RU192070U1 - QUICK RELEASE HEAT INSULATION PRODUCT FOR HEAT INSULATION OF PIPELINE FITTINGS - Google Patents

Abstract

The technical solution relates to the field of power engineering, namely to devices used for thermal insulation of pipelines, mainly for insulation of pipeline valves (valves, valves, flanges, bends, filters, taps, gates, valves, filters, bends, pipe junctions, curved pipe sections and etc.), and can be used on pipelines with temperatures, flowing media in them, above 200 ° C, as well as on low-temperature pipelines with cryogenic media. The technical result achieved in the process of use is declared This thermal insulation product is an increase in the stiffness of the product while reducing heat loss. A removable thermal insulation product, characterized in that it includes detachably interconnected parts, each of which has a base in the form of an open thermal insulation shell, reinforced by supporting frame elements located inside the shell near it end faces made of a heat-insulating material having greater rigidity compared to the shell material, and inextricably connected to the shell. On the outside, the shells are covered with a protective layer of flexible material that connects the parts of the product with the possibility of rotation relative to each other. 1 n and 9 z.p. f-ly, 8 ill.

Description

The technical solution relates to the field of power engineering, namely, devices used for thermal insulation of pipelines, mainly for insulation of pipe fittings (valves, valves, flanges, bends, filters, taps, gates, pipe interchanges, curved sections of pipes, etc.) and can be used on pipelines with temperatures, flowing media in them, over 200 ° C, as well as on low-temperature pipelines with cryogenic media.

Known protective module comprising a housing consisting of two parts connected by quick disconnect fasteners, each wall of which includes at least three layers - an external wear-resistant coating layer forming the outer shell of the shell, the inner layer forming the inner shell of the shell, and heat-insulating located between them layer, while the outer and inner shells are interconnected by means of quick disconnect fasteners, and the heat-insulating layer is made single-layer and fixed between the outer and inner by early layers - (RU 147289 U1, F16L 59/00, 10/10/2014)

A disadvantage of the known module is that the replacement of a worn-out heat-insulating layer or the use of another having better characteristics, due to its fixation between the outer and inner layers, is possible only by replacing the entire device or its parts.

Known mobile heat and sound insulation module for objects of complex geometric shape, containing an outer protective shell, inside which is placed an inorganic or polymer filler, made in the form of an insert with a thickness of 3 mm to 200 mm, having an expanded configuration depending on the geometry of the object of heat and sound insulation, an outer protective shell made in the form of a closed cavity, the internal volume of which is 1.1 volumes of the liner, and consists of reinforced fiberglass with a polymer coating on silicone a new base, tensile strength of which is 3000 N / 5 cm on the base, 1600 N / 5 cm on the weft, and thermal conductivity not more than 0.24 W / (mK), the shell has a shape identical to the expanded form , sewn with either polyamide, or polyester, or water-repellent polyamide yarns, and on the outside of the protective sheath there are rigidly connected elements for fixing and sealing the mobile heat and sound insulation module at the object - (RU 2489636 C1, F16L 59/16, 08/10/2013)

A well-known cover for thermal insulation of objects of complex geometric shape, made of waterproof technical fabric according to the patterns corresponding to the insulated surface, and made in the form of a closed cavity of the coating layer and the inner shell, which is hemmed to the surface of the coating layer immediately adjacent to the object, between the coating layer and the inner the shell is a layer of thermal insulation, and on the outer side of the coating layer are placed rigidly associated with it the elements of fixation and sealing of the cover on The project, characterized in that the inner shell is equipped with a zipper fastener located along the perimeter of the seam connecting the coating layer and the inner shell (RU 174567 U1, F16L 59/16, 10.20.2017).

A protective cover is known, characterized in that it is made antistatic and is a three-dimensional structure having walls equipped with quick-release fasteners, formed by shells placed one in the other so that each of the walls includes at least three layers - an external chemical resistant resistant coating layer with water and oil repellent properties, an inner layer made of heat-resistant and heat-reflecting material, as well as a warming layer located between them, are made from vibration-proof insulation, while the insulation layer is multilayer with adhesive bonding of its layers and freely placed between the inner and outer layers, which are interconnected, at least by means of adhesive tape, while the walls are connected to each other and the fasteners are connected to the walls with the use of heat-resistant products from non-combustible and / or non-combustible materials (RU 90875 U1, F16L 59/00, F16K 49/00, 01/20/2010).

Known thermal insulation for pipelines containing airgel high-temperature insulating layer adjacent to one or more heating elements; and a low-temperature insulating layer adjacent to the airgel high-temperature insulating layer (RU 2499941 C2, 11.27.2013).

The closest analogue to the claimed technical solution is a heat-insulating product made in the form of an annular shell containing an inner layer of deposited airgel (WO 2006133155 A2, 12/14/2006, RU 2419737 C2, 05.27.2011)

The closest analogue to the claimed technical solution is a heat-insulating product, which consists of two interconnected insulation layers, one of which is made on the basis of mullite-siliceous fiber, and the other of mineral wool insulation (RU 92933 U1, F16L59 / 00, 04/10/2010).

The main drawback of the technical solution identified during operation, described in the closest analogue, is compaction due to crushing (compression deformation) of the heat-insulating and compressible compressible layer of mullite-siliceous fiber during installation, as well as under the weight of the upper heat-insulating layer. With significant deformations, the thickness of the mullite-siliceous fiber layer can significantly decrease, which can lead to a loss of thermal insulation properties of the layer, as well as to temperature deformations of the mineral wool insulation.

The technical problem, the solution of which the technical solution is aimed at, is to simplify and increase the efficiency of use due to the possibility of combining the characteristics of materials.

The technical result achieved in the process of using the claimed heat-insulating product is to increase the rigidity of the product while reducing heat loss.

A removable heat-insulating product, characterized in that it includes detachably interconnected parts, each of which has a base in the form of an open heat-insulating shell reinforced by supporting-frame elements located inside the shell at its ends, made of a heat-insulating material having greater rigidity compared to with shell material, and inextricably connected to the shell. On the outside, the shells are covered with a protective layer of flexible material that connects the parts of the product with the possibility of rotation relative to each other.

A removable heat-insulating product, characterized in that the shells are made curved, preferably in the form of halves of a hollow cylinder, while the supporting frame elements are made open and arcuate, for example, C-shaped, preferably in the form of ring parts.

A removable heat-insulating product, characterized in that on the longitudinal side of one of the parts of the product there is a release of the protective layer that overlaps the junction of the parts of the product, and the parts of the product have detachable fasteners made with the possibility of fixing the release of the protective layer of one of the parts of the product on the protective layer of another part of the product e.g. adhesive tapes, tie straps, elastic bands.

Removable heat-insulating product, characterized in that the outer surfaces of the supporting frame elements are covered with a protective layer of flexible material.

A removable insulating product, characterized in that the supporting frame elements are made of heat-resistant materials, preferably of mullite-siliceous materials.

Removable thermal insulation product, characterized in that the supporting frame elements are made of mullite-siliceous material with a density of more than 150 kg / m ³ .

A removable heat-insulating product, characterized in that each shell is made of composite and consists of an external hard or semi-rigid layer and an internal elastic-flexible layer which is preferably made of heat-resistant or heat-resistant, preferably lightweight and fibrous material, with a high degree of compressibility, able to withstand exposure to temperatures above 200 ° C.

A removable heat-insulating product, characterized in that the density of the resilient layer is from 50 to 150 kg / m ³ .

A removable heat-insulating product, characterized in that the resilient layer is made of mullite-siliceous felt or felt, or mullite-siliceous wool, or of needle-punched mullite-siliceous mat.

A removable heat-insulating product, characterized in that the supporting frame elements are made of heat-resistant or heat-resistant material, preferably of mullite-siliceous cardboard or of a mullite-siliceous plate.

The device is illustrated by drawings:

In FIG. 1 is an isometric view of a device.

In FIG. 2 is an isometric view of a device configured to isolate a shutoff valve.

In FIG. 3 and 4 are isometric views of the device with composite parts, each of which has an internal resilient layer.

In FIG. 5 shows the device shown in FIG. 2 mounted on shutoff valves (longitudinal section).

In FIG. 6 shows a device mounted on valves with an additional longitudinal overlap of the protective layer fixed to the pipe.

In FIG. 7-8 shows cross sections at the locations of the supporting frame elements.

The removable heat-insulating product includes interconnected parts 1 and 2, each of which has a base in the form of an open heat-insulating shell 3, reinforced by rigid support-frame elements 4 located inside the shell at its ends 5, which are made of a heat-insulating material having great stiffness and density compared to the shell material, and are inextricably connected to the shell.

Parts 1 and 2 are interconnected with the possibility of rotation relative to each other, docking with each other, and the formation around the insulated object of a closed shell. By a closed shell is meant a shell, the contour of the cross section of which is continuous.

The location of the support-frame elements 4 in the ends of the parts of the product on the one hand is due to the formation of the supporting frame of the product, which it rests on the pipes near the insulated reinforcement and / or on the reinforcement elements. On the other hand, the supporting frame elements 4 also perform the enclosing function and close the ends of the closed shell after joining the parts 1 and 2 of the product, forming a closed space inside the said shell (Fig. 5).

Most preferably, the shells 3 are made of semi-rigid heat-insulating material and are made curved (cylindrical) in the form of half a hollow cylinder, while the supporting frame elements 4 are made open and arcuate (C-shaped) in the form of ring parts (half rings) and are arranged transversely shells 3 with the formation of their ends.

On the outside, the shells are covered with a protective layer 6 of flexible material that connects parts 1 and 2 of the product with the possibility of rotation relative to each other, forming a flexible hinge (flexible hinge). The protective layer 6 is adhesively connected to the shells 3 and is preferably made waterproof composite and / or reinforced. Adhesive bonding in the context of the described technical solution means adhesive bonding or bonding by melt of the polymer part of the protective layer.

On the longitudinal side of one of the parts 1 of the product there is a release 7 of the protective layer 6, which provides overlap of the junction of parts 1 and 2 of the product. Moreover, the parts 1 and 2 of the product have detachable fasteners made with the possibility of fixing the release of the protective layer of one of the parts 1 of the product on the protective layer of the other part of the product 2.

The drawings (Fig. 1-4) show the implementation of detachable fastening in the form of contact textile tapes ("adhesive" tape type Velcro). One of the tapes is attached to the inner side of the outlet 7 of the protective layer 6 of one of the parts 1 of the product and is located along the edge of this outlet and adjacent to it. In this case, another tape is located on the protective layer 6, covering another part 2 of the product, also along the edge of the protective layer, but indented from it.

Unclosed heat-insulating shells 3 of parts 1 and 2 of the product can be made of uniform rigid or, preferably, semi-rigid heat-insulating materials, however, in some cases, they can either be made of composite materials, or of soft and / or flexible heat-insulating materials.

When parts 1 and 2 of the product are made composite, they consist of several layers interconnected. So, for example, each shell 3 of part 1 or 2 of the product may consist of an external hard or semi-rigid layer 8 and an internal resilient layer 9 (Fig. 3-4). Preferably, the resilient layer 9 is made of heat-resistant or heat-resistant, preferably lightweight and fibrous material, with a high degree of compressibility, able to withstand temperatures above 200 ° C.

The elastic-flexible layer 9 ensures maximum adhesion of the insulation to the fittings due to its compression during installation, which ensures the absence of gaps and heat leaks, which is especially important for the use of fittings in high-temperature or cryogenic pipelines. Also, the resilient layer 9 made of heat-resistant or heat-resistant material is able to withstand heat shock and serve as protection for the semi-rigid layer 8 from temperature deformations.

The inner elastically flexible layer 9 can be made of mullite-siliceous material with a density of 50 to 150 kg / m3.

For example, the resiliently flexible layer 9 can be made of mullite-siliceous felt or felt, or mullite-siliceous wool, or of needle-punched mullite-siliceous mat.

Supporting frame elements 4 can be made of heat-resistant or heat-resistant material, for example, of mullite-siliceous material with a density of more than 150 kg / m3, ensuring the constant geometric dimensions of the heat-insulating shells of 3 parts 1 and 2 of the product, preventing them from sagging and sagging. To ensure the above conditions, the supporting frame elements 4 can be made (cut) from mullite-siliceous cardboard or mullite-siliceous plate.

To prevent dust and particles of thermal insulation from entering insulated equipment or fittings, the inner surface of the heat-insulating shells 3 can be glued with a cloth forming the inner protective layer corresponding to the temperature range of use (not shown conventionally in the drawings). As the fabric can be applied fiberglass, basalt or silica fabric.

For cases when it is necessary to seal the heat-insulating shells 3, fabrics can be used, including those listed above, with a silicone coating or other polymer coating or impregnation.

The fabric can be attached to the inner surface adhesively or mechanically, for example, using screeds (such as “fungi”).

The protective layer 6 covering the outer surfaces of the shells 3 can be made of waterproof flexible, including reinforced fiberglass-based coatings with various additional impregnations or an additional coating or covering layers of rubber, polymers, aluminum foil and other materials. The coatings or layers forming the protective layer 6 are glued directly to the shells 3 of parts 1 and 2 of the product and can serve as a kind of hinge joint for quick installation and dismantling of the product.

The shells of 3 parts 1 and 2 of the product can be made of such insulating materials as mineral wool, ceramic wool, foam glass, perlite, foamed polymeric materials. Shell 3 can be made of one of the mentioned materials, or be composite, and combine layers of several of the above materials.

Detachable fasteners, in addition to the mentioned Velcro tapes, can serve both individually and in combination with tension belts with buckles and / or locks.

The size of the outlets 7 to ensure overlapping of the protective layer 6 should ensure that moisture cannot penetrate into the insulation of the shells 3. It is advisable to fix the straps 11 to avoid loss during the periodic dismantling of the product on the protective layer 6 with glue or rivets.

Protective layers (not shown conditionally) similar to the protective layer 6 are also present on the side of the ends of the products, and seal both the ends of the shells and supporting frame elements. At the same time, in order to maximize sealing of the seams and joints of the mentioned protective layers, both adhesive overlaps and overlaps with additional sealing with tape or silicone are used (not shown conditionally).

All joints (places of connectors) of the shells of 3 parts 1 and 2 of the product have thermal locks in the form of protrusions and depressions along the edges of the joined parts (such as overlap, spike groove), or other type of locks. Similarly, locks can have support frame elements 4, for example, lock elements in the form of protrusions or depressions. Or, to form a thermal lock and eliminate lateral displacements, one of the ends of each supporting frame element 4 extends beyond the lower contour of the shell 3 by the amount of displacement of its other end into the shell 3. Thus, the thermal lock can be formed by displacement and / or rotation of the support frame elements 4 with a C-shape inside the curved (cylindrical) shells (Fig. 8).

The ends of the assembled product, in the center of which the supporting frame elements 4 are located, serve as the main bearing and frame-forming parts of the structure. Supporting-frame elements 4 are made of rigid heat-insulating material and are designed to support the pipeline or rigid thermal insulation around the pipeline (not shown conditionally). In addition, the supporting frame elements 4 perform and enclosing function.

The seats at the ends can have an additional overlap of the coating material in order to avoid leakage of moisture, which can also be equipped with a strap or Velcro. Mentioned additional overlap 10 may be formed by longitudinal outlets (Fig. 6) of the protective layer 6 on both sides of the shells and drawn to the pipe or insulation with straps 11 or elastic tapes, while under the additional overlap, in the place of contact with the pipe or pipe insulation sealant or compound to be applied. Shell 3 can be formed from a uniform insulation material and density, as well as composite and combined thermal insulation from different materials, or from layers of homogeneous materials with different densities and thicknesses.

For supporting frame elements, a more rigid heat-insulating and preferably heat-resistant material is chosen, the rigidity and density of which exceeds the similar parameters of any of the shell materials 3.

Outlets for valve stems, cranes and other rebar protrusions also have supporting frame elements 4 at the ends of the shells 3 and corresponding overlaps for sealing with the possibility of fixation to coupling belts (elastic bands) and Velcro.

In the case of products of complex shape, it is possible to use flexible or resilient shells with reversible deformations, while their arrangement is essentially similar to the described rigid or semi-rigid shells.

The proposed device is a heat-insulating product, which combines the simplicity of production and installation, high performance and speed of installation / disassembly, tightness, low maintenance, the possibility of repair at the facility (in case of damage), the ability to adapt to existing conditions during installation, the possibility of application combined (composite) materials, lower cost compared to existing analogues.

Claims (10)

1. A removable heat-insulating product, characterized in that it includes detachably interconnected parts, each of which has a base in the form of an open heat-insulating shell reinforced by supporting frame elements located inside the shell at its ends, made of a heat-insulating material having great rigidity in comparison with the shell material, and inseparably connected to the shell, while on the outside the shells are covered with a protective layer of flexible material that connects the parts of the product I am with the possibility of their rotation relative to each other. 2. A removable heat-insulating product according to claim 1, characterized in that the shells are made curved, preferably in the form of halves of a hollow cylinder, while the supporting frame elements are made open and arcuate, for example, C-shaped, preferably in the form of ring parts. 3. A removable heat-insulating product according to claim 1, characterized in that on the longitudinal side of one of the parts of the product there is a release of a protective layer that overlaps the junction of the parts of the product, and parts of the product have detachable fasteners made with the possibility of fixing the release of the protective layer of one of the parts of the product on the protective layer of another part of the product, for example, adhesive tapes, coupling belts, elastic tapes. 4. A removable heat-insulating product according to claim 1, characterized in that the outer surfaces of the supporting frame elements are coated with a protective layer of flexible material. 5. A removable heat-insulating product according to claim 1, characterized in that the supporting frame elements are made of heat-resistant materials, preferably of mullite-siliceous materials. 6. A removable thermal insulation product according to claim 1, characterized in that the supporting frame elements are made of mullite-siliceous material with a density of more than 150 kg / m ³ . 7. A removable heat-insulating product according to claim 1, characterized in that each shell is made of composite and consists of an external hard or semi-rigid layer and an internal resilient layer, which is preferably made of heat-resistant or heat-resistant, preferably lightweight and fibrous material with a high degree compressibility, able to withstand temperatures above 200 ° C. 8. A removable heat-insulating product according to claim 7, characterized in that the density of the resilient layer is from 50 kg / m ³ to 150 kg / m ³ . 9. A removable heat-insulating product according to claim 8, characterized in that the resilient layer is made of mullite-siliceous felt or felt, or mullite-siliceous wool, or of needle-punched mullite-siliceous mat. 10. A removable insulating product according to claim 1, characterized in that the supporting frame elements are made of heat-resistant or heat-resistant material, preferably from mullite-siliceous cardboard or from mullite-siliceous plate.

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