DE19839295C2 - Composite thermal insulation system and method for manufacturing a thermal composite system - Google Patents

Description

The invention relates to a use as a facade cover Tough insulation system according to the generic term of the patent Claims 1 and a method for producing a Thermal insulation composite system.

Can be used for thermal insulation of new and old buildings Thermal insulation composite systems have been known for a long time. The be writing the individual elements of such thermal insulation Terms used in composite systems are already in DE 32 02 960 A1 Are defined. After that, the term insulation board one according to the cited document preferably made of extruded Polystyrene rigid foam formed thermal insulation board understood. A material for embedding is used as the reinforcing compound  of a reinforcing fabric, wherein the reinforcing fabric a coarse-mesh fabric made of glass fibers with a mesh size of about 5 mm. The term also refers to Armie layer in general the composite of reinforcement and reinforcement fabrics. In addition, a composite thermal insulation system one to fix the insulation board on the building wall have adhesive. Alternatively or in addition the insulation board also mechanically, for example with an expansion nozzle or fixed to the building wall with a rail system be placed. On the reinforcement layer can also Base coat and / or one for weather protection and that Appearance of the facade plaster applied his. Finally, the finishing coat can also have an exterior paint can be painted. The entire layer over the dam In the cited document, plate is reinforced as a multi-layer Plaster coating called. According to DE 32 02 960 A1 Production of the reinforcing compound from a mortar-like mixture Cement and an adhesive or a filler on the ba sis used by plastic dispersions, the 20 to maximum 50% Portland cement can be added.

According to DE 30 40 077 C2, the use of an Ar lubrication fabric, if one of a ge foam plastic existing insulation board a reinforcement mass is applied next to a hydraulic bandage medium, a surcharge and usual additives cut, alkali-resistant glass fibers with a Text number from 20 to 200 g / km and a length from 5 to 33 mm in Contains proportions of 0.3 to 3.0 vol .-%. With such a on an insulation made of a foamed plastic plate applied reinforcement can reduce the risk of cracking formation on the surface of the finished composite thermal insulation system be reduced because the armia forming a rigid shell compound, if necessary together with the plaster, practically springy  adheres to the yielding surface so that it may appear tensions are reduced.

However, it has been shown that with DE 30 40 077 C2 known reinforcing compound at low temperatures observed increased risk of cracking and detachment is. To solve this problem, DE 34 29 251 C2 the use of an armie that can be applied without reinforcement fabric mass proposed by a pre-networked or crosslinkable synthetic resin binder is bound, the plastoela properties between -10 and + 40 ° C, a glass temperature temperature transition at less than -15 ° C and an elongation at break at -15 ° C of at least 200%. With such a Reinforcing compounds can reliably prevent cracking become. The plaster structure using this reinforcement is, however, disadvantageous in that it is higher Outside temperatures become very soft and sticky and therefore strong tends to get dirty. In addition, the high art deteriorates Portion of the reinforcing material known from DE 34 29 251 C2 the fire-related and ecological properties of one there with manufactured plaster structure.

To improve fire engineering and environmental Properties of composite thermal insulation systems became in the latter Time has progressed to the well-known insulation boards foamed plastic with mineral insulation boards replace. One using a mineral insulation board manufactured thermal insulation composite system according to the preamble of Claim 1 is for example in DE 42 16 204 A1 specified. According to this document, mineral thermal insulation plates from 15 to 25 mass% of a lime binder, 50 to 70 mass% silicon dioxide, 0 to 10 mass% of a porous Surcharge, 0 to 2 mass% of other additives and one from what This existing rest can be manufactured.  

In the thermal insulation composite specified in DE 42 16 204 A1 system is a layer of plaster on the mineral insulation boards applied to a mineral plaster material that a Po and a porous aggregate and a Contains water repellant. The one in this document beaten thermal insulation composite system is said to be a permanent crack Freedom of the plaster layer can be ensured that between the thermal insulation boards and the plaster layer with Filler embedded reinforcement fabric is provided.

Process for the production of similar mineral heat Insulation boards are in EP 0 816 303 A1, DE 44 08 088 A1, DE 43 39 137 A1 and DE 43 27 074 A1.

In the manufacture of composite thermal insulation systems under It has become known to use the known mineral insulation boards however, showed that cracks on the outer surface of the thermal insulation can only be reliably prevented if a reinforcing fabric is in the possibly also the outer deck layer-forming reinforcing compound is embedded. By one Set of such a reinforcing fabric is achieved that Shrinkage and swelling processes do not lead to deformation of the plaster lead shell, the larger areas of the outer surface of the heat insulation system, but only in small Partial areas occur that are approximately the mesh size of the fabric bes correspond. These deformations in parts of weni square millimeters are so small that they do not crack lead education and can therefore be neglected The deformation of large areas is several millimeters and accordingly cracks of this size can occur.  

The attachment of this embedded in the reinforcing compound Reinforcing fabric is, however, with a high level of craftsmanship On-site effort connected.

In view of the problems in the prior art, the Invention, the object of a thermal insulation composite system for example, be described in DE 42 16 204 A1 put it back, avoiding the formation of cracks quickly and can easily be attached to a building wall.

To solve this problem, the characterizing Part of claim 1 specified training of the known Wär medämmverbundsystems proposed.

Conventional composite thermal insulation systems have a plurality of heat determined independently of one another on the building wall insulation boards. Surprisingly, it has now been shown that the stability of such thermal insulation composite systems under at the same time reducing the tendency to crack in the Outside surface is accessible if the thermal insulation boards are not only attached to the building wall, but also directly connected to each other, preferably glued. The increases the mechanical strength of the thermal insulation composite system is achieved in that by direct connection of the individual thermal insulation boards a rigid outer shell for the building wall is formed. This outer shell forms a continuous underlay for the reinforcement layer, whereby a crack formation due to the otherwise possible shifts the thermal insulation boards is avoided relative to each other.

It is in the thermal insulation composite according to the invention stem the desired avoidance of cracks in the outer surface thereby ensuring that not only the thermal insulation boards and the light plaster with regard to its mechanical properties are adapted to each other, but also as an adhesive of the  Light plaster is used to ensure uniform behavior of the entire system. Therefore, when in use of the composite thermal insulation system according to the invention Reinforcement fabric to avoid tears in the Outer surface can be dispensed with.

Therefore, the composite thermal insulation system according to the invention ensuring reliable crack prevention quickly and simply be fixed on a building wall. Further The mineral light plaster contains at most small amounts organic additives, so that with the invention Thermal insulation composite system also satisfactory ecological and Fire protection properties can be obtained.

A particularly good adaptation of the hygrothermal ver shaping properties of the light plaster to the corresponding Properties of the lightweight insulation board is achieved when the Foam concrete or foam mortar from a binder slurry from water, quartz flour, hydrated lime, cement and possibly a pro tein or chemical foaming agent is made. A white Further adaptation of the hygrothermal properties of the individual NEN components of the thermal insulation composite system according to the invention stems can be reached, even if the mineral light plaster Hydrated lime in an amount of preferably 2 to 8% by mass contains.

With regard to the desired insulation properties of the he inventive thermal insulation composite system, it is preferred if the lightweight insulation panels have a thermal conductivity of less than 0.05 W / mK.

To obtain advantageous mechanical properties of the thermal insulation composite system according to the invention, it has proven to be advantageous if the lightweight insulation boards have a compressive strength of more than 0.3 N / mm ² , an adhesive tensile strength of more than 0.03 N / mm ² , and a moisture expansion of less than 1 mm / m, a thermal change in length of less than 14.10 ^-6 m / mK and a density of 80 kg / m ³ to 130 kg / m ³ .

To avoid the undesirable increase in thermal conductivity ability by penetrating water has gone further than Proven useful when the lightweight insulation boards of the inventor thermal insulation composite system according to the invention with an additional Hydrophobing are provided. Process for producing hy Doped light insulation boards are for example in DE 44 08 088 and EP 0 816 303, to which in this reference context is expressly referred to.

To improve the mechanical properties of a he inventive thermal insulation composite system, it has further than proven to be advantageous if the lightweight insulation panels are fiber-reinforced are strengthened. Organic and / or inorganic ver Reinforcing fibers are used. The is particularly preferred Use of cotton fibers.

The light plaster of the thermal insulation composite system according to the invention stems can 30 to 50 mass% of a preferably carbonati fine filler such as quartz powder or the like 15 to 35, preferably 25 to 35% by mass of a light filler, such as such as natural pumice, perlite, fillite, expanded clay or the like, 3 up to 5 mass% of a polymer dispersion, the organic and / or inorganic reinforcing fibers and optionally additives to achieve the characteristic cleaning properties, such as for example setting retarders, setting accelerators, ver liquid, anti-foaming agent and / or anti-sedimentation agent tel and / or anti-shrinkage may contain.

Particularly advantageous properties were achieved with light plaster of the following composition:
20.0% by mass Portland cement (CEM 32 , 5 R)
5.0% by mass of white lime hydrate
40.0 mass% carbonatic fine fillers
30.0 mass% expanded aluminum silicate (light filler)
2.0 mass% polymer dispersion
2.0 mass% cotton fibers
1.0% by mass of additives

The cement portion of the light plaster is preferably 10 to 30 particularly preferably 10 to 20 mass%. You can instead of Portland cement also Portland limestone cement, Alumina cement, pozzolana or other cements with comparable properties are used.

The thermal insulation board of the thermal insulation according to the invention bundsystems can, for example, mechanically on the building wall be determined. System anchors can be used, for example be set. Furthermore, thermal insulation board is also considered ten insert that preferably a circumferential notch point and with a rail system on the building wall can be laid.

In addition or as an alternative to the mechanical fastening The thermal insulation board is also fastened with a Adhesive possible. This adhesive can, depending on the surface texture, mineral and / or organic additives point.

The tendency to crack in an inventive Composite insulation system can be further reduced if the Adhesive essentially identical to the reinforcing compound is because in this way an adjustment of the mechanical deformation properties  the adhesive to the reinforcing compound and thus also reached on the thermal insulation board.

The light plaster of the thermal insulation composite system according to the invention Stems can also cover the thermal insulation form bundle systems, on which an outer color may be applied will wear. In addition, however, there is also thought of the the lightweight plaster forming an additional reinforcement apply smooth or structured plaster layer to the if necessary, an exterior paint is also applied. Appropriately become wise for the production of the thermal insulation according to the invention verbundsystems adhesive, light plasters and / or top coat used that can also be processed by machine.

When choosing the materials for making a thermal insulation composite system according to the invention is preferably so proceeded that the fire resistance of the system in the Building material class A2 falls in accordance with DIN 4102.

When installing a thermal insulation composite according to the invention systems has proven to be particularly useful if after fixing and gluing the lightweight insulation panels together initially only a comparatively thin layer of light plaster with a thickness of less than about 1 cm, preferably less than about 0.5 cm applied to the lightweight insulation board and after the reduction of the hygric tensions of the first Apply a second layer while drying conditions and to maintain the desired overall visual impression is equalized. The second layer can be in the same Thickness like the first layer or with a lower one Layer thickness can be applied. With this approach can arise during the drying of the first layer Shrinkage cracks are compensated for by applying the second layer become.

Claims (20)

1. Thermal insulation composite system with a plurality of heat-insulating panels which can be fixed on a building wall and a light plaster applied to the thermal insulation panels without reinforcing fabric, in which the thermal insulation panels are formed in the form of mineral lightweight insulating panels consisting of foam concrete and / or foam mortar, characterized in that at least two thermal insulation boards are preferably glued to one another directly along a horizontal and / or vertical joint with the light plaster. 2. Thermal insulation composite system according to claim 1, characterized records that the foam concrete or foam mortar from a bin detergent sludges from water, quartz powder, hydrated lime, cement and possibly proteins or chemical foaming agents is produced. 3. A composite thermal insulation system according to claim 1 or 2, characterized characterized in that the mineral lightweight insulation boards a Have thermal conductivity of less than 0.05 W / mK. 4. Thermal insulation composite system according to one of the preceding An sayings, characterized in that the mineral light Insulation boards have an additional hydrophobization. 5. Thermal insulation composite system according to one of the preceding An sayings, characterized in that the mineral light Insulation boards are fiber reinforced. 6. A composite thermal insulation system according to claim 5, characterized records that the reinforcing fibers are organic and / or anor have ganic fibers.   7. A composite thermal insulation system according to claim 5 or 6, characterized characterized in that the reinforcing fibers are cotton fibers point. 8. Thermal insulation composite system according to one of the preceding An sayings, characterized in that the light plaster hydrated lime in an amount of preferably up to 15% by mass. 9. Thermal insulation composite system according to one of the preceding claims, characterized in that the light plaster contains 10 to 30 , preferably 10 to 20% by mass of a cement. 10. A composite thermal insulation system according to one of the preceding claims, characterized in that the light plaster contains 30 to 50 % by mass of a fine filler. 11. A thermal insulation composite system according to one of the preceding claims, characterized in that the light plaster contains 15 to 35 , preferably 25 to 35% by mass of a light filler. 12. A composite thermal insulation system according to one of the preceding claims, characterized in that the light plaster contains 3 to 5 % by mass of a polymer dispersion. 13. Thermal insulation composite system according to one of the preceding An sayings, characterized in that the light plaster 0.2 to 2 Contains% by mass of reinforcing fibers. 14. Thermal insulation composite system according to one of the preceding An sayings, characterized in that the thermal insulation panel me can be fixed mechanically on the building wall.   15. A composite thermal insulation system according to claim 14, characterized records that the thermal insulation board with one or more Sy can be fixed on the wall of the building. 16. A composite thermal insulation system according to claim 14 or 15, characterized characterized in that the thermal insulation board preferably around has running notch and with a rail system on the Building wall can be determined. 17. Thermal insulation composite system according to one of the preceding An sayings, characterized in that the thermal insulation board with an adhesive can be fixed to the building wall. 18. Thermal insulation composite system according to claim 17, characterized records that the adhesive mineral and / or organic Has additives. 19. A composite thermal insulation system according to claim 17 or 18, characterized characterized in that the adhesive with the light plaster in the we is essentially identical. 20. Method of making a composite thermal insulation system according to one of the preceding claims, in which according to Festle and gluing the lightweight insulation panels together Most layer of light plaster with a thickness of preferably less than 1 cm is applied to the lightweight insulation board, characterized in that after the reduction of the hygric tension a second layer of light plaster in the first layer is applied to the first layer.