RU161658U1 - PIPELINE BANDAGE HEATED INSULATED - Google Patents

Abstract

1. The pipe brace is insulated, installed on the pipe in the place of installation of the pipe support, characterized in that it consists of two half shells, the inner surface of which the bandage covers the pipeline, and completely covering the shell half shells, which has two parts, each half shell consisting of a base made in the form of a half-shell, fixed to the base along the inner diameter of at least three frames located transversely to the axis of the pipeline, and at least two longitudinal ribs located longitudinally to the axis of the pipeline, while the interconnection of the base, frames and longitudinal ribs of each half-shell forms at least four cells in which the insulation segments are laid, the joints and mating surfaces of which are covered with adhesive materials, and the half-shells and parts of the casing are provided with eyes through which they are interconnected in pairs. 2. The bandage according to claim 1, characterized in that the thickness of the segment of the insulation of the bandage is not less than the thickness of the layer of thermal insulation of the pipeline. 3. The bandage according to claim 1, characterized in that the half shells and parts of the casing are connected through holes in the eyes using bolted connections. 4. The bandage according to claim 1, characterized in that a protective gasket is made between the bandage and the pipeline, made of rock sheet and secured to the pipeline with tie rods and brackets, and the dimensions of the protective gasket are interconnected with the values of the diameter of the pipeline and the structural length of the bandage. 5. The bandage according to claim 1, characterized in that on the outer part of the bandage

Description

The claimed utility model relates to the field of construction of underground and elevated pipelines and can be used for laying and reconstruction of pipelines in difficult geological conditions, for example, in permafrost, including in the presence of a slope of the terrain.

The prior art protective shell [copyright certificate for the invention SU 1149099 A1, publ. 04/07/1985, IPC: F16L 59/12, F16L 59/10], made primarily of aluminum for thermal insulation of pipes, having a protective cylindrical shell made of pipe halves with longitudinal sides bent outward at an angle of 90 ° with rectangular holes on one side and the bending petals entering them on the other hand. In order to increase reliability and reduce installation time, the width of the side is seven to eleven thicknesses of the sheath sheet, and the height of each bent blade is four thicknesses of the sheath sheet, and the holes in the sides are made in the center of their field.

The disadvantages of the known invention include the low strength characteristic of the base metal of the insulation casing - aluminum. With significant mechanical loads on the pipeline for sections of the underground installation, damage to the protective casing is possible and, as a result, damage to the thermal insulation layer and the anticorrosive coating of the pipeline.

The closest analogue of the claimed utility model is a prefabricated insulating structure [patent for invention RU 2229654 C2, publ. 05/27/2004, IPC: F16L 59/10], which is made in the form of sections covering the pipeline, forming a casing between themselves. Each section is made in the form of a box, consisting of an outer shell and an inner shell, which are interconnected by jumpers and locks. Locks are located on the outer shell. On the inner shell and the pipeline installed stops with the ability to control. Thermal insulation is placed between the outer shell and the inner shell. At the ends of the sections, protective screens are installed, which can be made perforated or in the form of a mesh.

A disadvantage of the known device is the complexity and complexity of installation, as well as the lack of the possibility of combining the multifaceted outer surface of the bandage with the lodgement cylindrical part of the pipe support.

The objective of the claimed utility model is to reduce the effects on the heat-insulating layer and the anticorrosive coating of the pipeline and its protection in the places of installation of the support elements of the support (lodges and half clamps) when moving the pipeline due to temperature deformations during operation.

The technical result of the claimed utility model is to unload the heat-insulating layer of the pipeline under the support of the loads arising from the operation of the pipeline.

The problem is solved, and the technical result is achieved due to the fact that the pipe brace is thermally insulated, installed on the pipe at the installation site of the pipe support consists of two half shells, the inner surface of which the bandage covers the pipeline, and a fully enclosing half shell shell with two parts, each half shell consists of a base made in the form of a half shell fixed to the base along the inner diameter of at least three frames located across inferior to the axis of the pipeline, and at least two longitudinal ribs located longitudinally to the axis of the pipeline, while the interconnection of the base, frames and longitudinal ribs of each half-shell forms at least four cells in which heat insulation segments are laid, the joints and mating surfaces of which are coated with adhesive materials, and half-shells and parts of the casing are equipped with eyes through which they are interconnected in pairs.

Additionally, the thickness of the segment of insulation of the bandage has a value not less than the thickness of the layer of insulation of the pipeline.

In addition, half shells and parts of the casing are connected through holes in the eyes with bolted connections.

Additionally, between the bandage and the pipeline, a protective gasket is made of rock sheet and secured to the pipeline with tie rods and brackets, and the dimensions of the protective gasket are interconnected with the values of the diameter of the pipeline and the structural length of the band.

In addition, sling loops are installed on the outside of the brace.

The joints and mating surfaces of the insulation segments are coated with adhesive materials to ensure uniformity of insulation and fixing the segments in the half-shell cells.

The invention is illustrated by the following drawings:

In FIG. 1 presents a view of the claimed design of the brace of the pipe insulated.

In FIG. 2 presents a view of a suspended thermally insulated pipe support on a two-pile foundation with the claimed bandage design.

The positions in the drawings indicate:

1 - half shell;

2 - frame;

3 - longitudinal rib;

4 - base;

5 - a casing;

6 - segments of thermal insulation;

7 - protective cushioning material;

8 - bolted connection;

9 - thermal insulation of the pipeline;

10 - waterproofing shell of thermal insulation of the pipeline;

11 - lodgement;

12 - heat insulated bandage;

13 - half clamp;

14 - chain suspension;

15 - grillage;

16 - sling loops;

17 - supporting clutch.

The claimed utility model provides a reduction in the effects on the anticorrosion coating of the pipeline and their protection in the places of installation of the support elements of the support (lodgements and half clamps) when moving the pipeline due to temperature deformations during operation. The reduction of contact stresses on the pipeline (protective layer of the pipeline) from the loads perceived by the support is achieved by increasing the contact area of the bandage with the outer surface of the pipeline.

With underground pipeline laying, a case with pinching of the pipeline support in the ground is possible. Due to the rigid fixing of the pipeline and the bandage, the pipeline has the possibility of longitudinal (axial) movement in a pinched tool tray in a predetermined design range.

The heat-insulated pipe bandage (Fig. 1) consists of two half shells 1: the upper and lower. Each half shell 1 consists of a base 4 in the form of a half shell, at least three frames 2, two longitudinal ribs 3 and two eyes. To ensure a rigid connection with the pipeline in a horizontal plane, a technological gap is made along the interface line of the two half shells 1. The interconnection of the base 4 with the frames 2 and the longitudinal ribs 3 of the half-shell forms at least four cells in which the heat insulation segments are laid 6. The thickness of the heat insulation segment of the bandage 6 is not less than the thickness of the thermal insulation layer of the pipeline 9. To ensure uniformity of thermal insulation and fixing segments 6 to in the cells of the half-shell 1, all joints and mating surfaces of the segments are covered with mastic (adhesive). A protective cushioning material 7, a rock sheet, is mounted on the pipeline, which is fastened with tie rods and brackets in at least three places along the outer diameter of the pipeline. The lower and upper half shells 1 are mounted and tightened onto the secured protective material, using bolted joints 8. The passage points of the bolted joints 8 are additionally insulated with heat insulation segments 6 having recesses whose size corresponds to the size of the bolted joints and are sealed with adhesive material. On the upper and lower half-shells, a casing 5 is installed, consisting of two parts connected by a bolt connection through the eyes. To ensure loading and unloading during the manufacture and installation of the bandage 12, there are sling loops 16 located on the outer part of the bandage 12.

Depending on the operating conditions, a protective anticorrosive coating is applied to the brace assembly units. When operating the pipeline in aggressive, corrosive environments, the metal parts of the brace can be made of corrosion-resistant steels, while the corrosion tolerance for the estimated period of operation when determining the thicknesses of parts of structural elements can be reduced. Material design, coating of parts and brace elements are selected in accordance with the climatic zone of operation of the suspension supports.

For a detailed consideration of the design of the utility model, an example of the construction of the pipe brace for the suspension support of the pipeline on a two-pile foundation shown in FIG. 2.

When carrying out work on laying an underground pipeline, support structures are arranged taking into account the quality of the soil, its slope, etc.

In place for the installation of support on the pipeline, protective gasket material 7 (rock sheet) is laid and fixed with tie straps. The dimensions of the protective strip 7 are selected depending on the diameter of the pipeline and the structural length of the bandage. The installation of the bandage 12 is made on the pipeline with a protective gasket. Orientation of the half-shell bandage - the surface of the connector bandage is located horizontally. The lower and upper half-shells of the bandage are pulled together by a bolt connection, the connection to the pipeline is rigid, the tightening torque is regulated in the technical documentation. Also, with the help of bolted connections, the installation of protective bandages is carried out. Next, on the bandage mounted on the pipeline, the lodgement 11 and the support half-clamp 13 are sequentially mounted. The pipeline bottom part is supported through the bandage 12 on the cradle of the support 11, the upper part is limited to a half-clamp 13 with a technological gap. When installing the aerial part of the support, compensation sleeves are installed in the hole of the adjusting screw, into the holes of which the chain suspensions are installed with the fingers 14. The screws with chain suspensions are inserted into the holes of the base plates of the grill 15, the installation of support and spherical washers, nuts. With the help of lifting mechanisms, the grillage is installed on the supporting parts of the supporting couplings 17, mounted on a pile foundation. Compensation sleeves are installed in the eyes of the tool tray 11 (mounted on the pipeline), then, with the help of fingers, flexible chain suspensions 14 are fixed through the holes of the compensation sleeves. The swivel joint of the flexible suspension with the eye of the lodgement of the support allows you to mount the support under the pipeline with a slope of up to 30 °. By successive tightening of the nuts, the chain hangers 14 are smoothly tensioned, the bearings are aligned to the design position, followed by locking the tensioning nuts. At the end of the installation, excavation work is carried out with filling the soil.

Regular changes in the temperature of the transported working medium, vibrations, changes in pressure inside the pipeline — all this causes constant, often significant (up to 100-200 mm) displacements of the pipeline, if it is incompletely crushed by the ground, which are perceived by the support, or rather, its moving part, in As a result, the movable part, together with the rigidly fixed pipeline in it, is displaced. The lodgement moves in the soil, connected on chain suspensions. The bandage in the structure performs a protective function, and also distributes the contact load from the support cradle on the surface of the bandage. In cases of crushing of the underground part of the support in the ground (support lodgement), the pipeline in the bandage can longitudinally move along the inner surface of the lodgement, thereby the possible longitudinal movement of the bandage in the lodgement will not damage the pipeline.

The result is the unloading of the heat-insulating layer of the pipeline under support from the loads arising from the operation of the pipeline, the transfer of loads to the support through frames and longitudinal stiffeners.

Claims (5)

1. The pipe brace is insulated, installed on the pipe in the place of installation of the pipe support, characterized in that it consists of two half shells, the inner surface of which the bandage covers the pipeline, and completely covering the shell half shells, which has two parts, each half shell consisting of a base made in the form of a half-shell, fixed to the base along the inner diameter of at least three frames located transversely to the axis of the pipeline, and at least two longitudinal ribs located longitudinally to the axis of the pipeline, while the interconnection of the base, frames and longitudinal ribs of each half-shell forms at least four cells in which the insulation segments are laid, the joints and mating surfaces of which are covered with adhesive materials, and the half-shells and parts of the casing are provided with eyes through which they are interconnected in pairs. 2. The bandage according to claim 1, characterized in that the thickness of the segment of insulation of the bandage is not less than the thickness of the layer of thermal insulation of the pipeline. 3. The bandage according to claim 1, characterized in that the half shells and parts of the casing are connected through holes in the eyes using bolted connections. 4. The bandage according to claim 1, characterized in that a protective gasket is made between the bandage and the pipeline, made of rock sheet and secured to the pipeline with tie straps and brackets, and the dimensions of the protective gasket are interconnected with the values of the diameter of the pipeline and the structural length of the bandage. 5. The bandage according to claim 1, characterized in that the hinges are installed on the outer part of the bandage.

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