DE4110454C2 - Thermal insulation system with panels and method for surface treatment of these panels - Google Patents

Description

The invention relates to a thermal insulation system with panels made of hydrophobized Mineral fiber insulation, in particular basalt fiber insulation, which is the characteristics of the preamble of claim 1, and a method for Surface treatment of such plates.

Such a thermal insulation system is known from DE 40 32 769 A1. This document describes a thermal insulation system with panels fiber-reinforced insulation material, one side of the system on the with the Thermal insulation system to be provided supports, and with one the other Side of the panels as well as the seamless joints between adjacent panels covering coating. The plates have an extension of the essentially parallel fibers between the am Carrier side and the side covered by the coating. The consisting of a wetting binder and in the insulation penetrating coating is free of reinforcement fabric. The one with the present  Invention identical features of the known from this document Thermal insulation systems form the preamble of claim 1.

DE 90 04 776 U1 shows a mounting tool for applying a spreadable adhesive, especially on hydrophobic mineral fiber boards teeth arranged next to one another transversely to the direction of movement along the Edge of a plate.

DE 90 13 146 U1 describes one made from individual fibers, in particular from Rock wool composite insulation mat for insulation of buildings, which is connected to the outward-facing surface of the building wall and has an orientation of the individual fibers, with another Protective layer is provided.

DE 34 17 332 A1 shows a method for producing structures inorganic fiber based on silicone resin.

DE 36 16 454 A1 describes an aqueous emulsion of a water-insoluble additive for insulation made from mineral fibers.

The publication "Thermal insulation composite systems on mineral fiber insulation boards" by E. Roschild and H. Wagner, in: Zeitschrift für Wärmeschutz, Käleschutz, Schallschutz, Brandschutz, Issue 9, (1979), pp. 13 to 15, shows the advantages of Mineral fiber insulation boards in thermal insulation composite systems in connection with mineral cleaning.

The publication "SILLAN acoustic ceiling" by Grünzweig and Hartmann AG, No. 250 dated January 30, 1972, pp. 1 to 6 and the publication "Außenwand- Insulation with BASALAN facade insulation boards "by Reinhold and Mahla vom  October 3, 1972, pp. 1 to 10, show further areas of application for Thermal insulation systems.

DE 31 10 967 A1 describes adhesive and / or coating compositions the basis of alkali metal silicate solutions and their use.

In the Römpps Chemical Lexicon, 8th edition, Franckh'sche Verlaghandlung Stuttgart (1988), p. 4593, the term "water glass" is explained.

DE 88 02 288 U1 shows an inorganic insulation board with a Insulation layer made of mineral fibers, especially rock wool, and with at least a one-sided top layer.

The publication "Mineral facade insulation boards for non-combustible Wärmedämm-Verbundsysteme ", the Bauzentrum, 5/88, pp. 34 and 35, shows one Plaster base coating with a closed insulation surface arises. This will make the water repellent effect of the hydrophobized Facade insulation panels reinforced.

DE 32 48 663 shows a facade or roof insulation panel Mineral fibers and a process for their production.

DE 24 55 691 C2 shows a thermal insulation board through one side applied coating of water glass is impregnated.

DE 33 40 556 C1 shows an insulation system for joints between the In-situ concrete individual shells of partition walls and associated insulation boards.

In thermal insulation systems of the type mentioned at the beginning, the panels need not to be attached to the carrier with dowels. Rather, they can do what  is cheaper to be glued to the carrier. However, at the gluing the application of the glue is done very intensely to a reliable connection with high strength values between the panels and to reach the carrier. Because of the hydrophobization of the plates wetting with aqueous adhesives difficult.

The invention is therefore based on the object of having a thermal insulation system Plates of the type mentioned and a method for To provide surface treatment of these panels, which is a sticking of the Sheets and thus an application of the thermal insulation system on the carrier enables easier and cheaper.

This object is achieved by a thermal insulation system according to claim 1 and solved by a method for surface treatment according to claim 7.  

The always dusty surface of the panels is in the areas provided with the solution largely from dust free and the hydrophobization in the surface zone of this Areas so far removed that the binder in which it is preferably a plastic-tempered, hydraulic setting adhesive acts without forced wetting on the plat surface can be applied without doing anything special Precautions such as B. incorporating the adhesive into the Plates to have to hit. This is due to, that the highly hydrophobic even in the area of their surface Plates by wetting with the solution according to the invention be hydrophilized on the surface, which means that a tempered, hydraulically setting adhesive the surface of the slat wetted so far that a full-surface gluing without further ado can be achieved.

Since preferably the thickness of the layer wetted by the solution the plates do not exceed approx. 2 mm, and also the wetted areas remain permeable to air essential properties of the plates, namely the total hydro phobia and air permeability, not affected.

In a preferred embodiment, they are also attached to one another the abutting surface areas of the plates by means of the solution wetted. The plates can then be which can also be this solution, to larger ones Panels are glued together, what the cost of that Attachment of the plates to the carrier reduced.

With a colored marking of the wetted with the solution th surface areas of the plates, e.g. B. by pigmentation the solution and / or labeling with a stamp be ensured in a simple manner that in the further Processing of the plates hydrophilized and hydrophobic surface surface areas can be safely distinguished from one another.

The solution consists of an alkali water glass solution with a mass ratio of SiO ₂ : alkali oxide of approx. 1.8 to 2.5: 1.

To achieve better stiffness you can use the solution also fillers, e.g. B. up to 100 parts by weight of calcium car bonat, be added.

So that the high Ar beits speed is not reduced by that careful attention to the correct amount of solution to be applied needs to be, preferably after applying the Aspirated excess solution in the vacuum air flow, whereby complete dedusting is achieved at the same time. The side of the plates used for coating can also be completely dedusted using this method. Here water can be applied instead of the solution and under negative pressure airflow can be extracted. Using water the hydrophobization of the surface zone was not removed.

The drying process by removing excess is favored, can be by microwave radiation be accelerated.

In the following, the invention is based on exemplary embodiments len explained. Show it

Fig. 1 is a cross-sectional incomplete illustrated a first embodiment,

Fig. 2 shows a corresponding cross section of a second embodiment.

The thermal insulation system shown in Fig. 1 in the assembled state consists of hydrophobized basalt fiberboard 1 in the dimension 100 × 20 cm with predominantly perpendicular to the to be attached to a metallic support 3 , namely a wall of a building, back 2 fibers. These Bastalt fibreboards 1 are attached to the carrier 3 on their back 2 with an incombustible solution of an alkali water glass solution with the mass ratio SiO ₂ before being attached to the carrier 3 . Alkaline oxide from approx. 1.8 to 2.5: 1 wetted with air in a spraying, pouring or rolling process. Any excess of the applied solution is sucked off in the vacuum air flow. The remaining amount of the solution is chosen so that a penetration depth of the solution of a maximum of 2 mm in the basalt fiberboard is not exceeded. The layer within which the fibers are wetted is designated 2 a. If accelerated drying is required, this can be done by microwave radiation.

A colorant can be added to the solution to color-code the back 2 wetted with the solution.

On the back 2 of the basalt fiber boards 1 treated in this way, a plastic-coated, hydraulically setting adhesive mortar 5 is applied for the bonding of the basalt fiber boards 1 to the carrier 3 . The connection of the adhesive mortar 5 with the basalt fiber boards is simple and so intimate thanks to the surface treatment with the solution that no connection dowels are required. As shown in Fig. 1, the basalt fiberboard 1 are glued to the support 3, abutting against one another. Thereafter, a dispersion facade paint 4 based on a styrene / acrylate dispersion with a binder content of approx. 22% and a proportion of mineral pigments and fillers of approx. 78% (based on the solids content ) is applied to the coating surface 2 'pointing away from the support 3 ', applied so that a closed surface is created. It is not necessary to apply reinforcement mesh beforehand.

To achieve higher rigidity, the non-flammable Additional solution with up to 100 parts by weight of calcium carbonate be transferred.  

The embodiment shown in FIG. 2 also consists of basalt fiber boards 1 , which have the same design as the basalt fiber boards 1 of the first embodiment. In a departure from the first exemplary embodiment, in the second exemplary embodiment, in addition to the rear side 2 of the basalt fiber boards 1 , their side faces 2 ″, with which they abut one another in the assembled state, are made with the non-flammable solution from an alkali water glass solution with a mass ratio of SiO ₂ : Alkaline oxide from approx. 1.8 to 2.5: 1 wetted in a spraying, pouring or rolling process. After suctioning off any excess of the applied solution in a vacuum air stream and drying, which can be accelerated by microwave radiation, two or three basalt fiber panels 1 are glued together to form panels of 100 × 40 or 100 × 60. For this purpose, a plastic-coated, hydraulically setting adhesive mortar is applied to the abutting side surfaces 2 ″. The adhesive mortar layer is marked with 6 .

On the back of the panels formed by the wetted layer 2 a, a plastic-coated, hy cally setting adhesive mortar 5 is then applied, with which thanks to the wetting by means of the alkali-water glass solution without further measures, a full-surface, highly resilient adhesive connection with the carrier 3 can be reached. In addition, the panels are glued to each other in the same manner as before, the basalt fiber boards 1 .

A synthetic resin plaster 7 is applied to the coating surface 2 'of the basalt fiber boards 1 pointing away from the carrier 3 , after they have been glued to the carrier 3 , into which a glass fiber fleece can be embedded to increase the strength of the coating.

Alternatively, in the direction away from the carrier 3 Beschich processing surface 2 'of the basalt fiber boards 1 after bonding with the carrier 3, a tempered mineral Armierungsmör tel under insertion of a glass silk lattice fabric coated and this surface to be plastered, after drying, with a mineral thin layer mortar.

All mentioned in the above description as well which are characteristics that can only be inferred from the drawing as further developments, components of the invention, too if not particularly emphasized and especially not are mentioned in the claims.

Claims (10)

1. Thermal insulation system with panels ( 1 ) made of mineral fiber insulation, in particular basalt fiber insulation, wherein

• a) the plates ( 1 ) are fastened to a support ( 3 ) in a butt joint with a binder,
• b) the mineral fibers of the plates ( 1 ) are oriented essentially parallel to one another,
• c) and the mineral fibers) to be applied back (2) have an extension from one to the support (3) of the plates (1 to the support (3) facing away from the front side (2 ') of the plates (1),

characterized in that on the rear sides ( 2 ) of the plates ( 1 ) in areas which come into contact with the binder, a hydrophilizing solution from an alkali water glass solution with a mass ratio of SiO ₂ : alkali oxide of 1.8: 1 to 1 is applied, and thus the areas of the backs (2) (a 2) hydrophilic in an air-permeable surface area: 2.5. 2. Thermal insulation system according to claim 1, characterized in that the thickness of the surface zone wetted by the solution ( 2 a) of the plates ( 1 ) does not exceed a value of about 2 mm. 3. Thermal insulation system according to claim 1 or 2, characterized in that abutting surface areas ( 2 '') of the plates ( 1 ) are wetted by the solution. 4. Thermal insulation system according to one of claims 1 to 3, characterized in that the side ( 2 ) of the plates ( 1 ) wetted with the solution is color-coded. 5. Thermal insulation system according to one of claims 1 to 4, characterized characterized in that the solution contains an incombustible binder. 6. Thermal insulation system according to one of claims 1 to 5, characterized characterized in that the solution up to 100 parts by weight Calcium carbonate are added. 7. A method for the surface treatment of a plate ( 1 ) made of mineral fiber insulation material, in particular basalt fiber insulation material, for a thermal insulation system, the mineral fibers of the plate ( 1 ) being oriented essentially parallel to one another, and the mineral fibers extending from one to a support ( 3 ) rear side ( 2 ) of the plate ( 1 ) to be applied to a front side ( 2 ') of the plate ( 1 ) facing away from the carrier ( 3 ), characterized by the step:
Applying a hydrophilizing solution from an alkali-water glass solution with a mass ratio SiO ₂ : alkali oxide of 1.8: 1 to 2.5: 1 on the back ( 2 ) of the plate ( 1 ) in areas with a binding agent for fastening the plate ( 1 ) on the support ( 3 ) come into contact, and thereby hydrophilizing an air-permeable surface zone ( 2 a) in the areas of the back ( 2 ) of the plate ( 1 ), the solution being sprayed, poured or rolled is applied. 8. The method according to claim 7, characterized by Suction in the vacuum air flow of an excess of the applied Solution. 9. The method according to claim 7 or 8, characterized by accelerated drying of the surface wetted with the solution Microwave radiation. 10. The method according to any one of claims 7 or 9, characterized by gluing together, before connecting to the carrier ( 3 ), the plates ( 1 ) in the region of the joints.