RU163434U1 - THERMAL INSULATION PRODUCT - Google Patents

Abstract

1. A heat-insulating product, including a heat-insulating layer and an outer protective shell, characterized in that the heat-insulating layer is made in the form of a composite body, most of which is made of the main heat-insulating material, while the composite body includes a frame ring made of heat-insulating material, the rigidity of which exceeds stiffness of the main heat-insulating material. 2. The heat-insulating product according to claim 1, characterized in that the composite body, as well as the heat-insulating product as a whole, have a cylindrical or close to cylindrical shape, wherein the composite body has an inner cylindrical through channel for accommodating the pipe, the composite body and shell having a longitudinal section or cuts made with the possibility of ensuring the disclosure of the product when it is mounted on the pipe. 3. A heat-insulating product according to claim 2, characterized in that a longitudinal section or sections are made along the entire length of the outer protective sheath. 4. A heat-insulating product according to claim 1, characterized in that most of the composite body is made of soft or semi-rigid heat-insulating material, and the frame ring is made of semi-rigid or hard heat-insulating material or heat-insulating material of increased stiffness and equipped with at least one locking element. 5. A heat-insulating product according to claim 1, characterized in that the heat-insulating material of which the frame ring is made has a high density and / or compressive strength. 6. A heat-insulating product according to claim 1, characterized in that the frame ring is connected to most of the composite body;

Description

Thermal insulation product

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 heat-insulating product is known, the inner surface of which is formed by alternating protrusions and depressions, which consists of a layer of fibrous heat-insulating material or includes a layer of fibrous heat-insulating material, which has an inner surface intended to adjoin a thermally insulated surface, and an outer surface, the inner surface of which is formed by alternating protrusions and depressions, inclined to the outer surface of the layer of insulating material (RU 1394 81 U1, F16L 59/14, 04/20/2014).

Known pipe insulation containing a heat-insulating layer and a protective sheath, and it is made in the form of a semi-cylindrical module, internal

the 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 spike-groove locking elements, the heat-insulating layer is made of polyurethane foam with a density of 50-80 kg / m3, and the protective sheath is made in the form of a metal foil (RU 24263 U1, F16L 59 / 06.07.07.2002).

The closest analogue to the claimed technical solution is a modular pipe heater made in the form of a half cylinder, the inner diameter of which is equal to the outer diameter of the insulated pipe, in which the insulation layer of the module is made of polyurethane foam, the outer shell is made in the form of paper with a metal foil applied to the outer surface, length module does not exceed two meters. The modular insulation contains an additional half-cylinder connected to the first half-cylinder by the outer shell, the heat-insulating layer of the half-cylinders is made of polyurethane foam with a density of 15 ÷ 30 kg / m3, the outer shell of the half-cylinders overlaps their connection line, and the overlap strip of the shell on the inside is covered with an adhesive layer (RU 59197 U1, F16L 59/06, 12/10/2006).

The disadvantages of these technical solutions is the lack of rigidity, as well as the complexity of installation.

For insulation of pipelines, either rigid heat-insulating products are used, ready for installation, capable of absorbing significant loads with slight deformation, for example, cylinders, shells of mineral wool, polyurethane foam, polystyrene foam, foam glass, expanded perlite and vermiculite, with a fairly high resistance to compression.

Or soft heat-insulating mats, for example, of mineral wool, foamed polymers, the compressibility coefficient of which exceeds 3%, requiring additional processing for installation (fitting of sizes, special fasteners).

When placing thermal insulation in open spaces, the question arises of its protection against atmospheric effects (moisture, ultraviolet, etc.). The vast majority of the insulation located in open spaces is additionally equipped with a cover layer made of metal sheet material or hard plastic sheet, which requires additional labor and time costs.

The most preferred thermal insulation with an additional coating layer are rigid thermal insulation products due to the constancy of their geometric dimensions.

In the case of using soft heat-insulating materials with an additional cover layer, during operation, situations constantly arise when the main heat-insulating layer as a result of loads, such as the load from the cover layer itself and the snow load, gradually settles (deforms), which leads to a decrease in the thickness of the insulation layer in the place of compression, as well as the possibility of “sagging” of the thermal insulation (the formation of an inner pocket between the thermal insulation layer and the insulated object in the lower part of the pipeline ). This, in turn, leads to an increase in heat loss, as well as a possible deformation of the entire heat-insulating structure.

The inventive utility model combines all the advantages of using a rigid heat-insulating product (constancy of geometric dimensions, ease of installation) and a soft heat-insulating product (lower cost of thermal insulation, the possibility of facilitating the heat-insulating layer) for which, from one edge (or from both edges), an external protective (integumentary) the shell, which is made of metal, is glued a frame ring made of (from mineral wool with a density of more than 50 kg / m3, or of foamed polymer with a density of more than 30 kg / m3, of foam glass a, expanded vermiculite and perlite density over 80 kg / m3), which has sufficient rigidity, to which all the load from the external protective shell, as well as from other possible loads, such as snow and other loads, will be fully transmitted.

The length l (height) of the frame ring is from 1% to 25% of the total length L of the outer protective shell; soft or semi-rigid thermal insulation (mineral wool thermal insulation mat, foamed polymer, etc.) is glued to the entire remaining inner part of the shell. Frame (support) ring consists of 2 or more segments, have a longitudinal section (s) in the upper and lower parts, providing ease of opening / closing of the insulating product during installation.

The mounted heat-insulating product is fixed with fasteners, for example, self-tapping screws along the longitudinal joint of the integument. Or, for example, if it is made of hard plastic with sufficient rigidity, the shell is glued or fastened with special bandages or knitting wire.

Thus, from the prior art, heat-insulating products for pipe insulation are known including an insulating layer (thermal insulation) as well as an external protective sheath.

Also known from the prior art are frame rings made of heat-insulating material. Namely, a heat-insulating frame ring is known, which is made of a heat-insulating material with a density of more than 90 kg / m3, the thickness of the ring is equal to the thickness of the main heat-insulating layer, and the inner diameter is to the outer diameter of the insulated product. The frame ring consists of several interconnected elements, and the elements of the ring are connected to each other using heat-locking locks (RU 95381 U1, F16L 59/00, 06/27/2010). The description of RU 95381 U1 contains information on how a heat-insulating frame ring is mounted together with other components - thermal insulation and a protective coating layer. The installation of components begins with mats of soft thermal insulation, which are wrapped around pipes, between which heat-insulating frame rings are mounted, after which a metal casing is mounted on mats with frame rings or wrapped in a metallized coating layer. The disadvantage described in RU 95381 U1 technical solutions

is the complexity of installation and loose fit of the coating layer to thermal insulation.

The technical result is to increase the stiffness of the insulating product without heat loss.

The technical result is achieved due to the fact that the heat-insulating product includes a heat-insulating layer and an outer protective shell, while the heat-insulating layer is made in the form of a composite body, most of which is made of the main heat-insulating material, while the composite body includes at least one frame a ring made of heat-insulating material, the rigidity of which exceeds the stiffness of the main heat-insulating material.

It is preferable that the composite body, as well as the product as a whole, have a cylindrical or close to cylindrical shape, while the composite body has an inner cylindrical through channel for accommodating the pipe, the composite body and shell having a longitudinal section or sections made with the possibility of opening the product its mounting on the pipe.

Preferably, the longitudinal section or sections are made along the entire length of the outer protective sheath.

It is preferable that most of the composite body is made of soft or semi-rigid heat-insulating material, and the frame ring is made of semi-rigid or hard heat-insulating material, or of heat-insulating material of increased rigidity and provided with at least one locking element.

Preferably, the heat-insulating material of which the frame ring is made has a high density and / or compressive strength.

It is preferable that at least one frame ring is connected to most of the composite body, preferably by means of an adhesive joint.

Preferably, a large part of the composite body, which is made of a basic heat-insulating material, is glued to the outer protective sheath.

Preferably, most of the composite body is made of fibrous insulating material, preferably mineral wool, or a porous polymeric material.

Preferably, the frame ring has a cylindrical shape or close to a cylindrical shape and consists of at least two elements.

Preferably, the elements of which the frame ring consists are made in the form of segments, each of which is equipped with a locking element.

Preferably, the locking elements of the segments are protrusions and depressions of the mating shape.

Preferably, the protrusion is made tapering towards the cavity, preferably of a pyramidal shape.

Preferably, the frame ring is connected to the outer protective sheath by means of separate discrete adhesive joints.

It is preferable that at least one frame ring is located in the frontal area of the insulating product.

Preferably, at least one frame ring is located near the edge of the outer protective shell, or the end of the frame ring is placed at a level with the edge of the outer protective shell.

At least one frame ring may be located in the middle of the composite body.

The outer protective sheath may be made of a composite material including layers of polymer and / or foil, for example, of a laminated foil.

The outer protective shell can be made of a sheet of metal, or thick foil and / or elastic plastic and is a thin-walled tubular open-ended axisymmetric shell, the ratio of the thickness of which to the inner radius does not exceed 1/20.

Preferably, the length of the frame ring is from 1% to 25% of the total length of the outer protective sheath.

Preferably, the frame ring is made of mineral wool with a density of more than 50 kg / m3, or of foamed polymer with a density of more than 30

kg / m3, either from foam glass, or expanded vermiculite or perlite with a density of more than 80 kg / m3.

It is preferable that the shell within the location of the at least one frame ring has locking elements for coupling with the shell of another heat-insulating product of a similar design.

Preferably, the locking elements of the shell are made in the form of annular bulges curved outwardly of the outer protective shell.

In FIG. 1 shows a thermal insulation product (isometric view);

In FIG. 2 shows a part of the product in a half-open state (isometric view);

In FIG. 3 shows a product mounted on a thermally insulated pipe (isometric view);

In FIG. 4 is a cross section AA in FIG. 3;

In FIG. 5 is a longitudinal section BB in FIG. four;

In FIG. 6 shows a longitudinal section of a pipe with a heat-insulating product mounted on it, equipped with one frame ring located in the near-end zone of the product shell.

In FIG. 7 shows a longitudinal section of a pipe with two heat-insulating products mounted on it, each of which is equipped with one frame ring interconnected.

In FIG. 8, the assembly B in FIG. 7

In FIG. 9-12 depict possible embodiments of the frame rings (transverse sections).

The heat-insulating product includes a heat-insulating layer and an outer protective shell 1. The heat-insulating layer is made in the form of a composite body, most of which 2 is made of the main heat-insulating material.

The composite body includes one frame ring 3 made of a heat-insulating material, the rigidity of which exceeds the stiffness of the main heat-insulating material (FIG. 6).

The composite body, as well as the product as a whole, have a cylindrical or close to cylindrical shape, while the composite body 1 has an inner cylindrical through channel 4 for accommodating the pipe 5.

The composite body and the sheath have a longitudinal section 6 or sections made with the possibility of ensuring the disclosure of the product when it is mounted on the pipe 5.

Most of the composite body 2 is made of soft or semi-rigid heat-insulating material, and the frame ring 3 is made of hard heat-insulating material or heat-insulating material of increased rigidity and is equipped with at least one locking element 7.

The frame ring 3 is connected to a soft or semi-rigid thermal insulation, preferably by means of an adhesive joint, and a large part 2 of the composite body, which is made of the main heat-insulating material, is glued to the outer protective sheath. Thus, all the elements that make up the product are interconnected and combined into a single structure.

It is preferable that most of the composite body 2 is made of fibrous heat-insulating material, preferably mineral wool, or of a porous polymeric material (foamed polymer).

The frame ring 6 has a cylindrical shape or close to a cylindrical shape and consists of at least two elements. The elements of which the frame ring consists are made in the form of segments 8, each of which is equipped with a locking element 7. The locking elements of the 7 segments are protrusions and depressions of a reciprocal shape. Each protrusion is made tapering towards the cavity, preferably of a pyramidal shape.

Preferably, the frame ring 3 is connected to the outer protective sheath 1 through separate discrete adhesive joints 9 (FIG. 4).

The frame ring 3 is located in the front-end zone 10 of the thermal insulation product (name).

Preferably, the frame ring 3 is located near the edge 11 of the outer protective shell 1, or the end face 12 of the frame ring 3 is placed at a level with the edge 11 of the outer protective shell (FIG. 6).

The outer protective shell 1 may be made of a composite material including layers of polymer and / or foil, for example, of a laminated foil.

The outer protective shell 1 is made of a sheet of metal or of thick foil and / or of elastic plastic and is a thin-walled tubular open-ended axisymmetric shell whose ratio of thickness t to the inner radius R does not exceed 1/20 (t / R≤1 / 20) , that is, the material from which the shell is made has a certain rigidity, the possibility of independent resistance to external influences while maintaining its geometric shape (FIG. 4).

The length (height) l of the frame ring is from 1% to 25% of the total length L of the outer protective sheath.

The frame ring 3 is made of mineral wool with a density of more than 50 kg / m3, or of foamed polymer with a density of more than 30 kg / m3, or of foam glass, or expanded vermiculite or perlite with a density of more than 80 kg / m3.

The most preferred embodiment of the heat-insulating product is a variant in which the device includes a heat-insulating layer and an outer protective shell 1, wherein the heat-insulating layer is made in the form of a composite body, most of which 2 is made of soft or semi-rigid main heat-insulating material. In this case, the composite body includes a frame ring 3 made of semi-rigid or rigid heat-insulating material, or of heat-insulating material with increased stiffness, the rigidity of which exceeds the stiffness of the main heat-insulating material. A soft or semi-rigid material is mineral wool, while the heat-insulating material of which the frame ring 3 is made also is mineral wool with density, rigidity and compressive strength greater than that of mineral wool, of which most of the composite body is made. The outer protective shell 1 is a thin-walled cylindrical shell, which due to the cut 6 is made open. The outer protective shell is made of laminated foil with sufficient rigidity and elasticity to maintain its geometric shape

during installation and operation. The frame ring is placed at the edge 11 of the outer shell in a level with it, while the composite body does not reach the other edge 14 of the outer protective shell, forming a cavity 15 (FIG. 6) to accommodate part of another heat-insulating product, similar to the design, while this part contains frame ring 3 (FIG. 7, 8). The frame ring 3 is made of a cylindrical shape from separate segments joined together by means of the locking elements 7. It is possible that the frame ring 3 does not consist of segments 8, and its disclosure during installation is achieved through the corresponding sections 6 (FIG. 12). The outer protective shell 1 on the one hand within the framework of the frame ring has locking elements 13, and on the other hand within the cavity 15 has locking elements 16 for the possibility of adhesion with the shells of a heat-insulating product of a similar design when installing heat-insulating products on the pipe 5 (FIG. 7, 8). Thus, on the pipe 5, from a stacked heat-insulating products, a single connected structure is formed (FIG. 7), in which one frame ring 3 of each heat-insulating product provides both its own rigidity and the rigidity of the adjacent heat-insulating product. The locking elements 13, 16 are made in the form of annular convexities curved outwardly of the outer protective shell, provide reliable adhesion of adjacent heat-insulating products to each other, and also create additional rigidity at the joints of adjacent heat-insulating products (FIG. 8).

The insulating product is mounted on the pipe 5 as follows. The heat-insulating product is opened by spreading to the sides its longitudinal edges 17 of the outer protective shell 1 along the cut 6, while the protrusions of the locking elements come out from the hollows of adjacent segments 8. After that, the pipe 5 is covered by the opened heat-insulating product, the edges of the outer protective shell 1 are released, under the action of forces of elasticity, the longitudinal edges 17 are closed, and the pipe is placed inside the channel 4. Next, the insulating product is fixed on the pipe 5 using screws 18, screwed through the outer protective sheath 1 into a composite body . To be able to fix with screws and provide sealing, the outer protective shell 1 has an inlet 19 extending beyond the face 20 of the composite body,

formed by a cut 6. Due to the inlet 19, the longitudinal edges of the shell of the mounted heat-insulating product are overlapped. After mounting the first heat-insulating product, the following is mounted, while the outer protective shell 1 of the next heat-insulating product covers a part of the outer protective shell 1 of the heat-insulating product so that the end part of the first heat-insulating product is located inside the cavity 15 whose depth Δl does not exceed length l.

Using the described thermal insulation allows you to reduce the time and complexity of installation, to ensure compliance with the geometric dimensions of the structure, to rationally use the properties of materials, to avoid deformation and heat loss as a result of loads arising during the installation and operation of the thermal insulation product.

Claims (22)

1. A heat-insulating product, including a heat-insulating layer and an outer protective shell, characterized in that the heat-insulating layer is made in the form of a composite body, most of which is made of the main heat-insulating material, while the composite body includes a frame ring made of heat-insulating material, the rigidity of which exceeds stiffness of the main heat-insulating material. 2. The heat-insulating product according to claim 1, characterized in that the composite body, as well as the heat-insulating product as a whole, have a cylindrical or close to cylindrical shape, wherein the composite body has an inner cylindrical through channel for accommodating the pipe, wherein the composite body and shell section or sections made with the possibility of ensuring the disclosure of the product when it is mounted on the pipe. 3. A heat-insulating product according to claim 2, characterized in that a longitudinal section or sections are made along the entire length of the outer protective sheath. 4. The heat-insulating product according to claim 1, characterized in that most of the composite body is made of soft or semi-rigid heat-insulating material, and the frame ring is made of semi-rigid or hard heat-insulating material or heat-insulating material of increased stiffness and equipped with at least one lock an element. 5. A heat-insulating product according to claim 1, characterized in that the heat-insulating material of which the frame ring is made has a high density and / or compressive strength. 6. Thermal insulation product according to claim 1, characterized in that the frame ring is connected to most of the composite body, preferably by means of an adhesive joint. 7. The heat-insulating product according to claim 1, characterized in that a large part of the composite body, which is made of the main heat-insulating material, is glued to the outer protective sheath. 8. The heat-insulating product according to claim 1, characterized in that the bulk of the composite body is made of fibrous heat-insulating material, preferably mineral wool, or of a porous polymeric material. 9. Thermal insulation product according to claim 1, characterized in that the frame ring has a cylindrical shape or is close to a cylindrical shape and consists of at least two elements. 10. A heat-insulating product according to claim 9, characterized in that the elements of which the frame ring consists are made in the form of segments, each of which is equipped with a locking element. 11. Thermal insulation product according to claim 10, characterized in that the locking elements of the segments are protrusions and depressions of the reciprocal form. 12. A heat-insulating product according to claim 11, characterized in that the protrusion is made tapering towards the cavity, preferably of a pyramidal shape. 13. A heat-insulating product according to claim 1, characterized in that the frame ring is connected to the outer protective sheath by means of separate discrete adhesive joints. 14. The heat-insulating product according to claim 1, characterized in that preferably at least one frame ring is located in the side zone of the heat-insulating product. 15. The heat-insulating product according to claim 1, characterized in that the frame ring is located near the edge of the outer protective shell or the end of the frame ring is placed at a level with the edge of the outer protective shell. 16. The heat-insulating product according to claim 1, characterized in that the frame ring is located in the middle of the composite body. 17. Thermal insulation product according to claim 1, characterized in that the outer protective shell is made of a composite material including layers of polymer and / or foil, for example, of a laminated foil. 18. A heat-insulating product according to claim 1, characterized in that the outer protective shell is made of a sheet of metal or thick foil and / or elastic plastic and is a thin-walled tubular open axisymmetric shell, the ratio of the thickness of which to the inner radius does not exceed 1/20. 19. A heat-insulating product according to claim 1, characterized in that the length of the frame ring is from 1 to 25% of the total length of the outer protective sheath. 20. Thermal insulation product according to claim 1, characterized in that the frame ring is made of mineral wool with a density of more than 50 kg / m ³ , or of foamed polymer with a density of more than 30 kg / m ³ , or of foam glass, or expanded vermiculite or perlite with a density of more than 80 kg / m ³ . 21. The heat-insulating product according to claim 1, characterized in that the outer protective shell within the placement of at least one frame ring has locking elements for the possibility of coupling with the shell of another heat-insulating product of a similar design. 22. The heat-insulating product according to p. 21, characterized in that the locking elements of the outer protective shell are made in the form of annular bulges curved outward of the outer protective shell.

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