DE29802495U1 - Wall cassette - Google Patents

Description

The present invention relates to wall cassettes as described by the preamble of claim 1.

When building industrial halls, it is common practice to make the facades of the industrial halls out of steel cassette sheets. However, these steel cassette sheets have very low thermal insulation properties, so that industrial hall facades constructed in this way must be insulated with additional thermal insulation materials. In the usual procedure, thermal insulation panels or similar thermal insulation materials, which usually consist of mineral wool, are arranged between the cassette webs of the steel cassette sheets from which the industrial hall facades are constructed. The problem here is that the cassette webs themselves represent significant thermal bridges, which noticeably worsen the overall insulation value of the facade construction. Attempts are made to counteract this problem, for example, by using additional insulation materials in the area of the cassette webs.

Schaeferstrasse 18 D - 44023 Heme Tel. +49 02323 - 95440 Fax+49 02323-12232

Hainstrasse 20/24
D-04109 Leipzig
Tel.+49 0341 -2113818
Fax+49 0341 -2113818

10. ES - 03002 Alicante Tel.+49 089-745541-0 Fax +49 089 - 7593869

Forstenrieder Allee 59
D -81476 Munich
Tel.+49 089-745541-0
Fax +49 089 - 7593869
PO Box 7105 20
D-81455 Munich

However, it has been shown that these additional insulation materials in the area of the cassette webs cannot be attached properly and do not have a sufficient insulating effect. In addition, the installation of additional insulation materials in the area of the cassette webs represents an additional work step, which disadvantageously increases the overall costs of such an industrial hall façade.

From the document DE-G 91 05 036, wall elements in a cassette construction are known for industrial buildings, into which plasterable insulation panels can be inserted. To avoid thermal bridges in the area of the cassette webs, the insulation panels according to this document are thicker than the cassettes. The insulation panels according to this document are also not compressible, as they must be able to support external plaster and absorb shear forces and wind suction forces. The insulation panels are provided with slot-like recesses with the help of which they are pushed over the cassette webs. In addition, the aforementioned document provides for the provision of flanges on the crossbars of the cassette elements that point both upwards and downwards, which engage in the slot-like recesses provided in them to fix the insulation elements. Apart from the fact that the formation of slot-like recesses in the insulation panels as well as the provision of both upward and downward facing flanges of the crossbars of the cassette elements is extremely costly to manufacture, this system is extremely difficult to install due to the inability to compress the insulation panels, so that even mountable holding strips are provided to make handling the insulation panels easier.

The object of the present invention is to provide a wall cassette that is easy to install, inexpensive to manufacture and eliminates the need for complex retaining elements on the steel cassette sheets into which the insulation panels are installed.

This object is achieved by the characterizing features of patent claim 1, whereby expedient embodiments are described by the characterizing features of the dependent subclaims.

An insulated wall cassette is provided, which can be easily fitted with the insulation material. For this purpose, a strip, preferably projecting downwards, is provided on the horizontal webs of the strips or cassette sheets forming the cassettes in the upper area of the horizontal cassette web, which engages directly in the insulation board and fixes it within the cassette. The external cladding of this industrial hall facade consists preferably of trapezoidal sheets, which are screwed to the metal cassettes or fastened in another suitable way.

The thickness of the insulation panels is greater than the horizontal extension of the cassette webs.

According to the invention, the insulation panels to be arranged in the cassettes are essentially designed to be compressible, so that the area of the respective insulation panel that protrudes beyond the horizontal extension of the cassette webs can be pressed and/or compacted if necessary when fastening the trapezoidal sheets to the metal cassettes, whereby there is no direct contact between the metal of the trapezoidal surface and the metal of the cassette sheets, since the protruding part of the insulation panel covers the cassette web, whereby the inner sheet shell is thermally decoupled from the outer cladding. The disadvantageous effect of heat and/or cold bridges can therefore be significantly reduced in a simple and advantageous manner. The insulation or wall cassette panel with excess thickness is free of prefabricated recesses according to the invention. Rather, it is intended that the downward-facing cassette web flanges in the upper cassette area or the upper cassette sheet are knife- or

claw-like into the material of the respective insulation panel. The fixing of the insulation panels in the cassettes is therefore carried out in a surprisingly simple and advantageous manner by a knife-like or claw-like engagement of the web flanges or by web flange elements arranged at intervals directly into the material of the insulation mat. This can significantly reduce the manufacturing effort for the insulation panel with extra thickness, which is reflected in significantly reduced overall costs for industrial hall facades made from such elements.

In a variant of the present invention, it is possible to provide spacer profiles between the cassette webs and the outer cladding of the industrial hall facade, which preferably consists of trapezoidal sheet metal. These can consist, for example, of simple wooden battens or of profiles made of material with low heat conductivity. With the help of such spacer profiles, it is possible to set the compression of the over-thickness insulation board by fastening the outer cladding of the industrial hall facade, which preferably consists of trapezoidal sheet metal, to a desired value or to avoid this completely, so that impairments of the insulating properties of the over-thickness insulation board can be avoided. Such spacer profiles, which offer the advantage, among other things, that the fastening points for the outer shell of the industrial hall facade are visible and the insulation layer is not subjected to pressure, can be provided on each individual cassette web or only on a certain number of cassette webs, depending on the statics of the industrial hall facade.

In a further variation of the present invention, it is possible to design the insulation or wall box panel with extra thickness as an insulation panel with areas of different densities. In this case, the area of the insulation panel with extra thickness that protrudes outwards over the cassette webs is made of a material with a higher bulk density, whereas the remaining part of the respective insulation panel has a lower strength or bulk density.

The strength setting of the layer of the respective insulation board that protrudes outwards over the cassette webs can be achieved, in addition to the increased bulk density in the case of mineral wool boards, for example, by a corresponding adjustment of the binding agent content and/or the fiber quality of the mineral wool material or by laminating a flat structure of low thickness, such as a glass fleece, glass fabric or the like. The fastening function achieved by the strength setting is concentrated on the layer of the wall cassette boards with excess thickness that protrudes outwards over the cassette webs, whereby the remaining area of the insulation boards can be selected according to the respective requirement profile in terms of thermal conductivity. It is even conceivable to reduce the strength setting to those areas of the insulation board with excess thickness that are in the immediate vicinity of the cassette webs and in which the external cladding of correspondingly constructed industrial hall facades is fastened. The use of such insulation panels with areas of different densities or strengths is conceivable both with the spacer profiles described above and without them.

Further advantages and features of the present invention will become apparent from the following description, taken in conjunction with the accompanying drawings, in which:

Figure 1 shows a partial cross-section through an industrial hall façade made of
Steel cassette sheets with insulation panels;

Figure 2 shows a cross-section through the industrial hall façade

Steel cassette sheets according to Figure 1, with a
external cladding;

Figure 3 shows a cross section through another embodiment of the

Industrial hall façade made of steel cassette sheets with insulation panels
with different density ranges;

Figure 4 shows a cross-section through the industrial hall façade

Steel cassette sheets according to Figure 3, with attached
external cladding;

Figure 5 shows a partial cross-section through the industrial hall façade from

Steel cassette sheets according to Figure 2, with spacers between
Cassette webs and external cladding;

Figure 6 is a detailed view of the cassette web with spacer element according to Figure 5; and

Figure 7 is an isolated cross-sectional view of the spacer element according to Figures 5 and 6.

Figure 1 shows a partial cross-section through an industrial hall facade, which is formed from steel cassette sheets 1 arranged one above the other, which preferably extend between vertical support columns (not shown). These steel cassette sheets 1 have a cassette web 2 at their lower end that projects horizontally in the direction of the outside of the facade. In addition, the steel cassette sheets 1 are also provided at their upper end with a cassette web 3 that projects horizontally in the direction of the outside of the facade, at the end of which on the outside of the facade a flange 4 is provided that projects vertically downwards, preferably in one piece with the upper cassette web 3, which serves for the engagement in the material of an insulation panel element in the manner of a claw, as explained in more detail below. In the embodiment according to Figure 1, a bevel or bend 4a is also provided on the lower edge of the vertical cassette web flange 4.

seen. If, as in the described embodiment, cassettes arranged one above the other are to be held by mutual overlapping, a flange 4' projecting vertically downwards is also provided on the lower cassette edge, which here also has a bevel or angle 4a', which are formed complementarily to the flange 4 and the angle 4a'. When the cassette sheets are arranged one above the other, the lower cassette edge with flange 4' and angle 4a' overlaps the flange 4 and the angle 4a of the upper cassette edge of the cassette sheet arranged below. For this purpose, the cassette web 2 is made longer by the thickness of the flange 4. In the overlapping position, flange 4, 4' and angle 4a, 4a' act as a claw-like engagement element in the material of the insulation board. At the same time, the overlap ensures that the cassettes arranged one above the other are held together. Although the steel cassette sheets 1 in the embodiment shown in Figure 1 are shown as one-piece elements, it is of course also conceivable to provide steel cassettes made up of several elements instead, with the actual cassette being formed by vertically spaced cassette strips, each of which is provided with either the lower horizontal cassette web 2 or the upper horizontal cassette web 3 with the cassette web flange 4 arranged thereon, with both webs 2 and 3 being provided with the flange 4, 4' or the bend 4a, 4a' in the case of mutual cassette support. In a further modification of the last described embodiment, it is also possible to provide steel cassette strip elements in which a lower cassette web 2 and an upper cassette web 3 with a cassette web flange 4 arranged thereon are combined.

Within the cassette formed by the steel cassette sheets of the embodiment shown in Figure 1, an insulation panel element 5 is arranged, which in the embodiment shown is made of compressible mineral wool material. The insulation panels are expediently stretched between the cassette webs with a certain excess width, so that in the

No gaps are created in the joint area and the panels do not fall out during assembly. As can also be seen from Figure 1, the thickness of the respective insulation panel 5 is chosen to be greater than the depth or length of the cassette webs 2 and 3, which can otherwise be designed as a continuous strip or as spaced-apart individual elements. In this case, the cassette web flanges projecting vertically downwards cut or dig directly into the material of the insulation panels arranged between the cassette webs 2 and 3, so that the cassette webs 2 and 3, with their flanges 4; 4' acting as an engagement knife, dig into the insulation panel and hold it inside the cassette. The bends 4a; 4' arranged on the lower edge of the cassette web flanges 4; 4' projecting vertically downwards. 4a' reinforce the knife-like grip and also lead to a positive form-fitting and force-fitting engagement with the respective insulation panel 5, so that a secure fixation of the insulation panels 5 within the steel cassette sheets 1 is ensured.

In order to control the intervention, it is advisable to provide the insulation board with an incision 5' in this area, but without removing any material. The incision is expediently created using a rotating knife. Of course, the depth of the incision 5' is adapted to the engagement claw. As can also be seen from Figure 1, the backs of the steel cassette sheets 1 are profiled to create greater surface stability. The same applies to the cassette webs 2 and 3, which are each provided with protrusions 2a and 3a protruding towards the interior of the cassette. Due to the compressible design of the insulation boards 5, they can adapt to the profiles that increase the surface stability of the steel cassette sheets without leaving gaps. An optimal insulation effect is therefore achieved.

Figure 2 essentially contains the same elements as those already described in Figure 1. In addition, Figure 2

but an external cladding 6 can be seen, which in the embodiment shown in Figure 2 is made of trapezoidal sheets. As can also be seen from Figure 2, the arrangement of the external cladding 6 made of trapezoidal sheets on the cassette webs 2 and 3 of the steel cassette sheets 1 compresses the area of the insulation panels 5 that protrudes outwards beyond the vertical cassette web sheets, without there being any direct contact between the external cladding 6 and the cassette webs 2 and 3 or the vertical cassette web flanges 4; 4', apart from the fastening elements (not shown). In this way, heat and/or cold bridges can be significantly reduced in a safe and simple manner.

Figure 3 again shows the essential elements as in Figure 1. In contrast to the embodiment shown in Figure 1, the insulation panel 5 in the embodiment shown in Figure 3 consists of an insulation panel with areas of different strength or bulk density. As can be easily seen from Figure 3, in the embodiment shown, the area 5a of the insulation panel 5 that protrudes beyond the horizontal extension of the cassette webs 2 and 3 in the direction of the outside of the facade is designed as an area of higher bulk density of the mineral wool material of the insulation panel 5. As can be seen from Figure 4, which again shows essentially the same elements as Figure 3, with external formwork elements 6, preferably in the form of trapezoidal sheets, being arranged on the outside of the facade, the fastening of the external formwork elements 6 to the cassette webs 2 and 3 or to the cassette web flanges 4; 4' to a compression of the areas of higher strength 5a of the insulation board 5, whereby the areas 5a of the insulation board 5 also have a heat-insulating effect. Due to the higher strength of these areas 5a, the compression in the areas of the insulation boards 5 that protrude beyond the horizontal extension of the cassette webs 2 and 3 is less than in the embodiments according to Figures 1 and 2, whereby the overall strength of the entire facade can also be improved, which

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which in turn affects the resistance of facades constructed in this way to wind suction forces and the like.

As far as Figure 5 is concerned, the embodiment according to Figure 2 is essentially shown here with all elements. In contrast, in the embodiment according to Figure 5, one or more spacer profiles 7 are provided for fastening the outer cladding 6, which, as also shown in detail in Figure 6, extend between the cassette webs 2 and 3 and the cassette web flanges and the outer cladding elements 6. These spacer elements 7 are preferably made of a material with low heat conductivity, so that thermal bridges caused by them between the outer cladding elements 6 and the steel cassette sheets 1 are significantly reduced, because thermal bridges simply worsen the overall insulation value of the facade construction. As can be seen from Figure 5, it is possible to provide such spacer elements 7 only on selected cassette webs 2 and 3, depending on the static requirements of the respective facade. The spacer elements 7 can be used to prevent or control compression of the areas of the insulation panel 5 that protrude outwards beyond the horizontally extending cassette webs 2 and 3, which in turn has a positive effect on the overall insulation value of the facade construction.

Finally, Figure 7 shows a possible embodiment of the spacer element 7 as a profile. The spacer profile according to Figure 7 consists of a vertically extending head part 7a to which the external cladding elements 6 are attached, a horizontally inwardly extending area 7b which comes to rest on the cassette webs 2 and to which this area is attached, and a stop flange 7c which projects vertically downwards and is spaced from the vertical head area 7a of the spacer profile towards the inside of the facade, which in the assembled state comes to rest on the cassette web flange 4' and is connected via its spacing to the copy area 7a of the spacer profile.

. 11 .

files the compression of the area of the insulation panel 5 that protrudes towards the outside of the facade can also be adjusted.

Claims (11)

PROTECTION CLAIMS 1. Wall cassette for a building facade in particular, made of wall cassettes arranged one above the other, preferably made of sheet steel, with horizontally projecting cassette webs, at the free ends of which projecting cassette web flanges are provided, and insulation panels arranged between them, the thickness of which is preferably greater than the horizontal extent of the cassette webs and which are held by the cassette web flanges, characterized in that the insulation panels are attached in the wall cassette by knife-like or claw-like engagement of the cassette web flanges (4; 4') directly into the material of the insulation panel (5) which is free of recesses in this area. 2. Wall cassette according to claim 1, characterized in that downwardly projecting cassette web flanges (4; 4') are provided for fastening the insulation panel only in the upper cassette region (3). 3. Wall cassette according to claim 1 or 2, characterized in that bevels (4a; 4a') directed in particular towards the inside of the facade are provided on the lower edge of the cassette web flanges (4; 4'). 4. Wall cassette according to one of the preceding claims, characterized in that the insulation panel is provided with a cut (5') (without removing material) in the area of engagement of the cassette web flanges (4; 4'). 5. Wall cassette according to one of the preceding claims, characterized in that on the cassette webs (2, 3) with the interposition of the areas of the respective insulation board (5) projecting outwards beyond the horizontal extent of the cassette webs (2, 3), external Formwork elements (6) are attached, preferably in the form of trapezoidal sheets. 6. Wall cassette according to one of the preceding claims, characterized in that the insulation panels (5) are formed with regions of different strength, preferably with two or more layers running perpendicular to the cassette webs and preferably with different bulk densities. 7. Wall cassette according to claim 6, characterized in that the region of the insulation panels (5) projecting beyond the horizontal extension of the cassette webs (2, 3) is preferably designed as a region of higher strength (5a). 8. Wall cassette according to claim 6 or 7, characterized in that the region of higher strength (5a) of the insulation board (5) is designed as a region of higher bulk density. 9. Wall cassette according to one of the preceding claims, characterized in that outwardly projecting spacer elements (7) for fastening external cladding elements (6) are provided on at least a selection of the cassette webs (2, 3), which consist of a material with low heat conductivity. 10. Wall cassette according to claim 9, characterized in that the spacer elements (7) are profile-like and have elements (7a, 7b, 7c) for setting a defined distance between the outer cladding elements (6) and the cassette webs (2, 3). 11. Insulation board for insertion into a wall cassette according to at least one of claims 1-10, characterized in that it is made of mineral 1 Λ ^# * ral wool and has a preferably continuous incision (5') on at least one end face.