DE29609674U1 - Multi-layer insulation module for structures as well as moisture-insulated structures - Google Patents

Description

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Multi-layer insulation module for building structures and moisture-insulated structures

The innovation concerns a multi-layer solar module for buildings and moisture-insulated buildings.

A well-known and yet unsolved problem is the penetration of moisture into building structures, such as balcony cantilever slabs, slab floors and basement walls. Groundwater penetrates basement floors and walls, while balcony cantilever slabs or flat roofs often show leaks when it rains. This problem does not only affect older buildings (mostly those in need of renovation). In particular, with building elements for prefabricated house systems and with the modular construction used for larger building units, the aspect of moisture impermeability or insulation is of particular importance when manufacturing the individual building structures. The underlying problem is always the same in principle.

Attempts have long been made to prevent moisture from penetrating by coating the affected structures with plastic. However, a satisfactory solution that really solves the problems permanently has not yet been found. Plastic coatings are very vulnerable for many reasons. First of all, plastic ages very quickly, so that cracks appear and moisture can penetrate. This process is always accelerated when the coated structure is subject to large thermal expansion and cold shrinkage, which causes cracks in the coating, for example at the wall connections and in the coating surfaces. The expansion coefficient of the plastics used differs considerably from the expansion coefficient of the building materials, so that tensions arise between the layers. This also reduces the adhesion between the plastic and the coated structure and the plastic layer bursts.

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quickly. At the same time, the formation of condensate prevents a proper bond from forming, and bubbles form.

Insofar as floor coverings are to be insulated against moisture penetration, an additional disadvantage with conventional insulation is that it has not yet been possible to develop suitable construction systems based on plastic or other materials that would enable a satisfactory attachment of a permanently resilient surface without it easily coming off again or damaging the insulating base. The desired results could not be achieved, for example, by applying the surface, such as tiles, to a metal sheet plate insulating the structure using an adhesive layer. The bond between the surface and the metal sheet regularly did not withstand long-term stress, with the result that tiles, for example, came off either individually or in large groups.

There is therefore a need for building structures, particularly for prefabricated house systems and for modular construction, that have reliable and permanent insulation against moisture, as well as for insulation systems, particularly for horizontal building structures, that allow the reliable installation of a usable surface.

One of the aims of this innovation is therefore to develop moisture-insulated structures that no longer have the disadvantages described when using plastic coatings. Cracking should be avoided and good adhesion of the insulation to the structure should be achieved. Tensions caused by different thermal expansions of the layers placed on top of each other should also be prevented. After insulation, any residual moisture in the structure should be able to dry out. The composite of the building support and the insulating coating applied to it should also form a durable unit and be easy to manufacture.

Another innovative task is to develop horizontal, moisture-insulated building structures that have a permanently resilient usable surface and that do not have the disadvantages of conventional building systems described.

According to the innovation, moisture-insulated structures are now proposed, which are characterized by the fact that they have a metal sheet plate embedded in an adhesive layer. A polyurethane adhesive is preferably used for bonding. Neighboring plates advantageously overlap at the edges and can also be bonded together. It is advantageous to use sheet metal plates made of chromium-nickel steel, copper, zinc, aluminum or galvanized iron sheet. Chromium-nickel steel in particular is particularly suitable because the thermal expansion coefficient of chromium-nickel steel is approximately the same as that of reinforced concrete, so that there can be no tension between the coated structures and the coating. The chromium-nickel sheets are also corrosion-resistant. The sheet metal plates that are bonded to the structure can also be sandblasted and heat and/or acid-treated for optimal durability and adhesion. It is also conceivable that the plates are slightly corrugated to increase their stability.

In a preferred embodiment, the surface of the sheet metal plates is covered with an adhesive layer of fire-dried quartz sand, among other things to increase corrosion resistance and resistance to external influences. A polyurethane adhesive is again preferably used to bond the quartz sand.

Furthermore, moisture-insulated structures are proposed, which are characterized by the fact that they have the layer sequence structure / adhesive layer (2) / metal sheet plate (3) / adhesive layer (6) / quartz sand layer (7) / adhesive layer (8) / usable surface (9). This means that attempts are no longer being made, as has been the case up to now, to apply a usable surface directly to a plastic or metal sheet substrate. Instead, it was surprisingly found that

shows that a reliable bond between the working surface and the insulating substrate is always achieved when an intermediate layer of quartz sand is inserted. Working surfaces can be applied to this rough surface using the usual adhesives. A mineral acrylic-based adhesive is ideal. Tiles, panels, strips, etc. can be used as working surfaces. Only with the new layer sequence of adhesive / quartz sand / adhesive / working surface is it possible to achieve an insulation that prevents the penetration of moisture and at the same time is a reliable basis for the application of a working surface. The new insulation module has the advantage that the working surface has a permanently good bond to the sheet metal plate even under permanent load, unlike when it is applied directly to the sheet metal plate without an adhesive and quartz sand layer.

In addition, an insulation module for moisture insulation of, in particular, horizontal structures is proposed, consisting of a metal sheet plate (3) / adhesive layer (6) / quartz sand layer (7) / adhesive layer (8) / usable surface (9). In particular for structures that need to be subsequently protected against the ingress of moisture, the prefabricated insulation module according to the innovation allows for quick and reliable insulation of structures. The size of the insulation modules can be adapted in advance to the areas to be insulated, which means that even larger areas or those with a more complicated scope can be sealed against moisture penetration quickly and easily by gluing the metal sheet base and the structure, e.g. with a polyurethane adhesive.

For structures that are free at the bottom, such as freely hanging balcony cantilever slabs, it is sufficient to glue the described sheet metal panel systems in a uniform adhesive bed. For inhabited areas below, such as roof terraces or areas where rising moisture occurs from below, such as basement floors and walls, it is advantageous to create the adhesive bed with continuous recesses directed towards the wall connection.

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The metal plates do not lie flat, but leave flat air channels between the building and the coating. The building to be insulated usually has residual moisture. They therefore still have to dry out after insulation. Buildings that are free to the bottom dry out completely within a short time after insulation. However, in buildings that are inhabited below, the steam pressure cannot easily escape downwards. In addition, new moisture is constantly being created in inhabited rooms, which penetrates the ceiling and must be drained upwards. The steam can be guided along the recesses in the adhesive bed to the wall connection and escape there. In tests, adhesive layers approx. 10 cm wide, separated from each other by approx. 5 cm wide recesses, have proven to be effective.

The wall connection of a building surface that has been insulated in accordance with the new regulations can be made with an angled sheet that is placed from above on the sheet closest to the wall. The angled sheet is preferably glued to the sheet metal coating. It is advantageous for the vertical leg of the angled sheet to run at a distance from the wall. Vapors that are discharged through the recesses in the adhesive bed can then escape between the wall and the angled sheet or be guided by another facing sheet to the floor surface and escape there.

The new insulation systems have the advantage of being permanently resistant to damage, cracks and the like.

The new structures are explained in more detail in the attached illustration:

The illustration shows the new construction element of a balcony cantilever slab 1 with the layer sequence building body / adhesive bed (2) / metal sheet plate (3) / adhesive bed (6) / fire-dried quartz sand layer (7) / adhesive layer (8) / usable surface (9). The balcony cantilever slab 1 is first provided with an adhesive bed 2 made of polyurethane adhesive. The adhesive bed can

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Have recesses in the adhesive layer that run in the direction of the wall connection 11. This is particularly advantageous if it is not a freely hanging balcony cantilever plate, but an inhabited area below, such as a roof terrace. Sheet metal plates 3 made of chrome-nickel steel are then glued to the adhesive bed 2 with overlapping edges. The overlapping areas of the sheets are also glued to one another.

The wall connection is covered with an angle plate 4, which is glued from above to the sheet metal plate 3a closest to the wall connection. Preferably, the vertical leg 4a of this angle plate can run at a small distance from the wall 5. Water vapor, which is guided through the recesses in the adhesive bed under the sheet steel plates 3 to the wall connection, can then escape upwards.

A further adhesive layer 6 made of polyurethane adhesive can be applied to the steel sheet plates 3. This adhesive layer is sprinkled with fire-dried quartz sand 7. Only then does an adhesive bed 8 made of MineraS acrylic-based adhesive adhere to the steel sheet plates 3, into which tiles, for example, can be glued as a usable surface 9.

To improve the appearance and to prevent water seepage, seal panels 10 can be installed along the wall connection, which are sealed against the wall 5 at the top with sealing compound 12. Water vapor escaping from behind the angled sheet is guided downwards by the screens and diverted along their edge to the tiles.

It goes without saying that the adjacent vertical wall element can also be clad in accordance with the renovation. The cladding must be extended to the wall, for example in damp cellars where moisture penetrates through the floor and wall. The wall is then clad from the floor up to the height to which it is damp. The

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The sealed screen 10 is again attached to the upper end of the panel.

Claims (18)

Protection claims 1. Moisture-insulated building structures, characterized in that the building structures have metal sheet panels (3) embedded in an adhesive layer (2). 2. Moisture-insulated building structure according to claim 1, characterized in that the sheet metal plates (3) have on their surface a quartz sand layer (7) embedded in an adhesive layer (6). 3. Moisture-insulated building structures according to claims 1 and 2, characterized in that the building structures have the layer sequence building structure / adhesive layer (2) / metal sheet (3) / adhesive layer (6) / quartz sand layer (7) / adhesive layer (8) / usable surface (9). 4. Moisture-insulated building structures according to claims 1 to 3, characterized in that the sheet metal plates (3) consist of chromium-nickel steel, copper, zinc, aluminum or galvanized iron. 5. Moisture-insulated building structures according to claims 1 to 4, characterized in that the sheet metal plates (3) are sandblasted, heat-treated and/or acid-treated. 6. Moisture-insulated building structure according to claims 1 to 5, characterized in that the sheet metal plates (3) are corrugated. 7. Moisture-insulated building structures according to claims 1 to 6, characterized in that a polyurethane adhesive is used for the adhesive layer (2). 8. Moisture-insulated building structures according to claims 2 to 7, characterized in that a polyurethane adhesive is used for the adhesive layer (6). -2- 9. Moisture-insulated building structure according to claims 2 to 8, characterized in that the layer (7) consists of fire-dried quartz sand. 10. Moisture-insulated building structure according to claims 1 to 9, characterized in that the adhesive layer (2) has continuous recesses directed towards the surface (11) of the building structure (1). 11. Moisture-insulated building structures according to claims 3 to 10, characterized in that a mineral-acrylic-based adhesive is used for the adhesive bed (8). 12. Moisture-insulated building structures according to claims 3 to 11, characterized in that tiles are used as the usable surface (9). 13. Insulation module for building structure consisting of metal sheet (3) / adhesive layer (6) / fire-dried quartz sand layer (7) / adhesive layer (8) / usable surface (9). 14. Insulating module according to claim 13, characterized in that a polyurethane adhesive is used for the adhesive layer (6). 15. Insulating module according to claim 13 or 14, characterized in that the sheet metal plates (3) consist of chromium-nickel steel, copper, zinc, aluminum or galvanized iron. 16. Insulation module according to claim 13 to 15, characterized in that the sheet metal plates (3) are sandblasted, heat and/or acid treated. 17. Insulating module according to claim 13 to 16, characterized in that
For the adhesive bed (8) a mineral acrylic based adhesive is used
becomes. -3- 18. Insulation module according to claim 13 to 17, characterized in that tiles are used as the usable surface (9).