RU40433U1 - THERMAL INSULATION CONSTRUCTION - Google Patents

Abstract

Thermal insulation design, made of collapsible, including removable shells fastened with bandages, characterized in that the removable shells are made in the form of segments of extruded polystyrene foam with a density of at least 33 kg / m ³ n compressive strength at 10% deformation of at least 0.25 MPa that can be machined to give the required shell shape, the segments are combined into a structure that forms a heat-insulating shell around the pipeline and consists of N sectors interconnected in a diametrical pressure The pressure in the lock, and bandages are designed as a tie fixed protracted device equipped with a stopper.

Description

The utility model "Thermal insulation design" is intended for construction and installation works during the construction of pipelines in any climatic zone. In particular, it can be used for thermal insulation of the outer surface of gas and oil pipelines of pipelines with a diameter from 57 to 1420 mm of underground and elevated laying. In addition, the collapsible heat-insulating structure can be used for thermal insulation of foundations, floors, walls, roofs, as well as for protecting soils of railways, roadways, pipelines from frost heaving of saturated soils.

The invention is known, “Pipe thermal insulation unit and a device for its installation”, application RU No. 2001131547, published 2003.06.20, IPC F 16 L 59/00, in which there is a sheath of insulation material, an outer sheath, fasteners made of wire or steel tape, which fix the sheets of the shell. However, this design has a complex design of the attachment points, it is bulky, takes up a lot of space, with its help it is impossible to mount the structure on already welded pipelines.

The invention is known, "Heating pipeline system", application RU, No. 98116465, published 2000.06.10, IPC F 16 L 9/12, E 03 B 7/04, which has a pipeline and a layer of thermal insulation. However, it cannot be mounted on already welded

pipelines, due to the fact that rings are sequentially put on the pipeline, installation of the pipeline is much more complicated, the insulation material is unstable and it is inconvenient to work with it.

The invention is known "Method of applying a thermal insulation coating to a pipe", patent RU No. 2136495, application No. 97118577, published 1999.09.10, IPC B 29 C 63/18, F 16 L 59/14 consisting in the fact that thermal insulation coating is applied from a foaming material - polyurethane foams on the outer surface of the pipes, an elastic shell is placed on top of the pipe. However, it cannot be mounted on welded pipelines, the method requires additional fixtures - forms, which complicates and increases the cost of thermal insulation, requires additional sealing work. All this significantly complicates and increases the cost of thermal insulation of the pipeline.

Closest to the proposed technical solution is the invention "Collapsible insulation for underground and above-ground channelless laying of pipelines", application RU, No.2000106633, published 2002.04.10, IPC F 16 L 59/00, containing thermal insulation, which is collapsible in in the form of removable shells, shells fastened with bandages. However, this design requires an additional cover, which complicates the installation, does not allow installation on a welded pipeline.

When installing pipelines in conditions of frosty heaving of moisture-saturated complex soils, the installation of the pipeline, as well as the installation of a railway track or road surface, does not allow thermal insulation of parts of the pipeline in stationary, factory conditions, or requires complex

additional work on sealing joints. In addition, it is inconvenient to transport already insulated parts to the installation site, since thermal insulation can be broken during transportation to the place. Collapsible heat insulation structures are required so that after installation, for example, of a pipeline, it is easy, quick and reliable to insulate a pipeline welded into a string. All methods of thermal insulation using polyurethane foams, in this case, suggested complex mold designs for foaming and stabilization of foamed polyurethanes on the pipeline.

The proposed technical solution using shells made of PENOPLEX allows eliminating the deformation of the pipe or roadway due to subsidence or ascent due to the formation of pulp around them due to the sufficient bearing capacity of the shells made of PENOPLEX, which provide reliable thermal insulation.

The achievable technical result of the utility model is a significant simplification of the installation of thermal insulation, the implementation of this installation on a pipe welded into a string, improvement of the technology for installing insulation both on the pipeline and under the roadbed, which, in turn, reduces the cost of installation, extends the diameter range of insulated pipelines, increases productivity .

The technical task is carried out as follows. The heat-insulating design, made collapsible, includes removable shells fastened with bandages. The proposed design is characterized in that the removable shells are made in the form of segments of extruded polystyrene foam with a density of at least 33 kg / m ³ and compressive strength at 10%

deformation of not less than 0.25 MPa, allowing machining to give the required shape of the shell, the segments are combined into a structure that forms a heat-insulating shell around the pipeline and consists of N sectors, diametrically joined together in a lock, and the bandages are made in the form of tightening bands, fixed with a protracted device equipped with a stopper. For example, the shells are made in the form of segments made of PENOPLEX. The segments are made with the length of the outer arc, selected on the basis of compliance with the conditions of compressive strength and thickness, providing reliable thermal insulation of the pipeline. For pipes of small diameter, instead of a segment, half cylinders are used. Segments of a given shape are made by curly cutting, for example, heated nichrome wire from plates. The density of the segments provides a homogeneous fine-meshed structure with water absorption in 24 hours of no more than 0.2% vol. and thermal conductivity at (25 + 5) ° C no more than 0.03 W / m C. Sectors in the structure can be distributed unevenly along the diameter of the pipeline, for example, segments in the lower part of the pipeline have an outer arc length two times less than segments in top of the pipeline. Based on the technological requirements that can be ensured by the alignment of the mounted pipes, the segments usually have a length of no more than 2500 mm. A lock connecting the segments to each other in the diametrical direction is formed by protrusions and grooves made in the radial direction and located at both ends of the segments, while the height of the protrusion, usually from strength conditions, is at least 1/4 of the thickness of the segment. If the insulation is carried out in a stationary position at the plant, then after the installation of the pipeline, a set of segments with a reduced length is used to insulate the pipe joints. Segments can be used when assembling a heat-insulating structure separately or can be combined with each other in a tape with flexible sections,

providing the connection of the segments in the lock after mounting the insulating structure on the pipeline. Tightening tapes can be made both steel and polymer.

Usually tightening tapes are distributed along the segment length in an amount of at least four tapes. The lingering device may be provided with a stopper in the form of a lever. For ease of assembly of the heat insulating structure, the lagging device is typically located at or above the axis of the pipe.

The drawings illustrate a collapsible heat insulating structure. Figure 1 is a longitudinal section. Figure 2 - cross section Figure 3 - a segment of the shell

The proposed collapsible heat-insulating structure works as follows.

There are two options for manufacturing the design: from individual polystyrene foam segments and fully assembled, when the segments are pre-connected to the tape with flexible sections.

In trust conditions, individual segments are mounted using either a mobile cassette or soft mounting towels.

In the case of installation using a mobile cartridge, prior to installing the pipes (1), the segments (2) of the heat-insulating structure are laid along the pipeline, the segments are laid on the lower half of the rings of the mobile cartridge, and then the segments are pushed inside the cartridge, filling the space around the pipeline, including the upper part then fill

the remaining space by segments, all segments are secured with coupling belts (3) and secured with coupling clamps (4).

In the case of using soft towels during installation, individual segments using soft mounting towels are pushed up the towel around the circumference of the pipe, secured with coupling belts (3), and secured with coupling clamps (4). Segments (2) tightly fit each other into the castle along the protrusions and depressions "a" - "b". The number of segments is selected based on the diameter of the pipe (1) and compliance with the strength condition of the segment in such a way that the calculated value of the outer arc length “C” ensures the segment strength is not less than the compressive strength at 10% deformation - 0.25 MPa.

In highway conditions, they can also use prefabricated heat-insulating structures that are pre-laid along the pipeline, installers lift the structure from two edges, lay it on the pipe, fit it tightly to the already insulated part, and then fasten the structure with tightening belts and close the clamps.

If heat-insulating segments are applied to the pipe in the factory, then at the edges of the pipe end sections of about 150 mm are left for welding. After the installation of the pipeline in a thread, the heat insulation of the welded joint is carried out in shortened segments according to the technology of route assembly using a mobile cassette or soft mounting towels.

Thus, a technical result is achieved - a significant simplification of the installation of thermal insulation, the implementation of this installation on a pipe welded into a thread.

Due to the fact that thermal insulation material is used, for example, PENOPLEX 45, which has sufficient strength and moisture absorption in 24 hours not exceeding% vol. more than 0.2, reliable protection against frost heaving of saturated soils is achieved. Since PENOPLEX is well subjected to mechanical processing, for example, by heated wire, it becomes possible to produce segments of complex insulating shells, which are required for the thermal insulation of not only pipes, but also railway tracks or other buried extended structures, as a result of which the scope of collapsible collapses significantly thermal insulation design.

Claims (15)

1. The heat-insulating structure is made of collapsible, including removable shells fastened with bandages, characterized in that the removable shells are made in the form of segments of extruded polystyrene foam with a density of at least 33 kg / m ³ and compressive strength at 10% deformation of at least 0.25 MPa, allowing machining to give the necessary shape of the shell, the segments are combined into a structure that forms a heat-insulating shell around the pipeline and consists of N sectors interconnected in a diametrical pressure The pressure in the lock, and bandages are designed as a tie fixed protracted device equipped with a stopper. 2. The heat-insulating structure according to claim 1, characterized in that the shells are made in the form of segments of PENOPLEX. 3. The heat-insulating structure according to claim 1, characterized in that the segments are made with the length of the outer arc, selected on the basis of compliance with the conditions of compressive strength, and a thickness that provides reliable thermal insulation of the pipeline. 4. The heat-insulating structure according to claim 1, characterized in that half-cylinders are used for pipes of small diameter. 5. The heat-insulating structure according to claim 1 or 4, characterized in that the segments of a given shape are made by curly cutting of heated nichrome wire from plates. 6. The heat-insulating structure according to claim 1, characterized in that the density of the segments provides a homogeneous fine-meshed structure with water absorption in 24 hours of not more than 0.2 vol.% And thermal conductivity at (25 ± 5) ° C not more than 0.03 W / m FROM. 7. The heat-insulating structure according to claim 1, characterized in that the sectors in the structure are distributed unevenly along the diameter of the pipeline, the segments in the lower part of the pipeline have an outer arc length two times less than the segments in the upper part of the pipeline. 8. The heat-insulating structure according to claim 1, or 4, or 7, characterized in that the segments have a length of not more than 2500 mm 9. The heat-insulating structure according to claim 1, characterized in that the lock connecting the segments to each other in the diametrical direction is formed by protrusions and grooves made in the radial direction and located on both ends of the segments, while the height of the protrusion is at least 1/4 of segment thickness. 10. The heat-insulating structure according to claim 1, or 4, or 7, characterized in that for the thermal insulation of the pipe joints a set of segments with a reduced length is used. 11. The heat-insulating structure according to claim 1, characterized in that the segments are interconnected into a tape with flexible sections that connect the segments to the lock after mounting the heat-insulating structure on the pipeline. 12. The heat-insulating structure according to claim 1, characterized in that the tightening tapes are made of steel or polymer. 13. The heat-insulating structure according to claim 1, characterized in that the constricting tapes are distributed along the length of the segment in an amount of at least four tapes. 14. The heat-insulating structure according to claim 1, characterized in that the protracting device is equipped with a stopper in the form of a lever. 15. The heat-insulating structure according to claim 1, characterized in that the lagging device is located at the level of the axis or above the axis of the pipe.