RU192081U1 - THERMAL INSULATION PRODUCT WITH SIDE ENDS - Google Patents

Abstract

A heat-insulating product with end protrusions, characterized in that it is made in the form of a volumetric curvilinear open shell, on one end of which there is an inner protrusion, the inner side of which is curved and bounded by the inner curved surface of the shell, while the outer side of the inner protrusion is made flat, and on the opposite end of the shell has an external protrusion, the outer side of which is made curved and bounded by an external curved surface about span of, the inner side of the inner projection is flat.

Description

The technical solution relates to the field of power engineering and is a heat-insulating device for insulation of pipes with end protrusions designed to form overlapping joints of elements along the length of the pipe (thermal locks) to prevent heat leakage in the joints.

Currently, cylindrical elements for insulation of pipelines without end locks are most widely used. However, when the temperature of the coolant in the pipe exceeds 150 degrees Celsius, it is necessary to arrange a second insulation layer with a shift in the separation of the end joints to eliminate intense heat loss, which significantly increases the labor cost and cost of the thermal insulation device.

Thermal insulating elements with end locks are known from the prior art, but all of them are laborious to manufacture. Examples of such locks are given in the links below.

A heat-insulating element is known from the prior art, comprising heat-insulating liners in the form of hollow half-cylinders made of heat-insulating material and a protective shell that is fixed on their surface, while the longitudinal edges of the heat-insulating liners facing each other are provided with curly protrusions and grooves corresponding to them in cross-sectional shape, with this width of the protrusion exceeds the width of its portion adjacent to the longitudinal edge. The heat-insulating element is made with the possibility of forming end thermal locks due to the fact that its ends are made beveled (RU 58655 U1, 11.27.2006).

A heat-insulating element is known, which is a shell of mineral wool clad in aluminum foil based on basalt rocks made with U-shaped castle joints along the length and ends of mineral wool (RU 2611925 C1, 03/01/2017 and RU 2661563 C2, 07/17/2018) .

The closest analogue to the claimed technical solution is a heat-insulating element, which is made in the form of a half-cylinder module, the inner 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, (RU 24263 U1, 07.27.2002)

The technical result is to simplify the manufacture of the element, which is achieved due to the fact that the end protrusions have flat surfaces, the formation of which does not require laborious curvilinear cuts for the manufacture of end elements, but it is enough to make two straight cuts at right angles to each other.

The technical result is achieved due to the fact that the heat-insulating product with end protrusions is made in the form of a volumetric curvilinear open shell, at one end of which there is an internal protrusion, the inner side of which is curved and bounded by the inner curved surface of the shell, while the outer side of the inner protrusion is made flat, moreover, on the opposite end of the shell there is an external protrusion, the outer side of which is curved and bounded by an external curvature hydrochloric surface shell, wherein the inner side of the inner projection is flat.

The end face of the inner protrusion is made flat and perpendicular to the outer side of said protrusion, while the end face of the outer protrusion is also made flat and perpendicular to the inner side of said protrusion.

The heat-insulating product has two flat longitudinal sides located perpendicular to curved surfaces and shells.

The heat-insulating product has two flat longitudinal sides on which longitudinal locking elements can be made, for example, a protrusion located on one longitudinal side of the product and a depression located on the other longitudinal side of the product.

The outer flat end part of the product is adjacent to the outer side of the inner protrusion at a right angle with the formation of the outer ledge, while the inner flat end part of the product is adjacent to the inner side of the outer protrusion at the right angle to form the inner ledge.

The outer dimension of the outer protrusion is equal to the width of the product, while the inner dimension of the outer protrusion is equal to the outer dimension of the inner protrusion.

The insulating product may be made of fibrous insulation, preferably mineral wool, or of a porous insulation, preferably of foamed polymer.

Preferably, the insulating product is made elongated, and its length exceeds its width or thickness.

The shell is made in the form of part 1 / n of the hollow cylinder, where n≥3, preferably in the form of 1/4, or 1/6, or 1/8 of the part of the hollow cylinder.

In FIG. 1 shows an isometric view of the product from the side of the inner protrusion.

In FIG. 2 shows an isometric view of the product from the side of the outer protrusion.

In FIG. Figure 3 shows an isometric view of four products joined together to form a closed shell around the pipe (view from the side of the internal protrusions).

In FIG. 4 is an isometric view of four products joined together to form a closed shell around the pipe (view from the side of the outer protrusions).

In FIG. 5 shows a serial assembly of products on a pipe (isometric view).

The heat-insulating product with end protrusions 1 and 2 is made in the form of a volumetric curvilinear open shell, on one end of which there is an inner protrusion 1, the inner side of which is curved and bounded (formed) by the inner curved surface 3 of the shell, while the outer side 4 of the inner protrusion 1 is made flat (Fig. 1).

At the opposite end of the shell there is an outer protrusion 2, the outer side of which is curved and bounded (formed) by the outer curved surface 5 of the shell, while the inner side 6 of the inner protrusion is made flat.

The curved surfaces of the open shell are cylindrical and arranged concentrically, the generators of which have radii drawn from one point (lying on one straight line).

The end face 7 of the inner protrusion 1 is made flat and perpendicular to the outer side 4 of the said protrusion 1 (Fig. 1), while the end face 8 of the outer protrusion 2 is also made flat and perpendicular to the inner side 6 of the said protrusion (Fig. 2).

The heat-insulating product is made in the form of a part of a hollow cylinder and has two flat longitudinal sides (faces) 9 and 10 located perpendicular to the curved surfaces 3 and 5 of the shell.

It is preferable that on the flat longitudinal sides 9 and 10 there are made longitudinal locking elements of the thorn-groove type, ledges, bevels, etc.

The drawings show the longitudinal locking elements, which are a protrusion 11 located on one longitudinal side 10 of the product and a cavity 12 located on the other longitudinal side of the product. Mentioned protrusion 11 and the cavity 12 perform the entire length of each longitudinal side 9 and 10 of the shell, including the inner protrusion 1 of the product.

The outer flat end portion 13 of the product is adjacent to the outer side 4 of the inner protrusion 1 at a right angle with the formation of the outer ledge 14 (Fig. 1), while the inner flat end portion 15 of the product is adjacent to the inner side 6 of the outer protrusion 2 at a right angle to form the inner ledge 16 (Fig. 2). The depth h of the outer and inner steps 14 and 16 (the size of the protrusions 1 and 2) is the same and can range from 10 mm to 70 mm, depending on the size of the product, determined by the diameter of the insulated pipe.

The outer dimension B of the outer protrusion 2 is equal to the width of the product, while the inner dimension of the outer protrusion 2 is equal to the outer dimension b of the inner protrusion (Fig. 1-2). That allows you to completely block the end joints along the length of the pipe (Fig. 5).

The heat-insulating product may be made of fibrous insulation, preferably mineral wool, or of porous insulation, preferably of foamed polymer, for example polyethylene or rubber.

The thickness of the protrusions is variable in width, however, in any longitudinal section drawn radially (perpendicularly) to the surfaces forming the shell, the sum of the thicknesses of the protrusions will be equal to the thickness T of the shell (Fig. 5).

The heat-insulating product is made elongated, so that its length L exceeds its width B or thickness T and is intended mainly for insulation of pipes of medium and large diameters. Moreover, to create a closed shell around the pipe, at least three, and preferably at least four heat-insulating products are used, as shown in FIG. 3-4. For insulation of pipes of large diameters, 6-8 or more heat-insulating products of the described construction can be used.

Thus, the shell is made in the form of part 1 / n of the hollow cylinder, where n≥3. Preferably, in the form of 1/4, or 1/6, or 1/8 of the hollow cylinder.

In this case, each of the protrusions 1 and 2 is formed by two cuts at the ends of the hollow cylinder and the removal of the clipped part. One of the cuts is carried out in the plane parallel to the radial axis of symmetry 17 of the part of the hollow cylinder, and the other in the plane perpendicular to it.

Products of the described construction are mounted on the pipe as follows. Consistently join together the insulating products, forming a closed shell on the pipe (Fig. 3-4). In the case of longitudinal locking elements of the "thorn-groove" type, which is most preferred, the products are joined in a closed cylindrical shell by means of these elements. In the absence of the mentioned elements, or in the case of the execution on the longitudinal sides of the longitudinal locking elements in the form of ledges or bevels (not shown conventionally in the drawings), the products are fastened together with the formation of a closed cylindrical shell by wire or tape. After the formation of a closed cylindrical shell around the pipe, the next closed shell is formed, sequentially superimposing the products with external protrusions on the internal protrusions of the previous closed shell so that their flat sides are in contact, joining the products along the longitudinal sides. After the thermal insulation device, an external protective layer is formed around the entire length of the pipe around it.

Using the proposed product will significantly reduce labor costs during installation compared to analogues without end lock elements by eliminating the need for an additional heat-insulating layer and significantly reduce labor costs when forming end lock elements compared to analogues with end lock elements of a more complex shape.

Claims (9)

1. A heat-insulating product with end protrusions, characterized in that it is made in the form of a volumetric curvilinear open shell, at one end of which there is an inner protrusion, the inner side of which is curved and bounded by the inner curved surface of the shell, while the outer side of the inner protrusion is made flat, moreover, on the opposite end of the shell there is an external protrusion, the outer side of which is made curved and bounded by an external curved surface about bolts, while the inner side of the inner protrusion is made flat. 2. The heat-insulating product according to claim 1, characterized in that the end face of the inner protrusion is made flat and perpendicular to the outer side of the protrusion, while the end face of the outer protrusion is also made flat and perpendicular to the inner side of the protrusion. 3. The heat-insulating product according to claim 1, characterized in that it has two flat longitudinal sides located radially curved surfaces of the shell. 4. The heat-insulating product according to claim 1, characterized in that it has two flat longitudinal sides on which longitudinal locking elements are made, for example, a protrusion located on one longitudinal side of the product and a cavity located on the other longitudinal side of the product. 5. The heat-insulating product according to claim 1, characterized in that the outer flat end part of the product is adjacent to the outer side of the protrusion at right angles with the formation of the outer ledge, while the inner flat end part of the product is adjacent to the inner side of the outer protrusion at right angles to form internal ledge. 6. The heat-insulating product according to claim 1, characterized in that the external dimension of the outer protrusion is equal to the width of the product, while the inner dimension of the outer protrusion is equal to the outer dimension of the inner protrusion. 7. A heat-insulating product according to claim 1, characterized in that it is made of fibrous insulation, preferably mineral wool, or of porous insulation, preferably of foamed polymer. 8. The heat-insulating product according to claim 1, characterized in that it is made elongated, and its length exceeds its width or thickness. 9. The heat-insulating product according to claim 1, characterized in that the shell is made in the form of part 1 / n of the hollow cylinder, where n≥3, preferably in the form of 1/4, or 1/6, or 1/8 of the hollow cylinder

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