufacturing a multilayer pipe with reference to the accompanying drawings.

Figure 1 shows a multilayer pipe, a longitudinal section.

Figure 2 shows a multilayer pipe, a cross section.

The multilayer pipe (FIGS. 1, 2) contains interconnected inner protective layer 1 made of wear-resistant material, an intermediate layer 2 and an outer protective layer 3 made of composite material, as well as a tip 4 for connection with adjacent pipes or pipe fittings.

The inner protective layer 1 and the intermediate layer 2 are fastened together by flexible braids 5, while the intermediate layer 2 is made of polymer concrete reinforced with longitudinal rods 6, rigidly bonded with the tips 4 in reinforcing frames.

The inner protective layer 1 may be made of a wear-resistant elastic polymer material, for example rubber, or of a wear-resistant solid material having low adhesive properties, such as glass, porcelain, fluoroplastic or other material with similar properties.

Endings 4 for connection with adjacent pipes or pipe fittings can be made of steel in the form of flanges, pipes, fittings or fittings.

The longitudinal rods 6 can be made, for example, of reinforcing steel, and connected to the ends 4 in reinforcing frames using welded joints forming a reliable and durable power frame of both the intermediate layer 2 and the multilayer pipe as a whole.

A method of manufacturing a multilayer pipe (Fig. 1, 2) includes forming, using a mandrel (not shown in the drawings), an inner protective layer 1 made of wear-resistant material, an intermediate layer 2 and an outer protective layer 3 made of composite material, and also fastening the ends 4 for connection to adjacent pipes or pipe fittings.

When forming the inner protective layer 1, separate parts of flexible strands 5 are attached to it, and then an intermediate layer 2 of reinforced polymer concrete is formed, for which longitudinal rods 6 are laid on the formed inner protective layer 1, which are rigidly fastened with the tips 4 in reinforcing frames, free parts flexible harnesses 5 are fastened to the longitudinal rods 6 of the reinforcing frames, and the gaps between the longitudinal rods 6 of the reinforcing frames are filled with polymer concrete, and then the outer protective layer 3 is formed.

The mentioned parts of the flexible bundles 5 are mounted on the inner protective layer 1 by winding or strapping in the case when both elastic polymer material, i.e. rubber, and solid material, for example glass, porcelain, fluoroplastic, or other material with similar properties are used as wear-resistant material.

In the case when an elastic polymer material, i.e. rubber, is used as a wear-resistant material, in this case these parts of the flexible strands 5 are inserted into the crude rubber and fixed in the inner protective layer 1 by vulcanized rubber after subsequent heat treatment of the latter.

After the formation of the outer layer 3, the billet of the multilayer pipe, together with the mandrel or without it, is subjected to aging under natural conditions or in a thermal unit, in which the binder of the outer protective layer 3 is cured, the polymer concrete of the intermediate layer 2 is cured while the rubber is vulcanized, when it is used as a wear-resistant material of the inner protective layer 1.

An improved multilayer pipe and an improved method for its manufacture through the use of flexible bundles fastening the inner protective layer and the intermediate layer to each other, forming a reinforcing frame from longitudinal rods with endings, and the use of an inexpensive material — polymer concrete during the formation of the intermediate layer — increase the bond strength of the inner protective layer with an intermediate layer, improving reliability and also simplifying the design of the pipe and the process its manufacture, which is the technical problem to which these inventions are directed.

This can significantly reduce the complexity and cost of manufacturing a multilayer pipe while ensuring its high strength, which is the technical result that is achieved when using this group invented.

The invention is not limited to the embodiments described and shown in the drawings, but can be changed, modified and supplemented within the scope defined by the claims.

The proposed inventions are industrially applicable, as they can be implemented in industrial production using standard equipment, modern materials and technology at any polymer engineering enterprise.

They can be widely used in various industries for the production of rigid composite reinforced pipes made of several materials and designed to transport liquid products under high pressure or vacuum.

Notation list

1. The inner protective layer

2. The intermediate layer

3. The outer protective layer

4. Ending

5. Flexible harness

6. The longitudinal shaft

Claims (2)

1. A multilayer pipe containing interconnected inner protective layer made of wear-resistant material, an intermediate layer and an outer protective layer made of composite material, as well as endings for connection with adjacent pipes or pipe fittings, characterized in that the inner protective layer and the intermediate layer is fastened together by flexible braids, while the intermediate layer is made of polymer concrete reinforced with longitudinal rods, rigidly bonded with the tips in the reinforcement general frameworks. 2. A method of manufacturing a multilayer pipe, comprising forming, using a mandrel, an inner protective layer made of wear-resistant material, an intermediate layer and an outer protective layer made of composite material, as well as fastening the endings for connection with adjacent pipes or pipe fittings, characterized in that when forming the inner protective layer, separate parts of flexible bundles are attached to it, and then an intermediate layer of reinforced polymer concrete is formed, for which The inner protective layer is laid with longitudinal rods, which are rigidly fastened to the reinforcing frames with the tips, the free parts of the flexible harnesses are fastened with the longitudinal rods of the reinforcing frames, and the gaps between the longitudinal rods of the reinforcing frames are filled with polymer concrete, after which the outer protective layer is formed.

Images