DE29607387U1 - Insulation element - Google Patents

Description

Insulating element

The invention relates to an insulating element of essentially plate-shaped design made of mineral wool, in particular rock wool for the thermal insulation of pipes with a polygonal, in particular rectangular, preferably square cross-section, in particular pipes for the removal of exhaust gases generated during the combustion of fossil fuels in heating systems.

Such insulation elements are known from the state of the art. They are used in particular for the thermal insulation of three-layer chimneys, which consist of a smoke pipe, an insulation layer and casing bricks. The smoke pipe, which consists of pipe sections arranged one above the other, is arranged inside the casing bricks.

Between the casing stones and the pipe sections of the smoke pipe, which can also be constructed in one piece, insulating elements are arranged which consist of mineral wool, in particular stone wool, and are designed in the form of plates.

The smoke pipe is made in particular of coarse ceramic materials, such as fireclay, and can be round or essentially polygonal in cross-section, preferably rectangular, in particular square, with the edges of a smoke pipe with a polygonal cross-section being rounded for flow and material-related reasons. These house chimneys are assembled by first placing casing stones on top of one another using mortar. The number of casing stones, which are shorter for weight reasons, depends on the length of the smoke pipe segments.

i.e. the pipe sections, which are arranged in the casing stones with the insulation elements in between. For this purpose, four plates of the insulation element are normally arranged in the space between the casing stones and the smoke pipe segments. The insulation elements support the smoke pipe against the casing stone and must be fitted very precisely so that complete thermal insulation is achieved, which is not impaired by discontinuities in the area of the insulation elements, i.e. between adjacent insulation elements. Such insulation elements usually have a material thickness of 3 to 5 cm, so that these are relatively thin plates. The high coefficient of friction of the insulation material on the casing stone surface or the surface of the smoke pipe can cause damage to the insulation elements. It is also possible that the high coefficient of friction causes compression of the inserted insulation elements, so that adjacent insulation elements do not lie against one another with their entire edges. In addition, these thin insulation panels tend to bend, so that areas can arise between the casing stone and the smoke pipe that are not sufficiently thermally insulated, since open joints at the joints of the panels significantly reduce the thermal resistance of the insulation layer.

Based on this prior art, the invention is based on the object of creating an insulation element which has good thermal insulation properties for the application in question here, is sufficiently stable and is suitable for wrapping around pipes with a polygonal cross-section, whereby in particular a high thermal resistance is to be achieved.

The solution to this problem provides an insulating element with the features of claim 1.

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In an insulating element according to the invention, it is therefore provided that a number of essentially parallel recesses are arranged in a main surface, which are arranged in a number of groups corresponding to the number of outer surfaces of the pipes and spaced apart from one another. This creates a thermal insulation element that can be easily placed around a pipe, namely a smoke pipe, which pipe has a polygonal cross-section. The recesses are particularly located in the area of the edge areas of the pipe, whereby the recesses make it possible to adapt the insulating element to the outer contour of the pipe in such a way that a dense thermal insulation layer is achieved that has a high thermal resistance. The recesses extend over the entire length or width of the insulating element.

According to a further feature of the invention, each group of recesses has at least two and preferably four recesses. It has proven advantageous to arrange four recesses parallel to one another, with the distance between the recesses being the same. Between the groups of recesses there is a distance which is a multiple of the distance between two adjacent recesses and which is matched to the width of a surface of the smoke pipe.

Preferably, the recesses are designed as V-shaped notches in cross section. This design has the advantage that when the insulation element is arranged on the smoke pipe, the two opposite flanks of the V-shaped notches move towards each other and rest on each other, so that a tight bond of mineral wool is created.

It is also intended that the insulation element consists of mineral wool with a density of 75 to 180. Preferably, the main surface opposite the main surface with the recesses has a lamination and/or coating made of a non-flammable material, such as glass fleece, glass fabric, glass mesh fabric or the like. This lamination and/or coating serves to reinforce the insulation element so that when processing the insulation element, no discontinuities in the thermal insulation arise even when the individual insulation elements are inserted into the space between the casing stones and the smoke pipe.

Finally, according to a further feature of the invention, it is provided that the recesses have a width and a depth that is matched to the thickness of the mineral wool and/or the radius of curvature of the rounded edge areas of the pipeline to be coated.

Further features and advantages emerge from the following description of the accompanying drawing, in which a preferred embodiment of an insulating element according to the invention is shown.
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In the drawing show:

Fig. 1 a section of an insulation element in side view and
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Fig. 2 shows the insulation element used in a three-part chimney between the casing stone and the smoke pipe according to Fig. 1 in a top view.

An insulation element 1 shown in Fig. 1 consists of a mineral wool fleece 2, which has two main surfaces 3 and 4. The mineral wool fleece 2 has a density between 75 and

140 kg/m ³ and is used for the thermal insulation of pipes with a square cross-section, for example a smoke pipe 5 shown in Fig. 2, which consists of fireclay.
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The smoke pipe 5 is made up of several pipe sections arranged one above the other, which are arranged within casing stones 6 (Fig. 2). Between the smoke pipe 5 and the casing stones 6 there is an intermediate space which is filled with the insulation element 1. The outer surface of the smoke pipe 5 lies against the main surface 3 and the inner surface of the casing stone 6 lies against the main surface 4 of the mineral wool fleece 2.

The insulation element 1 is dimensioned in such a way that it covers the entire circumference of the smoke pipe 5 in one piece. In order to simplify the installation of the insulation element 1 on the smoke pipe 5 and in particular to achieve a stable insulation layer with a high thermal resistance, the insulation element 1 is provided with four groups 7 of recesses 8 designed as V-shaped notches in cross section in the main surface 3 of the mineral wool fleece 2. Ribs 9 made of mineral wool 5 with a trapezoidal cross section are arranged between these recesses 8.

In Fig. 1 it can be seen that each group 7 has three recesses 8 or two ribs 9. The groups 7 are arranged at the same distance from each other over the length of the mineral wool fleece 2. This distance is shown in Fig. 1 with the dimension SL.

As can be seen in Fig. 2, the two free edges of the mineral wool fleece 2 meet at a joint 10, whereby joints can be provided in the edge area of the insulation element 1, which further improve the sealing or increase the thermal resistance of the

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Insulation element 1. The joint 10 is arranged approximately in the middle between two groups 7 of the insulation element 1, so that the first and last group 7 are arranged at a distance Sa from the edge area of the mineral wool fleece 2. The distance Sa corresponds to approximately half the distance SL.

Furthermore, the distance Sp is indicated in Fig. 1, which indicates the distance between two adjacent recesses 8 in their groove base. The distance Sp is many times smaller than the distance SL.

The recesses 8 have a width and a depth k that are matched to the thickness of the mineral wool fleece and the radius of curvature of the rounded edge areas of the smoke pipe 5. In the illustrated embodiment, the recesses 8 are cut very deeply into the mineral wool fleece 2. In order to reinforce the mineral wool fleece 2, in particular in the area of the recesses 8, a lamination 12 is applied to the main surface 4, which consists of a non-flammable material, for example a glass fleece, a glass fabric or a glass mesh fabric.

Finally, Fig. 2 shows the widths of the insulation element 1 applied to the smoke pipe 5 and of the smoke pipe 5, on the one hand with the dimension bm (insulation element 1) and on the other hand with the dimension ra (smoke pipe 5). The difference between the distance bm and the distance ra then corresponds again to the material thickness rm of the mineral wool fleece.

Claims (6)

Il I ·· · jtafeenfeclaims 1. Insulating element (1) of essentially plate-shaped design made of mineral wool, in particular rock wool for thermal insulation of pipes with a polygonal, in particular rectangular, preferably square cross-section , in particular pipes for the removal of exhaust gases produced during the combustion of fossil fuels in heating systems, wherein in a main surface (3) several, essentially parallel recesses (8) are arranged, which are arranged in several groups (7) corresponding to the number of outer surfaces of the pipe and spaced apart from one another. 2. Insulating element according to claim 1, characterized in that each group (7) has at least two and preferably four recesses (8). 3. Insulating element according to claim 1, characterized in that the recesses (8) are designed as V-shaped notches in cross section. 4. Insulating element according to claim I ₁ characterized by a mineral wool density of 75 to 14o kg/m ³ . 5. Insulating element according to claim 1,
characterized in that the main surface (3, 4) arranged opposite the main surface (3) with the recesses (8) has a lamination (12) and / or coating made of a non-combustible material, such as glass fleece, glass fabric, glass mesh fabric or the like 6. Insulating element according to claim 1,
characterized in that the recesses (8) have a width and a depth (k) which are adapted to the thickness (rm) of the mineral wool and/or the radius of curvature of the rounded edge regions (11) of the pipeline to be coated.