EP2620567A2 - Composite heat insulation system with a fire barrier, heat insulation element and use of the heat insulation element as a fire barrier - Google Patents

Abstract

The thermal insulation system has a barrier layer that is provided with a heat insulating plate made of a rigid foam such as a polystyrene foam. The heat insulating plate has a profile shaped heat insulating element that forms a fire barrier. The profile shaped heat insulating element is made of aerogel particles, water-based organic or inorganic binder with thermal conductivity of less than or equal to 0.022W/mK.

Description

The invention relates to a thermal insulation composite system with a fire barrier and the other features of the preamble of claim 1. Furthermore, the invention relates to a usable as a fire barrier in a thermal insulation system heat insulation element and the use of such a thermal insulation element as a fire barrier.

State of the art

Thermal insulation systems of the type mentioned above include a one or more layers of several thermal insulation panels formed thermal barrier, often heat insulation panels are used, which consist of a hard foam, in particular of a polystyrene foam, or at least include such a thermal insulation material. Because appropriate thermal insulation materials have good thermal insulation properties and are relatively inexpensive. However, the fire behavior of such thermal insulation materials proves to be disadvantageous, which according to DIN 4102-1 are regularly attributable to building material class B (combustible building materials). If polystyrene rigid foam panels are flame-retardant, they are assigned to building material class B1 (flame retardant). The attached to the outside of a building exterior wall thermal barrier layer can therefore lead to an increase in fire load. For example, if the source of the fire is in a closed room, the windows burst at first, and the flames fall behind beat outside. However, the thermal insulation composite system withstood the flames only for a limited period of time, so that the fire eventually spread to the façade. In order to prevent or at least delay such an attack, fire bars are used regularly above an opening of a building exterior wall. The fire bars can be arranged above each opening or floor by floor as a circulating belt.

From the utility model DE 84 26 763 U1 For example, a façade full thermal insulation composite system is known, which includes an effective as a fire barrier, insulation board made of polystyrene foam. The insulation board made of polystyrene foam has for this purpose a full thickness of the insulation board formed, embedded or attached strips of a non-melting in the heat, preferably non-flammable or flame-retardant insulation. This insulating material may be, for example, a mineral fiber or glass fiber insulating material. If a single- or multi-layered plaster layer is subsequently applied, the use of such insulating materials within an insulating layer consisting of polystyrene rigid foam can lead to undesired color deviations or markings on the facade.

To avoid such markings is in the DE 196 43618 C5 a thermal insulation composite system with plastic insulation panels made of hard foam, in particular polystyrene foam, proposed, which comprises a provided with a flame retardant and arranged between adjacent insulation panels fabric to form a release layer. In case of fire, the heat causes foaming and curing of the flame retardant, so that a stabilization of the separation layer takes place. The use of a coated with the flame retardant and / or impregnated tissue helps to avoid unwanted discoloration or decals.

In order to avoid discoloration and cracks in the plaster layer of a thermal insulation composite system due to inhomogeneity of the insulating layer, is further in the

Utility Model DE 20 207 007 225 U1 a component for a thermal insulation composite system proposed which comprises two insulating elements and an intermediate, substantially over the entire cross-sectional area of the component extending fire protection layer. The fire protection layer is preferably made of mineral wool, glass cloth, needle felt, a coated glass net and / or mortar.

Based on the above-mentioned prior art, the present invention seeks to provide a simplified thermal insulation composite system with a fire barrier. As a fire barrier to find a flexible and easy to use as possible thermal insulation element use. In particular, the thermal insulation element should allow the formation of a fire barrier in a fall and / or reveal area of an opening in a building exterior wall.

To solve the problem, a composite thermal insulation system with the features of claim 1 and an insertable as a fire barrier thermal insulation element with the features of claim 5 are proposed. Advantageous developments of the invention can be found in the respective subclaims.

Disclosure of the invention

The proposed composite thermal insulation system has a mounted on an outer side of a building exterior wall single or multi-layer thermal barrier coating and a single or multi-layered plaster layer applied thereto, wherein the thermal barrier coating at least one thermal insulation panel of a rigid foam, in particular of a polystyrene foam, and at least one plate or profile-shaped thermal insulation element for forming a fire barrier comprises. According to the invention it is further proposed that the fire barrier forming, plate or profile-shaped thermal insulation element comprises a thermal insulation material, which airgel particles and at least one water-based organic and / or inorganic binder and has a thermal conductivity ≤ 0.028 W / (mK), preferably < 0.025 W / (mK), further preferably < 0.022 W / (mK).

Airgel-based thermal insulation materials have a very low thermal conductivity and thus excellent thermal insulation properties. As a result, the insulation thicknesses can be significantly reduced while fulfilling the requirements with regard to thermal protection. The addition of at least one water-based organic and / or inorganic binder causes a stable composite of the airgel particles with each other, so that further the mechanical properties and thus the construction site suitability of the thermal insulation material containing thermal insulation element can be improved. A heat insulating element made of such a thermal insulation material may be formed as a thin plate, which is particularly suitable for thermal insulation of a lintel or soffit surface of an opening in the building exterior wall. As a rule, in the fall or reveal area of an opening, such as a window or a door, no large insulation thicknesses can be performed. Here, the excellent thermal insulation properties of the thermal insulation material or of the thermal insulation element produced therefrom have a particularly advantageous effect.

At the same time, the specified thermal insulation element of the thermal insulation composite system according to the invention fulfills the function of a fire barrier, which in case of fire can prevent or at least significantly delay a fire expansion to an adjacent thermal insulation layer from a heat insulation material which is combustible according to DIN 4102-1. In this case, aerogels are also classified as flammable on their own, whereby the classification into the building material class B1 (flame retardant) takes place. The binder contained in the thermal insulation element, in particular in the case of a water-based organic binder, may be assigned to the building material class B2 (normally flammable), so that the thermal insulation element may only reach the building material class B2. Surprisingly, nevertheless, a fire propagation preventing or at least significantly delaying effect achieved, which makes the arrangement of a separate, consisting of a non-combustible building material fire bar - unless required by building regulations - unnecessary. In addition to a building inspection required fire bars the fire protection is significantly improved by the dual function of the specified thermal insulation element, so that here also the use of a thermal insulation composite system according to the invention for thermal insulation of a building exterior wall has advantages.

The effect of the thermal insulation element as a fire barrier could be demonstrated in the context of attempts by the applicant - which will be described below with reference to concrete examples. It is due to the low thermal conductivity of the thermal insulation material of the thermal insulation element, which in the present case ≤ 0.028 W / (mK), preferably ≤ 0.025 W / (mK), further preferably ≤ 0.022 W / (mK).

According to a preferred embodiment of a thermal insulation composite system according to the invention, the fire barrier forming, plate or profile-shaped thermal insulation element in the region of an opening of the building exterior wall, in particular above and / or arranged laterally of the opening. As a rule, fires occur in closed rooms and are transmitted to the façade via openings in the external wall of the building, in particular windows and doors. Due to the proposed arrangement of the plate or profile-shaped thermal insulation element, such a fire flashover can be effectively prevented or at least significantly delayed.

Particularly preferably, the fire barrier forming, plate-shaped or profile-shaped thermal insulation element on a substantially perpendicular to the outside of the building exterior wall extending surface, in particular a lintel or soffit surface arranged. In this particularly preferred arrangement, in particular the reduced insulation thickness of the thermal insulation material of the plate-shaped or profile-shaped thermal insulation element comes into play. Because usually is at a window or door opening only the visible depth of the window frame of the built-in window or door system for the realization of a thermal barrier coating available. In this arrangement, therefore, the plate or profile-shaped thermal insulation element of a thermal insulation composite system according to the invention preferably has a thickness of 10 to 30 mm, which is sufficient to form a fire barrier. If the thermal insulation element is formed in a profile shape, it may for example be L-shaped and embrace the soffit or the lintel.

Furthermore, preferably, the fire barrier forming, plate or profile-shaped thermal insulation element of a thermal insulation composite system according to the invention has a flush with the outside of the single or multi-layer thermal barrier coating final upper or side surface. This applies both to an arrangement of the thermal insulation element on the outside of the building exterior wall, in particular above or to the side of an opening, as well as when arranged on a lintel or soffit surface. The flush with the thermal barrier coating final upper or side surface of the thermal insulation element serves to accommodate the one or more layers of plaster, so that they can be formed without interruption and also in uniform thickness. The plaster layer can also be performed uninterrupted and in uniform thickness around the soffit or the fall around to the window or door system.

The flush with the thermal barrier coating final upper or side surface of the thermal insulation element further ensures that the space between the outside of the building exterior wall and the single or multi-layer plaster layer is completely filled by the thermal insulation element. There remains no cavity, which could favor fire expansion. In this way it is further prevented that already molten thermal insulation material drips above a firing bar and ignites or at least damages the hot melt underlying material. The dripping melt could also persons hurt. Thus, a particularly effective protection is achieved by the fire barrier.

The plate-like or profile-shaped thermal insulation element which is also proposed for solving the above-mentioned object can be used as a fire barrier in a thermal insulation composite system according to the invention and comprises a thermal insulation material which contains airgel particles and at least one water-based organic and / or inorganic binder and has a thermal conductivity ≦ 0.028 W / (mK), preferably ≤ 0.025 W / (mK), further preferably ≤ 0.022 W / (mK). The low thermal conductivity is due to the contained airgel particles. Compared to known thermal insulation materials containing airgel particles, the present thermal insulation of a thermal insulation element according to the invention also due to the binder further contained good mechanical properties, in particular sufficient stability, so that even low insulation thicknesses can be realized. The low thermal conductivity of the thermal insulation material is one reason that the thermal insulation element also fulfills the function of a fire barrier. Because of the plate-shaped or profile-shaped thermal insulation element, the adjacent thermal barrier coating of the thermal insulation composite system is essentially protected from the heat generated during firing. In this way, in particular a melting of the adjacent thermal barrier coating is prevented. Accordingly, the plate or profile-shaped thermal insulation element could also be referred to as a heat protection element.

Since the binder content contained in the thermal insulation material basically leads to a deterioration of the thermal insulation properties, it is further proposed that the binder content contained in the thermal insulation material less than 5 vol .-%, preferably less than 3 vol .-%, more preferably less than 2 vol. % based on the total volume of the thermal insulation material. The binder content thus hardly contributes to increasing the thermal conductivity. At the same time, a stable composite of the airgel particles is ensured with each other, when the binder content is not less than 0.5% by volume based on the total volume of the thermal insulation material.

A higher binder content not only has an unfavorable effect on the thermal insulation properties of the plate-shaped or profile-shaped thermal insulation element. He also has the disadvantage that there is a risk that the binder decomposes in the event of fire under the action of heat and burned or evaporated. The resulting decomposition gas has a high explosive force and can lead to complete destruction of the thermal insulation element. In this respect, the specified maximum values should not be exceeded and the further specified minimum value for achieving a sufficient mechanical strength should not be undershot.

Further preferably, the Gesamtzwickelvolumen formed between the airgel particles less than 35 vol .-%, preferably less than 25 vol .-%, more preferably less than 20 vol .-%, based on the total volume of the thermal insulation material. This measure also contributes to a low thermal conductivity and increased stability of the thermal insulation material and thus of the thermal insulation element. Total gusset volume is understood here to mean the entire volume of air and / or binder filled gusset volume between the airgel particles. In order to realize the stated total gusset volume, the thermal insulation material has preferably been compacted during production in a mold or on a belt system with the addition of pressure and / or heat.

Furthermore, it is proposed that the water content of the water-based organic and / or inorganic binder contained in the thermal insulation material of the thermal insulation element is at least 50% by weight, based on the total weight of the binder. The high water content increases the wettability, so that a uniform distribution of the binder and, consequently, a stable composite of the airgel particles can be achieved with one another even at the low binder content described above.

Preferably, the water-based organic binder is a water-based thermosetting binder such as epoxy resin or polyurethane, and / or a dispersion binder based on thermoplastic vinyl acetate, acrylate, styrene acrylate or styrene butyl acrylate polymers or other polymer dispersion. When using such organic binder, the binder content can be further reduced because they have a particularly high binding force and therefore with less binder a stable composite of the airgel particles is guaranteed to each other.

Alternatively or additionally, a water-based inorganic binder may also be present, this being preferably soda or potassium silicate glass.

Furthermore, it is proposed that at least part of the contained airgel particles consists of airgel recyclate. In this way, costs can be saved because the airgel particles are expensive to manufacture and thus expensive. It also contributes to environmental protection by producing less waste.

Advantageously, the plate or profile-shaped thermal insulation element according to the invention is produced continuously from the airgel particles and at least one water-based organic and / or inorganic binder containing thermal insulation material. It thus preferably has a homogeneous structure. Such a thermal insulation element is simpler and thus less expensive to produce compared to a thermal insulation element with an example layered structure. In addition, a homogeneously constructed thermal insulation element has the same properties over its entire cross section. As a result, the effect is guaranteed as a fire barrier over the entire cross section of the thermal insulation element.

Finally, the use of a plate-shaped or profile-shaped thermal insulation element according to the invention is claimed as a fire barrier in a thermal insulation composite system. The thermal insulation system has a mounted on an outer side of a building exterior wall single or multi-layer thermal barrier coating and a single or multi-layer plaster layer applied thereto, wherein the thermal barrier coating comprises at least one thermal insulation panel of a rigid foam, in particular of a polystyrene foam. In the claimed use, the plate or profile-shaped thermal insulation element has a dual function, namely the function of thermal insulation and the function of a fire barrier. The heat-insulating element thus replaces or supports the function of an additionally arranged in the thermal barrier coating of a thermal insulation composite fire, so that if not required by building supervision - if necessary, can be omitted. For this purpose, the thermal insulation element in the surface, for example, be arranged as a circulating belt in the area of a floor slab and / or above an opening of the building exterior wall. Alternatively or additionally, the arrangement of a thermal insulation element according to the invention in a lintel and / or soffit area of an opening is advantageous since it is able to prevent or at least significantly delay an attack by a room-side source of fire on the facade.

The fire propagation preventing or at least significantly retarding effect of a thermal insulation element according to the invention has been demonstrated in experiments. The thermal insulation elements used in the tests consisted continuously of a thermal insulation material, wherein the thermal insulation material was prepared according to the following Example or Example 2:

example 1

The thermal insulation material was made from a homogeneous mixture of: 42 g Silica airgel granules with a particle size ≤ 1.2 mm and a bulk density of 85 g / L, 23 g Vinyl acetate-ethylene polymer dispersion having a polymer content of 53 wt .-% and 10 g water produced in a mold with the addition of pressure and heat. The binder content is 3.4% by volume based on the total volume of the thermal insulation material.

Example 2

This thermal insulation material was made from a homogeneous mixture of: 42 g Silica airgel granules with a particle size ≤ 1.2 mm and a bulk density of 85 g / L, 15 g Styrene butyl acrylate polymer dispersion having a polymer content of 50 wt.% And 10 g water produced in a mold with the addition of pressure and heat. The binder content is 1.9% by volume based on the total volume of the thermal insulation material. Furthermore, the pattern was laminated on top and bottom with a non-combustible glass fiber fabric to improve mechanical stability and feel.

As part of the experiments, the fire behavior of this thermal insulation element compared to thermal insulation elements of other thermal insulation materials, namely polystyrene foam, phenolic resin, mineral wool and mineral foam was examined. The dimensions of the patterns were each 300 mm × 300 mm × 20 mm.

The following table shows the examined insulating materials in an overview: insulation Thickness [mm] WLF [W / (mK)] Bulk density [g / L] laminated Building material class DIN 4102-1 Bound Airgel Particles (Example 1) 20 0,017 145 No B2 Bound Airgel Particles (Example 2) 20 0.016 150 Yes B2 Polystyrene foam 20 0.032 17 No B1 phenolic resin 20 0.024 38 Yes B2 mineral wool 20 0,040 100 No A1 mineral foam 20 0,045 110 No A1

For soffit insulation usually polystyrene foam boards or phenolic resin boards are used because they have sufficient inherent stability even in thinner insulation thicknesses. Although a plate made of mineral wool would be more useful for reasons of fire protection, since this is not flammable according to DIN 4102-1, due to the low intrinsic stability mineral wool is usually unsuitable as reveal insulation. To compensate for the stability problem, the plate of mineral wool would have to be additionally secured by means of mechanical fasteners, such as dowels, to the substrate. However, this is usually not possible in the area of a soffit. Due to its classification as building material class A (non-flammable), mineral wool is typically used to form fire barriers in the thermal insulation layer of a thermal insulation composite system. Here, the plates can be made significantly thicker and / or additionally pegged.

First, an experimental set-up was defined to investigate the resistance of the various insulation patterns under direct flame exposure. With a large area, each pattern was placed on a metal stand and exposed from the bottom directly to the rushing mantle flame of a Bunsen burner. In the jacket flame, the temperature was 1000-1200 ° C. Using a digital contact thermometer, the temperature profile on the top of the plate was followed over the plate thickness of 20 mm.

In a first experiment, the flame application was carried out for 5 minutes each. The results are shown in the following table: Time Bound Airgel Particles (Example 1) Polystyrene foam phenolic resin mineral wool [Min] [° C] [° C] [° C] [° C] 0.0 23.0 23.4 23.6 22.9 1.0 26.3 Melting with breakthrough 41.9 42.8 2.0 26.9 107.8 113.9 3.0 43.7 165.5 188.2 4.0 93.1 188.6 207.0

The table shows that with brief direct flame exposure, the temperature on the top of the airgel particle-containing pattern increases relatively slowly compared to the other patterns. The pattern of polystyrene hard foam melts within the first minute. After extinguishing the flame, none of the remaining patterns will burn on their own.

In a second experiment, the flame application was carried out for 45 minutes. The pattern containing bound airgel particles was made according to Example 2, and instead of a pattern of mineral wool, a pattern of mineral foam was examined. The repetition of the test using a pattern made of polystyrene hard foam was omitted, since this insulation failed in the first attempt after a short time.

The results of the second experiment are again shown in the following table: Time Bound Airgel Particles (Example 2) phenolic resin mineral foam [Min] [° C] [° C] [° C] 0.0 22.4 21.6 22.0 0.5 22.5 36.8 24.1 1.0 22.6 65.6 31.6 1.5 23.0 107.7 38.6 2.0 25.1 138.2 43.4 2.5 28.5 158.9 48.8 3.0 32.6 172.6 56.2 3.5 40.1 182.7 64.2 4.0 54.9 189.6 75.3 4.5 73.2 194.5 87.3 5.0 94.9 197.8 94.3 5.5 114.4 201.0 100.8 6.0 130.6 207.0 250.0 6.5 137.6 215.0 803.0 7.0 145.5 225.0 7.5 151.7 246.0 8.0 154.6 285.0 8.5 158.0 406.0 9.0 162.1 615.0 9.5 167.6 748.0 10.0 170.1 903.0 ... 20.0 186.3 ... 30.0 188.0 ... 40.0 204.0 ... 45.0 207.0

From the table it can be seen that with prolonged exposure to flame, the pattern of mineral foam failed first, after about 6 minutes. The sudden increase in temperature from 250 ° C to over 800 ° C resulted in an insulation breakage. A similar behavior was observed in the pattern of phenolic resin, with the breakage of the insulation after about 9-10 minutes due to a sudden rise in temperature to over 900 ° C. The pattern of bound airgel particles withstood the stress, in particular, no similar sudden increase in temperature could be observed. In addition, the temperature only rose to 207 ° C.

The behavior of the insulating materials in the second experiment is clearly shown in the graph of the attached figure. It shows the temperature curve on top of the respective sample (in ° C) over time (duration of flame application in minutes). The crosses indicate the values for the pattern of mineral foam, the squares the values for the pattern of phenolic resin and the diamonds for the values of the airgel particle and binder containing pattern, each firing a pattern of plate thickness 20 mm. The graph clearly shows the sudden increase in temperature in the samples of mineral foam and phenolic resin, while the temperature increase in the other pattern was limited to about 200 ° C and held over a period of about 30 minutes. The first steep slope of the curve associated with the pattern of phenolic resin illustrates the breakthrough of the first cladding layer and the second steep slope the breakthrough of the second cladding layer. The pattern of mineral foam suffered a complete breakthrough while the pattern of bound airgel particles showed only a breakthrough in the area of the first liner that was in direct contact with the burner flame.

The invention is not limited to the thermal insulation materials or thermal insulation elements used during the tests. In addition to the samples studied, the thermal insulation material contained in the thermal insulation element can also be made of other compositions. In addition, a lamination with a non-flammable tissue is not mandatory (see also Example 1). However, such a lamination can make a contribution to the mechanical stability of the thermal insulation element, so that it is further improved. In addition, the feel is improved by an outside mounted lamination. The lamination is preferably placed in the mold immediately with the mold and pressed, wherein the binder content of the mixture introduced into the mold, the composite of the fabric with the Guaranteed thermal insulation element. On an additional bond can be dispensed with in this way.

Another possible composition for producing a heat insulating material containing a thermal insulation element according to the invention is mentioned below:

Example 3

40 g

Silica airgel granules with a particle size ≤ 1.2 mm and a bulk density of 85 g / L,

10 g

aqueous pure acrylate polymer dispersion having a polymer content of 50 wt .-% and

10 g

water

Are mixed homogeneously and shaped in a mold with the addition of pressure and heat. The bulk density of the thermal insulation material obtained in this way is 125 g / L and the thermal conductivity is 0.016 W / (mK). The binder content is 1.4% by volume, based on the total volume of the thermal insulation material. A thermal insulation element made of this thermal insulation material can also be used as a fire barrier.

Claims (14)

Thermal insulation composite system with a mounted on an outer side of a building exterior wall single or multi-layer thermal insulation layer and a single or multi-layer plaster layer applied thereto, wherein the thermal barrier coating at least one thermal insulation panel made of a rigid foam, in particular of a polystyrene foam, and at least one plate or profile-shaped thermal insulation element Includes training a fire barrier,
characterized in that the fire barrier forming, plate - or profile-shaped thermal insulation element comprises a thermal insulation material containing airgel particles and at least one water-based organic and / or inorganic binder and a thermal conductivity ≤ 0.028 W / (mK), preferably < 0.025 W / ( mK), furthermore preferably ≤ 0.022 W / (mK). Thermal insulation composite system according to claim 1,
characterized in that the fire barrier forming, plate - or profile-shaped thermal insulation element in the region of an opening of the building exterior wall, in particular above and / or laterally of the opening is arranged. Thermal insulation composite system according to claim 1 or 2,
characterized in that the fire barrier forming, plate - or profile-shaped thermal insulation element on a substantially perpendicular to the outside of the building exterior wall extending surface, in particular a lintel or soffit surface, is arranged. Thermal insulation composite system according to one of the preceding claims,
characterized in that the fire barrier forming, plate - or profile-shaped thermal insulation element has a flush with the outside of the single or multi-layer thermal barrier coating final upper or side surface. Can be used as a fire barrier in a thermal insulation composite system according to one of the preceding claims, plate-shaped or profile-shaped thermal insulation element,
characterized in that the thermal insulation element comprises a thermal insulation material containing airgel particles and at least one water-based organic and / or inorganic binder and a thermal conductivity < 0.028 W / (mK), preferably < 0.025 W / (mK), further preferably < 0.022 W. / (mK), owns. Thermal insulation element according to claim 5,
characterized in that the binder content contained in the thermal insulation material is less than 5 vol .-%, preferably less than 3 vol .-%, more preferably less than 2 vol .-% based on the total volume of the thermal insulation material. Thermal insulation element according to claim 5 or 6,
characterized in that the Gesamtzwickelvolumen formed between the airgel particles less than 35 vol .-%, preferably less than 25 vol .-%, more preferably less than 20 vol .-%, based on the total volume of the thermal insulation material. Thermal insulation element according to one of claims 5 to 7,
characterized in that the water content of the water-based organic and / or inorganic binder contained is at least 50 wt .-% based on the total weight of the binder. Thermal insulation element according to one of claims 5 to 8,
characterized in that the water-based organic binder is a water-based thermosetting binder such as epoxy resin or polyurethane, and / or a dispersion binder based on thermoplastic vinyl acetate, acrylate, styrene acrylate or styrene butyl acrylate polymers or other polymer dispersion. Thermal insulation element according to one of claims 5 to 9,
characterized in that the water-based inorganic binder is soda or potassium silicate. Thermal insulation element according to one of claims 5 to 10,
characterized in that at least a portion of the contained airgel particles consists of airgel recyclate. Thermal insulation element according to one of claims 5 to 11,
characterized in that the plate or profile-shaped thermal insulation element is made continuously from the airgel particles and at least one water-based organic and / or inorganic binder containing thermal insulation material. Thermal insulation element according to one of claims 5 to 12,
characterized in that at least one top and / or side surface is provided with a lamination, wherein the lamination preferably comprises at least one flame-retardant or non-combustible tissue. Use of a plate or profile-shaped thermal insulation element according to one of claims 5 to 13 as a fire barrier in a thermal insulation system with a mounted on an outer side of a building exterior wall single or multi-layer thermal barrier coating and a single or multi-layered plaster layer applied thereto, wherein the thermal barrier coating at least one thermal insulation panel of a Hard foam, in particular comprising a polystyrene foam.

Images