RU208930U1 - Thermal insulation mat with internal fastening - Google Patents

Abstract

The utility model relates to the field of thermal insulation of pipelines, namely to thermal insulation mats, such as lamellar thermal insulation mats. The technical task is to expand the technical means. The technical result consists in the implementation of the purpose of the device. A heat-insulating mat, characterized in that it includes a flexible shell, on which, on its inner side, flexible fastening strips and a heat-insulating layer are placed and fixed, moreover, flexible fastening strips are located between the heat-insulating layer and the sheath, which are also interconnected. 8 w.p. f-ly, 4 ill.

Description

The utility model relates to the field of thermal power engineering, namely to devices used for thermal insulation of pipelines, namely to heat-insulating mats.

The prior art heat-insulating products fixed on pipelines with clamps SU1663253A1, 1991.07.15; RU2016348C1, 1994.07.15 RU2419737C2, 2011.05.27.

The technical task is to expand the technical means.

The technical result consists in the realization of its purpose by the device.

The technical result is achieved due to the fact that the heat-insulating mat, characterized in that it includes a flexible shell, on which flexible fastening strips and a heat-insulating layer are placed and fixed on its inner side, moreover, the flexible fastening strips are located between the heat-insulating layer and the sheath, which are also connected between themselves.

The heat-insulating layer is made of elastic or elastic-yielding and/or crushable heat-insulating material.

The shell is a polymer-based web, preferably reinforced, for example, with glass fiber and having at least one foil layer connected to the base and laminated with a polymer film.

The fastening strips are made in the form of flexible metal or plastic strips.

The flexible sheath is made of a woven or non-woven polymer material.

The heat-insulating layer is made in the form of elongated heat-insulating elements located close to each other, for example, strips, or elongated bars, or lamellas from a heat-insulating material, preferably from a fibrous heat-insulating material, for example, from mineral wool, or from a porous polymer material, for example, polyurethane foam.

The heat-insulating layer is made continuous, for example, in the form of a flexible mat. The fastening strips are additionally secured to the shell by means of a heat-insulating layer 4, preferably by adhesive bonding.

The flexible shell is made rectangular in plan, has elongated sides and sides of shorter length, flexible fastening strips are located along the elongated sides of the shell and are placed between it and the heat-insulating layer.

The strips are fixed on the inner side of the shell by discrete connections, for example, rivets, or by means of adhesive bonding, while the end parts of the strips free from thermal insulation are not fixed on the flexible shell, and go beyond the thermal insulation layer, while, preferably, in the mentioned free parts of the strips holes are made for the passage of fasteners.

It is preferable that the heat-insulating mat includes a flexible shell of a rectangular shape in terms of shape, has elongated sides c and sides of shorter length, flexible fastening strips 3 and a heat-insulating layer are attached to its inner side of the shell, which is made of a stack of elongated heat-insulating elements located close to each other, and fastening the strips are located along the elongated sides of the shell of smaller length, perpendicular to the direction of orientation of the heat-insulating elements that make up the heat-insulating layer, and along one of the long sides there is a shell outlet free from the heat-insulating layer, on which there is an additional extreme flexible fastening strip, not covered with a heat-insulating layer, which is attached to shell, except for its final free part, while the remaining fastening strips are located under the heat-insulating layer and attached to the shell, with the exception of their final free parts, which are not fixed to the shell and are not covered with a heat-insulating layer, holes are made in the said end free parts of the fastening strips for passing fasteners, and along the side of the shell of a shorter length, at the locations of the end free parts of the fastening strips, the shell is released to cover the end parts of the fastening strips, for which the width of the release is chosen larger, than the length of said end parts.

The device is illustrated by drawings.

On FIG. 1 shows an isometric view of the device (thermal insulation layer up).

On FIG. 2 shows the device in plan (thermal insulation layer up) FIG. 3-4 schemes for mounting the device on a pipe.

The heat-insulating mat includes a flexible shell, on which, on its inner side, flexible fastening strips 3 and a heat-insulating layer 4 are placed and fixed. Moreover, flexible fastening strips 3 are located between the heat-insulating layer and the sheath, which are also interconnected, for example, by adhesive bonding.

The heat-insulating layer 4 is made of an elastic or resiliently pliable and/or crushable material.

The shell 1 is a polymer-based web, preferably reinforced, for example, with glass fiber and having at least one foil layer connected to the base and laminated with a polymer film.

The fastening strips are preferably in the form of flexible metal or plastic strips.

The flexible sheath is made of a woven or non-woven polymer material.

It is preferable that the heat-insulating layer 4 is made in the form of elongated heat-insulating elements 5 located close to each other, for example, strips, or elongated bars, or lamellas from a heat-insulating material, preferably from a fibrous heat-insulating material, for example, from mineral wool, or from porous polymeric material, such as polyurethane foam.

The heat-insulating layer can be made continuous, for example, in the form of a flexible mat.

The fastening strips can be additionally fixed to the shell by means of a heat-insulating layer 4, preferably by adhesive bonding.

The flexible shell is made rectangular in plan, has elongated sides and sides of shorter length, while the flexible fastening strips are located along the elongated sides of the shell 1 and are placed between it and the heat-insulating layer 4.

The fastening strips 3 are fixed on the inner side 2 of the shell by means of discrete connections, for example, rivets (conditionally not shown), or by adhesive bonding, while the end parts of the strips 6 free from thermal insulation are not fixed on the flexible shell 1, and go beyond the thermal insulation layer 4, at the same time, holes 7 are preliminarily made in the said parts of the strips for passing fasteners 8, preferably self-tapping screws.

Thus, a heat-insulating mat, characterized in that it includes a flexible shell of a rectangular shape in terms of shape, has elongated sides with a size L and sides of shorter length with a size B (Fig.1-2), flexible fastening strips are attached to its inner side 2 shell 1 3 and a heat-insulating layer 4, which is made of a set of elongated heat-insulating elements 5 located close to each other, and the fastening strips 3 are located along the elongated sides of the shell 1 of smaller length, perpendicular to the direction of orientation of the heat-insulating elements 5 that make up the heat-insulating layer 4, and along one of the long sides there is an outlet 9 of the shell free from the heat-insulating layer 2, on which there is an additional extreme flexible fastening strip 10, not covered with a heat-insulating layer 4, which is attached to the shell with the exception of its final free part 11, while the remaining fastening strips are located under the heat-insulating layer and attached To shell 1, with the exception of their final free parts 11, which are not fixed to the shell and are not covered with a heat-insulating layer 4, holes 7 are made in the said final free parts 11 of the fastening strips 3 for passing fasteners 8, and along the side of the shell 1 of shorter length in places finding the final free parts 11 of the fastening strips 3, 10, the release 12 of the shell is made to cover the end parts 11 of the fastening strips, for which the width of the release b is chosen greater than the length l of the mentioned end parts 11 (Fig.2).

The device is mounted (Figure 3-4), wrapping it around the pipe 13, so that the heat-insulating layer 4 is adjacent to the outer surface of the pipe 13, and the mounting strips 3 are located across the axis of the pipe, after which the device is fixed in one or more places with mounting belts (conditionally not shown) which provide a snug fit (joint) of the edges of the heat-insulating layer and its compression, after which the fasteners 8 are screwed into the fastening strips 3.

In the case when the heat-insulating layer 4 is made in the form of elongated heat-insulating elements 5, for example, mineral wool lamellas, the flexible shell has outlets 9 and 12, while the end parts 11 of the fastening strips are not fixed on the shell, the device is mounted as follows. The shell is wrapped around the pipe, orienting the elongated heat-insulating elements 5 along the longitudinal axis of the pipe, fixing the device in one or several places with mounting belts that provide a snug fit (joint) of the extreme elongated heat-insulating elements 5 (lamellae), while the end parts 11 of the mounting strips 3 are located on top of the shell, above the opposite end parts of 14 fastening strips 3, which are fixed on the flexible shell 1.

Next, raise (turn off) the outlet 12 of the shell (Fig. 3), insert the fasteners (screws) into the holes 7 in the end parts 11 of the fastening strips 3. Next, the fasteners are screwed through the shell into the end parts 14 fixed on the flexible shell 1, after which the release 12 is pressed against the flexible shell, closing the end parts of the fastening strips 3 and fasteners 8, and the outlet 12 is fixed with mounting tape 15 (Fig. 4).

As a result of the tests, an improvement in the insulating and operational properties of the mat was recorded, providing ease of installation by equipping the product with fasteners, ensuring a tighter fit of the heat-insulating layer to the insulated pipe, compared with fixing known mats with wire or tape, increasing the thermal insulation properties of the mounted device by providing more tight coverage of the pipe provided by the strips, and as a result of the absence of sagging, the fastening is hidden and prevents corrosion of the fasteners.

Claims (9)

1. A heat-insulating mat with internal fastening, characterized in that it includes a flexible shell, on which flexible fastening strips and a heat-insulating layer are placed and fixed on its inner side, moreover, flexible fastening strips are located between the heat-insulating layer and the sheath, which are also interconnected. 2. Heat-insulating mat with internal fastening according to claim 1, characterized in that the heat-insulating layer is made of an elastic or resiliently pliable and/or crushable heat-insulating material. 3. A heat-insulating mat with internal fastening according to claim 1, characterized in that the shell is a polymer-based fabric reinforced with fiberglass and having at least one layer of foil connected to the base and laminated with a polymer film, while the fastening strips are made in the form of flexible metal or plastic strips. 4. Heat-insulating mat with internal fastening according to claim 1, characterized in that the flexible shell is made of a woven or non-woven polymer material. 5. Heat-insulating mat with internal fastening according to claim 1, characterized in that the heat-insulating layer is made in the form of elongated heat-insulating elements located close to each other strips, or elongated bars, or lamellas from heat-insulating material, from fibrous heat-insulating material, from mineral cotton wool, or from a porous polymeric material of polyurethane foam. 6. Heat-insulating mat with internal fastening according to claim 1, characterized in that the heat-insulating layer is made continuous, for example, in the form of a flexible mat. 7. Heat-insulating mat with internal fastening according to claim 1, characterized in that the fastening strips are additionally fixed on the shell by means of a heat-insulating layer by adhesive bonding. 8. Heat-insulating mat with internal fastening according to claim 1, characterized in that the flexible shell is made rectangular in plan, has elongated sides and sides of shorter length, flexible fastening strips are located along the elongated sides of the shell and are placed between it and the heat-insulating layer. 9. Heat-insulating mat with internal fastening according to claim 1, characterized in that the strips are fixed on the inner side of the shell by means of discrete rivet joints or by means of adhesive bonding, while the end parts of the strips free from thermal insulation are not fixed on the flexible shell and go beyond the heat-insulating layer , while in the mentioned free parts of the strips there are holes for passing fasteners.

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