RU196210U1 - REINFORCED PIPE - Google Patents

Abstract

The utility model relates to reinforced pipes designed for pumping liquid, gaseous and mixed media, as well as transmitting various kinds of signals and electricity, and can be used in difficult climatic conditions, such as the conditions of the Far North. The reinforced pipe contains a channel for transporting liquid, gaseous or mixed media, a first anti-wear layer, a reinforcing layer, a cable layer, a damping layer, an outer layer and connecting elements. Preferably, the damping layer is made of a material having a lower density and higher elasticity than the material of the outer layer. The reinforced pipe may further comprise a gas-tight layer located on the inner or outer surface of the channel. The reinforcing elements of the reinforcing layer may contain a protective coating. The technical result is a reduction in the influence of various factors on the structural integrity of the reinforced pipe, increasing its service life in difficult climatic conditions.

Description

The utility model relates to reinforced pipes, in particular, pipes that are designed both for pumping liquid, gaseous and mixed media, and for transmitting various kinds of signals and electricity, and can be used in difficult climatic conditions, such as the Far North.

Known embodiments of pipes for pumping liquid, gaseous and mixed media for use in difficult climatic conditions, which, in addition, provide the transmission of various signals and / or electricity. For convenience, in the framework of this application, this type of pipe will be called a cable pipe. One of the options for a cable pipe is a polymer reinforced pipe with electric heating according to the patent of the Russian Federation RU 2665776 (published 04.09.2018, IPC F16L 9/12), selected as the closest analogue of this utility model.

The known polymer reinforced pipe consists of an inner polymer layer forming the base of the pipe, on the outer surface of which a reinforcing layer, an intermediate polymer sheath are successively applied, twisted from insulated conductors and an external polymer sheath. Insulated conductors can be conductors in the form of twisted pairs, optical modules or fillers and have an additional outer shell in the form of a ring sector, limited by the inner and outer radius of the conductors. The reinforcing layer is made of coils of metal or polymer tapes, polymer threads or metal wires. A heat-insulating layer can be applied between a coil of insulated conductors and the outer polymer sheath, and a twist of a metal tape under the outer polymer sheath. According to the inventors, the pipe is characterized by increased thermal insulation and an integrated electric heating system, which allows to reduce heat loss to the environment and to prevent freezing of the fluid transported through the pipe at low temperatures, as well as to reduce installation time and maintenance costs, to increase the service life of the pipeline.

Despite this, the drawback of the closest analogue is the poor protection of the pipe from external and internal physical (mechanical) and chemical influences, which can lead to degradation and even destruction of the functional layers of the pipe, in particular its reinforcing layer, and as a result, the inner polymer layer, determining the fluid pumping channel.

The objective of this utility model is to develop a cable pipe designed for use in difficult climatic conditions, in particular, in the Far North, which is characterized by increased resistance to various physicochemical factors that occur during operation of the cable pipe, and therefore, increased service life such a pipe.

The technical result is to reduce the influence of various external factors on the integrity of the cable-pipe structure, as a result - increase its service life in difficult climatic conditions.

The problem is solved, and the claimed technical result is achieved in a cable pipe containing a channel for transporting liquid, gaseous or mixed media, a first anti-wear layer, a reinforcing (or supporting) layer, a cable layer, a damping layer, an outer layer and connecting elements.

For convenience, within the framework of this application, a channel for transporting liquid, gaseous, or mixed media (briefly, fluids) will hereinafter also be called a hydrochannel.

The presence of a damping layer protects the cable pipe from damage / fracture under external factors such as bends (for example, this can happen when unwinding from the drum), especially in cold weather, soil movement (for example, when laying in a trench), expansion and / or narrowing of adhering snow-ice crusts with temperature differences, and so on. The damping layer allows you to reliably protect the layers below it, especially the reinforcing layer, which to a large extent determines the strength and durability of the entire cable-pipe construction.

Preferably, if the damping layer is made of a material having a lower density and higher elasticity than the material of the outer layer, which can further increase the strength and durability of the entire structure of the cable pipe.

External physical and chemical effects on a cable pipe also include effects associated with the composition and parameters of the fluid pumped through the pipe — a liquid medium, a gaseous medium, or a mixed medium. In this case, any deformation around the perimeter of the cable-pipe, especially undesirable in the Far North, is prevented by the presence of a damping layer.

Since the fluid may have a chemical effect leading to degradation of the layers, in particular the reinforcing layer and / or the damping layer, it is preferable if the cable conduit also contains a gas-tight layer.

The gas-tight layer inhibits the penetration of aggressive or chemically active gases and liquids into the most critical layers of the cable pipe, thereby further increasing the integrity of the structure during operation and increasing the service life. Preferably, if the gas-tight layer is in contact with the hydrochannel, i.e. located either on the inner surface of the hydrochannel, or on the outer surface of the hydrochannel.

In addition, in order to increase the integrity of the cable-pipe structure during operation and increase its service life, the elements of the reinforcing layer may contain a protective coating.

It is also preferable to use one or more additional anti-wear layers, which, along with a damping layer, can further increase the strength and durability of the entire cable-pipe construction. In particular, the cable pipe may comprise a second anti-wear layer interposed between the reinforcing layer and the cable layer, and, as an additional measure, a third anti-wear layer interposed between the damping layer and the outer layer.

Further, some of the possible embodiments of the present utility model are described in more detail with reference to the figures in which:

in FIG. 1 shows a cross section of the claimed cable pipe according to a utility model;

in FIG. 2 shows a cross section of the claimed cable pipe with a gas-tight layer on the inner surface of the hydrochannel;

in FIG. 3 shows a cross section of the claimed cable pipe with a gas-tight layer on the outer surface of the hydrochannel.

According to a utility model, a cable pipe contains a hydrochannel (1) for transporting fluids (liquid, gaseous or mixed media), a first antiwear layer (2), a reinforcing layer (3), a cable layer (4), a damping layer (5), an outer layer (6) and connecting elements (not shown in the figures).

The fluid is pumped in the inner space (7) of the hydrochannel (1). The fluid can be hydrocarbons, water, chemicals, including aggressive ones, and so on. As in the closest analogue, the hydrochannel (1) can be made of a polymer material or any other material intended for pumping these fluids, including in difficult climatic conditions.

The anti-wear layer (2) serves to protect the supporting frame of the cable-pipe - the reinforcing layer (3) and can be made of a polymeric material, composite material, etc. in the form of a continuous layer or tapes.

The reinforcing layer (3) substantially determines the strength of the entire cable-pipe structure. It is made of a suitable material, for example, polymeric, with reinforcing elements (8) placed in it, made, for example, of metal. Additionally, in order to protect against exposure to active substances contained in the fluid, which can lead to degradation or destruction of reinforcing elements (8), the latter can be coated with a protective coating (not shown in the figures).

The cable layer (4) is designed to accommodate various types of signal transmission means, which is an integral function of the cable pipe. In particular, such means may include power cables (9), signal cables (10) (for example, twisted pairs), fiber optic cables (11), and other means known to those skilled in the art. The cable layer (4) can be one or more of these signal transmission means or a matrix (for example, polymer), continuous or segmented, in which these signal transmission means are placed.

The damping layer (5) is intended primarily to protect the entire cable-pipe structure from damage and / or fractures that occur, in particular, when bending in the cold, unwinding / winding the cable-pipe to the drum, soil movements (for example, when laying in the trench), expansion / contraction of adhering snow-ice crusts with temperature differences, effects of fluid pressure drops, and so on.

The outer layer (6) protects the cable pipe from direct external environmental influences on it. It is preferable if the material of the damping layer (5) has a lower density and higher elasticity than the material of the outer layer (6), which allows to increase the efficiency of the damping layer (5), which protects the underlying layers of the cable pipe from undesirable external influences, which can lead to damage and even destruction, especially when it comes to the reinforcing layer (3).

The connecting elements of the cable-pipe in the figures are not shown, since they are well known to the specialist, and their execution is not the subject of this utility model. So, the connecting elements can be fittings that provide docking / connection of hydrochannels (1) of measured segments of the cable-pipe system when laying it; couplings providing inside closure of the joint, protection against precipitation, connection of cores for various purposes - power cables (9), signal cables (10), fiber optic cables (11) - using special connectors, heating elements, control sensors if necessary; devices, adapters and special devices for docking to consumer equipment; fittings and tubes (pipes) for the removal of gases at the junction; and other.

To increase the protection of the declared cable pipe from external factors, in particular, when pumping active and aggressive fluids, a gas-tight layer (12) can be placed on the surface of the hydrochannel (1). The gas-tight layer (12) is placed either on the inner surface of the hydrochannel (1), as shown in FIG. 2, or on the outer surface of the hydrochannel (1), as shown in FIG. 3.

For example, in the case of pumping dry gases, non-aggressive media that do not have any noticeable effect on the reinforcing layer (3) and reinforcing elements (8), the use of a gas-tight layer (12) is not mandatory. You can do without it or apply the protective coating of the reinforcing elements mentioned above (8).

At low partial pressures of aggressive gases, which can lead to corrosion, in particular, of reinforcing elements (8), and possibly degradation of the damping layer (5), the gas-tight layer (12) is preferably applied to the internal (Fig. 2) or external ( Fig. 3) the surface of the hydrochannel (1). The choice of the surface of the hydrochannel (1) for applying a gas-tight layer (12) to it is determined not only by the resistance of the surface of the hydrochannel (1) to the fluid, but also by the resistance of the gas-tight layer (12) to both the fluid and the vapors and gases of the aggressive components of the fluid.

In the case of high concentrations and high partial pressures of aggressive media, preferably a gas-tight layer (12) and a protective coating of the reinforcing elements (8) are used. To reduce the concentration and pressure of gases in the annulus, a gas exhaust system (not shown in the figures) can be additionally used, consisting of a fitting located on the connecting element, a gas outlet pipe and relief valves. The gas exhaust system combines the inter-ring spaces of all segments of the cable-pipe with each other and / or with the atmosphere (annulus).

In addition, the cable-pipe can contain additional anti-wear layers, which, along with the damping layer (5) and, optionally, a gas-tight layer (12), help to increase the integrity of the cable-pipe structure during operation and increase its service life. In particular, for these purposes, between the reinforcing layer (3) and the cable layer (4) there may be a second anti-wear layer (not shown in the figures). In addition to it, between the damping layer (5) and the outer layer (6), one more additional, third anti-wear layer (not shown in the figures) can be placed. Like the first anti-wear layer (2), the additional second and third anti-wear layers can be made of polymeric material, composite material, etc. in the form of a continuous layer or tapes.

Polyolefins (thermoplastic elastomers, thermoplastic elastomers, etc.), compositions based on polyolefins and other known suitable materials, in particular, can be used as materials of these layers, including the outer layer, the damping layer, the gas-tight layer, and also the coating of the reinforcing elements. allowing to form the components of the claimed cable pipe by extrusion.

Various compatibilizers can also be used for better miscibility of the compositions, in particular for better phase adhesion, for example, in a reinforcing layer. In addition, various adhesives can be used for better adhesion of the layers, for example, when applying a protective (anti-corrosion) coating to reinforcing elements.

The cable pipe described above and its variants can be manufactured by any method known to a person skilled in the art, in particular, as described in RF patent RU 2665776, which discloses the closest analogue of the claimed utility model.

According to the utility model, the cable pipe can be used in difficult climatic conditions, in particular, in the Far North, providing increased resistance to various physical and chemical factors that arise during operation, reducing the influence of these factors on the integrity of the structure, and therefore, increased service life .

Claims (9)

1. Reinforced pipe containing a channel for transporting fluids, the first anti-wear layer, a reinforcing layer containing reinforcing elements, a cable layer, a damping layer, an outer layer, characterized in that the damping layer is made of a material having a lower density and higher elasticity, than the material of the outer layer. 2. The reinforced pipe according to claim 1, characterized in that it further comprises a gas-tight layer. 3. The reinforced pipe according to claim 2, characterized in that in which the gas-tight layer is located on the inner surface of the channel. 4. The reinforced pipe according to claim 2, characterized in that in which the gas-tight layer is located on the outer surface of the channel. 5. Reinforced pipe according to any one of paragraphs. 1-4, in which the reinforcing elements of the reinforcing layer contain a protective coating. 6. The reinforced pipe according to claim 1, wherein the at least one cable layer comprises at least one selected from a power cable, a signal cable, an optical fiber cable. 7. The reinforced pipe according to claim 1, characterized in that it further comprises a second anti-wear layer located between the reinforcing layer and the cable layer. 8. The reinforced pipe according to claim 1, characterized in that it further comprises a third anti-wear layer located between the damping layer and the outer layer.

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