RU172059U1 - Curved pipe insulation element - Google Patents

Abstract

The technical solution relates to the field of power engineering, namely to devices serving for thermal insulation of pipelines. The technical result is to improve the heat-insulating properties of the device through the use of two heat-insulating shells, one of which is equipped with a protrusion and a hollow for the formation of thermal locks. namely, from the inner shell and the outer shell, while the outer shell covers the inner shell, one of the shells on the one hand has a longitudinal protrusion, and on the other hand a longitudinal hollow. 22 s.p. f-ly, 5 ill.

Description

The technical solution relates to the field of power engineering, namely to devices serving for thermal insulation of pipelines.

From the prior art, a protective casing for thermal insulation of the pipeline is known, consisting of a cylindrical shell with stiffeners and a device for fixing it to thermal insulation, the ribs being made longitudinal on the inner surface of the shell and flexible connections are installed on the free edges of the ribs (RU 15215 U1, F16L 59 / 00, 09.27.2000).

Known thermal insulation with a shell, which is a thermal insulation made of heat-insulating material and having longitudinal slots extending from the surface facing the pipeline, and partially dividing the insulation into sectors, as well as the shell. The shell is connected with thermal insulation, and at the ends of the shell protrusions and troughs are made to accommodate the corresponding protrusion or trough of an adjacent element with mating parts, also protrusions and troughs can be made at the ends of the thermal insulation to accommodate the corresponding protrusion or trough of an adjacent element with mating parts and on the sides of the shell there are elements for fastening (RU 123491 U1, F16L 59/00, 02.17.2012).

A known unit for thermal insulation of a pipeline, consisting of two rigid elements forming a cavity, one of which is made in the form of a gutter, the inner surface of the bottom of which repeats the shape of the surface of the pipeline, and the second element is made in the form of a segment insert installed in the gutter with a possibility of jamming, and the lateral parts of the gutter are made in the form of flat diverging surfaces, and the second element is installed in the gutter with the possibility of forming a closed cavity. Each end of the block can be made in the form of a locking part, which can be made in the form of a protrusion-trough (RU 2047811, F16L 59/12, 10.11.1995).

The closest analogue to the claimed technical solution is a pipe insulation containing a heat-insulating layer and a protective shell, and it is made in the form of a semi-cylindrical module, the inner diameter of which is equal to the outer diameter of the insulated pipe, the opposite surfaces of the ends of the half-cylinder are equipped with locking elements such as a spike-groove, heat-insulating layer made of polyurethane foam with a density of 50-80 kg / m ³ and the protective shell is made in the form of a metal foil (RU 24263 U1, F16L 59/06, 07.27.2002).

The disadvantage of the closest analogue is that the heat-insulating layer with protrusions and depressions is made monolithic and obtained by casting in a matrix, which is due, inter alia, to the complexity of manufacturing associated with the need to clean the matrix.

The task to which the technical solution is directed is to simplify manufacturing and increase use efficiency due to the possibility of combining the characteristics of the materials of flexible mats (layers) forming a multilayer product.

The technical result is to improve the thermal insulation properties of the device through the use of two thermal insulation shells, one of which is equipped with a protrusion and a cavity for the formation of thermal locks.

The technical result is achieved due to the fact that the curvilinear element for pipe insulation consists of two open curved cylindrical heat-insulating shells that are inextricably interconnected, namely, the inner shell and the outer shell, while the outer shell covers the inner shell, and one of the shells has one side has a longitudinal protrusion, and on the other hand a longitudinal hollow.

The inner shell has a longitudinal protrusion and a longitudinal cavity (Fig. 2).

The inner shell is located in the outer with a longitudinal displacement in such a way that an inner transverse step is formed on one end side, and a transverse protrusion is formed on the opposite end side. (Fig. 3).

The outer and inner shells are located coaxially.

The outer radius of the inner shell is equal to the inner radius of the outer shell.

The arc length of the circumference of the inner shell along its outer radius is equal to the arc length of the circumference of the outer shell along its inner radius.

The length of the inner shell is equal to the length of the outer shell.

The depth of the transverse step is equal to the length of the transverse protrusion.

The inner shell is connected to the outer by polymer adhesion, or by adhesive bonding.

The outer and inner shells are made of different materials.

The outer and inner shells have different physical and / or mechanical characteristics.

The outer and inner shells have different densities.

The inner shell has a higher density compared to the outer shell.

The outer shell has a higher density compared to the inner shell.

The outer and inner shells have different thermal conductivity, while it is preferable that the inner shell has lower thermal conductivity.

The outer and inner shells have different heat resistance, while it is preferable that the inner shell has greater heat resistance.

The outer and inner shells have different temperatures of use, while it is preferable that the inner shell has a high temperature of use.

The outer and inner shells have different thicknesses.

The outer shell is made of foamed polymeric material.

The inner shell is made of foamed polymeric material.

One of the shells is made of foamed polymeric material, and the other of another material, for example, of stone wool.

The outer shell on the outside has a protective layer comprising a metal foil.

In FIG. 1 is shown

In FIG. 2 shows an isometric view of a device with a protrusion and a hollow on the inner shell.

In FIG. Figure 3 shows an isometric view of a device with a protrusion and a hollow on the outer shell, as well as with an end ledge and a protrusion.

In FIG. 4 shows a pipe section insulated by devices docked together in a single structure.

In FIG. 5 shows a longitudinal section AA in FIG. 4 along the axis of the insulated pipe.

The curvilinear element for pipe insulation consists of two open curvilinear cylindrical heat-insulating shells inextricably interconnected - the inner shell 1 and the outer shell 2.

In this case, the outer shell 1 covers the inner shell 2, and one of the shells has, on the one hand, a longitudinal protrusion 3 and, on the other hand, a longitudinal cavity 4.

The longitudinal protrusion and the longitudinal hollow can have both an inner and an outer shell (Fig. 1-2).

The inner shell can be located in the outer shell with a longitudinal displacement so that one transverse ledge 5 (depression) is formed on one end side, while a transverse protrusion 6 is formed on the opposite end side (Fig. 3).

The outer and inner shells are located coaxially, while the outer radius of the inner shell is equal to the inner radius of the outer shell.

The arc length of the circumference of the inner shell along its outer radius is equal to the arc length of the circumference of the outer shell along its inner radius.

The length of the inner shell 1 is equal to the length of the outer shell 2.

The depth of the transverse step 5 is equal to the length of the transverse protrusion 6, and

The offset by which the transverse step 5 and the transverse protrusion 6 are formed is the longitudinal displacement of the inner shell along the conditional longitudinal axis 7, coinciding with the longitudinal axis of the insulated pipe 8.

The inner shell is connected to the outer through polymer adhesion, resulting from the heating of the shells, or through adhesive bonding.

The outer and inner shells can be made of different materials.

The outer and inner shells may have different physical and / or mechanical characteristics.

Preferably, the outer and inner shells can have different densities, different heat conductivity, different heat resistance, temperature of use, and also different thickness.

Preferably, the inner shell has a higher density compared to the outer shell.

It is preferable that the inner shell has greater heat resistance compared to the outer shell and the maximum temperature of use.

Preferably, the inner shell has lower thermal conductivity than the inner shell.

It is preferable that both shells are made of foamed polymeric material, for example, polyurethane foam or foamed polyethylene, but other heat-insulating materials, such as stone wool, are also possible.

The outer shell on the outside can have a protective layer (not shown conventionally), including a metal foil and / or polymer network.

Thus, the products in addition to the formation of a multilayer structure with end and longitudinal thermal locking elements (docking nodes) provides the opportunity to use different materials or homogeneous materials of different densities, which is due to different necessary coefficients of thermal conductivity.

Claims (23)

1. A curvilinear element for insulation of pipes, characterized in that it consists of two open curved cylindrical heat-insulating shells, one-piece connected to each other, namely the inner shell and the outer shell, while the outer shell covers the inner shell, and one of the shells has one the sides are a longitudinal protrusion, and on the other hand, a longitudinal hollow. 2. The curvilinear element according to claim 1, characterized in that the outer shell has a longitudinal protrusion and a longitudinal depression. 3. The curvilinear element according to claim 1, characterized in that the inner shell has a longitudinal protrusion and a longitudinal depression. 4. The curvilinear element according to claim 1, characterized in that the inner shell is located in the outer with a longitudinal displacement so that an inner transverse ledge is formed on one end side, and a transverse protrusion is formed on the opposite end side. 5. The curvilinear element according to claim 1, characterized in that the outer and inner shells are located coaxially. 6. The curvilinear element according to claim 1, characterized in that the outer radius of the inner shell is equal to the inner radius of the outer shell. 7. The curvilinear element according to claim 1, characterized in that the arc length of the circumference of the inner shell along its outer radius is equal to the arc length of the circumference of the outer shell along its inner radius. 8. The curvilinear element according to claim 1, characterized in that the length of the inner shell is equal to the length of the outer shell. 9. The curved element according to claim 1, characterized in that the depth of the transverse step is equal to the length of the transverse protrusion. 10. The curvilinear element according to claim 1, characterized in that the inner shell is connected to the outer by means of polymer adhesion, or by means of adhesive bonding. 11. The curvilinear element according to claim 1, characterized in that the outer and inner shells are made of different materials. 12. The curvilinear element according to claim 1, characterized in that the outer and inner shells have different physical and / or mechanical characteristics. 13. The curvilinear element according to claim 1, characterized in that the outer and inner shells have different densities. 14. The curvilinear element according to claim 13, characterized in that the inner shell has a higher density compared to the outer shell. 15. The curvilinear element according to claim 13, characterized in that the outer shell has a higher density compared to the inner shell. 16. The curvilinear element according to claim 1, characterized in that the outer and inner shells have different thermal conductivity, while it is preferable that the inner shell has lower thermal conductivity. 17. The curvilinear element according to claim 1, characterized in that the outer and inner shells have different heat resistance, while it is preferable that the inner shell has greater heat resistance. 18. The curved element according to claim 1, characterized in that the outer and inner shells have different temperatures of use, while it is preferable that the inner shell has a high temperature of use. 19. The curved element according to claim 1, characterized in that the outer and inner shells have different thicknesses. 20. The curvilinear element according to claim 1, characterized in that the outer shell is made of foamed polymeric material. 21. The curvilinear element according to claim 1, characterized in that the inner shell is made of foamed polymeric material. 22. The curvilinear element according to claim 1, characterized in that one of the shells is made of foamed polymeric material, and the other of another material, for example, of stone wool. 23. The curvilinear element according to claim 1, characterized in that the outer shell on the outside has a protective layer comprising a metal foil.

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