RU2317467C1 - Multiple-unit pipe - Google Patents

Abstract

FIELD: pipeline engineering.

SUBSTANCE: pipe comprises conducting pipe, shell made of a polymeric material; and bearing-guiding means. The shell has bearing and guiding means defined by the group of hollow bearings projecting in the radial direction until it abuts against the outer side of the conducting pipe. According to the second version, the combined pipe has heat insulating and weighting coating.

EFFECT: enhanced reliability.

24 cl, 12 dwg

Description

The invention relates to pipeline technology, namely to pipes with a ballast coating, used when laying pipelines along the bottom of reservoirs.

Known pipe with a ballast coating, consisting of a Central steel pipe with an anti-corrosion coating, a support device consisting of rings with concrete bearings, distributed and fixed to the Central pipe by reinforcing wire, passed through holes and grooves made in concrete bearings, a metal cylindrical shell supported on the upper surfaces of concrete supports, an annular space formed between the outer surface of the central pipe and the inner surface of the metal shell, in which concrete is introduced and hardened between concrete supports with the formation of a reinforced ballast coating [1].

The disadvantages of the known pipe is as follows. The metal shell has a longitudinal connector, is thin and removable, and the open surface of the ballast coating in the pipe laid on the bottom of the reservoir is destroyed. Repairing and replacing ballast-coated pipelines is expensive. Entering a steel pipe with centering rings including concrete supports into a polyethylene pipe-sheath will cause damage to the inner surface of the pipe due to the abrasive action of concrete, which can lead to damage or destruction of the polyethylene pipe.

Known heat-insulated pipe coated with concrete as a weighting and waterproofing material, in which the heat-insulating layer is separated from the concrete layer by a polyethylene pipe, and the concrete is placed in a polyethylene pipe and obtained after injection of cement-sand mortar into the annular space between the pipes, in which the supporting guide device [2].

Known metal-plastic pipe, which contains a steel pipe placed in it coaxially with the annular gap of the polyethylene pipe. The alignment of the pipes is provided by centralizers located in the annular gap. The annular gap is filled with a solid cement mass [3].

The first disadvantage of the pipe is that it is not intended for permanent connections when laying the pipeline. Another disadvantage is the need for a corrosion-resistant coating of a steel pipe if it is not made of corrosion-resistant steel or other material that is not subject to corrosion. The structural need to tighten the ends of the inner polyethylene pipe to the ends of the metal pipe does not allow to establish an annular gap between the pipes, so that after filling with the cement-sand mixture the pipe acquires negative buoyancy and is suitable for laying the pipeline along the bottom of the reservoir.

Known combined pipe [4], with centralizers in the annular space, made in the form of an open ring, mounted on a conductive pipe, having three protrusions in contact with the inner surface of the shell. The disadvantage of this pipe is that when the annular space is filled with weighting material, the polymer shell is deformed by the weight of the weighting material due to the small area of the supporting surface of the three supporting projections.

Known combined pipe [5], having in the annular space support and guide device, consisting of supports mounted on a tape and located on the outer surface of the Central pipe along a helical line. The advantages of such a pipe are that a support-guide device placed on a conductive pipe along a helix provides greater resistance to bending of the pipe than a support-guide device in the form of ring centralizers distributed and mounted on a conductive pipe with supports distributed around the ring. The disadvantage of this combined pipe is that the supports mounted on the tape weakly keep the sheath from shifting relative to the surface of the supports when an axial shear force appears.

A known pipe adopted for the prototype described in the invention for the method [6], consisting of a central steel pipe, a sheath pipe made of polyethylene, mounted coaxially to the central pipe, annular annular space, support-guide centering rings located and mounted on the Central steel pipe with a corrosion-resistant coating, comprising at least one tape covering the pipe with tension, with centering bearings distributed and fixed on it, having on the outer surface in contact the inner surface of the shell, inlet chamfers, and cement-sand mixture with heavier additional components solidified after filling and shutter speed.

The first disadvantage of the pipe is that when the central pipe with centering rings is inserted into the polyethylene pipe, which, as a rule, has deviations from cylindricity, significant pressure arises on the surfaces of the polyethylene centering supports in contact with the inner surface of the polyethylene pipe, and, accordingly, significant friction force, which creates, in the absence of lubrication, a tilting moment on the supports, worsening the conditions of movement and sometimes causing local buckling of the shell and even its rupture.

The second drawback is rectangular supports, which create significant hydraulic resistance to the movement of a viscous weighting cement-sand or concrete mixture, and, as a result, a significant pressure drop of the mixture in front of and behind the supports, and the occurrence of a tipping moment on the supports, which can cause them to tip over with a possible break of fasteners tapes.

The third disadvantage of this pipe is that the supports mounted on the tape weakly keep the shell from shifting relative to the surface of the supports when an axial shear force appears, for example, when lowering the pipe from the pipe-laying vessel to the bottom of the reservoir.

Three of these drawbacks reduce the quality of the combination pipe.

The technical task of the invention is to create a construction of a combined pipe that provides high resistance of the supports to the tipping moment and a shear axial force acting on the shell, for example, when lowering the pipe from the pipe-laying vessel to the bottom of the reservoir.

The problem is solved in the design options for a combined pipe consisting of a conductive pipe, a sheath having support-guiding means formed by groups of hollow supports, preferably axially streamlined shapes that protrude into the annular space in the radial direction until they contact the outer surface of the conductive pipe.

To reduce the mass of the shell and simplify the technology of its manufacture, the supports are hollow. To reduce hydraulic resistance to the flow of the material filling the annular space, the hollow supports have a streamlined shape in cross section with a plane parallel to the pipe axis.

To give the combined pipe the required resistance to bending, the supports form groups having a given spatial arrangement: groups of supports are located in sections perpendicular to the pipe axis along a helical line with a given interval, with the ratio of the helix pitch to the inner diameter of the sheath selected from 1 to 2 ; groups of supports are located in sections at an angle to the axis of the pipe, while at some distance from the end of the pipe there is an additional group of supports in an amount of three or more, located in a plane perpendicular to the axis of the pipe.

The shell may be composed of several sections, the adjacent ends of which are hermetically connected, from alternating hermetically interconnected polyethylene smooth pipes and sections with groups of supports located in planes perpendicular to the axis of the pipe.

The combined pipe may include a steel conductive pipe having an anti-corrosion coating on the outer surface, or a conductive pipe made of a polymeric material, for example, polyethylene.

The material filling the annular space may be heat insulating or weighting if the pipe has one annular space.

If the combined pipe has both thermally insulating and weighting coatings, then in this embodiment it consists of a conductive pipe,

the first shell with an inner diameter greater than the outer diameter of the conductive pipe, and its smaller length, installed coaxially with the conductive pipe with the formation of the first annular space,

first support-guiding means for guiding during the assembly and centering of the first shell relative to the conductive pipe having supports located in the annular space,

thermal insulation material filling the first annular space,

a second shell with an inner diameter greater than the outer diameter of the first shell mounted concentrically to the first shell to form a second annular space,

second supporting-guiding means with groups of bearings for guiding during assembly and centering of the second shell relative to the first shell located in the second annular space,

ballast filler filling the second annular space, wherein the first shell is a continuous pipe, and the second shell has support-guiding means formed therein, formed by groups of hollow supports, preferably axially streamlined, with a wall thickness approximately equal to the thickness of the shell protruding in annular space in the radial direction.

In various embodiments, the groups of supports of the second shell directed to the second annular space can be located in planes perpendicular to the axis of the pipe, while the second shell is a composite of several sections, the adjacent ends of which are hermetically connected; each section has at least one support group; between sections with support groups there are smooth pipes hermetically connected to sections having support groups; the supports forming the group can be arranged along a helical line with a predetermined step, while at some distance from the pipe end there is an additional group of supports in an amount of three or more, located in a plane perpendicular to the axis of the pipe.

It is possible that at some distance from the pipe end there is an additional group of supports in the amount of three or more, located in a plane perpendicular to the pipe axis, and the groups of supports are located in planes at an angle to the plane perpendicular to the pipe axis, not exceeding 45 ° in absolute size.

The novelty of the combined pipe is that the shell has groups of supports directed to the axis of the pipe with ends contacting the outer surface of the conductive pipe, which form support-guiding means.

The new design of the shell, made together with the supports, allows the supports to effectively resist the action of the tipping moment during assembly, when filling the annular space with weighting material, and also to create resistance to shear of the shell relative to the ballast coating under the action of shear forces, for example, when lowering the pipe to the bottom of the reservoir with pipe-laying vessel.

These new distinctive features were not found in the study of the level of this technical field.

Figure 1 shows a combined pipe, the polymer shell of which consists of sections, each of which has a group of supports; figure 2 is a section aa in figure 1; figure 3 is a cross-section bb of the combined pipe of figure 2, the polymer shell of which consists of alternating sections with a group of supports and smooth pipes; figure 4 is a section CC of the support of figure 3; figure 5 - combined pipe, consisting of sections having supports, and smooth pipes; Fig.6 is a combined pipe, the polymer shell of which has a group of supports located at an angle to a plane perpendicular to the axis of the pipe; Fig.7 is a section D-D of the combined pipe of Fig.6; on Fig - combined pipe, the polymer shell of which has a group of supports located at opposite angles to a plane perpendicular to the axis of the pipe; Fig.9 is a combined pipe, the polymer shell of which has a group of supports located along a helical line; figure 10 is a cross-section EE of the combined pipe in figure 9; figure 11 is a longitudinal section of a combined pipe with thermally insulating and ballast coating; in Fig.12 is a cross-section EE of the combined pipe shown in Fig.11.

The combined pipe (FIGS. 1-12) consists of a conductive pipe 1, a sheath 2 of polymer material concentric with respect to the conductive pipe 1 and shorter in length, an annular space 3 formed between the outer surface 4 of the conductive pipe 1 and the inner surface 5 of the sheath, support-guiding means 6 for guiding during assembly and centering of the sheath 2 relative to the conductive pipe 1 located in the annular space 3, including supports 7, forming groups 8, having a given spatial arrangement, rial 9, filling the annular space 3, while the shell 2 has support-guiding means 6, formed by groups 8 of hollow supports 7, preferably axially streamlined in the form (figure 4), protruding into the annular space 3 in the radial direction to contact with the outer surface 4 of the conductive pipe 1.

In various embodiments of the shell, it is possible to arrange groups of hollow supports perpendicular to the axis of the shell (Figs. 1, 3, 5, 11), at an angle to a plane perpendicular to the axis of the shell (Fig. 6, 8), along a helix (Fig. 9).

In addition, the shell may be composite of several sections 11, the adjacent ends 12 of which are connected tightly (Figs. 1, 5).

Each section can have one group of supports (Fig. 1), between sections 11 with groups of 8 supports there are smooth pipes 13, hermetically connected to sections 11 having groups of supports 8.

In the embodiment of the shell (Fig. 9), the supports forming a group are located along a helical line 14 with a given step. This design has an important advantage: in the pipe sections within the group of supports located along a helical line, there is only one support, which significantly increases the strength of the pipe when it is bent.

The ratio of the pitch of the helix to the inner diameter of the shell is selected from values from 0.5 to 2.

At some distance from the end of the pipe there is an additional group of 15 supports 7 in the amount of three or more, located in a plane perpendicular to the axis of the pipe, necessary to guide the conductive pipe when it is assembled with the shell.

When the group of supports is located in planes at an angle to the plane perpendicular to the pipe axis, not exceeding 45 ° in absolute value, two supports fall into the cross section of the pipe, which increases the strength of the pipe when it is bent.

The conductive pipe 1 may be steel, having an anti-corrosion coating 16 on the outer surface, of a polymeric material, of a composite material.

The material filling the annular space may be heat insulating or weighting.

Combinations are possible: the conductive pipe is steel, has an anticorrosive coating on the outer surface, and the material filling the annular space is weighting or the conductive pipe is made of polymeric material, and the material filling the annular space is weighting or heat insulating.

If it is necessary to use both heat-insulating and weighting materials, the combined pipe consists of a conductive pipe (11, 12), a first shell 17 with an inner diameter greater than the outer diameter of the conductive pipe, and its shorter length, installed coaxially with the conductive pipe 1 s the formation of the first annular space 18, the first support-guiding means 19 for guiding during assembly and centering of the first shell 17 relative to the conductive pipe 1, having supports 20 located in the annular space 18; a heat-insulating material 21 filling the first annular space 18; a second shell 22 with an inner diameter greater than the outer diameter of the first shell 17 mounted concentrically to the first shell 17 to form a second annular space 23; second support-guiding means 24 with groups of supports 25 for guiding during assembly and centering of the second shell 22 relative to the first shell 17 located in the second annular space; ballast filler 26 filling the second annular space 23; wherein the first shell is a continuous pipe, and the second shell has support-guiding means made therein, formed by groups of hollow supports, preferably streamlined in the axial direction of the mold, with a wall thickness approximately equal to the thickness of the shell, protruding into the annular space in the radial direction.

In the second shell, groups of hollow supports can be located in planes perpendicular to the axis of the pipe, at an angle to a plane perpendicular to the axis of the pipe, not exceeding 45 °, at opposite angles or along a helix with a given step, while at a certain distance from the pipe end an additional group of supports in an amount of three or more, located in a plane perpendicular to the axis of the pipe.

The second shell may be composed of several sections, the adjacent ends of which are hermetically connected; each section has at least one support group; between the sections with groups of supports, smooth pipes can be located which are hermetically connected to sections having groups of supports.

When assembling a shell having internal supports with a central pipe, such supports have a significant moment of resistance to tipping moment arising both when the conductive pipe is pushed into the shell and when the annular space is filled with weighting material (cement-sand mortar, concrete).

When lowering the pipe to the bottom of the pond from the pipe-laying vessel, the supports prevent the sheath pipe from shifting relative to the weighting material filling the annular space in its solid state.

Information sources

1. US patent No. 3267969 from 08/17/1964.

2. Patent RU No. 2246658 of March 19, 2004.

3. Patent RU No.2138723 from 03/12/1997.

4. EP patent No. 0046617 B1 from 08/14/1981.

5. Patent EP No. 0036032 A3 of 06/12/1980.

6. Patent RU No. 2257503 dated 10.22.2003.

Claims (23)

1. Combined pipe, consisting of a conductive pipe, a shell of polymer material, concentric with respect to the conductive pipe and shorter in length, an annular space formed between the outer surface of the conductive pipe and the inner surface of the shell, support-guiding means for guiding during assembly and centering of the shell relative to the conductive pipe located in the annular space, including supports, forming groups having a given spatial location, material, filling an annular space, characterized in that the shell has support-guiding means formed by groups of hollow supports, preferably axially streamlined shapes, protruding into the annular space in the radial direction until it contacts the outer surface of the conductive pipe. 2. The combined pipe according to claim 1, characterized in that the groups of hollow supports are located in planes perpendicular to the axis of the pipe. 3. The combined pipe according to claim 1, characterized in that the shell is a composite of several sections, the adjacent ends of which are hermetically connected. 4. The combined pipe according to claim 3, characterized in that each section has at least one group of supports. 5. The combined pipe according to claim 4, characterized in that between the sections with groups of supports there are smooth pipes hermetically connected to sections having groups of supports. 6. The combined pipe according to claim 1, characterized in that the supports forming the group are arranged along a helical line with a predetermined pitch. 7. The combined pipe according to claim 5, characterized in that the ratio of the pitch of the helix to the inner diameter of the shell is selected from values from 0.5 to 2. 8. The combined pipe according to claim 6, characterized in that at some distance from the end of the pipe there is an additional group of supports in an amount of three or more, located in a plane perpendicular to the axis of the pipe. 9. The combined pipe according to claim 1, characterized in that the groups of supports are located in planes at an angle to a plane perpendicular to the axis of the pipe, not exceeding 45 ° in absolute value. 10. The combined pipe according to claim 9, characterized in that at some distance from the pipe end there is an additional group of at least three supports located in a plane perpendicular to the pipe axis. 11. The combined pipe according to any one of claims 1 to 10, characterized in that the conductive pipe is steel and has an anti-corrosion coating on the outer surface. 12. The combined pipe according to any one of claims 1 to 10, characterized in that the conductive pipe is made of a polymeric material. 13. The combined pipe according to any one of claims 1 to 10, characterized in that the material filling the annular space is heat insulating. 14. The combined pipe according to any one of claims 1 to 10, characterized in that the material filling the annular space is weighting. 15. The combined pipe according to any one of claims 1 to 10, characterized in that the conductive pipe is steel, has a corrosion-resistant coating on the outer surface, and the material filling the annular space is heavier. 16. The combined pipe according to any one of claims 1 to 10, characterized in that the conductive pipe is made of a polymeric material, and the material filling the annular space is heavier. 17. Combined pipe, consisting of a conductive pipe, the first shell with an inner diameter greater than the outer diameter of the conductive pipe, and its smaller length, installed coaxially with the conductive pipe with the formation of the first annular space, first support-guiding means for guiding during the assembly and centering of the first shell relative to the conductive pipe having supports located in the annular space, thermal insulation material filling the first annular space, a second shell with an inner diameter greater than the outer diameter of the first shell mounted concentrically to the first shell to form a second annular space, second supporting-guiding means with groups of bearings for guiding during assembly and centering of the second shell relative to the first shell located in the second annular space, ballast filler filling the second annular space, characterized in that the first shell is a continuous pipe, and the second shell has support-guiding means made therein, formed by groups of hollow supports, preferably axially streamlined, with a wall thickness approximately equal to the thickness of the shell, protruding into the annular space in the radial direction. 18. The combined pipe according to claim 17, characterized in that in the second shell the groups of hollow supports are located in planes perpendicular to the axis of the pipe. 19. The combined pipe according to claim 17, wherein the second shell is a composite of several sections, the adjacent ends of which are hermetically connected. 20. The combined pipe according to claim 19, characterized in that each section has at least one group of supports. 21. The combined pipe according to claim 20, characterized in that between the sections with groups of supports there are smooth pipes hermetically connected to sections having groups of supports. 22. The combined pipe according to claim 17, characterized in that the supports forming the group are arranged along a helical line with a predetermined pitch, while at a certain distance from the pipe end there is an additional group of supports in an amount of three or more, located in a plane perpendicular to the axis pipes. 23. The combined pipe according to claim 17, characterized in that at a certain distance from the end of the pipe there is an additional group of supports in an amount of three or more, located in a plane perpendicular to the axis of the pipe, and the groups of supports are located in planes at an angle to a plane perpendicular to the axis pipes not exceeding 45 ° in absolute value.

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