DE19860993C2 - insulating element - Google Patents

Abstract

An insulating material element (1), especially for the thermal insulation of building facades and for use in laminar thermal insulation systems, consists of a plate-shaped element made of concrete containing pores. The concrete density is 75-250 kg/m<3> and it has a thermal conductivity of 0.003-0.005 W/mK. Its surface has a strength-enhancing coating.

Description

The invention relates to an insulation element for thermal insulation of building facades and for use in composite thermal insulation systems, consisting of a plate-shaped element made of aerated concrete.

Insulation elements are known in a variety of designs. You can out Mineral fibers, rigid foams exist and single-layer or multi-layer Have structure. Such insulation elements are used, for example Thermal insulation of building facades used. Here are the Insulation elements part of composite thermal insulation systems. As The insulation elements become part of the thermal insulation composite systems glued to a supporting surface and, if necessary, additionally by Insulation holder secured with inserted dowel. Systems are known which are only fixed by insulation holders. With others Thermal insulation composite systems, the insulation layer is held by rails, which engage in grooves cut into the side surfaces. The rails are screwed in and expansion anchors embedded in the load-bearing surface held.

As a rule, a two-layer coating is applied to the surface of the insulation elements Plaster applied, which consists of a base plaster, in the one Reinforcing fabric is embedded. There is a finishing coat on the base coat applied, which represents the outer surface of the facade insulation. To the number to reduce the insulation holder or the stability of the The insulation holder can increase the thermal insulation composite system the fabric can be installed in the base plaster throughout.

In the thermal insulation composite systems described above, for example, plate-shaped elements made of aerated concrete are used as insulation elements. Aerated concrete is admittedly an insulation layer suitable for composite thermal insulation systems, since, for example, the thermal coefficient of linear expansion is low and therefore cannot cause cracking in the plaster, the usual bulk densities of more than 400 kg / m ³ and the thermal conductivity of more than essentially 0.10 W / mK make the processing of such aerated concrete slabs cumbersome, since extremely thick insulation layers have to be applied in order to achieve adequate thermal insulation. However, these thick layers of insulation lead to a high weight of the thermal insulation composite system, which is disadvantageous on the one hand during processing and on the other hand causes high stress on the connecting means between the facade and the thermal insulation panels.

In addition, the aerated concrete slabs have the disadvantage that they are only one have low breaking strength, so that edges break off easily and the surfaces are not resistant to abrasion. With the prevailing on construction sites Working conditions are therefore large quantities of cellular concrete insulation panels damaged, which is then disadvantageous for the composite thermal insulation system impact if these damaged insulation boards are installed.

A partition for a raised floor is known from DE 34 25 581 A1, which has an aerated concrete slab and a mineral wool strip, the Mineral wool strips as a filling between a U-profile and the end face of the AAC plate is provided. The U profile is on the top of the AAC plate placed and movable, so that over the U-profile Compensation for the length of the partition is created relative to the installation space. The mineral wool strip is therefore not connected to the aerated concrete slab.

Based on this prior art, the invention lies The task is based on an insulation element of the generic type to further develop that the disadvantages described above avoided can be.

The solution to this problem is seen in an insulation element generic type that on at least one narrow side of the a strip of mineral wool is arranged.  

Such an insulation element is ge for composite thermal insulation systems suitable.

The plate-shaped elements made of aerated concrete are indeed high Dimensional accuracy can be produced, but laying joints cannot necessarily ver avoid. Such installation joints are usually according to the state the technology for polystyrene rigid foam panels with polyurethane foam closed near the surface. However, this procedure delivers one additional work step that is time-consuming and therefore costly. Around Avoiding disadvantages is with the insulating material according to the invention elements provided that on at least one narrow side of the plate-shaped a mineral wool strip is arranged against the element.

The mineral wool strip is preferably made of binders den individual fibers which are substantially parallel to the surface normal of the large surfaces of the plate-shaped element, so that the Mineral wool stripes in a direction perpendicular to the surface normal of the large surfaces is compressible and seals the corresponding joints can eat.

Preferably, on several narrow sides of the plate-shaped element mineral wool strip arranged. The one uniform material thickness exhibit. But there is also the possibility of working on the different Narrow sides of the plate-shaped element of mineral wool strips with under arrange different material thicknesses to the insulation element in dependency joint width either with a narrower strip of mineral wool or with a wider strip of mineral wool in the thermal insulation composite to arrange stem.  

A material thickness between 5 and 50 mm, preferably less than 15 mm has proven to be advantageous for mineral wool strips.

According to a further feature of the invention it is provided that the plat-shaped element made of aerated concrete has a bulk density of 100 to 150 kg / m ³ .

Coatings provided on a large surface can also made of plastic-containing construction adhesives, mortars, for example based on hydraulically setting cements exist. There are also synthetic plasters and / or silicic acid suitable as the so-called Ormocere on the Nanotechnology is applied and essentially in the below the Areas that solidify surface areas. Furthermore, as Be layered with silica sol, water or aluminum phosphates, mixtures of minerals such as quartz sand, aluminum, doped with plastics umhydroxyd and similar suitable. It is only necessary to ensure that minerals are excluded that are exposed to moisture swell.

According to the invention, the surfaces of the plate-shaped element are included Deep foundation on the basis of acrylates, butadiene-styrene copolymers and similar saponification-resistant plastic dispersions or Solutions stabilized. Because these substances have negative effects on the Building material class, they are preferably with adhesive and Mortar layers covered.

The thickness of the coating is as small as possible for reasons of weight hold. It has proven advantageous to coat with a thickness of less than 5 mm.  

The bending tensile strength of the plate-shaped element made of aerated concrete to increase and achieve an even application of force, he will According to the invention, mesh, for example made of glass fibers, aramid or Carbon fibers, cellulose fibers or the like on one or both large surfaces of the plate-shaped element in the coating bedded or glued on with their help.

According to a further feature of the invention it is provided that to at least a large surface of the plate-shaped element, in particular that of the surface facing the facade of the building, preferably wise with a layer of coating, a compressible mineral wool le insulation board or a mineral wool insulation felt is arranged.

The insulation panels made of aerated concrete lie on uneven subsurface conditions nissen at a certain distance from the facade, so that between between the facade and the insulation panels forms a cavity. Such one Cavity or several such cavities allows circulation of the Air, so that a significant reduction in thermal resistance is recorded. This reduction in thermal resistance also leads to continuous cavities with a connection to the outside air to an almost complete abolition of the insulation effect. Around To avoid this problem is the compressible mineral wool Insulation board or the mineral wool insulation felt provided with which cavities corresponding to compressibility can be closed NEN.

For this, it has proven to be advantageous to use the mineral wool insulation board or the mineral wool insulation felt with a material thickness of 10 to 50 mm train. The cavities are then maximally closed,  if the mineral wool insulation board or the mineral wool insulation felt the Cover the entire surface of the plate-shaped element. It exists but also the possibility that on the surface of the plate-shaped Ele the mineral wool insulation board or the mineral wool insulation felt chig is applied, with a strip-shaped configuration of this Has proven beneficial. These are preferably mineral wool Stripes all around or parallel to the long sides or as individual Sealing strips arranged.

With a full coverage of the plate-shaped element, it has proved to be advantageous, the mineral wool insulation board or the mine RAL wool insulation felt with recesses for holding an adhesive element train. The adhesive element preferably forms in the hardened case stood a spacer. This spacer is pressure-resistant and ver prevents the insulation board from breaking through under external pressure. Wei the spacer in conjunction with an insulation holder increases the Stability of the thermal composite system.

Further advantages and disadvantages result from the following description writing the associated drawing. The drawing shows:

Fig. 1 shows a first embodiment of an insulation element in per perspective view and

Fig. 2 shows a second embodiment of an insulation element in side view.

In Fig. 1, an insulation element 1 for thermal insulation of buildings is facade and for use in composite thermal insulation systems Darge provides.

The insulation element 1 consists of a plate-shaped element 2 made of aerated concrete with a bulk density of 100 kg / m ³ and a thermal conductivity of 0.040 W / mK. A strength-increasing and adhesion-promoting coating 3 is arranged on the two large surfaces of the element 2 . The coating can consist of plastic-containing construction adhesives, mortars, for example on the basis of hydraulically setting cements and / or synthetic resin plasters.

It can be seen that the insulation element 1 has four bores 4 which are arranged in the corner regions of the insulation element 1 . These holes 4 are used to hold insulation holders in order to attach the insulation element 1 to the facade of the building. The holes 4 are arranged in a dowel pattern matched to the plate size.

On three of the four narrow sides 5 of the element 2 , mineral wool strips 6 consisting of mineral fibers are attached. The mineral wool strips have 5 different material thicknesses on each narrow side and serve to compensate for the joints when laying several insulation elements 1 next to each other. The mineral fibers of the mineral wool strip 6 are aligned parallel to the narrow sides 5 and parallel to the surface normal of the element 2, so that the mineral wool strip 6 in the direction of the insulating material element 1 are formed compressible.

The second embodiment of the insulating element 1 according to the invention shown in FIG. 2 also consists of the plate-shaped element 2 made of aerated concrete with the characteristics specified above. Furthermore, it can be seen that in the embodiment according to FIG. 2, the element 2 has a coating 3 on both large surfaces.

For the fastening of the insulation element 1 according to FIG. 2, insulation holders are again provided, which are not shown in detail and can be used in bores 4 . The bores 4 are in this case designed to expand in a truncated cone at one end, so that appropriately designed insulation holders can be used.

On the surface facing the facade 7 of the element 2 is a mineral wool plate 8 glued fully. The mineral wool plate 8 is designed to be compressible in the direction of the surface 7 .

In addition, it can be seen that the mineral wool plate 8 has recesses 9 , in which adhesive elements 10 are inserted. These adhesive elements form spacers in the hardened state, which prevent the element 2 from breaking.

Claims (20)

1. Insulating element for thermal insulation of building facades and for use in composite thermal insulation systems, consisting of a plate-shaped element made of aerated concrete with a bulk density of 75 to 250 kg / m ³ and a thermal conductivity between 0.030 to 0.050 W / mK, characterized in that A mineral wool strip is arranged on at least one narrow side of the plate-shaped element. 2. Insulating element according to claim 1, characterized, that the mineral wool strip consists of single fibers, which essentially parallel to the surface normal of the large surfaces of the plate-shaped Element run. 3. Insulating element according to claim 1, characterized, mineral wool on several narrow sides of the plate-shaped element strips are arranged, which have a uniform material thickness. 4. insulation element according to claim 1, characterized, mineral wool on several narrow sides of the plate-shaped element strips are arranged, the one on different narrow sides have different material thickness. 5. insulation element according to claims 1 to 4, characterized,  that the mineral wool strips have a material thickness between 5 and 50 mm preferably less than 15 mm. 6. Insulating element according to claim 1, characterized in that the plate-shaped element made of aerated concrete has a bulk density of 100 to 150 kg / m ³ . 7. insulation element according to claim 1, characterized, that at least a large surface of the plate-shaped element Coating made of plastic-containing construction adhesives, mortars, for example the basis of hydraulically setting cements and / or synthetic resin plasters, has and / or consists of silica, which as Ormocere on the nano technology is applied and in the below the surfaces of the plate-shaped gene elements arranged areas has a consolidating effect and / or from with Silica sol, water glass or aluminum phosphate bound, with plastic fen doped mixtures of minerals, such as quartz sand, aluminum hydroxide the like. 8. insulation element according to claim 1, characterized, that the surfaces of the plate-shaped element with a deep ground based on acrylates, butadiene-styrene copolymers and / or the like Saponification-resistant plastic dispersions or solutions stabilizing is coated. 9. insulation element according to claim 8, characterized, that the deep ground on the surfaces of the plate-shaped element with a layer of adhesive or mortar is covered.   10. insulation element according to claim 7, characterized, that the thickness of the coating is less than 5 mm. 11. Insulating element according to claim 1, characterized, that at least the coating on a large surface of the plate Migen element has a mesh fabric, in particular made of glass sern, aramid or carbon fibers, cellulose fibers or the like stands. 12. Insulating element according to claim 11, characterized, that the mesh fabric is embedded in the coating. 13. Insulating element according to claim 12, characterized, that the mesh fabric between the coating and the surface of the plate-shaped element is arranged. 14. Insulating element according to claim 1, characterized, that on at least a large surface of the plate-shaped element, especially the surface facing the facade of the building, preferably with the interposition of the coating, a compressible lead ral wool insulation board or a mineral wool insulation felt is arranged. 15. Insulating element according to claim 14, characterized, that the mineral wool insulation board or the mineral wool insulation felt is a mate rial thickness from 10 to 50 mm.   16. Insulating element according to claim 14, characterized, that the mineral wool insulation board or the mineral wool insulation felt the upper covers the entire surface of the plate-shaped element. 17. Insulating element according to claim 14, characterized, that the mineral wool insulation board or mineral wool insulation felt Ausspa has stanchions for receiving an adhesive element. 18. Insulating element according to claim 14, characterized, that the adhesive element forms a spacer in the hardened state. 19. Insulating element according to claim 14, characterized, that the mineral wool insulation board or the mineral wool insulation felt the upper surface of the plate-shaped element over part of the surface, in particular strip-shaped, covers. 20. Insulating element according to claims 14 to 19, characterized, that the mineral wool insulation board or the mineral wool insulation felt with the plate-shaped element is glued.