RU223325U1 - Thermal insulation product for insulating pipe sections with variable diameters - Google Patents

Abstract

The utility model relates to thermal insulation products, namely to products for insulating pipe transitions - areas (places) where a pipe of a larger diameter is joined to a pipe of a smaller diameter, as well as for areas where pipes are joined to pipeline fittings (taps, pressure sensors, etc. ). The technical challenge is to expand the arsenal of technical means. The technical result is the device achieving its intended purpose. A thermal insulation product for insulating pipe transitions, characterized in that it is a heat-insulating shell in the form of a volumetric body with a through central hole and cutouts made in part of the shell wall, between which are formed extended elements tapering towards the end part of the shell, united by the base of the shell and connected with him. 17 salary f-ly, 9 ill.

Description

The utility model relates to thermal insulation products, mainly to products for insulating pipe transitions - sections (places) where a pipe of a larger diameter is joined to a pipe of a smaller diameter, as well as for areas where pipes are joined with pipeline fittings (taps, pressure sensors, etc.) .

From the prior art, a device for insulating pipe transitions is known, made in the form of a conical shell https://pipewool.com/katalog/teploizolyatsiya/perehody-teploizoljacionnye/, 12/30/2021.

An elastic insulating cuff is known from the prior art, designed for fastening to a transition pipeline (RU 2407941C1, 12/27/2010).

It is known to be a multilayer composite device for insulating pipe joints (RU 38884U1, 07/10/2004).

The closest analogue to the claimed technical solution is the conical transitions “Х0ТР1РЭ”, made in the form of a detachable conical shell with a locking element https://www.youtube.com/watch?v=JKcitN2grmk 11/05/2020.

The technical challenge is to expand the arsenal of technical means.

The technical result is to simplify the installation of the heat-insulating product.

A thermal insulation product for insulating pipe transitions, characterized in that it is a heat-insulating shell in the form of a volumetric body with a through central hole and cutouts made in part of the shell wall, between which are formed extended elements tapering towards the end part of the shell, united by the base of the shell and connected with him.

A thermal insulation product, characterized in that it is made in the form of a closed thermal insulation curved, preferably cylindrical, thick-walled shell and radially located, preferably wedge-shaped cutouts made in the wall of the shell, between which radially located, preferably wedge-shaped extended elements are formed, with a central hole , predominantly made with a round or rounded cross-section.

A thermal insulation product characterized by the fact that the wedge-shaped cutouts are made extended along the length of the shell.

A thermal insulation product characterized by the fact that the base of the shell is shorter in length compared to the larger part of the shell with wedge-shaped cutouts and wedge-shaped extended elements located between them.

A thermal insulation product characterized by the fact that the base of the shell unites extended elements.

A thermal insulation product characterized by the fact that a thick-walled cylindrical shell has radial wedge-shaped cuts made along its height, each of which is made over most of the height of the cylindrical shell.

A thermal insulation product characterized by the fact that between each two adjacent wedge-shaped cutouts, extended elements are formed, tapering towards the end part of the cylindrical shell, located in accordance with radial symmetry relative to the longitudinal axis of the shell.

A thermal insulation product characterized by the fact that wedge-shaped cutouts are made in the wall of the shell in accordance with radial symmetry relative to the longitudinal axis of the cylindrical shell.

A thermal insulation product characterized by the fact that adjacent cutouts are at the same distance from each other and evenly spaced along the perimeter of the cylindrical shell.

A thermal insulation product characterized by the fact that the symmetry plane of each cutout passes through the longitudinal axis of the cylindrical shell.

A thermal insulation product characterized by the fact that the plane of symmetry of each of the extended elements located between adjacent cutouts also passes through the axis of symmetry of the cylindrical shell.

A thermal insulation product, characterized in that the ends of the extended elements have external bevels to ensure better joining with the ends of the thermal insulation products adjacent to the claimed thermal insulation product.

A thermal insulation product characterized by the fact that the base of the shell has an incision, slot or through cut.

A thermal insulation product characterized by the fact that adjacent wedge-shaped cutouts are at the same distance from each other and evenly spaced along the perimeter of the curved shell.

A thermal insulation product characterized by the fact that it is made of compressible or elastic thermal insulation material.

A thermal insulation product characterized by the fact that it is made of elastic thermal insulation material.

A thermal insulation product characterized by the fact that it is made of mineral or stone wool.

A thermal insulation product characterized by the fact that it is made of a polymer material, for example polyurethane.

The device is illustrated by drawings.

In FIG. 1 shows the device (isometric front view).

In FIG. 2 shows the device (isometric rear view).

In FIG. 3 shows the device (rear view).

In FIG. 4 shows the device (side view).

In FIG. 5 shows the device (front view).

In FIG. Figure 6 shows a device mounted on a pipe transition.

In FIG. 7 shows a device with external bevels at the ends (isometric front view).

In FIG. Figure 8 shows a device with external bevels at the ends (side view).

In FIG. Figure 9 shows a device with external bevels at the ends, mounted on the transition (side view).

A thermal insulation product for insulating pipe transitions, characterized in that it is a heat-insulating shell in the form of a volumetric body with a through central hole 1 and cutouts 2 made in part of the shell wall, between which extended elements 3 are formed, tapering towards the end part 4 of the shell, combined with a closed shell base 5 and connected to it.

It is preferable that the heat-insulating product is a cylindrical volumetric body, preferably having radial symmetry.

It is preferable that the volumetric body is made of a polymer and/or fibrous thermal insulating elastic material, for example, polyurethane foam, and preferably, mineral wool.

Preferably, the material from which the volumetric body is made is made compressible or at least partially deformable under load.

It is preferable that the volumetric body is made in the form of a closed heat-insulating curvilinear, preferably cylindrical, thick-walled shell with a through central hole 1 of rounded cross-section and extended along the length (height) of the shell, radially (diametrically) located, predominantly wedge-shaped cutouts 2, made in the wall of the shell.

Between the wedge-shaped cutouts 2 are formed radially located, preferably, wedge-shaped extended elements 3, tapering towards the end part 4 of the shell, connected to each other by a part of the shell without wedge-shaped cutouts 2, namely the base 5 of the shell.

Adjacent cutouts 3 are located approximately (with tolerances for dimensional deviations) at the same distance from each other and approximately (with tolerances for dimensional deviations) evenly located along the perimeter (circumference length) of the curved (cylindrical) shell.

Preferably, the solid, without cutouts 2, smaller part of the shell has a shorter length (height) compared to the larger part of the shell with cutouts 2 and extended elements 3 located between them.

The base of the shell 5 unites extended elements of 3 m and is permanently, preferably, monolithically connected to them.

It is preferable that the cylindrical shell is made thick-walled and has, preferably, radial (diametral] wedge-shaped cuts 2 made along its height, each of which is made over most of the height of the cylindrical shell.

Between each two adjacent cutouts 2, extended elements are formed, tapering towards the end part of the cylindrical shell, also located in accordance with radial symmetry relative to the longitudinal axis of the shell.

It is preferable that the cutouts 2 are made in the wall of the shell in accordance with radial (circular) symmetry relative to the longitudinal axis of the cylindrical shell.

Adjacent cutouts 2 are at the same distance from each other and are evenly spaced along the perimeter (circumference length) of the cylindrical shell.

The plane of symmetry of each wedge-shaped cut passes through the longitudinal axis of the cylindrical shell.

The plane of symmetry of each of the extended element 3 located between the cutouts 2 also passes through the axis of symmetry of the cylindrical shell.

The ends of the wedge-shaped extended elements 3 may have external bevels 6.

External bevels 6 are designed to ensure better joining of the claimed product with the flat end of the heat-insulating product on a straight section of the pipe adjacent to the claimed heat-insulating product.

In the absence of the mentioned external bevels 6, when the transition is covered by wedge-shaped elements, protrusions 7 are formed (Fig. 6) at the end of the claimed product, and in order to tightly dock the end of the product to it in a straight section, it is necessary to apply additional force to crush the mentioned protrusions 7. In the case the presence of external bevels 6 does not require force, which facilitates installation and insulation of the pipeline].

Adjacent cuts 2 are preferably at the same distance from each other (relative to their planes of symmetry] and are evenly spaced along the perimeter of the curved shell, which provides a better approximation of the surface covered by the tapering elements 3 of the transition section.

The thermal insulation product is predominantly made of compressible (deformable without destruction] and/or elastic thermal insulation material to be able to enclose and isolate the transition without destroying or compromising the integrity of the product.

The thermal insulation product is preferably made of mineral or stone wool.

The thermal insulation product can be made of a polymer material, for example, polyurethane.

The device is manufactured as follows.

An elongated solid or composite heat-insulating cylinder is used as the initial blank for the production of the product, having a central through hole of a rounded cross-section, in which, in accordance with the radial symmetries, wedge-shaped symmetrical cuts 2 are made to allow further closure of the extended elements 3 located between them in the area connection (transition) of two pipes, which is made tapering (mostly conical] from a pipe of larger diameter to a pipe of smaller diameter. Or extended elements 3 can be manufactured separately and permanently connected to the base 5 with the formation of cutouts 2 between them.

The device is mounted at the pipe junction as follows. A through cut 8 is made from the bottom of one of the cutouts 2 in the solid part of the shell, after which the shell is opened, maintaining its integrity due to the elasticity of the heat-insulating material, by moving apart the edges formed as a result of making the through cut.

After that, the shell open along the through cut 8 covers the place where the pipes join (transition) and the adjacent part of the pipe of larger diameter. The part of the larger diameter pipe is covered by the smaller part of the shell (the part without cutouts 2]. To reduce the work operations, the mentioned cut 8, slot or an incision to open the shell can be made in advance at the enterprise during the manufacture of the heat-insulating product.

Due to the elasticity of the material, the shell, after enveloping the pipe and transition, closes in the place of the above-mentioned through cut made from one of, preferably, the wedge-shaped cutouts 2.

Moreover, part of the shell without cutouts - the base 5 of the shell - is placed and fixed on a pipe of a larger diameter, which, on the one hand, allows for a “fit-to-size” joining of the mounted heat-insulating product with a heat-insulating product of the same diameter on a straight section of the pipeline. On the other hand, it allows you to securely fix the product on the transition without the possibility of its displacement along the transition during and after installation of the heat-insulating product.

By tightening the extended elements, after installation they are located at an angle to the longitudinal axis of a part of the cylindrical shell, which preferably coincides with the longitudinal axis of a larger diameter pipe.

A part of the shell with, preferably, wedge-shaped cutouts 2 and extended elements between them is tightened using wire, mounting tape, ties, clamps or other fastening devices so that the tapering extended elements 3 tightly close together in those areas where wedge-shaped cutouts were made 2 at the pipe joining place (transition).

Thus, after the closure of the extended elements 3, the junction of the pipes is isolated, and the base 5 isolates the part of the pipe of larger diameter adjacent to the mentioned junction (transition), which is made tapering (mostly conical) from a pipe of a larger diameter to a pipe of a smaller diameter.

Using the proposed solution simplifies and speeds up the process of isolating transitions, and also expands the arsenal of existing solutions.

The proposed product is easy to manufacture, in comparison with existing analogues, it makes it possible to improve manufacturability and reduce the cost of manufacturing products. In addition, the device is easy to install and allows you to increase labor productivity during installation and increase the speed of installation. In the case of the preferred execution of the cutouts 2 wedge-shaped, the best approximation of the transition, which has a tapered or conical shape, is achieved by the tapering protrusions 3.

Claims (18)

1. Thermal insulation product for insulating pipes with variable diameter, containing a heat-insulating thick-walled cylindrical shell with a through central hole and radially located wedge-shaped cutouts made in the wall of the shell, between which radially located wedge-shaped extended elements are formed, tapering towards the end part of the shell, united by the base of the shell and connected to it, characterized in that the ends of the extended wedge-shaped elements have external bevels. 2. Thermal insulation product for insulating pipes with variable diameter according to claim 1, characterized in that it is made in the form of a closed thermal insulating curved, preferably cylindrical thick-walled shell and radially located, preferably wedge-shaped cutouts made in the wall of the shell, between which there are radially formed located, preferably, wedge-shaped extended elements, while the central hole is preferably made with a round or rounded cross-section. 3. Thermal insulation product for insulating pipes with variable diameter according to claim 1, characterized in that the wedge-shaped cutouts are made extended along the length of the shell. 4. Thermal insulation product for insulating pipes with variable diameter according to claim 1, characterized in that the base (5) of the shell has a shorter length compared to the majority of the shell with wedge-shaped cutouts and wedge-shaped extended elements located between them. 5. Thermal insulation product for insulating pipes with variable diameter according to claim 1, characterized in that the base of the shell unites extended elements. 6. Thermal insulation product for insulating pipes with variable diameter according to claim 1, characterized in that the thick-walled cylindrical shell has radial wedge-shaped cuts made along its height, each of which is made over most of the height of the cylindrical shell. 7. Thermal insulation product for insulating pipes with variable diameter according to claim 2, characterized in that between each two adjacent wedge-shaped cutouts, extended elements are formed, tapering towards the end part of the cylindrical shell, located in accordance with radial symmetry relative to the longitudinal axis of the shell. 8. Thermal insulation product for insulating pipes with variable diameter according to claim 1, characterized in that wedge-shaped cutouts are made in the wall of the shell in accordance with radial symmetry relative to the longitudinal axis of the cylindrical shell. 9. Thermal insulation product for insulating pipes with variable diameter according to claim 1, characterized in that adjacent cutouts are at the same distance from each other and are evenly spaced along the perimeter of the cylindrical shell. 10. Thermal insulation product for insulating pipes with variable diameter according to claim 1, characterized in that the symmetry plane of each cutout passes through the longitudinal axis of the cylindrical shell. 11. Thermal insulation product for insulating pipes with variable diameter according to claim 1, characterized in that the plane of symmetry of each extended element located between adjacent cutouts also passes through the axis of symmetry of the cylindrical shell. 12. Thermal insulation product for insulating pipes with variable diameter according to claim 1, characterized in that the ends of the extended elements have external bevels to ensure better joining with the ends of the heat-insulating products adjacent to the claimed heat-insulating product. 13. Thermal insulation product for insulating pipes with variable diameter according to claim 1, characterized in that the base of the shell has an incision, slot or through cut. 14. Thermal insulation product for insulating pipes with variable diameter according to claim 1, characterized in that adjacent wedge-shaped cutouts are at the same distance from each other and are evenly located along the perimeter of the curved shell. 15. Thermal insulation product for insulating pipes with variable diameter according to claim 1, characterized in that it is made of compressible and/or elastic thermal insulation material. 16. Thermal insulation product for insulating pipes with variable diameter according to claim 1, characterized in that it is made of elastic heat-insulating material. 17. Thermal insulation product for insulating pipes with variable diameter according to claim 1, characterized in that it is made of mineral or stone wool. 18. Thermal insulation product for insulating pipes with variable diameter according to claim 1, characterized in that it is made of a polymer material, for example polyurethane.