RU174401U1 - Device for isolating a curved section of the pipeline - Google Patents

Abstract

The technical solution relates to the field of power engineering, and in particular to devices used for thermal insulation of curved sections of a pipeline, such as fittings - bends or elbows. The technical result is to reduce the cost of the device by simplifying its manufacture and reducing the amount of waste. A device for isolating a curved section 1 of pipeline 2 consists of insulating elements 3, each of which has a thickening 4 in its middle part, as well as tapering extreme parts 5, the width of which in the plan decreases in the direction from the middle part to the ends 6 of the insulating elements, this insulating elements are arranged in series and interconnected by a flexible connection 7. 1 n.p. f-ly, 8 wp f-ly, 9 ill.

Description

The technical solution relates to the field of power engineering, and in particular to devices used for thermal insulation of curved sections of a pipeline, such as fittings - bends or elbows.

The prior art known protective shell of thermal insulation of pipe bends. Thermal insulation is encompassed by two plastic half-molds on the longitudinal supporting edges of which are made respectively elements of a snap-on tongue-and-groove joint in the form of grooves and protrusions located in them. On the outer walls of the protrusions and grooves, pins and oblique grooves, respectively, are formed into mutual engagement. The grooves and protrusions are alternately arranged at half the length of each edge of the mold half. All elements of the tongue-and-groove connection are located mirror symmetrically (RU 2000514 C1, F16L 59/16, 09/07/1993).

A prior art device is known for thermal insulation of a shaped article, including a heat-insulating coating, in which the thickness of the heat-insulating coating increases with increasing bending radius of the pipe (RU 111243 U1, F16L 59/16, 12/10/2011).

A known segment of thermal insulation made of fibrous material, which is a three-dimensional body consisting of a main part made of fibrous heat-insulating material, and attached to it at least one end part, also made of fibrous heat-insulating material, but with a greater degree compressibility and / or lower density with respect to the material of the main part (RU 138052 U1, F16L 59/14, 02.27.2014).

A device for thermal insulation, including the installation of composite shells as a coating on pipes and fittings, fastening them with bandages and protecting the joint seams is known. Moreover, foamed rubber in the form of tubes or rolls is used as thermal insulation of pipes and parts of technological pipelines, which are installed in several layers depending on the required thickness of thermal insulation, while segments or sections are used for thermal insulation of connecting parts, thermal insulation joints are glued with glue, and as a protective the shells use a casing made of galvanized steel, while the casing is fixed using self-tapping screws (RU 2530985 C2, F16L 59/14, 10.20.2014).

It is known heat-insulating product containing bandage elements and heat-insulating elements of an elongated shape, enclosed in a shell that covers the side surfaces of the elongated elements and consists of two flexible sheets, one of which is placed on the side surfaces of the insulating elements opposite to the surfaces facing the insulated object, and the other placed on the remaining lateral surfaces of the elongated elements, characterized in that the flexible sheets are connected in between the insulating elements pit segments of metal wire located orthogonally to the retaining elements, the connection of flexible sheets made in the form of stitches, the stitches of which are the same length and evenly alternate on both surfaces of the stitches (RU 97802 U1, F16L 59/02, 09/20/2010).

Closest to the claimed technical solution is a universal heat-insulating belt made by stitching and containing a cover-case, inside of which there is a heat-insulating layer, characterized in that the working surface, which is in direct contact with the surface of the pipeline, the cover-case of the device is made of refractory fabrics, having the property of operation in high temperature mode, and the heat-insulating layer contains one or more layers of heat-insulating material with low thermal conductivity, while on the outer side of the cover-case opposite each other there are chains and hooks and / or belts and buckles, and / or cords, and / or adhesive tapes, the function of which is to fix and fix the device with an overlap on the pipeline (RU 126424 U1 , F16L 59/00, 03/27/2013).

The disadvantage of the closest analogue is the complexity of its manufacture and installation.

The technical result is to reduce the cost of the device by simplifying its manufacture and reducing the amount of waste.

The technical result is achieved due to the fact that the device for isolating a curved section of the pipeline consists of interconnected flexible insulating elements, each of which in plan has a thickening and tapering extreme parts in its middle part, the width of which decreases in the direction from the middle part to the ends of the insulating elements.

The insulating elements are arranged in series and interconnected by a flexible connection.

The flexible bond is a tape, preferably an adhesive tape.

Each of the insulating elements has two mutually perpendicular axes of symmetry.

Each of the insulating elements is made in the plan of a biconvex shape, while the thickening is made convex, and the tapering extreme parts are made at least partially concave, while the bulges of the thickening are associated with concavities of the extreme parts by means of smooth transitions.

Each of the insulating elements includes a layer of thermal insulation.

Each of the insulating elements includes an inner layer of thermal insulation and an external protective layer connected to it, preferably made of lacquered foil.

The thermal insulation layer is made of polymer insulating material.

The thermal insulation layer is made of fibrous insulation material, preferably mineral or ceramic wool.

The outer protective layer of each insulating element has an inlet - an edge protruding beyond the thermal insulation layer.

In FIG. 1 is an isometric view.

In FIG. 2 top view

In FIG. 3, section AA in FIG. 2

In FIG. 4-6 stages of installation of the device on the pipeline section

In FIG. 7 shows an isometric view of a device in which the end parts of the elements have protrusions of the protective layer to overlap the junction of their ends.

In FIG. 8 shows a pattern for cutting a rectangular mat into insulating elements of a preferred shape.

In FIG. 9 shows a pattern for cutting a rectangular mat into diamond-shaped insulating elements.

A device for isolating a curved section 1 of a pipe 2, consists of insulating elements 3, each of which has a thickening 4 in its middle part and tapering extreme parts 5, the width of which in the plan decreases in the direction from the middle part to the ends 6 of the insulating elements,

The insulating elements are arranged in series in a row and interconnected by a flexible connection 7.

It is preferable that each of the insulating elements 3 has two mutually perpendicular axes of symmetry (not shown conventionally in the drawings), each of the insulating elements 3 being made in a biconvex plan, the thickening 4 being made convex, and the tapering edge parts 5 are made at least partially concave, while the bulge 8 of the bulge 4 is associated with concavity 9 of the extreme parts by means of smooth transitions 10.

It is preferable that each of the elements 3 includes an internal (adjacent to the pipe 1 section 2) thermal insulation layer 11 and an external protective layer 12 connected to it, preferably made of a lacquered foil (foil coated on one or both sides with a polymer film - not conventionally shown) .

Flexible connection 7 is a tape, preferably an adhesive tape.

The thermal insulation layer 11 may be made of polymer insulating material.

However, it is preferable that the thermal insulation layer is made of fibrous insulation material, preferably mineral or ceramic wool.

The outer protective layer may have an inlet - an edge protruding beyond the thermal insulation layer to insulate the joints (see Fig. 7, 8).

The device is made as follows. Elements are cut out of a rectangular mat according to the marking shown in FIG. 9 or FIG. 10. The manufacturing process of elements 3 cut out according to the marking in FIG. 9 is more time consuming since requires cutting along curved contours, compared with the elements obtained by cutting in Figure 10, however, this configuration gives a better approximation of the curved section 1 of the pipe 2 with smaller values of the gaps 14 between the longitudinal sides 15 of adjacent elements 3 in assembled form. From the extreme parts — the “halves” and “quarters” of the elements 3 obtained after cutting, it is possible to assemble whole elements 3 by fastening them with duct tape, thus obtaining virtually waste-free production.

The device is mounted as follows. The device is wrapped around a curved section 1 of the pipe 2 so that half of each insulating element 3 is located on both sides of the pipe 2 - as shown in FIG. 4, 5, while the flexible connection 7 is located approximately along the arc of the pipeline having the largest external radius.

Next, wrap parts of the insulating elements 3, having a narrowing 5 in the direction of the part of the curved section with the smallest inner radius, joining the ends 6 of each insulating element 3 and connecting them together with adhesive tape or staples. Next, the longitudinal sides 15 of adjacent insulating elements 3 are joined, attracting them to each other, while compressing the insulation to minimize gaps 14, after which the elements are fixed with adhesive tape segments or staples (Fig. 5).

At the final stage, each joint of adjacent insulating elements 3 is wrapped with a gap 14 with adhesive tape 15. Also, adhesive tape 15 connects the insulated section of the device with thermal insulation 16 on straight sections of the pipeline (Fig. 6).

By means of the claimed device, any types of existing bends can be isolated, including steeply bent bends, while the installation of the device does not require specialized technical skills and time-consuming.

Claims (10)

1. Device for isolating a curved section of the pipeline, characterized in that it consists of interconnected flexible insulating elements, each of which in plan has a thickening in its middle part and tapering extreme parts, the width of which decreases in the direction from the middle part to the ends of the insulating elements. 2. The device according to claim 1, characterized in that the insulating elements are arranged in series and interconnected by a flexible connection. 3. The device according to claim 1, characterized in that the flexible connection is a tape, preferably an adhesive tape. 4. The device according to claim 1, characterized in that each of the insulating elements has two mutually perpendicular axes of symmetry. 5. The device according to claim 1, characterized in that each of the insulating elements is made in the plan of a biconvex shape, while the bulge is convex, and the tapering extreme parts are made at least partially concave, while the bulge of the thickening is associated with concavities of the extreme parts through smooth transitions. 6. The device according to claim 1, characterized in that each of the insulating elements includes a layer of thermal insulation. 7. The device according to claim 1, characterized in that each of the insulating elements includes an inner layer of thermal insulation and an external protective layer connected to it, preferably made of lacquered foil. 8. The device according to p. 6 or 7, characterized in that the thermal insulation layer is made of polymer insulating material. 9. The device according to claim 6 or 7, characterized in that the thermal insulation layer is made of fibrous insulation material, preferably mineral or ceramic wool. 10. The device according to p. 7, characterized in that the outer protective layer of each insulating element has an inlet - an edge protruding beyond the insulating layer.

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